Methods and systems for analyzing nucleic acid molecules

Information

  • Patent Grant
  • 11965215
  • Patent Number
    11,965,215
  • Date Filed
    Friday, February 10, 2023
    a year ago
  • Date Issued
    Tuesday, April 23, 2024
    7 months ago
Abstract
Processes and materials to detect cancer from a biopsy are described. In some cases, cell-free nucleic acids can be sequenced, and the sequencing result can be utilized to detect sequences derived from a neoplasm. Detection of somatic variants occurring in phase can indicate the presence of cancer in a diagnostic scan and a clinical intervention can be performed.
Description
SEQUENCE LISTING

The instant application contains a Sequence Listing which has been submitted electronically in XML file format and is hereby incorporated by reference in its entirety. Said XML copy, created on Aug. 11, 2022, is named 58626-702_601_SL.xml and is 1,304,877 bytes in size.


BACKGROUND

Noninvasive blood tests that can detect somatic alterations (e.g., mutated nucleic acids) based on the analysis of cell-free nucleic acids (e.g., cell-free deoxyribonucleic acid (cfDNA) and cell-free ribonucleic acid (cfRNA)) are attractive candidates for cancer screening applications due to the relative ease of obtaining biological specimens (e.g., biological fluids). Circulating tumor nucleic acids (e.g., ctDNA or ctRNA; i.e., nucleic acids derived from cancerous cells) can be sensitive and specific biomarkers in numerous cancer subtypes. However, current methods for minimal residual disease (MRD) detection from ctDNA can be limited by one or more factors, such as low input DNA amounts and high background error rates.


Recent approaches have improved ctDNA MRD performance by tracking multiple somatic mutations with error-suppressed sequencing, resulting in detection limits as low as 4 parts in 100,000 from limited cfDNA input. Detection of residual disease during or after treatment is a powerful tool, with detectable MRD representing an adverse prognostic sign even during radiographic remission. However, current limits of detection may be insufficient to universally detect residual disease in patients destined for disease relapse or progression. This ‘loss of detection’ is exemplified in diffuse large B-cell lymphoma (DLBCL), where ctDNA detection after two cycles of curative-intent therapy is a strong prognostic marker. Despite this, almost one-third of patients experiencing disease progression do not have detectable ctDNA at this landmark, representing ‘false-negative’ tests. Similar false-negative rates in colon cancer and breast cancer have been observed.


SUMMARY

The present disclosure provides methods and systems for analyzing cell-free nucleic acids (e.g., cfDNA, cfRNA) from a subject. Methods and systems of the present disclosure can utilize sequencing results derived from the subject to detect cancer-derived nucleic acids (e.g., ctDNA, ctRNA) for, e.g., disease diagnosis, disease monitoring, or determining treatments for the subject. Methods and systems of the present disclosure can exhibit enhanced sensitivity, specificity and/or reliability of detection of cancer-derived nucleic acids.


In one aspect, the present disclosure provides a method comprising: (a) obtaining, by a computer system, sequencing data derived from a plurality of cell-free nucleic acid molecules that is obtained or derived from a subject; (b) processing, by the computer system, the sequencing data to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules, wherein each of the one or more cell-free nucleic acid molecules comprises a plurality of phased variants relative to a reference genomic sequence, wherein at least about 10% of the one or more cell-free nucleic acid molecules comprises a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants that are separated by at least one nucleotide; and (c) analyzing, by the computer system, the identified one or more cell-free nucleic acid molecules to determine a condition of the subject.


In some embodiments of any one of the methods disclosed herein, the at least about 10% of the cell-free nucleic acid molecules comprise at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, at least about 90%, or about 100% of the one or more cell-free nucleic acid molecules.


In one aspect, the present disclosure provides a method comprising: (a) obtaining, by a computer system, sequencing data derived from a plurality of cell-free nucleic acid molecules that is obtained or derived from a subject; (b) processing, by the computer system, the sequencing data to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules, wherein each of the one or more cell-free nucleic acid molecules comprises a plurality of phased variants relative to a reference genomic sequence that are separated by at least one nucleotide; and (c) analyzing, by the computer system, the identified one or more cell-free nucleic acid molecules to determine a condition of the subject.


In one aspect, the present disclosure provides a method comprising: (a) obtaining sequencing data derived from a plurality of cell-free nucleic acid molecules that is obtained or derived from a subject; (b) processing the sequencing data to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules with a limit of detection of less than about 1 out of 50,000 observations from the sequencing data; and (c) analyzing the identified one or more cell-free nucleic acid molecules to determine a condition of the subject.


In some embodiments of any one of the methods disclosed herein, the limit of detection of the identification step is less than about 1 out of 100,000, less than about 1 out of 500,000, less than about 1 out of 1,000,000, less than about 1 out of 1,500,000, or less than about 1 out of 2,000,000 observations from the sequencing data.


In some embodiments of any one of the methods disclosed herein, each of the one or more cell-free nucleic acid molecules comprises a plurality of phased variants relative to a reference genomic sequence. In some embodiments of any one of the methods disclosed herein, a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants are separated by at least one nucleotide.


In some embodiments of any one of the methods disclosed herein, the processes (a) to (c) are performed by a computer system.


In some embodiments of any one of the methods disclosed herein, the sequencing data is generated based on nucleic acid amplification. In some embodiments of any one of the methods disclosed herein, the sequencing data is generated based on polymerase chain reaction. In some embodiments of any one of the methods disclosed herein, the sequencing data is generated based on amplicon sequencing.


In some embodiments of any one of the methods disclosed herein, the sequencing data is generated based on next-generation sequencing (NGS). Alternatively, in some embodiments of any one of the methods disclosed herein, the sequencing data is generated based on non-hybridization-based NGS.


In some embodiments of any one of the methods disclosed herein, the sequencing data is generated without use of molecular barcoding of at least a portion of the plurality of cell-free nucleic acid molecules. In some embodiments of any one of the methods disclosed herein, the sequencing data is obtained without use of sample barcoding of at least a portion of the plurality of cell-free nucleic acid molecules.


In some embodiments of any one of the methods disclosed herein, the sequencing data is obtained without in silico removal or suppression of (i) background error or (ii) sequencing error.


In one aspect, the present disclosure provides a method of treating a condition of a subject, the method comprising: (a) identifying the subject for treatment of the condition, wherein the subject has been determined to have the condition based on identification of one or more cell-free nucleic acid molecules from a plurality of cell-free nucleic acid molecules that is obtained or derived from the subject, wherein each of the one or more cell-free nucleic acid molecules identified comprises a plurality of phased variants relative to a reference genomic sequence that are separated by at least one nucleotide, and wherein a presence of the plurality of phased variants is indicative of the condition of the subject; and (b) subjecting the subject to the treatment based on the identification in (a).


In one aspect, the present disclosure provides a method of monitoring a progress of a condition of a subject, the method comprising: (a) determining a first state of the condition of the subject based on identification of a first set of one or more cell-free nucleic acid molecules from a first plurality of cell-free nucleic acid molecules that is obtained or derived from the subject; (b) determining a second state of the condition of the subject based on identification of a second set of one or more cell-free nucleic acid molecules from a second plurality of cell-free nucleic acid molecules that is obtained or derived from the subject, wherein the second plurality of cell-free nucleic acid molecules are obtained from the subject subsequent to obtaining the first plurality of cell-free nucleic acid molecules from the subject; and (c) determining the progress of the condition based on the first state of the condition and the second state of the condition, wherein each of the one or more cell-free nucleic acid molecules comprises a plurality of phased variants relative to a reference genomic sequence that are separated by at least one nucleotide.


In some embodiments of any one of the methods disclosed herein, the progress of the condition is worsening of the condition.


In some embodiments of any one of the methods disclosed herein, the progress of the condition is at least a partial remission of the condition.


In some embodiments of any one of the methods disclosed herein, a presence of the plurality of phased variants is indicative of the first state or the second state of the condition of the subject.


In some embodiments of any one of the methods disclosed herein, the second plurality of cell-free nucleic acid molecules is obtained from the subject at least about 1 week, at least about 2 weeks, at least about 3 weeks, at least about 4 weeks, at least about 2 months, or at least about 3 months subsequent to obtaining the first plurality of cell-free nucleic acid molecules from the subject.


In some embodiments of any one of the methods disclosed herein, the subject is subjected to a treatment for the condition (i) prior to obtaining the second plurality of cell-free nucleic acid molecules from the subject and (ii) subsequent to obtaining the first plurality of cell-free nucleic acid molecules from the subject.


In some embodiments of any one of the methods disclosed herein, the progress of the condition is indicative of minimal residual disease of the condition of the subject. In some embodiments of any one of the methods disclosed herein, the progress of the condition is indicative of tumor burden or cancer burden of the subject.


In some embodiments of any one of the methods disclosed herein, the one or more cell-free nucleic acid molecules are captured from among the plurality of cell-free nucleic acid molecules with a set of nucleic acid probes, wherein the set of nucleic acid probes is configured to hybridize to at least a portion of cell-free nucleic acid molecules comprising one or more genomic regions associated with the condition.


In one aspect, the present disclosure provides a method comprising: (a) providing a mixture comprising (1) a set of nucleic acid probes and (2) a plurality of cell-free nucleic acid molecules that is obtained or derived from a subject, wherein an individual nucleic acid probe of the set of nucleic acid probes is designed to hybridize to at least a portion of a target cell-free nucleic acid molecule comprising a plurality of phased variants relative to a reference genomic sequence that are separated by at least one nucleotide, and wherein the individual nucleic acid probe comprises an activatable reporter agent, activation of the activatable reporter agent being selected from the group consisting of: (i) hybridization of the individual nucleic acid probe to the plurality of phased variants and (ii) dehybridization of at least a portion of the individual nucleic acid probe that has been hybridized to the plurality of phased variants; (b) detecting the activatable reporter agent that is activated, to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules, wherein each of the one or more cell-free nucleic acid molecules comprises the plurality of phased variants; and (c) analyzing the identified one or more cell-free nucleic acid molecules to determine a condition of the subject.


In one aspect, the present disclosure provides a method comprising: (a) providing a mixture comprising (1) a set of nucleic acid probes and (2) a plurality of cell-free nucleic acid molecules that is obtained or derived from a subject, wherein an individual nucleic acid probe of the set of nucleic acid probes is designed to hybridize to at least a portion of a target cell-free nucleic acid molecule comprising a plurality of phased variants relative to a reference genomic sequence, and wherein the individual nucleic acid probe comprises an activatable reporter agent, activation of the activatable reporter agent being selected from the group consisting of: (i) hybridization of the individual nucleic acid probe to the plurality of phased variants and (ii) dehybridization of at least a portion of the individual nucleic acid probe that has been hybridized to the plurality of phased variants; (b) detecting the activatable reporter agent that is activated, to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules, wherein each of the one or more cell-free nucleic acid molecules comprises the plurality of phased variants, wherein a limit of detection of the identification step is less than about 1 out of 50,000 cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules; and (c) analyzing the identified one or more cell-free nucleic acid molecules to determine a condition of the subject.


In some embodiments of any one of the methods disclosed herein, the limit of detection of the identification step is less than about 1 out of 100,000, less than about 1 out of 500,000, less than about 1 out of 1,000,000, less than about 1 out of 1,500,000, or less than about 1 out of 2,000,000 cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules.


In some embodiments of any one of the methods disclosed herein, a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants are separated by at least one nucleotide.


In some embodiments of any one of the methods disclosed herein, the activatable reporter agent is activated upon hybridization of the individual nucleic acid probe to the plurality of phased variants.


In some embodiments of any one of the methods disclosed herein, the activatable reporter agent is activated upon dehybridization of at least a portion of the individual nucleic acid probe that has been hybridized to the plurality of phased variants.


In some embodiments of any one of the methods disclosed herein, the method further comprises mixing (1) the set of nucleic acid probes and (2) the plurality of cell-free nucleic acid molecules.


In some embodiments of any one of the methods disclosed herein, the activatable reporter agent is a fluorophore.


In some embodiments of any one of the methods disclosed herein, analyzing the identified one or more cell-free nucleic acid molecules comprises analyzing (i) the identified one or more cell-free nucleic acid molecules and (ii) other cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules that do not comprise the plurality of phased variants as different variables.


In some embodiments of any one of the methods disclosed herein, the analyzing of the identified one or more cell-free nucleic acid molecules is not based on other cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules that do not comprise the plurality of phased variants.


In some embodiments of any one of the methods disclosed herein, a number of the plurality of phased variants from the identified one or more cell-free nucleic acid molecules is indicative of the condition of the subject. In some embodiments, a ratio of (i) the number of the plurality of phased variants from the one or more cell-free nucleic acid molecules and (ii) a number of single nucleotide variants (SNVs) from the one or more cell-free nucleic acid molecules is indicative of the condition of the subject.


In some embodiments of any one of the methods disclosed herein, a frequency of the plurality of phased variants in the identified one or more cell-free nucleic acid molecules is indicative of the condition of the subject. In some embodiments, the frequency is indicative of a diseased cell associated with the condition. In some embodiments, the condition is diffuse large B-cell lymphoma, and wherein the frequency is indicative of whether the one or more cell-free nucleic acid molecules are derived from germinal center B-cell (GCB) or activated B-cell (ABC).


In some embodiments of any one of the methods disclosed herein, genomic origin of the identified one or more cell-free nucleic acid molecules is indicative of the condition of the subject.


In some embodiments of any one of the methods disclosed herein, the first and second phased variants are separated by at least 2, at least 3, at least 4, at least 5, at least 6, at least 7, or at least 8 nucleotides. In some embodiments of any one of the methods disclosed herein, the first and second phased variants are separated by at most about 180, at most about 170, at most about 160, at most about 150, or at most about 140 nucleotides.


In some embodiments of any one of the methods disclosed herein, at least about 10%, at least about 20%, at least about 30%, at least about 40%, or at least about 50% of the one or more cell-free nucleic acid molecules comprising a plurality of phased variants comprises a single nucleotide variant (SNV) that is at least 2 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, the plurality of phased variants comprises at least 3, at least 4, at least 5, at least 10, at least 15, at least 20, or at least 25 phased variants within the same cell-free nucleic acid molecule.


In some embodiments of any one of the methods disclosed herein, the one or more cell-free nucleic acid molecules identified comprises at least 2, at least 3, at least 4, at least 5, at least 10, at least 50, at least 100, at least 500, or at least 1,000 cell-free nucleic acid molecules.


In some embodiments of any one of the methods disclosed herein, the reference genomic sequence is derived from a reference cohort. In some embodiments, the reference genomic sequence comprises a consensus sequence from the reference cohort. In some embodiments, the reference genomic sequence comprises at least a portion of hg19 human genome, hg18 genome, hg17 genome, hg16 genome, or hg38 genome.


In some embodiments of any one of the methods disclosed herein, the reference genomic sequence is derived from a sample of the subject.


In some embodiments of any one of the methods disclosed herein, the sample is a healthy sample. In some embodiments, the sample comprises a healthy cell. In some embodiments, the healthy cell comprises a healthy leukocyte.


In some embodiments of any one of the methods disclosed herein, the sample is a diseased sample. In some embodiments, the diseased sample comprises a diseased cell. In some embodiments, the diseased cell comprises a tumor cell. In some embodiments, the diseased sample comprises a solid tumor.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes is designed based on the plurality of phased variants that are identified by comparing (i) sequencing data from a solid tumor, lymphoma, or blood tumor of the subject and (ii) sequencing data from a healthy cell of the subject or a healthy cohort. In some embodiments, the healthy cell is from the subject. In some embodiments, the healthy cell is from the healthy cohort.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes are designed to hybridize to at least a portion of sequences of genomic loci associated with the condition. In some embodiments, the genomic loci associated with the condition are known to exhibit aberrant somatic hypermutation when the subject has the condition.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes are designed to hybridize to at least about 5%, at least about 10%, at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, at least about 90%, or about 100% of (i) the genomic regions identified in Table 1, (ii) the genomic regions identified in Table 3, or (iii) the genomic regions identified to have a plurality of phased variants in Table 3.


In some embodiments of any one of the methods disclosed herein, each nucleic acid probe of the set of nucleic acid probes has at least about 70%, at least about 80%, at least about 90% sequence identity, at least about 95% sequence identity, or about 100% sequence identity to a probe sequence selected from Table 6.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes comprises at least about 5%, at least about 10%, at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, or at least about 90% of probe sequences in Table 6.


In some embodiments of any one of the methods disclosed herein, the method further comprises determining that the subject has the condition or determining a degree or status of the condition of the subject, based on the identified one or more cell-free nucleic acid molecules comprising the plurality of phased variants. In some embodiments, the method further comprises determining that the one or more cell-free nucleic acid molecules are derived from a sample associated with the condition, based on performing a statistical model analysis of the identified one or more cell-free nucleic acid molecules. In some embodiments, the statistical model analysis comprises a Monte Carlo statistical analysis.


In some embodiments of any one of the methods disclosed herein, the method further comprises monitoring a progress of the condition of the subject based on the identified one or more cell-free nucleic acid molecules.


In some embodiments of any one of the methods disclosed herein, the method further comprises performing a different procedure to confirm the condition of the subject. In some embodiments, the different procedure comprises a blood test, genetic test, medical imaging, physical exam, or tissue biopsy.


In some embodiments of any one of the methods disclosed herein, the method further comprises determining a treatment for the condition of the subject based on the identified one or more cell-free nucleic acid molecules.


In some embodiments of any one of the methods disclosed herein, the subject has been subjected to a treatment for the condition prior to (a).


In some embodiments of any one of the methods disclosed herein, the treatment comprises chemotherapy, radiotherapy, chemoradiotherapy, immunotherapy, adoptive cell therapy, hormone therapy, targeted drug therapy, surgery, transplant, transfusion, or medical surveillance.


In some embodiments of any one of the methods disclosed herein, the plurality of cell-free nucleic acid molecules comprise a plurality of cell-free deoxyribonucleic acid (DNA) molecules.


In some embodiments of any one of the methods disclosed herein, condition comprises a disease.


In some embodiments of any one of the methods disclosed herein, the plurality of cell-free nucleic acid molecules are derived from a bodily sample of the subject. In some embodiments, the bodily sample comprises plasma, serum, blood, cerebrospinal fluid, lymph fluid, saliva, urine, or stool.


In some embodiments of any one of the methods disclosed herein, the subject is a mammal. In some embodiments of any one of the methods disclosed herein, the subject is a human.


In some embodiments of any one of the methods disclosed herein, the condition comprises neoplasm, cancer, or tumor. In some embodiments, the condition comprises a solid tumor. In some embodiments, the condition comprises a lymphoma. In some embodiments, the condition comprises a B-cell lymphoma. In some embodiments, the condition comprises a sub-type of B-cell lymphoma selected from the group consisting of diffuse large B-cell lymphoma, follicular lymphoma, Burkitt lymphoma, and B-cell chronic lymphocytic leukemia.


In some embodiments of any one of the methods disclosed herein, the plurality of phased variants have been previously identified as tumor-derived from sequencing a prior tumor sample or cell-free nucleic acid sample.


In one aspect, the present disclosure provides a composition comprising a bait set comprising a set of nucleic acid probes designed to capture cell-free DNA molecules derived from at least about 5% of genomic regions set forth in (i) the genomic regions identified in Table 1, (ii) the genomic regions identified in Table 3, or (iii) the genomic regions identified to have a plurality of phased variants in Table 3.


In some embodiments of any of the compositions disclosed herein, the set of nucleic acid probes are designed to pull down cell-free DNA molecules derived from at least about 10%, at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, at least about 90%, or about 100% of the genomic regions set forth in (i) the genomic regions identified in Table 1, (ii) the genomic regions identified in Table 3, or (iii) the genomic regions identified to have a plurality of phased variants in Table 3.


In some embodiments of any of the compositions disclosed herein, the set of nucleic acid probes are designed to capture the one or more cell-free DNA molecules derived from at most about 10%, at most about 20%, at most about 30%, at most about 40%, at most about 50%, at most about 60%, at most about 70%, at most about 80%, at most about 90%, or about 100% of the genomic regions set forth in (i) the genomic regions identified in Table 1, (ii) the genomic regions identified in Table 3, or (iii) the genomic regions identified to have a plurality of phased variants in Table 3.


In some embodiments of any of the compositions disclosed herein, the bait set comprises at most 5, at most 10, at most 50, at most 100, at most 500, at most 1000, or at most 2000 nucleic acid probes.


In some embodiments of any of the compositions disclosed herein, an individual nucleic acid probe of the set of nucleic acid probes comprises a pull-down tag.


In some embodiments of any of the compositions disclosed herein, the pull-down tag comprises a nucleic acid barcode.


In some embodiments of any of the compositions disclosed herein, the pull-down tag comprises biotin.


In some embodiments of any of the compositions disclosed herein, each of the cell-free DNA molecules is between about 100 nucleotides and about 180 nucleotides in length.


In some embodiments of any of the compositions disclosed herein, the genomic regions are associated with a condition.


In some embodiments of any of the compositions disclosed herein, the genomic regions exhibit aberrant somatic hypermutation when a subject has the condition.


In some embodiments of any of the compositions disclosed herein, the condition comprises a B-cell lymphoma. In some embodiments, the condition comprises a sub-type of B-cell lymphoma selected from the group consisting of diffuse large B-cell lymphoma, follicular lymphoma, Burkitt lymphoma, and B-cell chronic lymphocytic leukemia.


In some embodiments of any of the compositions disclosed herein, the composition further comprises a plurality of cell-free DNA molecules obtained or derived from a subject.


In one aspect, the present disclosure provides a method to perform a clinical procedure on an individual, the method comprising: (a) obtaining or having obtained a targeted sequencing result of a collection of cell-free nucleic acid molecules, wherein the collection of cell-free nucleic acid molecules are sourced from a liquid or waste biopsy of an individual, and wherein the targeting sequencing is performed utilizing nucleic acid probes to pull down sequences of genomic loci known to experience aberrant somatic hypermutation in a B-cell cancer; (b) identifying or having identified a plurality of variants in phase within the cell-free nucleic acid sequencing result; (c) determining or having determined, utilizing a statistical model and the identified phased variants, that the cell-free nucleic acid sequencing result contains nucleotides derived from a neoplasm; and (d) performing a clinical procedure on the individual to confirm the presence of the B-cell cancer, based upon determining that the cell-free nucleic acid sequencing result contains nucleic acid sequences likely derived from the B-cell cancer.


In some embodiments of any of the compositions disclosed herein, the biopsy is one of blood, serum, cerebrospinal fluid, lymph fluid, urine, or stool.


In some embodiments of any of the compositions disclosed herein, the genomic loci are selected from (i) the genomic regions identified in Table 1, (ii) the genomic regions identified in Table 3, or (iii) the genomic regions identified to have a plurality of phased variants in Table 3.


In some embodiments of any of the compositions disclosed herein, the sequences of the nucleic acid probes are selected from Table 6.


In some embodiments of any of the compositions disclosed herein, the clinical is procedure is a blood test, medical imaging, or a physical exam.


In one aspect, the present disclosure provides a method to treat an individual for a B-cell cancer, the method comprising: (a) obtaining or having obtained a targeted sequencing result of a collection of cell-free nucleic acid molecules, wherein the collection of cell-free nucleic acid molecules are sourced from a liquid or waste biopsy of an individual, and wherein the targeting sequencing is performed utilizing nucleic acid probes to pull down sequences of genomic loci known to experience aberrant somatic hypermutation in a B-cell cancer; (b) identifying or having identified a plurality of variants in phase within the cell-free nucleic acid sequencing result; (c) determining or having determined, utilizing a statistical model and the identified phased variants, that the cell-free nucleic acid sequencing result contains nucleotides derived from a neoplasm; and (d) treating the individual to curtail the B-cell cancer, based upon determining that the cell-free nucleic acid sequencing result contains nucleic acid sequences derived from the B-cell cancer.


In some embodiments of any of the compositions disclosed herein, the biopsy is one of blood, serum, cerebrospinal fluid, lymph fluid, urine or stool.


In some embodiments of any of the compositions disclosed herein, the genomic loci are selected from (i) the genomic regions identified in Table 1, (ii) the genomic regions identified in Table 3, or (iii) the genomic regions identified to have a plurality of phased variants in Table 3.


In some embodiments of any of the compositions disclosed herein, the sequences of the nucleic acid probes are selected from Table 6.


In some embodiments of any of the compositions disclosed herein, the treatment is chemotherapy, radiotherapy, immunotherapy, hormone therapy, targeted drug therapy, or medical surveillance.


In one aspect, the present disclosure provides a method to detect cancerous minimal residual disease in an individual and to treat the individual for a cancer, the method comprising: (a) obtaining or having obtained a targeted sequencing result of a collection of cell-free nucleic acid molecules, wherein the collection of cell-free nucleic acid molecules are sourced from a liquid or waste biopsy of an individual, wherein the liquid or waste biopsy is sourced after a series of treatments in order to detect minimal residual disease, and wherein the targeting sequencing is performed utilizing nucleic acid probes to pull down sequences of genomic loci determined to contain a plurality of variants in phase, as determined by a prior sequencing result on a prior biopsy derived from the cancer; (b) identifying or having identified at least one set of the plurality of variants in phase within the cell-free nucleic acid sequencing result; and (c) treating the individual to curtail the cancer, based upon determining that the cell-free nucleic acid sequencing result contains nucleic acid sequences derived from the cancer.


In some embodiments of any of the compositions disclosed herein, the liquid or waste biopsy is one of blood, serum, cerebrospinal fluid, lymph fluid, urine or stool.


In some embodiments of any of the compositions disclosed herein, the treatment is chemotherapy, radiotherapy, immunotherapy, hormone therapy, targeted drug therapy, or medical surveillance.


In one aspect, the present disclosure provides a computer program product comprising a non-transitory computer-readable medium having computer-executable code encoded therein, the computer-executable code adapted to be executed to implement any one of the methods disclosed herein.


In one aspect, the present disclosure provides a system comprising one or more computer processors and computer memory coupled thereto, wherein the computer memory comprises machine executable code that, upon execution by the one or more computer processors, implements any one of the methods disclosed herein.


Additional aspects and advantages of the present disclosure will become readily apparent to those skilled in this art from the following detailed description, wherein only illustrative embodiments of the present disclosure are shown and described. As will be realized, the present disclosure is capable of other and different embodiments, and its several details are capable of modifications in various obvious respects, all without departing from the disclosure. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.


INCORPORATION BY REFERENCE

All publications, patents, and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication, patent, or patent application was specifically and individually indicated to be incorporated by reference. To the extent publications and patents or patent applications incorporated by reference contradict the disclosure contained in the specification, the specification is intended to supersede and/or take precedence over any such contradictory material.





BRIEF DESCRIPTION OF THE DRAWINGS

Various features of the invention are set forth with particularity in the appended claims. A better understanding of the features and advantages of the present invention will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the invention are utilized, and the accompanying drawings (also “Figure” and “FIG.” herein), of which:



FIGS. 1A-1E illustrate discovery of phased variants and their mutational signatures via analysis of whole-genome sequencing data. FIG. 1A. is a cartoon depicting the difference between detection of a single nucleotide variant (SNV) (top) and multiple variants ‘in-phase’ (phased variants, PVs; bottom) on individual cell-free DNA molecules. In theory, detection of a PV is a more specific event than detection of an isolated SNV. FIG. 1B. is a scatter plot showing the distribution of the number of PVs from WGS data for 24 different histologies of cancer, normalized by the total number of SNVs. Bars show the median value and interquartile range. (FL-NHL, follicular lymphoma; DLBCL-NHL, diffuse large B-cell lymphoma; Burkitt-NHL, Burkitt lymphoma; Lung-SCC, squamous cell lung cancer; Lung-Adeno, lung adenocarcinoma; Kidney-RCC, renal cell carcinoma; Bone-Osteosarc, osteosarcoma; Liver-HCC, hepatocellular carcinoma; Breast-Adeno, breast adenocarcinoma; Panc-Adeno, pancreatic adenocarcinoma; Head-SCC, head and neck squamous cell carcinoma; Ovary-Adeno, ovarian adenocarcinoma; Eso-Adeno, esophageal adenocarcinoma; Uterus-Adeno, uterine adenocarcinoma; Stomach-Adeno, stomach adenocarcinoma; CLL, chronic lymphocytic leukemia; ColoRect-Adeno, colorectal adenocarcinoma; Prost-Adeno, prostate adenocarcinoma; CNS-GBM, glioblastoma multiforme; Panc-Endocrine, pancreatic neuroendocrine tumor; Thy-Adeno, thyroid adenocarcinoma; CNS-PiloAstro, piloastrocytoma; CNS-Medullo, medulloblastoma.) FIG. 1C. is a heatmap demonstrating the enrichment in single base substitution (SBS) mutational signatures for PVs versus single SNVs across multiple cancer types. Blue represents signatures which are enriched in PVs in specific histologies; darker gray represents signatures where un-phased, single SNVs are enriched; and red represents SNVs occurring in isolation. Only signatures which have a significant difference between PVs and unphased SNVs after correcting for multiple hypotheses are shown; other signatures are grey. Signatures associated with smoking, AID/AICDA, and APOBEC are indicated. FIG. 1D. demonstrate bar plots showing the distribution of PVs occurring in stereotyped regions across the genome in B-lymphoid malignancies and lung adenocarcinoma. In this plot, the genome was divided into 1000 bp bins, and the fraction of samples of a given histology with a PV in each 1000 bp bin was calculated. Only bins that have at least a 2 percent recurrence frequency in any cancer subtype are shown. Key genomic loci are also labeled. FIG. 1E. is a comparison of duplex sequencing to phased variant sequencing. A schema comparing error-suppressed sequencing by duplex sequencing vs. recovery of phased variants. In duplex sequencing, recovery of a single SNV observed on both strands of an original DNA double-helix (i.e., in trans) is required. This requires independent recovery of two molecules by sequencing as the plus and minus strands of the original DNA molecule go through library preparation and PCR independently. In contrast, recovery of PVs requires multiple SNVs observed on the same single strand of DNA (i.e., in cis). Thus, recovery of only the plus or the minus strand (rather than both) is sufficient for identification of PVs.



FIGS. 2A-2F illustrate design, validation, and application of phased variant enrichment sequencing. FIG. 2A is a schematic of the design for PhasED-Seq. WGS data from DLBCL tumor samples were aggregated (left), and areas of recurrent putative PVs were identified (middle). An assay capturing the genomic regions most recurrently containing PVs was then designed (right), resulting in an ˜7500× enrichment in PVs compared to WGS. The top right panel shows the in silico expected number of PVs per case per kilobase of panel size (y-axis) for increasing panel sizes (x-axis). The dashed line shows the selected regions in the PhasED-Seq panel. The bottom right panel shows the total number of expected PVs per case (y-axis, assessed in silico from WGS data, for increasing panel sizes (y-axis). The dark area shows the selected regions in the PhasED-Seq panel. FIG. 2B illustrate two panels showing the yield of SNVs (left) and PVs (right) for sequencing tumor DNA and matched germline by a previously established lymphoma CAPP-Seq panel or PhasED-Seq; values are assessed in silico by limiting WGS to the targeted space of interest. PVs reported in the right panel include doublet, triplet, and quadruplet phased events. FIG. 2C shows the yield of SNVs (left) and PVs (right) from experimental sequencing of tumor and/or cell-free DNA from CAPP-Seq versus PhasED-Seq, similar to FIG. 2B. FIG. 2D is a scatterplot showing the frequency of PVs by genomic location (in 1000 bp bins) for patients with DLBCL, identified either by WGS or identified by PhasED-Seq. PVs in IGH, BCL2, MYC, and BCL6 are highlighted. FIG. 2E illustrate scatterplots comparing the frequency of PVs by genomic location (in 50 bp bins) for patients with different types of lymphomas. The colored circles show the relative frequency of PVs in 50 bp bins from a specific gene of interest; the other (gray) circles show the relative frequency of PVs in 50 bp bins from the remainder of the PhasED-Seq sequencing panel. FIG. 2F illustrate volcano plots summarizing the difference in relative frequency of PVs in specific genetic loci between types of lymphoma, including ABC-DLBCL vs. GCB-DLBCL (dark Gray, left); PMBCL vs DLBCL (dark gray, middle); and HL vs. DLBCL (dark gray, right). The x-axis demonstrates the relative enrichment in PVs in a specific locus, while the y-axis demonstrates the statistical significance of this association. (Example 10).



FIGS. 3A-3I illustrate technical performance of PhasED-Seq for disease detection. FIG. 3A illustrates bar plot showing the performance of hybrid capture sequencing for recovery of synthetic 150 bp oligonucleotides from two loci (MYC and BCL6) with increasing degree of mutation/non-reference bases. Error bars represent the 95% confidence interval (n=3 replicates of each condition in distinct samples). FIG. 3B illustrates plot demonstrating the background error-rate (Example 10) for different types of error-suppression from 12 healthy control cell-free DNA samples sequenced on the PhasED-Seq panel. ‘PhasED-Seq 2×’ or ‘doublets’ represents detection of two mutations in-phase on the same DNA molecule; ‘PhasED-Seq 3×’ or ‘triplets’ represents detection of three mutations in-phase on the same DNA molecule. FIG. 3C illustrates bar plot showing the depth of unique molecular recovery (e.g., depth after barcode-mediated PCR duplicate removal) from sequencing data from 12 cell-free DNA samples for different types of error-suppression, including barcode deduplication, duplex sequencing, and recovery of PVs of increasing maximal distance between SNVs in-phase. FIG. 3D illustrates bar plot showing the cumulative fraction of PVs that have a maximal distance between SNVs less than the number of base-pairs shown on the x-axis. FIG. 3E illustrates a plot demonstrating the results of a limiting dilution series simulating cell-free DNA samples containing patient-specific tumor fractions of 1×10−3 to 0.5×10−6; cfDNA from 3 independent patients samples were used in each dilution. The same sequencing data was analyzed using a variety of error-suppression methods for recovery of expected tumor fractions, including iDES, duplex sequencing, and PhasED-Seq (both for recovery of doublet and triplet molecules). Points and error-bars represent the mean, minimum, and maximum across the three patient-specific tumor mutations considered. The difference between observed and expected tumor fractions for sample <1:10,000 were compared via paired t-test. *, P<0.05, **, P<0.005, ***, P<0.0005. FIG. 3F illustrates plot demonstrating the background signal for detection of tumor-specific alleles in 12 unrelated, healthy cell-free DNA samples, and the healthy cfDNA sample used for limiting dilution series (n=13 total samples). In each sample, tumor-specific SNVs or PVs from the 3 patient samples utilized in the limiting dilution experiment shown in FIG. 3E, for a total of 39 assessments were assessed. Bars represent the arithmetic mean across all 39 assessments; statistical comparison performed by Wilcoxon rank-sum test. *, P<0.05, **, P<0.005, ***, P<0.0005. FIG. 3G illustrates plot showing the theoretical rate of detection for a sample with a given number of PV-containing regions, according to simple binomial sampling. This plot is produced by assuming a unique sequencing depth of 5000× (line), along with a varying number of independent 150 bp PV-containing regions, from 3 regions (blue) to 67 regions (purple). Confidence envelopes consider depth from 4000-6000×; a 5% false-positive rate is also assumed. FIG. 3H illustrates plot showing the observed rate of detection (y-axis) for sample of a given true tumor fraction (x-axis), with varying numbers of PV-containing regions. For each number of tumor-reporter regions ranging from 3 to 67, this number of 150 bp windows was randomly sampled from each of 3 patient-specific PV reporter lists 25 times and used to assess tumor-detection at each dilution. Filled-in points represent ‘wet’ dilution series experiments, while open points represent in silico dilution experiments. Points and error-bars represent the mean, minimum, and maximum across the three patient-specific PV reporter lists used in the original sampling. FIG. 3I illustrates scatter plot compares the predicted vs observed rate of detection for samples from the dilution series shown in panels FIG. 3G and FIG. 3H. Additional details of this experiment are provided in Example 10.



FIGS. 4A-4G illustrate clinical application of PhasED-Seq for ultra-sensitive disease detection and response monitoring in DLBCL. FIG. 4A illustrates plot showing ctDNA levels for a patient with DLBCL responding to, and subsequently relapsing after, first-line immuno-chemotherapy. Levels measured by CAPP-Seq are shown in darker gray circles while levels measured by PhasED-Seq are shown in lighter gray circles. Open circles represent undetectable levels by CAPP-Seq. FIG. 4B illustrates a univariate scatter plot showing the mean tumor allele fraction measured by PhasED-Seq for clinical samples at time-points of minimal disease (i.e., after 1 or 2 cycles of therapy). The plot is divided by samples detected vs undetected by standard CAPP-Seq; P-value from Wilcoxon rank-sum test. FIG. 4C illustrates bar plot showing the fraction of DLBCL patients who have detectable ctDNA by CAPP-Seq after 1 or 2 cycles of treatment (dark gray bars), as well as the fraction of additional patients with detectable disease when adding PhasED-Seq to standard CAPP-Seq (medium gray bars). P-value represents a Fisher's Exact Test for detection by CAPP-Seq alone versus the combination of PhasED-Seq and CAPP-Seq in 171 samples after 1 or 2 cycles of treatment. FIG. 4D illustrates a waterfall plot showing the change in ctDNA levels measured by CAPP-Seq after 2 cycles of first-line therapy in patients with DLBCL. Patients with undetectable ctDNA by CAPP-Seq are shown as “ND” (“not detected”), in darker colors. The colors of the bars also indicate the eventual clinical outcomes for these patients. FIG. 4E illustrates a Kaplan-Meier plot showing the event-free survival for 52 DLBCL patients with undetectable ctDNA measured by CAPP-Seq after 2 cycles. FIG. 4F illustrates a Kaplan-Meier plot showing the event-free survival of 52 patients shown in FIG. 4E (undetectable ctDNA by CAPP-Seq) stratified by ctDNA detection via PhasED-Seq at this same time-point (cycle 3, day 1). FIG. 4G illustrates a Kaplan-Meier plot showing the event-free survival for 89 patients with DLBCL stratified by ctDNA at cycle 3, day 1 separated into 3 strata—patients failing to achieve a major molecular response (dark gray), patients with a major molecular response who still have detectable ctDNA by PhasED-Seq and/or CAPP-Seq (light grey), and patients who have a stringent molecular remission (undetectable ctDNA by PhasED-Seq and CAPP-Seq; medium gray).



FIGS. 5A-5C illustrate enumeration of SNVs and PVs in diverse cancers from WGS. FIG. 5A-C illustrate Univariate scatter plots showing the number of SNVs (FIG. 5A), PVs (FIG. 5B), and PVs, controlling for total number of SNVs (FIG. 5C), from WGS data for 24 different histologies of cancer. Bars show the median value and interquartile range. (FL-NHL, follicular lymphoma; DLBCL-NHL, diffuse large B cell lymphoma; Burkitt-NHL, Burkitt lymphoma; Lung-SCC, squamous cell lung cancer; Lung-Adeno, lung adenocarcinoma; Kidney-RCC, renal cell carcinoma; Bone-Osteosarc, osteosarcoma; Liver-HCC, hepatocellular carcinoma; Breast-Adeno, breast adenocarcinoma; Panc-Adeno, pancreatic adenocarcinoma; Head-SCC, head and neck squamous cell carcinoma; Ovary-Adeno, ovarian adenocarcinoma; Eso-Adeno, esophageal adenocarcinoma; Uterus-Adeno, uterine adenocarcinoma; Stomach-Adeno, stomach adenocarcinoma; CLL, chronic lymphocytic leukemia; ColoRect-Adeno, colorectal adenocarcinoma; Prost-Adeno, prostate adenocarcinoma; CNS-GBM, glioblastoma multiforme; Panc-Endocrine, pancreatic neuroendocrine tumor; Thy-Adeno, thyroid adenocarcinoma; CNS-PiloAstro, piloastrocytoma; CNS-Medullo, medulloblastoma).



FIGS. 6A-6WW illustrate contribution of mutational signatures in phased and un-phased SNVs in WGS (FIGS. 6A-6WW.) Scatterplots showing the contribution of established single base substitution (SBS) mutational signatures to SNVs seen in PVs, shown in dark colors, and SNVs seen outside of possible phased relationships, shown in light colors, from WGS. This is presented for 49 SBS mutational signatures across 24 subtypes of cancer. Mutational signatures that show a significant difference in contribution between phased and un-phased SNVs after multiple hypothesis testing correction are indicated with a *. These figures represent the raw data summarized in FIG. 1C.



FIG. 7 illustrates distribution of PVs in stereotyped regions across the genome. Bar plots show the distribution of PVs occurring in stereotyped regions across the genome of multiple cancer types. In this plot, the genome was divided into 1000 bp bins, and the fraction of samples of a given histology with a PV in each 1000 bp bin was calculated. Only bins that have at least a 2 percent recurrence frequency in any cancer subtype are shown. Histologies shown are as in FIG. 1E; activated B-cell (ABC) and germinal center B-cell (GCB) subtypes of DLBCL are also shown.



FIGS. 8A-8E illustrate quantity and genomic location of PVs from WGS in lymphoid malignancies. FIG. 8A. illustrates bar plot showing the number of independent 1000 bp regions across the genome that recurrently contain PVs for DLBCL, FL, BL, and CLL (n=68, 74, 36, and 151 respectively). FIG. 8B-D illustrate plots showing the frequency of PVs for multiple lymphoid malignancies with relationships to specific genetic loci, including FIG. 8B: BCL2, FIG. 8C: MYC, and FIG. 8D: ID3. The location of the transcript for a given gene is shown below the plot in grey; exons are shown in darker gray. * indicates a region with significantly more PVs in a given cancer histology compared to all other histologies by Fisher's Exact Test (P<0.05). FIG. 8E, similar to FIG. 8B-D, these plots show the frequency of PVs across lymphoma subtypes. Here, it is shown the IGH locus, consisting of IGHV, IGHD, and IGHJ parts, for ABC and GCB subtype DLBCLs (n=25 and 25, respectively). Coding regions for Ig parts, including Ig-constant regions and V-genes, are shown. (DLBCL, diffuse large B-cell lymphoma; FL, follicular lymphoma; BL, Burkitt lymphoma, CLL, chronic lymphocytic leukemia).



FIGS. 9A-9K illustrate performance of PhasED-Seq for recovery of PVs across lymphomas. FIG. 9A illustrates univariate scatter plot showing the fraction of all PVs across the genome identified by WGS (n=79) that were recovered by previously reported lymphoma CAPP-Seq panel8 (left) compared to PhasED-Seq (right). FIG. 9B illustrates the expected yield of SNVs per case identified from WGS using a previously established lymphoma CAPP-Seq panel or the PhasED-Seq panel. FIG. 9C illustrates the expected yield of PVs per case identified from WGS using a previously established lymphoma CAPP-Seq panel or the PhasED-Seq panel. Data from three independent publicly available cohorts are shown in FIGS. 9A-9C. FIGS. 9D-9F illustrate plots showing the improvement in recovery of PVs by PhasED-Seq compared to CAPP-Seq in 16 patients sequenced by both assays. This includes improvement in d) two SNVs in phase (e.g., 2× or ‘doublet PVs’), e) three SNVs in phase (3× or ‘triplet PVs’) and f) four SNVs in phase (e.g., 4× or ‘quadruplet PVs’). FIGS. 9G-9K. illustrate panels showing the number of SNVs and PVs identified for patients with different types of lymphomas. These panels show the number of g) SNVs, h) doublet PVs, i) triplet PVs, j) quadruplet PVs, and k) all PVs. *, P<0.05; **, P<0.01, ***, P<0.001. (DLBCL, diffuse large B-cell lymphoma; GCB, germinal center B-cell like DLBCL; ABC, activated B-cell like DLBCL; PMBCL, primary mediastinal B-cell lymphoma; HL, Hodgkin lymphoma).



FIGS. 10A-10Y illustrate location-specific differences in PVs between ABC-DLBCL and GCB-DLBC (FIGS. 10A-10Y.) Similar to FIG. 2D, these scatterplots compare the frequency of PVs by genomic location (in 50 bp bins) for patients with different types of lymphomas; in this figure, the difference between ABC-DLBCL and GCB-DLBCL is shown. The red circles show the relative frequency of PVs in 50 bp bins from a specific gene of interest; the other (grey) circles show the relative frequency of PVs in 50 bp bins from the remainder of the PhasED-Seq sequencing panel. Only genes with a statistically significant difference in PVs between ABC-DLBCL and GCB-DLBCL are shown. P-values represent a Wilcoxon rank-sum test of 50 bp bins from a given gene against all other 50 bp bins; see Example 10.



FIGS. 11A-11X illustrate Location-specific differences in PVs between DLBCL and PMBCL (FIGS. 11A-11X). Similar to FIG. 2D, these scatterplots compare the frequency of PVs by genomic location (in 50 bp bins) for patients with different types of lymphomas; in this figure, the difference between DLBCL and PMBCL is shown. The blue circles show the relative frequency of PVs in 50 bp bins from a specific gene of interest; the other (gray) circles show the relative frequency of PVs in 50 bp bins from the remainder of the PhasED-Seq sequencing panel. Only genes with a statistically significant difference in PVs between DLBCL and PMBCL are shown. P-values represent a Wilcoxon rank-sum test of 50 bp bins from a given gene against all other 50 bp bins; see Example 10.



FIGS. 12A-12NN illustrate Location-specific differences in PVs between DLBCL and HL. Similar to FIG. 2D, scatterplots of FIGS. 12A-12NN compare the frequency of PVs by genomic location (in 50 bp bins) for patients with different types of lymphomas; in this figure, the difference between DLBCL and HL is shown. The green circles show the relative frequency of PVs in 50 bp bins from a specific gene of interest; the other (grey) circles show the relative frequency of PVs in 50 bp bins from the remainder of the PhasED-Seq sequencing panel. Only genes with a statistically significant difference in PVs between DLBCL and HL are shown. P-values represent a Wilcoxon rank sum test of 50 bp bins from a given gene against all other 50 bp bins; see Example 10.



FIG. 13 illustrates differences in PVs between lymphoma types in mutations in the IGH locus. This figure shows the frequency of PVs from PhasED-Seq across the @IGH locus for different types of B-cell lymphomas. The bottom track shows the structure of the @IGH locus and gene-parts, including Ig-constant genes and V-genes. The next (outlined) track shows the frequency of PVs in this genomic region from WGS data (ICGC cohort). The remainder of the tracks show the frequency of PVs from PhasED-Seq targeted sequencing data, including 1) DLBCL, GCB-DLBCL, ABC-DLBCL, PMBCL, and HL. The regions targeted by the PhasED-Seq panel are shown at the top. Selected immunoglobulin parts with PVs enriched in specific histologies are labeled (i.e., IGHV4-34, Sε, Sγ3 and Sγ1).



FIGS. 14A-14E illustrate Technical aspects of PhasED-Seq by hybrid-capture sequencing. FIG. 14A shows a plot of the theoretical energy of binding for typical 150-mers across the genome with increasing fraction of bases mutated from the reference genome. Mutations were spread throughout the 150-mer either clustered to one end of the sequence, clustered in the middle of the sequence, or randomly throughout the sequence. Point and error-bars represent the median and interquartile ranges from 10,000 in silico simulations. FIG. 14B illustrates a plot showing two histograms of summary metrics of the mutation rate of 151-bp windows across the PhasED-Seq panel across all patients in this study. The light gray histogram shows the maximum percent mutated in any 151-bp window for all patients in this study; the dark gray histogram shows the 95th percentile mutation rate across all mutated 151-bp windows. FIG. 14C is a plot showing the percentile of mutation rate across all mutated 151-bp windows across all patients in this study.



FIG. 14D illustrates heatmaps showing the relative error rate (as log 10(error rate)) for single SNVs (left, “RED”), doublet PVs (middle, “YELLOW”), and triplet PVs (right, “BLUE”). FIG. 14D demonstrates that analysis based on the plurality of phased variants (e.g., double or triplet PVs) yields a lower error rate than analysis based on single SNVs. In addition, FIG. 14D demonstrates that analysis using a higher number of phased variant sets (e.g., triplet PVs labeled as “BLUE”) yields a lower error rate than analysis based on a lower number of phased variant sets (e.g., doublet PVs labeled as “YELLOW”). The error rate of single SNVs from sequencing with multiple error suppression methods is shown, including barcode deduplication, iDES, and duplex sequencing. Error rates are summarized by the type of mutation. In the case of triplet PVs, the x and y-axis of the heatmap represent the first and second type of base alteration in the PV; the third alteration is averaged over all 12 possible base changes. FIG. 14E illustrates a plot showing the error rate for doublet/2× PVs as a function of the genomic distance between the component SNVs.



FIGS. 15 and 16A-16B illustrates comparison of ctDNA quantitation by PhasED-Seq to CAPP-Seq and clinical applications. FIG. 15 illustrates the detection-rate of ctDNA from pretreatment samples across 107 patients with large-B cell lymphomas by standard CAPP-Seq (green), as well as PhasED-Seq using doublets (light blue), triplets (medium blue), and quadruplets (dark blue). The specificity of ctDNA detection is also shown. In the lower two plots, the false-detection rate in 40 withheld healthy control cfDNA samples is shown. The size of each bar in these two plots shows the detection-rate for patient-specific cfDNA mutations in these 40-withheld controls, across all 107 cases. FIG. 16A illustrates table summarizing the sensitivity and specificity for ctDNA detection in pretreatment samples by CAPP-Seq and PhasED-Seq using doublets, triplets, and quadruplets, shown in panel A. Sensitivity is calculated across all 107 cases, while specificity is calculated across the 40 withheld control samples, assessing for each of the 107 independent patient-specific mutation lists, for a total of 4280 independent tests. FIG. 16B illustrates a scatterplot showing the quantity of ctDNA (measured as log 10(haploid genome equivalents/mL)) as measured by CAPP-Seq vs. PhasED-Seq in individual samples. Samples taken prior to cycle 1 of RCHOP therapy (i.e., pretreatment), prior to cycle 2, and prior to cycle 3, are shown in independent colors (blue, green, and red respectively; 278 total samples). Undetectable levels fall on the axes. Spearman correlation and P-value are shown.



FIGS. 17A-17D illustrate detection of ctDNA after two cycles of systemic therapy. FIG. 17A illustrates a scatter plot showing the log-fold change in ctDNA after 2 cycles of therapy (i.e., the Major Molecular Response or MMR) measured by CAPP-Seq or PhasED-Seq for patients receiving RCHOP therapy. Dotted lines show the previously established threshold of a 2.5-log reduction in ctDNA for MMR. Undetectable samples fall on the axes; the correlation coefficient represents a Spearman rho for the 33 samples detected by both CAPP-Seq and PhasED-Seq. FIG. 17B illustrates 2 by 2 tables summarizing the detection rate of ctDNA samples after 2 cycles of therapy by PhasED-Seq vs CAPP-Seq. Patients with eventual disease progression are shown in bottom panel, while patients without eventual disease progression are shown in upper panel. FIG. 17C illustrates bar-plots showing the area under the receiver operator curve (AUC) for classification of patients for event-free survival at 24 months based on CAPP-Seq (light colors) or PhasED-Seq (dark colors) after 2 cycles of therapy. Classification of all patient (n=89, left) and only patients achieving a MMR (n=69, right) are both shown. FIG. 17D illustrates Kaplan-Meier plots showing the event-free survival of 69 patients achieving a MMR stratified by ctDNA detection with CAPP-Seq (top) or PhasED-Seq (bottom).



FIGS. 18A-18H illustrate detection of ctDNA after one cycle of systemic therapy. FIG. 18A illustrates scatterplot showing the log-fold change in ctDNA after 1 cycle of therapy (i.e., the Early Molecular Response or EMR) measured by CAPP-Seq or PhasED-Seq for patients receiving RCHOP therapy. Dotted lines show the previously established threshold of a 2-log reduction in ctDNA for EMR. Undetectable samples fall on the axes; the correlation coefficient represents a Spearman rho for the 45 samples detected by both CAPP-Seq and PhasED-Seq. FIG. 18B illustrates 2 by 2 tables summarizing the detection rate of ctDNA samples after 1 cycle of therapy by PhasED-Seq vs CAPP-Ceq. Patients with eventual disease progression are shown in red, while patients without eventual disease progression are shown in blue. FIG. 18C illustrates bar-plots showing the area under the receiver operator curve (AUC) for classification of patients for event-free survival at 24 months based on CAPP-Seq (light colors) or PhasED-Seq (dark colors) after 1 cycle of therapy. Classification of all patient (n=82, left) and only patients achieving an EMR (n=63, right) are both shown. FIG. 18D illustrates Kaplan-Meier plots showing the event-free survival of 63 patients achieving an EMR stratified by ctDNA detection with CAPP-Seq (top) or PhasED-Seq (bottom). FIG. 18E illustrates waterfall plot showing the change in ctDNA levels measured by CAPP-Seq after 1 cycle of first-line therapy in patients with DLBCL. Patients with undetectable ctDNA by CAPP-Seq are shown as “ND” (“not detected”), in darker colors. The colors of the bars also indicate the eventual clinical outcomes for these patients. FIG. 18F illustrates a Kaplan-Meier plot showing the event-free survival for 33 DLBCL patients with undetectable ctDNA measured by CAPP-Seq after 1 cycle of therapy. FIG. 18G illustrates a Kaplan-Meier plot showing the event-free survival of 33 patients shown in FIG. 18F (undetectable ctDNA by CAPP-Seq) stratified by ctDNA detection via PhasED-Seq at this same time-point (cycle 2, day 1). FIG. 18H illustrates a Kaplan-Meier plot showing the event-free survival for 82 patients with DLBCL stratified by ctDNA at cycle 2, day 1 separated into 3 strata—patients failing to achieve an early molecular response, patients with an early molecular response who still have detectable ctDNA by PhasED-Seq and/or CAPP-Seq, and patients who have a stringent molecular remission (undetectable ctDNA by PhasED-Seq and CAPP-Seq).



FIG. 19 illustrates a fraction of patients where PhasED-Seq would achieve a lower LOD than duplex sequencing tracking SNVs based on PCAWG data (whole genome sequencing) from which the number of SNVs and phased variants (PVs) in different tumor types was quantified.



FIG. 20 illustrates improved LODs achieved in lung cancers (adenocarcinoma, abbreviated ‘A’, and squamous cell carcinoma, abbreviated ‘S’), compared to duplex sequencing of whole genome sequencing data.



FIG. 21 illustrates empiric data from an experiment where WGS was performed on tumor tissue and custom panels were designed for 5 patients with solid tumors (5 lung cancers) to examine and compare the LODs of custom CAPP-Seq vs PhasED-Seq, showing a ˜10× lower LOD using PhasED-Seq in 5/5 patients.



FIG. 22A illustrates proof of principle example patient vignette comparing using custom CAPP-Seq and PhasED-Seq for disease surveillance in lung cancer showing earlier detection of relapse using PhasED-Seq.



FIG. 22B illustrates proof of principle example patient vignette comparing using custom CAPP-Seq and PhasED-Seq for early detection of disease in breast cancer, showing earlier detection of disease with PhasED-Seq.



FIGS. 23A-23B illustrate that the method describe herein (e.g. method depicted yielding FIG. 3E and FIG. 3F) does not require barcode meditated error suppression.



FIG. 24 illustrates a flow diagram of a process to perform a clinical intervention and/or treatment on an individual based on detecting circulating-tumor nucleic acid sequences in a sequencing result in accordance with an embodiment.



FIGS. 25A-25C show example flowcharts of methods for determining a condition of a subject based on one or more cell-free nucleic acid molecules comprising a plurality of variants.



FIG. 25D shows an example flowchart of a method for treating a condition of a subject based on one or more cell-free nucleic acid molecules comprising a plurality of variants.



FIG. 25E shows an example flowchart of a method for determining a progress (e.g., progression or regression) of a condition of a subject based on one or more cell-free nucleic acid molecules comprising a plurality of variants.



FIGS. 25F and 25G show example flowcharts of methods for determining a condition of a subject based on one or more cell-free nucleic acid molecules comprising a plurality of variants.



FIGS. 26A and 26B schematically illustrate different fluorescent probes for identifying one or more cell-free nucleic acid molecules comprising a plurality of phased variants.



FIG. 27 shows a computer system that is programmed or otherwise configured to implement methods provided herein.





DETAILED DESCRIPTION

While various embodiments of the invention have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions may occur to those skilled in the art without departing from the invention. It should be understood that various alternatives to the embodiments of the invention described herein may be employed.


The term “about” or “approximately” generally mean within an acceptable error range for the particular value, which may depend in part on how the value is measured or determined, e.g., the limitations of the measurement system. For example, “about” can mean within 1 or more than 1 standard deviation, per the practice in the art. Alternatively, “about” can mean a range of up to 20%, up to 10%, up to 5%, or up to 1% of a given value. Alternatively, particularly with respect to biological systems or processes, the term can mean within an order of magnitude, preferably within 5-fold, and more preferably within 2-fold, of a value. Where particular values are described in the application and claims, unless otherwise stated, the term “about” meaning within an acceptable error range for the particular value may be assumed.


The term “phased variants,” “variants in phase,” “PV,” or “somatic variants in phase,” as used interchangeably herein, generally refers to two or more mutations (e.g., SNVs or indels) that occur in cis (i.e., on the same strand of a nucleic acid molecule) within a single cell-free nucleic acid molecule. In some cases, a cell-free nucleic acid molecule can be a cell-free deoxyribonucleic acid (cfDNA) molecule. In some cases, a cfDNA molecule can be derived from a diseased tissue, such as a tumor (e.g., a circulating tumor DNA (ctDNA) molecule).


The term “biological sample” or “bodily sample,” as used interchangeably herein, generally refers to a tissue or fluid sample derived from a subject. A biological sample can be directly obtained from the subject. Alternatively, a biological sample can be derived from the subject (e.g., by processing an initial biological sample obtained from the subject). The biological sample can be or can include one or more nucleic acid molecules, such as DNA or ribonucleic acid (RNA) molecules. The biological sample can be derived from any organ, tissue or biological fluid. A biological sample can comprise, for example, a bodily fluid or a solid tissue sample. An example of a solid tissue sample is a tumor sample, e.g., from a solid tumor biopsy. Non-limiting examples of bodily fluids include blood, serum, plasma, tumor cells, saliva, urine, cerebrospinal fluid, lymphatic fluid, prostatic fluid, seminal fluid, milk, sputum, stool, tears, and derivatives of these. In some cases, one or more cell-free nucleic acid molecules as disclosed herein can be derived from a biological sample.


The term “subject,” as used herein, generally refers to any animal, mammal, or human. A subject can have, potentially have, or be suspected of having one or more conditions, such as a disease. In some cases, a condition of the subject can be cancer, a symptom(s) associated with cancer, or asymptomatic with respect to cancer or undiagnosed (e.g., not diagnosed for cancer). In some cases, the subject can have cancer, the subject can show a symptom(s) associated with cancer, the subject can be free from symptoms associated with cancer, or the subject may not be diagnosed with cancer. In some examples, the subject is a human.


The term “cell-free DNA” or “cfDNA,” as used interchangeably herein, generally refers to DNA fragments circulating freely in a blood stream of a subject. Cell-free DNA fragments can have dinucleosomal protection (e.g., a fragment size of at least 240 base pairs (“bp”)). These cfDNA fragments with dinucleosomal protection were likely not cut between the nucleosome, resulting in a longer fragment length (e.g., with a typical size distribution centered around 334 bp). Cell-free DNA fragments can have mononucleosomal protection (e.g., a fragment size of less than 240 base pairs (“bp”)). These cfDNA fragments with mononucleosomal protection were likely cut between the nucleosome, resulting in a shorter fragment length (e.g., with a typical size distribution centered around 167 bp).


The term “sequencing data,” as used herein, generally refers to “raw sequence reads” and/or “consensus sequences” of nucleic acids, such as cell-free nucleic acids or derivatives thereof. Raw sequence reads are the output of a DNA sequencer, and typically include redundant sequences of the same parent molecule, for example after amplification. “Consensus sequences” are sequences derived from redundant sequences of a parent molecule intended to represent the sequence of the original parent molecule. Consensus sequences can be produced by voting (wherein each majority nucleotide, e.g., the most commonly observed nucleotide at a given base position, among the sequences is the consensus nucleotide) or other approaches such as comparing to a reference genome. In some cases, consensus sequences can be produced by tagging original parent molecules with unique or non-unique molecular tags, which allow tracking of the progeny sequences (e.g., after amplification) by tracking of the tag and/or use of sequence read internal information.


The term “reference genomic sequence,” as used herein, generally refers to a nucleotide sequence against which a subject's nucleotide sequences are compared.


The term “genomic region,” as used herein, generally refers to any region (e.g., range of base pair locations) of a genome, e.g., an entire genome, a chromosome, a gene, or an exon. A genomic region can be a contiguous or a non-contiguous region. A “genetic locus” (or “locus”) can be a portion or entirety of a genomic region (e.g., a gene, a portion of a gene, or a single nucleotide of a gene).


The term “likelihood,” as used herein, generally refers to a probability, a relative probability, a presence or an absence, or a degree.


The term “liquid biopsy,” as used herein, generally refers to a non-invasive or minimally invasive laboratory test or assay (e.g., of a biological sample or cell-free nucleic acids). The “liquid biopsy” assays can report detections or measurements (e.g., minor allele frequencies, gene expression, or protein expression) of one or more marker genes associated with a condition of a subject (e.g., cancer or tumor-associated marker genes).


A. Introduction

Modifications (e.g., mutations) of genomic DNA can be manifested in a formation and/or progression of one or more conditions (e.g., a disease, such as cancer or tumor) of a subject. The present disclosure provides methods and systems for analyzing cell-free nucleic acid molecules, such as cfDNA, from a subject to determine the presence or absence of a condition of the subject, prognosis of a diagnosed condition of the subject, progress of the condition of the subject over time, therapeutic treatment of a diagnosed condition of the subject, or predicted treatment outcome for a condition of the subject.


Analysis of cell-free nucleic acids, such as cfDNA, have been developed with broad applications in, e.g., prenatal testing, organ transplantation, infectious disease, and oncology. In the context of detecting or monitoring a disease of a subject, such as cancer, circulating tumor DNA (ctDNA) can be a sensitive and specific biomarker in numerous cancer types. In some cases, ctDNA can be used to detect the presence of minimal residual disease (MRD) or tumor burden after treatment, such as chemotherapies or surgical resection of solid tumors. However, the limit of detection (LOD) for ctDNA analysis can be restricted by a number of factors including (i) low input DNA amounts from a typical blood collection and (ii) background error rates from sequencing.


In some cases, ctDNA-based cancer detection can be improved by tracking multiple somatic mutations with error-suppressed sequencing, e.g., with LOD of about 2 parts in 100,000 from cfDNA input while using off-the-shelf panels or personalized assays. However, in some cases, current LOD of ctDNA of interest can be insufficient to universally detect MIRD in patients destined for disease relapse or progression. For example, such ‘loss of detection’ can be exemplified in diffuse large B-cell lymphoma (DLBCL). For DLBCL, interim ctDNA detection after only two cycles of curative-intent therapy can represent a major molecular response (MMR), and can be a strong prognostic marker for ultimate clinical outcomes. Despite this, nearly one-third of patients ultimately experiencing disease progression do not have detectable ctDNA at this interim landmark using available techniques (e.g., Cancer Personalized Profiling by Deep Sequencing (CAPP-Seq)), thus representing ‘false-negative’ measurements. Such high false-negative rates have also been observed in DLBCL patients by alternative methods, such as monitoring ctDNA through immunoglobulin gene rearrangements. Therefore, there exists a need for improved methods of ctDNA-based cancer detection with greater sensitivity.


Somatic variants detected on both of the complementary strands of parental DNA duplexes can be used to lower the LOD of ctDNA detection, thereby advantageously increasing the sensitivity of ctDNA detection. Such ‘duplex sequencing’ can reduce background error profile due to the requirement of two concordant events for detection of a single nucleotide variant (SNV). However, the duplex sequencing approach alone can be limited by inefficient recovery of DNA duplexes as recovery of both original strands can occur in a minority of all recovered molecules. Thus, duplex sequencing may be suboptimal and inefficient for real-world ctDNA detection with limited amount of starting sample, where input DNA from practical blood volumes (e.g., between about 4,000 to about 8,000 genomes per standard 10 milliliter (mL) blood collection tube) is limited and maximal recovery of genomes is essential.


Thus, there remains a significant unmet need for detection and analysis of ctDNA with low LOD (e.g., thereby yielding high sensitivity) for determining, for example, presence or absence of a disease of a subject, prognosis of the disease, treatment for the disease, and/or predicted outcome of the treatment.


B. Methods and Systems for Determining or Monitoring a Condition

The present disclosure describes methods and systems for detecting and analyzing cell free nucleic acids with a plurality of phased variants as a characteristic of a condition of a subject. In some aspects, the cell-free nucleic acid molecules can comprise cfDNA molecules, such as ctDNA molecules. The methods and systems disclosed herein can utilize sequencing data derived from a plurality of cell-free nucleic acid molecules of the subject to identify a subset of the plurality of cell-free nucleic acid molecules having the plurality of phased variants, thereby to determine the condition of the subject. The methods and systems disclosed herein can directly detect and, in some cases, pull down (or capture) such subset of the plurality of cell-free nucleic acid molecules that exhibit the plurality of phased variants, thereby to determine the condition of the subject with or without sequencing. The methods and systems disclosed herein can reduce background error rate often involved during detection and analysis of cell-free nucleic acid molecules, such as cfDNA.


In some aspects, methods and systems for cell-free nucleic acid sequencing and detection of cancer are provided. In some embodiments, cell-free nucleic acids (e.g., cfDNA or cfRNA) can be extracted from a liquid biopsy of an individual and prepared for sequencing. Sequencing results of the cell-free nucleic acids can be analyzed to detect somatic variants in phase (i.e., phased variants, as disclosed herein) as an indication of circulating-tumor nucleic acid (ctDNA or ctRNA) sequences (i.e., sequences that derived or are originated from nucleic acids of a cancer cell). Accordingly, in some cases, cancer can be detected in the individual by extracting a liquid biopsy from the individual and sequencing the cell-free nucleic acids derived from that liquid biopsy to detect circulating-tumor nucleic acid sequences, and the presence of circulating-tumor nucleic acid sequences can indicate that the individual has a cancer (e.g., a specific type of cancer). In some cases, a clinical intervention and/or treatment can be determined and/or performed on the individual based on the detection of the cancer.


As disclosed herein, a presence of somatic variants in phase can be a strong indication that the nucleic acids containing such phased variants are derived from a bodily sample with a condition, such as a cancerous cell (or alternatively, that the nucleic acids are from derived from a bodily sample obtained or derived from a subject with a condition, such as cancer). Detection of phased somatic variants can enhance the signal-to-noise ratio of cell-free nucleic acid detection methods (e.g., by reducing or eliminating spurious “noise” signals) as it may be unlikely that phased mutations would occur within a small genetic window that is approximately the size of a typical cell-free nucleic acid molecule (e.g., about 170 bp or less).


In some aspects, a number of genomic regions can be used as hotspots for detection of phased variants, especially in various cancers, e.g., lymphomas. In some cases, enzymes (e.g., AID, Apobec3a) can stereotypically mutagenize DNA in specific genes and locations, leading to development of particular cancers. Accordingly, cell-free nucleic acids derived from such hotspot genomic regions can be captured or targeted (e.g., with or without deep sequencing) for cancer detection and/or monitoring. Alternatively, capture or targeted sequencing can performed on regions in which phased variants have been previously detected from a cancerous source (e.g., tumor) of a particular individual in order to detect cancer in that individual.


In some aspects, capture sequencing on cell-free nucleic acids can be performed as a screening diagnostic. In some cases, a screening diagnostic can be developed and used to detect circulating-tumor nucleic acids for cancers that have stereotypical regions of phased variants. In some cases, capture sequencing on cell-free nucleic acids is performed as a diagnostic to detect MRD or tumor burden to determine if a particular disease is present during or after treatment. In some cases, capture sequencing on cell-free nucleic acids can be performed as a diagnostic to determine progress (e.g., progression or regression) of a treatment.


In some aspects, cell-free nucleic acid sequencing results can be analyzed to detect whether phased somatic single nucleotide variants (SNVs) or other mutations or variants (e.g., indels) exist within the cell-free nucleic acid sample. In some cases, the presence of particular somatic SNVs or other variants can be indicative of circulating-tumor nucleic acid sequences, and thus indicative of a tumor present in the subject. In some cases, a minimum of two variants can be detected in phase on a cell-free nucleic acid molecule. In some cases, a minimum of three variants can be detected in phase on a cell-free nucleic acid molecule. In some cases, a minimum of four variants can be detected in phase on a cell-free nucleic acid molecule. In some cases, a minimum of five or more variants can be detected in phase on a cell-free nucleic acid molecule. In some cases, the greater number of phased variants detected on a cell-free nucleic acid molecule, the greater the likelihood that the cell-free nucleic acid molecule is derived from cancer, as opposed to detecting an innocuous sequence of somatic variants that arise from molecular preparation of the sequence library or random biological errors. Accordingly, the likelihood of false-positive detection can decrease with detection of more variants in phase within a molecule (e.g., thereby increasing specificity of detection).


In some aspects, a cell-free nucleic acid sequencing result can be analyzed to detect whether an insertion or deletion of one or more nucleobases (i.e., indel) exist within the cell-free nucleic acid sample, e.g., relative to a reference genomic sequence. Without wishing to be bound by theory, in some cases, presence of indels in a cell-free nucleic acid molecule (e.g., cfDNA) can be indicative of a condition of a subject, e.g., a disease such as cancer. In some cases, a genetic variation as a result of an indel can be treated as a variant or mutation, and thus two indels can be treated a two phased variants, as disclosed herein. In some examples, within a cell-free nucleic acid molecule, a first genetic variation from a first indel (a first phase variant) and a second genetic variation from a second indel (a second phase variant) can be separated from each other by at least 1 nucleotide.


Within a single cell-free nucleic acid molecule (e.g., a single cfDNA molecule), as disclosed herein, a first phased variant can be a SNV and a second phased variant can be a part of a different small nucleotide polymorphism, e.g., another SNV or a part of a multi-nucleotide variant (MNV). A multi-nucleotide variant can be a cluster of two or more (e.g., at least 2, 3, 4, 5, or more) adjacent variants existing within the same stand of nucleic acid molecule. In some cases, the first phased variant and the second phased variant can be parts of the same MNV within the single cell-free nucleic acid molecule. In some cases, the first phased variant and the second phased variant can be from two different MNVs within the single cell-free nucleic acid molecule.


In some aspects, a statistical method can be utilized to calculate the likelihood that detected phased variants are from a cancer and not random or artificial (e.g., from sample prep or sequencing error). In some cases, a Monte Carlo sampling method can be utilized to determine the likelihood that detected phased variants are from a cancer and not random or artificial.


Aspects of the present disclosure provide identification or detection of cell-free nucleic acids (e.g., cfDNA molecule) with a plurality of phased variants, e.g., from a liquid biopsy of a subject. In some cases, a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants can be directly adjacent to each other (e.g., neighboring SNVs). In some cases, a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants can be separated by at least one nucleotide. The spacing between the first phased variant and the second phased variant can be limited by the length of the cell-free nucleic acid molecule.


Within a single cell-free nucleic acid molecule (e.g., a single cfDNA molecule), as disclosed herein, a first phased variant and a second phased variant can be separated from each other by at least or up to about 1 nucleotide, at least or up to about 2 nucleotides, at least or up to about 3 nucleotides, at least or up to about 4 nucleotides, at least or up to about 5 nucleotides, at least or up to about 6 nucleotides, at least or up to about 7 nucleotides, at least or up to about 8 nucleotides, at least or up to about 9 nucleotides, at least or up to about 10 nucleotides, at least or up to about 11 nucleotides, at least or up to about 12 nucleotides, at least or up to about 13 nucleotides, at least or up to about 14 nucleotides, at least or up to about 15 nucleotides, at least or up to about 20 nucleotides, at least or up to about 25 nucleotides, at least or up to about 30 nucleotides, at least or up to about 35 nucleotides, at least or up to about 40 nucleotides, at least or up to about 45 nucleotides, at least or up to about 50 nucleotides, at least or up to about 60 nucleotides, at least or up to about 70 nucleotides, at least or up to about 80 nucleotides, at least or up to about 90 nucleotides, at least or up to about 100 nucleotides, at least or up to about 110 nucleotides, at least or up to about 120 nucleotides, at least or up to about 130 nucleotides, at least or up to about 140 nucleotides, at least or up to about 150 nucleotides, at least or up to about 160 nucleotides, at least or up to about 170 nucleotides, or at least or up to about 180 nucleotides. Alternatively or in addition to, within a single cell-free nucleic acid molecule, a first phased variant and a second phased variant may not or need not be separated by one or more nucleotides and thus can be directly adjacent to one another.


A single cell-free nucleic acid molecule (e.g., a single cfDNA molecule), as disclosed herein, can comprise at least or up to about 2 phased variants, at least or up to about 3 phased variants, at least or up to about 4 phased variants, at least or up to about 5 phased variants, at least or up to about 6 phased variants, at least or up to about 7 phased variants, at least or up to about 8 phased variants, at least or up to about 9 phased variants, at least or up to about 10 phased variants, at least or up to about 12 phased variants, at least or up to about 12 phased variants, at least or up to about 13 phased variants, at least or up to about 14 phased variants, at least or up to about 15 phased variants, at least or up to about 20 phased variants, or at least or up to about 25 phased variants within the same molecule.


From a plurality of cell-free nucleic acid molecules obtained (e.g., from a liquid biopsy of a subject), two or more (e.g., 10 or more, 1,000 or more, 10,000 or more) cell-free nucleic acid molecules can be identified to have an average of at least or up to about 2 phased variants, at least or up to about 3 phased variants, at least or up to about 4 phased variants, at least or up to about 5 phased variants, at least or up to about 6 phased variants, at least or up to about 7 phased variants, at least or up to about 8 phased variants, at least or up to about 9 phased variants, at least or up to about 10 phased variants, at least or up to about 12 phased variants, at least or up to about 12 phased variants, at least or up to about 13 phased variants, at least or up to about 14 phased variants, at least or up to about 15 phased variants, at least or up to about 20 phased variants, or at least or up to about 25 phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants.


In some cases, a plurality of cell-free nucleic acid molecules (e.g., cfDNA molecules) can be obtained from a biological sample of a subject (e.g., solid tumor or liquid biopsy). Out of the plurality of cell-free nucleic acid molecules, at least or up to 1, at least or up to 2, at least or up to 3, at least or up to 4, at least or up to 5, at least or up to 6, at least or up to 7, at least or up to 8, at least or up to 9, at least or up to 10, at least or up to 15, at least or up to 20, at least or up to 25, at least or up to 30, at least or up to 35, at least or up to 40, at least or up to 45, at least or up to 50, at least or up to 60, at least or up to 70, at least or up to 80, at least or up to 90, at least or up to 100, at least or up to 150, at least or up to 200, at least or up to 300, at least or up to 400, at least or up to 500, at least or up to 600, at least or up to 700, at least or up to 800, at least or up to 900, at least or up to 1,000, at least or up to 5,000, at least or up to, 10,000, at least or up to 50,000, or at least or up to 100,000 cell-free nucleic acid molecules can be identified, such that each identified cell-free nucleic acid molecule comprises the plurality of phased variants, as disclosed herein.


In some cases, a plurality of cell-free nucleic acid molecules (e.g., cfDNA molecules) can be obtained from a biological sample of a subject (e.g., solid tumor or liquid biopsy). Out of the plurality of cell-free nucleic acid molecules, at least or up to 1, at least or up to 2, at least or up to 3, at least or up to 4, at least or up to 5, at least or up to 6, at least or up to 7, at least or up to 8, at least or up to 9, at least or up to 10, at least or up to 15, at least or up to 20, at least or up to 25, at least or up to 30, at least or up to 35, at least or up to 40, at least or up to 45, at least or up to 50, at least or up to 60, at least or up to 70, at least or up to 80, at least or up to 90, at least or up to 100, at least or up to 150, at least or up to 200, at least or up to 300, at least or up to 400, at least or up to 500, at least or up to 600, at least or up to 700, at least or up to 800, at least or up to 900, or at least or up to 1,000 cell-free nucleic acid molecules can be identified from a target genomic region (e.g., a target genomic locus), such that each identified cell-free nucleic acid molecule comprises the plurality of phased variants, as disclosed herein.



FIGS. 1A and 1E schematically illustrate examples of (i) a cfDNA molecule comprising a SNV and (ii) another cfDNA molecule comprising a plurality of phased variants. Each variant identified within the cfDNA can indicate a presence of one more genetic mutations in the cell that the cfNDA is originated from. In alternative embodiments, one or more of the phased variants may be an insertion or deletion (indel) instead of an SNV.


In one aspect, the present disclosure provides a method for determining a condition of a subject, as shown by flowchart 2510 in FIG. 25A. The method can comprise (a) obtaining, by a computer system, sequencing data derived from a plurality of cell-free nucleic acid molecules that is obtained or derived from the subject (process 2512). The method can further comprise (b) processing, by the computer system, the sequencing data to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules, wherein each of the one or more cell-free nucleic acid molecules identified comprises a plurality of phased variants relative to a reference genomic sequence (process 2514). In some cases, at least a portion of the one or more cell-free nucleic acid molecules can comprise a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants that are separated by at least one nucleotide, as disclosed herein. The method can optionally comprise (c) analyzing, by the computer system, at least a portion of the identified one or more cell-free nucleic acid molecules to determine the condition of the subject (process 2516).


In some cases, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, at least or up to about 50%, at least or up to about 60%, at least or up to about 70%, at least or up to about 80%, at least or up to about 90%, at least or up to about 95%, at least or up to about 99%, or about 100% of the one or more cell-free nucleic acid molecules can comprise a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants that are separated by at least one nucleotide, as disclosed herein. In some examples, a plurality of phased variants within a single cfDNA molecule can comprise (i) a first plurality of phased variants that are separated by at least one nucleotide from one another and (ii) a second plurality of phased variants that are adjacent to one another (e.g., two phased variants within a MNV). In some examples, a plurality of phased variants within a single cfDNA molecule can consist of phased variants that are separate by at least one nucleotide from one another.


In one aspect, the present disclosure provides a method for determining a condition of the subject, as shown by flowchart 2520 in FIG. 25B. The method can comprise (a) obtaining, by a computer system, sequencing data derived from a plurality of cell-free nucleic acid molecules that is obtained or derived from a subject (process 2522). The method can further comprise (b) processing, by the computer system, the sequencing data to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules, wherein each of the one or more cell-free nucleic acid molecules comprises a plurality of phased variants relative to a reference genomic sequence (process 2524). In some cases, a first phased variant of the plurality of phased variant and a second phased variant of the plurality of phased variant can be separated by at least one nucleotide, as disclosed herein. The method can optionally comprise (c) analyzing, by the computer system, at least a portion of the identified one or more cell-free nucleic acid molecules to determine the condition of the subject (process 2526).


In one aspect, the present disclosure provides a method for determining a condition of a subject, as shown by flowchart 2530 in FIG. 25C. The method can comprise (a) obtaining sequencing data derived from a plurality of cell-free nucleic acid molecules that is obtained or derived from the subject (process 2532). The method can further comprise (b) processing the sequencing data to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules with a LOD being less than about 1 out of 50,000 observations (or cell-free nucleic acid molecules) from the sequencing data (process 2534). In some cases, each of the one or more cell-free nucleic acid molecules comprises a plurality of phased variants relative to a reference genomic sequence. The method can optionally comprise (c) analyzing at least a portion of the identified one or more cell-free nucleic acid molecules to determine the condition of the subject (process 2536).


In some cases, the LOD of the operation of identifying the one or more cell-free nucleic acid molecules, as disclosed herein, can be less than about 1 out of 60,000, less than 1 out of 70,000, less than 10 out of 80,000, less than 1 out of 90,000, less than 1 out of 100,000, less than 1 out of 150,000, less than 1 out of 200,000, less than 1 out of 300,000, less than 1 out of 400,000, less than 1 out of 500,000, less than 1 out of 600,000, less than 1 out of 700,000, less than 1 out of 800,000, less than 1 out of 900,000, less than 1 out of 1,000,000, less than 1 out of 1,000,000, less than 1 out of 1,100,000, less than 1 out of 1,200,000, less than 1 out of 1,300,000, less than 1 out of 1,400,000, less than 1 out of 1,500,000, or less than 1 out of 2,000,000 observations from the sequencing data.


In some cases, at least one cell-free nucleic acid molecule of the identified one or more cell-free nucleic acid molecules can comprise a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants that are separated by at least one nucleotide, as disclosed herein.


In some cases, one or more of the operations (a) through (c) of the subject method can be performed by a computer system. In an example, all of the operations (a) through (c) of the subject method can be performed by the computer system.


The sequencing data, as disclosed herein, can be obtained from one or more sequencing methods. A sequencing method can be a first-generation sequencing method (e.g., Maxam-Gilbert sequencing, Sanger sequencing). A sequencing method can be a high-throughput sequencing method, such as next-generation sequencing (NGS) (e.g., sequencing by synthesis). A high-throughput sequencing method can sequence simultaneously (or substantially simultaneously) at least about 10,000, at least about 100,000, at least about 1 million, at least about 10 million, at least about 100 million, at least about 1 billion, or more polynucleotide molecules (e.g., cell-free nucleic acid molecules or derivatives thereof). NGS can be any generation number of sequencing technologies (e.g., second-generation sequencing technologies, third-generation sequencing technologies, fourth-generation sequencing technologies, etc.). Non-limiting examples of high-throughput sequencing methods include massively parallel signature sequencing, polony sequencing, pyrosequencing, sequencing-by-synthesis, combinatorial probe anchor synthesis (cPAS), sequencing-by-ligation (e.g., sequencing by oligonucleotide ligation and detection (SOLiD) sequencing), semiconductor sequencing (e.g., Ion Torrent semiconductor sequencing), DNA nanoball sequencing, and single-molecule sequencing, sequencing-by-hybridization.


In some embodiments of any one of the methods disclosed herein, the sequencing data can be obtained based on any of the disclosed sequencing methods that utilizes nucleic acid amplification (e.g., polymerase chain reaction (PCR)). Non-limiting examples of such sequencing methods can include 454 pyrosequencing, polony sequencing, and SoLiD sequencing. In some cases, amplicons (e.g., derivatives of the plurality of cell-free nucleic acid molecules that is obtained or derived from the subject, as disclosed herein) that correspond to a genomic region of interest (e.g., a genomic region associated with a disease) can be generated by PCR, optionally pooled, and subsequently sequenced to generating sequencing data. In some examples, because the regions of interest are amplified into amplicons by PCR before being sequenced, the nucleic acid sample is already enriched for the region of interest, and thus any additional pooling (e.g., hybridization) may not and need not be needed prior to sequencing (e.g., non-hybridization based NGS). Alternatively, pooling via hybridization can further be performed for additional enrichment prior to sequencing. Alternatively, the sequencing data can be obtained without generating PCR copies, e.g., via cPAS sequencing.


A number of embodiments utilize capture hybridization techniques to perform targeted sequencing. When performing sequencing on cell-free nucleic acids, in order to enhance resolution on particular genomic loci, library products can be captured by hybridization prior to sequencing. Capture hybridization can be particularly useful when trying to detect rare and/or somatic phased variants from a sample at particular genomic loci. In some situations, detection of rare and/or somatic phased variants is indicative of the source of nucleic acids, including nucleic acids derived from a cancer source. Accordingly, capture hybridization is a tool that can enhance detection of circulating-tumor nucleic acids within cell-free nucleic acids.


Various types of cancers repeatedly experience aberrant somatic hypermutation in particular genomic loci. For instance, the enzyme activation-induced deaminase induces aberrant somatic hypermutation in B-cells, which leads to various B-cell lymphomas, including (but not limited to) diffuse large B-cell lymphoma (DLBCL), follicular lymphoma (FL), Burkitt lymphoma (BL), and B-cell chronic lymphocytic leukemia (CLL). Accordingly, in numerous embodiments, probes are designed to pull down (or capture) genomic loci known to experience aberrant somatic hypermutation in a lymphoma. FIG. 1D and Table 1 describe a number of regions that experience aberrant somatic hypermutation in DLBCL, FL, BL and CLL. Provided in Table 6 is list of nucleic acid probes that can be utilized to pull down (or capture) genomic loci to detect aberrant somatic hypermutation in B-cell cancers.


Capture sequencing can also be performed utilizing personalized nucleic acid probes designed to detect the existence of an individual's cancer. An individual having a cancer can have their cancer biopsied and sequenced to detect somatic phased variants that have accumulated in the cancer. Based on the sequencing result, in accordance with a number of embodiments, nucleic acid probes are designed and synthesized capable of pulling down the genomic loci inclusive of the positions of where the phased variants. These personalized designed and synthesized nucleic acid probes can be utilized to detect circulating-tumor nucleic acids from a liquid biopsy of that individual. Accordingly, the personalized nucleic acid probes can be useful for determining treatment response and/or detecting MRD after treatment.


In some embodiments of any one of the methods disclosed herein, the sequencing data can be obtained based on any sequencing method that utilizes adapters. Nucleic acid samples (e.g., the plurality of cell-free nucleic acid molecules from the subject, as disclosed herein) can be conjugated with one or more adapters (or adapter sequences) for recognizing (e.g., via hybridization) of the sample or any derivatives thereof (e.g., amplicons). In some examples, the nucleic acid samples can be tagged with a molecular barcode, e.g., such that each cell-free nucleic acid molecule of the plurality of cell-free nucleic acid molecules can have a unique barcode. Alternatively or in addition to, the nucleic acid samples can be tagged with a sample barcode, e.g., such that the plurality of cell-free nucleic acid molecules from the subject (e.g., a plurality of cell-free nucleic acid molecules obtained from a specific bodily tissue of the subject) can have the same barcode.


In alternative embodiments, the methods of identifying one or more cell-free nucleic acid molecules comprising the plurality of phased variants, as disclosed herein, can be performed without molecular barcoding, without sample barcoding, or without molecular barcoding and sample barcoding, at least in part due to high specificity and low LOD achieved by relying on identifying the phased variants as opposed to, e.g., a single SNV.


In some embodiments of any one of the methods disclosed herein, the sequencing data can be obtained and analyzed without in silico removal or suppression of (i) background error and/or (ii) sequencing error, at least in part due to high specificity and low LOD achieved by relying on identifying the phased variants as opposed to, e.g., a single SNV or indel.


In some embodiments of any one of the methods disclosed herein, using the plurality of variants as a condition to identify target cell-free nucleic acid molecules with specific mutations of interest without in silico methods of error suppression can yield a background error-rate that is lower than that of (i) barcode-deduplication, (ii) integrated digital error suppression, or (iii) duplex sequencing by at least about 5-fold, at least about 10-fold, at least about 20-fold, at least about 30-fold, at least about 40-fold, at least about 50-fold, at least about 60-fold, at least about 70-fold, at least about 80-fold, at least about 90-fold, at least about 100-fold, at least about 200-fold, at least about 400-fold, at least about 600-fold, at least about 800-fold, or at least about 1,000-fold. This approach may advantageously increase signal-to-noise ratio (thereby increasing sensitivity and/or specificity) of identifying target cell-free nucleic acid molecules with specific mutations of interest.


In some embodiments of any one of the methods disclosed herein, increasing a minimum number of phased variants (e.g., increasing from at least two phased variants to at least three phased variants) per cell-free nucleic acid molecule required as a condition to identify target cell-free nucleic acid molecules with specific mutations of interest can reduce the background error-rate by at least about 5-fold, at least about 10-fold, at least about 20-fold, at least about 30-fold, at least about 40-fold, at least about 50-fold, at least about 60-fold, at least about 70-fold, at least about 80-fold, at least about 90-fold, or at least about 100-fold. This approach may advantageously increase signal-to-noise ratio (thereby increasing sensitivity and/or specificity) of identifying target cell-free nucleic acid molecules with specific mutations of interest.


In one aspect, the present disclosure provides a method of treating a condition of a subject, as shown in flowchart 2540 in FIG. 25D. The method can comprise (a) identifying the subject for treatment of the condition, wherein the subject has been determined to have the condition based on identification of one or more cell-free nucleic acid molecules from a plurality of cell-free nucleic acid molecules that is obtained or derived from the subject (Process 2542). Each of the identified one or more cell-free nucleic acid molecules can comprise a plurality of phased variants relative to a reference genomic sequence. At least a portion (e.g., partial or all) of the plurality of phased variants can be separated by at least one nucleotide, such that a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants are separated by at least one nucleotide, as disclosed herein. In some cases, a presence of the plurality of phased variants is indicative of the condition (e.g., a disease, such as cancer) of the subject. The method can further comprise (b) subjecting the subject to the treatment based on the step (a) (process 2544). Examples of such treatment of the condition of the subject are disclosed elsewhere in the present disclosure.


In one aspect, the present disclosure provides a method of monitoring a progress (e.g., progression or regression) of a condition of a subject, as shown in flowchart 2550 in FIG. 25E. The method can comprise (a) determining a first state of the condition of the subject based on identification of a first set of one or more cell-free nucleic acid molecules from a first plurality of cell-free nucleic acid molecules that is obtained or derived from the subject (process 2552). The method can further comprise (b) determining a second state of the condition of the subject based on identification of a second set of one or more cell-free nucleic acid molecules from a second plurality of cell-free nucleic acid molecules that is obtained or derived from the subject (process 2554). The second plurality of cell-free nucleic acid molecules can be obtained from the subject subsequent to obtaining the first plurality of cell-free nucleic acid molecules from the subject. The method can optionally comprise (c) determining the progress (e.g., progression or regression) of the condition based at least in part on the first state of the condition and the second state of the condition (process 2556). In some cases, each of the one or more cell-free nucleic acid molecules identified (e.g., each of the first set of one or more cell-free nucleic acid molecules identified, each of the second set of one or more cell-free nucleic acid molecules identified) can comprise a plurality of phased variants relative to a reference genomic sequence. At least a portion (e.g., partial or all) of the one or more cell-free nucleic acid molecules identified can be separated by at least one nucleotide, as disclosed herein. In some cases, presence of the plurality of phased variants can be indicative of a state of the condition of the subject.


In some cases, the first plurality of cell-free nucleic acid molecules from the subject can be obtained (e.g., via blood biopsy) and analyzed to determine (e.g., diagnose) a first state of the condition (e.g., a disease, such as cancer) of the subject. The first plurality of cell-free nucleic acid molecules can be analyzed via any of the methods disclosed herein (e.g., with or without sequencing) to identify the first set of one or more cell-free nucleic acid molecules comprising the plurality of phased variants, and the presence or characteristics of the first set of one or more cell-free nucleic acid molecules can be used to determine the first state of the condition (e.g., an initial diagnosis) of the subject. Based on the determined first state of the condition, the subject can be subjected to one or more treatments (e.g., chemotherapy) as disclosed herein. Subsequent to the one or more treatments, he second plurality of cell-free nucleic acid molecules can be obtained from the subject.


In some cases, the subject can be subjected to at least or up to about 1 treatment, at least or up to about 2 treatments, at least or up to about 3 treatments, at least or up to about 4 treatments, at least or up to about 5 treatments, at least or up to about 6 treatments, at least or up to about 7 treatments, at least or up to about 8 treatments, at least or up to about 9 treatments, or at least or up to about 10 treatments based on the determined first state of the condition. In some cases, the subject can be subjected to a plurality of treatments based on the determined first state of the condition, and a first treatment of the plurality of treatments and a second treatment of the plurality of treatments can be separated by at least or up to about 1 day, at least or up to about 7 days, at least or up to about 2 weeks, at least or up to about 3 weeks, at least or up to about 4 weeks, at least or up to about 2 months, at least or up to about 3 months, at least or up to about 4 months, at least or up to about 5 months, at least or up to about 6 months, at least or up to about 12 months, at least or up to about 2 years, at least or up to about 3 years, at least or up to about 4 years, at least or up to about 5 years, or at least or up to about 10 years. The plurality of treatments for the subject can be the same. Alternatively, the plurality of treatments can be different by drug type (e.g., different chemotherapeutic drugs), drug dosage (e.g., increasing dosage, decreasing dosage), presence or absence of a co-therapeutic agent (e.g., chemotherapy and immunotherapy), modes of administration (e.g., intravenous vs oral administrations), frequency of administration (e.g., daily, weekly, monthly), etc.


In some cases, the subject may not and need not be treated for the condition between determination of the first state of the condition and determination of the second state of the condition. For example, without any intervening treatment, the second plurality of cell-free nucleic acid molecules may be contained (e.g., via liquid biopsy) from the subject to confirm whether the subject still exhibits indications of the first state of the condition.


In some cases, the second plurality of cell-free nucleic acid molecules from the subject can be obtained (e.g., via blood biopsy) at least or up to about 1 day, at least or up to about 7 days, at least or up to about 2 weeks, at least or up to about 3 weeks, at least or up to about 4 weeks, at least or up to about 2 months, at least or up to about 3 months, at least or up to about 4 months, at least or up to about 5 months, at least or up to about 6 months, at least or up to about 12 months, at least or up to about 2 years, at least or up to about 3 years, at least or up to about 4 years, at least or up to about 5 years, or at least or up to about 10 years after obtaining the first plurality of cell-free nucleic acid molecules from the subject.


In some cases, at least or up to about 2, at least or up to about 3, at least or up to about 4, at least or up to about 5, at least or up to about 6, at least or up to about 7, at least or up to about 8, at least or up to about 9, or at least or up to about 10 different samples comprising a plurality of nucleic acid molecules (e.g., at least the first plurality of cell-free nucleic acid molecules and the second plurality of cell-free nucleic acid molecules) can be obtained over time (e.g., once every month for 6 months, once every two months for a year, once every three months for a year, once every 6 months for one or more years, etc.) to monitor the progress of the condition of the subject, as disclosed herein.


In some cases, the step of determining the progress of the condition based on the first state of the condition and the second state of the condition can comprise comparing one or more characteristics of the first state and the second state of the condition, such as, for example, (i) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants in each state (e.g., per equal weight or volume of the biological sample of origin, per equal number of initial cell-free nucleic acid molecules analyzed, etc.), (ii) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants (i.e., two or more phased variants), or (iii) a number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants divided by a total number of cell-free nucleic acid molecules that comprise a mutation that overlaps with some of the plurality of phased variants (i.e., phased variant allele frequency). Based on such comparison, MRD of the condition (e.g., cancer or tumor) of the subject can be determined. For example, tumor burden or cancer burden of the subject can be determined based on such comparison.


In some cases, the progress of the condition can be progression or worsening of the condition. In an example, the worsening of the condition can comprise developing of a cancer from an earlier stage to a later stage, such as from stage I cancer to stage III cancer. In another example, the worsening of the condition can comprise increasing size (e.g., volume) of a solid tumor. Yet in a different example, the worsening of the condition can comprise cancer metastasis from once location to another location within the subject's body.


In some examples, (i) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants from the second state of the condition of the subject can be higher than (ii) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants from the first state of the condition of the subject by at least or up to about 0.1-fold, at least or up to about 0.2-fold, at least or up to about 0.3-fold, at least or up to about 0.4-fold, at least or up to about 0.5-fold, at least or up to about 0.6-fold, at least or up to about 0.7-fold, at least or up to about 0.8-fold, at least or up to about 0.9-fold, at least or up to about 1-fold, at least or up to about 2-fold, at least or up to about 3-fold, at least or up to about 4-fold, at least or up to about 5-fold, at least or up to about 6-fold, at least or up to about 7-fold, at least or up to about 8-fold, at least or up to about 9-fold, at least or up to about 10-fold, at least or up to about 15-fold, at least or up to about 20-fold, at least or up to about 30-fold, at least or up to about 40-fold, at least or up to about 50-fold, at least or up to about 60-fold, at least or up to about 70-fold, at least or up to about 80-fold, at least or up to about 90-fold, at least or up to about 100-fold, at least or up to about 200-fold, at least or up to about 300-fold, at least or up to about 400-fold, or at least or up to about 500-fold.


In some examples, (i) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants from the second state of the condition of the subject can be higher than (ii) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants from the first state of the condition of the subject by at least or up to about 0.1-fold, at least or up to about 0.2-fold, at least or up to about 0.3-fold, at least or up to about 0.4-fold, at least or up to about 0.5-fold, at least or up to about 0.6-fold, at least or up to about 0.7-fold, at least or up to about 0.8-fold, at least or up to about 0.9-fold, at least or up to about 1-fold, at least or up to about 2-fold, at least or up to about 3-fold, at least or up to about 4-fold, at least or up to about 5-fold, at least or up to about 6-fold, at least or up to about 7-fold, at least or up to about 8-fold, at least or up to about 9-fold, at least or up to about 10-fold, at least or up to about 15-fold, at least or up to about 20-fold, at least or up to about 30-fold, at least or up to about 40-fold, at least or up to about 50-fold, at least or up to about 60-fold, at least or up to about 70-fold, at least or up to about 80-fold, at least or up to about 90-fold, at least or up to about 100-fold, at least or up to about 200-fold, at least or up to about 300-fold, at least or up to about 400-fold, or at least or up to about 500-fold.


In some cases, the progress of the condition can be regression or at least a partial remission of the condition. In an example, the at least the partial remission of the condition can comprise downstaging of a cancer from a later stage to an earlier stage, such as from stage IV cancer to stage II cancer. Alternatively, the at least the partial remission of the condition can be full remission from cancer. In another example, the at least the partial remission of the condition can comprise decreasing size (e.g., volume) of a solid tumor.


In some examples, (i) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants from the second state of the condition of the subject can be lower than (ii) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants from the first state of the condition of the subject by at least or up to about 0.1-fold, at least or up to about 0.2-fold, at least or up to about 0.3-fold, at least or up to about 0.4-fold, at least or up to about 0.5-fold, at least or up to about 0.6-fold, at least or up to about 0.7-fold, at least or up to about 0.8-fold, at least or up to about 0.9-fold, at least or up to about 1-fold, at least or up to about 2-fold, at least or up to about 3-fold, at least or up to about 4-fold, at least or up to about 5-fold, at least or up to about 6-fold, at least or up to about 7-fold, at least or up to about 8-fold, at least or up to about 9-fold, at least or up to about 10-fold, at least or up to about 15-fold, at least or up to about 20-fold, at least or up to about 30-fold, at least or up to about 40-fold, at least or up to about 50-fold, at least or up to about 60-fold, at least or up to about 70-fold, at least or up to about 80-fold, at least or up to about 90-fold, at least or up to about 100-fold, at least or up to about 200-fold, at least or up to about 300-fold, at least or up to about 400-fold, or at least or up to about 500-fold.


In some examples, (i) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants from the second state of the condition of the subject can be lower than (ii) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants from the first state of the condition of the subject by at least or up to about 0.1-fold, at least or up to about 0.2-fold, at least or up to about 0.3-fold, at least or up to about 0.4-fold, at least or up to about 0.5-fold, at least or up to about 0.6-fold, at least or up to about 0.7-fold, at least or up to about 0.8-fold, at least or up to about 0.9-fold, at least or up to about 1-fold, at least or up to about 2-fold, at least or up to about 3-fold, at least or up to about 4-fold, at least or up to about 5-fold, at least or up to about 6-fold, at least or up to about 7-fold, at least or up to about 8-fold, at least or up to about 9-fold, at least or up to about 10-fold, at least or up to about 15-fold, at least or up to about 20-fold, at least or up to about 30-fold, at least or up to about 40-fold, at least or up to about 50-fold, at least or up to about 60-fold, at least or up to about 70-fold, at least or up to about 80-fold, at least or up to about 90-fold, at least or up to about 100-fold, at least or up to about 200-fold, at least or up to about 300-fold, at least or up to about 400-fold, or at least or up to about 500-fold.


In some cases, the progress of the condition can remain substantially the same between the two states of the condition of the subject. In some examples, (i) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants from the second state of the condition of the subject can be about the same as (ii) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants from the first state of the condition of the subject. In some examples, (i) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants from the second state of the condition of the subject can about the same as (ii) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants from the first state of the condition of the subject.


In some embodiments of any one of the methods disclosed herein, the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can be identified from the plurality of cell-free nucleic acid molecules by one or more sequencing methods. Alternatively or in addition to, the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can be identified by being pulled down from (or captured from among) the plurality of cell-free nucleic acid molecules with a set of nucleic acid probes. The pull down (or capture) method via the set of nucleic acid probes can be sufficient to identify the one or more cell-free nucleic acid molecules of interest without sequencing. In some cases, the set of nucleic acid probes can be configured to hybridize to at least a portion of cell-free nucleic acid (e.g., cfDNA) molecules from one or more genomic regions associated with the condition of the subject. As such, a presence of one or more cell-free nucleic acid molecules that have been pulled down by the set of nucleic acid probes can be an indication that the one or more cell-free nucleic acid molecules are derived from the condition (e.g., ctDNA or ctRNA). Additional details of the set of nucleic probes are disclosed elsewhere the present disclosure.


In some embodiments of any one of the methods disclosed herein, based the sequencing data derived from the plurality of cell-free nucleic acid molecules (e.g., cfDNA) that is obtained or derived from the subject, (i) the one or more cell-free nucleic acid molecules identified to comprise the plurality of phased variants can be separated, in silico, from (ii) one or more other cell-free nucleic acid molecules that are not identified to comprise the plurality of phased variants (or one or more other cell-free nucleic acid molecules that do not comprise the plurality of phased variants). In some cases, the method can further comprise generating an additional data comprising sequencing information of only (i) the one or more cell-free nucleic acid molecules identified to comprise the plurality of phased variants. In some cases, the method can further comprise generating a different data comprising sequencing information of only (ii) the one or more other cell-free nucleic acid molecules that are not identified to comprise the plurality of phased variants (or the one or more other cell-free nucleic acid molecules that do not comprise the plurality of phased variants).


In one aspect, the present disclosure provides a method for determining a condition of the subject, as shown by flowchart 2560 in FIG. 25F. The method can comprise (a) providing a mixture comprising (1) a set of nucleic acid probes and (2) a plurality of cell-free nucleic acid molecules obtained or derived from the subject (process 2562). In some cases, an individual nucleic acid probe of the set of nucleic acid probes can be designed to hybridize to a target cell-free nucleic acid molecule comprising a plurality of phased variants relative to a reference genomic sequence that are separated by at least one nucleotide. As such, a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants can be separated by at least one nucleotide, as disclosed herein. In some cases, the individual nucleic acid probe can comprise an activatable reporter agent. The activatable reporter agent can be activated by either one of (i) hybridization of the individual nucleic acid probe to the plurality of phased variants and (ii) dehybridization of at least a portion of the individual nucleic acid probe that has been hybridized to the plurality of phased variants. The method can further comprise (b) detecting the reporter agent that is activated, to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules (process 2564). Each of the one or more cell-free nucleic acid molecules can comprise the plurality of phased variants. The method can optionally comprise (c) analyzing at least a portion of the identified one or more cell-free nucleic acid molecules to determine the condition of the subject (process 2566).


In one aspect, the present disclosure provides a method for determining a condition of the subject, as shown by flowchart 2570 in FIG. 25G. The method can comprise (a) providing a mixture comprising (1) a set of nucleic acid probes and (2) a plurality of cell-free nucleic acid molecules obtained or derived from the subject (process 2572). In some cases, an individual nucleic acid probe of the set of nucleic acid probes can be designed to hybridize to a target cell-free nucleic acid molecule comprising a plurality of phased variants relative to a reference genomic sequence. In some cases, the individual nucleic acid probe can comprise an activatable reporter agent. The activatable reporter agent can be activated by either one of (i) hybridization of the individual nucleic acid probe to the plurality of phased variants and (ii) dehybridization of at least a portion of the individual nucleic acid probe that has been hybridized to the plurality of phased variants. The method can further comprise (b) detecting the reporter agent that is activated, to identify one or more cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules (process 2574). Each of the one or more cell-free nucleic acid molecules can comprise the plurality of phased variants, and a LOD of the identification step can be less than about 1 out of 50,000 cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules, as disclosed herein. The method can optionally comprise (c) analyzing at least a portion of the identified one or more cell-free nucleic acid molecules to determine the condition of the subject (process 2576).


In some cases, a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants are separated by at least one nucleotide, as disclosed herein.


In some cases, the LOD of the step of identifying the one or more cell-free nucleic acid molecules, as disclosed herein, can be less than about 1 out of 60,000, less than 1 out of 70,000, less than 10 out of 80,000, less than 1 out of 90,000, less than 1 out of 100,000, less than 1 out of 150,000, less than 1 out of 200,000, less than 1 out of 300,000, less than 1 out of 400,000, less than 1 out of 500,000, less than 1 out of 600,000, less than 1 out of 700,000, less than 1 out of 800,000, less than 1 out of 900,000, less than 1 out of 1,000,000, less than 1 out of 1,000,000, less than 1 out of 1,100,000, less than 1 out of 1,200,000, less than 1 out of 1,300,000, less than 1 out of 1,400,000, less than 1 out of 1,500,000, less than 1 out of 2,000,000, less than 1 out of 2,500,000, less than 1 out of 3,000,000, less than 1 out of 4,000,000, or less than 1 out of 5,000,000 cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules. Generally, a detection method with a lower LOD has a greater sensitivity of such detection.


In some embodiments of any one of the methods disclosed herein, the method can further comprise mixing (1) the set of nucleic acid probes and (2) the plurality of cell-free nucleic acid molecules.


In some embodiments of any one of the methods disclosed herein, the activatable reporter agent of a nucleic acid probe can be activated upon hybridization of the individual nucleic acid probe to the plurality of phased variants. Non-limiting examples of such nucleic acid probe can include a molecular beacon, eclipse probe, amplifluor probe, scorpions PCR primer, and light upon extension fluorogenic PCR primer (LUX primer).


For example, the nucleic acid probe can be a molecular beacon, as shown in FIG. 26A. The molecular beacon can be fluorescently labeled (e.g., dye-labeled) oligonucleotide probe that comprises complementarity to a target cell-free nucleic acid molecule 2603 in a region that comprises the plurality of phased variants. The molecular beacon can have a length between about 25 nucleotides to about 50 nucleotides. The molecular beacon can also be designed to be partially self-complimentary, such that it form a hairpin structure with a stem 2601a and a loop 2601b. The 5′ and 3′ ends of the molecular beacon probe can have complementary sequences (e.g., about 5-6 nucleotides) that form the stem structure 2601a. The loop portion 2601b of the hairpin can be designed to specifically hybridize to a portion (e.g., about 15-30 nucleotides) of the target sequence comprising two or more phased variants. The hairpin can be designed to hybridize to a portion that comprises at least 2, 3, 4, 5, or more phased variants. A fluorescent reporter molecule can be attached to the 5′ end of the molecular beacon probe, and a quencher that quenches fluorescence of the fluorescent reporter can be attached to the 3′ end of the molecular beacon probe. Formation of the hairpin therefore can bring the fluorescent reporter and quencher together, such that no fluorescence is emitted. However, during annealing operation of amplification reaction of the plurality of cell-free nucleic acid molecules that is obtained or derived from the subject, the loop portion of the molecular beacon can bind to its target sequence, causing the stem to denature. Thus, the reporter and quencher can be separated, abolishing quenching, and the fluorescent reporter is activated and detectable. Because fluorescence of the fluorescent reporter is emitted from the molecular beacon probe only when the probe is bound to the target sequence, the amount or level of fluorescence detected can be proportional to the amount of target in the reaction (e.g., (i) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants in each state or (ii) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants, as disclosed herein).


In some embodiments of any one of the methods disclosed herein, the activatable reporter agent can be activated upon dehybridization of at least a portion of the individual nucleic acid probe that has been hybridized to the plurality of phased variants. In other words, once the individual nucleic acid probe is hybridized to target cell-free nucleic acid molecule's portion that comprises the plurality of phased variants, dehybridization of at least a portion of the individual nucleic acid prob and the target cell-free nucleic acid can activate the activatable reporter agent. Non-limiting examples of such nucleic acid probe can include a hydrolysis probe (e.g., TaqMan prob), dual hybridization probes, and QZyme PCR primer.


For example, the nucleic acid probe can be a hydrolysis probe, as shown in FIG. 26B. The hydrolysis probe 2611 can be a fluorescently labeled oligonucleotide probe that can specifically hybridize to a portion (e.g., between about 10 and about 25 nucleotides) of the target cell-free nucleic acid molecule 2613, wherein the hybridized portion comprises two or more phased variants. The hydrolysis probe 2611 can be labeled with a fluorescent reporter at the 5′ end and a quencher at the 3′ end. When the hydrolysis probe is intact (e.g., not cleaved), the fluorescence of the reporter is quenched due to its proximity to the quencher (FIG. 26B). During annealing operation of amplification reaction of the plurality of cell-free nucleic acid molecules obtained or derived from the subject, 5′→3′ exonuclease activity of certain thermostable polymerases (e.g., Taq or Tth) The amplification reaction of the plurality of cell-free nucleic acid molecules obtained or derived from the subject can include a combined annealing/extension operation during which the hydrolysis probe hybridizes to the target cell-free nucleic acid molecule, and the dsDNA-specific 5′→3′ exonuclease activity of a thermostable polymerase (e.g., Taq or Tth) cleaves off the fluorescent reporter from the hydrolysis probe. As a result, the fluorescent reporter is separated from the quencher, resulting in a fluorescence signal that is proportional to the amount of target in the sample (e.g., (i) a total number of cell-free nucleic acid molecules identified to comprise the plurality of phased variants in each state or (ii) an average number of the plurality of phased variants per each cell-free nucleic acid molecule identified to comprise a plurality of phased variants, as disclosed herein).


In some embodiments of any one of the methods disclosed herein, the reporter agent can comprise a fluorescent reporter. Non-limiting examples of a fluorescent reporter include fluorescein amidite (FAM, 2-[3-(dimethylamino)-6-dimethyliminio-xanthen-9-yl]benzoate TAMRA, (2E)-2-[(2E,4E)-5-(2-tert-butyl-9-ethyl-6,8,8-trimethyl-pyrano[3,2-g]quinolin-1-ium-4-yl)penta-2,4-dienylidene]-1-(6-hydroxy-6-oxo-hexyl)-3,3-dimethyl-indoline-5-sulfonate Dy 750, 6-carboxy-2′,4,4′,5′,7,7′-hexachlorofluorescein, 4,5,6,7-Tetrachlorofluorescein TET™ sulforhodamine 101 acid chloride succinimidyl ester Texas Red-X, ALEXA Dyes, Bodipy Dyes, cyanine Dyes, Rhodamine 123 (hydrochloride), Well RED Dyes, MAX, and TEX 613. In some cases, the reporter agent further comprises a quencher, as disclosed herein. Non-limiting examples of a quencher can include Black Hole Quencher, Iowa Black Quencher, and 4-dimethylaminoazobenzene-4′-sulfonyl chloride (DABCYL).


In some embodiments of any one of the methods disclosed herein, any PCR reaction utilizing the set of nucleic acid probes can be performed using real-time PCR (qPCR). Alternatively, the PCR reaction utilizing the set of nucleic acid probes can be performed using digital PCR (dPCR).


Provided in FIG. 24 is an example flowchart of a process to perform a clinical intervention and/or treatment based on detecting circulating-tumor nucleic acids in an individual's biological sample. In several embodiments, detection of circulating-tumor nucleic acids is determined by the detection of somatic variants in phase in a cell-free nucleic acid sample. In many embodiments, detection of circulating-tumor nucleic acids indicates cancer is present, and thus appropriate clinical intervention and/or treatment can be performed.


Referring to FIG. 24, process 2400 can begin with obtaining, preparing, and sequencing (2401) cell-free nucleic acids obtained from a non-invasive biopsy (e.g., liquid or waste biopsy), utilizing a capture sequencing approach across regions shown to harbor a plurality of genetic mutations or variants occurring in phase. In several embodiments, cfDNA and/or cfRNA is extracted from plasma, blood, lymph, saliva, urine, stool, and/or other appropriate bodily fluid. Cell-free nucleic acids can be isolated and purified by any appropriate means. In some embodiments, column purification is utilized (e.g., QIAamp Circulating Nucleic Acid Kit from Qiagen, Hilden, Germany). In some embodiments, isolated RNA fragments can be converted into complementary DNA for further downstream analysis.


In some embodiments, a biopsy is extracted prior to any indication of cancer. In some embodiments, a biopsy is extracted to provide an early screen in order to detect a cancer. In some embodiments, a biopsy is extracted to detect if residual cancer exists after a treatment. In some embodiments, a biopsy is extracted during treatment to determine whether the treatment is providing the desired response. Screening of any particular cancer can be performed. In some embodiments, screening is performed to detect a cancer that develops somatic phased variants in stereotypical regions in the genome, such as (for example) lymphoma. In some embodiments, screening is performed to detect a cancer in which somatic phased variants were discovered utilizing a prior extracted cancer biopsy.


In some embodiments, a biopsy is extracted from an individual with a determined risk of developing cancer, such as those with a familial history of the disorder or have determined risk factors (e.g., exposure to carcinogens). In many embodiments, a biopsy is extracted from any individual within the general population. In some embodiments, a biopsy is extracted from individuals within a particular age group with higher risk of cancer, such as, for example, aging individuals above the age of 50. In some embodiments, a biopsy is extracted from an individual diagnosed with and treated for a cancer.


In some embodiments, extracted cell-free nucleic acids are prepared for sequencing. Accordingly, cell-free nucleic acids are converted into a molecular library for sequencing. In some embodiments, adapters and/or primers are attached onto cell-free nucleic acids to facilitate sequencing. In some embodiments, targeted sequencing of particular genomic loci is to be performed, and thus particular sequences corresponding to the particular loci are captured via hybridization prior to sequencing (e.g., capture sequencing). In some embodiments, capture sequencing is performed utilizing a set of probes that pull down (or capture) regions that have been discovered to commonly harbor phased variants for a particular cancer (e.g., lymphoma). In some embodiments, capture sequencing is performed utilizing a set of probes that pull down (or capture) regions that have been discovered to harbor phased variants as determined prior by sequencing a biopsy of the cancer. More detailed discussion of capture sequencing and probes is provided in the section entitled “Capture Sequencing.”


In some embodiments, any appropriate sequencing technique can be utilized that can detect phased variants indicative of circulating-tumor nucleic acids. Sequencing techniques include (but are not limited to) 454 sequencing, Illumina sequencing, SOLiD sequencing, Ion Torrent sequencing, single-read sequencing, paired-end sequencing, etc.


Process 2400 analyzes (2403) the cell-free nucleic acid sequencing result to detect circulating-tumor nucleic acid sequences, as determined by detection of somatic variants occurring in phase. Because cancers are actively growing and expanding, neoplastic cells are often releasing biomolecules (especially nucleic acids) into the vasculature, lymph, and/or waste systems. In addition, due to biophysical constraints in their local environment, neoplastic cells are often rupturing, releasing their inner cell contents into the vasculature, lymph, and/or waste systems. Accordingly, it is possible to detect distal primary tumors and/or metastases from a liquid or waste biopsy.


Detection of circulating-tumor nucleic acid sequences indicates that a cancer is present in the individual being examined. Accordingly, based on detection of circulating-tumor nucleic acids, a clinical intervention and/or treatment may be performed (2405). In a number of embodiments, a clinical procedure is performed, such as (for example) a blood test, genetic test, medical imaging, physical exam, a tumor biopsy, or any combination thereof. In several embodiments, diagnostics are preformed to determine the particular stage of cancer. In a number of embodiments, a treatment is performed, such as (for example) chemotherapy, radiotherapy, chemoradiotherapy, immunotherapy, hormone therapy, targeted drug therapy, surgery, transplant, transfusion, medical surveillance, or any combination thereof. In some embodiments, an individual is assessed and/or treated by medical professional, such as a doctor, physician, physician's assistant, nurse practitioner, nurse, caretaker, dietician, or similar.


Various embodiments of the present disclosure are directed towards utilizing detection of cancer to perform clinical interventions. In a number of embodiments, an individual has a liquid or waste biopsy screened and processed by methods described herein to indicate that the individual has cancer and thus an intervention is to be performed. Clinical interventions include clinical procedures and treatments. Clinical procedures include (but are not limited to) blood tests, genetic test, medical imaging, physical exams, and tumor biopsies. Treatments include (but are not limited to) chemotherapy, radiotherapy, chemoradiotherapy, immunotherapy, hormone therapy, targeted drug therapy, surgery, transplant, transfusion, and medical surveillance. In several embodiments, diagnostics are performed to determine the particular stage of cancer. In some embodiments, an individual is assessed and/or treated by medical professional, such as a doctor, physician, physician's assistant, nurse practitioner, nurse, caretaker, dietician, or similar.


In several embodiments as described herein a cancer can be detected utilizing a sequencing result of cell-free nucleic acids derived from blood, serum, cerebrospinal fluid, lymph fluid, urine or stool. In many embodiments, cancer is detected when a sequencing result has one or more somatic variants present in phase within a short genetic window, such as the length of a cell-free molecule (e.g., about 170 bp). In numerous embodiments, a statistical method is utilized to determine whether the presence of phased variants is derived from a cancerous source (as opposed to molecular artifact or other biological source). Various embodiments utilize a Monte Carlo sampling method as the statistical method to determine whether a sequencing result of cell-free nucleic acids includes sequences of circulating-tumor nucleic acids based on a score as determined by the presence of phased variants. Accordingly, in a number of embodiments, cell-free nucleic acids are extracted, processed, and sequenced, and the sequencing result is analyzed to detect cancer. This process is especially useful in a clinical setting to provide a diagnostic scan.


An exemplary procedure for a diagnostic scan of an individual for a B-cell cancer is as follows:

    • (a) extract liquid or waste biopsy from individual,
    • (b) prepare and perform targeted sequencing of cell-free nucleic acids from biopsy utilizing nucleic acid probes specific for the B-cell cancer,
    • (c) detect phased variants in a sequencing results that are indicative of circulating-tumor nucleic acid sequences, and
    • (d) perform clinical intervention based on detection of circulating-tumor nucleic acid sequences.


An exemplary procedure for a personalized diagnostic scan of an individual for a cancer that has been previously sequenced to detect phased variants in particular genomic loci is as follows:

    • extract cancer biopsy from individual
    • sequence cancer biopsy to detect phased variants that have accumulated in the cancer
      • (a) design and synthesize nucleic acid probes for genomic loci that include the positions of the detected phased variants,
      • (b) extract liquid or waste biopsy from individual,
      • (c) prepare and perform targeted sequencing of cell-free nucleic acids from biopsy utilizing the designed and synthesized nucleic acid probes,
      • (d) detect phased variants in a sequencing results that are indicative of circulating-tumor nucleic acid sequences, and
      • (e) perform clinical intervention based on detection of circulating-tumor nucleic acid sequences.


In some embodiments of any one of the methods disclosed herein, at least a portion of the identified one or more cell-free nucleic acid molecules comprising the plurality of phased variants can be further analyzed for determining the condition of the subject. In such analysis, (i) the identified one or more cell-free nucleic acid molecules and (ii) other cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules that do not comprise the plurality of phased variants can be analyzed as different variables. In some cases, a ratio of (i) a number the identified one or more cell-free nucleic acid molecules and (ii) a number of the other cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules that do not comprise the plurality of phased variants can be used a factor to determine the condition of the subject. In some cases, comparison of (i) a position(s) of the identified one or more cell-free nucleic acid molecules relative to the reference genomic sequence and (ii) a position(s) of the other cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules that do not comprise the plurality of phased variants relative to the reference genomic sequence can be used a factor to determine the condition of the subject.


Alternatively, in some cases, the analysis of the identified one or more cell-free nucleic acid molecules comprising the plurality of phased variants for determining the condition of the subject may not and need not be based on the other cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules that do not comprise the plurality of phased variants. As disclosed herein, non-limiting examples of information or characteristics of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can include (i) a total number of such cell-free nucleic acid molecules and (ii) an average number of the plurality of phased variations per each nucleic acid molecule in the population of identified cell-free nucleic acid molecules.


Thus, in some embodiments of any one of the methods disclosed herein, a number of the plurality of phased variants from the one or more cell-free nucleic acid molecules that have been identified to have the plurality of phased variants can be indicative of the condition of the subject. In some cases, a ratio of (i) the number of the plurality of phased variants from the one or more cell-free nucleic acid molecules and (ii) a number of single nucleotide variants from the one or more cell-free nucleic acid molecules can be indicative of the condition of the subject. For instance, a particular condition (e.g., follicular lymphoma) can exhibit a signature ratio that is different than that of another condition (e.g., breast cancer). In some examples, for cancer or solid tumor, the ratio as disclosed herein can be between about 0.01 and about 0.20. In some examples, for cancer or solid tumor, the ratio as disclosed herein can be about 0.01, about 0.02, about 0.03, about 0.04, about 0.05, about 0.06, about 0.07, about 0.08, about 0.09, about 0.10, about 0.11, about 0.12, about 0.13, about 0.14, about 0.15, about 0.16, about 0.17, about 0.18, about 0.19, or about 0.20. In some examples, for cancer or solid tumor, the ratio as disclosed herein can be at least or up to about 0.01, at least or up to about 0.02, at least or up to about 0.03, at least or up to about 0.04, at least or up to about 0.05, at least or up to about 0.06, at least or up to about 0.07, at least or up to about 0.08, at least or up to about 0.09, at least or up to about 0.10, at least or up to about 0.11, at least or up to about 0.12, at least or up to about 0.13, at least or up to about 0.14, at least or up to about 0.15, at least or up to about 0.16, at least or up to about 0.17, at least or up to about 0.18, at least or up to about 0.19, or at least or up to about 0.20.


In some embodiments of any one of the methods disclosed herein, a frequency of the plurality of phased variants in the one or more cell-free nucleic acid molecules that have been identified can be indicative of the condition of the subject. In some cases, based on the sequencing data disclosed herein, an average frequency of the plurality of phased variant per a predetermined bin length (e.g., a bin of about 50 base pairs) within each of the identified cell-free nucleic acid molecule can be indicative of the condition of the subject. In some cases, based on the sequencing data disclosed herein, an average frequency of the plurality of phased variant per a predetermined bin length (e.g., a bin of about 50 base pairs) within each of the identified cell-free nucleic acid molecule that is associated with a particular gene (e.g., BCL2, PIM1) can be indicative of the condition of the subject. The size of the bin can be about 30, about 40, about 50, about 60, about 70, or about 80.


In some examples, a first condition (e.g., Hodgkin lymphoma or HL) can exhibit a first average frequency and a second condition (e.g., DLBCL) can exhibit a different average frequency, thereby allowing identification and/or determination of whether the subject has or is suspected of having a particular condition. In some examples, a first sub-type of a disease can exhibit a first average frequency and a second sub-type of the same disease can exhibit a different average frequency, thereby allowing identification and/or determination of whether the subject has or is suspected of having a particular sub-type of the disease. For example, the subject can have DLBCL, and one or more cell-free nucleic acid molecules derived from germinal center B-cell (GCB) DLBCL or activated B-cell (ABC) DLBCL can have different average frequency of the plurality of phased variant per a predetermined bin length, as disclosed herein.


In some example, a condition of the subject may have a predetermined number of phased variants spanning predetermined genomic loci (i.e., a predetermined frequency of phased variants). When the predetermined frequency of phased variants match a frequency of the plurality of phased variants in the one or more cell-free nucleic acid molecules that have been identified from a plurality of cell-free nucleic acid molecules from the subject, it may indicate that the subject has such condition.


In some embodiments of any one of the methods disclosed herein, the one or more cell-free nucleic acid molecules identified to comprise the plurality of phased variants can be analyzed to determine their genomic origin (e.g., which gene locus they are from). The genomic origin of the one or more cell-free nucleic acid molecules that have been identified can be indicative of the condition of the subject, as different disease can have the plurality of phased variants in different signature genes. For example, a subject can have GCB DLBCL, and one or more cell-free nucleic acid molecules originated from GCBs of the subject can have the phased variants prevalent in BCL2 gene, while one or more cell-free nucleic acid molecules originated from ABCs of the same subject may not comprise as many phased variants in the BCL2 gene as those from GCBs. On the other hand, a subject can have ABC DLBCL, and one or more cell-free nucleic acid molecules originated from ABCs of the subject can have the phased variants prevalent in PIM1 gene, while one or more cell-free nucleic acid molecules originated from GCBs of the same subject may not comprise as many phased variants in the PIM1 gene as those from ABCs.


In some embodiments of any one of the methods disclosed herein, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, at least or up to about 50%, at least or up to about 55%, at least or up to about 60%, at least or up to about 65%, at least or up to about 70%, at least or up to about 75%, at least or up to about 80%, at least or up to about 85%, at least or up to about 90%, at least or up to about 95%, at least or up to about 99%, or about 100% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 2 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, or at least or up to about 50% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 3 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, or at least or up to about 50% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 4 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, or at least or up to about 50% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 5 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, or at least or up to about 50% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 6 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, or at least or up to about 50% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 7 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, or at least or up to about 50% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 8 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, or at least or up to about 50% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 9 nucleotides away from an adjacent SNV.


In some embodiments of any one of the methods disclosed herein, at least or up to about 5%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, or at least or up to about 50% of the one or more cell-free nucleic acid molecules comprising the plurality of phased variants can comprise a single nucleotide variant (SNV) that is at least 10 nucleotides away from an adjacent SNV.


C. Reference Genomic Sequence

In some embodiments of any one of the methods disclosed herein, the reference genomic sequence can be at least a portion of a nucleic acid sequence database (i.e., a reference genome), which database is assembled from genetic data and intended to represent the genome of a reference cohort. In some cases, a reference cohort can be a collection of individuals from a specific or varying genotype, haplotype, demographics, sex, nationality, age, ethnicity, relatives, physical condition (e.g., healthy or having been diagnosed to have the same or different condition, such as a specific type of cancer), or other groupings. A reference genomic sequence as disclosed herein can be a mosaic (or a consensus sequence) of the genomes of two or more individuals. The reference genomic sequence can comprise at least a portion of a publicly available reference genome or a private reference genome. Non-limiting examples of a human reference genome include hg19, hg18, hg17, hg16, and hg38.


In some examples, the reference genomic sequence can comprise at least or up to about 500 nucleobases, at least or up to about 1 kilobase (kb), at least or up to about 2 kb, at least or up to about 3 kb, at least or up to about 4 kb, at least or up to about 5 kb, at least or up to about 6 kb, at least or up to about 7 kb, at least or up to about 8 kb, at least or up to about 9 kb, at least or up to about 10 kb, at least or up to about 20 kb, at least or up to about 30 kb, at least or up to about 40 kb, at least or up to about 50 kb, at least or up to about 60 kb, at least or up to about 70 kb, at least or up to about 80 kb, at least or up to about 90 kb, at least or up to about 100 kb, at least or up to about 200 kb, at least or up to about 300 kb, at least or up to about 400 kb, at least or up to about 500 kb, at least or up to about 600 kb, at least or up to about 700 kb, at least or up to about 800 kb, at least or up to about 900 kb, at least or up to about 1,000 kb, at least or up to about 2,000 kb, at least or up to about 3,000 kb, at least or up to about 4,000 kb, at least or up to about 5,000 kb, at least or up to about 6,000 kb, at least or up to about 7,000 kb, at least or up to about 8,000 kb, at least or up to about 9,000 kb, at least or up to about 10,000 kb, at least or up to about 20,000 kb, at least or up to about 30,000 kb, at least or up to about 40,000 kb, at least or up to about 50,000 kb, at least or up to about 60,000 kb, at least or up to about 70,000 kb, at least or up to about 80,000 kb, at least or up to about 90,000 kb, or at least or up to about 100,000 kb.


In some cases, the reference genomic sequence can be whole reference genome or a portion (e.g., a portion relevant to the condition of interest) of the genome. For example, the reference genomic sequence can consist of at least 1, 2, 3, 4, 5, or more genes that experience aberrant somatic hypermutation under certain types of cancer. In some cases, the reference genomic sequence can be a whole chromosomal sequence, or a fragment thereof. In some cases, the reference genomic sequence can comprise two or more (e.g., at least 2, 3, 4, 5, or more) different portions of the reference genome that are not adjacent to one another (e.g., within the same chromosome or from different chromosomes).


In some embodiments of any one of the methods disclosed herein, the reference genomic sequence can be at least a portion of a reference genome of a selected individual, such as a healthy individual or the subject of any of the methods as disclosed herein.


In some cases, the reference genomic sequence can be derived from an individual who is not the subject (e.g., a healthy control individual). Alternatively, in some cases, the reference genomic sequence can be derived from a sample of the subject. In some examples, the sample can be a healthy sample of the subject. The healthy sample of the subject can be any subject cell that is healthy, e.g., a healthy leukocyte. By comparing sequencing data of the plurality of cell-free nucleic acid molecules (e.g., cfDNA molecules) of the subject against at least a portion of the genomic sequence of a healthy cell of the same subject, one or more cell-free nucleic acid molecules that comprise the plurality of phased variants can be identified and analyzed, as disclosed herein. In some examples, the sample can be a diseased sample of the subject, such as a diseased cell (e.g., a tumor cell) or a solid tumor. The reference genomic sequence can be obtained from sequencing at least a portion of a diseased cell of the subject or from sequencing a plurality of cell-free nucleic acid molecules obtained from the solid tumor of the subject. Once the subject is diagnosed to have a particular condition (e.g., a disease), the reference genomic sequence of the subject that comprises the plurality of phased variants can be used to determine whether the subject still exhibits the same phased variants at future time points. In this context, any new phased variants identified between the “diseased” reference genomic sequence of the subject and new cell-free nucleic acid molecules obtained or derived from the subject can indicate a reduced degree of aberrant somatic hypermutation in particular genomic loci (e.g., at least a partial remission).


In various embodiments, diagnostic scans can be performed for any neoplasm type, including (but not limited to) acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), anal cancer, astrocytomas, basal cell carcinoma, bile duct cancer, bladder cancer, breast cancer, Burkitt's lymphoma, cervical cancer, chronic lymphocytic leukemia (CLL) chronic myelogenous leukemia (CML), chronic myeloproliferative neoplasms, colorectal cancer, diffuse large B-cell lymphoma, endometrial cancer, ependymoma, esophageal cancer, esthesioneuroblastoma, Ewing sarcoma, fallopian tube cancer, follicular lymphoma, gallbladder cancer, gastric cancer, gastrointestinal carcinoid tumor, hairy cell leukemia, hepatocellular cancer, Hodgkin lymphoma, hypopharyngeal cancer, Kaposi sarcoma, Kidney cancer, Langerhans cell histiocytosis, laryngeal cancer, leukemia, liver cancer, lung cancer, lymphoma, melanoma, Merkel cell cancer, mesothelioma, mouth cancer, neuroblastoma, non-Hodgkin lymphoma, non-small cell lung cancer, osteosarcoma, ovarian cancer, pancreatic cancer, pancreatic neuroendocrine tumors, pharyngeal cancer, pituitary tumor, prostate cancer, rectal cancer, renal cell cancer, retinoblastoma, skin cancer, small cell lung cancer, small intestine cancer, squamous neck cancer, T-cell lymphoma, testicular cancer, thymoma, thyroid cancer, uterine cancer, vaginal cancer, and vascular tumors.


In a number of embodiments, a diagnostic scan is utilized to provide an early detection of cancer. In some embodiments, a diagnostic scan detects cancer in individuals having stage I, II, or III cancer. In some embodiments, a diagnostic scan is utilized to detect MRD or tumor burden. In some embodiments, a diagnostic scan is utilized to determine progress (e.g., progression or regression) of treatment. Based on the diagnostic scan, a clinical procedure and/or treatment may be performed.


D. Nucleic Acid Probes

In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes can be designed based on the any of the subject reference genomic sequences of the present disclosure. In some cases, the set of nucleic acid probes can be designed based on the plurality of phased variants that have been identified by comparing (i) sequencing data from a solid tumor of the subject and (ii) sequencing data from a healthy cell of the subject or a healthy cohort, as disclosed herein. The set of nucleic acid probes can be designed based on the plurality of phased variants that have been identified by comparing (i) sequencing data from a solid tumor of the subject and (ii) sequencing data from a healthy cell of the subject. The set of nucleic acid probes can be designed based on the plurality of phased variants that have been identified by comparing (i) sequencing data from a solid tumor of the subject and (ii) sequencing data from a healthy cell of a healthy cohort.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes are designed to hybridize to sequences of genomic loci associated with the condition. As disclosed herein, the genomic loci associated with the condition can be determined to experience or exhibit aberrant somatic hypermutation when the subject has the condition. Alternatively, the set of nucleic acid probes are designed to hybridize to sequences of stereotyped regions.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes can be designed to hybridize to at least about 5%, at least about 10%, at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, at least about 90%, at least about 95%, at least about 99%, or about 100% of the genomic regions identified in Table 1.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes can be designed to hybridize to at least a portion of cell-free nucleic acid (e.g., cfDNA) molecules derived from at least about 5%, at least about 10%, at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, at least about 90%, at least about 95%, at least about 99%, or about 100% of the genomic regions identified in Table 1.


In some embodiments of any one of the methods disclosed herein, each nucleic acid probe of the set of nucleic acid probes can have at least about 50%, at least about 55%, at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90% sequence identity, at least about 95% sequence identity, at least about 99%, or about 100% sequence identity to a probe sequence selected from Table 6.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes can comprise at least about 1%, at least about 2%, at least about 3%, at least about 4%, at least about 5%, at least about 6%, at least about 7%, at least about 8%, at least about 9%, at least about 10%, at least about 15%, at least about 20%, at least about 25%, at least about 30%, at least about 35%, at least about 40%, at least about 45%, at least about 50%, at least about 55%, at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90%, at least about 95%, at least about 99%, or about 100% of probe sequences in Table 6.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes can be designed to cover one or more target genomic regions comprising at least or up to about 500 nucleobases, at least or up to about 1 kilobase (kb), at least or up to about 2 kb, at least or up to about 3 kb, at least or up to about 4 kb, at least or up to about 5 kb, at least or up to about 6 kb, at least or up to about 7 kb, at least or up to about 8 kb, at least or up to about 9 kb, at least or up to about 10 kb, at least or up to about 20 kb, at least or up to about 30 kb, at least or up to about 40 kb, at least or up to about 50 kb, at least or up to about 60 kb, at least or up to about 70 kb, at least or up to about 80 kb, at least or up to about 90 kb, at least or up to about 100 kb, at least or up to about 200 kb, at least or up to about 300 kb, at least or up to about 400 kb, or at least or up to about 500 kb.


In some embodiments of any one of the methods disclosed herein, a target genomic region (e.g., a target genomic locus) of the one or more target genomic regions can comprise at most about 200 nucleobases, at most about 300 nucleobases, 400 nucleobases, at most about 500 nucleobases, at most about 600 nucleobases, at most about 700 nucleobases, at most about 800 nucleobases, at most about 900 nucleobases, at most about 1 kb, at most about 2 kb, at most about 3 kb, at most about 4 kb, at most about 5 kb, at most about 6 kb, at most about 7 kb, at most about 8 kb, at most about 9 kb, at most about 10 kb, at most about 11 kb, at most about 12 kb, at most about 13 kb, at most about 14 kb, at most about 15 kb, at most about 16 kb, at most about 17 kb, at most about 18 kb, at most about 19 kb, at most about 20 kb, at most about 25 kb, at most about 30 kb, at most about 35 kb, at most about 40 kb, at most about 45 kb, at most about 50 kb, or at most about 100 kb.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes can comprise at least or up to about 10, at least or up to about 20, at least or up to about 30, at least or up to about 40, at least or up to about 50, at least or up to about 60, at least or up to about 70, at least or up to about 80, at least or up to about 90, at least or up to about 100, at least or up to about 200, at least or up to about 300, at least or up to about 400, at least or up to about 500, at least or up to about 600, at least or up to about 700, at least or up to about 800, at least or up to about 900, at least or up to about 1,000, at least or up to about 2,000, at least or up to about 3,000, at least or up to about 4,000, or at least or up to about 5,000 different nucleic acid probes designed to hybridize to different target nucleic acid sequences.


In some embodiments of any one of the methods disclosed herein, the set of nucleic acid probes can have a length of at least or up to about 50, at least or up to about 55, at least or up to about 60, at least or up to about 65, at least or up to about 70, at least or up to about 75, at least or up to about 80, at least or up to about 85, at least or up to about 90, at least or up to about 95, or at least or up to about 100 nucleotides.


In one aspect, the present disclosure provides a composition comprising a bait set comprising any one of the set of nucleic acid probes disclosed herein. The composition comprising such bait set can be used for any of the methods disclosed herein. In some cases, the set of nucleic acid probes can be designed to pull down (or capture) cfDNA molecules. In some cases, the set of nucleic acid probes can be designed to pull down (or capture) cfRNA molecules.


In some embodiments, the bait set can comprise a set of nucleic acid probes designed to pull down cell-free nucleic acid (e.g., cfDNA) molecules derived from genomic regions set forth in Table 1. The set of nucleic acid probes can be designed to pull down cell-free nucleic acid molecules derived from at least or up to about 1%, at least or up to about 2%, at least or up to about 3%, at least or up to about 4%, at least or up to about 5%, at least or up to about 6%, at least or up to about 7%, at least or up to about 8%, at least or up to about 9%, at least or up to about 10%, at least or up to about 15%, at least or up to about 20%, at least or up to about 25%, at least or up to about 30%, at least or up to about 35%, at least or up to about 40%, at least or up to about 45%, at least or up to about 50%, at least or up to about 55%, at least or up to about 60%, at least or up to about 65%, at least or up to about 70%, at least or up to about 75%, at least or up to about 80%, at least or up to about 85%, at least or up to about 90%, at least or up to about 95%, at least or up to about 99%, or about 100% of the genomic regions set forth in Table 1. In some cases, the set of nucleic acid probes can be designed to pull down cfDNA molecules. In some cases, the set of nucleic acid probes can be designed to pull down cfRNA molecules.


In some embodiments of any one of the compositions disclosed herein, an individual nucleic acid probe (or each nucleic acid probe) of the set of nucleic acid probes can comprise a pull-down tag. The pull-down tag can be used to enrich a sample (e.g., a sample comprising the plurality of nucleic acid molecules obtained or derived from the subject) for a specific subset (e.g., for cell-free nucleic acid molecules comprising the plurality of phased variants as disclosed herein).


In some cases, pull-down tag can comprise a nucleic acid barcode (e.g., on either or both sides of the nucleic acid probe). By utilizing beads or substrates comprising nucleic acid sequences having complementarity to the nucleic acid barcode, the nucleic acid barcode can be used to pull-down and enrich for any nucleic acid probe that is hybridized to a target cell-free nucleic acid molecule. Alternatively or in addition to, the nucleic acid barcode can be used to identify the target cell-free nucleic acid molecule from any sequencing data (e.g., sequencing by amplification) obtained by using any of the set of nucleic acid probes disclosed herein.


In some cases, the pull-down tag can comprise an affinity target moiety that can be specifically recognized and bound by an affinity binding moiety. The affinity binding moiety specifically can bind the affinity target moiety to form an affinity pair. In some cases, by utilizing beads or substrates comprising the affinity binding moiety, the affinity target moiety can be used to pull-down and enrich for any nucleic acid probe that is hybridized to a target cell-free nucleic acid molecule. Alternatively, the pull-down tag can comprise the affinity binding moiety, while the beads/substrates can comprise the affinity target moiety. Non-limiting examples of the affinity pair can include biotin/avidin, antibody/antigen, biotin/streptavidin, metal/chelator, ligand/receptor, nucleic acid and binding protein, and complementary nucleic acids. In an example, the pull-down tag can comprise biotin.


In some embodiments of any one of the compositions disclosed herein, a length of a target cell-free nucleic acid (e.g., cfDNA) molecule that is to be pulled down by any subject nucleic acid probe can be about 100 nucleotides to about 200 nucleotides. The length of the target cell-free nucleic acid molecule can be at least about 100 nucleotides. The length of the target cell-free nucleic acid molecule can be at most about 200 nucleotides. The length of the target cell-free nucleic acid molecule can be about 100 nucleotides to about 110 nucleotides, about 100 nucleotides to about 120 nucleotides, about 100 nucleotides to about 130 nucleotides, about 100 nucleotides to about 140 nucleotides, about 100 nucleotides to about 150 nucleotides, about 100 nucleotides to about 160 nucleotides, about 100 nucleotides to about 170 nucleotides, about 100 nucleotides to about 180 nucleotides, about 100 nucleotides to about 190 nucleotides, about 100 nucleotides to about 200 nucleotides, about 110 nucleotides to about 120 nucleotides, about 110 nucleotides to about 130 nucleotides, about 110 nucleotides to about 140 nucleotides, about 110 nucleotides to about 150 nucleotides, about 110 nucleotides to about 160 nucleotides, about 110 nucleotides to about 170 nucleotides, about 110 nucleotides to about 180 nucleotides, about 110 nucleotides to about 190 nucleotides, about 110 nucleotides to about 200 nucleotides, about 120 nucleotides to about 130 nucleotides, about 120 nucleotides to about 140 nucleotides, about 120 nucleotides to about 150 nucleotides, about 120 nucleotides to about 160 nucleotides, about 120 nucleotides to about 170 nucleotides, about 120 nucleotides to about 180 nucleotides, about 120 nucleotides to about 190 nucleotides, about 120 nucleotides to about 200 nucleotides, about 130 nucleotides to about 140 nucleotides, about 130 nucleotides to about 150 nucleotides, about 130 nucleotides to about 160 nucleotides, about 130 nucleotides to about 170 nucleotides, about 130 nucleotides to about 180 nucleotides, about 130 nucleotides to about 190 nucleotides, about 130 nucleotides to about 200 nucleotides, about 140 nucleotides to about 150 nucleotides, about 140 nucleotides to about 160 nucleotides, about 140 nucleotides to about 170 nucleotides, about 140 nucleotides to about 180 nucleotides, about 140 nucleotides to about 190 nucleotides, about 140 nucleotides to about 200 nucleotides, about 150 nucleotides to about 160 nucleotides, about 150 nucleotides to about 170 nucleotides, about 150 nucleotides to about 180 nucleotides, about 150 nucleotides to about 190 nucleotides, about 150 nucleotides to about 200 nucleotides, about 160 nucleotides to about 170 nucleotides, about 160 nucleotides to about 180 nucleotides, about 160 nucleotides to about 190 nucleotides, about 160 nucleotides to about 200 nucleotides, about 170 nucleotides to about 180 nucleotides, about 170 nucleotides to about 190 nucleotides, about 170 nucleotides to about 200 nucleotides, about 180 nucleotides to about 190 nucleotides, about 180 nucleotides to about 200 nucleotides, or about 190 nucleotides to about 200 nucleotides. The length of the target cell-free nucleic acid molecule can be about 100 nucleotides, about 110 nucleotides, about 120 nucleotides, about 130 nucleotides, about 140 nucleotides, about 150 nucleotides, about 160 nucleotides, about 170 nucleotides, about 180 nucleotides, about 190 nucleotides, or about 200 nucleotides. In some examples, the length of the target cell-free nucleic acid molecule can range between about 100 nucleotides and about 180 nucleotides.


In some embodiments of any one of the compositions disclosed herein, the genomic regions can be associated with a condition. The genomic regions can be determined to exhibit aberrant somatic hypermutation when a subject has the condition. For example, the condition can comprise B-cell lymphoma or a sub-type thereof, such as diffuse large B-cell lymphoma, follicular lymphoma, Burkitt lymphoma, and B-cell chronic lymphocytic leukemia. Additional details of the condition are provided below.


In some embodiments of any one of the compositions disclosed herein, the composition further comprises the plurality of cell-free nucleic acid (e.g., cfDNA) molecules obtained or derived from the subject.


E. Diagnostic or Therapeutic Applications

A number of embodiments are directed towards performing a diagnostic scan on cell-free nucleic acids of an individual and then based on results of the scan indicating cancer, performing further clinical procedures and/or treating the individual. In accordance with various embodiments, numerous types of neoplasms can be detected.


In some embodiments of any one of the methods disclosed herein, the method can comprise determining that the subject has the condition or determining a degree or status of the condition of the subject, based on the one or more cell-free nucleic acid molecules comprising the plurality of phased variants. In some cases, the method can further comprise determining that the one or more cell-free nucleic acid molecules (each identified to comprise a plurality of phased variants) are derived from a sample associated with the condition (e.g., cancer), based on a statistical model analysis (i.e., molecular analysis). For example, the method can comprise using one or more algorithms (e.g., Monte Carlos simulation) to determine a first probability of a cell-free nucleic acid identified to have a plurality of phased variants being associated with or originated from a first condition (e.g., 80%) and a second probability of the same cell-free nucleic acid being associated with or originated from a second condition (or from a healthy cell) (e.g., 20%). In some cases, the method can comprise determining a likelihood or probability that the subject has one or more conditions based on analysis of the one or more cell-free nucleic acid molecules each identified to comprise a plurality of phased variants (i.e., macro- or global analysis). For example, the method can comprise using one or more algorithms (e.g., comprising one or more mathematical models as disclosed herein, such as binomial sampling) to analyze a plurality of cell-free nucleic acid molecules each identified to comprise a plurality of phased variants, thereby to determine a first probability of the subject having a first condition (e.g., 80%) and a second probability of the subject having a second condition (or being healthy) (e.g., 20%).


The statistical model analysis as disclosed herein can be an approximate solution by a numerical approximation such as a binomial model, a ternary model, a Monte Carlo simulation, or a finite difference method. In an example, the statistical model analysis as used herein can be a Monte Carlo statistical analysis. In another example, the statistical model analysis as used herein can be a binomial or ternary model analysis.


In some embodiments of any one of the methods disclosed herein, the method can comprise monitoring a progress of the condition of the subject based on the one or more cell-free nucleic acid molecules identified, such that each of the identified cell-free nucleic acid molecule comprises a plurality of phased variants. In some cases, the progress of the condition can be worsening of the condition, as described in the present disclosure (e.g., developing from stage I cancer to stage III cancer). In some cases, the progress of the condition can be at least a partial remission of the condition, as described in the present disclosure (e.g., downstaging from stage IV cancer to stage II cancer). Alternatively, in some cases, the progress of the condition can remain substantially the same between two different time points, as described in the present disclosure. In an example, the method can comprise determining likelihoods or probabilities of different progresses of the condition of the subject. For example, the method can comprise using one or more algorithms (e.g., comprising one or more mathematical models as disclosed herein, such as binomial sampling) to determine a first probability of the subject's condition being worse than before (e.g., 20%), a second probability of at least partial remission of the condition (e.g., 70%), and a third probability that the subject's condition is the same as before (e.g., 10%).


In some embodiments of any one of the methods disclosed herein, the method can comprise comprising performing a different procedure (e.g., follow-up diagnostic procedures) to confirm the condition of the subject, which condition has been determined and/or monitored progress thereof, as provided in the present disclosure. Non-limiting examples of a different procedure can include physical exam, medical imaging, genetic test, mammography, endoscopy, stool sampling, pap test, alpha-fetoprotein blood test, CA-125 test, prostate-specific antigen (PSA) test, biopsy extraction, bone marrow aspiration, and tumor marker detection tests. Medical imaging includes (but is not limited to) X-ray, magnetic resonance imaging (MRI), computed tomography (CT), ultrasound, and positron emission tomography (PET). Endoscopy includes (but is not limited to) bronchoscopy, colonoscopy, colposcopy, cystoscopy, esophagoscopy, gastroscopy, laparoscopy, neuroendoscopy, proctoscopy, and sigmoidoscopy.


In some embodiments of any one of the methods disclosed herein, the method can comprise determining a treatment for the condition of the subject based on the one or more cell-free nucleic acid molecules identified, each identified cell-free nucleic acid molecule comprising a plurality of phased variants. In some cases, the treatment can be determined based on (i) the determined condition of the subject and/or (ii) the determined progress of the condition of the subject. In addition, the treatment can be determined based on one or more additional factors of the following: sex, nationality, age, ethnicity, and other physical conditions of the subject. In some examples, the treatment can be determined based on one or more features of the plurality of phased variants of the identified cell-free nucleic acid molecules, as disclosed herein.


In some embodiments of any one of the methods disclosed herein, the subject may not have been subjected to any treatment for the condition, e.g., the subject may not have been diagnosed with the condition (e.g., a lymphoma). In some embodiments of any one of the methods disclosed herein, the subject may been subjected to a treatment for the condition prior to any subject method of the present disclosure. In some cases, the methods disclosed herein can be performed to monitor progress of the condition that the subject has been diagnosed with, thereby to (i) determine efficacy of the previous treatment and (ii) assess whether to keep the treatment, modify the treatment, or cancel the treatment in favor of a new treatment.


In some embodiments of any one of the methods disclosed herein, non-limiting examples of a treatment (e.g., prior treatment, new treatment to be determined based on the methods of the present disclosure, etc.) can include chemotherapy, radiotherapy, chemoradiotherapy, immunotherapy, adoptive cell therapy (e.g., chimeric antigen receptor (CAR) T cell therapy, CAR NK cell therapy, modified T cell receptor (TCR) T cell therapy, etc.) hormone therapy, targeted drug therapy, surgery, transplant, transfusion, or medical surveillance.


In some embodiments of any one of the methods disclosed herein, the condition can comprise a disease. In some embodiments of any one of the methods disclosed herein, the condition can comprise neoplasm, cancer, or tumor. In an example, the condition can comprise a solid tumor. In another example, the condition can comprise a lymphoma, such as B-cell lymphoma (BCL). Non-limiting examples of BCL can include diffuse large B-cell lymphoma (DLBCL), follicular lymphoma (FL), Burkitt lymphoma (BL), B-cell chronic lymphocytic leukemia (CLL), Marginal zone B-cell lymphoma (MZL), and Mantle cell lymphoma (MCL).


As disclosed herein, a treatment for a condition of subject can comprise administering the subject with one or more therapeutic agents. The one or more therapeutic drugs can be administered to the subject by one or more of the following: orally, intraperitoneally, intravenously, intraarterially, transdermally, intramuscularly, liposomally, via local delivery by catheter or stent, subcutaneously, intraadiposally, and intrathecally.


Non-limiting examples of the therapeutic drugs can include cytotoxic agents, chemotherapeutic agents, growth inhibitory agents, agents used in radiation therapy, anti-angiogenesis agents, apoptotic agents, anti-tubulin agents, and other agents to treat cancer, for example, anti-CD20 antibodies, anti-PD1 antibodies (e.g., Pembrolizumab) platelet derived growth factor inhibitors (e.g., GLEEVEC™ (imatinib mesylate)), a COX-2 inhibitor (e.g., celecoxib), interferons, cytokines, antagonists (e.g., neutralizing antibodies) that bind to one or more of the following targets PDGFR-β, BlyS, APRIL, BCMA receptor(s), TRAIL/Apo2, other bioactive and organic chemical agents, and the like.


Non-limiting examples of a cytotoxic agent can include radioactive isotopes (e.g., At211, I131, I125, Y90, Re186, Re188, Sm153, Bi212, P32, and radioactive isotopes of Lu), chemotherapeutic agents, e.g., methotrexate, adriamycin, vinca alkaloids (vincristine, vinblastine, etoposide), doxorubicin, melphalan, mitomycin C, chlorambucil, daunorubicin or other intercalating agents, enzymes and fragments thereof such as nucleolytic enzymes, antibiotics, and toxins such as small molecule toxins or enzymatically active toxins of bacterial, fungal, plant or animal origin.


Non-limiting examples of a chemotherapeutic agent can include alkylating agents such as thiotepa and CYTOXAN® cyclophosphamide; alkyl sulfonates such as busulfan, improsulfan and piposulfan; aziridines such as benzodopa, carboquone, meturedopa, and uredopa; ethylenimines and methylamelamines including altretamine, triethylenemelamine, triethylenephosphoramide, triethiylenethiophosphoramide and trimethylolmelamine; acetogenins (especially bullatacin and bullatacinone); delta-9-tetrahydrocannabinol (dronabinol, MARINOL®); beta-lapachone; lapachol; colchicines; betulinic acid; a camptothecin (including the synthetic analogue topotecan (HYCAMTIN®), CPT-11 (irinotecan, CAMPTOSAR®), acetylcamptothecin, scopolectin, and 9-aminocamptothecin); bryostatin; callystatin; CC-1065 (including its adozelesin, carzelesin and bizelesin synthetic analogues); podophyllotoxin; podophyllinic acid; teniposide; cryptophycins (particularly cryptophycin 1 and cryptophycin 8); dolastatin; duocarmycin (including the synthetic analogues, KW-2189 and CB1-TM1); eleutherobin; pancratistatin; a sarcodictyin; spongistatin; nitrogen mustards such as chlorambucil, chlornaphazine, cyclophosphamide, estramustine, ifosfamide, mechlorethamine, mechlorethamine oxide hydrochloride, melphalan, novembichin, phenesterine, prednimustine, trofosfamide, uracil mustard; nitrosoureas such as carmustine, chlorozotocin, fotemustine, lomustine, nimustine, and ranimnustine; antibiotics such as the enediyne antibiotics; dynemicin, including dynemicin A; an espiramicina; as well as neocarzinostatin chromophore and related chromoprotein enediyne antibiotic chromophores), aclacinomycins, actinomycin, anthramycin, azaserine, bleomycins, cactinomycin, carabicin, carminomycin, carzinophilin, chromomycinis, dactinomycin, daunorubicin, detorubicin, 6-diazo-5-oxo-L-norleucine, ADRIAMYCIN® doxorubicin (including morpholino-doxorubicin, cyanomorpholino-doxorubicin, 2-pyrrolino-doxorubicin and deoxydoxorubicin), epirubicin, esorubicin, idarubicin, marcellomycin, mitomycins such as mitomycin C, mycophenolic acid, nogalamycin, olivomycins, peplomycin, potfiromycin, puromycin, quelamycin, rodorubicin, streptonigrin, streptozocin, tubercidin, ubenimex, zinostatin, zorubicin; anti-metabolites such as methotrexate and 5-fluorouracil (5-FU); folic acid analogues such as denopterin, methotrexate, pteropterin, trimetrexate; purine analogs such as fludarabine, 6-mercaptopurine, thiamiprine, thioguanine; pyrimidine analogs such as ancitabine, azacitidine, 6-azauridine, carmofur, cytarabine, dideoxyuridine, doxifluridine, enocitabine, floxuridine; androgens such as calusterone, dromostanolone propionate, epitiostanol, mepitiostane, testolactone; anti-adrenals such as aminoglutethimide, mitotane, trilostane; folic acid replenisher such as folinic acid; aceglatone; aldophosphamide glycoside; aminolevulinic acid; eniluracil; amsacrine; bestrabucil; bisantrene; edatraxate; defofamine; demecolcine; diaziquone; eflornithine; elliptinium acetate; an epothilone; etoglucid; gallium nitrate; hydroxyurea; lentinan; lonidainine; maytansinoids such as maytansine and ansamitocins; mitoguazone; mitoxantrone; mopidanmol; nitraerine; pentostatin; phenamet; pirarubicin; losoxantrone; 2-ethylhydrazide; procarbazine; PSK® polysaccharide complex (JHS Natural Products, Eugene, Oreg.); razoxane; rhizoxin; sizofiran; spirogermanium; tenuazonic acid; triaziquone; 2,2′,2″-trichlorotriethylamine; trichothecenes (especially T-2 toxin, verrucarin A, roridin A and anguidine); urethan; vindesine (ELDISINE®, FILDESIN®); dacarbazine; mannomustine; mitobronitol; mitolactol; pipobroman; gacytosine; arabinoside (“Ara-C”); thiotepa; taxoids, for example taxanes including TAXOL® paclitaxel (Bristol-Myers Squibb Oncology, Princeton, N.J.), ABRAXANE™ Cremophor-free, albumin-engineered nanoparticle formulation of paclitaxel (American Pharmaceutical Partners, Schaumberg, Ill.), and TAXOTERE® docetaxel (Rhône-Poulenc Rorer, Antony, France); chlorambucil; gemcitabine (GEMZAR®); 6-thioguanine; mercaptopurine; methotrexate; platinum analogs such as cisplatin and carboplatin; vinblastine (VELBAN®); platinum; etoposide (VP-16); ifosfamide; mitoxantrone; vincristine (ONCOVIN®); oxaliplatin; leucovovin; vinorelbine (NAVELBINE®); novantrone; edatrexate; daunomycin; aminopterin; ibandronate; topoisomerase inhibitor RFS 2000; difluoromethylornithine (DMFO); retinoids such as retinoic acid; capecitabine (XELODA®); pharmaceutically acceptable salts, acids or derivatives of any of the above; as well as combinations of two or more of the above such as CHOP, an abbreviation for a combined therapy of cyclophosphamide, doxorubicin, vincristine, and prednisolone, and FOLFOX, an abbreviation for a treatment regimen with oxaliplatin (ELOXATIN™) combined with 5-FU and leucovorin.


Examples of a chemotherapeutic agent can also include “anti-hormonal agents” or “endocrine therapeutics” that act to regulate, reduce, block, or inhibit the effects of hormones that can promote the growth of cancer, and are often in the form of systemic, or whole-body treatment. They may be hormones themselves. Examples include anti-estrogens and selective estrogen receptor modulators (SERMs), including, for example, tamoxifen (including NOLVADEX® tamoxifen), EVISTA® raloxifene, droloxifene, 4-hydroxytamoxifen, trioxifene, keoxifene, LY117018, onapristone, and FARESTON® toremifene; anti-progesterones; estrogen receptor down-regulators (ERDs); agents that function to suppress or shut down the ovaries, for example, leutinizing hormone-releasing hormone (LHRH) agonists such as LUPRON® and ELIGARD) leuprolide acetate, goserelin acetate, buserelin acetate and tripterelin; other anti-androgens such as flutamide, nilutamide and bicalutamide; and aromatase inhibitors that inhibit the enzyme aromatase, which regulates estrogen production in the adrenal glands, such as, for example, 4(5)-imidazoles, aminoglutethimide, MEGASE® megestrol acetate, AROMASIN® exemestane, formestanie, fadrozole, RIVISOR® vorozole, FEMARA® letrozole, and ARIMIDEX® anastrozole. In addition, such definition of chemotherapeutic agents includes bisphosphonates such as clodronate (for example, BONEFOS® or OSTAC®), DIDROCAL® etidronate, NE-58095, ZOMETA® zoledronic acid/zoledronate, FOSAMAX® alendronate, AREDIA® pamidronate, SKELID® tiludronate, or ACTONEL® risedronate; as well as troxacitabine (a 1,3-dioxolane nucleoside cytosine analog); antisense oligonucleotides, particularly those that inhibit expression of genes in signaling pathways implicated in abherant cell proliferation, such as, for example, PKC-alpha, Raf, H-Ras, and epidermal growth factor receptor (EGFR); vaccines such as THERATOPE® vaccine and gene therapy vaccines, for example, ALLOVECTIN® vaccine, LEUVECTIN® vaccine, and VAXID® vaccine; LURTOTECAN® topoisomerase 1 inhibitor; ABARELIX® rmRH; lapatinib ditosylate (an ErbB-2 and EGFR dual tyrosine kinase small-molecule inhibitor also known as GW572016); and pharmaceutically acceptable salts, acids or derivatives of any of the above.


Examples of a chemotherapeutic agent can also include antibodies such as alemtuzumab (Campath), bevacizumab (AVASTIN®, Genentech); cetuximab (ERBITUX®, Imclone); panitumumab (VECTIBIX®, Amgen), rituximab (RITUXAN®, Genentech/Biogen Idec), pertuzumab (OMNITARG®, 2C4, Genentech), trastuzumab (HERCEPTIN®, Genentech), tositumomab (Bexxar, Corixia), and the antibody drug conjugate, gemtuzumab ozogamicin (MYLOTARG®, Wyeth). Additional humanized monoclonal antibodies with therapeutic potential as agents in combination with the compounds of the invention include: apolizumab, aselizumab, atlizumab, bapineuzumab, bivatuzumab mertansine, cantuzumab mertansine, cedelizumab, certolizumab pegol, cidfusituzumab, cidtuzumab, daclizumab, eculizumab, efalizumab, epratuzumab, erlizumab, feMzumab, fontolizumab, gemtuzumab ozogamicin, inotuzumab ozogamicin, ipilimumab, labetuzumab, lintuzumab, matuzumab, mepolizumab, motavizumab, motovizumab, natalizumab, nimotuzumab, nolovizumab, numavizumab, ocrelizumab, omalizumab, palivizumab, pascolizumab, pecfusituzumab, pectuzumab, pexelizumab, ralivizumab, ranibizumab, reslivizumab, reslizumab, resyvizumab, rovelizumab, ruplizumab, sibrotuzumab, siplizumab, sontuzumab, tacatuzumab tetraxetan, tadocizumab, talizumab, tefibazumab, tocilizumab, toralizumab, tucotuzumab celmoleukin, tucusituzumab, umavizumab, urtoxazumab, ustekinumab, visilizumab, and the anti-interleukin-12 (ABT-874/J695, Wyeth Research and Abbott Laboratories) which is a recombinant exclusively human-sequence, full-length IgG1λ antibody genetically modified to recognize interleukin-12 p40 protein.


Examples of a chemotherapeutic agent can also include “tyrosine kinase inhibitors” such as an EGFR-targeting agent (e.g., small molecule, antibody, etc.); small molecule HER2 tyrosine kinase inhibitor such as TAK165 available from Takeda; CP-724,714, an oral selective inhibitor of the ErbB2 receptor tyrosine kinase (Pfizer and OSI); dual-HER inhibitors such as EKB-569 (available from Wyeth) which preferentially binds EGFR but inhibits both HER2 and EGFR-overexpressing cells; lapatinib (GSK572016; available from Glaxo-SmithKline), an oral HER2 and EGFR tyrosine kinase inhibitor; PKI-166 (available from Novartis); pan-HER inhibitors such as canertinib (CI-1033; Pharmacia); Raf-1 inhibitors such as antisense agent ISIS-5132 available from ISIS Pharmaceuticals which inhibit Raf-1 signaling; non-HER targeted TK inhibitors such as imatinib mesylate (GLEEVEC®, available from Glaxo SmithKline); multi-targeted tyrosine kinase inhibitors such as sunitinib (SUTENT®, available from Pfizer); VEGF receptor tyrosine kinase inhibitors such as vatalanib (PTK787/ZK222584, available from Novartis/Schering AG); MAPK extracellular regulated kinase I inhibitor CI-1040 (available from Pharmacia); quinazolines, such as PD 153035,4-(3-chloroanilino) quinazoline; pyridopyrimidines; pyrimidopyrimidines; pyrrolopyrimidines, such as CGP 59326, CGP 60261 and CGP 62706; pyrazolopyrimidines, 4-(phenylamino)-7H-pyrrolo[2,3-d] pyrimidines; curcumin (diferuloyl methane, 4,5-bis (4-fluoroanilino)phthalimide); tyrphostines containing nitrothiophene moieties; PD-0183805 (Warner-Lamber); antisense molecules (e.g., those that bind to HER-encoding nucleic acid); quinoxalines (U.S. Pat. No. 5,804,396); tryphostins (U.S. Pat. No. 5,804,396); ZD6474 (Astra Zeneca); PTK-787 (Novartis/Schering AG); pan-HER inhibitors such as CI-1033 (Pfizer); Affinitac (ISIS 3521; Isis/Lilly); imatinib mesylate (GLEEVEC®); PKI 166 (Novartis); GW2016 (Glaxo SmithKline); CI-1033 (Pfizer); EKB-569 (Wyeth); Semaxinib (Pfizer); ZD6474 (AstraZeneca); PTK-787 (Novartis/Schering AG); INC-1C11 (Imclone); and rapamycin (sirolimus, RAPAMUNE®).


Examples of a chemotherapeutic agent can also include dexamethasone, interferons, colchicine, metoprine, cyclosporine, amphotericin, metronidazole, alemtuzumab, alitretinoin, allopurinol, amifostine, arsenic trioxide, asparaginase, BCG live, bevacuzimab, bexarotene, cladribine, clofarabine, darbepoetin alfa, denileukin, dexrazoxane, epoetin alfa, elotinib, filgrastim, histrelin acetate, ibritumomab, interferon alfa-2a, interferon alfa-2b, lenalidomide, levamisole, mesna, methoxsalen, nandrolone, nelarabine, nofetumomab, oprelvekin, palifermin, pamidronate, pegademase, pegaspargase, pegfilgrastim, pemetrexed disodium, plicamycin, porfimer sodium, quinacrine, rasburicase, sargramostim, temozolomide, VM-26, 6-TG, toremifene, tretinoin, ATRA, valrubicin, zoledronate, and zoledronic acid, and pharmaceutically acceptable salts thereof.


Examples of a chemotherapeutic agent can also include hydrocortisone, hydrocortisone acetate, cortisone acetate, tixocortol pivalate, triamcinolone acetonide, triamcinolone alcohol, mometasone, amcinonide, budesonide, desonide, fluocinonide, fluocinolone acetonide, betamethasone, betamethasone sodium phosphate, dexamethasone, dexamethasone sodium phosphate, fluocortolone, hydrocortisone-17-butyrate, hydrocortisone-17-valerate, aclometasone dipropionate, betamethasone valerate, betamethasone dipropionate, prednicarbate, clobetasone-17-butyrate, clobetasol-17-propionate, fluocortolone caproate, fluocortolone pivalate and fluprednidene acetate: immune selective anti-inflammatory peptides (ImSAIDs) such as phenylalanine-glutamine-glycine (FEG) and its D-isomeric form (feG) (IMULAN BioTherapeutics, LLC); anti-rheumatic drugs such as azathioprine, ciclosporin (cyclosporine A), D-penicillamine, gold salts, hydroxychloroquine, leflunomideminocycline, sulfasalazine, tumor necrosis factor alpha (TNFα) blockers such as etanercept (ENBREL®), infliximab (REMICADE®), adalimumab (HUMIRA®), certolizumab pegol (CIMZIA®), golimumab (SIMPONI®), Interleukin 1 (IL-1) blockers such as anakinra (KINERET®), T-cell costimulation blockers such as abatacept (ORENCIA®), Interleukin 6 (IL-6) blockers such as tocilizumab (ACTEMERA®); Interleukin 13 (IL-13) blockers such as lebrikizumab; Interferon alpha (IFN) blockers such as rontalizumab; beta 7 integrin blockers such as rhuMAb Beta7; IgE pathway blockers such as Anti-M1 prime; Secreted homotrimeric LTa3 and membrane bound heterotrimer LTa/β2 blockers such as Anti-lymphotoxin alpha (LTa); miscellaneous investigational agents such as thioplatin, PS-341, phenylbutyrate, ET-18-OCH3, or famesyl transferase inhibitors (L-739749, L-744832); polyphenols such as quercetin, resveratrol, piceatannol, epigallocatechine gallate, theaflavins, flavanols, procyanidins, betulinic acid and derivatives thereof; autophagy inhibitors such as chloroquine; delta-9-tetrahydrocannabinol (dronabinol, MARINOL®); beta-lapachone; lapachol; colchicines; betulinic acid; acetylcamptothecin, scopolectin, and 9-aminocamptothecin); podophyllotoxin; tegafur (UFTORAL®); bexarotene (TARGRETIN®); bisphosphonates such as clodronate (for example, BONEFOS® or OSTAC®), etidronate (DIDROCAL®), NE-58095, zoledronic acid/zoledronate (ZOMETA®), alendronate (FOSAMAX®), pamidronate (AREDIA®), tiludronate (SKELID®), or risedronate (ACTONEL®); and epidermal growth factor receptor (EGF-R); vaccines such as THERATOPE® vaccine; perifosine, COX-2 inhibitor (e.g., celecoxib or etoricoxib), proteosome inhibitor (e.g., PS341); CCI-779; tipifamib (R11577); orafenib, ABT510; Bcl-2 inhibitor such as oblimersen sodium (GENASENSE®); pixantrone; famesyltransferase inhibitors such as lonafamib (SCH 6636, SARASAR™); and pharmaceutically acceptable salts, acids or derivatives of any of the above; as well as combinations of two or more of the above.


In accordance with many embodiments, once a diagnosis of cancer is indicated, a number of treatments can be performed, including (but not limited to) surgery, resection, chemotherapy, radiation therapy, immunotherapy, targeted therapy, hormone therapy, stem cell transplant, and blood transfusion. In some embodiments, an anti-cancer and/or chemotherapeutic agent is administered, including (but not limited to) alkylating agents, platinum agents, taxanes, vinca agents, anti-estrogen drugs, aromatase inhibitors, ovarian suppression agents, endocrine/hormonal agents, bisphophonate therapy agents and targeted biological therapy agents. Medications include (but are not limited to) cyclophosphamide, fluorouracil (or 5-fluorouracil or 5-FU), methotrexate, thiotepa, carboplatin, cisplatin, taxanes, paclitaxel, protein-bound paclitaxel, docetaxel, vinorelbine, tamoxifen, raloxifene, toremifene, fulvestrant, gemcitabine, irinotecan, ixabepilone, temozolomide, topotecan, vincristine, vinblastine, eribulin, mutamycin, capecitabine, capecitabine, anastrozole, exemestane, letrozole, leuprolide, abarelix, buserelin, goserelin, megestrol acetate, risedronate, pamidronate, ibandronate, alendronate, zoledronate, tykerb, daunorubicin, doxorubicin, epirubicin, idarubicin, valrubicin mitoxantrone, bevacizumab, cetuximab, ipilimumab, ado-trastuzumab emtansine, afatinib, aldesleukin, alectinib, alemtuzumab, atezolizumab, avelumab, axtinib, belimumab, belinostat, bevacizumab, blinatumomab, bortezomib, bosutinib, brentuximab vedotin, brigatinib, cabozantinib, canakinumab, carfilzomib, certinib, cetuximab, cobimetinib, crizotinib, dabrafenib, daratumumab, dasatinib, denosumab, dinutuximab, durvalumab, elotuzumab, enasidenib, erlotinib, everolimus, gefitinib, ibritumomab tiuxetan, ibrutinib, idelalisib, imatinib, ipilimumab, ixazomib, lapatinib, lenvatinib, midostaurin, necitumumab, neratinib, nilotinib, niraparib, nivolumab, obinutuzumab, ofatumumab, olaparib, olaratumab, osimertinib, palbociclib, panitumumab, panobinostat, pembrolizumab, pertuzumab, ponatinib, ramucirumab, regorafenib, ribociclib, rituximab, romidepsin, rucaparib, ruxolitinib, siltuximab, sipuleucel-T, sonidegib, sorafenib, temsi rolimus, tocilizumab, tofacitinib, tositumomab, trametinib, trastuzumab, vandetanib, vemurafenib, venetoclax, vismodegib, vorinostat, and ziv-aflibercept. In accordance with various embodiments, an individual may be treated, by a single medication or a combination of medications described herein. A common treatment combination is cyclophosphamide, methotrexate, and 5-fluorouracil (CMF).


In some embodiments of any one of the methods disclosed herein, any of the cell-free nucleic acid molecules (e.g., cfDNA, cfRNA) can be derived from a cell. For example, a cell sample or tissue sample may be obtained from a subject and processed to remove all cells from the sample, thereby producing cell-free nucleic acid molecules derived from the sample.


In some embodiments of any one of the methods disclosed herein, a reference genomic sequence can be derived from a cell of an individual. The individual can be a healthy control or the subject who is being subjected to the methods disclosed herein for determining or monitoring progress of a condition.


A cell can be a healthy cell. Alternatively, a cell can be a diseased cell. A diseased cell can have altered metabolic, gene expression, and/or morphologic features. A diseased cell can be a cancer cell, a diabetic cell, and an apoptotic cell. A diseased cell can be a cell from a diseased subject. Exemplary diseases can include blood disorders, cancers, metabolic disorders, eye disorders, organ disorders, musculoskeletal disorders, cardiac disease, and the like.


A cell can be a mammalian cell or derived from a mammalian cell. A cell can be a rodent cell or derived from a rodent cell. A cell can be a human cell or derived from a human cell. A cell can be a prokaryotic cell or derived from a prokaryotic cell. A cell can be a bacterial cell or can be derived from a bacterial cell. A cell can be an archaeal cell or derived from an archaeal cell. A cell can be a eukaryotic cell or derived from a eukaryotic cell. A cell can be a pluripotent stem cell. A cell can be a plant cell or derived from a plant cell. A cell can be an animal cell or derived from an animal cell. A cell can be an invertebrate cell or derived from an invertebrate cell. A cell can be a vertebrate cell or derived from a vertebrate cell. A cell can be a microbe cell or derived from a microbe cell. A cell can be a fungi cell or derived from a fungi cell. A cell can be from a specific organ or tissue.


Non-limiting examples of a cell(s) can include lymphoid cells, such as B cell, T cell (Cytotoxic T cell, Natural Killer T cell, Regulatory T cell, T helper cell), Natural killer cell, cytokine induced killer (CTK) cells; myeloid cells, such as granulocytes (Basophil granulocyte, Eosinophil granulocyte, Neutrophil granulocyte/Hypersegmented neutrophil), Monocyte/Macrophage, Red blood cell (Reticulocyte), Mast cell, Thrombocyte/Megakaryocyte, Dendritic cell; cells from the endocrine system, including thyroid (Thyroid epithelial cell, Parafollicular cell), parathyroid (Parathyroid chief cell, Oxyphil cell), adrenal (Chromaffin cell), pineal (Pinealocyte) cells; cells of the nervous system, including glial cells (Astrocyte, Microglia), Magnocellular neurosecretory cell, Stellate cell, Boettcher cell, and pituitary (Gonadotrope, Corticotrope, Thyrotrope, Somatotrope, Lactotroph); cells of the Respiratory system, including Pneumocyte (Type I pneumocyte, Type II pneumocyte), Clara cell, Goblet cell, Dust cell; cells of the circulatory system, including Myocardiocyte, Pericyte; cells of the digestive system, including stomach (Gastric chief cell, Parietal cell), Goblet cell, Paneth cell, G cells, D cells, ECL cells, I cells, K cells, S cells; enteroendocrine cells, including enterochromaffm cell, APUD cell, liver (Hepatocyte, Kupffer cell), Cartilage/bone/muscle; bone cells, including Osteoblast, Osteocyte, Osteoclast, teeth (Cementoblast, Ameloblast); cartilage cells, including Chondroblast, Chondrocyte; skin cells, including Trichocyte, Keratinocyte, Melanocyte (Nevus cell); muscle cells, including Myocyte; urinary system cells, including Podocyte, Juxtaglomerular cell, Intraglomerular mesangial cell/Extraglomerular mesangial cell, Kidney proximal tubule brush border cell, Macula densa cell; reproductive system cells, including Spermatozoon, Sertoli cell, Leydig cell, Ovum; and other cells, including Adipocyte, Fibroblast, Tendon cell, Epidermal keratinocyte (differentiating epidermal cell), Epidermal basal cell (stem cell), Keratinocyte of fingernails and toenails, Nail bed basal cell (stem cell), Medullary hair shaft cell, Cortical hair shaft cell, Cuticular hair shaft cell, Cuticular hair root sheath cell, Hair root sheath cell of Huxley's layer, Hair root sheath cell of Henle's layer, External hair root sheath cell, Hair matrix cell (stem cell), Wet stratified barrier epithelial cells, Surface epithelial cell of stratified squamous epithelium of cornea, tongue, oral cavity, esophagus, anal canal, distal urethra and vagina, basal cell (stem cell) of epithelia of cornea, tongue, oral cavity, esophagus, anal canal, distal urethra and vagina, Urinary epithelium cell (lining urinary bladder and urinary ducts), Exocrine secretory epithelial cells, Salivary gland mucous cell (polysaccharide-rich secretion), Salivary gland serous cell (glycoprotein enzyme-rich secretion), Von Ebner's gland cell in tongue (washes taste buds), Mammary gland cell (milk secretion), Lacrimal gland cell (tear secretion), Ceruminous gland cell in ear (wax secretion), Eccrine sweat gland dark cell (glycoprotein secretion), Eccrine sweat gland clear cell (small molecule secretion). Apocrine sweat gland cell (odoriferous secretion, sex-hormone sensitive), Gland of Moll cell in eyelid (specialized sweat gland), Sebaceous gland cell (lipid-rich sebum secretion), Bowman's gland cell in nose (washes olfactory epithelium), Brunner's gland cell in duodenum (enzymes and alkaline mucus), Seminal vesicle cell (secretes seminal fluid components, including fructose for swimming sperm), Prostate gland cell (secretes seminal fluid components), Bulbourethral gland cell (mucus secretion), Bartholin's gland cell (vaginal lubricant secretion), Gland of Littre cell (mucus secretion), Uterus endometrium cell (carbohydrate secretion), Isolated goblet cell of respiratory and digestive tracts (mucus secretion), Stomach lining mucous cell (mucus secretion), Gastric gland zymogenic cell (pepsinogen secretion), Gastric gland oxyntic cell (hydrochloric acid secretion), Pancreatic acinar cell (bicarbonate and digestive enzyme secretion), Paneth cell of small intestine (lysozyme secretion), Type II pneumocyte of lung (surfactant secretion), Clara cell of lung, Hormone secreting cells, Anterior pituitary cells, Somatotropes, Lactotropes, Thyrotropes, Gonadotropes, Corticotropes, Intermediate pituitary cell, Magnocellular neurosecretory cells, Gut and respiratory tract cells, Thyroid gland cells, thyroid epithelial cell, parafollicular cell, Parathyroid gland cells, Parathyroid chief cell, Oxyphil cell, Adrenal gland cells, chromaffin cells, Ley dig cell of testes, Theca interna cell of ovarian follicle, Corpus luteum cell of ruptured ovarian follicle, Granulosa lutein cells, Theca lutein cells, Juxtaglomerular cell (renin secretion), Macula densa cell of kidney, Metabolism and storage cells, Barrier function cells (Lung, Gut, Exocrine Glands and Urogenital Tract), Kidney, Type I pneumocyte (lining air space of lung), Pancreatic duct cell (centroacinar cell), Nonstriated duct cell (of sweat gland, salivary gland, mammary gland, etc.), Duct cell (of seminal vesicle, prostate gland, etc.), Epithelial cells lining closed internal body cavities, Ciliated cells with propulsive function, Extracellular matrix secretion cells, Contractile cells; Skeletal muscle cells, stem cell, Heart muscle cells, Blood and immune system cells, Erythrocyte (red blood cell), Megakaryocyte (platelet precursor), Monocyte, Connective tissue macrophage (various types), Epidermal Langerhans cell, Osteoclast (in bone), Dendritic cell (in lymphoid tissues), Microglial cell (in central nervous system), Neutrophil granulocyte, Eosinophil granulocyte, Basophil granulocyte, Mast cell, Helper T cell, Suppressor T cell, Cytotoxic T cell, Natural Killer T cell, B cell, Natural killer cell, Reticulocyte, Stem cells and committed progenitors for the blood and immune system (various types), Pluripotent stem cells, Totipotent stem cells, Induced pluripotent stem cells, adult stem cells, Sensory transducer cells, Autonomic neuron cells, Sense organ and peripheral neuron supporting cells, Central nervous system neurons and glial cells, Lens cells, Pigment cells, Melanocyte, Retinal pigmented epithelial cell, Germ cells, Oogonium/Oocyte, Spermatid, Spermatocyte, Spermatogonium cell (stem cell for spermatocyte), Spermatozoon, Nurse cells, Ovarian follicle cell, Sertoli cell (in testis), Thymus epithelial cell, Interstitial cells, and Interstitial kidney cells.


In some embodiments of any one of the methods disclosed herein, the condition can be a cancer or tumor. Non-limiting examples of such condition can include Acanthoma, Acinic cell carcinoma, Acoustic neuroma, Acral lentiginous melanoma, Acrospiroma, Acute eosinophilic leukemia, Acute lymphoblastic leukemia, Acute megakaryoblastic leukemia, Acute monocytic leukemia, Acute myeloblastic leukemia with maturation, Acute myeloid dendritic cell leukemia, Acute myeloid leukemia, Acute promyelocytic leukemia, Adamantinoma, Adenocarcinoma, Adenoid cystic carcinoma, Adenoma, Adenomatoid odontogenic tumor, Adrenocortical carcinoma, Adult T-cell leukemia, Aggressive NK-cell leukemia, AIDS-Related Cancers, AIDS-related lymphoma, Alveolar soft part sarcoma, Ameloblastic fibroma, Anal cancer, Anaplastic large cell lymphoma, Anaplastic thyroid cancer, Angioimmunoblastic T-cell lymphoma, Angiomyolipoma, Angiosarcoma, Appendix cancer, Astrocytoma, Atypical teratoid rhabdoid tumor, Basal cell carcinoma, Basal-like carcinoma, B-cell leukemia, B-cell lymphoma, Bellini duct carcinoma, Biliary tract cancer, Bladder cancer, Blastoma, Bone Cancer, Bone tumor, Brain Stem Glioma, Brain Tumor, Breast Cancer, Brenner tumor, Bronchial Tumor, Bronchioloalveolar carcinoma, Brown tumor, Burkitt's lymphoma, Cancer of Unknown Primary Site, Carcinoid Tumor, Carcinoma, Carcinoma in situ, Carcinoma of the penis, Carcinoma of Unknown Primary Site, Carcinosarcoma, Castleman's Disease, Central Nervous System Embryonal Tumor, Cerebellar Astrocytoma, Cerebral Astrocytoma, Cervical Cancer, Cholangiocarcinoma, Chondroma, Chondrosarcoma, Chordoma, Choriocarcinoma, Choroid plexus papilloma, Chronic Lymphocytic Leukemia, Chronic monocytic leukemia, Chronic myelogenous leukemia, Chronic Myeloproliferative Disorder, Chronic neutrophilic leukemia, Clear-cell tumor, Colon Cancer, Colorectal cancer, Craniopharyngioma, Cutaneous T-cell lymphoma, Degos disease, Dermatofibrosarcoma protuberans, Dermoid cyst, Desmoplastic small round cell tumor, Diffuse large B cell lymphoma, Dysembryoplastic neuroepithelial tumor, Embryonal carcinoma, Endodermal sinus tumor, Endometrial cancer, Endometrial Uterine Cancer, Endometrioid tumor, Enteropathy-associated T-cell lymphoma, Ependymoblastoma, Ependymoma, Epithelioid sarcoma, Erythroleukemia, Esophageal cancer, Esthesioneuroblastoma, Ewing Family of Tumor, Ewing Family Sarcoma, Ewing's sarcoma, Extracranial Germ Cell Tumor, Extragonadal Germ Cell Tumor, Extrahepatic Bile Duct Cancer, Extramammary Paget's disease, Fallopian tube cancer, Fetus in fetu, Fibroma, Fibrosarcoma, Follicular lymphoma, Follicular thyroid cancer, Gallbladder Cancer, Gallbladder cancer, Ganglioglioma, Ganglioneuroma, Gastric Cancer, Gastric lymphoma, Gastrointestinal cancer, Gastrointestinal Carcinoid Tumor, Gastrointestinal Stromal Tumor, Gastrointestinal stromal tumor, Germ cell tumor, Germinoma, Gestational choriocarcinoma, Gestational Trophoblastic Tumor, Giant cell tumor of bone, Glioblastoma multiforme, Glioma, Gliomatosis cerebri, Glomus tumor, Glucagonoma, Gonadoblastoma, Granulosa cell tumor, Hairy Cell Leukemia, Hairy cell leukemia, Head and Neck Cancer, Head and neck cancer, Heart cancer, Hemangioblastoma, Hemangiopericytoma, Hemangiosarcoma, Hematological malignancy, Hepatocellular carcinoma, Hepatosplenic T-cell lymphoma, Hereditary breast-ovarian cancer syndrome, Hodgkin Lymphoma, Hodgkin's lymphoma, Hypopharyngeal Cancer, Hypothalamic Glioma, Inflammatory breast cancer, Intraocular Melanoma, Islet cell carcinoma, Islet Cell Tumor, Juvenile myelomonocytic leukemia, Kaposi Sarcoma, Kaposi's sarcoma, Kidney Cancer, Klatskin tumor, Krukenberg tumor, Laryngeal Cancer, Laryngeal cancer, Lentigo maligna melanoma, Leukemia, Leukemia, Lip and Oral Cavity Cancer, Liposarcoma, Lung cancer, Luteoma, Lymphangioma, Lymphangiosarcoma, Lymphoepithelioma, Lymphoid leukemia, Lymphoma, Macroglobulinemia, Malignant Fibrous Histiocytoma, Malignant fibrous histiocytoma, Malignant Fibrous Histiocytoma of Bone, Malignant Glioma, Malignant Mesothelioma, Malignant peripheral nerve sheath tumor, Malignant rhabdoid tumor, Malignant triton tumor, MALT lymphoma, Mantle cell lymphoma, Mast cell leukemia, Mediastinal germ cell tumor, Mediastinal tumor, Medullary thyroid cancer, Medulloblastoma, Medulloblastoma, Medulloepithelioma, Melanoma, Melanoma, Meningioma, Merkel Cell Carcinoma, Mesothelioma, Mesothelioma, Metastatic Squamous Neck Cancer with Occult Primary, Metastatic urothelial carcinoma, Mixed Mullerian tumor, Monocytic leukemia, Mouth Cancer, Mucinous tumor, Multiple Endocrine Neoplasia Syndrome, Multiple Myeloma, Multiple myeloma, Mycosis Fungoides, Mycosis fungoides, Myelodysplastic Disease, Myelodysplastic Syndromes, Myeloid leukemia, Myeloid sarcoma, Myeloproliferative Disease, Myxoma, Nasal Cavity Cancer, Nasopharyngeal Cancer, Nasopharyngeal carcinoma, Neoplasm, Neurinoma, Neuroblastoma, Neuroblastoma, Neurofibroma, Neuroma, Nodular melanoma, Non-Hodgkin Lymphoma, Non-Hodgkin lymphoma, Nonmelanoma Skin Cancer, Non-Small Cell Lung Cancer, Ocular oncology, Oligoastrocytoma, Oligodendroglioma, Oncocytoma, Optic nerve sheath meningioma, Oral Cancer, Oral cancer, Oropharyngeal Cancer, Osteosarcoma, Osteosarcoma, Ovarian Cancer, Ovarian cancer, Ovarian Epithelial Cancer, Ovarian Germ Cell Tumor, Ovarian Low Malignant Potential Tumor, Paget's disease of the breast, Pancoast tumor, Pancreatic Cancer, Pancreatic cancer, Papillary thyroid cancer, Papillomatosis, Paraganglioma, Paranasal Sinus Cancer, Parathyroid Cancer, Penile Cancer, Perivascular epithelioid cell tumor, Pharyngeal Cancer, Pheochromocytoma, Pineal Parenchymal Tumor of Intermediate Differentiation, Pineoblastoma, Pituicytoma, Pituitary adenoma, Pituitary tumor, Plasma Cell Neoplasm, Pleuropulmonary blastoma, Polyembryoma, Precursor T-lymphoblastic lymphoma, Primary central nervous system lymphoma, Primary effusion lymphoma, Primary Hepatocellular Cancer, Primary Liver Cancer, Primary peritoneal cancer, Primitive neuroectodermal tumor, Prostate cancer, Pseudomyxoma peritonei, Rectal Cancer, Renal cell carcinoma, Respiratory Tract Carcinoma Involving the NUT Gene on Chromosome 15, Retinoblastoma, Rhabdomyoma, Rhabdomyosarcoma, Richter's transformation, Sacrococcygeal teratoma, Salivary Gland Cancer, Sarcoma, Schwannomatosis, Sebaceous gland carcinoma, Secondary neoplasm, Seminoma, Serous tumor, Sertoli-Leydig cell tumor, Sex cord-stromal tumor, Sezary Syndrome, Signet ring cell carcinoma, Skin Cancer, Small blue round cell tumor, Small cell carcinoma, Small Cell Lung Cancer, Small cell lymphoma, Small intestine cancer, Soft tissue sarcoma, Somatostatinoma, Soot wart, Spinal Cord Tumor, Spinal tumor, Splenic marginal zone lymphoma, Squamous cell carcinoma, Stomach cancer, Superficial spreading melanoma, Supratentorial Primitive Neuroectodermal Tumor, Surface epithelial-stromal tumor, Synovial sarcoma, T-cell acute lymphoblastic leukemia, T-cell large granular lymphocyte leukemia, T-cell leukemia, T-cell lymphoma, T-cell prolymphocytic leukemia, Teratoma, Terminal lymphatic cancer, Testicular cancer, Thecoma, Throat Cancer, Thymic Carcinoma, Thymoma, Thyroid cancer, Transitional Cell Cancer of Renal Pelvis and Ureter, Transitional cell carcinoma, Urachal cancer, Urethral cancer, Urogenital neoplasm, Uterine sarcoma, Uveal melanoma, Vaginal Cancer, Verner Morrison syndrome, Verrucous carcinoma, Visual Pathway Glioma, Vulvar Cancer, Waldenstrom's macroglobulinemia, Warthin's tumor, and Wilms' tumor.


In accordance with various embodiments, numerous types of neoplasms can be detected, including (but not limited to) acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), anal cancer, astrocytomas, basal cell carcinoma, bile duct cancer, bladder cancer, breast cancer, Burkitt's lymphoma, cervical cancer, chronic lymphocytic leukemia (CLL) chronic myelogenous leukemia (CML), chronic myeloproliferative neoplasms, colorectal cancer, diffuse large B-cell lymphoma, endometrial cancer, ependymoma, esophageal cancer, esthesioneuroblastoma, Ewing sarcoma, fallopian tube cancer, follicular lymphoma, gallbladder cancer, gastric cancer, gastrointestinal carcinoid tumor, hairy cell leukemia, hepatocellular cancer, Hodgkin lymphoma, hypopharyngeal cancer, Kaposi sarcoma, Kidney cancer, Langerhans cell histiocytosis, laryngeal cancer, leukemia, liver cancer, lung cancer, lymphoma, melanoma, Merkel cell cancer, mesothelioma, mouth cancer, neuroblastoma, non-Hodgkin lymphoma, non-small cell lung cancer, osteosarcoma, ovarian cancer, pancreatic cancer, pancreatic neuroendocrine tumors, pharyngeal cancer, pituitary tumor, prostate cancer, rectal cancer, renal cell cancer, retinoblastoma, skin cancer, small cell lung cancer, small intestine cancer, squamous neck cancer, T-cell lymphoma, testicular cancer, thymoma, thyroid cancer, uterine cancer, vaginal cancer, and vascular tumors.


Many embodiments are directed to diagnostic or companion diagnostic scans performed during cancer treatment of an individual. When performing diagnostic scans during treatment, the ability of agent to treat the cancer growth can be monitored. Most anti-cancer therapeutic agents result in death and necrosis of neoplastic cells, which should release higher amounts nucleic acids from these cells into the samples being tested. Accordingly, the level of circulating-tumor nucleic acids can be monitored over time, as the level should increase during early treatments and begin to decrease as the number of cancerous cells are decreased. In some embodiments, treatments are adjusted based on the treatment effect on cancer cells. For instance, if the treatment isn't cytotoxic to neoplastic cells, a dosage amount may be increased or an agent with higher cytotoxicity can be administered. In the alternative, if cytotoxicity of cancer cells is good but unwanted side effects are high, a dosage amount can be decreased or an agent with less side effects can be administered.


Various embodiments are also directed to diagnostic scans performed after treatment of an individual to detect residual disease and/or recurrence of cancer. If a diagnostic scan indicates residual and/or recurrence of cancer, further diagnostic tests and/or treatments may be performed as described herein. If the cancer and/or individual is susceptible to recurrence, diagnostic scans can be performed frequently to monitor any potential relapse.


F. Computer Systems

In one aspect, the present disclosure provides a computer program product comprising a non-transitory computer-readable medium having computer-executable code encoded therein, the computer-executable code adapted to be executed to implement any one of the preceding methods.


The present disclosure provides computer systems that are programmed to implement methods of the disclosure. The system can, in some cases, include components such as a processor, an input module for inputting sequencing data or data derived therefrom, a computer-readable medium containing instructions that, when executed by the processor, perform an algorithm on the input regarding one or more cell-free nucleic acids molecules, and an output module providing one or more indicia associated with the condition.



FIG. 27 shows a computer system 2701 that is programmed or otherwise configured to implement partial or all of the methods disclosed herein. The computer system 2701 can regulate various aspects of the present disclosure, such as, for example, (i) identify, from sequencing data derived from a plurality of cell-free nucleic acid molecules, one or more cell-free nucleic acid molecules comprising the plurality of phased variants, (ii) analyze any of the identified cell-free nucleic acid molecules, (iii) determine a condition of the subject based at least in part on the identified cell-free nucleic acid molecules, (iv) monitor a progress of the condition of the subject based at least in part on the identified cell-free nucleic acid molecules, (v) identify the subject based at least in part on the identified cell-free nucleic acid molecules, or (vi) determine an appropriate treatment of the condition of the subject based at least in part on the identified cell-free nucleic acid molecules. The computer system 2701 can be an electronic device of a user or a computer system that is remotely located with respect to the electronic device. The electronic device can be a mobile electronic device.


The computer system 2701 includes a central processing unit (CPU, also “processor” and “computer processor” herein) 2705, which can be a single core or multi core processor, or a plurality of processors for parallel processing. The computer system 2701 also includes memory or memory location 2710 (e.g., random-access memory, read-only memory, flash memory), electronic storage unit 2715 (e.g., hard disk), communication interface 2720 (e.g., network adapter) for communicating with one or more other systems, and peripheral devices 2725, such as cache, other memory, data storage and/or electronic display adapters. The memory 2710, storage unit 2715, interface 2720 and peripheral devices 2725 are in communication with the CPU 2705 through a communication bus (solid lines), such as a motherboard. The storage unit 2715 can be a data storage unit (or data repository) for storing data. The computer system 2701 can be operatively coupled to a computer network (“network”) 2730 with the aid of the communication interface 2720. The network 2730 can be the Internet, an internet and/or extranet, or an intranet and/or extranet that is in communication with the Internet. The network 2730 in some cases is a telecommunication and/or data network. The network 2730 can include one or more computer servers, which can enable distributed computing, such as cloud computing. The network 2730, in some cases with the aid of the computer system 2701, can implement a peer-to-peer network, which may enable devices coupled to the computer system 2701 to behave as a client or a server.


The CPU 2705 can execute a sequence of machine-readable instructions, which can be embodied in a program or software. The instructions may be stored in a memory location, such as the memory 2710. The instructions can be directed to the CPU 2705, which can subsequently program or otherwise configure the CPU 2705 to implement methods of the present disclosure. Examples of operations performed by the CPU 2705 can include fetch, decode, execute, and writeback.


The CPU 2705 can be part of a circuit, such as an integrated circuit. One or more other components of the system 2701 can be included in the circuit. In some cases, the circuit is an application specific integrated circuit (ASIC).


The storage unit 2715 can store files, such as drivers, libraries and saved programs. The storage unit 2715 can store user data, e.g., user preferences and user programs. The computer system 2701 in some cases can include one or more additional data storage units that are external to the computer system 2701, such as located on a remote server that is in communication with the computer system 2701 through an intranet or the Internet.


The computer system 2701 can communicate with one or more remote computer systems through the network 2730. For instance, the computer system 2701 can communicate with a remote computer system of a user. Examples of remote computer systems include personal computers (e.g., portable PC), slate or tablet PC's (e.g., Apple® iPad, Samsung® Galaxy Tab), telephones, Smart phones (e.g., Apple® iPhone, Android-enabled device, Blackberry®), or personal digital assistants. The user can access the computer system 2701 via the network 2730.


Methods as described herein can be implemented by way of machine (e.g., computer processor) executable code stored on an electronic storage location of the computer system 2701, such as, for example, on the memory 2710 or electronic storage unit 2715. The machine executable or machine readable code can be provided in the form of software. During use, the code can be executed by the processor 2705. In some cases, the code can be retrieved from the storage unit 2715 and stored on the memory 2710 for ready access by the processor 2705. In some situations, the electronic storage unit 2715 can be precluded, and machine-executable instructions are stored on memory 2710.


The code can be pre-compiled and configured for use with a machine having a processer adapted to execute the code, or can be compiled during runtime. The code can be supplied in a programming language that can be selected to enable the code to execute in a pre-compiled or as-compiled fashion.


Aspects of the systems and methods provided herein, such as the computer system 2701, can be embodied in programming. Various aspects of the technology may be thought of as “products” or “articles of manufacture” typically in the form of machine (or processor) executable code and/or associated data that is carried on or embodied in a type of machine readable medium. Machine-executable code can be stored on an electronic storage unit, such as memory (e.g., read-only memory, random-access memory, flash memory) or a hard disk. “Storage” type media can include any or all of the tangible memory of the computers, processors or the like, or associated modules thereof, such as various semiconductor memories, tape drives, disk drives and the like, which may provide non-transitory storage at any time for the software programming. All or portions of the software may at times be communicated through the Internet or various other telecommunication networks. Such communications, for example, may enable loading of the software from one computer or processor into another, for example, from a management server or host computer into the computer platform of an application server. Thus, another type of media that may bear the software elements includes optical, electrical and electromagnetic waves, such as used across physical interfaces between local devices, through wired and optical landline networks and over various air-links. The physical elements that carry such waves, such as wired or wireless links, optical links or the like, also may be considered as media bearing the software. As used herein, unless restricted to non-transitory, tangible “storage” media, terms such as computer or machine “readable medium” refer to any medium that participates in providing instructions to a processor for execution.


Hence, a machine readable medium, such as computer-executable code, may take many forms, including but not limited to, a tangible storage medium, a carrier wave medium or physical transmission medium. Non-volatile storage media include, for example, optical or magnetic disks, such as any of the storage devices in any computer(s) or the like, such as may be used to implement the databases, etc. shown in the drawings. Volatile storage media include dynamic memory, such as main memory of such a computer platform. Tangible transmission media include coaxial cables; copper wire and fiber optics, including the wires that comprise a bus within a computer system. Carrier-wave transmission media may take the form of electric or electromagnetic signals, or acoustic or light waves such as those generated during radio frequency (RF) and infrared (IR) data communications. Common forms of computer-readable media therefore include for example: a floppy disk, a flexible disk, hard disk, magnetic tape, any other magnetic medium, a CD-ROM, DVD or DVD-ROM, any other optical medium, punch cards paper tape, any other physical storage medium with patterns of holes, a RAM, a ROM, a PROM and EPROM, a FLASH-EPROM, any other memory chip or cartridge, a carrier wave transporting data or instructions, cables or links transporting such a carrier wave, or any other medium from which a computer may read programming code and/or data. Many of these forms of computer readable media may be involved in carrying one or more sequences of one or more instructions to a processor for execution.


The computer system 2701 can include or be in communication with an electronic display 2735 that comprises a user interface (UI) 2740 for providing, for example, (i) analysis of any of the identified cell-free nucleic acid molecules, (ii) a determined condition of the subject based at least in part on the identified cell-free nucleic acid molecules, (iii) a determined progress of the condition of the subject based at least in part on the identified cell-free nucleic acid molecules, (iv) the identified subject suspected of having the condition based at least in part on the identified cell-free nucleic acid molecules, or (v) a determined treatment of the condition of the subject based at least in part on the identified cell-free nucleic acid molecules. Examples of UI's include, without limitation, a graphical user interface (GUI) and web-based user interface.


Methods and systems of the present disclosure can be implemented by way of one or more algorithms. An algorithm can be implemented by way of software upon execution by the central processing unit 2705. The algorithm can, for example, (i) identify, from sequencing data derived from a plurality of cell-free nucleic acid molecules, one or more cell-free nucleic acid molecules comprising the plurality of phased variants, (ii) analyze any of the identified cell-free nucleic acid molecules, (iii) determine a condition of the subject based at least in part on the identified cell-free nucleic acid molecules, (iv) monitor a progress of the condition of the subject based at least in part on the identified cell-free nucleic acid molecules, (v) identify the subject based at least in part on the identified cell-free nucleic acid molecules, or (vi) determine an appropriate treatment of the condition of the subject based at least in part on the identified cell-free nucleic acid molecules.


EXAMPLES

The following illustrative examples are representative of embodiments of the stimulation, systems, and methods described herein and are not meant to be limiting in any way.


Example 1: Genomic Distribution of Phased Variants

Described is an alternative to duplex sequencing for reducing the background error rate that involves detection of ‘phased variants’ (PVs), where two or more mutations occur in cis (i.e., on the same strand of DNA FIG. 1A and FIG. 1E). Similar to duplex sequencing, this method provides lower error profiles due to the concordant detection of two separate non-reference events in individual molecules. However, unlike duplex sequencing, both events occur on the same sequencing read-pair, thereby increasing the efficiency of genome recovery. Phased mutations are present in diverse cancer types, but occur in stereotyped portions of the genome in B-cell malignancies, likely due to on-target and aberrant somatic hypermutation (aSHM) driven by activation-induced deaminase (AID). The most common regions of aSHM in B-cell non-Hodgkin lymphomas (NHL) are identified. Described herein is phased variant Enrichment and Detection Sequencing (PhasED-Seq), a novel method to detect ctDNA through phased variants to tumor fractions on the order of parts per million. Described herein is demonstration that PhasED-Seq can meaningfully improve detection of ctDNA in clinical samples both during therapy and prior to disease relapse.


To identify malignancies where PVs may potentially improve disease detection, the frequency of PVs across cancer types were assessed. Publicly available whole-genome sequencing data was analyzed to identify sets of variants occurring at a distance of <170 bp apart, which represents the typical length of a single cfDNA fragment consisting of a single core nucleosome and associated linker. The frequency of these ‘putative phased variants,” (Example 10) controlling for the total number of SNVs, from 2538 tumors across 24 cancer histologies including solid tumors and hematological malignancies (FIG. 1B, FIG. 5, and Table 1) was identified and summarized. PVs were most significantly enriched in two B-cell lymphomas (DLBCL and follicular lymphoma, FL, P<0.05 vs all other histologies), a group of diseases with hypermutation driven by AID/AICDA.


Example 2: Mutational Mechanisms Underlying PVs

To investigate the origin of PVs, the single base substitution (SBS) mutational signatures contributing to SNVs occurring within 170 bp of another SNV, and SNVs occurring in isolation (e.g., not having another SNV within 170 bp) (Example 10) were compared. As expected, PVs were highly enriched in several mutational signatures associated with clustered mutations. Signatures of clustered mutations associated with activity of AID (SBS84 and SBS85) were significantly enriched in PVs from B-cell lymphomas and CLL, while signatures associated with activity of APOBEC3B (SBS2 and SBS13)—another mechanism of kataegis hypermutation—were significantly enriched in PVs from multiple solid cancer histologies, including ovarian, pancreatic, prostate, and breast adenocarcinomas (FIG. 1C and FIGS. 6A-6WW). Signatures of clustered mutations associated with activity of AID (SBS84 and SBS85) were enriched in PVs found in lymphomas and CLL, while signatures associated with activity of APOBEC3B (SBS2 and SBS13) were significantly enriched in breast cancer (FIG. 1C and FIGS. 6A-6WW). PVs from multiple tumor types were also associated with SBS4, a signature associated with tobacco use. Furthermore, among PVs across multiple tumor histologies, it was observed that novel enrichments in several other signatures without clearly associated mechanisms (e.g., SBS24, SBS37, SBS38, and SBS39). In contrast, aging-associated mutational signatures such as SBS1 and SBS5 were significantly enriched in isolated SNVs.


Example 3: PVs Occur in Stereotyped Genomic Regions in Lymphoid Cancers

To assess the genomic distribution of putative PVs, these events were first binned into 1-kb regions to visualize their frequency across tumor types. It was observed that a strikingly stereotyped distribution of PVs in individual lymphoid neoplasms (e.g., DLBCL, FL, Burkitt lymphoma (BL), and chronic lymphocytic leukemia (CLL); FIG. 1D and FIG. 7). In contrast, non-lymphoid cancers generally did not exhibit substantial recurrence of clustered PVs in stereotyped regions. This lack of stereotype in the position of PVs was true even when considering melanomas and lung cancers, diseases with frequent PVs.


Notably, the majority of hypermutated regions were shared between all three lymphoma subtypes, with the highest densities seen in known targets of aSHM including BCL2, BCL6, and MYC, as well as the immunoglobulin (Ig) loci encoding the heavy and light chains IGH, IGK, and IGL (Table 2). Strikingly, certain regions within Ig loci were densely mutated in nearly all lymphoma patients as well as in patients with CLL (FIG. 1D). Among lymphoma subtypes, DLBCL tumors harbored the most 1-kb regions recurrently containing PVs (FIG. 8A), consistent with the highest number of recurrently mutated genes being observed in this tumor type. In total, 1639 unique 1-kb regions recurrently containing PVs in B-lymphoid malignancies were identified. Among these lymphoma-associated 1-kb regions, nearly one-third fell into genomic areas previously associated with physiological or aberrant SHM in B-cells. Specifically, 19% (315/1639) were located in Ig regions, while 13% (218/1639) were in portions of 68 previously identified targets of aSHM (Table 2). While most PVs fell into noncoding regions of the genome, additional recurrently affected loci not previously described as targets of aSHM, including XBP1, LPP, and AICDA, among others, were also identified.


The distribution of PVs within each lymphoid malignancy correlated with oncogenic features associated with the distinct pathophysiology of the corresponding disease. For example, cases of FL—where more than 90% of tumors harbor oncogenic BCL2 fusions—were significantly more likely to contain phased variants in BCL2 than other lymphoid malignancies (FIG. 1D and FIG. 8B). Similarly, significantly more Burkitt lymphomas (BL) harbored PVs in MYC and ID3, two driver genes strongly associated with the BL pathogenesis, than other lymphoid malignancies (FIG. 1D and FIGS. 8C-8D). DLBCL molecular subtypes associated with distinct cell-of-origin also demonstrated distinct distributions of PVs (Table 2). Specifically, while germinal center B-cell like (GCB) and activated B-cell like (ABC) DLBCLs harbored similar frequencies of PVs overall (median 798 vs 516, P=0.37), significant enrichment for PVs in the telomeric IGH class-switch regions (Sγ1, and Sγ3) in ABC-DLBCLs, consistent with previous reports41 (FIG. 8E), was found. Conversely, GCB-DLBCLs harbored more phased haplotypes in centromeric IGH class switch regions (Sα2 and Sε) and in BCL2.


Example 4: Design and Validation of PhasED-Seq Panel for Lymphoma

To validate these PV-rich regions and assess their utility for disease detection from ctDNA, a sequencing panel targeting putative PVs identified within WGS from three independent cohorts of patients with DLBCL, as well as in patients with CLL (FIG. 2A and Example 10) was designed. This final Phased variant Enrichment and Detection Sequencing (PhasED-Seq) panel targeted ˜115 kb of genomic space focused on PVs, along with an additional ˜200 kb targeting genes that are recurrently mutated in B-NHLs (Table 3). While the 115 kb of space dedicated to PV-capture targets only 0.0035% of the human genome, it captures 26% of phased variants observed in mature B-cell neoplasms profiled by WGS (FIG. 9A), thus yielding a ˜7500-fold PV enrichment by PhasED-Seq over WGS.


Expected SNV and PV recovery was compared to previously reported CAPP-Seq selector designed to maximize SNVs per patient in B-cell lymphomas (FIG. 9A-C). When considering diverse B-NHLs with available WGS data, PhasED-Seq recovered 3.0× more SNVs (81 vs. 27) and 2.9× more PVs (50 vs. 17) in the median case than previous CAPP-Seq panel. This observation highlights the importance of including non-coding portions of the genome for maximal mutation recovery. To validate these yield improvements experimentally, 16 pretreatment tumor or plasma DNA samples from patients with DLBCL (Table 4) were profiled. Both CAPP-Seq and PhasED-Seq panels were applied to each specimen in parallel and then sequenced them to high unique molecular depths (FIG. 2B). Compared to the expected enrichment established from WGS, similar improvements in yield of SNVs by PhasED-Seq compared to CAPP-Seq (2.7×; median 304.5 vs. 114) were observed. However, when enumerating PVs observed in individual sequenced DNA fragments, an improvement in favor of PhasED-Seq beyond the expected improvement from WGS (7.7×; median 5554 vs 719.5 PVs/case) was found. This improvement is potentially due to either 1) the higher sequencing depth in targeted sequencing which leads to improvement in rare allele detection, or 2) enumeration of higher order PVs in targeted sequencing with PhasED-Seq or CAPP-Seq, which was not accounted for in the WGS design (i.e., >2 SNVs per fragment; FIGS. 9D-9F). Furthermore, across 1-kb windows in the panel, robust correlation between the frequency of putative PVs in WGS data and PVs from targeted sequencing by PhasED-Seq across 101 DLBCL samples (FIG. 2C) was observed, further validating the frequency and distribution of PVs in B-cell malignancies.


Example 5: Differences in Phased Variants Between Lymphoma Subtypes

Having validated the PhasED-Seq panel, the biological differences in PVs between various B-cell malignancies, including DLBCL (n=101), primary mediastinal B-cell lymphoma (PMBCL) (n=16), and classical Hodgkin lymphoma (cHL) (n=23) were examined. The number of SNVs identified per case was not significantly different between lymphoma subtypes (FIGS. 9G-9K). However, when considering mutational haplotypes, cHL had a significantly lower burden of PVs than either DLBCL or PMBCL. In addition to this quantitative disparity, differences in the genomic locations of PVs between different B-cell lymphoma subtypes were also observed (FIGS. 2D-2E and FIGS. 10-12). This included previously established biological associations in DLBCL subtypes, including more frequent PVs in BCL2 in GCB-type than ABC-type DLBCL, with the opposite association seen for PIM1. More frequent PVs in CIITA in PMBCL compared with DLBCL, a gene in which breakpoints are common in PMBCL, was also observed. Relative enrichments were also observed throughout the IGH locus, with more frequent PVs seen in Sγ3 and Sγ1 regions in ABC-DLBCL (compared with GCB-DLBCL) and interestingly, more frequent PVs in the Sε locus in cHL compared with DLBCL (FIG. 2E and FIG. 13). In total, after correcting for testing multiple hypotheses, significant relative enrichments in 25 genetic loci between ABC- and GCB-DLBCL, 24 between DLBCL and PMBCL, and 40 between DLBCL and cHL were found (FIG. 10-12).


Example 6: Recovery of Phased Variants Through PhasED-Seq

To facilitate detection of ctDNA using PVs, efficient recovery of DNA molecules is desired. Hybrid-capture sequencing is potentially sensitive to DNA mismatches, with increasing mutations decreasing hybridization efficiency. Indeed, AID hotspots can contain a 5-10% local mutation rate, with even higher rates in certain regions of IGH. To empirically assess the effect of mutation rate on capture efficiency, DNA hybridization of 150-mers with varying mutation rates in silico was simulated. As expected, predicted binding energy decreased with an increasing number of mutations (FIG. 14A). Notably, randomly distributed mutations had a greater effect on binding energy than clustered mutations. To assess the effect of this decreased binding affinity, 150-mer DNA oligonucleotides with 0 to 10% difference from the reference sequence in MYC and BCL6, two loci that are targets of aSHM were synthesized. To assess the worst-case scenario for hybridization, non-reference bases were randomly distributed rather than in clusters (Example 10). An equimolar mixture of these oligonucleotides were then captured with PhasED-Seq panel. Concordant with the in silico predictions, increased mutational rates resulted in decreased capture efficiency (FIG. 3A). Molecules with a 5% mutation rate were captured with 85% efficiency relative to fully-wildtype counterparts, while molecules with 10% mutation were captured with only 27% relative efficiency. To assess the prevalence of this degree of mutation in human tumors, the distribution of variants in panel in 140 patients with B-cell lymphomas, calculating the fraction of mutated bases in overlapping 151-bp windows (Example 10) was examined. Only 7% ( 10/140) of patients had any 151-bp window exceeding 10% mutation rate (FIG. 14B-C). Indeed, in the experiment with synthetic oligonucleotides, a 5% mutation rate was recovered nearly as efficiently as the wild-type sequence. In over half of all cases considered, no locus had >5% mutation rate at any window, while in all cases >90% of windows had <5% mutations. Overall, these observations indicate that the majority of phased mutations are recoverable by efficient hybrid capture, despite hybridization biases.


Example 7: Error Profile and Limit of Detection for Phased Variant Sequencing

Previous methods for highly error-suppressed sequencing applied to cfDNA have utilized either a combination of molecular and in silico methods for error suppression (e.g., integrated digital error suppression, iDES) or duplex molecular recovery. However, each of these has limitations, either for detecting events at ultra-low tumor fractions or for efficient recovery of original DNA molecules, which are important considerations for cfDNA analysis where input DNA is limited. The error profile and recovery of input genomes from plasma cfDNA samples form 12 heathy adults by PhasED-Seq were compared with both iDES-CAPP-Seq and duplex sequencing. While iDES-enhanced CAPP-Seq had a lower background error profile than barcode-deduplication alone, duplex sequencing offered the lowest background error rate for non-reference single nucleotide substitutions (FIG. 3B, 3.3×10−5 vs. 1.2×10−5, P<0.0001). However, the rate of phased errors—e.g., multiple non-reference bases occurring on the same sequencing fragment—was significantly lower than the rate of single errors in either iDES-enhanced CAPP-Seq or duplex sequencing data. This was true for the incidence of both two (2× or ‘doublet’ PVs) or three (3× or ‘triplet’ PVs) substitutions on the same DNA molecule (FIG. 3B, 8.0×10−7 and 3.4×10−8 respectively, P<0.0001). Phased errors containing C to T or T to C transition substitutions were more common than other types of PVs (FIG. 14D). Notably, the rate doublet PVs errors in cfDNA was also correlated with distance between positions, with the highest PV error-rate consisting of neighboring SNVs (e.g., DNVs) and decreasing error rate with increasing distance between constituent variants (FIG. 14E). When considering unique molecular depth, duplex sequencing recovered only 19% of all unique cfDNA fragments (FIG. 3C). In contrast, the unique depth of PVs within a genomic distance of <20 bp was nearly identical to the depth of individual positions (e.g., molecules covering individual SNVs). Similarly, PVs up to 80 bps in size had depth greater than 50% of the median unique molecular depth for a sample. Importantly, almost half (48%) of all PVs were within 80 bp of each other, demonstrating their utility for disease detection from input-limited cfDNA samples (FIG. 3D).


To quantitatively compare the performance of PhasED-Seq to alternative methods for ctDNA detection, limiting dilutions of ctDNA from 3 lymphoma patients into healthy control cfDNA were generated, resulting in expected tumor fractions between 0.1% and 0.00005% (1 part in 2,000,000; (Example 10). The expected tumor fraction was compared to the estimated tumor content in each of these dilutions using PhasED-Seq to track tumor-derived PVs, as well as to error-suppressed detection methods depending on individual SNVs (e.g. iDES-enhanced CAPP-Seq or duplex sequencing; FIG. 3E). All methods performed equally well down to tumor fractions of 0.01% (1 part in 10,000). However, below this level (e.g., 0.001%, 0.0002%, 0.0001%, and 0.00005%), both PhasED-Seq and duplex sequencing significantly outperformed iDES-enhanced CAPP-Seq (P<0.0001 for duplex, ‘2×’ PhasED-Seq, and ‘3×’ PhasED-Seq; FIG. 3E). In addition, when compared to duplex-sequencing, tracking either 2 or 3 variants in-phase (e.g., 2× and 3× PhasED-Seq) more accurately identified expected tumor content, with superior linearity down to 1 part in 2,000,000 (P=0.005 for duplex vs 2× PhasED-Seq, P=0.002 for 3× PhasED-Seq) (Example 10). Specificity of PVs by looking for evidence of tumor-derived SNVs or PVs in cfDNA samples from 12 unrelated healthy control subjects and the healthy control used for the limiting dilution was assessed. Here again, both 2×- or 3×-PhasED-Seq showed significantly lower background signal levels than did CAPP-Seq and duplex sequencing (FIG. 3F). This lower error rate and background from PVs improves the detection limit for ctDNA disease detection. In some instances, the method of sequencing-based cfDNA assays described herein (e.g. the method depicted in FIG. 3E and FIG. 3F) does not require molecular barcodes to achieve exquisite error-suppression and low limits of detection. Signal assessed by the method without barcode used limiting dilution series from 1:1,000 to 5:10,000,000, and ‘blank’ controls (FIGS. 23A-23B).


This dilution series was used to assess the limit of detection for a given number of PVs (FIGS. 3G-3I). When considering a set of PVs within 150 base pair (bp) regions, the probability of detection for a given sample may be accurately modelled by binomial sampling, considering both the depth of sequencing and the number of 150 bp regions with PVs (Example 10).


Example 8: Improvements in Detection of Low-Burden Minimal Residual Disease

To test the utility of the lower LOD afforded by PhasED-Seq for detection of ultra-low burden MRD from cfDNA, Serial cell-free DNA samples were sequenced from a patient undergoing front-line therapy for DLBCL (FIG. 4A). Using CAPP-Seq, this patient had undetectable ctDNA after only one cycle of therapy, with multiple subsequent samples during and after treatment also remaining undetectable. This patient had subsequent re-emergence of detectable ctDNA >250 days after the start of therapy, with eventual clinical and radiographic disease progression 5 months later, indicating falsely negative serial measurements with CAPP-Seq. Strikingly, all four of the plasma samples that were undetectable by CAPP-Seq during and after treatment had detectable ctDNA levels by PhasED-Seq, with mean allelic fractions as low as 6 parts in 1,000,000. This increased sensitivity improved the lead-time of disease detection by ctDNA compared to radiographic surveillance from 5 with CAPP-Seq to 10 months with PhasED-Seq.


Next, the performance of PhasED-Seq ctDNA detection in a cohort of 107 patients with large B-cell lymphomas and blood samples available after 1 or 2 cycles of standard immuno-chemotherapy was next assessed. Importantly, ctDNA levels measured by PhasED-Seq were highly correlated with those measured by CAPP-Seq. In total, 443 tumor, germ-line, and cell-free DNA samples, including cfDNA prior to therapy (n=107) and after 1 or 2 cycles of treatment (n=82 and 89), were assessed. Prior to therapy, patient-specific PVs were detectable by PhaseED-Seq in 98% of samples, with 95% specificity in cfDNA from healthy controls (FIGS. 15 and 16A). Importantly, ctDNA levels measured by PhasED-Seq were highly correlated with those measured by CAPP-Seq, considering both pretreatment and post treatment samples (Spearman rho=0.91, FIG. 16B). Next, quantitative levels of ctDNA measured by PhasED-Seq and CAPP-Seq from cfDNA samples after initiation of therapy were compared. In total, 72% ( 78/108) of samples with detectable ctDNA by PhasED-Seq after 1 or 2 cycles were also detected by conventional CAPP-Seq (FIG. 4B). Among 108 samples detected by PhasED-Seq, disease burden was significantly lower for those with undetectable (28%) vs. detectable (72%) ctDNA levels using conventional CAPP-Seq, with a >10× difference in median ctDNA levels (tumor fraction 2.2×104 vs 1.2×105, P<0.001, FIG. 4B). In total, an additional 16% ( 13/82) of samples after 1 cycle of therapy and 19% ( 17/89) of samples after 2 cycles of therapy had detectable ctDNA when comparing PhasED-Seq with CAPP-Seq (FIG. 4C).


ctDNA molecular response criteria was previously described for DLBCL patients using CAPP-Seq, including Major Molecular Response (MMR), defined as a 2.5-log reduction in ctDNA after 2 cycles of therapy22. While MMR at this time-point is prognostic for outcomes, many patients have undetectable ctDNA by CAPP-Seq at this landmark (FIGS. 4D-4E). Importantly, even in patients with undetectable ctDNA by CAPP-Seq, detection of occult ultra-low ctDNA levels by PhasED-Seq was prognostic for outcomes including event-free and overall survival (FIG. 4D). Indeed, in the 89 patients with a sample available from this time-point, 58% ( 52/89) had undetectable ctDNA by CAPP-Seq at their interim MMR assessment, after completing 2 of 6 planned cycles of therapy. Using PhasED-Seq, 33% ( 17/52) of samples not detected by CAPP-Seq had evidence of ctDNA as evidenced by PVs, with levels as low as ˜3:1,000,000 (FIGS. 17A-17D)—these 17 cases additionally detected by PhasED-Seq represent potential false negative tests by CAPP-Seq. Similar results were seen at the Early Molecular Response (EMR) time-point (i.e., after 1 cycle of therapy, FIGS. 18A-18H).


While detection of ctDNA in DLBCL after 1 or 2 cycles of therapy is a known adverse prognostic marker outcomes for patients with undetectable ctDNA at these time-points are heterogeneous (FIG. 4E and FIG. 18F). Importantly, even in patients with undetectable ctDNA by CAPP-Seq after 1 or 2 cycles of therapy, detection of ultra-low ctDNA levels by PhasED-Seq was strongly prognostic for outcomes including event-free survival (FIG. 4F, FIGS. 17C-D, FIGS. 18C-D, and FIG. 18G). When combining detection by PhasED-Seq with previously described MMR threshold, patients could be stratified into three groups—patients not achieving MMR, patients achieving MMR but with persistent ctDNA, and patients with undetectable ctDNA (FIG. 4G). Interestingly, while patients not achieving MMR were at especially high risk for early events despite additional planned first line therapy (e.g., within the first year of treatment), patients with persistent low levels of ctDNA appeared to have a higher risk of later relapse or progression events. In contrast, patients with undetectable ctDNA after 2 cycles of therapy by PhasED-Seq had overwhelmingly favorable outcomes, with 95% being event-free and 97% overall survival at 5 years. Similar results were seen at the EMR time-point after 1 cycle of therapy (FIG. 1811).


Example 9: Exemplary Embodiments of Mutation Detection Using Next Generation Sequencing (NGS) when the Mutation is not a Single Base Substation, but Rather a Pair of Mutations

In many instances, a limitation of cfDNA tracking may be the limitation on the number of molecules available for detection. Additionally, there are multiple potential limitations on tracking tumor molecules from cell-free DNA, including not only the sequencing error profile, but also the number of molecules available for detection. The number of molecules available for detection—here termed the number of “evaluable fragments”—can be thought of as both a function of the number of recovered unique genomes (e.g., unique depth of sequencing) and the number of somatic mutations being tracked. More specifically, the number of evaluable fragments is equal to: EF=d*n.


Where d=the unique molecular depth considered and n=the number of somatic alterations tracked. For the typical cell-free DNA samples, less than 10,000 unique genomes are often recovered (d), requiring any sensitive method to track multiple alterations (n). Furthermore, as stated above, the major limitation for duplex sequencing is difficulty recovering sufficient unique molecular depth (d); thus, from a typical plasma sample with duplex depth of ˜1,500×, even if following 100 somatic alterations, there are only 150,000 evaluable fragments. Thus, in this scenario, sensitivity is limited by the number of molecules available for detection. In contrast, other methods such as iDES-enhanced CAPP-Seq consider all molecules recovered. Here, as many as 5,000-6,000× unique haploid genomes can be recovered. Therefore, the number of evaluable fragments, tracking the same 100 somatic alterations, may be 500,000-600,000×. However, the error profile of single-stranded sequencing, even with error suppression, allows detection to levels of at best 1 part in 50,000. Therefore, methods aiming to improve on the detection limits for ctDNA must overcome both the error-profile of sequencing and the recovery of sufficient evaluable fragments to utilize said lower error-profiles.


To remedy this apparent deficiency, the method of PhasED-Seq, as described in the instant disclosure, allows for lymphoid malignancies and was applicable to other cancer histologies, (e.g., using a “personalized” approach). For a personalized approach, customized hybrid-capture oligonucleotides (or primers for PCR amplicons) were used to capture personalized somatic mutations identified from whole exome or genome sequencing. The PCAWG dataset assessed for SNVs occurring within 170 bp of each other in genomic space was re-analyzed. It was found that in 14 of 24 cancer histologies considered, the median case contained >100 possible phased variants, including in several solid tumors such as Melanoma (median 2072), lung squamous cell carcinoma (1268), lung adenocarcinoma (644.5), and colorectal adenocarcinoma (216.5).


Next, the expected limit of detection in all cases in the PCAWG dataset using either duplex sequencing or PhasED-Seq was assessed. Again, the limit of detection was defined by the expected number of evaluable fragments, and thus depends on both the number of variants tracked and the expected depth of sequencing. Utilizing the data from optimized hybrid capture conditions, a model to predict the expected deduplicated (single-stranded) and duplex (double-stranded) molecular depth with a given DNA input and number of sequencing reads was constructed. Using this, along with the number of SNVs or possible PVs from the PCAWG dataset, for each case, which method would lead to a greater number of evaluable fragments, and therefore a superior limit of detection was assessed. The results of this exercise, assuming 64 nanograms (ng) of total cfDNA input and a total of 20 million sequencing reads are shown in FIG. 19. Notably, in the majority of cancer types ( 18/24 histologies), PhasED-Seq had a lower limit of detection than duplex sequencing. This importantly included not only B-cell lymphomas, but common solid tumors, including lung squamous cell carcinoma and adenocarcinoma, colorectal adenocarcinoma, esophageal and gastric adenocarcinoma, and breast adenocarcinoma, among others. Indeed, taking lung cancers as a specific example, an almost 10-fold lower limit of detection was found for the median squamous cell and adenocarcinoma lung cancer case using PhasED-Seq compared to duplex sequencing (FIG. 20). Both PhasED-Seq and duplex sequencing using a personalized approach had a lower limit of detection than non-personalized approaches (e.g., iDES-enhanced CAPP-Seq).


To further confirm the applicability of phased variants and PhasED-Seq in diverse solid tumors, WGS (20-30×) was performed on paired tumor and normal DNA to identify PVs from five solid tumor patients predicted to have low ctDNA burden prior to treatment (lung cancer (n=5)). After identifying putative PVs in each case, a set of personalized hybrid capture oligonucleotides was subsequently designed to performed targeted resequencing of tumor and normal DNA to validate candidate PVs. Finally, plasma samples were sequenced from all 5 patients to high unique molecular depth using personalized PhasED-Seq to detect ctDNA. Considering these five lung cancer cases the PhasED-Seq approach achieved a ˜10-fold improvement in analytical sensitivity, achieving a median LOD of 0.00018% compared to 0.0019% using customized CAPP-Seq (FIG. 21).


To demonstrate the clinical significance of this improved limit of detection for ctDNA from PhasED-Seq in solid tumors, serial plasma samples from a patient with stage 3 adenocarcinoma of the lung treated with chemoradiotherapy with curative intent (LUP814) were analyzed using both CAPP-Seq and PhasED-Seq. As outlined above, both CAPP-Seq and PhasED-Seq quantified a similar level of ctDNA prior to therapy (˜1% tumor fraction). However, 3 subsequent samples after beginning therapy had undetectable ctDNA by standard CAPP-Seq, including samples during and after chemoradiation and during adjuvant immunotherapy with Durvalumab. Despite the lack of detectable disease by CAPP-Seq, the patient had biopsy-confirmed recurrent disease after an initial radiographic response. However, when analyzing these same samples with PhasED-Seq, molecular residual disease in 3/3 (100%) of samples was detected, with mean tumor fraction as low as 0.00016% (1.6 parts per million). Furthermore, the trend in ctDNA quantitation mirrored the patient's disease course, with an initial response to chemoradiotherapy but disease progression during immunotherapy. Importantly, this patient's disease remained detectable at all timepoints, with detectable disease at the completion of chemoradiotherapy 8 months prior to the patient's biopsy-confirmed disease progression (FIG. 22).


Example 10: Methods of Phased Variant Enrichment for Enhanced Disease Detection from Cell-Free DNA

10(a): Whole-Genome Sequencing Analysis


10(a)(1): Whole-Genome Sequencing Data Putative Phased Variant Identification


Whole-genome sequencing data were obtained from two sources. Data for lymphoid malignancies (diffuse large B-cell lymphoma, DLBCL; follicular lymphoma, FL; Burkitt lymphoma, BL; chronic lymphocytic leukemia, CLL) were downloaded from the International Cancer Genome Consortium (ICGC) data portal on May 7, 2018. Data from all other histologies were part of the pan-Cancer analysis of whole genomes (PCAWG) and downloaded on Nov. 11, 2019. Only cancer histologies with at least 35 available cases were considered; details of the dataset considered are provided in Table 1. All samples had somatic mutations called from WGS using matched tumor and normal genotyping. Queries were limited to base substitutions obtained from WGS (single, double, triple, and oligo nucleotide variants; SNVs, DNVs, TNVs, and ONVs). Having thus identified the cases and variants of interest, the number of putative phased variants (PVs) in each tumor was next identified. To function as a PV on a single cell-free DNA (cfDNA) molecule, two variants, such as two single nucleotide variants (SNVs) generally must occur within a genomic distance less than the length of a typical cfDNA molecule (˜170 bp). Therefore, putative PVs were defined as two variants occurring on the same chromosome within a genomic distance of <170 bp. DNVs, TNVs, and ONVs were considered as the set of their respective component SNVs. The number of SNVs as well as the identity of putative PVs for each case are detailed in Table 1. The raw number of SNVs and putative PVs, as well as the number of putative PVs controlling for the number of SNVs, is shown in FIG. 5A-C.


10(a)(2): Mutational Signatures of Phased Variants from WGS


To assess the mutational processes associated with phased and non-phased mutations across different cancer types/subtypes, the mutational signatures of single base substitutions (SBS) were enumerated for each WGS case described above using the R package ‘deconstructSigs’. The list of SNVs for each patient was first divided into two groups: 1) SNVs contained within a possible PV; that is, with an adjacent or ‘nearest neighbor’ SNV <170 bp away, and 2) isolated SNVs (i.e., non-phased), defined as those occurring ≥170 bp in distance from the closest adjacent SNV. ‘DeconstructSigs’ was then applied using the 49 SBS signatures described in COSMIC (excluding signatures linked to possible sequencing artefacts) to assess the contribution of each SBS signature to both candidate phased SNVs and un-phased SNVs for each patient. To compare the contribution of each SBS signature to phased and isolated SNVs, a Wilcoxon signed rank test was performed to compare the relative contribution of each SBS signature between these two categories for each cancer type (FIGS. 6A-6WW). To account for multiple hypotheses, Bonferroni's correction was applied, by considering any SBS signature that differed in contribution to phased vs. un-phased SNVs to be significant if the Wilcoxon signed rank test resulted in a P-value of <0.05/49 or 0.001. The distributions of these comparisons, along with significance testing, are depicted in FIGS. 6A-6WW. A summary of this analysis is also shown in FIG. 1C using a heat-map display, where the ‘heat’ represents the difference between the mean contribution of the SBS signature to phased variants to the mean contribution to isolated/un-phased variants.


10(a)(3): Genomic Distribution of Phased Variants from WGS


The recurrence frequency for PVs was assessed in each cancer type across the genome within each tumor type. Specifically, the human genome (build GRCh37/hg19) was first divided into 1-kb bins (3,095,689 total bins); then, for each sample, the number of PVs (as defined above) contained in each 1-kb bin was counted. For this analysis, any PV with at least one of its constituent SNVs falling within the 1-kb bin of interest was included. The fraction of patients whose tumors harbored a PV for each cancer type within each genomic bin was then calculated. To identify 1-kb bins recurrently harboring PVs across patients, the fraction of patients containing PVs in each 1-kb bin vs. genomic coordinates (FIG. 1D and FIG. 7) was plotted; for this analysis, only bins where at least 2% of samples contained a PV in at least one cancer subtype were plotted.


10(a)(4): Identification of Recurrent 1-kb Bins with Phased Variants


To identify 1-kb bins that recurrently contain PVs in B-lymphoid malignancies, WGS data was utilized from the following diseases: DLBCL, FL, BL, and CLL. Any 1-kb bin where >1 sample from these tumor types was considered to recurrently contain PVs from B-lymphoid malignancies. The genomic coordinates of 1-kb bins containing recurrent PVs in lymphoid malignancies are enumerated in Table 2, and are plotted in FIG. 8A.


10(b): Design of PhasED-Seq Panel for B-Lymphoid Malignancies


10(b)(1): Identification of Recurrent PVs from WGS Data at Higher Resolution


Given the prevalence of recurrent putative PVs from WGS data in B-cell malignancies, a targeted sequencing approach was designed for their hybridization-mediated capture—Phased variant Enrichment Sequencing (PhasED-Seq)—to enrich these specific PV events from tumor or cell-free DNA. In addition to the ICGC data described above, WGS data was also utilized from other sources in this design, including both B-cell NHLs as well as CLL.


Previous experience with targeted sequencing from cfDNA in NHLs was also examined. Pairs of SNVs occurring at a distance of <170 bp apart in each B-cell tumor sample were identified. Then, genomic “windows” that contained PVs was identified as follows: for each chromosome, the PVs were sorted by genomic coordinates relative to reference genome. Then, the lowest (i.e., left-most) position was identified for any PV in any patient; this defined the left-hand (5′) coordinate seeding a desired window of interest, to be captured from the genome. This window was then extended by growing its 3′ end to capture successive PVs until a gap of ≥340 bp was reached, with 340-bp chosen as capturing two successive chromatosomal sized fragments of ˜170-bp. When such a gap was reached, a new window was started, and this iterative process of adding neighboring PVs was repeated again until the next gap of ≥340 bp was reached. This resulted in a BED file of genomic windows containing all possible PVs from all samples considered. Finally, each window was additionally padded by 50 bp on each side, to enable efficient capture from flanking sequences in rare scenarios when repetitive or poorly mapping intervening sequences might preclude their direct targeting for enrichment.


Having identified the regions of interest containing putative PVs, each window was then into 170 bp segments (e.g., the approximate size of a chromatosomal cfDNA molecule). Then, the number of cases containing a PV was enumerated in each case. For each 170 bp region, the region in final sequencing panel design was included if one or more of the following criteria was met: 1) at least one patient contained a PV in the 170 bp region in 3 of 5 independent data-sets, 2) at least one patient contained a PV in the region in 2 of 5 independent data-sets if one dataset was prior CAPP-Seq experience, or 3) at least one patient contained a PV in the region in 2 of 5 independent data-sets, with a total of at least 3 patients containing a PV in the region. This resulted in 691 ‘tiles’, with each tile representing a 170 bp genomic region. These tiles, along with an additional ˜200 kb of genomic space targeting driver genes recurrently mutated in B-NHL, were combined into a unified targeted sequencing panel as previously described for both tumor and cfDNA genotyping using NimbleDesign (Roche NimbleGen). The final coordinates of this panel are provided in Table 3.


10(b)(2): Comparison of PhasED-Seq and CAPP-Seq Performance in PV Yield


To evaluate the performance of PhasED-Seq for capturing both SNVs and PVs compared to previously reported CAPP-Seq selector for B-cell lymphomas, the predicted number of both SNVs and PVs that may be recovered with each panel by limiting WGS in silico to the capture targets of each approach (FIG. 9A-C) was quantified. The predicted number of variants was then compared using the Wilcoxon signed rank test. Both CAPP-Seq and PhasED-Seq were also performed on 16 samples from patients with DLBCL. In these samples, tumor or plasma DNA, along with matched germ-line DNA, was sequenced. The resulting number of variants were again compared by the Wilcoxon signed rank text (FIG. 2B, and FIGS. 9D-9E). The sequencing depth for the samples included in this analysis are provided in Tables 4.


10(c): Identification of Phased Variants from Targeted Sequencing Data


10(c)(1): Patient Enrollment and Clinical Sample Collection


Patients with B-cell lymphomas undergoing front-line therapy were enrolled on this study from six centers across North America and Europe, including Stanford University, MD Anderson Cancer Center, the National Cancer Institute, University of Eastern Piedmont (Italy), Essen University Hospital (Germany), and CHU Dijon (France). In total, 343 cell-free DNA, 73 tumor, and 183 germ-line samples from 183 patients were included in this study. All patient samples were collected with written informed consent for research use and were approved by the corresponding Institutional Review Boards in accordance with the Declaration of Helsinki. Cell-free, tumor, and germ-line DNA were isolated as previously described. All radiographic imaging was performed as part of standard clinical care.


10(c)(2): Library Preparation and Sequencing


To generate sequencing libraries and targeted sequencing data, CAPP-Seq was applied as previously described. Briefly, cell-free, tumor, and germ-line DNA were used to construct sequencing libraries through end repair, A-tailing, and adapter ligation following the KAPA Hyper Prep Kit manufacturer's instructions with ligation performed overnight at 4° C. CAPP-Seq adapters with unique molecular identifiers (UMIDs) were used for barcoding of unique DNA duplexes and subsequent deduplication of sequencing read pairs. Hybrid capture was then performed (SeqCap EZ Choice; NimbleGen) using the PhasED-Seq panel described above. Affinity capture was performed according to the manufacturer's protocol, with all 47° C. hybridizations conducted on an Eppendorf thermal cycler. Following enrichment, libraries were sequenced using an Illumina HiSeq4000 instrument with 2×150 bp paired-end (PE) reads.


10(c)(3): Pre-Processing and Alignment


FASTQ files were de-multiplexed and UMIDs were extracted using a custom pipeline as previously described. Following demultiplexing, reads were aligned to the human genome (build GRCh37/hg19) using BWA ALN. Molecular barcode-mediated error suppression and background polishing (i.e., integrated digital error suppression; iDES) were then performed as previously described.


10(c)(4): Identification of Phased Variants and Allelic Quantitation


After generating UMID error-suppressed alignment files (e.g., BAM files), PVs were identified from each sample as follows. First, matched germ-line sequencing of uninvolved peripheral blood mononuclear cells (PBMCs) was performed to identify patient-specific constitutional single nucleotide polymorphisms (SNPs). These were defined as non-reference positions with a variant allele fraction (VAF) above 40% with a depth of at least 10, or a VAF of above 0.25% with a depth of at least 100. Next, PVs were identified from read-level data for a sample of interest. Following UMID-mediated error suppression, each individual paired-end (PE) read and identified all non-reference positions were using ‘samtools calmd’. PE data was used rather than single reads to identify variants occurring on the same template DNA molecule, which may subsequently fall into either read 1 or read 2. Any read-pair containing ≥2 non-reference positions was considered to represent a possible somatic PV. For reads with ≥2 non-reference positions, each permutation of size ≥2 was considered independently: i.e., if 4 non-reference positions were identified in a read-pair, all combinations of 2 SNVs (i.e., ‘doublet’ phased variants) and all combinations of 3 SNVs (i.e., ‘triplet’ phased variants) were independently considered. PVs containing putative germ-line SNPs were also removed as follows: if in a given n-mer (i.e., n SNVs in phase on a given molecule) ≥n−1 of the component variants were identified as germ-line SNPs, the PV was redacted. This filtering strategy ensures that for any remaining PV, at least 2 of the component SNVs were not seen in the germ-line, as relevant for both sensitivity and specificity.


Putative somatic PVs were filtered using a heuristic blacklisting approach in considering sequencing data from 170 germ-line DNA samples serving as controls. In each of these samples, PVs were identified on read-pairs as described above, but without filtering for matched germ-line. Any PV that occurred in one or greater paired-end read, in one or more of these control samples, was included in the blacklist and removed from patient-specific somatic PV lists.


To calculate the VAF of each PV, a numerator representing the number of DNA molecules containing a PV of interest was calculated over a denominator representing the total number of DNA molecules that covered the genomic region of interest. That is, the numerator is simply the total number of deduplicated read-pairs that contain a given PV while the denominator is the number of read-pairs that span the genomic locus of a given PV.


10(c)(5): Genotyping Phased Variants from Pretreatment Samples


The above strategy resulted in a list of PVs of ≥1 read-depth in each sample. To identify PVs serving as tumor-specific somatic reporters for disease monitoring, for each case a ‘best genotyping’ specimen—either DNA from a tumor tissue biopsy (preferred), or pretreatment cell-free DNA was identified. After identifying all possible PVs in the ‘best genotyping sample’, the list for specificity was further filtered as follows. For any n-mer PV set, if ≥n−1 of the constituent SNVs were present as germ-line SNPs in the 170 control samples described above, the PV was removed. Furthermore, only PVs that meet the following criteria were considered: 1) AF>1%; 2) depth of the PV locus of ≥100 read-pairs, and 3) at least one component SNV must be in the on-target space. Finally, 4) any PV meeting these criteria was assessed for read-support in a cohort of 12 healthy control cfDNA samples. If any read-support was present in >1 of these 12 samples, the PV was removed. For genotyping from cell-free DNA samples identified as low tumor fraction by SNVs (i.e., <1% mean AF across all SNVs), the AF threshold for determining PVs was relaxed to >0.2%. This filtering resulted in the PV lists used for disease monitoring and MRD detection.


10(c)(6): Determination of Tumor Fraction in a Sample from Phased Variants


For evaluation of a sample for minimal residual disease (MRD) detection with prior knowledge of the tumor genotype, the presence of any PV identified in the best pretreatment genotyping sample in the MRD sample of interest can be assessed. Given a list of k possible tumor-derived PVs observed in the best genotyping sample, all read-pairs covering at least 1 of the k possible PVs were determined. This value, d, can be thought of as the aggregated ‘informative depth’ across all PVs spanned by cfDNA molecules in a PhasED-Seq experiment. It was then assessed how many of these d read-pairs actually contained 1 or more of the k possible PVs—this value, x, represents the number of tumor-derived molecules containing somatic PVs in a given sample. The number of tumor-derived molecules containing PVs divided by the informative depth—x/d—is therefore the phased-variant tumor fraction (PVAF) in a given sample. For detection of MRD in each sample, PVAF was calculated independently for doublet, triplet, and quadruplet PVs.


10(c)(7): Monte Carlo Simulation for Empirical Significance of PV Detection within a Specimen


To assess the statistical significance of the detection of tumor-derived PVs in any sample, an empiric significance testing approach was implemented. A test statistic f was first defined as follows—from a given list of k possible tumor-derived PVs observed in the best genotyping sample, the arithmetic mean of allele fractions was calculated across all k PVs (allele fraction defined as the number of read-pairs containing an individual PV (xi) over the number of read-pairs spanning the PV positions (di)):









f
=








i
=
1

k




x
i


d
i



k





(
1
)








to assess the hypothesis that f is not significantly different from the background error-rate of similar PVs assessed from the same sample. A Monte Carlo approach was used to develop a null distribution and perform statistical testing as follows:

    • 1. Given a set of k PVs, {pv1 . . . pvi . . . pvk}, an ‘alternate’ list of PVs, {pv′1 . . . pv″i . . . pv′k}, was generated such that for each alternate PV had the same type of base change and distance between SNVs as the test PV. For example, if a doublet PV, chr14:106329929 C>T and chr14:106329977 G>A, was identified in the genotyping sample and searched for an alternate two positions at the same genomic distance (here, 48 bp) with reference bases C and G, and assessed for read-pairs with the same types of base changes (i.e., C>T and G>A), using the heuristic search scheme below.
    • 2. For each tumor pvi in the set of k, 50 such alternates were identified. This was performed with a random search algorithm to scan the genomic space and identify alternates. To find these 50 alternates, a random position on the same chromosome as the test pvi was identified and then searched for the same types of reference bases at the same genomic distance as described above. Synteny of observed/alternate PVs was used to control for regional variation in SHM/aSHM as well as copy number variation, as potential confounders of the null distribution. Alternate positions that were identified as a germ-line SNP, defined as having AF>5%, were excluded.
    • 3. After identifying 50 such alternates for each pvi, 10,000 random permutations of 1 alternate were generated for each of the k original PVs and calculated the phased-variant fraction f′ for these alternate lists in the sample of interest being evaluated for presence of MRD, as described above.
    • 4. An empiric P-value was calculated, defined as the fraction of times the true phased-variant fraction f is observed to be less than or equal to the alternate f′ across the 10,000 random PV lists as an empirical measure of significance of MRD significance in the blood sample of interest.


While this resulting comparison is a measure of the significance for PV detection of tumor-reporter list compared to the empirically defined background PV error-rate within the sample of interest, its relationship to specificity of detection across cases and control samples was also evaluated, as described below.


10(c)(8): Assessment of Specificity of PhasED-Seq


To determine the specificity of disease and MRD detection through PhasED-Seq, patient-specific PVs from 107 patients with DLBCL were first identified using pretreatment tumor or plasma DNA along with paired germ-line samples. 40 independent plasma DNA samples were then assessed from healthy individuals for presence of these patient-specific PVs, using the Monte Carlo approach outlined above. A threshold for P-values was empirically determined from Monte Carlo such that 95% specificity was achieved for disease detection from doublet, triplet, and quadruplet PVs. The P-value threshold yielding ≥95% specificity for each size of PV was as follows: <0.041 for doublets, <1 for triplets, and <1 for quadruplets. The results of this specificity in control cfDNA analysis is shown in FIGS. 15 and 16.


10(c)(9): Calculation of Error Rates


To assess the error profile of both isolated SNVs and PVs, the non-reference base observation rate of each type of variant was examined across all reads. For isolated SNVs, the error-rate for each possible base change en1>n1′ was calculated as the fraction of on-target bases with reference allele n1 that are mutated to alternate allele n1′, when considering all possible base-changes of the reference allele. Positions with a non-reference allele rate exceeding 5% were classified as probable germ-line events, and excluded from the error-rate analysis. A global error rate, defined as the rate of mutation from the hg19 reference allele to any alternate allele, was also calculated.


For phased variants, a similar calculation was performed. For the error-rate of a given type of phased variant composed of k constituent base-changes {en1>n1′ . . . enk>nk′}, the error-rate was calculated by determining both the number of instances of the type of base change (i.e., the numerator), as well as the number of possible instances for the base change (i.e., the denominator). To calculate the numerator, N, the number of occurrences of the PV of interest over all read-pairs was counted in a given sample. For example, to calculate the error-rate of C>T and G>A phased doublets, the number of read-pairs that include both a reference C mutated to a T as well as a reference G mutated to an A was first counted.


To calculate the denominator, D, the number of possible instances of this type of phased variant was also calculated; this was performed first for each read-pair i, and then summed over all read pairs. A PV with k components can be summarized as having certain set of reference bases pA, pC, pG, pT, where pN is the number of each reference base in the PV. Similarly, a given read pair contains a certain set of reference bases bA, bC, bG, bT, where bN is the number of each reference base in the read pair. Therefore, for each read pair in a given sample, the number of possible occurrences of PV type of interest can be calculated combinatorically as:










D
i

=


(




b
A






p
A




)



(




b
C






p
C




)



(




b
G






p
G




)



(




b
T






p
T




)






(
2
)








For example, consider a read-pair with 40 reference As, 50 reference Cs, 45 reference Gs, and 35 reference Ts. The number of positions for a C>T and G>A PV is:










D
i

=



(




4

0





0



)



(




5

0





1



)



(




4

5





1



)



(




3

5





0



)


=

2

2

5

0






(
3
)








The aggregated denominator, D, for error rate calculation is then simply the sum of this value over all read pairs. The error rate for this type of PV is then simply ND.


10(d): Differences in Phased Variants Between Lymphoma Subtypes


To compare the distribution of phased variants in different types of lymphomas, tumor-specific PVs were identified in 101 DLBCL, 16 PMBCL, and 23 cHL patients via sequencing of tumor biopsy specimens and/or pre-treatment cell-free DNA and paired germ-line specimens. After identifying these tumor-specific PVs, their distribution was the assessed across the targeted sequencing panel. The panel was first divided into 50 bp bins; for each patient, it was then determined if each patient had evidence of a PV within the 50 bp bin, defined as having at least one component of the PV within the bin. The nearest gene to each 50 bp bin was further determined, based on GENCODEv19 annotation of the reference genome.


To assess how the distribution of PVs between subtypes of lymphoma varies at the level of specific genes, the distribution of PVs was examined across the 50 bp bins spanning each gene (or nearest gene). For example, consider a given gene with n such 50 bp bins represented in targeted sequencing panel. For each bin, it was first determined the fraction of patients, f, in each type of lymphoma with a PV falling within the 50 bp bin—i.e., determining {ftype1,1, . . . ftype1,n} and {ftype2,1, . . . ftype2,n}. Then, any two histologies were then compared for the fraction of cases harboring PVs in the set of 50 bp bins assigned to each gene. These comparisons are depicted for individual genes on gene-specific plots in FIG. 2D and FIGS. 10-12.


The enrichment in PVs was statistically compared in a specific lymphoma type or subtype vs. another by calculating the difference in the fraction of patients which contain a PV in each 50 bp bin across all bins assigned to a gene (i.e., overlapping a given gene or with a given nearest gene). Specifically, for any comparison between two lymphoma types (type1 and type2), this set of differences in PV-rate was first identified between histologies {ftype1,1−ftype2,1, . . . ftype1,n−ftype2,n}. This set of gene-specific differences in frequency of PVs was the compared between types of lymphoma against the distribution of all other 50 bp bins in the sequencing panel by the Wilcoxon rank sum test. For this test, the set of n 50 bp bins assigned to a given gene was compared to all other 50 bp bins (i.e., 6755−n, since there are 6755 50 bp bins in sequencing panel). This P-value, along with the mean difference in fraction of patients with a PV in each bin for each gene between histologies, is depicted as a volcano plot in FIG. 2E. To account for the global difference in rate of PVs between different histologies, the mean difference in fraction of patients with a PV between histologies was centered on 0 by subtracting the mean difference across all genes.


10(e): Hybridization Bias


To assess the effect of mutations on hybridization efficiency, the affinity of mutated molecules to wildtype capture baits in silico was first estimated by considering DNA fragments harboring 0-30% mutations across the entire fragment. For each mutation condition across this range, 10,000 regions were first randomly sampled, each 150 bp in length, from across the whole genome. These 150-mers were then mutated in silico to simulate the desired mutation rate in 3 different ways: 1) mutating ‘clustered’ or contiguous bases starting from the ends of a sequence, 2) mutating clustered bases started from the middle of the sequence, or 3) mutating bases selected at random positions throughout the sequence. The energy.c package was then used to calculate the theoretical binding energy (kcal/mol) between the mutated and wild-type sequences, in relying on a nearest-neighbor model employing established thermodynamic parameters (FIG. 14A).


This in silico experiment was then replicated by testing the effects of same mutation rates in vitro. Specifically, oligonucleotides (IDT) were synthesized and annealed to form DNA duplexes harboring 0-10% mutations at defined positions relative to the human reference genome sequence. These synthetic DNA molecules were then captured together at equimolar concentrations and quantified the relative capture efficiency of mutated duplexes compared to the wild-type, unmutated species (FIG. 3A). Two sets of oligonucleotide sequences were selected from coding regions of BCL6 and MYC to capture AID-mediated aberrant somatic hypermutations associated with each gene (Table 5); the preserved mappability of the mutated species was ensured by BWA ALN. These synthetic oligonucleotide duplexes were then subjected to library preparation, then captured and sequenced using PhasED-Seq, performed in triplicate using distinct samples. This allowed assessment of the relative efficiency of hybrid capture and molecular recovery as directly compared to wildtype molecules identical to the reference genome.


10(f): Assessment of Limit of Detection with Limiting Dilution Series


To empirically define the analytical sensitivity of PhasED-Seq, a limited dilution series of cell-free DNA from 3 patients that were spiked into healthy control cell-free DNA at defined concentrations was utilized. The dilution series contained samples with an expected mean tumor fraction of 0.1%, 0.01%, 0.001%, 0.0002%, 0.0001%, and 0.00005% or ranging from 1 part in 1,000 to 1 part in 2,000,000. The sequencing characteristics and ctDNA quantification via CAPP-Seq, duplex sequencing, and PhasED-Seq are provided. To compare the performance of each method, the difference was calculated, δ, between the observed and expected tumor fraction for each patient i at each dilution concentration j:

δi,j=custom character−tumorfraci,j  (4)

This value was calculated for patients i={1,2,3} and concentrations j={0.001%, 0.0002%, 0.0001%, 0.00005%} for each ctDNA detection method (CAPP-Seq, duplex, doublet PhasED-Seq, and triplet PhasED-Seq). The performance of each method was then compared to each other by paired t-test across this set of patients and concentrations.


10(g): Model to Predict the Probability of Detection for a Given Set of Phased Variants


To build a mathematical model to predict the probability of detection for a given sample of interest, it began with the common assumption that cfDNA detection can be considered a random process based on binomial sampling. However, unlike SNVs occurring at large genomic distances apart from one another, detection of PVs can be highly inter-dependent, especially when PVs are degenerate (i.e., when two PVs share component SNVs) or occur in close proximity. To account for this, only PVs occurring >150 bp apart from each other was considered as independent ‘tumor reporters’. The number of ‘tumor reporters’ to allow for disease detection in a given sample can thus be determined as follows. The PhasED-Seq panel was broken apart into 150 bp bins. Each PV in a given patient's reporter list was then turned into a BED coordinate, consisting of the start position (defined as the left-most component SNV) and end position (defined as the right-most component SNV). For each PV, the 150 bp bin from the PhasED-Seq selector panel containing the PV was determined; if a PV spanned two or more 150 bp bins, it was assigned to both bins. The number of independent tumor reporters was then defined as the number of separate 150 bp bins containing a tumor-specific PV.


A mathematical model was then developed comparing the expected probability of detection for a given sample at a given tumor fraction with a given number of independent tumor reporters (e.g., 150 bp bins). With a given number of tumor reporters r, at a given tumor fraction f, with a given sequencing depth d, the probability of detecting 1 or more cell-free DNA molecule containing a tumor-specific PV containing can be defined as:













Pr

(
detection
)

=


1
-

Pr

(
nondetection
)








=


1
-


(




d
*
r





0



)





f
0

(

1
-
f

)


d
*
r











(
5
)








based on simple binomial sampling. However, as ctDNA detection method was trained to have a 5% false positive rate, this false positive rate term was added to the model as well:










Pr

(
detection
)

=

1
-

Pr

(
nondetection
)

+

0.05
*

Pr

(
nondetection
)







(
7
)
















Pr

(
detection
)

=


1
-

0.95
*

Pr

(
nondetection
)









=


1
-

0.95
*

(




d
*
r





0



)





f
0

(

1
-
f

)


d
*
r















(
8
)








(
9
)












FIG. 3G shows the results of this model for a range of tumor reporters r from 3 to 67 at depth d of 5000. The confidence envelope on this plot shows solutions for a range of depth d from 4000 to 6000.


To empirically validate this model assessing the probability of disease detection, samples from limiting dilution series were utilized. In this dilution series, 3 patient cfDNA samples, each containing patient-specific PVs, were spiked into healthy control cfDNA. For each list of patient specific PVs, 25 random subsamplings of the 150 bp bins containing patient-specific PVs were performed to generate reporter lists containing variable numbers of tumor-specific reporters. A maximum bin number of 67 was selected to allow sampling from all 3 patient-specific PV lists, followed by scaling down the number of bins by 2× or 3× per operation. This resulted in reporter lists containing patient-specific PVs from 3, 6, 17, 34, or 67 independent 150 bp bins. Disease detection was then assessed using each of these patient-specific PV lists of increasing size in each of ‘wet’ limiting dilution samples from 1:1,000 to 1:1,000,000 (FIG. 3H, closed circles). In silico mixtures was further created using sequencing reads from limiting dilution samples with varying expected tumor-content, and again assessed for the probability of disease detection using patient-specific subsampled PV reporter lists of varying lengths (open circles). For this experiment, both the ‘wet’ and ‘in-silico’ dilution bam files were down-sampled to achieve a depth of ˜4000-6000× to correspond with modeled depth. The final mean and standard deviation of depth across all down-sampled bam files was 4214×±789. The probability of detection was summarized across all tests at a given expected tumor fraction, for a given patient-specific PV list. For each given dilution, multiple independently sampled sets of reads were considered to allow superior estimation of the true probability of detection. Specifically, the following number of replicates at each dilution indicated was considered in Table 7.









TABLE 7







Replicates at each dilution for predicting the probability of


detection for a given set of phased variants.












Number of Tests



Dilution
Replicates
(Replicates * 25)
Wet or In silico













  1:1,000
1
 25
Wet


  5:10,000
3
 75
In silico


3.5:10,000
3
 75
In silico


  2:10,000
3
 75
In silico


  1:10,000
3
 75
Wet


  5:100,000
3
 75
In silico


3.5:100,000
3
 75
In silico


  2:100,000
3
 75
In silico


  1:100,000
3
 75
Wet


  5:1,000,000
8
200
In silico


3.5:1,000,000
8
200
In silico


  2:1,000,000
8
200
Wet


  1:1,000,000
8
200
Wet









The total number of tests, for each patient-specific PV list, is therefore the number of randomly subsampled PV lists (e.g., 25) times the number of independently downsampled bam files; this number is provided in the table above. In FIG. 3H, the points and error-bars represent the mean, minimum, and maximum across all three patients. The concordance between the predicted probability of disease detection from theoretical mathematical model and wet and in silico samples validating this model, is shown in FIG. 3I.


10(h): Statistical Analyses & Software Availability


All P-values reported in this manuscript are 2-sided unless otherwise noted. Comparisons of matched samples and populations were performed using the Wilcoxon signed rank test; comparisons of samples drawn from unrelated populations were performed using the Wilcoxon rank-sum test. Comparisons of paired samples were performed by paired t-test. Survival probabilities were estimated using the Kaplan-Meier method; survival of groups of patients based on ctDNA levels were compared using the log-rank test. Other statistical tests are noted in the manuscript text where utilized. All analyses were performed with the use of MATLAB, version 2018b, R Statistical Software version 3.4.1, and GraphPad Prism, version 8.0.2. The contribution of known mutational processes to phased and isolated SNVs from WGS was assessed with the deconstruct Sigs R package using the COSMIC signature set (v2) as described. Calculation of AUC accounting for survival and censorship was performed using the R ‘survivalROC’ package version 1.0.3 with default settings. An executable version of the PhasED-Seq software, developed in C++ 17, is available at phasedseq(dot)stanford(dot)edu.


Example 11

Additional details of the tables described throughout the present disclosure are provided herein:


TABLE 1: 1000 bp regions of interest throughout the genome containing putative phased variants (PV) in various lymphoid neoplasms. Only regions containing >1 subject with a PV are shown. Coordinates are in hg19. Regions from genes that were previously identified as targets of activation-induced deaminase (AID) are labeled. Regions that contain PVs in >5% of subjects in any histology (BL, CLL, DLBCL, FL) are also labeled. BL, Burkitt lymphoma; CLL, chronic lymphocytic leukemia; DLBCL, diffuse large B-cell lymphoma; FL, follicular lymphoma.


TABLE 2: 1000 bp regions of interest throughout the genome containing putative phased variants (PV) in the ABC and GCB subtypes of DLBCL. Only regions containing >1 subject with a PV are shown. Coordinates are in hg19. Regions from genes that were previously identified as targets of AID are labeled. ABC, activated B-cell subtype; GCB, germinal center B-cell subtype.


TABLE 3: Regions used for the PhasED-Seq capture reagent described in this paper focused on lymphoid malignancies. Coordinates are in hg19. The closest gene and the reason for inclusion (Phased Variants vs general DLBCL genotyping) is also shown.


TABLE 4: Enrichment of PVs at genetic loci throughout the PhasED-Seq targeted sequencing panel for different types of B-cell lymphomas (DLBCL including ABC and GCB subtypes, PMBCL, and cHL). The PhasED-Seq selector was binned into 50 bp bins in hg19 coordinates, and each bin was labelled by gene or nearest gene. The mean of the fraction of cases of a given histology with a PV across all 50 bp bins is shown. Significance was determined by rank-sum (Mann-Whitney U) test of 50 bp bins for a given gene against the remainder of the sequencing panel. Uncorrected P-values are shown; multiple-hypothesis testing correction was performed by Bonferroni method. DLBCL, diffuse large B-cell lymphoma; PMBCL, primary mediastinal B-cell lymphoma; cHL, classical Hodgkin lymphoma; ABC, activated B-cell DLBCL; GCB, germinal center B-cell DLBCL.


TABLE 5: Sequences of oligonucleotides synthesized to assess hybridization and molecular recovery bias with increasing mutational burden (SEQ ID NOs. 1331-1358).


TABLE 6: Nucleic acid probes for Capture Sequencing of B-cell Cancers (SEQ ID NOs. 0001-1330).


While preferred embodiments of the present invention have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. It is not intended that the invention be limited by the specific examples provided within the specification. While the invention has been described with reference to the aforementioned specification, the descriptions and illustrations of the embodiments herein are not meant to be construed in a limiting sense. Numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the invention. Furthermore, it shall be understood that all aspects of the invention are not limited to the specific depictions, configurations or relative proportions set forth herein which depend upon a variety of conditions and variables. It should be understood that various alternatives to the embodiments of the invention described herein may be employed in practicing the invention. It is therefore contemplated that the invention shall also cover any such alternatives, modifications, variations or equivalents. It is intended that the following claims define the scope of the invention and that methods and structures within the scope of these claims and their equivalents be covered thereby.









TABLE 1







Fisher_p_DLBCL_vs Fisher_p_DLBCL v Fisher_p_DLBCL y





























Fisher_p_DLBCL_
Fisher_p_DLBCL_
Fisher_p_DLBCL_
Previously
overSPctInAny


#
Chromosome
Region Start
Region End
BL
CLL
DLBCL
FL
ClosestGene
vs_FL
vs_BL
vs_CLL
Identified
Histology























1
chr1
756000
757000
0.028
0.000
0.015
0.000
AL669831.1
0.47887
1.00000
0.29694
0
0


2
chr1
1963000
1964000
0.028
0.000
0.015
0.000
GABRD
0.47887
1.00000
0.29694
0
0


3
chr1
2052000
2053000
0.028
0.000
0.000
0.014
PRKCZ
1.00000
0.34615
1.00000
0
0


4
chr1
3789000
3790000
0.000
0.000
0.029
0.000
DFFB
0.22755
0.54294
0.08726
0
0


5
chr1
6613000
6614000
0.000
0.000
0.044
0.014
NOL9
0.34948
0.54966
0.02537
1
0


6
chr1
6614000
6615000
0.000
0.000
0.088
0.027
NOL9
0.15270
0.09031
0.00058
1
1


7
chr1
6661000
6662000
0.000
0.000
0.029
0.014
KLHL21
0.60686
0.54294
0.08726
0
0


8
chr1
6662000
6663000
0.000
0.000
0.044
0.014
KLHL21
0.34948
0.54966
0.02537
0
0


9
chr1
9129000
9130000
0.000
0.000
0.044
0.000
SLC2A5
0.10727
0.54966
0.02537
0
0


10
chr1
10894000
10895000
0.028
0.000
0.000
0.014
Clorf127
1.00000
0.34615
1.00000
0
0


11
chr1
17019000
17020000
0.028
0.000
0.000
0.014
AL137798.1
1.00000
0.34615
1.00000
0
0


12
chr1
17231000
17232000
0.000
0.000
0.015
0.014
CROCC
1.00000
1.00000
0.29694
0
0


13
chr1
19935000
19936000
0.000
0.000
0.029
0.000
MINOS1-NBL1
0.22755
0.54294
0.08726
0
0


14
chr1
21091000
21092000
0.000
0.000
0.015
0.014
HPIBP3
1.00000
1.00000
0.29694
0
0


15
chr1
23885000
23886000
0.444
0.000
0.015
0.000
ID3
0.47887
0.00000
0.29694
1
1


16
chr1
28408000
28409000
0.000
0.000
0.029
0.000
EYA3
0.22755
0.54294
0.08726
0
0


17
chr1
32373000
32374000
0.000
0.000
0.029
0.000
FTP4A2
0.22755
0.54294
0.08726
0
0


18
chr1
36722000
36723000
0.000
0.012
0.015
0.000
THRAP3
0.47887
1.00000
1.00000
0
0


19
chr1
46576000
46577000
0.000
0.000
0.015
0.014
PIK3R3
1.00000
1.00000
0.29694
0
0


20
chr1
51965000
51966000
0.000
0.006
0.015
0.000
EPS15
0.47887
1.00000
0.50663
0
0


21
chr1
51978000
51979000
0.000
0.000
0.029
0.000
EPS15
0.22755
0.54294
0.08726
0
0


22
chr1
51983000
51984000
0.000
0.006
0.029
0.000
EPS15
0.22755
0.54294
0.21104
0
0


23
chr1
72393000
72394000
0.000
0.000
0.015
0.014
NEGR1
1.00000
1.00000
0.29694
0
0


24
chr1
73719000
73720000
0.000
0.000
0.029
0.000
LRRIQ3
0.22755
0.54294
0.08726
0
0


25
chr1
77315000
77316000
0.028
0.006
0.000
0.000
ST6GALNAC5
1.00000
0.34615
1.00000
0
0


26
chr1
81306000
81307000
0.000
0.000
0.015
0.014
LPHN2
1.00000
1.00000
0.29694
0
0


27
chr1
81527000
81528000
0.000
0.000
0.029
0.000
LPHN2
0.22755
0.54294
0.08726
0
0


28
chr1
S2009000
82010000
0.028
0.000
0.015
0.000
LPHN2
0.47887
1.00000
0.29694
0
0


29
chr1
84106000
84107000
0.000
0.006
0.015
0.000
TTLL7
0.47887
1.00000
0.50663
0
0


30
chr1
87524000
87525000
0.000
0.006
0.015
0.000
HS2ST1;
0.47887
1.00000
0.50663
0
0










HS2ST1LOC339524;







31
chr1
94551000
94552000
0.000
0.000
0.029
0.000
ABCA4
0.22755
0.54294
0.08726
0
0


32
chr1
94552000
94553000
0.000
0.000
0.029
0.000
ABCA4
0.22755
0.54294
0.08726
0
0


33
chr1
103696000
103697000
0.000
0.000
0.000
0.027
COL11A1
0.49735
1.00000
1.00000
0
0


34
chr1
116979000
116980000
0.000
0.000
0.044
0.041
ATP1A1
1.00000
0.54966
0.02537
0
0


35
chr1
149784000
149785000
0.000
0.000
0.015
0.014
HIST2H3D
1.00000
1.00000
0.29694
1
0


36
chr1
149821000
149822000
0.000
0.000
0.044
0.000
HIST2H2AA4
0.10727
0.54966
0.02537
1
0


37
chr1
149857000
149858000
0.000
0.000
0.015
0.014
HIST2H2BE
1.00000
1.00000
0.29694
1
0


38
chr1
149858000
149859000
0.000
0.000
0.059
0.000
HIST2H2AC;
0.05016
0.29551
0.00730
0
1










HIST2H2BE;







39
chr1
160616000
160617000
0.000
0.000
0.015
0.014
SLAMF1
1.00000
1.00000
0.29694
0
0


40
chr1
162711000
162712000
0.000
0.000
0.015
0.014
DDR2
1.00000
1.00000
0.29694
0
0


41
chr1
163684000
163685000
0.000
0.000
0.015
0.014
NUF2
1.00000
1.00000
0.29694
0
0


42
chr1
167598000
167599000
0.000
0.000
0.044
0.014
RCSD1
0.34948
0.54966
0.02537
0
0


43
chr1
167599000
167600000
0.000
0.000
0.029
0.014
RCSD1
0.60686
0.54294
0.08726
0
0


44
chr1
167600000
167601000
0.000
0.000
0.044
0.000
RCSD1
0.10727
0.54966
0.02537
0
0


45
chr1
174333000
174334000
0.000
0.000
0.015
0.014
RABGAP1L
1.00000
1.00000
0.29694
0
0


46
chr1
187263000
187264000
0.000
0.000
0.044
0.000
PLA2G4A
0.10727
0.54966
0.02537
0
0


47
chr1
187283000
187284000
0.000
0.000
0.029
0.000
PLA2G4A
0.22755
0.54294
0.08726
0
0


48
chr1
187892000
187893000
0.028
0.000
0.015
0.000
PLA2G4A
0.47887
1.00000
0.29694
0
0


49
chr1
195282000
195283000
0.000
0.000
0.015
0.014
KCNT2
1.00000
1.00000
0.29694
0
0


50
chr1
198591000
198592000
0.000
0.000
0.029
0.000
PTPRC
0.22755
0.54294
0.08726
0
0


51
chr1
198608000
198609000
0.000
0.000
0.029
0.000
PTPRC
0.22755
0.54294
0.08726
0
0


52
chr1
198609000
198610000
0.000
0.000
0.029
0.000
PTPRC
0.22755
0.54294
0.08726
0
0


53
chr1
202004000
202005000
0.028
0.000
0.029
0.000
ELF3
0.22755
1.00000
0.08726
0
0


54
chr1
203273000
203274000
0.000
0.000
0.029
0.000
BTG2
0.22755
0.54294
0.08726
1
0


55
chr1
203274000
203275000
0.000
0.000
0.176
0.014
BTG2
0.00078
0.00730
0.00000
1
1


56
chr1
203275000
203276000
0.028
0.006
0.471
0.081
BTG2
0.00000
0.00000
0.00000
1
1


57
chr1
203276000
203277000
0.028
0.000
0.059
0.000
BTG2
0.05016
0.65667
0.00730
1
1


58
chr1
205780000
205781000
0.000
0.000
0.000
0.027
SLC41A1
0.49735
1.00000
1.00000
0
0


59
chr1
205781000
205782000
0.000
0.000
0.000
0.027
SLC41A1
0.49735
1.00000
1.00000
0
0


60
chr1
206283000
206284000
0.000
0.000
0.015
0.014
CTSE
1.00000
1.00000
0.29694
0
0


61
chr1
206286000
206287000
0.000
0.000
0.029
0.014
CTSE
0.60686
0.54294
0.08726
0
0


62
chr1
217044000
217045000
0.000
0.000
0.029
0.000
ESRRG
0.22755
0.54294
0.08726
0
0


63
chr1
226924000
226925000
0.000
0.000
0.029
0.000
ITPKB
0.22755
0.54294
0.08726
1
0


64
chr1
226925000
226926000
0.000
0.000
0.044
0.000
ITPKB
0.10727
0.54966
0.02537
1
0


65
chr1
226926000
226927000
0.000
0.000
0.029
0.000
ITPKB
0.22755
0.54294
0.08726
1
0


66
chr1
229974000
229975000
0.028
0.000
0.015
0.027
URB2
1.00000
1.00000
0.29694
0
0


67
chr1
235131000
235132000
0.000
0.000
0.000
0.027
TOMM20
0.49735
1.00000
1.00000
0
0


68
chr1
235141000
235142000
0.000
0.000
0.015
0.014
TOMM20
1.00000
1.00000
0.29694
0
0


69
chr1
238787000
238788000
0.000
0.000
0.029
0.000
MTRNR2L11
0.22755
0.54294
0.08726
0
0


70
chr1
248088000
248089000
0.028
0.000
0.015
0.000
OR2TS
0.47887
1.00000
0.29694
0
0


71
chr2
630000
631000
0.000
0.000
0.000
0.027
TMEM18
0.49735
1.00000
1.00000
0
0


72
chr2
1484000
1485000
0.000
0.000
0.000
0.027
TPO
0.49735
1.00000
1.00000
0
0


73
chr2
7991000
7992000
0.056
0.000
0.000
0.000
RNF144A
1.00000
0.11763
1.00000
0
1


74
chr2
12173000
12174000
0.000
0.000
0.044
0.000
LPIN1
0.10727
0.54966
0.02537
0
0


75
chr2
12175000
12176000
0.000
0.000
0.029
0.000
LPIN1
0.22755
0.54294
0.08726
0
0


76
chr2
12249000
12250000
0.000
0.000
0.029
0.000
LPIN1
0.22755
0.54294
0.08726
0
0


77
chr2
14113000
14114000
0.000
0.000
0.000
0.027
FAM84A
0.49735
1.00000
1.00000
0
0


78
chr2
17577000
17578000
0.000
0.000
0.015
0.014
RAD51AP2
1.00000
1.00000
0.29694
0
0


79
chr2
19253000
19254000
0.000
0.000
0.029
0.000
OSR1
0.22755
0.54294
0.08726
0
0


80
chr2
24802000
24803000
0.000
0.000
0.029
0.000
NCOA1
0.22755
0.54294
0.08726
0
0


81
chr2
31478000
31479000
0.000
0.000
0.015
0.014
EHD3
1.00000
1.00000
0.29694
0
0


82
chr2
41728000
41729000
0.000
0.000
0.015
0.014
C2orf91
1.00000
1.00000
0.29694
0
0


83
chr2
45404000
45405000
0.000
0.000
0.000
0.027
SIX2
0.49735
1.00000
1.00000
0
0


84
chr2
47923000
47924000
0.000
0.000
0.015
0.014
MSH6
1.00000
1.00000
0.29694
0
0


00
chr2
47944000
47945000
0.000
0.000
0.029
0.000
MSH6
0.22755
0.54294
0.08726
0
0


86
chr2
51360000
51361000
0.000
0.000
0.015
0.014
NRXN1
1.00000
1.00000
0.29694
0
0


87
chr2
51655000
51656000
0.000
0.000
0.000
0.027
NRXN1
0.49735
1.00000
1.00000
0
0


88
chr2
56565000
56566000
0.000
0.000
0.029
0.000
CCDC85A
0.22755
0.54294
0.08726
0
0


89
chr2
57800000
57801000
0.000
0.000
0.015
0.014
VRK2
1.00000
1.00000
0.29694
0
0


90
chr2
60779000
60780000
0.000
0.000
0.029
0.027
BCL11A
1.00000
0.54294
0.08726
0
0


91
chr2
60780000
60781000
0.000
0.000
0.029
0.000
BCL11A
0.22755
0.54294
0.08726
0
0


92
chr2
63802000
63803000
0.000
0.000
0.000
0.027
WDPCP
0.49735
1.00000
1.00000
0
0


93
chr2
63827000
63828000
0.000
0.000
0.015
0.014
MDH1
1.00000
1.00000
0.29694
0
0


94
chr2
64319000
64320000
0.000
0.000
0.044
0.000
PELI1
0.10727
0.54966
0.02537
0
0


95
chr2
65593000
65594000
0.000
0.000
0.044
0.054
SPRED2
1.00000
0.54966
0.02537
1
1


96
chr2
67002000
67003000
0.028
0.000
0.029
0.000
MEIS1
0.22755
1.00000
0.08726
0
0


97
chr2
70315000
70316000
0.083
0.000
0.000
0.000
PCBP1
1.00000
0.03921
1.00000
0
1


98
chr2
79502000
79503000
0.028
0.000
0.015
0.000
REG3A
0.47887
1.00000
0.29694
0
0


99
chr2
79644000
79645000
0.000
0.000
0.000
0.027
CTNNA2
0.49735
1.00000
1.00000
0
0


100
chr2
81818000
81819000
0.000
0.000
0.000
0.027
CTNNA2
0.49735
1.00000
1.00000
0
0


101
chr2
82310000
82311000
0.028
0.000
0.015
0.000
CTNNA2
0.47887
1.00000
0.29694
0
0


102
chr2
82948000
82949000
0.000
0.000
0.029
0.000
SUCLG1
0.22755
0.54294
0.08726
0
0


103
chr2
85335000
85336000
0.000
0.000
0.000
0.027
TCF7L1
0.49735
1.00000
1.00000
0
0


104
chr2
83905000
88906000
0.000
0.000
0.059
0.000
EIF2AK3
0.05016
0.29551
0.00730
0
1


105
chr2
88906000
88907000
0.000
0.006
0.074
0.014
EIF2AK3
0.10420
0.16101
0.00953
0
1


106
churz
88907000
88908000
0.000
0.000
0.059
0.000
EIF2AK3
0.05016
0.29551
0.00730
0
1


107
chr2
89052000
89053000
0.000
0.006
0.015
0.000
RPIA
0.47887
1.00000
0.50663
0
0


108
ch?2
89065000
89066000
0.000
0.000
0.015
0.027
RPIA
1.00000
1.00000
0.29694
0
0


109
chr2
89066000
89067000
0.000
0.000
0.015
0.014
RPIA
1.00000
1.00000
0.29694
0
0


110
chr2
89095000
89096000
0.000
0.000
0.015
0.014
RPIA
1.00000
1.00000
0.29694
0
0


111
chr2
89127000
89128000
0.000
0.006
0.147
0.041
IGKC
0.03985
0.01404
0.00003
0
1


112
chr2
89128000
89129000
0.028
0.006
0.176
0.041
IGKC
0.01224
0.03142
0.00000
0
1


113
chr2
89129000
89130000
0.000
0.000
0.044
0.041
IGKC
1.00000
0.54966
0.02537
0
0


114
clu2
89130000
89131000
0.000
0.000
0.044
0.000
IGKC
0.10727
0.54966
0.02537
0
0


115
chr2
89131000
89132000
0.000
0.000
0.029
0.000
IGKC
0.22755
0.54294
0.08726
0
0


116
chr2
89132000
89133000
0.000
0.006
0.015
0.014
IGKC
1.00000
1.00000
0.50663
0
0


117
chr2
89133000
89134000
0.000
0.000
0.029
0.041
IGKC
1.00000
0.54294
0.08726
0
0


118
chr2
89137000
89138000
0.000
0.000
0.044
0.014
IGKC
0.34948
0.54966
0.02537
0
0


119
chr2
89138000
89139000
0.000
0.000
0.015
0.014
IGKC
1.00000
1.00000
0.29694
0
0


120
chr2
89139000
89140000
0.000
0.000
0.044
0.014
IGKC
0.34948
0.54966
0.02537
0
0


121
chr2
89140000
89141000
0.000
0.000
0.088
0.054
IGKC
0.52007
0.09031
0.00058
0
1


122
clu2
89141000
89142000
0.000
0.006
0.103
0.027
IGKC
0.08710
0.09269
0.00099
0
1


123
chr2
89142000
89143000
0.000
0.000
0.088
0.000
IGKC
0.01070
0.09031
0.00058
0
1


124
chr2
89143000
89144000
0.000
0.000
0.029
0.000
IGKC
0.22755
0.54294
0.08726
0
0


125
chr2
89144000
89145000
0.000
0.000
0.015
0.014
IGKC
1.00000
1.00000
0.29694
0
0


126
chr2
89145000
89146000
0.000
0.000
0.029
0.014
IGKC
0.60686
0.54294
0.08726
0
0


127
chr2
89146000
89147000
0.000
0.000
0.029
0.014
IGKC
0.60686
0.54294
0.08726
0
0


128
chr2
89153000
89154000
0.000
0.000
0.029
0.000
IGKC
0.22755
0.54294
0.08726
0
0


129
chr2
89155000
89156000
0.000
0.000
0.059
0.014
IGKC
0.19371
0.29551
0.00730
0
1


130
chr2
89156000
89157000
0.000
0.000
0.103
0.014
IGKC
0.02808
0.09269
0.00016
0
1


131
chr2
89157000
89158000
0.000
0.000
0.250
0.149
IGKC
0.14439
0.00048
0.00000
0
1


132
chr2
89158000
89159000
0.028
0.019
0.426
0.270
IGKC
0.05462
0.00001
0.00000
0
1


133
chr2
89159000
89160000
0.222
0.180
0.574
0.473
IGKJ5
0.24418
0.00083
0.00000
0
1


134
chr2
89160000
89161000
0.444
0.242
0.500
0.608
IGKJ3; IGKJ4;
0.23729
0.68125
0.00019
0
1










IGKJ5;







135
chr2
89161000
89162000
0.222
0.081
0.265
0.405
IGKJ1; IGKJ2;
0.10957
0.81234
0.00049
0
1


136
chr2
89162000
89163000
0.056
0.012
0.221
0.108
IGKJI
0.10913
0.04835
0.00000
0
1


137
chr2
89163000
89164000
0.000
0.068
0.235
0.176
IGKJI
0.41068
0.00098
0.00117
0
1


138
chrz
89164000
89165000
0.028
0.137
0.294
0.216
IGKJI
0.33637
0.00075
0.00821
0
1


139
chr2
89165000
89166000
0.083
0.143
0.279
0.216
IGKJI
0.43812
0.02316
0.02379
0
1


140
ch?2
89166000
89167000
0.028
0.012
0.044
0.027
IGKJI
0.67043
1.00000
0.15671
0
0


141
chr2
89169000
89170000
0.000
0.000
0.015
0.014
IGKJI
1.00000
1.00000
0.29694
0
0


142
chr2
89184000
89185000
0.000
0.006
0.015
0.054
IGKV4-1
0.36833
1.00000
0.50663
0
1


143
chr2
89185000
89186000
0.028
0.056
0.162
0.135
IGKV4-1
0.81354
0.05349
0.01836
0
1


144
chr2
89196000
89197000
0.000
0.000
0.059
0.014
IGKV5-2
0.19371
0.29551
0.00730
0
1


145
chr2
89197000
89198000
0.000
0.000
0.000
0.027
IGKV5-2
0.49735
1.00000
1.00000
0
0


146
cluz
89214000
89215000
0.000
0.012
0.000
0.000
IGKV5-2
1.00000
1.00000
1.00000
0
0


147
chr2
89246000
89247000
0.000
0.031
0.029
0.027
IGKV1-5
1.00000
0.54294
1.00000
0
0


148
chr2
89247000
89248000
0.028
0.019
0.118
0.054
IGKV1-5
0.23086
0.15803
0.00321
0
1


149
chr2
89248000
89249000
0.028
0.000
0.044
0.000
IGKV1-5
0.10727
1.00000
0.02537
0
0


150
chr2
89266000
89267000
0.000
0.000
0.015
0.014
IGKV1-6
1.00000
1.00000
0.29694
0
0


151
chr2
89291000
89292000
0.000
0.019
0.029
0.000
IGKV1-8
0.22755
0.54294
0.63492
0
0


152
chr2
89292000
89293000
0.000
0.025
0.044
0.000
IGKV1-8
0.10727
0.54966
0.42650
0
0


153
chr2
89326000
89327000
0.000
0.019
0.000
0.041
IGKV3-11
0.24603
1.00000
0.55662
0
0


154
chr2
89327000
89328000
0.000
0.012
0.015
0.027
IGKV3-11
1.00000
1.00000
1.00000
0
0


155
chr2
89442000
89443000
0.111
0.050
0.074
0.122
IGKV3-20
0.40586
0.71556
0.53493
0
1


156
chr2
89443000
89444000
0.000
0.000
0.015
0.041
IGKV3-20
0.62100
1.00000
0.29694
0
0


157
chr2
89476000
89477000
0.028
0.000
0.000
0.014
IGKV2-24
1.00000
0.34615
1.00000
0
0


158
chr2
89513000
89514000
0.000
0.000
0.029
0.000
IGKV1-27
0.22755
0.54294
0.08726
0
0


159
chr2
89521000
89522000
0.028
0.000
0.015
0.014
IGKV2-28
1.00000
1.00000
0.29694
0
0


160
chr2
89533000
89534000
0.028
0.000
0.044
0.014
IGKV2-30
0.34948
1.00000
0.02537
0
0


161
chr2
89534000
89535000
0.000
0.000
0.029
0.014
IGKV2-30
0.60686
0.54294
0.08726
0
0


162
chr2
89544000
89545000
0.028
0.012
0.059
0.014
IGKV2-30
0.19371
0.65667
0.06548
0
1


163
chr2
89545000
89546000
0.000
0.006
0.029
0.000
IGKV2-30
0.22755
0.54294
0.21104
0
0


164
chr2
90259000
90260000
0.000
0.000
0.015
0.014
IGKV1D-8
1.00000
1.00000
0.29694
0
0


165
chr2
90260000
90261000
0.000
0.000
0.059
0.014
IGKV1D-8
0.19371
0.29551
0.00730
0
1


166
chr2
96809000
96810000
0.000
0.000
0.044
0.000
DUSP2
0.10727
0.54966
0.02537
1
0


167
chr2
96810000
96811000
0.000
0.000
0.044
0.014
DUSP2
0.34948
0.54966
0.02537
1
0


168
chr2
96811000
96812000
0.000
0.000
0.029
0.000
DUSP2
0.22755
0.54294
0.08726
1
0


169
chr2
98611000
98612000
0.000
0.000
0.015
0.014
TMEM131
1.00000
1.00000
0.29694
0
0


170
chr2
100757000
100758000
0.000
0.000
0.029
0.027
AFF3
1.00000
0.54294
0.08726
0
0


171
chr2
100758000
100759000
0.000
0.000
0.044
0.014
AFF3
0.34948
0.54966
0.02537
0
0


172
chr2
106144000
106145000
0.000
0.000
0.029
0.000
FHL2
0.22755
0.54294
0.08726
0
0


173
chr2
111878000
111879000
0.000
0.000
0.029
0.014
BCL2L11
0.60686
0.54294
0.08726
0
0


174
chr2
111879000
111880000
0.000
0.000
0.044
0.014
BCL2L11
0.34948
0.54966
0.02537
0
0


175
chr2
112305000
112306000
0.000
0.000
0.015
0.014
ANAPC1
1.00000
1.00000
0.29694
0
0


176
chr2
116234000
116235000
0.000
0.000
0.015
0.014
DPP10
1.00000
1.00000
0.29694
0
0


177
chr2
116439000
116440000
0.028
0.000
0.000
0.014
DPP10
1.00000
0.34615
1.00000
0
0


178
chr2
124697000
124698000
0.028
0.000
0.015
0.000
CNTNAP5
0.47887
1.00000
0.29694
0
0


179
chr2
125235000
125236000
0.000
0.000
0.029
0.000
CNTNAP5
0.22755
0.54294
0.08726
0
0


180
chr2
127538000
127539000
0.028
0.000
0.015
0.000
GYPC
0.47887
1.00000
0.29694
0
0


181
chr2
136874000
136875000
0.000
0.000
0.191
0.014
CXCR4
0.00036
0.00372
0.00000
1
1


182
chr2
136875000
136876000
0.083
0.019
0.265
0.081
CXCR4
0.00626
0.03882
0.00000
1
1


183
chr2
136996000
136997000
0.000
0.000
0.029
0.000
CXCR4
0.22755
0.54294
0.08726
1
0


184
chr2
137082000
137083000
0.000
0.000
0.015
0.014
CXCR4
1.00000
1.00000
0.29694
1
0


185
chr2
140951000
140952000
0.000
0.000
0.029
0.000
LRP1B
0.22755
0.54294
0.08726
0
0


186
chr2
141335000
141336000
0.000
0.000
0.015
0.014
LRP1B
1.00000
1.00000
0.29694
0
0


187
chr2
141770000
141771000
0.000
0.000
0.029
0.000
LRP1B
0.22755
0.54294
0.08726
0
0


188
chr2
146445000
146446000
0.000
0.000
0.029
0.000
ZEB2
0.22755
0.54294
0.08726
0
0


189
chr2
146446000
146447000
0.000
0.000
0.029
0.014
ZEB2
0.60686
0.54294
0.08726
0
0


190
chr2
156443000
156444000
0.000
0.000
0.029
0.000
KCNJ3
0.22755
0.54294
0.08726
0
0


191
chr2
172590000
172591000
0.000
0.000
0.029
0.000
DYNC1I2
0.22755
0.54294
0.08726
0
0


192
chr2
176581000
176582000
0.028
0.000
0.000
0.014
KIAA1715
1.00000
0.34615
1.00000
0
0


193
chr2
179880000
179881000
0.000
0.000
0.015
0.014
CCDC141
1.00000
1.00000
0.29694
0
0


194
chr2
180358000
180359000
0.000
0.000
0.029
0.000
ZNF385B
0.22755
0.54294
0.08726
0
0


195
chr2
189285000
189286000
0.000
0.000
0.015
0.014
GULP1
1.00000
1.00000
0.29694
0
0


196
chr2
189432000
189433000
0.028
0.000
0.000
0.014
GULP1
1.00000
0.34615
1.00000
0
0


197
chr2
194115000
194116000
0.000
0.000
0.015
0.014
TMEFF2
1.00000
1.00000
0.29694
0
0


198
chr2
197035000
197036000
0.000
0.000
0.044
0.014
STK17B
0.34948
0.54966
0.02537
0
0


199
chr2
197041000
197042000
0.000
0.000
0.029
0.000
STK17B
0.22755
0.54294
0.08726
0
0


200
chr2
215999000
216000000
0.000
0.006
0.015
0.000
ABCA12
0.47887
1.00000
0.50663
0
0


201
chr2
216973000
216974000
0.028
0.000
0.000
0.014
XRCC5
1.00000
0.34615
1.00000
0
0


202
chr2
217247000
217248000
0.028
0.000
0.000
0.014
4-Mar-19
1.00000
0.34615
1.00000
0
0


203
chr2
225386000
225387000
0.000
0.000
0.029
0.000
CUL3
0.22755
0.54294
0.08726
0
0


204
chr2
225524000
225525000
0.000
0.000
0.029
0.000
CUL3
0.22755
0.54294
0.08726
0
0


205
chr2
233478000
233479000
0.028
0.000
0.015
0.000
EFHD1
0.47887
1.00000
0.29694
0
0


206
chr2
233980000
233981000
0.028
0.000
0.029
0.000
INPP5D
0.22755
1.00000
0.08726
0
0


207
chr2
240641000
240642000
0.028
0.000
0.000
0.027
AC093802.1
0.49735
0.34615
1.00000
0
0


208
chr2
241125000
241126000
0.000
0.000
0.000
0.027
OTOS
0.49735
1.00000
1.00000
0
0


209
chr3
8739000
8740000
0.000
0.000
0.000
0.027
CAV3
0.49735
1.00000
1.00000
0
0


210
chr3
16407000
16408000
0.000
0.000
0.000
0.027
RFTN1
0.49735
1.00000
1.00000
1
0


211
chr3
16409000
16410000
0.028
0.000
0.000
0.041
RFTN1
0.24603
0.34615
1.00000
1
0


212
chr3
16419000
16420000
0.000
0.006
0.044
0.000
RFTN1
0.10727
0.54966
0.07959
1
0


213
chr3
16472000
16473000
0.000
0.000
0.015
0.014
RFTN1
1.00000
1.00000
0.29694
1
0


214
chr3
16495000
16496000
0.000
0.000
0.029
0.000
RFTN1
0.22755
0.54294
0.08726
1
0


215
chr3
16552000
16553000
0.000
0.012
0.029
0.014
RFTN1
0.60686
0.54294
0.58408
1
0


216
chr3
16554000
16555000
0.000
0.000
0.103
0.027
RFTN1
0.08710
0.09269
0.00016
1
1


217
chr3
16555000
16556000
0.000
0.000
0.029
0.000
RFTN1
0.22755
0.54294
0.08726
1
0


218
chr3
21658000
21659000
0.000
0.000
0.029
0.000
ZNF385D
0.22755
0.54294
0.08726
0
0


219
chr3
25691000
25692000
0.000
0.000
0.029
0.000
TOP2B
0.22755
0.54294
0.08726
0
0


220
chr3
31969000
31970000
0.000
0.000
0.029
0.000
OSBPL10
0.22755
0.54294
0.08726
1
0


221
chr3
31993000
31994000
0.000
0.000
0.044
0.000
OSBPL10
0.10727
0.54966
0.02537
1
0


222
chr3
32001000
32002000
0.000
0.000
0.044
0.000
OSBPL10
0.10727
0.54966
0.02537
1
0


223
chr3
32022000
32023000
0.000
0.000
0.088
0.014
OSBPL10
0.05468
0.09031
0.00058
1
1


224
chr3
32023000
32024000
0.000
0.000
0.029
0.000
OSBPL10
0.22755
0.54294
0.08726
1
0


225
chr3
50128000
50129000
0.000
0.000
0.029
0.000
RBM5
0.22755
0.54294
0.08726
0
0


226
chr3
54913000
54914000
0.000
0.006
0.015
0.000
CACNA2D3
0.47887
1.00000
0.50663
0
0


227
chr3
56074000
56075000
0.028
0.000
0.000
0.014
ERC2
1.00000
0.34615
1.00000
0
0


228
chr3
59577000
59578000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


229
chr3
60351000
60352000
0.000
0.000
0.044
0.000
FHIT
0.10727
0.54966
0.02537
0
0


230
chr3
60356000
60357000
0.028
0.000
0.000
0.014
FHIT
1.00000
0.34615
1.00000
0
0


231
chr3
60357000
60358000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


232
chr3
60358000
60359000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


233
chr3
60359000
60360000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


234
chr3
60389000
60390000
0.000
0.000
0.015
0.027
FHIT
1.00000
1.00000
0.29694
0
0


235
chr3
60392000
60393000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


236
chr3
60395000
60396000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


237
chr3
60404000
60405000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


238
chr3
60436000
60437000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


239
chr3
60437000
60438000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


240
chr3
60477000
60478000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


241
chr3
60485000
60486000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


242
chr3
60515000
60516000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


243
chr3
60535000
60536000
0.000
0.006
0.015
0.000
FHIT
0.47887
1.00000
0.50663
0
0


244
chr3
60602000
60603000
0.000
0.000
0.029
0.014
FHIT
0.60686
0.54294
0.08726
0
0


245
chr3
60613000
60614000
0.000
0.000
0.029
0.014
FHIT
0.60686
0.54294
0.08726
0
0


246
chr3
60614000
60615000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


247
chr3
60632000
60633000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


248
chr3
60635000
60636000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


249
chr3
60640000
60641000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


250
chr3
60647000
60648000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


251
chr3
60648000
60649000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


252
chr3
60652000
60653000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


253
chr3
60660000
60661000
0.000
0.000
0.029
0.014
FHIT
0.60686
0.54294
0.08726
0
0


254
chr3
60665000
60666000
0.000
0.000
0.015
0.027
FHIT
1.00000
1.00000
0.29694
0
0


255
chr3
60666000
60667000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


256
chr3
60671000
60672000
0.000
0.000
0.000
0.041
FHIT
0.24603
1.00000
1.00000
0
0


257
chr3
60673000
60674000
0.000
0.000
0.044
0.000
FHIT
0.10727
0.54966
0.02537
0
0


258
chr3
60675000
60676000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


259
chr3
60678000
60679000
0.000
0.000
0.044
0.000
FHIT
0.10727
0.54966
0.02537
0
0


260
chr3
60683000
60684000
0.000
0.000
0.015
0.027
FHIT
1.00000
1.00000
0.29694
0
0


261
chr3
60684000
60685000
0.000
0.000
0.015
0.041
FHIT
0.62100
1.00000
0.29694
0
0


262
chr3
60688000
60689000
0.000
0.000
0.015
0.014
FHIT
1.00000
1.00000
0.29694
0
0


263
chr3
60717000
60718000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


264
chr3
60740000
60741000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


265
chr3
60774000
60775000
0.000
0.000
0.029
0.000
FHIT
0.22755
0.54294
0.08726
0
0


266
chr3
60792000
60793000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


267
chr3
60806000
60807000
0.028
0.000
0.000
0.014
FHIT
1.00000
0.34615
1.00000
0
0


268
chr3
60812000
60813000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


269
chr3
60860000
60861000
0.000
0.000
0.000
0.027
FHIT
0.49735
1.00000
1.00000
0
0


270
chr3
71551000
71552000
0.000
0.000
0.000
0.027
EIF4E3
0.49735
1.00000
1.00000
0
0


271
chr3
78274000
78275000
0.000
0.000
0.015
0.014
ROBO1
1.00000
1.00000
0.29694
0
0


272
chr3
80273000
80274000
0.000
0.006
0.015
0.000
ROBO1
0.47887
1.00000
0.50663
0
0


273
chr3
83094000
83095000
0.028
0.000
0.015
0.000
GBE1
0.47887
1.00000
0.29694
0
0


274
chr3
83924000
83925000
0.028
0.000
0.000
0.014
CADM2
1.00000
0.34615
1.00000
0
0


275
chr3
84293000
84294000
0.000
0.000
0.015
0.014
CADM2
1.00000
1.00000
0.29694
0
0


276
chr3
85260000
85261000
0.000
0.000
0.044
0.000
CADM2
0.10727
0.54966
0.02537
0
0


277
chr3
85261000
85262000
0.000
0.000
0.029
0.000
CADM2
0.22755
0.54294
0.08726
0
0


278
chr3
85799000
85800000
0.000
0.000
0.029
0.000
CADM2
0.22755
0.54294
0.08726
0
0


279
chr3
86226000
86227000
0.000
0.000
0.029
0.000
CADM2
0.22755
0.54294
0.08726
0
0


280
chr3
88146000
88147000
0.000
0.000
0.029
0.000
CGGBP1
0.22755
0.54294
0.08726
0
0


281
chr3
94709000
94710000
0.000
0.000
0.029
0.000
NSUN3
0.22755
0.54294
0.08726
0
0


282
chr3
95460000
95461000
0.028
0.000
0.015
0.000
MTRNR2L12
0.47887
1.00000
0.29694
0
0


283
chr3
95724000
95725000
0.000
0.000
0.029
0.000
MTRNR2L12
0.22755
0.54294
0.08726
0
0


284
chr3
101569000
101570000
0.028
0.000
0.015
0.000
NFKRIZ
0.47887
1.00000
0.29694
0
0


285
chr3
111851000
111852000
0.000
0.000
0.044
0.000
GCSAM
0.10727
0.54966
0.02537
0
0


286
chr3
111852000
111853000
0.000
0.000
0.059
0.000
GCSAM
0.05016
0.29551
0.00730
0
1


287
chr3
122377000
122378000
0.028
0.000
0.044
0.000
PARP14
0.10727
1.00000
0.02537
0
0


288
chr3
150478000
150479000
0.000
0.000
0.029
0.000
SIAH2
0.22755
0.54294
0.08726
0
0


289
chr3
150479000
150480000
0.000
0.000
0.029
0.000
SIAH2
0.22755
0.54294
0.08726
0
0


290
chr3
150480000
150481000
0.000
0.000
0.015
0.014
SIAH2
1.00000
1.00000
0.29694
0
0


291
chr3
163237000
163238000
0.000
0.000
0.000
0.027
SI
0.49735
1.00000
1.00000
0
0


292
chr3
163238000
163239000
0.000
0.000
0.029
0.000
SI
0.22755
0.54294
0.08726
0
0


293
chr3
163615000
163616000
0.000
0.000
0.029
0.000
SI
0.22755
0.54294
0.08726
0
0


294
chr3
183270000
183271000
0.000
0.000
0.029
0.000
KLHL6
0.22755
0.54294
0.08726
0
0


295
chr3
183271000
183272000
0.000
0.000
0.029
0.014
KLHL6
0.60686
0.54294
0.08726
0
0


296
chr3
183272000
183273000
0.000
0.000
0.029
0.014
KLHL6
0.60686
0.54294
0.08726
0
0


297
chr3
183273000
183274000
0.000
0.019
0.044
0.027
KLHL6
0.67043
0.54966
0.36534
0
0


298
chr3
186648000
186649000
0.000
0.000
0.044
0.014
ADIPOQ
0.34948
0.54966
0.02537
0
0


299
clu3
186714000
186715000
0.000
0.006
0.132
0.027
ST6GAL1
0.02624
0.02564
0.00009
1
1


300
chr3
186715000
186716000
0.000
0.000
0.044
0.014
ST6GAL1
0.34948
0.54966
0.02537
1
0


301
chr3
186739000
186740000
0.000
0.006
0.074
0.014
ST6GAL1
0.10420
0.16101
0.00953
1
1


302
chr3
186740000
186741000
0.056
0.006
0.074
0.027
ST6GAL1
0.25970
1.00000
0.00953
1
1


303
chr3
186742000
186743000
0.000
0.000
0.029
0.000
ST6GAL1
0.22755
0.54294
0.08726
1
0


304
chr3
186783000
186784000
0.000
0.050
0.338
0.041
ST6GAL1
0.00001
0.00001
0.00000
1
1


305
chr3
186784000
186785000
0.000
0.025
0.044
0.000
ST6GAL1
0.10727
0.54966
0.42650
1
0


306
chr3
187458000
187459000
0.000
0.000
0.029
0.000
BCL6
0.22755
0.54294
0.08726
1
0


307
chr3
187459000
187460000
0.000
0.000
0.029
0.000
BCL6
0.22755
0.54294
0.08726
1
0


308
chr3
187460000
187461000
0.000
0.000
0.088
0.041
BCL6
0.31126
0.09031
0.00058
1
1


309
chr3
187461000
187462000
0.000
0.006
0.353
0.122
BCL6
0.00137
0.00001
0.00000
1
1


310
chr3
187462000
187463000
0.056
0.081
0.647
0.392
BCL6
0.00266
0.00000
0.00000
1
1


311
chr3
187463000
187464000
0.000
0.037
0.485
0.230
BCL6
0.00164
0.00000
0.00000
1
1


312
chr3
187464000
187465000
0.028
0.000
0.162
0.000
BCL6
0.00019
0.05349
0.00000
1
1


313
chr3
187468000
187469000
0.000
0.000
0.044
0.000
BCL6
0.10727
0.54966
0.02537
1
0


314
chr3
187635000
187636000
0.000
0.000
0.029
0.000
BCL6
0.22755
0.54294
0.08726
1
0


315
chr3
187636000
187637000
0.000
0.000
0.000
0.027
BCL6
0.49735
1.00000
1.00000
1
0


316
chr3
187653000
187654000
0.000
0.000
0.044
0.014
BCL6
0.34948
0.54966
0.02537
1
0


317
chr3
187658000
187659000
0.000
0.000
0.029
0.000
BCL6
0.22755
0.54294
0.08726
1
0


318
chr3
187660000
187661000
0.000
0.019
0.118
0.054
BCL6
0.23086
0.04825
0.00321
1
1


319
chr3
187661000
187662000
0.000
0.012
0.191
0.081
BCL6
0.08249
0.00372
0.00000
1
1


320
chr3
187664000
187665000
0.000
0.000
0.044
0.000
BCL6
0.10727
0.54966
0.02537
1
0


321
chr3
187686000
187687000
0.028
0.000
0.029
0.014
AC022498.1
0.60686
1.00000
0.08726
0
0


322
chr3
187687000
187688000
0.000
0.006
0.000
0.014
AC022498.1
1.00000
1.00000
1.00000
0
0


323
chr3
187693000
187694000
0.000
0.000
0.015
0.014
AC022498.1
1.00000
1.00000
0.29694
0
0


324
chr3
187696000
187697000
0.000
0.006
0.059
0.000
AC022498.1
0.05016
0.29551
0.02818
0
1


325
chr3
187697000
187698000
0.000
0.000
0.044
0.000
AC022498.1
0.10727
0.54966
0.02537
0
0


326
chr3
187803000
187804000
0.000
0.000
0.029
0.000
AC022498.1
0.22755
0.54294
0.08726
0
0


32?
chr3
187806000
187807000
0.000
0.000
0.059
0.014
AC022498.1
0.19371
0.29551
0.00730
0
1


328
chr3
187957000
187958000
0.000
0.006
0.132
0.014
AC022498.1
0.00701
0.02564
0.00009
0
1


329
chr3
187958000
187959000
0.028
0.025
0.221
0.095
AC022498.1
0.06156
0.00936
0.00000
0
1


330
chr3
187959000
187960000
0.000
0.012
0.118
0.000
AC022498.1
0.00220
0.04825
0.00116
0
1


331
chr3
187960000
187961000
0.000
0.000
0.029
0.000
AC022498.1
0.22755
0.54294
0.08726
0
0


332
chr3
188222000
188223000
0.000
0.000
0.029
0.000
LPP
0.22755
0.54294
0.08726
0
0


333
chr3
188298000
188299000
0.000
0.000
0.015
0.014
LPP
1.00000
1.00000
0.29694
0
0


334
chr3
188299000
188300000
0.000
0.006
0.088
0.027
LPP
0.15270
0.09031
0.00311
0
1


335
chr3
188471000
188472000
0.000
0.006
0.191
0.068
LPP
0.04150
0.00372
0.00000
0
1


336
chr3
188472000
188473000
0.000
0.000
0.044
0.027
LPP
0.67043
0.54966
0.02537
0
0


337
chr4
50000
51000
0.000
0.000
0.029
0.000
ZNF595; ZNF718;
0.22755
0.54294
0.08726
0
0


338
chr4
51000
52000
0.000
0.000
0.044
0.014
ZNF595; ZNF718;
0.34948
0.54966
0.02537
0
0


339
chr4
54000
55000
0.000
0.000
0.029
0.000
ZNF595; ZNF718;
0.22755
0.54294
0.08726
0
0


340
chr4
290000
291000
0.056
0.000
0.000
0.000
ZNF732
1.00000
0.11763
1.00000
0
1


341
chr4
385000
386000
0.000
0.000
0.029
0.000
ZNF141
0.22755
0.54294
0.08726
0
0


342
chr4
550000
551000
0.000
0.000
0.000
0.027
PIGG
0.49735
1.00000
1.00000
0
0


343
chr4
2707000
2708000
0.028
0.000
0.015
0.000
FAM193A
0.47887
1.00000
0.29694
0
0


344
chr4
5206000
5207000
0.000
0.000
0.029
0.000
STK32B
0.22755
0.54294
0.08726
0
0


345
chr4
25863000
25864000
0.000
0.000
0.059
0.014
SEL1L3
0.19371
0.29551
0.00730
0
1


346
chr4
25864000
25865000
0.000
0.006
0.044
0.027
SEL1L3
0.67043
0.54966
0.07959
0
0


347
chr4
25865000
25866000
0.000
0.000
0.074
0.027
SEL1L3
0.25970
0.1610J
0.00208
0
1


348
chr4
29657000
29658000
0.000
0.000
0.015
0.014
PCDH7
1.00000
1.00000
0.29694
0
0


349
chr4
30356000
30357000
0.000
0.006
0.015
0.000
PCDH7
0.47887
1.00000
0.50663
0
0


350
chr4
33418000
33419000
0.000
0.000
0.029
0.000
PCDH7
0.22755
0.54294
0.08726
0
0


351
chr4
33449000
33450000
0.028
0.000
0.015
0.000
PCDH7
0.47887
1.00000
0.29694
0
0


352
chr4
39348000
39349000
0.000
0.000
0.015
0.014
RFC1
1.00000
1.00000
0.29694
0
0


353
chr4
39974000
39975000
0.000
0.000
0.000
0.027
PDS5A
0.49735
1.00000
1.00000
0
0


354
chr4
40194000
40195000
0.000
0.000
0.044
0.027
N4BP2
0.67043
0.54966
0.02537
0
0


355
chr4
40195000
40196000
0.000
0.000
0.015
0.027
N4BP2
1.00000
1.00000
0.29694
0
0


356
chr4
40196000
40197000
0.000
0.000
0.074
0.014
N4BP2
0.10420
0.16101
0.00208
0
1


357
chr4
40197000
40198000
0.000
0.000
0.015
0.027
N4BP2
1.00000
1.00000
0.29694
0
0


358
chr4
40198000
40199000
0.000
0.000
0.088
0.041
N4BP2
0.31126
0.09031
0.00058
0
1


359
chr4
40199000
40200000
0.056
0.000
0.279
0.162
N4BP2
0.10628
0.00895
0.00000
0
1


360
chr4
40200000
40201000
0.000
0.006
0.118
0.041
RHOH
0.11795
0.04825
0.00030
1
1


361
chr4
40201000
40202000
0.000
0.000
0.088
0.041
RHOH
0.31126
0.09031
0.00058
1
1


362
chr4
40202000
40203000
0.000
0.000
0.029
0.014
RHOH
0.60686
0.54294
0.08726
1
0


363
chr4
40204000
40205000
0.000
0.000
0.029
0.000
RHOH
0.22755
0.54294
0.08726
1
0


364
chr4
45308000
45309000
0.000
0.000
0.029
0.000
GNPDA2
0.22755
0.54294
0.08726
0
0


365
chr4
46360000
46361000
0.000
0.000
0.015
0.014
GABRA2
1.00000
1.00000
0.29694
0
0


366
chr4
62375000
62376000
0.000
0.000
0.029
0.000
LPHN3
0.22755
0.54294
0.08726
0
0


367
chr4
62530000
62531000
0.000
0.000
0.029
0.000
LPHN3
0.22755
0.54294
0.08726
0
0


368
chr4
62911000
62912000
0.000
0.000
0.029
0.000
LPHN3
0.22755
0.54294
0.08726
0
0


369
chr4
63120000
63121000
0.000
0.000
0.029
0.000
LPHN3
0.22755
0.54294
0.08726
0
0


370
chr4
64015000
64016000
0.000
0.000
0.029
0.000
LPHN3
0.22755
0.54294
0.08726
0
0


371
chr4
65038000
65039000
0.000
0.000
0.015
0.014
TECRL
1.00000
1.00000
0.29694
0
0


372
chr4
65165000
65166000
0.000
0.000
0.015
0.014
TECRL
1.00000
1.00000
0.29694
0
0


373
chr4
65966000
65967000
0.000
0.006
0.000
0.014
EPHA5
1.00000
1.00000
1.00000
0
0


374
chr4
66827000
66828000
0.000
0.000
0.029
0.000
EPHA5
0.22755
0.54294
0.08726
0
0


375
chr4
71531000
71532000
0.000
0.000
0.015
0.041
IGJ
0.62100
1.00000
0.29694
0
0


376
chr4
71532000
71533000
0.000
0.000
0.000
0.027
IGJ
0.49735
1.00000
1.00000
0
0


377
chr4
74456000
74457000
0.000
0.000
0.029
0.000
RASSF6
0.22755
0.54294
0.08726
0
0


378
chr4
74483000
74484000
0.00€
0.006
0.015
0.000
RASSF6
0.47887
1.00000
0.50663
0
0


379
chr4
74484000
74485000
0.000
0.000
0.044
0.000
RASSF6
0.10727
0.54966
0.02537
0
0


380
chr4
74485000
74486000
0.000
0.000
0.088
0.000
RASSF6
0.01070
0.09031
0.00058
0
1


381
chr4
91886000
91887000
0.000
0.000
0.015
0.014
CCSER1
1.00000
1.00000
0.29694
0
0


382
chr4
92787000
92788000
0.000
0.000
0.029
0.000
CCSER1
0.22755
0.54294
0.08726
0
0


383
chr4
113206000
113207000
0.000
0.000
0.029
0.000
TIFA
0.22755
0.54294
0.08726
0
0


384
chr4
114466000
114467000
0.000
0.000
0.029
0.000
CAMK2D
0.22755
0.54294
0.08726
0
0


385
chr4
114681000
114682000
0.000
0.000
0.044
0.000
CAMK2D
0.10727
0.54966
0.02537
0
0


386
chr4
117928000
117929000
0.000
0.000
0.029
0.000
TRAM1L1
0.22755
0.54294
0.08726
0
0


387
chr4
123637000
123638000
0.000
0.000
0.000
0.027
BBS12
0.49735
1.00000
1.00000
0
0


388
chr4
125227000
125228000
0.000
0.000
0.015
0.014
ANKRD50
1.00000
1.00000
0.29694
0
0


389
chr4
127371000
127372000
0.000
0.000
0.029
0.000
FAT4
0.22755
0.54294
0.08726
0
0


390
chr4
133455000
133456000
0.000
0.000
0.000
0.027
PCDH10
0.49735
1.00000
1.00000
0
0


391
chr4
134538000
134539000
0.000
0.000
0.015
0.014
PCDH10
1.00000
1.00000
0.29694
0
0


392
chr4
134743000
134744000
0.000
0.000
0.029
0.000
PABPC4L
0.22755
0.54294
0.08726
0
0


393
chr4
134867000
134868000
0.000
0.000
0.029
0.000
PABPC4L
0.22755
0.54294
0.08726
0
0


394
chr4
134949000
134950000
0.000
0.000
0.029
0.000
PABPC4L
0.22755
0.54294
0.08726
0
0


395
chr4
135064000
135065000
0.000
0.000
0.015
0.014
PABPC4L
1.00000
1.00000
0.29694
0
0


396
chr4
135077000
135078000
0.000
0.000
0.029
0.000
PABPC4L
0.22755
0.54294
0.08726
0
0


397
chr4
136799000
136800000
0.028
0.006
0.000
0.000
PCDH18
1.00000
0.34615
1.00000
0
0


398
chr4
136867000
136868000
0.000
0.000
0.015
0.014
PCDH18
1.00000
1.00000
0.29694
0
0


399
chr4
140236000
140237000
0.000
0.000
0.015
0.014
NAA15
1.00000
1.00000
0.29694
0
0


400
chr4
151723000
151724000
0.000
0.000
0.029
0.000
LRBA
0.22755
0.54294
0.08726
0
0


401
chr4
151950000
151951000
0.000
0.000
0.000
0.027
LRBA
0.49735
1.00000
1.00000
0
0


402
chr4
152125000
152126000
0.028
0.000
0.029
0.000
SH3D19
0.22755
1.00000
0.08726
0
0


403
chr4
157246000
157247000
0.000
0.000
0.015
0.014
CTSO
1.00000
1.00000
0.29694
0
0


404
chr4
164532000
164533000
0.000
0.000
0.000
0.027
1-Mar-19
0.49735
1.00000
1.00000
0
0


405
chr4
178732000
178733000
0.028
0.000
0.000
0.014
AGA
1.00000
0.34615
1.00000
0
0


406
chr4
178885000
178886000
0.000
0.000
0.029
0.000
AGA
0.22755
0.54294
0.08726
0
0


407
chr4
179898000
179899000
0.000
0.000
0.029
0.000
AGA
0.22755
0.54294
0.08726
0
0


408
chr4
180885000
180886000
0.000
0.006
0.029
0.000
TENM3
0.22755
0.54294
0.21104
0
0


409
chr4
181554000
181555000
0.000
0.000
0.029
0.000
TENM3
0.22755
0.54294
0.08726
0
0


410
chr4
182122000
182123000
0.000
0.000
0.015
0.014
TENM3
1.00000
1.00000
0.29694
0
0


411
chr5
436000
437000
0.028
0.000
0.000
0.014
AHRR
1.00000
0.34615
1.00000
0
0


412
chr5
3982000
3983000
0.000
0.000
0.029
0.000
IRX1
0.22755
0.54294
0.08726
0
0


413
chr5
17218000
17219000
0.000
0.000
0.029
0.000
BASP1
0.22755
0.54294
0.08726
0
0


414
chr5
17219000
17220000
0.000
0.000
0.029
0.000
BASP1
0.22755
0.54294
0.08726
0
0


415
chr5
18514000
18515000
0.028
0.000
0.000
0.014
CDH18
1.00000
0.34615
1.00000
0
0


416
chr5
22356000
22357000
0.000
0.000
0.029
0.000
CDH12
0.22755
0.54294
0.08726
0
0


417
chr5
22517000
22518000
0.000
0.000
0.015
0.014
CDH12
1.00000
1.00000
0.29694
0
0


418
chr5
24632000
24633000
0.000
0.000
0.029
0.000
CDH10
0.22755
0.54294
0.08726
0
0


419
chr5
25275000
25276000
0.000
0.000
0.015
0.014
CDH10
1.00000
1.00000
0.29694
0
0


420
chr5
25541000
25542000
0.000
0.000
0.029
0.000
CDH10
0.22755
0.54294
0.08726
0
0


421
chr5
26119000
26120000
0.000
0.000
0.015
0.014
CDH9
1.00000
1.00000
0.29694
0
0


422
chr5
26450000
26451000
0.000
0.000
0.029
0.000
CDH9
0.22755
0.54294
0.08726
0
0


423
chr5
29224000
29225000
0.000
0.000
0.029
0.000
CDH6
0.22755
0.54294
0.08726
0
0


424
chr5
29492000
29493000
0.000
0.000
0.029
0.000
CDH6
0.22755
0.54294
0.08726
0
0


425
chr5
29648000
29649000
0.000
0.000
0.029
0.000
CDH6
0.22755
0.54294
0.08726
0
0


426
chr5
51521000
51522000
0.000
0.000
0.044
0.014
CTD-2203A3.1
0.34948
0.54966
0.02537
0
0


427
chr5
83841000
83842000
0.000
0.000
0.029
0.000
EDIL3
0.22755
0.54294
0.08726
0
0


428
chr5
88177000
88178000
0.000
0.000
0.029
0.000
MEF2C
0.22755
0.54294
0.08726
0
0


429
chr5
88178000
88179000
0.000
0.000
0.015
0.014
MEF2C
1.00000
1.00000
0.29694
0
0


430
chr5
91417000
91418000
0.000
0.000
0.000
0.027
ARRDC3
0.49735
1.00000
1.00000
0
0


431
chr5
103678000
103679000
0.000
0.000
0.015
0.014
NUDT12
1.00000
1.00000
0.29694
0
0


432
chr5
123696000
123697000
0.000
0.000
0.000
0.027
ZNF608
0.49735
1.00000
1.00000
1
0


433
chr5
124079000
124080000
0.000
0.000
0.029
0.014
ZNF608
0.60686
0.54294
0.08726
1
0


434
chr5
124080000
124081000
0.000
0.000
0.029
0.014
ZNF608
0.60686
0.54294
0.08726
1
0


435
chr5
127594000
127595000
0.000
0.000
0.015
0.014
FBN2
1.00000
1.00000
0.29694
0
0


436
chr5
127875000
127876000
0.000
0.000
0.000
0.027
FBN2
0.49735
1.00000
1.00000
0
0


437
chr5
131825000
131826000
0.000
0.000
0.074
0.000
IRF1
0.02326
0.16101
0.00208
0
1


438
chr5
131826000
131827000
0.000
0.000
0.029
0.000
IRF1
0.22755
0.54294
0.08726
0
0


439
chr5
149791000
149792000
0.000
0.000
0.132
0.014
CD74
0.00701
0.02564
0.00001
1
1


440
chr5
149792000
149793000
0.000
0.000
0.015
0.014
CD74
1.00000
1.00000
0.29694
1
0


441
chr5
158380000
158381000
0.028
0.000
0.015
0.000
EBF1
0.47887
1.00000
0.29694
0
0


442
chr5
158479000
158480000
0.000
0.000
0.025
0.000
EBF1
0.22755
0.54294
0.08726
0
0


443
chr5
158526000
158527000
0.028
0.000
0.044
0.000
EBF1
0.10727
1.00000
0.02537
0
0


444
chr5
158527000
158528000
0.000
0.000
0.029
0.000
EBF1
0.22755
0.54294
0.08726
0
0


445
chr5
158528000
158529000
0.000
0.000
0.059
0.000
EBF1
0.05016
0.29551
0.00730
0
1


446
chr5
164247000
164248000
0.000
0.000
0.029
0.000
MAT2B
0.22755
0.54294
0.08726
0
0


447
chr5
164441000
164442000
0.028
0.000
0.015
0.000
MAT2B
0.47887
1.00000
0.29694
0
0


448
chr5
165932000
165933000
0.000
0.000
0.015
0.014
TENM2
1.00000
1.00000
0.29694
0
0


449
chr5
173300000
173301000
0.000
0.000
0.000
0.027
CPEB4
0.49735
1.00000
1.00000
0
0


450
chr5
179166000
179167000
0.000
0.000
0.015
0.027
MAML1
1.00000
1.00000
0.29694
0
0


451
chr5
180102000
180103000
0.000
0.000
0.015
0.014
FLT4
1.00000
1.00000
0.29694
0
0


452
chr6
392000
393000
0.000
0.000
0.074
0.000
IRF4
0.02326
0.16101
0.00208
1
1


453
chr6
393000
394000
0.000
0.000
0.074
0.000
IRF4
0.02326
0.16101
0.00208
1
1


454
chr6
14118000
14119000
0.000
0.000
0.279
0.041
CD83
0.00011
0.00013
0.00000
1
1


455
chr6
14119000
14120000
0.000
0.000
0.044
0.027
CD83
0.67043
0.54966
0.02537
1
0


456
chr6
18111000
18112000
0.028
0.000
0.044
0.000
NHLRC1
0.10727
1.00000
0.02537
0
0


457
chr6
18387000
18388000
0.000
0.000
0.000
0.027
RNF144B
0.49735
1.00000
1.00000
1
0


458
chr6
18388000
18389000
0.000
0.000
0.000
0.027
RNF144B
0.49735
1.00000
1.00000
1
0


459
chr6
19573000
19574000
0.000
0.000
0.029
0.000
ID4
0.22755
0.54294
0.08726
0
0


460
chr6
22873000
22874000
0.000
0.000
0.015
0.014
HDGFL1
1.00000
1.00000
0.29694
0
0


461
chr6
26031000
26032000
0.000
0.000
0.000
0.027
HIST1H3B
0.49735
1.00000
1.00000
1
0


462
chr6
26032000
26033000
0.000
0.000
0.000
0.027
HIST1H3B
0.49735
1.00000
1.00000
1
0


463
chr6
26056000
26057000
0.000
0.000
0.059
0.027
HIST1H1C
0.42627
0.29551
0.00730
1
1


464
chr6
26123000
26124000
0.000
0.000
0.059
0.014
HIST1H2BC
0.19371
0.29551
0.00730
1
1


465
chr6
26124000
26125000
0.000
0.000
0.074
0.000
HIST1H2AC;
0.02326
0.16101
0.00208
0
1










HIST1H2BC;







466
chr6
26125000
26126000
0.000
0.000
0.015
0.014
HIST1H2AC
1.00000
1.00000
0.29694
1
0


467
chr6
26156000
26157000
0.000
0.000
0.074
0.014
HIST1H1E
0.10420
0.16101
0.00208
1
1


468
chr6
26157000
26158000
0.000
0.000
0.029
0.014
HIST1H1E
0.60686
0.54294
0.08726
1
0


469
chr6
26216000
26217000
0.000
0.000
0.029
0.000
HIST1H2BG
0.22755
0.54294
0.08726
1
0


470
chr6
26234000
26235000
0.000
0.000
0.044
0.000
HIST1H1D
0.10727
0.54966
0.02537
0
0


471
chr6
27101000
27102000
0.000
0.000
0.029
0.000
HIST1H2AG
0.22755
0.54294
0.08726
1
0


472
chr6
27114000
27115000
0.000
0.000
0.059
0.014
HIST1H2AH;
0.19371
0.29551
0.00730
0
1










HIST1H2BK;







473
chr6
27792000
27793000
0.000
0.000
0.044
0.014
HIST1H4J
0.34948
0.54966
0.02537
0
0


474
chr6
27833000
27834000
0.000
0.000
0.015
0.014
HIST1H2AL
1.00000
1.00000
0.29694
1
0


475
chr6
27860000
27861000
0.000
0.000
0.029
0.027
HIST1H2AM
1.00000
0.54294
0.08726
1
0


476
chr6
27861000
27862000
0.000
0.000
0.015
0.014
HIST1H2BO
1.00000
1.00000
0.29694
1
0


477
chr6
29778000
29779000
0.028
0.000
0.000
0.014
LOC554223
1.00000
0.34615
1.00000
0
0


478
chr6
29780000
29781000
0.000
0.000
0.015
0.014
HLA-G
1.00000
1.00000
0.29694
0
0


479
chr6
29911000
29912000
0.000
0.000
0.044
0.000
HLA-A
0.10727
0.54966
0.02537
0
0


480
chr6
29927000
29928000
0.000
0.000
0.015
0.014
HLA-A
1.00000
1.00000
0.29694
0
0


481
chr6
31324000
31325000
0.000
0.000
0.029
0.014
HLA-B
0.60686
0.54294
0.08726
1
0


482
chr6
31325000
31326000
0.028
0.000
0.000
0.014
HLA-B
1.00000
0.34615
1.00000
1
0


483
chr6
31543000
31544000
0.000
0.000
0.029
0.000
TNF
0.22755
0.54294
0.08726
1
0


484
chr6
31549000
31550000
0.000
0.006
0.191
0.068
LTB
0.04150
0.00372
0.00000
1
1


485
chr6
31550000
31551000
0.000
0.000
0.044
0.000
LTB
0.10727
0.54966
0.02537
1
0


486
chr6
32440000
32441000
0.000
0.000
0.044
0.027
HLA-DRA
0.67043
0.54966
0.02537
0
0


487
chr6
32451000
32452000
0.056
0.000
0.000
0.000
HLA-DRB5
1.00000
0.11763
1.00000
0
1


488
chr6
32452000
32453000
0.028
0.000
0.015
0.000
HLA-DRB5
0.47887
1.00000
0.29694
0
0


489
chr6
32455000
32456000
0.028
0.000
0.015
0.000
HLA-DRB5
0.47887
1.00000
0.29694
0
0


490
chr6
32457000
32458000
0.000
0.000
0.000
0.027
HLA-DRB5
0.49735
1.00000
1.00000
0
0


491
chr6
32498000
32499000
0.000
0.000
0.000
0.027
HLA-DRB5
0.49735
1.00000
1.00000
0
0


492
chr6
32505000
32506000
0.000
0.000
0.029
0.014
HLA-DRB5
0.60686
0.54294
0.08726
0
0


493
chr6
32511000
32512000
0.000
0.000
0.000
0.041
HLA-DRB5
0.24603
1.00000
1.00000
0
0


494
chr6
32522000
32523000
0.028
0.000
0.015
0.027
HLA-DRB1
1.00000
1.00000
0.29694
0
0


495
chr6
32525000
32526000
0.000
0.000
0.029
0.014
HLA-DRB1
0.60686
0.54294
0.08726
0
0


496
chr6
32526000
32527000
0.000
0.000
0.000
0.041
HLA-DRB1
0.24603
1.00000
1.00000
0
0


497
chr6
32527000
32528000
0.000
0.000
0.000
0.027
HLA-DRB1
0.49735
1.00000
1.00000
0
0


498
chr6
32548000
32549000
0.000
0.000
0.029
0.014
HLA-DRB1
0.60686
0.54294
0.08726
0
0


499
chr6
32552000
32553000
0.056
0.000
0.015
0.027
HLA-DRB1
1.00000
0.27446
0.29694
0
1


500
chr6
32557000
32558000
0.028
0.000
0.000
0.041
HLA-DRB1
0.24603
0.34615
1.00000
0
0


501
chr6
32609000
32610000
0.028
0.000
0.059
0.014
HLA-DQA1
0.19371
0.65667
0.00730
0
1


502
chr6
32630000
32631000
0.000
0.000
0.015
0.014
HLA-DQB1
1.00000
1.00000
0.29694
0
0


503
chr6
32632000
32633000
0.111
0.000
0.029
0.027
HLA-DQB1
1.00000
0.17874
0.08726
0
1


504
chr6
32727000
32728000
0.056
0.000
0.015
0.000
HLA-DQB2
0.47887
0.27446
0.29694
0
1


505
chr6
32729000
32730000
0.056
0.000
0.029
0.014
HLA-DQB2
0.60686
0.60763
0.08726
0
1


506
chr6
33048000
33049000
0.000
0.000
0.015
0.014
HLA-DPB1
1.00000
1.00000
0.29694
0
0


507
chr6
34179000
34180000
0.000
0.000
0.029
0.000
HMGA1
0.22755
0.54294
0.08726
0
0


508
chr6
37138000
37139000
0.000
0.000
0.191
0.081
PIM1
0.08249
0.00372
0.00000
1
1


509
chr6
37139000
37140000
0.000
0.000
0.088
0.041
PIM1
0.31126
0.09031
0.00058
1
1


510
chr6
37140000
37141000
0.000
0.000
0.029
0.014
PIM1
0.60686
0.54294
0.08726
1
0


511
chr6
58001000
58002000
0.000
0.000
0.015
0.014
PRIM2
1.00000
1.00000
0.29694
0
0


512
chr6
67923000
67924000
0.000
0.000
0.015
0.014
BAI3
1.00000
1.00000
0.29694
0
0


513
chr6
77256000
77257000
0.000
0.000
0.029
0.000
IMPG1
0.22755
0.54294
0.08726
0
0


514
chr6
81437000
81438000
0.000
0.000
0.015
0.014
BCKDHB
1.00000
1.00000
0.29694
0
0


51.5
chr6
88468000
88469000
0.000
0.000
0.015
0.014
AKIRIN2
1.00000
1.00000
0.29694
0
0


516
chr6
88630000
88631000
0.000
0.000
0.044
0.014
SPACA1
0.34948
0.54966
0.02537
0
0


517
chr6
88876000
88877000
0.028
0.000
0.015
0.000
CNR1
0.47887
1.00000
0.29694
0
0


518
chr6
89323000
89324000
0.000
0.000
0.029
0.014
RNGTT
0.60686
0.54294
0.08726
0
0


519
chr6
89338000
89339000
0.000
0.000
0.029
0.000
RNGTT
0.22755
0.54294
0.08726
0
0


520
chr6
89348000
89349000
0.000
0.000
0.044
0.000
RNGTT
0.10727
0.54966
0.02537
0
0


521
chr6
89470000
89471000
0.000
0.000
0.029
0.000
RNGTT
0.22755
0.54294
0.08726
0
0


522
chr6
89471000
89472000
0.000
0.000
0.029
0.000
RNGTT
0.22755
0.54294
0.08726
0
0


523
chr6
90061000
90062000
0.000
0.000
0.059
0.000
UBE2J1
0.05016
0.29551
0.00730
1
1


524
chr6
90062000
90063000
0.000
0.000
0.029
0.000
UBE2J1
0.22755
0.54294
0.08726
1
0


525
chr6
90994000
90995000
0.000
0.000
0.029
0.014
MAP3K7
0.60686
0.54294
0.08726
0
0


526
chr6
91004000
91005000
0.000
0.000
0.059
0.014
MAP3K7
0.19371
0.29551
0.00730
0
1


527
chr6
91005000
91006000
0.000
0.019
0.294
0.095
MAP3K7
0.00279
0.00011
0.00000
0
1


528
chr6
91006000
91007000
0.000
0.006
0.118
0.027
MAP3K7
0.04838
0.04825
0.00030
0
1


529
chr6
91007000
91008000
0.000
0.012
0.029
0.000
MAP3K7
0.22755
0.54294
0.58408
0
0


530
chr6
94822000
94823000
0.028
0.000
0.015
0.000
EPHA7
0.47887
1.00000
0.29694
0
0


531
chr6
107704000
107705000
0.028
0.000
0.000
0.014
PDSS2
1.00000
0.34615
1.00000
0
0


532
chr6
112885000
112886000
0.000
0.000
0.015
0.014
RFPL4B
1.00000
1.00000
0.29694
0
0


533
chr6
118244000
118245000
0.000
0.000
0.015
0.014
SLC35F1
1.00000
1.00000
0.29694
0
0


534
chr6
121288000
121289000
0.000
0.000
0.000
0.027
C6orf170
0.49735
1.00000
1.00000
0
0


535
chr6
121489000
121490000
0.000
0.000
0.029
0.000
C6orf170
0.22755
0.54294
0.08726
0
0


536
chr6
123504000
123505000
0.000
0.006
0.015
0.000
TRDN
0.47887
1.00000
0.50663
0
0


537
chr6
127313000
127314000
0.000
0.006
0.015
0.000
RSPO3
0.47887
1.00000
0.50663
0
0


538
chr6
133785000
133786000
0.000
0.000
0.029
0.000
EYA4
0.22755
0.54294
0.08726
0
0


539
chr6
134491000
134492000
0.000
0.000
0.029
0.000
SGK1
0.22755
0.54294
0.08726
1
0


540
chr6
134492000
134493000
0.000
0.000
0.044
0.014
SGK1
0.34948
0.54966
0.02537
1
0


541
chr6
134493000
134494000
0.000
0.000
0.029
0.000
SGK1
0.22755
0.54294
0.08726
1
0


542
chr6
134494000
134495000
0.000
0.000
0.029
0.000
SGK1
0.22755
0.54294
0.08726
1
0


543
chr6
134495000
134496000
0.000
0.000
0.162
0.041
SGK1
0.02233
0.01471
0.00000
1
1


544
chr6
134496000
134497000
0.000
0.000
0.029
0.000
SGK1
0.22755
0.54294
0.08726
1
0


545
chr6
142046000
142047000
0.000
0.000
0.059
0.000
NMBR
0.05016
0.29551
0.00730
0
1


546
chr6
147860000
147861000
0.028
0.000
0.015
0.000
SAMD5
0.47887
1.00000
0.29694
0
0


547
chr6
150954000
150955000
0.000
0.000
0.044
0.014
PLEKHG1
0.34948
0.54966
0.02537
0
0


548
chr6
159238000
159239000
0.000
0.012
0.044
0.014
EZR
0.34948
0.54966
0.15671
0
0


549
chr6
159239000
159240000
0.000
0.000
0.029
0.014
EZR
0.60686
0.54294
0.08726
0
0


550
chr6
159240000
159241000
0.000
0.000
0.029
0.014
EZR
0.60686
0.54294
0.08726
0
0


551
chr6
159464000
159465000
0.000
0.000
0.015
0.014
TAGAP
1.00000
1.00000
0.29694
0
0


552
chr6
159465000
159466000
0.000
0.000
0.029
0.000
TAGAP
0.22755
0.54294
0.08726
0
0


553
chr6
161265000
161266000
0.028
0.000
0.000
0.027
PLG
0.49735
0.34615
1.00000
0
0


554
chr6
161833000
161834000
0.028
0.000
0.000
0.027
PARK2
0.49735
0.34615
1.00000
0
0


555
chr6
162712000
162713000
0.000
0.000
0.029
0.000
PARK2
0.22755
0.54294
0.08726
0
0


556
chr6
164941000
164942000
0.000
0.000
0.029
0.000
C6orf118
0.22755
0.54294
0.08726
0
0


557
chr6
168813000
168814000
0.028
0.000
0.015
0.000
SMOC2
0.47887
1.00000
0.29694
0
0


558
chr7
1898000
1899000
0.000
0.000
0.029
0.000
AC110781.3
0.22755
0.54294
0.08726
0
0


559
chr7
1963000
1964000
0.028
0.000
0.015
0.000
MAD1L1
0.47887
1.00000
0.29694
0
0


560
chr7
2080000
2081000
0.000
0.000
0.015
0.014
MAD1L1
1.00000
1.00000
0.29694
0
0


561
chr7
5568000
5569000
0.000
0.000
0.059
0.014
ACTB
0.19371
0.29551
0.00730
1
1


562
chr7
5569000
5570000
0.000
0.000
0.059
0.014
ACTB
0.19371
0.29551
0.00730
1
1


563
chr7
5570000
5571000
0.000
0.000
0.015
0.027
ACTB
1.00000
1.00000
0.29694
1
0


564
chr7
9933000
9934000
0.000
0.000
0.029
0.014
NDUFA4
0.60686
0.54294
0.08726
0
0


565
chr7
13017000
13018000
0.028
0.000
0.015
0.000
ARL4A
0.47887
1.00000
0.29694
0
0


566
chr7
13346000
13347000
0.000
0.000
0.000
0.027
ETV1
0.49735
1.00000
1.00000
0
0


567
chr7
15459000
15460000
0.000
0.000
0.000
0.027
AGMO
0.49735
1.00000
1.00000
0
0


568
chr7
16382000
16383000
0.000
0.000
0.015
0.014
ISPD
1.00000
1.00000
0.29694
0
0


569
chr7
28600000
28601000
0.028
0.000
0.015
0.000
CREB5
0.47887
1.00000
0.29694
0
0


570
chr7
40846000
40847000
0.000
0.000
0.015
0.041
C7orf10
0.62100
1.00000
0.29694
0
0


571
chr7
50349000
50350000
0.000
0.000
0.059
0.014
IKZF1
0.19371
0.29551
0.00730
0
1


572
chr7
50350000
50351000
0.000
0.000
0.044
0.000
IKZF1
0.10727
0.54966
0.02537
0
0


573
chr7
53335000
53336000
0.000
0.000
0.000
0.027
POM12IL12
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr7
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
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chr8
143183000
143184000
0.028
0.000
0.015
0.000
ISNARE1
0.47887
1.00000
0.29694
0
0


698
chr8
144123000
144124000
0.000
0.000
0.029
0.000
C8orf31
0.22755
0.54294
0.08726
0
0


699
chr9
6411000
6412000
0.000
0.000
0.029
0.000
UHRF2
0.22755
0.54294
0.08726
0
0


700
chr9
6413000
6414000
0.000
0.000
0.015
0.014
UHRF2
1.00000
1.00000
0.29694
0
0


701
chr9
6414000
6415000
0.000
0.000
0.029
0.014
UHRF2
0.60686
0.54294
0.08726
0
0


702
chr9
9928000
9929000
0.000
0.000
0.000
0.027
PTPRD
0.49735
1.00000
1.00000
0
0


703
chr9
13965000
13966000
0.000
0.000
0.029
0.000
NFIB
0.22755
0.54294
0.08726
0
0


704
chr9
22824000
22825000
0.000
0.000
0.029
0.000
DMRTA1
0.22755
0.54294
0.08726
0
0


705
chr9
25260000
25261000
0.000
0.000
0.029
0.000
TUSC1
0.22755
0.54294
0.08726
0
0


706
chr9
29890000
29891000
0.000
0.000
0.015
0.014
LINGO2
1.00000
1.00000
0.29694
0
0


707
chr9
30656000
30657000
0.000
0.000
0.015
0.014
ACO1
1.00000
1.00000
0.29694
0
0


708
chr9
37003000
37004000
0.000
0.006
0.015
0.000
PAX5
0.47887
1.00000
0.50663
1
0


709
chr9
37005000
37006000
0.000
0.000
0.015
0.014
PAX5
1.00000
1.00000
0.29694
1
0


710
chr9
37024000
37025000
0.000
0.000
0.044
0.027
PAX5
0.67043
0.54966
0.02537
1
0


711
chr9
37025000
37026000
0.000
0.000
0.132
0.054
PAX5
0.14640
0.02564
0.00001
1
1


712
chr9
37026000
37027000
0.000
0.006
0.221
0.108
PAX5
0.10913
0.00107
0.00000
1
1


713
chr9
37027000
37028000
0.000
0.000
0.029
0.014
PAX5
0.60686
0.54294
0.08726
1
0


714
chr9
37033000
37034000
0.000
0.000
0.044
0.014
PAX5
0.34948
0.54966
0.02537
1
0


715
chr9
37034000
37035000
0.000
0.000
0.074
0.041
PAX5
0.47996
0.16101
0.00208
1
1


716
chr9
37035000
37036000
0.000
0.000
0.015
0.014
PAX5
1.00000
1.00000
0.29694
1
0


717
chr9
37196000
37197000
0.000
0.000
0.029
0.014
ZCCHC7
0.60686
0.54294
0.08726
0
0


718
chr9
37197000
37198000
0.000
0.000
0.029
0.000
ZCCHC7
0.22755
0.54294
0.08726
0
0


719
chr9
37293000
37294000
0.000
0.000
0.029
0.027
ZCCHC7
1.00000
0.54294
0.08726
0
0


720
chr9
37294000
37295000
0.000
0.000
0.044
0.027
ZCCHC7
0.67043
0.54966
0.02537
0
0


721
chr9
37327000
37328000
0.000
0.000
0.015
0.014
ZCCHC7
1.00000
1.00000
0.29694
0
0


722
chr9
37336000
37337000
0.000
0.000
0.044
0.014
ZCCHC7
0.34948
0.54966
0.02537
0
0


723
chr9
37337000
37338000
0.000
0.012
0.015
0.041
ZCCHC7
0.62100
1.00000
1.00000
0
0


724
chr9
37338000
37339000
0.000
0.000
0.029
0.014
ZCCHC7
0.60686
0.54294
0.08726
0
0


725
chr9
37369000
37370000
0.000
0.000
0.029
0.000
ZCCHC7
0.22755
0.54294
0.08726
0
0


726
chr9
37371000
37372000
0.028
0.025
0.118
0.068
ZCCHC7
0.38669
0.15803
0.00732
0
1


727
chr9
37372000
37373000
0.000
0.000
0.015
0.014
ZCCHC7
1.00000
1.00000
0.29694
0
0


728
chr9
37383000
37384000
0.000
0.000
0.059
0.027
ZCCHC7
0.42627
0.29551
0.00730
0
1


729
chr9
37384000
37385000
0.000
0.000
0.059
0.054
ZCCHC7
1.00000
0.29551
0.00730
0
1


730
chr9
37385000
37386000
0.000
0.000
0.029
0.014
ZCCHC7
0.60686
0.54294
0.08726
0
0


731
chr9
37387000
37388000
0.000
0.000
0.059
0.014
ZCCHC7
0.19371
0.29551
0.00730
0
1


732
chr9
37397000
37398000
0.000
0.000
0.044
0.000
GRHPR
0.10727
0.54966
0.02537
0
0


733
chr9
37398000
37399000
0.000
0.000
0.029
0.000
GRHPR
0.22755
0.54294
0.08726
0
0


734
chr9
37399000
37400000
0.000
0.000
0.029
0.000
GRHPR
0.22755
0.54294
0.08726
0
0


735
chr9
37402000
37403000
0.000
0.006
0.029
0.000
GRHPR
0.22755
0.54294
0.21104
0
0


736
chr9
37406000
37407000
0.000
0.000
0.015
0.014
GRHPR
1.00000
1.00000
0.29694
0
0


737
chr9
37407000
37408000
0.000
0.000
0.132
0.149
GRHPR
0.81382
0.02564
0.00001
0
1


738
chr9
37408000
37409000
0.000
0.006
0.029
0.027
GRHPR
1.00000
0.54294
0.21104
0
0


739
chr9
37410000
37411000
0.000
0.000
0.029
0.000
GRHPR
0.22755
0.54294
0.08726
0
0


740
chr9
37424000
37425000
0.000
0.000
0.044
0.000
GRHPR
0.10727
0.54966
0.02537
0
0


741
chr9
37425000
37426000
0.000
0.000
0.029
0.000
GRHPR
0.22755
0.54294
0.08726
0
0


742
chr9
112811000
112812000
0.000
0.000
0.059
0.014
AKAP2
0.19371
0.29551
0.00730
0
1


743
chr9
117037000
117038000
0.056
0.000
0.000
0.014
COL27A1
1.00000
0.11763
1.00000
0
1


744
chr9
119779000
119780000
0.000
0.000
0.044
0.000
ASTN2
0.10727
0.54966
0.02537
0
0


745
chr9
126232000
126233000
0.056
0.000
0.000
0.000
DENND1A
1.00000
0.11763
1.00000
0
1


746
chr9
130741000
130742000
0.000
0.000
0.059
0.000
FAM102A
0.05016
0.29551
0.00730
1
1


747
chr9
130742000
130743000
0.000
0.000
0.059
0.027
FAM102A
0.42627
0.29551
0.00730
1
1


748
chr9
132767000
132768000
0.000
0.000
0.015
0.014
FNBP1
1.00000
1.00000
0.29694
0
0


749
chr9
132785000
132786000
0.000
0.000
0.029
0.000
FNBP1
0.22755
0.54294
0.08726
0
0


750
chr9
132803000
132804000
0.000
0.000
0.015
0.014
FNBP1
1.00000
1.00000
0.29694
0
0


751
chr9
132804000
132805000
0.000
0.000
0.029
0.027
FNBP1
1.00000
0.54294
0.08726
0
0


752
chr9
134551000
134552000
0.000
0.000
0.029
0.000
RAPGEF1
0.22755
0.54294
0.08726
0
0


753
chr9
138874000
138875000
0.056
0.000
0.029
0.014
UBAC1
0.60686
0.60763
0.08726
0
1


754
chr10
3333000
3334000
0.000
0.000
0.000
0.027
PITRM1
0.49735
1.00000
1.00000
0
0


755
chr10
5707000
5708000
0.000
0.000
0.029
0.014
ASB13
0.60686
0.54294
0.08726
0
0


756
chr10
5728000
5729000
0.000
0.006
0.015
0.000
ASB13
0.47887
1.00000
0.50663
0
0


757
chr10
15393000
15394000
0.028
0.000
0.015
0.000
FAM171A1
0.47887
1.00000
0.29694
0
0


758
chr10
20796000
20797000
0.000
0.006
0.015
0.000
PLXDC2
0.47887
1.00000
0.50663
0
0


759
chr10
35424000
35425000
0.000
0.000
0.029
0.000
CREM
0.22755
0.54294
0.08726
0
0


760
chr10
56678000
56679000
0.000
0.000
0.000
0.027
PCDH15
0.49735
1.00000
1.00000
0
0


761
chr10
63440000
63441000
0.028
0.000
0.015
0.000
C10orf107
0.47887
1.00000
0.29694
0
0


762
chr10
63659000
63660000
0.000
0.000
0.044
0.014
ARID5B
0.34948
0.54966
0.02537
1
0


763
chr10
63660000
63661000
0.000
0.000
0.059
0.014
ARID5B
0.19371
0.295SI
0.00730
1
1


764
chr10
63662000
63663000
0.000
0.000
0.029
0.014
ARID5B
0.60686
0.54294
0.08726
1
0


765
chr10
63720000
63721000
0.000
0.000
0.029
0.000
ARID5B
0.22755
0.54294
0.08726
1
0


766
chr10
63803000
63804000
0.000
0.000
0.000
0.027
ARID5B
0.49735
1.00000
1.00000
1
0


767
chr10
63809000
63810000
0.000
0.000
0.015
0.014
ARID5B
1.00000
1.00000
0.29694
1
0


768
chr10
63810000
63811000
0.000
0.000
0.000
0.027
ARID5B
0.49735
1.00000
1.00000
1
0


769
chr10
67907000
67908000
0.000
0.006
0.015
0.000
CTNNA3
0.47887
1.00000
0.50663
0
0


770
chr10
68474000
68475000
0.000
0.000
0.000
0.027
CTNNA3
0.49735
1.00000
1.00000
0
0


771
chr10
98510000
98511000
0.000
0.000
0.029
0.000
PIK3AP1
0.22755
0.54294
0.08726
0
0


772
chr10
101384000
101385000
0.028
0.000
0.015
0.014
SLC25A28
1.00000
1.00000
0.29694
0
0


773
chr10
108276000
108277000
0.000
0.000
0.029
0.000
SORCS1
0.22755
0.54294
0.08726
0
0


774
chr10
113473000
113474000
0.028
0.000
0.015
0.000
GPAM
0.47887
1.00000
0.29694
0
0


775
chr10
113636000
113637000
0.000
0.000
0.029
0.000
GPAM
0.22755
0.54294
0.08726
0
0


776
chr10
116458000
116459000
0.000
0.000
0.044
0.000
ABLIM1
0.10727
0.54966
0.02537
0
0


777
chr10
121623000
121624000
0.000
0.000
0.029
0.000
MCMBP
0.22755
0.54294
0.08726
0
0


778
chr10
132973000
132974000
0.000
0.000
0.015
0.027
TCERG1L
1.00000
1.00000
0.29694
0
0


779
chr10
134326000
134327000
0.028
0.000
0.015
0.000
INPP5A
0.47887
1.00000
0.29694
0
0


780
chr11
871000
872000
0.028
0.000
0.029
0.000
CHID1
0.22755
1.00000
0.08726
0
0


781
chr11
1149000
1150000
0.028
0.000
0.015
0.000
MUC5AC
0.47887
1.00000
0.29694
0
0


782
chr11
25065000
25066000
0.000
0.000
0.029
0.000
LUZP2
0.22755
0.54294
0.08726
0
0


783
chr11
25289000
25290000
0.000
0.000
0.029
0.000
LUZP2
0.22755
0.54294
0.08726
0
0


784
chr11
27216000
27217000
0.028
0.000
0.029
0.014
BBOX1
0.60686
1.00000
0.08726
0
0


785
chr11
28849000
28850000
0.000
0.000
0.000
0.027
METTL15
0.49735
1.00000
1.00000
0
0


786
chr11
29253000
29254000
0.000
0.000
0.029
0.000
KCNA4
0.22755
0.54294
0.08726
0
0


787
chr11
29900000
29901000
0.000
0.000
0.029
0.000
KCNA4
0.22755
0.54294
0.08726
0
0


788
chr11
40626000
40627000
0.000
0.000
0.029
0.000
LRRC4C
0.22755
0.54294
0.08726
0
0


789
chr11
40845000
40846000
0.000
0.000
0.025
0.000
LRRC4C
0.22755
0.54294
0.08726
0
0


790
chr11
40868000
40869000
0.000
0.000
0.029
0.000
LRRC4C
0.22755
0.54294
0.08726
0
0


791
chr11
41066000
41067000
0.000
0.000
0.029
0.000
LRRC4C
0.22755
0.54294
0.08726
0
0


792
chr11
41844000
41845000
0.028
0.000
0.015
0.000
API5
0.47887
1.00000
0.29694
0
0


793
chr11
57171000
57172000
0.000
0.000
0.029
0.014
SLC43A3
0.60686
0.54294
0.08726
0
0


794
chr11
60224000
60225000
0.000
0.000
0.074
0.014
MS4A1
0.10420
0.16101
0.00208
1
1


795
chr11
65190000
65191000
0.000
0.000
0.074
0.027
FRMD8
0.25970
0.16101
0.00208
0
1


796
chr11
65191000
65192000
0.000
0.000
0.103
0.014
FRMD8
0.02808
0.09269
0.00016
0
1


797
chr11
65266000
65267000
0.000
0.000
0.029
0.014
SCYL1
0.60686
0.54294
0.08726
0
0


798
chr11
65267000
65268000
0.000
0.000
0.103
0.000
SCYL1
0.00488
0.09269
0.00016
0
1


799
chr11
85963000
85964000
0.000
0.000
0.029
0.000
EED
0.22755
0.54294
0.08726
0
0


800
chr11
92261000
92262000
0.000
0.000
0.029
0.000
FAT3
0.22755
0.54294
0.08726
0
0


801
chr11
102117000
102118000
0.000
0.000
0.000
0.027
YAP1
0.49735
1.00000
1.00000
0
0


802
chr11
102188000
102189000
0.000
0.012
0.206
0.108
BIRC3
0.16270
0.00197
0.00000
1
1


803
chr11
102189000
102190000
0.000
0.000
0.059
0.000
BIRC3
0.05016
0.29551
0.00730
1
1


804
chr11
107497000
107498000
0.028
0.000
0.015
0.000
ELMOD1
0.47887
1.00000
0.29694
0
0


805
chr11
108781000
108782000
0.000
0.000
0.015
0.014
DDX10
1.00000
1.00000
0.29694
0
0


806
chr11
108975000
108976000
0.000
0.000
0.015
0.014
DDX10
1.00000
1.00000
0.29694
0
0


807
chr11
109066000
109067000
0.028
0.000
0.015
0.000
C11orf87
0.47887
1.00000
0.29694
0
0


808
chr11
111248000
111249000
0.000
0.000
0.029
0.014
POU2AF1
0.60686
0.54294
0.08726
1
0


809
chr11
111249000
111250000
0.000
0.012
0.103
0.081
POU2AF1
0.77363
0.09269
0.00337
1
1


810
chr11
115761000
115762000
0.028
0.000
0.015
0.041
CADM1
0.62100
1.00000
0.29694
0
0


811
chr11
118723000
118724000
0.000
0.000
0.029
0.000
CXCR5
0.22755
0.54294
0.08726
0
0


812
chr11
126496000
126497000
0.028
0.000
0.015
0.014
KIRREL3
1.00000
1.00000
0.29694
0
0


813
chr11
128390000
128391000
0.000
0.000
0.044
0.014
ETS1
0.34948
0.54966
0.02537
1
0


814
chr11
128391000
128392000
0.000
0.000
0.118
0.014
ETS1
0.01415
0.04825
0.00004
1
1


815
chr12
6554000
6555000
0.000
0.000
0.029
0.000
CD27
0.22755
0.54294
0.08726
0
0


816
chr12
8762000
8763000
0.000
0.000
0.015
0.014
AICDA
1.00000
1.00000
0.29694
0
0


817
chr12
8763000
8764000
0.000
0.000
0.044
0.041
AICDA
1.00000
0.54966
0.02537
0
0


818
chr12
8764000
8765000
0.000
0.000
0.029
0.068
AICDA
0.44431
0.54294
0.08726
0
1


819
chr12
8765000
8766000
0.000
0.000
0.015
0.027
AICDA
1.00000
1.00000
0.29694
0
0


820
chr12
9823000
9824000
0.000
0.000
0.015
0.014
CLEC2D
1.00000
1.00000
0.29694
0
0


821
chr12
11710000
11711000
0.000
0.000
0.029
0.000
ETV6
0.22755
0.54294
0.08726
1
0


822
chr12
11803000
11804000
0.000
0.000
0.015
0.014
ETV6
1.00000
1.00000
0.29694
1
0


823
chr12
14923000
14924000
0.000
0.000
0.015
0.014
HIST4H4
1.00000
1.00000
0.29694
1
0


824
chr12
16717000
16718000
0.000
0.000
0.000
0.027
LMO3
0.49735
1.00000
1.00000
0
0


825
chr12
23805000
23806000
0.000
0.000
0.029
0.000
SOX5
0.22755
0.54294
0.08726
0
0


826
chr12
25149000
25150000
0.000
0.000
0.029
0.000
C12orf77
0.22755
0.54294
0.08726
0
0


827
chr12
25151000
25152000
0.000
0.000
0.015
0.014
C12orf77
1.00000
1.00000
0.29694
0
0


828
chr12
25174000
25175000
0.000
0.000
0.044
0.000
C12orf77
0.10727
0.54966
0.02537
0
0


829
chr12
25205000
25206000
0.000
0.006
0.015
0.000
LRMP
0.47887
1.00000
0.50663
1
0


830
chr12
25206000
25207000
0.000
0.006
0.103
0.014
LRMP
0.02808
0.09269
0.00099
1
1


831
chr12
25207000
25208000
0.000
0.006
0.118
0.014
LRMP
0.01415
0.04825
0.00030
1
1


832
chr12
25208000
25209000
0.000
0.000
0.029
0.014
LRMP
0.60686
0.54294
0.08726
1
0


833
chr12
25665000
25666000
0.028
0.000
0.015
0.000
IFLTD1
0.47887
1.00000
0.29694
0
0


834
chr12
38920000
38921000
0.000
0.000
0.029
0.000
CPNE8
0.22755
0.54294
0.08726
0
0


835
chr12
48027000
48028000
0.028
0.000
0.059
0.027
RPAP3
0.42627
0.65667
0.00730
0
1


836
chr12
57496000
57497000
0.000
0.000
0.015
0.014
STAT6
1.00000
1.00000
0.29694
0
0


837
chr12
69203000
69204000
0.000
0.006
0.015
0.000
MDM2
0.47887
1.00000
0.50663
0
0


838
chr12
76202000
76203000
0.000
0.000
0.000
0.027
PHLDA1
0.49735
1.00000
1.00000
0
0


839
chr12
79270000
79271000
0.000
0.000
0.029
0.027
SYT1
1.00000
0.54294
0.08726
0
0


840
chr12
82572000
82573000
0.000
0.000
0.015
0.014
CCDC59
1.00000
1.00000
0.29694
0
0


841
chr12
84837000
84838000
0.000
0.000
0.000
0.027
SLC6A15
0.49735
1.00000
1.00000
0
0


842
chr12
86114000
86115000
0.000
0.000
0.029
0.000
RASSF9
0.22755
0.54294
0.08726
0
0


843
chr12
86115000
86116000
0.000
0.000
0.029
0.000
RASSF9
0.22755
0.54294
0.08726
0
0


844
chr12
92538000
92539000
0.000
0.000
0.088
0.027
BTG1
0.15270
0.09031
0.00058
1
1


845
chr12
92539000
92540000
0.000
0.000
0.074
0.014
BTG1
0.10420
0.16101
0.00208
1
1


846
chr12
96030000
96031000
0.028
0.000
0.015
0.000
NTN4
0.47887
1.00000
0.29694
0
0


847
chr12
110171000
110172000
0.000
0.006
0.015
0.000
FAM222A
0.47887
1.00000
0.50663
0
0


848
chr12
110980000
110981000
0.000
0.000
0.015
0.014
PPTC7
1.00000
1.00000
0.29694
0
0


849
chr12
113493000
113494000
0.000
0.000
0.059
0.000
DTX1
0.05016
0.29551
0.00730
1
1


850
chr12
113494000
113495000
0.000
0.000
0.176
0.041
DTX1
0.01224
0.00730
0.00000
1
1


851
chr12
113495000
113496000
0.000
0.000
0.162
0.068
DTX1
0.11004
0.01471
0.00000
1
1


852
chr12
113496000
113497000
0.000
0.000
0.132
0.054
DTX1
0.14640
0.02564
0.00001
1
1


853
chr12
113497000
113498000
0.000
0.000
0.074
0.000
DTX1
0.02326
0.16101
0.00208
1
1


854
chr12
113499000
113500000
0.000
0.000
0.029
0.000
DTX1
0.22755
0.54294
0.08726
1
0


855
chr12
113512000
113513000
0.000
0.000
0.029
0.000
DTX1
0.22755
0.54294
0.08726
1
0


856
chr12
115966000
115967000
0.000
0.000
0.000
0.027
MED13L
0.49735
1.00000
1.00000
0
0


857
chr12
122432000
122433000
0.000
0.000
0.029
0.000
WDR66
0.22755
0.54294
0.08726
0
0


858
chr12
122433000
122434000
0.000
0.000
0.059
0.014
WDR66
0.19371
0.29551
0.00730
0
1


859
chr12
122447000
122448000
0.000
0.000
0.000
0.027
WDR66
0.49735
1.00000
1.00000
0
0


860
chr12
122458000
122459000
0.000
0.006
0.118
0.068
BCL7A
0.38669
0.04825
0.00030
1
1


861
chr12
122459000
122460000
0.000
0.006
0.324
0.108
BCL7A
0.00197
0.00003
0.00000
1
1


862
chr12
122460000
122461000
0.000
0.000
0.176
0.081
BCL7A
0.12879
0.00730
0.00000
1
1


863
chr12
122461000
122462000
0.000
0.006
0.279
0.162
BCL7A
0.10628
0.00013
0.00000
1
1


864
chr12
122462000
122463000
0.000
0.012
0.191
0.027
BCL7A
0.00186
0.00372
0.00000
1
1


865
chr12
122463000
122464000
0.000
0.012
0.132
0.054
BCL7A
0.14640
0.02564
0.00038
1
1


866
chr12
124054000
124055000
0.028
0.000
0.015
0.014
TMED2
1.00000
1.00000
0.29694
0
0


867
chr12
127965000
127966000
0.000
0.000
0.000
0.027
TMEM132C
0.49735
1.00000
1.00000
0
0


868
chr12
131303000
131304000
0.056
0.000
0.015
0.014
STX2
1.00000
0.27446
0.29694
0
1


869
chr12
131649000
131650000
0.000
0.000
0.000
0.027
GPR133
0.49735
1.00000
1.00000
0
0


870
chr12
133306000
133307000
0.028
0.000
0.015
0.027
ANKLE2
1.00000
1.00000
0.29694
0
0


871
chr13
21913000
21914000
0.000
0.000
0.029
0.000
ZDHHC20
0.22755
0.54294
0.08726
0
0


872
chr13
32116000
32117000
0.028
0.000
0.015
0.000
RXFP2
0.47887
1.00000
0.29694
0
0


873
chr13
35498000
35499000
0.000
0.000
0.015
0.027
NBEA
1.00000
1.00000
0.29694
0
0


874
chr13
38371000
38372000
0.028
0.000
0.015
0.000
TRPC4
0.47887
1.00000
0.29694
0
0


875
chr13
38630000
38631000
0.000
0.000
0.029
0.000
TRPC4
0.22755
0.54294
0.08726
0
0


876
chr13
41156000
41157000
0.000
0.000
0.029
0.000
FOXO1
0.22755
0.54294
0.08726
1
0


877
chr13
41240000
41241000
0.028
0.000
0.029
0.000
FOXO1
0.22755
1.00000
0.08726
1
0


878
chr13
46958000
46959000
0.000
0.000
0.029
0.000
KIAA0226L
0.22755
0.54294
0.08726
0
0


879
chr13
46959000
46960000
0.000
0.000
0.029
0.000
KIAA0226L
0.22755
0.54294
0.08726
0
0


880
chr13
46960000
46961000
0.000
0.000
0.088
0.027
KIAA0226L
0.15270
0.09031
0.00058
0
1


881
chr13
46961000
46962000
0.000
0.000
0.015
0.014
KIAA0226L
1.00000
1.00000
0.29694
0
0


882
chr13
46962000
46963000
0.000
0.000
0.015
0.014
KIAA0226L
1.00000
1.00000
0.29694
0
0


883
chr13
55239000
55240000
0.000
0.000
0.029
0.000
OLFM4
0.22755
0.54294
0.08726
0
0


884
chr13
55386000
55387000
0.000
0.000
0.029
0.000
OLFM4
0.22755
0.54294
0.08726
0
0


885
chr13
55598000
55599000
0.000
0.000
0.029
0.000
OLFM4
0.22755
0.54294
0.08726
0
0


886
chr13
57222000
57223000
0.000
0.000
0.029
0.000
PRR20A;
0.22755
0.54294
0.08726
0
0










PRR20DPRR20BPRR20E;







887
chr13
61343000
61344000
0.028
0.000
0.015
0.000
TDRD3
0.47887
1.00000
0.29694
0
0


888
chr13
62830000
62831000
0.000
0.000
0.000
0.027
PCDH20
0.49735
1.00000
1.00000
0
0


889
chr13
63049000
63050000
0.000
0.000
0.029
0.000
PCDH20
0.22755
0.54294
0.08726
0
0


890
chr13
63157000
63158000
0.028
0.000
0.015
0.000
AL445989.1
0.47887
1.00000
0.29694
0
0


891
chr13
63214000
63215000
0.028
0.000
0.015
0.000
AL445989.1
0.47887
1.00000
0.29694
0
0


892
chr13
64802000
64803000
0.000
0.000
0.015
0.014
AL445989.1
1.00000
1.00000
0.29694
0
0


893
chr13
65637000
65638000
0.000
0.000
0.029
0.000
PCDH9
0.22755
0.54294
0.08726
0
0


894
chr13
68656000
68657000
0.000
0.000
0.000
0.027
PCDH9
0.49735
1.00000
1.00000
0
0


895
chr13
69418000
69419000
0.000
0.000
0.029
0.014
KLHL1
0.60686
0.54294
0.08726
0
0


896
chr13
70956000
70957000
0.000
0.012
0.015
0.000
KLHL1
0.47887
1.00000
1.00000
0
0


897
chr13
74542000
74543000
0.000
0.000
0.029
0.000
KLF12
0.22755
0.54294
0.08726
0
0


898
chr13
75983000
75984000
0.000
0.000
0.074
0.014
TBC1D4
0.10420
0.16101
0.00208
0
1


899
chr13
75984000
75985000
0.000
0.000
0.118
0.027
TBC1D4
0.04838
0.04825
0.00004
0
1


900
chr13
83450000
83451000
0.000
0.000
0.029
0.000
SLITRK1
0.22755
0.54294
0.08726
0
0


901
chr13
84641000
84642000
0.000
0.000
0.015
0.014
SLITRK1
1.00000
1.00000
0.29694
0
0


902
chr13
87793000
87794000
0.000
0.000
0.015
0.014
SLITRK5
1.00000
1.00000
0.29694
0
0


903
chr13
91480000
91481000
0.000
0.000
0.000
0.027
GPC5
0.49735
1.00000
1.00000
0
0


904
chr13
106081000
106082000
0.000
0.000
0.015
0.014
DAOA
1.00000
1.00000
0.29694
0
0


905
chr13
114786000
114787000
0.000
0.000
0.015
0.027
RASA3
1.00000
1.00000
0.29694
0
0


906
chr13
114916000
114917000
0.028
0.000
0.000
0.014
RASA3
1.00000
0.34615
1.00000
0
0


907
chr14
22948000
22949000
0.000
0.000
0.029
0.000
TRAJ56
0.22755
0.54294
0.08726
0
0


908
chr14
22949000
22950000
0.000
0.000
0.044
0.000
TRAJ56
0.10727
0.54966
0.02537
0
0


909
chr14
22950000
22951000
0.000
0.000
0.029
0.000
TRAJ54
0.22755
0.54294
0.08726
0
0


910
chr14
22977000
22978000
0.000
0.000
0.015
0.014
TRAJ33
1.00000
1.00000
0.29694
0
0


911
chr14
27286000
27287000
0.000
0.000
0.029
0.000
NOVA1
0.22755
0.54294
0.08726
0
0


912
chr14
28645000
28646000
0.000
0.000
0.000
0.027
FOXG1
0.49735
1.00000
1.00000
0
0


913
chr14
49407000
49408000
0.000
0.000
0.000
0.041
RPS29
0.24603
1.00000
1.00000
0
0


914
chr14
50864000
50865000
0.000
0.000
0.029
0.000
CDKL1
0.22755
0.54294
0.08726
0
0


915
chr14
54812000
54813000
0.000
0.000
0.000
0.027
CDKN3
0.49735
1.00000
1.00000
0
0


916
chr14
55348000
55349000
0.000
0.000
0.029
0.000
GCH1
0.22755
0.54294
0.08726
0
0


917
chr14
59827000
59828000
0.000
0.000
0.029
0.000
DAAM1
0.22755
0.54294
0.08726
0
0


918
chr14
63143000
63144000
0.000
0.000
0.015
0.014
KCNH5
1.00000
1.00000
0.29694
0
0


919
chr14
64194000
64195000
0.000
0.000
0.015
0.014
SGPP1
1.00000
1.00000
0.29694
0
0


920
chr14
69258000
69259000
0.000
0.000
0.191
0.027
ZFP36L1
0.00186
0.00372
0.00000
1
1


921
chr14
69259000
69260000
0.000
0.012
0.265
0.068
ZFP36L1
0.00244
0.00024
0.00000
1
1


922
chr14
78418000
78419000
0.000
0.000
0.029
0.000
ADCK1
0.22755
0.54294
0.08726
0
0


923
chr14
81685000
81686000
0.028
0.000
0.015
0.000
GTFZA1
0.47887
1.00000
0.29694
0
0


924
chr14
84420000
84421000
0.000
0.006
0.015
0.000
FLRT2
0.47887
1.00000
0.50663
0
0


925
chr14
91883000
91884000
0.000
0.000
0.015
0.014
CCDC88C
1.00000
1.00000
0.29694
0
0


926
chr14
94941000
94942000
0.000
0.006
0.029
0.014
SERPINA9
0.60686
0.54294
0.21104
1
0


927
chr14
94942000
94943000
0.000
0.000
0.118
0.014
SERPINA9
0.01415
0.04825
0.00004
1
1


928
chr14
96179000
96180000
0.028
0.037
0.132
0.108
TCL1A
0.79702
0.15881
0.01566
1
1


929
chr14
96180000
96181000
0.028
0.025
0.088
0.054
TCL1A
0.52007
0.41714
0.06858
1
1


930
chr14
101597000
101598000
0.000
0.000
0.000
0.027
AL117190.3
0.49735
1.00000
1.00000
0
0


931
chr14
102285000
102286000
0.000
0.000
0.015
0.014
PPP2R5C
1.00000
1.00000
0.29694
0
0


932
chr14
105954000
105955000
0.000
0.000
0.044
0.014
CRIP1
0.34948
0.54966
0.02537
0
0


933
chr14
106031000
106032000
0.000
0.000
0.015
0.014
IGHA2
1.00000
1.00000
0.29694
0
0


934
chr14
106042000
106043000
0.000
0.019
0.103
0.041
IGHA2
0.19468
0.09269
0.00855
0
1


935
chr14
106048000
106049000
0.000
0.006
0.015
0.000
IGHA2
0.47887
1.00000
0.50663
0
0


936
chr14
106054000
106055000
0.000
0.000
0.029
0.014
IGHA2
0.60686
0.54294
0.08726
0
0


937
chr14
106055000
106056000
0.056
0.000
0.103
0.027
IGHA2
0.08710
0.49207
0.00016
0
1


938
chr14
106056000
106057000
0.056
0.006
0.074
0.027
IGHA2
0.25970
1.00000
0.00953
0
1


939
chr14
106057000
106058000
0.000
0.000
0.059
0.000
IGHA2
0.05016
0.29551
0.00730
0
1


940
chr14
106058000
106059000
0.000
0.000
0.029
0.000
IGHA2
0.22755
0.54294
0.08726
0
0


941
chr14
106066000
106067000
0.000
0.000
0.059
0.000
IGHE
0.05016
0.29551
0.00730
0
1


942
chr14
106067000
106068000
0.000
0.000
0.044
0.014
IGHE
0.34948
0.54966
0.02537
0
0


943
chr14
106068000
106069000
0.000
0.000
0.103
0.027
IGHE
0.08710
0.09269
0.00016
0
1


944
chr14
106069000
106070000
0.000
0.006
0.206
0.216
IGHE
1.00000
0.00197
0.00000
0
1


945
chr14
106070000
106071000
0.000
0.000
0.088
0.068
IGHE
0.75773
0.09031
0.00058
0
1


946
chr14
106071000
106072000
0.000
0.000
0.074
0.068
IGHE
1.00000
0.16101
0.00208
0
1


947
chr14
106072000
106073000
0.000
0.000
0.029
0.014
IGHE
0.60686
0.54294
0.08726
0
0


948
chr14
106082000
106083000
0.000
0.000
0.015
0.027
IGHG4
1.00000
1.00000
0.29694
0
0


949
chr14
106092000
106093000
0.000
0.000
0.029
0.000
IGHG4
0.22755
0.54294
0.08726
0
0


950
chr14
106094000
106095000
0.000
0.006
0.147
0.027
IGHG4
0.01393
0.01404
0.00003
0
1


951
chr14
106095000
106096000
0.000
0.000
0.103
0.081
IGHG4
0.77363
0.09269
0.00016
0
1


952
chr14
106110000
106111000
0.000
0.000
0.074
0.014
IGHG2
0.10420
0.16101
0.00208
0
1


953
chr14
106111000
106112000
0.000
0.000
0.015
0.014
IGHG2
1.00000
1.00000
0.29694
0
0


954
chr14
106112000
106113000
0.000
0.056
0.294
0.257
IGHG2
0.70749
0.00011
0.00000
0
1


955
chr14
106113000
106114000
0.028
0.068
0.397
0.284
IGHG2
0.16121
0.00002
0.00000
0
1


956
chr14
106114000
106115000
0.000
0.000
0.279
0.122
IGHG2
0.02111
0.00013
0.00000
0
1


957
chr14
106146000
106147000
0.000
0.000
0.029
0.000
IGHA1
0.22755
0.54294
0.08726
0
0


958
chr14
106151000
106152000
0.000
0.006
0.015
0.014
IGHA1
1.00000
1.00000
0.50663
0
0


959
chr14
106152000
106153000
0.000
0.006
0.015
0.027
IGHA1
1.00000
1.00000
0.50663
0
0


960
chr14
106161000
106162000
0.000
0.000
0.015
0.014
IGHA1
1.00000
1.00000
0.29694
0
0


961
chr14
106173000
106174000
0.028
0.006
0.029
0.027
IGHA1
1.00000
1.00000
0.21104
0
0


962
chr14
106174000
106175000
0.000
0.006
0.029
0.000
IGHA1
0.22755
0.54294
0.21104
0
0


963
chr14
106175000
106176000
0.028
0.006
0.059
0.014
IGHA1
0.19371
0.65667
0.02818
0
1


964
chr14
106176000
106177000
0.139
0.031
0.103
0.068
IGHA1
0.55139
0.74810
0.04551
0
1


965
chr14
106177000
106178000
0.000
0.019
0.059
0.027
IGHA1
0.42627
0.29551
0.20027
0
1


966
chr14
106178000
106179000
0.000
0.006
0.059
0.014
IGHA1
0.19371
0.295SI
0.02818
0
1


967
chr14
106208000
106209000
0.000
0.000
0.103
0.027
IGHG1
0.08710
0.09269
0.00016
0
1


968
chr14
106209000
106210000
0.000
0.006
0.118
0.054
IGHG1
0.23086
0.04825
0.00030
0
1


969
chr14
106210000
106211000
0.000
0.000
0.118
0.068
IGHG1
0.38669
0.04825
0.00004
0
1


970
chr14
106211000
106212000
0.000
0.056
0.235
0.149
IGHG1
0.20587
0.00098
0.00025
0
1


971
chr14
106212000
106213000
0.028
0.106
0.309
0.270
IGHG1
0.71144
0.00070
0.00035
0
1


972
chr14
106213000
106214000
0.056
0.068
0.382
0.216
IGHG1
0.04243
0.00034
0.00000
0
1


973
chr14
106214000
106215000
0.000
0.000
0.147
0.000
IGHG1
0.00044
0.01404
0.00000
0
1


974
chr14
106237000
106238000
0.000
0.000
0.088
0.000
IGHG3
0.01070
0.09031
0.00058
0
1


975
chr14
106238000
106239000
0.000
0.000
0.176
0.027
IGHG3
0.003 70
0.00730
0.00000
0
1


976
chr14
106239000
106240000
0.056
0.062
0.206
0.135
IGHG3
0.27339
0.04910
0.00349
0
1


977
chr14
106240000
106241000
0.028
0.130
0.324
0.230
IGHG3
0.25971
0.00034
0.00136
0
1


978
chr14
106241000
106242000
0.000
0.025
0.221
0.081
IGHG3
0.03144
0.00107
0.00000
0
1


979
chr14
106242000
106243000
0.000
0.000
0.044
0.014
IGHG3
0.34948
0.54966
0.02537
0
0


980
chr14
106321000
106322000
0.000
0.000
0.059
0.000
IGHM
0.05016
0.29551
0.00730
0
1


981
chr14
106322000
106323000
0.000
0.006
0.221
0.054
IGHM
0.00556
0.00107
0.00000
0
1


982
chr14
106323000
106324000
0.056
0.062
0.235
0.162
IGHM
0.29797
0.02782
0.00040
0
1


983
chr14
106324000
106325000
0.250
0.193
0.221
0.284
IGHM
0.44266
0.80827
0.71834
0
1


984
chr14
106325000
106326000
0.694
0.335
0.279
0.365
IGHM
0.28848
0.00006
0.44111
0
1


985
chr14
106326000
106327000
0.833
0.540
0.838
0.838
IGHJ6
1.00000
1.00000
0.00001
0
1


986
chr14
106327000
106328000
0.333
0.335
0.926
0.905
IGHJ6
0.76698
0.00000
0.00000
0
1


987
chr14
106328000
106329000
0.250
0.248
0.809
0.730
IGHJ6
0.32171
0.00000
0.00000
0
1


988
chr14
106329000
106330000
0.694
0.441
0.882
0.932
IGHJ6
0.38669
0.03086
0.00000
0
1


989
chr14
106330000
106331000
0.694
0.298
0.574
0.649
IGHJ3; IGHJ4; IGHJ5;
0.39187
0.29080
0.00017
0
1


990
chr14
106331000
106332000
0.028
0.012
0.044
0.027
IGHD7-27;
0.67043
1.00000
0.15671
0
0










IGHJ1; IGHJ2;







991
chr14
106338000
106339000
0.028
0.006
0.000
0.000
IGHD7-27
1.00000
0.34615
2.00000
0
0


992
chr14
106350000
106351000
0.000
0.006
0.029
0.000
IGHD4-23
0.22755
0.54294
0.21104
0
0


993
chr14
106352000
106353000
0.000
0.000
0.029
0.000
IGHD3-22
0.22755
0.54294
0.08726
0
0


994
chr14
106353000
106354000
0.000
0.006
0.029
0.000
IGHD2-21
0.22755
0.54294
0.21104
0
0


995
chr14
106354000
106355000
0.000
0.006
0.015
0.000
IGHD2-21
0.47887
1.00000
0.50663
0
0


996
chr14
106355000
106356000
0.000
0.000
0.044
0.000
IGHD2-21
0.10727
0.54966
0.02537
0
0


997
chr14
106357000
106358000
0.028
0.000
0.059
0.000
IGHD1-20; IGHD6-19;
0.05016
0.65667
0.00730
0
1


998
chr14
106358000
106359000
0.000
0.006
0.029
0.000
IGHD5-18
0.22755
0.54294
0.21104
0
0


999
chr14
106362000
106363000
0.028
0.006
0.000
0.000
IGHD3-16
1.00000
0.34615
1.00000
0
0


1000
chr14
106364000
106365000
0.000
0.000
0.029
0.000
IGHD2-15
0.22755
0.54294
0.08726
0
0


1001
chr14
106367000
106368000
0.000
0.000
0.029
0.000
IGHD6-13
0.22755
0.54294
0.08726
0
0


1002
chr14
106370000
106371000
0.000
0.012
0.044
0.014
IGHD3-10; IGHD3-9;
0.34948
0.54966
0.15671
0
0


1003
chr14
106371000
106372000
0.000
0.012
0.029
0.014
IGHD3-9
0.60686
0.54294
0.58408
0
0


1004
chr14
106372000
106373000
0.000
0.006
0.015
0.000
IGHD2-8
0.47887
1.00000
0.50663
0
0


1005
chr14
106375000
106376000
0.000
0.019
0.015
0.000
IGHD1-7
0.47887
1.00000
1.00000
0
0


1006
chr14
106376000
106377000
0.000
0.012
0.015
0.000
IGHD6-6
0.47887
1.00000
1.00000
0
0


1007
chr14
106380000
106381000
0.000
0.031
0.000
0.000
IGHD3-3
1.00000
1.00000
0.32529
0
0


1008
chr14
106381000
106382000
0.000
0.031
0.000
0.000
IGHD2-2
1.00000
1.00000
0.32529
0
0


1009
chr14
106382000
106383000
0.000
0.037
0.044
0.014
IGHD2-2
0.34948
0.54966
0.72719
0
0


1010
chr14
106383000
106384000
0.000
0.000
0.044
0.014
IGHD2-2
0.34948
0.54966
0.02537
0
0


1011
chr14
106384000
106385000
0.000
0.012
0.044
0.014
IGHD1-1
0.34948
0.54966
0.15671
0
0


1012
chr14
106385000
106386000
0.000
0.000
0.029
0.014
IGHD1-1
0.60686
0.54294
0.08726
0
0


1013
chr14
106387000
106388000
0.000
0.000
0.029
0.014
KIAA0125
0.60686
0.54294
0.08726
0
0


1014
chr14
106405000
106406000
0.000
0.006
0.015
0.014
IGHV6-1
1.00000
1.00000
0.50663
0
0


1015
chr14
106406000
106407000
0.000
0.006
0.015
0.014
IGHV6-1
1.00000
1.00000
0.50663
0
0


1016
chr14
106419000
106420000
0.000
0.006
0.015
0.000
IGHV6-1
0.47887
1.00000
0.50663
0
0


1017
chr14
106452000
106453000
0.000
0.006
0.029
0.000
IGHV1-2
0.22755
0.54294
0.21104
0
0


1018
chr14
106453000
106454000
0.000
0.006
0.044
0.000
IGHV1-2
0.10727
0.54966
0.07959
0
0


1019
chr14
106454000
106455000
0.000
0.000
0.029
0.000
IGHV1-2
0.22755
0.54294
0.08726
0
0


1020
chr14
106494000
106495000
0.000
0.019
0.000
0.014
IGHV2-5
1.00000
1.00000
0.55662
0
0


1021
chr14
106518000
106519000
0.028
0.037
0.000
0.054
IGHV3-7
0.12104
0.34615
0.18288
0
1


1022
chr14
106519000
106520000
0.000
0.012
0.000
0.027
IGHV3-7
0.49735
1.00000
1.00000
0
0


1023
chr14
106539000
106540000
0.000
0.031
0.015
0.000
IGHV1-8
0.47887
1.00000
0.67240
0
0


1024
chr14
106552000
106553000
0.000
0.006
0.029
0.014
IGHV3-9
0.60686
0.54294
0.21104
0
0


1025
chr14
106573000
106574000
0.000
0.019
0.029
0.068
IGHV3-11
0.44431
0.54294
0.63492
0
1


1026
chr14
106574000
106575000
0.000
0.006
0.029
0.041
IGHV3-11
1.00000
0.54294
0.21104
0
0


1027
chr14
106578000
106579000
0.000
0.000
0.015
0.027
IGHV3-11
1.00000
1.00000
0.29694
0
0


1028
chr14
106579000
106580000
0.000
0.000
0.015
0.027
IGHV3-11
1.00000
1.00000
0.29694
0
0


1029
chr14
106610000
106611000
0.056
0.012
0.029
0.000
IGHV3-15
0.22755
0.60763
0.58408
0
1


1030
chr14
106641000
106642000
0.000
0.019
0.015
0.000
IGHV1-18
0.47887
1.00000
1.00000
0
0


1031
chr14
106642000
106643000
0.000
0.012
0.015
0.000
IGHV1-18
0.47887
1.00000
1.00000
0
0


1032
chr14
106691000
106692000
0.000
0.012
0.029
0.027
IGHV3-21
1.00000
0.54294
0.58408
0
0


1033
chr14
106692000
106693000
0.000
0.006
0.015
0.041
IGHV3-21
0.62100
1.00000
0.50663
0
0


1034
chr14
106725000
106726000
0.083
0.068
0.103
0.135
IGHV3-23
0.61250
1.00000
0.42238
0
1


1035
chr14
106726000
106727000
0.028
0.019
0.088
0.095
IGHV3-23
1.00000
0.41714
0.02173
0
1


1036
chr14
106733000
106734000
0.028
0.006
0.015
0.027
IGHV1-24
1.00000
1.00000
0.50663
0
0


1037
chr14
106757000
106758000
0.056
0.000
0.015
0.000
IGHV2-26
0.47887
0.27446
0.29694
0
1


1038
chr14
106758000
106759000
0.056
0.000
0.000
0.000
IGHV2-26
1.00000
0.11763
1.00000
0
1


1039
chr14
106791000
106792000
0.056
0.006
0.015
0.000
IGHV3-30
0.47887
0.27446
0.50663
0
1


1040
chr14
106804000
106805000
0.000
0.006
0.029
0.000
IGHV4-31
0.22755
0.54294
0.21104
0
0


1041
chr14
106805000
106806000
0.000
0.006
0.044
0.014
IGHV4-31
0.34948
0.54966
0.07959
0
0


1042
chr14
106806000
106807000
0.000
0.006
0.015
0.000
IGHV4-31
0.47887
1.00000
0.50663
0
0


1043
chr14
106815000
106816000
0.000
0.012
0.044
0.027
IGHV3-33
0.67043
0.54966
0.15671
0
0


1044
chr14
106816000
106817000
0.000
0.006
0.074
0.014
IGHV3-33
0.10420
0.16101
0.00953
0
1


1045
chr14
106817000
106818000
0.000
0.000
0.029
0.000
IGHV3-33
0.22755
0.54294
0.08726
0
0


1046
chr14
106829000
106830000
0.167
0.050
0.162
0.135
IGHV4-34
0.81354
1.00000
0.00804
0
1


1047
chr14
106830000
106831000
0.028
0.043
0.118
0.135
IGHV4-34
0.80514
0.15803
0.07447
0
1


1048
chr14
106877000
106878000
0.056
0.006
0.015
0.041
IGHV4-39
0.62100
0.27446
0.50663
0
1


1049
chr14
106878000
106879000
0.028
0.012
0.044
0.041
IGHV4-39
1.00000
1.00000
0.15671
0
0


1050
chr14
106967000
106968000
0.056
0.000
0.015
0.000
IGHV1-46
0.47887
0.27446
0.29694
0
1


1051
chr14
106994000
106995000
0.028
0.012
0.088
0.122
IGHV3-48
0.59201
0.41714
0.00949
0
1


1052
chr14
106995000
106996000
0.000
0.000
0.000
0.027
IGHV3-48
0.49735
1.00000
1.00000
0
0


1053
chr14
107034000
107035000
0.028
0.000
0.000
0.014
IGHV5-51
1.00000
0.34615
1.00000
0
0


1054
chr14
107035000
107036000
0.000
0.006
0.029
0.014
IGHV5-51
0.60686
0.54294
0.21104
0
0


1055
chr14
107048000
107049000
0.028
0.006
0.000
0.000
IGHV3-53
1.00000
0.34615
1.00000
0
0


1056
chr14
107049000
107050000
0.000
0.012
0.044
0.027
IGHV3-53
0.67043
0.54966
0.15671
0
0


1057
chr14
107083000
107084000
0.000
0.006
0.044
0.054
IGHV4-59
1.00000
0.54966
0.07959
0
1


1058
chr14
107084000
107085000
0.000
0.006
0.029
0.027
IGHV4-59
1.00000
0.54294
0.21104
0
0


1059
chr14
107095000
107096000
0.000
0.006
0.015
0.000
IGHV4-61
0.47887
1.00000
0.50663
0
0


1060
chr14
107113000
107114000
0.000
0.000
0.029
0.000
IGHV3-64
0.22755
0.54294
0.08726
0
0


1061
chr14
107114000
107115000
0.000
0.000
0.029
0.000
IGHV3-64
0.22755
0.54294
0.08726
0
0


1062
chr14
107169000
107170000
0.056
0.068
0.206
0.041
IGHV1-69
0.00346
0.04910
0.00442
0
1


1063
chr14
107170000
107171000
0.028
0.075
0.294
0.095
IGHV1-69
0.00279
0.00075
0.00004
0
1


1064
chr14
107176000
107177000
0.028
0.006
0.118
0.027
IGHV2-70
0.04838
0.15803
0.00030
0
1


1065
chr14
107177000
107178000
0.000
0.000
0.044
0.027
IGHV2-70
0.67043
0.54966
0.02537
0
0


1066
chr14
107178000
107179000
0.056
0.161
0.456
0.284
IGHV2-70
0.03781
0.00002
0.00001
0
1


1067
chr14
107179000
107180000
0.056
0.180
0.382
0.338
IGHV2-70
0.60350
0.00034
0.00206
0
1


1068
chr14
107183000
107184000
0.000
0.006
0.029
0.000
IGHV2-70
0.22755
0.54294
0.21104
0
0


1069
chr14
107199000
107200000
0.000
0.012
0.015
0.000
IGHV3-72
0.47887
1.00000
1.00000
0
0


1070
chr14
107218000
107219000
0.028
0.012
0.015
0.000
IGHV3-74
0.47887
1.00000
1.00000
0
0


1071
chr14
107219000
107220000
0.000
0.012
0.074
0.027
IGHV3-74
0.25970
0.16101
0.02559
0
1


1072
chr14
107221000
107222000
0.000
0.000
0.059
0.000
IGHV3-74
0.05016
0.29551
0.00730
0
1


1073
chr14
107232000
107233000
0.000
0.000
0.029
0.000
IGHV3-74
0.22755
0.54294
0.08726
0
0


1074
chr14
107253000
107254000
0.000
0.000
0.044
0.014
IGHV7-81
0.34948
0.54966
0.02537
0
0


1075
chr14
107258000
107259000
0.000
0.000
0.015
0.014
IGHV7-81
1.00000
1.00000
0.29694
0
0


1076
chr14
107259000
107260000
0.000
0.025
0.235
0.027
IGHV7-81
0.00021
0.00098
0.00000
0
1


1077
chr15
45003000
45004000
0.000
0.000
0.044
0.000
B2M
0.10727
0.54966
0.02537
0
0


1078
chr15
45007000
45008000
0.000
0.000
0.044
0.000
B2M
0.10727
0.54966
0.02537
0
0


1079
chr15
45814000
45815000
0.000
0.000
0.015
0.014
SLC30A4
1.00000
1.00000
0.29694
0
0


1080
chr15
59664000
59665000
0.000
0.000
0.044
0.041
MYO1E
1.00000
0.54966
0.02537
0
0


1081
chr15
65588000
65589000
0.028
0.000
0.000
0.014
PARP16
1.00000
0.34615
1.00000
0
0


1082
chr15
78332000
78333000
0.028
0.000
0.000
0.014
TBC1D2B
1.00000
0.34615
1.00000
0
0


1083
chr15
83227000
83228000
0.000
0.000
0.029
0.000
CPEB1
0.22755
0.54294
0.08726
0
0


1084
chr15
86226000
86227000
0.000
0.000
0.044
0.000
AKAP13
0.10727
0.54966
0.02537
0
0


1085
chr15
86233000
86234000
0.000
0.000
0.029
0.014
AKAP13
0.60686
0.54294
0.08726
0
0


1086
chr15
86245000
86246000
0.000
0.000
0.059
0.000
AKAP13
0.05016
0.29551
0.00730
0
1


1087
chr16
368000
369000
0.000
0.000
0.015
0.014
AXIN1
1.00000
1.00000
0.29694
0
0


1088
chr16
3788000
3789000
0.000
0.000
0.015
0.014
CREBBP
1.00000
1.00000
0.29694
0
0


1089
chr16
10971000
10972000
0.000
0.000
0.162
0.041
CHTA
0.02233
0.01471
0.00000
1
1


1090
chr16
10972000
10973000
0.000
0.000
0.191
0.081
CHTA
0.08249
0.00372
0.00000
1
1


1091
chr16
10973000
10974000
0.000
0.000
0.162
0.095
CHTA
0.31342
0.01471
0.00000
1
1


1092
chr16
10974000
10975000
0.000
0.000
0.059
0.000
CHTA
0.05016
0.29551
0.00730
1
1


1093
chr16
11348000
11349000
0.000
0.000
0.191
0.027
SOCS1
0.00186
0.00372
0.00000
1
1


1094
chr16
11349000
11350000
0.000
0.000
0.221
0.041
SOCS1
0.00179
0.00107
0.00000
1
1


1095
chr16
21167000
21168000
0.000
0.000
0.015
0.014
DNAH3
1.00000
1.00000
0.29694
0
0


1096
chr16
27325000
27326000
0.000
0.000
0.029
0.041
CTD-3203P2.2
1.00000
0.54294
0.08726
0
0


1097
chr16
27326000
27327000
0.000
0.000
0.088
0.041
CTD-3203P2.2
0.31126
0.09031
0.00058
0
1


1098
chr16
27327000
27328000
0.000
0.000
0.029
0.000
IL4R
0.22755
0.54294
0.08726
0
0


1099
chr16
27414000
27415000
0.000
0.000
0.029
0.000
IL21R
0.22755
0.54294
0.08726
0
0


1100
chr16
29248000
29249000
0.000
0.000
0.029
0.000
61E3.4
0.22755
0.54294
0.08726
0
0


1101
chr16
31910000
31911000
0.000
0.000
0.015
0.014
ZNF267
1.00000
1.00000
0.29694
0
0


1102
chr16
46821000
46822000
0.000
0.000
0.015
0.014
C16orf87
1.00000
1.00000
0.29694
0
0


1103
chr16
50985000
50986000
0.000
0.000
0.015
0.014
CYLD
1.00000
1.00000
0.29694
0
0


1104
chr16
64351000
64352000
0.000
0.000
0.029
0.014
CDH11
0.60686
0.54294
0.08726
0
0


1105
chr16
78398000
78399000
0.000
0.000
0.000
0.027
WWOX
0.49735
1.00000
1.00000
0
0


1106
chr16
78615000
78616000
0.000
0.000
0.015
0.014
WWOX
1.00000
1.00000
0.29694
0
0


1107
chr16
78753000
78754000
0.000
0.000
0.015
0.014
WWOX
1.00000
1.00000
0.29694
0
0


1108
chr16
78811000
78812000
0.000
0.000
0.000
0.027
WWOX
0.49735
1.00000
1.00000
0
0


1109
chr16
79988000
79989000
0.000
0.000
0.015
0.014
MAF
1.00000
1.00000
0.29694
0
0


1110
chr16
81836000
81837000
0.000
0.000
0.029
0.000
PLCG2
0.22755
0.54294
0.08726
0
0


1111
chr16
85932000
85933000
0.000
0.000
0.059
0.027
IRF8
0.42627
0.29551
0.00730
1
1


1112
chr16
85933000
85934000
0.000
0.012
0.221
0.081
IRF8
0.03144
0.00107
0.00000
1
1


1113
chr16
85934000
85935000
0.000
0.006
0.015
0.027
IRF8
1.00000
1.00000
0.50663
1
0


1114
chr16
85936000
85937000
0.000
0.000
0.029
0.000
IRF8
0.22755
0.54294
0.08726
1
0


1115
chr16
88441000
88442000
0.000
0.000
0.015
0.014
ZNF469
1.00000
1.00000
0.29694
0
0


1116
chr17
3598000
3599000
0.000
0.000
0.029
0.014
P2RX5; P2RX5-
0.60686
0.54294
0.08726
0
0










TAX1BP3P2RX5;







1117
chr17
17286000
17287000
0.000
0.000
0.029
0.000
SMCR9
0.22755
0.54294
0.08726
0
0


1118
chr17
21194000
21195000
0.000
0.000
0.015
0.041
MAP2K3
0.62100
1.00000
0.29694
0
0


1119
chr17
29646000
29647000
0.000
0.000
0.029
0.014
EVI2A
0.60686
0.54294
0.08726
0
0


1120
chr17
38020000
38021000
0.000
0.000
0.029
0.014
IKZF3
0.60686
0.54294
0.08726
0
0


1121
chr17
43662000
43663000
0.000
0.000
0.029
0.000
PLEKHM1
0.22755
0.54294
0.08726
0
0


1122
chr17
56408000
56409000
0.000
0.006
0.059
0.027
BZRAP1
0.42627
0.29551
0.02818
0
1


1123
chr17
56409000
56410000
0.000
0.000
0.265
0.027
BZRAP1
0.00005
0.00024
0.00000
0
1


1124
chr17
57916000
57917000
0.000
0.000
0.029
0.014
VMP1
0.60686
0.54294
0.08726
1
0


1125
chr17
57917000
57918000
0.000
0.000
0.029
0.000
VMP1
0.22755
0.54294
0.08726
1
0


1126
chr17
62007000
62008000
0.000
0.000
0.029
0.000
CD79B
0.22755
0.54294
0.08726
0
0


1127
chr17
62008000
62009000
0.000
0.000
0.044
0.014
CD79B
0.34948
0.54966
0.02537
0
0


1128
chr17
63067000
63068000
0.000
0.000
0.015
0.014
GNA13
1.00000
1.00000
0.29694
0
0


1129
chr17
65676000
65677000
0.000
0.000
0.029
0.000
PITPNC1
0.22755
0.54294
0.08726
0
0


1130
chr17
69365000
69366000
0.000
0.000
0.015
0.014
AC007461.J
1.00000
1.00000
0.29694
0
0


1131
chr17
70083000
70084000
0.028
0.000
0.000
0.014
SOX9
1.00000
0.34615
1.00000
0
0


1132
chr17
74733000
74734000
0.000
0.000
0.000
0.027
SRSF2
0.49735
1.00000
1.00000
0
0


1133
chr17
75447000
75448000
0.000
0.000
0.044
0.000
9-Sep-19
0.10727
0.54966
0.02537
0
0


1134
chr17
75448000
75449000
0.000
0.000
0.044
0.000
9-Sep-19
0.10727
0.54966
0.02537
0
0


1135
chr17
76775000
76776000
0.000
0.000
0.000
0.027
CYTH1
0.49735
1.00000
1.00000
0
0


1136
chr17
80928000
80929000
0.000
0.000
0.029
0.000
B3GNTL1
0.22755
0.54294
0.08726
0
0


1137
chr17
80976000
80977000
0.000
0.000
0.015
0.014
B3GNTL1
1.00000
1.00000
0.29694
0
0


1138
chr18
2709000
2710000
0.000
0.000
0.029
0.000
SMCHD1
0.22755
0.54294
0.08726
0
0


1139
chr18
3600000
3601000
0.000
0.000
0.015
0.014
DLGAP1
1.00000
1.00000
0.29694
0
0


1140
chr18
12062000
12063000
0.000
0.000
0.000
0.041
ANKRD62
0.24603
1.00000
1.00000
0
0


1141
chr18
27771000
27772000
0.000
0.000
0.029
0.000
DSC3
0.22755
0.54294
0.08726
0
0


1142
chr18
28066000
28067000
0.000
0.000
0.029
0.000
DSC3
0.22755
0.54294
0.08726
0
0


1143
chr18
30349000
30350000
0.000
0.000
0.000
0.027
AC012123.1; KLHL14;
0.49735
1.00000
1.00000
0
0


1144
chr18
36806000
36807000
0.000
0.000
0.029
0.000
CELF4
0.22755
0.54294
0.08726
0
0


1145
chr18
37751000
37752000
0.000
0.000
0.015
0.014
PIK3C3
1.00000
1.00000
0.29694
0
0


1146
chr18
38672000
38673000
0.028
0.000
0.000
0.014
PIK3C3
1.00000
0.34615
1.00000
0
0


1147
chr18
42168000
42169000
0.028
0.000
0.000
0.014
SETBP1
1.00000
0.34615
1.00000
0
0


1148
chr18
51952000
51953000
0.000
0.000
0.029
0.000
C18orf54
0.22755
0.54294
0.08726
0
0


1149
chr18
52447000
52448000
0.000
0.000
0.015
0.014
RAB27B
1.00000
1.00000
0.29694
0
0


1150
chr18
52988000
52989000
0.000
0.000
0.029
0.000
TCF4
0.22755
0.54294
0.08726
0
0


1151
chr18
54653000
54654000
0.000
0.000
0.000
0.027
WDR7
0.49735
1.00000
1.00000
0
0


1152
chr18
60794000
60795000
0.000
0.000
0.029
0.000
BCL2
0.22755
0.54294
0.08726
1
0


1153
chr18
60805000
60806000
0.000
0.000
0.074
0.081
BCL2
1.00000
0.16101
0.00208
1
1


1154
chr18
60806000
60807000
0.000
0.006
0.132
0.122
BCL2
1.00000
0.02564
0.00009
1
1


1155
chr18
60809000
60810000
0.000
0.000
0.059
0.027
BCL2
0.42627
0.29551
0.00730
1
1


1156
chr18
60821000
60822000
0.000
0.000
0.029
0.000
BCL2
0.22755
0.54294
0.08726
1
0


1157
chr18
60825000
60826000
0.000
0.000
0.044
0.027
BCL2
0.67043
0.54966
0.02537
1
0


1158
chr18
60826000
60827000
0.000
0.000
0.029
0.000
BCL2
0.22755
0.54294
0.08726
1
0


1159
chr18
60828000
60829000
0.000
0.000
0.015
0.027
BCL2
1.00000
1.00000
0.29694
1
0


1160
chr18
60873000
60874000
0.000
0.000
0.044
0.027
BCL2
0.67043
0.54966
0.02537
1
0


1161
chr18
60875000
60876000
0.000
0.000
0.044
0.027
BCL2
0.67043
0.54966
0.02537
1
0


1162
chr18
60876000
60877000
0.000
0.000
0.015
0.054
BCL2
0.36833
1.00000
0.29694
1
1


1163
chr18
60983000
60984000
0.000
0.006
0.059
0.068
BCL2
1.00000
0.29551
0.02818
1
1


1164
chr18
60984000
60985000
0.000
0.012
0.176
0.459
BCL2
0.00034
0.00730
0.00001
1
1


1165
chr18
60985000
60986000
0.000
0.000
0.221
0.635
BCL2
0.00000
0.00107
0.00000
1
1


1166
chr18
60986000
60987000
0.000
0.019
0.235
0.730
BCL2
0.00000
0.00098
0.00000
1
1


1167
chr18
60987000
60988000
0.000
0.019
0.191
0.500
BCL2
0.00019
0.00372
0.00001
1
1


1168
chr18
60988000
60989000
0.000
0.012
0.221
0.595
BCL2
0.00001
0.00107
0.00000
1
1


1169
chr18
61810000
61811000
0.000
0.000
0.015
0.014
SERPINB8
1.00000
1.00000
0.29694
0
0


1170
chr1s
63080000
63081000
0.000
0.000
0.029
0.000
CDH7
0.22755
0.54294
0.08726
0
0


1171
chr18
63791000
63792000
0.028
0.000
0.015
0.000
CDH7
0.47887
1.00000
0.29694
0
0


1172
chr18
63875000
63876000
0.000
0.000
0.029
0.000
CDH19
0.22755
0.54294
0.08726
0
0


1173
chr18
64643000
64644000
0.000
0.000
0.029
0.000
CDH19
0.22755
0.54294
0.08726
0
0


1174
chr18
65863000
65864000
0.000
0.000
0.000
0.027
TMX3
0.49735
1.00000
1.00000
0
0


1175
chr18
66328000
66329000
0.000
0.000
0.015
0.014
TMX3
1.00000
1.00000
0.29694
0
0


1176
chr18
70462000
70463000
0.000
0.000
0.015
0.014
NETO1
1.00000
1.00000
0.29694
0
0


1177
chr18
73767000
73768000
0.000
0.000
0.015
0.014
ZNF516
1.00000
1.00000
0.29694
0
0


1178
chr1s
76515000
76516000
0.000
0.000
0.029
0.014
SALL3
0.60686
0.54294
0.08726
0
0


1179
chr18
76724000
76725000
0.000
0.000
0.015
0.014
SALL3
1.00000
1.00000
0.29694
0
0


1180
chr18
76725000
76726000
0.000
0.000
0.015
0.014
SALL3
1.00000
1.00000
0.29694
0
0


1181
chr19
1612000
1613000
0.056
0.000
0.000
0.000
TCF3
1.00000
0.11763
1.00000
0
1


1182
chr19
2476000
2477000
0.000
0.000
0.029
0.000
GADD45B
0.22755
0.54294
0.08726
1
0


1183
chr19
10304000
10305000
0.000
0.000
0.059
0.000
DNMT1
0.05016
0.29551
0.00730
0
1


1184
chr19
10305000
10306000
0.000
0.000
0.044
0.000
DNMT1
0.10727
0.54966
0.02537
0
0


1185
chr19
10335000
10336000
0.000
0.000
0.015
0.014
SIPR2
1.00000
1.00000
0.29694
1
0


1186
chr19
10340000
10341000
0.000
0.000
0.118
0.041
SIPR2
0.11795
0.04825
0.00004
1
1


1187
chr19
10341000
10342000
0.000
0.012
0.206
0.054
SIPR2
0.01013
0.00197
0.00000
1
1


1188
chr19
16030000
16031000
0.028
0.000
0.015
0.000
CYP4F11
0.47887
1.00000
0.29694
0
0


1189
chr19
16436000
16437000
0.000
0.000
0.029
0.014
KLF2
0.60686
0.54294
0.08726
1
0


1190
chr19
20889000
20890000
0.000
0.006
0.015
0.000
ZNF626
0.47887
1.00000
0.50663
0
0


1191
chr19
21073000
21074000
0.000
0.000
0.015
0.027
ZNF85
1.00000
1.00000
0.29694
0
0


1192
chr19
21092000
21093000
0.000
0.000
0.029
0.000
ZNF85
0.22755
0.54294
0.08726
0
0


1193
chr19
23841000
23842000
0.000
0.000
0.015
0.027
ZNF675
1.00000
1.00000
0.29694
0
0


1194
chr19
29256000
29257000
0.000
0.000
0.029
0.000
UQCRFS1
0.22755
0.54294
0.08726
0
0


1195
chr19
44183000
44184000
0.000
0.000
0.029
0.000
PLAUR
0.22755
0.54294
0.08726
0
0


1196
chr19
50399000
50400000
0.000
0.000
0.029
0.000
IL4I1
0.22755
0.54294
0.08726
0
0


1197
chr19
53419000
S3420000
0.028
0.000
0.015
0.014
ZNF321P; ZNF816;
1.00000
1.00000
0.29694
0
0










ZNF816-















ZNF321PZNF321PZNF816-















ZNF321P;







1198
chr20
15470000
15471000
0.028
0.006
0.000
0.000
MACROD2
1.00000
0.34615
1.00000
0
0


1199
chr20
23359000
23360000
0.056
0.000
0.000
0.000
NAPB
1.00000
0.11763
1.00000
0
1


1200
chr20
23912000
23913000
0.000
0.000
0.000
0.027
CST5
0.49735
1.00000
1.00000
0
0


1201
chr20
46131000
46132000
0.000
0.000
0.059
0.014
NCOA3
0.19371
0.29551
0.00730
1
1


1202
chr20
49127000
49128000
0.000
0.000
0.029
0.014
PTPN1
0.60686
0.54294
0.08726
0
0


1203
chr20
49648000
49649000
0.000
0.000
0.029
0.000
KCNG1
0.22755
0.54294
0.08726
0
0


1204
chr20
61607000
61608000
0.000
0.000
0.000
0.027
SLC17A9
0.49735
1.00000
1.00000
0
0


1205
chr21
21597000
21598000
0.000
0.000
0.029
0.000
NCAM2
0.22755
0.54294
0.08726
0
0


1206
chr21
23458000
23459000
0.000
0.000
0.029
0.000
NCAM2
0.22755
0.54294
0.08726
0
0


1207
chr21
24998000
24999000
0.000
0.000
0.029
0.000
MRPL39
0.22755
0.54294
0.08726
0
0


1208
chr21
26935000
26936000
0.000
0.000
0.015
0.014
MRPL39
1.00000
1.00000
0.29694
0
0


1209
chr21
35779000
35780000
0.000
0.000
0.000
0.027
SMIM11
0.49735
1.00000
1.00000
0
0


1210
chr21
38779000
38780000
0.000
0.000
0.000
0.027
DYRK1A
0.49735
1.00000
1.00000
0
0


1211
chr21
43254000
43255000
0.000
0.000
0.029
0.000
PRDM15
0.22755
0.54294
0.08726
0
0


1212
chr21
44612000
44613000
0.000
0.000
0.000
0.027
CRYAA
0.49735
1.00000
1.00000
0
0


1213
chr21
45381000
45382000
0.000
0.000
0.029
0.000
AGPAT3
0.22755
0.54294
0.08726
0
0


1214
chr21
46058000
46059000
0.000
0.000
0.015
0.027
KRTAP10-10
1.00000
1.00000
0.29694
0
0


1215
chr22
19050000
19051000
0.000
0.006
0.000
0.027
DGCR2
0.49735
1.00000
1.00000
0
0


1216
chr22
20212000
20213000
0.000
0.000
0.029
0.014
RTN4R
0.60686
0.54294
0.08726
0
0


1217
chr22
20708000
20709000
0.000
0.000
0.029
0.000
FAM230A
0.22755
0.54294
0.08726
0
0


1218
chr22
21994000
21995000
0.028
0.000
0.015
0.000
SDF2L1
0.47887
1.00000
0.29694
0
0


1219
chr22
22379000
22380000
0.000
0.000
0.029
0.027
IGLV4-69
1.00000
0.54294
0.08726
0
0


1220
chr22
22380000
22381000
0.000
0.012
0.044
0.068
IGLV4-69
0.72064
0.54966
0.15671
0
1


1221
chr22
22381000
22382000
0.000
0.012
0.015
0.027
IGLV4-69
1.00000
1.00000
1.00000
0
0


1222
chr22
22385000
22386000
0.028
0.031
0.029
0.068
IGLV4-69
0.44431
1.00000
1.00000
0
1


1223
chr22
22452000
22453000
0.000
0.012
0.015
0.014
IGLV8-61
1.00000
1.00000
1.00000
0
0


1224
chr22
22453000
22454000
0.000
0.012
0.015
0.014
IGLV8-61
1.00000
1.00000
1.00000
0
0


1225
chr22
22516000
22517000
0.000
0.025
0.015
0.054
IGLV4-60
0.36833
1.00000
1.00000
0
1


1226
chr22
22517000
22518000
0.000
0.019
0.000
0.014
IGLV4-60
1.00000
1.00000
0.55662
0
0


1227
chr22
22550000
22551000
0.056
0.006
0.044
0.054
IGLV6-57
1.00000
1.00000
0.07959
0
1


1228
chr22
22569000
22570000
0.000
0.006
0.015
0.014
IGLV10-54
1.00000
1.00000
0.50663
0
0


1229
chr22
22676000
22677000
0.028
0.000
0.015
0.000
IGLV1-51
0.47887
1.00000
0.29694
0
0


1230
chr22
22677000
22678000
0.083
0.012
0.015
0.014
IGLV1-51
1.00000
0.11840
1.00000
0
1


1231
chr22
22707000
22708000
0.028
0.006
0.044
0.014
IGLV5-48
0.34948
1.00000
0.07959
0
0


1232
chr22
22712000
22713000
0.083
0.012
0.088
0.041
IGLV1-47
0.31126
1.00000
0.00949
0
1


1233
chr22
22723000
22724000
0.000
0.006
0.015
0.027
IGLV7-46
1.00000
1.00000
0.50663
0
0


1234
chr22
22724000
22725000
0.028
0.012
0.088
0.041
IGLV7-46
0.31126
0.41714
0.00949
0
1


1235
chr22
22730000
22731000
0.000
0.006
0.059
0.054
IGLV5-45
1.00000
0.29551
0.02818
0
1


1236
chr22
22731000
22732000
0.000
0.006
0.029
0.000
IGLV5-45
0.22755
0.54294
0.21104
0
0


1237
chr22
22735000
22736000
0.028
0.037
0.059
0.068
IGLV1-44
1.00000
0.65667
0.48849
0
1


1238
chr22
22749000
22750000
0.000
0.006
0.059
0.027
IGLV7-43
0.42627
0.29551
0.02818
0
1


1239
chr22
22758000
22759000
0.028
0.006
0.029
0.014
IGLV1-40
0.60686
1.00000
0.21104
0
0


1240
chr22
22759000
22760000
0.056
0.006
0.044
0.027
IGLV1-40
0.67043
1.00000
0.07959
0
1


1241
chr22
22764000
22765000
0.111
0.006
0.044
0.068
IGLV1-40
0.72064
0.23165
0.07959
0
1


1242
chr22
23028000
23029000
0.000
0.006
0.015
0.000
IGLV3-25
0.47887
2.00000
0.50663
0
0


1243
chr22
23029000
23030000
0.028
0.062
0.132
0.108
IGLV3-25
0.79702
0.15881
0.11274
0
1


1244
chr22
23035000
23036000
0.000
0.000
0.015
0.014
IGLV2-23
1.00000
1.00000
0.29694
0
0


1245
chr22
23039000
23040000
0.000
0.000
0.000
0.027
IGLV2-23
0.49735
1.00000
1.00000
0
0


1246
chr22
23040000
23041000
0.000
0.043
0.103
0.054
IGLV2-23
0.35266
0.09269
0.12716
0
1


1247
chr22
23041000
23042000
0.000
0.006
0.044
0.000
IGLV2-23
0.10727
0.54966
0.07959
0
0


1248
chr22
23055000
23056000
0.028
0.056
0.059
0.014
IGLV3-21
0.19371
0.65667
1.00000
0
1


1249
chr22
23063000
23064000
0.000
0.000
0.074
0.041
IGLV3-19
0.47996
0.16101
0.00208
0
1


1250
chr22
23090000
23091000
0.000
0.000
0.059
0.041
IGLV3-16
0.70990
0.29551
0.00730
0
1


1251
chr22
23100000
23101000
0.000
0.019
0.044
0.054
IGLV2-14
1.00000
0.54966
0.36534
0
1


1252
chr22
23101000
23102000
0.028
0.031
0.074
0.081
IGLV2-14
1.00000
0.66188
0.16714
0
1


1253
chr22
23114000
23115000
0.000
0.000
0.015
0.027
IGLV3-12
1.00000
1.00000
0.29694
0
0


1254
chr22
23134000
23135000
0.000
0.000
0.029
0.014
IGLV2-11
0.60686
0.54294
0.08726
0
0


1255
chr22
23154000
23155000
0.000
0.019
0.074
0.027
IGLV3-10
0.25970
0.16101
0.05242
0
1


1256
chr22
23161000
23162000
0.000
0.006
0.000
0.014
IGLV3-9
1.00000
1.00000
1.00000
0
0


1257
chr22
23162000
23163000
0.000
0.012
0.000
0.014
IGLV3-9
1.00000
1.00000
1.00000
0
0


1258
chr22
23165000
23166000
0.000
0.012
0.000
0.041
IGLV2-8
0.24603
1.00000
1.00000
0
0


1259
chr22
23192000
23193000
0.000
0.006
0.088
0.041
IGLV4-3
0.31126
0.09031
0.00311
0
1


1260
chr22
23197000
23198000
0.000
0.006
0.015
0.000
IGLV4-3
0.47887
1.00000
0.50663
0
0


1261
chr22
23198000
23199000
0.000
0.025
0.147
0.068
IGLV4-3
0.17231
0.01404
0.00108
0
1


1262
chr22
23199000
23200000
0.000
0.031
0.221
0.068
IGLV4-3
0.01424
0.00107
0.00002
0
1


1263
chr22
23203000
23204000
0.000
0.000
0.029
0.000
IGLV4-3
0.22755
0.54294
0.08726
0
0


1264
chr22
23204000
23205000
0.056
0.000
0.059
0.041
IGLV4-3
0.70990
1.00000
0.00730
0
1


1265
chr22
23205000
23206000
0.000
0.000
0.015
0.027
IGLV4-3
1.00000
1.00000
0.29694
0
0


1266
chr22
23207000
23208000
0.000
0.000
0.029
0.000
IGLV4-3
0.22755
0.54294
0.08726
0
0


1267
chr22
23209000
23210000
0.000
0.000
0.029
0.000
IGLV4-3
0.22755
0.54294
0.08726
0
0


1268
chr22
23213000
23214000
0.000
0.000
0.088
0.027
IGLV4-3
0.15270
0.09031
0.00058
0
1


1269
chr22
23214000
23215000
0.000
0.000
0.074
0.027
IGLV4-3
0.25970
0.16101
0.00208
0
1


1270
chr22
23219000
23220000
0.000
0.000
0.044
0.000
IGLV3-1
0.10727
0.54966
0.02537
0
0


1271
chr22
23220000
23221000
0.000
0.000
0.059
0.000
IGLV3-1
0.05016
0.29551
0.00730
0
1


1272
chr22
23222000
23223000
0.000
0.006
0.147
0.014
IGLV3-1
0.00342
0.01404
0.00003
0
1


1273
chr22
23223000
23224000
0.033
0.149
0.544
0.432
IGLV3-1
0.23940
0.00000
0.00000
0
1


1274
chr22
23224000
23225000
0.000
0.000
0.118
0.027
IGLV3-1
0.04838
0.04825
0.00004
0
1


1275
chr22
23226000
23227000
0.000
0.000
0.029
0.000
IGLV3-1
0.22755
0.54294
0.08726
0
0


1276
chr22
23227000
23228000
0.028
0.056
0.412
0.257
IGLL5
0.07371
0.00001
0.00000
0
1


1277
chr22
23228000
23229000
0.028
0.019
0.309
0.095
IGLL5
0.00152
0.00070
0.00000
0
1


1278
chr22
23229000
23230000
0.000
0.000
0.118
0.041
IGLL5
0.11795
0.04825
0.00004
0
1


1279
chr22
23230000
23231000
0.222
0.161
0.647
0.514
IGLL5
0.12719
0.00007
0.00000
0
1


1280
chr22
23231000
23232000
0.250
0.155
0.647
0.514
IGLL5
0.12719
0.00017
0.00000
0
1


1281
chr22
23232000
23233000
0.000
0.012
0.426
0.162
IGLL5
0.00075
0.00000
0.00000
0
1


1282
chr22
23233000
23234000
0.000
0.006
0.162
0.054
IGLJ1
0.05410
0.01471
0.00001
0
1


1283
chr22
23234000
23235000
0.056
0.000
0.147
0.041
IGLJ1
0.03985
0.20979
0.00000
0
1


1284
chr22
23235000
23236000
0.056
0.031
0.176
0.068
IGLJ1; IGLL5;
0.06843
0.13046
0.00035
0
1


1285
chr22
23236000
23237000
0.111
0.043
0.250
0.095
IGLJ1; IGLL5;
0.02356
0.12484
0.00001
0
1


1286
chr22
23237000
23238000
0.083
0.006
0.103
0.054
IGLC1; IGLL5;
0.35266
1.00000
0.00099
0
1


1287
chr22
23241000
23242000
0.028
0.012
0.074
0.000
IGLJ2
0.02326
0.66188
0.02559
0
1


1288
chr22
23242000
23243000
0.028
0.050
0.147
0.108
IGLC2
0.61516
0.09212
0.02792
0
1


1289
chr22
23243000
23244000
0.000
0.000
0.029
0.000
IGLC2
0.22755
0.54294
0.08726
0
0


1290
chr22
23244000
23245000
0.000
0.012
0.015
0.014
IGLC2
1.00000
1.00000
1.00000
0
0


1291
chr22
23247000
23248000
0.111
0.099
0.088
0.122
IGLJ3
0.59201
0.73481
1.00000
0
1


1292
chr22
23248000
23249000
0.000
0.012
0.015
0.027
IGLC3
1.00000
1.00000
1.00000
0
0


1293
chr22
23249000
23250000
0.000
0.006
0.029
0.027
IGLC3
1.00000
0.54294
0.21104
0
0


1294
chr22
23260000
23261000
0.000
0.025
0.015
0.000
IGLJ6
0.47887
1.00000
1.00000
0
0


1295
chr22
23261000
23262000
0.000
0.012
0.015
0.014
IGLJ6
1.00000
1.00000
1.00000
0
0


1296
chr22
23263000
23264000
0.000
0.006
0.044
0.014
IGLJ7
0.34948
0.54966
0.07959
0
0


1297
chr22
23264000
23265000
0.000
0.006
0.044
0.027
IGLC7
0.67043
0.54966
0.07959
0
0


1298
chr22
23273000
23274000
0.000
0.000
0.044
0.000
IGLC7
0.10727
0.54966
0.02537
0
0


1299
chr22
23277000
23278000
0.000
0.000
0.029
0.014
IGLC7
0.60686
0.54294
0.08726
0
0


1300
chr22
23278000
23279000
0.000
0.006
0.059
0.014
IGLC7
0.19371
0.29551
0.02818
0
1


1301
chr22
23281000
23282000
0.000
0.000
0.029
0.014
IGLC7
0.60686
0.54294
0.08726
0
0


1302
chr22
23282000
23283000
0.000
0.006
0.147
0.027
IGLC7
0.01393
0.01404
0.00003
0
1


1303
chr22
23284000
23285000
0.000
0.000
0.029
0.000
IGLC7
0.22755
0.54294
0.08726
0
0


1304
chr22
23523000
23524000
0.000
0.000
0.015
0.041
BCR
0.62100
1.00000
0.29694
0
0


1305
chr22
23524000
23525000
0.000
0.000
0.029
0.014
BCR
0.60686
0.54294
0.08726
0
0


1306
chr22
27236000
27237000
0.028
0.000
0.029
0.000
CRYBA4
0.22755
1.00000
0.08726
0
0


1307
chr22
29195000
29196000
0.000
0.000
0.088
0.000
XBP1
0.01070
0.09031
0.00058
0
1


1308
chr22
29196000
29197000
0.000
0.000
0.059
0.04.
XBP1
0.70990
0.29551
0.00730
0
1


1309
chr22
31826000
31827000
0.000
0.000
0.029
0.000
DRG1
0.22755
0.54294
0.08726
0
0


1310
chr22
32982000
32983000
0.028
0.000
0.015
0.000
SYN3
0.47887
1.00000
0.29694
0
0


1311
chr22
39852000
39853000
0.000
0.000
0.029
0.000
TAB1
0.22755
0.54294
0.08726
0
0


1312
chr22
39854000
39855000
0.000
0.000
0.029
0.000
TAB1
0.22755
0.54294
0.08726
0
0


1313
chr22
43360000
43361000
0.000
0.000
0.029
0.000
PACSIN2
0.22755
0.54294
0.08726
0
0


1314
chr22
47186000
47187000
0.000
0.000
0.029
0.000
TBC1D22A
0.22755
0.54294
0.08726
0
0


1315
chr22
47738000
47739000
0.000
0.000
0.000
0.027
LL22NC03-75H12.2
0.49735
1.00000
1.00000
0
0


1316
chr22
50336000
50337000
0.028
0.000
0.015
0.000
CRELD2
0.47887
1.00000
0.29694
0
0


1317
chrX
228000
229000
0.000
0.000
0.000
0.027
GTPBP6
0.49735
1.00000
1.00000
0
0


1318
chrX
1514000
1515000
0.000
0.000
0.015
0.014
SLC25A6
1.00000
1.00000
0.29694
0
0


1319
chrX
1611000
1612000
0.000
0.000
0.029
0.000
P2RY8
0.22755
0.54294
0.08726
1
0


1320
chrX
12993000
12994000
0.000
0.000
0.235
0.041
TMSB4X
0.00091
0.00098
0.00000
1
1


1321
chrX
12994000
12995000
0.000
0.000
0.221
0.027
TMSB4X
0.00045
0.00107
0.00000
1
1


1322
chrX
13419000
13420000
0.028
0.000
0.029
0.027
ATXN3L
1.00000
1.00000
0.08726
0
0


1323
chrX
27031000
27032000
0.000
0.000
0.059
0.000
DCAF8L2
0.05016
0.29551
0.00730
0
1


1324
chrX
32315000
32316000
0.000
0.000
0.000
0.027
DMD
0.49735
1.00000
1.00000
1
0


1325
chrX
32317000
32318000
0.028
0.000
0.000
0.014
DMD
1.00000
0.34615
1.00000
1
0


1326
chrX
33144000
33145000
0.000
0.000
0.029
0.014
DMD
0.60686
0.54294
0.08726
1
0


1327
chrX
33145000
33146000
0.000
0.000
0.044
0.027
DMD
0.67043
0.54966
0.02537
1
0


1328
chrX
33146000
33147000
0.000
0.000
0.162
0.068
DMD
0.11004
0.01471
0.00000
1
1


1329
chrX
41366000
41367000
0.000
0.000
0.015
0.027
CASK
1.00000
1.00000
0.29694
0
0


1330
chrX
42802000
42803000
0.000
0.000
0.074
0.027
MAOA
0.25970
0.16101
0.00208
0
1


1331
chrX
48775000
48776000
0.000
0.000
0.044
0.014
PIM2
0.34948
0.54966
0.02537
1
0


1332
chrX
48776000
48777000
0.000
0.000
0.029
0.014
PIM2
0.60686
0.54294
0.08726
1
0


1333
chrX
64071000
64072000
0.000
0.000
0.059
0.014
ZC4H2
0.19371
0.29551
0.00730
0
0


1334
chrX
67030000
67031000
0.028
0.000
0.015
0.000
AR
0.47887
1.00000
0.29694
0
0


1335
chrX
80258000
80259000
0.000
0.000
0.000
0.027
HMGN5
0.49735
1.00000
1.00000
0
0


1336
chrX
81172000
81173000
0.000
0.000
0.015
0.027
SH3BGRL
1.00000
1.00000
0.29694
0
0


1337
chrX
87742000
87743000
0.000
0.000
0.029
0.000
CPXCR1
0.22755
0.54294
0.08726
0
0


1338
chrX
87831000
87832000
0.000
0.000
0.000
0.027
CPXCR1
0.49735
1.00000
1.00000
0
0


1339
chrX
88263000
88264000
0.000
0.000
0.000
0.027
CPXCR1
0.49735
1.00000
1.00000
0
0


1340
chrX
88458000
88459000
0.000
0.000
0.029
0.000
CPXCR1
0.22755
0.54294
0.08726
0
0


1341
chrX
92647000
92648000
0.000
0.000
0.000
0.027
NAP1L3
0.49735
1.00000
1.00000
0
0


1342
chrX
93279000
93280000
0.000
0.000
0.015
0.014
FAM133A
1.00000
1.00000
0.29694
0
0


1343
chrX
94079000
94080000
0.000
0.000
0.015
0.014
FAM133A
1.00000
1.00000
0.29694
0
0


1344
chrX
104006000
104007000
0.000
0.000
0.015
0.014
IL1RAPL2
1.00000
1.00000
0.29694
0
0


1345
chrX
104269000
104270000
0.000
0.000
0.015
0.014
IL1RAPL2
1.00000
1.00000
0.29694
0
0


1346
chrX
106132000
106133000
0.000
0.000
0.000
0.027
RIPPLY1
0.49735
1.00000
1.00000
0
0


1347
chrX
113095000
113096000
0.000
0.006
0.015
0.000
HTR2C
0.47887
1.00000
0.50663
0
0


1348
chrX
115676000
115677000
0.000
0.000
0.015
0.014
CXorf61
1.00000
1.00000
0.29694
0
0


1349
chrX
124996000
124997000
0.000
0.000
0.029
0.000
DCAF12L2
0.22755
0.54294
0.08726
0
0


1350
chrX
125708000
125709000
0.000
0.000
0.029
0.000
DCAF12L1
0.22755
0.54294
0.08726
0
0


1351
chrX
128565000
128566000
0.000
0.000
0.015
0.014
SMARCA1
1.00000
1.00000
0.29694
0
0


1352
chrX
129643000
129644000
0.000
0.000
0.015
0.027
RBMX2
1.00000
1.00000
0.29694
0
0


1353
chrX
134903000
134904000
0.000
0.000
0.029
0.014
CT45A3; CT45A4;
0.60686
0.54294
0.08726
0
0


1354
chrX
140846000
140847000
0.000
0.000
0.029
0.000
SPANXD; SPANXE;
0.22755
0.54294
0.08726
0
0


1355
chrX
143750000
143751000
0.000
0.000
0.000
0.027
SPANXN1
0.49735
1.00000
1.00000
0
0


1356
chrX
145016000
145017000
0.028
0.000
0.000
0.027
TMEM257
0.49735
0.34615
1.00000
0
0
























TABLE 2







Region
Region
ABC-
GCB-

p_ABC_
Previously


#
Chromosome
Start
End
subtype
subtype
ClosestGene
vs_GCB
Identified























1
chr1
756000
757000
0.040
0.000
AL669831.1
1.00000
0


2
chr1
1963000
1964000
0.000
0.000
GABRD
1.00000
0


3
chr1
2052000
2053000
0.000
0.040
PRKCZ
1.00000
0


4
chr1
3789000
3790000
0.000
0.000
DFFB
1.00000
0


5
chr1
6613000
6614000
0.000
0.000
NOL9
1.00000
1


6
chr1
6614000
6615000
0.120
0.040
NOL9
0.60921
1


7
chr1
6661000
6662000
0.000
0.000
KLHL21
1.00000
0


8
chr1
6662000
6663000
0.120
0.000
KLHL21
0.23469
0


9
chr1
9129000
9130000
0.000
0.080
SLC2A5
0.48980
0


10
chr1
10894000
10895000
0.040
0.000
C1orf127
1.00000
0


11
chr1
17019000
17020000
0.000
0.000
AL137798.1
1.00000
0


12
chr1
17231000
17232000
0.040
0.000
CROCC
1.00000
0


13
chr1
19935000
19936000
0.080
0.000
MINOS1-NBL1
0.48980
0


14
chr1
21091000
21092000
0.040
0.000
HP1BP3
1.00000
0


15
chr1
23885000
23886000
0.080
0.040
ID3
1.00000
1


16
chr1
28408000
28409000
0.000
0.040
EYA3
1.00000
0


17
chr1
32373000
32374000
0.000
0.040
PTP4A2
1.00000
0


18
chr1
36722000
36723000
0.040
0.000
THRAP3
1.00000
0


19
chr1
46576000
46577000
0.040
0.000
PIK3R3
1.00000
0


20
chr1
51965000
51966000
0.000
0.040
EPS15
1.00000
0


21
chr1
51978000
51979000
0.040
0.080
EPS15
1.00000
0


22
chr1
51983000
51984000
0.040
0.000
EPS15
1.00000
0


23
chr1
72393000
72394000
0.040
0.000
NEGR1
1.00000
0


24
chr1
73719000
73720000
0.040
0.040
LRRIQ3
1.00000
0


25
chr1
77315000
77316000
0.000
0.040
ST6GALNAC5
1.00000
0


26
chr1
81306000
81307000
0.040
0.000
LPHN2
1.00000
0


27
chr1
81527000
81528000
0.000
0.000
LPHN2
1.00000
0


28
chr1
82009000
82010000
0.000
0.000
LPHN2
1.00000
0


29
chr1
84106000
84107000
0.040
0.000
TTLL7
1.00000
0


30
chr1
87524000
87525000
0.000
0.040
HS2ST1; HS2ST1
1.00000
0








LOC339524;




31
chr1
94551000
94552000
0.000
0.040
ABCA4
1.00000
0


32
chr1
94552000
94553000
0.000
0.040
ABCA4
1.00000
0


33
chr1
103696000
103697000
0.000
0.000
COL11A1
1.00000
0


34
chr1
116979000
116980000
0.000
0.040
ATP1A1
1.00000
0


35
chr1
149784000
149785000
0.040
0.040
HIST2H3D
1.00000
1


36
chr1
149821000
149822000
0.040
0.000
HIST2H2AA4
1.00000
1


37
chr1
149857000
149858000
0.000
0.040
HIST2H2BE
1.00000
1


38
chr1
149858000
149859000
0.080
0.040
HIST2H2AC;
1.00000
0








HIST2H2BE;




39
chr1
160616000
160617000
0.040
0.040
SLAMF1
1.00000
0


40
chr1
162711000
162712000
0.040
0.000
DDR2
1.00000
0


41
chr1
163684000
163685000
0.040
0.000
NUF2
1.00000
0


42
chr1
167598000
167599000
0.080
0.000
RCSD1
0.48980
0


43
chr1
167599000
167600000
0.040
0.000
RCSD1
1.00000
0


44
chr1
167600000
167601000
0.040
0.040
RCSD1
1.00000
0


45
chr1
174333000
174334000
0.040
0.000
RABGAP1L
1.00000
0


46
chr1
187263000
187264000
0.000
0.000
PLA2G4A
1.00000
0


47
chr1
187283000
187284000
0.040
0.000
PLA2G4A
1.00000
0


48
chr1
187892000
187893000
0.040
0.000
PLA2G4A
1.00000
0


49
chr1
195282000
195283000
0.000
0.040
KCNT2
1.00000
0


50
chr1
198591000
198592000
0.000
0.040
PTPRC
1.00000
0


51
chr1
198608000
198609000
0.040
0.000
PTPRC
1.00000
0


52
chr1
198609000
198610000
0.080
0.000
PTPRC
0.48980
0


53
chr1
202004000
202005000
0.040
0.040
ELF3
1.00000
0


54
chr1
203273000
203274000
0.040
0.000
BTG2
1.00000
1


55
chr1
203274000
203275000
0.160
0.160
BTG2
1.00000
1


56
chr1
203275000
203276000
0.400
0.280
BTG2
0.55122
1


57
chr1
203276000
203277000
0.080
0.040
BTG2
1.00000
1


58
chr1
205780000
205781000
0.000
0.000
SLC41A1
1.00000
0


59
chr1
205781000
205782000
0.000
0.000
SLC41A1
1.00000
0


60
chr1
206283000
206284000
0.000
0.040
CTSE
1.00000
0


61
chr]
206286000
206287000
0.040
0.000
CTSE
1.00000
0


62
chr1
217044000
217045000
0.040
0.000
ESRRG
1.00000
0


63
chr1
226924000
226925000
0.080
0.120
ITPKB
1.00000
1


64
chr1
226925000
226926000
0.120
0.000
ITPKB
0.23469
1


65
chr1
226926000
226927000
0.120
0.000
ITPKB
0.23469
1


66
chr1
229974000
229975000
0.040
0.040
URB2
1.00000
0


67
chr1
235131000
235132000
0.000
0.000
TOMM20
1.00000
0


68
chr1
235141000
235142000
0.040
0.000
TOMM20
1.00000
0


69
chr1
238787000
238788000
0.040
0.000
MTRNR2L11
1.00000
0


70
chr1
248088000
248089000
0.040
0.000
OR2T8
1.00000
0


71
chr2
630000
631000
0.000
0.000
TMEM18
1.00000
0


72
chr2
1484000
1485000
0.000
0.000
TPO
1.00000
0


73
chr2
7991000
7992000
0.000
0.040
RNF144A
1.00000
0


74
chr2
12173000
12174000
0.000
0.040
LPIN1
1.00000
0


75
chr2
12175000
12176000
0.000
0.000
LPIN1
1.00000
0


76
chr2
12249000
12250000
0.000
0.040
LPIN1
1.00000
0


77
chr2
14113000
14114000
0.000
0.000
FAM84A
1.00000
0


78
chr2
17577000
17578000
0.000
0.040
RAD51AP2
1.00000
0


79
chr2
19253000
19254000
0.000
0.000
OSR1
1.00000
0


80
chr2
24802000
24803000
0.040
0.000
NCOA1
1.00000
0


81
chr2
31478000
31479000
0.040
0.000
EHD3
1.00000
0


82
chr2
41728000
41729000
0.040
0.000
C2orf91
1.00000
0


83
chr2
45404000
45405000
0.000
0.000
SIX2
1.00000
0


84
chr2
47923000
47924000
0.000
0.040
MSH6
1.00000
0


85
chr2
47944000
47945000
0.000
0.000
MSH6
1.00000
0


86
chr2
51360000
51361000
0.040
0.000
NRXN1
1.00000
0


87
chr2
51655000
51656000
0.000
0.000
NRXN1
1.00000
0


88
chr2
56565000
56566000
0.040
0.000
CCDC85A
1.00000
0


89
chr2
57800000
57801000
0.040
0.000
VRK2
1.00000
0


90
chr2
60779000
60780000
0.000
0.040
BCL11A
1.00000
0


91
chr2
60780000
60781000
0.080
0.000
BCL11A
0.48980
0


92
chr2
63802000
63803000
0.000
0.000
WDPCP
1.00000
0


93
chr2
63827000
63828000
0.000
0.040
MDH1
1.00000
0


94
chr2
64319000
64320000
0.000
0.040
PELI1
1.00000
0


95
chr2
65593000
65594000
0.000
0.040
SPRED2
1.00000
1


96
chr2
67002000
67003000
0.040
0.040
MEIS1
1.00000
0


97
chr2
70315000
70316000
0.040
0.000
PCBP1
1.00000
0


98
chr2
79502000
79503000
0.000
0.000
REG3A
1.00000
0


99
chr2
79644000
79645000
0.000
0.000
CTNNA2
1.00000
0


100
chr2
81818000
81819000
0.000
0.000
CTNNA2
1.00000
0


101
chr2
82310000
82311000
0.000
0.000
CTNNA2
1.00000
0


102
chr2
82948000
82949000
0.000
0.040
SUCLG1
1.00000
0


103
chr2
85335000
85336000
0.000
0.000
TCF7L1
1.00000
0


104
chr2
88905000
88906000
0.080
0.000
EIF2AK3
0.48980
0


105
chr2
88906000
88907000
0.160
0.040
EIF2AK3
0.34868
0


106
chr2
88907000
88908000
0.040
0.040
EIF2AK3
1.00000
0


107
chr2
89052000
89053000
0.000
0.080
RPIA
0.48980
0


108
chr2
89065000
89066000
0.000
0.000
RPIA
1.00000
0


109
chr2
89066000
89067000
0.040
0.000
RPIA
1.00000
0


110
chr2
89095000
89096000
0.000
0.040
RPIA
1.00000
0


111
chr2
89127000
89128000
0.120
0.080
IGKC
1.00000
0


112
chr2
89128000
89129000
0.160
0.160
IGKC
1.00000
0


113
chr2
89129000
89130000
0.120
0.000
IGKC
0.23469
0


114
chr2
89130000
89131000
0.080
0.000
IGKC
0.48980
0


115
chr2
89131000
89132000
0.040
0.040
IGKC
1.00000
0


116
chr2
89132000
89133000
0.040
0.000
IGKC
1.00000
0


117
chr2
89133000
89134000
0.000
0.040
IGKC
1.00000
0


118
chr2
89137000
89138000
0.000
0.040
IGKC
1.00000
0


119
chr2
89138000
89139000
0.040
0.000
IGKC
1.00000
0


120
chr2
89139000
89140000
0.000
0.040
IGKC
1.00000
0


121
chr2
89140000
89141000
0.040
0.120
IGKC
0.60921
0


122
chr2
89141000
89142000
0.080
0.120
IGKC
1.00000
0


123
chr2
89142000
89143000
0.040
0.200
IGKC
0.18946
0


124
chr2
89143000
89144000
0.000
0.080
IGKC
0.48980
0


125
chr2
89144000
89145000
0.040
0.040
IGKC
1.00000
0


126
chr2
89145000
89146000
0.040
0.000
IGKC
1.00000
0


127
chr2
89146000
89147000
0.000
0.000
IGKC
1.00000
0


128
chr2
89153000
89154000
0.000
0.000
IGKC
1.00000
0


129
chr2
89155000
89156000
0.080
0.080
IGKC
1.00000
0


130
chr2
89156000
89157000
0.120
0.000
IGKC
0.23469
0


131
chr2
89157000
89158000
0.240
0.160
IGKC
0.72520
0


132
chr2
89158000
89159000
0.240
0.280
IGKC
1.00000
0


133
chr2
89159000
89160000
0.360
0.640
IGKJ5
0.08874
0


134
chr2
89160000
89161000
0.320
0.680
IGKJ3; IGKJ4;
0.02271
0








IGKJ5;




135
chr2
89161000
89162000
0.240
0.320
IGKJ1; IGKJ2;
0.75361
0


136
chr2
89162000
89163000
0.200
0.200
IGKJ1
1.00000
0


137
chr2
89163000
89164000
0.120
0.240
IGKJ1
0.46349
0


138
chr2
89164000
89165000
0.160
0.280
IGKJ1
0.49620
0


139
chr2
89165000
89166000
0.160
0.360
IGKJ1
0.19633
0


140
chr2
89166000
89167000
0.000
0.040
IGKJ1
1.00000
0


141
chr2
89169000
89170000
0.000
0.040
IGKJ1
1.00000
0


142
chr2
89184000
89185000
0.000
0.000
IGKV4-1
1.00000
0


143
chr2
89185000
89186000
0.120
0.320
IGKV4-1
0.17062
0


144
chr2
89196000
89197000
0.000
0.160
IGKV5-2
0.10986
0


145
chr2
89197000
89198000
0.000
0.040
IGKV5-2
1.00000
0


146
chr2
89214000
89215000
0.000
0.040
IGKV5-2
1.00000
0


147
chr2
89246000
89247000
0.040
0.000
IGKV1-5
1.00000
0


148
chr2
89247000
89248000
0.160
0.000
IGKV1-5
0.10986
0


149
chr2
89248000
89249000
0.040
0.000
IGKV1-5
1.00000
0


150
chr2
89266000
89267000
0.000
0.040
IGKV1-6
1.00000
0


151
chr2
89291000
89292000
0.040
0.040
IGKV1-8
1.00000
0


152
chr2
89292000
89293000
0.000
0.040
IGKV1-8
1.00000
0


153
chr2
89326000
89327000
0.040
0.000
IGKV3-11
1.00000
0


154
chr2
89327000
89328000
0.040
0.000
IGKV3-11
1.00000
0


155
chr2
89442000
89443000
0.040
0.160
IGKV3-20
0.34868
0


156
chr2
89443000
89444000
0.000
0.000
IGKV3-20
1.00000
0


157
chr2
89476000
89477000
0.000
0.000
IGKV2-24
1.00000
0


158
chr2
89513000
89514000
0.040
0.000
IGKV1-27
1.00000
0


159
chr2
89521000
89522000
0.040
0.040
IGKV2-28
1.00000
0


160
chr2
89533000
89534000
0.040
0.000
IGKV2-30
1.00000
0


161
chr2
89534000
89535000
0.080
0.000
IGKV2-30
0.48980
0


162
chr2
89544000
89545000
0.000
0.080
IGKV2-30
0.48980
0


163
chr2
89545000
89546000
0.040
0.000
IGKV2-30
1.00000
0


164
chr2
90259000
90260000
0.040
0.000
IGKV1D-8
1.00000
0


165
chr2
90260000
90261000
0.120
0.000
IGKV1D-8
0.23469
0


166
chr2
96809000
96810000
0.040
0.080
DUSP2
1.00000
1


167
chr2
96810000
96811000
0.080
0.120
DUSP2
1.00000
1


168
chr2
96811000
96812000
0.000
0.080
DUSP2
0.48980
1


169
chr2
98611000
98612000
0.000
0.040
TMEM131
1.00000
0


170
chr2
100757000
100758000
0.080
0.000
AFF3
0.48980
0


171
chr2
100758000
100759000
0.120
0.000
AFF3
0.23469
0


172
chr2
106144000
106145000
0.000
0.080
FHL2
0.48980
0


173
chr2
111878000
111879000
0.000
0.120
BCL2L11
0.23469
0


174
chr2
111879000
111880000
0.040
0.120
BCL2L11
0.60921
0


175
chr2
112305000
112306000
0.000
0.040
ANAPC1
1.00000
0


176
chr2
116234000
116235000
0.040
0.000
DPP10
1.00000
0


177
chr2
116439000
116440000
0.040
0.000
DPP10
1.00000
0


178
chr2
124697000
124698000
0.000
0.040
CNTNAP5
1.00000
0


179
chr2
125235000
125236000
0.000
0.000
CNTNAP5
1.00000
0


180
chr2
127538000
127539000
0.000
0.000
GYPC
1.00000
0


181
chr2
136874000
136875000
0.200
0.120
CXCR4
0.70194
1


182
chr2
136875000
136876000
0.240
0.240
CXCR4
1.00000
1


183
chr2
136996000
136997000
0.000
0.040
CXCR4
1.00000
1


184
chr2
137082000
137083000
0.040
0.000
CXCR4
1.00000
1


185
chr2
140951000
140952000
0.040
0.000
LRP1B
1.00000
0


186
chr2
141335000
141336000
0.040
0.000
LRP1B
1.00000
0


187
chr2
141770000
141771000
0.000
0.000
LRP1B
1.00000
0


188
chr2
146445000
146446000
0.000
0.000
ZEB2
1.00000
0


189
chr2
146446000
146447000
0.000
0.080
ZEB2
0.48980
0


190
chr2
156443000
156444000
0.000
0.000
KCNJ3
1.00000
0


191
chr2
172590000
172591000
0.040
0.000
DYNC1I2
1.00000
0


192
chr2
176581000
176582000
0.000
0.000
KIAA1715
1.00000
0


193
chr2
179880000
179881000
0.000
0.040
CCDC141
1.00000
0


194
chr2
180358000
180359000
0.040
0.000
ZNF385B
1.00000
0


195
chr2
189285000
189286000
0.040
0.000
GULP1
1.00000
0


196
chr2
189432000
189433000
0.000
0.040
GULP1
1.00000
0


197
chr2
194115000
194116000
0.040
0.000
TMEFF2
1.00000
0


198
chr2
197035000
197036000
0.040
0.080
STK17B
1.00000
0


199
chr2
197041000
197042000
0.080
0.000
STK17B
0.48980
0


200
chr2
215999000
216000000
0.040
0.000
ABCA12
1.00000
0


201
chr2
216973000
216974000
0.000
0.000
XRCC5
1.00000
0


202
chr2
217247000
217248000
0.000
0.000
4 Mar. 2019
1.00000
0


203
chr2
225386000
225387000
0.040
0.000
CUL3
1.00000
0


204
chr2
225524000
225525000
0.000
0.040
CUL3
1.00000
0


205
chr2
233478000
233479000
0.040
0.000
EFHD1
1.00000
0


206
chr2
233980000
233981000
0.000
0.080
INPP5D
0.48980
0


207
chr2
240641000
240642000
0.000
0.000
AC093802.1
1.00000
0


208
chr2
241125000
241126000
0.000
0.000
OTOS
1.00000
0


209
chr3
8739000
8740000
0.000
0.000
CAV3
1.00000
0


210
chr3
16407000
16408000
0.000
0.000
RFTN1
1.00000
1


211
chr3
16409000
16410000
0.000
0.000
RFTN1
1.00000
1


212
chr3
16419000
16420000
0.040
0.080
RFTN1
1.00000
1


213
chr3
16472000
16473000
0.040
0.000
RFTN1
1.00000
1


214
chr3
16495000
16496000
0.000
0.080
RFTN1
0.48980
1


215
chr3
16552000
16553000
0.000
0.080
RFTN1
0.48980
1


216
chr3
16554000
16555000
0.120
0.120
RFTN1
1.00000
1


217
chr3
16555000
16556000
0.000
0.040
RFTN1
1.00000
1


218
chr3
21658000
21659000
0.040
0.000
ZNF385D
1.00000
0


219
chr3
25691000
25692000
0.040
0.040
TOP2B
1.00000
0


220
chr3
31969000
31970000
0.000
0.040
OSBPL10
1.00000
1


221
chr3
31993000
31994000
0.040
0.000
OSBPL10
1.00000
1


222
chr3
32001000
32002000
0.080
0.040
OSBPL10
1.00000
1


223
chr3
32022000
32023000
0.120
0.080
OSBPL10
1.00000
1


224
chr3
32023000
32024000
0.080
0.000
OSBPL10
0.48980
1


225
chr3
50128000
50129000
0.000
0.040
RBM5
1.00000
0


226
chr3
54913000
54914000
0.040
0.000
CACNA2D3
1.00000
0


227
chr3
56074000
56075000
0.040
0.040
ERC2
1.00000
0


228
chr3
59577000
59578000
0.000
0.000
FHIT
1.00000
0


229
chr3
60351000
60352000
0.000
0.040
FHIT
1.00000
0


230
chr3
60356000
60357000
0.000
0.000
FHIT
1.00000
0


231
chr3
60357000
60358000
0.040
0.000
FHIT
1.00000
0


232
chr3
60358000
60359000
0.040
0.000
FHIT
1.00000
0


233
chr3
60359000
60360000
0.000
0.000
FHIT
1.00000
0


234
chr3
60389000
60390000
0.000
0.040
FHIT
1.00000
0


235
chr3
60392000
60393000
0.040
0.000
FHIT
1.00000
0


236
chr3
60395000
60396000
0.000
0.000
FHIT
1.00000
0


237
chr3
60404000
60405000
0.040
0.000
FHIT
1.00000
0


238
chr3
60436000
60437000
0.000
0.000
FHIT
1.00000
0


239
chr3
60437000
60438000
0.000
0.040
FHIT
1.00000
0


240
chr3
60477000
60478000
0.040
0.040
FHIT
1.00000
0


241
chr3
60485000
60486000
0.040
0.000
FHIT
1.00000
0


242
chr3
60515000
60516000
0.000
0.040
FHIT
1.00000
0


243
chr3
60535000
60536000
0.040
0.000
FHIT
1.00000
0


244
chr3
60602000
60603000
0.000
0.000
FHIT
1.00000
0


245
chr3
60613000
60614000
0.000
0.040
FHIT
1.00000
0


246
chr3
60614000
60615000
0.000
0.040
FHIT
1.00000
0


247
chr3
60632000
60633000
0.000
0.000
FHIT
1.00000
0


248
chr3
60635000
60636000
0.000
0.000
FHIT
1.00000
0


249
chr3
60640000
60641000
0.000
0.000
FHIT
1.00000
0


250
chr3
60647000
60648000
0.000
0.040
FHIT
1.00000
0


251
chr3
60648000
60649000
0.000
0.040
FHIT
1.00000
0


252
chr3
60652000
60653000
0.000
0.000
FHIT
1.00000
0


253
chr3
60660000
60661000
0.040
0.000
FHIT
1.00000
0


254
chr3
60665000
60666000
0.000
0.040
FHIT
1.00000
0


255
chr3
60666000
60667000
0.000
0.040
FHIT
1.00000
0


256
chr3
60671000
60672000
0.000
0.000
FHIT
1.00000
0


257
chr3
60673000
60674000
0.040
0.000
FHIT
1.00000
0


258
chr3
60675000
60676000
0.000
0.040
FHIT
1.00000
0


259
chr3
60678000
60679000
0.000
0.040
FHIT
1.00000
0


260
chr3
60683000
60684000
0.000
0.000
FHIT
1.00000
0


261
chr3
60684000
60685000
0.000
0.040
FHIT
1.00000
0


262
chr3
60688000
60689000
0.040
0.000
FHIT
1.00000
0


263
chr3
60717000
60718000
0.000
0.000
FHIT
1.00000
0


264
chr3
60740000
60741000
0.040
0.000
FHIT
1.00000
0


265
chr3
60774000
60775000
0.000
0.040
FHIT
1.00000
0


266
chr3
60792000
60793000
0.000
0.000
FHIT
1.00000
0


267
chr3
60806000
60807000
0.040
0.000
FHIT
1.00000
0


268
chr3
60812000
60813000
0.000
0.000
FHIT
1.00000
0


269
chr3
60860000
60861000
0.000
0.000
FHIT
1.00000
0


270
chr3
71551000
71552000
0.040
0.000
EIF4E3
1.00000
0


271
chr3
78274000
78275000
0.000
0.040
ROBO1
1.00000
0


272
chr3
80273000
80274000
0.000
0.000
ROBO1
1.00000
0


273
chr3
83094000
83095000
0.000
0.000
GBE1
1.00000
0


274
chr3
83924000
83925000
0.000
0.000
CADM2
1.00000
0


275
chr3
84293000
84294000
0.000
0.040
CADM2
1.00000
0


276
chr3
85260000
85261000
0.000
0.040
CADM2
1.00000
0


277
chr3
85261000
85262000
0.000
0.000
CADM2
1.00000
0


278
chr3
85799000
85800000
0.040
0.000
CADM2
1.00000
0


279
chr3
86226000
86227000
0.000
0.000
CADM2
1.00000
0


280
chr3
88146000
88147000
0.040
0.000
CGGBP1
1.00000
0


281
chr3
94709000
94710000
0.000
0.000
NSUN3
1.00000
0


282
chr3
95460000
95461000
0.000
0.000
MTRNR2L12
1.00000
0


283
chr3
95724000
95725000
0.080
0.000
MTRNR2L12
0.48980
0


284
chr3
101569000
101570000
0.000
0.040
NFKBIZ
1.00000
0


285
chr3
111851000
111852000
0.000
0.000
GCSAM
1.00000
0


286
chr3
111852000
111853000
0.040
0.040
GCSAM
1.00000
0


287
chr3
122377000
122378000
0.080
0.040
PARP14
1.00000
0


288
chr3
150478000
150479000
0.000
0.000
SIAH2
1.00000
0


289
chr3
150479000
150480000
0.000
0.040
SIAH2
1.00000
0


290
chr3
150480000
150481000
0.000
0.120
SIAH2
0.23469
0


291
chr3
163237000
163238000
0.000
0.000
SI
1.00000
0


292
chr3
163238000
163239000
0.000
0.000
SI
1.00000
0


293
chr3
163615000
163616000
0.040
0.040
SI
1.00000
0


294
chr3
183270000
183271000
0.000
0.000
KLHL6
1.00000
0


295
chr3
183271000
183272000
0.000
0.040
KLHL6
1.00000
0


296
chr3
183272000
183273000
0.000
0.120
KLHL6
0.23469
0


297
chr3
183273000
183274000
0.000
0.040
KLHL6
1.00000
0


298
chr3
186648000
186649000
0.000
0.040
ADIPOQ
1.00000
0


299
chr3
186714000
186715000
0.080
0.160
ST6GAL1
0.66710
1


300
chr3
186715000
186716000
0.080
0.000
ST6GAL1
0.48980
1


301
chr3
186739000
186740000
0.120
0.040
ST6GAL1
0.60921
1


302
chr3
186740000
186741000
0.160
0.080
ST6GAL1
0.66710
1


303
chr3
186742000
186743000
0.000
0.000
ST6GAL1
1.00000
1


304
chr3
186783000
186784000
0.160
0.240
ST6GAL1
0.72520
1


305
chr3
86784000
186785000
0.040
0.040
ST6GAL1
1.00000
1


306
chr3
187458000
187459000
0.000
0.000
BCL6
1.00000
1


307
chr3
187459000
187460000
0.000
0.000
BCL6
1.00000
1


308
chr3
187460000
187461000
0.040
0.040
BCL6
1.00000
1


309
chr3
187461000
187462000
0.240
0.360
BCL6
0.53803
1


310
chr3
187462000
187463000
0.440
0.560
BCL6
0.57214
1


311
chr3
187463000
187464000
0.360
0.440
BCL6
0.77329
1


312
chr3
187464000
187465000
0.200
0.200
BCL6
1.00000
1


313
chr3
187468000
187469000
0.120
0.000
BCL6
0.23469
1


314
chr3
187635000
187636000
0.040
0.000
BCL6
1.00000
1


315
chr3
187636000
187637000
0.000
0.000
BCL6
1.00000
1


316
chr3
187653000
187654000
0.040
0.040
BCL6
1.00000
1


317
chr3
187658000
187659000
0.000
0.040
BCL6
1.00000
1


318
chr3
187660000
187661000
0.040
0.160
BCL6
0.34868
1


319
chr3
187661000
187662000
0.040
0.240
BCL6
0.09828
1


320
chr3
187664000
187665000
0.040
0.080
BCL6
1.00000
1


321
chr3
187686000
187687000
0.040
0.000
AC022498.1
1.00000
0


322
chr3
187687000
187688000
0.000
0.040
AC022498.1
1.00000
0


323
chr3
187693000
187694000
0.040
0.040
AC022498.1
1.00000
0


324
chr3
187696000
187697000
0.040
0.000
AC022498.1
1.00000
0


325
chr3
187697000
187698000
0.040
0.000
AC022498.1
1.00000
0


326
chr3
187803000
187804000
0.000
0.000
AC022498.1
1.00000
0


327
chr3
187806000
187807000
0.080
0.080
AC022498.1
1.00000
0


328
chr3
187957000
187958000
0.120
0.160
AC022498.1
1.00000
0


329
chr3
187958000
187959000
0.240
0.280
AC022498.1
1.00000
0


330
chr3
187959000
187960000
0.120
0.040
AC022498.1
0.60921
0


331
chr3
187960000
187961000
0.000
0.040
AC022498.1
1.00000
0


332
chr3
188222000
188223000
0.000
0.000
LPP
1.00000
0


333
chr3
188298000
188299000
0.040
0.000
LPP
1.00000
0


334
chr3
188299000
188300000
0.080
0.080
LPP
1.00000
0


335
chr3
188471000
188472000
0.120
0.240
LPP
0.46349
0


336
chr3
188472000
188473000
0.000
0.080
LPP
0.48980
0


337
chr4
50000
51000
0.080
0.000
ZNF595;
0.48980
0








ZNF718;




338
chr4
51000
52000
0.120
0.040
ZNF595;
0.60921
0








ZNF718;




339
chr4
54000
55000
0.080
0.000
ZNF595;
0.48980
0








ZNF718;




340
chr4
290000
291000
0.000
0.000
ZNF732
1.00000
0


341
chr4
385000
386000
0.080
0.000
ZNF141
0.48980
0


342
chr4
550000
551000
0.000
0.000
PIGG
1.00000
0


343
chr4
2707000
2708000
0.000
0.040
FAM193A
1.00000
0


344
chr4
5206000
5207000
0.080
0.000
STK32B
0.48980
0


345
chr4
25863000
25864000
0.080
0.040
SEL1L3
1.00000
0


346
chr4
25864000
25865000
0.000
0.040
SEL1L3
1.00000
0


347
chr4
25865000
25866000
0.040
0.000
SEL1L3
1.00000
0


348
chr4
29657000
29658000
0.040
0.000
PCDH7
1.00000
0


349
chr4
30356000
30357000
0.040
0.000
PCDH7
1.00000
0


350
chr4
33418000
33419000
0.000
0.000
PCDH7
1.00000
0


351
chr4
33449000
33450000
0.000
0.040
PCDH7
1.00000
0


352
chr4
39348000
39349000
0.000
0.040
RFC1
1.00000
0


353
chr4
39974000
39975000
0.000
0.000
PDS5A
1.00000
0


354
chr4
40194000
40195000
0.000
0.120
N4BP2
0.23469
0


355
chr4
40195000
40196000
0.000
0.040
N4BP2
1.00000
0


356
chr4
40196000
40197000
0.040
0.000
N4BP2
1.00000
0


357
chr4
40197000
40198000
0.000
0.000
N4BP2
1.00000
0


358
chr4
40198000
40199000
0.120
0.080
N4BP2
1.00000
0


359
chr4
40199000
40200000
0.280
0.240
N4BP2
1.00000
0


360
chr4
40200000
40201000
0.080
0.080
RHOH
1.00000
1


361
chr4
40201000
40202000
0.120
0.120
RHOH
1.00000
1


362
chr4
40202000
40203000
0.080
0.000
RHOH
0.48980
1


363
chr4
40204000
40205000
0.000
0.040
RHOH
1.00000
1


364
chr4
45308000
45309000
0.000
0.000
GNPDA2
1.00000
0


365
chr4
46360000
46361000
0.000
0.040
GABRA2
1.00000
0


366
chr4
62375000
62376000
0.000
0.000
LPHN3
1.00000
0


367
chr4
62530000
62531000
0.000
0.000
LPHN3
1.00000
0


368
chr4
62911000
62912000
0.000
0.040
LPHN3
1.00000
0


369
chr4
63120000
63121000
0.040
0.040
LPHN3
1.00000
0


370
chr4
64015000
64016000
0.000
0.000
LPHN3
1.00000
0


371
chr4
65038000
65039000
0.040
0.000
TECRL
1.00000
0


372
chr4
65165000
65166000
0.000
0.040
TECRL
1.00000
0


373
chr4
65966000
65967000
0.000
0.040
EPHA5
1.00000
0


374
chr4
66827000
66828000
0.000
0.080
EPHA5
0.48980
0


375
chr4
71531000
71532000
0.000
0.040
IGJ
1.00000
0


376
chr4
71532000
71533000
0.000
0.000
IGJ
1.00000
0


377
chr4
74456000
74457000
0.040
0.000
RASSF6
1.00000
0


378
chr4
74483000
74484000
0.040
0.000
RASSF6
1.00000
0


379
chr4
74484000
74485000
0.040
0.000
RASSF6
1.00000
0


380
chr4
74485000
74486000
0.120
0.000
RASSF6
0.23469
0


381
chr4
91886000
91887000
0.040
0.000
CCSER1
1.00000
0


382
chr4
92787000
92788000
0.000
0.040
CCSER1
1.00000
0


383
chr4
113206000
113207000
0.000
0.000
TIFA
1.00000
0


384
chr4
114466000
114467000
0.000
0.000
CAMK2D
1.00000
0


385
chr4
114681000
114682000
0.000
0.080
CAMK2D
0.48980
0


386
chr4
117928000
117929000
0.040
0.000
TRAM1L1
1.00000
0


387
chr4
123637000
123638000
0.000
0.000
BBS12
1.00000
0


388
chr4
125227000
125228000
0.040
0.000
ANKRD50
1.00000
0


389
chr4
127371000
127372000
0.000
0.000
FAT4
1.00000
0


390
chr4
133455000
133456000
0.000
0.000
PCDH10
1.00000
0


391
chr4
134538000
134539000
0.000
0.040
PCDH10
1.00000
0


392
chr4
134743000
134744000
0.040
0.040
PABPC4L
1.00000
0


393
chr4
134867000
134868000
0.000
0.000
PABPC4L
1.00000
0


394
chr4
134949000
134950000
0.080
0.000
PABPC4L
0.48980
0


395
chr4
135064000
135065000
0.040
0.000
PABPC4L
1.00000
0


396
chr4
135077000
135078000
0.000
0.000
PABPC4L
1.00000
0


397
chr4
136799000
136800000
0.000
0.000
PCDH18
1.00000
0


398
chr4
136867000
136868000
0.000
0.040
PCDH18
1.00000
0


399
chr4
140236000
140237000
0.040
0.000
NAA15
1.00000
0


400
chr4
151723000
151724000
0.000
0.000
LRBA
1.00000
0


401
chr4
151950000
151951000
0.000
0.000
LRBA
1.00000
0


402
chr4
152125000
152126000
0.040
0.040
SH3D19
1.00000
0


403
chr4
157246000
157247000
0.040
0.000
CTSO
1.00000
0


404
chr4
164532000
164533000
0.000
0.000
1 Mar. 2019
1.00000
0


405
chr4
178732000
178733000
0.040
0.040
AGA
1.00000
0


406
chr4
178885000
178886000
0.040
0.000
AGA
1.00000
0


407
chr4
179898000
179899000
0.000
0.040
AGA
1.00000
0


408
chr4
180885000
180886000
0.040
0.000
TENM3
1.00000
0


409
chr4
181554000
181555000
0.040
0.040
TENM3
1.00000
0


410
chr4
182122000
182123000
0.000
0.040
TENM3
1.00000
0


411
chr5
436000
437000
0.000
0.000
AHRR
1.00000
0


412
chr5
3982000
3983000
0.040
0.000
IRX1
1.00000
0


413
chr5
17218000
17219000
0.040
0.000
BASP1
1.00000
0


414
chr5
17219000
17220000
0.080
0.000
BASP1
0.48980
0


415
chr5
18514000
18515000
0.040
0.000
CDH18
1.00000
0


416
chr5
22356000
22357000
0.040
0.000
CDH12
1.00000
0


417
chr5
22517000
22518000
0.040
0.000
CDH12
1.00000
0


418
chr5
24632000
24633000
0.000
0.000
CDH10
1.00000
0


419
chr5
25275000
25276000
0.000
0.040
CDH10
1.00000
0


420
chr5
25541000
25542000
0.000
0.000
CDH10
1.00000
0


421
chr5
26119000
26120000
0.000
0.080
CDH9
0.48980
0


422
chr5
26450000
26451000
0.000
0.000
CDH9
1.00000
0


423
chr5
29224000
29225000
0.080
0.000
CDH6
0.48980
0


424
chr5
29492000
29493000
0.000
0.000
CDH6
1.00000
0


425
chr5
29648000
29649000
0.000
0.000
CDH6
1.00000
0


426
chr5
51521000
51522000
0.000
0.040
CTD-2203A3.1
1.00000
0


427
chr5
83841000
83842000
0.040
0.000
EDIL3
1.00000
0


428
chr5
88177000
88178000
0.040
0.000
MEF2C
1.00000
0


429
chr5
88178000
88179000
0.040
0.000
MEF2C
1.00000
0


430
chr5
91417000
91418000
0.000
0.000
ARRDC3
1.00000
0


431
chr5
103678000
103679000
0.040
0.000
NUDT12
1.00000
0


432
chr5
123696000
123697000
0.000
0.000
ZNF608
1.00000
1


433
chr5
124079000
124080000
0.000
0.040
ZNF608
1.00000
1


434
chr5
124080000
124081000
0.040
0.000
ZNF608
1.00000
1


435
chr5
127594000
127595000
0.000
0.040
FBN2
1.00000
0


436
chr5
127875000
127876000
0.000
0.000
FBN2
1.00000
0


437
chr5
131825000
131826000
0.120
0.040
IRF1
0.60921
0


438
chr5
131826000
131827000
0.040
0.040
IRF1
1.00000
0


439
chr5
149791000
149792000
0.160
0.240
CD74
0.72520
1


440
chr5
149792000
149793000
0.040
0.080
CD74
1.00000
1


441
chr5
158380000
158381000
0.000
0.080
EBF1
0.48980
0


442
chr5
158479000
158480000
0.000
0.000
EBF1
1.00000
0


443
chr5
158526000
158527000
0.040
0.080
EBF1
1.00000
0


444
chr5
158527000
158528000
0.040
0.040
EBF1
1.00000
0


445
chr5
158528000
158529000
0.040
0.000
EBF1
1.00000
0


446
chr5
164247000
164248000
0.040
0.040
MAT2B
1.00000
0


447
chr5
164441000
164442000
0.000
0.000
MAT2B
1.00000
0


448
chr5
165932000
165933000
0.000
0.000
TENM2
1.00000
0


449
chr5
173300000
173301000
0.000
0.000
CPEB4
1.00000
0


450
chr5
179166000
179167000
0.040
0.040
MAML1
1.00000
0


451
chr5
180102000
180103000
0.040
0.000
FLT4
1.00000
0


452
chr6
392000
393000
0.120
0.080
IRF4
1.00000
1


453
chr6
393000
394000
0.080
0.080
IRF4
1.00000
1


454
chr6
14118000
14119000
0.160
0.440
CD83
0.06222
1


455
chr6
14119000
14120000
0.000
0.120
CD83
0.23469
1


456
chr6
18111000
18112000
0.000
0.080
NHLRC1
0.48980
0


457
chr6
18387000
18388000
0.000
0.040
RNF144B
1.00000
1


458
chr6
18388000
18389000
0.000
0.040
RNF144B
1.00000
1


459
chr6
19573000
19574000
0.040
0.040
ID4
1.00000
0


460
chr6
22873000
22874000
0.040
0.000
HDGFL1
1.00000
0


461
chr6
26031000
26032000
0.000
0.040
HIST1H3B
1.00000
1


462
chr6
26032000
26033000
0.000
0.040
HIST1H3B
1.00000
1


463
chr6
26056000
26057000
0.120
0.040
HIST1H1C
0.60921
1


464
chr6
26123000
26124000
0.120
0.040
HIST1H2BC
0.60921
1


465
chr6
26124000
26125000
0.120
0.080
HIST1H2AC;
1.00000
0








HIST1H2BC;




466
chr6
26125000
26126000
0.000
0.040
HIST1H2AC
1.00000
1


467
chr6
26156000
26157000
0.120
0.080
HIST1H1E
1.00000
1


468
chr6
26157000
26158000
0.080
0.040
HIST1H1E
1.00000
1


469
chr6
26216000
26217000
0.040
0.040
HIST1H2BG
1.00000
1


470
chr6
26234000
26235000
0.080
0.040
HIST1H1D
1.00000
0


471
chr6
27101000
27102000
0.040
0.040
HIST1H2AG
1.00000
1


472
chr6
27114000
27115000
0.080
0.040
HIST1H2AH;
1.00000
0








HIST1H2BK;




473
chr6
27792000
27793000
0.120
0.040
HIST1H4J
0.60921
0


474
chr6
27833000
27834000
0.040
0.000
HIST1H2AL
1.00000
1


475
chr6
27860000
27861000
0.000
0.080
HIST1H2AM
0.48980
1


476
chr6
27861000
27862000
0.000
0.040
HIST1H2BO
1.00000
1


477
chr6
29778000
29779000
0.000
0.040
LOC554223
1.00000
0


478
chr6
29780000
29781000
0.040
0.000
HLA-G
1.00000
0


479
chr6
29911000
29912000
0.080
0.040
HLA-A
1.00000
0


480
chr6
29927000
29928000
0.040
0.000
HLA-A
1.00000
0


481
chr6
31324000
31325000
0.040
0.040
HLA-B
1.00000
1


482
chr6
31325000
31326000
0.000
0.000
HLA-B
1.00000
1


483
chr6
31543000
31544000
0.080
0.000
TNF
0.48980
1


484
chr6
31549000
31550000
0.200
0.240
LTB
1.00000
1


485
chr6
31550000
31551000
0.040
0.040
LTB
1.00000
1


486
chr6
32440000
32441000
0.120
0.000
HLA-DRA
0.23469
0


487
chr6
32451000
32452000
0.040
0.000
HLA-DRB5
1.00000
0


488
chr6
32452000
32453000
0.080
0.000
HLA-DRBS
0.48980
0


489
chr6
32455000
32456000
0.040
0.040
HLA-DRB5
1.00000
0


490
chr6
32457000
32458000
0.000
0.000
HLA-DRB5
1.00000
0


491
chr6
32498000
32499000
0.000
0.040
HLA-DRB5
1.00000
0


492
chr6
32505000
32506000
0.040
0.000
HLA-DRBS
1.00000
0


493
chr6
32511000
32512000
0.000
0.000
HLA-DRB5
1.00000
0


494
chr6
32522000
32523000
0.040
0.000
HLA-DRB1
1.00000
0


495
chr6
32525000
32526000
0.040
0.000
HLA-DRB1
1.00000
0


496
chr6
32526000
32527000
0.000
0.000
HLA-DRB1
1.00000
0


497
chr6
32527000
32528000
0.000
0.000
HLA-DRB1
1.00000
0


498
chr6
32548000
32549000
0.000
0.000
HLA-DRB1
1.00000
0


499
chr6
32552000
32553000
0.040
0.000
HLA-DRB1
1.00000
0


500
chr6
32557000
32558000
0.000
0.080
HLA-DRB1
0.48980
0


501
chr6
32609000
32610000
0.000
0.040
HLA-DQA1
1.00000
0


502
chr6
32630000
32631000
0.000
0.040
HLA-DQB1
1.00000
0


503
chr6
32632000
32633000
0.080
0.040
HLA-DQB1
1.00000
0


504
chr6
32727000
32728000
0.040
0.040
HLA-DQB2
1.00000
0


505
chr6
32729000
32730000
0.000
0.040
HLA-DQB2
1.00000
0


506
chr6
33048000
33049000
0.000
0.040
HLA-DPB1
1.00000
0


507
chr6
34179000
34180000
0.000
0.040
HMGA1
1.00000
0


508
chr6
37138000
37139000
0.200
0.200
PIM1
1.00000
1


509
chr6
37139000
37140000
0.120
0.120
PIM1
1.00000
1


510
chr6
37140000
37141000
0.040
0.000
PIM1
1.00000
1


511
chr6
58001000
58002000
0.040
0.000
PRIM2
1.00000
0


512
chr6
67923000
67924000
0.040
0.000
BAI3
1.00000
0


513
chr6
77256000
77257000
0.040
0.000
IMPG1
1.00000
0


514
chr6
81437000
81438000
0.040
0.000
BCKDHB
1.00000
0


515
chr6
88468000
88469000
0.000
0.040
AKIRIN2
1.00000
0


516
chr6
88630000
88631000
0.040
0.080
SPACA1
1.00000
0


517
chr6
88876000
88877000
0.000
0.000
CNR1
1.00000
0


518
chr6
89323000
89324000
0.000
0.000
RNGTT
1.00000
0


519
chr6
89338000
89339000
0.080
0.000
RNGTT
0.48980
0


520
chr6
89348000
89349000
0.080
0.000
RNGTT
0.48980
0


521
chr6
89470000
89471000
0.080
0.000
RNGTT
0.48980
0


522
chr6
89471000
89472000
0.000
0.000
RNGTT
1.00000
0


523
chr6
90061000
90062000
0.040
0.040
UBE2J1
1.00000
1


524
chr6
90062000
90063000
0.040
0.000
UBE2J1
1.00000
1


525
chr6
90994000
90995000
0.000
0.080
MAP3K7
0.48980
0


526
chr6
91004000
91005000
0.040
0.040
MAP3K7
1.00000
0


527
chr6
91005000
91006000
0.120
0.280
MAP3K7
0.28902
0


528
chr6
91006000
91007000
0.040
0.120
MAP3K7
0.60921
0


529
chr6
91007000
91008000
0.000
0.040
MAP3K7
1.00000
0


530
chr6
94822000
94823000
0.000
0.040
EPHA7
1.00000
0


531
chr6
107704000
107705000
0.000
0.000
PDSS2
1.00000
0


532
chr6
112885000
112886000
0.040
0.000
RFPL4B
1.00000
0


533
chr6
118244000
118245000
0.040
0.000
SLC35F1
1.00000
0


534
chr6
121288000
121289000
0.000
0.000
C6orf170
1.00000
0


535
chr6
121489000
121490000
0.000
0.080
C6orf170
0.48980
0


536
chr6
123504000
123505000
0.040
0.000
TRDN
1.00000
0


537
chr6
127313000
127314000
0.040
0.000
RSPO3
1.00000
0


538
chr6
133785000
133786000
0.080
0.000
EYA4
0.48980
0


539
chr6
134491000
134492000
0.000
0.080
SGK1
0.48980
1


540
chr6
134492000
134493000
0.080
0.040
SGK1
1.00000
1


541
chr6
134493000
134494000
0.040
0.080
SGK1
1.00000
1


542
chr6
134494000
134495000
0.040
0.080
SGK1
1.00000
1


543
chr6
134495000
134496000
0.160
0.280
SGK1
0.49620
1


544
chr6
134496000
134497000
0.000
0.200
SGK1
0.05015
1


545
chr6
142046000
142047000
0.000
0.080
NMBR
0.48980
0


546
chr6
147860000
147861000
0.000
0.040
SAMD5
1.00000
0


547
chr6
150954000
150955000
0.040
0.040
PLEKHG1
1.00000
0


548
chr6
159238000
159239000
0.000
0.080
EZR
0.48980
0


549
chr6
159239000
159240000
0.040
0.000
EZR
1.00000
0


550
chr6
159240000
159241000
0.040
0.000
EZR
1.00000
0


551
chr6
159464000
159465000
0.040
0.000
TAGAP
1.00000
0


552
chr6
159465000
159466000
0.040
0.000
TAGAP
1.00000
0


553
chr6
161265000
161266000
0.000
0.040
PLG
1.00000
0


554
chr6
161833000
161834000
0.000
0.000
PARK2
1.00000
0


555
chr6
162712000
162713000
0.000
0.000
PARK2
1.00000
0


556
chr6
164941000
164942000
0.000
0.000
C6orf118
1.00000
0


557
chr6
168813000
168814000
0.000
0.000
SMOC2
1.00000
0


558
chr7
1898000
1899000
0.040
0.040
AC110781.3
1.00000
0


559
chr7
1963000
1964000
0.040
0.000
MAD1L1
1.00000
0


560
chr7
2080000
2081000
0.000
0.040
MAD1L1
1.00000
0


561
chr7
5568000
5569000
0.040
0.080
ACTB
1.00000
1


562
chr7
5569000
5570000
0.040
0.120
ACTB
0.60921
1


563
chr7
5570000
5571000
0.040
0.040
ACTB
1.00000
1


564
chr7
9933000
9934000
0.040
0.040
NDUFA4
1.00000
0


565
chr7
13017000
13018000
0.000
0.040
ARL4A
1.00000
0


566
chr7
13346000
13347000
0.000
0.000
ETV1
1.00000
0


567
chr7
15459000
15460000
0.000
0.000
AGMO
1.00000
0


568
chr7
16382000
16383000
0.040
0.000
ISPD
1.00000
0


569
chr7
28600000
28601000
0.040
0.000
CREB5
1.00000
0


570
chr7
40846000
40847000
0.040
0.000
C7orf10
1.00000
0


571
chr7
50349000
50350000
0.040
0.040
IKZF1
1.00000
0


572
chr7
50350000
50351000
0.080
0.040
IKZF1
1.00000
0


573
chr7
53335000
53336000
0.000
0.000
POM121L12
1.00000
0


574
chr7
57713000
57714000
0.080
0.040
ZNF716
1.00000
0


575
chr7
62475000
62476000
0.040
0.040
AC006455.1
1.00000
0


576
chr7
70669000
70670000
0.040
0.000
WBSCR17
1.00000
0


577
chr7
71553000
71554000
0.000
0.040
CALN1
1.00000
0


578
chr7
79847000
79848000
0.040
0.000
GNAI1
1.00000
0


579
chr7
80694000
80695000
0.040
0.000
AC005008.2
1.00000
0


580
chr7
81556000
81557000
0.000
0.000
CACNA2D1
1.00000
0


581
chr7
84127000
84128000
0.040
0.000
SEMA3A
1.00000
0


582
chr7
84247000
84248000
0.000
0.040
SEMA3D
1.00000
0


583
chr7
84257000
84258000
0.000
0.000
SEMA3D
1.00000
0


584
chr7
86914000
86915000
0.000
0.040
CROT
1.00000
0


585
chr7
90356000
90357000
0.000
0.040
CDK14
1.00000
0


586
chr7
93304000
93305000
0.000
0.000
CALCR
1.00000
0


587
chr7
93682000
93683000
0.040
0.000
BET1
1.00000
0


588
chr7
102644000
102645000
0.000
0.000
FBXL13
1.00000
0


589
chr7
105699000
105700000
0.000
0.040
CDHR3
1.00000
0


590
chr7
110521000
110522000
0.040
0.040
IMMP2L
1.00000
0


591
chr7
110543000
110544000
0.040
0.000
IMMP2L
1.00000
0


592
chr7
110545000
110546000
0.040
0.000
IMMP2L
1.00000
0


593
chr7
110597000
110598000
0.000
0.040
IMMP21
1.00000
0


594
chr7
110601000
110602000
0.000
0.000
IMMP2L
1.00000
0


595
chr7
110602000
110603000
0.040
0.000
IMMP2L
1.00000
0


596
chr7
110609000
110610000
0.040
0.000
IMMP2L
1.00000
0


597
chr7
110610000
110611000
0.040
0.000
IMMP2L
1.00000
0


598
chr7
110617000
110618000
0.040
0.000
IMMP2L
1.00000
0


599
chr7
110618000
110619000
0.000
0.000
IMMP2L
1.00000
0


600
chr7
110619000
110620000
0.040
0.000
IMMP2L
1.00000
0


601
chr7
110621000
110622000
0.000
0.040
IMMP2L
1.00000
0


602
chr7
110628000
110629000
0.040
0.000
IMMP2L
1.00000
0


603
chr7
110629000
110630000
0.000
0.000
IMMP2L
1.00000
0


604
chr7
110631000
110632000
0.000
0.040
IMMP2L
1.00000
0


605
chr7
110632000
110633000
0.040
0.000
IMMP2L
1.00000
0


606
chr7
110636000
110637000
0.040
0.000
IMMP2L
1.00000
0


607
chr7
110637000
110638000
0.000
0.000
IMMP2L
1.00000
0


608
chr7
110638000
110639000
0.000
0.040
IMMP2L
1.00000
0


609
chr7
110639000
110640000
0.000
0.040
IMMP2L
1.00000
0


610
chr7
110641000
110642000
0.000
0.000
IMMP2L
1.00000
0


611
chr7
110650000
110651000
0.000
0.000
IMMP2L
1.00000
0


612
chr7
110651000
110652000
0.000
0.040
IMMP2L
1.00000
0


613
chr7
110666000
110667000
0.000
0.000
IMMP2L
1.00000
0


614
chr7
110671000
110672000
0.000
0.080
IMMP2L
0.48980
0


615
chr7
110677000
110678000
0.000
0.000
IMMP2L
1.00000
0


616
chr7
110679000
110680000
0.000
0.000
IMMP2L
1.00000
0


617
chr7
110680000
110681000
0.000
0.000
IMMP2L
1.00000
0


618
chr7
110685000
110686000
0.000
0.000
LRRN3
1.00000
0


619
chr7
110686000
110687000
0.000
0.040
LRRN3
1.00000
0


620
chr7
110688000
110689000
0.000
0.000
LRRN3
1.00000
0


621
chr7
110699000
110700000
0.080
0.000
LRRN3
0.48980
0


622
chr7
110700000
110701000
0.040
0.000
LRRN3
1.00000
0


623
chr7
110709000
110710000
0.000
0.040
LRRN3
1.00000
0


624
chr7
110711000
110712000
0.000
0.040
LRRN3
1.00000
0


625
chr7
110714000
110715000
0.000
0.040
LRRN3
1.00000
0


626
chr7
110727000
110728000
0.000
0.040
LRRN3
1.00000
0


627
chr7
110728000
110729000
0.040
0.000
LRRN3
1.00000
0


628
chr7
110729000
110730000
0.000
0.040
LRRN3
1.00000
0


629
chr7
110734000
110735000
0.000
0.040
LRRN3
1.00000
0


630
chr7
110737000
110738000
0.000
0.000
LRRN3
1.00000
0


631
chr7
110740000
110741000
0.040
0.080
LRRN3
1.00000
0


632
chr7
110744000
110745000
0.000
0.000
LRRN3
1.00000
0


633
chr7
110746000
110747000
0.000
0.040
LRRN3
1.00000
0


634
chr7
110747000
110748000
0.000
0.000
LRRN3
1.00000
0


635
chr7
110748000
110749000
0.000
0.000
LRRN3
1.00000
0


636
chr7
110755000
110756000
0.000
0.000
LRRN3
1.00000
0


637
chr7
110764000
110765000
0.000
0.000
LRRN3
1.00000
0


638
chr7
110767000
110768000
0.040
0.000
LRRN3
1.00000
0


639
chr7
110769000
110770000
0.000
0.040
LRRN3
1.00000
0


640
chr7
110771000
110772000
0.040
0.040
LRRN3
1.00000
0


641
chr7
110779000
110780000
0.000
0.000
LRRN3
1.00000
0


642
chr7
110780000
110781000
0.000
0.040
LRRN3
1.00000
0


643
chr7
110783000
110784000
0.000
0.040
LRRN3
1.00000
0


644
chr7
110785000
110786000
0.000
0.080
LRRN3
0.48980
0


645
chr7
110801000
110802000
0.000
0.040
LRRN3
1.00000
0


646
chr7
110802000
110803000
0.000
0.040
LRRN3
1.00000
0


647
chr7
110810000
110811000
0.000
0.000
LRRN3
1.00000
0


648
chr7
110816000
110817000
0.000
0.000
LRRN3
1.00000
0


649
chr7
110821000
110822000
0.000
0.040
LRRN3
1.00000
0


650
chr7
110824000
110825000
0.000
0.000
LRRN3
1.00000
0


651
chr7
110827000
110828000
0.040
0.000
LRRN3
1.00000
0


652
chr7
110836000
110837000
0.040
0.040
LRRN3
1.00000
0


653
chr7
110847000
110848000
0.000
0.040
LRRN3
1.00000
0


654
chr7
111567000
111568000
0.000
0.000
DOCK4
1.00000
0


655
chr7
119056000
119057000
0.040
0.000
KCND2
1.00000
0


656
chr7
121380000
121381000
0.040
0.000
PTPRZ1
1.00000
0


657
chr7
123887000
123888000
0.000
0.000
TMEM229A
1.00000
0


658
chr7
125262000
125263000
0.000
0.040
POT1
1.00000
0


659
chr7
145723000
145724000
0.000
0.000
CNTNAP2
1.00000
0


660
chr7
148508000
148509000
0.000
0.000
EZH2
1.00000
0


661
chr7
155127000
155128000
0.000
0.000
BLACE
1.00000
0


662
chr7
157162000
157163000
0.040
0.000
DNAJB6
1.00000
0


663
chr7
158684000
158685000
0.000
0.040
WDR60
1.00000
0


664
chr8
1646000
1647000
0.000
0.040
DLGAP2
1.00000
0


665
chr8
5558000
5559000
0.000
0.040
MCPH1
1.00000
0


666
chr8
5612000
5613000
0.000
0.000
MCPH1
1.00000
0


667
chr8
8602000
8603000
0.000
0.120
MFHAS1
0.23469
0


668
chr8
8706000
8707000
0.000
0.000
MFHAS1
1.00000
0


669
chr8
8717000
8718000
0.000
0.040
MFHAS1
1.00000
0


670
chr8
11352000
11353000
0.040
0.040
BLK
1.00000
0


671
chr8
14080000
14081000
0.000
0.040
SGCZ
1.00000
0


672
chr8
14796000
14797000
0.040
0.000
SGCZ
1.00000
0


673
chr8
16090000
16091000
0.000
0.040
MSR1
1.00000
0


674
chr8
16187000
16188000
0.000
0.080
MSR1
0.48980
0


675
chr8
23101000
23102000
0.000
0.040
CHMP7
1.00000
0


676
chr8
24207000
24208000
0.000
0.000
ADAM28
1.00000
0


677
chr8
29155000
29156000
0.000
0.040
KIF13B
1.00000
0


678
chr8
35657000
35658000
0.000
0.000
AC012215.1
1.00000
0


679
chr8
38759000
38760000
0.040
0.000
PLEKHA2
1.00000
0


680
chr8
54986000
54987000
0.040
0.000
LYPLA1
1.00000
0


681
chr8
60031000
60032000
0.040
0.000
TOX
1.00000
0


682
chr8
67525000
67526000
0.040
0.000
MYBL1
1.00000
0


683
chr8
77105000
77106000
0.000
0.000
ZFHX4
1.00000
0


684
chr8
78400000
78401000
0.000
0.040
PEX2
1.00000
0


685
chr8
90322000
90323000
0.040
0.000
RIPK2
1.00000
0


686
chr8
93199000
93200000
0.000
0.040
RUNX1T1
1.00000
0


687
chr8
94618000
94619000
0.000
0.040
FAM92A1
1.00000
0


688
chr8
110586000
110587000
0.000
0.040
SYBU
1.00000
0


689
chr8
126687000
126688000
0.000
0.000
TRIB1
1.00000
0


690
chr8
128748000
128749000
0.080
0.280
MYC
0.13833
1


691
chr8
128749000
128750000
0.080
0.320
MYC
0.07375
1


692
chr8
128750000
128751000
0.080
0.120
MYC
1.00000
1


693
chr8
128751000
128752000
0.040
0.080
MYC
1.00000
1


694
chr8
128752000
128753000
0.000
0.000
MYC
1.00000
1


695
chr8
137918000
137919000
0.000
0.040
FAM135B
1.00000
0


696
chr8
138274000
138275000
0.000
0.000
FAM135B
1.00000
0


697
chr8
143183000
143184000
0.000
0.040
TSNARE1
1.00000
0


698
chr8
144123000
144124000
0.000
0.040
C8orf31
1.00000
0


699
chr9
6411000
6412000
0.040
0.040
UHRF2
1.00000
0


700
chr9
6413000
6414000
0.040
0.040
UHRF2
1.00000
0


701
chr9
6414000
6415000
0.000
0.000
UHRF2
1.00000
0


702
chr9
9928000
9929000
0.000
0.000
PTPRD
1.00000
0


703
chr9
13965000
13966000
0.040
0.000
NFIB
1.00000
0


704
chr9
22824000
22825000
0.040
0.000
DMRTA1
1.00000
0


705
chr9
25260000
25261000
0.040
0.000
TUSC1
1.00000
0


706
chr9
29890000
29891000
0.040
0.000
LINGO2
1.00000
0


707
chr9
30656000
30657000
0.000
0.040
ACO1
1.00000
0


708
chr9
37003000
37004000
0.040
0.000
PAX5
1.00000
1


709
chr9
37005000
37006000
0.040
0.000
PAX5
1.00000
1


710
chr9
37024000
37025000
0.040
0.040
PAX5
1.00000
1


711
chr9
37025000
37026000
0.160
0.120
PAX5
1.00000
1


712
chr9
37026000
37027000
0.240
0.120
PAX5
0.46349
1


713
chr9
37027000
37028000
0.080
0.040
PAX5
1.00000
1


714
chr9
37033000
37034000
0.120
0.040
PAX5
0.60921
1


715
chr9
37034000
37035000
0.120
0.040
PAX5
0.60921
1


716
chr9
37035000
37036000
0.000
0.040
PAX5
1.00000
1


717
chr9
37196000
37197000
0.040
0.000
ZCCHC7
1.00000
0


718
chr9
37197000
37198000
0.040
0.000
ZCCHC7
1.00000
0


719
chr9
37293000
37294000
0.000
0.000
ZCCHC7
1.00000
0


720
chr9
37294000
37295000
0.080
0.000
ZCCHC7
0.48980
0


721
chr9
37327000
37328000
0.040
0.000
ZCCHC7
1.00000
0


722
chr9
37336000
37337000
0.080
0.000
ZCCHC7
0.48980
0


723
chr9
37337000
37338000
0.000
0.000
ZCCHC7
1.00000
0


724
chr9
37338000
37339000
0.000
0.040
ZCCHC7
1.00000
0


725
chr9
37369000
37370000
0.040
0.000
ZCCHC7
1.00000
0


726
chr9
37371000
37372000
0.080
0.080
ZCCHC7
1.00000
0


727
chr9
37372000
37373000
0.000
0.000
ZCCHC7
1.00000
0


728
chr9
37383000
37384000
0.080
0.080
ZCCHC7
1.00000
0


729
chr9
37384000
37385000
0.120
0.040
ZCCHC7
0.60921
0


730
chr9
37385000
37386000
0.040
0.000
ZCCHC7
1.00000
0


731
chr9
37387000
37388000
0.080
0.040
ZCCHC7
1.00000
0


732
chr9
37397000
37398000
0.040
0.120
GRHPR
0.60921
0


733
chr9
37398000
37399000
0.040
0.000
GRHPR
1.00000
0


734
chr9
37399000
37400000
0.080
0.000
GRHPR
0.48980
0


735
chr9
37402000
37403000
0.000
0.040
GRHPR
1.00000
0


736
chr9
37406000
37407000
0.000
0.040
GRHPR
1.00000
0


737
chr9
37407000
37408000
0.200
0.080
GRHPR
0.41743
0


738
chr9
37408000
37409000
0.080
0.000
GRHPR
0.48980
0


739
chr9
37410000
37411000
0.000
0.000
GRHPR
1.00000
0


740
chr9
37424000
37425000
0.040
0.040
GRHPR
1.00000
0


741
chr9
37425000
37426000
0.000
0.040
GRHPR
1.00000
0


742
chr9
112811000
112812000
0.080
0.080
AKAP2
1.00000
0


743
chr9
117037000
117038000
0.000
0.040
COL27A1
1.00000
0


744
chr9
119779000
119780000
0.040
0.000
ASTN2
1.00000
0


745
chr9
126232000
126233000
0.040
0.000
DENND1A
1.00000
0


746
chr9
130741000
130742000
0.040
0.000
FAM102A
1.00000
1


747
chr9
130742000
130743000
0.040
0.080
FAM102A
1.00000
1


748
chr9
132767000
132768000
0.000
0.040
FNBP1
1.00000
0


749
chr9
132785000
132786000
0.040
0.000
FNBP1
1.00000
0


750
chr9
132803000
132804000
0.000
0.040
FNBP1
1.00000
0


751
chr9
132804000
132805000
0.040
0.120
FNBP1
0.60921
0


752
chr9
134551000
134552000
0.040
0.000
RAPGEF1
1.00000
0


753
chr9
138874000
138875000
0.000
0.040
UBAC1
1.00000
0


754
chr10
3333000
3334000
0.000
0.000
PITRM1
1.00000
0


755
chr10
5707000
5708000
0.040
0.040
ASB13
1.00000
0


756
chr10
5728000
5729000
0.000
0.040
ASB13
1.00000
0


757
chr10
15393000
15394000
0.000
0.000
FAM171A1
1.00000
0


758
chr10
20796000
20797000
0.040
0.000
PLXDC2
1.00000
0


759
chr10
35424000
35425000
0.000
0.000
CREM
1.00000
0


760
chr10
56678000
56679000
0.000
0.000
PCDH15
1.00000
0


761
chr10
63440000
63441000
0.000
0.040
C10orf107
1.00000
0


762
chr10
63659000
63660000
0.040
0.000
ARID5B
1.00000
1


763
chr10
63660000
63661000
0.040
0.080
ARID5B
1.00000
1


764
chr10
63662000
63663000
0.000
0.000
ARID5B
1.00000
1


765
chr10
63720000
63721000
0.000
0.000
ARID5B
1.00000
1


766
chr10
63803000
63804000
0.000
0.000
ARID5B
1.00000
1


767
chr10
63809000
63810000
0.000
0.080
ARID5B
0.48980
1


768
chr10
63810000
63811000
0.000
0.040
ARID5B
1.00000
1


769
chr10
67907000
67908000
0.000
0.040
CTNNA3
1.00000
0


770
chr10
68474000
68475000
0.000
0.000
CTNNA3
1.00000
0


771
chr10
98510000
98511000
0.080
0.000
PIK3AP1
0.48980
0


772
chr10
101384000
101385000
0.000
0.000
SLC25A28
1.00000
0


773
chr10
108276000
108277000
0.040
0.000
SORCS1
1.00000
0


774
chr10
113473000
113474000
0.040
0.040
GPAM
1.00000
0


775
chr10
113636000
113637000
0.040
0.000
GPAM
1.00000
0


776
chr10
116458000
116459000
0.000
0.040
ABLIM1
1.00000
0


777
chr10
121623000
121624000
0.040
0.000
MCMBP
1.00000
0


778
chr10
132973000
132974000
0.040
0.000
TCERG1L
1.00000
0


779
chr10
134326000
134327000
0.000
0.000
INPP5A
1.00000
0


780
chr11
871000
872000
0.040
0.040
CHID1
1.00000
0


781
chr11
1149000
1150000
0.000
0.000
MUC5AC
1.00000
0


782
chr11
25065000
25066000
0.040
0.000
LUZP2
1.00000
0


783
chr11
25289000
25290000
0.040
0.040
LUZP2
1.00000
0


784
chr11
27216000
27217000
0.000
0.040
BBOX1
1.00000
0


785
chr11
28849000
28850000
0.000
0.000
METTL15
1.00000
0


786
chr11
29253000
29254000
0.040
0.000
KCNA4
1.00000
0


787
chr11
29900000
29901000
0.000
0.000
KCNA4
1.00000
0


788
chr11
40626000
40627000
0.000
0.000
LRRC4C
1.00000
0


789
chr11
40845000
40846000
0.000
0.000
LRRC4C
1.00000
0


790
chr11
40868000
40869000
0.000
0.000
LRRC4C
1.00000
0


791
chr11
41066000
41067000
0.000
0.000
LRRC4C
1.00000
0


792
chr11
41844000
41845000
0.000
0.000
API5
1.00000
0


793
chr11
57171000
57172000
0.040
0.000
SLC43A3
1.00000
0


794
chr11
60224000
60225000
0.040
0.080
MS4A1
1.00000
1


795
chr11
65190000
65191000
0.080
0.120
FRMD8
1.00000
0


796
chr11
65191000
65192000
0.080
0.120
FRMD8
1.00000
0


797
chr11
65266000
65267000
0.000
0.040
SCYL1
1.00000
0


798
chr11
65267000
65268000
0.120
0.040
SCYL1
0.60921
0


799
chr11
85963000
85964000
0.000
0.000
EED
1.00000
0


800
chr11
92261000
92262000
0.000
0.040
FAT3
1.00000
0


801
chr11
102117000
102118000
0.000
0.000
YAP1
1.00000
0


802
chr11
102188000
102189000
0.200
0.280
BIRC3
0.74164
1


803
chr11
102189000
102190000
0.040
0.080
BIRC3
1.00000
1


804
chr11
107497000
107498000
0.000
0.000
ELMOD1
1.00000
0


805
chr11
108781000
108782000
0.000
0.040
DDX10
1.00000
0


806
chr11
108975000
108976000
0.040
0.000
DDX10
1.00000
0


807
chr11
109066000
109067000
0.000
0.000
C11orf87
1.00000
0


808
chr11
111248000
111249000
0.000
0.040
POU2AF1
1.00000
1


809
chr11
111249000
111250000
0.120
0.160
POU2AF1
1.00000
1


810
chr11
115761000
115762000
0.000
0.040
CADM1
1.00000
0


811
chr11
118723000
118724000
0.040
0.000
CXCR5
1.00000
0


812
chr11
126496000
126497000
0.040
0.000
KIRREL3
1.00000
0


813
chr11
128390000
128391000
0.040
0.040
ETS1
1.00000
1


814
chr11
128391000
128392000
0.160
0.040
ETS1
0.34868
1


815
chr12
6554000
6555000
0.000
0.040
CD27
1.00000
0


816
chr12
8762000
8763000
0.040
0.000
AICDA
1.00000
0


817
chr12
8763000
8764000
0.080
0.040
AICDA
1.00000
0


818
chr12
8764000
8765000
0.080
0.000
AICDA
0.48980
0


819
chr12
8765000
8766000
0.040
0.000
AICDA
1.00000
0


820
chr12
9823000
9824000
0.040
0.000
CLEC2D
1.00000
0


821
chr12
11710000
11711000
0.000
0.040
ETV6
1.00000
1


822
chr12
11803000
11804000
0.040
0.000
ETV6
1.00000
1


823
chr12
14923000
14924000
0.040
0.040
HIST4H4
1.00000
1


824
chr12
16717000
16718000
0.000
0.000
LMO3
1.00000
0


825
chr12
23805000
23806000
0.000
0.040
SOX5
1.00000
0


826
chr12
25149000
25150000
0.000
0.040
C12orf77
1.00000
0


827
chr12
25151000
25152000
0.000
0.040
C12orf77
1.00000
0


828
chr12
25174000
25175000
0.040
0.040
C12orf77
1.00000
0


829
chr12
25205000
25206000
0.040
0.040
LRMP
1.00000
1


830
chr12
25206000
25207000
0.080
0.120
LRMP
1.00000
1


831
chr12
25207000
25208000
0.080
0.120
LRMP
1.00000
1


832
chr12
25208000
25209000
0.000
0.040
LRMP
1.00000
1


833
chr12
25665000
25666000
0.000
0.000
IFLTD1
1.00000
0


834
chr12
38920000
38921000
0.000
0.000
CPNE8
1.00000
0


835
chr12
48027000
48028000
0.080
0.080
RPAP3
1.00000
0


836
chr12
57496000
57497000
0.040
0.000
STAT6
1.00000
0


837
chr12
69203000
69204000
0.000
0.040
MDM2
1.00000
0


838
chr12
76202000
76203000
0.000
0.000
PHLDA1
1.00000
0


839
chr12
79270000
79271000
0.000
0.000
SYT1
1.00000
0


840
chr12
82572000
82573000
0.000
0.040
CCDC59
1.00000
0


841
chr12
84837000
84838000
0.000
0.000
SLC6A15
1.00000
0


842
chr12
86114000
86115000
0.040
0.000
RASSF9
1.00000
0


843
chr12
86115000
86116000
0.040
0.000
RASSF9
1.00000
0


844
chr12
92538000
92539000
0.080
0.080
BTG1
1.00000
1


845
chr12
92539000
92540000
0.080
0.040
BTG1
1.00000
1


846
chr12
96030000
96031000
0.000
0.040
NTN4
1.00000
0


847
chr12
110171000
110172000
0.000
0.040
FAM222A
1.00000
0


848
chr12
110980000
110981000
0.000
0.040
PPTC7
1.00000
0


849
chr12
113493000
113494000
0.080
0.000
DTX1
0.48980
1


850
chr12
113494000
113495000
0.240
0.040
DTX1
0.09828
1


851
chr12
113495000
113496000
0.160
0.080
DTX1
0.66710
1


852
chr12
113496000
113497000
0.160
0.040
DTX1
0.34868
1


853
chr12
113497000
113498000
0.080
0.040
DTX1
1.00000
1


854
chr12
113499000
113500000
0.000
0.000
DTX1
1.00000
1


855
chr12
113512000
113513000
0.000
0.000
DTX1
1.00000
1


856
chr12
115966000
115967000
0.000
0.000
MED13L
1.00000
0


857
chr12
122432000
122433000
0.040
0.000
WDR66
1.00000
0


858
chr12
122433000
122434000
0.080
0.000
WDR66
0.48980
0


859
chr12
122447000
122448000
0.000
0.040
WDR66
1.00000
0


860
chr12
122458000
122459000
0.080
0.120
BCL7A
1.00000
1


861
chr12
122459000
122460000
0.240
0.320
BCL7A
0.75361
1


862
chr12
122460000
122461000
0.120
0.280
BCL7A
0.28902
1


863
chr12
122461000
122462000
0.240
0.240
BCL7A
1.00000
1


864
chr12
122462000
122463000
0.160
0.200
BCL7A
1.00000
1


865
chr12
122463000
122464000
0.120
0.200
BCL7A
0.70194
1


866
chr12
124054000
124055000
0.000
0.080
TMED2
0.48980
0


867
chr12
127965000
127966000
0.000
0.000
TMEM132C
1.00000
0


868
chr12
131303000
131304000
0.000
0.120
STX2
0.23469
0


869
chr12
131649000
131650000
0.000
0.000
GPR133
1.00000
0


870
chr12
133306000
133307000
0.000
0.000
ANKLE2
1.00000
0


871
chr13
21913000
21914000
0.040
0.040
ZDHHC20
1.00000
0


872
chr13
32116000
32117000
0.040
0.040
RXFP2
1.00000
0


873
chr13
35498000
35499000
0.000
0.000
NBEA
1.00000
0


874
chr13
38371000
38372000
0.040
0.000
TRPC4
1.00000
0


875
chr13
38630000
38631000
0.040
0.000
TRPC4
1.00000
0


876
chr13
41156000
41157000
0.000
0.040
FOXO1
1.00000
1


877
chr13
41240000
41241000
0.000
0.040
FOXO1
1.00000
1


878
chr13
46958000
46959000
0.000
0.000
KIAA0226L
1.00000
0


879
chr13
46959000
46960000
0.040
0.000
KIAA0226L
1.00000
0


880
chr13
46960000
46961000
0.160
0.040
KIAA0226L
0.34868
0


881
chr13
46961000
46962000
0.000
0.040
KIAA0226L
1.00000
0


882
chr13
46962000
46963000
0.000
0.040
KIAA0226L
1.00000
0


883
chr13
55239000
55240000
0.040
0.000
OLFM4
1.00000
0


884
chr13
55386000
55387000
0.040
0.000
OLFM4
1.00000
0


885
chr13
55598000
55599000
0.000
0.000
OLFM4
1.00000
0


886
chr13
57222000
57223000
0.000
0.040
PRR20A;
1.00000
0








PRR20D










PRR20B










PRR20E;




887
chr13
61343000
61344000
0.000
0.000
TDRD3
1.00000
0


888
chr13
62830000
62831000
0.000
0.000
PCDH20
1.00000
0


889
chr13
63049000
63050000
0.080
0.000
PCDH20
0.48980
0


890
chr13
63157000
63158000
0.000
0.000
AL445989.1
1.00000
0


891
chr13
63214000
63215000
0.040
0.000
AL445989.1
1.00000
0


892
chr13
64802000
64803000
0.000
0.040
AL445989.1
1.00000
0


893
chr13
65637000
65638000
0.000
0.040
PCDH9
1.00000
0


894
chr13
68656000
68657000
0.000
0.000
PCDH9
1.00000
0


895
chr13
69418000
69419000
0.000
0.000
KLHL1
1.00000
0


896
chr13
70956000
70957000
0.040
0.000
KLHL1
1.00000
0


897
chr13
74542000
74543000
0.000
0.040
KLF12
1.00000
0


898
chr13
75983000
75984000
0.000
0.040
TBC1D4
1.00000
0


899
chr13
75984000
75985000
0.000
0.160
TBC1D4
0.10986
0


900
chr13
83450000
83451000
0.000
0.000
SLITRK1
1.00000
0


901
chr13
84641000
84642000
0.040
0.000
SLITRK1
1.00000
0


902
chr13
87793000
87794000
0.040
0.000
SLITRK5
1.00000
0


903
chr13
91480000
91481000
0.000
0.000
GPC5
1.00000
0


904
chr13
106081000
106082000
0.040
0.000
DAOA
1.00000
0


905
chr13
114786000
114787000
0.040
0.000
RASA3
1.00000
0


906
chr13
114916000
114917000
0.000
0.000
RASA3
1.00000
0


907
chr14
22948000
22949000
0.040
0.000
TRAJ56
1.00000
0


908
chr14
22949000
22950000
0.040
0.000
TRAJ56
1.00000
0


909
chr14
22950000
22951000
0.040
0.000
TRAJ54
1.00000
0


910
chr14
22977000
22978000
0.000
0.040
TRAJ33
1.00000
0


911
chr14
27286000
27287000
0.000
0.000
NOVA1
1.00000
0


912
chr14
28645000
28646000
0.000
0.000
FOXG1
1.00000
0


913
chr14
49407000
49408000
0.000
0.000
RPS29
1.00000
0


914
chr14
50864000
50865000
0.000
0.000
CDKL1
1.00000
0


915
chr14
54812000
54813000
0.000
0.000
CDKN3
1.00000
0


916
chr14
55348000
55349000
0.040
0.000
GCH1
1.00000
0


917
chr14
59827000
59828000
0.000
0.040
DAAM1
1.00000
0


918
chr14
63143000
63144000
0.000
0.040
KCNH5
1.00000
0


919
chr14
64194000
64195000
0.000
0.040
SGPP1
1.00000
0


920
chr14
69258000
69259000
0.240
0.200
ZFP36L1
1.00000
1


921
chr14
69259000
69260000
0.360
0.240
ZFP36L1
0.53803
1


922
chr14
78418000
78419000
0.000
0.040
ADCK1
1.00000
0


923
chr14
81685000
81686000
0.000
0.040
GTF2A1
1.00000
0


924
chr14
84420000
84421000
0.040
0.000
FLRT2
1.00000
0


925
chr14
91883000
91884000
0.040
0.000
CCDC88C
1.00000
0


926
chr14
94941000
94942000
0.000
0.120
SERPINA9
0.23469
1


927
chr14
94942000
94943000
0.040
0.200
SERPINA9
0.18946
1


928
chr14
96179000
96180000
0.160
0.120
TCL1A
1.00000
1


929
chr14
96180000
96181000
0.080
0.160
TCL1A
0.66710
1


930
chr14
101597000
101598000
0.000
0.000
AL117190.3
1.00000
0


931
chr14
102285000
102286000
0.040
0.000
PPP2R5C
1.00000
0


932
chr14
105954000
105955000
0.040
0.040
CRIP1
1.00000
0


933
chr14
106031000
106032000
0.040
0.000
IGHA2
1.00000
0


934
chr14
106042000
106043000
0.080
0.200
IGHA2
0.41743
0


935
chr14
106048000
106049000
0.040
0.040
IGHA2
1.00000
0


936
chr14
106054000
106055000
0.040
0.040
IGHA2
1.00000
0


937
chr14
106055000
106056000
0.080
0.240
IGHA2
0.24672
0


938
chr14
106056000
106057000
0.040
0.200
IGHA2
0.18946
0


939
chr14
106057000
106058000
0.000
0.080
IGHA2
0.48980
0


940
chr14
106058000
106059000
0.000
0.080
IGHA2
0.48980
0


941
chr14
06066000
106067000
0.000
0.120
IGHE
0.23469
0


942
chr14
106067000
106068000
0.000
0.120
IGHE
0.23469
0


943
chr14
106068000
106069000
0.040
0.120
IGHE
0.60921
0


944
chr14
106069000
106070000
0.040
0.200
IGHE
0.18946
0


945
chr14
106070000
106071000
0.000
0.160
IGHE
0.10986
0


946
chr14
106071000
106072000
0.000
0.160
IGHE
0.10986
0


947
chr14
106072000
106073000
0.000
0.120
IGHE
0.23469
0


948
chr14
106082000
106083000
0.000
0.000
IGHG4
1.00000
0


949
chr14
106092000
106093000
0.040
0.000
IGHG4
1.00000
0


950
chr14
106094000
106095000
0.160
0.200
IGHG4
1.00000
0


951
chr14
106095000
106096000
0.080
0.160
IGHG4
0.66710
0


952
chr14
106110000
106111000
0.080
0.040
IGHG2
1.00000
0


953
chr14
106111000
106112000
0.000
0.040
IGHG2
1.00000
0


954
chr14
106112000
106113000
0.280
0.200
IGHG2
0.74164
0


955
chr14
106113000
106114000
0.240
0.320
IGHG2
0.75361
0


956
chr14
106114000
106115000
0.320
0.200
IGHG2
0.52019
0


957
chr14
106146000
106147000
0.000
0.000
IGHA1
1.00000
0


958
chr14
106151000
106152000
0.040
0.000
IGHA1
1.00000
0


959
chr14
106152000
106153000
0.040
0.000
IGHA1
1.00000
0


960
chr14
106161000
106162000
0.000
0.040
IGHA1
1.00000
0


961
chr14
106173000
106174000
0.040
0.040
IGHA1
1.00000
0


962
chr14
106174000
106175000
0.040
0.000
IGHA1
1.00000
0


963
chr14
106175000
106176000
0.040
0.000
IGHA1
1.00000
0


964
chr14
106176000
106177000
0.080
0.040
IGHA1
1.00000
0


965
chr14
106177000
106178000
0.000
0.000
IGHA1
1.00000
0


966
chr14
106178000
106179000
0.120
0.000
IGHA1
0.23469
0


967
chr14
106208000
106209000
0.040
0.040
IGHG1
1.00000
0


968
chr14
106209000
106210000
0.160
0.080
IGHG1
0.66710
0


969
chr14
106210000
106211000
0.160
0.120
IGHG1
1.00000
0


970
chr14
106211000
106212000
0.440
0.120
IGHG1
0.02548
0


971
chr14
106212000
106213000
0.520
0.120
IGHG1
0.00544
0


972
chr14
106213000
106214000
0.520
0.120
IGHG1
0.00544
0


973
chr14
106214000
106215000
0.240
0.000
IGHG1
0.02229
0


974
chr14
106237000
106238000
0.080
0.040
IGHG3
1.00000
0


975
chr14
106238000
106239000
0.320
0.120
IGHG3
0.17062
0


976
chr14
106239000
106240000
0.440
0.040
IGHG3
0.00192
0


977
chr14
106240000
06241000
0.480
0.080
IGHG3
0.00361
0


978
chr14
106241000
106242000
0.320
0.040
IGHG3
0.02322
0


979
chr14
106242000
106243000
0.040
0.000
IGHG3
1.00000
0


980
chr14
106321000
106322000
0.040
0.000
IGHM
1.00000
0


981
chr14
106322000
106323000
0.240
0.040
IGHM
0.09828
0


982
chr14
106323000
106324000
0.400
0.160
IGHM
0.11366
0


983
chr14
106324000
106325000
0.320
0.120
IGHM
0.17062
0


984
chr14
106325000
106326000
0.160
0.320
IGHM
0.32089
0


985
chr14
106326000
106327000
0.920
0.920
IGHJ6
1.00000
0


986
chr14
106327000
106328000
0.800
0.760
IGHJ6
1.00000
0


987
chr14
106328000
106329000
0.680
0.800
IGHJ6
0.52019
0


988
chr14
106329000
106330000
0.880
0.920
IGHJ6
1.00000
0


989
chr14
106330000
106331000
0.720
0.520
IGHJ3; IGHJ4;
0.24363
0








IGHJ5;




990
chr14
106331000
106332000
0.120
0.080
IGHD7-27;
1.00000
0








IGHJ1; IGHJ2




991
chr14
106338000
106339000
0.040
0.000
IGHD7-27
1.00000
0


992
chr14
106350000
106351000
0.040
0.000
IGHD4-23
1.00000
0


993
chr14
106352000
106353000
0.000
0.040
IGHD3-22
1.00000
0


994
chr14
106353000
106354000
0.000
0.000
IGHD2-21
1.00000
0


995
chr14
106354000
106355000
0.000
0.040
IGHD2-21
1.00000
0


996
chr14
106355000
106356000
0.000
0.040
IGHD2-21
1.00000
0


997
chr14
106357000
106358000
0.040
0.080
IGHD1-20;
1.00000
0








IGHD6-19;




998
chr14
106358000
106359000
0.000
0.040
IGHD5-18
1.00000
0


999
chr14
106362000
106363000
0.000
0.000
IGHD3-16
1.00000
0


1000
chr14
106364000
106365000
0.040
0.000
IGHD2-15
1.00000
0


1001
chr14
106367000
106368000
0.040
0.000
IGHD6-13
1.00000
0


1002
chr14
106370000
106371000
0.080
0.000
IGHD3-10;
0.48980
0








IGHD3-9;




1003
chr14
106371000
106372000
0.040
0.000
IGHD3-9
1.00000
0


1004
chr14
106372000
106373000
0.040
0.000
IGHD2-8
1.00000
0


1005
chr14
106375000
106376000
0.000
0.000
IGHD1-7
1.00000
0


1006
chr14
106376000
106377000
0.000
0.040
IGHD6-6
1.00000
0


1007
chr14
106380000
106381000
0.000
0.040
IGHD3-3
1.00000
0


1008
chr14
106381000
106382000
0.000
0.040
IGHD2-2
1.00000
0


1009
chr14
106382000
106383000
0.040
0.120
IGHD2-2
0.60921
0


1010
chr14
106383000
106384000
0.080
0.040
IGHD2-2
1.00000
0


1011
chr14
106384000
106385000
0.040
0.040
IGHD1-1
1.00000
0


1012
chr14
106385000
106386000
0.080
0.040
IGHD1-1
1.00000
0


1013
chr14
106387000
106388000
0.040
0.080
KIAA0125
1.00000
0


1014
chr14
106405000
106406000
0.000
0.040
IGHV6-1
1.00000
0


1015
chr14
106406000
106407000
0.000
0.040
IGHV6-1
1.00000
0


1016
chr14
106419000
106420000
0.000
0.080
IGHV6-1
0.48980
0


1017
chr14
106452000
106453000
0.040
0.000
IGHV1-2
1.00000
0


1018
chr14
106453000
106454000
0.080
0.000
IGHV1-2
0.48980
0


1019
chr14
106454000
106455000
0.040
0.000
IGHV1-2
1.00000
0


1020
chr14
106494000
106495000
0.000
0.040
IGHV2-5
1.00000
0


1021
chr14
106518000
106519000
0.000
0.080
IGHV3-7
0.48980
0


1022
chr14
106519000
106520000
0.000
0.080
IGHV3-7
0.48980
0


1023
chr14
106539000
106540000
0.000
0.040
IGHV1-8
1.00000
0


1024
chr14
106552000
106553000
0.000
0.000
IGHV3-9
1.00000
0


1025
chr14
106573000
106574000
0.040
0.000
IGHV3-11
1.00000
0


1026
chr14
106574000
106575000
0.040
0.000
IGHV3-11
1.00000
0


1027
chr14
106578000
106579000
0.040
0.000
IGHV3-11
1.00000
0


1028
chr14
106579000
106580000
0.040
0.000
IGHV3-11
1.00000
0


1029
chr14
106610000
106611000
0.000
0.000
IGHV3-15
1.00000
0


1030
chr14
106641000
106642000
0.040
0.040
IGHV1-18
1.00000
0


1031
chr14
106642000
106643000
0.040
0.000
IGHV1-18
1.00000
0


1032
chr14
106691000
106692000
0.000
0.000
IGHV3-21
1.00000
0


1033
chr14
106692000
106693000
0.000
0.040
IGHV3-21
1.00000
0


1034
chr14
106725000
106726000
0.120
0.160
IGHV3-23
1.00000
0


1035
chr14
106726000
106727000
0.040
0.080
IGHV3-23
1.00000
0


1036
chr14
106733000
106734000
0.000
0.080
IGHV1-24
0.48980
0


1037
chr14
106757000
106758000
0.000
0.040
IGHV2-26
1.00000
0


1038
chr14
106758000
106759000
0.000
0.040
IGHV2-26
1.00000
0


1039
chr14
106791000
106792000
0.040
0.040
IGHV3-30
1.00000
0


1040
chr14
106804000
106805000
0.040
0.040
IGHV4-31
1.00000
0


1041
chr14
106805000
106806000
0.040
0.040
IGHV4-31
1.00000
0


1042
chr14
106806000
106807000
0.000
0.000
IGHV4-31
1.00000
0


1043
chr14
106815000
106816000
0.000
0.040
IGHV3-33
1.00000
0


1044
chr14
106816000
106817000
0.000
0.160
IGHV3-33
0.10986
0


1045
chr14
106817000
106818000
0.000
0.080
IGHV3-33
0.48980
0


1046
chr14
106829000
106830000
0.160
0.080
IGHV4-34
0.66710
0


1047
chr14
106830000
106831000
0.160
0.000
IGHV4-34
0.10986
0


1048
chr14
106877000
106878000
0.040
0.080
IGHV4-39
1.00000
0


1049
chr14
106878000
106879000
0.000
0.080
IGHV4-39
0.48980
0


1050
chr14
106967000
106968000
0.040
0.040
IGHV1-46
1.00000
0


1051
chr14
106994000
106995000
0.000
0.120
IGHV3-48
0.23469
0


1052
chr14
106995000
106996000
0.000
0.000
IGHV3-48
1.00000
0


1053
chr14
107034000
107035000
0.040
0.000
IGHV5-51
1.00000
0


1054
chr14
107035000
107036000
0.080
0.000
IGHV5-51
0.48980
0


1055
chr14
107048000
107049000
0.000
0.000
IGHV3-53
1.00000
0


1056
chr14
107049000
107050000
0.000
0.000
IGHV3-53
1.00000
0


1057
chr14
107083000
107084000
0.040
0.040
IGHV4-59
1.00000
0


1058
chr14
107084000
107085000
0.000
0.040
IGHV4-59
1.00000
0


1059
chr14
107095000
107096000
0.040
0.000
IGHV4-61
1.00000
0


1060
chr14
107113000
107114000
0.080
0.000
IGHV3-64
0.48980
0


1061
chr14
107114000
107115000
0.080
0.000
IGHV3-64
0.48980
0


1062
chr14
107169000
107170000
0.200
0.240
IGHV1-69
1.00000
0


1063
chr14
107170000
107171000
0.360
0.280
IGHV1-69
0.76241
0


1064
chr14
107176000
107177000
0.200
0.200
IGHV2-70
1.00000
0


1065
chr14
107177000
107178000
0.080
0.040
IGHV2-70
1.00000
0


1066
chr14
107178000
107179000
0.200
0.520
IGHV2-70
0.03776
0


1067
chr14
107179000
107180000
0.240
0.360
IGHV2-70
0.53803
0


1068
chr14
107183000
107184000
0.000
0.000
IGHV2-70
1.00000
0


1069
chr14
107199000
107200000
0.000
0.080
IGHV3-72
0.48980
0


1070
chr14
107218000
107219000
0.000
0.080
IGHV3-74
0.48980
0


1071
chr14
107219000
107220000
0.000
0.160
IGHV3-74
0.10986
0


1072
chr14
107221000
107222000
0.000
0.080
IGHV3-74
0.48980
0


1073
chr14
107232000
107233000
0.000
0.000
IGHV3-74
1.00000
0


1074
chr14
107253000
107254000
0.000
0.000
IGHV7-81
1.00000
0


1075
chr14
107258000
107259000
0.000
0.040
IGHV7-81
1.00000
0


1076
chr14
107259000
107260000
0.160
0.200
IGHV7-81
1.00000
0


1077
chr15
45003000
45004000
0.040
0.040
B2M
1.00000
0


1078
chr15
45007000
45008000
0.000
0.000
B2M
1.00000
0


1079
chr15
45814000
45815000
0.000
0.040
SLC30A4
1.00000
0


1080
chr15
59664000
59665000
0.000
0.080
MYO1E
0.48980
0


1081
chr15
65588000
65589000
0.040
0.000
PARP16
1.00000
0


1082
chr15
78332000
78333000
0.000
0.000
TBC1D2B
1.00000
0


1083
chr15
83227000
83228000
0.000
0.040
CPEB1
1.00000
0


1084
chr15
86226000
86227000
0.040
0.040
AKAP13
1.00000
0


1085
chr15
86233000
86234000
0.040
0.000
AKAP13
1.00000
0


1086
chr15
86245000
86246000
0.080
0.120
AKAP13
1.00000
0


1087
chr16
368000
369000
0.000
0.040
AXIN1
1.00000
0


1088
chr16
3788000
3789000
0.040
0.000
CREBBP
1.00000
0


1089
chr16
10971000
10972000
0.080
0.120
CIITA
1.00000
1


1090
chr16
10972000
10973000
0.120
0.320
CIITA
0.17062
1


1091
chr16
10973000
10974000
0.120
0.240
CIITA
0.46349
1


1092
chr16
10974000
10975000
0.080
0.120
CIITA
1.00000
1


1093
chr16
11348000
11349000
0.080
0.200
SOCS1
0.41743
1


1094
chr16
11349000
11350000
0.120
0.240
SOCS1
0.46349
1


1095
chr16
21167000
21168000
0.040
0.000
DNAH3
1.00000
0


1096
chr16
27325000
27326000
0.000
0.040
CTD-3203P2.2
1.00000
0


1097
chr16
27326000
27327000
0.080
0.080
CTD-3203P2.2
1.00000
0


1098
chr16
27327000
27328000
0.000
0.000
IL4R
1.00000
0


1099
chr16
27414000
27415000
0.040
0.000
IL21R
1.00000
0


1100
chr16
29248000
29249000
0.000
0.000
61E3.4
1.00000
0


1101
chr16
31910000
31911000
0.040
0.000
ZNF267
1.00000
0


1102
chr16
46821000
46822000
0.000
0.040
C16orf87
1.00000
0


1103
chr16
50985000
50986000
0.040
0.000
CYLD
1.00000
0


1104
chr16
64351000
64352000
0.000
0.040
CDH11
1.00000
0


1105
chr16
78398000
78399000
0.000
0.000
WWOX
1.00000
0


1106
chr16
78615000
78616000
0.040
0.000
WWOX
1.00000
0


1107
chr16
78753000
78754000
0.000
0.040
WWOX
1.00000
0


1108
chr16
78811000
78812000
0.000
0.040
WWOX
1.00000
0


1109
chr16
79988000
79989000
0.000
0.040
MAF
1.00000
0


1110
chr16
81836000
81837000
0.000
0.000
PLCG2
1.00000
0


1111
chr16
85932000
85933000
0.040
0.040
IRF8
1.00000
1


1112
chr16
85933000
85934000
0.080
0.240
IRF8
0.24672
1


1113
chr16
85934000
85935000
0.040
0.000
IRF8
1.00000
1


1114
chr16
85936000
85937000
0.000
0.000
IRF8
1.00000
1


1115
chr16
88441000
88442000
0.040
0.000
ZNF469
1.00000
0


1116
chr17
3598000
3599000
0.040
0.040
P2RX5;
1.00000
0








P2RX5-










TAX1BP3P2RX5;




1117
chr17
17286000
17287000
0.080
0.000
SMCR9
0.48980
0


1118
chr17
21194000
21195000
0.000
0.040
MAP2K3
1.00000
0


1119
chr17
29646000
29647000
0.000
0.000
EVI2A
1.00000
0


1120
chr17
38020000
38021000
0.000
0.040
IKZF3
1.00000
0


1121
chr17
43662000
43663000
0.040
0.00€
PLEKHM1
1.00000
0


1122
chr17
56408000
56409000
0.120
0.040
BZRAP1
0.60921
0


1123
chr17
56409000
56410000
0.360
0.200
BZRAP1
0.34513
0


1124
chr17
57916000
57917000
0.040
0.080
VMP1
1.00000
1


1125
chr17
57917000
57918000
0.040
0.080
VMP1
1.00000
1


1126
chr17
62007000
62008000
0.040
0.000
CD79B
1.00000
0


1127
chr17
62008000
62009000
0.040
0.000
CD79B
1.00000
0


1128
chr17
63067000
63068000
0.040
0.000
GNA13
1.00000
0


1129
chr17
65676000
65677000
0.040
0.000
PITPNC1
1.00000
0


1130
chr17
69365000
69366000
0.000
0.040
AC007461.1
1.00000
0


1131
chr17
70083000
70084000
0.000
0.000
SOX9
1.00000
0


1132
chr17
74733000
74734000
0.000
0.000
SRSF2
1.00000
0


1133
chr17
75447000
75448000
0.080
0.000
9 Sep. 2019
0.48980
0


1134
chr17
75448000
75449000
0.040
0.000
9 Sep. 2019
1.00000
0


1135
chr17
76775000
76776000
0.000
0.000
CYTH1
1.00000
0


1136
chr17
80928000
80929000
0.000
0.000
B3GNTL1
1.00000
0


1137
chr17
80976000
80977000
0.000
0.040
B3GNTL1
1.00000
0


1138
chr18
2709000
2710000
0.000
0.000
SMCHD1
1.00000
0


1139
chr18
3600000
3601000
0.040
0.000
DLGAP1
1.00000
0


1140
chr18
12062000
12063000
0.000
0.000
ANKRD62
1.00000
0


1141
chr18
27771000
27772000
0.040
0.000
DSC3
1.00000
0


1142
chr18
28066000
28067000
0.000
0.040
DSC3
1.00000
0


1143
chr18
30349000
30350000
0.000
0.000
AC012123.1;
1.00000
0








KLHL14;




1144
chr18
36806000
36807000
0.040
0.000
CELF4
1.00000
0


1145
chr18
37751000
37752000
0.000
0.040
PIK3C3
1.00000
0


1146
chr18
38672000
38673000
0.000
0.040
PIK3C3
1.00000
0


1147
chr18
42168000
42169000
0.000
0.000
SETBP1
1.00000
0


1148
chr18
51952000
51953000
0.040
0.000
C18orf54
1.00000
0


1149
chr18
52447000
52448000
0.000
0.080
RAB27B
0.48980
0


1150
chr18
52988000
52989000
0.040
0.000
TCF4
1.00000
0


1151
chr18
54653000
54654000
0.000
0.000
WDR7
1.00000
0


1152
chr18
60794000
60795000
0.000
0.080
BCL2
0.48980
1


1153
chr18
60805000
60806000
0.000
0.000
BCL2
1.00000
1


1154
chr18
60806000
60807000
0.000
0.120
BCL2
0.23469
1


1155
chr18
60809000
60810000
0.000
0.080
BCL2
0.48980
1


1156
chr18
60821000
60822000
0.000
0.040
BCL2
1.00000
1


1157
chr18
60825000
60826000
0.000
0.080
BCL2
0.48980
1


1158
chr18
60826000
60827000
0.000
0.040
BCL2
1.00000
1


1159
chr18
60828000
60829000
0.000
0.000
BCL2
1.00000
1


1160
chr18
60873000
60874000
0.000
0.040
BCL2
1.00000
1


1161
chr18
60875000
60876000
0.000
0.000
BCL2
1.00000
1


1162
chr18
60876000
60877000
0.000
0.040
BCL2
1.00000
1


1163
chr18
60983000
60984000
0.000
0.040
BCL2
1.00000
1


1164
chr18
60984000
60985000
0.000
0.240
BCL2
0.02229
1


1165
chr18
60985000
60986000
0.040
0.320
BCL2
0.02322
1


1166
chr18
60986000
60987000
0.080
0.320
BCL2
0.07375
1


1167
chr18
60987000
60988000
0.080
0.320
BCL2
0.07375
1


1168
chr18
60988000
60989000
0.080
0.280
BCL2
0.13833
1


1169
chr18
61810000
61811000
0.040
0.000
SERPINB8
1.00000
0


1170
chr18
63080000
63081000
0.000
0.000
CDH7
1.00000
0


1171
chr18
63791000
63792000
0.000
0.000
CDH7
1.00000
0


1172
chr18
63875000
63876000
0.040
0.000
CDH19
1.00000
0


1173
chr18
64643000
64644000
0.000
0.000
CDH19
1.00000
0


1174
chr18
65863000
65864000
0.000
0.000
TMX3
1.00000
0


1175
chr18
66328000
66329000
0.040
0.000
TMX3
1.00000
0


1176
chr18
70462000
70463000
0.000
0.040
NETO1
1.00000
0


1177
chr18
73767000
73768000
0.040
0.000
ZNF516
1.00000
0


1178
chr18
76515000
76516000
0.040
0.000
SALL3
1.00000
0


1179
chr18
76724000
76725000
0.040
0.000
SALL3
1.00000
0


1180
chr18
76725000
76726000
0.040
0.000
SALL3
1.00000
0


1181
chr19
1612000
1613000
0.000
0.040
TCF3
1.00000
0


1182
chr19
2476000
2477000
0.040
0.040
GADD45B
1.00000
1


1183
chr19
10304000
10305000
0.040
0.080
DNMT1
1.00000
0


1184
chr19
10305000
10306000
0.000
0.080
DNMT1
0.48980
0


1185
chr19
10335000
10336000
0.000
0.040
S1PR2
1.00000
1


1186
chr19
10340000
10341000
0.080
0.160
S1PR2
0.66710
1


1187
chr19
10341000
10342000
0.120
0.280
S1PR2
0.28902
1


1188
chr19
16030000
16031000
0.000
0.000
CYP4F11
1.00000
0


1189
chr19
16436000
16437000
0.040
0.000
KLF2
1.00000
1


1190
chr19
20889000
20890000
0.000
0.040
ZNF626
1.00000
0


1191
chr19
21073000
21074000
0.040
0.000
ZNF85
1.00000
0


1192
chr19
21092000
21093000
0.000
0.040
ZNF85
1.00000
0


1193
chr19
23841000
23842000
0.040
0.000
ZNF675
1.00000
0


1194
chr19
29256000
29257000
0.040
0.000
UQCRFS1
1.00000
0


1195
chr19
44183000
44184000
0.040
0.000
PLAUR
1.00000
0


1196
chr19
50399000
50400000
0.040
0.040
IL4I1
1.00000
0


1197
chr19
53419000
53420000
0.000
0.000
ZNF321P;
1.00000
0








ZNF816;










ZNF816-










ZNF321P










ZNF321P










ZNF816-










ZNF321P;




1198
chr20
15470000
15471000
0.000
0.040
MACROD2
1.00000
0


1199
chr20
23359000
23360000
0.000
0.000
NAPB
1.00000
0


1200
chr20
23912000
23913000
0.000
0.000
CST5
1.00000
0


1201
chr20
46131000
46132000
0.040
0.120
NCOA3
0.60921
1


1202
chr20
49127000
49128000
0.000
0.000
PTPN1
1.00000
0


1203
chr20
49648000
49649000
0.040
0.000
KCNG1
1.00000
0


1204
chr20
61607000
61608000
0.000
0.000
SLC17A9
1.00000
0


1205
chr21
21597000
21598000
0.000
0.000
NCAM2
1.00000
0


1206
chr21
23458000
23459000
0.000
0.040
NCAM2
1.00000
0


1207
chr21
24998000
24999000
0.000
0.040
MRPL39
1.00000
0


1208
chr21
26935000
26936000
0.000
0.080
MRPL39
0.48980
0


1209
chr21
35779000
35780000
0.000
0.000
SMIM11
1.00000
0


1210
chr21
38779000
38780000
0.000
0.000
DYRK1A
1.00000
0


1211
chr21
43254000
43255000
0.000
0.040
PRDM15
1.00000
0


1212
chr21
44612000
44613000
0.000
0.000
CRYAA
1.00000
0


1213
chr21
45381000
45382000
0.040
0.000
AGPAT3
1.00000
0


1214
chr21
46058000
46059000
0.000
0.000
KRTAP10-10
1.00000
0


1215
chr22
19050000
19051000
0.000
0.000
DGCR2
1.00000
0


1216
chr22
20212000
20213000
0.040
0.000
RTN4R
1.00000
0


1217
chr22
20708000
20709000
0.040
0.040
FAM230A
1.00000
0


1218
chr22
21994000
21995000
0.000
0.000
SDF2L1
1.00000
0


1219
chr22
22379000
22380000
0.040
0.040
IGLV4-69
1.00000
0


1220
chr22
22380000
22381000
0.040
0.080
IGLV4-69
1.00000
0


1221
chr22
22381000
22382000
0.040
0.040
IGLV4-69
1.00000
0


1222
chr22
22385000
22386000
0.040
0.080
IGLV4-69
1.00000
0


1223
chr22
22452000
22453000
0.000
0.040
IGLV8-61
1.00000
0


1224
chr22
22453000
22454000
0.000
0.040
IGLV8-61
1.00000
0


1225
chr22
22516000
22517000
0.000
0.160
IGLV4-60
0.10986
0


1226
chr22
22517000
22518000
0.000
0.080
IGLV4-60
0.48980
0


1227
chr22
22550000
22551000
0.160
0.000
IGLV6-57
0.10986
0


1228
chr22
22569000
22570000
0.040
0.000
IGLV10-54
1.00000
0


1229
chr22
22676000
22677000
0.040
0.000
IGLV1-51
1.00000
0


1230
chr22
22677000
22678000
0.040
0.000
IGLV1-51
1.00000
0


1231
chr22
22707000
22708000
0.040
0.080
IGLV5-48
1.00000
0


1232
chr22
22712000
22713000
0.160
0.040
IGLV1-47
0.34868
0


1233
chr22
22723000
22724000
0.000
0.000
IGLV7-46
1.00000
0


1234
chr22
22724000
22725000
0.080
0.040
IGLV7-46
1.00000
0


1235
chr22
22730000
22731000
0.040
0.040
IGLV5-45
1.00000
0


1236
chr22
22731000
22732000
0.000
0.000
IGLV5-45
1.00000
0


1237
chr22
22735000
22736000
0.080
0.120
IGLV1-44
1.00000
0


1238
chr22
22749000
22750000
0.120
0.040
IGLV7-43
0.60921
0


1239
chr22
22758000
22759000
0.080
0.040
IGLV1-40
1.00000
0


1240
chr22
22759000
22760000
0.080
0.080
IGLV1-40
1.00000
0


1241
chr22
22764000
22765000
0.120
0.080
IGLV1-40
1.00000
0


1242
chr22
23028000
23029000
0.000
0.040
IGLV3-25
1.00000
0


1243
chr22
23029000
23030000
0.040
0.120
IGLV3-25
0.60921
0


1244
chr22
23035000
23036000
0.000
0.040
IGLV2-23
1.00000
0


1245
chr22
23039000
23040000
0.000
0.000
IGLV2-23
1.00000
0


1246
chr22
23040000
23041000
0.120
0.040
IGLV2-23
0.60921
0


1247
chr22
23041000
23042000
0.040
0.000
IGLV2-23
1.00000
0


1248
chr22
23055000
23056000
0.040
0.000
IGLV3-21
1.00000
0


1249
chr22
23063000
23064000
0.040
0.000
IGLV3-19
1.00000
0


1250
chr22
23090000
23091000
0.120
0.000
IGLV3-16
0.23469
0


1251
chr22
23100000
23101000
0.040
0.000
IGLV2-14
1.00000
0


1252
chr22
23101000
23102000
0.120
0.040
IGLV2-14
0.60921
0


1253
chr22
23114000
23115000
0.000
0.000
IGLV3-12
1.00000
0


1254
chr22
23134000
23135000
0.000
0.000
IGLV2-11
1.00000
0


1255
chr22
23154000
23155000
0.120
0.000
IGLV3-10
0.23469
0


1256
chr22
23161000
23162000
0.000
0.000
IGLV3-9
1.00000
0


1257
chr22
23162000
23163000
0.000
0.000
IGLV3-9
1.00000
0


1258
chr22
23165000
23166000
0.000
0.000
IGLV2-8
1.00000
0


1259
chr22
23192000
23193000
0.080
0.080
IGLV4-3
1.00000
0


1260
chr22
23197000
23198000
0.040
0.000
IGLV4-3
1.00000
0


1261
chr22
23198000
23199000
0.160
0.040
IGLV4-3
0.34868
0


1262
chr22
23199000
23200000
0.200
0.200
IGLV4-3
1.00000
0


1263
chr22
23203000
23204000
0.000
0.000
IGLV4-3
1.00000
0


1264
chr22
23204000
23205000
0.080
0.000
IGLV4-3
0.48980
0


1265
chr22
23205000
23206000
0.000
0.000
IGLV4-3
1.00000
0


1266
chr22
23207000
23208000
0.000
0.040
IGLV4-3
1.00000
0


1267
chr22
23209000
23210000
0.000
0.040
IGLV4-3
1.00000
0


1268
chr22
23213000
23214000
0.120
0.040
IGLV4-3
0.60921
0


1269
chr22
23214000
23215000
0.040
0.040
IGLV4-3
1.00000
0


1270
chr22
23219000
23220000
0.080
0.000
IGLV3-1
0.48980
0


1271
chr22
23220000
23221000
0.080
0.000
IGLV3-1
0.48980
0


1272
chr22
23222000
23223000
0.040
0.120
IGLV3-1
0.60921
0


1273
chr22
23223000
23224000
0.320
0.520
IGLV3-1
0.25159
0


1274
chr22
23224000
23225000
0.080
0.080
IGLV3-1
1.00000
0


1275
chr22
23226000
23227000
0.120
0.000
IGLV3-1
0.23469
0


1276
chr22
23227000
23228000
0.200
0.360
IGLL5
0.34513
0


1277
chr22
23228000
23229000
0.240
0.200
IGLL5
1.00000
0


1278
chr22
23229000
23230000
0.040
0.160
IGLLS
0.34868
0


1279
chr22
23230000
23231000
0.440
0.600
IGLL5
0.39610
0


1280
chr22
23231000
23232000
0.480
0.440
IGLL5
1.00000
0


1281
chr22
23232000
23233000
0.320
0.240
IGLL5
0.75361
0


1282
chr22
23233000
23234000
0.200
0.040
IGLJ1
0.18946
0


1283
chr22
23234000
23235000
0.200
0.080
IGLJ1
0.41743
0


1284
chr22
23235000
23236000
0.320
0.080
IGLJ1; IGLL5;
0.07375
0


1285
chr22
23236000
23237000
0.240
0.200
IGLJ1; IGLL5;
1.00000
0


1286
chr22
23237000
23238000
0.040
0.160
IGLC1; IGLL5;
0.34868
0


1287
chr22
23241000
23242000
0.040
0.040
IGLJ2
1.00000
0


1288
chr22
23242000
23243000
0.120
0.040
IGLC2
0.60921
0


1289
chr22
23243000
23244000
0.080
0.040
IGLC2
1.00000
0


1290
chr22
23244000
23245000
0.000
0.040
IGLC2
1.00000
0


1291
chr22
23247000
23248000
0.280
0.160
IGLJ3
0.49620
0


1292
chr22
23248000
23249000
0.040
0.000
IGLC3
1.00000
0


1293
chr22
23249000
23250000
0.040
0.000
IGLC3
1.00000
0


1294
chr22
23260000
23261000
0.000
0.000
IGLJ6
1.00000
0


1295
chr22
23261000
23262000
0.000
0.000
IGLJ6
1.00000
0


1296
chr22
23263000
23264000
0.000
0.040
IGLJ7
1.00000
0


1297
chr22
23264000
23265000
0.000
0.040
IGLC7
1.00000
0


1298
chr22
23273000
23274000
0.000
0.040
IGLC7
1.00000
0


1299
chr22
23277000
23278000
0.040
0.040
IGLC7
1.00000
0


1300
chr22
23278000
23279000
0.000
0.120
IGLC7
0.23469
0


1301
chr22
23281000
23282000
0.040
0.000
IGLC7
1.00000
0


1302
chr22
23282000
23283000
0.080
0.160
IGLC7
0.66710
0


1303
chr22
23284000
23285000
0.000
0.000
IGLC7
1.00000
0


1304
chr22
23523000
23524000
0.000
0.080
BCR
0.48980
0


1305
chr22
23524000
23525000
0.000
0.000
BCR
1.00000
0


1306
chr22
27236000
27237000
0.000
0.000
CRYBA4
1.00000
0


1307
chr22
29195000
29196000
0.040
0.040
XBP1
1.00000
0


1308
chr22
29196000
29197000
0.040
0.040
XBP1
1.00000
0


1309
chr22
31826000
31827000
0.040
0.000
DRG1
1.00000
0


1310
chr22
32982000
32983000
0.000
0.040
SYN3
1.00000
0


1311
chr22
39852000
39853000
0.040
0.000
TAB1
1.00000
0


1312
chr22
39854000
39855000
0.000
0.000
TAB1
1.00000
0


1313
chr22
43360000
43361000
0.000
0.000
PACSIN2
1.00000
0


1314
chr22
47186000
47187000
0.000
0.000
TBC1D22A
1.00000
0


1315
chr22
47738000
47739000
0.000
0.000
LL22NC03-
1.00000
0








75H12.2




1316
chr22
50336000
50337000
0.000
0.000
CRELD2
1.00000
0


1317
chrX
228000
229000
0.000
0.000
GTPBP6
1.00000
0


1318
chrX
1514000
1515000
0.000
0.040
SLC25A6
1.00000
0


1319
chrX
1611000
1612000
0.040
0.040
P2RY8
1.00000
1


1320
chrX
12993000
12994000
0.320
0.280
TMSB4X
1.00000
1


1321
chrX
12994000
12995000
0.200
0.160
TMSB4X
1.00000
1


1322
chrX
13419000
13420000
0.000
0.040
ATXN3L
1.00000
0


1323
chrX
27031000
27032000
0.080
0.040
DCAF8L2
1.00000
0


1324
chrX
32315000
32316000
0.000
0.000
DMD
1.00000
1


1325
chrX
32317000
32318000
0.000
0.000
DMD
1.00000
1


1326
chrX
33144000
33145000
0.000
0.000
DMD
1.00000
1


1327
chrX
33145000
33146000
0.000
0.040
DMD
1.00000
1


1328
chrX
33146000
33147000
0.080
0.120
DMD
1.00000
1


1329
chrX
41366000
41367000
0.040
0.000
CASK
1.00000
0


1330
chrX
42802000
42803000
0.080
0.120
MAOA
1.00000
0


1331
chrX
48775000
48776000
0.120
0.040
PIM2
0.60921
1


1332
chrX
48776000
48777000
0.080
0.000
PIM2
0.48980
1


1333
chrX
64071000
64072000
0.120
0.080
ZC4H2
1.00000
0


1334
chrX
67030000
67031000
0.000
0.000
AR
1.00000
0


1335
chrX
80258000
80259000
0.000
0.000
HMGN5
1.00000
0


1336
chrX
81172000
81173000
0.040
0.000
SH3BGRL
1.00000
0


1337
chrX
87742000
87743000
0.040
0.000
CPXCR1
1.00000
0


1338
chrX
87831000
87832000
0.000
0.000
CPXCR1
1.00000
0


1339
chrX
88263000
88264000
0.000
0.000
CPXCR1
1.00000
0


1340
chrX
88458000
88459000
0.040
0.000
CPXCR1
1.00000
0


1341
chrX
92647000
92648000
0.000
0.000
NAPIL3
1.00000
0


1342
chrX
93279000
93280000
0.040
0.000
FAM133A
1.00000
0


1343
chrX
94079000
94080000
0.040
0.000
FAM133A
1.00000
0


1344
chrX
104006000
104007000
0.040
0.000
IL1RAPL2
1.00000
0


1345
chrX
104269000
104270000
0.040
0.000
IL1RAPL2
1.00000
0


1346
chrX
106132000
106133000
0.000
0.000
RIPPLY1
1.00000
0


1347
chrX
113095000
113096000
0.000
0.040
HTR2C
1.00000
0


1348
chrX
115676000
115677000
0.040
0.000
CXorf61
1.00000
0


1349
chrX
124996000
124997000
0.000
0.000
DCAF12L2
1.00000
0


1350
chrX
125708000
125709000
0.000
0.000
DCAF12L1
1.00000
0


1351
chrX
128565000
128566000
0.040
0.040
SMARCA1
1.00000
0


1352
chrX
129643000
129644000
0.000
0.040
RBMX2
1.00000
0


1353
chrX
134903000
134904000
0.000
0.000
CT45A3;
1.00000
0








CT45A4;




1354
chrX
140846000
140847000
0.040
0.000
SPANXD;
1.00000
0








SPANXE;




1355
chrX
143750000
143751000
0.000
0.000
SPANXN1
1.00000
0


1356
chrX
145016000
145017000
0.040
0.000
TMEM257
1.00000
0





















TABLE 3





#
Chromosome
Region Start
Region End
Closest Gene
Reason for Inclusion




















1
chr1
2306311
2306832
MORN1
Genotyping


2
chr1
2334441
2334664
RER1
Genotyping


3
chr1
2334671
2335161
RER1
Genotyping


4
chr1
2488006
2488247
TNFRSF14
Phased Variants


5
chr1
2489111
2489330
TNFRSF14
Genotyping


6
chr1
2489726
2489973
TNFRSF14
Genotyping


7
chr1
2491206
2491455
TNFRSF14
Genotyping


8
chr1
2492036
2492175
TNFRSF14
Genotyping


9
chr1
2493051
2493333
TNFRSF14
Genotyping


10
chr1
2494241
2494376
TNFRSF14
Genotyping


11
chr1
2494556
2494745
TNFRSF14
Genotyping


12
chr1
3547350
3547715
WRAP73
Genotyping


13
chr1
3747620
3747798
CEP104
Genotyping


14
chr1
3800045
3800148
DFFB
Genotyping


15
chr1
3800155
3800363
DFFB
Genotyping


16
chr1
4472438
4472621
AJAP1
Genotyping


17
chr1
4476348
4476627
AJAP1
Genotyping


18
chr1
9784432
9784540
PIK3CD
Genotyping


19
chr1
23885407
23885541
ID3
Genotyping


20
chr1
23885582
23885938
ID3
Genotyping


21
chr1
27059146
27059321
ARID1A
Genotyping


22
chr1
27101071
27101294
ARID1A
Genotyping


23
chr1
27101401
27101613
ARID1A
Genotyping


24
chr1
27105466
27105671
ARID1A
Genotyping


25
chr1
27106311
27106523
ARID1A
Genotyping


26
chr1
27106711
27106920
ARID1A
Genotyping


27
chr1
29069531
29070185
YTHDF2
Genotyping


28
chr1
34404022
34404171
CSMD2
Phased Variants


29
chr1
35472492
35472739
ZMYM6
Genotyping


30
chr1
61553802
61554330
NFIA
Genotyping


31
chr1
72334891
72335045
NEGR1
Phased Variants


32
chr1
72335051
72335120
NEGR1
Phased Variants


33
chr1
85733207
85733640
BCL10
Phased Variants


34
chr1
85736272
85736619
BCL10
Genotyping


35
chr1
85741932
85742068
BCL10
Genotyping


36
chr1
86591437
86591909
COL24A1
Genotyping


37
chr1
107866871
107867579
NTNG1
Genotyping


38
chr1
109649126
109649304
C1orf194
Genotyping


39
chr1
109822181
109822805
PSRC1
Genotyping


40
chr1
110561141
110561757
AHCYL1
Genotyping


41
chr1
111441722
111442219
CD53
Genotyping


42
chr1
111715727
111715908
CEPT1
Genotyping


43
chr1
117078642
117078856
CD58
Genotyping


44
chr1
117086927
117087172
CD58
Genotyping


45
chr1
120457960
120459297
NOTCH2
Genotyping


46
chr1
160319283
160319532
NCSTN
Genotyping


47
chr1
181452914
181453131
CACNA1E
Genotyping


48
chr1
185833555
185833832
HMCN1
Genotyping


49
chr1
185972790
185973006
HMCN1
Genotyping


50
chr1
186062580
186062797
HMCN1
Genotyping


51
chr1
186083050
186083301
HMCN1
Genotyping


52
chr1
186143590
186143828
HMCN1
Genotyping


53
chr1
186158895
186159102
HMCN1
Genotyping


54
chr1
190067139
190068194
FAMSC
Genotyping


55
chr1
201038552
201038756
CACNA1S
Genotyping


56
chr1
203274697
203275926
BTG2
Phased Variants


57
chr1
203276207
203276586
BTG2
Genotyping


58
chr1
226923691
226925200
ITPKB
Phased Variants


59
chr1
227842646
227842718
ZNF678
Genotyping


60
chr2
1652010
1652858
PXDN
Genotyping


61
chr2
48027958
48028159
MSH6
Genotyping


62
chr2
48059883
48060051
FBXO11
Genotyping


63
chr2
48065973
48066184
FBXO11
Genotyping


64
chr2
55237198
55237610
RTN4
Genotyping


65
chr2
56149510
56150116
EFEMP1
Genotyping


66
chr2
58520800
58521222
FANCL
Genotyping


67
chr2
59821914
59822083
BCL11A
Genotyping


68
chr2
60773084
60773479
BCL11A
Genotyping


69
chr2
61118794
61118998
REL
Genotyping


70
chr2
61145504
61145785
REL
Genotyping


71
chr2
61148869
61149644
REL
Genotyping


72
chr2
61441169
61441870
USP34
Genotyping


73
chr2
61719434
61719642
XPO1
Genotyping


74
chr2
62934009
62934460
EHBP1
Genotyping


75
chr2
63217829
63218002
EHBP1
Genotyping


76
chr2
63335242
63335600
WDPCP
Genotyping


77
chr2
63631157
63631817
WDPCP
Genotyping


78
chr2
63826277
63826429
MDH1
Genotyping


79
chr2
65258145
65258367
SLC1A4
Phased Variants


80
chr2
65593035
65593153
SPRED2
Phased Variants


81
chr2
65593180
65593250
SPRED2
Phased Variants


82
chr2
77746602
77746988
LRRTM4
Genotyping


83
chr2
80801235
80801513
CTNNA2
Genotyping


84
chr2
88906681
88906861
EIF2AK3
Phased Variants


85
chr2
89127261
89127335
IGKC
Phased Variants


86
chr2
89127461
89127946
IGKC
Phased Variants


87
chr2
89128431
89128574
IGKC
Phased Variants


88
chr2
89131726
89132295
IGKC
Phased Variants


89
chr2
89140556
89140755
IGKC
Phased Variants


90
chr2
89140886
89141350
IGKC
Phased Variants


91
chr2
89157326
89157609
IGKC
Phased Variants


92
chr2
89157626
89158011
IGKC
Phased Variants


93
chr2
89158036
89158938
IGKC
Phased Variants


94
chr2
89158941
89159493
IGKJ5
Phased Variants


95
chr2
89159511
89161445
IGKJ1
Phased Variants


96
chr2
89161926
89162149
IGKJ1
Phased Variants


97
chr2
89162776
89163285
IGKJ1
Phased Variants


98
chr2
89163306
89163837
IGKJ1
Phased Variants


99
chr2
89163861
89164838
IGKJ1
Phased Variants


100
chr2
89164866
89165181
IGKJ1
Phased Variants


101
chr2
89165191
89165644
IGKJ1
Phased Variants


102
chr2
89184966
89185186
IGKV4-1
Phased Variants


103
chr2
89185196
89185704
IGKV4-1
Phased Variants


104
chr2
89196226
89196411
IGKV5-2
Phased Variants


105
chr2
89196851
89197324
IGKV5-2
Phased Variants


106
chr2
89214836
89215040
IGKV5-2
Phased Variants


107
chr2
89246681
89246772
IGKV1-5
Phased Variants


108
chr2
89246786
89246857
IGKV1-5
Phased Variants


109
chr2
89246911
89247053
IGKV1-5
Phased Variants


110
chr2
89247096
89247215
IGKV1-5
Phased Variants


111
chr2
89247526
89247628
IGKV1-5
Phased Variants


112
chr2
89247641
89247735
IGKV1-5
Phased Variants


113
chr2
89247831
89248010
IGKV1-5
Phased Variants


114
chr2
89265756
89265829
IGKV1-6
Genotyping


115
chr2
89265936
89266013
IGKV1-6
Genotyping


116
chr2
89291906
89291981
IGKV1-8
Phased Variants


117
chr2
89292131
89292217
IGKV1-8
Phased Variants


118
chr2
89442291
89442561
IGKV3-20
Phased Variants


119
chr2
89442616
89443259
IGKV3-20
Phased Variants


120
chr2
89475781
89476009
IGKV2-24
Genotyping


121
chr2
89476041
89476122
IGKV2-24
Genotyping


122
chr2
89544331
89544608
IGKV2-30
Genotyping


123
chr2
89544656
89544899
IGKV2-30
Phased Variants


124
chr2
89976276
89976426
IGKV2D-30
Genotyping


125
chr2
89986776
89987023
IGKV2D-29
Genotyping


126
chr2
89987031
89987108
IGKV2D-29
Genotyping


127
chr2
90025206
90025289
IGKV2D-26
Genotyping


128
chr2
90025296
90025378
IGKV2D-26
Genotyping


129
chr2
90025471
90025554
IGKV2D-26
Genotyping


130
chr2
90077981
90078054
IGKV3D-20
Genotyping


131
chr2
90078136
90078222
IGKV3D-20
Genotyping


132
chr2
90078251
90078335
IGKV3D-20
Genotyping


133
chr2
90121891
90122008
IGKV1D-17
Genotyping


134
chr2
90122021
90122157
IGKV1D-17
Genotyping


135
chr2
90212016
90212093
IGKV3D-11
Genotyping


136
chr2
90212196
90212278
IGKV3D-11
Genotyping


137
chr2
90249151
90249275
IGKV1D-43
Genotyping


138
chr2
90249346
90249419
IGKV1D-43
Genotyping


139
chr2
90259931
90260059
IGKV1D-8
Genotyping


140
chr2
90260181
90260258
IGKV1D-8
Genotyping


141
chr2
96809889
96810144
DUSP2
Genotyping


142
chr2
96810164
96810374
DUSP2
Phased Variants


143
chr2
100758483
100758660
AFF3
Phased Variants


144
chr2
103148733
103148948
SLC9A4
Genotyping


145
chr2
117951919
117952057
DDX18
Phased Variants


146
chr2
136872525
136872740
CXCR4
Genotyping


147
chr2
136874415
136874797
CXCR4
Phased Variants


148
chr2
136874920
136875662
CXCR4
Phased Variants


149
chr2
141245127
141245373
LRP1B
Genotyping


150
chr2
145162401
145162624
ZEB2
Genotyping


151
chr2
145187091
145187638
ZEB2
Genotyping


152
chr2
145270956
145271394
ZEB2
Genotyping


153
chr2
145275631
145275744
ZEB2
Genotyping


154
chr2
145275756
145276174
ZEB2
Genotyping


155
chr2
145278026
145278305
ZEB2
Genotyping


156
chr2
145278311
145278659
ZEB2
Genotyping


157
chr2
145692901
145693081
ZEB2
Genotyping


158
chr2
148680516
148680692
ACVR2A
Genotyping


159
chr2
169781120
169781352
ABCB11
Genotyping


160
chr2
170101185
170101401
LRP2
Genotyping


161
chr2
198950434
198951003
PLCL1
Genotyping


162
chr2
242793232
242793447
PDCD1
Genotyping


163
chr2
242794037
242794192
PDCD1
Genotyping


164
chr2
242794317
242794537
PDCD1
Genotyping


165
chr2
242794822
242795040
PDCD1
Genotyping


166
chr2
242800887
242801093
PDCD1
Genotyping


167
chr3
7620223
7620990
GRM7
Genotyping


168
chr3
16419204
16419479
RFTN1
Phased Variants


169
chr3
38180129
38180549
MYD88
Genotyping


170
chr3
38181334
38181509
MYD88
Genotyping


171
chr3
38181854
38182099
MYD88
Genotyping


172
chr3
38182194
38182407
MYD88
Genotyping


173
chr3
38182554
38182844
MYD88
Genotyping


174
chr3
49397608
49397717
RHOA
Genotyping


175
chr3
49397718
49397827
RHOA
Genotyping


176
chr3
49399903
49400084
RHOA
Genotyping


177
chr3
49405833
49406013
RHOA
Genotyping


178
chr3
49412838
49413046
RHOA
Genotyping


179
chr3
64547204
64547477
ADAMTS9
Genotyping


180
chr3
64579889
64580094
ADAMTS9
Genotyping


181
chr3
71551101
71551497
EIF4E3
Phased Variants


182
chr3
140281598
140281875
CLSTN2
Genotyping


183
chr3
164730700
164730888
SI
Genotyping


184
chr3
165548198
165548680
BCHE
Genotyping


185
chr3
176750699
176750928
TBL1XR1
Genotyping


186
chr3
176767759
176767977
TBL1XR1
Genotyping


187
chr3
176769304
176769543
TBL1XR1
Genotyping


188
chr3
176771659
176771732
TBL1XR1
Genotyping


189
chr3
183209758
183209937
KLHL6
Genotyping


190
chr3
183210258
183210544
KLHL6
Genotyping


191
chr3
183272308
183272521
KLHL6
Phased Variants


192
chr3
183273063
183273456
KLHL6
Phased Variants


193
chr3
184580663
184580872
VPS8
Genotyping


194
chr3
185146278
185146873
MAP3K13
Genotyping


195
chr3
185197923
185198317
MAP3K13
Genotyping


196
chr3
185236908
185237109
LIPH
Genotyping


197
chr3
185446223
185446389
C3orf65
Genotyping


198
chr3
185538773
185538951
IGF2BP2
Genotyping


199
chr3
185697423
185697669
TRA2B
Genotyping


200
chr3
186714604
186715001
ST6GAL1
Phased Variants


201
chr3
186782529
186782790
ST6GAL1
Phased Variants


202
chr3
186783389
186784291
ST6GAL1
Phased Variants


203
chr3
187440189
187440445
BCL6
Genotyping


204
chr3
187442669
187442920
BCL6
Genotyping


205
chr3
187443239
187443438
BCL6
Genotyping


206
chr3
187446814
187447831
BCL6
Genotyping


207
chr3
187449434
187449655
BCL6
Genotyping


208
chr3
187451284
187451667
BCL6
Genotyping


209
chr3
187460134
187460530
BCL6
Phased Variants


210
chr3
187460824
187461302
BCL6
Phased Variants


211
chr3
187461319
187461381
BCL6
Phased Variants


212
chr3
187461454
187461918
BCL6
Phased Variants


213
chr3
187461924
187462343
BCL6
Phased Variants


214
chr3
187462374
187462887
BCL6
Phased Variants


215
chr3
187462924
187462999
BCL6
Phased Variants


216
chr3
187463004
187463525
BCL6
Phased Variants


217
chr3
187463709
187463781
BCL6
Phased Variants


218
chr3
187463794
187464109
BCL6
Phased Variants


219
chr3
187619334
187619708
BCL6
Phased Variants


220
chr3
187660817
187661390
BCL6
Phased Variants


221
chr3
187957432
187957507
AC022498.1
Phased Variants


222
chr3
187957512
187957754
AC022498.1
Phased Variants


223
chr3
187957767
187958110
AC022498.1
Phased Variants


224
chr3
187958282
187958675
AC022498.1
Phased Variants


225
chr3
187958787
187959184
AC022498.1
Phased Variants


226
chr3
187959462
187959686
AC022498.1
Phased Variants


227
chr3
188299217
188299605
LPP
Phased Variants


228
chr3
188471412
188471549
LPP
Phased Variants


229
chr3
188471567
188471937
LPP
Phased Variants


230
chr4
7728456
7728661
SORCS2
Genotyping


231
chr4
40198810
40199653
N4BP2
Phased Variants


232
chr4
40199660
40199873
N4BP2
Phased Variants


233
chr4
40199990
40200211
N4BP2
Phased Variants


234
chr4
40200505
40200727
RHOH
Phased Variants


235
chr4
40200730
40201571
RHOH
Phased Variants


236
chr4
80327792
80328151
GK2
Genotyping


237
chr4
88011077
88011285
AFF1
Genotyping


238
chr4
106157604
106157813
TET2
Genotyping


239
chr4
134727698
134727916
PABPC4L
Phased Variants


240
chr4
153249285
153249507
FBXW7
Genotyping


241
chr4
154624670
154625050
TLR2
Genotyping


242
chr4
187509884
187510410
FAT1
Genotyping


243
chr4
187557779
187557985
FAT1
Genotyping


244
chr4
188924114
188924897
ZFP42
Genotyping


245
chr5
5182145
5182494
ADAMTS16
Genotyping


246
chr5
11110990
11111137
CTNND2
Genotyping


247
chr5
11236740
11236956
CTNND2
Genotyping


248
chr5
11364700
11364923
CTNND2
Genotyping


249
chr5
11397080
11397377
CTNND2
Genotyping


250
chr5
11411600
11411807
CTNND2
Genotyping


251
chr5
13864465
13864696
DNAH5
Genotyping


252
chr5
21783415
21783668
CDH12
Genotyping


253
chr5
54964698
54964921
SLC38A9
Phased Variants


254
chr5
67590966
67591183
PIK3R1
Genotyping


255
chr5
75913716
75914448
F2RL2
Genotyping


256
chr5
83258967
83259183
EDIL3
Genotyping


257
chr5
112176756
112176958
APC
Genotyping


258
chr5
124079827
124080721
ZNF608
Phased Variants


259
chr5
131825017
131825239
IRF1
Genotyping


260
chr5
135381969
135382218
TGFBI
Genotyping


261
chr5
137801487
137801637
EGR1
Genotyping


262
chr5
137801697
137801804
EGR1
Genotyping


263
chr5
140208033
140208874
PCDHA6
Genotyping


264
chr5
158527642
158528019
EBF1
Phased Variants


265
chr5
176522449
176522613
FGFR4
Genotyping


266
chr6
392760
392967
IRF4
Phased Variants


267
chr6
393090
393309
IRF4
Phased Variants


268
chr6
394815
395025
IRF4
Genotyping


269
chr6
14117992
14118654
CD83
Phased Variants


270
chr6
14131732
14132021
CD83
Genotyping


271
chr6
14133857
14133996
CD83
Genotyping


272
chr6
14135317
14135496
CD83
Genotyping


273
chr6
26020709
26020958
HIST1H3A
Genotyping


274
chr6
26032014
26032217
HIST1H3B
Genotyping


275
chr6
26045744
26046077
HIST1H3C
Genotyping


276
chr6
26056034
26056315
HIST1H1C
Genotyping


277
chr6
26056319
26056558
HIST1H1C
Genotyping


278
chr6
26123614
26123778
HIST1H2BC
Phased Variants


279
chr6
26123879
26124098
HIST1H2BC
Genotyping


280
chr6
26124544
26124640
HIST1H2AC
Genotyping


281
chr6
26124714
26124889
HIST1H2AC
Genotyping


282
chr6
26156649
26157377
HIST1H1E
Phased Variants


283
chr6
26158529
26158608
HIST1H2BD
Genotyping


284
chr6
26158739
26158835
HIST1H2BD
Genotyping


285
chr6
26197104
26197182
HIST1H3D
Genotyping


286
chr6
26197189
26197465
HIST1H3D
Genotyping


287
chr6
26216779
26216920
HIST1H2BG
Genotyping


288
chr6
26217214
26217431
HIST1H2AE
Genotyping


289
chr6
26234654
26234976
HIST1H1D
Genotyping


290
chr6
26250459
26250537
HIST1H3F
Genotyping


291
chr6
26250594
26250703
HIST1H3F
Genotyping


292
chr6
26252154
26252232
HIST1H2BH
Genotyping


293
chr6
27100079
27100185
HIST1H2BJ
Genotyping


294
chr6
27100939
27101039
HIST1H2AG
Genotyping


295
chr6
27101159
27101300
HIST1H2AG
Genotyping


296
chr6
27114004
27114216
HIST1H2BK
Phased Variants


297
chr6
27114319
27114396
HIST1H2BK
Genotyping


298
chr6
27114494
27114592
HIST1H2BK
Genotyping


299
chr6
27277284
27277495
POM121L2
Genotyping


300
chr6
27777783
27777900
HIST1H3H
Genotyping


301
chr6
27777928
27778106
HIST1H3H
Genotyping


302
chr6
27782718
27782926
HIST1H2BM
Genotyping


303
chr6
27799168
27799381
HIST1H4K
Genotyping


304
chr6
27833408
27833516
HIST1H2AL
Genotyping


305
chr6
27834968
27835075
HIST1H1B
Genotyping


306
chr6
27839658
27839805
HIST1H3I
Genotyping


307
chr6
27860479
27860659
HIST1H2AM
Genotyping


308
chr6
27860794
27860938
HIST1H2AM
Genotyping


309
chr6
27861244
27861344
HIST1H2BO
Genotyping


310
chr6
27861399
27861485
HIST1H2BO
Genotyping


311
chr6
37138284
37139559
PIM1
Phased Variants


312
chr6
37140749
37140956
PIM1
Genotyping


313
chr6
37141679
37141903
PIMI
Genotyping


314
chr6
41903611
41903834
CCND3
Genotyping


315
chr6
41904271
41904477
CCND3
Genotyping


316
chr6
41904941
41905155
CCND3
Genotyping


317
chr6
41908071
41908365
CCND3
Genotyping


318
chr6
41909196
41909441
CCND3
Genotyping


319
chr6
75965846
75966046
TMEM30A
Genotyping


320
chr6
75969006
75969288
TMEM30A
Genotyping


321
chr6
91004618
91004828
MAP3K7
Phased Variants


322
chr6
91005793
91005998
MAP3K7
Phased Variants


323
chr6
94120219
94120743
EPHA7
Genotyping


324
chr6
106534266
106534477
PRDM1
Genotyping


325
chr6
106536046
106536340
PRDM1
Genotyping


326
chr6
106543466
106543637
PRDM1
Genotyping


327
chr6
106547146
106547437
PRDM1
Genotyping


328
chr6
106552761
106552932
PRDM1
Genotyping


329
chr6
106552961
106553841
PRDM1
Genotyping


330
chr6
106554221
106554400
PRDM1
Genotyping


331
chr6
106554766
106555383
PRDM1
Genotyping


332
chr6
108040228
108040856
SCML4
Genotyping


333
chr6
108041553
108042219
SCML4
Genotyping


334
chr6
110777718
110778244
SLC22A16
Genotyping


335
chr6
134491382
134491589
SGK1
Genotyping


336
chr6
134491892
134492111
SGK1
Genotyping


337
chr6
134492132
134492333
SGK1
Genotyping


338
chr6
134492717
134492923
SGK1
Genotyping


339
chr6
134493307
134493474
SGK1
Genotyping


340
chr6
134493732
134494308
SGK1
Phased Variants


341
chr6
134494342
134494514
SGK1
Genotyping


342
chr6
134494552
134494718
SGK1
Phased Variants


343
chr6
134494722
134494795
SGK1
Phased Variants


344
chr6
134494967
134495974
SGK1
Phased Variants


345
chr6
138188483
138188650
TNFAIP3
Genotyping


346
chr6
138192338
138192683
TNFAIP3
Genotyping


347
chr6
138195963
138196172
TNFAIP3
Genotyping


348
chr6
138196803
138197021
TNFAIP3
Genotyping


349
chr6
138197108
138197313
TNFAIP3
Genotyping


350
chr6
138198193
138198407
TNFAIP3
Genotyping


351
chr6
138199548
138200525
TNFAIP3
Genotyping


352
chr6
138201178
138201404
TNFAIP3
Genotyping


353
chr6
138202138
138202494
TNFAIP3
Genotyping


354
chr6
150954420
150954823
PLEKHG1
Phased Variants


355
chr6
59238415
159238794
EZR
Phased Variants


356
chr7
2963818
2963952
CARD11
Genotyping


357
chr7
2963953
2964056
CARD11
Genotyping


358
chr7
2969593
2969738
CARD11
Genotyping


359
chr7
2976668
2976876
CARD11
Genotyping


360
chr7
2977493
2977712
CARD11
Genotyping


361
chr7
2978258
2978502
CARD11
Genotyping


362
chr7
2979398
2979601
CARD11
Genotyping


363
chr7
2983918
2984199
CARD11
Genotyping


364
chr7
2985403
2985610
CARD11
Genotyping


365
chr7
2987163
2987382
CARD11
Genotyping


366
chr7
5569095
5569200
ACTB
Genotyping


367
chr7
5569210
5569359
ACTB
Genotyping


368
chr7
80285799
80286074
CD36
Genotyping


369
chr7
82387830
82388061
PCLO
Genotyping


370
chr7
82453520
82453733
PCLO
Genotyping


371
chr7
82763800
82764050
PCLO
Genotyping


372
chr7
82784490
82784643
PCLO
Genotyping


373
chr7
106508490
106509161
PIK3CG
Genotyping


374
chr7
110545276
110545445
IMMP2L
Phased Variants


375
chr7
110697971
110698144
LRRN3
Phased Variants


376
chr7
110737411
110737634
LRRN3
Phased Variants


377
chr7
110746681
110746893
LRRN3
Phased Variants


378
chr7
110762936
110764629
LRRN3
Genotyping


379
chr7
110764636
110764981
LRRN3
Genotyping


380
chr7
119915406
119915800
KCND2
Genotyping


381
chr7
122634905
122635140
TAS2R16
Genotyping


382
chr7
140453012
140453121
BRAF
Genotyping


383
chr7
140453162
140453268
BRAF
Genotyping


384
chr7
146997183
146997422
CNTNAP2
Genotyping


385
chr7
148506318
148506416
EZH2
Genotyping


386
chr7
148506448
148506551
EZH2
Genotyping


387
chr7
148508658
148508867
EZH2
Genotyping


388
chr7
148513738
148513900
EZH2
Genotyping


389
chr7
148523533
148523743
EZH2
Genotyping


390
chr7
151943421
151943500
KMT2C
Phased Variants


391
chr8
623880
624090
ERICH1
Genotyping


392
chr8
3141724
3141942
CSMD1
Genotyping


393
chr8
4494931
4495105
CSMD1
Genotyping


394
chr8
8748687
8749284
MFHAS1
Genotyping


395
chr8
8750067
8750281
MFHAS1
Genotyping


396
chr8
18729445
18729937
PSD3
Genotyping


397
chr8
75898190
75898400
CRISPLD1
Genotyping


398
chr8
101730376
101730457
PABPC1
Genotyping


399
chr8
103663491
103664160
KLF10
Genotyping


400
chr8
104897561
104898479
RIMS2
Genotyping


401
chr8
113308014
113308283
CSMD3
Genotyping


402
chr8
113364624
113364791
CSMD3
Genotyping


403
chr8
113568994
113569205
CSMD3
Genotyping


404
chr8
116616145
116616886
TRPS1
Genotyping


405
chr8
122626847
122627163
HAS2
Genotyping


406
chr8
128492947
128493338
POU5F1B
Genotyping


407
chr8
128746807
128748893
MYC
Genotyping


408
chr8
128748902
128749969
MYC
Genotyping


409
chr8
128750367
128751183
MYC
Phased Variants


410
chr8
128752612
128753235
MYC
Genotyping


411
chr8
128754007
128754731
MYC
Genotyping


412
chr8
128754752
128756424
MYC
Genotyping


413
chr8
128756707
128756931
MYC
Genotyping


414
chr8
128756947
128757361
MYC
Genotyping


415
chr8
128757737
128757921
MYC
Genotyping


416
chr8
128764072
128764292
MYC
Genotyping


417
chr8
128951724
128951896
TMEM75
Genotyping


418
chr8
130692149
130692503
GSDMC
Genotyping


419
chr8
130760594
130761023
GSDMC
Genotyping


420
chr8
131373024
131373443
ASAP1
Genotyping


421
chr&
136569669
136569842
KHDRBS3
Genotyping


422
chr8
136659204
136659414
KHDRBS3
Genotyping


423
chr8
137101252
137101464
KHDRBS3
Genotyping


424
chr8
137528187
137528570
KHDRBS3
Genotyping


425
chr8
138849937
138850149
FAM135B
Genotyping


426
chr8
139600457
139601255
COL22A1
Genotyping


427
chr8
139601392
139601569
COL22A1
Genotyping


428
chr9
5450474
5450616
CD274
Genotyping


429
chr9
5456059
5456200
CD274
Genotyping


430
chr9
5457054
5457446
CD274
Genotyping


431
chr9
5462809
5463160
CD274
Genotyping


432
chr9
5465489
5465622
CD274
Genotyping


433
chr9
5466724
5466867
CD274
Genotyping


434
chr9
5467814
5468022
CD274
Genotyping


435
chr9
5510589
5510804
PDCD1LG2
Genotyping


436
chr9
5522484
5522636
PDCD1LG2
Genotyping


437
chr9
5534764
5535047
PDCD1LG2
Genotyping


438
chr9
5549309
5549627
PDCD1LG2
Genotyping


439
chr9
5557589
5557762
PDCD1LG2
Genotyping


440
chr9
5563119
5563251
PDCD1LG2
Genotyping


441
chr9
$569929
5570140
PDCD1LG2
Genotyping


442
chr9
13222185
13222409
MPDZ
Genotyping


443
chr9
16435498
16436307
BNC2
Genotyping


444
chr9
19957356
19958178
SLC24A2
Genotyping


445
chr9
20820916
20821095
FOCAD
Genotyping


446
chr9
20946676
20946849
FOCAD
Genotyping


447
chr9
21808814
21808891
MTAP
Genotyping


448
chr9
21808894
21808973
MTAP
Genotyping


449
chr9
21859249
21859469
MTAP
Genotyping


450
chr9
21970834
21971023
CDKN2A
Genotyping


451
chr9
21971069
21971170
CDKN2A
Genotyping


452
chr9
21974409
21974881
CDKN2A
Genotyping


453
chr9
21989304
21989976
CDKN2A
Genotyping


454
chr9
21994084
21994405
CDKN2A
Genotyping


455
chr9
22005929
22006067
CDKN2B
Genotyping


456
chr9
22006109
22006187
CDKN2B
Genotyping


457
chr9
22008649
22009012
CDKN2B
Genotyping


458
chr9
24545399
24545922
IZUMO3
Genotyping


459
chr9
24905444
24905729
IZUMO3
Genotyping


460
chr9
27950144
27950532
LINGO2
Genotyping


461
chr9
37024919
37025642
PAX5
Phased Variants


462
chr9
37025829
37025996
PAX5
Phased Variants


463
chr9
37026269
37027015
PAX5
Phased Variants


464
chr9
37033619
37033797
PAX5
Phased Variants


465
chr9
37293169
37293378
ZCCHC7
Phased Variants


466
chr9
37371494
37371879
ZCCHC7
Phased Variants


467
chr9
37384684
37384911
ZCCHC7
Phased Variants


468
chr9
37407369
37407588
GRHPR
Phased Variants


469
chr9
78686579
78686854
PCSK5
Genotyping


470
chr9
139390582
139390950
NOTCH1
Genotyping


471
chr9
139390952
139391172
NOTCH1
Genotyping


472
chr9
139402662
139402868
NOTCH1
Genotyping


473
chr10
5755066
5755273
FAM208B
Phased Variants


474
chr10
89500957
89501139
PAPSS2
Genotyping


475
chr10
89603602
89604077
KLLN
Genotyping


476
chr10
89624272
89624350
PTEN
Genotyping


477
chr10
89653752
89653825
PTEN
Genotyping


478
chr10
89653832
89653909
PTEN
Genotyping


479
chr10
89685272
89685379
PTEN
Genotyping


480
chr10
89690752
89690894
PTEN
Genotyping


481
chr10
89692737
89692810
PTEN
Genotyping


482
chr10
89692877
89692951
PTEN
Genotyping


483
chr10
89692972
89693037
PTEN
Genotyping


484
chr10
89711837
89711966
PTEN
Genotyping


485
chr10
89711982
89712058
PTEN
Genotyping


486
chr10
89717577
89717714
PTEN
Genotyping


487
chr10
89717742
89717811
PTEN
Genotyping


488
chr10
89720637
89720904
PTEN
Genotyping


489
chr10
90074239
90074419
RNLS
Genotyping


490
chr10
90537736
90538027
LIPN
Genotyping


491
chr10
90579966
90580319
LIPM
Genotyping


492
chr10
90699126
90699647
ACTA2
Genotyping


493
chr10
90773866
90774076
FAS
Genotyping


494
chr10
91092211
91092423
IFIT3
Genotyping


495
chr10
91358986
91359298
PANK1
Genotyping


496
chr10
131640289
131640505
EBF3
Genotyping


497
chr11
58978692
58978791
MPEG1
Genotyping


498
chr11
58978927
58979095
MPEG1
Genotyping


499
chr11
58979112
58979365
MPEG1
Genotyping


500
chr11
65190342
65190557
FRMD8
Phased Variants


501
chr11
65266552
65266924
SCYL1
Phased Variants


502
chr11
65267397
65267603
SCYL1
Phased Variants


503
chr11
65623422
65623506
CFL1
Genotyping


504
chr11
69346691
69346940
CCND1
Genotyping


505
chr11
102188381
102188945
BIRC3
Phased Variants


506
chr11
111234536
111235068
POU2AF1
Genotyping


507
chr11
111249311
111249530
POU2AF1
Phased Variants


508
chr11
111613196
111613432
PPP2R1B
Genotyping


509
chr11
111781036
111781641
CRYAB
Genotyping


510
chr11
111904096
111904291
DLAT
Genotyping


511
chr11
112405016
112405330
AP002884.2
Genotyping


512
chr11
112405341
112405621
AP002884.2
Genotyping


513
chr11
117101043
117101217
PCSK7
Genotyping


514
chr11
117712683
117712997
FXYD6
Genotyping


515
chr11
118754793
118755011
CXCR5
Phased Variants


516
chr11
118764838
118765408
CXCR5
Genotyping


517
chr11
118967323
118968029
DPAGT1
Genotyping


518
chr11
120127163
120127588
POU2F3
Genotyping


519
chr11
120189028
120189629
POU2F3
Genotyping


520
chr11
125472640
125472915
STT3A
Genotyping


521
chr11
128391383
128391629
ETS1
Phased Variants


522
chr11
128391648
128392132
ETS1
Phased Variants


523
chr11
129739778
129740102
NFRKB
Genotyping


524
chr11
131747549
131748030
NTM
Genotyping


525
chr11
134027789
134027980
NCAPD3
Genotyping


526
chr11
134118684
134118873
THYN1
Genotyping


527
chr11
134129469
134130211
ACAD8
Genotyping


528
chr11
134130464
134131097
ACAD8
Genotyping


529
chr11
134133389
134133972
ACAD8
Genotyping


530
chr12
6439713
6439920
TNFRSF1A
Genotyping


531
chr12
15813487
15813687
EPS8
Genotyping


532
chr12
18534682
18534856
PIK3C2G
Genotyping


533
chr12
18544037
18544241
PIK3C2G
Genotyping


534
chr12
18573807
18574017
PIK3C2G
Genotyping


535
chr12
18699197
18699459
PIK3C2G
Genotyping


536
chr12
18747397
18747562
PIK3C2G
Genotyping


537
chr12
18800762
18801046
PIK3C2G
Genotyping


538
chr12
18891267
18891560
CAPZA3
Genotyping


539
chr12
25205888
25206105
LRMP
Phased Variants


540
chr12
25206398
25206616
LRMP
Phased Variants


541
chr12
25206748
25206877
LRMP
Phased Variants


542
chr12
25207088
25207474
LRMP
Phased Variants


543
chr12
25398218
25398299
KRAS
Genotyping


544
chr12
48190731
48190983
HDAC7
Genotyping


545
chr12
49415991
49416144
KMT2D
Genotyping


546
chr12
49418306
49418550
KMT2D
Genotyping


547
chr12
49420531
49420750
KMT2D
Genotyping


548
chr12
49426451
49426592
KMT2D
Genotyping


549
chr12
49427886
49428116
KMT2D
Genotyping


550
chr12
49433331
49433507
KMT2D
Genotyping


551
chr12
49437926
49438391
KMT2D
Genotyping


552
chr12
49444391
49444595
KMT2D
Genotyping


553
chr12
49447196
49447491
KMT2D
Genotyping


554
chr12
57496552
57496735
STAT6
Genotyping


555
chr12
57498222
57498396
STAT6
Genotyping


556
chr12
57498912
57499150
STAT6
Genotyping


557
chr12
86198698
86199622
RASSF9
Genotyping


558
chr12
92537875
92538647
BTG1
Phased Variants


559
chr12
92538790
92539374
BTG1
Phased Variants


560
chr12
113495364
113496458
DTX1
Phased Variants


561
chr12
113496509
113496679
DTX1
Phased Variants


562
chr12
113496694
113496945
DTX1
Phased Variants


563
chr12
113497059
113497278
DTX1
Phased Variants


564
chr12
113515199
113515658
DTX1
Genotyping


565
chr12
113515664
113515934
DTX1
Genotyping


566
chr12
113530924
113531055
DTX1
Genotyping


567
chr12
113531319
113531531
DTX1
Genotyping


568
chr12
113531799
113531930
DTX1
Genotyping


569
chr12
113532569
113532781
DTX1
Genotyping


570
chr12
113532809
113533032
DTX1
Genotyping


571
chr12
113533099
113533237
DTX1
Genotyping


572
chr12
113534494
113534778
DTX1
Genotyping


573
chr12
122458781
122459524
BCL7A
Phased Variants


574
chr12
122460811
122461193
BCL7A
Phased Variants


575
chr12
122461316
122461882
BCL7A
Phased Variants


576
chr12
122462001
122462210
BCL7A
Phased Variants


577
chr12
122462716
122462935
BCL7A
Phased Variants


578
chr12
122463031
122463137
BCL7A
Phased Variants


579
chr13
32907206
32907376
BRCA2
Genotyping


580
chr13
32912226
32912828
BRCA2
Genotyping


581
chr13
41133662
41133842
FOXO1
Genotyping


582
chr13
41133922
41135026
FOXO1
Genotyping


583
chr13
41239682
41239755
FOXO1
Genotyping


584
chr13
41239827
41240356
FOXO1
Genotyping


585
chr13
41240362
41240788
FOXO1
Genotyping


586
chr13
46959165
46959379
KIAA0226L
Phased Variants


587
chr13
46961680
46962067
KIAA0226L
Phased Variants


588
chr13
51915233
51915552
SERPINE3
Genotyping


589
chr13
58207131
58209129
PCDH17
Genotyping


590
chr13
84453542
84455255
SLITRK1
Genotyping


591
chr13
113516229
113516436
ATP11A
Phased Variants


592
chr14
23344697
23345206
LRP10
Genotyping


593
chr14
32615405
32615617
ARHGAP5
Genotyping


594
chr14
35873671
35873838
NFKBIA
Genotyping


595
chr14
64330252
64330462
SYNE2
Phased Variants


596
chr14
69258238
69259642
ZFP36L1
Phased Variants


597
chr14
84420586
84420796
FLRT2
Phased Variants


598
chr14
96179592
96180295
TCL1A
Phased Variants


599
chr14
106048955
106049032
IGHA2
Phased Variants


600
chr14
106054695
106055541
IGHA2
Genotyping


601
chr14
106055740
106055827
IGHA2
Genotyping


602
chr14
106055910
106055995
IGHA2
Genotyping


603
chr14
106056035
106056121
IGHA2
Genotyping


604
chr14
106068705
106068911
IGHE
Phased Variants


605
chr14
06069045
106069384
IGHE
Phased Variants


606
chr14
106071060
106071135
IGHE
Phased Variants


607
chr14
106071190
106071271
IGHE
Phased Variants


608
chr14
106092380
106092608
IGHG4
Genotyping


609
chr14
106092670
106093406
IGHG4
Genotyping


610
chr14
106093435
106093575
IGHG4
Genotyping


611
chr14
106093610
106094215
IGHG4
Genotyping


612
chr14
106094235
106094479
IGHG4
Genotyping


613
chr14
106094580
106094654
IGHG4
Genotyping


614
chr14
106094675
106094915
IGHG4
Genotyping


615
chr14
106095335
106095417
IGHG4
Phased Variants


616
chr14
106095480
106095560
IGHG4
Phased Variants


617
chr14
106110675
106110814
IGHG2
Phased Variants


618
chr14
106110830
106110904
IGHG2
Phased Variants


619
chr14
106110950
106111025
IGHG2
Phased Variants


620
chr14
106111100
106111311
IGHG2
Genotyping


621
chr14
106111390
106112121
IGHG2
Genotyping


622
chr14
106112160
106112302
IGHG2
Genotyping


623
chr14
106112335
106113010
IGHG2
Phased Variants


624
chr14
106113020
106113438
IGHG2
Phased Variants


625
chr14
106113450
106113625
IGHG2
Phased Variants


626
chr14
106113695
106113901
IGHG2
Phased Variants


627
chr14
106113905
106113984
IGHG2
Phased Variants


628
chr14
106114175
106114414
IGHG2
Phased Variants


629
chr14
106174970
106175819
IGHA1
Genotyping


630
chr14
106175820
106176042
IGHA1
Genotyping


631
chr14
106176070
106176217
IGHA1
Genotyping


632
chr14
106176235
106176320
IGHA1
Genotyping


633
chr14
106176375
106176932
IGHA1
Phased Variants


634
chr14
106176985
106177069
IGHA1
Phased Variants


635
chr14
106177425
106177536
IGHA1
Genotyping


636
chr14
106211960
106212864
IGHG1
Phased Variants


637
chr14
106212870
106212948
IGHG1
Phased Variants


638
chr14
106212980
106213124
IGHG1
Phased Variants


639
chr14
106213125
106213200
IGHG1
Phased Variants


640
chr14
106213210
106213525
IGHG1
Phased Variants


641
chr14
106213660
106214042
IGHG1
Phased Variants


642
chr14
106239250
106239357
IGHG3
Phased Variants


643
chr14
106239455
106239900
IGHG3
Phased Variants


644
chr14
106239990
106240155
IGHG3
Phased Variants


645
chr14
106240170
106240815
IGHG3
Phased Variants


646
chr14
106240820
106240892
IGHG3
Phased Variants


647
chr14
106240915
106241118
IGHG3
Phased Variants


648
chr14
106241200
106241278
IGHG3
Phased Variants


649
chr14
106241345
106241627
IGHG3
Phased Variants


650
chr14
106241630
106241705
IGHG3
Genotyping


651
chr14
106241710
106241975
IGHG3
Genotyping


652
chr14
106318100
106318327
IGHM
Phased Variants


653
chr14
106322055
106322271
IGHM
Phased Variants


654
chr14
106322905
106323129
IGHM
Phased Variants


655
chr14
106323470
106323656
IGHM
Phased Variants


656
chr14
106323805
106323896
IGHM
Phased Variants


657
chr14
106324010
106324087
IGHM
Phased Variants


658
chr14
106324155
106324245
IGHM
Phased Variants


659
chr14
106324290
106324369
IGHM
Phased Variants


660
chr14
106324490
106324577
IGHM
Phased Variants


661
chr14
106324750
106325340
IGHM
Phased Variants


662
chr14
106325360
106325513
IGHM
Phased Variants


663
chr14
106325515
106325791
IGHM
Phased Variants


664
chr14
106325820
106326095
IGHJ6
Phased Variants


665
chr14
106326245
106326338
IGHJ6
Phased Variants


666
chr14
106326450
106331808
IGHD7-27
Phased Variants


667
chr14
106357890
106357967
IGHD6-19
Phased Variants


668
chr14
106380360
106380541
IGHD3-3
Phased Variants


669
chr14
106380550
106380901
IGHD3-3
Phased Variants


670
chr14
106380910
106381109
IGHD3-3
Phased Variants


671
chr14
106381275
106381351
IGHD3-3
Phased Variants


672
chr14
106381485
106381633
IGHD2-2
Phased Variants


673
chr14
106381655
106381724
IGHD2-2
Phased Variants


674
chr14
106381890
106381968
IGHD2-2
Phased Variants


675
chr14
106381990
106382161
IGHD2-2
Phased Variants


676
chr14
106382325
106382403
IGHD2-2
Phased Variants


677
chr14
106382905
106383014
IGHD2-2
Phased Variants


678
chr14
106383030
106383140
IGHD2-2
Phased Variants


679
chr14
106383980
106384142
IGHD1-1
Phased Variants


680
chr14
106384630
106384702
IGHD1-1
Phased Variants


681
chr14
106384720
106384798
IGHD1-1
Phased Variants


682
chr14
106384825
106384957
IGHD1-1
Phased Variants


683
chr14
106405615
106405963
IGHV6-1
Genotyping


684
chr14
106452660
106452748
IGHV1-2
Genotyping


685
chr14
106452755
106452907
IGHV1-2
Genotyping


686
chr14
106452940
106453023
IGHV1-2
Genotyping


687
chr14
106471395
106471476
IGHV1-3
Genotyping


688
chr14
106471510
106471609
IGHV1-3
Genotyping


689
chr14
106494090
106494168
IGHV2-5
Phased Variants


690
chr14
106494210
106494365
IGHV2-5
Phased Variants


691
chr14
106494445
106494553
IGHV2-5
Phased Variants


692
chr14
106494565
106494640
IGHV2-5
Phased Variants


693
chr14
106494650
106494806
IGHV2-5
Phased Variants


694
chr14
106518495
106518570
IGHV3-7
Phased Variants


695
chr14
106518855
106518962
IGHV3-7
Phased Variants


696
chr14
106518970
106519111
IGHV3-7
Phased Variants


697
chr14
106539175
106539315
IGHV1-8
Genotyping


698
chr14
106552365
106552502
IGHV3-9
Genotyping


699
chr14
106573315
106573414
IGHV3-11
Genotyping


700
chr14
106573445
106573524
IGHV3-11
Genotyping


701
chr14
106573540
106573645
IGHV3-11
Phased Variants


702
chr14
106573685
106574021
IGHV3-11
Phased Variants


703
chr14
106586200
106586343
IGHV3-13
Genotyping


704
chr14
106610380
106610479
IGHV3-15
Genotyping


705
chr14
106610480
106610557
IGHV3-15
Genotyping


706
chr14
106610690
106610765
IGHV3-15
Phased Variants


707
chr14
106621885
106622026
IGHV3-16
Genotyping


708
chr14
106622035
106622108
IGHV3-16
Genotyping


709
chr14
106641655
106641789
IGHV1-18
Genotyping


710
chr14
106642110
106642265
IGHV1-18
Phased Variants


711
chr14
106667545
106667628
IGHV3-20
Genotyping


712
chr14
106667675
106667750
IGHV3-20
Genotyping


713
chr14
106667805
106667882
IGHV3-20
Genotyping


714
chr14
106691755
106691904
IGHV3-21
Genotyping


715
chr14
106725295
106725442
IGHV3-23
Phased Variants


716
chr14
106725550
106725663
IGHV3-23
Phased Variants


717
chr14
106725780
106725952
IGHV3-23
Phased Variants


718
chr14
106725995
106726188
IGHV3-23
Phased Variants


719
chr14
106732970
106733077
IGHV1-24
Phased Variants


720
chr14
106733185
106733270
IGHV1-24
Phased Variants


721
chr14
106733275
106733487
IGHV1-24
Phased Variants


722
chr14
106757725
106757888
IGHV2-26
Genotyping


723
chr14
106758470
106758653
IGHV2-26
Phased Variants


724
chr14
106780610
106780752
IGHV4-28
Genotyping


725
chr14
106791090
106791169
IGHV3-30
Phased Variants


726
chr14
106805290
106805428
IGHV4-31
Genotyping


727
chr14
106805945
106806076
IGHV4-31
Phased Variants


728
chr14
106806120
106806219
IGHV4-31
Phased Variants


729
chr14
106815805
106815910
IGHV3-33
Phased Variants


730
chr14
106829685
106829757
IGHV4-34
Phased Variants


731
chr14
106829765
106829986
IGHV4-34
Phased Variants


732
chr14
106830125
106830196
IGHV4-34
Phased Variants


733
chr14
106830240
106830312
IGHV4-34
Phased Variants


734
chr14
106830315
106830884
IGHV4-34
Phased Variants


735
chr14
106831185
106831594
IGHV4-34
Phased Variants


736
chr14
106845300
106845540
IGHV3-35
Genotyping


737
chr14
106846385
106846557
IGHV3-35
Phased Variants


738
chr14
106866380
106866461
IGHV3-38
Genotyping


739
chr14
106866475
106866638
IGHV3-38
Genotyping


740
chr14
106877715
106877858
IGHV4-39
Phased Variants


741
chr14
106877930
106878498
IGHV4-39
Phased Variants


742
chr14
106878540
106878612
IGHV4-39
Phased Variants


743
chr14
106878680
106878759
IGHV4-39
Phased Variants


744
chr14
106926180
106926405
IGHV3-43
Genotyping


745
chr14
106962965
106963167
IGHV1-45
Genotyping


746
chr14
106963170
106963280
IGHV1-45
Genotyping


747
chr14
106967130
106967209
IGHV1-46
Genotyping


748
chr14
106967315
106967397
IGHV1-46
Genotyping


749
chr14
106994300
106994376
IGHV3-48
Phased Variants


750
chr14
106994430
106994534
IGHV3-48
Phased Variants


751
chr14
106994545
106994618
IGHV3-48
Phased Variants


752
chr14
106994660
106994745
IGHV3-48
Phased Variants


753
chr14
106994760
106994904
IGHV3-48
Phased Variants


754
chr14
107013035
107013204
IGHV3-49
Genotyping


755
chr14
107034665
107034845
IGHV5-51
Genotyping


756
chr14
107034955
107035097
IGHV5-51
Genotyping


757
chr14
107078455
107078631
IGHV1-58
Genotyping


758
chr14
107083565
107083726
IGHV4-59
Phased Variants


759
chr14
107083790
107083923
IGHV4-59
Phased Variants


760
chr14
107113405
107113560
IGHV3-64
Phased Variants


761
chr14
107113820
107113922
IGHV3-64
Phased Variants


762
chr14
107114095
107114238
IGHV3-64
Phased Variants


763
chr14
107136755
107136899
IGHV3-66
Phased Variants


764
chr14
107169645
107169841
IGHV1-69
Phased Variants


765
chr14
107169970
107170195
IGHV1-69
Phased Variants


766
chr14
107170220
107170472
IGHV1-69
Phased Variants


767
chr14
107170475
107170563
IGHV1-69
Phased Variants


768
chr14
107170660
107170871
IGHV1-69
Phased Variants


769
chr14
107178305
107178377
IGHV2-70
Phased Variants


770
chr14
107178415
107178869
IGHV2-70
Phased Variants


771
chr14
107178880
107179116
IGHV2-70
Phased Variants


772
chr14
107179130
107179339
IGHV2-70
Phased Variants


773
chr14
107179360
107180001
IGHV2-70
Phased Variants


774
chr14
107199020
107199094
IGHV3-72
Genotyping


775
chr14
107199095
107199173
IGHV3-72
Genotyping


776
chr14
107210955
107211159
IGHV3-73
Genotyping


777
chr14
107218755
107218891
IGHV3-74
Genotyping


778
chr14
107258910
107259078
IGHV7-81
Phased Variants


779
chr14
107259100
107259206
IGHV7-81
Phased Variants


780
chr14
107259235
107259444
IGHV7-81
Phased Variants


781
chr14
107259555
107259635
IGHV7-81
Phased Variants


782
chr14
107282770
107282884
IGHV7-81
Genotyping


783
chr14
107282945
107283018
IGHV7-81
Genotyping


784
chr15
45003678
45003861
B2M
Genotyping


785
chr15
45007718
45007927
B2M
Genotyping


786
chr15
45008463
45008603
B2M
Genotyping


787
chr15
66727354
66727536
MAP2K1
Genotyping


788
chr15
66729014
66729123
MAP2K1
Genotyping


789
chr15
66729139
66729292
MAP2K1
Genotyping


790
chr15
86312062
86312565
KLHL25
Genotyping


791
chr16
2812096
2812786
SRRM2
Genotyping


792
chr16
3779106
3779320
CREBBP
Genotyping


793
chr16
3781171
3781464
CREBBP
Genotyping


794
chr16
3781756
3781972
CREBBP
Genotyping


795
chr16
3786011
3786223
CREBBP
Genotyping


796
chr16
3786591
3786885
CREBBP
Genotyping


797
chr16
3788511
3788716
CREBBP
Genotyping


798
chr16
3789521
3789770
CREBBP
Genotyping


799
chr16
3790376
3790580
CREBBP
Genotyping


800
chr16
3794846
3794994
CREBBP
Genotyping


801
chr16
3808801
3809009
CREBBP
Genotyping


802
chr16
3817706
3817915
CREBBP
Genotyping


803
chr16
3823711
3823942
CREBBP
Genotyping


804
chr16
3824536
3824719
CREBBP
Genotyping


805
chr16
3832716
3832942
CREBBP
Genotyping


806
chr16
3900236
3900462
CREBBP
Genotyping


807
chr16
3900561
3900914
CREBBP
Genotyping


808
chr16
10971440
10973882
CIITA
Phased Variants


809
chr16
10973885
10974203
CIITA
Phased Variants


810
chr16
11348520
11349249
SOCS1
Phased Variants


811
chr16
30093722
30093935
PPP4C
Genotyping


812
chr16
33523607
33523675
IGHV3OR16-12
Phased Variants


813
chr16
81946175
81946356
PLCG2
Genotyping


814
chr16
81953055
81953307
PLCG2
Genotyping


815
chr16
81962120
81962263
PLCG2
Genotyping


816
chr16
85933003
85933569
IRF8
Phased Variants


817
chr16
85936563
85936836
IRF8
Genotyping


818
chr16
85942563
85942821
IRF8
Genotyping


819
chr16
85945108
85945330
IRF8
Genotyping


820
chr16
85946708
85946887
IRF8
Genotyping


821
chr16
85948018
85948170
IRF8
Genotyping


822
chr16
85951993
85952448
IRF8
Genotyping


823
chr16
85953683
85953837
IRF8
Genotyping


824
chr16
85954723
85954937
IRF8
Genotyping


825
chr17
5366796
5367031
DHX33
Genotyping


826
chr17
7576949
7577197
TP53
Genotyping


827
chr17
7577444
7577683
TP53
Genotyping


828
chr17
7578129
7578336
TP53
Genotyping


829
chr17
7578344
7578591
TP53
Genotyping


830
chr17
7579259
7579428
TP53
Genotyping


831
chr17
18001529
18001704
DRG2
Genotyping


832
chr17
18022119
18022791
MYO15A
Genotyping


833
chr17
40467709
40467857
STAT3
Genotyping


834
chr17
40469104
40469321
STAT3
Genotyping


835
chr17
40474309
40474530
STAT3
Genotyping


836
chr17
40474974
40475190
STAT3
Genotyping


837
chr17
40475254
40475394
STAT3
Genotyping


838
chr17
40478074
40478252
STAT3
Genotyping


839
chr17
40485844
40486132
STAT3
Genotyping


840
chr17
40489754
40489903
STAT3
Genotyping


841
chr17
40491284
40491489
STAT3
Genotyping


842
chr17
41847058
41847241
DUSP3
Genotyping


843
chr17
51900441
51900897
KIF2B
Genotyping


844
chr17
56408574
56408755
BZRAP1
Phased Variants


845
chr17
56408884
56409615
BZRAP1
Phased Variants


846
chr17
62006520
62006919
CD79B
Genotyping


847
chr17
62007105
62007279
CD79B
Genotyping


848
chr17
62007410
62007761
CD79B
Genotyping


849
chr17
62008645
62008786
CD79B
Genotyping


850
chr17
62009505
62009659
CD79B
Genotyping


851
chr17
63010240
63010308
GNA13
Phased Variants


852
chr17
63010315
63010973
GNA13
Phased Variants


853
chr17
63014313
63014461
GNA13
Genotyping


854
chr17
63049573
63049774
GNA13
Genotyping


855
chr17
63052443
63052678
GNA13
Genotyping


856
chr17
75447868
75448421
9-Sep
Phased Variants


857
chr17
78343503
78343715
RNF213
Genotyping


858
chr17
79478953
79479026
ACTG1
Genotyping


859
chr18
1477565
1477666
ADCYAP1
Phased Variants


860
chr18
6947104
6947347
LAMA1
Genotyping


861
chr18
6980464
6980680
LAMAI
Genotyping


862
chr18
13825915
13826461
MC5R
Genotyping


863
chr18
30349775
30350300
AC012123.1
Phased Variants


864
chr18
48231684
48232112
MAPK4
Genotyping


865
chr18
48327694
48327901
MRO
Genotyping


866
chr18
48512954
48513347
ELAC1
Genotyping


867
chr18
48591759
48592011
SMAD4
Genotyping


868
chr18
48593364
48593571
SMAD4
Genotyping


869
chr18
48604604
48604852
SMAD4
Genotyping


870
chr18
48703169
48703965
MEX3C
Genotyping


871
chr18
53804515
53804796
TXNL1
Genotyping


872
chr18
55274405
55274580
NARS
Genotyping


873
chr18
55319680
55319999
ATP8B1
Genotyping


874
chr18
55329690
55329857
ATP8B1
Genotyping


875
chr18
55359005
55359259
ATP8B1
Genotyping


876
chr18
56054915
56055594
NEDD4L
Genotyping


877
chr18
56063365
56063826
NEDD4L
Genotyping


878
chr18
60763829
60764032
BCL2
Genotyping


879
chr18
60764299
60764540
BCL2
Genotyping


880
chr18
60774414
60774660
BCL2
Genotyping


881
chr18
60793369
60793654
BCL2
Genotyping


882
chr18
60795829
60796006
BCL2
Genotyping


883
chr18
60806264
60806836
BCL2
Phased Variants


884
chr18
60983784
60983991
BCL2
Phased Variants


885
chr18
60984454
60986731
BCL2
Phased Variants


886
chr18
60986844
60987047
BCL2
Phased Variants


887
chr18
60987964
60988511
BCL2
Phased Variants


888
chr18
64172116
64172531
CDH19
Genotyping


889
chr18
64176241
64176518
CDH19
Genotyping


890
chr18
64239166
64239357
CDH19
Genotyping


891
chr18
65179856
65181824
DSEL
Genotyping


892
chr18
73944893
73945380
ZNF516
Genotyping


893
chr18
75683734
75684502
GALR1
Genotyping


894
chr18
77092820
77093034
ATP9B
Genotyping


895
chr18
77170715
77171032
NEATC1
Genotyping


896
chr18
77208755
77208996
NFATC1
Genotyping


897
chr18
77227415
77227661
NFATC1
Genotyping


898
chr18
77288040
77288611
NFATCI
Genotyping


899
chr18
77794425
77795130
RBFA
Genotyping


900
chr19
1376440
1376662
MUM1
Genotyping


901
chr19
6586161
6586445
CD70
Genotyping


902
chr19
6590026
6590238
CD70
Genotyping


903
chr19
6590786
6591079
CD70
Genotyping


904
chr19
8028408
8028583
ELAVL1
Genotyping


905
chr19
10334563
10335187
S1PR2
Genotyping


906
chr19
10335308
10335585
S1PR2
Genotyping


907
chr19
10340823
10341376
S1PR2
Phased Variants


908
chr19
10341833
10341984
S1PR2
Genotyping


909
chr19
12902574
12902861
JUNB
Genotyping


910
chr19
19256469
19256851
MEF2B
Genotyping


911
chr19
19257044
19257222
MEF2B
Genotyping


912
chr19
19257339
19257480
MEF2B
Genotyping


913
chr19
19257489
19257741
MEF2B
Genotyping


914
chr19
19257824
19258036
MEF2B
Genotyping


915
chr19
19258484
19258662
MEF2B
Genotyping


916
chr19
19259984
19260176
MEF2B
Genotyping


917
chr19
19261414
19261588
MEF2B
Genotyping


918
chr19
19293309
19293478
MEF2BNB
Genotyping


919
chr19
42599890
42600121
POU2F2
Genotyping


920
chr19
51525626
51525937
KLK11
Genotyping


921
chr19
51559441
51560040
KLK13
Genotyping


922
chr19
51561771
51561943
KLK13
Genotyping


923
chr19
52381611
52381786
ZNF577
Genotyping


924
chr19
52403336
52403586
ZNF649
Genotyping


925
chr19
52961146
52961224
ZNF534
Genotyping


926
chr19
52961226
52961578
ZNF534
Genotyping


927
chr19
53598586
53599055
ZNF160
Genotyping


928
chr20
23028372
23028858
THBD
Genotyping


929
chr20
25003526
25003774
ACSS1
Genotyping


930
chr20
46131072
46131213
NCOA3
Phased Variants


931
chr20
46131217
46131287
NCOA3
Phased Variants


932
chr21
18981233
18981504
BTG3
Genotyping


933
chr21
28213258
28213536
ADAMTS1
Genotyping


934
chr21
28216763
28217005
ADAMTS1
Genotyping


935
chr22
22380472
22381038
IGLV4-69
Phased Variants


936
chr22
22385622
22385767
IGLV4-69
Genotyping


937
chr22
22385777
22385898
IGLV4-69
Genotyping


938
chr22
22453287
22453502
IGLV8-61
Genotyping


939
chr22
22453527
22453608
IGLV8-61
Genotyping


940
chr22
22516707
22516785
IGLV4-60
Phased Variants


941
chr22
22516827
22517113
IGLV4-60
Phased Variants


942
chr22
22550337
22550812
IGLV6-57
Genotyping


943
chr22
22556227
22556630
IGLV11-55
Genotyping


944
chr22
22569332
22569655
IGLV10-54
Genotyping


945
chr22
22673242
22673607
IGLV5-52
Genotyping


946
chr22
22677077
22677216
IGLV1-51
Phased Variants


947
chr22
22677227
22677337
IGLV1-51
Genotyping


948
chr22
22681927
22682007
IGLV1-50
Genotyping


949
chr22
22682097
22682213
IGLV1-50
Genotyping


950
chr22
22697727
22698123
IGLV9-49
Genotyping


951
chr22
22707427
22707509
IGLV5-48
Genotyping


952
chr22
22707517
22707658
IGLV5-48
Phased Variants


953
chr22
22707742
22707823
IGLV5-48
Genotyping


954
chr22
22712077
22712496
IGLV1-47
Phased Variants


955
chr22
22712512
22712625
IGLV1-47
Genotyping


956
chr22
22723897
22724189
IGLV7-46
Phased Variants


957
chr22
22724207
22724494
IGLV7-46
Phased Variants


958
chr22
22730452
22730552
IGLV5-45
Phased Variants


959
chr22
22730607
22730756
IGLV5-45
Phased Variants


960
chr22
22730887
22730955
IGLV5-45
Phased Variants


961
chr22
22735417
22735604
IGLV1-44
Phased Variants


962
chr22
22735792
22735878
IGLV1-44
Phased Variants


963
chr22
22749602
22749701
IGLV7-43
Phased Variants


964
chr22
22749732
22749853
IGLV7-43
Phased Variants


965
chr22
22749857
22749939
IGLV7-43
Phased Variants


966
chr22
22749942
22750074
IGLV7-43
Phased Variants


967
chr22
22750092
22750342
IGLV7-43
Phased Variants


968
chr22
22758647
22759294
IGLV1-40
Phased Variants


969
chr22
22759297
22759377
IGLV1-40
Phased Variants


970
chr22
22764167
22764309
IGLV1-40
Phased Variants


971
chr22
22764367
22764450
IGLV1-40
Phased Variants


972
chr22
22764552
22764634
IGLV1-40
Phased Variants


973
chr22
22782037
22782325
IGLV5-37
Genotyping


974
chr22
22786477
22786702
IGLV1-36
Genotyping


975
chr22
22786727
22786842
IGLV1-36
Genotyping


976
chr22
22930852
22931173
IGLV2-33
Genotyping


977
chr22
22937192
22937341
IGLV3-32
Genotyping


978
chr22
22937347
22937548
IGLV3-32
Genotyping


979
chr22
23010977
23011143
IGLV3-27
Genotyping


980
chr22
23011172
23011316
IGLV3-27
Genotyping


981
chr22
23029497
23029581
IGLV3-25
Genotyping


982
chr22
23029622
23029778
IGLV3-25
Genotyping


983
chr22
23040452
23040527
IGLV2-23
Phased Variants


984
chr22
23040592
23040811
IGLV2-23
Phased Variants


985
chr22
23040852
23041365
IGLV2-23
Phased Variants


986
chr22
23047067
23047329
IGLV3-22
Genotyping


987
chr22
23055367
23055445
IGLV3-21
Genotyping


988
chr22
23055497
23055577
IGLV3-21
Phased Variants


989
chr22
23055727
23055857
IGLV3-21
Phased Variants


990
chr22
23063307
23063661
IGLV3-19
Genotyping


991
chr22
23077337
23077435
IGLV2-18
Genotyping


992
chr22
23077537
23077615
IGLV2-18
Genotyping


993
chr22
23090122
23090205
IGLV3-16
Genotyping


994
chr22
23090287
23090372
IGLV3-16
Genotyping


995
chr22
23101392
23101473
IGLV2-14
Phased Variants


996
chr22
23101532
23101605
IGLV2-14
Phased Variants


997
chr22
23101652
23101735
IGLV2-14
Genotyping


998
chr22
23114792
23114874
IGLV3-12
Genotyping


999
chr22
23114947
23115052
IGLV3-12
Genotyping


1000
chr22
23135152
23135230
IGLV2-11
Genotyping


1001
chr22
23135247
23135399
IGLV2-11
Genotyping


1002
chr22
23135437
23135521
IGLV2-11
Genotyping


1003
chr22
23154347
23154477
IGLV3-10
Phased Variants


1004
chr22
23154597
23154815
IGLV3-10
Phased Variants


1005
chr22
23161917
23162052
IGLV3-9
Genotyping


1006
chr22
23162072
23162290
IGLV3-9
Genotyping


1007
chr22
23165422
23165496
IGLV2-8
Phased Variants


1008
chr22
2316SS42
23165680
IGLV2-8
Phased Variants


1009
chr22
23165727
23165811
IGLV2-8
Phased Variants


1010
chr22
23192412
23192818
IGLV4-3
Phased Variants


1011
chr22
23197917
23198053
IGLV4-3
Phased Variants


1012
chr22
23198067
23198475
IGLV4-3
Phased Variants


1013
chr22
23198587
23198732
IGLV4-3
Phased Variants


1014
chr22
23198797
23198869
IGLV4-3
Phased Variants


1015
chr22
23199022
23199127
IGLV4-3
Phased Variants


1016
chr22
23199182
23199261
IGLV4-3
Phased Variants


1017
chr22
23199277
23199671
IGLV4-3
Phased Variants


1018
chr22
23213857
23214141
IGLV4-3
Genotyping


1019
chr22
23214167
23214249
IGLV4-3
Genotyping


1020
chr22
23222927
23223065
IGLV3-1
Phased Variants


1021
chr22
23223077
23223319
IGLV3-1
Phased Variants


1022
chr22
23223327
23224010
IGLV3-1
Phased Variants


1023
chr22
23227062
23227279
IGLL5
Phased Variants


1024
chr22
23227567
23227896
IGLL5
Phased Variants


1025
chr22
23227897
23228624
IGLL5
Phased Variants


1026
chr22
23229332
23229550
IGLL5
Phased Variants


1027
chr22
23229562
23229739
IGLL5
Phased Variants


1028
chr22
23230012
23231063
IGLL5
Phased Variants


1029
chr22
23231072
23231764
IGLL5
Phased Variants


1030
chr22
23231927
23232005
IGLL5
Phased Variants


1031
chr22
23232062
23232346
IGLL5
Phased Variants


1032
chr22
23232362
23232465
IGLL5
Phased Variants


1033
chr22
23232517
23232737
IGLL5
Phased Variants


1034
chr22
23234612
23235837
IGLJ1
Phased Variants


1035
chr22
23235847
23236276
IGLJ1
Phased Variants


1036
chr22
23236277
23236378
IGLJ1
Phased Variants


1037
chr22
23236387
23236526
IGLJ1
Phased Variants


1038
chr22
23236557
23236851
IGLJ1
Phased Variants


1039
chr22
23236877
23237366
IGLC1
Phased Variants


1040
chr22
23241762
23241835
IGLJ2
Genotyping


1041
chr22
23242602
23242981
IGLC2
Phased Variants


1042
chr22
23244157
23244373
IGLC2
Phased Variants


1043
chr22
23247137
23247209
IGLJ3
Genotyping


1044
chr22
23247257
23247444
IGLJ3
Phased Variants


1045
chr22
23247467
23247630
IGLJ3
Phased Variants


1046
chr22
23248182
23248404
IGLC3
Phased Variants


1047
chr22
23252687
23252824
IGLJ4
Genotyping


1048
chr22
23256362
23256504
IGLJ5
Genotyping


1049
chr22
23260267
23260399
IGLJ6
Genotyping


1050
chr22
23263507
23263653
IGLJ7
Genotyping


1051
chr22
23263872
23264263
IGLJ7
Phased Variants


1052
chr22
23278157
23278381
IGLC7
Phased Variants


1053
chr22
23282767
23282839
IGLC7
Phased Variants


1054
chr22
23282842
23282956
IGLC7
Phased Variants


1055
chr22
23523567
23524204
BCR
Genotyping


1056
chr22
23524212
23524419
BCR
Genotyping


1057
chr22
23610547
23610791
BCR
Genotyping


1058
chr22
29191136
29191455
XBP1
Genotyping


1059
chr22
29191461
29191746
XBP1
Genotyping


1060
chr22
29192006
29192215
XBP1
Genotyping


1061
chr22
29193041
29193205
XBP1
Genotyping


1062
chr22
29196261
29196547
XBP1
Genotyping


1063
chr22
41513340
41513562
EP300
Genotyping


1064
chr22
41525845
41526047
EP300
Genotyping


1065
chr22
41527440
41527664
EP300
Genotyping


1066
chr22
41536110
41536291
EP300
Genotyping


1067
chr22
41545740
41545940
EP300
Genotyping


1068
chr22
41545995
41546223
EP300
Genotyping


1069
chr22
41565485
41565650
EP300
Genotyping


1070
chr22
41566385
41566592
EP300
Genotyping


1071
chr22
41568480
41568693
EP300
Genotyping


1072
chr22
41569600
41569814
EP300
Genotyping


1073
chr22
41572225
41572436
EP300
Genotyping


1074
chr22
41572800
41573022
EP300
Genotyping


1075
chr22
41573300
41573515
EP300
Genotyping


1076
chr22
41574255
41574486
EP300
Genotyping


1077
chr22
41574685
41574904
EP300
Genotyping


1078
chr22
47570209
47570414
TBC1D22A
Phased Variants


1079
chrX
1584324
1585521
P2RY8
Genotyping


1080
chrX
1655789
1656029
AKAP17A
Genotyping


1081
chrX
12993264
12993539
TMSB4X
Phased Variants


1082
chrX
12993544
12994173
TMSB4X
Phased Variants


1083
chrX
12994289
12994397
TMSB4X
Phased Variants


1084
chrX
12994444
12994514
TMSB4X
Phased Variants


1085
chrX
33146106
33146490
DMD
Phased Variants


1086
chrX
35820576
35821268
MAGEB16
Genotyping


1087
chrX
70347816
70348034
MED12
Genotyping


1088
chrX
70612661
70612778
TAF1
Genotyping


1089
chrX
73962123
73963110
KIAA2022
Genotyping


1090
chrX
86772953
86773345
KLHL4
Genotyping


1091
chrX
90026453
90026652
PABPC5
Phased Variants


1092
chrX
100610984
100611308
BTK
Genotyping


1093
chrX
119509280
119509492
ATP1B4
Genotyping


1094
chrX
141291052
141291326
MAGEC2
Genotyping


1095
chrX
141291357
141291566
MAGEC2
Genotyping


1096
chrX
153997383
153997622
DKC1
Genotyping





























TABLE 4













Mean frac
Mean frac
Mean frac







Region
Region


Mean frac
Mean frac
ABC
PMBCL
CHIL
ranksamP
ranksumP
ranksumP


#
Chromosome
Start
End
Number of 50 bp bins
Gene
DLBCL with PV
GCB with PV
with PV
with PV
with PV
ABCvsGCB
PMBCLvsDLBCL
CHLv&DLBCL




























1
chr22
23227063
23237340
135
IGLL5
0.184
0.158
0.224
0.242
0.088
0.00000
0.00003
0.00000


2
chr18
60763830
60988465
104
BCL2
0.111
0.165
0.029
0.056
0.004
0.00000
0.00000
0.00000


3
chr14
106239251
106241954
49
IGHG3
0.193
0.155
0.251
0.105
0.032
0.00000
0.00000
0.00000


4
chr14
106092381
106095531
51
IGHG4
0.179
0.155
0.217
0.136
0.056
0.00000
0.00000
0.00000


5
chr6
37138285
37141880
36
PIM1
0.073
0.039
0.124
0.068
0.000
0.00000
0.00251
0.00000


6
chr22
22758648
22764603
22
IGLV1-40
0.064
0.098
0.013
0.102
0.000
0.00000
0.46986
0.00001


7
chr2
89161240
89165610
66
IGKJ1
0.144
0.134
0.160
0.140
0.109
0.00000
0.00006
0.36296


8
chr14
106829686
106831586
30
IGHV4-34
0.077
0.049
0.121
0.100
0.012
0.00000
0.10144
0.01432


9
chr2
89158619
89160190
32
IGKJ5
0.307
0.286
0.339
0.350
0.219
0.00000
0.28398
0.00000


10
chr22
23222928
23223998
22
IGLV3-1
0.266
0.300
0.215
0.429
0.208
0.00000
0.00000
0.22589


11
chr14
106211961
106214011
39
IGHG1
0.229
0.197
0.277
0.131
0.035
0.00000
0.00000
0.00000


12
chr14
106329751
106330201
10
IGHJ5
0.320
0.261
0.410
0.375
0.148
0.00000
0.24822
0.00000


13
chr3
187957433
188471931
54
LPP
0.080
0.102
0.046
0.168
0.062
0.00001
0.00027
0.00345


14
chr2
89160890
89161190
7
IGKJ2
0.151
0.096
0.236
0.116
0.062
0.00001
0.02569
0.00086


15
chr6
134491383
134495968
64
SGK1
0.039
0.053
0.018
0.075
0.001
0.00002
0.58192
0.99403


16
chr6
150954421
150954821
9
PLEKHG1
0.067
0.049
0.094
0.063
0.000
0.00002
0.11666
0.00114


17
chr2
89246682
89247982
18
IGKV1-5
0.031
0.023
0.043
0.097
0.024
0.00003
0.01798
0.00005


18
chr18
128746808
128764273
164
MYC
0.037
0.047
0.021
0.039
0.001
0.00003
0.00000
0.86966


19
chr22
23040453
23041334
17
IGLV2-23
0.051
0.073
0.018
0.088
0.005
0.00003
0.77724
0.04594


20
chr2
89160240
89160540
7
IGKJ4
0.259
0.225
0.311
0.241
0.130
0.00003
0.04157
0.00006


21
chr22
22516708
22517100
8
IGLV4-60
0.084
0.117
0.034
0.078
0.022
0.00003
0.17854
0.01628


22
chr12
122458782
122463132
48
BCL7A
0.091
0.106
0.068
0.173
0.041
0.00005
0.00033
0.01552


23
chr14
107178306
107179990
33
IGHV2-70
0.224
0.242
0.195
0.182
0.115
0.00006
0.00002
0.00004


24
chr2
89160590
89160840
6
IGKJ3
0.185
0.137
0.258
0.135
0.109
0.00006
0.00291
0.00284


25
chr22
22730453
22730938
7
IGLV5-45
0.069
0.108
0.011
0.107
0.019
0.00010
0.70241
0.37522


26
chr22
23248183
23248383
5
IGLC3
0.164
0.236
0.055
0.113
0.035
0.00014
0.00837
0.00072


27
chr2
89127262
89158569
66
IGKC
0.089
0.077
0.107
0.164
0.041
0.00022
0.00008
0.04625


28
chr9
37293170
37384885
18
ZCCHC7
0.055
0.075
0.025
0.069
0.002
0.00023
0.36871
0.42872


29
chr14
106732971
106733441
9
IGHV1-24
0.036
0.060
0.000
0.090
0.000
0.00026
0.33149
0.77291


30
chr2
89184967
89185677
15
IGKV4-1
0.103
0.133
0.057
0.133
0.078
0.00035
0.83189
0.36813


31
chr2
59821915
60773435
12
BCL11A
0.035
0.053
0.008
0.089
0.000
0.00075
0.19138
0.80319


32
chr20
46131073
46131277
5
NCOA3
0.071
0.102
0.025
0.025
0.009
0.00085
0.00670
0.02848


33
chr22
23165423
23165766
6
IGLV2-8
0.045
0.022
0.079
0.083
0.043
0.00090
0.90873
0.01148


34
chr8
8748688
8750268
17
MFHASI
0.033
0.051
0.004
0.055
0.000
0.00099
0.48925
0.69644


35
chr19
52961147
52961549
9
ZNF534
0.029
0.018
0.044
0.063
0.000
0.00113
0.75367
0.44231


36
chr9
16435499
16436299
17
BNC2
0.034
0.049
0.012
0.077
0.000
0.00119
0.51920
0.84956


37
chr22
23264173
23282921
11
IGLC7
0.041
0.061
0.011
0.131
0.000
0.00129
0.00884
0.29860


38
chr14
106318101
106325773
50
IGHM
0.181
0.175
0.190
0.139
0.024
0.00192
0.00000
0.00000


39
chr22
23235813
23235973
4
IGLJ1
0.059
0.033
0.100
0.266
0.000
0.00225
0.00168
0.05724


40
chr16
11348521
11349221
15
SOCS1
0.108
0.126
0.080
0.292
0.046
0.00303
0.00000
0.07342


41
chr16
10971441
10974194
56
CHITA
0.072
0.084
0.054
0.289
0.082
0.00307
0.00000
0.00000


42
chr5
13864466
13864666
5
DNAHS
0.034
0.056
0.000
0.088
0.000
0.00408
0.40676
0.90937


43
chr6
27777784
27778062
6
HISTIH3H
0.041
0.025
0.067
0.042
0.000
0.00488
0.21081
0.62256


44
chr22
23192413
23214234
46
IGLV4-3
0.061
0.074
0.042
0.162
0.025
0.00501
0.00000
0.65960


45
chr14
106330251
106330601
00
IGHJ4
0.166
0.143
0.200
0.180
0.043
0.00606
0.43909
0.00002


46
chr14
106877716
106878731
18
IGHV4-39
0.050
0.064
0.028
0.059
0.053
0.00685
0.08333
0.00000


47
chr10
90773867
90774067
5
FAS
0.042
0.066
0.005
0.038
0.000
0.00715
0.19681
0.45229


48
chr22
22723898
22724466
12
IGLV7-46
0.057
0.081
0.021
0.094
0.000
0.00728
0.81618
0.00596


49
chr5
137801488
137801798
6
EGR1
0.031
0.052
0.000
0.167
0.000
0.00799
0.01126
0.75859


50
chr22
23242603
23244358
13
IGLC2
0.139
0.164
0.100
0.163
0.094
0.00835
0.72971
0.51511


51
chr22
22930853
22931153
7
IGLV2-33
0.030
0.021
0.043
0.045
0.000
0.00870
0.55261
0.56841


52
chr14
106325852
106329701
73
IGHJ6
0.474
0.471
0.478
0.470
0.362
0.00948
0.02862
0.00000


53
chr3
185697424
185697624
5
TRA2B
0.040
0.059
0.010
0.075
0.000
0.00954
0.90180
0.48859


54
chr6
26056035
26056539
11
HISTIHIC
0.059
0.079
0.027
0.017
0.000
0.00967
0.00022
0.00680


55
chr3
71551102
71551452
8
FOXP1
0.015
0.006
0.028
0.031
0.011
0.00999
0.57172
0.00116


56
chr3
187440190
187661368
137
BCL6
0.106
0.116
0.089
0.126
0.044
0.01002
0.04210
0.00007


57
chr11
128391384
128392103
15
ETS1
0.061
0.059
0.065
0.021
0.000
0.01042
0.00001
0.00039


58
chr13
46959166
46962031
13
KIAA0226L
0.034
0.029
0.042
0.067
0.000
0.01112
0.97915
0.84801


59
chr11
118754794
118765389
17
CXCR5
0.035
0.029
0.044
0.077
0.000
0.01378
0.40303
0.93788


60
chr17
62006521
62009656
27
CD79B
0.041
0.039
0.044
0.083
0.002
0.01401
0.66941
0.59741


61
chr1
2334442
2335149
15
RER1
0.019
0.016
0.023
0.088
0.000
0.01514
0.02024
0.00677


62
chr8
139600458
139601543
20
COL22A1
0.031
0.043
0.011
0.078
0.000
0.01532
0.28495
0.48626


63
chr1
34404023
34404123
3
CSMD2
0.073
0.104
0.025
0.042
0.000
0.01556
0.06834
0.05288


64
chr6
26216780
26216880
3
HISTIH2BG
0.040
0.066
0.000
0.063
0.000
0.01575
0.79954
0.58401


65
chr18
52381612
52381762
4
ZNF577
0.032
0.053
0.000
0.063
0.000
0.01627
0.93639
0.94029


66
chr11
65266553
65267598
13
SCYL1
0.030
0.045
0.008
0.048
0.003
0.01646
0.43210
0.34042


67
chr22
23029498
23029739
5
IGLV3-25
0.085
0.108
0.050
0.113
0.043
0.01712
0.97583
0.80122


68
chr9
78686580
78686830
6
PCSK5
0.035
0.052
0.008
0.073
0.000
0.01813
0.77106
0.87235


69
chr14
106048956
106056101
25
IGHA2
0.071
0.071
0.072
0.180
0.007
0.01828
0.00255
0.02269


70
chr14
69258239
69259639
29
ZFP36L1
0.088
0.103
0.065
0.159
0.013
0.01945
0.03212
0.00000


71
chr5
75913717
75914417
15
F2RL2
0.030
0.044
0.010
0.108
0.000
0.01980
0.01754
0.55332


72
chr14
106926181
106926381
5
IGHV3-43
0.038
0.056
0.010
0.038
0.000
0.01981
0.22178
0.96725


73
chr6
27782719
27782919
5
HIST1H2BM
0.032
0.052
0.000
0.000
0.000
0.02014
0.01525
0.81176


74
chr2
100758484
100758634
4
AFF3
0.037
0.025
0.056
0.078
0.033
0.02064
0.69126
0.04169


75
chr8
136569670
137528538
22
KHDRBS3
0.029
0.041
0.011
0.065
0.000
0.02090
0.60391
0.32890


76
chr6
392761
395016
15
IRF4
0.035
0.031
0.042
0.021
0.000
0.02146
0.00420
0.95404


77
chr8
3141725
4495082
9
CSMD1
0.034
0.051
0.008
0.076
0.000
0.02188
0.57834
0.96296


78
chr14
106330651
106331101
10
IGHJ3
0.057
0.075
0.030
0.150
0.009
0.02210
0.00851
0.25752


79
chr16
30093723
30093923
5
PPP4C
0.034
0.023
0.050
0.050
0.000
0.02254
0.59983
0.95843


80
chr12
92537876
92539341
28
BTG1
0.058
0.057
0.059
0.074
0.012
0.02452
0.27041
0.12731


81
chr17
5366797
5366997
5
DHX33
0.022
0.010
0.040
0.025
0.000
0.02494
0.30467
0.19851


82
chr22
22697728
22698078
8
IGLV9-49
0.041
0.035
0.050
0.047
0.000
0.02532
0.32106
0.47874


83
chr22
23256363
23256463
3
IGLJS
0.059
0.082
0.025
0.042
0.000
0.02682
0.15950
0.08878


84
chr5
176522450
176522600
4
FGFR4
0.037
0.025
0.056
0.063
0.000
0.02722
0.79786
0.74613


85
chr13
113516230
113516430
5
ATP11A
0.050
0.069
0.020
0.113
0.000
0.02729
0.27017
0.10654


86
chr14
106331551
106331651
3
IGHJ1
0.046
0.033
0.067
0.104
0.029
0.02734
0.59010
0.16336


87
chr2
117951920
117952020
3
DDX18
0.033
0.055
0.000
0.063
0.000
0.02815
0.98381
0.97542


88
chr14
107210956
107211156
5
IGHV3-73
0.046
0.033
0.065
0.113
0.000
0.02872
0.30080
0.42892


89
chr12
6439714
6439914
5
TNFRSFIA
0.038
0.056
0.010
0.050
0.000
0.02933
0.46779
0.82988


90
chr2
136872526
136875621
28
CXCR4
0.105
0.101
0.113
0.100
0.025
0.03071
0.00337
0.00000


91
chr3
165548199
165548649
10
BCHE
0.012
0.008
0.018
0.081
0.000
0.03118
0.04749
0.00098


92
chr4
188924115
188924865
16
ZFP42
0.033
0.046
0.014
0.066
0.000
0.03190
0.74698
0.62135


93
chr20
25003527
25003727
5
ACSS1
0.032
0.049
0.005
0.138
0.000
0.03215
0.03660
0.87436


94
chr14
106994301
106994899
11
IGHV3-48
0.041
0.036
0.048
0.125
0.043
0.03245
0.00471
0.00001


95
chr16
3779107
3900912
82
CREBBP
0.035
0.043
0.022
0.070
0.001
0.03490
0.47515
0.61294


96
chr2
89544332
89544880
11
IGKV2-30
0.029
0.042
0.009
0.091
0.000
0.03816
0.14785
0.41409


97
chr5
112176757
112176957
5
APC
0.028
0.046
0.000
0.088
0.000
0.03821
0.23210
0.50694


98
chr3
185146279
185198274
20
MAP3K13
0.022
0.033
0.006
0.103
0.000
0.03855
0.00439
0.01617


99
chr11
129739779
129740079
7
NFRKB
0.037
0.030
0.046
0.054
0.000
0.03877
0.49619
0.72943


100
chr12
86198699
86199599
19
RASSF9
0.035
0.047
0.017
0.066
0.000
0.04167
0.79797
0.81991


101
chr12
15813488
15813638
4
EPS8
0.035
0.025
0.050
0.031
0.000
0.04189
0.24118
0.93977


102
chr2
63826278
63826428
4
MDH1
0.017
0.008
0.031
0.203
0.000
0.04203
0.00443
0.12932


103
chr14
107083566
107083891
7
IGHV4-59
0.040
0.054
0.018
0.179
0.043
0.04206
0.00035
0.00040


104
chr22
22735418
22735843
6
IGLV1-44
0.059
0.079
0.029
0.073
0.000
0.04311
0.62445
0.18113


105
chr12
18891268
18891518
6
CAPZA3
0.012
0.005
0.021
0.125
0.000
0.04368
0.00589
0.00868


106
chr14
106174971
106177526
44
IGHA1
0.117
0.117
0.116
0.125
0.027
0.04581
0.05495
0.00009


107
chr13
58207132
58209082
40
PCDH17
0.038
0.047
0.024
0.092
0.000
0.04705
0.03043
0.23893


108
chr6
26156650
26157350
15
HISTIHIE
0.064
0.077
0.045
0.008
0.000
0.04776
0.00000
0.00658


109
chr8
75898191
75898391
5
CRISPLD1
0.012
0.007
0.020
0.050
0.000
0.04779
0.61717
0.01894


110
chr9
37024920
37033770
38
PAX5
0.059
0.060
0.059
0.107
0.015
0.04840
0.84733
0.06185


111
chr17
18001530
18001680
4
DRG2
0.015
0.008
0.025
0.031
0.000
0.04924
0.70570
0.06008


112
chr10
91092212
91092412
5
IFIT3
0.026
0.016
0.040
0.050
0.000
0.05027
0.89626
0.41400


113
chr2
56149511
56150111
13
EFEMP1
0.030
0.029
0.031
0.115
0.000
0.05115
0.00217
0.49133


114
chr6
26032015
26032215
5
HIST1H3B
0.030
0.046
0.005
0.013
0.000
0.05360
0.05680
0.72269


115
chrX
1584325
1655990
29
P2RY8
0.031
0.041
0.016
0.093
0.001
0.05546
0.01173
0.29622


116
chr4
187509885
187557980
16
FAT1
0.028
0.039
0.013
0.094
0.000
0.05661
0.05492
0.36536


117
chr5
11110991
11411801
24
CTNND2
0.031
0.040
0.016
0.060
0.000
0.05690
0.95068
0.19315


118
chr14
106110676
106114376
65
IGHG2
0.213
0.210
0.217
0.147
0.049
0.05698
0.00000
0.00000


119
chr1
4472439
4476599
10
AJAP1
0.030
0.026
0.035
0.031
0.000
0.05889
0.10905
0.59078


120
chr1
110561142
110561742
13
AHCYL1
0.019
0.018
0.021
0.058
0.000
0.05908
0.58438
0.01312


121
chr14
106725296
106726174
14
IGHV3-23
0.099
0.111
0.080
0.027
0.000
0.05952
0.00000
0.00001


122
chr1
111715728
111715878
4
CEPTI
0.022
0.016
0.031
0.047
0.000
0.06085
0.91905
0.26127


123
chr11
118967324
118968024
15
DPAGT1
0.032
0.044
0.013
0.046
0.000
0.06151
0.19789
0.69126


124
chr2
55237199
55237599
9
RTN4
0.047
0.060
0.028
0.063
0.000
0.06231
0.41805
0.17702


125
chr11
111781037
111781637
13
CRYAB
0.025
0.037
0.008
0.082
0.000
0.06377
0.11838
0.14383


126
chr14
106573316
106574003
13
IGHV3-11
0.041
0.054
0.021
0.082
0.007
0.06792
0.84332
0.93964


127
chr18
48231685
48232085
9
MAPK4
0.022
0.020
0.025
0.021
0.000
0.07104
0.07945
0.10112


128
chr2
62934010
63217980
14
EHBP1
0.030
0.042
0.013
0.080
0.000
0.07190
0.51773
0.62080


129
chr22
22677078
22677289
5
IGLV1-51
0.046
0.066
0.015
0.113
0.000
0.07234
0.37625
0.20872


130
chr7
119915407
119915757
8
KCND2
0.038
0.053
0.016
0.039
0.000
0.07723
0.12619
0.48614


131
chr22
23154348
23154798
8
IGLV3-10
0.024
0.020
0.028
0.102
0.000
0.07866
0.03037
0.15798


132
chr6
26045745
26046045
7
HISTIH3C
0.030
0.026
0.036
0.045
0.019
0.08101
0.47189
0.03046


133
chr10
131640290
131640490
5
EBF3
0.040
0.036
0.045
0.100
0.000
0.08357
0.26942
0.76490


134
chr1
109822182
109822782
13
PSRC1
0.027
0.038
0.012
0.072
0.000
0.08367
0.51165
0.24502


135
chr17
18022120
18022770
14
MYO15A
0.039
0.036
0.043
0.085
0.000
0.08686
0.51095
0.37846


136
chr16
85933004
85954924
56
IRF8
0.037
0.047
0.024
0.065
0.012
0.08712
0.41154
0.04982


137
chr2
89986777
89987085
7
IGKV2D-29
0.024
0.021
0.029
0.045
0.000
0.09053
0.66530
0.22260


138
chr2
90249152
90249397
5
IGKVID-43
0.040
0.033
0.050
0.063
0.009
0.09076
0.87053
0.96927


139
chr2
242793233
242801088
24
PDCD1
0.047
0.048
0.046
0.083
0.000
0.09248
0.64737
0.01000


140
chr6
27100080
27100180
3
HISTIH2BJ
0.033
0.027
0.042
0.000
0.029
0.09735
0.05014
0.09524


141
chr7
110545277
110698122
8
IMMP2L
0.004
0.002
0.006
0.063
0.000
0.10148
0.15804
0.00010


142
chr1
111441723
111442173
10
CD53
0.027
0.038
0.010
0.100
0.000
0.10715
0.04221
0.30553


143
chrX
70612662
70612762
3
TAF1
0.007
0.000
0.017
0.063
0.000
0.10731
0.45417
0.02634


144
chr21
18981234
18981484
6
BTG3
0.020
0.033
0.000
0.073
0.000
0.10744
0.29340
0.11987


145
chr14
107113406
107114196
10
IGHV3-64
0.015
0.013
0.018
0.050
0.000
0.10843
0.80649
0.00490


146
chr22
22380473
22385883
18
IGLV4-69
0.044
0.054
0.029
0.073
0.000
0.10860
0.97247
0.18279


147
chr9
5510590
5570130
34
PDCDILG2
0.026
0.028
0.024
0.057
0.000
0.11075
0.98596
0.05983


148
chr1
27059147
27106912
29
ARIDIA
0.035
0.043
0.023
0.073
0.006
0.11182
0.58280
0.43378


149
chr13
32907207
32912827
17
BRCA2
0.013
0.013
0.013
0.088
0.000
0.11539
0.00502
0.00005


150
chr18
48703170
48703920
16
MEX3C
0.022
0.023
0.022
0.059
0.000
0.11749
0.74407
0.02655


151
chr1
203274698
203276558
33
BTG2
0.131
0.129
0.133
0.133
0.012
0.11791
0.01136
0.00000


152
chr8
128492948
128493298
8
POUSFIB
0.022
0.035
0.003
0.047
0.000
0.11971
0.87638
0.11243


153
chr6
27834969
27835069
3
HIST1H1B
0.043
0.038
0.050
0.042
0.000
0.12081
0.31080
0.40430


154
chr22
23010978
23011307
7
IGLV3-27
0.045
0.059
0.025
0.045
0.000
0.12123
0.15843
0.35845


155
chr1
117078643
117087128
10
CD58
0.022
0.021
0.023
0.025
0.000
0.12266
0.14627
0.06157


156
chr14
106380361
106381326
17
IGHD3-3
0.040
0.040
0.040
0.022
0.010
0.12443
0.00226
0.54240


157
chr12
49415992
49447447
47
KMT2D
0.029
0.031
0.026
0.097
0.000
0.12454
0.00102
0.09879


158
chr22
22782038
22782288
6
IGLV5-37
0.051
0.066
0.029
0.052
0.000
0.12900
0.22779
0.08945


159
chr8
18729446
18729896
10
PSD3
0.036
0.048
0.018
0.100
0.000
0.12911
0.49227
0.67922


160
chr14
106552366
106552466
3
IGHV3-9
0.020
0.011
0.033
0.063
0.000
0.12919
0.69275
0.24178


161
chrX
35820577
35821227
14
MAGEB16
0.021
0.032
0.005
0.080
0.000
0.13076
0.08392
0.03514


162
chr16
81946176
81962221
13
PLCG2
0.027
0.028
0.027
0.058
0.000
0.13686
0.98920
0.29436


163
chr22
22712078
22712594
11
IGLV1-47
0.050
0.063
0.032
0.108
0.000
0.13854
0.36497
0.04398


164
chr3
16419205
16419455
6
RFTN1
0.050
0.046
0.054
0.063
0.000
0.14045
0.43890
0.10024


165
chr11
111613197
111613397
5
PPP2R1B
0.026
0.039
0.005
0.000
0.000
0.14058
0.02490
0.46424


166
chr14
106331151
106331501
8
IGHJ2
0.048
0.047
0.050
0.102
0.027
0.14335
0.33135
0.15651


167
chr1
226923692
226925192
31
ITPKB
0.044
0.053
0.031
0.139
0.000
0.14412
0.00007
0.03739


168
chr6
27100940
27101260
5
HISTIH2AG
0.024
0.020
0.030
0.038
0.000
0.14525
0.54138
0.28737


169
chr10
91358987
91359287
7
PANK1
0.021
0.019
0.025
0.107
0.000
0.15224
0.01412
0.10864


170
chr14
32615406
32615606
5
ARHGAPS
0.020
0.033
0.000
0.100
0.000
0.15384
0.16273
0.16433


171
chrX
119509281
119509481
5
ATPIB4
0.016
0.013
0.020
0.088
0.000
0.15508
0.23890
0.07712


172
chr18
77794426
77795126
15
RBFA
0.014
0.014
0.013
0.075
0.000
0.15602
0.08296
0.00029


173
chr10
89624273
89720888
32
PTEN
0.015
0.016
0.013
0.023
0.000
0.15663
0.04633
0.00000


174
chr14
64330253
54330453
5
SYNE2
0.006
0.003
0.010
0.025
0.000
0.15837
0.74245
0.00357


175
chr9
24545400
24905695
17
IZUMO3
0.030
0.039
0.016
0.037
0.000
0.15955
0.10765
0.43759


176
chr5
54964699
54964899
5
SLC38A9
0.002
0.000
0.005
0.013
0.000
0.16320
0.46997
0.00144


177
chr8
101730377
101730427
2
PABPC1
0.015
0.008
0.025
0.000
0.000
0.16445
0.26379
0.18377


178
chr8
131373025
131373425
9
ASAP1
0.030
0.040
0.014
0.028
0.000
0.16655
0.08650
0.59884


179
chr22
23101393
23101730
6
IGLV2-14
0.048
0.044
0.054
0.073
0.022
0.16893
0.83695
0.56495


180
chr1
109649127
109649277
4
Clorf194
0.047
0.045
0.050
0.078
0.022
0.17014
0.88867
0.40591


181
chr11
65623423
65623473
2
CFL1
0.025
0.041
0.000
0.031
0.000
0.17060
0.58174
0.54924


182
chr22
22707428
22707793
7
IGLV5-48
0.035
0.047
0.018
0.071
0.000
0.17227
0.95304
0.82874


183
chr14
106331701
106331801
3
IGHD7-27
0.026
0.022
0.033
0.125
0.000
0.17412
0.05590
0.56584


184
chr14
96179593
96180293
15
TCLIA
0.050
0.050
0.050
0.071
0.000
0.17445
0.59106
0.01278


185
chr22
23063308
23063658
8
IGLV3-19
0.031
0.029
0.034
0.039
0.000
0.17496
0.31060
0.64225


186
chr17
7576950
7579410
24
TP53
0.040
0.051
0.023
0.107
0.000
0.17822
0.03641
0.51953


187
chr2
148680517
148680667
4
ACVR2A
0.025
0.037
0.006
0.031
0.000
0.18073
0.41320
0.38140


188
chr19
10334564
10341984
35
SIPR2
0.064
0.077
0.044
0.104
0.002
0.18105
0.40386
0.00014


189
chr6
108040229
108042204
27
SCML4
0.025
0.026
0.023
0.060
0.005
0.18315
0.54097
0.01195


190
chr6
27277285
27277485
5
POM121L2
0.042
0.039
0.045
0.050
0.000
0.18414
0.38135
0.41604


191
chr3
186714605
186784290
33
ST6GAL1
0.084
0.091
0.072
0.087
0.018
0.18556
0.01425
0.00007


192
chr19
12902575
12902825
6
JUNB
0.053
0.052
0.054
0.010
0.000
0.18604
0.00259
0.04452


193
chr14
107199021
107199172
4
IGHV3-72
0.045
0.041
0.050
0.000
0.000
0.18636
0.00860
0.27305


194
chr11
102188382
102188932
12
BIRC3
0.104
0.123
0.075
0.104
0.043
0.18760
0.23061
0.02703


195
chr1
185833556
186159096
32
HMCN1
0.021
0.023
0.018
0.074
0.000
0.18799
0.04332
0.00092


196
chr12
18534683
18801013
30
PIK3C2G
0.017
0.020
0.013
0.054
0.000
0.18947
0.52931
0.00001


197
chrX
100610985
100611285
7
BTK
0.021
0.021
0.021
0.116
0.000
0.18957
0.01363
0.10957


198
chr18
64172117
64239317
19
CDH19
0.023
0.032
0.009
0.072
0.002
0.19120
0.37384
0.02195


199
chr2
1652011
1652811
17
PXDN
0.045
0.054
0.031
0.092
0.000
0.19342
0.57240
0.03398


200
chr11
111904097
111904247
4
DLAT
0.037
0.049
0.019
0.016
0.000
0.19688
0.06546
0.70963


201
chr22
22556228
22556628
9
IGLV11-55
0.039
0.038
0.039
0.111
0.000
0.19910
0.04960
0.53925


202
chr2
103148734
103148934
5
SLC9A4
0.024
0.036
0.005
0.063
0.000
0.20039
0.78808
0.29891


203
chr2
48027959
48028159
5
MSH6
0.012
0.010
0.015
0.000
0.000
0.20189
0.09865
0.01894


204
chr4
134727699
134727899
5
PABPC4L
0.012
0.010
0.015
0.150
0.000
0.20189
0.02007
0.01894


205
chr11
134027790
134027940
4
NCAPD3
0.047
0.061
0.025
0.078
0.000
0.20429
0.99130
0.21830


206
chr2
77746603
77746953
8
LRRTM4
0.026
0.037
0.009
0.047
0.000
0.20711
0.60835
0.35208


207
chr1
160319284
160319484
5
NCSTN
0.044
0.039
0.050
0.025
0.000
0.21582
0.05416
0.28073


208
chr18
65179857
65181807
40
DSEL
0.021
0.029
0.009
0.073
0.000
0.21609
0.19591
0.00018


209
chr15
45003679
45008564
12
B2M
0.035
0.046
0.017
0.031
0.007
0.21616
0.04427
0.31773


210
chr1
29069532
29070182
14
YTHDF2
0.043
0.052
0.030
0.040
0.006
0.21620
0.03795
0.84925


211
chr4
80327793
80328143
8
GK2
0.030
0.041
0.013
0.117
0.000
0.21872
0.01766
0.70075


212
chr5
158527643
158527993
8
EBF1
0.052
0.064
0.034
0.055
0.000
0.22009
0.11870
0.13982


213
chr1
3747621
3747771
4
CEP104
0.025
0.037
0.006
0.109
0.000
0.22034
0.26105
0.39687


214
chr2
48059884
48066174
9
FBXO11
0.014
0.015
0.014
0.063
0.000
0.22199
0.44292
0.00401


215
chrX
33146107
33146457
8
DMD
0.059
0.059
0.059
0.359
0.082
0.22404
0.00000
0.00004


216
chr6
26124545
26124865
6
HIST1H2AC
0.051
0.063
0.033
0.010
0.000
0.22855
0.00394
0.11588


217
chr14
106791091
106791141
2
IGHV3-30
0.045
0.041
0.050
0.063
0.000
0.24046
0.72117
0.43844


218
chr3
183209759
183273414
23
KLHL6
0.036
0.036
0.036
0.052
0.006
0.24437
0.12177
0.41139


219
chr17
79478954
79479004
2
ACTG1
0.005
0.000
0.013
0.125
0.043
0.24604
0.05674
0.01689


220
chr22
47570210
47570410
5
TBCID22A
0.030
0.043
0.010
0.175
0.000
0.24818
0.00334
0.70762


221
chr6
27799169
27799369
5
HISTIH4K
0.022
0.033
0.005
0.038
0.000
0.24870
0.54640
0.19851


222
chr2
65258146
65258346
5
SLC1A4
0.018
0.030
0.000
0.050
0.000
0.25016
0.78384
0.08170


223
chr14
106586201
106586301
3
IGHV3-13
0.033
0.027
0.042
0.021
0.000
0.25073
0.17545
0.97542


224
chr6
26158530
26158790
4
HISTIH2BD
0.030
0.041
0.013
0.016
0.000
0.25147
0.13295
0.69509


225
chr14
106691756
106691856
3
IGHV3-21
0.053
0.066
0.033
0.042
0.000
0.25208
0.23957
0.18828


226
chr10
90579967
90580317
8
LIPM
0.035
0.035
0.034
0.047
0.000
0.25854
0.32941
0.85606


227
chr7
82387831
82784641
19
PCLO
0.035
0.044
0.022
0.049
0.000
0.25896
0.17138
0.85294


228
chr22
23090123
23090338
4
IGLV3-16
0.030
0.041
0.013
0.063
0.065
0.26082
0.88005
0.00186


229
chr2
89475782
89476114
7
IGKV2-24
0.044
0.042
0.046
0.125
0.000
0.26354
0.03650
0.25182


230
chr2
90121892
90122155
6
IGKVID-17
0.030
0.041
0.013
0.083
0.000
0.26708
0.50393
0.47148


231
chr14
107034666
107035056
7
IGHV5-51
0.038
0.049
0.021
0.071
0.000
0.26981
0.83901
0.54622


232
chr6
26217215
26217415
5
HISTIHLAE
0.024
0.023
0.025
0.038
0.000
0.26983
0.53539
0.29891


233
chr14
84420587
84420787
5
FLRT2
0.000
0.000
0.000
0.025
0.000
0.27098
0.90753
0.00089


234
chr4
40198811
40201559
49
RHOH
0.062
0.068
0.053
0.028
0.015
0.27123
0.00000
0.12156


235
chr14
106539176
106539276
3
IGHV1-8
0.040
0.038
0.042
0.063
0.000
0.27246
0.79783
0.70059


236
chr5
83258968
83259168
5
EDIL3
0.022
0.033
0.005
0.063
0.000
0.27662
0.67082
0.19851


237
chrX
70347817
70348017
5
MED12
0.022
0.033
0.005
0.075
0.000
0.27662
0.38460
0.19851


238
chr18
48512955
48513305
8
ELAC1
0.026
0.027
0.025
0.102
0.000
0.27685
0.05340
0.35208


239
chrX
12993265
12994487
23
TMSB4X
0.098
0.108
0.083
0.177
0.057
0.27705
0.03023
0.53439


240
chr19
6586162
6591037
17
CD70
0.052
0.064
0.035
0.121
0.000
0.27742
0.02768
0.05558


241
chr9
13222186
13222386
5
MPDZ
0.018
0.016
0.020
0.050
0.000
0.27845
0.92556
0.10149


242
chr19
8028409
8028559
4
ELAVL1
0.037
0.049
0.019
0.094
0.000
0.28231
0.39328
0.68881


243
chr17
63010241
63052644
28
GNA13
0.033
0.035
0.029
0.051
0.005
0.29192
0.20921
0.55174


244
chr6
75965847
75969257
10
TMEM30A
0.017
0.018
0.015
0.063
0.000
0.29877
0.61973
0.01289


245
chr2
61118795
61149620
27
REL
0.024
0.030
0.014
0.053
0.006
0.29909
0.79282
0.00093


246
chr8
103663492
103664142
14
KLF10
0.032
0.034
0.029
0.103
0.000
0.29943
0.04753
0.77217


247
chr7
122634906
122635106
5
TAS2R16
0.040
0.036
0.045
0.050
0.000
0.30121
0.42497
0.50451


248
chr7
106508491
106509141
14
PIK3CG
0.043
0.044
0.04]
0.058
0.000
0.30584
0.28865
0.12742


249
chr19
1376441
1376641
5
MUM1
0.053
0.066
0.035
0.063
0.000
0.30591
0.40617
0.10207


250
chr10
90074240
90074390
4
RNLS
0.012
0.012
0.013
0.141
0.000
0.30697
0.04146
0.05611


251
chr17
56408575
56409585
19
BZRAP1
0.107
0.116
0.095
0.122
0.050
0.31066
0.24386
0.00835


252
chr18
48327695
48327895
5
MRO
0.034
0.033
0.035
0.088
0.000
0.32051
0.36874
0.94107


253
chr2
90212017
90212247
4
IGKV3D-11
0.000
0.000
0.000
0.063
0.000
0.32488
0.18259
0.00295


254
chr3
164730701
164730851
4
SI
0.000
0.000
0.000
0.031
0.000
0.32488
0.89232
0.00295


255
chr18
75683735
75684485
16
GALRI
0.025
0.026
0.023
0.055
0.000
0.32688
0.88862
0.08570


256
chr10
90699127
90699627
11
ACTA2
0.022
0.030
0.009
0.074
0.000
0.32826
0.22549
0.05225


257
chr7
146997184
146997384
5
CNTNAP2
0.020
0.030
0.005
0.063
0.000
0.33654
0.72508
0.12531


258
chr10
90537737
90537987
6
LIPN
0.021
0.022
0.021
0.063
0.000
0.33950
0.63054
0.15262


259
chr8
116616146
116616846
15
TRPS1
0.033
0.042
0.020
0.088
0.000
0.34027
0.10857
0.96046


260
chro
14117993
14135468
27
CD83
0.061
0.069
0.049
0.146
0.006
0.34145
0.00006
0.25221


261
chr14
106610381
106610741
6
IGHV3-15
0.036
0.046
0.021
0.042
0.000
0.34253
0.25513
0.68243


262
chr14
106962966
106963269
7
IGHV1-45
0.023
0.023
0.021
0.036
0.000
0.34439
0.45188
0.16111


263
chr6
27833409
27833509
3
HISTIH2AL
0.017
0.027
0.000
0.042
0.000
0.34503
0.82367
0.13637


264
chr7
2963819
2987364
44
CARD11
0.047
0.055
0.035
0.075
0.000
0.34677
0.68708
0.00272


265
chr11
134118685
134118835
4
THYN1
0.017
0.016
0.019
0.094
0.000
0.35301
0.26225
0.10870


266
chr14
107258911
107282996
17
IGHV7-81
0.031
0.040
0.019
0.088
0.026
0.35469
0.15903
0.00002


267
chrX
73962124
73963074
20
KIAA2022
0.020
0.028
0.009
0.103
0.000
0.35514
0.00284
0.00632


268
chr3
185236909
185237109
5
LIPH
0.022
0.033
0.005
0.038
0.000
0.35786
0.57454
0.20093


269
chr3
64547205
64580090
11
ADAMTS9
0.028
0.030
0.025
0.091
0.000
0.35888
0.08153
0.38328


270
chr14
106405616
106405916
7
IGHV6-1
0.028
0.037
0.014
0.098
0.000
0.36129
0.28061
0.53891


271
chr11
117712684
117712984
7
FXYD6
0.035
0.035
0.036
0.045
0.000
0.36200
0.39501
0.93264


272
chr8
130692150
130760995
17
GSDMC
0.029
0.037
0.018
0.051
0.000
0.36490
0.59248
0.38946


273
chr22
22749603
22750309
14
IGLV7-43
0.021
0.022
0.018
0.067
0.000
0.36721
0.26604
0.01881


274
chr22
23135153
23135508
7
IGLV2-11
0.020
0.021
0.018
0.098
0.000
0.36740
0.03964
0.07222


275
chr6
26234655
26234955
7
HISTIHID
0.042
0.044
0.039
0.018
0.000
0.36781
0.01092
0.23508


276
chr11
112405017
112405578
12
Cllorf34
0.029
0.037
0.017
0.099
0.000
0.36795
0.03866
0.51208


277
chr1
2488007
2494707
36
TNFRSF14
0.035
0.042
0.024
0.082
0.000
0.37037
0.15033
0.73903


278
chr18
48591760
48604805
16
SMAD4
0.019
0.020
0.016
0.035
0.000
0.37088
0.36837
0.00422


279
chr18
55274406
55274556
4
NARS
0.015
0.025
0.000
0.047
0.000
0.37631
0.84014
0.07298


280
chrX
90026454
90026604
4
PABPCS
0.015
0.025
0.000
0.031
0.000
0.37790
0.70713
0.06008


281
chr8
623881
624081
5
ERICH1
0.020
0.020
0.020
0.025
0.000
0.38591
0.34374
0.13521


282
chr18
1477566
1477666
3
ADCYAP1
0.043
0.055
0.025
0.000
0.000
0.38723
0.02764
0.48180


283
chr12
48190732
48190982
6
HDAC7
0.043
0.041
0.046
0.021
0.000
0.38786
0.03107
0.34087


284
chr14
106381486
106383981
18
IGHD2-2
0.029
0.032
0.025
0.059
0.024
0.39142
0.82914
0.00001


285
chr5
135381970
135382170
5
TGFB1
0.034
0.030
0.040
0.038
0.000
0.39274
0.28309
0.98151


286
chr3
184580664
184580864
5
VPS8
0.006
0.007
0.005
0.075
0.000
0.40112
0.15248
0.00357


287
chr14
106805291
106806190
8
IGHV4-31
0.038
0.041
0.034
0.117
0.000
0.40201
0.02655
0.49158


288
chr22
23077338
23077588
4
IGLV2-18
0.025
0.025
0.025
0.063
0.000
0.40450
0.82223
0.42774


289
chr11
134129470
134133940
40
ACAD8
0.027
0.034
0.016
0.063
0.000
0.40456
0.61602
0.02024


290
chr1
190067140
190068190
22
FAM5C
0.028
0.035
0.017
0.077
0.000
0.40678
0.18209
0.12955


291
chr19
52403337
52403537
5
ZNF649
0.026
0.026
0.025
0.075
0.000
0.41027
0.52307
0.41005


292
chr15
66727355
66729281
10
MAP2K1
0.035
0.044
0.020
0.069
0.000
0.41169
0.93852
0.81159


293
chr6
94120220
94120720
11
EPHA7
0.024
0.027
0.020
0.119
0.000
0.41348
0.00251
0.10186


294
chr20
23028373
23028823
10
THBD
0.044
0.052
0.030
0.075
0.009
0.41401
0.97196
0.91852


295
chr19
42599891
42600091
5
POU2F2
0.038
0.049
0.020
0.125
0.000
0.41703
0.03149
0.68257


296
chrX
86772954
86773304
8
KLHL4
0.026
0.035
0.013
0.086
0.000
0.41822
0.64743
0.29530


297
chr9
37407370
37407570
5
GRHPR
0.046
0.056
0.030
0.113
0.000
0.42725
0.84925
0.34749


298
chry
20820917
20946827
8
FOCAD
0.015
0.016
0.013
0.078
0.000
0.43273
0.41122
0.00842


299
chr6
91004619
91005994
10
BACH2
0.051
0.061
0.038
0.100
0.017
0.43292
0.62927
0.61655


300
chr9
139390583
139402863
17
NOTCH1
0.038
0.045
0.028
0.140
0.000
0.44217
0.00038
0.66264


301
chr14
106452661
106453001
7
IGHV1-2
0.020
0.021
0.018
0.080
0.000
0.44604
0.33603
0.09047


302
chr6
26020710
26020910
5
HISTIH3A
0.036
0.036
0.035
0.000
0.000
0.44876
0.01256
0.96541


303
chr9
27950145
27950495
8
LINGO2
0.022
0.031
0.009
0.117
0.000
0.45177
0.00957
0.11783


304
chr7
80285800
80286050
6
CD36
0.013
0.022
0.000
0.135
0.000
0.45506
0.00452
0.01644


305
chr18
13825916
13826416
11
MC5R
0.035
0.043
0.023
0.085
0.000
0.45807
0.35320
0.85391


306
chr9
5450475
5468015
33
CD274
0.026
0.029
0.020
0.049
0.000
0.46045
0.38390
0.02293


307
chr3
185446224
185538924
8
IGF2BP2
0.019
0.027
0.006
0.102
0.000
0.47564
0.05373
0.03579


308
chr1
3800046
3800353
7
DFFB
0.042
0.044
0.039
0.107
0.000
0.47590
0.23069
0.43666


309
chr22
23055368
23055828
7
IGLV3-21
0.034
0.035
0.032
0.107
0.000
0.47614
0.19555
0.90440


310
chr6
27114005
27114545
9
HISTIH2BK
0.023
0.031
0.011
0.021
0.000
0.48388
0.09402
0.14560


311
chr14
107013036
107013186
4
IGHV3-49
0.020
0.029
0.006
0.109
0.000
0.48557
0.05983
0.17265


312
chr22
22453288
22453563
6
IGLV8-61
0.053
0.055
0.050
0.083
0.000
0.48567
0.96231
0.04559


313
chr14
106357891
106357941
2
IGHD6-19
0.000
0.000
0.000
0.000
0.000
0.48646
0.45288
0.03556


314
chr16
33523608
33523658
2
IGHV3OR16-12
0.000
0.000
0.000
0.125
0.022
0.48646
0.05020
0.02436


315
chr7
151943422
151943472
2
KMT2C
0.000
0.000
0.000
0.125
0.000
0.48646
0.10655
0.03556


316
chr22
23114793
23115048
5
IGLV3-12
0.018
0.026
0.005
0.000
0.000
0.49420
0.05467
0.09497


317
chr2
80801236
80801486
6
CINNA2
0.017
0.025
0.004
0.146
0.000
0.50036
0.00472
0.03774


318
chr22
23161918
23162288
8
IGLV3-9
0.036
0.039
0.031
0.063
0.000
0.50251
0.65174
0.76665


319
chr12
113495365
113534745
80
DTX1
0.058
0.065
0.047
0.075
0.000
0.50409
0.06246
0.00000


320
chr1]
65190343
65190543
5
FRMD8
0.050
0.049
0.050
0.038
0.009
0.51163
0.10472
0.60740


321
chr14
106967131
106967366
4
IGHV1-46
0.022
0.033
0.006
0.063
0.000
0.51321
0.66087
0.32094


322
chr12
25205889
25207439
21
LRMP
0.038
0.041
0.033
0.080
0.027
0.51555
0.36573
0.00948


323
chr14
106780611
106780711
3
IGHV4-28
0.036
0.038
0.033
0.125
0.000
0.51984
0.19368
0.92185


324
chr11
125472641
125472891
6
STT3A
0.046
0.055
0.033
0.052
0.000
0.52125
0.24640
0.20117


325
chr11
69346692
69346892
5
CCND1
0.024
0.026
0.020
0.113
0.000
0.52233
0.04449
0.30659


326
chr13
51915234
51915534
7
SERPINE3
0.035
0.044
0.021
0.152
0.000
0.53028
0.03239
0.74664


327
chr5
21783416
21783666
6
CDH12
0.020
0.022
0.017
0.083
0.000
0.53207
0.16100
0.13344


328
chr12
25398219
25398269
2
KRAS
0.015
0.025
0.000
0.000
0.000
0.53308
0.26379
0.18377


329
chr1
85733208
85742033
19
BCL10
0.021
0.025
0.016
0.056
0.000
0.53493
0.60987
0.00831


330
chr1
107866872
107867572
15
NING1
0.013
0.015
0.010
0.063
0.000
0.53686
0.17297
0.00018


331
chr1
86591438
86591888
10
COL24A1
0.029
0.036
0.018
0.075
0.000
0.53874
0.54478
0.46033


332
chr18
30349776
30350276
11
KLHL14
0.033
0.036
0.030
0.091
0.000
0.53960
0.49213
0.94697


333
chr14
106641656
106642261
7
IGHV1-18
0.023
0.026
0.018
0.063
0.019
0.54851
0.55397
0.01550


334
chr17
78343504
78343704
5
RNF213
0.014
0.016
0.010
0.038
0.000
0.54949
0.86764
0.04664


335
chr1
120457961
120459261
27
NOTCH2
0.036
0.039
0.031
0.053
0.000
0.55999
0.22789
0.63380


336
chr17
40467710
40491485
39
STAT3
0.034
0.040
0.023
0.059
0.000
0.56418
0.51376
0.71754


337
chr9
19957357
19958157
17
SLC24A2
0.027
0.031
0.022
0.063
0.000
0.56498
0.75617
0.22788


338
chr3
38180130
38182805
29
MYD88
0.045
0.053
0.033
0.073
0.000
0.56578
0.70668
0.03867


339
chr18
73944894
73945344
10
ZNF516
0.018
0.025
0.008
0.056
0.000
0.56926
0.67544
0.01359


340
chr7
140453013
140453254
5
BRAF
0.012
0.020
0.000
0.075
0.000
0.56966
0.30182
0.01894


341
chr6
159238416
159238766
8
EZR
0.050
0.057
0.038
0.016
0.000
0.57311
0.00246
0.08463


342
chr18
77092821
77093021
5
ATP9B
0.008
0.010
0.005
0.075
0.000
0.57396
0.16232
0.00549


343
chr22
23523568
23610748
22
BCR
0.038
0.045
0.028
0.097
0.000
0.57399
0.04814
0.27043


344
chr22
22673243
22673593
8
IGLV5-52
0.027
0.035
0.016
0.117
0.000
0.57479
0.00701
0.30927


345
chr4
88011078
88011278
5
AFF1
0.014
0.016
0.010
0.038
0.000
0.57733
0.89980
0.03303


346
chr11
131747550
131748000
9
NTM
0.029
0.036
0.018
0.119
0.000
0.57801
0.02773
0.42832


347
chr2
90077982
90078316
6
IGKV3D-20
0.025
0.033
0.013
0.031
0.000
0.57996
0.26904
0.32350


348
chr2
96809890
96810360
10
DUSP2
0.063
0.066
0.060
0.006
0.000
0.58190
0.00002
0.00216


349
chr2
89265757
89265987
4
IGKV1-6
0.010
0.012
0.006
0.047
0.000
0.59812
0.84325
0.02299


350
chr19
53598587
53599037
10
ZNF160
0.024
0.031
0.013
0.063
0.000
0.60291
0.98122
0.12855


351
chr2
63335243
63631808
22
WDPCP
0.026
0.033
0.016
0.091
0.000
0.60661
0.01199
0.09457


352
chr9
21808815
21859450
9
MTAP
0.019
0.026
0.008
0.042
0.000
0.61688
0.80480
0.03120


353
chr6
27860480
27860895
7
HISTIH2AM
0.030
0.033
0.025
0.045
0.000
0.61920
0.45404
0.60865


354
chr6
27839659
27839759
3
HISTIH31
0.036
0.038
0.033
0.021
0.000
0.62267
0.15955
0.75106


355
chr6
26252155
26252205
2
HISTIH2BH
0.015
0.016
0.013
0.063
0.000
0.62577
0.55784
0.18377


356
chr19
19256470
19293460
41
MEF2B
0.040
0.045
0.032
0.091
0.000
0.62683
0.04274
0.29098


357
chr14
107169646
107170861
21
IGHV1-69
0.091
0.098
0.082
0.107
0.029
0.63032
0.38178
0.00266


358
chr8
113308015
113569195
15
CSMD3
0.013
0.020
0.003
0.046
0.000
0.63047
0.85436
0.00010


359
chr22
22550338
22550788
10
IGLV6-57
0.042
0.049
0.030
0.131
0.017
0.64049
0.04005
0.29687


360
chr4
153249286
153249486
5
FBXW7
0.026
0.026
0.025
0.038
0.000
0.64551
0.50853
0.39977


361
chr11
120127164
120189629
22
POU2F3
0.027
0.033
0.018
0.091
0.000
0.64824
0.02013
0.09628


362
chr12
57496553
57499113
13
STAT6
0.046
0.054
0.035
0.072
0.013
0.65115
0.71967
0.94722


363
chr22
22937193
22937499
7
IGLV3-32
0.018
0.026
0.007
0.063
0.000
0.65348
0.49810
0.05644


364
chr6
138188484
138202489
64
TNFAIP3
0.024
0.028
0.018
0.035
0.004
0.65552
0.00591
0.00002


365
chr8
138849938
138850138
5
FAM135B
0.020
0.023
0.015
0.038
0.000
0.65643
0.70665
0.12531


366
chr14
107218756
107218856
3
IGHV3-74
0.073
0.082
0.058
0.104
0.058
0.66142
0.98960
0.26299


367
chr14
23344698
23345198
11
LRP10
0.059
0.063
0.052
0.034
0.000
0.66215
0.00576
0.01137


368
chr14
106866381
106866595
5
IGHV3-38
0.032
0.033
0.030
0.163
0.000
0.66584
0.01626
0.86538


369
chr1
3547351
3547701
8
WRAP73
0.024
0.027
0.019
0.063
0.000
0.66789
0.68610
0.19690


370
chr21
28213259
28216964
11
ADAMTS1
0.028
0.036
0.016
0.108
0.012
0.67094
0.03930
0.06299


371
chr2
169781121
169781321
5
ABCB11
0.016
0.023
0.005
0.125
0.000
0.67664
0.00990
0.06041


372
chr22
41513341
41574886
72
EP300
0.031
0.037
0.022
0.067
0.000
0.67996
0.51033
0.09373


373
chr18
56054916
56063816
24
NEDD4L
0.016
0.020
0.009
0.031
0.000
0.68133
0.24138
0.00003


374
chr14
106845301
106846536
9
IGHV3-35
0.055
0.064
0.042
0.097
0.000
0.68499
0.76566
0.05591


375
chr14
107136756
107136856
3
IGHV3-66
0.030
0.038
0.017
0.021
0.000
0.68512
0.22171
0.79848


376
chr22
23047068
23047318
6
IGLV3-22
0.043
0.049
0.033
0.042
0.014
0.68905
0.16524
0.80319


377
chr22
22786478
22786803
7
IGLV1-36
0.040
0.047
0.029
0.080
0.000
0.69080
0.82010
0.41665


378
chr8
122626848
122627148
7
HAS2
0.030
0.033
0.025
0.063
0.000
0.70243
0.90117
0.66520


379
chrs
131825018
131825218
5
IRF1
0.026
0.030
0.020
0.138
0.000
0.70868
0.00725
0.42851


380
chr22
23252688
23252788
3
IGLJ4
0.020
0.022
0.017
0.021
0.000
0.71377
0.39782
0.24178


381
chr14
107078456
107078606
4
IGHV1-58
0.050
0.053
0.044
0.063
0.000
0.71737
0.53128
0.17192


382
chr4
154624671
154625021
8
TLR2
0.017
0.020
0.013
0.125
0.000
0.72168
0.00257
0.03397


383
chr2
89196227
89215037
19
IGKV5-2
0.024
0.028
0.017
0.036
0.007
0.73228
0.12196
0.02080


384
chr18
55319681
55359256
17
ATP8B1
0.028
0.031
0.024
0.044
0.000
0.73256
0.29761
0.29755


385
chr1
61553803
61554303
11
NFIA
0.030
0.033
0.025
0.097
0.000
0.73331
0.11994
0.58902


386
chr10
89603603
89604053
10
KLLN
0.024
0.028
0.018
0.044
0.000
0.73666
0.57207
0.12653


387
chr22
23247138
23247609
9
IGLJ3
0.165
0.169
0.158
0.153
0.048
0.73794
0.02871
0.00093


388
chr11
117101044
117101194
4
PCSK7
0.042
0.049
0.031
0.016
0.000
0.73868
0.05815
0.47968


389
chr6
27861245
27861450
4
HISTIH2BO
0.037
0.045
0.025
0.031
0.000
0.74033
0.21815
0.85767


390
chr2
61441170
61441870
15
USP34
0.025
0.028
0.020
0.042
0.000
0.74279
0.23146
0.11749


391
chr11
111234537
111249512
16
POU2AF1
0.030
0.034
0.023
0.105
0.008
0.74326
0.02352
0.08875


392
chr5
5182146
5182446
7
ADAMTS16
0.038
0.044
0.029
0.107
0.000
0.75162
0.19189
0.54007


393
chr14
106667546
106667856
6
IGHV3-20
0.021
0.025
0.017
0.063
0.000
0.75404
0.64784
0.15262


394
chr2
145162402
145693052
53
ZEB2
0.041
0.046
0.032
0.048
0.008
0.76200
0.00643
0.47223


395
chr14
106494091
106494768
12
IGHV2-5
0.027
0.034
0.017
0.063
0.014
0.76623
0.78849
0.01259


396
chr2
65593036
65593213
4
SPRED2
0.057
0.061
0.050
0.250
0.033
0.77068
0.00195
0.40243


397
chr2
141245128
141245328
5
LRPIB
0.010
0.016
0.000
0.088
0.000
0.77497
0.10161
0.00830


398
chr22
23241763
23241813
2
IGLJ2
0.030
0.033
0.025
0.094
0.000
0.77602
0.38252
0.80404


399
chrX
153997384
153997584
5
DKC1
0.042
0.046
0.035
0.075
0.000
0.77946
0.93861
0.49207


400
chr10
5755067
5755267
5
FAM208B
0.016
0.020
0.010
0.000
0.000
0.77955
0.06988
0.04606


401
chr1
35472493
35472693
5
ZMYM6
0.016
0.020
0.010
0.025
0.000
0.77955
0.46246
0.04606


402
chr6
26250460
26250695
5
HISTIH3F
0.028
0.033
0.020
0.013
0.000
0.78052
0.07461
0.50252


403
chr3
176750700
176771710
17
TBLIXR1
0.020
0.024
0.013
0.051
0.003
0.78556
0.88935
0.00559


404
chr18
77170716
77288591
29
NFATC1
0.038
0.043
0.031
0.082
0.000
0.78831
0.61891
0.47180


405
chr13
41133663
41240784
49
FOXO1
0.025
0.031
0.016
0.042
0.000
0.78900
0.09626
0.00465


406
chr8
128951725
128951875
4
TMEM75
0.042
0.049
0.031
0.016
0.000
0.78980
0.05059
0.43332


407
chr22
22681928
22682198
5
IGLV1-50
0.020
0.026
0.010
0.088
0.000
0.79643
0.39142
0.12531


408
chr2
89976277
89976377
3
IGKV2D-30
0.066
0.071
0.058
0.125
0.000
0.79654
0.28677
0.06295


409
chr14
106757726
106758621
8
IGHV2-26
0.026
0.033
0.016
0.039
0.000
0.80101
0.48691
0.27328


410
chr1
2306312
2306812
11
MORN1
0.028
0.034
0.018
0.102
0.000
0.80151
0.03618
0.25568


411
chr14
106384031
106384926
9
IGHD1-1
0.039
0.046
0.028
0.132
0.024
0.81269
0.00673
0.00968


412
chr8
104897562
104898462
19
RIMS2
0.030
0.036
0.021
0.099
0.000
0.81294
0.04875
0.36772


413
chr10
89500958
89501108
4
PAPSS2
0.025
0.029
0.019
0.047
0.000
0.81562
0.75051
0.38140


414
chr1
201038553
201038753
5
CACNAIS
0.034
0.033
0.035
0.113
0.000
0.82537
0.08167
0.99310


415
chr13
84453543
84455243
35
SLITRK1
0.034
0.039
0.026
0.073
0.000
0.82863
0.60871
0.95353


416
chr22
23263508
23264123
9
IGLJ7
0.062
0.069
0.050
0.042
0.000
0.84212
0.02446
0.00290


417
chr5
140208034
140208834
17
PCDHA6
0.026
0.031
0.019
0.051
0.000
0.84499
0.73711
0.13168


418
chr1
23885408
23885899
10
ID3
0.015
0.020
0.008
0.081
0.000
0.84648
0.06666
0.00452


419
chr14
106518496
106519064
7
IGHV3-7
0.035
0.040
0.029
0.054
0.000
0.84779
0.54879
0.79096


420
chr9
22005930
22009000
13
CDKN2B
0.031
0.035
0.025
0.038
0.000
0.85460
0.20627
0.52500


421
chr11
58978693
58979345
11
MPEG1
0.032
0.036
0.025
0.080
0.000
0.85627
0.50475
0.70735


422
chr1
227842647
227842697
2
ZNF678
0.010
0.016
0.000
0.156
0.000
0.85664
0.04034
0.09510


423
chr6
106534267
106555367
60
PRDM1
0.031
0.036
0.023
0.065
0.000
0.86083
0.99103
0.15072


424
chr2
198950435
198950985
12
PLCL1
0.021
0.027
0.013
0.094
0.000
0.86126
0.14473
0.05072


425
chr18
6947105
6980665
1
LAMA1
0.027
0.033
0.018
0.094
0.000
0.86312
0.22629
0.28027


426
chr6
26197105
26197462
8
HISTIH3D
0.021
0.027
0.013
0.000
0.000
0.86864
0.00995
0.09168


427
chr19
51525627
51525927
7
KLK11
0.028
0.033
0.021
0.089
0.000
0.87219
0.14799
0.45199


428
chr2
61719435
61719635
5
XPO1
0.012
0.016
0.005
0.000
0.000
0.87795
0.09496
0.02531


429
chrX
141291053
141291534
10
MAGEC2
0.019
0.023
0.013
0.081
0.000
0.88059
0.07959
0.02755


430
chr14
35873672
35873822
4
NFKBIA
0.035
0.041
0.025
0.000
0.000
0.88119
0.02331
0.96205


431
chr2
89442292
89443217
19
IGKV3-20
0.042
0.047
0.036
0.148
0.050
0.88608
0.00002
0.00006


432
chr1
72334892
72335098
5
NEGR1
0.014
0.020
0.005
0.025
0.000
0.88638
0.51822
0.02712


433
chr1
9784433
9784533
3
PIK3CD
0.007
0.011
0.000
0.083
0.000
0.89151
0.14993
0.02634


434
chr2
170101186
170101386
5
LRP2
0.032
0.036
0.025
0.100
0.000
0.89564
0.18901
0.76737


435
chr7
110737412
110764944
61
LRRN3
0.019
0.024
0.011
0.086
0.002
0.90183
0.00080
0.00000


436
chr3
7620224
7620974
16
GRM7
0.032
0.038
0.023
0.078
0.000
0.90333
0.28646
0.77891


437
chr22
22569333
22569633
7
IGLV10-54
0.031
0.037
0.021
0.063
0.000
0.90702
0.86839
0.77523


438
chr17
75447869
75448419
12
9-Sep
0.03]
0.037
0.021
0.036
0.000
0.90976
0.14194
0.64487


439
chr7
148506319
148523734
19
EZH2
0.019
0.025
0.011
0.082
0.000
0.91143
0.05741
0.00268


440
chr14
106621886
106622095
5
IGHV3-16
0.024
0.030
0.015
0.063
0.000
0.91521
0.67996
0.28737


441
chr1
181452915
181453115
5
CACNAIE
0.032
0.036
0.025
0.025
0.000
0.91767
0.14135
0.76209


442
chr2
58520801
58521201
9
FANCL
0.029
0.035
0.019
0.069
0.000
0.92005
0.73186
0.57669


443
chr19
51559442
51561922
16
KLK13
0.032
0.038
0.023
0.113
0.000
0.92076
0.04033
0.89701


444
chr16
2812097
2812747
14
SRRM2
0.056
0.062
0.046
0.045
0.000
0.92192
0.02154
0.01164


445
chro
41903612
41909397
26
CCND3
0.041
0.047
0.033
0.058
0.000
0.92504
0.14949
0.21095


446
chr14
106068706
106071241
16
IGHE
0.118
0.124
0.108
0.215
0.158
0.92648
0.00059
0.00000


447
chr6
110777719
110778219
11
SLC22A16
0.027
0.033
0.018
0.034
0.000
0.92796
0.19315
0.23193


448
chr9
21970835
21994385
37
CDKN2A
0.027
0.031
0.020
0.039
0.000
0.92888
0.04082
0.03393


449
chr2
90025207
90025522
6
IGKV2D-26
0.012
0.016
0.004
0.031
0.000
0.92990
0.73921
0.01161


450
chr4
7728457
7728657
5
SORCS2
0.034
0.039
0.025
0.038
0.000
0.93035
0.30875
0.99310


451
chr?
5569096
5569356
6
ACTB
0.048
0.055
0.038
0.208
0.007
0.93481
0.00069
0.95055


452
chr3
140281599
140281849
6
CLSTN2
0.036
0.038
0.033
0.031
0.000
0.94099
0.11813
0.72422


453
chr2
89291907
89292182
4
IGKV1-8
0.020
0.025
0.013
0.047
0.022
0.94155
0.86146
0.00511


454
chr22
23260268
23260368
3
IGLJ6
0.043
0.049
0.033
0.063
0.000
0.94574
0.74604
0.48180


455
chr14
106815806
106815906
3
IGHV3-33
0.059
0.066
0.050
0.063
0.043
0.94598
0.41907
0.10857


456
chr6
26123615
26124080
9
HIST1H2BC
0.031
0.036
0.022
0.028
0.000
0.95616
0.07091
0.75304


457
chr3
49397609
49413039
18
RHOA
0.030
0.035
0.022
0.045
0.000
0.95622
0.26281
0.40030


458
chr22
29191137
29196512
28
XBPI
0.032
0.039
0.022
0.085
0.003
0.95630
0.05799
0.16891


459
chr14
106471396
106471580
4
IGHV1-3
0.007
0.012
0.000
0.141
0.000
0.95914
0.00935
0.01524


460
chr17
41847059
41847209
4
DUSP3
0.032
0.037
0.025
0.094
0.000
0.96078
0.74050
0.94029


461
chr17
51900442
51900892
10
KIF2B
0.035
0.039
0.028
0.088
0.000
0.96080
0.24029
0.71768


462
chr15
86312063
86312563
11
KLHL25
0.032
0.037
0.025
0.074
0.000
0.96521
0.83987
0.74482


463
chr18
53804516
53804766
6
TXNL1
0.036
0.041
0.029
0.115
0.000
0.96529
0.05667
0.84317


464
chr5
67590967
67591167
5
PIK3R1
0.018
0.023
0.010
0.075
0.009
0.97792
0.39415
0.02207


465
chr5
124079828
124080678
18
ZNF608
0.026
0.031
0.019
0.063
0.000
0.98245
0.74836
0.14794


466
chr2
90259932
90260232
5
IGKVID-8
0.034
0.039
0.025
0.163
0.000
0.98690
0.17514
0.96394


467
chr2
88906682
88906832
4
EIF2AK3
0.059
0.066
0.050
0.063
0.000
0.98750
0.34568
0.07429


468
chr4
106157605
106157805
5
TET2
0.018
0.023
0.010
0.075
0.000
0.99542
0.34309
0.09635





















TABLE 5







Percent
Total Non-





Nearest
Non-
Reference

SEQ ID


Reference Coordinates
Gene
Reference
Bases
Plus Strand Oligonuclotide
NOS:







chr8:128,750,550-128,750,699
MYC
 0
 0
CGACTACGACTCGGTGCAGCCGTATTTCTACTGCGACGAGGAGGAGAACTT
1331






CTACCAGCAGCAGCAGCAGAGCGAGCTGCAGCCCCCGGCGCCCAGCGAGG







ATATCTGGAAGAAATTCGAGCTGCTGCCCACCCCGCCCCTGTCCCCTAG






chr8:128,750,550-128,750,699
MYC
 2.5
 4
CGACTACGACTCGGTGCAGCCGTAGTTCTACTGCGACGAGGAGGAAAACT
1332






TCTACCAGCAGCAGCAGCAGAGCGAGCTGCAGCCCCTGGCGCCCAGCGAG







GATATCTGGAAGAACTTCGAGCTGCTGCCCACCCCGCCCCTGTCCCCTAG






chr8:128,750,550-128,750,699
MYC
 5
 8
CGACTACGACTCGGTGCAGCCGTAGTTCTACTGCGACGAGGAGGAATACTT
1333






CTACCAGCAGCAGCCGCAGAGCGAGCTGCAGCCCCTGGCGCCCAGCGAGG







GTATCTGGAAGAACTTCGAGCTACTGCCCACCCCGCCCCTGTCCCCTAG






chr8:128,750,550-128,750,699
MYC
 7.5
11
CGACTACGACTCGTTGCAGCCGTAGTTCTACTGCGACGAGGAGGAATACTT
1334






CTACCAGCAGCAGCCGCAGAGCGAGCTGCAGCGCCTGGCGCCCAGCGAGG







GTATCTGGAAGAACTTCGAGCTACAGCCCACCCCGCCCCTGTCCCCTAG






chr8:128,750,550-128,750,699
MYC
10
15
CGACTACGACTCGTTGCAGCCGTAGATCTACTGCGACGAGGAGGAATACTT
1335






CTACCTGCAGCAGCCGCAGAGCGAGCTGCAGCGCCTGGCGCCCAGCGAGC







GTATCTGGAAGAACTTCGAGCTACAGCCCACCCCGCCCTTGTCCCCTAG






chr8:128,750,550-128,750,699
MYC
12.5
19
CGACAACGACTCGTTGCACCCGTAGATCTACTGCGACGAGGAGGAATACTT
1336






CTACCTGCAGCAGCCGCAGAGCGAGCTGCAGCGCCTGGCGCCCAGCGAGC







GTATCTGAAAGAACTTCGAGCTACAGCCCACGCCGCCCTTGTCCCCTAG






chr8:128,750,550-128,750,699
MYC
15
23
CGACAACGACTCGTTGCACCCGTAGATCTACTGCGACGAGGAGGAATACTT
1337






CTACCTGCAGCAGCCGCAGAGCGAGCTGCAGCGCCTGGCGCCCAGCGAGC







GTATCTGAAAGAACTTCGAGCTACAGCCCACGCCGCCCTTGTCCCCTAG






chr3:187,443,281-187,443,430
BCL6
 0
 0
GCTCACCTGTACAAATCTGGCTCCGCAGGTTTCGCATTTGTAGGGCTTCTCT
1338






CCAGAGTGAATTCGAGTGTGGGTTTTCAGGTTGGCTGGCCGGTTGAACTGG







GCCCCACAGATGTTGCAACGATAGGGTTTCTCACCTATTACCAAGAA






chr3:187,443,281-187,443,430
BCL6
 2.5
 4
GCTCACCTGTACAAATCTGCCTCCGCAGGTTTCGCATTTGTAGGGCTCCTCT
1339






CCAGAGTGAATTCGAGTGTGGGTTTTCAGGTTGGCTGGGCGGTTGAACTGG







GCCCCACAGATGTTGCAACGCTAGGGTTTCTCACCTATTACCAAGAA






chr3:187,443,281-187,443,430
BCL6
 5
 8
GCTCACCTGTACAAATCTGCCTCCGCAGGTTTCGCCTTTGTAGGGCTCCTCT
1340






CCAGAGTGAATTCGAGTGTAGGTTTTCAAGTTGGCTGGGCGGTTGAACTGG







GCCCCACGGATGTTGCAACGCTAGGGTTTCTCACCTATTACCAAGAA






chr3:187,443,281-187,443,430
BCL6
 7.5
11
GCTCACCTGTACAAATCTGCCTCCGCCGGTTTCGCCTTTTTAGGGCTCCTCT
1341






CCAGAGTGAATTCGAGTGTAGGTTTTCAAGTTGGCTGGGCGGTTGAACTGG







GCCCCACGGATGTTGCAACGCTAGGGTTTCTCACCTATTTCCAAGAA






chr3:187,443,281-187,443,430
BCL6
10
15
GCTCACCTGTACAAGTCTGCCTCCGCCGGTTACGCCTTTTTAGGGCTCCTCT
1342






CCAGAGTGAATTCGAGTGTAGGTTTTCAAGTTGGCTGGGCGGTTGAACTGG







GCTCCACGGATGTTGCAACGCTAGGGATTCTCACCTATTTCCAAGAA






chr3:187,443,281-187,443,430
BCL6
12.5
19
GCTCACCTGGACAAGTCTGCCTCCGCCGGTTACGACTTTTTAGGGCTCCTCT
1343






CCAGAGTGAATTCGAGTGTAGGCTTTCAAGTTGGCTGGGCGGTTGAACTGG







GCTCCACGGCTGTTGCAACGCTAGGGATTCTCACCTATTTCCAAGAA






chr3:187,443,281-187,443,430
BCL6
15
23
GCTCACCTGGACAAGTCTGCCTCCGCCGGTTACGACTTTTTAGGGCACCTCT
1344






CCAGAGTGAATTCGAGTGTAGGCTTTCAAGTTGGCTGGGAGCTTGAACTGG







GCTGCACGGCTGTTGCAACGCTAGGGATTCTCACCTATTTCCAAGAA










Minus Strand Oligonucleotide






chr8:128,750,550-128,750,699
MYC
 0
 0
CTAGGGGACAGGGGCGGGGTGGGCAGCAGCTCGAATTTCTTCCAGATATC
1345






CTCGCTGGGCGCCGGGGGCTGCAGCTCGCTCTGCTGCTGCTGCTGGTAGAA







GTTCTCCTCCTCGTCGCAGTAGAAATACGGCTGCACCGAGTCGTAGTCG






chr8:128,750,550-128,750,699
MYC
 2.5
 4
CTAGGGGACAGGGGCGGGGTGGGCAGCAGCTCGAAGTTCTTCCAGATATC
1346






CTCGCTGGGCGCCAGGGGCTGCAGCTCGCTCTGCTGCTGCTGCTGGTAGAA







GTTTTCCTCCTCGTCGCAGTAGAACTACGGCTGCACCGAGTCGTAGTCG






chr8:128,750,550-128,750,699
MYC
 5
 8
CTAGGGGACAGGGGCGGGGTGGGCAGTAGCTCGAAGTTCTTCCAGATACC
1347






CTCGCTGGGCGCCAGGGGCTGCAGCTCGCTCTGCGGCTGCTGCTGGTAGAA







GTATTCCTCCTCGTCGCAGTAGAACTACGGCTGCACCGAGTCGTAGTCG






chr8:128,750,550-128,750,699
MYC
 7.5
11
CTAGGGGACAGGGGCGGGGTGGGCTGTAGCTCGAAGTTCTTCCAGATACC
1348






CTCGCTGGGCGCCAGGCGCTGCAGCTCGCTCTGCGGCTGCTGCTGGTAGAA







GTATTCCTCCTCGTCGCAGTAGAACTACGGCTGCAACGAGTCGTAGTCG






chr8:128,750,550-128,750,699
MYC
10
15
CTAGGGGACAAGGGCGGGGTGGGCTGTAGCTCGAAGTTCTTCCAGATACG
1349






CTCGCTGGGCGCCAGGCGCTGCAGCTCGCTCTGCGGCTGCTGCAGGTAGAA







GTATTCCTCCTCGTCGCAGTAGATCTACGGCTGCAACGAGTCGTAGTCG






chr8:128,750,550-128,750,699
MYC
12.5
19
CTAGGGGACAAGGGCGGCGTGGGCTGTAGCTCGAAGTTCTTTCAGATACG
1350






CTCGCTGGGCGCCAGGCGCTGCAGCTCGCTCTGCGGCTGCTGCAGGTAGAA







GTATTCCTCCTCGTCGCAGTAGATCTACGGGTGCAACGAGTCGTTGTCG






chr8:128,750,550-128,750,699
MYC
15
23
CTAGGCGACAAGGGCGGCGTGGGCTGTAGCTCGAAGTTCTTTCAGATACGC
1351






TCGGTGGGCGCCAGGCGCTGCAGCACGCTCTGCGGCTGCTGCAGGTAGAA







GTATTCCTCCTCGTCGCAGTAGATCTACGGGTGCAACGAGTCGCTGTCG






chr3:187,443,281-187,443,430
BCL6
 0
 0
TTCTTGGTAATAGGTGAGAAACCCTATCGTTGCAACATCTGTGGGGCCCAG
1352






TTCAACCGGCCAGCCAACCTGAAAACCCACACTCGAATTCACTCTGGAGAG







AAGCCCTACAAATGCGAAACCTGCGGAGCCAGATTTGTACAGGTGAGC






chr3:187,443,281-187,443,430
BCL6
 2.5
 4
TTCTTGGTAATAGGTGAGAAACCCTAGCGTTGCAACATCTGTGGGGCCCAG
1353






TTCAACCGCCCAGCCAACCTGAAAACCCACACTCGAATTCACTCTGGAGAG







GAGCCCTACAAATGCGAAACCTGCGGAGGCAGATTTGTACAGGTGAGC






chr3:187,443,281-187,443,430
BCL6
 5
 8
TTCTTGGTAATAGGTGAGAAACCCTAGCGTTGCAACATCCGTGGGGCCCAG
1354






TTCAACCGCCCAGCCAACTTGAAAACCTACACTCGAATTCACTCTGGAGAG







GAGCCCTACAAAGGCGAAACCTGCGGAGGCAGATTTGTACAGGTGAGC






chr3:187,443,281-187,443,430
BCL6
 7.5
11
TTCTTGGAAATAGGTGAGAAACCCTAGCGTTGCAACATCCGTGGGGCCCAG
1355






TTCAACCGCCCAGCCAACTTGAAAACCTACACTCGAATTCACTCTGGAGAG







GAGCCCTAAAAAGGCGAAACCGGCGGAGGCAGATTTGTACAGGTGAGC






chr3:187,443,281-187,443,430
BCL6
10
15
TTCTTGGAAATAGGTGAGAATCCCTAGCGTTGCAACATCCGTGGAGCCCAG
1356






TTCAACCGCCCAGCCAACTTGAAAACCTACACTCGAATTCACTCTGGAGAG







GAGCCCTAAAAAGGCGTAACCGGCGGAGGCAGACTTGTACAGGTGAGC






chr3:187,443,281-187,443,430
BCL6
12.5
19
TTCTTGGAAATAGGTGAGAATCCCTAGCGTTGCAACAGCCGTGGAGCCCAG
1357






TTCAACCGCCCAGCCAACTTGAAAGCCTACACTCGAATTCACTCTGGAGAG







GAGCCCTAAAAAGTCGTAACCGGCGGAGGCAGACTTGTCCAGGTGAGC






chr3:187,443,281-187,443,430
BCL6
15
23
TTCTTGGAAATAGGTGAGAATCCCTAGCGTTGCAACAGCCGTGCAGCCCAG
1358






TTCAAGCTCCCAGCCAACTTGAAAGCCTACACTCGAATTCACTCTGGAGAG







GTGCCCTAAAAAGTCGTAACCGGCGGAGGCAGACTTGTCCAGGTGAGC


















TABLE 6







SEQ ID


Name
Sequence
NOs.

















TNFRSF14_chr1:2488006-2488106
TCTCTTCTGGCCCACAGCCGCAGCAATGGCGCTGAGTTCCTCTGCTGGAGTTCATCCTGCTAGCTGGGTTC
1



CCGAGCTGCCGGTCTGAGCCTGAGGCATG






TNFRSF14_chr1:2488106-2488206
GAGCCTCCTGGAGACTGGGGGCCTCCTCCCTGGAGATCCACCCCCAAAACCGACGTCTTGAGGCTGGTGA
2



GCCCCCGAGCCTCCTCTCCGTCTGCTCGCA






TNFRSF14_chr1:2488206-2488306
GATCCCAGTTCTGACCCCAGGGCCTCCCACAGATCTCTTCCCCATGCCCCTGTCCTGGCCGTTGCTGGCTC
3



CGGCGTCCAGCCCGTCCCCTGCTGCCTGG






CSMD2_chr1:34404022-34404122
CCATGTTGCTGGCTTACTTGGCATTTCCCATGATCTCACACTGCTGGCTTATTTGGCATTTCCCATGATCCC
4



CTGCTGCTGGTTTACTTGGCATTCCCTA






CSMD2_chr1:34404122-34404222
TGATCCCATGTTGCTGGTTTACTTAGCATTTCCCATGATCCCATGTTGCTGGCTTACTTGGCATTTCCCATG
5



ATACCATGTTGCTGGCTTACTTGGCATT






NEGR1_chr1:72334891-72334991
ATAGATTAGAGGAAGGAATTCTAGATGAAATTAAGTAAATGAGTTATTTAAGTCAACTAATACAAGTCCT
6



CAAAACTTTGATTATATAGAGAGCTAAACT






NEGR1_chr1:72334991-72335091
GATAAATATAGACAAATATAGTGAGCCTATAAATTAAAGCTATACTATGATGAAAAAATAAATGAATAAT
7



TGTGAAATAGCCAAAAATACTAAAATACAG






NEGR1_chr1:72335051-72335151
AATGAATAATTGTGAAATAGCCAAAAATACTAAAATACAGCTATAAGGTTAAAAATAAATCTGAATAAAA
8



AATGTAGGAGGGAAAAGTGATTACCTTACC






BCL10_chr1:85733207-85733307
GACATGCATCAAATGTAAACAAATGATTACAGCCATTTTATAAAAAGTCATATTCTTTAAAACATTTTTTG
9



TCATCATTAAAAATTAAAAGGCAATAAAG






BCL10_chr1:85733307-85733407
TGTCATTGTCGTGAAACAGTACGTGATCTTAAGGGAAGAAACATCTCACTAGAGTTTGCACAAGTTCCTT
10



CTTCTTCTAACTGTAGATCTGGTGGCAAAG






BCL10_chr1:85733407-85733507
GAGGAGCCCCTGGGTCCCCAGGTCTGGGAAGTGTAGTTGAAGAGAAGATGGTATTTTCAGTTCTGCCTAC
11



TTCTAGAACAGGCAAATTCAGAGAAGAATT






BCL10_chr1:85733507-85733607
AGTAGAAAAAAAGGGCGTCGTGCTGGATTCTCCTTCTGGATGGTACATGACAGTGGATGCCCTCAGTTTT
12



TCAGAGAAATTACTCTCATCTGAATTTGAT






BCL10_chr1:85733607-85733707
CTGGAGAGGTTGTTCGTGGCTCCATCTGGAAAAGGTTCACAACTGCTACATTTTAGTCCTACAATAAAATT
13



ATTCAGATGTAAATGAAAAAGTAACTAAA






BTG2_chr1:203274697-203274797
ACCCGAGACCTCTCACTGAGCCCGAGCCGCGCGCGACATGAGCCACGGGAAGGGAACCGACATGCTCCC
14



GGAGATCGCCGCCGCCGTGGGCTTCCTCTCC






BTG2_chr1:203274797-203274897
AGCCTCCTGAGGACCCGGGGCTGCGTGAGCGAGCAGAGGCTTAAGGTCTTCAGCGGGGCGCTCCAGGAG
15



GCACTCACAGGTGAGCGCATGCCGAGGGGCC






BTG2_chr1:203274897-203274997
TGGCGCCACCGGGGGTCGGCCCCATCCCTGCCAGGGCCGTCTTTCTTCTACTCCTGCGGCAGGGTGACCC
16



ACGGGAGCAGCTTTGGGACTCGGTGGCCCT






BTG2_chr1:203274997-203275097
CCTCCGACCCCCGGGGCGGCCCGCAGTCCCCAGTTTCCTGGGTCCTCCTCCCCAGCCCTGTGCTCGGGTCT
17



CGGCCGTGGCGGTTCTGATGGGGCGCGCC






BTG2_chr1:203275097-203275197
CCTCTACGCTCTCGGAGGCGCAGACCCTGGTCCTGGAGTGCCAGCCCGAGTCCCCAGCTTATGCCCCTGTC
18



TCATTACGGGCTCGTCTCCCTCGCTGGAC






BTG2_chr1:203275197-203275297
CCTCGAGATCTTAAGACCCTCGATGGATGTTGTTGCGGGCCGCCCGGTCGGCCGAGGGGTCCCGATGAGG
19



GAAGAAGGTGCAGTCGAGCCTTTTCAACAA






BTG2_chr1:203275297-203275397
TTTGGAGTCCCAGTGCGGTTCTTCCTGCCGGTCGGGGTGCGCTGTGCCTGGGGTAGTCCACTGGTTGCTGA
20



CTGGCTTCAAGTTGGAATTTGGGCCCCCT






BTG2_chr1:203275397-203275497
TTGTGTTATCTTTGGTTCCCCTTAGCCATCTGCCACCTATTGTGGTAGGGAGGAGAGCCTCGTAGCTCGTG
21



ACCCTGCCGTGCGGGCCTTCAAGTTGGGA






BTG2_chr1:203275497-203275597
GGTGAAGAGATAAGCAGCCCGCTCGCTGGCTGGGGAGAGACCTCTCTCCCAGCTGTTTCTAGCTGGTTAC
22



TGTCAGTTTTGGGAAGCGATAGCCATCTCG






BTG2_chr1:203275597-203275697
GAACGCACCCACACAGACCCTGCCTTCTGAGGAAAACAGATGTTTCATCAAAACAACCCAGTTTTCACTC
23



CCTTAGGCACTGCTAAGGAAGGTTCTCTGA






BTG2_chr1:203275697-203275797
CTCTTCTGAAGGAAGCAGAGGGAACACAGGGTGGGAGGTCCAGTGACTTGCTGTGGACCCAACAATGTTG
24



GCAGCCTTCCTGGCCCTGAAACTTCAGCTC






BTG2_chr1:203275797-203275897
ACAGGTCTCCAGAGGCCCTGCCTGGACATGCCAGTCCCAGTCACACCCTTCCCTTGCTTTGGGGGTGTGCC
25



AAAAGCAATACACTGGCCACTAGAGAGTA






BTG2_chr1:203275897-203275997
CCCTAGAGCTCTAGAATCCCCTCCCAACACGCACACACACACACACACACACTCTCTCTCTCACACACACA
26



CACTCAGTCACACACACACACACACACAC






ITPKB_chr1:226923691-226923791
CTTTCAGATCTTTCGCAGCGTCCCAACAGGGCAAAGGCTCCAGCATTCTGCCAGAAGGAATTCCCGCCTCC
27



ACATTCCCGGTCCCCGGCTGTGCTGAGGG






ITPKB_chr1:226923791-226923891
GCTGCCCCCAAGCAAGCCCAGCGTTGGGGACCCTCCCTCCACTCTGTCGGAGAGCTGCCAACGCCCCCCG
28



CCCACGGGGGCCCCACTTCGGGCCTCCTCA






ITPKB_chr1:226923891-226923991
GGGCCTACGGAGGCCAGGGCCCTGGGCAGCCTGGACCAGCTCAGGGAATCAGAGGACTCTGCGCTTTGC
29



ACGCTCACAGTCGTCTCCTCTGGCCTTTTGC






ITPKB_chr1:226923991-226924091
CCACTTCAGGCTCCCCAGAGCCCGGCATGCCACAGGGCAGATATCCTTTCCCCATCTTCCCAGGGGGTTCT
30



CCATCGCGGGGCCCGCCCCTTTCTGGGGC






ITPKB_chr1:226924091-226924191
TGGGCTTGTCTCACTGCCCAGAAACTGCCCCTGCCTCTCCACCAGGGCCTCTGGGGGCTGCAGGTCCTCAA
31



GCTCACGGGCTCTCCCAGACGGCTCAGTG






ITPKB_chr1:226924191-226924291
AGGGCAAGATCCTGTGGACGGTGTGGCCCAGTGGATGTAACTCTCGCTGCCACTTCCGTGGCCATCGTTA
32



AGCTAGCTCCGAACAGCCCCAATGAGGGAG






ITPKB_chr1:226924291-226924391
CTAGGCAGCTCCGAGTTCCCGGGGTAGGAGAGCCCCTTTTGTCAATTTCCATAGCTGTGGGTGAGCCACA
33



GCGGGGACTGGCAGGGATACCCTTCTCCAT






ITPKB_chr1:226924391-226924491
CCTTACAAAAGCGGATGGACCCTGAGCCTCTGATCCTGTAGGGGCAGCCCGGCCGGGAAGAGGTGGCATT
34



CCTTTCTTCACCTGCGAGGAGCATAGGCTG






ITPKB_chr1:226924491-226924591
GGCCCTCCTTTCCTCCCGGAGTCGGTTCCTGAAGTCTCTGGACATTGCTCCCCCCAGGACTTTGTCCTCCG
35



TTCCTCGCTCCGGGCGCCCTGAACCAGGA






ITPKB_chr1:226924591-226924691
CCCTTCCAGGGGGCTGACTGCTGCTGCGGAAGGGGCACGGGGAGGGCGAGCGAGCCCTGCCCAAACGCG
36



GGCTGCGGGGCGCTTGAATGGCGGAGCTCTG






ITPKB_chr1:226924691-226924791
TGCCTGGATGTGCGCCTCAAACATGCCCACTTTCTGGTTCACCTGCACGTTCTGCAACTCGCGCTGCAAGA
37



TCCGCAGCTTCCTCTTGGCCTCCTCCGGC






ITPKB_chr1:226924791-226924891
CCTGGCGGGGAGAGGGTACCGGCTGCCACCACCTGCTGCCGGTCCCCTCGCAGGCGACCAGCCCAACTTG
38



GGCTGCTCACGCTACTGCCGCTGCTGCCGC






ITPKB_chr1:226924891-226924991
TGCCACTGCCGCTGCTACTATTCAGCCTGCGCCGGCCGCTCCGCCAGCCCCCGGGGCTCCGGGGCTCCTCG
39



GGGGACAGCGACTCGGCTGGGGGGAAGAG






ITPKB_chr1:226924991-226925091
GAAAGAGGCGCCTCTCCCGGGGCTGAAAACGCTGCCGGGGCTCAGCACTGCCCTCCTCGGGGGCGGGGG
40



CGTCTCGCTGCCACTGGGCCCCGGGCCGCCG






ITPKB_chr1:226925091-226925191
CCGCTCTTCATCTCGTTGGCGCTATTCATGATCACCAGGCTATTGAGCGCATAGCAGTACACAGCCATAGT
41



ACTGGGTCCCGCGCTGCCCGCCGCCGCGG






ITPKB_chr1:226925191-226925291
CTCCCGCTCCTGCTCCGCCGCCGGCGCCTCCTCCTCCCGGCGCTCCCGGCTCAGCCCCGGAGGCCCGGCAG
42



CCGCGGCTCCGCGCGCAGATGGGGCGGCA






SLC1A4_chr2:65258145-65258245
AAGTGCGAAGGAAGTGTCAGGCTGGATGTCAAAATGAACACCTTGGAGAACTGGATGATGGAACAGACG
43



GTAAAAATCAGCTAAACATCAGAGAAAATGG






SLC1A4_chr2:65258245-65258345
AGGAAGAGGTCAAAACTGTGAACAGGAACTAGAAGAAAGTGTAGCAGAAAAAGACTTGTCACAAACTTC
44



GAGAGATTTGGAGAAAATGATGTCAAAACAC






SLC1A4_chr2:65258345-65258445
ATCTTCCTCAAGCCCATGCTGAGTATCTCTGATTTGGTTAATTTCTTGGTAAGTGTTCCAAGTACAGACAA
45



CAAAGCAGAAAAGCACTGATTACAGGGAA






SPRED2_chr2:65593035-65593135
TATGCAGAATGATCCTTCAGATCATGTGAACGCTATAATTAAATGTTGCTACCAAATCCCCACTACCCTTT
46



CTCCCACCTAGAAAAAGTTAATGCATGAA






SPRED2_chr2:65593135-65593235
TTCAGTATGAGCAAATTGTGATTTATAAAAACAAACAAACAAACAAACAAACAAAACCCACCCTATTCAC
47



TCCGTAGGGGAATAAAGCTTTCTTGCATTA






SPRED2_chr2:65593180-65593280
AACAAACAAAACCCACCCTATTCACTCCGTAGGGGAATAAAGCTTTCTTGCATTAAGTCACGCATCATGG
48



GGGTAGGAAAAAAGCACAGTACTGAAAGAA






EIF2AK3_chr2:88906681-88906781
GTGAAGTGATCCAAATGTAGCCCAGAGATCCTAAAGAAAAAACGATGCTCATGTGTTACAAAACAAAATT
49



TTAAGGCAATCAGTGAGGAATCACAGACAA






EIF2AK3_chr2:88906781-88906881
ATTTCCTTAGTGCTTTTATCAAGGTTGAATCTGAATATAAATTACTAGAGGAAAGCAAATCAGATTTCACA
50



TCTGAAAATTAAAAACAAAATTCTTAGCT






IGKC_chr2:89127261-89127361
AGGCAACAAAATGAGATCCTGTCCCTAGAAAACATTTCAAAAAATTAACAGCATGGTGACGCACACTTGT
51



AGCCCTAGCTACTTGGGAGGCTGAGTGGGA






IGKC_chr2:89127461-89127561
AAGAACTTAAGCAGACTAGGATATAAAGTATAGGAGCGTATTGTGTACAGGAACGGGAAATACTGTTTCC
52



TGGATCTTTTGTTTCACTTACGCACACACC






IGKC_chr:89127561-89127661
CACACCCGCCAGTAGTGTACCAGGTTGCGATGGAAATCTCTCTCTTTCTGTGGATGAGTTTGTGGAAGCCC
53



TTGCTCCAGCATGCCCTCCTTCCTGCCCA






IGKC_chr2:89127661-89127761
CCCCTGGACCATTCCTTCCCTTCACAGCACTGTCCCATGGGTAGGCCACAGCCCAGCACAGGCCCCAGCCT
54



GGCGGCTGCAGCAGGAGCCCCATCCCAGG






IGKC_chr2:89127761-89127861
GCCTGAGGGGCCATGCGGGGGTCTGGGTGGGAGTGGGAACCGCTGAGGAAGGTGAAGGGAAATATGGTG
55



AGATGACAGGCCCGCTGTCAGGGAGAGTGGG






IGKC_chr2:89127861-89127961
AGGAGCCCTGGAGTGCCCTACCTCTGTGGGGCTGGAACTCCCTGTATCCGAGCTAGGGTCTTCCACACGC
56



ATGCTACTACCCCAAGTGCCACAGCTGGAG






IGKC_chr2:89128431-89128531
TCATCTCCCACTGGATAACAGTGTTGTCGGGAACTTCCATCCAGCACTGGCGGACACTCCCGTCGCAGCTG
57



CTCCTGACTGAGCAAGTCATTTAAGGGGG






IGKC_chr2:89128531-89128631
TCCTTGGCACTCATAAGCACTCACAGAATGGGGCTGGCAGTGCGCCCGGCCTCCCTGGGATGGGTCCAGA
58



ATGGTAGGAAGCGCAGTCCGGGAGGGACCC






IGKC_chr2:89131726-89131826
ACTGCTTAGAGCTCTCAGCCCTAGATGGCGTATCACAGTTAATGCTCTATAAAACCCATCATGGCTTTTCC
59



CTAGTAAGCCTCAAATCGCTGCAAGCAAG






IGKC_chr2:89131826-89131926
GCTTCATATATGAGAGTTTCTGCTGTCTCCTGGAGCCATCTCACCCAAAGCCACTGACTCTGGGAGACCAG
60



CCCAGGCCACAAACCAGCAAAGCACCAGT






IGKC_chr2:89131926-89132026
TATAGTTAGAGCTGCATTATAAAGTGGCCAGAGGACATTTCTTTGCAGTGAGATGTGTATCGTGAACGTT
61



TGGGGCCTGTGCTCGCCTAGTCCTCATCTT






IGKC_chr2:89132026-89132126
TGCTTTTCTAGGTACACAAAGCCATCCCATGGCTGCAAATGTTAGCTGGGCTGGGCTCCCTACTTGCCTCA
62



AGCCCCTTCATAGACCCTTCAGGCACATG






IGKC_chr2:89132126-89132226
CTTTTCTCTGGACGTTTACAGACAGGTCCTCAGAGGTCAGAGCAGGTTGTCCTAGGGAGCAGGGAGGCTT
63



CCTAGGGAGGTCAGACTCCAAATAGTGGAT






IGKC_chr2:89132226-89132326
ATGGCAAAAATGCAGCTGCAGACTCATGAGGAGTCGCCCTGGGCTGCCACTAGGGCTCCCACAGTGTGCG
64



CTGCCAACCTGCTGCCCGTGCAGAAACTCT






IGKC_chr2:89140556-89140656
CAACTGTGCCCTGCACTGTTAGGGCCCTTGTCAAAACAACACATTTCTCAGTGATTCTGAGACTCTTTCTC
65



TTATCTATAGAAGTCATAACTCAAGAGTA






IGKC_chr2:89140656-89140756
AAATCATACCAATATTTTACATAAACCCTAGAATTTTTATAGATCTATTATTTCTTTTTAGAGTACATATTG
66



GAAGTAACTTCACAAGGAACATTTTCTT






IGKC_chr2:89140886-89140986
TCTGGTCAAACCACTCCACAAATAAAGTGGACTGATCCTCTTGACTCTATGTGTAAGTGCCCATTGTGTGT
67



GCACAGAGCTGGTGAGAACGGCCATGGTG






IGKC_chr2:89140986-89141086
CTAGGTGGGGGTGGTGTTGGTGGAGTTGGACTAGATTATCTGGGATCATGCGAAATGGAAATTCATTTCT
68



AGCTGGCTGGCTTCAGAAGGTGCCATCTCC






IGKC_chr2:89141086-89141186
TATTTTTATATGAAGCGTGCTTTGGAACTCAGGGCAACGAAGGGTGGGTGTGCTGCACAAGGACAGCAGA
69



AGAGTGAGCTGACTGGTCCCTGAAATCGCA






IGKC_chr2:89141186-89141286
GTTGGAAAGTGGATTACCAGTGCAGTAGAACTCTTCACGGAGGCCTGGACCATCAGGTCTAATGGTGTTG
70



TTCCAGGTGGGTGGTCATGTGGAGCAAAAA






IGKC_chr2:89141286-89141386
TATTTGAAATCAGCGAGCACGTACCTGAGAGATGACTTTTCCACTTGGGCTAGTCTCTTGATATTTCTGGT
71



CCTGTTTCTTCATCTGTAAACTGGGTTAG






IGKC_chr2:89157326-89157426
AAGGAGACCAAGAAGCGTATTTAAAATCTTGATGTTTTGAGTTTCTTCCTAGCTTCCCCCTATTCCTTAAT
72



AAAGTTCTAAATTGTTTTGTTGGAGCTCT






IGKC_chr2:89157426-89157526
TTGCAGCCATTCTGAGGGCTTTGCATGCTTTTCTGACCTTGCAGTAAACTCAATGCTTTAGGCAAAGAATG
73



GCCACGTCATCCGACCCCCTCAGAGTTTA






IGKC_chr2:89157526-89157626
GAATTCAGAACAGGTCTGAAGAAGACCAGGCAGCGGCTGAGTCAAGGAAAGCCTCCGTCCGCTTTTATTT
74



CCCCTGTGCCTCTTCCAGGACTGTGCTGGG






IGKC_chr2:89157626-89157726
ATAACAGGCTCCCGGGGGTTACTTTGGCTGGGCTGGGCTAAAACCTCCCTGCAGAGCAGGCCCTGAGCCC
75



TGCCTCTGCGCCTGGGTGGTGTCAGCCCCT






IGKC_chr2:89157726-89157826
CCACCTTCTGACTGTTCCAGCAACTCTCTAAGCCCTCCCAAAGGCCTCAAGGCCTGTAACCATATGCAGCA
76



ATTTTCAGCCATACCAGGAGAGGTCAACT






IGKC_chr2:89157826-89157926
GTAATCTTGGCCACCTGCCTAAGAGGAAGTGGCTAGCTTCACTTCTGACCCTCAGCAACTGCCAGGTGGC
77



CTCTTGGAAATCCCCCTCTGGGGGATTCCA






IGKC_chr2:89157926-89158026
CCCGTTGGGTGGGAGAGCAGTAGTTAAAATGTAAAATAAGAATCTTTTGCTGGGAGAAGTCAACAGATAG
78



GGAGAAGTCAGCTGATAACAGAAATAGTTT






IGKC_chr2:89158036-89158136
TAAAACTAACTTCACTGTTAACCAAGCAGTTCAACATGAAAGACTGAATCTCTTATGTTTAATATTTTCTT
79



CTCTTTTAATCTTCATAACTAATTTTTTT






IGKC_chr2:89158136-89158236
CAGATAATTGTATAAAATAACCATGGTAGCAAAATAATGTGATCACTGGAAAATAAGCAGGGAAAAACA
80



TGCTATGAAGATACTCCTATCTGGGTGAATT






IGKC_chr2:89158236-89158336
CTTGATAGCTTTACATTTTTCATCTGGCATTTAAACATTAAACAGTTAATGTATTTGACATGAAAATTATT
81



TCAAGTTATCTTATTAGTTTTAATAGAGT






IGKC_chr2:89158336-89158436
TTAAAAAGTGTTTAAAAGAGTTTTCAAAAGGCTCTAAAATCATTTTGAAATAGTTTAAAACAGTTTTGAAT
82



CGTTGTAAGTTAGTTTTAATAGAGCTTTA






IGKC_chr2:89158436-89158536
AAAAGGCCCTAAAATAGTCCTATCAAGTTGTTGCAGACCAAAATAATCTCCTTAAATATCACTTTTGAGAT
83



CAGCTGGGGTAAACGACAGCAACACAATG






IGKC_chr2:89158536-89158636
ACAAATCATTAAACTATTTTAGAGATTATGAAATTAAAATACTCAGATTAAAATTTTCCTATCACAGAATT
84



AAGGTACTGGAAAATATGTTTAAGTTTTT






IGKJ5_chr2:89158636-89158736
ATTAATCACATTGCTATAGGTTTAGATATTTTGTACAACTGAAATAAAATCACACACTGGCAGCTACATTT
85



TTGAAAGTTAAAAACATGGTCACGAATAT






IGKJ5_chr2:89158736-89158836
ATCTTATTTTAAAATCAGTTAATATACCTTAATGGTATTTAATGCCAAATTCAAAGTGAATTGATCAAGCC
86



CTCAGTGGCCAGGTCATGGGTGTGATTTT






IGKJ5_chr2:89158836-89158936
TACTCTGAAAGAATTACATATTTCTTTCTTTTTGGTTGAGCTTTTGTTATTTAAATACATTTGATGAGAGG
87



ATATTGAAATAATTAAATAGCACTGAAAA






IGKJ5_chr2:89158936-89159036
AAAAAAAGCTTTAAATTATTTACAATCCCCTAATGGAAATTTTCACTAATGAGATATCATAATGAATGTGA
88



ATTTTATTTCTGAAATCTCTAATAAATCA






IGKJ5_chr2:89158941-89159041
AAGCTTTAAATTATTTACAATCCCCTAATGGAAATTTTCACTAATGAGATATCATAATGAATGTGAATTTT
89



ATTTCTGAAATCTCTAATAAATCAGTCTT






IGKJ5_chr2:89159041-89159141
CTCCCTGGTTTTCCCAGCTCAGCGCCCATTACGTTTCTGTTCTCTTTCCCTTAGTGGCATTATTTGTATCAC
90



TGTGCATCAGGAAAGCTGGCTACGGCAG






IGKJ5_chr2:89159141-89159241
CATCAATCGGGCAGACACAGGGTGGCCACGGCCACTAGCGGCAAGGCGGCTGCCCCAAGAGCGCGGTGG
91



CATGGCCACCAAAGCCACTCAATCGAGAAAG






IGKJ5_chr2:89159241-89159341
ACCGCGGCTCTGTCTACAGCTCGCGGTGCCACGGCCTTCTTGGCAGAATAAAAATGTAGACAAGTAATAA
92



CAGAGGATAATGAAAGAACATACTCTTTAA






IGKJ5_chr2:89159341-89159441
AATATTTCCTATTTTTTTCACAGACCCACGGTCATTAAAAAATGCAATTATTTACTTTTTTTCATTTAAACA
93



CATTTCTTTGAGATTGAGCTTTTGGGAA






IGKJ5_chr2:89159441-89159541
TAACCACCTTTCCACCATTACAATAAGAGATAATTTCACGTTTAGTCTAATGTACAAATTGGATTTTTAAA
94



AAATGAGCTCTATCTGTGAAGCCCTTATT






IGKJ5_chr2:89159511-89159611
AAAATGAGCTCTATCTGTGAAGCCCTTATTCCTATAGAATGTGTCTTTTTGAGTTTATTACTTATTACAGA
95



CTCTAAAAACAACATTGCTGCTGATTTTC






IGKJ5_chr2:89159611-89159711
AAGTAAGCTGCCTCTTCTACATAGCAAATAGGTACACTTCACTTTTCCCTGATTTTTCTTAGGGCGTGCTA
96



TTGATTTTTATTGTTGTCTGACAAAATAA






IGKJ5_chr2:89159711-89159811
TTTATCAAACAAAAGGGAGAAAGACTAAAAAATGTATTTTTCCACTTTTCTGTATCATGCATAATCAGCAA
97



CAACCAATACAATATTTGGCAAGAGTGAA






IGKJ5_chr2:89159811-89159911
CAAAAATAAATTTACTTTTGCTCCTTAGAAATACAAGGGTTCCTTTTTAGTTACACTTTTTTTTTTTACTTT
98



GTGTCATTCAGTTTAGAGCAATTTAATC






IGKJ5_chr2:89159911-89160011
TTTTTTTCTCCAAATCCATTTTTGAAGCTGAGTTTAACTTTTGCAACCCATGGCAAATCTTAAATGCCCTCA
99



TTTACCAATCTTTACCAAACTCCTATTT






IGKJ5_chr2:89160011-89160111
AAGCCTCTAAAAGTCAATACTGGCCATCAGACCCAAATTTCAGAAGACAATAGTGAAAAATTACTTACGT
100



TTAATCTCCAGTCGTGTCCCTTGGCCGAAG






IGKJ5_chr2:89160111-89160211
GTGATCCACAGTGTTAACTTAATTACTTTCCCCTTAACAAAAATCTCTTTTCGCTGTTAATATCACTAACCT
101



GACCGATGCAGAGAAAATCTTGCAATTG






IGKJ4_chr2:89160211-89160311
AGATGCCTCACTTAACTGGCTAGCGCTTGGCTGTTCCTTAAGATGAACTAATTTTCTATCCCTTACTCATC
102



TGACTTTTTGAAAGAATCTGGTACTCTTT






IGKJ4_chr2:89160311-89160411
GGAATTGACCTGAGCTAATATCTCAAACACAAAAACGCTCCAAATTTAAAACCTTATAAGAAAAAGCATT
103



AGGAAAGTGCACTTACGTTTGATCTCCACC






IGKJ4_chr2:89160411-89160511
TTGGTCCCTCCGCCGAAAGTGAGCCACAGTGAGGGATCTCACCCTTTCCCCTCAACAAAAACCTCTCTTGA
104



AGCCAATCATATGAGATAGGCTGCTTGTT






IGKJ4_chr2:89160511-89160611
CAGAGAAAAATCTAGCTATTTCTTCCCCATTTCCCCCATGAATCCTATTCTCCTCTCAAACCCAATGATTC
105



GTCTATTTGCTCAGCTTTTTAAGTTCATT






IGKJ3_chr2:89160611-89160711
TTCTGGTGTCCTGCTATTTACTTCTGGGTCACCAGGTTTATTCAACCAAAATATCACAAAACTTGCACAAA
106



TGATACAATGGCACTAAAATCTCACGAAT






IGKJ3_chr2:89160711-89160811
AATTGAGACAGATGTACTTACGTTTGATATCCACTTTGGTCCCAGGGCCGAAAGTGAATCACAGTGATTC
107



GTCTTAACTTTTCCCTTTACAAAAACCTCC






IGKJ3_chr2:89160811-89160911
CTGAAAGCTCAGCAAGCCTCTTTCCCCCAATGAAGTTATTTTGATTTAGAAATCTTAAAAATTAGCCACAA
108



GCTAGCGTCCTGTGGAACAATTTCCCCTC






IGKJ2_chr2:89160911-89161011
CTCTGTACCTAACCTGGGAATGAAGTTTGTTAGATCCCTGGCATCCGACTAATGAAAATCCACACAAAGG
109



AACACAAAGTAAACTAATTAGCAACAGTGA






IGKJ2_chr2:89161011-89161111
AGAATCAGTGGAAAAAAGTACTTACGTTTGATCTCCAGCTTGGTCCCCTGGCCAAAAGTGTACACACAAT
110



GGTTCCTCTTAACTTCCCTCCTATACAAAA






IGKJ2_chr2:89161111-89161211
ACTCCCTTTCTGACAATTGACCAAGGCTCTGTCCAGAACATGTTATGTTCCCCAGGACATTTCTGAAGCTA
111



TTACTTAGACAAGTTATTCTCACCCAATG






IGKI1_chr2:89161211-89161311
ACTGAATCTTGCTTGCTCTTCAAAGAAAATGTGCAATCAATTCTCGAGTTTGACTACAGACTTATCTTTAT
112



CTTTTCCCTGAAGGATATCAGAGGCTGAT






IGKI1_chr2:89161311-89161411
TGCAGAGTCACCTTATAGATCACTTCATAGACACAGGGAACAGAAGACACAGACAACTGAGGAAGCAAA
113



GTTTAAATTCTACTCACGTTTGATTTCCACC






IGKI1_chr2:89161411-89161511
TTGGTCCCTTGGCCGAACGTCCACCACAGTGAGAGCTCTCCATTGTCTTGCTGAACAAAAACCCTTCTCAC
114



CAAAGGGGAACAGAGTCCTGGGTCAGCTG






IGKI1_chr2:89161926-89162026
ATCAACTTAAGGCTCATAACTTTGAAATGCATTTTGAAATGTAGCTCCAGATGGTATACGAAACCAAAGT
115



GAAGACTAATAGAGTAGAAAAGTAGACTTT






IGKI1_chr2:89162026-89162126
ACTTGGTTGGTTTGTCTGTTTTCACAGCACAGGAAGAGCTCAGCTCTTACTGAGCTGGACCAGGCGCATG
116



CCATCTTTGGAGCTGCCATGGAGTCCCAGT






IGKI1_chr2:89162126-89162226
GTTCCATAGTGTTTCCATAGTAATCTCATCAACAACACTGAAGACCTTTTCAGTATTTTCTTTTGAGTCCA
117



GCTCCATTTTTGCAGCCTTGTATCTCTCT






IGKI1_chr2:89162776-89162876
CCGCGCCCAGCCGAGTGCCTGTTTATTTTTACCTGCTTTCAGATTCTCTTCTACCCTTCTAAATTATAAGCT
118



GTTTGATGTTTTATTTGCCCTGTATTTG






IGKI1_chr2:89162876-89162976
GGAGGCTCCGTCCAGTATCTTTACTTAGCAAATGCTTAACAAACATTTTCAGAATAAATAAAAAAAAATA
119



CCTAATTGAAAGTCAATAATAGATCAGAGA






IGKI1_chr2:89162976-89163076
TGCTATCATAGACCAAAGACTAATACTGACTGCCACAACAGTAACTTTTACAACAGAAATCATAACTACA
120



ATTCTAAAGATTAGGGGTAGGTTTATTTGA






IGKI1_chr2:89163076-89163176
TTCTGTCACTGGCAGCTTTGCTAGTTGCCTTGAATAGCAGAATTAGCATTTGGTCTCACCAGAAGATGAGG
121



AAGGAGAGGGATCAAGTTAGAGGTGGAGA






IGKI1_chr2:89163176-89163276
GTTAACATTGGCAAGTGAAATTTAATGTGCAAAATAGCTGACCAAGGGCATAGTCCTTTTTTAAAGGGGA
122



CACAAAGTGATTTTCTCTGCAGACATACAC






IGKI1_chr2:89163276-89163376
GCAATACCAATCATAAAGGGTGACATTTATTGAGCACTTACTAAGTGCCAGACATTGTACATGGATCATC
123



ACATTTAATTATTCCCAAGACTCTATGAAC






IGKI1_chr2:89163306-89163406
TGAGCACTTACTAAGTGCCAGACATTGTACATGGATCATCACATTTAATTATTCCCAAGACTCTATGAACT
124



AGGAACTAATATTATCCCCTACTTTGTAG






IGKI1_chr2:89163406-89163506
GTGCAAAAACTTGAGGGCAGAGAGGTCAAGGAACTGGCTTATGGCAGTAAGTGGCAGAGCTGTGACCTA
125



AACTCAGATCCCATGTTTTTAACTGAACTAT






IGKI1_chr2:89163506-89163606
ATGCAGATTATACTCCAGGAGTAAAGTCACTCAACGGAAGCAACAAGCGTGACAGGGAATGCTGGGATG
126



GGGGAAGGTAAAAGGAACTCCTTAGACTGGG






IGKI1_chr2:89163606-89163706
ATAAGTGTGTACAGACGTATGTATAAGACTACACATGGAAATATTGTTTAAAGAGTGAAAAATAACTAAA
127



ATCCTCATTAATAGGAGTTTGGTTAAACTG






IGKI1_chr2:89163706-89163806
TGCTAGAGCTTTACAATGTAGCACAAAGCAGACATTAAGGGGAAGACGTAGACTTCTATATAGTTACGTG
128



GAAGGTGTTTGTGAAAATGCAGGTCACTGA






IGKI1_chr2:89163806-89163906
AGAGTATGTGTGGTGAGATATCATGATCCCATCTACATTGAATATATATGTATATAAATACGGGCTGAAT
129



TTTAAAAGACATAAATTGTGCTTGGTAGTT






IGKI1_chr2:89163861-89163961
AAATACGGGCTGAATTTTAAAAGACATAAATTGTGCTTGGTAGTTATCTCCTGGGATTGCAGAGGAGGAA
130



CAATGACACTTTATGCCATCTCCTCCTACT






IGKI1_chr2:89163961-89164061
CTTCTGTATGGTGATGTGAATATATTCATTTTATAGTTTTTAGAAATAATAAAACTGTACTAATTTTGAAA
131



AACAGTAAACTCTGACATTGCCTATTAGC






IGKI1_chr2:89164061-89164161
ATTCTCGATATTCCTGTGCAATGCATAAACATAACTTTTTAAAAGATATGTACACACATGTGTGAGTTTTC
132



TTTGTCAAATACTTTTCTATAATCTTTAA






IGKJ1_chr2:89164161-89164261
ATCAAGCATGCCAAAAAGGTAAAAGCTTTCCTGTTTCAGTGTAGGAGATAGTCGTCTGCAAAGGAAAGAG
133



ATGTAGGGGATAGAAACAGGAATGAAAAAG






IGKJ1_chr2:89164261-89164361
ATGACTGAGCTGTTCGAGGGACTTATGTTCCTAAGTGAGCTAATTGGAAATCTAATATGAACAGTGCAAC
134



CGAATAACTATTGTAAAGCAGTATTTGTAA






IGKJ1_chr2:89164361-89164461
ACAATAAAAGATGATTATCATAAGTACCATTGTTGCAAAAACTATTTTATTGATCACATGCAGTGGTGATC
135



TGTAGGAATGATTGTTGTGATGTTTGCTG






IGKJ1_chr2:89164461-89164561
TAACATAAAATGAAACATGGGAAGTGGCTGAGATCTTTAGGATGTGTGTGGTTCATTTTTTGAAAGCAAA
136



TGTTGTCTCAGAAGCATCTGTGAGACTCTG






IGKJ1_chr2:89164561-89164661
CCAGGATCCACCGTTCTACAAAATATCTGTGATGGACATTGATAAGATTGATCTGTTGAGGAAAGGCAAG
137



GTGTCAGTAAGATAGTCTGAGAGCTTCTTG






IGKJ1_chr2:89164661-89164761
GATTTCATGTAAAAGAGTGCTGGAAATAGAATTTCTTGGGGAACATTCCAACTAACTCATCACTGAAGGT
138



GCTTTACATTGAACCCTCAGCAAAGTTAGA






IGKJ1_chr2:89164761-89164861
TTATCAGAAAAAAAATATAAACTGCTGTGGAGGGGACAGGAAGGAAAGTCAGGGAGGGAGGGGGGCAA
139



GGAGAGAAAGAGCGAGAGAGAGGAGAGAAAGA






IGKJ1_chr2:89164866-89164966
AGAGAGGAGAGAGAGAGCACAAGTACACACTTCAATGCACATCTATAAATCATCCTGAAAACTACTGATA
140



AATTATTTTAGCAATGTTCCTCAGATGTAA






IGKJ1_chr2:89164966-89165066
CATTTCAAGAAATATCATTTTTGCTTTTTATTTGGCATAATTTACTAGCCAATTTAGGAAGTTCCCCTCACA
141



TCAGTAACATACAGTACATCACCCAGTA






IGKJ1_chr2:89165066-89165166
TGTCAGAGGACACAATGGCATAAGTTTGCCTTTTGCAAGGTTTGAGGGATGGCCATTTCCCTACCTGACTC
142



AGGAAAGTCTGTAGCTGATATCCATCTTC






IGKJ1_chr2:89165166-89165266
AAGTTTGTGGTTCTTTCTCTCTATATATATATTTGAGCTCAGCAGTCATGCTGGAGTCCAGAGTAGGTGAT
143



TCTTTCTGCTTTAGCTTGACTCCTCCTTA






IGKJ1_chr2:89165191-89165291
TATATATTTGAGCTCAGCAGTCATGCTGGAGTCCAGAGTAGGTGATTCTTTCTGCTTTAGCTTGACTCCTC
144



CTTAAGATTGTAACTCTCTCAGTTTTACA






IGKJ1_chr2:89165291-89165391
TTTTTTGTCAGACGTAAGCTGACATTCCACAAGGAGAGGAGGAAATTCTGTGGTTCACATCCAGTGGTGC
145



TTGGAACCTGATTGGTTGTCATTCTTCCAG






IGKJ1_chr2:89165391-89165491
CTAGTTTGTCACGAGTGGATATCTGTCCTGGATTCCCAAGGATCAAGGCTGCCCCATTAGCCAGGAAGTA
146



GGGAGATAGAGGAGGTCACTTGAGAAAGAG






IGK1_chr2:89165491-89165591
CTGCTTCTTTGCCGCCTCCAGGTTGTGTCTGTTTCCTCTCATATCTGAAGACAGATGTGCTGGCAGAAGCA
147



AAGTCCTTTGTCCGGCCACGTGCAAATGC






IGK1_chr2:89165591-89165691
ATGGGACATAAATATGAACAGAGATTCTTGTCCCACTCTAGAAAATGTAGATGTTCATCTTGTTTCCAAG
148



GGGACAGTAAGGCTGCAGGTGTTTTTTGAC






IGKV4-1_chr2:89184966-89185066
CTTTTGTACTCACTGGTTGTTTTTGCATAGGCCCCTCCAGGCCACGACCAGCTGTTTGGATTTTATAAACG
149



GGCCGTTTGCATTGTGAACTGAGCTACAA






IGKV4-1_chr2:89185066-89185166
CAGGCAGGCAGGGGCAGCAAGATGGTGTTGCAGACCCAGGTCTTCATTTCTCTGTTGCTCTGGATCTCTG
150



GTGAGGAATTAAAAAGTGCCACAGTCTTTT






IGKV4-1_chr2:89185166-89185266
CAGAGTAATATCTGTGTAGAAATAAAAAAAATTAAGATATAGTTGGAAATAATGACTATTTCCAATATGG
151



ATCCAATTATCTGCTGACTTATAATACTAC






IGKV4-1_chr2:89185196-89185296
ATTAAGATATAGTTGGAAATAATGACTATTTCCAATATGGATCCAATTATCTGCTGACTTATAATACTACT
152



AGAAAGCAAATTTAAATGACATATTTCAA






IGKV4-1_chr2:89185296-89185396
TTATATCTGAGACAGCGTGTATAAGTTTATGTATAATCATTGTCCATTACTGACTACAGGTGCCTACGGGG
153



ACATCGTGATGACCCAGTCTCCAGACTCC






IGKV4-1_chr2:89185396-89185496
CTGGCTGTGTCTCTGGGCGAGAGGGCCACCATCAACTGCAAGTCCAGCCAGAGTGTTTTATACAGCTCCA
154



ACAATAAGAACTACTTAGCTTGGTACCAGC






IGKV4-1_chr2:89185496-89185596
AGAAACCAGGACAGCCTCCTAAGCTGCTCATTTACTGGGCATCTACCCGGGAATCCGGGGTCCCTGACCG
155



ATTCAGTGGCAGCGGGTCTGGGACAGATTT






IGKV4-1_chr2:89185596-89185696
CACTCTCACCATCAGCAGCCTGCAGGCTGAAGATGTGGCAGTTTATTACTGTCAGCAATATTATAGTACTC
156



CTCCCACAGTGCTTCAGCCTCGAACACAA






IGKV4-1_chr2:89185696-89185796
ACCTCCTCCCCATACGCTGGGCCAGTAGGTCTTTGCTGCAGCAGCTGCTTCCTCTGCACACAGCCCCCAAC
157



ATGCATGCTTCCTCTGTGTGTTGGGGAGG






IGKV5-2_chr2:89196226-89196326
AATACATGAAAACAACTACCGAAATGTTATGAAATTATAGTTTAGTAGAACTAACAAGTGCATTAATGCA
158



AAAGAAAAGTAGGGCTCAGTAATCAGGGAA






IGKV5-2_chr2:89196326-89196426
CCAAGTGTGCATTGTAAAAGTGCAGCCTCTCTAACACTGGGTTTCATCACAAGTAACAGAACAGGATGCC
159



TGATGCAGGGAAAAAAGAAAGGCAATTGTT






IGKV5-2_chr2:89196851-89196951
GATCTCTGGTAAGAGAAACACTTCCTCTCCTCTGTGCCACCAAGTCCCCTGCATATCCACAAAAATAATAT
160



ATTTTCATAAGGAATTGATTTTCCTCATT






IGKV5-2_chr2:89196951-89197051
CTCTGCAAATATGATGCATTTGATTTATGTTTTTTACTTTGCTCCATAATCAGATACCAGGGCAGAAACGA
161



CACTCACGCAGTCTCCAGCATTCATGTCA






IGKV5-2_chr2:89197051-89197151
GCGACTCCAGGAGACAAAGTCAACATCTCCTGCAAAGCCAGCCAAGACATTGATGATGATATGAACTGGT
162



ACCAACAGAAACCAGGAGAAGCTGCTATTT






IGKV5-2_chr2:89197151-89197251
TCATTATTCAAGAAGCTACTACTCTCGTTCCTGGAATCCCACCTCGATTCAGTGGCAGCGGGTATGGAACA
163



GATTTTACCCTCACAATTAATAACATAGA






IGKV5-2_chr2:89197251-89197351
ATCTGAGGATGCTGCATATTACTTCTGTCTACAACATGATAATTTCCCTCTCACAGTGATACACCCTGTTA
164



CAAAAACCTCCAAGTTCTCTCAGTGGGAT






IGKV5-2_chr2:89214836-89214936
GCCCTCTGTCCTGGAGACACGGCCAAGGAGGCTGGAGACTGGGTCAGCACAATGTCCCCATTGCAGCCTG
165



AAATGATAAAGACAGATAAATTATATCAGA






IGKV5-2_chr2:89214936-89215036
TATACTGAGACTGTCCCCATGTAGGCCATGCATTGGTGACACTTGTAACCACAGTCATATGCAACATCTTG
166



AGTAACCAGAAAACAAAAGATAACTGGGG






IGKV5-2_chr2:89215036-89215136
AACTTACAACCTACAATGAGTGCCCTAAATCCAACAACCAAGAATCCAGAGACACAAAAAACAATGATGG
167



CCACATGAGTTTGCCCGATGTTTCCCTATA






IGKV1-5_chr2:89246681-89246781
TACCAACACCATCAGAGTGTGGCTGCATCTGAGGACCACTCTCAGCTGATAGAGGCATCAGGAGGAGCAG
168



CTGGGGCAGCCCTGCCTCACACATCTGCTT






IGKV1-5_chr2:89246786-89246886
GGGGTTTATGTTCGGGTGTGTAACACTGTGGGAGAATAACTATTATACTGTTGGCAGTAATAAGTTGCAA
169



AATCATCAGGCTGCAGGCTGCTGATGGTGA






IGKV1-5_chr2:89246911-89247011
GCCGCTGAACCTTGATGGGACCCCACTTTCTAAACTAGACGCCTTATAGATCAGGAGCTTAGGGGCTTTCC
170



CTGGTTTCTGCTGATACCAGGCCAACCAG






IGKV1-5_chr2:89247011-89247111
CTACTAATACTCTGACTGGCCCGGCAAGTGATGGTGACTCTGTCTCCTACAGATGCAGACAGGGTGGAAG
171



GAGACTGGGTCATCTGGATGTCACATTTGG






IGKV1-5_chr2:89247096-89247196
GGATGTCACATTTGGCACCTGAGATTGGAAATAGAAACACAAATATTCATACTATTGATCATATTATAGG
172



AAGACTTCCCTGAATAACCAGGCAGTACTG






IGKV1-5_chr2:89247196-89247296
AGCACACTGGGCTGAGTAAATTCCTAGTGTTCTCCTTCCTTACCTGGGAGCCAGAGCAGCAGGAGCCCCA
173



GGAGCTGAGCGGGGACCCTCATGTCCATGC






IGKV1-5_chr2:89247526-89247626
GGGACTATTTTATTATGAGAAACAATTTTTAGGTATTTTTTTGAGAATTTTAAATATTCCTCAGGAGCCGA
174



TAGAGTAATGTATTTCATTGGTGTATCAG






IGKV1-5_chr2:89247626-89247726
GATTATTTAGGAGAATATTCTTGTTTGTAGGAAACACATAGTAAAATGTTAGATGGTAGGATTCTCAAGT
175



CTTCAAAAGACTCTCATAAGATTCCGGGTA






IGKV1-5_chr2:89247641-89247741
TATTCTTGTTTGTAGGAAACACATAGTAAAATGTTAGATGGTAGGATTCTCAAGTCTTCAAAAGACTCTCA
176



TAAGATTCCGGGTAGGGAAGGGGGTAATT






IGKV1-5_chr2:89247831-89247931
TGTAAGTATTAGGTAATGGTGTTATGCCTTTGTTCTTACTAGTATTAGATCAAGCAATTTATTACAGATAT
177



ACAAAGATGATACCGTGTTGTCTCCATGC






IGKV1-5_chr2:89247931-89248031
ATGCAGCACTCACAGATCCACCACTATCAAGAACTGCAGGTCTCTTTAATACCCAGAGACTAAATGAGGT
178



GCACCTTATTCTTGTTTTGGGTACCTTCAT






IGKV1-8_chr2:89291906-89292006
TTGGGTGTGTAACACTGTGGGAGGGTAACTATAATACTGTTGACAGTAATAAGTTGCAAAATCTTCAGAC
179



TGCAGGCAGCTGATGGTGAGAGTGAAATCT






IGKV1-8_chr2:89292131-89292231
CTGACTCGCCCGACAAGTGATGGTGACTCTGTCTCCTGTAGATGCAGAGAATGAGGATGGAGACTGGGTC
180



ATCCGGATGGCACATCTGGCACCTGAGATT






IGKV3-20_chr2:89442291-89442391
CTTTCCCCTGGAGACAAAGACAGGGTGCCTGGAGACTGCGTCAACACAATTTCTCCGGTGGTATCTGAGA
181



TTGGAAATAAAACAGAAAAGTCACCCATGT






IGKV3-20_chr2:89442391-89442491
AATCTAAATCAAACCCATTGTCTTCCCAGAAGAGCCAGAATTATTGCTTTATATTGAGCTTTAATTATTGT
182



ATTGACTGAGCAGAGTTGCCAGGTAACAG






IGKV3-20_chr2:89442491-89442591
GACTTGAGAGGGTTTTCACTGACATGCAAAACCATCCCATGTTCCCCTCACCTGGGAGCCAGAGTAGCAG
183



GAGGAAGAGAAGCTGCGCTGGGGTTTCCAT






IGKV3-20_chr2:89442616-89442716
AGCTCTTCTCCAGAGCTCTGACCCAGGCATTGATATGGGCTCTGGACTGCAGGGCGGCTGGGAGGGACAT
184



GCAAAGCAGCTGGGGCGGGTGCTGGGCTTG






IGKV3-20_chr2:89442716-89442816
CAGCTGCAGAGACAATCTGCCTCCCCTTTCTGCTCTCAGCAGCCCATGCCCAGGTGATCAGGCCAGAAAA
185



GGCCGTTGGCTCAGTCTGAGGGTAGAACTT






IGKV3-20_chr2:89442816-89442916
CTCCCCTGCGGCCACAGAATTTAACCCCTGTGTCCTCTTGTCTCACCATCACCTAGATTGAGCCACAGAAT
186



GTTTGGTACAAGTCTGTTAGAAACAAAAT






IGKV3-20_chr2:89442916-89443016
AGAAGGCTGTGGTTTCATTTTTCTCTTTCTGCTCCAACTTGTGCCCAGTCAGCTCCCTAAATGCATGATGG
187



ATCAGGTTGAAAGGAAGAGTCTATTACAA






IGKV3-20_chr2:89443016-89443116
CTTTATCTTCCGGATATACTTGTATTTACTTGTTAGTGATCTTTCCTGAGGGTCCAGAAGCTGTCTCATTCT
188



TTGCAGAAATTAAAAGAGTAACATTCAA






IGKV3-20_chr2:89443116-89443216
TTAACCTCAGCACTGTGGGTGTGAGGACTTTCACAACTGCACAGATAAGTGAGACCTGGGCTCCAAATCC
189



TCAGGGTAGTGATACCATTTCCCTAAAGAC






IGKV3-20_chr2:89443216-89443316
AGAAGATGGTTTTGTCCATGCAGGCAAAGAACTATTTCTTGGGTGATCCTCTAAACTATCCAGTCTTTTTA
190



TTCTGTATAGCTGGTATAGTTTACCCTTA






IGKV2-30_chr2:89544656-89544756
GGCTATATATGTATTTGTTCATATTTCAAAAATACACAGTTTCAAAATGGAACTCAAGGGATCCAAGGCTC
191



AAAGGGGTCTCCAGAAGACCCCACACCAT






IGKV2-30_chr2:89544756-89544856
CCCCTTTCTGTGTCAGTCTTCCCCAGAGCACAGATCCTTGTTTCTGCTTGAATCTTCCTCACTCTCACAGAT
192



CTGATCATCACATGCCCCACTCTGGAGG






IGKV2-30_chr2:89544856-89544956
ACAACATGTGCATGTCCAATACAGGAAAGGAACACACATAGGAGTGTAGTGAGACCCCCAGAGATCACT
193



GTTGTTAGAGGCAGTGGGGCCCCAGAACTCA






DUSP2_chr2:96810164-96810264
GGAGCAGCAGCGGGTGGAGACCCCATGGGCTGGCCGAGACAAGAGGACTCCTCAGCCAGTCCTCCTGAC
194



CTGAGACAGGTCTCAGGAATGTGCGGAGGAC






DUSP2_chr2:96810264-96810364
ACACCGGGACATACATTTCCCTTCATGCTCCCAACATACACATGCAAACATACACAGACCCATACAGGCA
195



CGCGCGAGCAGCCATGCCCCACCCCCTCCC






DUSP2_chr2:96810364-96810464
CCAACACACACACGTATAAAAGTGTGTGTATATGGGCAAACTGCTCGCATCCCCAAATGGCAGGCTCTTT
196



CCCTAGAGGCGCCCAGTCCGCGGCGGGGAG






AFF3_chr2:100758483-100758583
AAGCTCACTCACTGGGGCCATTGACTGGGATCCAGTCTGTGGCCATGTCATGGTTTCTATTTTTGAGGTTA
197



TAGCTAATGAGCAACATGAGGTTAAGACA






AFF3_chr2:100758583-100758683
CACTTTTCATAAGGCCCCAGCCAGCATCATAAATATGTGTGTGAGCATGTTCACACTCAGGTTATGTCTTC
198



TTTATGTGCACCCTCTACCACACACACAC






DDX18_chr2:117951919-117952019
GCCAAGAACCACGACTCTCTAATTTTACTTCCCAGCAGGTATTCAGTGCATAATAGTTCCTACTTAGAAGT
199



ATCATATTTGCCCAAACACAAGGTGATAC






DDX18_chr2:117952019-117952119
CCAAAATGAGGTAAGTTTCCTGTTTTCTCAGTGAGATCTTTTGTTGTTGTTGTTGTTGTTGTTGTTTTGTTG
200



TCGATGTTGTTGTTTTTGGTTTTGGTCT






CXCR4_chr2:136874415-136874515
CCGGGTCGTCCAGCCCCGGGCCGCCGCGGCTGCCCACTACACCCACGCCAACCGCCCGCAAGCAGCGCTG
201



CAGGGGCTCCGCTGGGCGACACGCCAGGCT






CXCR4_chr2:136874515-136874615
CTGTCCCACAGGGTGCTGGGGAGCGACTGGGCGGCTCCGCCGCGAGCGTCTTTGAATTGCGCGCCGCTGC
202



AGGAAACCAAAAACTCCCTAGCAAGAGGGT






CXCR4_chr2:136874615-136874715
TTCAAAAGGTTTCTGGAAACCACCGACGGTTAAACATCACAACTGGACTCGGAGAGAGCCAAACGGTTTC
203



CCCACTTGCACCTGCCAGTCTTCGCGGCGG






CXCR4_chr2:136874715-136874815
CGACCTGGCAGCCCAGGTGCGGTCTTAACCGCCCCCGCCCCTCACCCCGTACCCGCTCCTATCCCCGGAGC
204



GCAAATCTCAGGGCTGGCAGCTGCGCGGT






CXCR4_chr2:136874920-136875020
GGAAGGTTTTCCCCCTCAAACCCAAAGCGCGCGGGCGGATCAACTCCTAGCTGCTGCCACCACTCGATCC
205



CCTCAGAGGATCGGCGCGGTGGGTCCACCC






CXCR4_chr2:136875020-136875120
GCCTCTCCCGCCCTCTGCCTACTGTGCTGGGAGACTGGCACAGCTCCGTCGGCCGCACAGAGTTTAACAA
206



ACACGCACCCAGTGTCAAGAACAGTCACCA






CXCR4_chr2:136875120-136875220
GGCGCTTAACCCCGAAGTTAAAGCGGGCGCAATCTCCTCCTGGGAACTCAGCCCAGGCACGCCGCCCTCC
207



GCCTCTAAATTCAGACAATGTAACTCGCTC






CXCR4_chr2:136875220-136875320
CAAGACATCCCCGCTTCCCCAAGGAAGAGACCGGTGGTCTGAGTCCCGAGGCAGCGCGCACGCCTTCTCT
208



GCACTTGTGCACAGAATGTTCTTACGTTTG






CXCR4_chr2:136875320-136875420
CAAACAGCGTGCAAGCCGCCGCGCGCGGCGGGACTCAAGGGGGAGACACATGCAGCCACTGGAACGCTC
209



TTTCCAGTCGTTTCTCCTCGACTCACAGAGA






CXCR4_chr2:136875420-136875520
AAAAGATTCCAATCCTGCTCCCCCCCCACCCACCCGCACTATATAGGCATGGTCAAGAAAACTCCTTTCGG
210



TGACCCTTTTTTGGAGTACGGGTACCTCC






CXCR4_chr2:136875520-136875620
AATGTCCTGGCCGCTTCTGCCCGCTCGGAGAGGGGCTGCGCTCTAAGTTCAAACGTTTGTACATTTATGAC
211



AAAGCAGGTTGAAACTGGACTTACACTGA






CXCR4_chr2:136875620-136875720
TCCCCTCCATGGTAACCGCTGGTTCTCCAGATGCGGTGGCTACTGGAGCACTCAGGCCCTCGGCGTCACTT
212



TGCTACCTGCTGCCGCAGCCAACAAACTG






RFTN1_chr3:16419204-16419304
CCCATTGCTGACATACTTACTCCCTGAGAGTGGCTCTTCATGCACCTCCAAGGGGTTGCTCTCCGGTCCAT
213



CCAGTGTCTTGCTCACCCCCTGTGGTGAA






RFTN1_chr3:16419304-16419404
AGTTCTCCACCATCTCCCTCTCCGGAGGGTGAGCTGGGCTGCTTGGCGAGGGGCACCTCCCCTCTGGGGC
214



CTGAGCTGGGCTCTGGGCTTTGGTTTCTCC






RFTN1_chr3:16419404-16419504
CAGCCGGAGCACTGCACACATCCCCAGTCCCCGGTTTCTCATTCTCCAGTGACGCGTGATCCCCACGTGCG
215



TTTTTTGCATCTCTGGCATCCTCGGTGCT






EIF4E3_chr3:71551101-71551201
ATTTGCAGGTTATATCCTGGATGGTGGCACGACAGCGCCTGGAACACAGAAGGTTGGGAGGCGTGACGCT
216



CATCAGGAAGGCTCTTTTGGGGAGCCAGGA






EIF4E3_chr3:71551201-71551301
AGAGTCCCCCAGAAGCCCACTTGGCACCCTATCTATAACAAGTTGCTCTTTAAGAATCATGGGAACTCCA
217



GAATCATTTTCACAAATACCTTCCACTCAT






EIF4E3_chr3:71551301-71551401
GATTCAATTAAATGGCAGAAAACACAAACCTTCCGTTCCCACTGGCAAACTGGGTCTAGCTAACTGAGCA
218



CAGCTAGCACAAGGCAGGCCCCCTGCTAGC






EIF4E3_chr3:71551401-71551501
AGGGCAAGTGGCGGCCCGGTCCCCAAGGCCCAGGGGAGCCTCTGCAGCTCCCTGGAAGGACGGTCAAGT
219



GAACAGAGAGCTGGCTGCCATCTGGGTTCTT






KLHL6_chr3:183272308-183272408
ATGAGATCACCAGTTTATCGTAACTAGAGGCCTCTCCCATCTAAAGCATCTTTGTAACTGCTTTCCCTTTC
220



CCCACACTGCCTACACATAAAGAAGCCCC






KLHL6_chr3:183272408-183272508
TAATTTGTAACAAGTCATTTGACAACTCCAGAAGAGGGGCCACATCCTTTTTCTCTATGTCTGTTGATTAA
221



CAAAGACAACATTATGTTTCCAACACCAG






KLHL6_chr3:183272508-183272608
TCAGACCAAGGGGGAAAAAAGTCCCCATGACTTCAGTAATTTTCCATCCTTTGGAACAAGGAAATATACA
222



CAAAAGGTTTACTATAGAATGTAAGCATTG






KLHL6_chr3:183273063-183273163
AACTGTTCAAGATTGGGCTCTCACACTAACACACCTCTTCCTTGCAACTTGCACCCAATTTGACTCTGGTC
223



CTAGGCATGCTGACCTGAAATAGTTGCTG






KLHL6_chr3:183273163-183273263
GCTGCGGCAAGCACCACGCGGTGGCAGGAGAATTCCTGAATGTCCACACACAAGATGACATCTGTCAGAG
224



CGTTTTCCATTCGCAGGGTTTCCAGGCCAT






KLHL6_chr3:183273263-183273363
TCTGAAGAATTAAGGAGAGTCCCGCGTCGTCAAATTTGACCTTTTCCCCATTTAAGATCTCGACCAAGTCT
225



CCTGTTTTCTGGGAGGGCTCATCTGTAGA






KLHL6_chr3:183273363-183273463
AGGTGCCAGGGGCCCTTCCAAACTCTTCTCGACCACATCACCCATGGTCCAGGCGCCCCTTTGTCCTGCCA
226



TCAACATCGAGACTGAAGGAGCGCCCAAG






ST6GAL1_chr3:186714604-
CCTTCCTGTTGGCCACTACATACGTGTCCCCCGCTTCTTGCCCCTCTCTGCTTGGGTCCCTGCTACACTGGT
227


186714704
ATCCTGCACTTTCCACCTTGTATTGCCA






ST6GAL1_chr3:186714704-
GTTTGTTTCCAAGGCCATCTCCACTTTGAGCTTGTTCATGACCACCTCACACAGCACACTTGGTCTGTGTG
228


186714804
GTGGTTTGAGGGGTTCTGTCTGTACACTG






ST6GAL1_chr3:186714804-
TGCTTTGGCTGTGTTGGAGGCGGGCAGGTGGGAAGGAAGAAATGTATTCTTGGGGAGATTTGTTTTTAGA
229


186714904
GACATGAGACATGGAAAATAGTTAAGTAAT






ST6GAL1_chr3:186714904-
AATATAATATGGGAGGCATGGACTATCAGAGGAGGCAGGCAGGACTGCCCAACCTCCTCACTGGGCACGT
230


186715004
TACGCTACTTCCTCCTGACCTCTATAGTCC






ST6GAL1_chr3:186782529-
CTATCATTGCCCTTTCTTACCTTGATATCCTAAAAAGCTGGTGGTCTGTCTTCTCTATCTTTTGTCCTGGTC
231


186782629
AGTTATCCTAACTATTTTGTGTCTGTTT






ST6GAL1_chr3:186782629-
CTGTGGATTAGTAAACGGGGTCCCCACCCCCACTCCACAAGGAGAACATCTGGCACCCAGAAGTCACTGA
232


186782729
GAGAATAGCTGTTGCTTTGGTAGAATTCTG






ST6GAL1_chr3:186782729-
CCTCTGAGTGGCTTGTTCTTTTCCCAGACGGAGAGGTCTCCTGACAGCAGCTCTCTTCTTTTTCTTTTTTTT
233


186782829
TTTTTTTGAGACAGAGTTTTGCTCTTGC






ST6GAL1_chr3:186783389-
CTCCTGTACCCTGTGGGCCTGAGAGAGGAGACAATGGGACAAGAAGACCCAGTGGCTTCCTTGGAAGCTT
234


186783489
TTGTGCTAGCTGGAGAGAGAAGACCTACTT






ST6GAL1_chr3:186783489-
CCTATATGCCTAGCAACAGTCCACACTGACTGGACTGCAACCAGGACATTTCCAGATTACTCAGTGGGGC
235


186783589
TTATCTTGAAATAATAGTTGATGCCATTTG






ST6GAL1_chr3:186783589-
TTAAATATATTATATATACCATCTAAGGGTCTTACATGCCTTCTCTCATTTGATCTTCATGGCAAACCCTGT
236


186783689
GAGGTATGACCACCAACCACCATTTTAC






ST6GAL1_chr3:186783689-
CTCAGAACTCAGGCTCCCAGAGTTTAAGTTGCTCACAGGAGCCCAGAAAGTAAGCGACAGAGGTGGGATT
237


186783789
TGGTTCTAGGTGTTTGCCACCAGCACTTTA






ST6GAL1_chr3:186783789-
AATCACCAAAGCTTTCTGGAAGCTCCAACTTTTCTTCTCAAGATACTGAAAGACAGGTATCTGGATGGGTT
238


186783889
GGCAGGGCGGGTGGGAGGTGGGCGAGATT






ST6GAL1_chr3:186783889-
TCCATCAACAACGGGTCTAAAACCAGCGATGGTGAGCTGGGTGATTTTGATGGAACCCCTGCCATACAGT
239


186783989
CTATTAATATCATAATTGGAGCTAAAATTT






ST6GAL1_chr3:186783989-
AATCATGATGGCAATCATGAGTTCTGGGGCTTCTTGATTTGGGCCAGCAGACACAGTCTCAGTCACTAGTT
240


186784089
CTCCGAATCAGAGAAAGGATGCCTTCAGG






ST6GAL1_chr3:186784089-
CTGTGTCTTCACATGGCTTTTCCTCTGTGCGTGGTGGAAAGAGAGAGCTCTGCGGGTCTCTTCTTGTTGTA
241


186784189
AGGACACTGGCCCCATTGGATTAGGGCCC






ST6GAL1_chr3:186784189-
CACCACATGACACATTTAATCCTAATTACCTCCCTCACAGCCCTATTTCCAAACAGGGTATTAGTCACATT
242


186784289
AGGGATTAGGGCTTCAACATAGGAATTCT






ST6GAL1_chr3:186784289-
GGGGGCACACAATTCAGTCTATAACAGAGGGAAAACAGATTTGAGAAGAAAAAAGTCCAAAATATGCAC
243


186784389
AGTGGTAATATCTGAAGATGTGCGTGCGTGC






BCL6_chr3:187460134-187460234
TCAAGGGCTCAGCAAACGACAACTTAAGCATTTAGAGTCCCATCCCTATCCACCAAACCCAGAATAAGTT
244



AGTCTTTTCAAGAAAGCATTGGTATAAAAC






BCL6_chr3:187460234-187460334
CCTTCAAAACTGAAAAGAAGAAAGGGGCAATTGGAGAATTCCCACTTTTTCTGGCTGTCTCCTTCAAGTC
245



GCCCAGTTTTTATGAACAGCATCTAGCCTT






BCL6_chr3:187460334-187460434
ACTGTCACTATCAACAACCCTTAAAACTAGCCAATGCTTCGGCCTCTAGTATTGGAAAGTCTTCCAAATAG
246



GATACTGGAAACTTCTATTTATAAGCTTG






BCL6_chr3:187460434-187460534
GGGTGGCGGGCGGGGCGGGGAGGTGGAGAGAGAGTTGCCATCTACAGGTTTCTATTTTGGCCTGAAGAC
247



TCAACTGCAGTCATTAGAGTAAGGGAATGCC






BCL6_chr3:187460824-187460924
TTATTTATTAAAACCACACACACCTTGCAAAGAAAAAGGGAAACTGGCAGTCTCTGTAGAGGAAGCCGGT
248



GGCATCGCTCAGAGCCACAAACTGTATTTC






BCL6_chr3:187460924-187461024
TAAACAGCCCTTTCCCTGGTTCCCTCTCTCCTGCCCCACTTTTTTTAAAATCCAGACTGTAAAAAACACATC
249



TACTGACACTCACTTTACTTTAAAAAAA






BCL6_chr3:187461024-187461124
GAAGAGAAAAAGTAAAGCGTTACAAGACTTTCCTCCTGGAAACTATAAACTGAAAAAAAAATCCATAAA
250



AGATTAAATCCTGGCGGGTTGTGGGGTGGCG






BCL6_chr3:187461124-187461224
GGGGCCGGCGGGGAGGGGGCGCGGAGTGGAGATTGGCTCTCTGAGGTGGTCAGGGGCCCTGTGACAGCT
251



TGGGACTTTCAGCACCTGGTTTGGGGTCATT






BCL6_chr3:187461224-187461324
TATCTGCTCAACTGTCAGGACCCCCCACCCCCAAACCCCAGCCACCAACACAACCATCGTAGAAGGGAAC
252



ACAACACAGAGGGTCTTTTTTCATTTTTTT






BCL6_chr3:187461319-187461419
TTTTTAAAAAATCGGTTTGGTTGTGTTTTTGTTTTCCATGGGGGAGCTTTAAAACTCATTATTGCAACACT
253



AGTTCCATTTTTCGCCAGGGTTCCAATAA






BCL6_chr3:187461454-187461554
CAAGACATTTACCACGGTCACTACATCCGGCAGCGGGGTGGCCCCTAGCTCCTGCTGCCCCCCCGCCCTTT
254



CTCCCCGCCCGCCCCCGGAGCTCAGCCGA






BCL6_chr3:187461554-187461654
TTTCTGAGGCTCCAACTCTACCCACTCCCTCCCCGGGCCGCCGCCGCCGCGCCTTCCCCCATTCTTACTCCC
255



TCGAGGAGAGCCACAGGTTGCAAATCCA






BCL6_chr3:187461654-187461754
ACCAACCTCGCAATCTATTTTTGCAAAATCACTCACAAAGATCTCCCTTTCGCGCCCGCGCCCGCTCCTCC
256



CGCGCCGGGTCCCCTCAGCCACGGCCACA






BCL6_chr3:187461754-187461854
AAGTGCCCTTCTCTCCTCCTGAGTCTTGCACATAAGGAACGCGGGCTGGGGCTCTGTTCGTCTTTCTCCTC
257



GCCCAAGGTAAGGACCTCGGGAATCTGAA






BCL6_chr3:187461854-187461954
GCCTGGCGTCCACTACGCTCAGGCCCGCAGTTCCCTTTTTACAGAGCTTGCACCATGGGAAAAAATAAAA
258



TAAAATTTAGGAAAGGGAGGCAACAGCCAT






BCL6_chr3:187461924-187462024
TAAAATTTAGGAAAGGGAGGCAACAGCCATTGGGAGCCAACACAGAGTCACGCAGCGCCCAAAATACAA
259



ACACCGCAGCGGCCAGAAATCCCGCCACCTT






BCL6_chr3:187462024-187462124
TCTCGTTCTCCCAGGCTGTCCTGTCGAGGTTCCCTGAGTCCCCCCGCACACTGAAAGGCATCGCAGGTGCA
260



GTGCGCACCCCTTTCCCACCCACCCCAAG






BCL6_chr3:187462124-187462224
AAGCCCTGTCCCGCCATCAGTCTCTCTCCTCGGGATGAGCAGGGAGAGCGCGCGGAGGTTCCCGACTCCC
261



TCGACTACAACCAAGAAAGAATAATTTTCA






BCL6_chr3:187462224-187462324
AAGTGTTCAACATCCCCGCCCCCAAGCTCCCCAAAACACAGGGGCAGGGAACACCAAAACACTCGGCTCT
262



CATTAGGAAGATCACGGCTCTGAAAGGAAA






BCL6_chr3:187462324-187462424
TAGTAGACACGATACTTCATCTCATCTGGATTTATGACCAAAAAAACAAAAACAAAAACCCAAAGAGTTC
263



GCTTGCATTTTTTCCTTCCAAATCTCGGTT






BCL6_chr3:187462374-187462474
AACAAAAACCCAAAGAGTTCGCTTGCATTTTTTCCTTCCAAATCTCGGTTCGGCTCGAAGGCAGGGAATCT
264



AAAAGACCGAGGCCGATGGAAGAGAGCCA






BCL6_chr3:187462474-187462574
GCGGGGCGAGCGAGCGGGCAGCCTCCCTTTTTGCCTCCCGGAGTTACCCAGAAGGACAGGGGAAGGGAA
265



GGAAGAAGAGGCGAGGAAAAAGAGGAGGGAG






BCL6_chr3:187462574-187462674
GGAAGCGGAGGCCAGGAGCGACGGAGCAAGGAAAGCAGTTTGCAAGCGAGAAAAGAGGGAAAAAACAC
266



AGCCGCACGAATCCAGAGAGATCACAAGCCGT






BCL6_chr3:187462674-187462774
ACGCAAGCAGCAGCAGAAAGAGCGAGAGCGCGAGCGCGCGTCCTCTCCGCGGTCTGGGGCCAGACAGCC
267



CCCAGACTAGCCCGAATCACCCCCCAAGCAC






BCL6_chr3:187462774-187462874
TGTCTCGTCCTCTCTGCTCCGGCCGCCCCCTAATTCCCCTCCTTCCTCTCCTCCACCTCCTTTCCAAAAACC
268



AAAACAACACAAGGGAGGGTGGCAAAAG






BCL6_chr3:187462874-187462974
CCTCCCCAAACCGGCCGATTCACTCAAAGACAACAATAATAATAATAAATACATAACAATCTATATCCTA
269



TGGTGGGAGAGACGTGGGACTAATCTTCGG






BCL6_chr3:187462924-187463024
ACATAACAATCTATATCCTATGGTGGGAGAGACGTGGGACTAATCTTCGGCATTTATTTTAACACCTGACA
270



GCTAGAATAAATAAATATATACATTTATA






BCL6_chr3:187463004-187463104
AATAAATATATACATTTATATCAATAGATACACATAGAAAACTTGGAGCCAAAGCATTTGGCAAGAGCGG
271



AAAAAAAAAGAATTAAAAGGTAAAATAATG






BCL6_chr3:187463104-187463204
ATCATGAGCAGCGGCGGCGGCAGCGGCACCAGCGGCAACAGCGGCGGCGGCGGCAGTAGCAGCAGCAGC
272



GGCGGCAGCAACAGCAATAATCACCTGGTGT






BCL6_chr3:187463204-187463304
CCGGCCTTTCCTAGAAACTTCTTGCATCACCACTTCTAAGAACCCCAGTTCTAAGAATCAACAGAGCTCAA
273



TTCTCGGAATTTGAGCTTCGGACTTTACC






BCL6_chr3:187463304-187463404
ACTGCTACGTGGCAGGGGAGGACTTGGTGTCAGCTCTCCGAGATTTTTACTGCCCCTGGCCAACCAAAAG
274



CCCTCAAAGCCACAAGATTTTTTCACTGGC






BCL6_chr3:187463404-187463504
CGGCATATTTCGAGGTCCTCATAAGCAGAGCGTCTCGGATTTGGAGGTTCCGGTTCGAGGCTCGAGGGGC
275



CTGAAGGTGGCTCTCCCTCCCCGGGCCCAA






BCL6_chr3:187463504-187463604
GACGATGGTATGGCCTGCTCCGCCACCATCACGTGGGCTCCTCCTCTGTGACGTCGGCGCCTTCGCTGTAG
276



CAAAGCTCGGCCTCTGGAATTCTGAGAAC






BCL6_chr3:187463709-187463809
GCACAAAAGGGAGCGAGAGGTTTGAACCACTGGGAAAAGTATGTTATATATATAGTAGGGTTAGAGAGG
277



CGAGTAAGAGAAAAATAAAATAAAATAAACA






BCL6_chr3:187463794-187463894
AAAATAAAATAAACATCACAGCTCTTTCCAACTAGAATATTAGGCACCACGAGAAAAATATTTGCCAAGC
278



AGTTTTCGGTGGGTTCATTTGCTTTATTTT






BCL6_chr3:187463894-187463994
TATTTAGGACAGGGGTTTTTGCTGTTGTTCTGGGTTTTTTTCTTTCTGGTGTGGTGGCTTGGGATTTTTGGT
279



TTCTGTATTTTGATGGTTTATGGATTTT






BCL6_chr3:187463994-187464094
TGCTTCTGATTTTTTGCCTTTTGCAAGTTTGTGGTGTTACGTAAATCACAGGATCGGCATCGGTTGGATTT
280



TTTTGTACGTGCCTTTTCTTTCCCTATCT






BCL6_chr3:187464094-187464194
AATCCCTCAAGCGTTTTAAAGATGTATTATTTCAATACTAATACTATTGAAAGAAGCTTAAATTTTTGGCC
281



ATATGTAACAATCCCAGCCCCCACTTTTT






BCL6_chr3:187619334-187619434
ATTATCATCATCACCACCAACATCCTCTGCCCTGGAGACCAAGAGAATTCAAACAGGTCAGCACCTCTAA
282



TTGCTGTATAGAACATTGACCCTACTGTCT






BCL6_chr3:187619434-187619534
CCCAGTTCCTGAGGATGGTGTGATAATAATACATCTCAGAGTTCTGTAGTTTCTTCACCACTGTGCAGGTG
283



TGGTTGGTGGGAGCAATGCCCTGGATGGA






BCL6_chr3:187619534-187619634
TAAGCCAAGCTCTTGTGTCCTGGCAGATAAACAAGGTGAACCCTCAATCCGTGTAGCAGGAGTTTCCAGA
284



CAAACTCACTTTGCATGGAAGGACACTAAC






BCL6_chr3:187619634-187619734
CCTTCCAGGTGCATGGAAATATTTTGTAGTTTTTACTGTCTCCCCCTTCCTCCACTGCCTCATCTTTTTTGT
285



TTTTTCCCCTGTGAGACTATTTGCTCTG






BCL6_chr3:187660817-187660917
CCTTTCCAACACTGGCCTGCCTTAGGGACTCACCGTCTGCACTCCGCCTGCACAGGTGGAACTGAGTTCAG
286



ATGAGGGAGAATTGCTTTCCATTGTTCAG






BCL6_chr3:187660917-187661017
TAGGCTTTTTGTAATTTCTAGTTTTGCTTACCTTTCCTACTCACCACACACACAAAACAGTGTGAGCTTTCT
287



CATTCTAGTGCATAAACACAGGTCGGTC






BCL6_chr3:187661017-187661117
AATACCCACAAGTGTTCCAAAAGGTGAGCTGGCATTGCTGCCCAACTGGGCATTATAGTCCCTTCTGTCCC
288



TGCCCATCAGGCTTGCCTTCCTCGGCAAC






BCL6_chr3:187661117-187661217
CTTTCTAGCTTGAATTGTACTGTGACTCCTTCTCACGGACCACTCCCGGAGACTGGTGAAAGTTGGGCCCA
289



TTCTTGAAGCCTCTGCTTCTAAATCATGT






BCL6_chr3:187661217-187661317
TTTCCATAAAGTCTCCCTCATCGTGCTTGCTTCCACCTTCTCCTATTTGGAATTACTGGTGGGCTCTTCCAC
290



TGTCCCATAGCAAGTGTTCTATACATTC






BCL6_chr3:187661317-187661417
TGAAGGCACATTTGAATATATACTTTGTCATGGTTGCTTGGAACCATGTCGTCTTTTCCAAGTAGGCTGTG
291



AACATTCAGTGGCATGGATCATACCGTGC






AC022498.1_chr3:187957432-
CCCATTGTTCAAAGAAAGGCATTATGGAGTCTCCAAAAGCCATTGGCAGGTGGTGTCTGTGACTTCCTTA
292


187957532
GCCTGGAAATAAACAAATAAACAAGCACAA






AC022498.1_chr3:187957512-
AAACAAATAAACAAGCACAAATTAGAAGTCTTTGCCCTATTACTGCACTATTAGTATTGATTGCGCAACA
293


187957612
TCATGCAAAAAGTCACTTTAATTTATCTGG






AC022498.1_chr3:187957612-
CAGGTCCTATGTAAACACCAATACAGTCAAGAGGGCTTGGATGGGTATTTGCTTTCATTTCTAATGAAATT
294


187957712
TCAGGCCTCTAGGGTAGGATATCAAAATT






AC022498.1_chr3:187957712-
GGTAGATCATTTGCAATTTATTTTATCCCAAACACCTCACTTTACAGTCAGAGAAACTGAGGCCCAGAGA
295


187957812
AGTAAAATGAGTTGCTCAAGGTCTCAGAGA






AC022498.1_chr3:187957767-
ACTGAGGCCCAGAGAAGTAAAATGAGTTGCTCAAGGTCTCAGAGAGCAAGAAATAGAGATGGGACTTGA
296


187957867
GCACCTAGATCTCTGGTATTGCTGTCCTGTA






AC022498.1_chr3:187957867-
GTTCATGGAGCTGGCAGATGGATACATCTGTGACCTGGGATGATGGAGAGACTGCTGGACCCTTCAGAGG
297


187957967
ATCTCATCTCAAGGTGGGGTTTATGTGTAA






AC022498.1_chr3:187957967-
ATGATATCTGTGTGTTTCATTTTCCTTTCATAAACTAATTTAAAAATCCTTTTGGTATCAAATTTTAAGCCA
298


187958067
AAAAGTAGTGAGGGGGAACATGGGTAGG






AC022498.1_chr3:187958067-
AATAGCTTACAGCTTGCCTAACAAGGTTGTTGACTGCATAAGAGTCAGGAGTTTTGGGTAAGAGTGTGTG
299


187958167
TGTGTGTGTGTGTGTGTGTGTGTGTGTGAG






AC022498.1_chr3:187958282-
CGTACTGAATTTGACTGCTTTATTTTGTAGGGAAGGAAACTGATGTGCCTAGAGTAGTTGAGAGCTTTATT
300


187958382
CAAACTCATTCCACTGTTATTGAGTAGTT






AC022498.1_chr3:187958382-
AGGATATTAGACCAGCAACATATTTGGGTAGAAACTTTCATATAAAAAAGCGTAATCATAACTATCCAAT
301


187958482
CATGTCAACTAGTAAGGCTGCTCAGGTGGG






AC022498.1_chr3:187958482-
ATAACACATCAACCTTCTTTGGGATTCTTCCCTCAGACATGGTTTTGGTGGGAGGAGCATGGCAAGGGAG
302


187958582
GGGCGAGCTCCAAATGCAGGGCTGCTCTGT






AC022498.1_chr3:187958582-
CCTCGGCGACCTGAGCAGACACACGAGCAGAGATCAGAGACACTCTTAGTGAATGAACCTCCCTATTGGC
303


187958682
TATATTAAAGTAATGCTCTGAAAAAGTTCC






AC022498.1_chr3:187958787-
TATGTATGCATAGTCTAAAGTGATGATTTTAGAGGTAGCAAGACAGTGAGAATGTCCCTACATGTGAAAT
304


187958887
GGGCACAGTTTTATCAGGGAAGTGTCAATA






AC022498.1_chr3:187958887-
GAGGGTTAATGTTCCACGTAGTGGCTGCAAGAATGATAAGTGGTCATGGGGATAGCCTGACACTCTAGGA
305


187958987
GCAGAAGGTGGTGGGTATGGATAGAACTAC






AC022498.1_chr3:187958987-
TGATATAGCATGAATCCAACCTGCTGTTATCTGCGCAGGCCTCTCTGCAGCTGTTTGCCCTGAAGTACATG
306


187959087
CTGTACGTTTCTCCAGCTGATCCTGCATG






AC022498.1_chr3:187959087-
ACTGGGTATAAACGCCTGTCCGCTGTGTGCTGGACAGCCCCAGACACCCTCGGCAGCCTGCTGTGTTTGT
307


187959187
GTGAGACATGCTGTGTTAGGGATTTAAGCA






AC022498.1_chr3:187959462-
ACAGCTTTCTCATCTACATGGACAACCTATTTTTAAAGAATCTTCAGAGAGTCGTTGACTTTGTTATAACT
308


187959562
ACTACTATATACGTAATTTCAGATGATAG






AC022498.1_chr3:187959562-
AATTGAAAATTTAACTTGTTTTTCTAGAAAGAGTTTATTTTCCCTATAACTTCAAAGAGTAATGGTGGGGA
309


187959662
GTAGGACATTCTGAAAATAAGAAGAAACA






AC022498.1_chr3:187959662-
TGTCAAATGAATTTCTGACTTCCAGCTAGGCATATGGAATAAAGGTCTTTATTCCAGTGACCTCTGCTCAT
310


187959762
TGGAAAACTTTGGGCTGGTAGATTTCATG






LPP_chr3:188299217-188299317
TCTCTTGCATTCTTAACTTGCAATTTAGTACTGTTTATATTCTGCTTGAAGGTTAGAGACATTCGACTAAA
311



TGGTCTTTTCTCCACATTGCTGTCATTCA






LPP_chr3:188299317-188299417
TTAATGTCCTGGTCCTGGACTTTACTCATTGACCACAGGACAAGTGGCTCAACTCTCTCCTGCCACTACCC
312



AGGCTGTTAGTCCTGTTGGGAGGCTCAGG






LPP_chr3:188299417-188299517
GCCCAACTCACTCATCTGTAACTCTCATCTCCATTCAGCTGCAGCCTCTACAGCCCCTGGTTATACCCTGG
313



ATCTTATCATTGCTTCGCTCTATTTTACC






LPP_chr3:188299517-188299617
TCCTAAATCGTAAAAATTAAAACCAGCCTCGGAACACAACCCCTCATTCTTCCAGCACTCTCTCTCATTCA
314



GGTAACTCCTATTCTACTTTTCTTCAGCA






LPP_chr3:188471412-188471512
TTGTTTTTTTTTACTTTACCTTAATTTCTCTTTTTGGACTAAGATGTTAAAATGTTTCTTAATGTGACTGTCT
315



CCGAAACTGTTTTGTGTCTACCACTCA






LPP_chr3:188471512-188471612
TCCTAGTGGCAGTCATTGATCCTTTTCTTGTTGCGAGTGTTTGAGTGTGGGTGTGTGTGAGTGTGTATATG
316



TATTTGTAGAGGGAAAAACAAGAGAGAGG






LPP_chr3:188471567-188471667
TGTGAGTGTGTATATGTATTTGTAGAGGGAAAAACAAGAGAGAGGGAAACAGACATTGGAGCCACCTTTC
317



CCCCACTAGCCACGTACCTGTTGAACCTTC






LPP_chr3:188471667-188471767
AAGCCTCTCTATAGAATCAGATATACACAAGCACAGTGACAGAACTACATGTGTCCTACAGTCCAGCTTT
318



TAAGATATGATAAAAACTCTTGTATTCACA






LPP_chr3:188471767-188471867
GAGCTAAATGGCAATAACCATAGGAGATTGCATATTGCTACATTATGTAAAGACAGAGTCCCAAGAAAAT
319



AGTGAGAACTCAGTTTGATGTATGATGTGA






LPP_chr3:188471867-188471967
TATGTGATATCTTACTTTACATGGCTAACAGTTGACATTCTTTGTGGATTCTATATTGTCTAAGGCTACAG
320



AAGAGCCATATGATAAATTCATCGGCAAC






N4BP2_chr4:40198810-40198910
CAGTGAAAAGGCTTGGGCCGCTTTTGTTTTCACCTGCTTTTGTTGAACAAATTTGATTTCCGGAGTCAGTC
321



ATTTTACTGTCAAGACATTTCTTCGGCAT






N4BP2_chr4:40198910-40199010
TCTGCAACAGGTAAGGATTTTGCTTCCTTAAAAGTATTTCTTTGGTGTCAAAAGAAATTTTTCTAATTTTA
322



TTTAGCTTTTACTCTAGGCCAAACATCGT






N4BP2_chr4:40199010-40199110
AATGACTCTGAGCTACCTGCTGTAAGGTGTAGAATCAATTTACAGGGGGACGGGGGTCGGGGGGGTGAG
323



TGTTGCTTTGATATTCACTGCCCCTCACCAC






N4BP2_chr4:40199110-40199210
AGTCCTAACAAGATTTTTGAAACATGAAAAGTTACAATAGTTGGCTTTTTGGTTTTCCAGATATTCTAGAG
324



AATGCATATGCTTGTGACTGTGGCTGAGC






N4BP2_chr4:40199210-40199310
TCAACTGTATGGGTAGTTTAAATACTACCCAAGGTTTGATGAAGTAAATCTAAAGATGCTCTAAGTTGTG
325



CAAATATGAATTTTAAAGTTGTCTAGTTCA






N4BP2_chr4:40199310-40199410
GAAAAGAAACAGAACCGAAGTCTAAATGATGTAGATTTCAATCTGGAATTTCTAGCTTGTGTTTTTCACCT
326



ATTGCCAATGTTAATGACCATTTCCCAAA






N4BP2_chr4:40199410-40199510
AGTGCTCTATGATGTATAACATGTATTTTTTAATTAAATTTAATCTTTCTTCTGAGGTGGTTTGATTTGGAG
327



ATATGCTACGAGGTACCAGTCAGTAGCC






N4BP2_chr4:40199510-40199610
TGAGTTGTAACTAAACAAAGTTTGGGAAATCACCGGTTTTAGGTGCTTTACTAAATGAAAGTTGCCATTG
328



ACGTATTCAAGCAGGCAACAAGTAGTTGGT






N4BP2_chr4:40199610-40199710
GTCCCCTTATTGGTTCTAAGCTGGTGCCGTGGAGGATATAAGAGAAATATTTTAAAAATCTCTACTTTGAA
329



GGACCCTATAATCTGGTAGTTGTGATAAG






N4BP2_chr4:40199660-40199760
TTTAAAAATCTCTACTTTGAAGGACCCTATAATCTGGTAGTTGTGATAAGAAGTAAAATTTAGGAAGCAA
330



TGCAAGATGAGAATTCAGTGATGAGTGGGG






N4BP2_chr4:40199760-40199860
CAGCACAGGCTTGAAGAGTTCTGTGAATTCCATGGAGGGGGCCTGGGGGCAAACTGGAGTTGTCAGGAA
331



GATCTGGGCTTTGGAAGAATGCGAAGTGTCG






N4BP2_chr4:40199860-40199960
GTAGAAGGAGAAGGGGCAGGTGATTTCAGACTGGGAGGACCTTGTGGGCAAAGGCACAAAGGCGAGACT
332



GACCTGGAGATGATAAGGCCAGTTGAAGAGA






N4BP2_chr4:40199990-40200090
ACATTGCAGGAAATCAGATTAGACAGTTAGGGTGTGGACACAAAAGCGAGGACCTTGCAGGCACTGGGG
333



AGAAGTGACCCCATTCAATAGTCCTTGGTCT






N4BP2_chr4:40200090-40200190
CCTTCTGCCCTGCGGCTGCGCTTCCTCGGCTCTCACGGCACCAGCAGAATTCCATGTGAGAGGGAGCTTGT
334



CGAGCGTGGCCTCTTCCCACTTGGGGCTG






N4BP2_chr4:40200190-40200290
CTTTCTGCATCCCTGTGCCTGGCTGTGGGCCTCCATTTGCCCTCTACTGTCTTCCCTTAGGACATCATTTAT
335



GCAGAGAAAGGTTCGTGTGGCTCGGGGT






RHOH_chr4:40200505-40200605
GGACGTTGTTTAGAGAGTCAGTAGATCATAATAATTCAGACACTTTTTTTCTGGACCATAAAATATCTGAA
336



CCCATATAATAACAAACATACAGCACGGT






RHOH_chr4:40200605-40200705
GAATAAGAACCCAACTTTTGAGCCAGATCACTTTGCATGGAATCCCCATTCTATCATTCTATCATTTCTGG
337



GCTGTGGGAACCTCAGACAAGTTACTTAA






RHOH_chr4:40200705-40200805
CTTCTTCAATGCTCAGATTAAAAAAAAAATTCACAAAATATCTCTAATAACAGTAATAATAACTGAAAAT
338



ACCTACCTCAGAGGGTTGTCGTAGAGATCA






RHOH_chr4:40200730-40200830
AAAATTCACAAAATATCTCTAATAACAGTAATAATAACTGAAAATACCTACCTCAGAGGGTTGTCGTAGA
339



GATCAAATGAGATAAAAATATGTAAAGCAT






RHOH_chr4:40200830-40200930
GTAGCCTAGTGCCTGACTGAAAAAAAAATCTCTCAATAGATGCAACTCTTATGATTCTTATTAAGGACTTG
340



GCTATTGCCACAAATGAAGGTGTTATGAG






RHOH_chr4:40200930-40201030
CCCTGGCTTAAGAGCAAGAAGCCTGCAAAGCTAACTCTCCTAATCCCAACATTCCTTTCCAGGGAAAGTA
341



GGGTGACAGGTGGAGGCTGGGAATTAACGT






RHOH_chr4:40201030-40201130
TTTTTGAGCACCAAATATGGACAAGGCACAGGGGTTGGGTGTTTTTCTAGTGAGAATACATATGAAAGAA
342



GGAAAACAAACTTGGAAACCGCTATTTTAA






RHOH_chr4:40201130-40201230
GCCATTTGGTAACAGTTTCTCTAGCTTATGAGATGAGAGAGGTCCTCTCAGTATCCGCTGCATTACTTGTG
343



GGCCTCCTTGGTTGACGTCGCTCTCTGAA






RHOH_chr4:40201230-40201330
CGCTTGGGGTGGAATTCTAGAGGTGCTTTTCATTAGAGGCAGAGAGCATGACCTTTCTTCCTTGCCCAGTT
344



TAAATTAAATTATTTTATCTTACAATGTG






RHOH_chr4:40201330-40201430
TTAATTTTAGTGCTAGCAAGGCACAGCTAAAATTCCATTTCTACTTAGGAGTGGGGATCATTGTGGCAGT
345



GAGTGCTTATTTGGGTTTGGGATGCTTGGA






RHOH_chr4:40201430-40201530
TCTGGGTGAAAGCCAGGATTAAAAAGCATCCTCCTTCCCCATTCCACTCTCTAGGTTATAAATATTTTTTT
346



GGATTAAAAGCCTCCTTTAAAAAAATGCA






RHOH_chr4:40201530-40201630
AATCCACCTGGCATGTTAATTGTGCAGGGGATTCCTAATTATGTGTGCAGATGACGTGAGTCACACGGTG
347



ATAGTGTTCCTTCTAGAGTCCCACTGGTGT






PABPC4L_chr4:134727698-
ACTAGGCGTTCATCCTGTGTAATTTGAAAATATGTCACACGTGGTGATGAGAATCTATTTGAGGAACATG
348


134727798
GGCAGTTTGAAATAATATATGCAATGTATG






PABPC4L_chr4:134727798-
ACTAGTTTATATAATGAAAGGAAGTATTTAAAAAGATAGAATGACATAGACTAATCTAATTGAGAAATAT
349


134727898
GAAAGTCTAACAGAAATGATTGCTTGTGAA






PABPC4L_chr4:134727898-
ATTTTATGAAGAAATCCACAGATAAATTCTCCACCTTGATCTATGTAATCCGAAATTTAGATGTTAAAAAT
350


134727998
ATGTTGATTCTGAAAATTTATATTTATTC






SLC38A9_chr5:54964698-54964798
TTTGGTATGAATAGGTCAAAACAAGTCACCATTAACTGACAGGAAGCACAGAATTCTCAATTTAGTTTTG
351



GCAAAGACATTATTTTATAAATATGAGTTT






SLC38A9_chr5:54964798-54964898
TTAAATGATTCTTATGAAGAAACTAGCACCAAAGTGAATGCACTCTGCAAATAACTCCCAGCTTCTCTGA
352



ATTTCAAAAGCAGCCACTAAATATTATTAG






SLC38A9_chr5:54964898-54964998
CAAATCAATTTAGCTGAAAGCGATGAATTACAGAAGTAAATCTTTAGGTACAAAGTAGACAGCTGACACA
353



CATGTAGCATATACACACTAGTGATCTGCC






ZNF608_chr5:124079827-124079927
TTCCTTCTTTACCAACATAGAGTTTCCCATGAGCCCTGAATCCGGGGCACTTTTGCTAACTTCCCCTGCAG
354



CGGCGACGCTGCCACTCCCAGTGCCCCCG






ZNF608_chr5:124079927-124080027
CAGTGGAAGGGGCTCGCGCCACCTCCATTGCTCTTGGCCCCAAAGCCATAGAGGTGCCCCCCGGAAGGGG
355



CCTGGCTGCCACTGCCATTCTGGTGGCCCT






ZNF608_chr5:124080027-124080127
GAAGCAGGTCGTGCTTGTCCTTCCTGGATTTCCCCGCATCCTTATCCCGCTTGGCGCCTCGGCTGCTCTGG
356



CTTTTACCTGGCTTCTCCTCTTTGCTTTT






ZNF608_chr5:124080127-124080227
CCCACAGGAGCCTGCCCCCGCGGTGGCGGCAGAGGTGCTGGTGCTGGTACTATTGCTGTTTGGGTTGCCG
357



CTGCCGCCGCTGCTCACACTTTGACCCAGC






ZNF608_chr5:124080227-124080327
GCTGAATTCATGCCAGTTGCCTCTCCAGGGCGCCCTTGGACTTCCTGCCTCTTGCCAGTGCTGCTGATCTC
358



GGGAATCCCATACAAGGCAGCAGAAGGCA






ZNF608_chr5:124080327-124080427
GAGATTTATTAGCATCCTTAGAAGTTTTACTCCTTTTCACTTTTGATTTGCTGGTCTCTTTGTGTGAATTCC
359



CCTGGGGAGCAGAGGCCTGAACAGAAGC






ZNF608_chr5:124080427-124080527
AAATTTTAGGCCATCAGCTAAGGCTGCGGTAGCACCAGCCCCACTGGAGGCCGGACCTCCACAATCCTTG
360



GAGTTGCTGCTACTAGTGGTGGTGGTGGAA






ZNF608_chr5:124080527-124080627
TTATTCATCTCAAATTTCTGTCTGTCCTTCTCCAAATCAGCGTCCAAATCAATTATTAAATTTCCAACCCCG
361



ATTTCCCAATCATCGCCACTGTCATAAG






ZNF608_chr5:124080627-124080727
TATCAACTGTATTTGGATCCACACCTTTTCCTGCAGTAGAAATGTTCACTGACATCCTGAAGATGAGCTCT
362



CTAGAATAAAAATCCGATGAACTTTTCTT






EBF1_chr5:158527642-158527742
TTCCTCAGGAATTTGAGCTGGGGATCTGCATCCTGGCCATTGCAGTCCTTTAGCATCCTCGCCGCGCCCTG
363



AGCGCGCTGGAGGCTCGCAGGCTGCGCCC






EBF1_chr5:158527742-158527842
TCCCAGGGCTGATGCCGCGTCCTGCTCCGCCGTTCTGGGACGTCGGGGACAAAAGTGGAGGAGACGGGA
364



GAGCCCGGGCAGAAAAAGCAGGACGCGCGTC






EBF1_chr5:158527842-158527942
CCAGGTGCCCACCTCTTCGCTTTGAGGCGGGGGCGGTGGGATGGAATATGGGTGCGCGAGGTCGGGGCTG
365



GTAACTCTCGGAGGGGCACGGCCTCCACGC






EBF1_chr5:158527942-158528042
TGGGAGGGATGAATGGACGCTGGGCCCCGGCAAATGAGGCGCTGTGGGTCCCCAGGAAGTGGGGTACCA
366



GGCTCTACTCCCACCCCGGCCTCTGAAACGC






IRF4_chr6:392760-392860
GGCCAGGAGGGGTGGCGGCTGGGTGGGGAGAGAGGGTGCAAGACGAGCGGCGCGTGTCGGGAGCCTTTG
367



GGCTGCGGGTGCGTTACAGGAGAGCAGGCGG






IRF4_chr6:392860-392960
GTAGGAGCCTTCGCGGGGGCCGAGCTCGGAAGGCGGACGGCTGTGCCCGCCCAGGGGATGCGCCCGGGC
368



CGGCCGCGAAGGTGCCTTCTTCCGGGGGCCC






IRF4_chr6:392960-393060
GGACGACCCTGACACGGCACGCGCGCGCTTCGCAGCCTCAAAGACTCCGGGGCCTCGTGGTCACTGGCGC
369



AGGGGATCGGGGCGGGGTGCCCGGAGTGCG






IRF4_chr6:393090-393190
CCCGCAGTGCAGAGCAGAGCGGGCGGAGGACCCCGGGCGCGGGCGCGGACGGCACGCGGGGCATGAACC
370



TGGAGGGCGGCGGCCGAGGCGGAGAGTTCGG






IRF4_chr6:393190-393290
CATGAGCGCGGTGAGCTGCGGCAACGGGAAGCTCCGCCAGTGGCTGATCGACCAGATCGACAGCGGCAA
371



GTACCCCGGGCTGGTGTGGGAGAACGAGGAG






IRF4_chr6:393290-393390
AAGAGCATCTTCCGCATCCCCTGGAAGCACGCGGGCAAGCAGGACTACAACCGCGAGGAGGACGCCGCG
372



CTCTTCAAGGTCTCCGGCCTCGGGAGCCGGC






CD83_chr6:14117992-14118092
CCCGCGCGCCACAGCTCTGCAGCTCGTGGCAGCGGCGCAGCGCTCCAGCCATGTCGCGCGGCCTCCAGCT
373



TCTGCTCCTGAGCTGCGGTAGGGCTCGCGA






CD83_chr6:14118092-14118192
GCGCCTGTCTCGCCTGTCGCCCCCCGCCCCTCCACGACACCCCCTCCCGTCGGTCGCTTGCTCACGACGCG
374



CTCTCTCTTTCTTGTAGCCTACAGCCTGG






CD83_chr6:14118192-14118292
CTCCCGCGACGCCGGAGGTGAAGGTGGCTTGCTCCGAAGATGTGGACTTGCCCTGCACCGCCCCCTGGGA
375



TCCGCAGGTTCCCTACACGGTCTCCTGGGT






CD83_chr6:14118292-14118392
CAAGGTAGGTGCTGCGATACCCACGGGCTGGGGTTTGGTGGGCTCATTTGAAGACAGCAGGAACCATCTC
376



CCCTAGGCTGGCGACCCTCTGTGGCTGCCA






CD83_chr6:14118392-14118492
GGTGGGGGCGAGGGGCGTCTCCCGCAGCTGAACTTGGAGTACCCAGCCTCCCGTCGCGCCTCCCCCACCC
377



CATCCGCATCCAGGTACAGGGCCGAATTAG






CD83_chr6:14118492-14118592
GTTTTGCTCTCCGCAGACCTCAATCCCCTTCCTGTCACTGAAGGTGGCCTGAGATGAATGATCCACTTAAG
378



ATGTTTTGGAAGGGCAGAGACTCTCATTT






CD83_chr6:14118592-14118692
GGATTAATTCTGGAGGCCACCTGTGGTTGTGGGCCAGCAGGTCAGGAAGAAAGCAACAGGGACCTAGAT
379



TTGGGCATTGGACAGGGGGAATGTCTCCAGA






HIST1H2BC_chr6:26123614-
CTCTCCAGTTCCTATATTCTAATACCCCTCCGCCGCCAAATAAAATTTGGCGTCTGGCCACAGCTCTTTTA
380


26123714
GTGGGTATCTGGGTGGCTCTTAAAAGAGC






HIST1H2BC_chr6:26123714-
CTTTGGGGTTAGGTGTTAAGACGCTTACTTGGAATGTTTACTTGGAGCTGGTGTACTTGGTGACGGCCTTG
381


26123814
GTGCCCTCCGACACGGCGTGCTTGGCCAG






HIST1H1E_chr6:26156649-26156749
CTCCGGCCCCTGCCGAGAAGACTCCCGTGAAGAAGAAGGCCCGCAAGTCTGCAGGTGCGGCCAAGCGCA
382



AAGCGTCTGGGCCCCCGGTGTCCGAGCTCAT






HIST1H1E_chr6:26156749-26156849
TACTAAAGCTGTTGCCGCCTCCAAGGAGCGCAGCGGCGTATCTTTGGCCGCTCTCAAGAAAGCGCTGGCA
383



GCCGCTGGCTATGACGTGGAGAAGAACAAC






HIST1H1E_chr6:26156849-26156949
AGCCGCATCAAGCTGGGTCTCAAGAGCCTGGTGAGCAAGGGCACCCTGGTGCAGACCAAGGGCACCGGC
384



GCGTCGGGTTCCTTCAAACTCAACAAGAAGG






HIST1H1E_chr6:26156949-26157049
CGGCCTCTGGGGAAGCCAAGCCTAAGGCTAAAAAGGCAGGCGCGGCCAAGGCCAAGAAGCCAGCAGGAG
385



CGGCGAAGAAGCCCAAGAAGGCGACGGGGGC






HIST1H1E_chr6:26157049-26157149
GGCCACCCCCAAGAAGAGCGCCAAGAAGACCCCAAAGAAGGCGAAGAAGCCGGCTGCAGCTGCTGGAGC
386



CAAAAAAGCGAAAAGCCCGAAAAAGGCGAAA






HIST1H1E_chr6:26157149-26157249
GCAGCCAAGCCAAAAAAGGCGCCCAAGAGCCCAGCGAAGGCCAAAGCAGTTAAACCCAAGGCGGCTAAA
387



CCAAAGACCGCCAAGCCCAAGGCAGCCAAGC






HIST1H1E_chr6:26157249-26157349
CAAAGAAGGCGGCAGCCAAGAAAAAGTAGAAAGTTCCTTTGGCCAACTGCTTAGAAGCCCAACACAACC
388



CAAAGGCTCTTTTCAGAGCCACCCACCGCTC






HIST1H1E_chr6:26157349-26157449
TCAGTAAAAGAGCTGTTGCACTATTAGGGGGCGTGGCTCGGGAAAACGCTGCTAAGCAGGGGCGGGTCT
389



CCCGGGAACAAAGTCGGGGAGAGGAGTGGGA






HIST1H2BK_chr6:27114004-
CTCCTTAGCCAGACTCGATTACAAGCACTGCATGCATTACTCAGTGTGATAAGATCATGATAATCCCTTTA
390


27114104
AAAAGATCGCCCGAATTTAAGCCTGGATT






HIST1H2BK_chr6:27114104-
AGGAACACGTGTTTACAGCTCTAATATCGATAATTTAAGTGGCTCTTAAAAGAGCCTTTGGGGTTGGGCT
391


27114204
TTAAGACGCTTACTTGGCAAGTTTACTTAG






HIST1H2BK_chr6:27114204-
CGCTGGTGTACTTGGTGACGGCCTTGGTGCCCTCGGACACGGCGTGCTTGGCCAACTCCCCGGGCAGCAG
392


27114304
CAGGCGCACGGCCGTCTGGATCTCCCTGGA






PIM1_chr6:37138284-37138384
CCCCGGCTCCGGCTCCTGCGGCAGCTCCTCTGGGCACCGTCCCTGCGCCGACATCCTGGAGGTTGGGATG
393



CTCTTGTCCAAAATCAACTCGCTTGCCCAC






PIM1_chr6:37138384-37138484
CTGCGCGCCGCGCCCTGCAACGACCTGCACGCCACCAAGCTGGCGCCCGGTGAGAGCACCCCCCGCCTCC
394



GGCCCGGGGATGCGGGGCGGCGGCGGGATC






PIM1_chr6:37138484-37138584
TCCTGGGTGGGGAGCTGGCGGCTCGCGGGCCGGCACTGAGTCCCCGTGCTTCCCCCTTTCCTAGGCAAGG
395



AGAAGGAGCCCCTGGAGTCGCAGTACCAGG






PIM1_chr6:37138584-37138684
TGGGCCCGCTACTGGGCAGCGGCGGCTTCGGCTCGGTCTACTCAGGCATCCGCGTCTCCGACAACTTGCC
396



GGTGAGTGGGCGCCCCGCGGTGGGGAGGGC






PIM1_chr6:37138684-37138784
GCGCCGGGCGGGGGGCGCACGGGCGTGCTTTAGCCCGGACGAGGGAACCTGACGGAGACCCTGGGCTTC
397



CAGGTGGCCATCAAACACGTGGAGAAGGACC






PIM1_chr6:37138784-37138884
GGATTTCCGACTGGGGAGAGCTGGTGAGTGCCCTGCAGGAGCGACCCCCAGGATGAGTGGGTGGGGTGA
398



GGGGCGCCCCCGACTCCCGCCCTAACGCGGC






PIM1_chr6:37138884-37138984
CCCCTCGCCCCTGCAGCCTAATGGCACTCGAGTGCCCATGGAAGTGGTCCTGCTGAAGAAGGTGAGCTCG
399



GGTTTCTCCGGCGTCATTAGGCTCCTGGAC






PIM1_chr6:37138984-37139084
TGGTTCGAGAGGCCCGACAGTTTCGTCCTGATCCTGGAGAGGCCCGAGCCGGTGCAAGATCTCTTCGACT
400



TCATCACGGAAAGGGGAGCCCTGCAAGAGG






PIM1_chr6:37139084-37139184
AGCTGGCCCGCAGCTTCTTCTGGCAGGTGCTGGAGGCCGTGCGGCACTGCCACAACTGCGGGGTGCTCCA
401



CCGCGACATCAAGGACGAAAACATCCTTAT






PIM1_chr6:37139184-37139284
CGACCTCAATCGCGGCGAGCTCAAGCTCATCGACTTCGGGTCGGGGGCGCTGCTCAAGGACACCGTCTAC
402



ACGGACTTCGATGGTGAGCCAGGCCCGGGA






PIM1_chr6:37139284-37139384
GGGAGCTGCCCAGGTGACTCGGCCCGGCCCGGCCCAGTCCGGAGGCCTCGGCCAGTCTCCCGCGCCAGCC
403



TTTTGTAAAGGTCATTGGGCCGCCTGGCTC






PIM1_chr6:37139384-37139484
GATGCTAGCCGGGGTGGGACGCAGGAGAGCCTCCCAGCGTAGTAAAGCCGGGGATTTTCAGCCAGCTGA
404



ACCTGTAATGTTTCTGGCATGATTTTATTCT






PIM1_chr6:37139484-37139584
TCAAGTGGAATTCAGTTAGTTCCAGGCTTTCCCGATGAATAAGAGGTTGTGGGCAACCGGCGGTAGCCCA
405



GATTTTTCTAAAGTCTGACCCAGTTTCCCC






MAP3K7_chr6:91004618-91004718
CTCTAAACAGACAAAAGCAAAATATCTCATTAGGCATCATCTCCGCCAAGGTTCCCACTAGGCAGGAAAG
406



GATTTTTATCTAAAGTAATTACCCTTTTTA






MAP3K7_chr6:91004718-91004818
GTTAAATACACTCAACAGATGAAATTTACAGAGAGTGAGAGACTGCAGCACTAGACAGCGAAGGTGAAA
407



ACCAGGAACGCCGCGTCTCGCCGCCCGCGGG






MAP3K7_chr6:91004818-91004918
CCCGCCGGGAGACTGCGGGTCCGTCTCGCGGGTGGGGCGCCCCGGTCCCTCTCGTTTCCTGGAGGCCACA
408



GGTCACGGCGACGGCGGTGACCGGGAGAGC






MAP3K7_chr6:91005793-91005893
CGGGTCTGACAGCTGCTGCGGCTCGCGCGGACGCGCGCCTCCTGCAGCCCGCCCTCCCCATGCCTGACTT
409



ATTACTCTCTGCTCCTCCTCCCTCTGCTGT






MAP3K7_chr6:91005893-91005993
TCCAAAACACCCTTCGACGCCAGCAAAATACAATGCGCCTCGGCCGCCGTAAACAGCCGGGAGGGAGAG
410



CACACATTCGGCGCGGCGCGGCCGCCGGCTC






MAP3K7_chr6:91005993-91006093
GGCTCCCACCCCCTTCCCGTTCCTAGAAAATGCCATAAAAGCGGGCAGGGCGCGGGGAGGGCGGCTGCGC
411



GCCCGGCGGCCGGGGCTCCCTTCCCGCGCC






SGK1_chr6:134493732-134493832
TATGAAACAGCCAGTGCTACGTCTCCTTTATACCAAAACTGGTAGCCTGAAGAGCTCTCAGGCTTACCTAT
412



AAACGATGTTCAGTGAATGCAGGTAGCCC






SGK1_chr6:134493832-134493932
AAGGCACTGGCTATTTCAGCAGCATAGAAACGAGCCCGTGGTTCCAGGAAGCAGCGTTCCCTCTGGAGAT
413



GGTAGAACAACTGCAGGAGACAGAACAAAG






SGK1_chr6:134493932-134494032
TCATTCTGGGTTGCAAATGAATTTAATTAGTTTTGACATACACAGCAAAAGAACAACTGCAGGAAGTGGC
414



CCCAAGTAATCTATTAACTATAAACCTGAC






SGK1_chr6:134494032-134494132
AGGTTGAAGGAAATGCTAATTCTGGTAACATTCTCCCCACCAAAAATCTTTGAAAACTTTTTTCTCAAACT
415



AAAACAAAGCAGGCTGTGCAGAGACACTA






SGK1_chr6:134494132-134494232
AGAGTTGACTTCTATCCCCCCTGCTCACCTCTCCACCATTAATGTAGTCTAGGACAAAGTACAATTTGTCA
416



GCAGTCTGGAAAGAGAAGTGAAGGCCCAC






SGK1_chr6:134494232-134494332
CAGGAAAGGGTGCTTCACATTCTTCAACAGAACATTCCGCTCCGACATAATATGCTTCTCCTAGGAAAAT
417



GACGATTCAGATTTAGTGGCATGTTTCAAC






SGK1_chr6:134494552-134494652
GAGGACATGAAGGAAGTGTACCAAAAGATCTTCAGATTTGAAATTACCTTTCCAAAACTGCCCTTTCCGA
418



TCACTTTCAAGAAGTGAAAGTCAGATGGTT






SGK1_chr6:134494652-134494752
TAGCATGAGGATTGGACGACGGGCCAAGGTTGATTTGCTGAGAAGGACTTGGCTAGAAAAAAAAAAAAA
419



GAATTTCTTTTAATACCATTGCTTCAAAGGA






SGK1_chr6:134494722-134494822
AATTTCTTTTAATACCATTGCTTCAAAGGAAGACATCTATAACATAAACGATGTAGAAAATGTTACATCTA
420



CAAATGACTGATGCAAATGACCATACATC






SGK1_chr6:134494967-134495067
AATAAAATAATACTCTGACTCAATACTTAAATATTTATATCACTTGTTATGCCATAATGAAGCATTCCTGC
421



CTTGATACTAATTTCTAGAAATGCTATTT






SGK1_chr6:134495067-134495167
TAATCCATTAATGTAGGAATACTAACTGACTCCCTTACAGTTCTCCACAGATGCACGGCACATACAAAAA
422



CTTACTGGAGGAGAAGGGTTGGCATTCATA






SGK1_chr6:134495167-134495267
AGCTCAGGCTCCTGAGGTTGGGAGATCTTCAAGATGGACTGAACTTCAGGGCTGCAGGGAATAAAGGGC
423



ACGATTTAGAATCCAGCTCGCCACTAGGGGG






SGK1_chr6:134495267-134495367
CACACCAACATCAAAAGTGAGTTTCTGGCTCTACCGACTTCTACCCGGATAATTCACTGTTTAAACTGAAA
424



ATACCCCAATACATTAGTCAGTTAAAGAA






SGK1_chr6:134495367-134495467
AATAATAAACCCCATTAAATACAGAAATAAGGATTGTTGCTCATGGAGAAAGGCCGTGAATTCGGCCAAC
425



ACGAACCATTTATCTTACATCTCCAGTTCA






SGK1_chr6:134495467-134495567
AGCCAAATCAGCAAATTAACTTTAATGTTTAAAATGTGTCAAATATATTAGAATTTAAGGAGAAATGAGA
426



TCCCCACCCCAGAAGAAGTCTTCGCCTTCC






SGK1_chr6:134495567-134495667
CGATAAACGCCGTGATGAGAATGTTTACCGCTGGCAAATTCAAACTATACTAGTTATTTCCTCAAATCCGG
427



TCAAACTTACTGTTTGCATGCATAGGAGT






SGK1_chr6:134495667-134495767
TATTGGCAATCTTCTGAATAAAGTCGTTCAGACCCATCCTCCTCTGCTTCATGAAAGCTGTGGATGAAGGA
428



GGAGAAATAAAGAAACGTTTAGACGGCTT






SGK1_chr6:134495767-134495867
CATAACGTCCGGCGCCACACACACTAATCTGATCCGGGACTTTCAAAAAATTTCCACTTTGCGTCTCCTGG
429



AGCAGAAGTCCCGCAAGATTCCTGCACTC






SGK1_chr6:134495867-134495967
ACCGATGAGAATTGCCACCATGCCCCTCATCCTGGAGTAAGTGAGGGTGCCCTTAGCAGCCTCAGTTTTC
430



ACCGTCATCACCACCGCGGGGAGACAGAAA






SGK1_chr6:134495967-134496067
GACGTTAGCGCTCAAAGACCGGCTCGGCGTATGCTGCGCCAGGCCGCGCGCTCGGCCTTATAAAAAAGGC
431



ACCGCCGCGGGGGCGGGGCCTGCGCGACAG






PLEKHG1_chr6:150954420-
AGGGTGAGAGGAGTCACCAGGTAAAGATGGGTTGGAAGGACCTGGCAGGCAGAGCAGGGAGCAGGACC
432


150954520
CCAGTCCAGGGCAGCAGGGAAGCGGGAGTCTG






PLEKHG1_chr6:150954520-
GGCAGAGCTGATTCCAGGCAGCTCAGTATTGCTGGCCTGTGCATCCTGAGACTTATCCGAGTCGCAGGTG
433


150954620
AAGCTGGTGGGAATCAGGCAGAGTGCAGAG






PLEKHG1_chr6:150954620-
CTTTAGCTGGGGCAGGGTTAGCCAAGAGCCTGTCATGGAGCTGCTCTCTGGGCACTGGGAAACATAAGTC
434


150954720
TGGAGGCTTTGGCTGCAGCTGCAGATAAAG






PLEKHG1_chr6:150954720-
ATGCAGGGGCCTCTGACGATGGGGGCCTTAGTCATCTCAGAGGTGGTGCAGAGGGTAGAAGCCTGACTG
435


150954820
GGGTCAGAGATGAGGAAGGAGAGGGTCAGAA






PLEKHG1_chr6:150954820-
ACAGTGATTCTAAACCAATTTGGTTGAGGCAGAAGATACTAATGGCCGAGGGGAGGAGAGAGGGAGCGT
436


150954920
AGGCTCTAAAGGGGAAGCTTGTTAGGAATGA






EZR_chr6:159238415-159238515
AGACAGAGGCGCAGGCACAGCCCTTTCATCAGCTGACCAGGAGTGCTCGGCCCGGCCTGCCAGGAACCTC
437



TTATCAAACTCCACCGGCTGCCTGCATCTA






EZR_chr6:159238515-159238615
CAATTCAAGTCCATGGCTAACCTTCTGTTAGAGACAGAAATTCTGCTGCAGCCAGCAAGTTTGCTGGTGT
438



ACAGGGCACCGCTTCATGGGCCTAGTAGGA






EZR_chr6:159238615-159238715
AGCGAAGCTGAAAGGCAACTTCCGAAAGCCAGTCTCCTCTCCCAAACGCCCTTTAATATCTCCCCAGTTG
439



GATCTGGGGCGCCTGTGGTTTCGGACCCTT






EZR_chr6:159238715-159238815
AGGAGCTCTGAGAACTGGTGTGTGTGGTCGGAAGCCATCTGAGTCTCCCTGTGATTTGGACTTTTTAAGA
440



AACTTCTAAGTTGTATTACTATACCCTTTA






IMMP2L_chr7:110545276-110545376
TTCCCTTGTCATATGACTTCCATCCTCAGCACTACAATATTATCATTAATGTTTAAATCATTGTCAAGTCTG
441



TGATTGCCTTAGAGATTTATTAAGAATA






IMMP2L_chr7:110545376-110545476
ACATGCTAGGATTAGGAAAGTTTAACTTTTTACCATCCTTAAAATTAGATTTTTGAAAACTGTCTTATCCC
442



CATTAAAGAAAAAAATAAAAAGGATGAAT






LRRN3_chr7:110697971-110698071
TATACATACCTGCACATATATACAGCATATGTATATGTGTCTGTATTATATGTATTAAATGAAAGATTATC
443



CACATTTTGTTCTTTAGGATCTTCAGCAG






LRRN3_chr7:110698071-110698171
CTCTCTTCCCATCACAATAGAAAGGCCTGAGCTAACATTTCCATTTCTGCAAAAGGCAGATTTTGTTCAAT
444



TAAAAATTATAATGCCTTAAATTTCCACA






LRRN3_chr7:110737411-110737511
GACATTTAAGAGACTTCGTTTTCACTGTGATAAACAGGTTTGATTTGGACTTATAACTTTTTTCTAAAATT
445



ATCAAATTAATAACGACTATAATGAAATA






LRRN3_chr7:110737511-110737611
GAGGCAAATATTTTAGAGGATTCATTCCTTGGGGTAACATTTGTTCTATAATTTATAGTCTCATAATGTTG
446



AGAGATTAAAGCATTTAAATAACATTGTC






LRRN3_chr7:110737611-110737711
AACTAACTTTCAGCTTACCTTTCTTAAGGAAAAAAAACAAAAAAATGTTAAAAATAGACATGTATTTTTC
447



AAACATACAATTCATGTTTTTATGTCATTA






LRRN3_chr7:110746681-110746781
AAGAGATGTGAGGGACTTATAAATAATATTAAGATAACAGGAATTAAAGTCTCGGTGTGTGAAAATACTG
448



TATATCTAGGATGCACATAAAAACTGCCCT






LRRN3_chr7:110746781-110746881
TACAGATCTTGCAGGGAAAAGTACCTGACTATACTGTATAAGACTTCTGCTGTACCATTTAATCATACCAA
449



AAAAAATGGAATCAACACACAAATAGATT






LRRN3_chr7:110746881-110746981
TCTTTTCCACTGTTCTCAATTTAAAAATAATTGGAGAAATGTGTGCTTTGTTTAGAAGAGTAAAGGAAAAC
450



ATTCATTCAATAGTACCATGCAGAATGAT






KMT2C_chr7:151943421-151943521
CAGAAAAATAGAAAGATTATCATCGGATTTGGGAATCAAAGACAGCTCAGCAAAATACTAGGACATGGC
451



TCATATAAGATGGAATAAGCCTGGAAATACA






MYC_chr8:128750367-128750467
CTTTAGGGGATAGCTCTGCAAGGGGAGAGGTTCGGGACTGTGGCGCGCACTGCGCGCTGCGCCAGGTTTC
452



CGCACCAAGACCCCTTTAACTCAAGACTGC






MYC_chr8:128750467-128750567
CTCCCGCTTTGTGTGCCCCGCTCCAGCAGCCTCCCGCGACGATGCCCCTCAACGTTAGCTTCACCAACAGG
453



AACTATGACCTCGACTACGACTCGGTGCA






MYC_chr8:128750567-128750667
GCCGTATTTCTACTGCGACGAGGAGGAGAACTTCTACCAGCAGCAGCAGCAGAGCGAGCTGCAGCCCCCG
454



GCGCCCAGCGAGGATATCTGGAAGAAATTC






MYC_chr8:128750667-128750767
GAGCTGCTGCCCACCCCGCCCCTGTCCCCTAGCCGCCGCTCCGGGCTCTGCTCGCCCTCCTACGTTGCGGT
455



CACACCCTTCTCCCTTCGGGGAGACAACG






MYC_chr8:128750767-128750867
ACGGCGGTGGCGGGAGCTTCTCCACGGCCGACCAGCTGGAGATGGTGACCGAGCTGCTGGGAGGAGACA
456



TGGTGAACCAGAGTTTCATCTGCGACCCGGA






MYC_chr8:128750867-128750967
CGACGAGACCTTCATCAAAAACATCATCATCCAGGACTGTATGTGGAGCGGCTTCTCGGCCGCCGCCAAG
457



CTCGTCTCAGAGAAGCTGGCCTCCTACCAG






MYC_chr8:128750967-128751067
GCTGCGCGCAAAGACAGCGGCAGCCCGAACCCCGCCCGCGGCCACAGCGTCTGCTCCACCTCCAGCTTGT
458



ACCTGCAGGATCTGAGCGCCGCCGCCTCAG






MYC_chr8:128751067-128751167
AGTGCATCGACCCCTCGGTGGTCTTCCCCTACCCTCTCAACGACAGCAGCTCGCCCAAGTCCTGCGCCTCG
459



CAAGACTCCAGCGCCTTCTCTCCGTCCTC






MYC_chr8:128751167-128751267
GGATTCTCTGCTCTCCTCGACGGAGTCCTCCCCGCAGGGCAGCCCCGAGCCCCTGGTGCTCCATGAGGAG
460



ACACCGCCCACCACCAGCAGCGACTCTGGT






PAX5_chr9:37024919-37025019
GCTCCCCATCTGTCCCCACAGTTGCTCCTTGGCTGAGCCAAGGGCTTGCTCACCTCTCAGAGCATTGCCCT
461



AACTGGTTTGTTTTGGGCTTACATTGCAA






PAX5_chr9:37025019-37025119
GATCAGGTCCTCCCCAGAGCCAGGCTGGAGTCCGAGGCAGAAAAGGCTGTGGAGGGCACTGGGGTCACC
462



ACAGACTGGAAACCGGTTGGGCGCAGGCCCC






PAX5_chr9:37025119-37025219
AAACCTTGAGGAATCGTTTGGGCTGGGACCAGAACAGGGGGCTCCTCTGCACAGAGCTCCCCACCGCTTT
463



GGTGGATTACTTCAGACTCAGAAAATTGAC






PAX5_chr9:37025219-37025319
ACAAAGAGAAACTGACCTGCCCGCAGCCAGCCCTGGCTGCCTACACAAGCTTTCCCCTGCTTGCCAGGCC
464



ACTCAGCACTGCGTGGCAGACACGGACATG






PAX5_chr9:37025319-37025419
CTCGCCCCGGGAAGCTCACCTTCACTCCAGCCGGGTCTCTGCTGCCTTTGTTAAATAGGGGACCTGCGGCT
465



AGGAAAGCTGGATCCCAGGCTGTTGGGAT






PAX5_chr9:37025419-37025519
GGGGGGGAGCGGGGTGGGAGGACCAGGCATGGGGACGGCTCCTAGCCCGGGAGCAACTCCCTGACCTGA
466



AGCCCGCAGAGACCCCGAGCGGCACCCGAGC






PAX5_chr9:37025519-37025619
CGAGGCTGCCGAAGCCTGTCACCTTCCTCCAGCCTGGCTCTGCAGCAAACAGAAAGGAAACGCGATTCGT
467



TCCACTTGGAATTTCCTTGAAATCTCCGAA






PAX5_chr9:37025619-37025719
TCTAATCCGGCGTTAACTCACCGTGAGAGGAGCGCTCATCTCACAGGAGGCTGTGGTAATGGGTGAATTG
468



GCAGGATCCCTGCGGGCCAGGCAGCCAGGC






PAX5_chr9:37025829-37025929
TTTTCGTTTCTTATCCTCTTTTTTTAAAGGGGAGAAGCCATGAGAAAAGGCGTCCTGCAGAGAAGGACCC
469



AATGGGGTCTTTAAGGGTCTCTGTATGAAC






PAX5_chr9:37025929-37026029
TGGCCGGCTCCTAAGCAGAAGCTGAACTCAGAAACCGCTACTTCCTTGATTTTTCAAAGCCCCCTCCTCAA
470



CTCCAGGACGCCTTTGGAGCCCTAGCCCC






PAX5_chr9:37026269-37026369
TGTCGCCGCCGGAGCCTTGAAAGGCTGCAGCTCGCTGCCCAAGCTACGCGTTGCCGGAGGCGGGATTCCC
471



AGGTGCCTCAGCCCGGGCGGCCAAGTGCGT






PAX5_chr9:37026369-37026469
TGTTTCAGGTCCCCTGCCTGGGATCCCTGCACTTTGCAAAGTTAGCTGCGCGGCTGCAGAGGTCCGAGATC
472



CTTCCGGCCTTAGTACCTGACCCACGGTC






PAX5_chr9:37026469-37026569
CGGCACCCCCAACCCGGTCCCGGCGGGAGAGTGAGAGAAGCGAGCTCGCCGCCTACTTACTATGCATGGA
473



TGCAAACGGGTCGTGCTTACAGTGTATTTC






PAX5_chr9:37026569-37026669
CATCGGGGCGCTCCAGACTGCAGGCCGGCCCACGCCGCCGCCTCCCGGCGCCAAGGGGCTGCCCAGGGCG
474



GATAGGGAGCCTCGCCACCAGGCCAGGCAC






PAX5_chr9:37026669-37026769
TGTGCGAGCTGGGCTCAGAAAACACTGCTGGAGCTTCGGGGTCTCTCTCAGAGCCTCCCTGCTGGAGACC
475



GCCCGGAGCTGCGCGGAGAGGCGGGAAATG






PAX5_chr9:37026769-37026869
GTGCTAGCGCACCCGGGCTAGGAGCGGGTGCCCAACTCCGGCTGGCTTCCCTCCCTGGCTGGCTCAAGCA
476



GCAGCTCCGGGCCCAGCCCGGGGTAGCTGC






PAX5_chr9:37026869-37026969
GGCCAAGGCGCCCGCGGCTTCGGGGGCATAGCGTAGGGGCCCGCCTCCGGGACAGCCAGCAGCCCCCGG
477



CCCCAGGAAGGAGCAGCTTTGAGGAGGCCGC






PAX5_chr9:37026969-37027069
CGGAACAATCGGCCCTTGACTTCACTCAGGGGGCGGAGAGACCCGGGGGCTGCCAGGCTGGTTCCGCGGC
478



CTCGATGCTTCTGAGGTCCCTCCTCGACCC






PAX5_chr9:37033619-37033719
CACACAGGCAAACAACTTTTGGACACAAACTCATATATTTTTACATCTTTTAAAAATACATATACTGTAAT
479



GAACACACTGAGTCCCTTATATAAACACA






PAX5_chr9:37033719-37033819
CAGGCCCTAACTTGCAGACCCCCGGAAGGACGCCAGCGTGAACATTCAGAAACAGAGAAAAACACAGAC
480



AAACTCACAGATATTTGGACTGATGCAGAAG






ZCCHC7_chr9:37293169-37293269
ACAGTTTGAAGTGTGAGCCTGAACATGTTTGATCTAAGGTCTGGAGGAAGATGTGAAGCAAATCTGACCT
481



AAAAAAAATTATAGGAAAAAAGCAAATTGT






ZCCHC7_chr9:37293269-37293369
TCTGGATTTGTTTCACCAAGGAACAAGTAAGCAGAGAACCAGACACTGGAGAAAAAAAGGAGTCAGGAA
482



GTAGACAAGGAAATGTTAAAAGAAATAATAG






ZCCHC7_chr9:37293369-37293469
GATAACTGAAAGAATGTAGCTTCCAGATTGCTAGCTATCAGCAGATAGATAGAAACTTTTATACAGCCTT
483



TAAATCTTCCCTAGAAACCTTTTTAAAAGT






ZCCHC7_chr9:37371494-37371594
CAAGGGCCTGCCAGGATGAGAACGGGCAAACCTGGCCAAGGTGACCCCATTAGGGACTACCCTCCTAGG
484



GACAGCACTCAGGGCCGTTCCCAATCACCCC






ZCCHC7_chr9:37371594-37371694
GGATTTCCTGTCCTGCTCGTCTCCTGCCACACCTCCTTTTGATCTACCCCCAAGACACCCCTACCTTTTTAT
485



TCTGTGAAAATTTACTCATGCTGTGGGC






ZCCHC7_chr9:37371694-37371794
CCTGCTGGAAATGCCCTCCTACTGTTTCCCCAAACCCCGTCAGAAATTCCACGGGGAAACTCCCTTCCCTT
486



CTGCTGCAGGCACCGTCACTGTGTCTCTC






ZCCHC7_chr9:37371794-37371894
AGCTCTGCCCCCCAGCCTCTGAGTACCACCTTATCCTAGCCCTTAGCTACTGGCTTGTCATTGTCTCTTTAC
487



GTTCTCAGCCTCCCACAGAAGCCTGGGA






ZCCHC7_chr9:37384684-37384784
AGGCACACTCGCCCCTGGTCTCCAAGGCTCTGGGTCCTCAGACTGGCTGAGTACTGGGGACCAAGGTCAC
488



CCAAGAAGCCCTGAGTGGCCCTCTTGAGGG






ZCCHC7_chr9:37384784-37384884
TTAGCAGAGCTTCTCTCTGTCCAAGACAGGTCAGGCTCTCTCCCCTGGCCCCAGCTCCACCGTCACTCAGA
489



GGAGTGGCCTAAACAAACGCTGCAGGTGA






ZCCHC7_chr9:37384884-37384984
GGCTCCCGAGCCCCTGACATGGATGTTTATGGAAGAGGACTCTTGGCATCAGCACCTGGGCAAGGTGGGT
490



AGAGGCAGGAGTGGGCAAATGGGAAAGTCT






GRHPR_chr9:37407369-37407469
GGAGAGCCGTTTGAGATTCACCAGGTGAATGAACCCCGGTTTTTTTCTGGGTAACAGGTCGAATGTGAAT
491



TACTTATTTTCACAAGCTCTTGACATGTTC






GRHPR_chr9:37407469-37407569
CGTCAAATTGCTGTTCCCCAAAGAGTGGACTCTGGTGACATATAAGTGTGTGGGACCATTGCATCTTACCC
492



CAGAGATCCACTCCTGATCTGGCATTATT






GRHPR_chr9:37407569-37407669
CAAAATCTGCTGAATTCAAAACGATCCTGTACTTCCTGCTCACCAGGTCTGAAAAGAAAAAAGAAAAAAG
493



AAGAAGGAAAGACTACACCTGACAAAAGAC






FAM208B_chr10:5755066-5755166
TTCACGGTTTCTCTTTAGTTTTATCTGAAATACATTTGTAAGCTTAGGGTGCAATTTGGATTAAAACAGTT
494



TTCTTTAGTGTCAATAATGGCCTTTACTA






FAM208B_chr10:5755166-5755266
GAGTGAATGGATATTTTTCCATTCTGGATTATCGTTTAATCGAAACTTTGTTTCCTGTGGAAATTTTTCTG
495



GTTTAAGTTATTTGATTTGGGAGATAAAT






FAM208B_chr10:5755266-5755366
CATGTAACTTAATAAACTTTGGCATCCTGGTTAACTGAAATTGCTTCATTCAATATTTGAAGACTGAAATC
496



TGTATTGTTGCCTGTACCTAAATTATGGG






FRMD8_chr11:65190342-65190442
GGACAGACAGGGAGAGATGACTGAGTTAGATGAGACGAGGGGGCGGGCTGGGGGTGCGAGAAGGAAGC
497



TTGGCAAGGAGACTAGGTCTAGGGGGACCACA






FRMD8_chr11:65190442-65190542
GTGGGGCAGGCTGCATGGAAAATATCCGCAGGGTCCCCCAGGCAGAACAGCCACGCTCCAGGCCAGGCT
498



GTCCCTACTGCCTGGTGGAGGGGGAACTTGA






FRMD8_chr11:65190542-65190642
CCTCTGGGAGGGCGCCGCTCTTGCATAGCTGAGCGAGCCCGGGTGCGCTGGTCTGTGTGGAAGGAGGAA
499



GGCAGGGAGAGGTAGAAGGGGTGGAGGAGTC






SCYL1_chr11:65266552-65266652
GGGGCAGGCGGAGCTTGAGGAAACCGCAGATAAGTTTTTTTCTCTTTGAAAGATAGAGATTAATACAACT
500



ACTTAAAAAATATAGTCAATAGGTTACTAA






SCYL1_chr11:65266652-65266752
GATATTGCTTAGCGTTAAGTTTTTAACGTAATTTTAATAGCTTAAGATTTTAAGAGAAAATATGAAGACTT
501



AGAAGAGTAGCATGAGGAAGGAAAAGATA






SCYL1_chr11:65266752-65266852
AAAGGTTTCTAAAACATGACGGAGGTTGAGATGAAGCTTCTTCATGGAGTAAAAAATGTATTTAAAAGAA
502



AATTGAGAGAAAGGACTACAGAGCCCCGAA






SCYL1_chr11:65266852-65266952
TTAATACCAATAGAAGGGCAATGCTTTTAGATTAAAATGAAGGTGACTTAAACAGCTTAAAGTTTAGTTT
503



AAAAGTTGTAGGTGATTAAAATAATTTGAA






SCYL1_chr11:65267397-65267497
TTGGAGAAGTATAGAAGATAGAAAAATATAAAGCCAAAAATTGGATAAAATAGCACTGAAAAAATGAGG
504



AAATTATTGGTAACCAATTTATTTTAAAAGC






SCYL1_chr11:65267497-65267597
CCATCAATTTAATTTCTGGTGGTGCAGAAGTTAGAAGGTAAAGCTTGAGAAGATGAGGGTGTTTACGTAG
505



ACCAGAACCAATTTAGAAGAATACTTGAAG






SCYL1_chr11:65267597-65267697
CTAGAAGGGGAAGTTGGTTAAAAATCACATCAAAAAGCTACTAAAAGGACTGGTGTAATTTAAAAAAAA
506



CTAAGGCAGAAGGCTTTTGGAAGAGTTAGAA






BIRC3_chr11:102188381-102188481
TGGTGTAAGAGATGTGCCAGCGGCTGGCCGAGGGGCGCTTAGGGCTAGAGCCCGGGGCGCTGCAGAGGT
507



TGAGAGTCAGTGGGTGGGGCGCAGTTATCAA






BIRC3_chr11:102188481-102188581
ACACCAGGGCCCAAAAGCAGGCTCTAGATAGGTTCCAGGTGCTCAATTTCTATTTCACGTTTGGAGTGAG
508



CCAGTGGAATTGTGAAGTTGTGGCATTTTG






BIRC3_chr11:102188581-102188681
ATTCGGTTGCCAAGAGTTATCACTGGGCCTTTGCAGGTGCCAAATAAATTTCAGGACAGAGCCTAAGGCA
509



GAGCTCTGGCACAGGAAGGAAGTAAAACGT






BIRC3_chr11:102188681-102188781
TTAATGAGCAAATGGACGCATGTTTCCAAGCGGTGGTAGGAAGACAGCAGTTTTTGGTTGTCTTCCTGGT
510



GATCAGCATGGAAACCTAGTAGTGCTCTTA






BIRC3_chr11:102188781-102188881
CTCTGATCAATACATTGTCGAAGGCATGTACCTGATGCTAACGTAACAATAATATTAAATATTGACTTTAT
511



TTGCTATTATTTATTGCTAACATTAAGTA






BIRC3_chr11:102188881-102188981
CTGCTACCTGCTATGTGCTAGGTTTGTCTCTGAAGACTTTACATGTATTTTTCACGTTTAATTATCATAATC
512



TTAAGAAGCAGGTACCATAATTATCTCC






POU2AF1_chr11:111249311-
GGGAAAAAGAATGACGAAAGGCAAGACAGTGGAGCAAGTGAGGACACGCTTCACCGAGCCAGATCTCCA
513


111249411
CTCCTCCCAGGGTATCCACAGGGACAAGTCA






POU2AF1_chr11:111249411-
CACCTGGCAGAAAGCTAAGTCACTCAGCTAGAAACAGGCCCAGGGAATTCAACAGAAGGCTGAAGAGCC
514


111249511
ACTGCTTATGGAAATAAAGCCCCTCCTGTAA






POU2AF1_chr11:111249511-
AGAACTGCATGGCTTTTCCCTCCCAACCCCAAACCCATCCCACATCTGGCTTTTGTTGTGTGAATCATAAA
515


111249611
CTGCCCTTTCTTCACCACAGTGATTCATG






CXCR5_chr11:118754793-118754893
AATCCTCTCCCACTGTGGATCTGTAAAATCTAGACAGGTCAGTCAGCTCCCGCCCTTTAAGAGTTTATTTT
516



CCATTCTGTGGAAGAAGCAGATAAGGAGA






CXCR5_chr11:118754893-118754993
GCTGCTGTCCTTAGGAGACATCCTTTAGAGGAAGCTGGAAGACACGGGTTCAGGCCCTGCATCCTCCTCT
517



GAGTTGCTATGTGACTGGGAACAGGATACT






CXCR5_chr11:118754993-118755093
TCACCTCTCCATTCTTTCTCTCCTTTTCTCTTAGGGTCGGAATATGGAACTAGACAGGAAAGTACTTTGGA
518



GGTTTTCTTACCGTAAGGAGGCTGGCATT






ETS1_chr11:128391383-128391483
GGGCCCTCCACCCAGCCTCAGTTCTATGGGGGACGTGGAGTCAGGCGATGATGTCCTCTGAGGCAGCGTC
519



CATCTCCCCTTAACATTAAGGAATAAGGCC






ETS1_chr11:128391483-128391583
AGAGGGTTCTCGCTCATTTGGGAAAATAAAAAAAGCAGGAATGGGGCGCTGGAAATTCTATAAGCTTTTC
520



CCCACCACTCACAAAAACACAGCTGTGAAA






ETS1_chr11:128391583-128391683
ATAAATACCACCCCCCAAACCAAGGGTCTAGGGCCACCAACAGTCCTCCTCCTCCTCCTCCTCCTCCTTCT
521



CCTCCTCGTCCTCCAGATCCAGCTGCCAA






ETS1_chr11:128391648-128391748
CCTTCTCCTCCTCGTCCTCCAGATCCAGCTGCCAACAGCATCCCCCGCTCCTGAAGAAATGCACCGCCCAG
522



AAGGGAACGGCGAAAGGGGGAAGAAGTCC






ETS1_chr11:128391748-128391848
AGGGGACCCCCGGCCTCTGGCCGAGAGCTTGGGTGGGGGCCTCGGCCGTCGCCACTCACCCGGGGAGGG
523



GAAAAGCTCCAGATCGACTTTTTCCGTCTTG






ETS1_chr11:128391848-128391948
ATGATGGTGAGAGTCGGCTTGAGATCGACGGCCGCCTTCATGGTGCCAGGAGTGGGGGACGTACGGGAT
524



GGTAGCAAGTTTGCAGTTACTGTTGTTTTTC






ETS1_chr11:128391948-128392048
TTTTTAATGAGGATTAGTAACAGGGGGAAGGGGACGGGGGAAATCCGACTTTCTTCCCAAAAATCTCAAA
525



TTCCCGCTGCCTTTCTTTCCCCCGCGCCCG






ETS1_chr11:128392048-128392148
GACGGTGCGCGCCCGGCACTCCAGGGGAAGTTGGCACTTTGCGGCGAAGTGAGCGCGCTCGGGTCCCAGC
526



CTCGCCCGCGCCGCGCCCGCTCCTCCTGCC






LRMP_chr12:25205888-25205988
GAGTGAGTAGCAAATATTCATTTATGACCCAGTTTTTGTCCACCCTCAGGCGGGGCATAGGACTACAGAC
527



ATTTTTCTAGATTACAGCTAGGATATTATT






LRMP_chr12:25205988-25206088
CCTGAGTTTATGACAATGAAATGGTTTGAGAAGGCAATATTGTGGGGCTTTCAGAGAGGTTTGCTGAGTG
528



GCTAGGTGCATGCATGGGTTTAACCATTAA






LRMP_chr12:25206088-25206188
CTTCCCTTTTTGCCTTTTTATTATAAGCTGGTTTTGTCTGTGGCTGTTTTTTTCTTTTAAAATTAATTAAAAC
529



TTCTCAAAATTTCTAAAAGTAAACAAG






LRMP_chr12:25206398-25206498
GCATTCTCTACATACATCTACATACATATTTTGCATTTTAAAAATTGGAATATTTGTCATTTTTCTGTATTA
530



CCCAAAAGTATATAAACAGTTACCAGAG






LRMP_chr12:25206498-25206598
ATTTATGTGAGAAGACAGTTGTCACATTACAGATGTCAGATTAGCTATAAAATTGTTTCATTCTAGAAACC
531



TAATATGGTAAAAATAAACCTTACTTATT






LRMP_chr12:25206598-25206698
TAGCCATTTATCAGACAATTGCTTTTGTTCAGCCAGTTTCTTGTTCTAGCAGTATAAATATTCTTTTTATAG
532



AAAGTTACTTGGTTTGAGAAATAAACAT






LRMP_chr12:25206748-25206848
ATAAGCTTAAGGTAGGCTAGAGATGAAAAATTTCAGACTTGTGTTTGTTTTGGATTTATTGTACCCTTTCT
533



ACTATTATCTGAGAAAGCTATTTAGGAGT






LRMP_chr12:25206848-25206948
TTAAGAAATAGTCTAGTTTTAAAATAGCAATGGTTTGCCGGACACAGTGGCTCACCCCTGTAATCCCAGC
534



ATTTTGGGAGGCCGAGGTGGGCAGATTGCT






LRMP_chr12:25207088-25207188
GAATTTGCCAGTTTTCAATATTCTGATTCACTCTGTTAAGCTAGTAAGGCAGTCTTTAAATTACACAGTCT
535



GTGTGTTATTTTACTACTGCTCAGAGGGC






LRMP_chr12:25207188-25207288
ATTGGAGAAGGTTCCCTTGTGATTAGAACTGTTCATGTTGAGACATGAATCATAAGGCATTCCAAAGTTG
536



GTTTAAGGTGTGTCTGCTTTAGACACTGTG






LRMP_chr12:25207288-25207388
CCCAGGACTATTCTTTTGCTCCAGTTTTGCCTTTTGATTAAATCAATATTATACCTGAGTTTTATAAACTAC
537



TAAGAATTTGTTCCCCTTCCTCACTGTG






LRMP_chr12:25207388-25207488
ATTTTCTTGCAGTATTTTCTTAGAAGAGTCAACTTTAATAACTTACCCCAAAGTGCACGTTCTTGATATTA
538



TGAACTTGCTATTGTTGTCTTCCCAGTTT






BTG1_chr12:92537875-92537975
TATTGTAGTTTTTGGAAGGGCTCGTTCTGCCCAAGAGAAGTTCCTCCTTACAGCTGATTCGGCTGTCTACC
539



ATTTGCACGTTGGTGCTGTTTTGAGTGCT






BTG1_chr12:92537975-92538075
ACCTCCTGCTGGTGAGGCTTCATACAGCACACAGATGGAGCCATCCTCTCCAATTCTGTAGGACACTTCAT
540



AGGGGTCAACCCAGAGTGTGAGTTCACTT






BTG1_chr12:92538075-92538175
GGGAGAAGCCTGAACAGCTCCTGACTGCTCAGTCCAATCCGCTGTGCTGCCTGTCCAATCAGAGGATCCA
541



TTTTATGGTTGATGCGAATACAACGGTAAC






BTG1_chr12:92538175-92538275
CCGATCCCTTGCATGGCTTTTCTGGGAACCAGTGATGTTTATAATGTTCTATAGAAGAAAAGAAGAACAG
542



AGAAACAACGCTTAGGATCGTTAGCTCCCA






BTG1_chr12:92538275-92538375
CTGCGGATTCCTCCTACCCCAGGCTCCTTTGAGGAGCGAAAATGAAAACTATCAACTTTTTAAAATGTCCA
543



GGATTGCATCCGTTGTTGTGCATGTGCGG






BTG1_chr12:92538375-92538475
GGATGGAAAAAGCGGGCAGGGTTTTAGAAATAACACAGTAGTACCGGACAAAACAATCTCCAGGAACCA
544



ACCGGTTGAGCCGCCAAAACAGGAATCAGGC






BTG1_chr12:92538475-92538575
GCGCAGCCTCGGCCAGTCGGGAAGCCACTGGCACCTATGGCCAGGCGAGAAACTGTTTACTTTCTCCACC
545



CCACCCCAGATGCACACAATGGAGTTGATG






BTG1_chr12:92538575-92538675
GCTTTGGAGATGAGAAGCGCCACCGGACTGTTAACCCCGAAGGGAAGAAAAACAAGCAACCCTAAACCA
546



CGCTCTGGGCAGGGCTGTTAATTGTGCCGGT






BTG1_chr12:92538790-92538890
ACGCAACGGTTGGAGGGGGCTGAGGAAAGGGGACGTCGAACCCACCCCAGCCCCACGGCTCCTTTGTCCC
547



CAAATCCGCCGACGGTCCTCGGACCGCAGC






BTG1_chr12:92538890-92538990
TCCCGCCTCGGTGGGCTTAAGTTTCTTTGTTGTGCGTGTTGTCTTCTCCTCTCCGTTTTGCCAGCTGGGGGG
548



AAGGGGGCGCCCTCCGTCCAGCCCCTAA






BTG1_chr12:92538990-92539090
AGCCTCGCGGGGAACCGCTGTTAGCGGCCACCCAGCGCAACCACACCGGTCCCGCGGCGGGGCCCAAGC
549



GCGACCGGCCCCGGGGCGCTGCCGAGGTTCC






BTG1_chr12:92539090-92539190
CGCAGCCCCGACGGCCGGACTCTGACCCAGGGATGTGGGGCCCGCGTCCCTCCGACGCCCTCGCCCTGCT
550



CACCTGCCAGCAGCTCCTGCAGGCTCTGGC






BTG1_chr12:92539190-92539290
TGAAGGTCTGCAGCTGTCGCTCGCTCGTGAGCCCCTTGGTGCGGAGAAACTTGGAGATGAAGGACACGGC
551



GGCGGCGATCTCGCCTATCATGGTGGCGGC






BTG1_chr12:92539290-92539390
CCGGGTGTAGAAGGGATGCATGGGGGCGGCGTGCGGGGGCGGCCCGGGGCGGCTGGGGCTCGGCGGCGC
552



GGCCCCGACGGCGGAGCAGCCACCCCGGGCT






DTX1_chr12:113495364-113495464
ACGCCGCACCCCTCCCCCGTGCGTTCTGCGGCCACCCAGGCCTTCCAGGACACCGTGGAGAGGGAACAAG
553



GGGGCAGGGACGCCCCCTTCGGCAGGAGCC






DTX1_chr12:113495464-113495564
GTCGGAGAAGGGGGCCCAGACCGGAGGGAGGCGAGAAGCCCCACTGAAGCCGGGCGCAGGGTCTGGGA
554



CGCAGTTGGGAGTGCAAAGGGCTGGCTGAGAG






DTX1_chr12:113495564-113495664
CCGCAGGAGCAGCAGGCTGTGGCCCAGGCCTCCTGGGTGACAGGCCCTGTCTGGCGGGGAAGAGGGACC
555



AAGAGACAACACGGAAGAGGCTGGACCTCGA






DTX1_chr12:113495664-113495764
ACAGGGGCGGCTGCCTCACTCCCTACCTGAGCCAGCCGAGGGGGCCAAGGACTTTAGAGCTGTTTCCTCC
556



GGCATAAGAGAGACACTTGCTTTCCAGGGC






DTX1_chr12:113495764-113495864
AGCACCCTTTATCGGAGAAGGCTCTACAGGGAAGGGGTCTTTGCAGCCTGGATGGCCATCCCACATTCCT
557



TTAACGGAGGTCTCTAGGCCTCAGAGAGAA






DTX1_chr12:113495864-113495964
CCCAGAGTTAGAAAGGAGGCCAGACGGTCCTTGCTGTCCCCCTGGGGAGAGAGGAAGTTGCCGCCTGCTG
558



CCAGGCCCAGGAGGAGCTGGGCCTGCAATA






DTX1_chr12:113495964-113496064
GTGGGGGACCTGGCCCCTGAGGCAGTGGCGGCCATGTCACGGCCAGGCCACGGTGGGCTGATGCCTGTG
559



AATGGTCTGGGCTTCCCACCGCAGAACGTGG






DTX1_chr12:113496064-113496164
CCCGGGTGGTGGTGTGGGAGTGGCTGAATGAGCACAGCCGCTGGCGGCCCTACACGGCCACCGTGTGCCA
560



CCACATTGAGAACGTGCTGAAGGAGGACGC






DTX1_chr12:113496164-113496264
TCGCGGTTCCGTGGTCCTGGGGCAGGTGGACGCCCAGCTTGTGCCCTACATCATCGACCTGCAGTCCATG
561



CACCAGTTTCGCCAGGACACAGGTGAGCAG






DTX1_chr12:113496264-113496364
ACACCCACCCCATGCCACCCGCCCCGCCGAGCCATCACTACCTTGCAGCGTAGGATGCTGAAAATCCCAG
562



TAAATCTGCTGATGCCAAATCCCTTCCCCA






DTX1_chr12:113496364-113496464
TCTCCCTGCCTCACCTCCAGAAAAACAGGGCAGTCTAACCTTGTCCAGTTTAAGACTTGGATTCCAATGCA
563



GCCTCTGAGCAAGCTGTAGGGCCTTGAGC






DTX1_chr12:113496509-113496609
GGGTAGATCAATATCTCTCACAGCTGAGTGAGGATTAAATAAAATTGTGCTCACTGAGCACAGAACCTAG
564



AACAGCAGTAGCATGGGATTGTAGAATAAG






DTX1_chr12:113496609-113496709
GGCTTTACATGCACTTCCTCATTTGATTTTTCCCAAGAATCACAGGCAGTAAGTCTGTGTATTGTTGTATT
565



ATTATGAGTCCCATTTTATAGATGAAGAA






DTX1_chr12:113496694-113496794
TTTATAGATGAAGAAACCGAGTCTCCCAGAAGCTGAGTGATTTAAACTCAGAGCTGGGATTTAAACCCAG
566



GCGGTTGAGTTCCAGAACCAAAGTTCTTAA






DTX1_chr12:113496794-113496894
CTGGTATCCTATACTGGCTCCAAGTGTTGGTTTGTGGGGTGGAGTCGTGCTGGTGGTAATTAATTGGGGA
567



TGGGGGGCGTTGGTGGTGTTGATGGTGGGG






DTX1_chr12:113496894-113496994
TGAGGTGGCAATGATGGAGGAGACAGTGTTAGCGGTTGTGTTGGTGGTGACTCAGTGATAGTATTGATGG
568



TGGTGGGGTCTTGGTGACAATGGAGGGATG






DTX1_chr12:113497059-113497159
TGTTGGTGACATTGATAGTTGTGTTGGTGGTGGTGCTGGAAGTGGTGTGATGGGGTGGTGATGATGGAGA
569



AAATGAGAGAATGATGTTGGTGGCAGTCTT






DTX1_chr12:113497159-113497259
CGTGGCCATGTGGTGTGGCTGGTAGCCCTGTGTGTGGCTGTTACTTAGTGGTATTGGTGATCCTGTTGTGG
570



TTGTAATGATGGTGATGTTGATGGTTGCG






DTX1_chr12:113497259-113497359
TTGGTGGTAATGTGATGGCTGATGATGGAGATAAAATCGATGAGGTCCCACTCTCAGGCCTACTCTCTTTT
571



GTTCTGGAGATTTGTCATCGTTGGGGAGA






BCL7A_chr12:122458781-122458881
TGAAATGGCTGCTGTCGGGCTGTCATCTCCAGGCCCGGGGCGCTGACATTTGGGCCACTCTCGGTCTCCCT
572



CTTCATTCTGGGCGCGCATTAGCTCTGGT






BCL7A_chr12:122458881-122458981
CCGGCCGGTTCCGCTGCAGCTGAACAGCAAGATGCGGCACCCAGGTTACCCTGATCATCGCAGATTTCTC
573



CCCGGGGCTCTGTTCTGAGGCCTCAAAAGT






BCL7A_chr12:122458981-122459081
GCTCCTTGTAGATGGGACCAGGGGTCATTTGGGCAGTAGCAGCGCCTGGTCTCAGTCTGGTACTGAAGTC
574



AGGAATGGCTTAAGGTGAAATCGTGGTCCT






BCL7A_chr12:122459081-122459181
CTGGTGAAGCTCAGCGAAGACCCCCTCGCCTTGTTTATGACAAGAGAACTTCTGGGGGCGGGAGGAAGAG
575



TCCCTGTTACGATGCTGATCATCATTGAGC






BCL7A_chr12:122459181-122459281
TTTTGCTGAGCAGAAAACTCTTTAGTACTCAAGGTCGAGAGTCTCTGGTGGTCTGCCTGGCACCAGGCAC
576



CTTCCTACAACCCTAGTTTTCCAAAAGGAC






BCL7A_chr12:122459281-122459381
AAAGCCTGGGGCAGGCGACGTCCTAGCTCGCATTTGAACAGGGCCGCGGGCCAGCAGAGATGCGCGATG
577



CCCAACTCTTTCCAAGAGCACCTCGCGTCCC






BCL7A_chr12:122459381-122459481
GAACCGGTGCCTTCAACTCGGAGAAGTCAAGAGACCCGCAAGAAACTTGCACGACTGCACCCGCCGCCGC
578



GCTCTGGGGGCTGGGCAGGGGCAGCTGGGC






BCL7A_chr12:122459481-122459581
TGGCTCCCGGGGAACGCGACCCCCCCGCGCCCCGCAGACCGGCTGTCTCCCATGGACCCCTCGGCACCTG
579



CAGCCTCCGAGGAAGGGTCAGCGCGCGTGT






BCL7A_chr12:122460811-122460911
GGGGGGCTCGGGCCAGCCGATGTTTTTGGCCAGAAGCCGTTCGTCCTGGGCCGCGGCTGCCTCTCCACAC
580



CGGGAGCTCGTGTTTGTTTTGCGGAGGGAG






BCL7A_chr12:122460911-122461011
CTGTTGTTTTTGTTCTCTGCACCGGGGAGAGGGGGACTTGGTGGCGGCCGCGCGTGGTTTTCGGGATCAC
581



ATTAGCGTCCGCCCGGCGTGGCCCGGTCGA






BCL7A_chr12:122461011-122461111
CATTAAGGGGATCGAACCTTTCCGCGGCCTCGTCGGGGTCTGCTCGGAATCGGCCCCTGGGCCAGGCCCG
582



AGGCGCAAGCAGATCGCCAGGTTGGGTCAG






BCL7A_chr12:122461111-122461211
AGTTGTTGAAAACTCCCCGCTGCCTGATTTCAACTTTATTATTTTTTTCCCACGCCTTCACTGGGGTCCCGG
583



AGGGAGAGGAGCCGCCGCAACGCTGGCT






BCL7A_chr12:122461316-122461416
AGTAGCGCCTCGGTCTCTAAAAGCCACTGGGGGCGAGCCTCCGGTGTGGCGGTGTCACAAGTTAGCTGTC
584



CTTTCTGAGTCAAACCCAACAAAAAAGGCA






BCL7A_chr12:122461416-122461516
AGAGGAAAATCAATAAAGTCCACGTGCTCCCCGGCCTCCTATGGAAAGGGCTGGCTGCGATGGCCGGATG
585



CCCGGCCGTGGGCTGGGTTTGGCTCCAGTG






BCL7A_chr12:122461516-122461616
GGACAAAGAATTTTCAGAACCGTGAGAAGGGGAGGCTTTCCAAAGTTGAGATCCAAGTCGTCGGTGTCTC
586



GGGAGCTCCCCTGGTACACAGGGTGCCCGG






BCL7A_chr12:122461616-122461716
TGCCCGACTGGAGCCATTTAAAAATGGCAGAAACAGCTGCAGGCCAACACACACACGCTGGAAAACAAC
587



CCGCAGCCCCCTCTACTGTGGGATTCCCCGC






BCL7A_chr12:122461716-122461816
GGGAAGCCCGGAGTTGCTCCCCTCCTTGCCTCAGCCCCTGTGCAAAGAAAGAACTGGTGTCTGTGCCTGG
588



GTCCCTTCTGTCGCCGGCCTGGAGGTTGGG






BCL7A_chr12:122461816-122461916
AAACAGCCGGCAAGCCGCCTTTCTCTGCTCGAGGAGGCGTGGTGGGGCCTCCTACTCCAGGTTCCCGGCT
589



GGACAGAGGCTCCTGCACCCTGACAGCTGC






BCL7A_chr12:122462001-122462101
GGAGGCCTTCCAGCCCGCTGACCCCGCGGGGACCAGGCCTGTAGTTGGAGCTTGAGGGGCTGTACCTCTG
590



CGCCTCCCTGGGTTTGGGGAAACAACACAT






BCL7A_chr12:122462101-122462201
CGTGTCCTCTGAAGACCTCAGGCTTTGGGATCTCATGGTCCAGCTTCCAGTTCACTTCGTTGCCGCGACCT
591



TGGGCATATCATTGTCACTTCTCTAACCA






BCL7A_chr12:122462201-122462301
TGGTGACCCGGGGTTTTGTGCTTGGCTTCCAGGTCCCCTCGGGTTATTGAGGACGATTGAGGTCATGCCTC
592



CGAGAGCACCGCGCCCTGGGCGCAGGAGG






BCL7A_chr12:122462716-122462816
AATGCAAATTTAACAGGGCACCCTGTATTTTACCCAGAGGGAAGCCGAAGTGTTTGGCAGATCATTTGGC
593



CCCATGAGCCTTGGGTGGGTTTCTCCTCAG






BCL7A_chr12:122462816-122462916
CCCTAGTGACCCCTAAAATTACCCCCCCGACCCACCCACTGTCCCCTGATGCTTCCCCCACCCCCGGAAAA
594



AGCTGTGGCCTCCCTCTCATTTGGGGCAG






BCL7A_chr12:122462916-122463016
GCTGCCTCCTGTTCTCTTTTTCTGGTGTTTCAGCAAGGCAGGCCAGTGGAGGTGAGGTGACCAGAAGATG
595



GCTAAAGGGAAAACAAAATGGTGGGCCTCT






BCL7A_chr12:122463031-122463131
CCAGGGTTTGGGGGCCCTGTGCTGGTGGAGGAGAGAAGACCCCAGGGCGATGGTAGGAGACGAAAGCTT
596



GGGCTGCAGCGTAAGCTTGGAGGCCCGCTGC






BCL7A_chr12:122463131-122463231
GGTGGCTCACGCCTGTAATCCCAGAGCTTTGGGAGGCTGAGACAGGAGGATTGCTTGAGCCCAGGAGTTT
597



GAGACCAGCCTGGGTCTCAAACCAAAAAAA






KIAA0226L_chr13:46959165-
TAAATATAATTTTAACGCCAATCTGAGAAAAATGACTTATTAGCTGTGTGATTTTGAGCAATGCTCTTAAC
598


46959265
CTCCCCCATGAAGGATGGTGTGAGAACGA






KIAA0226L_chr13:46959265-
ACAGAATTGTAGCACGTGTATCAGTCTGGTACACAATGTCCTATGAAGGTTAGCTTTATTATCACCATCAT
599


46959365
TATTATTGCAGAAAGACTTTCAGTTCAGA






KIAA0226L_chr13:46959365-
ATAAGACAGCACAGTTACAGAGACCTGGTTTTATTTTCCAGCTTCTTAACTGAGTCATCTTTCAGCTCCTT
600


46959465
TTAATTAAAAAGAAAAAACAATCAGAGAT






KIAA0226L_chr13:46961680-
TCAAAGACCTGGCAGAAATGACTTCCCAACCCCAGATGCCCCCAGCAGCAGTATTTAGCAGTCATACAAT
601


46961780
TGCCTGAAATGAAGAATGAGTAATCTGGAT






KIAA0226L_chr13:46961780-
GAGTCGGCCCTGAAATCGACCTGCAACTTACCCGGAACGTGAGCTGTCTCTCTCTGACCTCTGCTGGCTGC
602


46961880
TTCACCTGGAGTCTGAGTCCGACTCATGT






KIAA0226L_chr13:46961880-
AGCACTTCACTGTCCGCGTTAGTTTAGCCTTCACTGTCAGCAACTCGTCACCTTGTCCTCTTGCAGCGAAG
603


46961980
GTTTGGAATCCCATCACGGGTGTGCAGTG






KIAA0226L_chr13:46961980-
GTTAGTCCTGAGATCATGGTGGTGCTAGGAGAACCTGCCAACCAATACAGAAAGTTGTCACGAATAGAAA
604


46962080
CCTAAGCTCTGGCCGGGTGCGGTGGTTCAA






ATP11A_chr13:113516229-
AGATATACTGTTCTAGACATGTGTCTGAAAGGAATCCTGCAAATTCTGTCTTATTGAACAGGCATAAGGT
605


113516329
GTCACGTCAGGCGTAAGGTGTCACAGCAGG






ATP11A_chr13:113516329-
CGTAAGGCGTCACGTCAGGCGTAAGGTGTCACAGCAGGCGTAAGGCATCACGTCAGGCGTAAGGCGTCA
606


113516429
CGTCAGGCGTAAGGTGTCACAAGCTCGGTGA






ATP11A_chr13:113516429-
ACGTCAGGGGTGTGCCTTGTGTTCTCTGTTCGTTGCTTTCAGAAGCAGCAGCATGTGGCAGCATCTCTGTG
607


113516529
CCTATGACGATATTGCAGTGAATATGAGA






SYNE2_chr14:64330252-64330352
AATTGTACATTTCAACAACATAAATAAGCTGTTCAAGACTGTCTCCCATGCCTCCAAAACAAATAAAAAC
608



CCCCCACAACTCAAATGCATATAAGCTGTT






SYNE2_chr14:64330352-64330452
ACTATAGTATAATGGTGAGTTATAGCCAGTGTATGATGGGATTGTTGATAGAATAATGCATATTAGAGCT
609



TTTAGTTCAAAAATTTGAGATAGTGATTCA






SYNE2_chr14:64330452-64330552
GAAAGAAAAAAAGGAATGATTATCATGAATTCTGTTTATTAGAATTCTGTTTATTAAAGAGTTAAAGATA
610



TGTTTTATTTTTTTATCTTTATTATCATTA






ZFP36L1_chr14:69258238-69258338
AATTCTAATGTTGGTCCCTTAGGATCAGCAGGGGGGGACCGGGAATCTGTAACTGCAACCACCCCACCGA
611



GAGGATTACAGGAACCCAGTCGAGAGCTGG






ZFP36L1_chr14:69258338-69258438
TTCCCAACAATGAGGTTCATTTAAAAAGTCGTGAGGGGGGAGGGGGGCCAAAGAAAGAAATAGATCAAA
612



GAGCGGGAGAGTCGAGAAAAGAAGGAAGAAA






ZFP36L1_chr14:69258438-69258538
TGTTGGGGAGCGCTGGCAGCCGGGCTGGCAAGTGGAGTTTGGGAATGTGCAGGGAGGGAAGGAAGCTGA
613



AAAATTCAAACTTTTTAAATGCTACTCTTCA






ZFP36L1_chr14:69258538-69258638
GCTCCTCGGCGTCCCTGCACCCCAACCCTGCAGCCCTGGGGCGTTGGCAGCTGCACCAACAGGAGCAGCA
614



AGCTGGGAAAACAGAGCAACATGACCCGAC






ZFP36L1_chr14:69258638-69258738
GTGTTAAGAGAAGGCAAAACACTTCAGCAATTAAAAAGTAGCCCAGCAGCTTCACCCTTTCAAATTGGGA
615



GGGGGAGGTTGGAAAGAAATTTAACAACAT






ZFP36L1_chr14:69258738-69258838
CCATAGACTTTTGCTATGTACATTTAAACCGCAGTCCTGGAACATTCCGAGTTTAAAACTTGCTTTTTCAA
616



CACTGGCTGACAAGCAACATGTTTTAAGG






ZFP36L1_chr14:69258838-69258938
AGCCCCCCATTAAATCCTTACTCGCGGGACTCTCGAGTTCAAGCCAGCATTTTGTCGCCACCTCCCCCCCC
617



AACCCCGCCCGCAATCGATGAGCCGCAAT






ZFP36L1_chr14:69258938-69259038
GCCTCGGCAACACAGGTAAGCGGGTCAACCTGAATGCCTCTTTCACCCCAAAGTTTGCTGCACGATCGGC
618



TATCGCGGGAAGAAGCCCAACGGAGCTAGG






ZFP36L1_chr14:69259038-69259138
GCGGACTCAAGCCCCACTGCAAACTTGTTCTGCAACATCTTTTTGAATCACAACTTGGCCTTTCTTCCTCG
619



CATATCCCCAGCTCCCCCCAAAGAGTGGA






ZFP36L1_chr14:69259138-69259238
GGAAAACATTGTCCCGAGACTCACTTCCCCGAGGGACCTCCCACTCCCAACCCCACGGGTGGGTAATGCC
620



GCTGGACAGACCTAGGGCGCAGACTGGGAA






ZFP36L1_chr14:69259238-69259338
CCCGATCAGACCAGCAAACCTGGGATCCAGCAGCACGTTACGTAAAACAGGATCGCCCAAAACTTGTCCC
621



AATCCCAGCCCTCCCCCCGAAGCCCCCGGG






ZFP36L1_chr14:69259338-69259438
CTGCCCTGCCAGGCAAACTTCGCCCCTCAAAACCCTGGCCTCCAGATTCACATGTAATCCCCGCCAGCAAC
622



TGTTGAAACTCAAAGGGTGGGAAGGACGG






ZFP36L1_chr14:69259438-69259538
GGCCAAATTCCTTCAAACTTGGGAGAAATGCCGGAGGAGAAAAGAATCATCTCGCTGCACCACTTTCCCC
623



ATTGCCTTCCAAGACCCAAACTTTTGGGGG






ZFP36L1_chr14:69259538-69259638
TTCTTTCTTAAGGCAAAAGAAAAAGACTTTTTGAAAAGCAAATGCTCCGCCCCCCTTTACCTTGCATAAAA
624



CTTCGCTCAAGTCGAAGATGGTGGCAGAC






ZFP36L1_chr14:69259638-69259738
ACGAGGGTGGTGGTCATCCTGTGCGTTCGCGCGAGCCAGGGGCGAGGATCTGGTGTGTCGCGAAGGTCCC
625



GGTGCGGGGAAGGCGCAGCCTCTCCTGTCT






FLRT2_chr14:84420586-84420686
TTATTTTTTTATATTAAGATTTATTCTAAATTTTGATTCTTCTAAATATAGTATATATTTAGTATATATATA
626



ATGCACCTCTCTTACCTAATGATCATTT






FLRT2_chr14:84420686-84420786
CTAAATAATCATAACAACATCGAGTAAAACTATGTAATAACACATATTATTATTAAGATAAGTATAAGAA
627



ATATAATAATAAATTGTCCCTGTTCTAAAA






FLRT2_chr14:84420786-84420886
GGTAATTATATAATGCTGAATGTGTCAGAGGCATTCGAACCAGAGTGACTCCATTTTGAGTGAGGGCTAG
628



GAAAATGAGGCTGAGACTTGCTGGGATGCA






TCL1A_chr14:96179592-96179692
TTTAATTTTTATGCTTTCTTCAGTGTATGTTTGGAGAGAGTTTGAACATTTTTTGACTCTTTTTCATTGAGT
629



AAATCCAAATACTTGTAAAAGACTTATC






TCL1A_chr14:96179692-96179792
TATTTCTTTAACAAAAACTTAACATGGATTAAGGACCCATCTTAAGGCATCACACATTAAAAAAGTCAAT
630



ATTGATTCAATACCGGCGCTTATACTACGA






TCL1A_chr14:96179792-96179892
CATCACTTGTTAAATTTGTTTTCTAAATAAAGCCCAGAGGTAGTGGAAAATACTTCACACTCTAGGCCAGT
631



GTTTGCTATGCCTGGTTGACCCTAAACTG






TCL1A_chr14:96179892-96179992
TTGAGGGTTCTTTTTAAAAATACAGATTTCTGGGACCCACCTGAGATGATTCCGATAATCGGCCATATGGA
632



TGAGTCACTTAGAGATACCCATTTTTAAG






TCL1A_chr14:96179992-96180092
GATTAGGACCCCGAAGCCCAGAAAATGCCTGCTGTAGTCAACATTATAGTCACACTCCACAGGCACTGGG
633



TCCACCCCTTTGACCGACATTCCTTTGCGG






TCL1A_chr14:96180092-96180192
TTTTCCCACCCTTCTTCCCTGCCTGGAGAACTCCTATTCATCCTCCAGAGCCCGGCTCAAAGTGGCTTCATC
634



TGTGGGGATCCTCCCTGCCCCATAGTGA






TCL1A_chr14:96180192-96180292
GTGCTCCTTGAGTCCTCGCCCTTCCTAGGGCATCCCAAGCTCCCAGGGGCTGCCCCTGCTGCCTCGCCATC
635



CGCTCCAAAGCTGGCTGTACCTCGATGGT






TCLA1_chr14:96180292-96180392
TAAGGGCAGCCAGGCGTGCTGCTTCTCGTCCAAATACACGAACTTCTCCCAGGCCCACAGGCGGTCCGGG
636



TGGTCGGTGACTGCCTCCCCGAGTGTCGGG






IGHA2_chr14:106048955-106049055
AGGAATCAGATTTCAAAATGAATATGTATAAGAAAAGAACCGGGGATCAGTGATCAGGAACAGGGATCC
637



ATGATCTGGTCCAGGGCTCAGCGGTCAGGAA






IGHE_chr14:106068705-106068805
CCCTGGCCTGGAGTCCCAAGTCCCCAGCCCATCCTGCCCCTGGAGCCCAGTTTAGCTTGGTCTTGAAGTCT
638



GCTCTAGGTACCCCCAAAATCACAGTATC






IGHE_chr14:106068805-106068905
CAGCCCCGCTCTGCCCACCGGGACAGCCAAGTTCAGCTGAGACTGGCCTACCGGGGGAGTCGCCCTCTGA
639



AGTTCACTCTAAGCCAGCCTGGTTCAGCCT






IGHE_chr14:106068905-106069005
GGCCCAGGTCAGCCCAGGACCTCCCCTTGCAGGCAGCAAACTCTTATTTCAGTCCAGCCAGCTCAACCAG
640



CTTGCTTCTGACTCAGCTCCTCTTAGCCAG






IGHE_chr14:106069045-106069145
TTAGCTCAGCAAAGCTGGACCTAAAGTAGCCACCTCACCCCAGCTTCATCCAGATGAATACAGTCCAGAT
641



CAGCTTAGTCAGTTAAGCCTAGCCTAGCTA






IGHE_chr14:106069145-106069245
GTTAAATCCAGTTACGACCAGCTCAACTAATCCTGCTCAGGCCTGCTCAGCCCAGCCCAGCTGAACCCAGT
642



TTAGCCGAGGCCAGGCCAGCCCAGCTGAA






IGHE_chr14:106069245-106069345
TACAGTTGCCCAGTCTAGCTCAGCCCAGTCCAGCACTGCCCAGTTTAGCTGAGCTCAGCCTGGCCCAGCCC
643



AGCTCATATCAGCCCATCTCAGCTGAACC






IGHE_chr14:106069345-106069445
AGTTTGACCCAGTCTAACCCAACCCCGCTCAGCTGAACCCAGCCCAGCCCAGCCCAGCCCAGCCAAACCC
644



AGTTTAGCCTAGCTCAGCTCAGCCCATTTC






IGHE_chr14:106071060-106071160
CCTGTCCTAGGGGTGGCAGGCAGTCTGCACCCAGCCTAGCCCTGCCCAGCGTGGGGTCTCTGACCTTCTTG
645



GTCTTGGGCCCAGCCAAGATTCCCAGCCC






IGHE_chr14:106071190-106071290
TTCTAGCTTTCCTGTGTCCCCATGCAGGGAAGGGATGCCTAGAGTCCACGCAGTGACCAAGAAGCTTGGT
646



TGATGCTGTGAGGGTGGCCCAGGAGTCCCC






IGHG4_chr14:106095335-106095435
CACCTGCTGTCCTTGGTCCTGGCTGAGAGGAGGGCCCTACGGCCAGCTCTGCTGACCCTGCCCTGGGCTCT
647



GGTGATGCTGCCGGCCTGGACAAGCCCCT






IGHG4_chr14:106095480-106095580
GAGCTCAGGTCGGTCGTGCCCATCCTGGCATCACCCCACAGCCGGTTCTGCCGCATCCCGTCATGTTCCTC
648



GTGCTCCCAGCCCGGTCGTCCTGGAGGCC






IGHG2_chr14:106110675-106110775
TGAGCATGAGTGGGGCGGGCAGAGGCCTCCGGGTGAGGAGACAGATGGGGCCTGCCTTGCTGCCCTGGG
649



CTGGGGCTGCACAGCCGGGGTGCGTCCAGGC






IGHG2_chr14:106110775-106110875
AGGAGGGCTGAGCCTGGCTTCCAGCAGACACCCTCCCTCCCTGAGCTGGCCTCTCACCAACTGTCTTGTCC
650



ACCTTGGTGTTGCTGGGCTTGTGATCTAC






IGHG2_chr14:106110830-106110930
ACCAACTGTCTTGTCCACCTTGGTGTTGCTGGGCTTGTGATCTACGTTGCAGGTGTAGGTCTGGGTGCCGA
651



AGTTGCTGGAGGGCACGGTCACCACGCTG






IGHG2_chr14:106110950-106111050
GGACTGTAGGACAGCCGGGAAGGTGTGCACGCCGCTGGTCAGAGCGCCTGAGTTCCACGACACCGTCACC
652



GGTTCGGGGAAGTAGTCCTTGACCAGGCAG






IGHG2_chr14:106112335-106112435
TGCTACACTGCCCTGCACCACCTCCACTCAGCTTCATTGTGCTGGTGGCCCTGGCTCCTGGCAGCCCATCT
653



TGCTCCTTCTGGGGCGCCAGCCTCAGAGG






IGHG2_chr14:106112435-106112535
CCTTCCTGCCTAGGGTCCGCTGGGGCCAGCCCTGGGACCCTCCTGGTCTCAAGCACACATTCCCCCTGCAG
654



CCACACCTGCCCCTGCCTGAGAGCTCAGC






IGHG2_chr14:106112535-106112635
CCCGAGCCCTGGAATGCCTTCCCTTCTCCATCCCAGCTCACCCTTGCCAACTGCTCAGTGGGATGGGCTCA
655



CACTCCCTTCCTGGCACCAGGAGGCTGCA






IGHG2_chr14:106112635-106112735
CTGCACTTTCACCAGCCCTCAGCTGTCTGCTGCCAGCAACTACCCAGCTCCTGCCAAAATCTAGGAGCTGA
656



GTGATGCCTCCCACCGGCCCTGCTCACCT






IGHG2_chr14:106112735-106112835
GTGGTTGCCTTGCCCTGAGCTCTAGTGCCTGTCCCCTGCTCGTCCTGCCTCCCACCGGCCCTGCTCACCTG
657



TGGCTGCTCTGCTCTGATTCCCTGAGGCT






IGHG2_chr14:106112835-106112935
AAGCCTCAGTCCTGCTCACCTTCTGATGCTCTCCTCTGTCCCCTGAGCTCCAGGGGCTGTCCCCTGCTCGT
658



CCTGCCTCCTACCTGCCCCTGCTTACCTG






IGHG2_chr14:106112935-106113035
AGGGTGCTCTGCCCTGGTGCTCTGAGCTCCAGGGGCTGTCCCCTGCTCCTCCTGCTTCCTACCAGCCCCTG
659



CTCACCTGTGGCTGCTCTGCCCTGGTCCC






IGHG2_chr14:106113020-106113120
CTCTGCCCTGGTCCCCTGAGCTCCAGGGGCTTCCCCCTGCTCTTCCTGCCCCCACCAGCCCCTGTTCACCTT
660



CAGATGCCCTCCCCTGGTCCCCTGAAGT






IGHG2_chr14:106113120-106113220
CCCAGAGCTGCCCCCTGTTCCTCCTGCCTCCCACCAGCCCGTGCTCACCTGCCGCTGCTCTGCCCTGGTCC
661



CGAGTTCCAGGGGCTGCACCCTGTTCGCC






IGHG2_chr14:106113220-106113320
CACCTCCCACTAGCCATGCTCAGCTCTTGATGCTCTGTCCTGGTCCCCTGAGCTCCAGGAGCTGTCCCCTA
662



CTCGTCCTGCCACCCACCAGCCCCTGCTC






IGHG2_chr14:106113320-106113420
ACCTGAGGCACCTGAGGCTGCTCTGCCCTGGTCCCCTGAGCTCCAGGGTCTTCCCCCTGCTCATCCTGCCT
663



CCCACCTGCCCTTGTTCACCTTCAGTTGC






IGHG2_chr14:106113420-106113520
TCTGCCCTGGTCTGCTGAGCTCCAGGAGGTGCCCCCTGCTCCTTCTGCCCCCACCTGCCCTGCTCACCTGT
664



GGCTGCTCGGTCCTGGTACCCTGAACTCC






IGHG2_chr14:106113450-106113550
GCCCCCTGCTCCTTCTGCCCCCACCTGCCCTGCTCACCTGTGGCTGCTCGGTCCTGGTACCCTGAACTCCA
665



ATGCCTGCCCCCTGCTCACTCTGCCCTCC






IGHG2_chr14:106113550-106113650
CTCAACCCGGGCAGCAATGTCACTCAGGTCACTGTTGCCCCCCTGCCTGTCCTGGCACCCTCTGTCCAGGT
666



TTGGGCTGTTTTTCTGGCCTCATTTTTGT






IGHG2_chr14:106113695-106113795
TGTCCAGTCAGGTCTCCCCAACAGAGCCCCTTGCCCTTGCCCATGTGCCCCTCCTGGGTGAGCTCCCAGAT
667



CCTCCCGTCCCTGCACTGCTCCTGCTCTG






IGHG2_chr14:106113795-106113895
GAAGCCTCTCCAGAACCTCAGCTCCTCAGTGGCCTCTGCTCTGCTGGGTCAGCTCCCTGAACGCACGGAG
668



CCTCACCCCTCCCCTCGCCCCAGGCCTGCT






IGHG2_chr14:106113895-106113995
GCACTCTGGGCCTTTCTGGGCCTCCCTGGACTCTTCCCTCCTCCCATCTGTGCACTCAGCACAGCTCTCCCC
669



TCCACTCCGCTGCTGACCACAGCCCTGC






IGHG2_chr14:106113905-106114005
CCTTTCTGGGCCTCCCTGGACTCTTCCCTCCTCCCATCTGTGCACTCAGCACAGCTCTCCCCTCCACTCCGC
670



TGCTGACCACAGCCCTGCTCCCCGCCAG






IGHG2_chr14:106114175-106114275
CCCACGGCCAGCACTGCTGACCCTGCCCTGGGCTCCAGTGATGCTGCTGGCCTGGACAAGCCCCTCCGTTC
671



ACCTGGGGCCTCTCCTCCTCCCTCGTTCT






IGHG2_chr14:106114275-106114375
ACTGCCTCCTCAGCTCAGGTGGGTCCTGCCCATGCTGGCATCACCCCACGGCCGGCTCTGCCGCATCCCGT
672



CAGGTTCCTCGTGCTCCCAGCCTGGTCGT






IGHG2_chr14:106114375-106114475
CATGGAGGCCTCAGTCAGCCTCTGGTGTGTCCTGCCCTGTTGGCTTGGAAGCCCCTGCCCACGGTCCCCGT
673



CATCTTGCACTGGGTGGGCGTTGGTGCCT






IGHA1_chr14:106176375-106176475
AGCTCAGCCCAGCCTAGTCCAGCCCAGCCCAGCACAGGTCAGCCCAGCTTAGCTTAGCCCAGGTCAGTCC
674



AGCTCAGCTCAGTCCACTTAAGCTCACCCA






IGHA1_chr14:106176475-106176575
GGTCAGCTCCGTCCAGCTCAGCCCAGCCTAGCCCAGCTTAGCCCAGCCCAGCCCAACACAGGTCAGCCCA
675



GCTCAGCCTAGCCCAGCCCAGCTCAGCACA






IGHA1_chr14:106176575-106176675
GGTCAGACCAGCTCAGTACAGCTCAGGTCAGCCCAGACCAGTCCAACCCAGCCCAGCGCAGTCCAACCCA
676



GCCCAGCTCAGCTCATCCAAGCCTAGCTCA






IGHA1_chr14:106176675-106176775
GCTCAGCCCAGCCCAGGTCAGCCTAGCCCAGCCGAACCCAGCTCAGCCCAGGTCAACCCAATTCAGCTCA
677



GCTCAGCCCAGGTCAACCCAACCAAGCTCA






IGHA1_chr14:106176775-106176875
CAGCCTAGCCCAGTCCAGCTCAGCCCAGCTCAGCTCAGCCCAGTCCAGCTCAATCCACCTAAGCTCAC
678



CCAGCTCAGCCCAGTCTGGCTCAGCTTAG






IGHA1_chr14:106176875-106176975
GTCAGCCCAGCCCAGCCTAGCCCAGATCAGTCCAGCTTAGCCCAGCCCAGGTCAGCCCAGCCCAGGTCAG
679



CCCAGCTCAGCTCAGCCCAGCCCAGCTCAG






IGHA1_chr14:106176985-106177085
CCCAGCCCAGCTCAGCGCAGCCCAGCCTAGCTCACCCCAGCCAGGTCCAGCTTAGCCCAGCTCAGCCCAG
680



CCCAACTCAGCTCAGCCCAGCTCAGCCCAA






IGHG1_chr14:106211960-106212060
TCTGAGCTCCAGGGGCTGCCCACCTGCTCCTCCTGCTTCCCACCGGCCCTGCTCACCTGCAGCTGCTCTGC
681



CCTGGCTCCCTGAGGCTGAGCCTCAGTCC






IGHG1_chr14:106212060-106212160
TGCTCACCTTCTGATGCTCTCCCCTTGTCCCCTGAGCTCCAGGGGCTGACCCCTGATCTTTCTGCTTCCTAC
682



CTGCCCCTGCTCACCTGTGGCTGCTCTG






IGHG1_chr14:106212160-106212260
CCCTGATCCCCTGAGCTCCAGGAGCTGCCTCCTGCTCTTCCTGCCTCCCACCTGCCCCTGCTCACCTGCAG
683



ATCTGCCCTGGCTCTCTGAGGTCCAGGGG






IGHG1_chr14:106212260-106212360
CTGCCCCCTGCTCGCCCACCTCCCACCAGCCATGCTGACGTTGTGATGCTCTGCCCTGGTCTCCTGAGGTC
684



CAGGGGCTGTCCCCTGCTTATTCTGCCTC






IGHG1_chr14:106212360-106212460
CCACCTGCCCCTTCTCACCTGAGGCTCTTCTGCCCTGGTGCTCTGAGCTCCAAAAGCTGCCCACTTGCTCC
685



TCCTGCTTCCTACCAGCCCCTGCTCTCCT






IGHG1_chr14:106212460-106212560
GTGGATGATCTGCCCTGGCTCTCTGAGCTCCAGGGGCTGCCCACCTGCTCCCCATGCTTCCCACCTGCCCC
686



TGCTGACCTGCGGCTGCTCTGCCTTGGCT






IGHG1_chr14:106212560-106212660
CCCTGAGCTCCAGGAGCTTCCCCCTGCTCATCCTGCCCCCCACTGGCCCCTGTTCACCTTCAGATGCCCTC
687



CCTGGTCCCCTGAAGTCCAGGAGCTGCCC






IGHG1_chr14:106212660-106212760
CCTGTTCCTCCCGCCTCCCACCAGCCCGTGCTCACCTGCGGCTGCTCTGCCCTGGTCCCCTGAGTTCCAGG
688



GGCTGCCCCCTGCTCGCCCACCTCCCACT






IGHG1_chr14:106212760-106212860
AGCCATGCTCACCTCCTGATGCTCTGTCCTGGTCCCCTGAGCTCCAGGGGCTGCCCCCTGCTTGCCCATCT
689



CCCACTAGCCATGCTCACCTTCTGATGCT






IGHG1_chr14:106212860-106212960
CTGCCCTGGTCCCCTGAGCTCCAGGGTCTTCCCCCTGCTCATCCTGCCGCCCACCAGCCCCTGCTCACCTG
690



AGGCTGCTCTGCCCTGGTCCCCTGAGCTC






IGHG1_chr14:106212870-106212970
CCCCTGAGCTCCAGGGTCTTCCCCCTGCTCATCCTGCCGCCCACCAGCCCCTGCTCACCTGAGGCTGCTCT
691



GCCCTGGTCCCCTGAGCTCCAGGAGGTGC






IGHG1_chr14:106212980-106213080
TTCTGCCCCCACCTGCCCTGCTCACCTGTGGCTGCTTGGTCCTGGTCCCTGAGCTCCAATGCCTGCTCCCTG
692



CTCACTCTGCCCTCCCTCAACCCGGGCA






IGHG1_chr14:106213080-106213180
GCAATGTCACTCAGGTCACTGTTGCCCCCCTGCCTGTCCTGGCACCCTCTGTCCAGGTTTGGGCTGTTTTT
693



CTGCCCTCATTTTTGATTTTGCAGCACTT






IGHG1_chr14:106213125-106213225
CCTCTGTCCAGGTTTGGGCTGTTTTTCTGCCCTCATTTTTGATTTTGCAGCACTTGGCGTGTTCCCTATGCT
694



GTGGAGCAGCCCCAGTGTCCAGTCAGGT






IGHG1_chr14:106213210-106213310
AGTGTCCAGTCAGGTCTCCCCAACAGAGCCCCTTGCCCTTGCCCATGTGCCCCTCCTGAATGAGCTCCCGG
695



ATCCTCCTGTCCCTGCACTGCTCCTGCTC






IGHG1_chr14:106213310-106213410
TGGAAGCCTCTCTGGAACCTCAGCTCCTCAGTGGCCTCTGCTCTGCTGGGTCAGTTCCCTGAACGCACGGA
696



GCCTCAGCCCTTCCCCTCGCCCCAGGCCT






IGHG1_chr14:106213410-106213510
GCTGCACTCTGGGCCTTTCTGGGCCTCCCTGGACTCTTCCCTTCTCCCGCCCGTGCACTCAGCACAGCTCT
697



CCCCTCCTCTCCACTGCTGACCACAGCCC






IGHG1_chr14:106213510-106213610
TGCTCCCCGCCAGCAGGTGCCCCAACCCCATCAGCTGGCTCTGAGCCCAGCCCCTGTGCCTCCCCTGTCCC
698



TGCCTCTGCCTCTGGGCTCCTTGGCTTCC






IGHG1_chr14:106213660-106213760
ACCTGCTGTCCTTGGTCCTGGCTGAGAGGAGGGCCCCACGGCCAGCACTGCTGACCCTGCCCTGGGCTCC
699



GGTGATGCTGCCGGCCTGGACAAGCCCCTC






IGHG1_chr14:106213760-106213860
CGTTCACCTGGGGCCTCTCCTCCTCCCTCGCTCTGCTGCCTCCTGAGCTCAGGTCGGTCGTGCCCATCCTG
700



GCATCACCCCACGGCCGGCTCTGCCGCAT






IGHG1_chr14:106213860-106213960
CCAGTCATGTTCCTCGTGCTCCCAGCCCGGTCGTCCTGGAGGCCTCAGTCAGCCTCTGGTGTGTCCTGCCC
701



TGTTGGCTTGGAAGCCCCTGCCCACGGTC






IGHG1_chr14:106213960-106214060
CCCGTCGTCTCGCACTGGGTGGGCATCGGTGCCTGAAGGCTGCCCACCTCCCCCGTGCTGGCTCCGCTTGG
702



GCCTCCATGTGGGGCCGGCCTCGACCCCA






IGHG3_chr14:106239250-106239350
CACTGCACTTTCACCAGCCCTCAGCTGTCTGCTGCCGGCAACTACCCAGCTCCTGCCAAAGTCTAGGAGCT
703



GCGTGCTGCCTCCCACCGTCCCTGCTCAC






IGHG3_chr14:106239350-106239450
CTGTGGCTGCTCTGCCCTGGTGCTCTGAGCTCCAGGAGATGCCCCCTGCTCCTCCTGCCCCCCACCTGCCC
704



CTGCTCACCTGCAGCGGCTCTGCCCTGGT






IGHG3_chr14:106239455-106239555
GAGCTCCAAGAGCTGCCCCCTGCTCCTCCTGTCCCCTGACCCTGCTCCTGTTTGCCTATGGCTGCTCTGCC
705



CTTGTCCCCTGAGCTCCAGGAGCTGCCCC






IGHG3_chr14:106239555-106239655
TGCTCATTCTGCCGCCCACCTGCCCCTGTTCACCTGTGGCTGCTCTTCCCTGGTCCTCTGAGCTCCATGAGC
706



TGCCCCTTGCTCCTCCTGCTTTCCACCA






IGHG3_chr14:106239655-106239755
GCCCCTGCTCACCTACCGATGATCTTCCCCGGCTCTCTGAGCTCCAGGGGCTGCCCACCTGCTACCCCTGC
707



TTCCCACCAGCCCTGCTTACCTGCAGCTG






IGHG3_chr14:106239755-106239855
CTCTGCCCTGGCTGGCAGAGCTGCAGAAGCTGCCCCCTGCTCTGCAACCTCCCACCGGCCCTTCTCATCTT
708



CTGATGTTCTCCCCTGTTCCCTGAGCTCC






IGHG3_chr14:106239855-106239955
AGGAGCTGCCCCCTACTCGTTCTACCTCCCACCAACCCGTGCTCACCTGCGACTGCTCTGCCCTGGTCCCC
709



TGAGCTCCAGGGGCTGCCCCCTGCTCGCC






IGHG3_chr14:106239990-106240090
TGCCCTGATCCCCTGAGCTCCAGGACTGCCCCCTGCTCGTCCTGCCCCTCACCTGCCCCTGCTCACCTGAG
710



GCTGCTCTGCCCTGGTCCCCTGAGCTAAA






IGHG3_chr14:106240090-106240190
GGGGCTGCCCCTTACTCATCCTGCCTCCCACCAGCCCCTGCTCACCTTCTGATGCCCTCCCCTGGTCCCCTG
711



AGCTCCAGGGGCTGCCCCCTGCTCGTCC






IGHG3_chr14:106240170-106240270
GGGCTGCCCCCTGCTCGTCCTGCCTCCCACCAGCCCCTGCTCACCTGCAGCTACACTGCCCTGGTTCCCTG
712



AGCTCCAGGAGCTGCCACCTGCTTGTCCT






IGHG3_chr14:106240270-106240370
GCCTTCCACCAGCCCCTGCTCACCTGCAGCTACACTGCCCTGGTTCCCTGAGCTCCGGGAGCTGCCGCCTG
713



CTTGTCCTGCCTCCCACCAGCCCCTGCTC






IGHG3_chr14:106240370-106240470
ACCTGTGGCTACACTGCCCTGGTGCCCTGAGCTCCAGGAGCTGCCCCCTGCTTGCCCATCTTCCACTGAGC
714



CCTGCTCACCTGCAACTGCTCTGCCCTGG






IGHG3_chr14:106240470-106240570
CTCTATGAGCTCCAGGGGCTGCCCCCTGCTGGTCCTGCCTCCCACCTGCCCTGCGCACCTGTGGCTGCCTC
715



CTCACCTGTGGCTGCTCTGCCCTGGTCCC






IGHG3_chr14:106240570-106240670
CTGAGCTCCAGGGTCTTCCTCCTGCTCATCCTGCCCCTCCACCGGCTCCTGTTCACCTTCAGATGCTCTCCC
716



GTGGTCCCCTGAGCTCCAGGAGCTGCCC






IGHG3_chr14:106240670-106240770
CCTGTTCTTCCTGCCTCCCACCTGCCCTGTGCACCTGTGGCTGCTTGGTCCTGGTCCCCTGAACTCCAATGC
717



CTGCCCCCTGCTCACTCTGCCCTCCCTC






IGHG3_chr14:106240770-106240870
AACCTGGGGCAGCAACGTCACTCGGTCCACTGTTGCCCCCCTGCCTGTCCTGGCACCCTCTGTCCAGGTTT
718



AGGCTGTTTTTCTTGCCTCATTTTTGTTT






IGHG3_chr14:106240820-106240920
TGGCACCCTCTGTCCAGGTTTAGGCTGTTTTTCTTGCCTCATTTTTGTTTTTGCAGCACTTGGCGTGTTCCC
719



TATGCTGTGGAGCAGCCCCAGTGTCCAG






IGHG3_chr14:106240915-106241015
TCCAGTCAGGTCTCCCCAACAGAGCCCCTTGCCCTTGCCCATGTGCCCCTCCTGGATGAGCTCCCGGATCC
720



TCCCGTCCCTGCACTGCTCCTGCTCTGGA






IGHG3_chr14:106241015-106241115
AGCCTCTCCAGAACCTCAGCTCCTCAGTGGCCTCTGCTCTGCTGGGTCAGTTCCCTGAACGCACGGAGCCT
721



CAGCCCCTCCCCTCGCCCCAGGCCTGCTG






IGHG3_chr14:106241115-106241215
CACTCTGGGCCTTTCTGGGCCTCCCTGGACTCTTCCCTCCTCCCGCCCGTGCACTCAGCACAGCTCTCCCCT
722



CCTCTCCGCTGCTGACCACAGCCCTGCT






IGHG3_chr14:106241200-106241300
GACCACAGCCCTGCTCCCGGCCAGCAGGTGCCCCAACCCCATCAGCTGGCTCTGAGCCCAGCCCCTGTGC
723



CTCCCCTGTCCCTGCCTCTGCCTCTGGGCT






IGHG3_chr14:106241345-106241445
GCTCTGCTCCCAGCTCACCTGCTGTCCTTGGTCCTGGCTGAGAGGAGGGCCCTACGGCCAGCTCTGCTGAC
724



CCTGCCCTGGGCTCCGGTGATGCTGCCGG






IGHG3_chr14:106241445-106241545
CCTGGACAAGCCCCTCGGTTCACCTGGGGCCTCTCCTCCTCCCTCTCTCTGCTGCCTCCTGAGCTCAGGTC
725



GGTCATGCCCATCCTGGCATCACCCCATG






IGHG3_chr14:106241545-106241645
GCTGGCTCTGCCCCATCCCGTCATGTTCCTCACACTCCCAGCCCGGTCGTCCTGGAGGCCTCAGTCAGCCT
726



CTGGTGTGTCCTGCCCTGTTGGCTTGGAA






IGHM_chr14:106318100-106318200
GGGTAGAGCCCACCTCGTGGCCTGCAAGCCAGCCAGCCCCTGCCGGTCGAGAAGGAAGCCTGTGTGAGA
727



GCACACAACTGGAGGCCGGGCGGGGAAGAGA






IGHM_chr14:106318200-106318300
AACACGTGCCAACAGGCCACGCAGGCCAGGACCCCAGACCCGGAGGCAGCGCCCCTTTGAGTTCCTCTCT
728



CTGGTCTCCGATGTTCTTCTGTTGGGATCA






IGHM_chr14:106318300-106318400
TTTCACCTACAGGCAACAGAGACAGTGTGAAATGCTTTCCCTGTGGTCGGGAAGGGAGCCGGGGCAGAG
729



ATGACCCAGTGGGGTGGTGTGGGGGCCTCCG






IGHM_chr14:106322055-106322155
CTTTGCACACCACGTGTTCGTCTGTGCCCTGCATGACGTCCTTGGAAGGCAGCAGCACCTGTGAGGTGGCT
730



GCGTACTTGCCCCCTCTCAGGACTGATGG






IGHM_chr14:106322155-106322255
GAAGCCCCGGGTGCTGCTGATGTCAGAGTTGTTCTTGTATTTCCAGGAGAAAGTGATGGAGTCGGGAAGG
731



AAGTCCTGTGCGAGGCAGCCAACGGCCACG






IGHM_chr14:106322255-106322355
CTGCTCGTATCCGACGGGGAATTCTCACAGGAGACGAGGGGGAAAAGGGTTGGGGCGGATGCACTCCCT
732



GAGGACCCGCAGGACAAAAGAGAAAGGGAGG






IGHM_chr14:106322905-106323005
ACTCCAGCTACCCTGAAGTCTCCCCAGGCAGACAACCCAGGCCTGGGAGTGAGTATAGGGAGGGTGGGT
733



GTGATGGGGAACGCAGTGTAGACTCAGCTGA






IGHM_chr14:106323005-106323105
GGCTATCCATCTATGTCCAACAAGATCATGAAGATTGGCCCAGTGCCATGTCCTCCAGTTCATCCCAGCCC
734



AGGCCAGCTCAATCCAGTTCATCCCAGCC






IGHM_chr14:106323105-106323205
CAGGCCAGCTCAATCCAGCCCAGCCCACCCCACCCCAGCTCAGCAAAGCCAAGCTCAGCTCAGCCCAACT
735



CAGATGAGCTCAGACCAGCTCAGCCCAGCC






IGHM_chr14:106323470-106323570
CAGCTCAGCTCAGCCCAACCCAGCCCAGCTCGCTCAACCTTGCTCGGCTCAGCTTAGCCCAGCCCAGCCCA
736



GCTCAATCCAGCCTGGCTCAGCCCAGCCC






IGHM_chr14:106323570-106323670
AGCCCAGTTTGGCTCAACCCAGCTTGGCTCAGCCCAGGTCAGCCTGGCTCAACTCAGCCCAGCCCAGCCC
737



AGCTCTGCTCAACCCAGCTCTGCTCAACTC






IGHM_chr14:106323805-106323905
AGCCCAGCTCATCCCAGCTCAGCCCAGCCCAGCCTAGCTTAGCTCAACCCAGCTCAGCTCAGTTCAGCTCA
738



GCCCTGCTCAGCACAGCACAGCAGAGCCC






IGHM_chr14:106324010-106324110
AGCCCGGATCGGCTCAACCCAGCTTAGCTCAGCCCAGGTCAGCCCAGCTTAACTCAGCCCAGGTCAGCCC
739



AGCTTAACTCAGCCCAGCCCAGCCCAGCTC






IGHM_chr14:106324155-106324255
TCAGCCCAGTTCAGCCCAGCTCAGCCCAGCCCAGCCTAGCTTGGCTCAACACAGCTCAGCTCAGCCAGCC
740



CAGACCAGCTCAGCTCAGCCCAGTCCAGCT






IGHM_chr14:106324290-106324390
CAACCCAGCCCAGCCCAACCCAGCTCGGCTTAACCCAGCTCGGCTCAGCCCAGATCAGCCTGGCTCAACT
741



CAGCCCAGCCCAGCTCAACCCAGCCCAGTT






IGHM_chr14:106324490-106324590
CAGCTCAGCTGAGCCCAGCCCAGCCCAGTCCGGCTCAGCTCAGCCCCGCCCCACTCAGCCCAGCTCAGCT
742



CAGCCCAGCTCAGCCCAGCTCAGCTTAGCC






IGHM_chr14:106324750-106324850
CAGCCCAGATCATCCCAGCTCAGCTCAGCTCAGCTCGGCTTAGCCCAGCTCAACCTGGCCCAGCCTGGTCC
743



AGGTCAGCCCAGCCTGGACCACCCAGCCC






IGHM_chr14:106324850-106324950
AGCTCAGCTCAGCCCAGCTCATCCTGGTTCAGCTCAGCTCAACCCGGCTCAGCCCAGGTCTGCTCAACCCA
744



GCCCAAATCAGCTCAGCCCAGCCCAGGTC






IGHM_chr14:106324950-106325050
ATCCCAGCTCAGCCCAGCACAGCCTACTTCAGCTCAGCTCAGCTCAGCCTAGGTCAGCTCAGTTGAGGTC
745



AGCTCAACTCAGCCCAATCCAGCCTGGCTC






IGHM_chr14:106325050-106325150
AGCCCAGCTCACCCTAGCTCAGCTTAGCTCAGCCCAACTCAACCCAGCCCAGCCTTGCCCAACCCAGCTCA
746



GCTCAGCCCAGCCCAGGTTAGCCCAGCCC






IGHM_chr14:106325150-106325250
AGCCTCGGCTTAGCTCTGCTCAGCTCGGCCCTGCTCGCCTCAGCCCGTTCAGCCCAGTTCAGCTCAGCTCA
747



GCTCAGCCCAGCTCAGCCCAGCCCTGGTT






IGHM_chr14:106325250-106325350
AGCTCAGCCCAGCTAAGCTCAGCTCGGCTTGGCTCTGCTGAGCTTGGCCCAGCTTGGCTTAGCCTGATACA
748



ACCTGCTCAGCCCAGTTCAGCTCGGCTCA






IGHM_chr14:106325360-106325460
GCCCAGCGTAGCTCAGCTCAGCTGAGCCCAGCCCAGGTTAGCTCAGCCCCAGTCCAGGTCAGCTCAACTC
749



AGCCCAAACCAGCCTGGCTCGGCCCAGCTC






IGHM_chr14:106325460-106325560
ACCCTAGTTCAGCTTAGCTCAGCCCAGCCCAGCCCTGCCCAACCCAGCTCAGCTCAGCCCAGCCCAGGTTA
750



GCCCAGCCCAGCCTCGGCTTAGCTCTGCT






IGHM_chr14:106325515-106325615
AGCCCAGCCCAGGTTAGCCCAGCCCAGCCTCGGCTTAGCTCTGCTCAGCTCGGCCCAGCCCAGGTTAGCC
751



CAGCCCAGCCTCGGCTTAGCTCTGCTCAGC






IGHM_chr14:106325615-106325715
TCGGCCCTGCTCGCCTCAGCCCGTTCAGCCCAGTTCAGCTCAGCTCAGCTCAGCCCAGCTCAGCCCAGCCC
752



TGGTTAGCTCAGCCCAGCTAAGCTCAGCT






IGHM_chr14:106325715-106325815
CGGCTCAGCTCTGCTGAGCTCGGCCCAGCTTGGCTCAGCCCGACACAGCCTGCTCAGCCCAGTTCAGCTC
753



GGCTCAGCCCAGCCCAGCCCAGCGTAGCTC






IGHJ6_chr14:106325820-106325920
AGCTGAGCCCAGCCCAGGTTAGCTCAGCCCCAGCCCAGGTTAGCTCAGCCCAGCTCAGCTCTGCCCAGGT
754



TAGCTCAGCCCCAGTCCAGGTTAGCTCAGC






IGHJ6_chr14:106325920-106326020
CCAGCTCAGCTCTGCCCAGGTTAGCTCAGCCCCAGTCCAGGTTAGCTCAGCCCAGCTCAGCCTTGCCCAGG
755



TTAGCTCAGCCCAGCTAAGCTCAACTTGG






IGHJ6_chr14:106326020-106326120
CTCAGCTCAGCCTAGCTTGGCTCAGCCCAGCACAGCACGCTCAACCCGGTTCAGCTTGGCTCAGCCCAGC
756



CCAGCCCAGCCTAGCTCAGCTCAGCCCCGC






IGHJ6_chr14:106326245-106326345
CCAGCTCAGCGCAGCCCAGCTCAGCTCAGCTCAGCCTAGCCTTGCTCGGCCCAGCTCAGCTCAGCCCAGCT
757



CAGCCTAGCCTTGCTCAGCCCAGCTCAGC






IGHJ6_chr14:106326450-106326550
TCAGCCCAGCCCTGCCCAGCTCAGCCCAGCTTAGTGCAGCCAAGCCCAGCTCAGCTCAGCTCACCTGGTG
758



CAACTTAGCCCAGCTCAGCTCAGCTCAGCT






IGHJ6_chr14:106326550-106326650
CAACCCAGTTCAACTCAGCCCAGTTCAGCTCAGCTCAGCCCAGTTCAGCCTTGTTTAGTCTAGGTCAGCTT
759



AGGTCAGTTTTGCCCATCTGAGTCCATTT






IGHJ6_chr14:106326650-106326750
CTGAAAGCTGGATGGAGTTGTCATGGCCAGAAATGGTCAGCCCACCAGACCTGCTTGTCTCAGCTAAAGC
760



CATCTCATTGCCAGGTTCCTGCACAGCCAG






IGHJ6_chr14:106326750-106326850
GCTGGCTTCCATCTTTTGTCTCCCTCTACTTGATACCCCAGTTCCCTGCAGTCCTGCCCCAGCGCCACCTGG
761



GTTTTGGTTCCAAAGCATTACCAATCAT






IGHJ6_chr14:106326850-106326950
TACCACCCTCCACTACCTGGGTGGAATATTTCTTTGCTGCTTTAAAGTCATTAAAACATCTTGAGAATGAG
762



ACCAAGAATTTAGGAGCCTGTGCTGTGAT






IGHJ6_chr14:106326950-106327050
AAAAATGAGCAGGTCCCCTTGCTCTAGAAGTGGCAGCATATCTTCTGCACCAAGAGGAGGGTATTGAGAT
763



GCTCAGAGCCTCCACCTTCCCGGAGCATCC






IGHJ6_chr14:106327050-106327150
CCTCCCTTCTGAGTCTGCAGTAAACCCCTGCCTTTAAATTCCCTCTAGATAACAGTCATCATTGGAAACAA
764



CCAAGAAATGCATTTTATCTGAATTTGCC






IGHJ6_chr14:106327150-106327250
ACTTAAAATTCTGCCATTTACCATAAATCGCTTTGGAAGGCATGGGCTACTTTCAAGGGTGCGATGATGA
765



CCTACAGTCAATGACTTAGACAAGGGCGAT






IGHJ6_chr14:106327250-106327350
GCCAGTGGGGCTTGGTATGTTCTCAAGCATCATTACCCATGCCATCCCCATTCAGAGGTTGTGGAGCAGCT
766



CGTGCGACCTCTCCTTCAAATGGGCTTTA






IGHJ6_chr14:106327350-106327450
GGGAAAGTTAAATGGGAGTGACCCAGACAATGGTCACTCAAAAGACTCACATAAATGAGTCTCCTGCTCT
767



TCATCAAGCAATTAAGACCAGTTCCCCTTC






IGHJ6_chr14:106327450-106327550
TAGTGGAAATAAGACGTCAAATACAAAGTTTTAAGAGAAGCAAATGCAGCAGCGGCGGCTGCCTGTCTCT
768



TACCATGTCGGGCGCCTGGTCACTGCGAGC






IGHJ6_chr14:106327550-106327650
CTTGCAAAGCTTTGGCATGGAATCATTCCTCCAAGTCCATTAACAAGGGCTGGGGCCTGAGCAGCCAGTC
769



GGCCCGGCAGCAGAAGCCACGCATCCCAGC






IGHJ6_chr14:106327650-106327750
TCTGGGTAGTCCGGGGAGACCCAAAGCCCAGGCCGGGCCTGGCAGCCACCCTCCCAGAGCCTCCGCTAGG
770



CCAGTCCTGCTGACGCCGCATCGGTGATTC






IGHJ6_chr14:106327750-106327850
GGAACAGAATCTGTCCTTCTAAGGTGTCTCCACAGTCCTGTCTTCAGCACTATCTGATTGAGTTTTCTCTT
771



ATGCCACCAACTAACATGCTTAACTGAAA






IGHJ6_chr14:106327850-106327950
TAATTCAGGATAATGATGCACATTTTACCTAAAACTTATCCTAAAGTGAGTAGTTGAAAAGTGGTCTTGA
772



AAAATACTAAAATGAAGGCCACTCTATCAG






IGHJ6_chr14:106327950-106328050
AATATCAAAGTGTTTCTCCTTAATCACAAAGAGAAAACGAGTTAACCTAAAAAGATTGTGAACACAGTCA
773



TTATGAAAATAATGCTCTGAGGTATCGAAA






IGHJ6_chr14:106328050-106328150
AAGTATTTGAGATTAGTTATCACATGAAGGGATAACAAGCTAATTTAAAAAACTTTTTGAATACAGTCAT
774



AAACTCTCCCTAAGACTGTTTAATTTCTTA






IGHJ6_chr14:106328150-106328250
AACATCTTACTTTAAAAATGAATGCAGTTTAGAAGTTGATATGCTGTTTGCACAAACTAGCAGTTGATAA
775



GCTAAGATTGGAAATGAAATTCAGATAGTT






IGHJ6_chr14:106328250-106328350
AAAAAAAGCCTTTTCAGTTTCGGTCAGCCTCGCCTTATTTTAGAAACGCAAATTGTCCAGGTGTTGTTTTG
776



CTCAGTAGAGCACTTTCAGATCTGGGCCT






IGHJ6_chr14:106328350-106328450
GGGCAAAACCACCTCTTCACAACCAGAAGTGATAAATTTACCAATTGTGTTTTTTTGCTTCCTAAAATAGA
777



CTCTCGCGGTGACCTGCTTCCTGCCACCT






IGHJ6_chr14:106328450-106328550
GCTGTGGGTGCCGGAGACCCCCATGCAGCCATCTTGACTCTAATTCATCATCTGCTTCCAGCTTCGCTCAA
778



TTAATTAAAAAAATAAACTTGATTTATGA






IGHJ6_chr14:106328550-106328650
TGGTCAAAACGCAGTCCCGCATCGGGGCCGACAGCACTGTGCTAGTATTTCTTAGCTGAGCTTGCTTTGGC
779



CTCAATTCCAGACACATATCACTCATGGG






IGHJ6_chr14:106328650-106328750
TGTTAATCAAATGATAAGAATTTCAAATACTTGGACAGTTAAAAAAATTAATATACTTGAAAATCTCTCAC
780



ATTTTTAAGTCATAATTTTCTTAACCATT






IGHJ6_chr14:106328750-106328850
TTTCTCAGAAGCCACTTCAAACATATCCTGTCTTTTAACAGTAAGCATGCCTCCTAAGATAAACAATCCTT
781



TTCTCTTGGAAACCAGCTTCAAGGCACTG






IGHJ6_chr14:106328850-106328950
AGGTCCTGGAGCCTCCCTAAGCCCCTGTCAGGACGGCAGCCACCGTTTCTGGGCTACCCCTGCCCCCAACC
782



CTGCTCTCATCAAGACCGGGGCTACGCGT






IGHJ6_chr14:106328950-106329050
CCCTCCTGGCTGGATTCACCCACTCCGACAGTTCTCTTTCCAGCCAATAAAGAATTTAAGATGCAGGTTGA
783



CACACAGCGCACCTCATAATTCTAAAGAA






IGHJ6_chr14:106329050-106329150
AATATTTCACGATTCGCTGCTGTGCAGCGATCTTGCAGTCCTACAGACACCGCTCCTGAGACACATTCCTC
784



AGCCATCACTAAGACCCCTGGTTTGTTCA






IGHJ6_chr14:106329150-106329250
GGCATCTCGTCCAAATGTGGCTCCCCAAGCCCCCAGGCTCAGTTACTCCATCAGACGCACCCAACCTGAGT
785



CCCATTTTCCAAAGGCATCGGAAAATCCA






IGHJ6_chr14:106329250-106329350
CAGAGGCTCCCAGATCCTCAAGGCACCCCAGTGCCCGTCCCCTCCTGGCCAGTCCGCCCAGGTCCCCTCGG
786



AACATGCCCCGAGGACCAACCTGCAATGC






IGHJ6_chr14:106329350-106329450
TCAGGAAACCCCACAGGCAGTAGCAGAAAACAAAGGCCCTAGAGTGGCCATTCTTACCTGAGGAGACGG
787



TGACCGTGGTCCCTTTGCCCCAGACGTCCAT






IGHJ6_chr14:106329450-106329550
GTAGTAGTAGTAGTAGTAATCACAATGGCAGAATGTCCATCCTCACCCCACAAAAACCCAGCCACCCAGA
788



GACCTTCTGTCTCCGGGCGTCACATGGAAG






IGHJ6_chr14:106329550-106329650
CTGACTGTCCGTGGCCCTGTCCTGCCCTTCTCATGGAACCCTCTGCTGGCCTCCCACGTACCCCACATTCT
789



GGCCTGACCCCTCAGAAGCCAGACCACTG






IGHJ6_chr14:106329650-106329750
TCGGCCTGGGAAGTCCAACTGCAAGCAGACGGCTGCTAAGTCACCCCCAGGAGTCCAAAAACCCCGGGG
790



GGCACCCGTCCCAGAGAGCGGGTGCCTTGGA






IGHJ5_chr14:106329750-106329850
GCGGGACAGAGTCCCACCACGCAATCATCACGACAGCCCCTGAGAATGCTCCAGGTGAAGCGGAGAGAG
791



GTCACCCCAGACCAGCCGAAGGAGCCCCCCA






IGHJ5_chr14:106329850-106329950
GCTGCCGACATCTGTGGCCGGACTTGGGGAGGACAGGCTGGGTTCCCATTCGAAGGGTCCCTCTCCCCGG
792



CTTTCTTTCCTGACCTCCAAAATGCCTCCA






IGHJ5_chr14:106329950-106330050
AGACTCTGACCCTGAGACCCTGGCAAGCTGAGTCTCCCTAAGTGGACTCAGAGAGGGGGTGGTGAGGACT
793



CACCTGAGGAGACGGTGACCAGGGTTCCCT






IGHJ5_chr14:106330050-106330150
GGCCCCAGGGGTCGAACCAGTTGTCACATTGTGACAACAATGCCAGGACCCCAGGCAAGAACTGGCGCCC
794



CGCTACGTCCCTGGGACCCTCTCAGACTGA






IGHJ5_chr14:106330150-106330250
GCCCGGGGAGGGCCCGGGGGTTGTTGGGCATTGGACCCCAGAGGCCTAGGGTGGCCCTGGCCACAGAGA
795



GACCCGTGCTGCTGGGCTCAGGAGGAAGGAG






IGHJ4_chr14:106330250-106330350
CATCTGGAGCCCTTGCCCCTCGTCTGTGTGGCCGCTGTTGCCTCAGGGCATCCTCCTGAGCCCCCCAGGAT
796



GCTCCGGGGCTCTCTTGGCAGGAGACCCA






IGHJ4_chr14:106330350-106330450
GCACCCTTATTTCCCCCCAGAAATGCAGCAAAACCCTTCAGAGTTAAAGCAGGAGAGAGGTTGTGAGGAC
797



TCACCTGAGGAGACGGTGACCAGGGTTCCC






IGHJ4_chr14:106330450-106330550
TGGCCCCAGTAGTCAAAGTAGTCACATTGTGGGAGGCCCCATTAAGGGGTGCACAAAAACCTGACTCTCC
798



GACTGTCCCGGGCCGGCCGTGGCAGCCAGC






IGHJ4_chr14:106330550-106330650
CCCGTGTCCCAAGGTCATTTTGTCCCCAGCACAAGCATGACTCTGCCCACCCTTTGCCCCAGCAGCAGAGT
799



CCCAGTTCCCAAAGAAAGGCCTTCTGCTG






IGHJ3_chr14:106330650-106330750
AACGTGGTCCCAAACAGCCGGAGAAGGAGCCCCGGAGGGCCCCACATGGCCCAGCGCAGACCAAGGAGC
800



CCCCGGACATTATCTCCCAGCTCCAGGACAG






IGHJ3_chr14:106330750-106330850
AGGACGCTGGGCCCAGAGAAAGGAGGCAGAAGGAAAGCCATCTTACCTGAAGAGACGGTGACCATTGTC
801



CCTTGGCCCCAGATATCAAAAGCATCACACA






IGHJ3_chr14:106330850-106330950
GGGACACAGTCCCTGTTCCTGCCCAGACACAAACCTGTGCCCGTGCAGGACACTCGAATGGGTCACATGG
802



CCCAAGCACAGAGCAGAGGCAGCCGGCGTC






IGHJ3_chr14:106330950-106331050
CCTGTCCCCAGCCACACAGACCCCCGGGCTGAGACCCAGGCAGGGAGGGGTGACGTTCCCAGGGAGACG
803



GTGGCCGGGCTGCCCTGGCCCCAGTGCTCCA






IGHJ3_chr14:106331050-106331150
AGCACTTGTAGCCACACTAAAGCGCAGGCCTGGTCCCCGGCACATGAACAGCCAGCGCCCAGCCCCAGCC
804



CAGGCTCTGCCCACAACTTCTCCTTCCCGT






IGHJ2_chr14:106331150-106331250
CCCTGCCCTCGGCCTGCTTGCTACCTGTGGAGGGTCCCTGACGGGGCTGAAGCCCAGCGGGGTCCCTGCC
805



TGTCCTTGGGGGCTCCAGCTGGCCCCAGGG






IGHJ2_chr14:106331250-106331350
CTAAGTGACAGCAGGGCTCTGGCATGCAGCCCATGGCGGAGACCCCAGGGATGGCAGCTGGTGTGGCCTC
806



AGGCCAGACCCAGGCCGGCTGCAGACCCCA






IGHJ2_chr14:106331350-106331450
GATACCTGGCCTGGTGCCTGGACAGAGAAGACTGGGAGGGGGCTGCAGTGGGACTCACCTGAGGAGACA
807



GTGACCAGGGTGCCACGGCCCCAGAGATCGA






IGHJ2_chr14:106331450-106331550
AGTACCAGTAGCACAGCCTCTGCCCTCCTGCTTCTCCCATACAAAAACACACCCTCCGCCCTCCTGCCGAC
808



CTCCTTTGCTGAGCACCTGTCCCCAAGTC






IGHJ1_chr14:106331550-106331650
TGAAGCCAAAGCCCTTGCCTGGCCCAGTACACCTGGCTCCCCGCTATCCCCAGACAGCAGACTCACCTGA
809



GGAGACGGTGACCAGGGTGCCCTGGCCCCA






IGHJ1_chr14:106331650-106331750
GTGCTGGAAGTATTCAGCCACGGTGAGTCAGCCCTGAGCCAGGGGCTACAGAAACCCACAGCCCGGGGTC
810



CCGGGGGAGCATGGTTTTTGTAGAGCTGCC






IGHD7-27_chr14:106331750-
AATCACTGTGTCCCCAGTTAGCACAGTGGTTCTCAGCTCAGCCAAAACCCTGCGGCTGGTAGGGGGCCTG
811


106331850
TGGGGCTGGGGGCTGATGTGGCTGCGGTCT






IGHD6-19_chr14:106357890-
TGCTGGGTCTGTCCTCTGTGGGAGGGGCTGCTACCCAGGCCCAGGACTGCAGTGGAGGGCTCACTGAGGG
812


106357990
GCTTTTGGGTCTGGCCTGAGCCGCTGTGGG






IGHD3-3_chr14:106380360-
GCTCTCAGGTCTACTGCGGGGACACTCGGGTCTGCCCCTGGCTTAGGTGGACAGTGTCCGTGCCCACCTG
813


106380460
TGCCCTGAGGCTCCATTTCAGGCTGATATC






IGHD3-3_chr14:106380460-
TGTCTGTATTGTCCCTACCCGCTGCATGGCCATGTCCTTTTGGGTTTATAAATTGCCCCCAAATCACGCAG
814


106380560
GCATCATTCAGGCTTTTTATATTCCCTGG






IGHD3-3_chr14:106380550-
TATTCCCTGGGCCACCAGGTGCCTCCACCCAGAAAGCTGAGATGTGGGAGGTTCTAGAGTCATTCTGCAA
815


106380650
CCCTGGATGAGCCCCTGCAGCCTCAGTGCT






IGHD3-3_chr14:106380650-
ACTGAGGTTCCAGCAAGACCTGGAGCAGGTGCAGATGAGGCCTGAGGCCAGGTGAAGCCCAGGCCAGGT
816


106380750
GAGGTCCAGGCCAGTGAGGCCCAGGTCAGAT






IGHD3-3_chr14:106380750-
GAGGCCCAGGTCAGGTGAAGCCCAGGTCAGGTGAAACCCAGGTCAGGTGAGGCCCAGATCATGTGAGCT
817


106380850
CAGGACAGGCAAGGTCCAAGTCAGGTGAGGC






IGHD3-3_chr14:106380850-
CGAGCTCAGGTGAAGCCCAGAGGTGAGGTCTAGGCCAGGTGAGGTCCAGGCCAGGTGAGGTCCAGGTCA
818


106380950
GGTGAGGCCCAGGTCAGGCAAGGCTGAGGTA






IGHD3-3_chr14:106380910-
TCCAGGTCAGGTGAGGCCCAGGTCAGGCAAGGCTGAGGTAGATGTATGAGACTTCTGTAATTTTCAGTTG
819


106381010
GTGCCAACCCTGCCTGGTGTCCCTGCCCCT






IGHD3-3_chr14:106381010-
CCTCCCAGCCCATGCTCTGTGCCTGCCAGATGGCGGCCCCTGCACAGGTGCTGCTGGCTGTGGAGGAGCT
820


106381110
GGGCTCTGCCTCCCTGTGCATGGGCGTCCC






IGHD3-3_chr14:106381275-
GCCTGCAGCCTGTCCGGGGATGCCCAGGGAGGTGAGTGCCACCACATATCAGGCCTTTTCTCTTTAAAGT
821


106381375
CATTTCTTTGGGGATACATCATCAATGTCT






IGHD2-2_chr14:106381485-
TCTAAACACAGCTGTGTGCATTTTCCTCTTCTTGCAATTTAGAATTTTAACTGCTGTTTTCAAGGTACTGTA
822


106381585
ATGTATTTGTTCTCTTCTTGTTAGGAGA






IGHD2-2_chr14:106381585-
CTTGCCAACCCTGTGTGTCTCAGTTCATACCCTCTTCCTTCCCCAGTAGAAGTAACGACCACTGTGTTTAT
823


106381685
GTGATCATCCTTTTCTTGATTTTCCTTAT






IGHD2-2_chr14:106381655-
TGTGATCATCCTTTTCTTGATTTTCCTTATAGTTTTCCTAGTGGAAAGTTTATCCCTTAAGAAGATAGTTCA
824


106381755
TTTTGCCGGCTGTAAATTTTATTTAGAA






IGHD2-2_chr14:106381890-
CTGCCATCGTTTATTTGCCTGTTTTCCTTCAGATGGCTGTTTGCTTCATTCTCAGTTTGGGGCTATGACAAA
825


106381990
CATATGTTCTGCACATCTTTGCCCATGA






IGHD2-2_chr14:106381990-
GGCTCTCAGGGAGGGCTCTGGAGCTGGCATTGCCTGCAGGGCTCTGCTTTGTTGCAGGGAGTTCCTGCCA
826


106382090
AGGCTTTTCAGAGTGTCTGTGCCCAGCCTG






IGHD2-2_chr14:106382090-
AAGGTACACACTGTACTTTGCCCTTGCATCAGGCACTTTCCTTGTGCTTGCTTCTGTGTGGCTCCACATTCT
827


106382190
GGAGAATTTATTCAGATCTGTGCTGCAA






IGHD2-2_chr14:106382325-
CTTCCCACACTGTCCTCCTGGGCTCACTCCCAGCCATCGATCTTGAACACCAGTTTATGGAACTATCTGCA
828


106382425
CAGGAAAGCAGAAACAGCAAAAGGCCCTG






IGHD2-2_chr14:106382905-
TTGCGTGGACCCTGTTTTTGGTCAAGGGAAGTACTTGCTGGTGAAGGAGACCTCCCCTCCTTTCTTTCTCA
829


106383005
GGAGCCCCCTCTGATGCCGTTGCCTGGTG






IGHD2-2_chr14:106383005-
TTTCTCAGGGCTGGTGCTGGGGGCTCAGCAGTGTCTGCCCTGTTCCAGGTGGGAATGTGGGTCTGTTCTGT
830


106383105
TTCCACGCGGTGTTCTGGGGCCGCCAGTG






IGHD2-2_chr14:106383030-
CAGCAGTGTCTGCCCTGTTCCAGGTGGGAATGTGGGTCTGTTCTGTTTCCACGCGGTGTTCTGGGGCCGCC
831


106383130
AGTGAGGGGCTCGGGATGTCAGCGGCTGG






IGHD2-2_chr14:106383130-
TCTCTGTCCCTATGGTCTGGGCTCCGGTTCACTGCTCCCCTGCCCTCCAGGTCGGTCACTGACTCAGTTAC
832


106383230
TATCCAGCGGGCTCCGTGGCTGTTCAGTG






IGHD2-2_chr14:106383980-
GGGAGCAAATGGAGAGGGAAGTGGCAGCGGCCCGAGTGCCAGGCGGTCCCGGTTTGGGGTTGATCTTTG
833


106384080
TGGAACAGCTCCCTGGCCCGTGTGTAAGTGG






IGHD1-1_chr14:106384080-
TCGGGGGAGGCACGGAGGTCTGGAGCTACAAGCGGTGGCAGGAAGGCAGGTCCCAGTCTTGGGGGTCTG
834


106384180
GAGCTTATCTTCTTCCTGTGAACTGAGTGTG






IGHD1-1_chr14:106384630-
ATGGAGGACCTGCCTCGGATGACACCCCTATCTTAAGAAGGTCATGGTGGGTTCCAGCTGGGAGGAAGGG
835


106384730
AAGTGGGCCACCTCCTGGGGGTCTTCCACC






IGHD1-1_chr14:106384720-
GTCTTCCACCCCCACCACCTCAGCCTGGGGCCTCTGTGATTCCTCTCTGCACAGACCCCAAAGTCTGTGCT
836


106384820
GCCGCAGGGCAGGAAGGAAGGGCCTGTGG






IGHD1-1_chr14:106384825-
TCGAGGTTGGGGCCACAGTGGTGTTCCCTAAGCCCGAGTCTGGTCTCATGGCCCGCCCCGCAGCAGGTCC
837


106384925
TGAGTGAGGGACAGAGACCGGGGCGGGGTC






IGHD1-1_chr14:106384925-
TTTGGTCCTGGTGGACTCTGGGGTGGATTCCAGTGGGGAGTCATCAGGGTCGGTGTCCCCCAGGGTACTG
838


106385025
GGGTGTCTCTGCTCCTGGAGTCGGCTCTGG






IGHV2-5_chr14:106494090-
CCTGGGTTTTTGTACAGGAGGTGCCCTGGGCTGTGTCTTTGTGGTCTGTGTGCACAGTAATATGTGGCTGT
839


106494190
GTCCACAGGGTCCATGTTGGTCATTGTAA






IGHV2-5_chr14:106494210-
GTGTCCTTGGTGATGGTGAGCCTGCTCTTCAGAGATGGGCTGTAGCGCTTATCATCATTCCAATAAATGAG
840


106494310
TGCAAGCCACTCCAGGGCCTTTCCTGGGG






IGHV2-5_chr14:106494310-
GCTGACGGATCCAGCCCACACCCACTCCACTAGTGCTGAGTGAGAACCCAGAGAAGGTGCAGGTCAGCGT
841


106494410
GAGGGTCTGTGTGGGTTTCACCAGCGTAGG






IGHV2-5_chr14:106494445-
CTGTGGAGAAAGCATAAGAAGATGAAGCCCACAAACAAGAAAACTGATGTTTCACCCGTGAAGGAGTCC
842


106494545
CTGACCACAGCACTCACATGAAGGGATGGTC






IGHV2-5_chr14:106494545-
AGCAGCAGGAGCGTGGAGCAAAGTGTGTCCATGGTGGGGCACAGGAGTCACTGAGCTGGGACCTGTGCT
843


106494645
CGGCTTTTTCAACCCAGAGGAGGGTGGAGCT






IGHV2-5_chr14:106494565-
AAGTGTGTCCATGGTGGGGCACAGGAGTCACTGAGCTGGGACCTGTGCTCGGCTTTTTCAACCCAGAGGA
844


106494665
GGGTGGAGCTGGTGGAGATTTGCATTCCCC






IGHV2-5_chr14:106494650-
AGATTTGCATTCCCCTCATCTGTGCCCTACTCTATGGGATGGAGTCAGGTTTCAGGACTCAGGAGGGTGTT
845


106494750
GCATCTGTGGTGAGGACCAGTGATAGTAA






IGHV2-5_chr14:106494750-
CATGATCAGTGTAATTCAGATGGCATTAATCTAAGGCTGGGCAAGTAGATTCTGAGTAGAAGTCTTTGCA
846


106494850
GAAGTCATGATTATGAGGTCATGTTGGTCT






IGHV3-7_chr14:106518495-
GCCCTTCACAGAGTCCACATAGTATTTCTCACTTCCATCTTGCTTTATGTTGGCCACCCACTCCAGCCCCTT
847


106518595
CCCTGGAGCCTGGCGGACCCAGCTCATC






IGHV3-7_chr14:106518855-
TGAGTCCTCTGTGCTCAGTGCTGATCACCAAGTGGAAAGGCCTTGGAGTCCAGGGCTAAGGCTCCTCTCT
848


106518955
GAGACCTGCAGGGTCAGGGTTGGGTTGGTT






IGHV3-7_chr14:106518955-
TTCATCAGTAGAGGGAGGGCCCTATTTGCATGTCTCCTACTATATAAGAAGCTCTAGTGGGATGCTGGAG
849


106519055
GAATAGGCTGTACCCATATAAGAAGACGGT






IGHV3-7_chr14:106518970-
AGGGCCCTATTTGCATGTCTCCTACTATATAAGAAGCTCTAGTGGGATGCTGGAGGAATAGGCTGTACCC
850


106519070
ATATAAGAAGACGGTGCTCTGCAGAAGTTT






IGHV3-7_chr14:106519070-
GCTGACAATGATGGTATTTGGAAAATATGCTGTCTTATGAAATTGTGCTGTGATAAACACTTTGCCCTGAT
851


106519170
CACCCTATTACATTTTTTAAAAAATGTGT






IGHV3-11_chr14:106573540-
CAAACACAGAGACAACCTAGTCAGAAACTGCCACATATATTCACTGCTTATCTCACTCACGTCCACTCAAT
852


106573640
GTCTCTAGTTCTCCATAAATCACCTTTTA






IGHV3-11_chr14:106573640-
TAATAGCAACAAGGAAAACCCAGCTCAGCCCAAACTCCATGGTGAGTCCTCTGTGTTCAGTGCTGATCAC
853


106573740
CGAATGGAAACTCCTGGGAATTCTGGGGCT






IGHV3-11_chr14:106573685-
GTCCTCTGTGTTCAGTGCTGATCACCGAATGGAAACTCCTGGGAATTCTGGGGCTGGGGCTCTTCTCCCAG
854


106573785
AGCTGCAGGGTCTGGGCTCGGCTGGTTTT






IGHV3-11_chr14:106573785-
TATCAGCAGAGGGAGGGCCCTATTTGCATGTCTCCTACTATATAGCAAGCTCTAGTGGGACGCTGGAGGA
855


106573885
GAGGGCAGTGCCCAGAGCAGATGAGAGGGT






IGHV3-11_chr14:106573885-
CCCGGAAAACACTGGAGGTAATCCTATCTCTCAGGAAAATATAACTTCAGATTATGTGATTGTGACTTGA
856


106573985
TGATCAATTAGCAGTCATCATCTTATTTAA






IGHV3-11_chr14:106573985-
TGTTTACATATTTGCAGAATATATTCAGTGCAAGTGTCAATGTTACATTTTTAGAGAAGATGAATTACATA
857


106574085
CATAACAGAGCAGTTGTGCAATGTGTCCA






IGHV3-15_chr14:106610690-
ACTCACACTTAATCTCTCTAGTTCTCCATAAATCACCTTTTAAAATAGCAGCAAGGAAAATCCAGCTCAGC
858


106610790
CCAAACTCCATGGTGAGTCCTCTGTGTTC






IGHV1-18_chr14:106642110-
GATGCTATTTAATAGCCCAATTCCTGACCCAGGATGAGAAAGAGCAAATACATGACACATGGACGACACA
859


106642210
ATTGTAGAAGCTGAGGGTTCAAGCCGTAAT






IGHV1-18_chr14:106642210-
CCTGTTAGAGGCCACGCATCCCCTACCCATCCCTGAACTCTGTGTTGACAGAGCTTCCCCCACTGGAGAAC
860


106642310
AAGCTCCCCCAGGACACGCACCTCACTTA






IGHV3-23_chr14:106725295-
GGCCCTTCACGGAGTCTGCGTAGTATGTGCTACCACCACTACCACTAATAGCTGAGACCCACTCCAGCCCC
861


106725395
TTCCCTGGAGCCTGGCGGACCCAGCTCAT






IGHV3-23_chr14:106725395-
GGCATAGCTGCTAAAGGTGAATCCAGAGGCTGCACAGGAGAGTCTCAGGGACCCCCCAGGCTGTACCAA
862


106725495
GCCTCCCCCAGACTCCAACAGCTGCACCTCA






IGHV3-23_chr14:106725550-
ACTGTTTCTCTCACTCTTATCCATTCACACTCAATTTTTCTATTTCTCCATGAATTACCTTTTAAAATAGCC
863


106725650
ACAAGAAAAAGCCAGCTCAGCCCAAACT






IGHV3-23_chr14:106725650-
CCATGGTGAGTTCTCTCTGTTCAGTCCTGATCACCAAATGAAAACACCTGAAAATCCCAGGGCTGGGCTC
864


106725750
CTCTCTCAGAGCTGCAGGGTCAGGGCTGGG






IGHV3-23_chr14:106725780-
TTTGCATATCTCCTACTATATAGTAAGCTCTGGGGTGAGAGGCCTTTGGAGATAGTGGGGCTCAGAGCAT
865


106725880
GTCAGAATGTCCTCGGGGAGATCTGTGATA






IGHV3-23_chr14:106725880-
TTGAAAGCATTGGGAAATTGTGCTTTCCTATTGTCAGTTTGTTTTGTGATAAACTTAAACCTTAAAACCTA
866


106725980
AAAATCTTATAATTTTGTAATTTTTATTT






IGHV3-23_chr14:106725995-
GAGGTACCATAGATCTACATAAACTGCATATTTTTAAAGTTAGCACCAATCATCTTTTATTTTTACATACG
867


106726095
CAGAGAAACCATGGTATATAGTATCAATA






IGHV3-23_chr14:106726095-
TTATTTCCATGTTAAAGATGAAAAATTATCAGCAAAAGCACAGGTGGGTTTTACAATGTCCCCAGTGCTC
868


106726195
ACTTTTGGTCAGAGTGAGCCTGGGCATCTG






IGHV1-24_chr14:106732970-
TCCTACATAATGACAGTGTACACATCTTTCCATTGCTGTTTTACTCAATTACTCAACCCATTTTCTAAACAG
869


106733070
ATTTAAACTTCATAAATCCTGTCATCTC






IGHV1-24_chr14:106733070-
CTCAGCCTCAGCACAGCTGCCTCATTCCTCAGGGTTTCTGACGCTCTCAGGATGTGGGTTTTCACACTGTG
870


106733170
TCTGTTGCACAGTAATACACGGCCGTGTC






IGHV1-24_chr14:106733185-
GCTCAGCTCCATGTAGGCTGTGTCTGTAGATGTGTCCTCGGTCATGGTGACTCTGCCCTGGAACTTCTGTG
871


106733285
CGTAGATTGTTTCACCATCTTCAGGATCA






IGHV1-24_chr14:106733275-
TTCAGGATCAAAACCTCCCATCCACTCAAGCCCTTTTCCAGGAGCCTGTCGCACCCAGTGCATGGATAATT
872


106733375
CAGTGAGGGTGTATCCGGAAACCTTGCAG






IGHV1-24_chr14:106733375-
GAGACCTTCACTGAGGCCCCAGGCTTCTTCACCTCAGCCCCAGACTGTACCAGCTGGACCTGGGCGTGGG
873


106733475
TGCCTGTGGAGAGGACAGAGGAGTGGATGA






IGHV1-24_chr14:106733475-
GACACCACTTAACTGGACCCAGTCCCCTCATCAGCCCTGGAACTCAGGATTCTCTTGCCTGTAGCTGCTGC
874


106733575
CACCAAGAAGAGGATCCTCCAGGTGCAGT






IGHV2-26_chr14:106758470-
GAGGGTGGGAATCTGGGAGAGCAAGGGGCTTCCCATAAGTGTTCTGATAAAAATCCTCTTTGTTTAGGGG
875


106758570
GAAAGTGATGATTTTTTTGAATGATAGAGA






IGHV2-26_chr14:106758570-
ATACATCACCCAAACATTTAAAAATGTATTGTGTAAAGAAGTGTAAATGGCATCTCAGCCATTTACACAC
876


106758670
TGCAAGACACACAGCTTATTAGTGTGCCTG






IGHV3-30_chr14:106791090-
TGGTGAATCGGCCCTTCACGGAGTCTGCATAGTATTTATTACTTCCATCATATGATATAACTGCCACCCAC
877


106791190
TCCAGCCCCTTGCCTGGAGCCTGGCGGAC






IGHV4-31_chr14:106805945-
ACAATCACTTGAGTTCAGACACACCAGGATTCACTTAATGTTATTTTTAGTTCAGAACCTCTATCAGGTTT
878


106806045
AGAGGGAATCGCTCTGTCCCAGGGAGTGG






IGHV4-31_chr14:106806045-
ATCTTACAATAGCAAAACGGTCTTAGAAAACCCAACATAATCTACAGCGAGACCTCAGCATGGCAAGCAA
879


106806145
GGAATCACTAAAGCCACCAGGGAGATCCGG






IGHV4-31_chr14:106806120-
CACTAAAGCCACCAGGGAGATCCGGATGCACTGATACGATCCAGAAACATAGCGAGTCCGGGAACTGAT
880


106806220
GCGGACTTTGAGGCAGCCTCTTTTTTTTTTT






IGHV3-33_chr14:106815805-
GATGGTGAATCGGCCCTTCACGGAGTCTGCATAGTATTTATTACTTCCATCATACCATATAACTGCCACCC
881


106815905
ACTCCAGCCCCTTGCCTGGAGCCTGGCGG






IGHV3-33_chr14:106815905-
ACCCAGTGCATGCCATAGCTACTGAAGGTGAATCCAGACGCTGCACAGGAGAGTCTCAGGGACCTCCCAG
882


106816005
GCTGGACCACGCCTCCCCCAGACTCCACCA






IGHV4-34_chr14:106829685-
CTCGACTCTTGAGGGACGGGTTGTAGTTGGTGCTTCCACTATGATTGATTTCCCCAATCCACTCCAGCCCC
883


106829785
TTCCCTGGGGGCTGGCGGATCCAGCTCCA






IGHV4-34_chr14:106829765-
GGCTGGCGGATCCAGCTCCAGTAGTAACCACTGAAGGACCCACCATAGACAGCGCAGGTGAGGGACAGG
884


106829865
GTCTCCGAAGGCTTCAACAGTCCTGCGCCCC






IGHV4-34_chr14:106829865-
ACTGCTGTAGCTGCACCTGGGACAGGACCCCTGTGAACAGAGAAACCCACAGTGAGCCCTGGGATCAGA
885


106829965
GGCAGCATCTCATATCTTCATATCCGCATTC






IGHV4-34_chr14:106829965-
CTGAGACACTCACATCTGGGAGCTGCCACCAGGAGGAGGAAGAACCACAGGTGTTTCATGTTCTTGTGCA
886


106830065
GGAGGTCCATGACTCTCAGAAAGCACTTCC






IGHV4-34_chr14:106830125-
GAGGATTTGCATGTGGGTGGTGCCTTTGTATGGATAGGTAAAAAGGGATGAGGGAGGCCCCAGTCTTTTG
887


106830225
GGCTCACCCTGGGAGGTGTATGCTGGCTGT






IGHV4-34_chr14:106830240-
AGTTCTCTTCCTGTGGCCTCCCCTCACCAAACCCAGAGTCCTCTTCTTCCAGGTAGGAAATGTGCTGAAGG
888


106830340
AGCTGGTCTGGGAGACAAGTGTGATCATG






IGHV4-34_chr14:106830315-
GGTCTGGGAGACAAGTGTGATCATGGATCAAAGACAGATTTTGGAATACAGTTAATACTGTTCTACATTT
889


106830415
AAAGATTCATATAACACCAACCATACACCC






IGHV4-34_chr14:106830415-
AGGTCACCTAAATTGTCATTTACCCCTTCAGACATATTGAAACAGCTGCTGAGTGTAATAATCACAGTGA
890


106830515
ATTGAGACAAACCTGGATCCATGCAATGTG






IGHV4-34_chr14:106830515-
TACTGTAGTTCAGAACATCCATCATGGTTAGAAGGATGCTACCTGTCCCAGGAAGTGGGTTATTTTTAAAT
891


106830615
AGTACCTGAGAGCTGCCCTTCTGAGACCT






IGHV4-34_chr14:106830615-
TTTGAAATTTGAGATTGTGTGTGAGATCTCAGGAGAAGGTAGTAGAATATATCTCCATCCTTCTCAATGTG
892


106830715
TAACCCTGAGAATATGGCCTGACCTCTAA






IGHV4-34_chr14:106830715-
ACATTTCTGTGTGAAAAGATGTACATTGGGGATAGCAGTGACAGCTTCAGATGAAAACTCTATAGTACAT
893


106830815
CAGCACTGGAGGATAGTCTCATCACCAAGA






IGHV4-34_chr14:106830815-
TTAGTGAAATTACCTTTCCTGGGAACCAGAGAGGACCTCTGTGAGCTCTACCCTCTGAGAGAACAAGGAA
894


106830915
CTCTGGTTCTTCCCTGACAGGTCACACCTG






IGHV4-34_chr14:106831185-
AACAAGTGGGCTGGCCTTCTATGAGACGACAGAGGGAAAGAGACAGACTCAATATCCAGAGCGAGGTGA
895


106831285
GCTCCTTACCTACCTACCAGGTGGTCTCTGG






IGHV4-34_chr14:106831285-
GCCATTTGTTTGAGCAGACCCAGAAGTACCTTCCTCACCCTCAGGAGAATTATGAACATTGAGAGAAACT
896


106831385
GAGATACTTTTTTTATTTACAGGGAATATT






IGHV4-34_chr14:106831385-
TCATCGGCGTGTTTACATCTACCTGGGTGTGTACAGGGATGCTAGGATGTGCTCATACACAGAAGAGCAA
897


106831485
GAATTATATTTCGTGGAAAGAAAACCAAAG






IGHV4-34_chr14:106831485-
AGCTTCTGAATTTGTAGGTATTGTTTGCTGCAAATGTGTCAGGTCACTAGATCATGTTATGCTGCTAGAAG
898


106831585
AAAAACTTCCCAACATTGTCATGGAGACA






IGHV4-34_chr14:106831585-
AAATGCAAAACAGTAAAGATTCAACTGAGATTCCCTTGAAAATCACCAGTAATGAACAGGCCAAAAGAA
899


106831685
ATCAACCATTGTGGAAAGAGTGGTCATTAAG






IGHV3-35_chr14:106846385-
CCCAGTGTCACCTTACACATCCTGCAGGTCACCTCACACATCCACCAGGTCACCGCACATATACCCCACAT
900


106846485
CACCTCAGACACACCCTGGTCACCTCATA






IGHV3-35_chr14:106846485-
CATACGTCAGGTCACCTCACGCTCACCCAAGGTCACCTCACACATCCCGCAGGTCACCTCGTAAATCCCCC
901


106846585
AGGTCACCACATACATGCACCAGTTCACC






IGHV4-39_chr14:106877715-
CTCTTGAGGGACGGGTTGTAGTAGGTGCTCCCACTATAATAGATACTCCCAATCCACTCCAGCCCCTTCCC
902


106877815
TGGGGGCTGGCGGATCCAGCCCCAGTAGT






IGHV4-39_chr14:106877815-
AACTACTACTGCTGATGGAGCCACCAGAGACAGTGCAGGTGAGGGACAGGGTCTCCGAAGGCTTCACCA
903


106877915
GTCCTGGGCCCGACTCCTGCAGCTGCAGCTG






IGHV4-39_chr14:106877930-
GAACAGAAAAACCCACAGTGAGCCCTGGGATCAGAGGCAGCCTCCCATATCTCCATGTCTGCATCCTAGA
904


106878030
AACACTCACATCTGGGAGCCGCCACCAGCA






IGHV4-39_chr14:106878030-
GGAGGAAGAACCACAGGTGCTTCATTTTCTTGCACATGAGATCCATGACTCTCAGAAAGCATTTCCCTTAT
905


106878130
GAGTTGGACCTGAATTTAAGGAAATGTGT






IGHV4-39_chr14:106878130-
GGTGGCTTCCTGTGGGCGCCTAAGTGAGGATTTGCATGGGGGTGGTGCGTTTGTACGGAGCAGTGAAAAG
906


106878230
GGATGAGAGAGGCGCCAGTCTTTTGAGCTC






IGHV4-39_chr14:106878230-
ACCCTGGGAGGAGAATGCTGGCTGTGCCCTTTGAGAACTCAGTTCTCTTCTTGGGCCTCCCCTCTCCAAGC
907


106878330
CCAGAGTCCTCTTCTTCCAGGTAAAGAGA






IGHV4-39_chr14:106878330-
TGTGCTGAAGGAGCTGGTCTGAGAGATGAGTGTGATCCTGGATCAAGGACAGATTTTGGAATAGGGTCAG
908


106878430
TACTGTTCAACCCTTAAAGATTCATATAAA






IGHV4-39_chr14:106878430-
ACCCACCACACACCCAGGCCATCTAAATAGTCATTTACCCTTTCAGACACATTGAAACAACAGCTGAATGT
909


106878530
AATAATGACAGTGACTTCAAACAATACTG






IGHV4-39_chr14:106878540-
ATGTTTATTGTAGTTCAGAACATCCACCATGGTTACAGGGAAGCTCACTGTCCCTGGAAGTGGGTCATTTT
910


106878640
TTAAAAGCACCTGAGAGCTGTCCTTCTGT






IGHV4-39_chr14:106878680-
AAGGTAGTGGGACATATCTCCATACTTCTCAATGTGTGACCTTGAAGATGTGTCCTGCCCTCTAAACACTT
911


106878780
CTGATTGAAAATATGTAGATTGGGGATTA






IGHV3-48_chr14:106994300-
GTGGAAATGCCTTGGAATCCAGGGCTAAGGCACCTCTCTGAGAGCTGCAGGGTCAGGGTTGGGTTGGTTT
912


106994400
TCATCAGTAGAGGGAGGGCCCTATTTGCAT






IGHV3-48_chr14:106994430-
GGACCCTTGAGGAGTAGGCTGTACCCAGATAAGACGACGGTGCCCTGTAGAAGTTTGCTGGCAATGATTG
913


106994530
CATTTGGAAAATATGCTGTCTTATTATGAA






IGHV3-48_chr14:106994530-
ATTGTGCTGTGATAAACACTTTGCACTAATCACCCTATTTCATTTTAAATATTCATGTAAACTATGTTCTGT
914


106994630
AGGAGACAATATTTTCTCCATTTACAGA






IGHV3-48_chr14:106994545-
ACACTTTGCACTAATCACCCTATTTCATTTTAAATATTCATGTAAACTATGTTCTGTAGGAGACAATATTTT
915


106994645
CTCCATTTACAGAAGTGGAAGTAAACCC






IGHV3-48_chr14:106994660-
CTGTATGCATCTAGGAGCTCATGTCTGGGATGAGTGAACCCCGGTATCTGGCCCTGTGCTCTTCATCACTG
916


106994760
TCTCTGACATCCCCCTAAACCAACTCCAG






IGHV3-48_chr14:106994760-
GACAAAGCTGGATGTGTCTAGTGTTTTTATCAGAACCCACTTTCCGTAATAAGAGCATGTGTGGTTTTGCT
917


106994860
GCCCTCCAGCACTCTTCTGAAAATATGGA






IGHV3-48_chr14:106994860-
GAGAACTAGGATCCAGGCACATTAATTTTCAGGTACTTCTGACATTGAACTTATTTTTTCTATCTTTCTATT
918


106994960
ACTCTTTCCTTGTCTAAGTTTCCATTTG






IGHV4-59_chr14:107083565-
AGAGAGACCCACAGTGAGCCCTGGGATCAGAGGCACCTCCCATATCCCCATGTCTGGATCCCTGAGATAC
919


107083665
TCACATCTGGGAGCTGCCACCAGGAGAAGG






IGHV4-59_chr14:107083665-
AAGAACCACAGATGTTTCATGTTCTTGCACAGGAGGTCCAGGACTCTCAGAAAGTATTTCCCATGTGAGC
920


107083765
TGGAACCTGAATTTAAGGAAATGTGTGGTG






IGHV4-59_chr14:107083790-
ATTTGCATGTGGGTGGTGCCTTTGTATGGAGAGGTGAAAAAGGAGGAGGGAGGCCCCAGTCTTTTGGGCT
921


107083890
CGCCCTGGGAGTAGGATGCTGGCTGTGCCC






IGHV4-59_chr14:107083890-
TTTGAGAACTCAGTTGTCTTCTTGGGGTCTCCCCTCTCCAAGCCCAGAGTCCTCTTCTTTCAGGTAAAGAG
922


107083990
ACGTGCTGAAGGACCTGGTCTGGGAGATG






IGHV3-64_chr14:107113405-
CTGACAGTGGTGACCATGGTTGAGAACTTTTCATCTCCTCTGTGAGGATCAATCTGCATTTTCTGCATAGG
923


107113505
AGAATAGGTTTTCATATTAAAACAATCAT






IGHV3-64_chr14:107113505-
TTTAAAAATATGTAGAAATGACCCTAGTAATCACAGAATTCCGAACTTAGGTTCAGTAGAGAAACTTTAA
924


107113605
GAAGATGAAGTCCCACATCGTGACAGGAAA






IGHV3-64_chr14:107113820-
TGGAGATGGTGAATCTGCCCTTCACAGAGTCTGCATAATATGTGCTACCCCCATTACTACTAATAGCTGAA
925


107113920
ACATATTCCAGTCCCTTCCCTGGAGCCTG






IGHV3-64_chr14:107113920-
GCGGACCCAGTGCATAGCATAGCTACTGAAGGTGAATCCAGAGGCTGCACAGGAGAGTCTCAGGGACCC
926


107114020
CCCAGGCTGGACCAAGCCTTCCCCAGACTCC






IGHV3-64_chr14:107114095-
TTCTCTCACTCATGTCCACTCACACTCAATATCTCTATTTCCTCATGAATCACCTTTAAAAATAGCAACAA
927


107114195
GGAAAACCCAGCTCAGCCCAAACTCCATC






IGHV3-64_chr14:107114195-
ATGACTCTTCTGTGTTCAGTGCTGATCACCAAATGAAAACACCTGGGAATCCCAGGGCGGGGGCTCCTCT
928


107114295
CCCAGAGCTGCGGAGTCAGGGCTGGGCTGG






IGHV3-66_chr14:107136755-
TAGGGCACATCCTTCCCATCCACTCAAGCCCTTGTGCATGGGCCTGGCGCACCTAGTGCATAGAGTAACT
929


107136855
GGTGAAGGTAGGTGTATCCACAAGTCTTGC






IGHV3-66_chr14:107136855-
AGGAGACTTTCACTGATGCCCCAGCCTTCTTCATCTCATCCCCAGACTGCACCAGCTGCACCTGGGACTGG
930


107136955
GCACCTGTGGAGAGGACACGGGAGTGGAT






IGHV1-69_chr14:107169645-
GAAAACTTGTTCACAGTAGCACCTTCATGGAATGTTTGTATCAACGTTATAGAGTGTGGCCTTTTCCACTC
931


107169745
TGTGAATTTGGCTTATATTACGACTCTTG






IGHV1-69_chr14:107169745-
AATGGAATATTTATCTTAAAATTAGAGTATGTACTTGTTTCTACTGTTCTTTTTTTCTCAAATATATAACCC
932


107169845
ATTTTGTAAACAGCCTTAAACCTAATAA






IGHV1-69_chr14:107169970-
CTGCTCAGCTCCATGTAGGCTGTGCTCGTGGATTTGTCCGCGGTAATCGTGACTCTGCCCTGGAACTTCTG
933


107170070
TGCGTAGTTTGCTGTACCAAAGATAGGGA






IGHV1-69_chr14:107170070-
TGATCCCTCCCATCCACTCAAGCCCTTGTCCAGGGGCCTGTCGCACCCAGCTGATAGCATAGCTGCTGAAG
934


107170170
GTGCCTCCAGAAGCCTTGCAGGAGACCTT






IGHV1-69_chr14:107170170-
CACCGAGGACCCAGGCTTCTTCACCTCAGCCCCAGACTGCACCAGCTGCACCTGGGACTGGACACCTGTG
935


107170270
GAGAGGACACAGGGGTGAATAAAATCCTCT






IGHV1-69_chr14:107170220-
CCTGGGACTGGACACCTGTGGAGAGGACACAGGGGTGAATAAAATCCTCTTTAACTAAACCAGGATCCCT
936


107170320
TCCTCAGCCTTAGGACTAGGAAGCCCCTTA






IGHV1-69_chr14:107170320-
CCTGTAGCTGCTGCCACCACAAAGAGGAACCTCCAGGTCCAGTCCATGGTGATGAGCTGTGCTCCCAGGG
937


107170420
GCTTCTTCAGAGGAGGAATGTGGTTGTTAT






IGHV1-69_chr14:107170420-
GTGATGCTCTCAGGGCACCAATATATCTATATTTATCTCAGAAGACCTCAGGTTATTTGCATATGCATGAG
938


107170520
GCAGGGTATTTCACAGCTCAAAGCCTGAT






IGHV1-69_chr14:107170475-
TTTGCATATGCATGAGGCAGGGTATTTCACAGCTCAAAGCCTGATCTAGGATGAGAAAGAAAACACAGAT
939


107170575
GCCACATCAGCTGTACAAGTGTGGGATGCT






IGHV1-69_chr14:107170660-
CAGAACAAACCCCAACCCCAGGATGCACTCCTCACTGTGAACCCACATTTTATTGGCCTAAAGATTACCTG
940


107170760
GGTTTTTTGTGGGACCATTGCTGTCTCTG






IGHV1-69_chr14:107170760-
ACATTGAGCAGGCACCTAGACCCATCCTGGTCCCATTAGGAACACTCAGAGCTCACTGGTAACACTGAAA
941


107170860
AGGTGGCCACTCGTTACCCTACATGAGTGT






IGHV1-69_chr14:107170860-
CCAGCAGGACCCATGGAGAGTTCTGAGATCTGCTGGGCACTCCCAAGACAGGGTCCCCAGCACTTTCCTG
942


107170960
AGGGTCCTGACCTCCCAGGTCCTTCAGTGG






IGHV2-70_chr14:107178305-
TTATCCATTTCTATGTGTTCTTTTGAAAATGTCTACTCATGTCCTTTGCTCATTTTAACGGAGTTATTTGGT
943


107178405
TCTTGTTGCTGTTGTTGTTGTAGAGTTG






IGHV2-70_chr14:107178415-
TTGCAAATTCTTCATATTAGTTCCCTGTCACAGGCAAAGTGTGCAAAAGTTTTCTGTCATTCTGTAAATTG
944


107178515
CGTATTCACTCTGTTGTTGTGAAAAAAAT






IGHV2-70_chr14:107178515-
TATTTAGGTTAATTAAATCTCATCTGTCTATTTTTTTTTAGGTAGCAGGACCTTTCATGCTGAATCTTTGTC
945


107178615
AAACAGGATACAGCTTCTGCTTGCATGA






IGHV2-70_chr14:107178615-
ACCACTAACAGGGGACATGCCATTTATTAGTAAAGAAAAAGGAGGAAAACAAGGCTCTGAGTCAGATGG
946


107178715
GGATGGGAAACGCACGCCCTGGGCAGGAAAT






IGHV2-70_chr14:107178715-
GGCATCTCAGCCACACTATCCTGTTCTGCAGAAGTGGGGAGGGAGCACCACTGAAAAACACCTGGGTTCT
947


107178815
TGTACAGGAAGCGCCCTGGGCTGTGTCTCT






IGHV2-70_chr14:107178815-
GTGGTATCCGTGCACAATAATACGTGGCTGTGTCCACAGGGTCCATGTTGGTCATTGTAAGGACCACCTG
948


107178915
GTTTTTGGAGGTGTCCTTGGAGATGGTGAG






IGHV2-70_chr14:107178880-
ACCTGGTTTTTGGAGGTGTCCTTGGAGATGGTGAGCCTGGTCTTCAGAGATGTGCTGTAGTATTTATCATC
949


107178980
ATCCCAATCAATGAGTGCAAGCCACTCCA






IGHV2-70_chr14:107178980-
GGGCCTTCCCTGGGGGCTGACGGATCCAGCTCACACACATTCCACTAGTGCTGAGTGAGAACCCAGAGAA
950


107179080
GGTGCAGGTCAGTGTGAGGGTCTGTGTGGG






IGHV2-70_chr14:107179080-
TTTCACCAGCGCAGGACCAGACTCCCTCAAGGTGACCTGGGATAAGACCCCTGTGGAGAAGACATAAGAA
951


107179180
GATGAAGCCCACAAAGGAGAGAATAGATTT






IGHV2-70_chr14:107179130-
CTGTGGAGAAGACATAAGAAGATGAAGCCCACAAAGGAGAGAATAGATTTTTTGCTTCTGAAGTACTACC
952


107179230
TGACCACAGCACTCACAGGACGGGACAGTC






IGHV2-70_chr14:107179230-
AGTAGCAGGAGCGTGGAACAAAGTATGTCCATGGTGGAGAGCAGGATTCACTGAGCGAGGCCCTGTCCT
953


107179330
CGTCTTTTGAACCCAGGGGAGGGTGGAGCTG






IGHV2-70_chr14:107179330-
GTGGAGATTTGCATCCCCTCATCTGAGCCCTACTCTATGGGGTGCACTCAGGTCTCAGGACTCAGTAGGG
954


107179430
GAGTGCATCTGTGGTGAGGAGCAGTGAGCC






IGHV2-70_chr14:107179360-
TACTCTATGGGGTGCACTCAGGTCTCAGGACTCAGTAGGGGAGTGCATCTGTGGTGAGGAGCAGTGAGCC
955


107179460
CTCAGGTGTGGGGGTCCACGTGTGCTCTCC






IGHV2-70_chr14:107179460-
ATCAGGGAATCTATCTCATTTCAGCACCATGGCTCTCAGTCAAGTCTTGACGCTCCTGCTTCTACAGACAG
956


107179560
GATCTTCTTCGATGCTCCCGCACCGGACA






IGHV2-70_chr14:107179560-
TGCAACCTTCTGGTTTTAGTCCTAGAGGATTAGAGTAGAAATCAAGAGAGCTGCCGTTCCTCCTCCCTTCA
957


107179660
AGAATAATGATGGTGGGCATCTGGGGGGC






IGHV2-70_chr14:107179660-
AAGGGGCTCCCCACAAGCATTCTGATCAAAATCCTCTTTGATTATGGGGAAAAGTGATGAATTTGTGTAA
958


107179760
AAAAATTGGAGAGAATAAATAAGAAAATAC






IGHV2-70_chr14:107179760-
AGTTACAAGTAATTATGTAAAGAAGTGTGTGCTTAGCAGTGTGTGTGCACACAGCTGCATTCCTAGAGGC
959


107179860
ATGTTCCATGAAAAATCGATGTTGTCCTTG






IGHV2-70_chr14:107179860-
TGCCCCGTCAGTTCTGTGGAGAGAGTAGACTGCATGAATGACTTCCCTTTTCTCAGCCCATGAATGAGCG
960


107179960
GATGCTTTGGACAAGGGAATTGGAAGACTC






IGHV2-70_chr14:107179960-
CTGAGGGAGCAGCAGGCTGACTGTTGCAGCCTTGCTCTGCACCTGCACTGGATGTGGTCTCTGTGCTCAT
961


107180060
AAGGCCGTGGAAACTCATCAATCCAGGTTC






IGHV7-81_chr14:107258910-
CAAAAAGGGGTTAAATGATTTTGGAAAAGTAAGTAGAAAATAAAAGAAGGAGGGAGTAAGAGCGGACA
962


107259010
GAAGGGAGGAAGGCAAGCAAGCAATGATGAAC






IGHV7-81_chr14:107259010-
TGTGTAAAATTTTCACTAATTAAAAGACTATTATATTGAAGAGGTGCCTATTAGGCAGCCTTTTGATGTTA
963


107259110
ACCATGTAATATACACCATGAACAACCTT






IGHV7-81_chr14:107259100-
GAACAACCTTGTAGAACACACAAGAGCCCCCTCAGAGAACTGGATGGGTCAGGTCTCCCATCCAGTTGCC
964


107259200
TTAGGGGTTAGGAACGCTCCCATGTTGTTC






IGHV7-81_chr14:107259200-
TCTGGTTTTTGCTCCTGAGGACACAAACAGCCAGTGTTTCCTCCCCGGATGAATAGAGAGGCCCCTGGGG
965


107259300
AGGGTGTGTCTGGCAGCTCACTCTGCACCT






IGHV7-81_chr14:107259235-
GTTTCCTCCCCGGATGAATAGAGAGGCCCCTGGGGAGGGTGTGTCTGGCAGCTCACTCTGCACCTGCACC
966


107259335
GCGGAAGGTTTTAGATGGTCCCTCTCACAC






IGHV7-81_chr14:107259335-
AATAATACATGGCGGCGTCCGAGGCCTTCAGGCTGCTCCACTGCAGGTAGGCGGTGCTGCTGGAGCTGTC
967


107259435
GGCTGAGATGGTGACGTGGCCTTGGAAGGA






IGHV7-81_chr14:107259435-
TGGGCTGTATCTGGTATCAGAGTTCCCAGGATAGATGCTCCCCATCCACTCCAGTTCTTTCCCGGGCATCT
968


107259535
GGCGCACCCAGTGGATCCAGTAGCTGGTA






IGHV7-81_chr14:107259555-
ACAGGAGATCCTCAGAGACTCCCCGGGTCTTTTCACCTCTGCTGCAGACTGCAACAGCTGCACCTCGGCA
969


107259655
AAGACACCTGTGTGGGAGACACAAAATTTG






CIITA_chr16:10971440-10971540
GTGTCTGGAGTATGAACCATGTATCAGCACCGAAAGGTTCTAGAAGTCAGACTTTCGGGCAGTGTGTCAC
970



TAACTCTCAGCATGCTGGCCTGGCTCGGCC






CIITA_chr16:10971540-10971640
CACAGCAAGGTCTTCTCGCCTCCCTTTGGGTAAATACTGAGGGGTGCCTCTGCAGGACGGGACCTCTGCC
971



AGACTCCACTCCATACCCAGAGAAGCAGGG






CIITA_chr16:10971640-10971740
AAACCAAAATTGGAGTCAGCCTTGAGGTGTAGCTGTTGAGCCCTCAGCAGCTGGGGAGAGCTGGCGGAT
972



GCTGCCCTCCCCCCAGTTTCCTAATGGTGTT






CIITA_chr16:10971740-10971840
GTTTAAAAAGGGTCAGGGGACGGGGGAACAGATGGTGGGAAGAGCACAGTGCAGACACCTGGCACCGGC
973



TCTGAAGGCAGCATGGCAGCTACACCGTTGG






CIITA_chr16:10971840-10971940
CTGGGAAGGGTGTGCCCCTGAAGAAGTCGTTTACATTCTCGAGTCAATTTTCCTGGAGTGTACAATGGAC
974



CTGTGGGAAAGCCTGTATGAAAGGGTAATG






CIITA_chr16:10971940-10972040
ATGAGGGACCTAGCACAGTGTCCAATATTTTATAGGAACTGGAATTGAGCTCATAGGAGCTCAATTTTAT
975



TGGCATTGCTGTTGTTGGATGGTTAAAGGG






CIITA_chr16:10972040-10972140
GTGGTATCCCTTTTCTCAGACTCCCCTGAAATGTATGGTTTGCTTTGAACCCAGAGACTGATGACAGGTCT
976



GCCGGTGTGGTTGGGTGCAGCCTTAAGTT






CIITA_chr16:10972140-10972240
GCTACGGGAAAGTGTTGGAGGGGGAGAAGTCAGAGGTAACCTTGCCCCCTCCCTCAATTCCAGATGAGGA
977



AATTCAGGCCTGAAAAGGGAAAGTGACCAC






CIITA_chr16:10972240-10972340
CTCAAAGTCTCATGCCTTGGAGGACCCAGCAGGAATCCAAGACCTCTGAAAAGGACCGGCAGGGCTCTTG
978



CCACGGCTGGGGGTGTGGTCATGGTAACAC






CIITA_chr16:10972340-10972440
AGGTTTTCCATCCATGGAAGGTACCTGAGGGATTTTCTCTTCCTCCCTAGGGCCAGCATCAGAGGAGTGA
979



ATAGCTCAGTTAGCTCATCTCAGGGGCCAT






CIITA_chr16:10972440-10972540
GTGCCCTCGGAGGTGGTTTGCCACTTTCACGGTTGGACTGAGTTGGAGAGAAACAGAGACCCACCCAGGG
980



GTGGGGACAAGCTCCCTGCAACTCAGGACT






CIITA_chr16:10972540-10972640
TGCAGATCACTTGCCCAAGTGGCTCCCTAGCTCCTGGCTCCTGGCCCGGGGCCTGGGACTCTCCCCGAAGT
981



GGGGCTGGCCACTGTGAGGAACCGACTGG






CIITA_chr16:10972640-10972740
AGGCAGGGACCTCTTGGATGCCCCAGGCAGTTGGGATGCCACTTCTGATAAAGCACGTGGTGGCCACAGT
982



AGGTGCTTGGTTGCTCCACAGCCTGGCCCG






CIITA_chr16:10972740-10972840
AGCTCAGCGCTGCAGAAAGAAAGTGAAAGGGAAAAAGAACTGCGGGGAGGCGGGGAGGTAGGATGACC
983



AGCGGACGAGCTGCCACAGACTTGCCGCGGCC






CIITA_chr16:10972840-10972940
CCAGAGCTGGCGGGAGGGAGAGGCCACCAGCAGCGCGCGCGGGAGCCCGGGGAACAGCGGTAGGTGAC
984



CAAAGTCTCCTCTGTAACCCCTAAGGTCGGGC






CIITA_chr16:10972940-10973040
TGAGAATCGAGGCTCCGAGACTGTCAGCTACTTGCTCAAGGTCACACAGCAAGTCTGGGAGGATGGGGG
985



GATGGAATATGCAAAATGTAGGGCCGGGAAA






CIITA_chr16:10973040-10973140
CACCTCGTTTCCAGCATCCCCGCAACGACTCTGCGCGGGAACCAGGAGCCGGGAACCCGGAGCTTGGCTT
986



GCTGTGCCCAGAGCTCCGGGGCCGTGGGCG






CIITA_chr16:10973140-10973240
GGTGGCAGGAAAGCCTGGCGGCAGCTTCTGCAGAGAAGCCGGAGCGCAGACTGGGAGCGCGGAGCAGAC
987



ACACTCCCCCGGCCACCCTTGGCCGACTCCG






CIITA_chr16:10973240-10973340
CGCGCCCGGGATCCTGCAGAGGTGCGCGCCCTTCTTGTACGCCAGACTTTGGACCAGGGCCGCCGTTCCC
988



TGAGCTTCACTTTCCCTGTTGGGTCATATT






CIITA_chr16:10973340-10973440
CCATCTCTAACTCTGGAATCTTGGGTATTGGGCTCTCCAGGCGGGGGGCCCTGCTCAGGGAGGCAGTAGG
989



GAGCCAAACCTTTAACCAGAGGATGGGATA






CIITA_chr16:10973440-10973540
AGTCCTCAACTCTCGTTGAACATCTTGGCGAAGGTGTGTGTTGTTGGGAGGGGTGGGGGAGGGATCCCCC
990



CGGACTGAACCGATCTCTTGATCTCTCACT






CIITA_chr16:10973540-10973640
TCTCTACCTCGCTTTGGGGCCCTGAGTCACACCCTCTAAGGAGAGAGGCTAAAGCGCCCCGGAAAGCCAG
991



CGTGCGAATGCCGGGGTGGGAGTGGGAGAT






CIITA_chr16:10973640-10973740
TGGATCTCCCTGGGGTCCAGGAAAGCCGGAATCGGAGCCACCATGCTTAGCTTAGTCTGGAACTCTTAAA
992



AGCCGCGGTCCTCCTGAGTCCCACAGCCCC






CIITA_chr16:10973740-10973840
TCTCCACCCTAGGTGGCACAGGAGAGGTGGCAAAAGCCTAGAAGTTCAAGGCATGGCTCCCTCCCCAGCC
993



GCAGCCTGGAGTGTCTAACTTTGGCAGGAA






CIITA_chr16:10973840-10973940
GTCTTCCGTTTCTGCTCCCCACTCCAGAGAAAAAATAAATAAATACTTCTCCGGAGTGAGATTAAGGAAA
994



CAGGTACTTCTTCCTCTTGGAGAAAGAGGA






CIITA_chr16:10973885-10973985
CTTCTCCGGAGTGAGATTAAGGAAACAGGTACTTCTTCCTCTTGGAGAAAGAGGAGCCAAAGGAACTTGA
995



CTCCAACAAATGATCACCTTGCAAACCCCC






CIITA_chr16:10973985-10974085
GGCTCCCTTAGGGGATGACCTGGTCTCCAACAATCTCAGAGCGTTTGGAGGCAGGGTCTTTGGAGATGAC
996



TGAGTGGGGAATCCCAGGCTCCCCACACAT






CIITA_chr16:10974085-10974185
GAACATCACCTGGGATGATCAACCTGTTCAGGATGTAGGTTCCCGGGCTCACCCCCAGGCCCGGTTGGCT
997



AGGCCTGGGGTGAGGCTGAGATCCTGCAGG






CIITA_chr16:10974185-10974285
TTAAACCATCTATCCCAGGTGACTCCAATGTTCGTTTGTGGGGCAAAAGTCCCTCAAGTCAGAGACACTG
998



GGAGGCGCTGATGTGGTCTCATCTCTTTAC






SOCS1_chr16:11348520-11348620
CAAGAGGTGAGAAGGGGTCTGCGGCCTCGTCTCCAGCCGAGGGCGGGAGGCGCCTCGCCCCTACACCCAT
999



CCGCTCCCTCCAACCCAGGCCGGGGAGGGT






SOCS1_chr16:11348620-11348720
ACCCACATGGTTCCAGGCAAGTAATAACAAAATAACACGGCATCCCAGTTAATGCTGCGTGCACGGCGGG
1000



CGCTGCCGGTCAAATCTGGAAGGGGAAGGA






SOCS1_chr16:11348720-11348820
GCTCAGGTAGTCGCGGAGGACGGGGTTGAGGGGGATGCGAGCCAGGTTCTCGCGGCCCACGGTGGCCAC
1001



GATGCGCTGGCGGCACAGCTCCTGCAGCGGC






SOCS1_chr16:11348820-11348920
CGCACGCGGCGCTGGCGCAGCGGGGCCCCCAGCATGCGGCGCGGCGCCGCCACGTAGTGCTCCAGCAGCT
1002



CGAAGAGGCAGTCGAAGCTCTCGCGGCTGC






SOCS1_chr16:11348920-11349020
CATCCAGGTGAAAGCGGCCGGCCTGAAAGTGCACGCGGATGCTCGTGGGTCCCGAGGCCATCTTCACGCT
1003



AAGGGCGAAAAAGCAGTTCCGCTGGCGGCT






SOCS1_chr16:11349020-11349120
GTCGCGCACCAGGAAGGTGCCCACGGGCTCGGCGCGCAGCCGCTCGTGCGCCCCGTGCACGCTCAGGGGC
1004



CCCCAGTAGAATCCGCAGGCGTCCAGGAGC






SOCS1_chr16:11349120-11349220
GCGCTGGCGCGCGTGATGCGCCGGTAATCGGCGTGCGAACGGAATGTGCGGAAGTGCGTGTCGCCGGGG
1005



GCCGGGGCCGGGACCGCGGGGCACGGCCGCG






SOCS1_chr16:11349220-11349320
GGCGCGCGGGGGCCGCGGGCGAGGAGGAGGAAGAGGAGGAAGGTTCTGGCCGCCGTCGGGGCTCTGCTG
1006



CTGTGGAGACTGCATTGTCGGCTGCCACCTG






IGHV3OR16-12_chr16:33523607-
TTTAAAATCACCCAAATCAAAATAATTTTATCTTCATTAATAAATAATCATCAGAAGTTTAACTAATTTTT
1007


33523707
ACTTTATAATACTAGGTTTAAAAATTCTT






IRF8_chr16:85933003-85933103
AATCTGAATGCCCAAGTCGTTGATTGTCGTTTGCCTGTTTCCAAAGATTGGTAGATAGATGCCTTTTTAAA
1008



AATCTCATTTTTCTTTAAATCTGGTTTAC






IRF8_chr16:85933103-85933203
ATGGAAAACGTTAGGAGAGCTCATATAATGAACGGCAATAGCAACCCCCTATCTTGAAACGCGCTCTATC
1009



ATCCCACTGAAATTCTACCACGTGGAATAA






IRF8_chr16:85933203-85933303
TGCTTGGAGGGTCAGAGTTGTGGAACTGCCCAATAACCAGTCGTTACTGAGGGTTAGTTTGTGAAGGAGG
1010



GGACAGACTGCTTCTAAAATTCTGTTTAAT






IRF8_chr16:85933303-85933403
GACAGTCAATTAAGATTTCTGAGTCTGGCTTGAGGGCCTTTGCTTCCATCACAGCCCAGTCGTCCTTGGCA
1011



AGAGAGTCTGTATATGGGCCACAGCTCAC






IRF8_chr16:85933403-85933503
AAAAGCATTGTTTGAAAAAATTTATTGAAAGAACATTGTTTGTAAAATGAGTCCCAATACATAGGACAGA
1012



CTTTCCTAAGGTGAGATGTGTTACTTACCC






IRF8_chr16:85933503-85933603
AGAGCTGTGAAAGGCTTTACGGATGGAAACTAGAGACTGAATTTTCCAGAATTTTAAGAAGTCTCCCCAA
1013



CCAATGGCCCCCCACTTTCTTTTTTTAAAC






BZRAP1_chr17:56408574-56408674
GGCGTGATCTCCGAAGCCCACAGTACACTCATCCATAAAGTAGGAAACACTACACCCTCCAGTGCTGTTA
1014



GTAGTGCTTTCTACTTTATGGGTGACTGCA






BZRAP1_chr17:56408674-56408774
TGTCTGTCTGTCCGTCGGCGTGTACTCTTCAGGCTGCCCAGGCCTCCTGACTCCTGCTCCAAGAGCCCCC
1015



CAGCCCTCCTTGTGGCTTCCTAAGATCCC






BZRAP1_chr17:56408884-56408984
CCCTCTTCCCTTCCCCCTAAAGGCTCCACCCCATCCCCCCAGTTTCAGAGACACTCAGGTAGAGACTAGGG
1016



CCTCTGGAGGCCTCACCTTCAGTTCTGTG






BZRAP1_chr17:56408984-56409084
AACCCCTGGCTGGCCGCTTCCAGCCACGCTAGCCACCCTCCAGCGTCCAAATGAGGCAGCCACAGCTCCC
1017



CTGCCAAGGTCTTGGTCTCCAGTCCACCCC






BZRAP1_chr17:56409084-56409184
AACCGTGAGGTCCTGACTGCCCAGAGCCTCAGTCCCCACCCTTCAGCCTCCCCACCAGCCCAAGATCCTGA
1018



CCCCCCAGGGCCTAAGTCCCCAGCCTCCC






BZRAP1_chr17:56409184-56409284
CAACAGCCCAGGGTCCTGACCCCCCAGGGCCTCAGGCCCTGGCCTCCCCACCAGCCCAAGGTCTTGAACA
1019



CACCAGGGCCTCAATTCCCAGCCTCCCCAC






BZRAP1_chr17:56409284-56409384
CAGCTCAAGGTCCTGACTCCCCCAGAGCCTCAGTCCCAGCCTCCATAGCAGCCCAAGGTCCTGACCCCCCA
1020



GGGCCTCAGTCCCCAGCCACTCCACCAGC






BZRAP1_chr17:56409384-56409484
CCCAAAGTCCTGACTCCCCAGAGCCTTGATTCTCGGCCTCCCCACCAGCCCAAAGTCCTGACTCCCTCACT
1021



GCCCTGCTGTTCCCCTGGCAGGAGCCCAA






BZRAP1_chr17:56409484-56409584
GGCTATCCCAACAAAAATGGTGGCCATGTTGGGCGGAGGAAGAGGCTGGCGCCCCTTGAGACACTGGTCC
1022



CACTTCTCAGCCTCTGCGTACCCTCTGCCA






BZRAP1_chr17:56409584-56409684
TCCCCGCCTTACTCTCCAGCCCTCCTCCTTGGACACCTCTTTCCCCGCCTGGGGTCCCGGAGCCATTTTACC
1023



TTCCTTCACTAGAGAGGGTTTCAAGGCG






GNA13_chr17:63010240-63010340
CTAAGATTTTCAAGAAGTTAAACGTAGAATTAAGATTGTTCTAATTCTGGTTGTAAACTGCTATTTTAAAA
1024



AACAAAACAAACAGAAAACATCAAAAACA






GNA13_chr17:63010315-63010415
AAACAAACAGAAAACATCAAAAACACAAAAAGATATTAAAACAGCAAGTCTTTTGTACATCACTGTAGCA
1025



TAAGCTGCTTGAGGTTGTCATGCAGAATAG






GNA13_chr17:63010415-63010515
TATCCTTCACGTCACGGAAAACAAGGCGGATGTTCTCCGTGTTGATAGCAGTGGTGAAGTGGTGGTATAA
1026



GGGCTTCTGTTGCTGGTCCCGGCGTTTGTT






GNA13_chr17:63010515-63010615
CCGGAAACATTCCACCAGGAATTTTTGGACGTCTCTTAAGCAGTGGGGATCCCCTTCAAATTCTAGGAAA
1027



TAGTCTTTGATGCTCACAATTTGCACCTTC






GNA13_chr17:63010615-63010715
TCCTCAAGCAAGTCTGTCTTGTTTAAGAACAGAATTATGGAGACATTGCTGAAAACCCGGTTATTGACGA
1028



TTGTTTCAAAAATGTTCAGAGACTCTGTAA






GNA13_chr17:63010715-63010815
GGCGATTGGTCAGTCGATCTTCCATAAGCACCTGGTCAAATTCACTTGAGGAAACAAGGAAAAGTATTGA
1029



TGTCACACTGTCGAAACATTCAAACCAACG






GNA13_chr17:63010815-63010915
TTTCCTTTCTGATCTCTGACCACCTACATCAACCATTTTGAAAGGAACATTTTTTATTTCAAAGTCGTATTC
1030



ATGGATGCCTTTGGTGGGTCTTCTGGCA






GNA13_chr17:63010915-63011015
AGCAGAATATCTTGTTGTGATGGAATATAATCCTGGAAAAGAAAAAACTTGTTTTATACCTATTAATCCCG
1031



AAGTAATGCGAATTTTTAATGGACTACTA






43717_chr17:75447868-75447968
TGTAAATATTTGGCCAACTAAGCTGAGTGGCTAAGTTCTCCTGCTGCCCGGAGCTTCTTGGAACATGTTTC
1032



CTTTTCGCAAGGGGTTTCCCTGGCTTCCA






43717_chr17:75447968-75448068
GGAGGGCCAGGAAGAAATTCGAATTGGCCACCGCTTTCTCTAAAATCACTCCGCTCAAGTTATCACCCCT
1033



CTGGGCTCCCGAAGACCGGCTGGCTGGAGG






43717_chr17:75448068-75448168
CTGGAGATAGTCTCAATGCTCGAAATGCCGTAACCGAAGCTCCCCGCGGCGCCGGCACTGGGATCCAGGG
1034



AGCTGCTGCTACAGCGCAGCTCTGGATTCC






43717_chr17:75448168-75448268
TGGATGTGTTGGATATGTGCAGGGCGTTCCTGGGAGGAGCGGGGAGGGAGGGTGCTGCTGGCGGGGCTG
1035



GTCTGCGTGTGCTTTGCTTCTCTACAATGGC






43717_chr17:75448268-75448368
ATGCTGCGTGTCGGCCATGCAGAGGCATGTCAGTGAGCAGGGGCTGAGGGATCTCCCTAACGGACCTGCT
1036



TTCAGAGGGTCTTTTCATGCTGGGAGAACC






43717_chr17:75448368-75448468
CCAGAGACTAAATCATGCAGCCAACGGGGTGGTCCCCGGCCTCAAAGCAGGGAGGGGCGAGGAGCTTTG
1037



TAGGCAATGCCATCTGCTCCTGAAACGCCGT






ADCYAP1_chr18:1477565-1477665
CAGCCTCCTTAGTAGCTACCGCCTTAGTAAGTACCACTTAGTAAGTACCGCCTTAGTAAGTACCACTTAGT
1038



AGCTACCTCCTTAGTAAGTACCACTTAGT






ADCYAP1_chr18:1477665-1477765
AAGTACCTCCTTAGTAAGTACCACTTAGTACTACCACCACGCCTGGCTAATTTCGTATTTTTTTTTTTTTAG
1039



TAGAGACGGGGTTTCTCCATATTGGTCA






AC012123.1_chr18:30349775-
AGGTCAGGCGCATACTGCATGCGGGTCTCGCGGTCGTGCTCCAGCCACAGCACGGACATCTGGAAGAGCG
1040


30349875
CCAGCTCCGACTCCACGGGGGGCGGCAGCG






AC012123.1_chr18:30349875-
AGTCCAGCAGGGCGCGCATCTCCTCGAAGTTGAGCAGCAGCACATCCTCCACCAGGTACTTGTTGGCCAG
1041


30349975
CTTCTTGGTCTCCTCCAGGCCGTGCAGCGC






KLHL14_chr18:30349975-30350075
GGCGATCTTGCACACCTGCTTGTAGTTCTGCACCGAGATCTGGTCGTTGAGGAACTGCACGCAGAGCTTG
1042



GTGACCTGGGGGATGTGCAGGATCTTGCTG






KLHL14_chr18:30350075-30350175
ACCGACAGCACCTCCTCCACCGTGTCCAGGGACAGGGTCACGTTGGCCGTGTAGAGGTACTCGAGCACCA
1043



GGCGCAGCCCGATGGACGAGCAGCCCTGCA






KLHL14_chr18:30350175-30350275
GCACCAGGTTGTTGATGGCCCGGGGGCTGGTCAGCAGCTTGTCGTCGGGGGAGGAAGAAGGAGTCCCGG
1044



GCTCCTCCTGCGGCGGCGGCTGCTGCTGCTG






KLHL14_chr18:30350275-30350375
TGACGGCTGCTGCTGCGGCGGCTGCTGCTGGTCCTTGGGGGCCCCCAGGCCGTCCTGGCCGCCGACCCCT
1045



CCCCCGAGAGGGGGGTGGCTGGAGAAGAGC






BCL2_chr18:60806264-60806364
GAGACTTCAGCCGGAGCTGGCTATTCCAGAGATGGACCTCAGAGGATTCCTTAGTCTAATTACCTTCTGG
1046



GCTGGGGTAGAAGATGGTGTCTGGAGGGAA






BCL2_chr18:60806364-60806464
GCACAGAACCAAGTTCCCTACTGCCGCACTAGCTATGCAAATACTGCAGGGCACCTGTGGGCTCATGTCC
1047



CTCCTGCAAGAAGGTGTGGTCAGTCCAGTA






BCL2_chr18:60806464-60806564
ATTCAAAAGACGTACTTCTGAAATAGGTGGAGAAATGCATTTATAGCAAAAAGTGCTAAAAATATGTTAA
1048



TAGTTATGCTATTTGGTTCACCAGGTTAGT






BCL2_chr18:60806564-60806664
GTAATAAACCATAACAAGAGAGACTAAAGGCCGTATCTATATGACCTTGAAATCTCATCTTCAGCGGGCT
1049



TATTCATTCAGTAACCAAACTATTTTTGTA






BCL2_chr18:60806664-60806764
AGGTGCTGAGTATTTAGCTTAAAGCTAAATAAGACACATGCCCTGCCCTATAGTAACTGCTTGGTAATATT
1050



CCCAGTGGCTTCCATGGGCCTGATAATTT






BCL2_chr18:60806764-60806864
TCTTAGTACTGAATTCAAAGCACTTTGTGTCTTGTCTGCAGGCCCATTTGCCCAGCAGTGGCCTTGCCAGG
1051



AGAGAACAGGCCCATGCTCCTGTCCTCAT






BCL2_chr18:60983784-60983884
CAAACAAACAATTCAAGAAGAGGATTTAAATTTTAGAAATTTAAATTGGGGCATTTTAGTTAATCTTACTT
1052



TTAAACACCAAACAGTGGCATCAATATTT






BCL2_chr18:60983884-60983984
TGTCAACTTTGGTCAAATAAGATCAGATGTTCACATCAATCATCTACTTTTCTTGGCCTTTTCTCTATTTGG
1053



CCTCCTAGTATGAGCACACTTTGTAAAA






BCL2_chr18:60983984-60984084
TGTAATAAAAACATGTGGTGTGCTTCTTGACATCTAATCCACTTGCAGTAATTTCTAGGCTTTTTGCTCCT
1054



GTTAGGTCCTATAAAATAATGACATTAGT






BCL2_chr18:60984454-60984554
ATAGATACCTAGATGCAAATTTTTTTCAGCCGACCACAAAATTAGGTCCACTCTGAGTGGTGAAAAACAA
1055



AAGATTCTAACATTCTAGCAAACTGGTAAA






BCL2_chr18:60984554-60984654
CCATACACAAATTATAGAATACAAAGAATGCAGCCGATGCAAATTCTGTCACTGACAAGGTAGCAAAGCC
1056



ATAGCCTGATACTCCTCAGGACACCTCATC






BCL2_chr18:60984654-60984754
ACGCCCACTGGGAACATGGCACACACTGGAGATTCCAGTCCAAGGACTTTGGAATGTCAACTTAGCTCTT
1057



TACAAACACAACTAAGTTTTTCAGGGAAAA






BCL2_chr18:60984754-60984854
AGACTTACATTGGTTTTCCTCTTTTGGAAAATTTTACCGATTGATGATGCCCTTGGTCTTCTGTGGAGTCT
1058



ATTCTTCTAATCGGGTTGTTCTCCAATTT






BCL2_chr18:60984854-60984954
TAGTGTACAACGGGCTTGTTTCAGGGGAGCTTGTTTGGGATGCAGACTGTCAAGACCCAACCTGGTATCT
1059



GGTTCATAAGCAGTCCCTGAAACCTCCCTC






BCL2_chr18:60984954-60985054
CGGTTCCAACAAGCTGCTCAAGCCAGGAAACGGTGGTCCTGGGGACTCCTGGACCTTCAGCTTGAGAAAC
1060



ACTGAAGGGGTACCATTTACCACCACATCC






BCL2_chr18:60985054-60985154
TACTGGATTACAAACGCTAGATCTTTGGATCTCCACGACTAGCAAGCAAGTTAAAGACTTTTAGATGGCA
1061



GGCGTTATCGGTCAGGTTGGGAGTGAACGC






BCL2_chr18:60985154-60985254
TTTGTCCAGAGGAGGAGGTAGGGACGCCGGGAAGCAACAACTCTGATTTTATTTCGCCGGCTCCACAGCC
1062



TCCCATTGCCCCAGGAGCCCACCCGCACTC






BCL2_chr18:60985254-60985354
CAACCCCCGCATCTCGGACCTGTGGCCTCAGCCCAGACTCACATCACCAAGTGCACCTACCCAGCCTCCGT
1063



TATCCTGGATCCAGGTGTGCAGGTGCCGG






BCL2_chr18:60985354-60985454
TTCAGGTACTCAGTCATCCACAGGGCGATGTTGTCCACCAGGGGCGACATCTCCCGGTTGACGCTCTCCAC
1064



ACACATGACCCCACCGAACTCAAAGAAGG






BCL2_chr18:60985454-60985554
CCACAATCCTCCCCCAGTTCACCCCGTCCCTGAAGAGCTCCTCCACCACCGTGGCAAAGCGTCCCCGCGCG
1065



GTGAAGGGCGTCAGGTGCAGCTGGCTGGA






BCL2_chr18:60985554-60985654
CATCTCGGCGAAGTCGCGGCGGTAGCGGCGGGAGAAGTCGTCGCCGGCCTGGCGGAGGGTCAGGTGGAC
1066



CACAGGTGGCACCGGGCTGAGCGCAGGCCCC






BCL2_chr18:60985654-60985754
GCGGCGGCGCCGGGGGCAGCCGGGGTCTGCAGCGGCGAGGTCCTGGCGACCGGGTCCCGGGATGCGGCT
1067



GGATGGGGCGTGTGCCCGGGCTGGGAGGAGA






BCL2_chr18:60985754-60985854
AGATGCCCGGTGCGGGGGCGGCCCCCGGGGGCGCGGCGCCCACATCTCCCGCATCCCACTCGTAGCCCCT
1068



CTGCGACAGCTTATAATGGATGTACTTCAT






BCL2_chr18:60985854-60985954
CACTATCTCCCGGTTATCGTACCCTGTTCTCCCAGCGTGCGCCATCCTTCCCAGAGGAAAAGCAACGGGG
1069



GCCAACGGCACCTCTCGCCCCAGCTCCCAC






BCL2_chr18:60985954-60986054
CCCACGGCCCCCAGAGAAAGAAGAGGAGTTATAATCCAGCTATTTTATTGGATGTGCTTTGCATTCTTGG
1070



ACGAGGGGGTGTCTTCAATCACGCGGAACA






BCL2_chr18:60986054-60986154
CTTGATTCTGGTGTTTCCCCCTTGGCATGAGATGCAGGAAATTTTTATTCCAATTCCTTTCGGATCTTTATT
1071



TCATGAGGCACGTTATTATTAGTAAGTA






BCL2_chr18:60986154-60986254
TTGTTAATATCAGTCTACTTCCTCTGTGATGCTGAAAGGTTAAAGAAAAAACAAACTAATAAGTAAAAAA
1072



TCAGGTGCGTTTCCCTGTACACACTGAGTG






BCL2_chr18:60986254-60986354
AAAGCAGGGCATACACACTACAAGTAACACGGCTAAAAAGAATGTATTAAGCTGCCTGGAAATTAAATTT
1073



ACTCGAATGCACTTTAAGTAAAAAATCTCA






BCL2_chr18:60986354-60986454
AAGGTTTCCATTGAAAGTTACATTAAACCAATTTCCTGTGCAGAGAACTTACTTGTATTTTTTAAGTACAG
1074



CATGATCCTCTGTCAAGTTTCCTTTTTGT






BCL2_chr18:60986454-60986554
AAAACCAAAACAAATGCATAAGGCAACGATCCCATCAATCTTCAGCACTCTCCAGTTATAGCTGATTTGA
1075



AACTTCCCAATGAATCAGGAGTCGCGGGGA






BCL2_chr18:60986554-60986654
GAGGGAGTAAAAATTAGGAGGATTTCCAGATCGATTCCCAGACTTCTGCTTCACAGAAATGTCAATCCGC
1076



AGGAATCCCAACCGGAGATCTCAAGAGCTC






BCL2_chr18:60986654-60986754
GAGAAAAAAAAAAGGCAGCGGCGGCGGCAGATGAATTACAATTTTCAGTCCGGTATTCGCAGAAGTCCT
1077



GTGATGTTTTCCCCTTCTCGGCAATTTACAC






BCL2_chr18:60986844-60986944
TGAAGGAGCCGGGGACGGAGGCAGGAATCCTCTTCTGATTAAACTCCGAACAGCAAATGCATTTTCCGAA
1078



AAGCTGCTGGATAAATGAAGGCAGGACGCG






BCL2_chr18:60986944-60987044
CCTGGCCCGCCGGTGCCGAGCGCTAGAAGCCCGCGCTGTGTGTGGTGCGGCGAGGGGTGGGGAGAAGGA
1079



GGTGGTGGGGGAGGGTTTTATTTTTTCCCTC






BCL2_chr18:60987044-60987144
TTTTCCTAAAAAGGATGACTGCTACGAAGTTCTCCCCCCTGGACCCCCTCTTCCGCTGCACCCCACCGGCG
1080



CACCCCGCCTCCGGGCTGCGCACCCTTTC






BCL2_chr18:60987964-60988064
GTGTGTGTCTCGCCTGGACCTTTTCTAGCCGTGTATGTGGGAGTGTGTGTGTCGCCTGGACCCTTTCTAGC
1081



CGTGTATGAGAGTGTGTACACGCGCCTAC






BCL2_chr18:60988064-60988164
ACACACACACGTTGTGTTACCGGCGCTCGGCCGCCGGGGGAAGACCCAGGCCAATGCCGCCCCCCACCGC
1082



CCCCAGCAGTGGGACCTCAGCGCTGCCCTG






BCL2_chr18:60988164-60988264
CTGTGAAGACAGGTGACTCTGCACGTTTTAAGCAATGTCTAGGGACGCCCCGAGCGTGGTGTTTACTTTC
1083



AAGTAGCTTCCTAGGTGTCCGCGCACTACA






BCL2_chr18:60988264-60988364
CACGCACGCGCATCCCCGCCCGTGTCCACCTGAACACCTAGTCCGTGGCCCAGGCCATGCAGAACTCAGC
1084



GCTCCAGGGAAGGGGTTTATCAAGGGCTTT






BCL2_chr18:60988364-60988464
ACGACAGTTTAAGTCAATGTTTTCCCTCTGTCCCTAACACCTTTTACACTGGTTTAGTGCTACACGATGAG
1085



GACTTCCATATAGTAACTTTCAGGCCCAC






BCL2_chr18:60988464-60988564
CGTCCTAACGCTGGGGTGGGTGGGCTCCTAAAGGTCTCCACCTTTGCCTCGTAGCCAATCCTAGTTGGCCG
1086



CACTTTCTCAAATGAGGTACATAGATACA






S1PR2_chr19:10340823-10340923
GTGTCTCCATGGAGATGGCAGCAGGACCCGACCCCGTGCTGGCCCGCACTCTCGGCCTCCTTATCTGGTTT
1087



AGGAATGCGCGGTATCCACGCTCGCTCGC






S1PR2_chr19:10340923-10341023
GCGGGAGCCACGCCTCCTCTCCCCCCCGCCCCCGAGACCGCCACACGCGCGGGGCCCCCACGTCTCCAAG
1088



CGGCACTGGAAGGATTCCTCTCCGTCCCGC






S1PR2_chr19:10341023-10341123
CAGGGGTCCCGCCTCGAGATTCTGGGAAGACTGGGGGTGGGGGACCAGATCGCAGCAGCAGCTGCACCG
1089



CGAGTTCCGCGCCTGGCCGTGTCGCCCCACG






S1PR2_chr19:10341123-10341223
AGGGGGACTGTGGGCTCAGCGCGTGGGGCCCGGAGCATCTGACAAGGACAGAGACAGAGGAGGGGGTG
1090



GAAATCCCCGGGTGAGTCAACCCGTGCCTGAG






S1PR2_chr19:10341223-10341323
AAGGGGGCGAGTTCCGACGCTCCGCCCGGCTCGGGGCCACGCGAGGTCCGCGCCACGCGCGCCTTCACCC
1091



ACGACCCATCCCTGAGCCGGAGTTGAAAGA






S1PR2_chr19:10341323-10341423
GGAGGCGTCTGAGCCACGCAGTCACTTTCTCTTTCCTTACAAAACAAAGCCACGCCCCCCGCCGGGGGAC
1092



CGGAGGAGGCAAACAACTTGGGGAAACCGA






NCOA3_chr20:46131072-46131172
CCCACTTTCCCCTTCTGTCCCTAAAGTTTTTTCTTCCTCTTGCCTCCCCCAGCCCTTTTGAAAGCTCCCCGC
1093



GTCGTCCTCCTGCTGCCCCGGCTCCTTA






NCOA3_chr20:46131172-46131272
GCAGCTTCTGGGACGCACGGGAGGGAAAAGCCGCGGGGACCCCCCCCACCCCAGCCTCCCAGCCGGGTG
1094



AGATTTGGTTGCTGTGTTTCCTCCTCACTTG






NCOA3_chr20:46131217-46131317
CCACCCCAGCCTCCCAGCCGGGTGAGATTTGGTTGCTGTGTTTCCTCCTCACTTGGGCATTTAAAAAATAT
1095



TTTAACACGAATTGTCCGCGGAATTTTCA






IGLV4-69_chr22:22380472-22380572
CATGGCCTGGACCCCTCTCCTCCTCCAGCTTCTCACCCTCTGCTCAGGTGACTGCCTGTGGAATGCCAAAG
1096



TGATTATTGGGGACACATGGGATGACTTT






IGLV4-69_chr22:22380572-22380672
TCTCTTATATTTTAACATTGTGGGGTGGGTAGTGAACCCAGACTCACCTCTCTGTGCCTGCCTCCTCTGTT
1097



CCAGGGTCCTGGGCACAGTCTGCGCTGAC






IGLV4-69_chr22:22380672-22380772
CCAGGAAGCCTCGGTGTCAGGGACCGTGGGACAGAAGGTCACCCTCTCCTGTACTGGAAACAGCAACAAC
1098



GTTGGAAGTTATGCTGTGGGCTGGTACCAA






IGLV4-69_chr22:22380772-22380872
CAGATTTCTCACGGTGCTCCCAAAACTGTGATGTTTGGAAATTCTCTGCCCTCAGGGATCCCTGACCGCTT
1099



CTCTGGCTCAAAGTCTGGGACCACAGCCT






IGLV4-69_chr22:22380872-22380972
CCCTGACTATCTCGGGCCTCTAGCCTGAGGACGAGGCTGATTATTACTGTTCAACATGGGACTACAGCCTC
1100



AGTGCTCACACAGTGCTGCAGGCACATGG






IGLV4-69_chr22:22380972-22381072
GGAACCGAGACAAAAACCTGCCCTTGGCCTGTCCCGAGGCTGATCACTCCATACTTGCCTATGACAAACA
1101



AAGAGGGTGCCTGTGGCTGATCGTACAGTT






IGLV4-60_chr22:22516707-22516807
GAAATGTTGTTTGCTCTTGTCCTTCCTTCAGGCCATAATGAGCGTCTCTGTTTTCAGGGTCTCTCTCCCAGC
1102



CTGTGCTGACTCAATCATCCTCTGCCTC






IGLV4-60_chr22:22516827-22516927
TCAAGCTCACCTGCACTCTGAGCAGTGGGCACAGTAGCTACATCATCGCATGGCATCAGCAGCAGCCAGG
1103



GAAGGCCCCTCGGTACTTGATGAAGCTTGA






IGLV4-60_chr22:22516927-22517027
AGGTAGTGGAAGCTACAACAAGGGGAGCGGAGTTCCTGATCGCTTCTCAGGCTCCAGCTCTGGGGCTGAC
1104



CGCTACCTCACCATCTCCAACCTCCAGTTT






IGLV4-60_chr22:22517027-22517127
GAGGATGAGGCTGATTATTACTGTGAGACCTGGGACAGTAACACTCACACAGTGATACAGGCAGATGAG
1105



GAAGTGGGACAAAATCCTCAACCTGCTGAGG






IGLV1-51_chr22:22677077-22677177
AAGGTCACCATCTCCTGCTCTGGAAGCAGCTCCAACATTGGGAATAATTATGTATCCTGGTACCAGCAGC
1106



TCCCAGGAACAGCCCCCAAACTCCTCATTT






IGLV1-51_chr22:22677177-22677277
ATGACAATAATAAGCGACCCTCAGGGATTCCTGACCGATTCTCTGGCTCCAAGTCTGGCACGTCAGCCAC
1107



CCTGGGCATCACCGGACTCCAGACTGGGGA






IGLV5-48_chr22:22707517-22707617
TCAGCCAGACTCACCTGCACCTTGCGCAGTGGCATCAATCTTGGTAGCTACAGGATATTCTGGTACCAGC
1108



AGAAGCCAGAGAGCCCTCCCCGGTATCTCC






IGLV5-48_chr22:22707617-22707717
TGAGCTACTACTCAGACTCAAGTAAGCATCAGGGCTCTGGAGTCCCCAGCCGCTTCTCTGGATCCAAAGA
1109



TGCTTCGAGCAATGCAGGGATTTTAGTCAT






IGLV1-47_chr22:22712077-22712177
AGAGATCTGGGGGAAGCTCAGCTTCAGCTGTGGTAGAGAAGACAGGATTCAGGACAATCTCCAGCATGG
1110



CCGGCTTCCCTCTCCTCCTCACCCTCCTCAC






IGLV1-47_chr22:22712177-22712277
TCACTGTGCAGGTGACAGGATGGGGACCAAGAGAGGGGCCCTGGGAAGCCCATGGGGCCCTGCTTTCTCC
1111



TCTTGTCTCCTTTCGTCTCTTGTCAATCAC






IGLV1-47_chr22:22712277-22712377
CATGTCTGTGTCTCTCTCACTTCCAGGGTCCTGGGCCCAGTCTGTGCTGACTCAGCCACCCTCAGCGTCTG
1112



GGACCCCCGGGCAGAGGGTCACCATCTCT






IGLV1-47_chr22:22712377-22712477
TGTTCTGGAAGCAGCTCCAACATCGGAAGTAATTATGTATACTGGTACCAGCAGCTCCCAGGAACGGCCC
1113



CCAAACTCCTCATCTATAGTAATAATCAGC






IGLV1-47_chr22:22712477-22712577
GGCCCTCAGGGGTCCCTGACCGATTCTCTGGCTCCAAGTCTGGCACCTCAGCCTCCCTGGCCATCAGTGGG
1114



CTCCGGTCCGAGGATGAGGCTGATTATTA






IGLV7-46_chr22:22723897-22723997
ATTTGCATAAAGCAGCACACAGCACACCCCCTCCGTGCGGAGAGCTCAATAGGAGATAAAGAGCCATCAG
1115



AATCCAGCCCCAGCTCTGGCACCAGGGGTC






IGLV7-46_chr22:22723997-22724097
CCTTCCAATATCAGCACCATGGCCTGGACTCCTCTCTTTCTGTTCCTCCTCACTTGCTGCCCAGGTTAAGA
1116



GAGATTTCAAATACCAGCCTTTGGAGGGA






IGLV7-46_chr22:22724097-22724197
TCCCTTTTTCTCCCTTTCTAATTCCTAATATATGTCTGTTTTTTTTGTTTCAGGGTCCAATTCCCAGGCTGTG
1117



GTGACTCAGGAGCCCTCACTGACTGTG






IGLV7-46_chr22:22724207-22724307
GGACAGTCACTCTCACCTGTGGCTCCAGCACTGGAGCTGTCACCAGTGGTCATTATCCCTACTGGTTCCAG
1118



CAGAAGCCTGGCCAAGCCCCCAGGACACT






IGLV7-46_chr22:22724307-22724407
GATTTATGATACAAGCAACAAACACTCCTGGACACCTGCCCGGTTCTCAGGCTCCCTCCTTGGGGGCAAA
1119



GCTGCCCTGACCCTTTTGGGTGCGCAGCCT






IGLV7-46_chr22:22724407-22724507
GAGGATGAGGCTGAGTATTACTGCTTGCTCTCCTATAGTGGTGCTCGGCACAGTGACAGACCCATGAGAG
1120



GAACCAAGACATAAACCTCCCTCGGCCCTT






IGLV5-45_chr22:22730452-22730552
GGTCAGCCACCCAGCCTGATTCTGACTCTTCTGGCAAAGATCCCTGAAAAACTTTACCCTGGTTTCTGCCT
1121



TAGCACCCATTAATGTCTGTGTTTCCAGG






IGLV5-45_chr22:22730552-22730652
TTCCCTCTCGCAGGCTGTGCTGACTCAGCCGTCTTCCCTCTCTGCATCTCCTGGAGCATCAGCCAGTCTCA
1122



CCTGCACCTTGCGCAGTGGCATCAATGTT






IGLV5-45_chr22:22730607-22730707
GCATCAGCCAGTCTCACCTGCACCTTGCGCAGTGGCATCAATGTTGGTACCTACAGGATATACTGGTACC
1123



AGCAGAAGCCAGGGAGTCCTCCCCAGTATC






IGLV5-45_chr22:22730707-22730807
TCCTGAGGTACAAATCAGACTCAGATAAGCAGCAGGGCTCTGGAGTCCCCAGCCGCTTCTCTGGATCCAA
1124



AGATGCTTCGGCCAATGCAGGGATTTTACT






IGLV5-45_chr22:22730887-22730987
ACAGATGGGGAAGTGGGACAAAAACCTCACCCTGCTCTGGGTCTTGCTCTGTACCAATTTTTAAATTTTAA
1125



AATAACTGGCCTAGGCACAAACTATATTT






IGLV1-44_chr22:22735417-22735517
GCCCAGTCTGTGCTGACTCAGCCACCCTCAGCGTCTGGGACCCCCGGGCAGAGGGTCACCATCTCTTGTTC
1126



TGGAAGCAGCTCCAACATCGGAAGTAATA






IGLV1-44_chr22:22735517-22735617
CTGTAAACTGGTACCAGCAGCTCCCAGGAACGGCCCCCAAACTCCTCATCTATAGTAATAATCAGCGGCC
1127



CTCAGGGGTCCCTGACCGATTCTCTGGCTC






IGLV1-44_chr22:22735792-22735892
TGCTGCTCAGGCCTGGCCTGTGGCTTCTGCTGCTGCAGCTTCCTTCATGGGTCCAGGGGCATCCAGGGCCC
1128



TGCCTGAGAGTGGAGGCTCCTCCTCCCCT






IGLV7-43_chr22:22749602-22749702
TCCAGCACTGGAGCAGTCACCAGTGGTTACTATCCAAACTGGTTCCAGCAGAAACCTGGACAAGCACCCA
1129



GGGCACTGATTTATAGTACAAGCAACAAAC






IGLV7-43_chr22:22749732-22749832
CCCTCCTTGGGGGCAAAGCTGCCCTGACACTGTCAGGTGTGCAGCCTGAGGACGAGGCTGAGTATTACTG
1130



CCTGCTCTACTATGGTGGTGCTCAGCACAG






IGLV7-43_chr22:22749832-22749932
TGACAGACTCATAAGAGGAACCAAGACATAAACCTCCCTCGGCCCTTGTGATGTGGAGATTGTGTGATCA
1131



TACACACCAGCTCTCAAGACAGCCTACATG






IGLV7-43_chr22:22749857-22749957
ACATAAACCTCCCTCGGCCCTTGTGATGTGGAGATTGTGTGATCATACACACCAGCTCTCAAGACAGCCTA
1132



CATGTGGACCAGCCATAGAAAGGGGAAGG






IGLV7-43_chr22:22749942-22750042
ATAGAAAGGGGAAGGAAAGGGTCTGAATTGATTTCTATCCCTCCTTGTGCCCTGAAGTGGAGGAAATGTG
1133



AGAGTGATTTGCAGTAATTGAATGAGACAA






IGLV7-43_chr22:22750042-22750142
AGCAAAAGTTATTTGTTTTATATGAAAAAAAAAAACAGAAACAGCAGGATCAGATCTAAAGGCTGAGTCT
1134



AAATGCATTTCCTCCAGACAGAAGCTTCTT






IGLV7-43_chr22:22750092-22750192
CAGATCTAAAGGCTGAGTCTAAATGCATTTCCTCCAGACAGAAGCTTCTTCAAACGATGGGCTTTCTGAG
1135



CTAAGAGCAAAGAAAATAAACTCTCCACGG






IGLV7-43_chr22:22750192-22750292
GTATATTATTAAAGTTTATTTTATTGAGTTACTTTCAAAGCAATCCATGACTATTATATAAAGTCAGAAAG
1136



TATTAAAAATCACCAAGTTCTCTGCTAAG






IGLV7-43_chr22:22750292-22750392
CTACCTTATCCCATGCAATCAAAATAAGTACTTTTCTTCATTTGGATGCATTTTTTATTTCTGTTTTTAATA
1137



TTTCCACAATGGTGATTAAACCTGGTGC






IGLV1-40_chr22:22758647-22758747
ACAGGGTCAGGGGAGGGGTCCAGGAAGCCCATGAGGCCCTGCTTTCTCCTTCTCTCTCTAGACCAAGAAT
1138



CACCGTGTCTGTGTCTCTCCTGCTTCCACG






IGLV1-40_chr22:22758747-22758847
GTCCTGGGCCCAGTCTGTGTTGACGCAGCCGCCTTCAGTGTCTGCGGCCCCAGGACAGAAGGTCACCATC
1139



TCCTGCTCTGGAAGCAGCTCCGACATGGGG






IGLV1-40_chr22:22758847-22758947
AATTATGCGGTATCCTGGTACCAGCAGCTCCCAGGAACAGCCCCCAAACTCCTCATCTATGAAAATAATA
1140



AGCGACCCTCAGGGATTCCTGACCGATTCT






IGLV1-40_chr22:22758947-22759047
CTGGCTCCAAGTCTGGCACCTCAGCCACCCTGGGCATCACTGGCCTCTGGCCTGAGGACTAGGCCGATTA
1141



TTACTGCTTAGCATGGGATACCAGCCTGAG






IGLV1-40_chr22:22759047-22759147
AGCTTGCACAGTGCTCCAGGCCAATGGGGAACTGAGACAAGAACCCTCTTCCTCCTCCGCCAGGAGGGTG
1142



AGTGCCTGCAGCTGCTGCTCACACCTGACC






IGLV1-40_chr22:22759147-22759247
TGTAGCTTCTGCTGCTGTAGCTTCCCCCATGGGCCTCGGGGCATCCAGGGCCTTGCCTAGGAGTGGAGGC
1143



TCCACCACTTTTGTCCTCAGAGTCAGGAAC






IGLV1-40_chr22:22759247-22759347
AGGGACCCCAGGAGACAGAATATCCTGCTCCTCAGCTTGGGACACAGGGTCTCTGCACTGAAATCGTGGG
1144



CTGAGGTGGCAGGTCCAACTGTGTCTTCAC






IGLV1-40_chr22:22759297-22759397
CTCTGCACTGAAATCGTGGGCTGAGGTGGCAGGTCCAACTGTGTCTTCACAGTCCTTCCTGTGCCTGCCCA
1145



TGGTGTGGGGACGGAGTGAGGAAGTGTGG






IGLV1-40_chr22:22764167-22764267
TCCTCACTCTCCTCGCTCACTGCACAGGTGACTGGATACAGGTCCAGGGGAGGGGCCCTGGGAAGCCTAT
1146



GGATTCTTGCTTTCTCCTGTTGTCTCTAGA






IGLV1-40_chr22:22764267-22764367
AGCCGAATAATGATGCCTGTGTCTCTCCCACTTCCAGGGTCCTGGGCCCAGTCTGTGCTGACGCAGCCGCC
1147



CTCAGTGTCTGGGGCCCCAGGGCAGAGGG






IGLV1-40_chr22:22764367-22764467
TCACCATCTCCTGCACTGGGAGCAGCTCCAACATCGGGGCAGGTTATGATGTACACTGGTACCAGCAGCT
1148



TCCAGGAACAGCCCCCAAACTCCTCATCTA






IGLV1-40_chr22:22764552-22764652
CTCCAGGCTGAGGATGAGGCTGATTATTACTGCCAGTCCTATGACAGCAGCCTGAGTGGTTCCACAGTGC
1149



TCCAGGCCCGGGGGGAACTGAGACAAGAAC






IGLV2-23_chr22:23040452-23040552
GCTCCTCACTCTCCTCACTCAGGACACAGGTGACGCCTCCAGGGAAGGGGTCTTGGGGACCTCTGGGCTG
1150



ATCCTTGGTCTCCTGCTCCTCAGGCTCACC






IGLV2-23_chr22:23040592-23040692
TTCCAGGGTCCTGGGCCCAGTCTGCCCTGACTCAGCCTGCCTCCGTGTCTGGGTCTCCTGGACAGTCGATC
1151



ACCATCTCCTGCACTGGAACCAGCAGTGA






IGLV2-23_chr22:23040692-23040792
TGTTGGGAGTTATAACCTTGTCTCCTGGTACCAACAGCACCCAGGCAAAGCCCCCAAACTCATGATTTATG
1152



AGGGCAGTAAGCGGCCCTCAGGGGTTTCT






IGLV2-23_chr22:23040792-23040892
AATCGCTTCTCTGGCTCCAAGTCTGGCAACACGGCCTCCCTGACAATCTCTGGGCTCCAGGCTGAGGACG
1153



AGGCTGATTATTACTGCTGCTCATATGCAG






IGLV2-23_chr22:23040852-23040952
GCTGAGGACGAGGCTGATTATTACTGCTGCTCATATGCAGGTAGTAGCACTTTCCACAGTGGTCCAAGTT
1154



CATGGGGAACTGAGACCAAAACCTGCCCAG






IGLV2-23_chr22:23040952-23041052
GGCCTTCAGACTTCCTCCTTGCTCTGAAGATGCTTCCTCACCCGGTGCAAGAGGCTTGCTGCAGCGCGGCC
1155



TTGAGAATTCTTCTCTCTCAGCTCCTTCC






IGLV2-23_chr22:23041052-23041152
CTTTCCACCATGAATTCCAACAGGAAACCTGCCCTGTGGTTTCCCATCCAGGACAGGGACAGCTTCCTGAT
1156



GCTTGTGTGCTGTGGTCCCTGAATGTGCA






IGLV2-23_chr22:23041152-23041252
ACTCTTCCCAGCTCTTCAAATGCAGGGACAGTGACAAGGAGCTGCCTGATTGGTGCAGTCACTGCTTTTTT
1157



CAGGGATGTCTTCACCCTACATGTATCAT






IGLV2-23_chr22:23041252-23041352
CATCCCCTACACTGTGGGTAGAATTTTAGCAACTACATTCTAATGGTTATCGCCACAACTTTGATCTTAGA
1158



AATAACAGTGCAGTGAACATCCCTATGCA






IGLV2-23_chr22:23041352-23041452
GGCTCCTTTGAGTTCCTGTGTGAATACGACCATAGGATTCATTTCTAAAAGTGAAATTGCGGGTCAGAAA
1159



GATGTGTGTTTGTGATTTTCACCCAATGTT






IGLV3-21_chr22:23055497-23055597
ACCAGCAGAAGCCAGGCCAGGCCCCTGTGCTGGTCGTCTATGATGATAGCGACCGGCCCTCAGGGATCCC
1160



TGAGCGATTCTCTGGCTCCAACTCTGGGAA






IGLV3-21_chr22:23055727-23055827
CCCAGCCTCGGTCACCCTCTTGCTCCAGCCCCGGGAAGCCTGTTGATAAAGCCATGAGTGAATCTGGCCC
1161



AGTTCACCTGGATCTGAGCCTTTCAGGTTG






IGLV3-21_chr22:23055827-23055927
CCCTTCCCTCCAGCCCCCTCCAGGAGTCTCTACAGAAGATACATCAGGCATAAATATGGCCTGGAAGGGC
1162



CAGAATCATCTGGTGACTTGGGGCTGTTGT






IGLV2-14_chr22:23101392-23101492
GGTCCTGGGCCCAGTCTGCCCTGACTCAGCCTGCCTCCGTGTCTGGGTCTCCTGGACAGTCGATCACCATC
1163



TCCTGCACTGGAACCAGCAGTGACGTTGG






IGLV2-14_chr22:23101532-23101632
AAAGCCCCCAAACTCATGATTTATGAGGTCAGTAATCGGCCCTCAGGGGTTTCTAATCGCTTCTCTGGCTC
1164



CAAGTCTGGCAACACGGCCTCCCTGACCA






IGLV3-10_chr22:23154347-23154447
AGGCTCAGTGCCCATAGACCCCAAGTTGGCCCTGCCCTGAACCCTGTGCAAAGCCCAGACACAGTCTTAG
1165



GGTAGGACCCCTGGGAATGGGCTCTTGATC






IGLV3-10_chr22:23154447-23154547
TTCAAGCCCCCTCTCCTGTTTTCCTTGCAGTCTCTGAGGCCTCCTATGAGCTGACACAGCCACCCTCGGTG
1166



TCAGTGTCCCCAGGACAAACGGCCAGGAT






IGLV3-10_chr22:23154597-23154697
AGAAGTCAGGCCAGGCCCCTGTGCTGGTCATCTATGAGGACAGCAAACGACCCTCCGGGATCCCTGAGAG
1167



ATTCTCTGGCTCCAGCTCAGGGACAATGGC






IGLV3-10_chr22:23154697-23154797
CACCTTGACTATCAGTGGGGCCCAGGTGGAGGATGAAGCTGACTACTACTGTTACTCAACAGACAGCAGT
1168



GGTAATCATAGCACAGTGACACTGGCAGAT






IGLV3-10_chr22:23154797-23154897
GGGGAAGTGAGACACAAACCCCTTCTTCATCTATTTTACCCTCTCCCTCCAGCCCCAGGACCGCTGTGGAC
1169



CAACCCATAAGCAGGTCTGGCAGAATTCA






IGLV2-8_chr22:23165422-23165522
AGGCTCACCTGGGCCCAGCACTGACTCACTAGACTGTGTTTCTCCCTTTCCAGGGTCCTGGGCCCAGTCTG
1170



CCCTGACTCAGCCTCCCTCCGCGTCCGGG






IGLV2-8_chr22:23165542-23165642
CATCTCCTGCACTGGAACCAGCAGTGACGTTGGTGGTTATAACTATGTCTCCTGGTACCAACAGCACCCA
1171



GGCAAAGCCCCCAAACTCATGATTTATGAG






IGLV2-8_chr22:23165642-23165742
GTCAGTAAGCGGCCCTCAGGGGTCCCTGATCGCTTCTCTGGCTCCAAGTCTGGCAACACGGCCTCCCTGAC
1172



CGTCTCTGGGCTCCAGGCTGAGGATGAGG






IGLV2-8_chr22:23165727-23165827
AGGCTGAGGATGAGGCTGATTATTACTGCAGCTCATATGCAGGCAGCAACAATTTCCACAGTGTTTTAAG
1173



TCAATGAGGAAGTAAGATCAAAACCTGCCC






IGLV4-3_chr22:23192412-23192512
TCAGGCTCAGAACCCATAGGATCCTGAGCTGGGCCTGCCCAAACATGAGTTCATCCCAGGCACAACCTCA
1174



GGGTGGGACCCCCTGGGAACAGATTCATCA






IGLV4-3_chr22:23192512-23192612
TTTACAAGCCTCCTCTCCTGTCCTCTCTTGCAAGCTCCTATGAGCTTACACAGCCACCCTCAGTGTCAGTG
1175



TCACCAGGACAGGCAGCCATGATCACCTG






IGLV4-3_chr22:23192612-23192712
CTCTTGAGATAACCTCAAAGATGAGTATGTTTACTGGTTCTGGCAGAAGCCAGACCAGGCCCATACTGGT
1176



GATATATGAAGGCAGCAAGCGGCCCTCAGG






IGLV4-3_chr22:23192712-23192812
AATTTCTGATTTTCTGAGTCCAGCTCAGGGAACATGGCCACCCTGACCATCAGCAGGGCTCAGACTGAGG
1177



ACGAGGCTGACTATTACTGTCACAGGTACA






IGLV4-3_chr22:23192812-23192912
ATAGAAACAGTGATGAGCCCACAGTGACACAGGCAGATTAGGAAGTGAGACACAAACCCCTTCCCAATCT
1178



GTGTCACCCTCTTTCTCCAGCCCCAGGATG






IGLV4-3_chr22:23197917-23198017
GGGATGAGAAGGGACCAGGGGCCTGGGATTGAGCTGTGAAGGGAACCAAAAGGCAGGAGGGACAGGGC
1179



AGGGGCTGTCAGCTATGACTCAGGGGAGGTTC






IGLV4-3_chr22:23198017-23198117
CTGGGCCTCAGGATCCTCCCTCTGAGGCCACCAGGGGGCGGGGGTGGCACATGCCTGGACCTGGGAGGTC
1180



CCTGCTGGGCTTCACCCTGGGTGGGTCCTA






IGLV4-3_chr22:23198067-23198167
ATGCCTGGACCTGGGAGGTCCCTGCTGGGCTTCACCCTGGGTGGGTCCTAGGAGCTCCTTCCTCCTAAGTC
1181



CCCCTAAAGAGACAGAGGCATTCTGGGGT






IGLV4-3_chr22:23198167-23198267
CCTAAATCTGTCATGCCCCCATAAATGCATTTCTACGAGGGCCAATAAATGAACTCCAGGTTTATCCAAGC
1182



AGCAGCTTCAGGCGTCTGCAGACACAGAG






IGLV4-3_chr22:23198267-23198367
CGGGGAGGAATTAGCCAACCTGAGGCACCCTAGAAGGGCTGAAGGGGGCTGAAGGGGACTGAAGGGTCC
1183



CTGTGGGGCCTGTGGTCCTGGGGAGGGGAGA






IGLV4-3_chr22:23198367-23198467
GCTGGGGTGTCTCCCAGCCACTCTGGGCCCTGTCCTGACACTTCTCCCACAAAGAAGGGAAGGGAAATCC
1184



TGGGACCCCACAGCCAGGACCAACCGTGAA






IGLV4-3_chr22:23198467-23198567
CCACAGGACAGGAAGGACAGGGACCCCCAAGGCTGGCTCCATTTCCCAGGCACTGTCATGGGCTGAGTCT
1185



CAGGAAATCCAAGTCAAGGAGTTTCAATCC






IGLV4-3_chr22:23198587-23198687
CCAAGGAAACAGAAGTCTACGGGCCCAGGCCCAGGTGAGGGTGGGGTAAGAAGAGGAGCTTAGGATGCA
1186



GATTTGCATGGAGGCCCCGCCCTCCTCTGAG






IGLV4-3_chr22:23198687-23198787
GCATCAGGGTAAGACAAGGCTGGGGGCAGGCCCAGTGCTGGGGTCTCAGGAGGCAGCGCTCTGGGGACG
1187



TCTCCACCATGGCCTGGGCTCTGCTCCTCCT






IGLV4-3_chr22:23198797-23198897
CTCAGGGCACAGGTGACGCCTCCAGGGAAGGGGCCTCGGGGACCCTTGGGCTGATCCTTGGTCTCCTGCT
1188



CCTCAGGCTCACCTGGGCCCAGCACTGACT






IGLV4-3_chr22:23199022-23199122
TTGGGAGTTATGACTATGTCTCCTGGTACCAACAGCACCCAGGCACAGTCCCCAAACCCATGATCTACAA
1189



TGTCAATACTCAGCCCTCAGGGGTCCCTGA






IGLV4-3_chr22:23199122-23199222
TCGTTTCTCTGGCTCCAAGTCTGGCAATACGGCCTCCATGACCATCTCTGGACTCCAGGCTGAGGACGAG
1190



GCTGATTATTAGTGCTGCTCATATACAAGC






IGLV4-3_chr22:23199182-23199282
TGAGGACGAGGCTGATTATTAGTGCTGCTCATATACAAGCAGTGCCACTTAACCACAGTGGTCCAAGTTC
1191



TTGGGGAACTGAGACGAAAACCTGCCCTGG






IGLV4-3_chr22:23199277-23199377
CCTGGGCTCTCAGGCTCCCTTTTTGCTCTGAAGATGTTTCCTCACCCAGTGCAACGGGCTTCCTGAAGCAC
1192



AGCCTTGAGAATTCTTCTCCCTCAGCAAC






IGLV4-3_chr22:23199377-23199477
TCTCTTTTCCCACCATGAAATCCAAAGGAAACCTGCTCTGTGGTTTCTCATCCAGGACAGGGACAGCTTCC
1193



TTTTGCTTGTGTGTTGTGGTCCCTGAGTG






IGLV4-3_chr22:23199477-23199577
GGTGCAACTCTTCCTAGCTTTTTAAATTATGGGAGGGTGACAATGAGCTCCCTGACTGGTGCAGTCCCTGC
1194



TGTTTTCAGGAACATCCTCATCCTAAATG






IGLV4-3_chr22:23199577-23199677
CATCTGAATCTCCCACTGTGTGCAGACCAATCTGGACAGATGTTATTAGGGGGAGTTTCCAGAAGCCACA
1195



TCTTACTCAACTCTGTATCCACCACACTCT






IGLV3-1_chr22:23222927-23223027
TGCCTCAGCCATGGCATGGATCCCTCTCTTCCTCGGCGTCCTTGCTTACTGCACAGGTGCTGCCCCTAGGG
1196



TCCTAGCCACTGGTCCAGTCCCAGGGCTC






IGLV3-1_chr22:23223027-23223127
TGGGTCCAGCCTGGCCCTGACTCTGAGCTCAGCAGGGCCCCCGCCTGTGGTGGGCAGGATGCTCATGACC
1197



CTGCTGCAGGTGGATGGGCTCGGCGGGGCT






IGLV3-1_chr22:23223077-23223177
TGGGCAGGATGCTCATGACCCTGCTGCAGGTGGATGGGCTCGGCGGGGCTGAAATCCCCCCACACAGTGC
1198



TCATGTGCTCACACTGCCTTAGGGCTCTTT






IGLV3-1_chr22:23223177-23223277
CATCCCTGGATCTGTGTCCAGGCCAGGCACGTGGGAAGATTTACTTGGAGTTCAGCTCCTCAGTTTCAAGC
1199



CTTTTCTCTCCCGTTTTCTCTCCTGTAGG






IGLV3-1_chr22:23223277-23223377
ATCCGTGGCCTCCTATGAGCTGACTCAGCCACCCTCAGTGTCCGTGTCCCCAGGACAGACAGCCAGCATC
1200



ACCTGCTCTGGAGATAAATTGGGGGATAAA






IGLV3-1_chr22:23223327-23223427
CAGGACAGACAGCCAGCATCACCTGCTCTGGAGATAAATTGGGGGATAAATATGCTTGCTGGTATCAGCA
1201



GAAGCCAGGCCAGTCCCCTGTGCTGGTCAT






IGLV3-1_chr22:23223427-23223527
CTATCAAGATAGCAAGCGGCCCTCAGGGATCCCTGAGCGATTCTCTGGCTCCAACTCTGGGAACACAGCC
1202



ACTCTGACCATCAGCGGGACCCAGGCTATG






IGLV3-1_chr22:23223527-23223627
GATGAGGCTGACTATTACTGTCAGGCGTGGGACAGCAGCACTGCACACAGTGACACAGGCAGATGCGGA
1203



AGTGAGACAGAAACCAGCCACCTCGGCCTGG






IGLV3-1_chr22:23223627-23223727
CTCACAAGACCCTTCCCTCTCTCCTGCCCTGTCACACTGAGCAGGAGGGAGCCTTCCATGTGGAATGGAA
1204



GTTTCCAGTCCTATCCCTGCCCTTATGTTC






IGLV3-1_chr22:23223727-23223827
CTGAGAGACGGGAGCAAGTTCCTGCCCACCTCTAGGCTCAGCTTATCCCAGAATAAACTGAGCTAGTCAT
1205



TTTGATGATCAAATGCCAGCTCCCAAAAGA






IGLV3-1_chr22:23223827-23223927
CCCCAGAAACCCTGATATCTAAGTAGCACCGACTCTATTAGTATCAAGGGAGACTAGCCCTAGGGTGGAA
1206



TCATTTTAGTGTCTCAGAAGGCACAGGGCA






IGLV3-1_chr22:23223927-23224027
ATGGAAAGTGTTTATGAGGTTTCAGGATATGCACGTGAGCAGTTAAAGGCAGGTCTTACAAGGAAGGAA
1207



CCTACTAGAATTGGGGCCCATCTGTGACATC






IGLL5_chr22:23227062-23227162
ACATCCCTCTGCTTTGGGAGAGAAGGGCCAGGGCGGGACCCAGAGAGCTCTGCAGAGGCACCACAGACC
1208



CTCAGCAGGGGGTCTGCCAAACAGGACAGCT






IGLL5_chr22:23227162-23227262
GGACTTGGCTGCTTCTGCCCAGGCCTGGATCCAGCCCTTGCACATCTCAGGGCAGGGGATAGGCCTGGGT
1209



GGCCAGAGCTGCAGCTGCACCTGCTGGGGA






IGLL5_chr22:23227262-23227362
GGCCTAGTCCAGTCCTCCAGGGTCCCCAGACAGACTCGGATTTCCGACTGCAGCCACCATGGAAGGATGT
1210



GGTCTGCGGTGACGATGTCTATCCAGAGGC






IGLL5_chr22:23227567-23227667
CCGAATATCCAAGGAGCCCAAGATCAGAGGCAGGAATAGGCCAAGCTCCCCAGTGGAGAAGCTGTGCTG
1211



GACCAGGGGTTTCCCAGGGCCCTCCCTTGTG






IGLL5_chr22:23227667-23227767
CCCTGAATGATGTCTGTTAGGGCACCTACACCCTGTTACTGCTCAGTGCCTTGCCTATTTTGAAGGACAGG
1212



GATGTGTGGTGATTATTTGTATAATCCAG






IGLL5_chr22:23227767-23227867
CCCCCAGCACCTGGTCCTCAAAAGTTACCCAAGCAATGTGTATAAAGATCCAGCCTGGAGATCTTTGAAA
1213



ACCGATTCGATGAGTCGAACCATTAAGTCA






IGLL5_chr22:23227867-23227967
TGATCACCATCCTCAACTTCATCTCTTTCTTCCTCCTCCTCCTCATTATCATCACCTTCAAGAACTGTTAAG
1214



AGTCTGAGACTTCATCCTATTTGCAGAC






IGLL5_chr22:23227897-23227997
TCCTCCTCCTCCTCATTATCATCACCTTCAAGAACTGTTAAGAGTCTGAGACTTCATCCTATTTGCAGACTA
1215



AAAAGTAAGCCTGCCACAGTGCCATGGA






IGLL5_chr22:23227997-23228097
TGCTGGCAGAAGATACAAGACTCCTGGGTCAGAGACAACGAATAATCTGTTTTTCACAGCAATAGCAGTT
1216



GCCAAGGTATCAGCATTGTCTTGCACCAGT






IGLL5_chr22:23228097-23228197
TCCACAAGGTGATGCAAAGAGGGCCAGGTGACATCTGCATGCCAGAGCTCAGGGATCCCAAATATTTCAT
1217



ACTTGACAGTAAGCATATATCTGTGTTTTG






IGLL5_chr22:23228197-23228297
CTCCAAAGAGAGGCATTCTCTGTACCTTCCGAGGTTGTTCACTCCACAAACACTCTTGAAAAGATAATCCA
1218



CAATCAGTGCCTTTGCCCGAGAGACATGC






IGLL5_chr22:23228297-23228397
AGAAATGCAGAGATCCATAGTAGACCACTGTCTCCCAACAACCATCAACTTTATCAATGAAATGAAGTCT
1219



CAGGCTATTTGTCTGTTACCATAGCCCACA






IGLL5_chr22:23228397-23228497
AAAATGTCTGGCTTGATTGTCACCAAATGTATCAAGGAAGTTAAGGAGTATCTGACACAAAATGTGAACC
1220



AAGCAATTCTCAAAGGAGCCTCCCAGGAAA






IGLL5_chr22:23228497-23228597
TTCACTTTAGGAAGTCCTAGGAGGCTCCTCTGAGAGTTGCTAAAACAAAACATTGAGAGTCCTAGAGGGC
1221



TGCAGATCTGAACTTGAGCAGATATTTTTA






IGLL5_chr22:23228597-23228697
AAGATTTTGTGGCAGAAAAAGAAACTGGAAAGCAAGAGGGCAGACCCTCATTGCAGTTCTGTAATGTAA
1222



GGGGGCAGAGCAGGGGCCTTTCTCACCAGAG






IGLL5_chr22:23229332-23229432
GATATTGGACCCTGCATTCATCTTCTCTGGATGGTAATTTTCTCACCTGTAAAACAGAGACACTGGCCCCA
1223



AGGACACCCCACAAGTAGTTGTGAATCCC






IGLL5_chr22:23229432-23229532
AAAGTAAGAGAAGAACAAAAAAAGAACCAGAATTTATTCAACACCCACTGAGTGCTTAGCAAACACATG
1224



GTTTCTTTAACTCTCATAAGCTTCATGCTGC






IGLL5_chr22:23229532-23229632
AGAGGAACTCTCCCCATTTTACAGATAAGGAAACTGAGGCCCAGAGGTAACCTAGGTCTAGATAGACTCC
1225



ACATTTATGACTTCACCACTCTTCCTTGCC






IGLL5_chr22:23229562-23229662
AAACTGAGGCCCAGAGGTAACCTAGGTCTAGATAGACTCCACATTTATGACTTCACCACTCTTCCTTGCCT
1226



GAAGGATATAGAATCACTCCCTGCAGGGC






IGLL5_chr22:23229662-23229762
TCTTGCCTGACTCAGGAAAGGGCCACAGGATAGCCAGCCAGGCTTAACCAACCCAGCCAAGAAAGGGCT
1227



GGTCCCAACTGGCTGGAGTGCAGTGTACAGG






IGLL5_chr22:23230012-23230112
GTTGGTAGATGCCCCTCTGGGAGAGATCCCCAGGGGTGACAGCCATGGACCCTGGAAGGGCCTGGGCTA
1228



GGGACAGGGACCAGAGCCAGTCCAGGGAGAG






IGLL5_chr22:23230112-23230212
GACAGAGCCAATGGACTGGGGTGTACTGTAACAGCCCTGCTGGCGAGAGGGACCAGGGCACCGTCCTCC
1229



AGGGAGCCCATGCTGCAAGTCGGGCCAGAGG






IGLL5_chr22:23230212-23230312
TGCCCCTGAACCTGAAGGCCAATGAGACCCAAGACAGGCCAAGTGGGTTGTGAGACCCCTGAGGAGCTG
1230



GGCCCTGGTCCCAGGCAGCGCTGGCCCCTGC






IGLL5_chr22:23230312-23230412
TGCTGCTGGGTCTGGCCATGGTCGCCCATGGCCTGCTGCGCCCAATGGTTGCACCGCAAAGCGGGGACCC
1231



AGACCCTGGAGCCTCAGTTGGAAGCAGCCG






IGLL5_chr22:23230412-23230512
ATCCAGCCTGCGGAGCCTGTGGGGCAGGTAAGGGGCAAGAGATTCCAGGGGATGTGGGGGTCCTGCAGC
1232



AGAGCTGGGAAAGGGTGACCAAGGGGAGACA






IGLL5_chr22:23230512-23230612
AGCCAGAGGAGTGAGGAGGAAGGTTAACCCCTAAGAGGGGCCTGGGCTGACACTGGCTTTAGTAATGGG
1233



TTGATATTTTGTCCATCACAGATTTGTTTGA






IGLL5_chr22:23230612-23230712
ATTACTGTTTTTAATATCATATTACGATATTATTTTTCTTGATTTCTGAGTTTTCTGGCGCCACTTAAATTT
1234



TCACCAGGGTCAGTGCCTCAATCACCTA






IGLL5_chr22:23230712-23230812
GTCCTAGTCCTCTGGGTAGGGAAGGAACAGAGGCAGGGACAGGACATCCACAGGGGGTGGTGGCCACTG
1235



TCCCCACAGGGTGCCCAGGCCTGTTCCTCCC






IGLL5_chr22:23230812-23230912
CCTCCTCCTCTCTGCCCATGTGCCTCCTGCCCAGTGAGGGCAGGGGCCACTCCCTGGAGAAGGCAGCAAG
1236



GGCTTGGTTTGGTCTCCCCCAAGGCTGTCT






IGLL5_chr22:23230912-23231012
GTTCACCAACTTGCACATAAATGCTTACTGGGGCCAGGCTCAAGGACACAGGGAGGGTGGGATGAACCG
1237



AGGGGAGCTGTCCAGTCATTGGAACAGGCCC






IGLL5_chr22:23231012-23231112
ACGGCCCATGTTTGGAGCAATAAAGGGAGAGGGGATCTCCCTCTGGGATGATGCCCAGGCTGGTCTCACA
1238



GATCGAGGGGCACTGGCTGGTGATGGGTGC






IGLL5_chr22:23231072-23231172
TGGTCTCACAGATCGAGGGGCACTGGCTGGTGATGGGTGCCCCCAAAAGACAGAGCAGCGTCAGAGGAG
1239



AGGAGAGCACAGGATGAGGCTGGGAGCTCCT






IGLL5_chr22:23231172-23231272
GGGTGACTGGGAAGGGGAGGCAAGAAGACCATAGGGTCCGTGCACCATTCCCAGTCCAGGACGAGTCCT
1240



TGGATGGATTTAGGTAGATTGATTATCAGAG






IGLL5_chr22:23231272-23231372
TCAGATTTGTGTTTTTGGAAAAATCAGCACCGGATTGGAGGCTGATGCGACGCCCGATTAGAGGAGGGAG
1241



GAGAGGGGGTGATGGCCAAGTCCAGGGTAG






IGLL5_chr22:23231372-23231472
GTGGGGATCCTGGAGGAAGCCGTGCCTTGGGGATGGGGAGGACACTCAGATTCAGAGCACCCAGGGGCC
1242



CAGTTTCCTATGAAATGGGAGCATGAAGTTG






IGLL5_chr22:23231472-23231572
AAGTGAGGGCTGAGCAGAGGGGAGCAGACACGCTCGGGGACTGTCTATGGGCATTAAAAATGTATAACC
1243



ATTTTAGCAACAGGCGGCGAGTCAAAAAACA






IGLL5_chr22:23231572-23231672
AAGTGTGTTTATCTAAACTGGGCAATTCCACTTCTAGGAATTTATCCTAAGGGTTGGTTGGGGGAATAATC
1244



AAAGCTGTAACCAAATCTTTATAACAAGG






IGLL5_chr22:23231672-23231772
GTGGTTAGCTCAGCATTATTAGTGATGGGAGAAAACTGGAAAAAATCCAAATATCTACCAGAAAGGGTGT
1245



GAAAAAACACAATTGTATTTGGGGGACTGT






IGLL5_chr22:23231927-23232027
TGGCTAATTTTGATTAGGATTATTATTAGTTTAGAGACAGAGCCTCGCTATATTGCTCAGGCCTGTCTCAA
1246



ATTCCTAAGCTCAAGCAATCTTTCTGCCT






IGLL5_chr22:23232062-23232162
ACTGCACCTGACCCAACTGTGTTTTTAAAGTATATATGCATTTTCAAAAACCTGTCAGAAAATATAGAAAA
1247



ATGTCAATGGTGTGTCTGGCTGGCTGATG






IGLL5_chr22:23232162-23232262
GGATTTCACCTAATTTTAATGTGGCTTTATAATTTTCTGGTTTTGTGAAGTTGTTCACAAAAAGAGACATT
1248



TCTTCTAATATAATTTTTAATACAACAGT






IGLL5_chr22:23232262-23232362
AATGTACTCATGTGCATTACTCTTTTTGTAATGAGTATATTACAAAATGTAATGACTTTTGTACATTACTCT
1249



TTTTTCTTGCCAAAAAAAAAAAAGATTA






IGLL5_chr22:23232362-23232462
AGCAGAGAAGTATATAAAGTAAAAGCAAGTGCTTCTGCTTACCATCTCTCACCTCTTCCCAGAGATAGCC
1250



ACTGTCAGGTTGGTCAATATACTTCCAGAA






IGLL5_chr22:23232462-23232562
CTTTTCCTGTGTGTGTGTGTGTCCCTGAAAACACACACACACACACACACACACACACACACAGTTGGTGC
1251



TGGGATTTTATTTTGCAAAAGTAAGAGCC






IGLL5_chr22:23232517-23232617
CACACACAGTTGGTGCTGGGATTTTATTTTGCAAAAGTAAGAGCCATATTCTGCATATTACCAACTTTTAA
1252



TCTATTATTGACACTTTCTGTATCAGTCC






IGLL5_chr22:23232617-23232717
ATATGGATTAACCACATTCATTGCTTATAAACTTTGTTTTATAAGCAAAGTTTAGATGAGCCAGAATTTAT
1253



TTCCACTAAAAAATCTAAATGACAAATGA






IGLL5_chr22:23232717-23232817
TGCTGCAGTGGAAATTTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTATGTGTAC
1254



AAAGTGCACTTATATATCTCCCCAGGATA






IGLJ1_chr22:23234612-23234712
TGACCTGGGTGTTTTTCTTTTTCTCTGTAGGATGTTAATAGTATCTTGTGTCATGCTAGGATGTCTAGGAC
1255



AGAGGGCAATACAATGAGGGGAAGGCATT






IGLJ1_chr22:23234712-23234812
CTGCGATGTCCCCAGGCCTCTGGCTTGAAGAGTAACTTGCTGAAGTGAGGACTCTGTGGAGGAGCAAGTT
1256



ATACAGAAAGAAGTTTAGTTGTGATCTGTT






IGLJ1_chr22:23234812-23234912
GAGTTGGAGGTGTCTACAGGGCATCCAAGCAGACATAGGTTGAGGAGGCAGAATATATGTGAATCTGGA
1257



GCCAAGAAGAGAGGTAAGGGCTGGAAATAGG






IGLJ1_chr22:23234912-23235012
GATCTAAGACCCCTGGACAGTTGTGAGTGTGCACAATGAGGGTCAGATGCAGAGAAAATTAGGAGACTA
1258



CAGAGAGCAGAACCCAGGGTGGGGATCTGGG






IGLJ1_chr22:23235012-23235112
AGTCAGCAGTTGGGCATGGGCCTGGTAGAAAGGGAAGCCAAGGAGGAGGAGAGGGGGCAGTCTCAGAC
1259



ACCAAGGAGGGGAGAGTGACTAGAAAGAAAAC






IGLJ1_chr22:23235112-23235212
CTTCTTGCAGAGACATAGGGGATGGGGAAGAACTGCAGACTGAACTGGGGCAAAGGACTGTTGGCCTTA
1260



ACCAGAGAGATTTGAGGGAGAGATGAGGCTG






IGLJ1_chr22:23235212-23235312
AGAGCCAGGGGATCCTGCCATGTCCCAGCATAAAAACAGTACCTGACACAGATGGGTGCTTGGGAGCTGT
1261



TGTCGGATGAATGAGTGGACAGATGCATGG






IGLJ1_chr22:23235312-23235412
ATGGACGGATGGATGGAAGGATGATAGATTGATGGACAAACAGATGAACAGATGAATAGCTGGATGGAC
1262



AACTGGATGGATGGGTAGACAGAATGATCTC






IGLJ1_chr22:23235412-23235512
AGAGATCAGAAAAAGCTTCATGCACTAAGTGGGACTGAACCGCGTCTCCATGGGTAGAAAGCAGAGGAA
1263



TCTCCACTTGAGTCAGGAATGACCCAGTGCT






IGLJ1_chr22:23235512-23235612
CTCAATCCAGGGAGAAAGCCAGCCTGGCTTCACTGGGGACACTTGTGTGGGGGACTCAGAGGCCCTTTAA
1264



ATGAGGCCAGACGAGGTTGGACAGGTCCAA






IGLJ1_chr22:23235612-23235712
GCCAACTCAGCACTCCTCTGCCACACTGCACAGGAGGGGATGTGTCACTCAGGGAGTTGCTGGGACCTAT
1265



GGGTCCCAGTGTTGTCATCAGCACCGACAG






IGLJ1_chr22:23235712-23235812
CCTCAGAGAGGAAAGACACACACTGGGGTAACTCCAAGGCTGTGTGTGGCACTTGCCTTGGACAGCAGAC
1266



AGGCACAGGGACACCTCTAGGGGGCTGGCC






IGLJ1_chr22:23235812-23235912
ACCCCCCTGCCTCATGTCTAGGTCCCAGCCCCGCCCACTGCAACCCTGTGCCCGTCATGCCCAGCAGGCTC
1267



CTGCTCCAGCCCAGCCCCCAGAGAGCAGA






IGLJ1_chr22:23235847-23235947
CACTGCAACCCTGTGCCCGTCATGCCCAGCAGGCTCCTGCTCCAGCCCAGCCCCCAGAGAGCAGACCCCA
1268



GGTGCTGGCCCCGGGGGTTTTGGTCTGAGC






IGLJ1_chr22:23235947-23236047
CTCAGTCACTGTGTTATGTCTTCGGAACTGGGACCAAGGTCACCGTCCTAGGTAAGTGGCTCTCAACCTTT
1269



CCCAGCCTGTCTCACCCTCTGCTGTCCCT






IGLJ1_chr22:23236047-23236147
GGAAAATCTGTTTTCTCTCTCTGGGGCTTCCTCCCCTCTGTCCTCCCAGCCTTAAGCACTGACCCTTACCTT
1270



TCTCCATGGGGCCTGGAGGAGGTGCATT






IGLJ1_chr22:23236147-23236247
AGTCTCCGGGTAACCGGCAGGAAGGGCCTCCACAGTGGGAGCAGCCGGATGCAGCCTGGTCCCGGGGCC
1271



TGAGCTGGGATTGGGCAGGGTCAGGGCTCCT






IGLJ1_chr22:23236247-23236347
CCTCTCTTCCAGGGCAGATGTCTGAGTGAGGGACAGAGGCTGGTTCTGATGAGGGGCCCTGCAGTGTCCT
1272



TAGGGACATTGCCCAGTGACTCCTGGGGTC






IGLJ1_chr22:23236277-23236377
GGACAGAGGCTGGTTCTGATGAGGGGCCCTGCAGTGTCCTTAGGGACATTGCCCAGTGACTCCTGGGGTC
1273



AAGGACAGAGGCTGCTGGGGTGGGCCTGGG






IGLJ1_chr22:23236377-23236477
AGCTGCTGAGTCTCATAGTCTAGGGGAGCAGCCCCAAGAACAGCTGAGGGTCTAGGCTGAGGACTGGAT
1274



GCCAATCCAGCCTGGGAGGGCCACACGGCCT






IGLJ1_chr22:23236387-23236487
TCTCATAGTCTAGGGGAGCAGCCCCAAGAACAGCTGAGGGTCTAGGCTGAGGACTGGATGCCAATCCAGC
1275



CTGGGAGGGCCACACGGCCTGGTGACACAG






IGLJ1_chr22:23236487-23236587
AGGTCACCCCAAGGGGAGACCAATGGAGGGCACAGAGAGGGCTCTGGGTCTAGGCTGCAGCTCTGTGGC
1276



CTGTGCTGGGTCATGAGGACATGGGGACACA






IGLJ1_chr22:23236557-23236657
TGTGCTGGGTCATGAGGACATGGGGACACAGAGGGACGGGTGAGACTGGGTGAGGTGCCAGAATCCAAC
1277



CCTCCCAGGACAGTCACCAGAAAGGAGACAG






IGLJ1_chr22:23236657-23236757
TCTCTTAGGGCAGAGATGTGTCTGTCCCTGGAGCCCCGTCACCTCTGGGGCCCAGTGTCTCTCTGTTCACG
1278



GATCGGCCTCCTGCCTTCCTCAAAGGGCA






IGLC1_chr22:23236757-23236857
TGTTAGACTCAGGAAATGACCAGAGGGGAGTGAATGAGGGGTGCAGAGAACTCCATGGCTACCAGGTGA
1279



AGTTTGGGGTCATCACAGGCTGCTGGGGTGG






IGLC1_chr22:23236877-23236977
CATAGTCTGTGGGAGCAGCCCCAGGAACAGCTGAGGTGAAGGGTTCTGTGGTCGGGCTTGTGGAGACAG
1280



GAAACATCTCAGAGCCTCAGAGGAGCCCTGA






IGLC1_chr22:23236977-23237077
GGCTTGTCTAGGTGGAGCCCACTCCTTGCCAGGAGAGCCAAGTGGGCTGGGCTGGGGCAGAGCCCGGTGC
1281



CTGTGAGGGATAGGAAGCTCCAGTTCAAAG






IGLC1_chr22:23237077-23237177
CAGGCTTGGGTCTCCCCACACACTGCCTGCCAGGACAGTCCTACAGGATGAGCAGGGGACCCACAGTTCA
1282



CGGAGGAGGCTCTAGGTCCTGGAAGAATAA






IGLC1_chr22:23237177-23237277
AGTGGGTGATGGAGGGGGGTATAGGGATGGAAATGAGGGATCCAGGGGTCAAGGCCAGATTCTAAACTC
1283



AGACTCCAGAGATCAGAGAAGAAGGAACACA






IGLC1_chr22:23237277-23237377
GCCTGCCCTGGGTATATGGAGAAATTGAGGCTGTAGAGGAGAGGGGCTGGGCCAGGACACCTGTGAAAG
1284



GTGACTTGGGAGGGCTCCTAGGAAGGCACAG






IGLC2_chr22:23242602-23242702
TGAAAGCCCCACTGCTATGACCAGGTAGCCGGGACGTGGGGTGGATGCCAGAAAAGACTCCACGGAATA
1285



AGAGAGAGCCCAGGACAGCAGGCAGGCTCTC






IGLC2_chr22:23242702-23242802
CGATCCCCCCAGGCCCTTGCCCCATACACGGGCTCCAGAACACACATTTGGCTGGAACAGCCTGAGGGAC
1286



CAAAAGGCCCCAGTATCCCACAGAGCTGAG






IGLC2_chr22:23242802-23242902
GAGCCAGGCCAGAAAAGTAACCCCAGAGTTCGCTGTGCAGGGGAGACACAGAGCTCTCTTTATCTGTCAG
1287



GATGGCAGGAGGGGACAGGGTCAGGGCGCT






IGLC2_chr22:23242902-23243002
GAGGGTCAGATGTCGGTGTTGGGGGCCAAGGCCCCGAGAGATCTCAGGACAGGTGGTCAGGTGTCTAAG
1288



GTAAAACAGCTCCCCGTGCAGATCAGGGCAT






IGLC2_chr22:23244157-23244257
ATGCAGGACAGTCCGGAGAGGGAAATCAGGAGAAGTGAAGGGGTCTCTGGGGAGCCCAGATGTGGGCTA
1289



GAGGCAGAAGTAAGGGTGAAGAGCACCTATG






IGLC2_chr22:23244257-23244357
AGTCAATGTCATGGTCTCAGCAGGAACACAGTTGAAAATCCCCATTCCACACAAGACCGTTTAGCAGGAA
1290



AGGAGTCCATACTTGTGCTGCCACCAGGAT






IGLC2_chr22:23244357-23244457
GTCCTGAGAAGCCTTGGAGAATGAAACATACAGGTGCATTTCCTAGACTTGACAATGCACGTTAGCCAAG
1291



TAAAGGCAATGAAAAGTTCTCTACTAGGGA






IGLJ3_chr22:23247257-23247357
TTTGTTTGTTTCTGTATCTTGTCTCAACTTGTGGTCAGCCTTTCTCCCTGCATCCCAGGCCTGAGCAAGGAC
1292



CTCTGCCCTCCCTGTTCAGACCCTTGCT






IGLJ3_chr22:23247357-23247457
TGCCTCAGCAGGTCACTACAACCACTTCACCTCTGACCGCAGGGGCAGGGGACTAGATAGAATGACCTAC
1293



TGAGCCTCGTCTGTCTGTCTGTCTGTCTGT






IGLJ3_chr22:23247467-23247567
CTGTTTGTCTCTCTGTCTGTCTGACAGGCGCAGGCTGGGTCTCTAAGCCTTGTTCTGTTCTGGCCTCCTCA
1294



GTCTGGGTTCTTGTCGGAACAGCTTTGCC






IGLJ3_chr22:23247567-23247667
CTTGGGTTACCTGGGTTCCATCTCCTGGGGAATTGGGAACAAGGGGTCTGAGGGAGGCACCTCCTGGGAG
1295



ACTTTAGAAGGACCCAGTGCCCTCGGGGCT






IGLC3_chr22:23248182-23248282
AGAGTTCGCTGTGCAGGGGAGACACAGAGCTCTCTTTATCTGTCAGGATGGCAGGAGGGGACAGGGTCA
1296



GGGCGCTGAGGGTCAGATGTCGGTGTTGGGG






IGLC3_chr22:23248282-23248382
GCCAAGGCCCCGAGAGATCTCAGGACAGGTGGTCAGGTGTCTAAGGTAAAACAGCTCCCCGTGCAGATCA
1297



GGACATAGTGGAAAACACCCTGACCCCTCT






IGLC3_chr22:23248382-23248482
GCCTGGCATAGACCTTCAGACACAGAGCCCCTGAACAAGGGCACCCCAACACCTCATCATATACTGAGGT
1298



CAGGGGCTCCCCAGGTGGACACCAGGACTC






IGLJ7_chr22:23263872-23263972
AGAATATTCCGTGAGAAGGTGGCCCCACAGCGCTGGGTCACACGCCATCCCCCAAGACAGGCAGGACACC
1299



ACAGACAGGGTGGTGGGTCTCAGAAAACTC






IGLJ7_chr22:23263972-23264072
AGGCCCTAAACGTGGATGCTTACCAATTCCTCCACTGGAGGAAGACCTCAGAGCAGATGCCCAGGACAGG
1300



GACTTCTGGTAGGGACGGTGACTGGGACGG






IGLJ7_chr22:23264072-23264172
GTGCCTGTTTGTCAGGGAAAACCCACTGGAGAGTCAGATCCCCCAGATAACTTCTCACGACATGGAGACT
1301



CTTTCGAACAGACAAAGCTCCACGTTCAGC






IGLC7_chr22:23264172-23264272
TCAGGGAGTAAAAAAAAAATGCCTCAAATGGAGGCCTTTGATCTACTGGAATCCAGCCCCCAGGACTGAC
1302



ACCCTGTCTCACCAGGCAGCCCAGAGGGGT






IGLC7_chr22:23278157-23278257
CAGGGTCCACCAGAAGGCATCTCAGAACCAGCCAGCAGTGGCCCTGATTGTCAGCAGGACCCCAGGGAG
1303



GGGGGTGGCCAGGACAGGGCTCTGAAGCCCC






IGLC7_chr22:23278257-23278357
CACCCCAGGACCTTCCCTGGGCAGAACGAGTTGGTGAGGGAGTGATGAGCAACCACAGGCCTCCTAACTT
1304



CCCAAGCTGGCGATTCTGAGAGGCCTCAAG






IGLC7_chr22:23278357-23278457
GCTGAGACACGGTTCAGCCTTTTAGGCCCTCCTGAACGTGTCCCCTGTCTCCACAGCCTGGGAATGCACTC
1305



TCTTTTGACCCAGAAATCCTGCTCATAAG






IGLC7_chr22:23282767-23282867
CTGTCATTGTACAACACATCATTTCACTTTGTTTTTCAAACATAGTGAATTCTTTCCTAATTAAAGAAGAA
1306



AAGAGTATAAAGAGAAAGTTTCCAGTGCA






IGLC7_chr22:23282842-23282942
GTATAAAGAGAAAGTTTCCAGTGCAGCCTGGAGATCTGTACTGGTTGTATCTGGAATTCCAGACTCAGCC
1307



TTGCATTTCACATAGCAGATAGATGATGAT






IGLC7_chr22:23282942-23283042
GATGGAGAAGGAGAAGAAGAAGGAGGAGGAGGAGGAAAGAAGGAAGAAGAAGAAGAAGAGGAGGAGG
1308



AAGAAGAAGACGAAGGGAAGAAGAAGAAGGATG






TBC1D22A_chr22:47570209-
TCCAGGTCTGCCAGGTGTAGGGGAGGTGTGACTGGTTCCATCATGGACCGGTTCCTCCATGGACCGGTTC
1309


47570309
CTCCGTGGACCGGTTCCGCCATGGACCGGT






TBC1D22A_chr22:47570309-
TCCGCCATGGACCACTCCTGCCCTGGACCACTCCTGCCCTGGACCGGTTCTGCCGTGGACTGGTTCCCGCC
1310


47570409
GTGGACCAGTTCCCGCTGTATACTGGTTC






TBC1D22A_chr22:47570409-
TGCCCTGGACTGGTTCCCGCTGTGGACTGGTTCCTTGGGGCTCTAAGTGCGGAAGGGCCCAGAGCTGGTC
1311


47570509
CCTGCCCAGCGCCCTGCTAGGGCTGTGTCC






TMSB4X_chrX:12993264-12993364
TCGTACTCGTGCGCCTCGCTTCGGTGAGCCCCAGGGCCCCTGCCTCCTTCCTCCTGCCGTCCTGCCTCCGT
1312



CCCCGCCCTTTCATCATCCGCGTCCCTGT






TMSB4X_chrX:12993364-12993464
GAAGGCATTCCCTAAATCCGAGCCCGAGTGGTTCTCCCCGGGAAGGCTACTTTGGGGAGCTGGGGGGATG
1313



CGAAACACCCTAGATACTGGATAATGGGGT






TMSB4X_chrX:12993464-12993564
GGGGAAATCGATGATTTAAGAACAAAACCGAAAAACTGGCGTTTTGCCGTGCCGCTCGGAGGGGACATT
1314



AAAAAATTTCTTAGTGTTTGCCCGCAAAGGT






TMSB4X_chrX:12993544-12993644
TAGTGTTTGCCCGCAAAGGTATTGTGCGTTGCCTTGGAGGCTGAGATATGGGGGAATAGACAAGTCCTTT
1315



GTTCTGAGGTTCATCTTCCGAGCCCCGAGC






TMSB4X_chrX:12993644-12993744
CTCCTCCCAGCCTCGGACGGCTGCGCGGGCTGCATCTGTGCAGCCTGGCGGCGGCGGGGCTGTGCTATGA
1316



CATCTTTACAGTCCTTCTTGCAGAGACATG






TMSB4X_chrX:12993744-12993844
TGTGCCAGGGATGCCGAATTGCCGGGAGAGCAGGCAAGACCGGCTTCGGGGCGCGCGGCGGCCGCTTTG
1317



TGTGCGGGGCTGCATTGTGACGCGGGCGATG






TMSB4X_chrX:12993844-12993944
AAGCCGGTAGGGCGGTGGTCGGAAGCTCCAGCCGCGGCCGCCGCCTTTGTGAGAGGACTAGAAAGCCGG
1318



ATCCGGCCCGCATCCTTGCGGAGAGGCCGCG






TMSB4X_chrX:12993944-12994044
GCTAGGAAATGGAAACGCTTTTCCTACCTGGGCTCCATTTTAGGAATTCTTGCCGATTTTTCCCACTTGAA
1319



TTTGGAAGTGGCTTTCCTCTTCTTTCCTT






TMSB4X_chrX:12994044-12994144
GTCCTAGCCAGCCTTTAATTTTAAACGCTGTAATTAACAATTCGCAGTGGTCAATTTCCTTTATTCTGCAA
1320



GATTCGGCTTTGAGAGGCATCCGCCCTCT






TMSB4X_chrX:12994144-12994244
TTGGTCCACAGCGTTTTGAAATATGGGGAGGAGGGGCGCGGGGGGTGTCGCCTCTTTTTCTGTAGAAAGA
1321



GGAAGCTCGTGAGCGCGGAACGGCAGCAGT






TMSB4X_chrX:12994289-12994389
AAGTGCAGTTCCCAGCCCAGAGACAGCGGGGCGGGTGGCTCTTCCTCACGCTCGCTCTTGGCTTGCTCCCT
1322



GCAGCTTTTCCTCCGCAACCATGTCTGAC






TMSB4X_chrX:12994389-12994489
AAACCCGATATGGCTGAGATCGAGAAATTCGATAAGTCGAAACTGAAGAAGACAGAGACGCAAGAGAAA
1323



AATCCACTGCCTTCCAAAGAAAGTGAGCTCC






TMSB4X_chrX:12994444-12994544
AGACGCAAGAGAAAAATCCACTGCCTTCCAAAGAAAGTGAGCTCCGACCCACCCCCATCTTTAGAAAGGC
1324



TGGGTGGGAGCGGCCGGTGGGAGGGCGGGA






DMD_chrX:33146106-33146206
TTTATAGAAAGGCATATGGAACAGGAGTCATCCAAATATATCCCAGGGGTTGCAAATTGACCAAAAGAGT
1325



CACCTTTAGGGAAGCCTGCTTCTGAATGCT






DMD_chrX:33146206-33146306
TGTGGAATTTATCATTCTTCTGAATGGCTGTTGCATTTATCTGCAGCTTTTACTCACCAGATGAGACCTCA
1326



GACATTTCAAATTCTGCGGAGGCTGGCTA






DMD_chrX:33146306-33146406
CACACCTTCATAGGAAAGCTTTTTGCTGATTTCCCTGTTGGTACTTTTCTCTTACACATTCTATGGGGTATG
1327



GTAAACCTGGAGGTAGAGTCATAGCCAA






DMD_chrX:33146406-33146506
GCACAGATAAAGCAGGCACAGAATCTCTGACCAGCCTCACAAAAGCAGACAAACACACAATCTTTTTGCA
1328



CCTGTTTCTTCCACTCCGGTTGCCGTGAAT






PABPC5_chrX:90026453-90026553
TAGAAATGGTTCAACCAGTCCAATATCAATATAGCTGCTTATTACTCTATTCACTTACTTCAAAGTGGCAT
1329



TTGTTTTGAGTAAGACTTTATTTAATTCT






PABPC5_chrX:90026553-90026653
TACCGTTAGCTTGAAACCATAGAGATCTTCTCTCTATTTGCCCTACTTCCTTCAAAAGTCAAATGACCTCC
1330



TACAAATAAAAGACGTTCTTATTTTCATT








Claims
  • 1. A method comprising: (a) obtaining, by a computer system, sequencing data for at least 1,000 cell-free DNA molecules from a first sample of a human subject;(b) processing, by the computer system, the sequencing data of (a) to identify one or more cell-free DNA molecules of the at least 1,000 cell-free DNA molecules as phased variant-containing cell-free DNA molecules, wherein identifying the one or more cell-free DNA molecules as phased variant-containing cell-free DNA molecules comprises aligning reads corresponding to each of the at least 1,000 cell-free DNA molecules to a reference human genomic sequence of at least 10 kb in length, wherein each of the one or more cell-free nucleic acid molecules identified as phased variant-containing cell-free DNA molecules comprises a plurality of phased variants relative to a sequence derived from a second sample of the same subject, wherein at least 10% of the one or more cell-free nucleic acid molecules identified as phased variant-containing cell-free DNA molecules comprises a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants that are separated by at least one nucleotide; and(c) analyzing, by the computer system, the identified one or more cell-free nucleic acid molecules identified as phased variant-containing cell-free DNA molecules to determine a condition of the subject, wherein the condition comprises a cancer which is not a hematological malignancy.
  • 2. The method of claim 1, further comprising separating, in silico, (i) at least a portion of the identified one or more cell-free nucleic acid molecules from (ii) one or more other cell-free nucleic acid molecules of the plurality of cell-free nucleic acid molecules that are not identified to comprise the plurality of phased variants.
  • 3. The method of claim 2, further comprising analyzing, by the computer system, (i) and (ii) as different variables.
  • 4. The method of claim 1, wherein the sequencing data is obtained without in silico removal or suppression of (i) background error or (ii) sequencing error.
  • 5. The method of claim 1, wherein a number of the plurality of phased variants from the identified one or more cell-free nucleic acid molecules is indicative of the condition of the subject.
  • 6. The method of claim 5, wherein a ratio of (i) the number of the plurality of phased variants from the identified one or more cell-free nucleic acid molecules and (ii) a number of single nucleotide variants (SNVs) from the identified one or more cell-free nucleic acid molecules is indicative of the condition of the subject.
  • 7. The method of claim 1, wherein a frequency of the plurality of phased variants in the identified one or more cell-free nucleic acid molecules is indicative of the condition of the subject.
  • 8. The method of claim 1, wherein the at least 10% of the one or more cell-free nucleic acid molecules comprises at least 50% of the one or more cell-free nucleic acid molecules.
  • 9. The method of claim 8, wherein the at least 10% of the one or more cell-free nucleic acid molecules comprises 100% of the one or more cell-free nucleic acid molecules.
  • 10. The method of claim 1, wherein the first and second phased variants are separated by at least 2 nucleotides.
  • 11. The method of claim 1, wherein the first phased variant and the second phased variant are separated by at most 160 nucleotides.
  • 12. The method of claim 1, wherein the reference human genomic sequence is derived from a reference cohort and comprises at least a portion of hg19 human genome, hg18 genome, hg17 genome, hg16 genome, or hg38 genome.
  • 13. The method of claim 1, wherein the reference human genomic sequence is derived from a sample of the subject.
  • 14. The method of claim 1, wherein the reference genomic sequence is derived from a healthy cell of the subject.
  • 15. The method of claim 1, wherein the condition comprises a solid tumor.
  • 16. The method of claim 1, wherein the cancer is not a lymphoma.
  • 17. The method of claim 1, wherein the cancer is a lung cancer, a colorectal cancer, a gastrointestinal cancer, an esophageal cancer or a breast cancer.
  • 18. The method of claim 1, further comprising determining, by the computer, that the subject has the condition or determining a degree or status of the condition of the subject, based on the identified one or more cell-free nucleic acid molecules comprising the plurality of phased variants, wherein the identified one or more cell-free nucleic acid molecules are derived from a sample associated with the condition, based on performing a statistical model analysis of the identified one or more cell-free nucleic acid molecules.
  • 19. The method of claim 1, wherein the at least 1,000 cell-free DNA molecules from which sequencing data is derived are captured with a set of nucleic acid probes, wherein the set of nucleic acid probes is configured to hybridize to at least a portion of cell-free nucleic acid molecules comprising one or more genomic regions associated with the condition.
  • 20. The method of claim 19, wherein the set of nucleic acid probes is designed based on the plurality of phased variants that are identified by comparing (i) sequencing data from a tumor sample of the subject and (ii) sequencing data from a healthy cell of the subject or a healthy cohort.
  • 21. The method according to claim 1, wherein the first sample and the second sample are derived from separate components of a blood draw.
  • 22. The method according to claim 21, wherein the first sample is derived from plasma.
  • 23. The method according to claim 22, wherein the second sample is derived from peripheral blood mononuclear cells.
  • 24. A method comprising: (a) obtaining, by a computer system, sequencing data for at least 1,000 cell-free DNA molecules from a first sample of a human subject;(b) processing, by the computer system, the sequencing data of (a) to identify one or more cell-free DNA molecules of the at least 1,000 cell-free DNA molecules as phased variant-containing cell-free DNA molecules, wherein identifying the one or more cell-free DNA molecules as phased variant-containing cell-free DNA molecules comprises aligning reads corresponding to each of the at least 1,000 cell-free DNA molecules to a reference human genomic sequence of at least 10 kb in length, wherein each of the one or more cell-free nucleic acid molecules identified as phased variant-containing cell-free DNA molecules comprises a plurality of phased variants relative to a sequence derived from a second sample of the same subject, wherein at least 10% of the one or more cell-free nucleic acid molecules identified as phased variant-containing cell-free DNA molecules comprises a first phased variant of the plurality of phased variants and a second phased variant of the plurality of phased variants that are separated by at least one nucleotide; and(c) analyzing, by the computer system, the identified one or more cell-free nucleic acid molecules identified as phased variant-containing cell-free DNA molecules to determine a condition of the subject.
CROSS-REFERENCE

This application is a continuation of U.S. patent application Ser. No. 17/646,473, filed Dec. 29, 2021, which is a continuation of PCT Patent Application No. PCT/US2020/059526, filed Nov. 6, 2020, which claims the benefit of U.S. Provisional Patent Application No. 62/931,688, filed Nov. 6, 2019, the disclosures of which are entirely incorporated herein by reference in their entirety.

GOVERNMENT RIGHTS

This invention was made with Government support under CA233975, CA241076, and CA188298 awarded by the National Institutes of Health. The Government has certain rights in the invention.

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Related Publications (1)
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62931688 Nov 2019 US
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Parent 17646473 Dec 2021 US
Child 18167804 US
Parent PCT/US2020/059526 Nov 2020 US
Child 17646473 US