PROCESSES AND COMPOSITIONS FOR METHYLATION-BASED ENRICHMENT OF FETAL NUCLEIC ACID FROM A MATERNAL SAMPLE USEFUL FOR NON-INVASIVE PRENATAL DIAGNOSES

FIELD

The technology in part relates to prenatal diagnostics and enrichment methods.

BACKGROUND

Non-invasive prenatal testing is becoming a field of rapidly growing interest. Early detection of pregnancy-related conditions, including complications during pregnancy and genetic defects of the fetus is of crucial importance, as it allows early medical intervention necessary for the safety of both the mother and the fetus. Prenatal diagnosis has been conducted using cells isolated from the fetus through procedures such as chorionic villus sampling (CVS) or amniocentesis. However, these conventional methods are invasive and present an appreciable risk to both the mother and the fetus. The National Health Service currently cites a miscarriage rate of between 1 and 2 percent following the invasive amniocentesis and chorionic villus sampling (CVS) tests.

An alternative to these invasive approaches has been developed for prenatal screening, e.g., to detecting fetal abnormalities, following the discovery that circulating cell-free fetal nucleic acid can be detected in maternal plasma and serum (Lo et al., Lancet 350:485-487, 1997; and U.S. Pat. No. 6,258,540). Circulating cell free fetal nucleic acid (cffNA) has several advantages making it more applicable for non-invasive prenatal testing. For example, cell free nucleic acid is present at higher levels than fetal cells and at concentrations sufficient for genetic analysis. Also, cffNA is cleared from the maternal bloodstream within hours after delivery, preventing contamination from previous pregnancies.

Examples of prenatal tests performed by detecting fetal DNA in maternal plasma or serum include fetal rhesus D (RhD) genotyping (Lo et al., N. Engl. J. Med. 339:1734-1738, 1998), fetal sex determination (Costa et al., N. Engl. J. Med. 346:1502, 2002), and diagnosis of several fetal disorders (Amicucci et al., Clin. Chem. 46:301-302, 2000; Saito et al., Lancet 356:1170, 2000; and Chiu et al., Lancet 360:998-1000, 2002). In addition, quantitative abnormalities of fetal DNA in maternal plasma/serum have been reported in preeclampsia (Lo et al., Clin. Chem. 45:184-188, 1999 and Zhong et al., Am. J. Obstet. Gynecol. 184:414-419, 2001), fetal trisomy 21 (Lo et al., Clin. Chem. 45:1747-1751, 1999 and Zhong et al., Prenat. Diagn. 20:795-798, 2000) and hyperemesis gravidarum (Sekizawa et al., Clin. Chem. 47:2164-2165, 2001).

SUMMARY

The invention provides inter alia human epigenetic biomarkers that are useful for the noninvasive detection of fetal genetic traits, including, but not limited to, the presence or absence of fetal nucleic acid, the absolute or relative amount of fetal nucleic acid, fetal sex, and fetal chromosomal abnormalities such as aneuploidy. The human epigenetic biomarkers of the invention represent genomic DNA that display differential CpG methylation patterns between the fetus and mother. The compositions and processes of the invention allow for the detection and quantification of fetal nucleic acid in a maternal sample based on the methylation status of the nucleic acid in said sample. More specifically, the amount of fetal nucleic acid from a maternal sample can be determined relative to the total amount of nucleic acid present, thereby providing the percentage of fetal nucleic acid in the sample. Further, the amount of fetal nucleic acid can be determined in a sequence-specific (or locus-specific) manner and with sufficient sensitivity to allow for accurate chromosomal dosage analysis (for example, to detect the presence or absence of a fetal aneuploidy).

In the first aspect of the invention, a method is provided for enriching fetal nucleic acids from a maternal biological sample, based on differential methylation between fetal and maternal nucleic acid comprising the steps of: (a) binding a target nucleic acid, from a sample, and a control nucleic acid, from the sample, to a methylation-specific binding protein; and (b) eluting the bound nucleic acid based on methylation status, wherein differentially methylated nucleic acids elute at least partly into separate fractions. In an embodiment, the nucleic acid sequence includes one or more of the polynucleotide sequences of SEQ ID NOs: 1-261. SEQ ID NOs: 1-261 are provided in Tables 4A-4C. The invention includes the sequences of SEQ ID NOs: 1-261, and variations thereto. In an embodiment, a control nucleic acid is not included in step (a).

In a related embodiment, a method is provided for enriching fetal nucleic acid from a maternal sample, which comprises the following steps: (a) obtaining a biological sample from a woman; (b) separating fetal and maternal nucleic acid based on the methylation status of a CpG-containing genomic sequence in the sample, wherein the genomic sequence from the fetus and the genomic sequence from the woman are differentially methylated, thereby distinguishing the genomic sequence from the woman and the genomic sequence from the fetus in the sample. In an embodiment, the genomic sequence is at least 15 nucleotides in length, comprising at least one cytosine, further wherein the region consists of (1) a genomic locus selected from Tables 1A-1C; and (2) a DNA sequence of no more than 10 kb upstream and/or downstream from the locus. For this aspect and all aspects of the invention, obtaining a biological sample from a woman is not meant to limit the scope of the invention. Said obtaining can refer to actually drawing a sample from a woman (e.g., a blood draw) or to receiving a sample from elsewhere (e.g., from a clinic or hospital) and performing the remaining steps of the method.

In a related embodiment, a method is provided for enriching fetal nucleic acid from a maternal sample, which comprises the following steps: (a) obtaining a biological sample from the woman; (b) digesting or removing maternal nucleic acid based on the methylation status of a CpG-containing genomic sequence in the sample, wherein the genomic sequence from the fetus and the genomic sequence from the woman are differentially methylated, thereby enriching for the genomic sequence from the fetus in the sample. Maternal nucleic acid may be digested using one or more methylation sensitive restriction enzymes that selectively digest or cleave maternal nucleic acid based on its methylation status. In an embodiment, the genomic sequence is at least 15 nucleotides in length, comprising at least one cytosine, further wherein the region consists of (1) a genomic locus selected from Tables 1A-1C; and (2) a DNA sequence of no more than 10 kb upstream and/or downstream from the locus.

In a second aspect of the invention, a method is provided for preparing nucleic acid having a nucleotide sequence of a fetal nucleic acid, which comprises the following steps: (a) providing a sample from a pregnant female; (b) separating fetal nucleic acid from maternal nucleic acid from the sample of the pregnant female according to a different methylation state between the fetal nucleic acid and the maternal nucleic acid counterpart, wherein the nucleotide sequence of the fetal nucleic acid comprises one or more CpG sites from one or more of the polynucleotide sequences of SEQ ID NOs: 1-261 within a polynucleotide sequence from a gene or locus that contains one of the polynucleotide sequences of SEQ ID NOs: 1-261; and (c) preparing nucleic acid comprising a nucleotide sequence of the fetal nucleic acid by an amplification process in which fetal nucleic acid separated in part (b) is utilized as a template. In an embodiment, a method is provided for preparing nucleic acid having a nucleotide sequence of a fetal nucleic acid, which comprises the following steps: (a) providing a sample from a pregnant female; (b) digesting or removing maternal nucleic acid from the sample of the pregnant female according to a different methylation state between the fetal nucleic acid and the maternal nucleic acid counterpart, wherein the nucleotide sequence of the fetal nucleic acid comprises one or more CpG sites from one or more of the polynucleotide sequences of SEQ ID NOs: 1-261 within a polynucleotide sequence from a gene that contains one of the polynucleotide sequences of SEQ ID NOs: 1-261; and (c) preparing nucleic acid comprising a nucleotide sequence of the fetal nucleic acid. The preparing process of step (c) may be a hybridization process, a capture process, or an amplification process in which fetal nucleic acid separated in part (b) is utilized as a template. Also, in the above embodiment wherein maternal nucleic acid is digested, the maternal nucleic acid may be digested using one or more methylation sensitive restriction enzymes that selectively digest or cleave maternal nucleic acid based on its methylation status. In either embodiment, the polynucleotide sequences of SEQ ID NOs: 1-261 may be within a polynucleotide sequence from a CpG island that contains one of the polynucleotide sequences of SEQ ID NOs: 1-261. The polynucleotide sequences of SEQ ID NOs: 1-261 are further characterized in Tables 1-3 herein, including the identification of CpG islands that overlap with the polynucleotide sequences provided in SEQ ID NOs: 1-261. In an embodiment, the nucleic acid prepared by part (c) is in solution. In yet an embodiment, the method further comprises quantifying the fetal nucleic acid from the amplification process of step (c).

In a third aspect of the invention, a method is provided for enriching fetal nucleic acid from a sample from a pregnant female with respect to maternal nucleic acid, which comprises the following steps: (a) providing a sample from a pregnant female; and (b) separating or capturing fetal nucleic acid from maternal nucleic acid from the sample of the pregnant female according to a different methylation state between the fetal nucleic acid and the maternal nucleic acid, wherein the nucleotide sequence of the fetal nucleic acid comprises one or more CpG sites from one or more of the polynucleotide sequences of SEQ ID NOs: 1-261 within a polynucleotide sequence from a gene that contains one of the polynucleotide sequences of SEQ ID NOs: 1-261. In an embodiment, the polynucleotide sequences of SEQ ID NOs: 1-261 may be within a polynucleotide sequence from a CpG island that contains one of the polynucleotide sequences of SEQ ID NOs: 1-261. The polynucleotide sequences of SEQ ID NOs: 1-261 are characterized in Tables 1A-1C herein. In an embodiment, the nucleic acid separated by part (b) is in solution. In yet an embodiment, the method further comprises amplifying and/or quantifying the fetal nucleic acid from the separation process of step (b).

In a fourth aspect of the invention, a composition is provided comprising an isolated nucleic acid from a fetus of a pregnant female, wherein the nucleotide sequence of the nucleic acid comprises one or more of the polynucleotide sequences of SEQ ID NOs: 1-261. In one embodiment, the nucleotide sequence consists essentially of a nucleotide sequence of a gene, or portion thereof. In an embodiment, the nucleotide sequence consists essentially of a nucleotide sequence of a CpG island, or portion thereof. The polynucleotide sequences of SEQ ID NOs: 1-261 are further characterized in Tables 1A-1C. In an embodiment, the nucleic acid is in solution. In an embodiment, the nucleic acid from the fetus is enriched relative to maternal nucleic acid. In an embodiment, the composition further comprises an agent that binds to methylated nucleotides. For example, the agent may be a methyl-CpG binding protein (MBD) or fragment thereof.

In a fifth aspect of the invention, a composition is provided comprising an isolated nucleic acid from a fetus of a pregnant female, wherein the nucleotide sequence of the nucleic acid comprises one or more CpG sites from one or more of the polynucleotide sequences of SEQ ID NOs: 1-261 within a polynucleotide sequence from a gene, or portion thereof, that contains one of the polynucleotide sequences of SEQ ID NOs: 1-261. In an embodiment, the nucleotide sequence of the nucleic acid comprises one or more CpG sites from one or more of the polynucleotide sequences of SEQ ID NOs: 1-261 within a polynucleotide sequence from a CpG island, or portion thereof, that contains one of the polynucleotide sequences of SEQ ID NOs: 1-261. The polynucleotide sequences of SEQ ID NOs: 1-261 are further characterized in Tables 1A-1C. In an embodiment, the nucleic acid is in solution. In an embodiment, the nucleic acid from the fetus is enriched relative to maternal nucleic acid. Hyper- and hypomethylated nucleic acid sequences of the invention are identified in Tables 1A-1C. In an embodiment, the composition further comprises an agent that binds to methylated nucleotides. For example, the agent may be a methyl-CpG binding protein (MBD) or fragment thereof.

In some embodiments, a nucleotide sequence of the invention includes three or more of the CpG sites. In an embodiment, the nucleotide sequence includes five or more of the CpG sites. In an embodiment, the nucleotide sequence is from a gene region that comprises a PRC2 domain (see Table 3). In an embodiment, the nucleotide sequence is from a gene region involved with development. For example, SOX14—which is an epigenetic marker of the present invention (See Table 1)—is a member of the SOX (SRY-related HMG-box) family of transcription factors involved in the regulation of embryonic development and in the determination of cell fate.

In some embodiments, the genomic sequence from the woman is methylated and the genomic sequence from the fetus is unmethylated. In other embodiments, the genomic sequence from the woman is unmethylated and the genomic sequence from the fetus is methylated. In an embodiment, the genomic sequence from the fetus is hypermethylated relative to the genomic sequence from the mother. Fetal genomic sequences found to be hypermethylated relative to maternal genomic sequence are provided in SEQ ID NOs: 1-59, 90-163, 176, 179, 180, 184, 188, 189, 190, 191, 193, 195, 198, 199, 200, 201, 202, 203, 205, 206, 207, 208, 209, 210, 211, 212, 213, 214, 221, 223, 225, 226, 231, 232, 233, 235, 239, 241, 257, 258, 259, and 261. Alternatively, the genomic sequence from the fetus is hypomethylated relative to the genomic sequence from the mother. Fetal genomic sequences found to be hypomethylated relative to maternal genomic sequence are provided in SEQ ID NOs: 60-85, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 177, 178, 181, 182, 183, 185, 186, 187, 192, 194, 196, 197, 204, 215, 216, 217, 218, 219, 220, 222, 224, 227, 228, 229, 230, 234, 236, 237, 238, 240, 242, 243, 244, 245, 246, 247, 248, 249, 250, 251, 252, 253, 254, 255, 256, and 260. Methylation sensitive restriction enzymes of the invention may be sensitive to hypo- or hyper-methylated nucleic acid.

In an embodiment, the fetal nucleic acid is extracellular nucleic acid. Generally the extracellular fetal nucleic acid is about 500, 400, 300, 250, 200 or 150 (or any number there between) nucleotide bases or less. In an embodiment, the digested maternal nucleic acid is less than about 90, 100, 110, 120, 130, 140 or 150 base pairs. In a related embodiment, the fetal nucleic acid is selectively amplified, captured or separated from or relative to the digested maternal nucleic acid based on size. For example, PCR primers may be designed to amplify nucleic acid greater than about 75, 80, 85, 90, 95, 100, 105, 110, 115 or 120 (or any number there between) base pairs thereby amplifying fetal nucleic acid and not digested maternal nucleic acid. In an embodiment, the nucleic acid is subjected to fragmentation prior to the methods of the invention. Examples of methods of fragmenting nucleic acid, include but are not limited to sonication and restriction enzyme digestion. In some embodiments the fetal nucleic acid is derived from the placenta. In other embodiments the fetal nucleic acid is apoptotic.

In some embodiments, the present invention provides a method in which the sample is a member selected from the following: maternal whole blood, maternal plasma or serum, amniotic fluid, a chorionic villus sample, biopsy material from a pre-implantation embryo, fetal nucleated cells or fetal cellular remnants isolated from maternal blood, maternal urine, maternal saliva, washings of the female reproductive tract and a sample obtained by celocentesis or lung lavage. In certain embodiments, the biological sample is maternal blood. In some embodiments, the biological sample is a chorionic villus sample. In certain embodiments, the maternal sample is enriched for fetal nucleic acid prior to the methods of the present invention. Examples of fetal enrichment methods are provided in PCT Publication Nos. WO/2007140417A2, WO2009/032781A2 and US Publication No. 20050164241.

In some embodiments, all nucleated and a nucleated cell populations are removed from the sample prior to practicing the methods of the invention. In some embodiments, the sample is collected, stored or transported in a manner known to the person of ordinary skill in the art to minimize degradation or the quality of fetal nucleic acid present in the sample.

The sample can be from any animal, including but not limited, human, non-human, mammal, reptile, cattle, cat, dog, goat, swine, pig, monkey, ape, gorilla, bull, cow, bear, horse, sheep, poultry, mouse, rat, fish, dolphin, whale, and shark, or any animal or organism that may have a detectable pregnancy-associated disorder or chromosomal abnormality.

In some embodiments, the sample is treated with a reagent that differentially modifies methylated and unmethylated DNA. For example, the reagent may comprise bisulfite; or the reagent may comprise one or more enzymes that preferentially cleave methylated DNA; or the reagent may comprise one or more enzymes that preferentially cleave unmethylated DNA. Examples of methylation sensitive restriction enzymes include, but are not limited to, HhaI and HpaII.

In one embodiment, the fetal nucleic acid is separated from the maternal nucleic acid by an agent that specifically binds to methylated nucleotides in the fetal nucleic acid. In an embodiment, the fetal nucleic acid is separated or removed from the maternal nucleic acid by an agent that specifically binds to methylated nucleotides in the maternal nucleic acid counterpart. In an embodiment, the agent that binds to methylated nucleotides is a methyl-CpG binding protein (MBD) or fragment thereof.

In a sixth aspect of the invention, a method is provided for determining the amount or copy number of fetal DNA in a maternal sample that comprises differentially methylated maternal and fetal DNA. The method is performed by a) distinguishing between the maternal and fetal DNA based on differential methylation status; and b) quantifying the fetal DNA of step a). In a specific embodiment, the method comprises a) digesting the maternal DNA in a maternal sample using one or more methylation sensitive restriction enzymes thereby enriching the fetal DNA; and b) determining the amount of fetal DNA from step a). The amount of fetal DNA can be used inter alia to confirm the presence or absence of fetal nucleic acid, determine fetal sex, diagnose fetal disease or a pregnancy-associated disorder, or be used in conjunction with other fetal diagnostic methods to improve sensitivity or specificity. In one embodiment, the method for determining the amount of fetal DNA does not require the use of a polymorphic sequence. For example, an allelic ratio is not used to quantify the fetal DNA in step b). In an embodiment, the method for determining the amount of fetal DNA does not require the treatment of DNA with bisulfite to convert cytosine residues to uracil. Bisulfite is known to degrade DNA, thereby, further reducing the already limited fetal nucleic acid present in maternal samples. In one embodiment, determining the amount of fetal DNA in step b) is done by introducing one or more competitors at known concentrations. In an embodiment, determining the amount of fetal DNA in step b) is done by RT-PCR, primer extension, sequencing or counting. In a related embodiment, the amount of nucleic acid is determined using BEAMing technology as described in US Patent Publication No. US20070065823. In a another related embodiment, the amount of nucleic acid is determined using the shotgun sequencing technology described in US Patent Publication No. US20090029377 (U.S. application Ser. No. 12/178,181), or variations thereof. In an embodiment, the restriction efficiency is determined and the efficiency rate is used to further determine the amount of fetal DNA. Exemplary differentially methylated nucleic acids are provided in SEQ ID NOs: 1-261.

In a seventh aspect of the invention, a method is provided for determining the concentration of fetal DNA in a maternal sample, wherein the maternal sample comprises differentially methylated maternal and fetal DNA, comprising a) determining the total amount of DNA present in the maternal sample; b) selectively digesting the maternal DNA in a maternal sample using one or more methylation sensitive restriction enzymes thereby enriching the fetal DNA; c) determining the amount of fetal DNA from step b); and d) comparing the amount of fetal DNA from step c) to the total amount of DNA from step a), thereby determining the concentration of fetal DNA in the maternal sample. The concentration of fetal DNA can be used inter alia in conjunction with other fetal diagnostic methods to improve sensitivity or specificity. In one embodiment, the method for determining the amount of fetal DNA does not require the use of a polymorphic sequence. For example, an allelic ratio is not used to quantify the fetal DNA in step b). In an embodiment, the method for determining the amount of fetal DNA does not require the treatment of DNA with bisulfite to convert cytosine residues to uracil. In one embodiment, determining the amount of fetal DNA in step b) is done by introducing one or more competitors at known concentrations. In an embodiment, determining the amount of fetal DNA in step b) is done by RT-PCR, sequencing or counting. In an embodiment, the restriction efficiency is determined and used to further determine the amount of total DNA and fetal DNA. Exemplary differentially methylated nucleic acids are provided in SEQ ID NOs: 1-261.

In an eighth aspect of the invention, a method is provided for determining the presence or absence of a fetal aneuploidy using fetal DNA from a maternal sample, wherein the maternal sample comprises differentially methylated maternal and fetal DNA, comprising a) selectively digesting the maternal DNA in a maternal sample using one or more methylation sensitive restriction enzymes thereby enriching the fetal DNA; b) determining the amount of fetal DNA from a target chromosome; c) determining the amount of fetal DNA from a reference chromosome; and d) comparing the amount of fetal DNA from step b) to step c), wherein a biologically or statistically significant difference between the amount of target and reference fetal DNA is indicative of the presence of a fetal aneuploidy. In one embodiment, the method for determining the amount of fetal DNA does not require the use of a polymorphic sequence. For example, an allelic ratio is not used to quantify the fetal DNA in step b). In an embodiment, the method for determining the amount of fetal DNA does not require the treatment of DNA with bisulfite to convert cytosine residues to uracil. In one embodiment, determining the amount of fetal DNA in steps b) and c) is done by introducing one or more competitors at known concentrations. In an embodiment, determining the amount of fetal DNA in steps b) and c) is done by RT-PCR, sequencing or counting. In an embodiment, the amount of fetal DNA from a target chromosome determined in step b) is compared to a standard control, for example, the amount of fetal DNA from a target chromosome from euploid pregnancies. In an embodiment, the restriction efficiency is determined and used to further determine the amount of fetal DNA from a target chromosome and from a reference chromosome. Exemplary differentially methylated nucleic acids are provided in SEQ ID NOs: 1-261.

In a ninth aspect of the invention, a method is provided for detecting the presence or absence of a chromosomal abnormality by analyzing the amount or copy number of target nucleic acid and control nucleic acid from a sample of differentially methylated nucleic acids comprising the steps of: (a) enriching a target nucleic acid, from a sample, and a control nucleic acid, from the sample, based on its methylation state; (b) performing a copy number analysis of the enriched target nucleic acid in at least one of the fractions; (c) performing a copy number analysis of the enriched control nucleic acid in at least one of the fractions; (d) comparing the copy number from step (b) with the copy number from step (c); and (e) determining if a chromosomal abnormality exists based on the comparison in step (d), wherein the target nucleic acid and control nucleic acid have the same or substantially the same methylation status. In a related embodiment, a method is provided for detecting the presence or absence of a chromosomal abnormality by analyzing the amount or copy number of target nucleic acid and control nucleic acid from a sample of differentially methylated nucleic acids comprising the steps of: (a) binding a target nucleic acid, from a sample, and a control nucleic acid, from the sample, to a binding agent; (b) eluting the bound nucleic acid based on methylation status, wherein differentially methylated nucleic acids elute at least partly into separate fractions; (c) performing a copy number analysis of the eluted target nucleic acid in at least one of the fractions; (d) performing a copy number analysis of the eluted control nucleic acid in at least one of the fractions; (e) comparing the copy number from step (c) with the copy number from step (d); and (f) determining if a chromosomal abnormality exists based on the comparison in step (e), wherein the target nucleic acid and control nucleic acid have the same or substantially the same methylation status. Differentially methylated nucleic acids are provided in SEQ ID NOs: 1-261.

In a tenth aspect of the invention, a method is provided for detecting the presence or absence of a chromosomal abnormality by analyzing the allelic ratio of target nucleic acid and control nucleic acid from a sample of differentially methylated nucleic acids comprising the steps of: (a) binding a target nucleic acid, from a sample, and a control nucleic acid, from the sample, to a binding agent; (b) eluting the bound nucleic acid based on methylation status, wherein differentially methylated nucleic acids elute at least partly into separate fractions; (c) performing an allelic ratio analysis of the eluted target nucleic acid in at least one of the fractions; (d) performing an allelic ratio analysis of the eluted control nucleic acid in at least one of the fractions; (e) comparing the allelic ratio from step c with the all from step d; and (f) determining if a chromosomal abnormality exists based on the comparison in step (e), wherein the target nucleic acid and control nucleic acid have the same or substantially the same methylation status. Differentially methylated nucleic acids are provided in SEQ ID NOs: 1-261, and SNPs within the differentially methylated nucleic acids are provided in Table 2. The methods may also be useful for detecting a pregnancy-associated disorder.

In an eleventh aspect of the invention, the amount of maternal nucleic acid is determined using the methylation-based methods of the invention. For example, fetal nucleic acid can be separated (for example, digested using a methylation-sensitive enzyme) from the maternal nucleic acid in a sample, and the maternal nucleic acid can be quantified using the methods of the invention. Once the amount of maternal nucleic acid is determined, that amount can subtracted from the total amount of nucleic acid in a sample to determine the amount of fetal nucleic acid. The amount of fetal nucleic acid can be used to detect fetal traits, including fetal aneuploidy, as described herein.

For all aspects and embodiments of the invention described herein, the methods may also be useful for detecting a pregnancy-associated disorder. In some embodiments, the sample comprises fetal nucleic acid, or fetal nucleic acid and maternal nucleic acid. In the case when the sample comprises fetal and maternal nucleic acid, the fetal nucleic acid and the maternal nucleic acid may have a different methylation status. Nucleic acid species with a different methylation status can be differentiated by any method known in the art. In an embodiment, the fetal nucleic acid is enriched by the selective digestion of maternal nucleic acid by a methylation sensitive restriction enzyme. In an embodiment, the fetal nucleic acid is enriched by the selective digestion of maternal nucleic acid using two or more methylation sensitive restriction enzymes in the same assay. In an embodiment, the target nucleic acid and control nucleic acid are both from the fetus. In an embodiment, the average size of the fetal nucleic acid is about 100 bases to about 500 bases in length. In an embodiment the chromosomal abnormality is an aneuploidy, such as trisomy 21. In some embodiments, the target nucleic acid is at least a portion of a chromosome which may be abnormal and the control nucleic acid is at least a portion of a chromosome which is very rarely abnormal. For example, when the target nucleic acid is from chromosome 21, the control nucleic acid is from a chromosome other than chromosome 21—preferably another autosome. In an embodiment, the binding agent is a methylation-specific binding protein such as MBD-Fc. Also, the enriched or eluted nucleic acid is amplified and/or quantified by any method known in the art. In an embodiment, the fetal DNA is quantified using a method that does not require the use of a polymorphic sequence. For example, an allelic ratio is not used to quantify the fetal DNA. In an embodiment, the method for quantifying the amount of fetal DNA does not require the treatment of DNA with bisulfite to convert cytosine residues to uracil.

In some embodiments, the methods of the invention include the additional step of determining the amount of one or more Y-chromosome-specific sequences in a sample. In a related embodiment, the amount of fetal nucleic acid in a sample as determined by using the methylation-based methods of the invention is compared to the amount of Y-chromosome nucleic acid present.

Methods for differentiating nucleic acid based on methylation status include, but are not limited to, methylation sensitive capture, for example using, MBD2-Fc fragment; bisulfite conversion methods, for example, MSP (methylation-sensitive PCR), COBRA, methylation-sensitive single nucleotide primer extension (Ms-SNuPE) or Sequenom MassCLEAVE™ technology; and the use of methylation sensitive restriction enzymes. Except where explicitly stated, any method for differentiating nucleic acid based on methylation status can be used with the compositions and methods of the invention.

In some embodiments, methods of the invention may further comprise an amplification step. The amplification step can be performed by PCR, such as methylation-specific PCR. In an embodiment, the amplification reaction is performed on single molecules, for example, by digital PCR, which is further described in U.S. Pat. Nos. 6,143,496 and 6,440,706, both of which are hereby incorporated by reference. In other embodiments, the method does not require amplification. For example, the amount of enriched fetal DNA may be determined by counting the fetal DNA (or sequence tags attached thereto) with a flow cytometer or by sequencing means that do not require amplification. In an embodiment, the amount of fetal DNA is determined by an amplification reaction that generates amplicons larger than the digested maternal nucleic acid, thereby further enriching the fetal nucleic acid.

In some embodiments, the fetal nucleic acid (alone or in combination with the maternal nucleic acid) comprises one or more detection moieties. In one embodiment, the detection moiety may be any one or more of a compomer, sugar, peptide, protein, antibody, chemical compound (e.g., biotin), mass tag (e.g., metal ions or chemical groups), fluorescent tag, charge tag (e.g., such as polyamines or charged dyes) and hydrophobic tag. In a related embodiment, the detection moiety is a mass-distinguishable product (MDP) or part of an MDP detected by mass spectrometry. In a specific embodiment, the detection moiety is a fluorescent tag or label that is detected by mass spectrometry. In some embodiments, the detection moiety is at the 5′ end of a detector oligonucleotide, the detection moiety is attached to a non-complementary region of a detector oligonucleotide, or the detection moiety is at the 5′ terminus of a non-complementary sequence. In certain embodiments, the detection moiety is incorporated into or linked to an internal nucleotide or to a nucleotide at the 3′ end of a detector oligonucleotide. In some embodiments, one or more detection moieties are used either alone or in combination. See for example US Patent Applications US20080305479 and US20090111712. In certain embodiments, a detection moiety is cleaved by a restriction endonuclease, for example, as described in U.S. application Ser. No. 12/726,246. In some embodiments, a specific target chromosome is labeled with a specific detection moiety and one or more non-target chromosomes are labeled with a different detection moiety, whereby the amount target chromsome can be compared to the amount of non-target chromosome.

For embodiments that require sequence analysis, any one of the following sequencing technologies may be used: a primer extension method (e.g., iPLEX®; Sequenom, Inc.), direct DNA sequencing, restriction fragment length polymorphism (RFLP analysis), real-time PCR, for example using “STAR” (Scalable Transcription Analysis Routine) technology (see U.S. Pat. No. 7,081,339), or variations thereof, allele specific oligonucleotide (ASO) analysis, methylation-specific PCR (MSPCR), pyrosequencing analysis, acycloprime analysis, Reverse dot blot, GeneChip microarrays, Dynamic allele-specific hybridization (DASH), Peptide nucleic acid (PNA) and locked nucleic acids (LNA) probes, TaqMan, Molecular Beacons, Intercalating dye, FRET primers, fluorescence tagged dNTP/ddNTPs, AlphaScreen, SNPstream, genetic bit analysis (GBA), Multiplex minisequencing, SNaPshot, GOOD assay, Microarray miniseq, arrayed primer extension (APEX), Microarray primer extension, Tag arrays, Coded microspheres, Template-directed incorporation (TDI), fluorescence polarization, Colorimetric oligonucleotide ligation assay (OLA), Sequence-coded OLA, Microarray ligation, Ligase chain reaction, Padlock probes, Invader™ assay, hybridization using at least one probe, hybridization using at least one fluorescently labeled probe, electrophoresis, cloning and sequencing, for example as performed on the 454 platform (Roche) (Margulies, M. et al. 2005 Nature 437, 376-380), IIlumina Genome Analyzer (or Solexa platform) or SOLiD System (Applied Biosystems) or the Helicos True Single Molecule DNA sequencing technology (Harris T D et al. 2008 Science, 320, 106-109), the single molecule, real-time (SMRT™) technology of Pacific Biosciences, or nanopore-based sequencing (Soni G V and Meller A. 2007 Clin Chem 53: 1996-2001), for example, using an Ion Torrent ion sensor that measures an electrical charge associated with each individual base of DNA as each base passes through a tiny pore at the bottom of a sample well, or Oxford Nanopore device that uses a nanopore to measure the electrical charge associated with each individual unit of DNA, and combinations thereof. Nanopore-based methods may include sequencing nucleic acid using a nanopore, or counting nucleic acid molecules using a nanopore, for example, based on size wherein sequence information is not determined.

The absolute copy number of one or more nucleic acids can be determined, for example, using mass spectrometry, a system that uses a competitive PCR approach for absolute copy number measurements. See for example, Ding C, Cantor C R (2003) A high-throughput gene expression analysis technique using competitive PCR and matrix-assisted laser desorption ionization time-of-flight MS. Proc Natl Acad Sci USA 100:3059-3064, and U.S. patent application Ser. No. 10/655,762, which published as US Patent Publication No. 20040081993, both of which are hereby incorporated by reference.

In some embodiments, the amount of the genomic sequence is compared with a standard control, wherein an increase or decrease from the standard control indicates the presence or progression of a pregnancy-associated disorder. For example, the amount of fetal nucleic acid may be compared to the total amount of DNA present in the sample. Or when detecting the presence or absence of fetal aneuploidy, the amount of fetal nucleic acid from target chromosome may be compared to the amount of fetal nucleic acid from a reference chromosome. Preferably the reference chromosome is another autosome that has a low rate of aneuploidy. The ratio of target fetal nucleic acid to reference fetal nucleic acid may be compared to the same ratio from a normal, euploid pregnancy. For example, a control ratio may be determined from a DNA sample obtained from a female carrying a healthy fetus who does not have a chromosomal abnormality. Preferably, one uses a panel of control samples. Where certain chromosome anomalies are known, one can also have standards that are indicative of a specific disease or condition. Thus, for example, to screen for three different chromosomal aneuploidies in a maternal plasma of a pregnant female, one preferably uses a panel of control DNAs that have been isolated from mothers who are known to carry a fetus with, for example, chromosome 13, 18, or 21 trisomy, and a mother who is pregnant with a fetus who does not have a chromosomal abnormality.

In some embodiments, the present invention provides a method in which the alleles from the target nucleic acid and control nucleic acid are differentiated by sequence variation. The sequence variation may be a single nucleotide polymorphism (SNP) or an insertion/deletion polymorphism. In an embodiment, the fetal nucleic acid should comprise at least one high frequency heterozygous polymorphism (e.g., about 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, 10%, 11%, 12%, 13%, 14%, 15%, 16%, 17%, 18%, 19%, 20%, 25% or more frequency rate), which allows the determination of the allelic-ratio of the nucleic acid in order to assess the presence or absence of the chromosomal abnormality. A list of exemplary SNPs is provided in Table 2, however, this does not represent a complete list of polymorphic alleles that can be used as part of the invention. Any SNP meeting the following criteria may also be considered: (a) the SNP has a heterozygosity frequency greater than about 2% (preferably across a range of different populations), (b) the SNP is a heterozygous locus; and (c)(i) the SNP is within nucleic acid sequence described herein, or (c)(iii) the SNP is within about 5 to about 2000 base pairs of a SNP described herein (e.g., within about 5, 10, 15, 20, 25, 30, 40, 50, 60, 70, 80, 90, 100, 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1250, 1500, 1750 or 2000 base pairs of a SNP described herein).

In other embodiments, the sequence variation is a short tandem repeat (STR) polymorphism. In some embodiments, the sequence variation falls in a restriction site, whereby one allele is susceptible to digestion by a restriction enzyme and the one or more other alleles are not. In some embodiments, the sequence variation is a methylation site.

In some embodiments, performing an allelic ratio analysis comprises determining the ratio of alleles of the target nucleic acid and control nucleic acid from the fetus of a pregnant woman by obtaining an nucleic acid-containing biological sample from the pregnant woman, wherein the biological sample contains fetal nucleic acid, partially or wholly separating the fetal nucleic acid from the maternal nucleic acid based on differential methylation, discriminating the alleles from the target nucleic acid and the control nucleic acid, followed by determination of the ratio of the alleles, and detecting the presence or absence of a chromosomal disorder in the fetus based on the ratio of alleles, wherein a ratio above or below a normal, euploid ratio is indicative of a chromosomal disorder. In one embodiment, the target nucleic acid is from a suspected aneuploid chromosome (e.g., chromosome 21) and the control nucleic acid is from a euploid chromosome from the same fetus.

In some embodiments, the present invention is combined with other fetal markers to detect the presence or absence of multiple chromosomal abnormalities, wherein the chromosomal abnormalities are selected from the following: trisomy 21, trisomy 18 and trisomy 13, or combinations thereof. In some embodiments, the chromosomal disorder involves the X chromosome or the Y chromosome.

In some embodiments, the compositions or processes may be multiplexed in a single reaction. For example, the amount of fetal nucleic acid may be determined at multiple loci across the genome. Or when detecting the presence or absence of fetal aneuploidy, the amount of fetal nucleic acid may be determined at multiple loci on one or more target chromosomes (e.g., chromosomes 13, 18 or 21) and on one or more reference chromosomes. If an allelic ratio is being used, one or more alleles from Table 2 can be detected and discriminated simultaneously. When determining allelic ratios, multiplexing embodiments are particularly important when the genotype at a polymorphic locus is not known. In some instances, for example when the mother and child are homozygous at the polymorphic locus, the assay may not be informative. In one embodiment, greater than 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 50, 100, 200, 300 or 500, and any intermediate levels, polynucleotide sequences of the invention are enriched, separated and/or examined according the methods of the invention. When detecting a chromosomal abnormality by analyzing the copy number of target nucleic acid and control nucleic acid, less than 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, or 14 polynucleotide sequences may need to be analyzed to accurately detect the presence or absence of a chromosomal abnormality. In an embodiment, the compositions or processes of the invention may be used to assay samples that have been divided into 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 50, 100 or more replicates, or into single molecule equivalents. Methods for analyzing fetal nucleic acids from a maternal sample in replicates, including single molecule analyses, are provided in U.S. application Ser. No. 11/364,294, which published as US Patent Publication No. US 2007-0207466 A1, which is hereby incorporated by reference.

In a further embodiment, the present invention provides a method wherein a comparison step shows an increased risk of a fetus having a chromosomal disorder if the ratio of the alleles or absolute copy number of the target nucleic acid is higher or lower by 1 standard deviation from the standard control sequence. In some embodiments, the comparison step shows an increased risk of a fetus having a chromosomal disorder if the ratio of the alleles or absolute copy number of the target nucleic acid is higher or lower by 2 standard deviation from the standard control sequence. In some other embodiments, the comparison step shows an increased risk of a fetus having a chromosomal disorder if the ratio of the alleles or absolute copy number of the target nucleic acid is higher or lower by 3 standard deviation from the standard control sequence. In some embodiments, the comparison step shows an increased risk of a fetus having a chromosomal disorder if the ratio of the alleles or absolute copy number of the target nucleic acid is higher or lower than a statistically significant standard deviation from the control. In one embodiment, the standard control is a maternal reference, and in an embodiment the standard control is a fetal reference chromosome (e.g., non-trisomic autosome).

In some embodiments, the methods of the invention may be combined with other methods for diagnosing a chromosomal abnormality. For example, a noninvasive diagnostic method may require confirmation of the presence or absence of fetal nucleic acid, such as a sex test for a female fetus or to confirm an RhD negative female fetus in an RhD negative mother. In an embodiment, the compositions and methods of the invention may be used to determine the percentage of fetal nucleic acid in a maternal sample in order to enable another diagnostic method that requires the percentage of fetal nucleic acid be known. For example, does a sample meet certain threshold concentration requirements? When determining an allelic ratio to diagnose a fetal aneuploidy from a maternal sample, the amount or concentration of fetal nucleic acid may be required to make a diagnose with a given sensitivity and specificity. In other embodiments, the compositions and methods of the invention for detecting a chromosomal abnormality can be combined with other known methods thereby improving the overall sensitivity and specificity of the detection method. For example, mathematical models have suggested that a combined first-trimester screening program utilizing maternal age (MA), nuchal translucency (NT) thickness, serum-free beta-hCG, and serum PAPP-A will detect more than 80% of fetuses with Down's syndrome for a 5% invasive testing rate (Wald and Hackshaw, Prenat Diagn 17(9):921-9 (1997)). However, the combination of commonly used aneuploidy detection methods combined with the non-invasive free fetal nucleic acid-based methods described herein may offer improved accuracy with a lower false positive rate. Examples of combined diagnostic methods are provided in PCT Publication Number WO2008157264A2 (assigned to the Applicant), which is hereby incorporated by reference. In some embodiments, the methods of the invention may be combined with cell-based methods, wherein fetal cells are procured invasively or non-invasively.

In certain embodiments, an increased risk for a chromosomal abnormality is based on the outcome or result(s) produced from the compositions or methods provided herein. An example of an outcome is a deviation from the euploid absolute copy number or allelic ratio, which indicates the presence of chromosomal aneuploidy. This increase or decrease in the absolute copy number or ratio from the standard control indicates an increased risk of having a fetus with a chromosomal abnormality (e.g., trisomy 21). Information pertaining to a method described herein, such as an outcome, result, or risk of trisomy or aneuploidy, for example, may be transfixed, renditioned, recorded and/or displayed in any suitable medium. For example, an outcome may be transfixed in a medium to save, store, share, communicate or otherwise analyze the outcome. A medium can be tangible (e.g., paper) or intangible (e.g., electronic medium), and examples of media include, but are not limited to, computer media, databases, charts, patient charts, records, patient records, graphs and tables, and any other medium of expression. The information sometimes is stored and/or renditioned in computer readable form and sometimes is stored and organized in a database. In certain embodiments, the information may be transferred from one location to another using a physical medium (e.g., paper) or a computer readable medium (e.g., optical and/or magnetic storage or transmission medium, floppy disk, hard disk, random access memory, computer processing unit, facsimile signal, satellite signal, transmission over an internet or transmission over the world-wide web).

In practicing the present invention within all aspects mentioned above, a CpG island may be used as the CpG-containing genomic sequence in some cases, whereas in other cases the CpG-containing genomic sequence may not be a CpG island.

In some embodiments, the present invention provides a kit for performing the methods of the invention. One component of the kit is a methylation-sensitive binding agent.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1: Shows the design of the recombinant MBD-Fc protein used to separate differentially methylated DNA.

FIG. 2: Shows the methyl-CpG-binding, antibody-like protein has a high affinity and high avidity to its “antigen”, which is preferably DNA that is methylated at CpG di-nucleotides.

FIG. 3: Shows the methyl binding domain of MBD-FC binds all DNA molecules regardless of their methylation status. The strength of this protein/DNA interaction is defined by the level of DNA methylation. After binding genomic DNA, eluate solutions of increasing salt concentrations can be used to fractionate non-methylated and methylated DNA allowing for a controlled separation.

FIG. 4: Shows the experiment used to identify differentially methylated DNA from a fetus and mother using the recombinant MBD-Fc protein and a microarray.

FIG. 5: Shows typical results generated by Sequenom® EpiTYPER™ method, which was used to validate the results generated from the experiment illustrated in FIG. 4.

FIG. 6: Shows the correlation between the log ratios derived from microarray analysis (x axis) and methylation differences obtained by EpiTYPER analysis (y axis). Each data point represents the average for one region across all measured samples. The microarray analysis is comparative in nature because the highly methylated fraction of the maternal DNA is hybridized together with the highly methylated fraction of placenta DNA. Positive values indicate higher methylation of the placenta samples. In mass spectrometry each samples is measured individually. We first calculated difference in methylation by subtracting the maternal methylation values from the placenta methylation value. To compare the results with the microarray data we calculated the average of the differences for all maternal/placenta DNA pairs. FIG. 6 discloses SEQ ID NOS 350 and 351, respectively, in order of appearance.

FIG. 7 shows a correlation between microarray and EpiTYPER™ results.

FIG. 8: Shown is the correlation between the number of gDNA molecules that were expected and the number of molecules measured by competitive PCR in combination with mass spectrometry analysis. In this experiment we used DNA derived from whole blood (black plus signs) and commercially available fully methylated DNA (red crosses) in a 90 to 10 ratio. We used the MBD-FC fusion protein to separate the non-methylated and the methylated fraction of DNA. Each fraction was subject to competitive PCR analysis with mass spectrometry readout. The method has been described earlier for the analysis of copy number variations and is commercially available for gene expression analysis. The approach allows absolute quantification of DNA molecules with the help of a synthetic oligonucleotides of know concentration. In this experiment we targeted the MGMT locus, which was not methylated in the whole blood sample used here. Using an input of 300 total gDNA copies we expect to see 270 copies of non-methylated DNA and 30 copies of methylated DNA. The measured copy numbers are largely in agreement with the expected values. The data point at 600 copies of input DNA indicates a bias in the reaction and shows that this initial proof of concept experiment needs to be followed up with more development work, before the assay can be used. However, this initial data indicates the feasibility of the approach for capturing and quantifying of a few copies of methylated DNA in the presence of an excess of unmethylated DNA species.

FIG. 9A-9L show bar graph plots of the methylation differences obtained from the microarray analysis (dark bars) and the mass spectrometry analysis (light grey bars) with respect to their genomic location. For each of the 85 region that were identified to be differentially methylated by microarray an individual plot is provided. The x axis for each plot shows the chromosomal position of the region. The y axis depicts the log ration (in case of the microarrays) and the methylation differences (in case of the mass spectrometry results). For the microarrays each hybridization probe in the area is shown as a single black (or dark grey) bar. For the mass spectrometry results each CpG site, is shown as a light grey bar. Bars showing values greater than zero indicate higher DNA methylation in the placenta samples compared to the maternal DNA. For some genes the differences are small (i.e. RB1 or DSCR6) but still statistically significant. Those regions would be less suitable for a fetal DNA enrichment strategy.

FIG. 10: Shows one embodiment of the Fetal Quantifier Method. Maternal nucleic acid is selectively digested and the remaining fetal nucleic acid is quantified using a competitor of known concentration. In this schema, the analyte is separated and quantified by a mass spectromter.

FIG. 11: Shows one embodiment of the Methylation-Based Fetal Diagnostic Method. Maternal nucleic acid is selectively digested and the remaining fetal nucleic acid is quantified for three different chromosomes (13, 18 and 21). Parts 2 and 3 of the Figure illustrate the size distribution of the nucleic acid in the sample before and after digestion. The amplification reactions can be size-specific (e.g., greater than 100 base pair amplicons) such that they favor the longer, non-digested fetal nucleic acid over the digested maternal nucleic acid, thereby further enriching the fetal nucleic acid. The spectra at the bottom of the Figure show an increased amount of chromosome 21 fetal nucleic acid indicative of trisomy 21.

FIG. 12: Shows the total number of amplifiable genomic copies from four different DNA samples isolated from the blood of non-pregnant women. Each sample was diluted to contain approximately 2500, 1250, 625 or 313 copies per reaction. Each measurement was obtained by taking the mean DNA/competitor ratio obtained from two total copy number assays (ALB and RNAseP in Table X). As FIG. 12 shows, the total copy number is accurate and stable across the different samples, thus validating the usefulness of the competitor-based approach.

FIGS. 13A and B: A model system was created that contained a constant number of maternal non-methylated DNA with varying amounts of male placental methylated DNA spiked-in. The samples were spiked with male placental amounts ranging from approximately 0 to 25% relative to the maternal non-methylated DNA. The fraction of placental DNA was calculated using the ratios obtained from the methylation assays (FIG. 13A) and the Y-chromosome marker (FIG. 13B) as compared to the total copy number assay. The methylation and Y-chromosome markers are provided in Table X.

FIGS. 14 A and B: Show the results of the total copy number assay from plasma samples. In FIG. 14A, the copy number for each sample is shown. Two samples (no 25 and 26) have a significantly higher total copy number than all the other samples. A mean of approximately 1300 amplifiable copies/ml plasma was obtained (range 766-2055). FIG. 14B shows a box-and-whisker plot of the given values, summarizing the results.

FIGS. 15A and B: The amount (or copy numbers) of fetal nucleic acid from 33 different plasma samples taken from pregnant women with male fetuses are plotted. The copy numbers obtained were calculated using the methylation markers and the Y-chromosome-specific markers using the assays provided in Table X. As can be seen in FIG. 15B, the box-and-whisker plot of the given values indicated minimal difference between the two different measurements, thus validating the accuracy and stability of the method.

FIG. 16: Shows a paired correlation between the results obtained using the methylation markers versus the Y-chromosome marker from FIG. 15A.

FIG. 17: Shows the digestion efficiency of the restriction enzymes using the ratio of digestion for the control versus the competitor and comparing this value to the mean total copy number assays. Apart from sample 26 all reactions indicate the efficiency to be above about 99%.

FIG. 18: Provides a specific method for calculating fetal DNA fraction (or concentration) in a sample using the Y-chromosome-specific markers for male pregnancies and the mean of the methylated fraction for all pregnancies (regardless of fetal sex).

FIG. 19: Provides a specific method for calculating fetal DNA fraction (or concentration) in a sample without the Y-chromosome-specific markers. Instead, only the Assays for Methylation Quantification were used to determine the concentration of fetal DNA.

FIG. 20: Shows a power calculation t-test for a simulated trisomy 21 diagnosis using the methods of the invention. The Figure shows the relationship between the coefficient of variation (CV) on the x-axis and the power to discriminate the assay populations using a simple t-test (y-axis). The data indicates that in 99% of all cases, one can discriminate the two population (euploid vs. aneuploid) on a significance level of 0.001 provided a CV of 5% or less.

DEFINITIONS

The term “pregnancy-associated disorder,” as used in this application, refers to any condition or disease that may affect a pregnant woman, the fetus, or both the woman and the fetus. Such a condition or disease may manifest its symptoms during a limited time period, e.g., during pregnancy or delivery, or may last the entire life span of the fetus following its birth. Some examples of a pregnancy-associated disorder include ectopic pregnancy, preeclampsia, preterm labor, RhD incompatibility, fetal chromosomal abnormalities such as trisomy 21, and genetically inherited fetal disorders such as cystic fibrosis, beta-thalassemia or other monogenic disorders. The compositions and processes described herein are particularly useful for diagnosis, prognosis and monitoring of pregnancy-associated disorders associated with quantitative abnormalities of fetal DNA in maternal plasma/serum, including but not limited to, preeclampsia (Lo et al., Clin. Chem. 45:184-188, 1999 and Zhong et al., Am. J. Obstet. Gynecol. 184:414-419, 2001), fetal trisomy (Lo et al., Clin. Chem. 45:1747-1751, 1999 and Zhong et al., Prenat. Diagn. 20:795-798, 2000) and hyperemesis gravidarum (Sekizawa et al., Clin. Chem. 47:2164-2165, 2001). For example, an elevated level of fetal nucleic acid in maternal blood (as compared to a normal pregnancy or pregnancies) may be indicative of a preeclamptic preganancy. Further, the ability to enrich fetal nucleic from a maternal sample may prove particularly useful for the noninvasive prenatal diagnosis of autosomal recessive diseases such as the case when a mother and father share an identical disease causing mutation, an occurrence previously perceived as a challenge for maternal plasma-based non-trisomy prenatal diagnosis.

The term “chromosomal abnormality” or “aneuploidy” as used herein refers to a deviation between the structure of the subject chromosome and a normal homologous chromosome. The term “normal” refers to the predominate karyotype or banding pattern found in healthy individuals of a particular species, for example, a euploid genome (in humans, 46XX or 46XY). A chromosomal abnormality can be numerical or structural, and includes but is not limited to aneuploidy, polyploidy, inversion, a trisomy, a monosomy, duplication, deletion, deletion of a part of a chromosome, addition, addition of a part of chromosome, insertion, a fragment of a chromosome, a region of a chromosome, chromosomal rearrangement, and translocation. Chromosomal abnormality may also refer to a state of chromosomal abnormality where a portion of one or more chromosomes is not an exact multiple of the usual haploid number due to, for example, chromosome translocation. Chromosomal translocation (e.g. translocation between chromosome 21 and 14 where some of the 14th chromosome is replaced by extra 21st chromosome) may cause partial trisomy 21. A chromosomal abnormality can be correlated with presence of a pathological condition or with a predisposition to develop a pathological condition. A chromosomal abnormality may be detected by quantitative analysis of nucleic acid.

The terms “nucleic acid” and “nucleic acid molecule” may be used interchangeably throughout the disclosure. The terms refer to nucleic acids of any composition from, such as DNA (e.g., complementary DNA (cDNA), genomic DNA (gDNA) and the like), RNA (e.g., message RNA (mRNA), short inhibitory RNA (siRNA), ribosomal RNA (rRNA), tRNA, microRNA, RNA highly expressed by the fetus or placenta, and the like), and/or DNA or RNA analogs (e.g., containing base analogs, sugar analogs and/or a non-native backbone and the like), RNA/DNA hybrids and polyamide nucleic acids (PNAs), all of which can be in single- or double-stranded form, and unless otherwise limited, can encompass known analogs of natural nucleotides that can function in a similar manner as naturally occurring nucleotides. For example, the nucleic acids provided in SEQ ID NOs: 1-261 (see Tables 4A-4C) can be in any form useful for conducting processes herein (e.g., linear, circular, supercoiled, single-stranded, double-stranded and the like) or may include variations (e.g., insertions, deletions or substitutions) that do not alter their utility as part of the present invention. A nucleic acid may be, or may be from, a plasmid, phage, autonomously replicating sequence (ARS), centromere, artificial chromosome, chromosome, or other nucleic acid able to replicate or be replicated in vitro or in a host cell, a cell, a cell nucleus or cytoplasm of a cell in certain embodiments. A template nucleic acid in some embodiments can be from a single chromosome (e.g., a nucleic acid sample may be from one chromosome of a sample obtained from a diploid organism). Unless specifically limited, the term encompasses nucleic acids containing known analogs of natural nucleotides that have similar binding properties as the reference nucleic acid and are metabolized in a manner similar to naturally occurring nucleotides. Unless otherwise indicated, a particular nucleic acid sequence also implicitly encompasses conservatively modified variants thereof (e.g., degenerate codon substitutions), alleles, orthologs, single nucleotide polymorphisms (SNPs), and complementary sequences as well as the sequence explicitly indicated. Specifically, degenerate codon substitutions may be achieved by generating sequences in which the third position of one or more selected (or all) codons is substituted with mixed-base and/or deoxyinosine residues (Batzer et al., Nucleic Acid Res. 19:5081 (1991); Ohtsuka et al., J. Biol. Chem. 260:2605-2608 (1985); and Rossolini et al., Mol. Cell. Probes 8:91-98 (1994)). The term nucleic acid is used interchangeably with locus, gene, cDNA, and mRNA encoded by a gene. The term also may include, as equivalents, derivatives, variants and analogs of RNA or DNA synthesized from nucleotide analogs, single-stranded (“sense” or “antisense”, “plus” strand or “minus” strand, “forward” reading frame or “reverse” reading frame) and double-stranded polynucleotides. Deoxyribonucleotides include deoxyadenosine, deoxycytidine, deoxyguanosine and deoxythymidine. For RNA, the base cytosine is replaced with uracil. A template nucleic acid may be prepared using a nucleic acid obtained from a subject as a template.

A “nucleic acid comprising one or more CpG sites” or a “CpG-containing genomic sequence” as used herein refers to a segment of DNA sequence at a defined location in the genome of an individual such as a human fetus or a pregnant woman. Typically, a “CpG-containing genomic sequence” is at least 15 nucleotides in length and contains at least one cytosine. Preferably, it can be at least 30, 50, 80, 100, 150, 200, 250, or 300 nucleotides in length and contains at least 2, 5, 10, 15, 20, 25, or 30 cytosines. For anyone “CpG-containing genomic sequence” at a given location, e.g., within a region centering around a given genetic locus (see Tables 1A-1C), nucleotide sequence variations may exist from individual to individual and from allele to allele even for the same individual. Typically, such a region centering around a defined genetic locus (e.g., a CpG island) contains the locus as well as upstream and/or downstream sequences. Each of the upstream or downstream sequence (counting from the 5′ or 3′ boundary of the genetic locus, respectively) can be as long as 10 kb, in other cases may be as long as 5 kb, 2 kb, 1 kb, 500 bp, 200 bp, or 100 bp. Furthermore, a “CpG-containing genomic sequence” may encompass a nucleotide sequence transcribed or not transcribed for protein production, and the nucleotide sequence can be an inter-gene sequence, intra-gene sequence, protein-coding sequence, a non protein-coding sequence (such as a transcription promoter), or a combination thereof.

As used herein, a “methylated nucleotide” or a “methylated nucleotide base” refers to the presence of a methyl moiety on a nucleotide base, where the methyl moiety is not present in a recognized typical nucleotide base. For example, cytosine does not contain a methyl moiety on its pyrimidine ring, but 5-methylcytosine contains a methyl moiety at position 5 of its pyrimidine ring. Therefore, cytosine is not a methylated nucleotide and 5-methylcytosine is a methylated nucleotide. In another example, thymine contains a methyl moiety at position 5 of its pyrimidine ring, however, for purposes herein, thymine is not considered a methylated nucleotide when present in DNA since thymine is a typical nucleotide base of DNA. Typical nucleoside bases for DNA are thymine, adenine, cytosine and guanine. Typical bases for RNA are uracil, adenine, cytosine and guanine. Correspondingly a “methylation site” is the location in the target gene nucleic acid region where methylation has, or has the possibility of occurring. For example a location containing CpG is a methylation site wherein the cytosine may or may not be methylated.

As used herein, a “CpG site” or “methylation site” is a nucleotide within a nucleic acid that is susceptible to methylation either by natural occurring events in vivo or by an event instituted to chemically methylate the nucleotide in vitro.

As used herein, a “methylated nucleic acid molecule” refers to a nucleic acid molecule that contains one or more methylated nucleotides that is/are methylated.

A “CpG island” as used herein describes a segment of DNA sequence that comprises a functionally or structurally deviated CpG density. For example, Yamada et al. (Genome Research 14:247-266, 2004) have described a set of standards for determining a CpG island: it must be at least 400 nucleotides in length, has a greater than 50% GC content, and an OCF/ECF ratio greater than 0.6. Others (Takai et al., Proc. Natl. Acad. Sci. U.S.A. 99:3740-3745, 2002) have defined a CpG island less stringently as a sequence at least 200 nucleotides in length, having a greater than 50% GC content, and an OCF/ECF ratio greater than 0.6.

The term “epigenetic state” or “epigenetic status” as used herein refers to any structural feature at a molecular level of a nucleic acid (e.g., DNA or RNA) other than the primary nucleotide sequence. For instance, the epigenetic state of a genomic DNA may include its secondary or tertiary structure determined or influenced by, e.g., its methylation pattern or its association with cellular proteins.

The term “methylation profile” “methylation state” or “methylation status,” as used herein to describe the state of methylation of a genomic sequence, refers to the characteristics of a DNA segment at a particular genomic locus relevant to methylation. Such characteristics include, but are not limited to, whether any of the cytosine (C) residues within this DNA sequence are methylated, location of methylated C residue(s), percentage of methylated C at any particular stretch of residues, and allelic differences in methylation due to, e.g., difference in the origin of the alleles. The term “methylation” profile” or “methylation status” also refers to the relative or absolute concentration of methylated C or unmethylated C at any particular stretch of residues in a biological sample. For example, if the cytosine (C) residue(s) within a DNA sequence are methylated it may be referred to as “hypermethylated”; whereas if the cytosine (C) residue(s) within a DNA sequence are not methylated it may be referred to as “hypomethylated”. Likewise, if the cytosine (C) residue(s) within a DNA sequence (e.g., fetal nucleic acid) are methylated as compared to another sequence from a different region or from a different individual (e.g., relative to maternal nucleic acid), that sequence is considered hypermethylated compared to the other sequence. Alternatively, if the cytosine (C) residue(s) within a DNA sequence are not methylated as compared to another sequence from a different region or from a different individual (e.g., the mother), that sequence is considered hypomethylated compared to the other sequence. These sequences are said to be “differentially methylated”, and more specifically, when the methylation status differs between mother and fetus, the sequences are considered “differentially methylated maternal and fetal nucleic acid”.

The term “agent that binds to methylated nucleotides” as used herein refers to a substance that is capable of binding to methylated nucleic acid. The agent may be naturally-occurring or synthetic, and may be modified or unmodified. In one embodiment, the agent allows for the separation of different nucleic acid species according to their respective methylation states. An example of an agent that binds to methylated nucleotides is described in PCT Patent Application No. PCT/EP2005/012707, which published as WO06056480A2 and is hereby incorporated by reference. The described agent is a bifunctional polypeptide comprising the DNA-binding domain of a protein belonging to the family of Methyl-CpG binding proteins (MBDs) and an Fc portion of an antibody (see FIG. 1). The recombinant methyl-CpG-binding, antibody-like protein can preferably bind CpG methylated DNA in an antibody-like manner. That means, the methyl-CpG-binding, antibody-like protein has a high affinity and high avidity to its “antigen”, which is preferably DNA that is methylated at CpG dinucleotides. The agent may also be a multivalent MBD (see FIG. 2).

The term “polymorphism” as used herein refers to a sequence variation within different alleles of the same genomic sequence. A sequence that contains a polymorphism is considered “polymorphic sequence”. Detection of one or more polymorphisms allows differentiation of different alleles of a single genomic sequence or between two or more individuals. As used herein, the term “polymorphic marker” or “polymorphic sequence” refers to segments of genomic DNA that exhibit heritable variation in a DNA sequence between individuals. Such markers include, but are not limited to, single nucleotide polymorphisms (SNPs), restriction fragment length polymorphisms (RFLPs), short tandem repeats, such as di-, tri- or tetra-nucleotide repeats (STRs), and the like. Polymorphic markers according to the present invention can be used to specifically differentiate between a maternal and paternal allele in the enriched fetal nucleic acid sample.

The terms “single nucleotide polymorphism” or “SNP” as used herein refer to the polynucleotide sequence variation present at a single nucleotide residue within different alleles of the same genomic sequence. This variation may occur within the coding region or non-coding region (i.e., in the promoter or intronic region) of a genomic sequence, if the genomic sequence is transcribed during protein production. Detection of one or more SNP allows differentiation of different alleles of a single genomic sequence or between two or more individuals.

The term “allele” as used herein is one of several alternate forms of a gene or non-coding regions of DNA that occupy the same position on a chromosome. The term allele can be used to describe DNA from any organism including but not limited to bacteria, viruses, fungi, protozoa, molds, yeasts, plants, humans, non-humans, animals, and archeabacteria.

The terms “ratio of the alleles” or “allelic ratio” as used herein refer to the ratio of the population of one allele and the population of the other allele in a sample. In some trisomic cases, it is possible that a fetus may be tri-allelic for a particular locus. In such cases, the term “ratio of the alleles” refers to the ratio of the population of any one allele against one of the other alleles, or any one allele against the other two alleles.

The term “non-polymorphism-based quantitative method” as used herein refers to a method for determining the amount of an analyte (e.g., total nucleic acid, Y-chromosome nucleic acid, or fetal nucleic acid) that does not require the use of a polymorphic marker or sequence. Although a polymorphism may be present in the sequence, said polymorphism is not required to quantify the sequence. Examples of non-polymorphism-based quantitative methods include, but are not limited to, RT-PCR, digital PCR, array-based methods, sequencing methods, nanopore-based methods, nucleic acid-bound bead-based counting methods and competitor-based methods wherein one or more competitors are introduced at a known concentration(s) to determine the amount of one or more analytes. In some embodiments, some of the above exemplary methods (for example, sequencing) may need to be actively modified or designed such that one or more polymorphisms are not interrogated.

The terms “absolute amount” or “copy number” as used herein refers to the amount or quantity of an analyte (e.g., total nucleic acid or fetal nucleic acid). The present invention provides compositions and processes for determining the absolute amount of fetal nucleic acid in a mixed maternal sample. Absolute amount or copy number represents the number of molecules available for detection, and may be expressed as the genomic equivalents per unit. The term “concentration” refers to the amount or proportion of a substance in a mixture or solution (e.g., the amount of fetal nucleic acid in a maternal sample that comprises a mixture of maternal and fetal nucleic acid). The concentration may be expressed as a percentage, which is used to express how large/small one quantity is, relative to another quantity as a fraction of 100. Platforms for determining the quantity or amount of an analyte (e.g., target nucleic acid) include, but are not limited to, mass spectrometery, digital PCR, sequencing by synthesis platforms (e.g., pyrosequencing), fluorescence spectroscopy and flow cytometry.

The term “sample” as used herein refers to a specimen containing nucleic acid. Examples of samples include, but are not limited to, tissue, bodily fluid (for example, blood, serum, plasma, saliva, urine, tears, peritoneal fluid, ascitic fluid, vaginal secretion, breast fluid, breast milk, lymph fluid, cerebrospinal fluid or mucosa secretion), umbilical cord blood, chorionic villi, amniotic fluid, an embryo, a two-celled embryo, a four-celled embryo, an eight-celled embryo, a 16-celled embryo, a 32-celled embryo, a 64-celled embryo, a 128-celled embryo, a 256-celled embryo, a 512-celled embryo, a 1024-celled embryo, embryonic tissues, lymph fluid, cerebrospinal fluid, mucosa secretion, or other body exudate, fecal matter, an individual cell or extract of the such sources that contain the nucleic acid of the same, and subcellular structures such as mitochondria, using protocols well established within the art.

Fetal DNA can be obtained from sources including but not limited to maternal blood, maternal serum, maternal plasma, fetal cells, umbilical cord blood, chorionic villi, amniotic fluid, urine, saliva, lung lavage, cells or tissues.

The term “blood” as used herein refers to a blood sample or preparation from a pregnant woman or a woman being tested for possible pregnancy. The term encompasses whole blood or any fractions of blood, such as serum and plasma as conventionally defined.

The term “bisulfite” as used herein encompasses all types of bisulfites, such as sodium bisulfite, that are capable of chemically converting a cytosine (C) to a uracil (U) without chemically modifying a methylated cytosine and therefore can be used to differentially modify a DNA sequence based on the methylation status of the DNA.

As used herein, a reagent that “differentially modifies” methylated or non-methylated DNA encompasses any reagent that modifies methylated and/or unmethylated DNA in a process through which distinguishable products result from methylated and non-methylated DNA, thereby allowing the identification of the DNA methylation status. Such processes may include, but are not limited to, chemical reactions (such as a C.fwdarw.U conversion by bisulfite) and enzymatic treatment (such as cleavage by a methylation-dependent endonuclease). Thus, an enzyme that preferentially cleaves or digests methylated DNA is one capable of cleaving or digesting a DNA molecule at a much higher efficiency when the DNA is methylated, whereas an enzyme that preferentially cleaves or digests unmethylated DNA exhibits a significantly higher efficiency when the DNA is not methylated.

The terms “non-bisulfite-based method” and “non-bisulfite-based quantitative method” as used herein refer to any method for quantifying methylated or non-methylated nucleic acid that does not require the use of bisulfite. The terms also refer to methods for preparing a nucleic acid to be quantified that do not require bisulfite treatment. Examples of non-bisulfite-based methods include, but are not limited to, methods for digesting nucleic acid using one or more methylation sensitive enzymes and methods for separating nucleic acid using agents that bind nucleic acid based on methylation status.

The terms “methyl-sensitive enzymes” and “methylation sensitive restriction enzymes” are DNA restriction endonucleases that are dependent on the methylation state of their DNA recognition site for activity. For example, there are methyl-sensitive enzymes that cleave or digest at their DNA recognition sequence only if it is not methylated. Thus, an unmethylated DNA sample will be cut into smaller fragments than a methylated DNA sample. Similarly, a hypermethylated DNA sample will not be cleaved. In contrast, there are methyl-sensitive enzymes that cleave at their DNA recognition sequence only if it is methylated. As used herein, the terms “cleave”, “cut” and “digest” are used interchangeably.

The term “target nucleic acid” as used herein refers to a nucleic acid examined using the methods disclosed herein to determine if the nucleic acid is part of a pregnancy-related disorder or chromosomal abnormality. For example, a target nucleic acid from chromosome 21 could be examined using the methods of the invention to detect Down's Syndrome.

The term “control nucleic acid” as used herein refers to a nucleic acid used as a reference nucleic acid according to the methods disclosed herein to determine if the nucleic acid is part of a chromosomal abnormality. For example, a control nucleic acid from a chromosome other than chromosome 21 (herein referred to as a “reference chromosome”) could be as a reference sequence to detect Down's Syndrome. In some embodiments, the control sequence has a known or predetermined quantity.

The term “sequence-specific” or “locus-specific method” as used herein refers to a method that interrogates (for example, quantifies) nucleic acid at a specific location (or locus) in the genome based on the sequence composition. Sequence-specific or locus-specific methods allow for the quantification of specific regions or chromosomes.

The term “gene” means the segment of DNA involved in producing a polypeptide chain; it includes regions preceding and following the coding region (leader and trailer) involved in the transcription/translation of the gene product and the regulation of the transcription/translation, as well as intervening sequences (introns) between individual coding segments (exons).

In this application, the terms “polypeptide,” “peptide,” and “protein” are used interchangeably herein to refer to a polymer of amino acid residues. The terms apply to amino acid polymers in which one or more amino acid residue is an artificial chemical mimetic of a corresponding naturally occurring amino acid, as well as to naturally occurring amino acid polymers and non-naturally occurring amino acid polymers. As used herein, the terms encompass amino acid chains of any length, including full-length proteins (i.e., antigens), wherein the amino acid residues are linked by covalent peptide bonds.

The term “amino acid” refers to naturally occurring and synthetic amino acids, as well as amino acid analogs and amino acid mimetics that function in a manner similar to the naturally occurring amino acids. Naturally occurring amino acids are those encoded by the genetic code, as well as those amino acids that are later modified, e.g., hydroxyproline, .gamma.-carboxyglutamate, and O-phosphoserine.

Amino acids may be referred to herein by either the commonly known three letter symbols or by the one-letter symbols recommended by the IUPAC-IUB Biochemical Nomenclature Commission. Nucleotides, likewise, may be referred to by their commonly accepted single-letter codes.

“Primers” as used herein refer to oligonucleotides that can be used in an amplification method, such as a polymerase chain reaction (PCR), to amplify a nucleotide sequence based on the polynucleotide sequence corresponding to a particular genomic sequence, e.g., one located within the CpG island CG1137, PDE9A, or CGI009 on chromosome 21, in various methylation status. At least one of the PCR primers for amplification of a polynucleotide sequence is sequence-specific for the sequence. The term “template” refers to any nucleic acid molecule that can be used for amplification in the invention. RNA or DNA that is not naturally double stranded can be made into double stranded DNA so as to be used as template DNA. Any double stranded DNA or preparation containing multiple, different double stranded DNA molecules can be used as template DNA to amplify a locus or loci of interest contained in the template DNA.

The term “amplification reaction” as used herein refers to a process for copying nucleic acid one or more times. In embodiments, the method of amplification includes but is not limited to polymerase chain reaction, self-sustained sequence reaction, ligase chain reaction, rapid amplification of cDNA ends, polymerase chain reaction and ligase chain reaction, Q-beta phage amplification, strand displacement amplification, or splice overlap extension polymerase chain reaction. In some embodiments, a single molecule of nucleic acid is amplified, for example, by digital PCR.

The term “sensitivity” as used herein refers to the number of true positives divided by the number of true positives plus the number of false negatives, where sensitivity (sens) may be within the range of 0≦sens≦1. Ideally, method embodiments herein have the number of false negatives equaling zero or close to equaling zero, so that no subject is wrongly identified as not having at least one chromosome abnormality or other genetic disorder when they indeed have at least one chromosome abnormality or other genetic disorder. Conversely, an assessment often is made of the ability of a prediction algorithm to classify negatives correctly, a complementary measurement to sensitivity. The term “specificity” as used herein refers to the number of true negatives divided by the number of true negatives plus the number of false positives, where sensitivity (spec) may be within the range of 0≦spec≦1. Ideally, methods embodiments herein have the number of false positives equaling zero or close to equaling zero, so that no subject wrongly identified as having at least one chromosome abnormality other genetic disorder when they do not have the chromosome abnormality other genetic disorder being assessed. Hence, a method that has sensitivity and specificity equaling one, or 100%, sometimes is selected.

One or more prediction algorithms may be used to determine significance or give meaning to the detection data collected under variable conditions that may be weighed independently of or dependently on each other. The term “variable” as used herein refers to a factor, quantity, or function of an algorithm that has a value or set of values. For example, a variable may be the design of a set of amplified nucleic acid species, the number of sets of amplified nucleic acid species, percent fetal genetic contribution tested, percent maternal genetic contribution tested, type of chromosome abnormality assayed, type of genetic disorder assayed, type of sex-linked abnormalities assayed, the age of the mother and the like. The term “independent” as used herein refers to not being influenced or not being controlled by another. The term “dependent” as used herein refers to being influenced or controlled by another. For example, a particular chromosome and a trisomy event occurring for that particular chromosome that results in a viable being are variables that are dependent upon each other.

One of skill in the art may use any type of method or prediction algorithm to give significance to the data of the present invention within an acceptable sensitivity and/or specificity. For example, prediction algorithms such as Chi-squared test, z-test, t-test, ANOVA (analysis of variance), regression analysis, neural nets, fuzzy logic, Hidden Markov Models, multiple model state estimation, and the like may be used. One or more methods or prediction algorithms may be determined to give significance to the data having different independent and/or dependent variables of the present invention. And one or more methods or prediction algorithms may be determined not to give significance to the data having different independent and/or dependent variables of the present invention. One may design or change parameters of the different variables of methods described herein based on results of one or more prediction algorithms (e.g., number of sets analyzed, types of nucleotide species in each set). For example, applying the Chi-squared test to detection data may suggest that specific ranges of maternal age are correlated to a higher likelihood of having an offspring with a specific chromosome abnormality, hence the variable of maternal age may be weighed differently verses being weighed the same as other variables.

In certain embodiments, several algorithms may be chosen to be tested. These algorithms can be trained with raw data. For each new raw data sample, the trained algorithms will assign a classification to that sample (i.e. trisomy or normal). Based on the classifications of the new raw data samples, the trained algorithms' performance may be assessed based on sensitivity and specificity. Finally, an algorithm with the highest sensitivity and/or specificity or combination thereof may be identified.

DETAILED DESCRIPTION
Introduction

The presence of fetal nucleic acid in maternal plasma was first reported in 1997 and offers the possibility for non-invasive prenatal diagnosis simply through the analysis of a maternal blood sample (Lo et al., Lancet 350:485-487, 1997). To date, numerous potential clinical applications have been developed. In particular, quantitative abnormalities of fetal nucleic acid, for example DNA, concentrations in maternal plasma have been found to be associated with a number of pregnancy-associated disorders, including preeclampsia, preterm labor, antepartum hemorrhage, invasive placentation, fetal Down syndrome, and other fetal chromosomal aneuploidies. Hence, fetal nucleic acid analysis in maternal plasma represents a powerful mechanism for the monitoring of fetomaternal well-being.

However, fetal DNA co-exists with background maternal DNA in maternal plasma. Hence, most reported applications have relied on the detection of Y-chromosome sequences as these are most conveniently distinguishable from maternal DNA. Such an approach limits the applicability of the existing assays to only 50% of all pregnancies, namely those with male fetuses. Thus, there is much need for the development of sex-independent compositions and methods for enriching and analyzing fetal nucleic acid from a maternal sample. Also, methods that rely on polymorphic markers to quantify fetal nucleic acid may be susceptible to varying heterozygosity rates across different ethnicities thereby limiting their applicability (e.g., by increasing the number of markers that are needed).

It was previously demonstrated that fetal and maternal DNA can be distinguished by their differences in methylation status (U.S. Pat. No. 6,927,028, which is hereby incorporated by reference). Methylation is an epigenetic phenomenon, which refers to processes that alter a phenotype without involving changes in the DNA sequence. By exploiting the difference in the DNA methylation status between mother and fetus, one can successfully detect and analyze fetal nucleic acid in a background of maternal nucleic acid.

The present inventors provides novel genomic polynucleotides that are differentially methylated between the fetal DNA from the fetus (e.g., from the placenta) and the maternal DNA from the mother, for example from peripheral blood cells. This discovery thus provides a new approach for distinguishing fetal and maternal genomic DNA and new methods for accurately quantifying fetal nucleic which may be used for non-invasive prenatal diagnosis.

Methodology

Practicing the invention utilizes routine techniques in the field of molecular biology. Basic texts disclosing the general methods of use in the invention include Sambrook and Russell, Molecular Cloning, A Laboratory Manual (3rd ed. 2001); Kriegler, Gene Transfer and Expression: A Laboratory Manual (1990); and Current Protocols in Molecular Biology (Ausubel et al., eds., 1994)).

For nucleic acids, sizes are given in either kilobases (kb) or base pairs (bp). These are estimates derived from agarose or acrylamide gel electrophoresis, from sequenced nucleic acids, or from published DNA sequences. For proteins, sizes are given in kilodaltons (kDa) or amino acid residue numbers. Protein sizes are estimated from gel electrophoresis, from sequenced proteins, from derived amino acid sequences, or from published protein sequences.

Oligonucleotides that are not commercially available can be chemically synthesized, e.g., according to the solid phase phosphoramidite triester method first described by Beaucage & Caruthers, Tetrahedron Lett. 22: 1859-1862 (1981), using an automated synthesizer, as described in Van Devanter et. al., Nucleic Acids Res. 12: 6159-6168 (1984). Purification of oligonucleotides is performed using any art-recognized strategy, e.g., native acrylamide gel electrophoresis or anion-exchange high performance liquid chromatography (HPLC) as described in Pearson & Reanier, J. Chrom. 255: 137-149 (1983).

Acquisition of Blood Samples and Extraction of DNA

The present invention relates to separating, enriching and analyzing fetal DNA found in maternal blood as a non-invasive means to detect the presence and/or to monitor the progress of a pregnancy-associated condition or disorder. Thus, the first steps of practicing the invention are to obtain a blood sample from a pregnant woman and extract DNA from the sample.

A. Acquisition of Blood Samples

A blood sample is obtained from a pregnant woman at a gestational age suitable for testing using a method of the present invention. The suitable gestational age may vary depending on the disorder tested, as discussed below. Collection of blood from a woman is performed in accordance with the standard protocol hospitals or clinics generally follow. An appropriate amount of peripheral blood, e.g., typically between 5-50 ml, is collected and may be stored according to standard procedure prior to further preparation. Blood samples may be collected, stored or transported in a manner known to the person of ordinary skill in the art to minimize degradation or the quality of nucleic acid present in the sample.

B. Preparation of Blood Samples

The analysis of fetal DNA found in maternal blood according to the present invention may be performed using, e.g., the whole blood, serum, or plasma. The methods for preparing serum or plasma from maternal blood are well known among those of skill in the art. For example, a pregnant woman's blood can be placed in a tube containing EDTA or a specialized commercial product such as Vacutainer SST (Becton Dickinson, Franklin Lakes, N.J.) to prevent blood clotting, and plasma can then be obtained from whole blood through centrifugation. On the other hand, serum may be obtained with or without centrifugation-following blood clotting. If centrifugation is used then it is typically, though not exclusively, conducted at an appropriate speed, e.g., 1,500-3,000 times g. Plasma or serum may be subjected to additional centrifugation steps before being transferred to a fresh tube for DNA extraction.

In addition to the acellular portion of the whole blood, DNA may also be recovered from the cellular fraction, enriched in the buffy coat portion, which can be obtained following centrifugation of a whole blood sample from the woman and removal of the plasma.

C. Extraction of DNA

There are numerous known methods for extracting DNA from a biological sample including blood. The general methods of DNA preparation (e.g., described by Sambrook and Russell, Molecular Cloning: A Laboratory Manual 3d ed., 2001) can be followed; various commercially available reagents or kits, such as Qiagen's QIAamp Circulating Nucleic Acid Kit, QiaAmp DNA Mini Kit or QiaAmp DNA Blood Mini Kit (Qiagen, Hilden, Germany), GenomicPrep™ Blood DNA Isolation Kit (Promega, Madison, Wis.), and GFX™ Genomic Blood DNA Purification Kit (Amersham, Piscataway, N.J.), may also be used to obtain DNA from a blood sample from a pregnant woman. Combinations of more than one of these methods may also be used.

In some embodiments, the sample may first be enriched or relatively enriched for fetal nucleic acid by one or more methods. For example, the discrimination of fetal and maternal DNA can be performed using the compositions and processes of the present invention alone or in combination with other discriminating factors. Examples of these factors include, but are not limited to, single nucleotide differences between chromosome X and Y, chromosome Y-specific sequences, polymorphisms located elsewhere in the genome, size differences between fetal and maternal DNA and differences in methylation pattern between maternal and fetal tissues.

Other methods for enriching a sample for a particular species of nucleic acid are described in PCT Patent Application Number PCT/US07/69991, filed May 30, 2007, PCT Patent Application Number PCT/US2007/071232, filed Jun. 15, 2007, U.S. Provisional Application Nos. 60/968,876 and 60/968,878 (assigned to the Applicant), (PCT Patent Application Number PCT/EP05/012707, filed Nov. 28, 2005) which are all hereby incorporated by reference. In certain embodiments, maternal nucleic acid is selectively removed (either partially, substantially, almost completely or completely) from the sample.

Methylation Specific Separation of Nucleic Acid

The methods provided herein offer an alternative approach for the enrichment of fetal DNA based on the methylation-specific separation of differentially methylated DNA. It has recently been discovered that many genes involved in developmental regulation are controlled through epigenetics in embryonic stem cells. Consequently, multiple genes can be expected to show differential DNA methylation between nucleic acid of fetal origin and maternal origin. Once these regions are identified, a technique to capture methylated DNA can be used to specifically enrich fetal DNA. For identification of differentially methylated regions, a novel approach was used to capture methylated DNA. This approach uses a protein, in which the methyl binding domain of MBD2 is fused to the Fc fragment of an antibody (MBD-FC) (Gebhard C, Schwarzfischer L, Pham T H, Schilling E, Klug M, Andreesen R, Rehli M (2006) Genomewide profiling of CpG methylation identifies novel targets of aberrant hypermethylation in myeloid leukemia. Cancer Res 66:6118-6128). This fusion protein has several advantages over conventional methylation specific antibodies. The MBD-FC has a higher affinity to methylated DNA and it binds double stranded DNA. Most importantly the two proteins differ in the way they bind DNA. Methylation specific antibodies bind DNA stochastically, which means that only a binary answer can be obtained. The methyl binding domain of MBD-FC on the other hand binds all DNA molecules regardless of their methylation status. The strength of this protein—DNA interaction is defined by the level of DNA methylation. After binding genomic DNA, eluate solutions of increasing salt concentrations can be used to fractionate non-methylated and methylated DNA allowing for a more controlled separation (Gebhard C, Schwarzfischer L, Pham T H, Andreesen R, Mackensen A, Rehli M (2006) Rapid and sensitive detection of CpG-methylation using methyl-binding (MB)-PCR. Nucleic Acids Res 34:e82). Consequently this method, called Methyl-CpG immunoprecipitation (MCIP), cannot only enrich, but also fractionate genomic DNA according to methylation level, which is particularly helpful when the unmethylated DNA fraction should be investigated as well.

Methylation Sensitive Restriction Enzyme Digestion

The invention also provides compositions and processes for determining the amount of fetal nucleic acid from a maternal sample. The invention allows for the enrichment of fetal nucleic acid regions in a maternal sample by selectively digesting nucleic acid from said maternal sample with an enzyme that selectively and completely or substantially digests the maternal nucleic acid to enrich the sample for at least one fetal nucleic acid region. Preferably, the digestion efficiency is greater than about 75%, 76%, 77%, 78%, 79%, 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, or 99%. Following enrichment, the amount of fetal nucleic acid can be determined by quantitative methods that do not require polymorphic sequences or bisulfite treatment, thereby, offering a solution that works equally well for female fetuses and across different ethnicities and preserves the low copy number fetal nucleic acid present in the sample.

For example, there are methyl-sensitive enzymes that preferentially or substantially cleave or digest at their DNA recognition sequence if it is non-methylated. Thus, an unmethylated DNA sample will be cut into smaller fragments than a methylated DNA sample. Similarly, a hypermethylated DNA sample will not be cleaved. In contrast, there are methyl-sensitive enzymes that cleave at their DNA recognition sequence only if it is methylated.

Methyl-sensitive enzymes that digest unmethylated DNA suitable for use in methods of the invention include, but are not limited to, HpaII, HhaI, MaeII, BstUI and AciI. An enzyme that can be used is HpaII that cuts only the unmethylated sequence CCGG. Another enzyme that can be used is HhaI that cuts only the unmethylated sequence GCGC. Both enzymes are available from New England BioLabs®, Inc. Combinations of two or more methyl-sensitive enzymes that digest only unmethylated DNA can also be used. Suitable enzymes that digest only methylated DNA include, but are not limited to, DpnI, which cuts at a recognition sequence GATC, and McrBC, which belongs to the family of AAA.sup.+ proteins and cuts DNA containing modified cytosines and cuts at recognition site 5′ . . . Pu.sup.mC(N.sub.40-3000) Pu.sup.mC . . . 3′ (New England BioLabs, Inc., Beverly, Mass.).

Cleavage methods and procedures for selected restriction enzymes for cutting DNA at specific sites are well known to the skilled artisan. For example, many suppliers of restriction enzymes provide information on conditions and types of DNA sequences cut by specific restriction enzymes, including New England BioLabs, Pro-Mega Biochems, Boehringer-Mannheim, and the like. Sambrook et al. (See Sambrook et al., Molecular Biology: A laboratory Approach, Cold Spring Harbor, N.Y. 1989) provide a general description of methods for using restriction enzymes and other enzymes. Enzymes often are used under conditions that will enable cleavage of the maternal DNA with about 95%-100% efficiency, preferably with about 98%-100% efficiency.

Other Methods for Methylation Analysis

Various methylation analysis procedures are known in the art, and can be used in conjunction with the present invention. These assays allow for determination of the methylation state of one or a plurality of CpG islands within a DNA sequence. In addition, the methods maybe used to quantify methylated nucleic acid. Such assays involve, among other techniques, DNA sequencing of bisulfite-treated DNA, PCR (for sequence-specific amplification), Southern blot analysis, and use of methylation-sensitive restriction enzymes.

Genomic sequencing is a technique that has been simplified for analysis of DNA methylation patterns and 5-methylcytosine distribution by using bisulfite treatment (Frommer et al., Proc. Natl. Acad. Sci. USA 89:1827-1831, 1992). Additionally, restriction enzyme digestion of PCR products amplified from bisulfite-converted DNA may be used, e.g., the method described by Sadri & Hornsby (Nucl. Acids Res. 24:5058-5059, 1996), or COBRA (Combined Bisulfite Restriction Analysis) (Xiong & Laird, Nucleic Acids Res. 25:2532-2534, 1997).

COBRA analysis is a quantitative methylation assay useful for determining DNA methylation levels at specific gene loci in small amounts of genomic DNA (Xiong & Laird, Nucleic Acids Res. 25:2532-2534, 1997). Briefly, restriction enzyme digestion is used to reveal methylation-dependent sequence differences in PCR products of sodium bisulfite-treated DNA. Methylation-dependent sequence differences are first introduced into the genomic DNA by standard bisulfite treatment according to the procedure described by Frommer et al. (Proc. Natl. Acad. Sci. USA 89:1827-1831, 1992). PCR amplification of the bisulfite converted DNA is then performed using primers specific for the interested CpG islands, followed by restriction endonuclease digestion, gel electrophoresis, and detection using specific, labeled hybridization probes. Methylation levels in the original DNA sample are represented by the relative amounts of digested and undigested PCR product in a linearly quantitative fashion across a wide spectrum of DNA methylation levels. In addition, this technique can be reliably applied to DNA obtained from microdissected paraffin-embedded tissue samples. Typical reagents (e.g., as might be found in a typical COBRA-based kit) for COBRA analysis may include, but are not limited to: PCR primers for specific gene (or methylation-altered DNA sequence or CpG island); restriction enzyme and appropriate buffer; gene-hybridization oligo; control hybridization oligo; kinase labeling kit for oligo probe; and radioactive nucleotides. Additionally, bisulfite conversion reagents may include: DNA denaturation buffer; sulfonation buffer; DNA recovery reagents or kits (e.g., precipitation, ultrafiltration, affinity column); desulfonation buffer; and DNA recovery components.

The MethyLight™ assay is a high-throughput quantitative methylation assay that utilizes fluorescence-based real-time PCR (TaqMan™) technology that requires no further manipulations after the PCR step (Eads et al., Cancer Res. 59:2302-2306, 1999). Briefly, the MethyLight™ process begins with a mixed sample of genomic DNA that is converted, in a sodium bisulfite reaction, to a mixed pool of methylation-dependent sequence differences according to standard procedures (the bisulfite process converts unmethylated cytosine residues to uracil). Fluorescence-based PCR is then performed either in an “unbiased” (with primers that do not overlap known CpG methylation sites) PCR reaction, or in a “biased” (with PCR primers that overlap known CpG dinucleotides) reaction. Sequence discrimination can occur either at the level of the amplification process or at the level of the fluorescence detection process, or both.

The MethyLight assay may be used as a quantitative test for methylation patterns in the genomic DNA sample, wherein sequence discrimination occurs at the level of probe hybridization. In this quantitative version, the PCR reaction provides for unbiased amplification in the presence of a fluorescent probe that overlaps a particular putative methylation site. An unbiased control for the amount of input DNA is provided by a reaction in which neither the primers, nor the probe overlie any CpG dinucleotides. Alternatively, a qualitative test for genomic methylation is achieved by probing of the biased PCR pool with either control oligonucleotides that do not “cover” known methylation sites (a fluorescence-based version of the “MSP” technique), or with oligonucleotides covering potential methylation sites.

The MethyLight process can by used with a “Taq Man” probe in the amplification process. For example, double-stranded genomic DNA is treated with sodium bisulfite and subjected to one of two sets of PCR reactions using TaqMan™ probes; e.g., with either biased primers and TaqMan™ probe, or unbiased primers and TaqMan™ probe. The TaqMan™ probe is dual-labeled with fluorescent “reporter” and “quencher” molecules, and is designed to be specific for a relatively high GC content region so that it melts out at about 10.degree. C. higher temperature in the PCR cycle than the forward or reverse primers. This allows the TaqMan™ probe to remain fully hybridized during the PCR annealing/extension step. As the Taq polymerase enzymatically synthesizes a new strand during PCR, it will eventually reach the annealed TaqMan™ probe. The Taq polymerase 5′ to 3′ endonuclease activity will then displace the TaqMan™ probe by digesting it to release the fluorescent reporter molecule for quantitative detection of its now unquenched signal using a real-time fluorescent detection system.

Typical reagents (e.g., as might be found in a typical MethyLight™-based kit) for MethyLight™ analysis may include, but are not limited to: PCR primers for specific gene (or methylation-altered DNA sequence or CpG island); TaqMan™ probes; optimized PCR buffers and deoxynucleotides; and Taq polymerase.

The Ms-SNuPE technique is a quantitative method for assessing methylation differences at specific CpG sites based on bisulfite treatment of DNA, followed by single-nucleotide primer extension (Gonzalgo & Jones, Nucleic Acids Res. 25:2529-2531, 1997).

Briefly, genomic DNA is reacted with sodium bisulfite to convert unmethylated cytosine to uracil while leaving 5-methylcytosine unchanged. Amplification of the desired target sequence is then performed using PCR primers specific for bisulfite-converted DNA, and the resulting product is isolated and used as a template for methylation analysis at the CpG site(s) of interest.

Small amounts of DNA can be analyzed (e.g., microdissected pathology sections), and it avoids utilization of restriction enzymes for determining the methylation status at CpG sites.

Typical reagents (e.g., as might be found in a typical Ms-SNuPE-based kit) for Ms-SNuPE analysis may include, but are not limited to: PCR primers for specific gene (or methylation-altered DNA sequence or CpG island); optimized PCR buffers and deoxynucleotides; gel extraction kit; positive control primers; Ms-SNuPE primers for specific gene; reaction buffer (for the Ms-SNuPE reaction); and radioactive nucleotides. Additionally, bisulfite conversion reagents may include: DNA denaturation buffer; sulfonation buffer; DNA recovery regents or kit (e.g., precipitation, ultrafiltration, affinity column); desulfonation buffer; and DNA recovery components.

MSP (methylation-specific PCR) allows for assessing the methylation status of virtually any group of CpG sites within a CpG island, independent of the use of methylation-sensitive restriction enzymes (Herman et al. Proc. Nat. Acad. Sci. USA 93:9821-9826, 1996; U.S. Pat. No. 5,786,146). Briefly, DNA is modified by sodium bisulfite converting all unmethylated, but not methylated cytosines to uracil, and subsequently amplified with primers specific for methylated versus unmethylated DNA. MSP requires only small quantities of DNA, is sensitive to 0.1% methylated alleles of a given CpG island locus, and can be performed on DNA extracted from paraffin-embedded samples. Typical reagents (e.g., as might be found in a typical MSP-based kit) for MSP analysis may include, but are not limited to: methylated and unmethylated PCR primers for specific gene (or methylation-altered DNA sequence or CpG island), optimized PCR buffers and deoxynucleotides, and specific probes.

The MCA technique is a method that can be used to screen for altered methylation patterns in genomic DNA, and to isolate specific sequences associated with these changes (Toyota et al., Cancer Res. 59:2307-12, 1999). Briefly, restriction enzymes with different sensitivities to cytosine methylation in their recognition sites are used to digest genomic DNAs from primary tumors, cell lines, and normal tissues prior to arbitrarily primed PCR amplification. Fragments that show differential methylation are cloned and sequenced after resolving the PCR products on high-resolution polyacrylamide gels. The cloned fragments are then used as probes for Southern analysis to confirm differential methylation of these regions. Typical reagents (e.g., as might be found in a typical MCA-based kit) for MCA analysis may include, but are not limited to: PCR primers for arbitrary priming Genomic DNA; PCR buffers and nucleotides, restriction enzymes and appropriate buffers; gene-hybridization oligos or probes; control hybridization oligos or probes.

Another method for analyzing methylation sites is a primer extension assay, including an optimized PCR amplification reaction that produces amplified targets for subsequent primer extension genotyping analysis using mass spectrometry. The assay can also be done in multiplex. This method (particularly as it relates to genotyping single nucleotide polymorphisms) is described in detail in PCT publication WO05012578A1 and US publication US20050079521A1. For methylation analysis, the assay can be adopted to detect bisulfite introduced methylation dependent C to T sequence changes. These methods are particularly useful for performing multiplexed amplification reactions and multiplexed primer extension reactions (e.g., multiplexed homogeneous primer mass extension (hME) assays) in a single well to further increase the throughput and reduce the cost per reaction for primer extension reactions.

Four additional methods for DNA methylation analysis include restriction landmark genomic scanning (RLGS, Costello et al., 2000), methylation-sensitive-representational difference analysis (MS-RDA), methylation-specific AP-PCR (MS-AP-PCR) and methyl-CpG binding domain column/segregation of partly melted molecules (MBD/SPM).

Additional methylation analysis methods that may be used in conjunction with the present invention are described in the following papers: Laird, P. W. Nature Reviews Cancer 3, 253-266 (2003); Biotechniques; Uhlmann, K. et al. Electrophoresis 23:4072-4079 (2002)—PyroMeth; Colella et al. Biotechniques. 2003 July; 35(1):146-50; Dupont J M, Tost J, Jammes H, and Gut I G. Anal Biochem, October 2004; 333(1): 119-27; and Tooke N and Pettersson M. IVDT. November 2004; 41.

Polynucleotide Sequence Amplification and Determination

Following separation of nucleic acid in a methylation-differential manner, the nucleic acid may be subjected to sequence-based analysis. Furthermore, once it is determined that one particular genomic sequence of fetal origin is hypermethylated or hypomethylated compared to the maternal counterpart, the amount of this fetal genomic sequence can be determined. Subsequently, this amount can be compared to a standard control value and serve as an indication for the potential of certain pregnancy-associated disorder.

A. Amplification of Nucleotide Sequences

In many instances, it is desirable to amplify a nucleic acid sequence of the invention using any of several nucleic acid amplification procedures which are well known in the art (listed above and described in greater detail below). Specifically, nucleic acid amplification is the enzymatic synthesis of nucleic acid amplicons (copies) which contain a sequence that is complementary to a nucleic acid sequence being amplified. Nucleic acid amplification is especially beneficial when the amount of target sequence present in a sample is very low. By amplifying the target sequences and detecting the amplicon synthesized, the sensitivity of an assay can be vastly improved, since fewer target sequences are needed at the beginning of the assay to better ensure detection of nucleic acid in the sample belonging to the organism or virus of interest.

A variety of polynucleotide amplification methods are well established and frequently used in research. For instance, the general methods of polymerase chain reaction (PCR) for polynucleotide sequence amplification are well known in the art and are thus not described in detail herein. For a review of PCR methods, protocols, and principles in designing primers, see, e.g., Innis, et al., PCR Protocols: A Guide to Methods and Applications, Academic Press, Inc. N.Y., 1990. PCR reagents and protocols are also available from commercial vendors, such as Roche Molecular Systems.

PCR is most usually carried out as an automated process with a thermostable enzyme. In this process, the temperature of the reaction mixture is cycled through a denaturing region, a primer annealing region, and an extension reaction region automatically. Machines specifically adapted for this purpose are commercially available.

Although PCR amplification of a polynucleotide sequence is typically used in practicing the present invention, one of skill in the art will recognize that the amplification of a genomic sequence found in a maternal blood sample may be accomplished by any known method, such as ligase chain reaction (LCR), transcription-mediated amplification, and self-sustained sequence replication or nucleic acid sequence-based amplification (NASBA), each of which provides sufficient amplification. More recently developed branched-DNA technology may also be used to qualitatively demonstrate the presence of a particular genomic sequence of the invention, which represents a particular methylation pattern, or to quantitatively determine the amount of this particular genomic sequence in the maternal blood. For a review of branched-DNA signal amplification for direct quantitation of nucleic acid sequences in clinical samples, see Nolte, Adv. Clin. Chem. 33:201-235, 1998.

The compositions and processes of the invention are also particularly useful when practiced with digital PCR. Digital PCR was first developed by Kalinina and colleagues (Kalinina et al., “Nanoliter scale PCR with TaqMan detection.” Nucleic Acids Research. 25; 1999-2004, (1997)) and further developed by Vogelstein and Kinzler (Digital PCR. Proc Natl Acad Sci USA. 96; 9236-41, (1999)). The application of digital PCR for use with fetal diagnostics was first described by Cantor et al. (PCT Patent Publication No. WO05023091A2) and subsequently described by Quake et al. (US Patent Publication No. US 20070202525), which are both hereby incorporated by reference. Digital PCR takes advantage of nucleic acid (DNA, cDNA or RNA) amplification on a single molecule level, and offers a highly sensitive method for quantifying low copy number nucleic acid. Fluidigm® Corporation offers systems for the digital analysis of nucleic acids.

B. Determination of Polynucleotide Sequences

Techniques for polynucleotide sequence determination are also well established and widely practiced in the relevant research field. For instance, the basic principles and general techniques for polynucleotide sequencing are described in various research reports and treatises on molecular biology and recombinant genetics, such as Wallace et al., supra; Sambrook and Russell, supra, and Ausubel et al., supra. DNA sequencing methods routinely practiced in research laboratories, either manual or automated, can be used for practicing the present invention. Additional means suitable for detecting changes in a polynucleotide sequence for practicing the methods of the present invention include but are not limited to mass spectrometry, primer extension, polynucleotide hybridization, real-time PCR, and electrophoresis.

Use of a primer extension reaction also can be applied in methods of the invention. A primer extension reaction operates, for example, by discriminating the SNP alleles by the incorporation of deoxynucleotides and/or dideoxynucleotides to a primer extension primer which hybridizes to a region adjacent to the SNP site. The primer is extended with a polymerase. The primer extended SNP can be detected physically by mass spectrometry or by a tagging moiety such as biotin. As the SNP site is only extended by a complementary deoxynucleotide or dideoxynucleotide that is either tagged by a specific label or generates a primer extension product with a specific mass, the SNP alleles can be discriminated and quantified.

Reverse transcribed and amplified nucleic acids may be modified nucleic acids. Modified nucleic acids can include nucleotide analogs, and in certain embodiments include a detectable label and/or a capture agent. Examples of detectable labels include without limitation fluorophores, radioisotopes, colormetric agents, light emitting agents, chemiluminescent agents, light scattering agents, enzymes and the like. Examples of capture agents include without limitation an agent from a binding pair selected from antibody/antigen, antibody/antibody, antibody/antibody fragment, antibody/antibody receptor, antibody/protein A or protein G, hapten/anti-hapten, biotin/avidin, biotin/streptavidin, folic acid/folate binding protein, vitamin B12/intrinsic factor, chemical reactive group/complementary chemical reactive group (e.g., sulfhydryl/maleimide, sulfhydryl/haloacetyl derivative, amine/isotriocyanate, amine/succinimidyl ester, and amine/sulfonyl halides) pairs, and the like. Modified nucleic acids having a capture agent can be immobilized to a solid support in certain embodiments

Mass spectrometry is a particularly effective method for the detection of a polynucleotide of the invention, for example a PCR amplicon, a primer extension product or a detector probe that is cleaved from a target nucleic acid. The presence of the polynucleotide sequence is verified by comparing the mass of the detected signal with the expected mass of the polynucleotide of interest. The relative signal strength, e.g., mass peak on a spectra, for a particular polynucleotide sequence indicates the relative population of a specific allele, thus enabling calculation of the allele ratio directly from the data. For a review of genotyping methods using Sequenom® standard iPLEX™ assay and MassARRAY® technology, see Jurinke, C., Oeth, P., van den Boom, D., “MALDI-TOF mass spectrometry: a versatile tool for high-performance DNA analysis.” Mol. Biotechnol. 26, 147-164 (2004); and Oeth, P. et al., “iPLEX™ Assay: Increased Plexing Efficiency and Flexibility for MassARRAY® System through single base primer extension with mass-modified Terminators.” SEQUENOM Application Note (2005), both of which are hereby incorporated by reference. For a review of detecting and quantifying target nucleic using cleavable detector probes that are cleaved during the amplification process and detected by mass spectrometry, see U.S. patent application Ser. No. 11/950,395, which was filed Dec. 4, 2007, and is hereby incorporated by reference.

Sequencing technologies are improving in terms of throughput and cost. Sequencing technologies, such as that achievable on the 454 platform (Roche) (Margulies, M. et al. 2005 Nature 437, 376-380), IIlumina Genome Analyzer (or Solexa platform) or SOLiD System (Applied Biosystems) or the Helicos True Single Molecule DNA sequencing technology (Harris T D et al. 2008 Science, 320, 106-109), the single molecule, real-time (SMRT™) technology of Pacific Biosciences, and nanopore sequencing (Soni G V and Meller A. 2007 Clin Chem 53: 1996-2001), allow the sequencing of many nucleic acid molecules isolated from a specimen at high orders of multiplexing in a parallel fashion (Dear Brief Funct Genomic Proteomic 2003; 1: 397-416).

Each of these platforms allow sequencing of clonally expanded or non-amplified single molecules of nucleic acid fragments. Certain platforms involve, for example, (i) sequencing by ligation of dye-modified probes (including cyclic ligation and cleavage), (ii) pyrosequencing, and (iii) single-molecule sequencing. Nucleotide sequence species, amplification nucleic acid species and detectable products generated there from can be considered a “study nucleic acid” for purposes of analyzing a nucleotide sequence by such sequence analysis platforms.

Sequencing by ligation is a nucleic acid sequencing method that relies on the sensitivity of DNA ligase to base-pairing mismatch. DNA ligase joins together ends of DNA that are correctly base paired. Combining the ability of DNA ligase to join together only correctly base paired DNA ends, with mixed pools of fluorescently labeled oligonucleotides or primers, enables sequence determination by fluorescence detection. Longer sequence reads may be obtained by including primers containing cleavable linkages that can be cleaved after label identification. Cleavage at the linker removes the label and regenerates the 5′ phosphate on the end of the ligated primer, preparing the primer for another round of ligation. In some embodiments primers may be labeled with more than one fluorescent label (e.g., 1 fluorescent label, 2, 3, or 4 fluorescent labels).

An example of a system that can be used by a person of ordinary skill based on sequencing by ligation generally involves the following steps. Clonal bead populations can be prepared in emulsion microreactors containing study nucleic acid (“template”), amplification reaction components, beads and primers. After amplification, templates are denatured and bead enrichment is performed to separate beads with extended templates from undesired beads (e.g., beads with no extended templates). The template on the selected beads undergoes a 3′ modification to allow covalent bonding to the slide, and modified beads can be deposited onto a glass slide. Deposition chambers offer the ability to segment a slide into one, four or eight chambers during the bead loading process. For sequence analysis, primers hybridize to the adapter sequence. A set of four color dye-labeled probes competes for ligation to the sequencing primer. Specificity of probe ligation is achieved by interrogating every 4th and 5th base during the ligation series. Five to seven rounds of ligation, detection and cleavage record the color at every 5th position with the number of rounds determined by the type of library used. Following each round of ligation, a new complimentary primer offset by one base in the 5′ direction is laid down for another series of ligations. Primer reset and ligation rounds (5-7 ligation cycles per round) are repeated sequentially five times to generate 25-35 base pairs of sequence for a single tag. With mate-paired sequencing, this process is repeated for a second tag. Such a system can be used to exponentially amplify amplification products generated by a process described herein, e.g., by ligating a heterologous nucleic acid to the first amplification product generated by a process described herein and performing emulsion amplification using the same or a different solid support originally used to generate the first amplification product. Such a system also may be used to analyze amplification products directly generated by a process described herein by bypassing an exponential amplification process and directly sorting the solid supports described herein on the glass slide.

Pyrosequencing is a nucleic acid sequencing method based on sequencing by synthesis, which relies on detection of a pyrophosphate released on nucleotide incorporation. Generally, sequencing by synthesis involves synthesizing, one nucleotide at a time, a DNA strand complimentary to the strand whose sequence is being sought. Study nucleic acids may be immobilized to a solid support, hybridized with a sequencing primer, incubated with DNA polymerase, ATP sulfurylase, luciferase, apyrase, adenosine 5′ phosphsulfate and luciferin. Nucleotide solutions are sequentially added and removed. Correct incorporation of a nucleotide releases a pyrophosphate, which interacts with ATP sulfurylase and produces ATP in the presence of adenosine 5′ phosphsulfate, fueling the luciferin reaction, which produces a chemiluminescent signal allowing sequence determination.

An example of a system that can be used by a person of ordinary skill based on pyrosequencing generally involves the following steps: ligating an adaptor nucleic acid to a study nucleic acid and hybridizing the study nucleic acid to a bead; amplifying a nucleotide sequence in the study nucleic acid in an emulsion; sorting beads using a picoliter multiwell solid support; and sequencing amplified nucleotide sequences by pyrosequencing methodology (e.g., Nakano et al., “Single-molecule PCR using water-in-oil emulsion;” Journal of Biotechnology 102: 117-124 (2003)). Such a system can be used to exponentially amplify amplification products generated by a process described herein, e.g., by ligating a heterologous nucleic acid to the first amplification product generated by a process described herein.

Certain single-molecule sequencing embodiments are based on the principal of sequencing by synthesis, and utilize single-pair Fluorescence Resonance Energy Transfer (single pair FRET) as a mechanism by which photons are emitted as a result of successful nucleotide incorporation. The emitted photons often are detected using intensified or high sensitivity cooled charge-couple-devices in conjunction with total internal reflection microscopy (TIRM). Photons are only emitted when the introduced reaction solution contains the correct nucleotide for incorporation into the growing nucleic acid chain that is synthesized as a result of the sequencing process. In FRET based single-molecule sequencing, energy is transferred between two fluorescent dyes, sometimes polymethine cyanine dyes Cy3 and Cy5, through long-range dipole interactions. The donor is excited at its specific excitation wavelength and the excited state energy is transferred, non-radiatively to the acceptor dye, which in turn becomes excited. The acceptor dye eventually returns to the ground state by radiative emission of a photon. The two dyes used in the energy transfer process represent the “single pair”, in single pair FRET. Cy3 often is used as the donor fluorophore and often is incorporated as the first labeled nucleotide. Cy5 often is used as the acceptor fluorophore and is used as the nucleotide label for successive nucleotide additions after incorporation of a first Cy3 labeled nucleotide. The fluorophores generally are within 10 nanometers of each for energy transfer to occur successfully.

An example of a system that can be used based on single-molecule sequencing generally involves hybridizing a primer to a study nucleic acid to generate a complex; associating the complex with a solid phase; iteratively extending the primer by a nucleotide tagged with a fluorescent molecule; and capturing an image of fluorescence resonance energy transfer signals after each iteration (e.g., U.S. Pat. No. 7,169,314; Braslaysky et al., PNAS 100(7): 3960-3964 (2003)). Such a system can be used to directly sequence amplification products generated by processes described herein. In some embodiments the released linear amplification product can be hybridized to a primer that contains sequences complementary to immobilized capture sequences present on a solid support, a bead or glass slide for example. Hybridization of the primer—released linear amplification product complexes with the immobilized capture sequences, immobilizes released linear amplification products to solid supports for single pair FRET based sequencing by synthesis. The primer often is fluorescent, so that an initial reference image of the surface of the slide with immobilized nucleic acids can be generated. The initial reference image is useful for determining locations at which true nucleotide incorporation is occurring. Fluorescence signals detected in array locations not initially identified in the “primer only” reference image are discarded as non-specific fluorescence. Following immobilization of the primer—released linear amplification product complexes, the bound nucleic acids often are sequenced in parallel by the iterative steps of, a) polymerase extension in the presence of one fluorescently labeled nucleotide, b) detection of fluorescence using appropriate microscopy, TIRM for example, c) removal of fluorescent nucleotide, and d) return to step a with a different fluorescently labeled nucleotide.

In some embodiments, nucleotide sequencing may be by solid phase single nucleotide sequencing methods and processes. Solid phase single nucleotide sequencing methods involve contacting sample nucleic acid and solid support under conditions in which a single molecule of sample nucleic acid hybridizes to a single molecule of a solid support. Such conditions can include providing the solid support molecules and a single molecule of sample nucleic acid in a “microreactor.” Such conditions also can include providing a mixture in which the sample nucleic acid molecule can hybridize to solid phase nucleic acid on the solid support. Single nucleotide sequencing methods useful in the embodiments described herein are described in U.S. Provisional Patent Application Ser. No. 61/021,871 filed Jan. 17, 2008.

In certain embodiments, nanopore sequencing detection methods include (a) contacting a nucleic acid for sequencing (“base nucleic acid,” e.g., linked probe molecule) with sequence-specific detectors, under conditions in which the detectors specifically hybridize to substantially complementary subsequences of the base nucleic acid; (b) detecting signals from the detectors and (c) determining the sequence of the base nucleic acid according to the signals detected. In certain embodiments, the detectors hybridized to the base nucleic acid are disassociated from the base nucleic acid (e.g., sequentially dissociated) when the detectors interfere with a nanopore structure as the base nucleic acid passes through a pore, and the detectors disassociated from the base sequence are detected. In some embodiments, a detector disassociated from a base nucleic acid emits a detectable signal, and the detector hybridized to the base nucleic acid emits a different detectable signal or no detectable signal. In certain embodiments, nucleotides in a nucleic acid (e.g., linked probe molecule) are substituted with specific nucleotide sequences corresponding to specific nucleotides (“nucleotide representatives”), thereby giving rise to an expanded nucleic acid (e.g., U.S. Pat. No. 6,723,513), and the detectors hybridize to the nucleotide representatives in the expanded nucleic acid, which serves as a base nucleic acid. In such embodiments, nucleotide representatives may be arranged in a binary or higher order arrangement (e.g., Soni and Meller, Clinical Chemistry 53(11): 1996-2001 (2007)). In some embodiments, a nucleic acid is not expanded, does not give rise to an expanded nucleic acid, and directly serves a base nucleic acid (e.g., a linked probe molecule serves as a non-expanded base nucleic acid), and detectors are directly contacted with the base nucleic acid. For example, a first detector may hybridize to a first subsequence and a second detector may hybridize to a second subsequence, where the first detector and second detector each have detectable labels that can be distinguished from one another, and where the signals from the first detector and second detector can be distinguished from one another when the detectors are disassociated from the base nucleic acid. In certain embodiments, detectors include a region that hybridizes to the base nucleic acid (e.g., two regions), which can be about 3 to about 100 nucleotides in length (e.g., about 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 50, 55, 60, 65, 70, 75, 80, 85, 90, or 95 nucleotides in length). A detector also may include one or more regions of nucleotides that do not hybridize to the base nucleic acid. In some embodiments, a detector is a molecular beacon. A detector often comprises one or more detectable labels independently selected from those described herein. Each detectable label can be detected by any convenient detection process capable of detecting a signal generated by each label (e.g., magnetic, electric, chemical, optical and the like). For example, a CD camera can be used to detect signals from one or more distinguishable quantum dots linked to a detector.

In certain sequence analysis embodiments, reads may be used to construct a larger nucleotide sequence, which can be facilitated by identifying overlapping sequences in different reads and by using identification sequences in the reads. Such sequence analysis methods and software for constructing larger sequences from reads are known to the person of ordinary skill (e.g., Venter et al., Science 291: 1304-1351 (2001)). Specific reads, partial nucleotide sequence constructs, and full nucleotide sequence constructs may be compared between nucleotide sequences within a sample nucleic acid (i.e., internal comparison) or may be compared with a reference sequence (i.e., reference comparison) in certain sequence analysis embodiments. Internal comparisons sometimes are performed in situations where a sample nucleic acid is prepared from multiple samples or from a single sample source that contains sequence variations. Reference comparisons sometimes are performed when a reference nucleotide sequence is known and an objective is to determine whether a sample nucleic acid contains a nucleotide sequence that is substantially similar or the same, or different, than a reference nucleotide sequence. Sequence analysis is facilitated by sequence analysis apparatus and components known to the person of ordinary skill in the art.

Methods provided herein allow for high-throughput detection of nucleic acid species in a plurality of nucleic acids (e.g., nucleotide sequence species, amplified nucleic acid species and detectable products generated from the foregoing). Multiplexing refers to the simultaneous detection of more than one nucleic acid species. General methods for performing multiplexed reactions in conjunction with mass spectrometry, are known (see, e.g., U.S. Pat. Nos. 6,043,031, 5,547,835 and International PCT application No. WO 97/37041). Multiplexing provides an advantage that a plurality of nucleic acid species (e.g., some having different sequence variations) can be identified in as few as a single mass spectrum, as compared to having to perform a separate mass spectrometry analysis for each individual target nucleic acid species. Methods provided herein lend themselves to high-throughput, highly-automated processes for analyzing sequence variations with high speed and accuracy, in some embodiments. In some embodiments, methods herein may be multiplexed at high levels in a single reaction.

In certain embodiments, the number of nucleic acid species multiplexed include, without limitation, about 1 to about 500 (e.g., about 1-3, 3-5, 5-7, 7-9, 9-11, 11-13, 13-15, 15-17, 17-19, 19-21, 21-23, 23-25, 25-27, 27-29, 29-31, 31-33, 33-35, 35-37, 37-39, 39-41, 41-43, 43-45, 45-47, 47-49, 49-51, 51-53, 53-55, 55-57, 57-59, 59-61, 61-63, 63-65, 65-67, 67-69, 69-71, 71-73, 73-75, 75-77, 77-79, 79-81, 81-83, 83-85, 85-87, 87-89, 89-91, 91-93, 93-95, 95-97, 97-101, 101-103, 103-105, 105-107, 107-109, 109-111, 111-113, 113-115, 115-117, 117-119, 121-123, 123-125, 125-127, 127-129, 129-131, 131-133, 133-135, 135-137, 137-139, 139-141, 141-143, 143-145, 145-147, 147-149, 149-151, 151-153, 153-155, 155-157, 157-159, 159-161, 161-163, 163-165, 165-167, 167-169, 169-171, 171-173, 173-175, 175-177, 177-179, 179-181, 181-183, 183-185, 185-187, 187-189, 189-191, 191-193, 193-195, 195-197, 197-199, 199-201, 201-203, 203-205, 205-207, 207-209, 209-211, 211-213, 213-215, 215-217, 217-219, 219-221, 221-223, 223-225, 225-227, 227-229, 229-231, 231-233, 233-235, 235-237, 237-239, 239-241, 241-243, 243-245, 245-247, 247-249, 249-251, 251-253, 253-255, 255-257, 257-259, 259-261, 261-263, 263-265, 265-267, 267-269, 269-271, 271-273, 273-275, 275-277, 277-279, 279-281, 281-283, 283-285, 285-287, 287-289, 289-291, 291-293, 293-295, 295-297, 297-299, 299-301, 301-303, 303-305, 305-307, 307-309, 309-311, 311-313, 313-315, 315-317, 317-319, 319-321, 321-323, 323-325, 325-327, 327-329, 329-331, 331-333, 333-335, 335-337, 337-339, 339-341, 341-343, 343-345, 345-347, 347-349, 349-351, 351-353, 353-355, 355-357, 357-359, 359-361, 361-363, 363-365, 365-367, 367-369, 369-371, 371-373, 373-375, 375-377, 377-379, 379-381, 381-383, 383-385, 385-387, 387-389, 389-391, 391-393, 393-395, 395-397, 397-401, 401-403, 403-405, 405-407, 407-409, 409-411, 411-413, 413-415, 415-417, 417-419, 419-421, 421-423, 423-425, 425-427, 427-429, 429-431, 431-433, 433-435, 435-437, 437-439, 439-441, 441-443, 443-445, 445-447, 447-449, 449-451, 451-453, 453-455, 455-457, 457-459, 459-461, 461-463, 463-465, 465-467, 467-469, 469-471, 471-473, 473-475, 475-477, 477-479, 479-481, 481-483, 483-485, 485-487, 487-489, 489-491, 491-493, 493-495, 495-497, 497-501).

Design methods for achieving resolved mass spectra with multiplexed assays can include primer and oligonucleotide design methods and reaction design methods. See, for example, the multiplex schemes provided in Tables X and Y. For primer and oligonucleotide design in multiplexed assays, the same general guidelines for primer design applies for uniplexed reactions, such as avoiding false priming and primer dimers, only more primers are involved for multiplex reactions. For mass spectrometry applications, analyte peaks in the mass spectra for one assay are sufficiently resolved from a product of any assay with which that assay is multiplexed, including pausing peaks and any other by-product peaks. Also, analyte peaks optimally fall within a user-specified mass window, for example, within a range of 5,000-8,500 Da. In some embodiments multiplex analysis may be adapted to mass spectrometric detection of chromosome abnormalities, for example. In certain embodiments multiplex analysis may be adapted to various single nucleotide or nanopore based sequencing methods described herein. Commercially produced micro-reaction chambers or devices or arrays or chips may be used to facilitate multiplex analysis, and are commercially available.

Detection of Fetal Aneuploidy

For the detection of fetal aneuploidies, some methods rely on measuring the ratio between maternally and paternally inherited alleles. However, the ability to quantify chromosomal changes is impaired by the maternal contribution of cell free nucleic acids, which makes it necessary to deplete the sample from maternal DNA prior to measurement. Promising approaches take advantage of the different size distribution of fetal and maternal DNA or measure RNA that is exclusively expressed by the fetus (see for example, U.S. patent application Ser. No. 11/384,128, which published as US20060252071 and is hereby incorporated by reference). Assuming fetal DNA makes up only about 5% of all cell free DNA in the maternal plasma, there is a decrease of the ratio difference from 1.6% to only about 1.2% between a trisomy sample and a healthy control. Consequently, reliable detection of allele ratio changes requires enriching the fetal fraction of cell free DNA, for example, using the compositions and methods of the present invention.

Some methods rely on measuring the ratio of maternal to paternally inherited alleles to detect fetal chromosomal aneuploidies from maternal plasma. A diploid set yields a 1:1 ratio while trisomies can be detected as a 2:1 ratio. Detection of this difference is impaired by statistical sampling due to the low abundance of fetal DNA, presence of excess maternal DNA in the plasma sample and variability of the measurement technique. The latter is addressed by using methods with high measurement precision, like digital PCR or mass spectrometry. Enriching the fetal fraction of cell free DNA in a sample is currently achieved by either depleting maternal DNA through size exclusion or focusing on fetal-specific nucleic acids, like fetal-expressed RNA. Another differentiating feature of fetal DNA is its DNA methylation pattern. Thus, provided herein are novel compositions and methods for accurately quantifying fetal nucleic acid based on differential methylation between a fetus and mother. The methods rely on sensitive absolute copy number analysis to quantify the fetal nucleic acid portion of a maternal sample, thereby allowing for the prenatal detection of fetal traits. The methods of the invention have identified approximately 3000 CpG rich regions in the genome that are differentially methylated between maternal and fetal DNA. The selected regions showed highly conserved differential methylation across all measured samples. In addition the set of regions is enriched for genes important in developmental regulation, indicating that epigenetic regulation of these areas is a biologically relevant and consistent process (see Table 3). Enrichment of fetal DNA can now be achieved by using our MBD-FC protein to capture all cell free DNA and then elute the highly methylated DNA fraction with high salt concentrations. Using the low salt eluate fractions, the MBD-FC is equally capable of enriching non-methylated fetal DNA.

The present invention provides 63 confirmed genomic regions on chromosomes 13, 18 and 21 with low maternal and high fetal methylation levels. After capturing these regions, SNPs can be used to determine the aforementioned allele ratios. When high frequency SNPs are used around 10 markers have to be measured to achieve a high confidence of finding at least one SNP where the parents have opposite homozygote genotypes and the child has a heterozygote genotype.

In an embodiment, a method for chromosomal abnormality detection is provided that utilizes absolute copy number quantification. A diploid chromosome set will show the same number of copies for differentially methylated regions across all chromosomes, but, for example, a trisomy 21 sample would show 1.5 times more copies for differentially methylated regions on chromosome 21. Normalization of the genomic DNA amounts for a diploid chromosome set can be achieved by using unaltered autosomes as reference (also provided herein—see Table 1B). Comparable to other approaches, a single marker is less likely to be sufficient for detection of this difference, because the overall copy numbers are low. Typically there are approximately 100 to 200 copies of fetal DNA from 1 ml of maternal plasma at 10 to 12 weeks of gestation. However, the methods of the present invention offer a redundancy of detectable markers that enables highly reliable discrimination of diploid versus aneuploid chromosome sets.

Data Processing and Identifying Presence or Absence of a Chromosome Abnormality

The term “detection” of a chromosome abnormality as used herein refers to identification of an imbalance of chromosomes by processing data arising from detecting sets of amplified nucleic acid species, nucleotide sequence species, or a detectable product generated from the foregoing (collectively “detectable product”). Any suitable detection device and method can be used to distinguish one or more sets of detectable products, as addressed herein. An outcome pertaining to the presence or absence of a chromosome abnormality can be expressed in any suitable form, including, without limitation, probability (e.g., odds ratio, p-value), likelihood, percentage, value over a threshold, or risk factor, associated with the presence of a chromosome abnormality for a subject or sample. An outcome may be provided with one or more of sensitivity, specificity, standard deviation, coefficient of variation (CV) and/or confidence level, or combinations of the foregoing, in certain embodiments.

Detection of a chromosome abnormality based on one or more sets of detectable products may be identified based on one or more calculated variables, including, but not limited to, sensitivity, specificity, standard deviation, coefficient of variation (CV), a threshold, confidence level, score, probability and/or a combination thereof. In some embodiments, (i) the number of sets selected for a diagnostic method, and/or (ii) the particular nucleotide sequence species of each set selected for a diagnostic method, is determined in part or in full according to one or more of such calculated variables.

In certain embodiments, one or more of sensitivity, specificity and/or confidence level are expressed as a percentage. In some embodiments, the percentage, independently for each variable, is greater than about 90% (e.g., about 90, 91, 92, 93, 94, 95, 96, 97, 98 or 99%, or greater than 99% (e.g., about 99.5%, or greater, about 99.9% or greater, about 99.95% or greater, about 99.99% or greater)). Coefficient of variation (CV) in some embodiments is expressed as a percentage, and sometimes the percentage is about 10% or less (e.g., about 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1%, or less than 1% (e.g., about 0.5% or less, about 0.1% or less, about 0.05% or less, about 0.01% or less)). A probability (e.g., that a particular outcome determined by an algorithm is not due to chance) in certain embodiments is expressed as a p-value, and sometimes the p-value is about 0.05 or less (e.g., about 0.05, 0.04, 0.03, 0.02 or 0.01, or less than 0.01 (e.g., about 0.001 or less, about 0.0001 or less, about 0.00001 or less, about 0.000001 or less)).

For example, scoring or a score may refer to calculating the probability that a particular chromosome abnormality is actually present or absent in a subject/sample. The value of a score may be used to determine for example the variation, difference, or ratio of amplified nucleic detectable product that may correspond to the actual chromosome abnormality. For example, calculating a positive score from detectable products can lead to an identification of a chromosome abnormality, which is particularly relevant to analysis of single samples.

In certain embodiments, simulated (or simulation) data can aid data processing for example by training an algorithm or testing an algorithm. Simulated data may for instance involve hypothetical various samples of different concentrations of fetal and maternal nucleic acid in serum, plasma and the like. Simulated data may be based on what might be expected from a real population or may be skewed to test an algorithm and/or to assign a correct classification based on a simulated data set. Simulated data also is referred to herein as “virtual” data. Fetal/maternal contributions within a sample can be simulated as a table or array of numbers (for example, as a list of peaks corresponding to the mass signals of cleavage products of a reference biomolecule or amplified nucleic acid sequence), as a mass spectrum, as a pattern of bands on a gel, or as a representation of any technique that measures mass distribution. Simulations can be performed in most instances by a computer program. One possible step in using a simulated data set is to evaluate the confidence of the identified results, i.e. how well the selected positives/negatives match the sample and whether there are additional variations. A common approach is to calculate the probability value (p-value) which estimates the probability of a random sample having better score than the selected one. As p-value calculations can be prohibitive in certain circumstances, an empirical model may be assessed, in which it is assumed that at least one sample matches a reference sample (with or without resolved variations). Alternatively other distributions such as Poisson distribution can be used to describe the probability distribution.

In certain embodiments, an algorithm can assign a confidence value to the true positives, true negatives, false positives and false negatives calculated. The assignment of a likelihood of the occurrence of a chromosome abnormality can also be based on a certain probability model.

Simulated data often is generated in an in silico process. As used herein, the term “in silico” refers to research and experiments performed using a computer. In silico methods include, but are not limited to, molecular modeling studies, karyotyping, genetic calculations, biomolecular docking experiments, and virtual representations of molecular structures and/or processes, such as molecular interactions.

As used herein, a “data processing routine” refers to a process, that can be embodied in software, that determines the biological significance of acquired data (i.e., the ultimate results of an assay). For example, a data processing routine can determine the amount of each nucleotide sequence species based upon the data collected. A data processing routine also may control an instrument and/or a data collection routine based upon results determined. A data processing routine and a data collection routine often are integrated and provide feedback to operate data acquisition by the instrument, and hence provide assay-based judging methods provided herein.

As used herein, software refers to computer readable program instructions that, when executed by a computer, perform computer operations. Typically, software is provided on a program product containing program instructions recorded on a computer readable medium, including, but not limited to, magnetic media including floppy disks, hard disks, and magnetic tape; and optical media including CD-ROM discs, DVD discs, magneto-optical discs, and other such media on which the program instructions can be recorded.

Different methods of predicting abnormality or normality can produce different types of results. For any given prediction, there are four possible types of outcomes: true positive, true negative, false positive, or false negative. The term “true positive” as used herein refers to a subject correctly diagnosed as having a chromosome abnormality. The term “false positive” as used herein refers to a subject wrongly identified as having a chromosome abnormality. The term “true negative” as used herein refers to a subject correctly identified as not having a chromosome abnormality. The term “false negative” as used herein refers to a subject wrongly identified as not having a chromosome abnormality. Two measures of performance for any given method can be calculated based on the ratios of these occurrences: (i) a sensitivity value, the fraction of predicted positives that are correctly identified as being positives (e.g., the fraction of nucleotide sequence sets correctly identified by level comparison detection/determination as indicative of chromosome abnormality, relative to all nucleotide sequence sets identified as such, correctly or incorrectly), thereby reflecting the accuracy of the results in detecting the chromosome abnormality; and (ii) a specificity value, the fraction of predicted negatives correctly identified as being negative (the fraction of nucleotide sequence sets correctly identified by level comparison detection/determination as indicative of chromosomal normality, relative to all nucleotide sequence sets identified as such, correctly or incorrectly), thereby reflecting accuracy of the results in detecting the chromosome abnormality.

EXAMPLES

The following examples are provided by way of illustration only and not by way of limitation. Those of skill in the art will readily recognize a variety of non-critical parameters that could be changed or modified to yield essentially the same or similar results.

In Example 1 below, the Applicants used a new fusion protein that captures methylated DNA in combination with CpG Island array to identify genomic regions that are differentially methylated between fetal placenta tissue and maternal blood. A stringent statistical approach was used to only select regions which show little variation between the samples, and hence suggest an underlying biological mechanism. Eighty-five differentially methylated genomic regions predominantly located on chromosomes 13, 18 and 21 were validated. For this validation, a quantitative mass spectrometry based approach was used that interrogated 261 PCR amplicons covering these 85 regions. The results are in very good concordance (95% confirmation), proving the feasibility of the approach.

Next, the Applicants provide an innovative approach for aneuploidy testing, which relies on the measurement of absolute copy numbers rather than allele ratios.

Example 1

In the below Example, ten paired maternal and placental DNA samples were used to identify differentially methylated regions. These results were validated using a mass spectrometry-based quantitative methylation assay. First, genomic DNA from maternal buffy coat and corresponding placental tissue was first extracted. Next the MBD-FC was used to capture the methylated fraction of each DNA sample. See FIGS. 1-3. The two tissue fractions were labeled with different fluorescent dyes and hybridized to an Agilent® CpG Island microarray. See FIG. 4. This was done to identify differentially methylated regions that could be utilized for prenatal diagnoses. Therefore, two criteria were employed to select genomic regions as potential enrichment markers: the observed methylation difference had to be present in all tested sample pairs, and the region had to be more than 200 bp in length.

DNA Preparation and Fragmentation

Genomic DNA (gDNA) from maternal buffy coat and placental tissue was prepared using the QIAamp DNA Mini Kit™ and QIAamp DNA Blood Mini Kit™, respectively, from Qiagen® (Hilden, Germany). For MCIp, gDNA was quantified using the NanoDrop ND 1000™ spectrophotometer (Thermo Fisher®, Waltham, Mass., USA). Ultrasonication of 2.5 μg DNA in 500 μl TE buffer to a mean fragment size of 300-500 bp was carried out with the Branson Digital Sonifier 450™ (Danbury, Conn., USA) using the following settings: amplitude 20%, sonication time 110 seconds, pulse on/pulse off time 1.4/0.6 seconds. Fragment range was monitored using gel electrophoresis.

Methyl-CpG Immunoprecipitation

Per sample, 56 μg purified MBD-Fc protein and 150 μl of Protein A Sepharose 4 Fast Flow beads (Amersham Biosciences®, Piscataway, N.J., USA) were rotated in 15 ml TBS overnight at 4° C. Then, the MBD-Fc beads (150 μl/assay) were transferred and dispersed in to 2 ml Ultrafree-CL centrifugal filter devices (Millipore®, Billerica, Mass., USA) and spin-washed three times with Buffer A (20 mM Tris-HCl, pH8.0, 2 mM MgCl2, 0.5 mM EDTA 300 mM NaCl, 0.1% NP-40). Sonicated DNA (2 μg) was added to the washed MBD-Fc beads in 2 ml Buffer A and rotated for 3 hours at 4° C. Beads were centrifuged to recover unbound DNA fragments (300 mM fraction) and subsequently washed twice with 600 μl of buffers containing increasing NaCl concentrations (400, 500, 550, 600, and 1000 mM). The flow through of each wash step was collected in separate tubes and desalted using a MinElute PCR Purification Kit™ (Qiagen®). In parallel, 200 ng sonicated input DNA was processed as a control using the MinElute PCR Purification Kit™ (Qiagen®).

Microarray Handling and Analysis

To generate fluorescently labeled DNA for microarray hybridization, the 600 mM and 1M NaCl fractions (enriched methylated DNA) for each sample were combined and labeled with either Alexa Fluor 555-aha-dCTP (maternal) or Alexa Fluor 647-aha-dCTP (placental) using the BioPrime Total Genomic Labeling System™ (Invitrogen®, Carlsbad, Calif., USA). The labeling reaction was carried out according to the manufacturer's manual. The differently labeled genomic DNA fragments of matched maternal/placental pairs were combined to a final volume of 80 μl, supplemented with 50 μg Cot-1 DNA (Invitrogen®), 52 μl of Agilent 10× blocking reagent (Agilent Technologies®, Santa Clara, Calif., USA), 78 μl of deionized formamide, and 260 μl Agilent 2× hybridization buffer. The samples were heated to 95° C. for 3 min, mixed, and subsequently incubated at 37° C. for 30 min. Hybridization on Agilent CpG Island Microarray Kit™ was then carried out at 67° C. for 40 hours using an Agilent SureHyb™ chamber and an Agilent hybridization oven. Slides were washed in Wash I (6×SSPE, 0.005% N-lauroylsarcosine) at room temperature for 5 min and in Wash II (0.06×SSPE) at 37° C. for an additional 5 min. Next, the slides were submerged in acetonitrile and Agilent Ozone Protection Solution™, respectively, for 30 seconds. Images were scanned immediately and analyzed using an Agilent DNA Microarray Scanner™. Microarray images were processed using Feature Extraction Software v9.5 and the standard CGH protocol.

Bisulfite Treatment

Genomic DNA sodium bisulfite conversion was performed using EZ-96 DNA Methylation Kit™ (ZymoResearch, Orange County, Calif.). The manufacturer's protocol was followed using 1 ug of genomic DNA and the alternative conversion protocol (a two temperature DNA denaturation).

Quantitative Methylation Analysis

Sequenom's MassARRAY® System was used to perform quantitative methylation analysis. This system utilizes matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry in combination with RNA base specific cleavage (Sequenom® MassCLEAVE™). A detectable pattern is then analyzed for methylation status. PCR primers were designed using Sequenom® EpiDESIGNER™ (www.epidesigner.com). A total of 261 amplicons, covering 85 target regions, were used for validation (median amplification length=367 bp, min=108, max=500; median number of CpG's per amplicon=23, min=4, max=65). For each reverse primer, an additional T7 promoter tag for in-vivo transcription was added, as well as a 10mer tag on the forward primer to adjust for melting temperature differences. The MassCLEAVE™ biochemistry was performed as previously described (Ehrich M, et al. (2005) Quantitative high-throughput analysis of DNA methylation patterns by base specific cleavage and mass spectrometry. Proc Natl Acad Sci USA 102:15785-15790). Mass spectra were acquired using a MassARRAY™ Compact MALDI-TOF (Sequenom®, San Diego) and methylation ratios were generated by the EpiTYPER™ software v1.0 (Sequenom®, San Diego).

Statistical Analysis

All statistical calculations were performed using the R statistical software package (www.r-project.org). First, the array probes were grouped based on their genomic location. Subsequent probes that were less than 1000 bp apart were grouped together. To identify differentially methylated regions, a control sample was used as reference. In the control sample, the methylated fraction of a blood derived control DNA was hybridized against itself. Ideally this sample should show log ratios of the two color channels around 0. However because of the variability in hybridization behavior, the probes show a mean log ratio of 0.02 and a standard deviation of 0.18. Next the log ratios observed in our samples were compared to the control sample. A two way, paired t-test was used to test the NULL hypothesis that the groups are identical. Groups that contained less than 4 probes were excluded from the analysis. For groups including four or five probes, all probes were used in a paired t-test. For Groups with six or more probes, a sliding window test consisting of five probes at a time was used, whereby the window was moved by one probe increments. Each test sample was compared to the control sample and the p-values were recorded. Genomic regions were selected as being differentially methylated if eight out of ten samples showed a p value<0.01, or if six out of ten samples showed a p value<0.001. The genomic regions were classified as being not differentially methylated when the group showed less than eight samples with a p value<0.01 and less than six samples with a p value<0.001. Samples that didn't fall in either category were excluded from the analysis. For a subset of genomic regions that have been identified as differentially methylated, the results were confirmed using quantitative methylation analysis.

The Go analysis was performed using the online GOstat tool (http://gostat.wehi.edu.au/cgibin/-goStat.pl). P values were calculated using Fisher's exact test.

Microarray-Based Marker Discovery Results

To identify differentially methylated regions a standard sample was used, in which the methylated DNA fraction of monocytes was hybridized against itself. This standard provided a reference for the variability of fluorescent measurements in a genomic region. Differentially methylated regions were then identified by comparing the log ratios of each of the ten placental/maternal samples against this standard. Because the goal of this study was to identify markers that allow the reliable separation of maternal and fetal DNA, the target selection was limited to genes that showed a stable, consistent methylation difference over a contiguous stretch of genomic DNA. This focused the analysis on genomic regions where multiple probes indicated differential methylation. The selection was also limited to target regions where all samples showed differential methylation, excluding those with strong inter-individual differences. Two of the samples showed generally lower log ratios in the microarray analysis. Because a paired test was used for target selection, this did not negatively impact the results. Based on these selection criteria, 3043 genomic regions were identified that were differentially methylated between maternal and fetal DNA. 21778 regions did not show a methylation difference. No inter-chromosomal bias in the distribution of differentially methylated regions was observed. The differentially methylated regions were located next to or within 2159 known genes. The majority of differentially methylated regions are located in the promoter area (18%) and inside the coding region (68%), while only few regions are located downstream of the gene (7%) or at the transition from promoter to coding region (7%). Regions that showed no differential methylation showed a similar distribution for promoter (13%) and downstream (5%) locations, but the fraction of regions located in the transition of promoter to coding region was higher (39%) and the fraction inside the coding region was lower (43%).

It has been shown in embryonic stem cells (ES) that genes targeted by the polycomb repressive complex2 (PRC2) are enriched for genes regulating development (Lee T I, et al. (2006) Control of developmental regulators by Polycomb in human embryonic stem cells. Cell 125:301-313). It has also been shown that differentially methylated genes are enriched for genes targeted by PRC2 in many cancer types (Ehrich M, et al. (2008) Cytosine methylation profiling of cancer cell lines. Proc Natl Acad Sci USA 105:4844-48). The set of genes identified as differentially methylated in this study is also enriched for genes targeted by PRC2 (p-value<0.001, odds ratio=3.6, 95% CI for odds ratio=3.1−4.2). A GO analysis of the set of differentially methylated genes reveals that this set is significantly enriched for functions important during development. Six out of the ten most enriched functions include developmental or morphogenic processes [anatomical structure morphogenesis (GO:0009653, p value=0), developmental process (GO:0032502, p value=0), multicellular organismal development (GO:0007275, p value=0), developmental of an organ (GO:0048513, p value=0), system development (GO:0048731, p value=0) and development of an anatomical structure (GO:0048856, p value=0)].

Validation using Sequenom® EpiTYPER™

To validate the microarray findings, 63 regions from chromosomes 13, 18 and 21 and an additional 26 regions from other autosomes were selected for confirmation by a different technology. Sequenom EpiTYPER™ technology was used to quantitatively measure DNA methylation in maternal and placental samples. For an explanation of the EpiTYPER™ methods, see Ehrich M, Nelson M R, Stanssens P, Zabeau M, Liloglou T, Xinarianos G, Cantor C R, Field J K, van den Boom D (2005) Quantitative high-throughput analysis of DNA methylation patterns by base specific cleavage and mass spectrometry. Proc Natl Acad Sci USA 102:15785-15790). For each individual CpG site in a target region the average methylation value across all maternal DNA samples and across all placenta samples was calculated. The difference between average maternal and placenta methylation was then compared to the microarray results. The results from the two technologies were in good concordance (see FIG. 7). For 85 target regions the quantitative results confirm the microarray results (95% confirmation rate). For 4 target regions, all located on chromosome 18, the results could not be confirmed. The reason for this discrepancy is currently unclear.

In contrast to microarrays, which focus on identification of methylation differences, the quantitative measurement of DNA methylation allowed analysis of absolute methylation values. In the validation set of 85 confirmed differentially methylated regions, a subset of 26 regions is more methylated in the maternal DNA sample and 59 regions are more methylated in the placental sample (see Table 1A). Interestingly, genes that are hypomethylated in the placental samples tend to show larger methylation differences than genes that are hypermethylated in the placental sample (median methylation difference for hypomethylated genes=39%, for hypermethylated genes=20%).

Example 2

Example 2 describes a non-invasive approach for detecting the amount of fetal nucleic acid present in a maternal sample (herein referred to as the “Fetal Quantifier Method”), which may be used to detect or confirm fetal traits (e.g., fetal sex of RhD compatibility), or diagnose chromosomal abnormalities such as Trisomy 21 (both of which are herein referred to as the “Methylation-Based Fetal Diagnostic Method”). FIG. 10 shows one embodiment of the Fetal Quantifier Method, and FIG. 11 shows one embodiment of the Methylation-Based Fetal Diagnostic Method. Both processes use fetal DNA obtained from a maternal sample. The sample comprises maternal and fetal nucleic acid that is differentially methylated. For example, the sample may be maternal plasma or serum. Fetal DNA comprises approximately 2-30% of the total DNA in maternal plasma. The actual amount of fetal contribution to the total nucleic acid present in a sample varies from pregnancy to pregnancy and can change based on a number of factors, including, but not limited to, gestational age, the mother's health and the fetus' health.

As described herein, the technical challenge posed by analysis of fetal DNA in maternal plasma lies in the need to be able to discriminate the fetal DNA from the co-existing background maternal DNA. The methods of the present invention exploit such differences, for example, the differential methylation that is observed between fetal and maternal DNA, as a means to enrich for the relatively small percentage of fetal DNA present in a sample from the mother. The non-invasive nature of the approach provides a major advantage over conventional methods of prenatal diagnosis such as, amniocentesis, chronic villus sampling and cordocentesis, which are associated with a small but finite risk of fetal loss. Also, because the method is not dependent on fetal cells being in any particular cell phase, the method provides a rapid detection means to determine the presence and also the nature of the chromosomal abnormality. Further, the approach is sex-independent (i.e., does not require the presence of a Y-chromosome) and polymorphic-independent (i.e., an allelic ratio is not determined). Thus, the compositions and methods of the invention represent improved universal, noninvasive approaches for accurately determining the amount of fetal nucleic acid present in a maternal sample.

Assay Design and Advantages

There is a need for accurate detection and quantification of fetal DNA isolated noninvasively from a maternal sample. The present invention takes advantage of the presence of circulating, cell free fetal nucleic acid (ccfDNA) in maternal plasma or serum. In order to be commercially and clinically practical, the methods of the invention should only consume a small portion of the limited available fetal DNA. For example, less than 50%, 40%, 30%, 25%, 20%, 15%, 10%, 5% or less of the sample. Further, the approach should preferably be developed in a multiplex assay format in which one or more (preferably all) of the following assays are included:

- Assays for the detection of total amount of genomic equivalents present in the sample, i.e., assays recognizing both maternal and fetal DNA species;
- Assays for the detection of fetal DNA isolated from a male pregnancy, i.e., sequences specific for chromosome Y;
- Assays specific for regions identified as differentially methylated between the fetus and mother; or
- Assays specific for regions known to be hypomethylated in all tissues to be investigated, which can serve as a control for restriction efficiency.

Other features of the assay may include one or more of the following:

- For each assay, a target-specific, competitor oligonucleotide that is identical, or substantially identical, to the target sequence apart from a distinguishable feature of the competitor, such as a difference in one or more nucleotides relative to the target sequence. This oligonucleotide when added into the PCR reaction will be co-amplified with the target and a ratio obtained between these two PCR amplicons will indicate the number of target specific DNA sequences (e.g., fetal DNA from a specific locus) present in the maternal sample.
- The amplicon lengths should preferably be of similar length in order not to skew the amplification towards the shorter fragments. However, as long as the amplification efficiency is about equal, different lengths may be used.
- Differentially methylated targets can be selected from Tables 1A-1C or from any other targets known to be differentially methylated between mother and fetus. These targets can be hypomethylated in DNA isolated from non-pregnant women and hypermethylated in samples obtained from fetal samples. These assays will serve as controls for the restriction efficiency.
- The results obtained from the different assays can be used to quantify one or more of the following:
  - Total number of amplifiable genomes present in the sample (total amount of genomic equivalents);
  - The fetal fraction of the amplifiable genomes (fetal concentration or percentage); or
  - Differences in copy number between fetally-derived DNA sequences (for example, between fetal chromosome 21 and a reference chromosome such as chromosome 3).

Examples of Assays Used in the Test

Below is an outline of the reaction steps used to perform a method of the invention, for example, as provided in FIG. 10. This outline is not intended to limit the scope of the invention. Rather it provides one embodiment of the invention using the Sequenom® MassARRAY® technology.

- 1) DNA isolation from plasma samples.
- 2) Digestion of the DNA targets using methylation sensitive restriction enzymes (for example, HhaI and HpaII).
- For each reaction the available DNA was mixed with water to a final volume of 25 ul.
- 10 ul of a reaction mix consisting of 10 units HhaI, 10 units HpaII and a reaction buffer were added. The sample was incubated at an optimal temperature for the restriction enzymes. HhaI and HpaII digest non-methylated DNA (and will not digest hemi- or completely methylated DNA). Following digestion, the enzymes were denatured using a heating step.
- 3) Genomic Amplification—PCR was performed in a total volume of 50 ul by adding PCR reagents (Buffer, dNTPs, primers and polymerase). Exemplary PCR and extend primers are provided below. In addition, synthetic competitor oligonucleotide was added at known concentrations.
- 4) Replicates (optional)—Following PCR the 50 ul reaction was split into 5 ul parallel reactions (replicates) in order to minimize variation introduced during the post PCR steps of the test. Post PCR steps include SAP, primer extension (MassEXTEND® technology), resin treatment, dispensing of spectrochip and MassARRAY.
- 5) Quantification of the Amplifiable Genomes—Sequenom MassARRAY® technology was used to determine the amount of amplification product for each assay. Following PCR, a single base extension assay was used to interrogate the amplified regions (including the competitor oligonucleotides introduced in step 3). Specific extend primers designed to hybridize directly adjacent to the site of interest were introduced. See extend primers provided below. These DNA oligonucleotides are referred to as iPLEX® MassEXTEND® primers. In the extension reaction, the iPLEX primers were hybridized to the complementary DNA templates and extended with a DNA polymerase. Special termination mixtures that contain different combinations of deoxy- and dideoxynucleotide triphosphates along with enzyme and buffer, directed limited extension of the iPLEX primers. Primer extension occurs until a complementary dideoxynucleotide is incorporated.
- The extension reaction generated primer products of varying length, each with a unique molecular weight. As a result, the primer extension products can be simultaneously separated and detected using Matrix Assisted Laser Desorption/Ionization, Time-Of-Flight (MALDI-TOF) mass spectrometry on the MassARRAY® Analyzer Compact. Following this separation and detection, SEQUENOM's proprietary software automatically analyzes the data.
- 6) Calculating the amount and concentration of fetal nucleic acid—Methods for calculating the total amount of genomic equivalents present in the sample, the amount (and concentration) of fetal nucleic acid isolated from a male pregnancy, and the amount (and concentration) of fetal nucleic based on differentially methylated targets are provided below and in FIGS. 18 and 19.

The above protocol can be used to perform one or more of the assays described below. In addition to the sequences provided immediately below, a multiplex scheme that interrogates multiple targets is provided in Table X below.

1) Assay for the Quantification of the Total Number of Amplifiable Genomic Equivalents in the Sample.

Targets were selected in housekeeping genes not located on the chromosomes 13, 18, 21, X or Y. The targets should be in a single copy gene and not contain any recognition sites for the methylation sensitive restriction enzymes.

Underlined sequences are PCR primer sites, italic is the site for the single base extend primer and bold letter (C) is the nucleotide extended on human DNA

ApoE Chromosome 19:45409835-45409922 DNA target

sequence with interrogated nucleotide C in bold.

All of the chromosome positions provided in this

section are from the February 2009 UCSC Genome

Build.

(SEQ ID NO: 262)

GATTGACAGTTTCTCCTTCCCCAGACTGGCCAATCACAGGCAGGAAGATG

AAGGTT
CTGTGGGCTGCGTTGCTGGTCACATTCCTGGC

ApoE Forward Primer:

(SEQ ID NO: 263)

5′-ACGTTGGATG-TTGACAGTTTCTCCTTCCCC

(Primer contains a 5′ 10 bp MassTag separated by

a dash)

ApoE Reverse Primer:

(SEQ ID NO: 264)

5′-ACGTTGGATG-GAATGTGACCAGCAACGCAG

(Primer contains a 5′ 10 bp MassTag separated by

a dash)

ApoE Extension Primer:

(SEQ ID NO: 265)

5′-GCAGGAAGATGAAGGTT[C/T]

Primer extends C on human DNA targets and T on

synthetic DNA targets

ApoE synthetic competitor oligonucleotide:

(SEQ ID NO: 266)

5′-GATTGACAGTTTCTCCTTCCCCAGACTGGCCAATCACAGGCAGGAAG

ATGAAGGTTTTGTGGGCTGCGTTGCTGGTCACATTCCTGGC

(Bold T at position 57 is different from human

DNA)

2) Assay for the Quantification of the Total Number of Chromosome Y Sequences in the Sample.

Targets specific for the Y-chromosome were selected, with no similar or paralog sequences elsewhere in the genome. The targets should preferably be in a single copy gene and not contain any recognition sites for the methylation sensitive restriction enzyme(s).

Underlined sequences are PCR primer sites, and italic nucleotide(s) is the site for the single-base extend primer and bold letter (C) is the nucleotide extended on human DNA.

SRY on chrY:2655628-2655717 (reverse complement)

(SEQ ID NO: 267)

GAGTTTTGGATAGTAAAATAAGTTTCGAACTCTGGCACCTTTCAATTTTG

TCGCACT
CTCCTTGTTTTTGACAATGCAATCATATGCTTC

SRY Forward Primer:

(SEQ ID NO: 268)

5′-ACG-TGGATAGTAAAATAAGTTTCGAACTCTG

(Primer contains a 5′ 3 bp MassTag separated by

a dash)

SRY Reverse Primer:

(SEQ ID NO: 269)

5′-GAAGCATATGATTGCATTGTCAAAAAC

SRY Extension Primer:

(SEQ ID NO: 270)

5′-aTTTCAATTTTGTCGCACT[C/T]

Primer extends C on human DNA targets and T on

synthetic DNA targets. 5′ Lower case “a” is a non-

complementary nucleotide

SRY synthetic competitor oligonucleotide:

(SEQ ID NO: 271)

5′-GAGTTTTGGATAGTAAAATAAGTTTCGAACTCTGGCACCTTTCAATT

TTGTCGCACTTTCCTTGTTTTTGACAATGCAATCATATGCTTC

3) Assay for the Quantification of Fetal Methylated DNA Sequences Present in the Sample.

Targets were selected in regions known to be differentially methylated between maternal and fetal DNA. Sequences were selected to contain several restriction sites for methylation sensitive enzymes. For this study the HhaI (GCGC) and HpaII (CCGG) enzymes were used.

Underlined sequences are PCR primer sites, italic is the site for the single base extend primer and bold letter (C) is the nucleotide extended on human DNA, lower case letter are recognition sites for the methylation sensitive restriction enzymes.

TBX3 on chr12:115124905-115125001

(SEQ ID NO: 272)

GAACTCCTCTTTGTCTCTGCGTGCccggcgcgcCCCCCTCccggTGGGTG

ATAAA
CCCACTCTGgcgccggCCATgcgcTGGGTGATTAATTTGCGA

TBX3 Forward Primer:

(SEQ ID NO: 273)

5′-ACGTTGGATG-TCTTTGTCTCTGCGTGCCC

(Primer contains a 5′ 10 bp MassTag separated by

a dash)

TBX3 Reverse Primer:

(SEQ ID NO: 274)

5′-ACGTTGGATG-TTAATCACCCAGCGCATGGC

(Primer contains a 5′ 10 bp MassTag separated by

a dash)

TBX3 Extension Primer:

(SEQ ID NO: 275)

5′-CCCCTCCCGGTGGGTGATAAA[C/T]

Primer extends C on human DNA targets and T on

synthetic DNA targets. 5′ Lower case “a” is a non-

complementary nucleotide

TBX3 synthetic competitor oligonucleotide:

(SEQ ID NO: 276)

5′-GAACTCCTCTTTGTCTCTGCGTGCCCGGCGCGCCCCCCTCCCGGTGG

GTGATAAATCCACTCTGGCGCCGGCCATGCGCTGGGTGATTAATTTGCGA

4) Control Assay for the Enzyme Restriction Efficiency.

Targets were selected in regions known not to be methylated in any tissue to be investigated. Sequences were selected to contain no more than one site for each restriction enzyme to be used.

Underlined sequences are PCR primer sites, italic nucleotide(s) represent the site for the single-base extend primer and bold letter (G) is the reverse nucleotide extended on human DNA, lower case letter are recognition sites for the methylation sensitive restriction enzymes.

CACNA1G chr17:48637892-48637977 (reverse

complement)

(SEQ ID NO: 277)

CCATTGGCCGTCCGCCGTGGCAGTGCGGGCGGGAgcgcAGGGAGAGAACCA

CAGCTGGAATCCGATTCCCACCCCAAAACCCAGGA

HhaI Forward Primer:

(SEQ ID NO: 278)

5′-ACGTTGGATG-CCATTGGCCGTCCGCCGTG

(Primer contains a 5′ 10 bp MassTag separated by a

dash)

HhaI Reverse Primer:

(SEQ ID NO: 279)

5′-ACGTTGGATG-TCCTGGGTTTTGGGGTGGGAA

(Primer contains a 5′ 10 bp MassTag separated by a

dash)

HhaI Extension Primer:

(SEQ ID NO: 280)

5′-TTCCAGCTGTGGTTCTCTC

HhaI synthetic competitor oligonucleotide:

(SEQ ID NO: 281)

5′-CCATTGGCCGTCCGCCGTGGCAGTGCGGGCGGGAGCGCAGAGAGAGAA

CCACAGCTGGAATCCGATTCCCACCCCAAAACCCAGGA

Validation Experiments

The sensitivity and accuracy of the present invention was measured using both a model system and clinical samples. In the different samples, a multiplex assay was run that contains 2 assays for total copy number quantification, 3 assays for methylation quantification, 1 assay specific for chromosome Y and 1 digestion control assay. See Table X. Another multiplex scheme with additional assays is provided in Table Y.

TABLE X

PCR Primers and Extend Primers

Table X discloses ‘First Primer’ as

SEQ ID NOS 282-288, ‘Second Primer’ as

SEQ ID NOS 289-295, and ‘Extend Primer’

as SEQ ID NOS 296-302, respectively,

in order of appearance.

First
Second
Extend

Gene ID
*
Primer
Primer
Primer

SOX14
M
ACGTTGGATG
ACGTTGGATG
CAGGTTCCGG

ACATGGTCGG
CTCCTTCCTA
GGCTTGGG

CCCCACGGAA
GTGTGAGAAC

T
CG

HhaI_CTRL
D
ACGTTGGATG
ACGTTGGATG
CGCAGGGAGA

ACCCATTGGC
TTTTGGGGTG
GAACCACAG

CGTCCGCCGT
GGAATCGGAT

T

TBX3
M
ACGTTGGATG
ACGTTGGATG
CCCCTCCCGG

GAACTCCTCT
TGGCATGGCC
TGGGTGATAA

TTGTCTCTGC
GGCGCCAGA
A

G

SRY
Y
ACGTTGGATG
ACGTTGGCAT
AAAGCTGTAG

CGCAGCAACG
CTAGGTAGGT
GACAATCGGG

GGACCGCTAC
CTTTGTAGCC
T

A
AA

ALB
T
ACGTTGCGTA
ACGTTGGATC
CATTTTTCTA

GCAACCTGTT
TGAGCAAAGG
CATCCTTTGT

ACATATTAA
CAATCAACAC
TT

CC

EDG6
M
ACGTTGGATG
ACGTTGGATG
agAAGATCAC

CATAGAGGCC
ACCTTCTGCC
CAGGCAGAAG

CATGATGGTG
CCTCTACTCC
AGG

G
AA

RNaseP
T
ACGTTGGATG
ACGTTGGCCC
ACTTGGAGAA

GTGTGGTCAG
ACATGTAATG
CAAAGGACAC

CTCTTCCCTT
TGTTGAAAAA
CGTTA

CAT
GCA

TABLE X

Competitor Oligonucleotide Sequence

Table X discloses SEQ ID NOS 303-309,

respectively, in order of appearance.

Gene ID
*
Competitor Oligonucleotide Sequence

SOX14
M
GGTCGGCCCCACGGAATCCCGGCTCTGTGTGCGCC

CAGGTTCCGGGGCTTGGGTGTTGCCGGTTCTCACA

CTAGGAAGGAG

HhaI_CTRL
D
CCATTGGCCGTCCGCCGTGGCAGTGCGGGCGGGAG

CGCAGAGAGAGAACCACAGCTGGAATCCGATTCCC

ACCCCAAAA

TBX3
M
GAACTCCTCTTTGTCTCTGCGTGCCCGGCGCGCCC

CCCTCCCGGTGGGTGATAAATCCACTCTGGCGCCG

GCCATGC

SRY
Y
GCAGCAACGGGACCGCTACAGCCACTGGACAAAGC

CGTAGGACAATCGGGTAACATTGGCTACAAAGACC

TACCTAGATGC

ALB
T
GCGTAGCAACCTGTTACATATTAAAGTTTTATTAT

ACTACATTTTTCTACATCCTTTGTTTCAGAGTGTT

GATTGCCTTTGCTCAGTATCTTCAG

EDG6
M
CCTTCTGCCCCTCTACTCCAAGCGCTACACCCTCT

TCTGCCTGGTGATCTTTGCCGGCGTCCTGGCCACC

ATCATGGGCCTCTATG

RNaseP
T
GTGTGGTCAGCTCTTCCCTTCATCACATACTTGGA

GAACAAAGGACACCGTTATCCATGCTTTTTCAACA

CATTACATGTGGG

TABLE Y

PCR Primers and Extend Primers

Table Y discloses ‘First Primer’ as SEQ ID NOS

310-319, ‘Second Primer’ as SEQ ID NOS 320-329,

and ‘Extend Primer’ as SEQ ID NOS 330-339,

respectively, in order of appearance.

First
Second
Extend

Gene ID
*
Primer
Primer
Primer

EDG6
M
ACGTTGGATG
ACGTTGGATG
TTCTGCCTGG

TTCTGCCCCT
CATAGAGGCC
TGATCTT

CTACTCCAAG
CATGATGGTG

RNAseP
T
ACGTTGGATG
ACGTTGGATG
AACAAAGGAC

TCAGCTCTTC
CCTACCTCCC
ACCGTTA

CCTTCATCAC
ACATGTAATG

T

ApoE
T
ACGTTGGATG
ACGTTGGATG
GCAGGAAGAT

TTGACAGTTT
GAATGTGACC
GAAGGTT

CTCCTTCCCC
AGCAACGCAG

SOX14
M
ACGTTGGATG
ACGTTGGATG
aAGGTTCCGG

CGGTCGGCCC
CTCCTTCCTA
GGCTTGGG

CACGGAAT
GTGTGAGAAC

CG

SRY no2
Y
ACGTGGATAG
GAAGCATATG
aTTTCAATTT

TAAAATAAGT
ATTGCATTGT
TGTCGCACT

TTCGAACTCT
CAAAAAC

G

SRY no1
Y
ACGTTGGATG
ACGTTGGATG
AGCTGTAGGA

CACAGCTCAC
CTAGGTAGGT
CAATCGGGT

CGCAGCAACG
CTTTGTAGCC

AA

TBX3
M
ACGTTGGATG
ACGTTGGATG
CCCTCCCGGT

TCTTTGTCTC
TTAATCACCC
GGGTGATAAA

TGCGTGCCC
AGCGCATGGC

CACNA1G
D
ACGTTGGATG
ACGTTGGATG
AGGGCCGGGG

dig

GACTGAGCCC
GTGGGTTTGT
TCTGCGCGTG

CTRL 1

CAGAACTCG
GCTTTCCACG

DAPK1
D
ACGTTGGATG
ACGTTGGATG
GAGGCACTGC

dig

AAGCCAAGTT
CTTTTGCTTT
CCGGACAAAC

CTRL 2

TCCCTCCGC
CCCAGCCAGG
C

ALB
T
ACGTTAGCGT
ACGTTGGATG
CATTTTTCTA

AGCAACCTGT
CTGAGCAAAG
CATCCTTTGT

TACATATTAA
GCAATCAACA
TT

TABLE Y

Competitor Oligonucleotide Sequence

Table Y discloses SEQ ID NOS 340-349,

respectively, in order of appearance.

Gene ID
*
Competitor

EDG6
M
CCTTCTGCCCCTCTACTCCAAGCGCTACACCCTCT

TCTGCCTGGTGATCTTTGCCGGCGTCCTGGCCACC

ATCATGGGCCTCTATG

RNAseP
T
GTGTGGTCAGCTCTTCCCTTCATCACATACTTGGA

GAACAAAGGACACCGTTATCCATGCTTTTTCAACA

CATTACATGTGGGAGGTAGG

ApoE
T
GATTGACAGTTTCTCCTTCCCCAGACTGGCCAATC

ACAGGCAGGAAGATGAAGGTTTTGTGGGCTGCGTT

GCTGGTCACATTCCTGGC

SOX14
M
AAAACCAGAGATTCGCGGTCGGCCCCACGGAATCC

CGGCTCTGTGTGCGCCCAGGTTCCGGGGCTTGGGT

GTTGCCGGTTCTCACACTAGGAAGGAGC

SRY no2
Y
GAGTTTTGGATAGTAAAATAAGTTTCGAACTCTGG

CACCTTTCAATTTTGTCGCACTTTCCTTGTTTTTG

ACAATGCAATCATATGCTTC

SRY no1
Y
GCAGCCAGCTCACCGCAGCAACGGGACCGCTACAG

CCACTGGACAAAGCTGTAGGACAATCGGGTGACAT

TGGCTACAAAGACCTACCTAGATGC

TBX3
M
GAACTCCTCTTTGTCTCTGCGTGCCCGGCGCGCCC

CCCTCCCGGTGGGTGATAAATCCACTCTGGCGCCG

GCCATGCGCTGGGTGATTAATTTGCGA

CACNA1G
D
GTGGGTTTGTGCTTTCCACGCGTGCACACACACGC

dig CTRL

GCAGACCCCGGCCCTTGCCCCGCCTACCTCCCCGA

1

GTTCTGGGGCTCAGTC

DAPK1
D
GCGCCAGCTTTTGCTTTCCCAGCCAGGGCGCGGTG

dig

AGGTTTGTCCGGGCAGTGCCTCGAGCAACTGGGAA

CTRL 2

GGCCAAGGCGGAGGGAAAC

ALB
T
GCGTAGCAACCTGTTACATATTAAAGTTTTATTAT

ACTACATTTTTCTACATCCTTTGTTTTAGGGTGTT

GATTGCCTTTGCTCAGTATCTTCAGC

T = Assay for Total Amount

M = Assay for Methylation quantification

Y = Y-Chromosome Specific Assay

D = Digestion control

Model System Using Genomic DNA

In order to determine the sensitivity and accuracy of the method when determining the total number of amplifiable genomic copies in a sample, a subset of different DNA samples isolated from the blood of non-pregnant women was tested. Each sample was diluted to contain approximately 2500, 1250, 625 or 313 copies per reaction. The total number of amplifiable genomic copies was obtained by taking the mean DNA/competitor ratio obtained from the three total copy number assays. The results from the four different samples are shown in FIG. 12.

To optimize the reaction, a model system was developed to simulate DNA samples isolated from plasma. These samples contained a constant number of maternal non-methylated DNA and were spiked with different amounts of male placental methylated DNA. The samples were spiked with amounts ranging from approximately 0 to 25% relative to the maternal non-methylated DNA. The results are shown in FIGS. 13A and B. The fraction of placental DNA was calculated using the ratios obtained from the methylation assays (FIG. 13A), the SRY markers (FIG. 13B) and the total copy number assays. The primer sequences for the methylation assays (TBX), Y-chromosome assays (SRY) and total copy number (APOE) are provided above. The model system demonstrated that the methylation-based method performed equal to the Y-chromosome method (SRY markers), thus validating the methylation-based method as a sex-independent fetal quantifier.

Plasma Samples

To investigate the sensitivity and accuracy of the methods in clinical samples, 33 plasma samples obtained from women pregnant with a male fetus were investigated using the multiplex scheme from Table X. For each reaction, a quarter of the DNA obtained from a 4 ml extraction was used in order to meet the important requirement that only a portion of the total sample is used.

Total Copy Number Quantification

The results from the total copy number quantification can be seen in FIGS. 14A and B. In FIG. 14A, the copy number for each sample is shown. Two samples (nos. 25 and 26) have a significantly higher total copy number than all the other samples. In general, a mean of approximately 1300 amplifiable copies/ml plasma was obtained (range 766-2055). FIG. 14B shows a box-and-whisker plot of the given values, summarizing the results.

Correlation Between Results Obtained from the Methylation Markers and the Y-Chromosome Marker

In FIGS. 15A and B, the numbers of fetal copies for each sample are plotted. As all samples were from male pregnancies. The copy numbers obtained can be calculated using either the methylation or the Y-chromosome-specific markers. As can be seen in FIG. 15B, the box-and-whisker plot of the given values indicated minimal difference between the two different measurements.

The results showing the correlation between results obtained from the methylation markers and the Y-chromosome marker (SRY) is shown in FIG. 16. Again, the methylation-based method performed equal to the Y-chromosome method (SRY markers), further validating the methylation-based method as a sex-independent and polymorphism-independent fetal quantifier. The multiplexed assays disclosed in Table X were used to determine the amount fetal nucleic.

Finally, the digestion efficiency was determined by using the ratio of digestion for the control versus the competitor and comparing this value to the mean total copy number assays. See FIG. 17. Apart from sample 26 all reactions indicate the efficiency to be above 99%.

Data Analysis

Mass spectra analysis was done using Typer 4 (a Sequenom software product). The peak height (signal over noise) for each individual DNA analyte and competitor assay was determined and exported for further analysis.

The total number of molecules present for each amplicon was calculated by dividing the DNA specific peak by the competitor specific peak to give a ratio. (The “DNA” Peak in FIGS. 18 and 19 can be thought of as the analyte peak for a given assay). Since the number of competitor molecules added into the reaction is known, the total number of DNA molecules can be determined by multiplying the ratio by the number of added competitor molecules.

The fetal DNA fraction (or concentration) in each sample was calculated using the Y-chromosome-specific markers for male pregnancies and the mean of the methylated fraction for all pregnancies. In brief, for chromosome Y, the ratio was obtained by dividing the analyte (DNA) peak by the competitor peak and multiplying this ratio by the number of competitor molecules added into the reaction. This value was divided by a similar ratio obtained from the total number of amplifiable genome equivalents determination (using the Assay(s) for Total Amount). See FIG. 18. Since the total amount of nucleic acid present in a sample is a sum of maternal and fetal nucleic acid, the fetal contribution can be considered to be a fraction of the larger, background maternal contribution. Therefore, translating this into the equation shown in FIG. 18, the fetal fraction (k) of the total nucleic acid present in the sample is equal to the equation: k=2×R/(1−2R), where R is the ratio between the Y-chromosome amount and the total amount. Since the Y-chromosome is haploid and Assays for the Total Amount are determined using diploid targets, this calculation is limited to a fetal fraction smaller than 50% of the maternal fraction.

In FIG. 19, a similar calculation for the fetal concentration is shown by using the methylation specific markers (see Assays for Methylation Quantification). In contrast to Y-chromosome specific markers, these markers are from diploid targets, therefore, the limitations stated for the Y-Chromosome Specific Assay can be omitted. Thus, the fetal fraction (k) can be determined using the equation: k=R(1−R), where R is the ratio between the methylation assay and the total assay.

Simulation

A first simple power calculation was performed that assumes a measurement system that uses 20 markers from chromosome 21, and 20 markers from one or more other autosomes. Starting with 100 copies of fetal DNA, a measurement standard deviation of 25 copies and the probability for a type I error to be lower than 0.001, it was found that the methods of the invention will be able to differentiate a diploid from a triploid chromosome set in 99.5% of all cases. The practical implementation of such an approach could for example be achieved using mass spectrometry, a system that uses a competitive PCR approach for absolute copy number measurements. The method can run 20 assays in a single reaction and has been shown to have a standard deviation in repeated measurements of around 3 to 5%. This method was used in combination with known methods for differentiating methylated and non-methylated nucleic acid, for example, using methyl-binding agents to separate nucleic acid or using methylation-sensitive enzymes to digest maternal nucleic acid. FIG. 8 shows the effectiveness of MBD-FC protein (a methyl-binding agent) for capturing and thereby separating methylated DNA in the presence of an excess of unmethylated DNA (see FIG. 8).

A second statistical power analysis was performed to assess the predictive power of an embodiment of the Methylation-Based Fetal Diagnostic Method described herein. The simulation was designed to demonstrate the likelihood of differentiating a group of trisomic chromosome 21 specific markers from a group of reference markers (for example, autosomes excluding chromosome 21). Many parameters influence the ability to discriminate the two populations of markers reliably. For the present simulation, values were chosen for each parameter that have been shown to be the most likely to occur based on experimentation. The following parameters and respective values were used:

Copy Numbers

Maternal copy numbers=2000

Fetal copy numbers for chromosomes other than 21, X and Y=200

Fetal copy numbers for chromosome 21 in case of euploid fetus=200

Fetal copy numbers for chromosome 21 in case of aneuploid T21 fetus=300

Percent fetal DNA (before methylation-based enrichment)=10% (see above)

Methylation Frequency

Average methylation percentage in a target region for maternal DNA=10%

Average methylation percentage in a target region for fetal DNA=80%

Average percentage of non-methylated and non-digested maternal DNA (i.e., a function of restriction efficiency (among other things)=5%

Number of assays targeting chromosome 21=10

Number of assays targeting chromosomes other than 21, X and Y=10

The results are displayed in FIG. 20. Shown is the relationship between the coefficient of variation (CV) on the x-axis and the power to discriminate the assay populations using a simple t-test (y-axis). The data indicates that in 99% of all cases, one can discriminate the two population (euploid vs. aneuploid) on a significance level of 0.001 provided a CV of 5% or less. Based on this simulation, the method represents a powerful noninvasive diagnostic method for the prenatal detection of fetal aneuploidy that is sex-independent and will work in all ethnicities (i.e., no allelic bias).

Example 3—Additional Differentially-Methylated Targets
Differentially-Methylated Targets not Located on Chromosome 21

Additional differentially-methylated targets were selected for further analysis based upon previous microarray analysis. See Example 1 for a description of the microarray analysis. During the microarray screen, differentially methylated regions (DMRs) were defined between placenta tissue and PBMC. Regions were selected for EpiTYPER confirmation based upon being hypermethylated in placenta relative to PBMC. After directionality of the change was selected for, regions were chosen based upon statistical significance with regions designed beginning with the most significant and working downward in terms of significance. These studies were performed in eight paired samples of PBMC and placenta. Additional non-chromosome 21 targets are provided in Table 1B, along with a representative genomic sequence from each target in Table 4B.

Differentially-Methylated Targets Located on Chromosome 21

The microarray screen uncovered only a subset of DMRs located on chromosome 21. The coverage of chromosome 21 by the microarray, however, was insufficient. Therefore a further analysis was completed to examine all 356 CpG islands on chromosome 21 using the standard settings of the UCSC genome browser. As shown in Table 1C below, some of these targets overlapped with those already examined in Table 1A. More specifically, CpG sites located on chromosome 21 including ˜1000 bp upstream and downstream of each CpG was investigated using Sequenom's EpiTYPER® technology. See Example 1, “Validation using Sequenom® EpiTYPER™” for a description of Sequenom's EpiTYPER® technology. These studies were performed in eight paired samples of PBMC and placenta. In addition, since DMRs may also be located outside of defined CpG islands, data mining was performed on publicly available microarray data to identify potential candidate regions with the following characteristics: hypermethylated in placenta relative to maternal blood, not located in a defined CpG island, contained greater than 4 CpG dinucleotides, and contained a recognition sequence for methylation sensitive restriction enzymes. Regions that met these criteria were then examined using Sequenom's EpiTYPER® technology on eight paired PBMC and placenta samples. Additional chromosome 21 targets are provided in Table 1C, along with a representative genomic sequence from each target in Table 4C.

Tables 1B and 1C provide a description of the different targets, including their location and whether they were analyzed during the different phases of analysis, namely microarray analysis, EpiTYPER 8 analysis and EpiTYPER 73 analysis. A “YES” indicates it was analyzed and a “NO” indicates it was not analyzed. The definition of each column in Table 1B and 1C is listed below.

- Region Name: Each region is named by the gene(s) residing within the area defined or nearby. Regions where no gene name is listed but rather only contain a locus have no refseq genes in near proximity.
- Gene Region: For those regions contained either in close proximity to or within a gene, the gene region further explains the relationship of this region to the nearby gene.
- Chrom: The chromosome on which the DMR is located using the hg18 build of the UCSC genome browser.
- Start: The starting position of the DMR as designated by the hg18 build of the UCSC genome browser.
- End: The ending position of the DMR as designated by the hg18 build of the UCSC genome browser.
- Microarray Analysis: Describes whether this region was also/initially determined to be differentially methylated by microarray analysis. The methylated fraction of ten paired placenta and PBMC samples was isolated using the MBD-Fc protein. The two tissue fractions were then labeled with either Alexa Fluor 555-aha-dCTP (PBMC) or Alexa Fluor 647-aha-dCTP (placental) using the BioPrime Total Genomic Labeling System™ and hybridized to Agilent® CpG Island microarrays. Many regions examined in these studies were not contained on the initial microarray.
- EpiTYPER 8 Samples: Describes whether this region was analyzed and determined to be differentially methylated in eight paired samples of placenta and peripheral blood mononuclear cells (PBMC) using EpiTYPER technology. Regions that were chosen for examination were based on multiple criteria. First, regions were selected based on data from the Microarray Analysis. Secondly, a comprehensive examination of all CpG islands located on chromosome 21 was undertaken. Finally, selected regions on chromosome 21 which had lower CpG frequency than those located in CpG islands were examined.
- EpiTYPER 73 Samples: Describes whether this region was subsequently analyzed using EpiTYPER technology in a sample cohort consisting of 73 paired samples of placenta and PBMC. All regions selected for analysis in this second sample cohort were selected based on the results from the experimentation described in the EpiTYPER 8 column. More specifically, the regions in this additional cohort exhibited a methylation profile similar to that determined in the EpiTYPER 8 Samples analysis. For example, all of the regions listed in Tables 1B-1C exhibit different levels of DNA methylation in a significant portion of the examined CpG dinucleotides within the defined region. Differential DNA methylation of CpG sites was determined using a paired T Test with those sites considered differentially methylated if the p-value (when comparing placental tissue to PBMC) is p<0.05.
- Previously Validated EpiTYPER: Describes whether this region or a portion of this region was validated using EpiTYPER during previous experimentation. (See Examples 1 and 2).
- Relative Methylation Placenta to Maternal: Describes the direction of differential methylation. Regions labeled as “hypermethylation” are more methylated within the designated region in placenta samples relative to PBMC and “hypomethylation” are more methylated within the designated region in PBMC samples.

TABLE 1A

MEAN

METHYLATION
RELATIVE

MEAN
MATERNAL
MEAN PLACENTA
DIFFERENCE
METHYLATION

LOG RATIO
METHYLATION
METHYLATION
PLACENTA-
PLACENTA TO

GENE NAME
CHROM
START
END
CpG ISLAND
MICRO-ARRAY
EPITYPER
EPITYPER
MATERNAL
MATERNAL

chr13 group00016
chr13
19773745
19774050
chr13: 19773518-19774214
0.19
0.22
0.32
0.1
HYPERMETHYLATION

chr13 group00005
chr13
19290394
19290768
: —
−0.89
0.94
0.35
−0.59
HYPOMETHYLATION

CRYL1
chr13
19887090
19887336
chr13: 19887007-19887836
−0.63
0.74
0.21
−0.53
HYPOMETHYLATION

IL17D
chr13
20193675
20193897
chr13: 20193611-20194438
−1.01
0.53
0.13
−0.39
HYPOMETHYLATION

CENPJ
chr13
24404023
24404359
: —
0.57
0.17
0.49
0.32
HYPERMETHYLATION

ATP8A2
chr13
25484475
25484614
chr13: 25484287-25484761
0.81
0.16
0.43
0.27
HYPERMETHYLATION

GSH1
chr13
27265542
27265834
chr13: 27264549-27266505
0.57
0.13
0.19
0.05
HYPERMETHYLATION

PDX1
chr13
27393789
27393979
chr13: 27392001-27394099
0.55
0.06
0.2
0.14
HYPERMETHYLATION

PDX1
chr13
27400459
27401165
chr13: 27400362-27400744;
0.73
0.12
0.26
0.14
HYPERMETHYLATION

chr13: 27401057-27401374

MAB21L1
chr13
34947737
34948062
chr13: 34947570-34948159
0.66
0.11
0.17
0.06
HYPERMETHYLATION

RB1
chr13
47790983
47791646
chr13: 47790636-47791858
0.18
0.45
0.48
0.03
HYPERMETHYLATION

PCDH17
chr13
57104856
57106841
chr13: 57104527-57106931
0.46
0.15
0.21
0.06
HYPERMETHYLATION

KLHL1
chr13
69579933
69580146
chr13: 69579733-69580220
0.79
0.09
0.28
0.2
HYPERMETHYLATION

POU4F1
chr13
78079515
78081073
chr13: 78079328-78079615;
0.66
0.12
0.23
0.11
HYPERMETHYLATION

chr13: 78080860-78081881

GPC6
chr13
92677402
92678666
chr13: 92677246-92678878
0.66
0.06
0.19
0.13
HYPERMETHYLATION

SOX21
chr13
94152286
94153047
chr13: 94152190-94153185
0.94
0.16
0.4
0.25
HYPERMETHYLATION

ZIC2
chr13
99439660
99440858
chr13: 99439335-99440189;
0.89
0.13
0.35
0.22
HYPERMETHYLATION

chr13: 99440775-99441095

IRS2
chr13
109232856
109235065
chr13: 109232467-109238181
−0.17
0.73
0.38
−0.35
HYPOMETHYLATION

chr13 group00350
chr13
109716455
109716604
chr13: 109716325-109716726
−0.37
0.77
0.41
−0.36
HYPOMETHYLATION

chr13 group00385
chr13
111595578
111595955
chr13: 111595459-111596131
0.87
0.06
0.2
0.14
HYPERMETHYLATION

chr13 group00390
chr13
111756337
111756593
chr13: 111755805-111756697
0.71
0.12
0.34
0.22
HYPERMETHYLATION

chr13 group00391
chr13
111759856
111760045
chr13: 111757885-111760666
0.86
0.11
0.36
0.25
HYPERMETHYLATION

chr13 group00395
chr13
111808255
111808962
chr13: 111806599-111808492;
0.96
0.13
0.35
0.22
HYPERMETHYLATION

chr13: 111808866-111809114

chr13 group00399
chr13
112033503
112033685
chr13: 112032967-112033734
0.38
0.26
0.43
0.18
HYPERMETHYLATION

MCF2L
chr13
112724910
112725742
chr13: 112724782-112725121;
−0.47
0.91
0.33
−0.58
HYPOMETHYLATION

chr13: 112725628-112725837

F7
chr13
112799123
112799379
chr13: 112798487-112799566
−0.05
0.97
0.55
−0.41
HYPOMETHYLATION

PROZ
chr13
112855566
112855745
chr13: 112855289-112855866
0.29
0.15
0.3
0.16
HYPERMETHYLATION

chr18 group00039
chr18
6919797
6919981
chr18: 6919450-6920088
−0.38
0.88
0.39
−0.49
HYPOMETHYLATION

CIDEA
chr18
12244327
12244696
chr18: 12244147-12245089
0.23
0.14
0.23
0.1
HYPERMETHYLATION

chr18 group00091
chr18
12901467
12901643
chr18: 12901024-12902704
0.16
0.15
0.43
0.29
HYPERMETHYLATION

chr18 group00094
chr18
13126819
13126986
chr18: 13126596-13127564
0.41
0.07
0.34
0.27
HYPERMETHYLATION

C18orf1
chr18
13377536
13377654
chr18: 13377385-13377686
−0.12
0.95
0.69
−0.26
HYPOMETHYLATION

KLHL14
chr18
28603978
28605183
chr18: 28603688-28606300
0.83
0.07
0.19
0.12
HYPERMETHYLATION

CD33L3
chr18
41671477
41673011
chr18: 41671386-41673101
−0.34
0.49
0.44
−0.05
HYPOMETHYLATION

ST8SIA3
chr18
53171265
53171309
chr18: 53170705-53172603
1.02
0.09
0.25
0.16
HYPERMETHYLATION

ONECUT2
chr18
53254808
53259810
chr18: 53254152-53259851
0.74
0.09
0.23
0.14
HYPERMETHYLATION

RAX
chr18
55086286
55086436
chr18: 55085813-55087807
0.88
0.11
0.26
0.16
HYPERMETHYLATION

chr18 group00277
chr18
57151972
57152311
chr18: 57151663-57152672
0.58
0.08
0.21
0.13
HYPERMETHYLATION

TNFRSF11A
chr18
58203013
58203282
chr18: 58202849-58203367
−0.33
0.88
0.28
−0.6
HYPOMETHYLATION

NETO1
chr18
68685099
68687060
chr18: 68684945-68687851
0.65
0.09
0.22
0.13
HYPERMETHYLATION

chr18 group00304
chr18
70133945
70134397
chr18: 70133732-70134724
0.12
0.93
0.92
−0.01
NOT CONFIRMED

TSHZ1
chr18
71128742
71128974
chr18: 71128638-71129076
0.23
0.95
0.92
−0.03
NOT CONFIRMED

ZNF236
chr18
72664454
72664736
chr18: 72662797-72664893
−0.62
0.17
0.1
−0.07
HYPOMETHYLATION

MBP
chr18
72953150
72953464
chr18: 72953137-72953402
0.6
0.44
0.72
0.28
HYPERMETHYLATION

chr18 group00342
chr18
74170347
74170489
chr18: 74170210-74170687
−0.2
0.78
0.48
−0.3
HYPOMETHYLATION

NFATC1
chr18
75385424
75386008
chr18: 75385279-75386532
0.23
0.14
0.84
0.7
HYPERMETHYLATION

CTDP1
chr18
75596358
75596579
chr18: 75596009-75596899
0.07
0.97
0.96
−0.01
NOT CONFIRMED

chr18 group00430
chr18
75653272
75653621
: —
0.52
0.24
0.62
0.39
HYPERMETHYLATION

KCNG2
chr18
75760343
75760820
chr18: 75759900-75760988
0.01
0.84
0.75
−0.09
NOT CONFIRMED

OLIG2
chr21
33317673
33321183
chr21: 33316998-33322115
0.66
0.11
0.2
0.09
HYPERMETHYLATION

OLIG2
chr21
33327593
33328334
chr21: 33327447-33328408
−0.75
0.77
0.28
−0.49
HYPOMETHYLATION

RUNX1
chr21
35180938
35185436
chr21: 35180822-35181342;
−0.68
0.14
0.07
−0.07
HYPOMETHYLATION

chr21: 35182320-35185557

SIM2
chr21
36994965
36995298
chr21: 36990063-36995761
0.83
0.08
0.26
0.18
HYPERMETHYLATION

SIM2
chr21
36999025
36999410
chr21: 36998632-36999555
0.87
0.06
0.24
0.18
HYPERMETHYLATION

DSCR6
chr21
37300407
37300512
chr21: 37299807-37301307
0.22
0.04
0.14
0.11
HYPERMETHYLATION

DSCAM
chr21
41135559
41135706
chr21: 41135380-41135816
1.03
0.06
0.29
0.23
HYPERMETHYLATION

chr21 group00165
chr21
43643421
43643786
chr21: 43643322-43643874
1.14
0.16
0.81
0.65
HYPERMETHYLATION

AIRE
chr21
44529935
44530388
chr21: 44529856-44530472
−0.55
0.62
0.27
−0.35
HYPOMETHYLATION

SUMO3
chr21
45061293
45061853
chr21: 45061154-45063386
−0.41
0.55
0.46
−0.09
HYPOMETHYLATION

C21orf70
chr21
45202815
45202972
chr21: 45202706-45203073
−0.46
0.96
0.51
−0.46
HYPOMETHYLATION

C21orf123
chr21
45671984
45672098
chr21: 45671933-45672201
−0.63
0.92
0.43
−0.49
HYPOMETHYLATION

COL18A1
chr21
45754383
45754487
chr21: 45753653-45754639
−0.18
0.97
0.72
−0.25
HYPOMETHYLATION

PRMT2
chr21
46911967
46912385
chr21: 46911628-46912534
1.08
0.04
0.25
0.21
HYPERMETHYLATION

SIX2
chr2
45081223
45082129
chr2: 45081148-45082287
1.15
0.08
0.36
0.28
HYPERMETHYLATION

SIX2
chr2
45084851
45085711
chr2: 45084715-45084986;
1.21
0.07
0.35
0.28
HYPERMETHYLATION

chr2: 45085285-45086054

SOX14
chr3
138971870
138972322
chr3: 138971738-138972096;
1.35
0.08
0.33
0.25
HYPERMETHYLATION

chr3: 138972281-138973691

TLX3
chr5
170674439
170676431
chr5: 170674208-170675356;
0.91
0.11
0.35
0.24
HYPERMETHYLATION

chr5: 170675783-170676712

FOXP4
chr6
41623666
41624114
chr6: 41621630-41624167
1.1
0.07
0.27
0.2
HYPERMETHYLATION

FOXP4
chr6
41636384
41636779
chr6: 41636244-41636878
1.32
0.04
0.33
0.29
HYPERMETHYLATION

chr7 group00267
chr7
12576755
12577246
chr7: 12576690-12577359
0.94
0.08
0.26
0.17
HYPERMETHYLATION

NPY
chr7
24290224
24291508
chr7: 24290083-24291605
0.93
0.09
0.3
0.21
HYPERMETHYLATION

SHH
chr7
155291537
155292091
chr7: 155288453-155292175
0.98
0.19
0.52
0.33
HYPERMETHYLATION

OSR2
chr8
100029764
100030536
chr8: 100029673-100030614
1.21
0.08
0.43
0.35
HYPERMETHYLATION

GLIS3
chr9
4288283
4289645
chr9: 4287817-4290182
1.24
0.06
0.24
0.18
HYPERMETHYLATION

PRMT8
chr12
3472714
3473190
chr12: 3470227-3473269
0.86
0.07
0.23
0.16
HYPERMETHYLATION

TBX3
chr12
113609153
113609453
chr12: 113609112-113609535
1.45
0.09
0.56
0.48
HYPERMETHYLATION

chr12 group00801
chr12
118516189
118517435
chr12: 118515877-118517595
1.1
0.06
0.25
0.19
HYPERMETHYLATION

PAX9
chr14
36201402
36202386
chr14: 36200932-36202536
0.89
0.11
0.32
0.21
HYPERMETHYLATION

SIX1
chr14
60178801
60179346
chr14: 60178707-60179539
0.95
0.1
0.33
0.22
HYPERMETHYLATION

ISL2
chr15
74420013
74421546
chr15: 74419317-74422570
1.08
0.08
0.27
0.19
HYPERMETHYLATION

DLX4
chr17
45397228
45397930
chr17: 45396281-45398063
1.25
0.1
0.32
0.22
HYPERMETHYLATION

CBX4
chr17
75428613
75431793
chr17: 75427586-75433676
1
0.07
0.27
0.21
HYPERMETHYLATION

EDG6
chr19
3129836
3130874
chr19: 3129741-3130986
1.35
0.04
0.87
0.83
HYPERMETHYLATION

PRRT3
chr3
9963364
9964023
chr3: 9962895-9964619
−0.85
0.9
0.09
−0.81
HYPOMETHYLATION

MGC29506
chr5
138757911
138758724
chr5: 138755609-138758810
−0.63
0.93
0.17
−0.76
HYPOMETHYLATION

TEAD3
chr6
35561812
35562252
chr6: 35561754-35562413
−1.17
0.92
0.13
−0.8
HYPOMETHYLATION

chr12 group00022
chr12
1642456
1642708
chr12: 1642195-1642774
−1.33
0.66
0.09
−0.57
HYPOMETHYLATION

CENTG1
chr12
56406249
56407788
chr12: 56406176-56407818
−1.07
0.95
0.19
−0.77
HYPOMETHYLATION

CENTG1
chr12
56416146
56418794
chr12: 56416095-56416628;
−0.94
0.85
0.16
−0.69
HYPOMETHYLATION

chr12: 56418745-56419001

Information in Table 1A based on the March 2006 human reference sequence (NCBI Build 36.1), which was produced by the International Human Genome Sequencing Consortium.

TABLE 1B

Non-Chromosome 21 differentially methylated regions

Relative

Micro-

Previously
Methylation

array
EpiTYPER
EpiTYPER
Validated
Placenta to

Region Name
Gene Region
Chrom
Start
End
Analysis
8 Samples
73 Samples
EpiTYPER
Maternal

TFAP2E
Intron
chr1
35815000
35816200
YES
YES
NO
NO
Hypermethylation

LRRC8D
Intron/Exon
chr1
90081350
90082250
YES
YES
NO
NO
Hypermethylation

TBX15
Promoter
chr1
119333500
119333700
YES
YES
NO
NO
Hypermethylation

C1orf51
Upstream
chr1
148520900
148521300
YES
YES
NO
NO
Hypermethylation

chr1:
Intergenic
chr1
179553900
179554600
YES
YES
NO
NO
Hypermethylation

179553900-179554600

ZFP36L2
Exon
chr2
43304900
43305100
YES
YES
NO
NO
Hypermethylation

SIX2
Downstream
chr2
45081000
45086000
YES
YES
NO
YES
Hypermethylation

chr2:
Intergenic
chr2
137238500
137240000
YES
YES
NO
NO
Hypermethylation

137238500-137240000

MAP1D
Intron/Exon
chr2
172652800
172653600
YES
YES
NO
NO
Hypermethylation

WNT6
Intron
chr2
219444250
219444290
YES
YES
NO
NO
Hypermethylation

INPP5D
Promoter
chr2
233633200
233633700
YES
YES
YES
NO
Hypermethylation

chr2:
Intergenic
chr2
241211100
241211600
YES
YES
YES
NO
Hypermethylation

241211100-241211600

WNT5A
Intron
chr3
55492550
55492850
YES
YES
NO
NO
Hypermethylation

chr3:
Intergenic
chr3
138971600
138972200
YES
YES
YES
YES
Hypermethylation

138971600-138972200

ZIC4
Intron
chr3
148598200
148599000
YES
YES
NO
NO
Hypermethylation

FGF12
Intron/Exon
chr3
193608500
193610500
YES
YES
NO
NO
Hypermethylation

GP5
Exon
chr3
195598400
195599200
YES
YES
NO
NO
Hypermethylation

MSX1
Upstream
chr4
4910550
4911100
YES
YES
NO
NO
Hypermethylation

NKX3-2
Intron/Exon
chr4
13152500
13154500
YES
YES
NO
NO
Hypermethylation

chr4:
Intergenic
chr4
111752000
111753000
YES
YES
YES
NO
Hypermethylation

111752000-111753000

SFRP2
Promoter
chr4
154928800
154930100
YES
YES
NO
NO
Hypermethylation

chr4:
Intergenic
chr4
174664300
174664800
YES
YES
NO
NO
Hypermethylation

174664300-174664800

chr4:
Intergenic
chr4
174676300
174676800
YES
YES
NO
NO
Hypermethylation

174676300-174676800

SORBS2
Intron
chr4
186796900
186797500
YES
YES
NO
NO
Hypermethylation

chr5:
Intergenic
chr5
42986900
42988200
YES
YES
NO
NO
Hypermethylation

42986900-42988200

chr5:
Intergenic
chr5
72712000
72714100
YES
YES
NO
NO
Hypermethylation

72712000-72714100

chr5:
Intergenic
chr5
72767550
72767800
YES
YES
NO
NO
Hypermethylation

72767550-72767800

NR2F1
Intron/Exon
chr5
92955000
92955250
YES
YES
NO
NO
Hypermethylation

PCDHGA1
Intron
chr5
140850500
140852500
YES
YES
YES
NO
Hypermethylation

chr6:
Intergenic
chr6
10489100
10490200
YES
YES
YES
NO
Hypermethylation

10489100-10490200

FOXP4
Intron
chr6
41636200
41637000
YES
YES
NO
YES
Hypermethylation

chr7:
Intergenic
chr7
19118400
19118700
YES
YES
NO
NO
Hypermethylation

19118400-19118700

chr7:
Intergenic
chr7
27258000
27258400
YES
YES
NO
NO
Hypermethylation

27258000-27258400

TBX20
Upstream
chr7
35267500
35268300
YES
YES
NO
NO
Hypermethylation

AGBL3
Promoter
chr7
134321300
134322300
YES
YES
NO
NO
Hypermethylation

XPO7
Downstream
chr8
21924000
21924300
YES
YES
NO
NO
Hypermethylation

chr8:
Intergenic
chr8
41543400
41544000
YES
YES
NO
NO
Hypermethylation

41543400-41544000

GDF6
Exon
chr8
97225400
97227100
YES
YES
NO
NO
Hypermethylation

OSR2
Intron/Exon
chr8
100029000
100031000
YES
YES
YES
YES
Hypermethylation

GLIS3
Intron/Exon
chr9
4288000
4290000
YES
YES
NO
YES
Hypermethylation

NOTCH1
Intron
chr9
138547600
138548400
YES
YES
YES
NO
Hypermethylation

EGFL7
Upstream
chr9
138672350
138672850
YES
YES
NO
NO
Hypermethylation

CELF2
Intron/Exon
chr10
11246700
11247900
YES
YES
NO
NO
Hypermethylation

HHEX
Intron
chr10
94441000
94441800
YES
YES
NO
NO
Hypermethylation

DOCK1/FAM196A
Intron/Exon
chr10
128883000
128883500
YES
YES
NO
NO
Hypermethylation

PAX6
Intron
chr11
31782400
31783500
YES
YES
NO
NO
Hypermethylation

FERMT3
Intron/Exon
chr11
63731200
63731700
YES
YES
YES
NO
Hypermethylation

PKNOX2
Intron
chr11
124541200
124541800
YES
YES
NO
NO
Hypermethylation

KIRREL3
Intron
chr11
126375150
126375300
YES
YES
NO
NO
Hypermethylation

BCAT1
Intron
chr12
24946700
24947600
YES
YES
NO
NO
Hypermethylation

HOXC13
Intron/Exon
chr12
52625000
52625600
YES
YES
NO
NO
Hypermethylation

TBX5
Promoter
chr12
113330500
113332000
YES
YES
NO
NO
Hypermethylation

TBX3
Upstream
chr12
113609000
113609500
YES
YES
NO
YES
Hypermethylation

chr12:
Intergenic
chr12
113622100
113623000
YES
YES
YES
NO
Hypermethylation

113622100-113623000

chr12:
Intergenic
chr12
113657800
113658300
YES
YES
NO
NO
Hypermethylation

113657800-113658300

THEM233
Promoter
chr12
118515500
118517500
YES
YES
NO
YES
Hypermethylation

NCOR2
Intron/Exon
chr12
123516200
123516800
YES
YES
YES
NO
Hypermethylation

THEM132C
Intron
chr12
127416300
127416700
YES
YES
NO
NO
Hypermethylation

PTGDR
Promoter
chr14
51804000
51805200
YES
YES
NO
NO
Hypermethylation

ISL2
Intron/Exon
chr15
74420000
74422000
YES
YES
NO
YES
Hypermethylation

chr15:
Intergenic
chr15
87750000
87751000
YES
YES
NO
NO
Hypermethylation

87750000-87751000

chr15:
Intergenic
chr15
87753000
87754100
YES
YES
NO
NO
Hypermethylation

87753000-87754100

NR2F2
Upstream
chr15
94666000
94667500
YES
YES
YES
NO
Hypermethylation

chr16:
Intergenic
chr16
11234300
11234900
YES
YES
NO
NO
Hypermethylation

11234300-11234900

SPN
Exon
chr16
29582800
29583500
YES
YES
YES
NO
Hypermethylation

chr16:
Intergenic
chr16
85469900
85470200
YES
YES
NO
NO
Hypermethylation

85469900-85470200

SLFN11
Promoter
chr17
30725100
30725600
YES
YES
NO
NO
Hypermethylation

DLX4
Upstream
chr17
45396800
45397800
YES
YES
NO
YES
Hypermethylation

SLC38A10
Intron
chr17
76873800
76874300
YES
YES
YES
NO
Hypermethylation

(MGC15523)

S1PR4
Exon
chr19
3129900
3131100
YES
YES
YES
YES
Hypermethylation

MAP2K2
Intron
chr19
4059700
4060300
YES
YES
YES
NO
Hypermethylation

UHRF1
Intron
chr19
4867300
4867800
YES
YES
YES
NO
Hypermethylation

DEDD2
Exon
chr19
47395300
47395900
YES
YES
YES
NO
Hypermethylation

CDC42EP1
Exon
chr22
36292300
36292800
YES
YES
YES
NO
Hypermethylation

TABLE 1C

Chromosome 21 differentially methylated regions

Relative

Micro-

Previously
Methylation

array
EpiTYPER
EpiTYPER
Validated
Placenta to

Region Name
Gene Region
Chrom
Start
End
Analysis
8 Samples
73 Samples
EpiTYPER
Maternal

chr21: 9906600-9906800
Intergenic
chr21
9906600
9906800
NO
YES
NO
NO
Hypomethylation

chr21: 9907000-9907400
Intergenic
chr21
9907000
9907400
NO
YES
NO
NO
Hypomethylation

chr21: 9917800-9918450
Intergenic
chr21
9917800
9918450
NO
YES
NO
NO
Hypomethylation

TPTE
Promoter
chr21
10010000
10015000
NO
YES
NO
NO
Hypomethylation

chr21: 13974500-13976000
Intergenic
chr21
13974500
13976000
NO
YES
NO
NO
Hypomethylation

chr21: 13989500-13992000
Intergenic
chr21
13989500
13992000
NO
YES
NO
NO
Hypomethylation

chr21: 13998500-14000100
Intergenic
chr21
13998500
14000100
NO
YES
NO
NO
Hypomethylation

chr21: 14017000-14018500
Intergenic
chr21
14017000
14018500
NO
YES
NO
NO
Hypomethylation

chr21: 14056400-14058100
Intergenic
chr21
14056400
14058100
NO
YES
NO
NO
Hypomethylation

chr21: 14070250-14070550
Intergenic
chr21
14070250
14070550
NO
YES
NO
NO
Hypomethylation

chr21: 14119800-14120400
Intergenic
chr21
14119800
14120400
NO
YES
NO
NO
Hypomethylation

chr21: 14304800-14306100
Intergenic
chr21
14304800
14306100
NO
YES
NO
NO
Hypomethylation

chr21: 15649340-15649450
Intergenic
chr21
15649340
15649450
NO
YES
YES
NO
Hypermethylation

C21orf34
Intron
chr21
16881500
16883000
NO
YES
NO
NO
Hypomethylation

BTG3
Intron
chr21
17905300
17905500
NO
YES
NO
NO
Hypomethylation

CHODL
Promoter
chr21
18539000
18539800
NO
YES
YES
NO
Hypermethylation

NCAM2
Upstream
chr21
21291500
21292100
NO
YES
NO
NO
Hypermethylation

chr21: 23574000-23574600
Intergenic
chr21
23574000
23574600
NO
YES
NO
NO
Hypomethylation

chr21: 24366920-24367060
Intergenic
chr21
24366920
24367060
NO
YES
NO
NO
Hypomethylation

chr21: 25656000-25656900
Intergenic
chr21
25656000
25656900
NO
YES
NO
NO
Hypomethylation

MIR155HG
Promoter
chr21
25855800
25857200
NO
YES
YES
NO
Hypermethylation

CYYR1
Intron
chr21
26830750
26830950
NO
YES
NO
NO
Hypomethylation

chr21: 26938800-26939200
Intergenic
chr21
26938800
26939200
NO
YES
NO
NO
Hypomethylation

GRIK1
Intron
chr21
30176500
30176750
NO
YES
NO
NO
Hypomethylation

chr21: 30741350-30741600
Intergenic
chr21
30741350
30741600
NO
YES
NO
NO
Hypermethylation

TIAM1
Intron
chr21
31426800
31427300
NO
YES
YES
NO
Hypermethylation

TIAM1
Intron
chr21
31475300
31475450
NO
YES
NO
NO
Hypermethylation

TIAM1
Intron
chr21
31621050
31621350
NO
YES
YES
NO
Hypermethylation

SOD1
Intron
chr21
31955000
31955300
NO
YES
NO
NO
Hypomethylation

HUNK
Intron/Exon
chr21
32268700
32269100
NO
YES
YES
NO
Hypermethylation

chr21: 33272200-33273300
Intergenic
chr21
33272200
33273300
NO
YES
NO
NO
Hypomethylation

OLIG2
Promoter
chr21
33314000
33324000
YES
YES
NO
YES
Hypermethylation

OLIG2
Downstream
chr21
33328000
33328500
YES
YES
NO
NO
Hypomethylation

RUNX1
Intron
chr21
35185000
35186000
NO
YES
NO
NO
Hypomethylation

RUNX1
Intron
chr21
35320300
35320400
NO
YES
NO
NO
Hypermethylation

RUNX1
Intron
chr21
35321200
35321600
NO
YES
NO
NO
Hypermethylation

RUNX1
Intron/Exon
chr21
35340000
35345000
NO
YES
YES
NO
Hypermethylation

chr21: 35499200-35499700
Intergenic
chr21
35499200
35499700
NO
YES
YES
NO
Hypermethylation

chr21: 35822800-35823500
Intergenic
chr21
35822800
35823500
NO
YES
YES
NO
Hypermethylation

CBR1
Promoter
chr21
36364000
36364500
NO
YES
NO
NO
Hypermethylation

DOPEY2
Downstream
chr21
36589000
36590500
NO
YES
NO
NO
Hypomethylation

SIM2
Promoter
chr21
36988000
37005000
YES
YES
YES
YES
Hypermethylation

HLCS
Intron
chr21
37274000
37275500
YES
YES
YES
NO
Hypermethylation

DSCR6
Upstream
chr21
37300200
37300400
YES
YES
NO
YES
Hypermethylation

DSCR3
Intron
chr21
37551000
37553000
YES
YES
YES
NO
Hypermethylation

chr21: 37841100-37841800
Intergenic
chr21
37841100
37841800
NO
YES
YES
NO
Hypermethylation

ERG
Intron
chr21
38791400
38792000
NO
YES
YES
NO
Hypermethylation

chr21: 39278700-39279800
Intergenic
chr21
39278700
39279800
NO
YES
YES
NO
Hypermethylation

C21orf129
Exon
chr21
42006000
42006250
NO
YES
YES
NO
Hypermethylation

C2CD2
Intron
chr21
42188900
42189500
NO
YES
YES
NO
Hypermethylation

UMODL1
Upstream
chr21
42355500
42357500
NO
YES
YES
NO
Hypermethylation

UMODL1/C21orf128
Intron
chr21
42399200
42399900
NO
YES
NO
NO
Hypomethylation

ABCG1
Intron
chr21
42528400
42528600
YES
YES
NO
NO
Hypomethylation

chr21: 42598300-42599600
Intergenic
chr21
42598300
42599600
YES
YES
NO
NO
Hypomethylation

chr21: 42910000-42911000
Intergenic
chr21
42910000
42911000
NO
YES
NO
NO
Hypomethylation

PDE9A
Upstream
chr21
42945500
42946000
NO
YES
NO
NO
Hypomethylation

PDE9A
Intron
chr21
42961400
42962700
NO
YES
NO
NO
Hypomethylation

PDE9A
Intron
chr21
42977400
42977600
NO
YES
NO
NO
Hypermethylation

PDE9A
Intron/Exon
chr21
42978200
42979800
YES
YES
NO
NO
Hypomethylation

PDE9A
Intron
chr21
43039800
43040200
NO
YES
YES
NO
Hypermethylation

chr21: 43130800-43131500
Intergenic
chr21
43130800
43131500
NO
YES
NO
NO
Hypomethylation

U2AF1
Intron
chr21
43395500
43395800
NO
YES
NO
NO
Hypermethylation

U2AF1
Intron
chr21
43398000
43398450
NO
YES
YES
NO
Hypermethylation

chr21: 43446600-43447600
Intergenic
chr21
43446600
43447600
NO
YES
NO
NO
Hypomethylation

CRYAA
Intron/Exon
chr21
43463000
43466100
NO
YES
NO
NO
Hypomethylation

chr21: 43545000-43546000
Intergenic
chr21
43545000
43546000
YES
YES
NO
NO
Hypomethylation

chr21: 43606000-43606500
Intergenic
chr21
43606000
43606500
NO
YES
NO
NO
Hypomethylation

chr21: 43643000-43644300
Intergenic
chr21
43643000
43644300
YES
YES
YES
YES
Hypermethylation

C21orf125
Upstream
chr21
43689100
43689300
NO
YES
NO
NO
Hypermethylation

C21orf125
Downstream
chr21
43700700
43701700
NO
YES
NO
NO
Hypermethylation

HSF2BP
Intron/Exon
chr21
43902500
43903800
YES
YES
NO
NO
Hypomethylation

AGPAT3
Intron
chr21
44161100
44161400
NO
YES
YES
NO
Hypermethylation

chr21: 44446500-44447500
Intergenic
chr21
44446500
44447500
NO
YES
NO
NO
Hypomethylation

TRPM2
Intron
chr21
44614500
44615000
NO
YES
NO
NO
Hypomethylation

C21orf29
Intron
chr21
44750400
44751000
NO
YES
NO
NO
Hypomethylation

C21orf29
Intron
chr21
44950000
44955000
NO
YES
YES
NO
Hypermethylation

ITGB2
Intron/Exon
chr21
45145500
45146100
NO
YES
NO
NO
Hypomethylation

POFUT2
Downstream
chr21
45501000
45503000
NO
YES
NO
NO
Hypomethylation

chr21: 45571500-45573700
Intergenic
chr21
45571500
45573700
NO
YES
NO
NO
Hypomethylation

chr21: 45609000-45610600
Intergenic
chr21
45609000
45610600
NO
YES
NO
NO
Hypomethylation

COL18A1
Intron
chr21
45670000
45677000
YES
YES
NO
YES
Hypomethylation

COL18A1
Intron/Exon
chr21
45700500
45702000
NO
YES
NO
NO
Hypomethylation

COL18A1
Intron/Exon
chr21
45753000
45755000
YES
YES
NO
YES
Hypomethylation

chr21: 45885000-45887000
Intergenic
chr21
45885000
45887000
NO
YES
NO
NO
Hypomethylation

PCBP3
Intron
chr21
46111000
46114000
NO
YES
NO
NO
Hypomethylation

PCBP3
Intron/Exon
chr21
46142000
46144500
NO
YES
NO
NO
Hypomethylation

COL6A1
Intron/Exon
chr21
46227000
46233000
NO
YES
NO
NO
Hypomethylation

COL6A1
Intron/Exon
chr21
46245000
46252000
NO
YES
NO
NO
Hypomethylation

chr21: 46280500-46283000
Intergenic
chr21
46280500
46283000
NO
YES
NO
NO
Hypomethylation

COL6A2
Intron
chr21
46343500
46344200
NO
YES
NO
NO
Hypomethylation

COL6A2
Intron/Exon
chr21
46368000
46378000
NO
YES
NO
NO
Hypomethylation

C21orf56
Intron/Exon
chr21
46426700
46427500
NO
YES
NO
NO
Hypomethylation

C21orf57
Intron
chr21
46541568
46541861
NO
YES
NO
NO
Hypermethylation

C21orf57
Exon
chr21
46541872
46542346
NO
YES
NO
NO
Hypermethylation

C21orf57
Downstream
chr21
46542319
46542665
NO
YES
NO
NO
Hypermethylation

C21orf58
Intron
chr21
46546914
46547404
NO
YES
NO
NO
Hypomethylation

PRMT2
Downstream
chr21
46911000
46913000
YES
YES
NO
YES
Hypermethylation

ITGB2
Intron
chr21
45170700
45171100
NO
YES
YES
NO
Hypermethylation

TABLE 2

GENE

NAME
CHROM
START
END
SNPs

chr13
chr13
19773745
19774050
rs7996310; rs12870878

group00016

chr13
chr13
19290394
19290768
rs11304938

group00005

CENPJ
chr13
24404023
24404359
rs7326661

ATP8A2
chr13
25484475
25484614
rs61947088

PDX1
chr13
27400459
27401165
rs58173592; rs55836809; rs61944011

RB1
chr13
47790983
47791646
rs2804094; rs4151432; rs4151433; rs4151434; rs4151435

PCDH17
chr13
57104856
57106841
rs35287822; rs34642962; rs41292834; rs45500496; rs45571031; rs41292836;

rs28374395; rs41292838

KLHL1
chr13
69579933
69580146
rs3751429

POU4F1
chr13
78079515
78081073
rs11620410; rs35794447; rs2765065

GPC6
chr13
92677402
92678666
rs35689696; rs11839555; rs55695812; rs35259892

SOX21
chr13
94152286
94153047
rs41277652; rs41277654; rs35276096; rs5805873; rs35109406

ZIC2
chr13
99439660
99440858
rs9585309; rs35501321; rs9585310; rs7991728; rs1368511

IRS2
chr13
109232856
109235065
rs61747993; rs1805097; rs9583424; rs35927012; rs1056077; rs1056078;

rs34889228; rs1056080; rs1056081; rs12853546; rs4773092; rs35223808;

rs35894564; rs3742210; rs34412495; rs61962699; rs45545638; rs61743905

chr13
chr13
111808255
111808962
rs930346

group00395

MCF2L
chr13
112724910
112725742
rs35661110; rs2993304; rs1320519; rs7320418; rs58416100

F7
chr13
112799123
112799379
rs2480951; rs2476320

CIDEA
chr18
12244327
12244696
rs60132277

chr18
chr18
12901467
12901643
rs34568924; rs8094284; rs8094285

group00091

C18orf1
chr18
13377536
13377654
rs9957861

KLHL14
chr18
28603978
28605183
rs61737323; rs61737324; rs12960414

CD33L3
chr18
41671477
41673011
rs62095363; rs2919643

ONECUT2
chr18
53254808
53259810
rs35685953; rs61735644; rs8084084; rs35937482; rs35427632; rs7232930;

rs3786486; rs34286480; rs3786485; rs28655657; rs4940717; rs4940719;

rs3786484; rs34040569; rs35542747; rs33946478; rs35848049; rs7231349;

rs7231354; rs34481218; rs12962172; rs3911641

RAX
chr18
55086286
55086436
rs58797899; rs45501496

chr18
chr18
57151972
57152311
rs17062547

group00277

TNFRSF11A
chr18
58203013
58203282
rs35114461

NETO1
chr18
68685099
68687060
rs4433898; rs34497518; rs35135773; rs6566677; rs57425572; rs36026929;

rs34666288; rs10627137; rs35943684; rs9964226; rs4892054; rs9964397;

rs4606820; rs12966677; rs8095606

chr18
chr18
70133945
70134397
rs8086706; rs8086587; rs8090367; rs999332; rs17806420; rs58811193

group00304

TSHZ1
chr18
71128742
71128974
rs61732783; rs3744910; rs1802180

chr18
chr18
74170347
74170489
rs7226678

group00342

NFATC1
chr18
75385424
75386008
rs28446281; rs56384153; rs4531815; rs3894049

chr18
chr18
75653272
75653621
rs34967079; rs35465647

group00430

KCNG2
chr18
75760343
75760820
rs3744887; rs3744886

OLIG2
chr21
33317673
33321183
rs2236618; rs11908971; rs9975039; rs6517135; rs2009130; rs1005573; rs1122807;

rs10653491; rs10653077; rs35086972; rs28588289; rs7509766; rs62216114;

rs35561747; rs7509885; rs11547332

OLIG2
chr21
33327593
33328334
rs7276788; rs7275842; rs7275962; rs7276232; rs16990069; rs13051692;

rs56231743; rs35931056

RUNX1
chr21
35180938
35185436
rs2843956; rs55941652; rs56020428; rs56251824; rs13051109; rs13051111;

rs3833348; rs7510136; rs743289; rs5843690; rs33915227; rs11402829; rs2843723;

rs8128138; rs8131386; rs2843957; rs57537540; rs13048584; rs7281361;

rs2843965; rs2843958

SIM2
chr21
36994965
36995298
rs2252821

SIM2
chr21
36999025
36999410
rs58347144; rs737380

DSCAM
chr21
41135559
41135706
rs35298822

AIRE
chr21
44529935
44530388
rs35110251; rs751032; rs9978641

SUMO3
chr21
45061293
45061853
rs9979741; rs235337; rs7282882

C21orf70
chr21
45202815
45202972
rs61103857; rs9979028; rs881318; rs881317

COL18A1
chr21
45754383
45754487
rs35102708; rs9980939

PRMT2
chr21
46911967
46912385
rs35481242; rs61743122; rs8131044; rs2839379

SIX2
chr2
45081223
45082129
rs62130902

SIX2
chr2
45084851
45085711
rs35417092; rs57340219

SOX14
chr3
138971870
138972322
rs57343003

TLX3
chr5
170674439
170676431
rs11134682; rs35704956; rs2964533; rs35601828

FOXP4
chr6
41623666
41624114
rs12203107; rs1325690

FOXP4
chr6
41636384
41636779
rs56835416

chr7
chr7
12576755
12577246
rs56752985; rs17149965; rs6948573; rs2240572

group00267

NPY
chr7
24290224
24291508
rs2390965; rs2390966; rs2390967; rs2390968; rs3025123; rs16146; rs16145;

rs16144; rs13235842; rs13235935; rs13235938; rs13235940; rs13235944;

rs36083509; rs3025122; rs16143; rs16478; rs16142; rs16141; rs16140; rs16139;

rs2229966; rs1042552; rs5571; rs5572

SHH
chr7
155291537
155292091
rs9333622; rs1233554; rs9333620; rs1233555

GLIS3
chr9
4288283
4289645
rs56728573; rs12340657; rs12350099; rs35338539; rs10974444; rs7852293

PRMT8
chr12
3472714
3473190
rs12172776

TBX3
chr12
113609153
113609453
rs60114979

chr12
chr12
118516189
118517435
rs966246; rs17407022; rs970095; rs2711748

group00801

PAX9
chr14
36201402
36202386
rs17104893; rs12883298; rs17104895; rs35510737; rs12882923; rs12883049;

rs28933970; rs28933972; rs28933971; rs28933373; rs61734510

SIX1
chr14
60178801
60179346
rs761555

ISL2
chr15
74420013
74421546
rs34173230; rs11854453

DLX4
chr17
45397228
45397930
rs62059964; rs57481357; rs56888011; rs17638215; rs59056690; rs34601685;

rs17551082

CBX4
chr17
75428613
75431793
rs1285243; rs35035500; rs12949177; rs3764374; rs62075212; rs62075213;

rs3764373; rs3764372; rs55973291

EDG6
chr19
3129836
3130874
rs34728133; rs34573539; rs3826936; rs34914134; rs61731111; rs34205484

MGC29506
chr5
138757911
138758724
rs11748963; rs7447765; rs35262202

CENTG1
chr12
56406249
56407788
rs61935742; rs12318065; rs238519; rs238520; rs238521; rs808930; rs2640595;

rs2640596; rs2640597; rs2640598; rs34772922

CENTG1
chr12
56416146
56418794
rs11830475; rs34482618; rs2650057; rs2518686; rs12829991

TABLE 3

GENE
RELATIVE METHYLATION
PRC2

NAME
PLACENTA TO MATERNAL
TARGET

PCDH17
HYPERMETHYLATION
TRUE

KLHL1
HYPERMETHYLATION
TRUE

POU4F1
HYPERMETHYLATION
TRUE

SOX21
HYPERMETHYLATION
TRUE

ZIC2
HYPERMETHYLATION
TRUE

CIDEA
HYPERMETHYLATION
TRUE

KLHL14
HYPERMETHYLATION
TRUE

ONECUT2
HYPERMETHYLATION
TRUE

RAX
HYPERMETHYLATION
TRUE

TNFRSF11A
HYPOMETHYLATION
TRUE

OLIG2
HYPERMETHYLATION
TRUE

OLIG2
HYPOMETHYLATION
TRUE

SIM2
HYPERMETHYLATION
TRUE

SIM2
HYPERMETHYLATION
TRUE

CRYL1
HYPOMETHYLATION
TRUE

IL17D
HYPOMETHYLATION
TRUE

GSH1
HYPERMETHYLATION
TRUE

MAB21L1
HYPERMETHYLATION
TRUE

SIX2
HYPERMETHYLATION
TRUE

SIX2
HYPERMETHYLATION
TRUE

SOX14
HYPERMETHYLATION
TRUE

TLX3
HYPERMETHYLATION
TRUE

SHH
HYPERMETHYLATION
TRUE

OSR2
HYPERMETHYLATION
TRUE

TBX3
HYPERMETHYLATION
TRUE

PAX9
HYPERMETHYLATION
TRUE

SIX1
HYPERMETHYLATION
TRUE

ISL2
HYPERMETHYLATION
TRUE

DLX4
HYPERMETHYLATION
TRUE

CBX4
HYPERMETHYLATION
TRUE

CENTG1
HYPOMETHYLATION
TRUE

CENTG1
HYPOMETHYLATION
TRUE

TABLE 4A

SEQ

ID
GENE

NO
NAME
SEQUENCE

1
chr13
CAGCAGGCGCGCTCCCGGCGAATCTGCCTGAATCGCCGTGAATGCGGTGGGGTGCAGGGCAGGGGCTGGTTTTCTCAGCCGGT

group-
CTTGGCTTTTCTCTTTCTCTCCTGCTCCACCAGCAGCCCCTCCGCGGGTCCCATGGGCTCCGCGCTCAGAACAGCCCGGAACC

00016
AGGCGCCGCTCGCCGCTCGCTGGGGGCCACCCGCCTCTCCCCGGAACAGCCTCCCGCGGGCCTCTTGGCCTCGCACTGGCGCC

CTCACCCACACATCGTCCCTTTATCCGCTCAGACGCTGCAAAGGGCCTTCTGTCTC

2
CENPJ
GCTTTGGATTTATCCTCATTGGCTAAATCCCTCCTGAAACATGAAACTGAAACAAAGCCCTGAACCCCCTCAGGCTGAAAAGA

CAAACCCCGCCTGAGGCCGGGTCCCGCTCCCCACCTGGAGGGACCCAATTCTGGGCGCCTTCTGGCGACGGTCCCTGCTAGGG

ACGCTGCGCTCTCCGAGTGCGAGTTTTCGCCAAACTGATAAAGCACGCAGAACCGCAATCCCCAAACTAACACTGAACCCGGA

CCCGCGATCCCCAAACTGACAAGGGACCCGGAACAGCGACCCCCAAACCGACACGGGACTCGGGAACCGCTATCTCCAAAGGG

CAGC

3
ATP8A2
TTTCCACAACAGGGAGCCAGCATTGAGGCGCCCAGATGGCATCTGCTGGAAATCACGGGCCGCTGGTGAAGCACCACGCCTTA

CCCGACGTGGGGAGGTGATCCCCCACCTCATCCCACCCCCTTCTGTCTGTCTCCTT

4
GSH1
GCTGGACAAGGAGCGCTCACTGTAGCTCTGCTGTGGATTGTGTTGGGGCGAAGAGATGGGTAAGAGGTCAAAGTCGTAGGATT

CTGGCGACCGCCTACCAAGGGATTGGGTCCACAGCACAGAGGTCTGATCGCTTCCTTCTCTGCTCTGCCACCTCCAGACAGCA

GCTCTAACCAGCTGCCCAGCAGCAAGAGGATGCGCACGGCTTTCACCAGCACGCAGCTGCTAGAGCTGGAGCGCGAGTTCGCT

TCTAATATGTACCTGTCCCGCCTACGTCGCATCGAGATCGCGA

5
PDX1
TGCCTGACACTGACCCCAGGCGCAGCCAGGAGGGGCTTTGTGCGGGAGAGGGAGGGGGACCCCAGCTTGCCTGGGGTCCACGG

GACTCTCTTCTTCCTAGTTCACTTTCTTGCTAAGGCGAAGGTCCTGAGGCAGGACGAGGGCTGAACTGCGCTGCAATCGTCCC

CACCTCCAGCGAAACCCAGTTGAC

6
PDX1
TCGGCGGAGAGACCTCGAGGAGAGTATGGGGAAAGGAATGAATGCTGCGGAGCGCCCCTCTGGGCTCCACCCAAGCCTCGGAG

GCGGGACGGTGGGCTCCGTCCCGACCCCTTAGGCAGCTGGACCGATACCTCCTGGATCAGACCCCACAGGAAGACTCGCGTGG

GGCCCGATATGTGTACTTCAAACTCTGAGCGGCCACCCTCAGCCAACTGGCCAGTGGATGCGAATCGTGGGCCCTGAGGGGCG

AGGGCGCTCGGAACTGCATGCCTGTGCACGGTGCCGGGCTCTCCAGAGTGAGGGGGCCGTAAGGAGATCTCCAAGGAAGCCGA

AAAAAGCAGCCAGTTGGGCTTCGGGAAAGACTTTTCTGCAAAGGAAGTGATCTGGTCCCAGAACTCCAGGGTTGACCCCAGTA

CCTGACTTCTCCGGGAGCTGTCAGCTCTCCTCTGTTCTTCGGGCTTGGCGCGCTCCTTTCATAATGGACAGACACCAGTGGCC

TTCAAAAGGTCTGGGGTGGGGGAACGGAGGAAGTGGCCTTGGGTGCAGAGGAAGAGCAGAGCTCCTGCCAAAGCTGAACGCAG

TTAGCCCTACCCAAGTGCGCGCTGGCTCGGCATATGCGCTCCAGAGCCGGCAGGACAGCCCGGCCCTGCTCACCCCGAGGAGA

AATCCAACAGCGCAGCCTCCTGCACCTCCTTGCCCCAGAGAC

7
MAB21L1
AGATCCCGGTGCATTTAAAGGCCGGCGTGATCTGCACCACGTACCTATCTCGGATTCTCAGTTTCACTTCGCTGGTGTCTGCC

ACCATCTTTACCACATCCCGGTAGCTACATTTGTCTACCGCTTGAGCCACCAGCGTCTGAAACCTGGACCGGATTTTGCGCGC

CGAGAGGTAGCCGGAGGCGGTAATGAATTCCACCCAGAGGGACATGCTCCTCTTGCGCCCGTCGCTCAACTTCAGCACCGCGC

AGCCGGGCAGTGAGCCATCGTCCACGAAGTTGAACACCCCCATTTGGTTGAGATAAAGCACCACTTCAAATTCGGT

8
RB1
ACTATGCCTTGAGGGTCAAAACGTCTGGATTTCCTGATCGATGCTGTCGTCGCTGTCCACGGAGCTACTGTCGCCGTCAGAGC

GGGAAGGCACGTTCAGGGAGTAGAAGCGTGGGCTTGCAGAAAGGGACCTGTTGCTGCCTTACATGGGGGCCGGCAGGGTAGTC

TTGGAAATGCCCAAGATTGCTTCCGCGCGCGTCAGTTCAGCGGACGTGTCTGCCTGGCACGAGGACCGTTCTACAAACTCGTT

CCTGGAAGCCGGGCTCGCTGGAGGCGGAGCTTTGGTTTCCTTCGGGAGCTTGTGGGGAATGGTCAGCGTCTAGGCACCCCGGG

CAAGGGTCTGTGGCCTTGGTGGCCACTGGCTTCCTCTAGCTGGGTGTTTTCCTGTGGGTCTCGCGCAAGGCACTTTTTTGTGG

CGCTGCTTGTGCTGTGTGCGGGGTCAGGCGTCCTCTCTCCTCCCGGCGCTGGGCCCTCTGGGGCAGGTCCCCGTTGGCCTCCT

TGCGTGTTTGCCGCAGCTAGTACACCTGGATGGCCTCCTCAGTGCCGTCGTTGCTGCTGGAGTCTGACGCCTCGGGCGCCTGC

GCCGCACTTGTGACTTGCTTTCCCCTTCTCAGGGCGCCAGCGCTCCTCTTGACCCCGCTTTTATTCTGTGGTGCTTCTGAAG

9
PCDH17
GCAAGTCGGGTAGCTACCGGGTGCTGGAGAACTCCGCACCGCACCTGCTGGACGTGGACGCAGACAGCGGGCTCCTCTACACC

AAGCAGCGCATCGACCGCGAGTCCCTGTGCCGCCACAATGCCAAGTGCCAGCTGTCCCTCGAGGTGTTCGCCAACGACAAGGA

GATCTGCATGATCAAGGTAGAGATCCAGGACATCAACGACAACGCGCCCTCCTTCTCCTCGGACCAGATCGAAATGGACATCT

CGGAGAACGCTGCTCCGGGCACCCGCTTCCCCCTCACCAGCGCACATGACCCCGACGCCGGCGAGAATGGGCTCCGCACCTAC

CTGCTCACGCGCGACGATCACGGCCTCTTTGGACTGGACGTTAAGTCCCGCGGCGACGGCACCAAGTTCCCAGAACTGGTCAT

CCAGAAGGCTCTGGACCGCGAGCAACAGAATCACCATACGCTCGTGCTGACTGCCCTGGACGGTGGCGAGCCTCCACGTTCCG

CCACCGTACAGATCAACGTGAAGGTGATTGACTCCAACGACAACAGCCCGGTCTTCGAGGCGCCATCCTACTTGGTGGAACTG

CCCGAGAACGCTCCGCTGGGTACAGTGGTCATCGATCTGAACGCCACCGACGCCGATGAAGGTCCCAATGGTGAAGTGCTCTA

CTCTTTCAGCAGCTACGTGCCTGACCGCGTGCGGGAGCTCTTCTCCATCGACCCCAAGACCGGCCTAATCCGTGTGAAGGGCA

ATCTGGACTATGAGGAAAACGGGATGCTGGAGATTGACGTGCAGGCCCGAGACCTGGGGCCTAACCCTATCCCAGCCCACTGC

AAAGTCACGGTCAAGCTCATCGACCGCAACGACAATGCGCCGTCCATCGGTTTCGTCTCCGTGCGCCAGGGGGCGCTGAGCGA

GGCCGCCCCTCCCGGCACCGTCATCGCCCTGGTGCGGGTCACTGACCGGGACTCTGGCAAGAACGGACAGCTGCAGTGTCGGG

TCCTAGGCGGAGGAGGGACGGGCGGCGGCGGGGGCCTGGGCGGGCCCGGGGGTTCCGTCCCCTTCAAGCTTGAGGAGAACTAC

GACAACTTCTACACGGTGGTGACTGACCGCCCGCTGGACCGCGAGACACAAGACGAGTACAACGTGACCATCGTGGCGCGGGA

CGGGGGCTCTCCTCCCCTCAACTCCACCAAGTCGTTCGCGATCAAGATTCTAGACGAGAACGACAACCCGCCTCGGTTCACCA

AAGGGCTCTACGTGCTTCAGGTGCACGAGAACAACATCCCGGGAGAGTACCTGGGCTCTGTGCTCGCCCAGGATCCCGACCTG

GGCCAGAACGGCACCGTATCCTACTCTATCCTGCCCTCGCACATCGGCGACGTGTCTATCTACACCTATGTGTCTGTGAATCC

CACGAACGGGGCCATCTACGCCCTGCGCTCCTTTAACTTCGAGCAGACCAAGGCTTTTGAGTTCAAGGTGCTTGCTAAGGACT

CGGGGGCGCCCGCGCACTTGGAGAGCAACGCCACGGTGAGGGTGACAGTGCTAGACGTGAATGACAACGCGCCAGTGATCGTG

CTCCCCACGCTGCAGAACGACACCGCGGAGCTGCAGGTGCCGCGCAACGCTGGCCTGGGCTATCTGGTGAGCACTGTGCGCGC

CCTAGACAGCGACTTCGGCGAGAGCGGGCGTCTCACCTACGAGATCGTGGACGGCAACGACGACCACCTGTTTGAGATCGACC

CGTCCAGCGGCGAGATCCGCACGCTGCACCCTTTCTGGGAGGACGTGACGCCCGTGGTGGAGCTGGTGGTGAAGGTGACCGAC

CACGGCAAGCCTACCCTGTCCGCAGTGGCCAAGCTCATCATCCGCTCGGTGAGCGGATCCCTTCCCGAGGGGGTACCACGGGT

GAATGGCGAGCAGCACCACTGGGACATGTCGCTGCCGCTCATCGTGACTCTGAGCACTATCTCCATCATCCTCCTA

10
KLHL1
ATGCGCCCTCTGCACCCCTAGAGCCAGAAGACGCTAGGTGGGCTGCGCGCTCTGCCAGGCGAAGGCTGGAGCGCAGACGGCAA

AGCCGCGCGTTTCAGCCGTGGTCGGGTCCGCAGGACCTGGGCGTGGGGACACCACCAGGCAGGAGCAGAGGCAGGACTGGGAC

GCCAAAAGCTGAGAATCCTCGATGCCCGCGCGAGAGCCCCGTGTTAT

11
POU4F1
TTCTGGAAACCGGGCCCCACTTGCAGGCCCGGCCACCTTGGGTTCTGGTGGCCGAAGCCGGAGCTGTGTTTCTCGCAGACTCG

GGGAGCTACATTGTGCGTAGGCAATTGTTTAGTTTGAAAGGAGGCACATTTCACCACGCAGCCAGCGCCCTGCATGCAGGAGA

AGCCCCCAGGGCCCAGGGTCGGCTGGCTTTAGAGGCCACTTAGGTTGTTTTAAGCACATGTGAAAGGGCAGACAGCAGGGGAG

CAGGATATGGGTAAGATCTTCGGGTCTCAGAACAGGGGCTGCCCTTGGGCTGTCCCGGCGCCCTGGGCTCTGACACTGAAGGG

TGGAATGGAGGAAGGAATGGAGAAAGGACGGTGGAACTTTCGCTTCCCCTCTGGGCCGCCTTCCCAGGGTCATGCCTGAGCTG

CTTTGATCCCAGTGTCGCGCATCTTGGTCCGCTACCTCCCAGGCGATAGCTACTGGGCTCCTCGCTGGCCTCACTGGGGGCCA

TCCCGGGCAGTGGCCTGCCCTCCGAGGCCCGCGGGACCCAGCCCAGAGCTGAGGTTGGAGTTCTCCGGGCCACGTTCCGGGTC

GCTTAGGCTCGGAGATTTCCCGGAGACCGTCGTCCTCCCTTTCTGCTTGGCACTGCGGAGCTCCCTCGGCCTCTCTCCTCCTC

TGGTCCCTAAGGCCCGGAGTGGTTGGCGGTACTGGGGCCCGTCGTCATCTCTGCTTCTAAGGCATTCAGACTGGGCTCCAGCT

GGGACCGGCAGAGGAGGTTCTCAAGGAAACTGGTGGGAAATATAGTTTTCTTTCGTCTGGTCGTTTAATTTAAATGCAACTTC

CCTTGGGGACATTTTCCTGGACGTTAACCAGACCACCTTGAGATGTCGTTGATGACCTAGAGACCCAGATGATGCGTCCCAGG

AAAGTTCACTGCTGACTATTGTCACTCTTGGCGTTATATCTATAGATATAGACCTATGTACATATCTCCACCCTGATCTCTCC

GTGGACATGAAACCCACCTACCTTGTGAAAGCCCTACGGGTGACACATGACTACTACGTCTCTGTCCCAACAGGGGCTGGGCC

TCCCCTGCCTAATAGTTGCCAGGAGTTTCGCAGCCCAAGTGAATAATGTCTTATGGCTGAACGTGGCCAAGGACTCCTGTGAT

TTAGGTCCCAGGAGGAGCAGAGACGTCCCCGCCCCGCCTGGGCCCTGCCGCATTCAAAGCTGGAAGAAGGCGCTGATCAGAGA

AGGGGCTTCCAGGTCCTGGGTTAGAACAACAACAAACAAACGAAACTCCACAACAGACACGCCTGCCCATGACCCCACGCAAG

GACATAGGAAGTTCTGTCGCCTTCCTGCTCCGCGGATAGCCGCCTGCCGTCTGCTGCCACCAGAACGCACGGACGCTCGGGGT

GGAGGTAGTCAATGGGCAGCAGGGGACCCCCAGCCCCCACAAGCGCGGCTCCGAGGACCTGGAAGCGGGTGCCTGTCGCTCTC

CGCAGGCTCCGCTCTGCCTCCAGGAGCAAGATCCCCAAAAGGGTCTGGAAGCTGTGGAGAAAAC

12
GPC6
TTTTTTAAACACTTCTTTTCCTTCTCTTCCTCGTTTTGATTGCACCGTTTCCATCTGGGGGCTAGAGGAGCAAGGCAGCAGCC

TTCCCAGCCAGCCCTTGTTGGCTTGCCATCGTCCATCTGGCTTATAAAAGTTTGCTGAGCGCAGTCCAGAGGGCTGCGCTGCT

CGTCCCCTCGGCTGGCAGAAGGGGGTGACGCTGGGCAGCGGCGAGGAGCGCGCCGCTGCCTCTGGCGGGCTTTCGGCTTGAGG

GGCAAGGTGAAGAGCGCACCGGCCGTGGGGTTTACCGAGCTGGATTTGTATGTTGCACCATGCCTTCTTGGATCGGGGCTGTG

ATTCTTCCCCTCTTGGGGCTGCTGCTCTCCCTCCCCGCCGGGGCGGATGTGAAGGCTCGGAGCTGCGGAGAGGTCCGCCAGGC

GTACGGTGCCAAGGGATTCAGCCTGGCGGACATCCCCTACCAGGAGATCGCAGGTAAGCGCGGGCGCGCTGCAGGGGCAGGCT

GCAGCCCTCGGCTGCCGCACGTCCCACTGGCCGCCCGGCGTCCCCTTCCTTCCCCCTGTTGCTGAGTTGGTGCTCACTTTCTG

CCACCGCTATGGGACTCCGCGTCTCCGTGTTGGGCGGCGGATGCTCCTGCGGCTTCTTCGGCGGGGGAAGGTGTGCGTCTCCG

CCGCCTCATTGTGTGCACACGCGGGAGCACCCTGGCTCCCGCCTCCCGCTGCTCTCGCGCCCTTCTACCCCTTAGTTGATGGC

TCAGGCCCGGCTGGCCAGGGAGCCCGGGTCACTCCGGGGCGGCTGCAAGGCGCAGACGGAGAGCCGAGCCGGGCGCTCACTCC

GCGTTCTGGTTCGGGCAAACTTGGAAGAACTGCGACCGCAGTTTGCCCAGCGCCACAGTCTGAGTGGCGCCTTCTCCACTCCC

GCCCTTGCGCCGGCAGGGGCGGTGGAGAGACGCGGAGGGCTCCCCCAGCCCCTCTCTCCCCTATCCGTCCTTCGGGCGACAGA

GCGCCCGGCGCTCGGGCCGGGGGCGGGCAAGGCTGGGAGGGACCCTCGCCGGGGACCTGGCCTCTGGACGCCGGCGTTTCAAG

GCTGGTTTGGGGACTTCACGGGCTGCCTGTTTCAGATGTGGGGCGGGCTTTCCCGTTAGGGTTCCTCAGTGCTTCCCCAGTTG

CTGTTGGCCACTCAGGGCCCGGGGACACCCTGCCACCCGGTCTGGAGCCGGCCTCGTCTGCCAGCGAACAGCCAACTTTAGCG

GGTGGCTCAGCTGGGGATT

13
SOX21
CACTCAGTGTGTGCATATGAGAGCGGAGAGACAGCGACCTGGAGGCCATGGGTGGGGGCGGGTGGTGAAGCTGCCGAAGCCTA

CACATACACTTAGCTTTGACACTTCTCGTAGGTTCCAAAGACGAAGACACGGTGGCTTCAGGGAGACAAGTCGCAAGGGCGAC

TTTTCCAAGCGGGAGATGGTGAAGTCTTTGGACGTGTAGTGGGTAGGTGATGATCCCCGCAGCCGCCTGTAGGCCCGCAGACT

TCAGAAAACAAGGGCCTTCTGTGAGCGCTGTGTCCTCCCCGGAATCCGCGGCTTAACACATTCTTTCCAGCTGCGGGGCCAGG

ATCTCCACCCCGCGCATCCGTGGACACACTTAGGGTCGCCTTTGTTTTGCGCAGTGATTCAAGTTGGGTAACCCTTGCTCAAC

ACTTGGGAAATGGGGAGAATCTCCCCCACCCGCAACCTCCCGCACCCCAGGTTCCCAAAATCTGAATCTGTATCCTAGAGTGG

AGGCAGCGTCTAGAAAGCAAAGAAACGGTGTCCAAAGACCCCGGAGAGTTGAGTGAGCGCAGATCCGTGACGCCTGCGGTACG

CTAGGGCATCCAGGCTAGGGTGTGTGTGTGCGGGTCGGGGGGCGCACAGAGACCGCGCTGGTTTAGGTGGACCCGCAGTCCCG

CCCGCATCTGGAACGAGCTGCTTCGCAGTTCCGGCTCCCGGCGCCCCAGAGAAGTTCGGGGAGCGGTGAGCCTAGCCGCCGCG

CGCTCATGTTTATT

14
ZIC2
AGTCACTCCAGGATCAGAGGCCGCGTCGGTTCTGCTTGGGGCATGGGCAGAGGGAGGCTGCTGGGGCCAAGCCCCGGCTGGAC

GCGAGGGAAGAAACTCGTCCCAGGACCCGCACGCCCATACCTGGCTGTCCCAGAGCTCTTCCCTAGGCCGGCACCTTCGCTCT

TCCTCTTCCCCACCCCCTAGCCCTTTTGTCTCTTTTTCAGACGGATGTTTTCAGTCTCAAGTGGTTTTATTTTCCGCACAAAA

CCCTGAGATCAAGGGCAGATCACAGACTGTACCGGAGGCTCGGGTTTCCCTGGACTCTGTGCTGTTCTGCGTCCCAGGGTTGG

CTAGGAAGGAAGGCCTGGGCCGGCGAGGTGACGGGTCTCCCGCCCAGGTCGGCAGGACGGGGGGAGGTGTGTCCCGGTAGGTC

CCTGGTGAGCTCACCCGTGGCATCGGGGACCCGCGGGAACCCACCGGGCGCCCACTAGAGACTCGGGTCCTACCCTCCCCCAC

ACTACTCCACCGAAATGATCGGAAGGGCGCGCTAGGCCTGCTTCCAAGGGCTCAGTGATAAAGGCCTCAAAATCACACTCCAT

CAAGACTTGGTTGAAGCTTTGGGTAGGTTTGTTGTTGTTGTTGTTGTTGTTTGTTTGTTTGTTTTAGCAGACACGTCCTGGAA

AGAGGTCCTCAGAACCCAAAGGTTCAATAATGATTTGTGGATGGATTGATTATAGTCTGATATCGCTCTGGTTCCACAGAAAC

CCGGAGCTCCTTGGCCCACTGTTACCCCAGCAGACCTAAATGGACGGTTTCTGTTTTTCACTGGCAGCTCAGAACTGGACCGG

AAGAAGTTCCCCTCCACTTCCCCCCTCCCGACACCAGATCATTGCTGGGTTTTTATTTTCGGGGGAAAAACAACAACAACAAC

AACAAAAAAAACACTAGGTCCTTCCAGACTGGATCAGGTGATCGGGCAAAAACCCTCAGGCTAGTCCGGCTGGGTGCCCGAGC

ATGAAAAGGCCTCCGTGGCCGTTTGAACAGGGTGTTGCAAATGAGAACTTTTGTAAGCCATAACCAGGGCATCCTGAGGGTCT

GAGTTCACGGTCAAGGCTGTGGGCTACTAGGTCCAGCGAGTCCAGGCCTCGCCCCGCCCCCGAGCTGCCACAGCCAAGATCTT

CGGCAGGGAATTCGAGACCAGGGTCCTCCCACTCCT

15
chr13
TTTCGTGCCGCTGTTTTCAATGCGCTAACGAGGCACGTTATTCTTAGCCGCGTCCGGGAGGGGATCACATTCCTGCGCAGTTG

group-
CGCTGCTGGCGGAAGTGACTTGTTTTCTAACGACCCTCGTGACAGCCAGAGAATGTCCGTTTCTCGGAGCGCAGCACAGCCTG

00385
TCCCATCGAGAAGCCTCGGGTGAGGGGCCCGGTGGGCGCCCGTAAGCCACAGCGAGTGGTTAGAAGTAGGTTAGGAAGAAGGG

GAGGTAAGAAAGCCGAGTAGGGTT

16
chr13
GTTCGGTGGACAAGGGGGCAGCGCCCACAGCAAGCCGGAAAGAGGGAGGCGCGGGGCCGCGCTTGGGGCCTGCCGCTGCACGC

group-
CAGCCTGGGCAAAGAGCTGCCACCTTCTGCGGGCGAAGCGGGTCGGGACGCAGGACGGCAGCGGGGCTGGAGGCAGCTACGTG

00390
GGTCCACACCCCCATGCCCTGCAAGGCTCCTTGGCCCTGCTTCTCCTCTGTCTCGGCGGGAGAGGAGCAGCCTCGGTTTTACA

GAATTTC

17
chr13
TGTGCCATTTAGTGAGAGGTGTTTTGGGCAAAGAATCAATTTAACTGTGACTGACCGACGGGCTTGACTGTATTAATTCTGCT

group-
ACCGAAAAAAAAAAAAAAGCAATGAGCCGCAAGCCTTGGACTCGCAGAGCTGCCGGTGCCCGTCCGAGAGCCCCACCAGCGCG

00391
GCTCACGCCTCAGTCTC

18
chr13
AGAGTCCCAGTTCTGCAGGCCGCTCCAGGGCTAGGGGTAGAGATGGTGGCAGGTGGTGCGTCAACTCTCTAGGGAAGAGGAAC

group-
TTGCATTACAAAGACTTGTCTTTCTGAGCTGAAGTCAAAACGGGGGCGTCAAGCGCGCTCCGTTTGGCGGCGGTGGAGGGGCC

00395
GCGCGCCCGCGCTGTCCCAGCCGGAGCTGCCCTGGCTGGTGATTGGAGGTTTAACGTCCGGAATTCAGGCGCTTCTGCAGCTC

AGATTTGCCGGCCAAGGGGCCTCAGTTGCAACTTTTCAAAATGGTGTTTCTGGAAAATAACAAATTCAGACTCAACTGGTGAC

AGCTTTTGGCTATAGAGAATGAAACTGCTTCCCTTTGGCGGTGGAACTCTTAAACTTCGAAGAGTGAAAGAATACAATGAAAT

AAAATGCCATAAGATCACTGGATTTTTCAGAAAAAGGAAGACCCCAAATTACTCCCAAAATGAGGCTTTGTAAATTCTTGTTA

AAAATCTTTAAATCTCGAATTTCCCCCTACAACATCTGATGAGTGCTTTAAGAGCAAACGAGCAAATCCCACCTCGAGAATCA

ACAAACCCAAGCTCTGGCCAAGGCTCTCCCCGCGTTTTCTTCTCGTGACCTGGGGAATGTCCCGCCCCATCGCTCACCTGGCT

CTTGTCATCTCGCTCATCTTGAAGTGACCCGTGGACAATGCTG

19
chr13
AGCTGCCCTCTGTGGCCATGAGCGGGTGTCCAGCCCCTTCCAAGGCTGCACCGGGGAGACGCTGGTTTTCTGCTCGCTGTGAC

group-
CGAACAAAGCCCCTAAGAGTCAGTGCGCGGAACAGAAGAGCCGGACCCCGACGGGCCGAGTCCCAACGTGAGGCACCCGGCAG

00399
AGAAAACACGTTCACG

20
PROZ
CCTCGGCAGCACCGGCATGGCTGGAGGCCAGTACGGCCAGGTGTGGCGGGAGGGAGCGCCGTCTGGCTTGGGTCGTCCATCCT

GACAGGACGCTGCAAGGGCAGGAGCCCCGCGCCCCGTGTCCTGCGCCCCCGCTCGAGGACAAGCCCCAGCCGCCGGTCTCCGC

TGGGTTCCGACAG

21
CIDEA
CTTTAAGAGGCTGTGCAGGCAGACAGACCTCCAGGCCCGCTAGGGGATCCGCGCCATGGAGGCCGCCCGGGACTATGCAGGAG

CCCTCATCAGGCGAGTGCCCCGCGTCCCCCTGATTGCCGTGCGCTTCCAATCGCCTTGCGTTCGGTGGCCTCATATTCCCCTG

TGCGCCTCTAGTACCGTACCCCGCTCCCTTCAGCCCCCTGCTCCCCGCATTCTCTTGCGCTCCGCGACCCCGCGCACACACCC

ATCCGCCCCACTGGTGCCCAAGCCGTCCAGCCGCGCCCGCGGGCAGAGCCCAATCCCGTCCCGCGCCTCCTCACCCTCTTGCA

GCTGGGCACAGGTACCAGGTGTGGCTCTTGCGAGGTG

22
chr18
AGACTTGCAGAACTCGGGCCCCCTGGAGGAGACCTAACCGCCACGGTCTTGGGGAGGTTCCGGAGGGCCTCGGTTGTCTGCAC

group-
TCCCAACACCAAGAAACCCCTGAGACGCGAAGCTGCCAGCGTGCTGCCCTCAGAGCAGGGCGACGCAAAGCCAGCGGACCCCG

00091
GGGTGGCGGG

23
chr18
TGCTCGGCTGGGGGGCTCGCTCCGCACTTTCGGTGCCAGAAAATGCCCAGAGGAGCGGGGCGGCCCCAGAGCCTCCTTTCGGG

group-
GCGCGAGGCCCGGCGCGTGTGTACGGAGTCCAGTCCCCCCAGGGAGTGGGGTGCCCGCACCTTCCCCTCCGCGCTCGGAGCCA

00094
C

24
KLHL14
TCTTGCACACCTGCTTGTAGTTCTGCACCGAGATCTGGTCGTTGAGGAACTGCACGCAGAGCTTGGTGACCTGGGGGATGTGC

AGGATCTTGCTGACCGACAGCACCTCCTCCACCGTGTCCAGGGACAGGGTCACGTTGGCCGTGTAGAGGTACTCGAGCACCAG

GCGCAGCCCGATGGACGAGCAGCCCTGCAGCACCAGGTTGTTGATGGCCCGGGGGCTGGTCAGCAGCTTGTCGTCGGGGGAGG

AAGAAGGAGTCCCGGGCTCCTCCTGCGGCGGCGGCTGCTGCTGCTGTGACGGCTGCTGCTGCGGCGGCTGCTGCTGGTCCTTG

GGGGCCCCCAGGCCGTCCTGGCCGCCGACCCCTCCCCCGAGAGGGGGGTGGCTGGAGAAGAGCGATCGGAAGTACTGCGAGCA

GGAGGCCAGCACGGCCTTGTGGCAATGGAACTGCTGGCCCTGGGCCGTCAGGGTCACGTCGCAAAACAGCTGCTTCCTCCACA

GCAGGTTGAGGCCGTGCAGCAGGTTGTCGCTGTGGCTGGGGTCGAAGGTGGAGGTCCTGTCCCCGGATCTGGACATGGCGAGC

TGACTCGGTGCACCTGGCTTTAAACCCTCCTCCAACCTGGCAGACAGGGGTGGGGGATGGGAGGGAGGGGAGCAGGGTGGTGG

AGCGGGTGGGGTGTGGTCGGGGTGGGGAAGGGTGTGGAGGGGAGGGGAGGGCGAAGAACAAGAATCAAGGCTCAGCTTGACTC

CCTCCTGGCGCGCTCCGGACCCCGACCCTAGGAGGAAAGTCCGAAGACGCTGGATCCGTGAGCGCCACCAGAAGGGCCCTGTC

TGGGGTCCCGGCGCCGGTTCTGCGCCCTGCGGCTCCTCTCGCCACCTCCCACACACTTCGTCCCTCACTTTCCTAAAACCAAC

CACCTCAGCTCGGCTGTTGGCAGCAACAGCAGTGGCAGCAGCGACGGCAAAGTGGCGGCTGAGGCCGAGGCACCTCGTGGGCT

CGTGTCCATGCCGGGCCAGATGAAGGGAAAGGCCGGGAAGTGGGGAGCCGGGGGTGCCCTGAAAGCTCAGAGGCGACCGACGG

CGAAGGTTCCAGGTCAACTTGTGCCCGAAGCTTTGCTTTTCGCAGTTGGCCCAGTTTGGGGGAGGGGGTAGGAACAGGGGCCC

GACCAGCGTGCGGGGTGTGCGAATCTTAGCTCTCCAAAAGCTG

25
ST8SIA3
CCTCTGTGTTAGTGCCCTCGGGAATTTGGTTGATGGGGTGTTTG

26
ONECUT2
TGATGTCGCACCTGAACGGCCTGCACCACCCGGGCCACACTCAGTCTCACGGGCCGGTGCTGGCACCCAGTCGCGAGCGGCCA

CCCTCGTCCTCATCGGGCTCGCAGGTGGCCACGTCGGGCCAGCTGGAAGAAATCAACACCAAAGAGGTGGCCCAGCGCATCAC

AGCGGAGCTGAAGCGCTACAGTATCCCCCAGGCGATCTTTGCGCAGAGGGTGCTGTGCCGGTCTCAGGGGACTCTCTCCGACC

TGCTCCGGAATCCAAAACCGTGGAGTAAACTCAAATCTGGCAGGGAGACCTTCCGCAGGATGTGGAAGTGGCTTCAGGAGCCC

GAGTTCCAGCGCATGTCCGCCTTACGCCTGGCAGGTAAGGCCGGGGCTAGCCAGGGGCCAGGCTGCTGGGAAGAGGGCTCCGG

GTCCGGTGCTTGTGGCCCAAGTCTGCGCGCCGAGTCACTTCTCTTGATTCTTTCCTTCTCTTTCCTATACACGTCCTCTTTCT

TCTCGTTTTTATTTCTTCTTCCATTTTCTCTTTCTCTTCCGCTCTTCCCCTACTTTCCCTTCTCCCTTTTCTTTTTCTTTCTT

ACTCTCTCCTTGTCCCTGAGCTTTCATTGACCGACCCCCCCCCATTTCATTCGCCCTCCCCTCAATGTGCCAACCTTTGCCCT

ATTTCCGATCTTCCCAGGTACTGGGAGGCGGGATGGGGGTGTGCGTTTTCCTCTAGGAGCCCTGTCTTTCCAAGACCCACAGA

AACCAGGACCTGCCCTTATTCAAAACCCCATGCACTTCAAGTCTCTTTTAGACAACACATTTCAATTTTCCGGGCTGACTAGT

CTCCCTGTGCAGAGGCAGTTGAGAGGCTTTGCTCTGCAGAGGGAAAAGAGCTCTCTACTCTCCCACCCACCATATAGGCAAAC

TTATTTGGTCATTGGCTGAAGGCACAGCCTTGCCCCCGCGGGGAACCGGCGGCCAGGATACAACAGCGCTCCTGGAGCCCATC

TCTGGCCTTGGCGTTGGCGCAGGGACTTTCTGACCGGGCTTGAGGGGCTCGGGCCAGCTCCAATGTCACTACCTACAGCGAGG

GCAGGGTGTAAGGTTGAGAAGGTCACATTCACCGCTTTGGGAGGACGTGGGAGAAGAGACTGAGGTGGAAAGCGCTTTGCCTT

GCTCACCGGCCGTCCTTGCCCCGGTCCCAGCGTTTGCTGGGATTTGCCAGGATTTGCCGGGGCTCCGGGAGACCCTGAGCACT

CGCAGGAAGAGGTGCTGAGAAATTAAAAATTCAGGTTAGTTAATGCATCCCTGCCGCCGGCTGCAGGCTCCGCCTTTGCATTA

AGCGGGCGCTGATTGTGCGCGCCTGGCGACCGCGGGGAGGACTGGCGGCCCGCGGGAGGGGACGGGTAGAGGCGCGGGTTACA

TTGTTCTGGAGCCGGCTCGGCTCTTTGTGCCTCCTCTAGCGGCCAAGCTGCGAGGTACAGCCCTCTATTGTTCTAGGAGCACA

GAAACCTCCTGTGTGGGCGGCGGGTGCGCGAGCTAGAGGGAAAGATGCAGTAGTTACTGCGACTGGCACGCAGTTGCGCGCTT

TTGTGCGCACGGACCCCGCGCGGTGTGCGTGGCGACTGCGCTGCCCCTAGGAGCAAGCCACGGGCCCAGAGGGGCAAAATGTC

CAGGTCCCCCGCTGGGAAGGACACACTATACCCTATGGCAAGCCAGGGTGGGCGACTTCCCATGGATCGGGTGGAGGGGGGTA

TCTTTCAGGATCGGCGGGCGGTCTAGGGGAACAATTCGTGGTGGCGATGATTTGCATAGCGCGGGTCTTGGGATGCGCGCGGT

TCCGAGCCAGCCTCGCACAGCTCGCTTCCGGAGCTGCGAGCTCAGGTTTCCACCCCCGATCCCCCGGGCTTTCCTCGCACCGC

TGAGCCCAGCTTGTGGGGTGCACTCGACCAACGCCCGACAGGGCTGGGGAATGTGACAGGCAGCAGGTTCACCCGGGCTTGGG

GAGGGGGAGTTTCCGCTTTGACAGCATTTTCCTTTGCCGTCTGCTGGTGGATTCCTATTCCCAGTCGGTAATCGCCCCGCAGT

GTTGATCTAAGAAGGTAAAGAAAACTAGGTTTCCCTGCAAAGAGCCTCCCCCAAATCGGCGGACTCCGGATACTTTGAGTGGA

TTTAGAAATTTATGTAATCTTTCTCCTTTAGTTTATTTTTCATCCTCTCCTACAGTTTTCTCTGATTTGCTGTTGGTTCGGGG

CAAGATAAAGCAGCCAGTAGAGAGCGATAATAATAGCGGCGGGAAATGAACTGGAGACTGGCTGACAGTTCTTAACATTTTGT

CATAGATCCCCCCGAATGTCCCAGGCTGTCTCTGGTGGGTTTTAGTACCCGCCGGCTTCTTGGGCACCGGGGACCAGAAGGAA

CTTGGCAGCTGGTCTTAGGGGTACAGTTAAAGGCAGGATGACAGCTATTCTCCTGCTCATCTCAGAGCGCTGCCGCCCCCTCA

TGCCGGTCGCGCAAAGAACACAGCTTTTAAAAAACACGTGCCTTCTGCCCATATAGGTCTGAAAGTGATGAGGAAAGTAATGC

TTCGCCTATTAGCGAGTTTCAGCTTTTAAAATGATCCCAAGCGTTGCTGAGATGAGAAAGCGTGGCATCCCGGGGGTCCTCAG

CCCCACCCGCGCCCATGGTGCAAGTCTGCAGGGACAGGCCCGGGACAGCACTGCCCACGCTGCTAGATTTTCCGCAGAGGATC

GCTGAAGCTGCCTTCGTGGGAGACAGAATGCCTCCTCCAGCGAGTGGAAAAGGCCTGCTGAGGACCCCGCTTTGCTCGAGCAT

TCAAATGTGTGTCTGTTTTATTACCCTGGGTTGAAAAGGGACAAGAGCTTTAGCCTTTTTATCTGGCCATTTTATCAGCAACT

ACAAGTGTGTTGAGTGGTTATTATTACATAGGAGGCTTTTCAGTTTGGGGTCAGTAGATCAGTCTCTTCAGACACTGATGCAG

AAGCTGGGACTGGTAAGTAGGTATTATGTGCTCGGAGCGCTAGGGGACAGGAGCAAATGGAGAAGAAAAGCGGAGGCTTTCTC

CGCCCGGAGTATCGATCGGAATCCCCGCCGGTACGCCGCAGAGGGCCCTCGCCGTTGGGCCCCGGGGGTTTAACAAGCCCAGC

CGCTCCGCAGGCGGCTCGGCCGGACTCTCAGACCGGTGCCTGGAAGACACCGTCCCTGCCCCCCTCCCGCCAAACCTGCCTCT

TCTCTTTCTCTCATAGGTTATAGGTTCCCTTTCTCTCTCATTTTGGCCCCGCCCCCGGGTCCTGCCAAACAGCCAAGCAGGCC

GGGGTTTAGGGGGCTCAGAATGAAGAGGTCTGATTTGGCCAGCGCCGGCAAAGCTCACCCTTAGGCGAGGTCACAACAGAGGC

AGGTCCTTCCTGCCCAGCCTGCCGGTGTAGTCACAGCCAAGGGTGGCACTTGAAAGGAAAAGGGAGAAAACTTCGGAGAAATT

TAGATTGCCCCAACGTTAGATTTCAGAGAAATTGACTCCAAATGCACGGATTCGTTCGGAAAGGGCGGCTAAGTGGCAGGTGG

TTGCAACCCCGCCCGGTCGGGCCTTCGCAGAGGTTCCCCAAGACCAGCCCTTGCAGGGCGGTTTTCAGCAACCTGACAAGAGG

CGGCCAAGACAAATTTCTGCGGGTTCGAGCACACACTCTCGGGCGTTGGGCCCCAGAGACCTCTAAACCAAGCACAAACAAGA

AGGGAGTGAGAGAACCCAGGCTAGAACTTGCACGGGCATCCCACTGAGGAAAAGCGAGGCCTCGGTGGCAGGCATGTTTTCTT

CCGACGCCCGAAAATCGAGCCGAGCGCCCGACTACATTTACTGCAGAGGTTTCCGCCTCCAGTGAGCCCGGATCCCCCAGCGG

CCTGCCCGGAGCTGGTCTCCAGTCCCCGCCGTAGTCCGACGCACGGCCCTCTCCTGGCAGCAAGCTCCCAGCGGCCAGTCTGA

AGCCAATTCTGTTCAGGCGGCCGAGGGCCCTTAGCCAACCCACCATGATGTCGCCTGGGCCACCTGATGCCCGCAGCGGCGGG

ACACGGCCCGGGCAGTGCGCAGTGGCTCCTGCTAGGGGCACCGCGTGCGTGCTTGTCTCCCGCTGCGCCGGGGACGTCCTTGG

GTGACACGGGCCGCTGGGCACCTCCCAAGCCGAGGAAACGGACCCCCTTCGCAGAGTCTCGCGCCCACCCCCCAACCTCCCAC

CTCGTTTCTCGCTGCTAGGGCTCCCGACTCAGCCCACCTCTCCTGGCGGTTTAGTTAGGGATCAGAGCTGGAGAGGCTGAACG

CAACCCGTGCCAGTACGGAACAGACGATATGTTTGCCTGCTAGCTGCTTGGATGAATAATTGAAAAGTTCGCTGCAGTCTGTG

CTTCGTCAAGTCCCGGGTGCCGGGAGAACACCTTCCCAACACGCATCAGGGTGGGCGGGAGCGGGCAGAGGAGGCGGGACCCG

AGGGAGGAGAGTGAACCCGAGCAGGAGAAGCAGCCCAGGCAGCCAGGCGCCCTCGATGCGAGAGGCTGGGCATTTATTTTTAT

TCCAGGCTTTCCACTGTGTGGTTATGTCACTTTCTCAAACAAATGTGTATATGGAGGGAGATCGATGCTGATAATGTTTAGAA

GATTAAAAGAGCATTAATGCTGGCAACAATAACGTAAACGTGTGGACCCAGATTTCATTGATCTGGAACTTGATCCGGCGCGT

TTCCAGTAAGCCCGACGGCGCGCTCTTCCCAGCAGAGCGCTCACCAGCGCCACGGCCCCGCGGTTTTCCAGCGGTGCCGCTTC

GCCAGCTCTGCGCGGGTTCTCCCGTCTGACCGCAGCTCCTCCCCCGCGAGGCCCCAGCCCGCCTTACTTCCCCGAGGTTTTCT

CCTCCTCTCGCGGGGCTCTCTGCCCTCTGCACCCCCTCCCCCGACCTCTGCACCACCCGCCCCTGTGCGCACACACCGCTACT

TGCGCTTCCGGCGATCCGCCTG

27
RAX
AACCGGAGATCTGCTTGGTGAACTGAGAGGAGTCCTTAGGAGAGCGGGGACGCCAGGGGCCGGGGGACACTTCGCTCTCGCCC

TAGGGAAGGTGGTCTTGACGCTTTCTATTGAAGTCAAACTTGAAAATATCAGCTGCCGCTGGACTAT

28
chr18
CGTGAGCAGAACGCCCGCCCTGGAGCAGTTAGGACCGAAGGTCTCCGGAGAGTCGCCGGCGGTGCCAGGTAACGCAGAGGGCT

group-
CGGGTCGGGCCCCGCTTCTGGGGCTTGGGACTCCGGGCGCGCGGAGCCAGCCCTCTGGGGCGAAATCCCCGGGCGGCGTGCGC

00277
GGTCCCTCTCCGCGCTGTGCTCTCCCAGCAACTCCCTGCCACGGGAAGCTGGGGCGCACCGGGGCAGGT

29
NETO1
TAGAAGAGGAAGACTCCTCTGGCCCCACTAGGTATCATCCGCGCTCTCCCGCTTTCCACCTGCGCCCTCGCTTGGGCCAATCT

CTGCCGCACGTGTCCATCCCTGAACTGCACGCTATCCTCCACCCCCGGGGGGTTCCTGCGCACTGAAAGACCGTTCTCCGGCA

GGTTTTGGGATCCGGCGACGGCTGACCGCGCGCCGCCCCCACGCCCGGTTCCACGATGCTGCAATACAGAAAGTTTACGTCGG

CCCCGACCCGCGCGGGACTGCAGGGTCCGCCGGAGCGCGGCGCAGAGGCTTTTCCTGCGCGTTCGGCCCCGGGAAAGGGGCGG

GAGGGCTGGCTCCGGGAGCGCACGGGCGCGGCGGGGAGGGTACTCACTGTGAAGCACGCTGCGCCCATGGATCATGTCTGTGC

GTTACACCAGAGGCTCCGGGCTCCACTAATTCCATTTAGAGACGGGAAGACTTCCAGTGGCGGGGGGAGGACAGGGTCGAGAG

GTGTTAAAGACGCAAAGCAAGAAGGAAATAAAGGGGGGCCGAGAGGGAGACCGAGAGGAAGGGGGAGCTCCGAGCCCACGCTG

CAGCCAGATCCGGATGAGTCCGTCCTCCGCCCCGGGCGGGCTCTCGCTCTCGCTGGCCCTCAGCGCCGCGCAGCCAGCAGCAT

CCCCACCGTGACGCTCGCATCACACCCGGGCGCCGGCCGCCACCATCCGCGCCGCCGCCGTCAGGACCCTCCTCCCGGGCATC

GTCGCCGCCGCGGGGTCGGGAGGACGCGGCGCGCGGGAGGCGGCGGTCGCAGGGCGAGCCCCGGGACGCCCCGAGCCGGGGCC

GGGGCCGGGGAGAGGGCGCAGCGAGGTGGGGGCCAGTCCAGACCGACGGCAGCGACGGAGCGGGCGGCGGCGGCGGCGCCGGC

GGCGGCGGGGTGGCTCAGTCCCCAGTCTCAGACGCGCCGCGCAGCAGGTCGGAGCAGCCTCCCCGGGAGGATGTCCAGCGGCA

GCGCTCCTCGCTCCAGCCCTTGGGGATCTTCCGCTGAGGCATTGAAGGCAGGAAGAAGGGGTCCGTCATCGGCTCGCCGGGCT

GCGCGCCACCTCTGCTATCTTGCGGAAAGAGGAGCGGGTGGGTGGGCGTCTGGGAGGCGGGCTGGAGGGCGGTGCAGGGGAGC

GGGGCGGCCGGGGGGGGGGCCGGGGGGCGGGGAAGGGAGGGAGGAGAAAGGAGCCGGAAGAGGGCAGAGTTACCAAATGGGCT

CCTTAGTCATGGCTTGGGGCTCCACGACCCTCCTGGAAGCCCGGAGCCTGGGTGGGATAGCGAGGCTGCGCGCGGCCGGCGCC

CCGGGGCTGGTGCGCGGCAGAATGGGGCCGCGGCGGCGGCAGCAAGGACATCCCAGCCGCGCGGATCTGGGGGAGGGGCGGGG

AGGGGGTGAGGACCCGGCTGGGATCCGCGGCTCGGCCCGCCAGGGCGCAGAGAGAGGATGCAGCCGCAAATCCCGAGCCGGAT

CCTCGTGCCGGACGGAAGGCGTGGAAGCGGGAGGGGCCTTCGTGTGAAAATCCCTTGTGGGGTTTGGTGTTTCACTTTTTAAA

GGTTAGACCTTGCGGGCTCTCTGCCTCCCACCCCTTCTTTTCCATCCGCGTAAAGGAACTGGGCGCCCCCTCTCCCTCCCTCC

CTGGGGCGCAGGTTTCGCCGCGGACTCCGCGCTCAGCTTGGGAGACACGGCAGGGGCGCGCCCCAGGGAAAGGCGGCCGTAAA

AGTTTCGCGGTTGAGCACTGGGCCTGATGTCCAGTCCCCCCACCAAATTACTCCTGCAAAGACGCGGGCTTCTTGCAATTGAG

CCCCCCACCTCGAGGTATTTAAAACCACCCCAAGGCACACACGGACCCCCGTTCCCCCGCGCCACTTCCTCCTACAGGCTCGC

GCGGCGCGTTAAAGTCTGGGAGACACGAGTTGCGGGGAAACAGCACCGGAAG

30
MBP
AAGAAACAGCTCATTTCGGAGCTGAGGACAAGGCGTGGGAAGAAGACGCGTTTGGTTTCACCCAGGCGGGTGGCGGCAAAGCT

GTGGGATGCGCGCTGCACACTCCTTCCGTCATCCCGTTCCCACCTTCCACACACACCTGCGGGAGGTCGGACATGTCCTGATT

GCGTGTTCATCACGATGGCAAACCGAACATGAGGAGAACGCCACTGACGCTGGGTGCGCCGGCTTTCCCAGCCCTCGTGCATA

ACGGGGAGGGAGATGCAGAAGTTTTTTCCAACATCGGTGCAAAGGGGAAGCTGAGGTTTTCCTAT

31
NFATC1
TCTGTCAGCTGCTGCCATGGGGCAGCGGGAAGGCCCTGGAGGGTGCCTGGGCTGTGTCTGGTCCCGGCCACGCGTCCCTGCAG

CGTCTGAGACCTTGTGGAACACACTTGACCCGGCGCTGGGACGGGGTCGGCCCACACGCACCGCCAGCCCGCAGGAGTGAGGT

GCAGGCTGCCGCTGGCTCCTTAGGCCTCGACAGCTCTCTTGAGGTCGGCCCTCCTCCCCTCCCGAGAGCTCAGCAGCCGCAGA

CCCAGGCAGAGAGAGCAAAGGAGGCTGTGGTGGCCCCCGACGGGAACCTGGGTGGCCGGGGGACACACCGAGGAACTTTCCGC

CCCCCGACGGGCTCTCCCACCGAGGCTCAGGTGCTCGTGGGCAGCAAGGGGAAGCCCCATGGCCATGCCGCTTCCCTTTCACC

CTCAGCGACGCGCCCTCCTGTGCCCGCGGGGAACAAGACGGCTCTCGGCGGCCATGCAGGCGGCCTGTCCCACGAACACGATG

GAGACCTCAGACGCCGTCCCCACCCTGTCACTGTCACCATCACCCATCCTGTCCCCTCACGCCTCCCCACATCCCATCATTAC

TAC

32
chr18
GAAGTAGAATCACAGTAAATGAGGAGTTAGGGAATTTAGGGTAGAGATTAAAGTAATGAACAGAGGAGGAGGCCTGAGACAGC

group-
TGCAGAGAGACCCTGTGTTCCCTGTGAGGTGAAGCGTCTGCTGTCAAAGCCGGTTGGCGCTGAGAAGAGGTACCGGGGGCAGC

00430
ACCCGCCTCCTGGGAGAGGGATGGGCCTGCGGGCACCTGGGGCGCCACGCCACAGCCTCTTCCCCTCAGCACGCAGAGA

33
OLIG2
TACTCCGGCGACGGGAGGATGTTGAGGGAAGCCTGCCAGGTGAAGAAGGGGCCAGCAGCAGCACAGAGCTTCCGACTTTGCCT

TCCAGGCTCTAGACTCGCGCCATGCCAAGACGGGCCCCTCGACTTTCACCCCTGACTCCCAACTCCAGCCACTGGACCGAGCG

CGCAAAGAACCTGAGACCGCTTGCTCTCACCGCCGCAAGTCGGTCGCAGGACAGACACCAGTGGGCAGCAACAAAAAAAGAAA

CCGGGTTCCGGGACACGTGCCGGCGGCTGGACTAACCTCAGCGGCTGCAACCAAGGAGCGCGCACGTTGCGCCTGCTGGTGTT

TATTAGCTACACTGGCAGGCGCACAACTCCGCGCCCCGACTGGTGGCCCCACAGCGCGCACCACACATGGCCTCGCTGCTGTT

GGCGGGGTAGGCCCGAAGGAGGCATCTACAAATGCCCGAGCCCTTTCTGATCCCCACCCCCCCGCTCCCTGCGTCGTCCGAGT

GACAGATTCTACTAATTGAACGGTTATGGGTCATCCTTGTAACCGTTGGACGACATAACACCACGCTTCAGTTCTTCATGTTT

TAAATACATATTTAACGGATGGCTGCAGAGCCAGCTGGGAAACACGCGGATTGAAAAATAATGCTCCAGAAGGCACGAGACTG

GGGCGAAGGCGAGAGCGGGCTGGGCTTCTAGCGGAGACCGCAGAGGGAGACATATCTCAGAACTAGGGGCAATAACGTGGGTT

TCTCTTTGTATTTGTTTATTTTGTAACTTTGCTACTTGAAGACCAATTATTTACTATGCTAATTTGTTTGCTTGTTTTTAAAA

CCGTACTTGCACAGTAAAAGTTCCCCAACAACGGAAGTAACCCGACGTTCCTCACACTCCCTAGGAGACTGTGTGCGTGTGTG

CCCGCGCGTGCGCTCACAGTGTCAAGTGCTAGCATCCGAGATCTGCAGAAACAAATGTCTGAATTCGAAATGTATGGGTGTGA

GAAATTCAGCTCGGGGAAGAGATTAGGGACTGGGGGAGACAGGTGGCTGCCTGTACTATAAGGAACCGCCAACGCCAGCATCT

GTAGTCCAAGCAGGGCTGCTCTGTAAAGGCTTAGCAATTTTTTCTGTAGGCTTGCTGCACACGGTCTCTGGCTTTTCCCATCT

GTAAAATGGGTGAATGCATCCGTACCTCAGCTACCTCCGTGAGGTGCTTCTCCAGTTCGGGCTTAATTCCTCATCGTCAAGAG

TTTTCAGGTTTCAGAGCCAGCCTGCAATCGGTAAAACATGTCCCAACGCGGTCGCGAGTGGTTCCATCTCGCTGTCTGGCCCA

CAGCGTGGAGAAGCCTTGCCCAGGCCTGAAACTTCTCTTTGCAGTTCCAGAAAGCAGGCGACTGGGACGGAAGGCTCTTTGCT

AACCTTTTACAGCGGAGCCCTGCTTGGACTACAGATGCCAGCGTTGCCCCTGCCCCAAGGCGTGTGGTGATCACAAAGACGAC

ACTGAAAATACTTACTATCATCCGGCTCCCCTGCTAATAAATGGAGGGGTGTTTAACTACAGGCACGACCCTGCCCTTGTGCT

AGCGCGGTTACCGTGCGGAAATAACTCGTCCCTGTACCCACACCATCCTCAACCTAAAGGAGAGTTGTGAATTCTTTCAAAAC

ACTCTTCTGGAGTCCGTCCCCTCCCTCCTTGCCCGCCCTCTACCCCTCAAGTCCCTGCCCCCAGCTGGGGGCGCTACCGGCTG

CCGTCGGAGCTGCAGCCACGGCCATCTCCTAGACGCGCGAGTAGAGCACCAAGATAGTGGGGACTTTGTGCCTGGGCATCGTT

TACATTTGGGGCGCCAAATGCCCACGTGTTGATGAAACCAGTGAGATGGGAACAGGCGGCGGGAAACCAGACAGAGGAAGAGC

TAGGGAGGAGACCCCAGCCCCGGATCCTGGGTCGCCAGGGTTTTCCGCGCGCATCCCAAAAGGTGCGGCTGCGTGGGGCATCA

GGTTAGTTTGTTAGACTCTGCAGAGTCTCCAAACCATCCCATCCCCCAACCTGACTCTGTGGTGGCCGTATTTTTTACAGAAA

TTTGACCACGTTCCCTTTCTCCCTTGGTCCCAAGCGCGCTCAGCCCTCCCTCCATCCCCCTTGAGCCGCCCTTCTCCTCCCCC

TCGCCTCCTCGGGTCCCTCCTCCAGTCCCTCCCCAAGAATCTCCCGGCCACGGGCGCCCATTGGTTGTGCGCAGGGAGGAGGC

GTGTGCCCGGCCTGGCGAGTTTCATTGAGCGGAATTAGCCCGGATGACATCAGCTTCCCAGCCCCCCGGCGGGCCCAGCTCAT

TGGCGAGGCAGCCCCTCCAGGACACGCACATTGTTCCCCGCCCCCGCCCCCGCCACCGCTGCCGCCGTCGCCGCTGCCACCGG

GCTATAAAAACCGGCCGAGCCCCTAAAGGTGCGGATGCTTATTATAGATCGACGCGACACCAGCGCCCGGTGCCAGGTTCTCC

CCTGAGGCTTTTCGGAGCGAGCTCCTCAAATCGCATCCAGAGTAAGTGTCCCCGCCCCACAGCAGCCGCAGCCTAGATCCCAG

GGACAGACTCTCCTCAACTCGGCTGTGACCCAGAATGCTCCGATACAGGGGGTCTGGATCCCTACTCTGCGGGCCATTTCTCC

AGAGCGACTTTGCTCTTCTGTCCTCCCCACACTCACCGCTGCATCTCCCTCACCAAAAGCGAGAAGTCGGAGCGACAACAGCT

CTTTCTGCCCAAGCCCCAGTCAGCTGGTGAGCTCCCCGTGGTCTCCAGATGCAGCACATGGACTCTGGGCCCCGCGCCGGCTC

TGGGTGCATGTGCGTGTGCGTGTGTTTGCTGCGTGGTGTCGATGGAGATAAGGTGGATCCGTTTGAGGAACCAAATCATTAGT

TCTCTATCTAGATCTCCATTCTCCCCAAAGAAAGGCCCTCACTTCCCACTCGTTTATTCCAGCCCGGGGGCTCAGTTTTCCCA

CACCTAACTGAAAGCCCGAAGCCTCTAGAATGCCACCCGCACCCCGAGGGTCACCAACGCTCCCTGAAATAACCTGTTGCATG

AGAGCAGAGGGGAGATAGAGAGAGCTTAATTATAGGTACCCGCGTGCAGCTAAAAGGAGGGCCAGAGATAGTAGCGAGGGGGA

CGAGGAGCCACGGGCCACCTGTGCCGGGACCCCGCGCTGTGGTACTGCGGTGCAGGCGGGAGCAGCTTTTCTGTCTCTCACTG

ACTCACTCTCTCTCTCTCTCCCTCTCTCTCTCTCTCATTCTCTCTCTTTTCTCCTCCTCTCCTGGAAGTTTTCGGGTCCGAGG

GAAGGAGGACCCTGCGAAAGCTGCGACGACTATCTTCCCCTGGGGCCATGGACTCGGACGCCAGCCTGGTGTCCAGCCGCCCG

TCGTCGCCAGAGCCCGATGACCTTTTTCTGCCGGCCCGGAGTAAGGGCAGCAGCGGCAGCGCCTTCACTGGGGGCACCGTGTC

CTCGTCCACCCCGAGTGACTGCCC

34
SIM2
TTAATTCGAAAATGGCAGACAGAGCTGAGCGCTGCCGTTCTTTTCAGGATTGAAAATGTGCCAGTGGGCCAGGGGCGCTGGGA

CCCGCGGTGCGGAAGACTCGGAACAGGAAGAAATAGTGGCGCGCTGGGTGGGCTGCCCCGCCGCCCACGCCGGTTGCCGCTGG

TGACAGTGGCTGCCCGGCCAGGCACCTCCGAGCAGCAGGTCTGAGCGTTTTTGGCGTCCCAAGCGTTCCGGGCCGCGTCTTCC

AGAGCCTCTGCTCCCAGCGGGGTCGCTGCGGCCTGGCCCGAAGGATTTGACTCTTTGCTGGGAGGCGCGCTGCTCAGGGTTCT

G

35
SIM2
CCGGTCCCCAGTTTGGAAAAAGGCGCAAGAAGCGGGCTTTTCAGGGACCCCGGGGAGAACACGAGGGCTCCGACGCGGGAGAA

GGATTGAAGCGTGCAGAGGCGCCCCAAATTGCGACAATTTACTGGGATCCTTTTGTGGGGAAAGGAGGCTTAGAGGCTCAAGC

TATAGGCTGTCCTAGAGCAACTAGGCGAGAACCTGGCCCCAAACTCCCTCCTTACGCCCTGGCACAGGTTCCCGGCGACTGGT

GTTCCCAAGGGAGCCCCCTGAGCCTACCGCCCTTGCAGGGGGTCGTGCTGCGGCTTCTGGGTCATAAACGCCGAGGTCGGGGG

TGGCGGAGCTGTAGAGGCTGCCCGCGCAGAAAGCTCCAGGATCCCAATATGTG

36
DSCR6
GCGCAGGTCCCCCCAGTCCCCGAGGGAGTGCGCCCGACGGAAACGCCCCTAGCCCGCGGGCCTCGCTTTCCTCTCCCGGGTTC

CTGGGTCACTTCCCGCTGTCTC

37
DSCAM
TTCCCTCGCGGCTTTGGAAAGGGGGTGCAAATGCACCCTTCTGCGGGCCCGCTACCCGCTGCAACACCTGTGTTTCCTTTCTG

GGCACCTTCTAGGTTTCTAGATATTGCTGTGAATACGGTCCTCCGCTGTACAGTTGAAAACAAA

38
chr21
TGGGAATTTAGGTCGGGCACTGCCGATATGTCGCCTTCCACAAGGCGGGCCCGGGCCTCTGCTGACCGTGCACCGGTCCTGGG

group-
GCTGGGTAATTCTGCAGCAGCAGCGCAGCCCATGCCGGGGAATTTGCGGGCAGAGGAGACAGTGAGGCCCGCGTTCTGTGCGG

00165
GAACTCCCGAGCTCACAGAGCCCAAGACCACACGGCTGCATCGGATCGGGAGAGGGGCAGTGTCGCCCATCCCCGGAAGGCTG

AGCCTGGTGCAG

39
PRMT2
CGGTTTTCTCCTGGAGGACTGTGTTCAGACAGATACTGGTTTCCTTATCCGCAGGTGTGCGCGGCGCTCGCAAGTGGTCAGCA

TAACGCCGGGCGAATTCGGAAAGCCCGTGCGTCCGTGGACGACCCACTTGGAAGGAGTTGGGAGAAGTCCTTGTTCCCACGCG

CGGACGCTTCCCTCCGTGTGTCCTTCGAGCCACAAAAAGCCCAGACCCTAACCCGCTCCTTTCTCCCGCCGCGTCCATGCAGA

ACTCCGCCGTTCCTGGGAGGGGAAGCCCGCGAGGCGTCGGGAGAGGCACGTCCTCCGTGAGCAAAGAGCTCCTCCGAGCGCGC

GGCGGGGACGCTGGGCCGACAGGGGACCGCGGGGGCAGGGCGGAGAGGACCCGCCCTCGAGTCGGCCCAGCCCTAACACTCAG

GAC

40
SIX2
AGGGAATCGGGCTGACCAGTCCTAAGGTCCCACGCTCCCCTGACCTCAGGGCCCAGAGCCTCGCATTACCCCGAGCAGTGCGT

TGGTTACTCTCCCTGGAAAGCCGCCCCCGCCGGGGCAAGTGGGAGTTGCTGCACTGCGGTCTTTGGAGGCCTAGGTCGCCCAG

AGTAGGCGGAGCCCTGTATCCCTCCTGGAGCCGGCCTGCGGTGAGGTCGGTACCCAGTACTTAGGGAGGGAGGACGCGCTTGG

TGCTCAGGGTAGGCTGGGCCGCTGCTAGCTCTTGATTTAGTCTCATGTCCGCCTTTGTGCCGGCCTCTCCGATTTGTGGGTCC

TTCCAAGAAAGAGTCCTCTAGGGCAGCTAGGGTCGTCTCTTGGGTCTGGCGAGGCGGCAGGCCTTCTTCGGACCTATCCCCAG

AGGTGTAACGGAGACTTTCTCCACTGCAGGGCGGCCTGGGGCGGGCATCTGCCAGGCGAGGGAGCTGCCCTGCCGCCGAGATT

GTGGGGAAACGGCGTGGAAGACACCCCATCGGAGGGCACCCAATCTGCCTCTGCACTCGATTCCATCCTGCAACCCAGGAGAA

ACCATTTCCGAGTTCCAGCCGCAGAGGCACCCGCGGAGTTGCCAAAAGAGACTCCCGCGAGGTCGCTCGGAACCTTGACCCTG

ACACCTGGACGCGAGGTCTTTCAGGACCAGTCTCGGCTCGGTAGCCTGGTCCCCGACCACCGCGACCAGGAGTTCCTTCTTCC

CTTCCTGCTCACCAGCCGGCCGCCGGCAGCGGCTCCAGGAAGGAGCACCAACCCGCGCTGGGGGCGGAGGTTCAGGCGGCAGG

AATGGAGAGGCTGATCCTCCTCTAGCCCCGGCGCATTCACTTAGGTGCGGGAGCCCTGAGGTTCAGCCTGACTTTC

41
SIX2
CACTACGGATCTGCCTGGACTGGTTCAGATGCGTCGTTTAAAGGGGGGGGCTGGCACTCCAGAGAGGAGGGGGCGCTGCAGGT

TAATTGATAGCCACGGAAGCACCTAGGCGCCCCATGCGCGGAGCCGGAGCCGCCAGCTCAGTCTGACCCCTGTCTTTTCTCTC

CTCTTCCCTCTCCCACCCCTCACTCCGGGAAAGCGAGGGCCGAGGTAGGGGCAGATAGATCACCAGACAGGCGGAGAAGGACA

GGAGTACAGATGGAGGGACCAGGACACAGAATGCAAAAGACTGGCAGGTGAGAAGAAGGGAGAAACAGAGGGAGAGAGAAAGG

GAGAAACAGAGCAGAGGCGGCCGCCGGCCCGGCCGCCCTGAGTCCGATTTCCCTCCTTCCCTGACCCTTCAGTTTCACTGCAA

ATCCACAGAAGCAGGTTTGCGAGCTCGAATACCTTTGCTCCACTGCCACACGCAGCACCGGGACTGGGCGTCTGGAGCTTAAG

TCTGGGGGTCTGAGCCTGGGACCGGCAAATCCGCGCAGCGCATCGCGCCCAGTCTCGGAGACTGCAACCACCGCCAAGGAGTA

CGCGCGGCAGGAAACTTCTGCGGCCCAATTTCTTCCCCAGCTTTGGCATCTCCGAAGGCACGTACCCGCCCTCGGCACAAGCT

CTCTCGTCTTCCACTTCGACCTCGAGGTGGAGAAAGAGGCTGGCAAGGGCTGTGCGCGTCGCTGGTGTGGGGAGGGCAGCAGG

CTGCCCCTCCCCGCTTCTGCAGCGAGTTTTCCCAGCCAGGAAAAGGGAGGGAGCTGTTTCAGGAATTTCAGTGCCTTCACCTA

GCGACTGACACAAGTCGTGTGTATAGGAAG

42
SOX14
GGAGCCTGAAGTCAGAAAAGATGGGGCCTCGTTACTCACTTTCTAGCCCAGCCCCTGGCCCTGGGTCCCGCAGAGCCGTCATC

GCAGGCTCCTGCCCAGCCTCTGGGGTCGGGTGAGCAAGGTGTTCTCTTCGGAAGCGGGAAGGGCTGCGGGTCGGGGACGTCCC

TTGGCTGCCACCCCTGATTCTGCATCCTTTTCGCTCGAATCCCTGCGCTAGGCATCCTCCCCGATCCCCCAAAAGCCCAAGCA

CTGGGTCTGGGTTGAGGAAGGGAACGGGTGCCCAGGCCGGACAGAGGCTGAAAGGAGGCCTCAAGGTTCCTCTTTGCTACAAA

GTGGAGAAGTTGCTCTACTCTGGAGGGCAGTGGCCTTTTCCAAACTTTTCCACTTAGGTCCGTAAGAAAAGCAATTCATACAC

GATCAGCGCTTTCGGTGCGAGGATGGAAAGAAACTTC

43
TLX3
TTTTCCTGTTACAGAGCTGAGCCCACTCATGTGGTGCCAAGTAGCGACTATCTCTCGGCCACCTCCACCCAGAGCAATGTGGG

CGCCCCCAGCGGGTGGGAGCGATTGCCGAGCGGCGCAAGGGCGTTTAACGCCTAACCCCCTCCTCCTGGGTTGCCAAGCCGCT

AGGTCGCCGTTTCCAACGTGGCTGCGCGGGACTGAAGTCCGACGACTCCTCGTCCTCAGTAGGAGACACACCTCCCACTGCCC

CCAGCCACGCGAGCTATGGGCAGAATCGGGGCAACGGTAATATCTGGATGGGGCAGGCTCCCCTGAGGCTGTGCTTAAGAAAA

AAGGAATCTGGAGTAGCCTGAGGGGCCCCACGAGGGGGCCTCCTTTGCGATCGTCTCCCAGCCTTAGGCCAAGGCTACGGAGG

CAGGCGGCCGAGTGTTGGCGCCCAGCCCGGCCGAGGACTGGATGGAGGACGAGAAGCAGCCTGCCTCTGGGCGACAGCTGCGG

ACGCAGCCTCGCCGCCTCGCCGCCTCAGCCTCGGTCCCAGCGTCTCTAAAGCCGCGCCCATTTTACAGATGCAGGGCAGGGAG

ACAAGAGGCATCTCCGGGGGCCGAGTAGAATGATGGCGCGGGTTCTCCCGGCGCCCTGATTTCGAGGCTGCGCCCGGGGCCCT

ACATGCAGGCGGGGAGGCCTGGGCCGAAGGCGTCTGCAAGGAGGGGCGAGTCTGCCCGGTCCGGGCAGGGAGTGAGGCCACAG

TCAGTTCTCCCTAGGAGGCCGCGCAGCGGGTAGGGTATGGGACTGGGGGACGCAACGGGGACCTGGCCGAATCAGAGCCCTCA

GCAGAGAACGCCGAAAACTCTGGGGCCGGCCGCTCGCTTCCCGCTAGTGGGAATGGTTTCCGGTCATCCGTTCCCAGTCCAGC

CCCGGGTAGGGAGCTCTGATTTGCAATGCACAGCACTTGCGAGGTTCGAATGCCCCCGCAATTTGCAGATGGAAATACTAAGC

CTAGGCCGGGCGTGGTGGCTCAAGCCTATCATCTCAGCCCTTTGGGAGGCCAAGCCGGGAGGATTGTTTGAGCCCAAGAATTC

AAAACCAGCCTGAGCAACATAGCGACCCCGTCTCTACAAAATAAAATAAAATAAATTATCCGGGCGTGGTGGCACGCGCCTGT

GGTTCCAGCTACTCCGGAGGCTGAGGTGGGAGGATCGCTTGAGTCCGGGAGGTCGAGGCTACAGTGAGCCGTGATCGCACCAC

TGCACTCCAGCCTGGGCGACAGAGTGAGACCTTGTCTCAAAAAAGGAAAAAAAGAAAAAGAAAGTAAGCTTCAAAGAAGCTCT

GATAATAGTTCTGGGTCGTGCAGCGGTGGCGGCCCCGCGCTCTCGCCCCTAAAGCAAGCGCTCTTTGTACTGGGTGGAGGAGC

TTTGAGTAGTGAGGGTGGAGATGCAGCTTCGGGGTGGCGCAGCCACCCTGACACTAGGCCCGGGGTCGCAGTGGGACAGAAGA

GTCTGCCGCTCTGACTTGGGCTCTGAGTTCCAAGGGCGCCCGGCACTTCTAGCCTCCCAGGCTTGCGCGCTGGCGCCTTTGCC

ATCCGTGCCGAAGTGGGGAGACCTAGCCGCGACCACCACGAGCGCAGCGGTGACACCCAGAGGTCCCACCGGGCCCCTGGGCA

GGGTAACCTTAGCCTGTCCGCTTCGGCAGCTTTGCGAAGAGTGGCGCGCAGCTAGGGCTGAGGCTCTTGCGGACCTGCGGTCG

AAGCAGGCGGCTGAGCCAGTTCGATCGCCAAGGCCTGGGCTGCCGACAGTGGTGCGCGCTCTGTTCCGCCGCGGCCGGGCCAG

GCGCTCTGGAATAGCGATGGGGGGACACGGCCTCCAACTTTCTGCAGAGACCATCGGGCAGCTCCGGGCCTAAGCAGCGACCT

CACCGAAGGTTCCTGGGAACCTTTGCCAAAATCCCAGCCTCTGCCTCGGTCCAGCTAAACCGTGTGTAAACAAGTGCACCAAG

44
FOXP4
ATAAAGGACCGGGTAATTTCGCGGAATGCGGATTTTGAGACAGGCCCAGACGGCGGCGGATTCCCTGTGTCCCCCAACTGGGG

CGATCTCGTGAACACACCTGCGTCCCACCCCGATCCTAGGTTGGGGGGAAAGGGTATGGGAACCCTGAGCCCAGAGCGCGCCC

CGCTCTTTCCTTTGCTCCCCGGCTTCCCTGGCCAGCCCCCTCCCGGCTGGTTTCCTCGCTCACTCGGCGCCTGGCGTTTCGGG

CGTCTGGAGATCACCGCGTGTCTGGCACCCCAACGTCTAGTCTCCCCGCAGGTTGACCGCGGCGCCTGGAGCCGGGAATAGGG

GTGGGGAGTCCGGAGAACCAAACCCGAGCCTGAAGTTGCCATTCGGGTGACTCCCGAGAAAGCCCGGGAGCATTTTGGCCAAT

GCGGGTTTTTACCTGAACTTCAGCATCTTCACC

45
FOXP4
AATTGGAAAACCCTGGTATTGTGCCTGTTTGGGGGAAGAAAACGTCAATAAAAATTAATTGATGAGTTGGCAGGGCGGGCGGT

GCGGGTTCGCGGCGAGGCGCAGGGTGTCATGGCAAATGTTACGGCTCAGATTAAGCGATTGTTAATTAAAAAGCGACGGTAAT

TAATACTCGCTACGCCATATGGGCCCGTGAAAAGGCACAAAAGGTTTCTCCGCATGTGGGGTTCCCCTTCTCTTTTCTCCTTC

CACAAAAGCACCCCAGCCCGTGGGTCCCCCCTTTGGCCCCAAGGTAGGTGGAACTCGTCACTTCCGGCCAGGGAGGGGATGGG

GCGGTCTCCGGCGAGTTCCAAGGGCGTCCCTCGTTGCGCACTCGCCCGCCCAGGTTCTTTGAA

46
chr7
GGGAAGCGATCGTCTCCTCTGTCAACTCGCGCCTGGGCACTTAGCCCCTCCCGTTTCAGGGCGCCGCCTCCCCGGATGGCAAA

group-
CACTATAAAGTGGCGGCGAATAAGGTTCCTCCTGCTGCTCTCGGTTTAGTCCAAGATCAGCGATATCACGCGTCCCCCGGAGC

00267
ATCGCGTGCAGGAGCCATGGCGCGGGAGCTATACCACGAAGAGTTCGCCCGGGCGGGCAAGCAGGCGGGGCTGCAGGTCTGGA

GGATTGAGAAGCTGGAGCTGGTGCCCGTGCCCCAGAGCGCTCACGGCGACTTCTACGTCGGGGATGCCTACCTGGTGCTGCAC

ACGGCCAAGACGAGCCGAGGCTTCACCTACCACCTGCACTTCTGGCTCGGTAAGGGACGGCGGGCGGCGGGACCCCGACGCAC

CAAGGCCGGCGAGGGGAGGGCGTAGGGGTCTGAGATTTGCAGGCGTGGGAGTAAAGGGGACCGCAAACTGAGCTAG

47
NPY
CTCAGGGGCGGGAAGTGGCGGGTGGGAGTCACCCAAGCGTGACTGCCCGAGGCCCCTCCTGCCGCGGCGAGGAAGCTCCATAA

AAGCCCTGTCGCGACCCGCTCTCTGCACCCCATCCGCTGGCTCTCACCCCTCGGAGACGCTCGCCCGACAGCATAGTACTTGC

CGCCCAGCCACGCCCGCGCGCCAGCCACCGTGAGTGCTACGACCCGTCTGTCTAGGGGTGGGAGCGAACGGGGCGCCCGCGAA

CTTGCTAGAGACGCAGCCTCCCGCTCTGTGGAGCCCTGGGGCCCTGGGATGATCGCGCTCCACTCCCCAGCGGACTATGCCGG

CTCCGCGCCCCGACGCGGACCAGCCCTCTTGGCGGCTAAATTCCACTTGTTCCTCTGCTCCCCTCTGATTGTCCACGGCCCTT

CTCCCGGGCCCTTCCCGCTGGGCGGTTCTTCTGAGTTACCTTTTAGCAGATATGGAGGGAGAACCCGGGACCGCTATCCCAAG

GCAGCTGGCGGTCTCCCTGCGGGTCGCCGCCTTGAGGCCCAGGAAGCGGTGCGCGGTAGGAAGGTTTCCCCGGCAGCGCCATC

GAGTGAGGAATCCCTGGAGCTCTAGAGCCCCGCGCCCTGCCACCTCCCTGGATTCTTGGGCTCCAAATCTCTTTGGAGCAATT

CTGGCCCAGGGAGCAATTCTCTTTCCCCTTCCCCACCGCAGTCGTCACCCCGAGGTGATCTCTGCTGTCAGCGTTGATCCCCT

GAAGCTAGGCAGACCAGAAGTAACAGAGAAGAAACTTTTCTTCCCAGACAAGAGTTTGGGCAAGAAGGGAGAAAAGTGACCCA

GCAGGAAGAACTTCCAATTCGGTTTTGAATGCTAAACTGGCGGGGCCCCCACCTTGCACTCTCGCCGCGCGCTTCTTGGTCCC

TGAGACTTCGAACGAAGTTGCGCGAAGTTTTCAGGTGGAGCAGAGGGGCAGGTCCCGACCGGACGGCGCCCGGAGCCCGCAAG

GTGGTGCTAGCCACTCCTGGGTTCTCTCTGCGGGACTGGGACGAGAGCGGATTGGGGGTCGCGTGTGGTAGCAGGAGGAGGAG

CGCGGGGGGCAGAGGAGGGAGGTGCTGCGCGTGGGTGCTCTGAATCCCCAAGCCCGTCCGTTGAGCCTTCTGTGCCTGCAGAT

GCTAGGTAACAAGCGACTGGGGCTGTCCGGACTGACCCTCGCCCTGTCCCTGCTCGTGTGCCTGGGTGCGCTGGCCGAGGCGT

ACCCCTCCAAGCCGGACAACCCGGGCGAGGACGCACCAG

48
SHH
TGGAGAACCTTGGGCTCTGTGGCCTCAAAGGTAGGGGTGATTTCGAGGGGCCGGCACCTCACAGGGCAGGTTCCACCGCGGAA

ACGCAGTCATCGCCCAGCGACCCTGCTCCTGGCCCTCAGCCTCCCCCCAGGTTTCTTTTTCTCTTGAATCAAGCCGAGGTGCG

CCAATGGCCTTCCTTGGGTCGGATCCGGGGGGCCAGGGCCAGCTTACCTGCTTTCACCGAGCAGTGGATATGTGCCTTGGACT

CGTAGTACACCCAGTCGAAGCCGGCCTCCACCGCCAGGCGGGCCAGCATGCCGTACTTGCTGCGGTCGCGGTCAGACGTGGTG

ATGTCCACTGCGCGGCCCTCGTAGTGCAGAGACTCCTCTGAGTGGTGGCCATCTTCGTCCCAGCCCTCGGTCACCCGCAGTTT

CACTCCTGGCCACTGGTTCATCACCGAGATGGCCAAAGCGTTCAACTTGTCCTTACACCTCTGCGAAGACAAGGGGACCCCCA

CCGACGGACACGTTAGCCTGGGCAACCGCCACCCCTCCCGGCCCCTCCATCAGCCT

49
OSR2
TCTCACGACCCATCCGTTAACCCACCGTTCCCAGGAGCTCCGAGGCGCAGCGGCGACAGAGGTTCGCCCCGGCCTGCTAGCAT

TGGCATTGCGGTTGACTGAGCTTCGCCTAACAGGCTTGGGGAGGGTGGGCTGGGCTGGGCTGGGCTGGGCTGGGTGCTGCCCG

GCTGTCCGCCTTTCGTTTTCCTGGGACCGAGGAGTCTTCCGCTCCGTATCTGCCTAGAGTCTGAATCCGACTTTCTTTCCTTT

GGGCACGCGCTCGCCAGTGGAGCACTTCTTGTTCTGGCCCCGGGCTGATCTGCACGCGGACTTGAGCAGGTGCCAAGGTGCCA

CGCAGTCCCCTCACGGCTTTCGGGGGGTCTTGGAGTCGGGTGGGGAGGGAGACTTAGGTGTGGTAACCTGCGCAGGTGCCAAA

GGGCAGAAGGAGCAGCCTTGGATTATAGTCACGGTCTCTCCCTCTCTTCCCTGCCATTTTTAGGGCTTTCTCTACGTGCTGTT

GTCTCACTGGGTTTTTGTCGGAGCCCCACGCCCTCCGGCCTCTGATTCCTGGAAGAAAGGGTTGGTCCCCTCAGCACCCCCAG

CATCCCGGAAAATGGGGAGCAAGGCTCTGCCAGCGCCCATCCCGCTCCACCCGTCGCTGCAGCTCACCAATTACTCCTTCCTG

CAGGCCGTGAACACCTTCCCGGCCACGGTGGACCACCTGCAGGGCCTGTACGGTCTCAGCGCGGTACAGACCATGCACATGAA

CCACTGGACGCTGGGGTATCCCAAT

50
GLIS3
TGGTTTCCTTTCGCTTCTCGCCTCCCAAACACCTCCAGCAAGTCGGAGGGCGCGAACGCGGAGCCAGAAACCCTTCCCCAAAG

TTTCTCCCGCCAGGTACCTAATTGAATCATCCATAGGATGACAAATCAGCCAGGGCCAAGATTTCCAGACACTTGAGTGACTT

CCCGGTCCCCGAGGTGACTTGTCAGCTCCAGTGAGTAACTTGGAACTGTCGCTCGGGGCAAGGTGTGTGTCTAGGAGAGAGCC

GGCGGCTCACTCACGCTTTCCAGAGAGCGACCCGGGCCGACTTCAAAATACACACAGGGTCATTTATAGGGACTGGAGCCGCG

CGCAGGACAACGTCTCCGAGACTGAGACATTTTCCAAACAGTGCTGACATTTTGTCGGGCCCCATAAAAAATGTAAACGCGAG

GTGACGAACCCGGCGGGGAGGGTTCGTGTCTGGCTGTGTCTGCGTCCTGGCGGCGTGGGAGGTTATAGTTCCAGACCTGGCGG

CTGCGGATCGCCGGGCCGGTACCCGCGAGGAGTGTAGGTACCCTCAGCCCGACCACCTCCCGCAATCATGGGGACACCGGCTT

GGATGAGACACAGGCGTGGAAAACAGCCTTCGTGAAACTCCACAAACACGTGGAACTTGAAAAGACAACTACAGCCCCGCGTG

TGCGCGAGAGACCTCACGTCACCCCATCAGTTCCCACTTCGCCAAAGTTTCCCTTCAGTGGGGACTCCAGAGTGGTGCGCCCC

ATGCCCGTGCGTCCTGTAACGTGCCCTGATTGTGTACCCCTCTGCCCGCTCTACTTGAAATGAAAACACAAAAACTGTTCCGA

ATTAGCGCAACTTTAAAGCCCCGTTATCTGTCTTCTACACTGGGCGCTCTTAGGCCACTGACAGAAACATGGTTTGAACCCTA

ATTGTTGCTATCAGTCTCAGTCAGCGCAGGTCTCTCAGTGACCTGTGACGCCGGGAGTTGAGGTGCGCGTATCCTTAAACCCG

CGCGAACGCCACCGGCTCAGCGTAGAAAACTATTTGTAATCCCTAGTTTGCGTCTCTGAGCTTTAACTCCCCCACACTCTCAA

GCGCCCGGTTTCTCCTCGTCTCTCGCCTGCGAGCAAAGTTCCTATGGCATCCACTTACCAGGTAACCGGGATTTCCACAACAA

AGCCCGGCGTGCGGGTCCCTTCCCCCGGCCGGCCAGCGCGAGTGACAGCGGGCGGCCGGCGCTGGCGAGGAGTAACTTGGGGC

TCCAGCCCTTCAGAGCGCTCCGCGGGCTGTGCCTCCTTCGGAAATGAAAACCCCCATCCAAACGGGGGGACGGAGCGCGGAAA

CCCGGCCCAAGTGCCGTGTGTGCGCGCGCGTCTG

51
PRMT8
GAAAGCCATCCTTACCATTCCCCTCACCCTCCGCCCTCTGATCGCCCACCCGCCGAAAGGGTTTCTAAAAATAGCCCAGGGCT

TCAAGGCCGCGCTTCTGTGAAGTGTGGAGCGAGCGGGCACGTAGCGGTCTCTGCCAGGTGGCTGGAGCCCTGGAAGCGAGAAG

GCGCTTCCTCCCTGCATTTCCACCTCACCCCACCCCCGGCTCATTTTTCTAAGAAAAAGTTTTTGCGGTTCCCTTTGCCTCCT

ACCCCCGCTGCCGCGCGGGGTCTGGGTGCAGACCCCTGCCAGGTTCCGCAGTGTGCAGCGGCGGCTGCTGCGCTCTCCCAGCC

TCGGCGAGGGTTAAAGGCGTCCGGAGCAGGCAGAGCGCCGCGCGCCAGTCTATTTTTACTTGCTTCCCCCGCCGCTCCGCGCT

CCCCCTTCTCAGCAGTTGCACATGCCAGCTCTGCTGAAGGCATCAATGAAAACAGCAGTAG

52
TBX3
ATCGAAAATGTCGACATCTTGCTAATGGTCTGCAAACTTCCGCCAATTATGACTGACCTCCCAGACTCGGCCCCAGGAGGCTC

GTATTAGGCAGGGAGGCCGCCGTAATTCTGGGATCAAAAGCGGGAAGGTGCGAACTCCTCTTTGTCTCTGCGTGCCCGGCGCG

CCCCCCTCCCGGTGGGTGATAAACCCACTCTGGCGCCGGCCATGCGCTGGGTGATTAATTTGCGAACAAACAAAAGCGGCCTG

GTGGCCACTGCATTCGGGTTAAACATTGGCCAGCGTGTTCCGAAGGCTTGT

53
chr12
ATCAACATCGTGGCTTTGGTCTTTTCCATCATGGTGAGTGAATCACGGCCAGAGGCAGCCTGGGAGGAGAGACCCGGGCGGCT

group-
TTGAGCCCCTGCAGGGGAGTCCGCGCGCTCTCTGCGGCTCCCTTCCTCACGGCCCGGCCCGCGCTAGGTGTTCTTTGTCCTCG

00801
CACCTCCTCCTCACCTTTCTCGGGCTCTCAGAGCTCTCCCCGCAATCATCAGCACCTCCTCTGCACTCCTCGTGGTACTCAGA

GCCCTGATCAAGCTTCCCCCAGGCTAGCTTTCCTCTTCTTTCCAGCTCCCAGGGTGCGTTTCCTCTCCAACCCGGGGAAGTTC

TTCCGTGGACTTTGCTGACTCCTCTGACCTTCCTAGGCACTTGCCCGGGGCTTCTCAACCCTCTTTTCTAGAGCCCCAGTGCG

CGCCACCCTAGCGAGCGCAGTAAGCTCATACCCCGAGCATGCAGGCTCTACGTTCCTTTCCCTGCCGCTCCGGGGGCTCCTGC

TCTCCAGCGCCCAGGACTGTCTCTATCTCAGCCTGTGCTCCCTTCTCTCTTTGCTGCGCCCAAGGGCACCGCTTCCGCCACTC

TCCGGGGGGTCCCCAGGCGATTCCTGATGCCCCCTCCTTGATCTTAACGCGCCCGAGGCTGGCTCACACCCACTACCTCTTTA

GGCCTTTCTTAGGCTCCCCGTGTGCCCCCCTCACCAGCAAAGTGGGTGCGCCTCTCTTACTCTTTCTACCCAGCGCGTCGTAG

TTCCTCCCCGTTTGCTGCGCACTGGCCCTAACCTCTCTTCTCTTGGTGTCCCCCAGAGCTCCCAGGCGCCCCTCCACCGCTCT

GTCCTGCGCCCGGGGCTCTCCCGGGAATGAACTAGGGGATTCCACGCAACGTGCGGCTCCGCCCGCCCTCTGCGCTCAGACCT

CCCGAGCTGCCCGCCTCTCTAGGAGTGGCCGCTGGGGCCTCTAGTCCGCCCTTCCGGAGCTCAGCTCCCTAGCCCTCTTCAAC

CCTGGTAGGAACACCCGAGCGAACCCCACCAGGAGGGCGACGAGCGCCTGCTAGGCCCTCGCCTTATTGACTGCAGCAGCTGG

CCCGGGGGTGGCGGCGGGGTGAGGTTCGTACCGGCACTGTCCCGGGACAACCCTTGCAGTTGC

54
PAX9
ACAAATAAAACACCCTCTAGCTTCCCCTAGACTTTGTTTAACTGGCCGGGTCTCCAGAAGGAACGCTGGGGATGGGATGGGTG

GAGAGAGGGAGCGGCTCAAGGACTTTAGTGAGGAGCAGGCGAGAAGGAGCACGTTCAGGCGTCAAGACCGATTTCTCCCCCTG

CTTCGGGAGACTTTTGAACGCTCGGAGAGGCCCGGCATCTCACCACTTTACTTGGCCGTAGGGGCCTCCGGCACGGCAGGAAT

GAGGGAGGGGGTCCGATTGGACAGTGACGGTTTGGGGCCGTTCGGCTATGTTCAGGGACCATATGGTTTGGGGACAGCCCCAG

TAGTTAGTAGGGGACGGGTGCGTTCGCCCAGTCCCCGGATGCGTAGGGAGGCCCAGTGGCAGGCAGCTGTCCCAAGCAGCGGG

TGCGCGTCCCTGCGCGCTGTGTGTTCATTTTGCAGAGCCAGCCTTCGGGGAGGTGAACCAGCTGGGAGGAGTGTTCGTGAACG

GGAGGCCGCTGCCCAACGCCATCCGGCTTCGCATCGTGGAACTGGCCCAACTGGGCATCCGACCGTGTGACATCAGCCGCCAG

CTACGGGTCTCGCACGGCTGCGTCAGCAAGATCCTGGCGCGATACAACGAGACGGGCTCGATCTTGCCAGGAGCCATCGGGGG

CAGCAAGCCCCGGGTCACTACCCCCACCGTGGTGAAACACATCCGGACCTACAAGCAGAGAGACCCCGGCATCTTCGCCTGGG

AGATCCGGGACCGCCTGCTGGCGGACGGCGTGTGCGACAAGTACAATGTGCCCTCCGTGAGCTCCATCAGCCGCATTCTGCGC

AACAAGATCGGCAACTTGGCCCAGCAGGGTCATTACGACTCATACAAGCAGCACCAGCCGACGCCGCAGCCAGCGCTGCCCTA

CAACCACATCTACTCGTACCCCAGCCCTATCACGGCGGCGGCCGCCAAGGTGCCCACGCCACCCGGGGTGC

55
SIX1
AGGAGGCGCAACGCGCTGCCAGGGCGGCTTTATCCTGCCGCCACAGGGCGGGGACCAGCCCGGCAGCCGGGTGTCCAGCGCCG

CTCACGTGCCTCGCCTGGAGCTTAGCTCTCAGACTCCGAAGAGGGCGACTGAGACTTGGGCCTGGGAGTTGGCTTCGGGGTAC

CCAAGGCGACGACAGCTGAGTTGTACCACGAAGCTCAGGCCGAGGCCTCCTCCCTTGTCTGGCCTTCGAATCCATACTGGCAG

CCTCTCCTCTCAGGCACTCCGCGGGCCGGGCCACTAGGCCCCCTGCTCCTGGAGCTGCGCTATGATCCGGGTCTTGAGATGCG

CGCGATTCTCTCTGAACCGGTGGAGAGGAGGCTCTGCCCCGCGCGGAGCGAGGACAGCGGCGCCCGAGCTTCCCGCGCCTCTC

CAGGGCCCAATGGCAAGAACAGCCTCCGAAGTGCGCGGATGACAGGAAAAGATCTTCAGTTCTTCTGCCGCTAGAGAAGTGCG

GGATACAAGCCTCTATTGGATCCACAACCTGGAGTCCTGCCTTCGGA

56
ISL2
ATCTGCGTGCCCTTTTCTGGGCGAGCCCTGGGAGATCCAGGGAGAACTGGGCGCTCCAGATGGTGTATGTCTGTACCTTCACA

GCAAGGCTTCCCTTGGATTTGAGGCTTCCTATTTTGTCTGGGATCGGGGTTTCTCCTTGTCCCAGTGGCAGCCCCGCGTTGCG

GGTTCCGGGCGCTGCGCGGAGCCCAAGGCTGCATGGCAGTGTGCAGCGCCCGCCAGTCGGGCTGGTGGGTTGTGCACTCCGTC

GGCAGCTGCAGAAAGGTGGGAGTGCAGGTCTTGCCTTTCCTCACCGGGCGGTTGGCTTCCAGCACCGAGGCTGACCTATCGTG

GCAAGTTTGCGGCCCCCGCAGATCCCCAGTGGAGAAAGAGGGCTCTTCCGATGCGATCGAGTGTGCGCCTCCCCGCAAAGCAA

TGCAGACCCTAAATCACTCAAGGCCTGGAGCTCCAGTCTCAAAGGTGGCAGAAAAGGCCAGACCTAACTCGAGCACCTACTGC

CTTCTGCTTGCCCCGCAGAGCCTTCAGGGACTGACTGGGACGCCCCTGGTGGCGGGCAGTCCCATCCGCCATGAGAACGCCGT

GCAGGGCAGCGCAGTGGAGGTGCAGACGTACCAGCCGCCGTGGAAGGCGCTCAGCGAGTTTGCCCTCCAGAGCGACCTGGACC

AACCCGCCTTCCAACAGCTGGTGAGGCCCTGCCCTACCCGCCCCGACCTCGGGACTCTGCGGGTTGGGGATTTAGCCACTTAG

CCTGGCAGAGAGGGGAGGGGGTGGCCTTGGGCTGAGGGGCTGGGTACAGCCCTAGGCGGTGGGGGAGGGGGAACAGTGGCGGG

CTCTGAAACCTCACCTCGGCCCATTACGCGCCCTAAACCAGGTCTCCCTGGATTAAAGTGCTCACAAGAGAGGTCGCAGGATT

AACCAACCCGCTCCCCCGCCCTAATCCCCCCCTCGTGCGCCTGGGGACCTGGCCTCCTTCTCCGCAGGGCTTGCTCTCAGCTG

GCGGCCGGTCCCCAAGGGACACTTTCCGACTCGGAGCACGCGGCCCTGGAGCACCAGCTCGCGTGCCTCTTCACCTGCCTCTT

CCCGGTGTTTCCGCCGCCCCAGGTCTCCTTCTCCGAGTCCGGCTCCCTAGGCAACTCCTCCGGCAGCGACGTGACCTCCCTGT

CCTCGCAGCTCCCGGACACCCCCAACAGTATGGTGCCGAGTCCCGTGGAGACGTGAGGGGGACCCCTCCCTGCCAGCCCGCGG

ACCTCGCATGCTCCCTGCATGAGACTCACCCATGCTCAGGCCATTCCAGTTCCGAAAGCTCTCTCGCCTTCGTAATTATTCTA

TTGTTATTTATGAGAGAGTACCGAGAGACACGGTCTGGACAGCCCAAGGCGCCAGGATGCAACCTGCTTTCACCAGACTGCAG

ACCCCTGCTCCGAGGACTCTTAGTTTTTCAAAACCAGAATCTGGGACTTACCAGGGTTAGCTCTGCCCTCTCCTCTCCTCTCT

ACGTGGCCGCCGCTCTGTCTCTCCACGCCCCACCTGTGT

57
DLX4
AGGTCTCTTCAGACTGCCCATTCTCCGGGCCTCGCTGAATGCGGGGGCTCTATCCACAGCGCGCGGGGCCGAGCTCAGGCAGG

CTGGGGCGAAGATCTGATTCTTTCCTTCCCGCCGCCAAACCGAATTAATCAGTTTCTTCAACCTGAGTTACTAAGAAAGAAAG

GTCCTTCCAAATAAAACTGAAAATCACTGCGAATGACAATACTATACTACAAGTTCGTTTTGGGGCCGGTGGGTGGGATGGAG

GAGAAAGGGCACGGATAATCCCGGAGGGCCGCGGAGTGAGGAGGACTATGGTCGCGGTGGAATCTCTGTTCCGCTGGCACATC

CGCGCAGGTGCGGCTCTGAGTGCTGGCTCGGGGTTACAGACCTCGGCATCCGGCTGCAGGGGCAGACAGAGACCTCCTCTGCT

AGGGCGTGCGGTAGGCATCGTATGGAGCCCAGAGACTGCCGAGAGCACTGCGCACTCACCAAGTGTTAGGGGTGCCCGTGATA

GACCGCCAGGGAAGGGGCTGGTTCGGAGGGAATTCCCGCTACCGGGAAGGTCGGAACTCGGGGTGATCAAACAAGGAATGCAT

CTCACCTCCGTGGGTGCTTGTGCTGCGCAAGGAATTATTACCGGAGCGGTTGCGATGGCCTTTGCCCGGCGACCCAAGAAGAG

TAAGCAAACTACCGTCCACCCAGCGGATCAGGTCCAAT

58
CBX4
GATGTCCTGTTTCTAGCAGCCTCCAGAGCCAAGCTAGGCGAGAGGCGTAGGAGGCAGAGAGAGCGGGCGCGGGAGGCCAGGGT

CCGCCTGGGGGCCTGAGGGGACTTCGTGGGGTCCCGGGAGTGGCCTAGAAACAGGGAGCTGGGAGGGCCGGGAAGAGCTTGAG

GCTGAGCGGGGGACGAACGGGCAGCGCAAAGGGGAGATGAACGGAATGGCCGAGGAGCCACGCATTCGCCTTGTGTCCGCGGA

CCCTTGTTCCCGACAGGCGACCAAGCCAAGGCCCTCCGGACTGACGCGGCCTGAGCAGCAGCGAGTGTGAAGTTTGGCACCTC

CGGCGGCGAGACGGCGCGTTCTGGCGCGCGGCTCCTGCGTCCGGCTGGTGGAGCTGCTGCGCCCTATGCGGCCTGCCGAGGGC

GCCGCCGAGGGCCCGCGAGCTCCGTGGGGTCGGGGTGGGGGGACCCGGGAGCGGACAGCGCGGCCCGAGGGGCAGGGGCAGGG

GCGCGCCTGGCCTGGGGTGTGTCTGGGCCCCGGCTCCGGGCTCTTGAAGGACCGCGAGCAGGAGGCTTGCGCAATCCCTTGGC

TGAGCGTCCACGGAGAAAGAAAAAGAGCAAAAGCAGAGCGAGAGTGGAGCGAGGGATGGGGGCGGGCAAAGAGCCATCCGGGT

CTCCACCACCGCCCTGACACGCGACCCGGCTGTCTGTTGGGGACCGCACGGGGGCTCGGGCGAGCAGGGGAGGGAGGAGCCTG

CGCGGGGCTCGTGTTCGCCCAGGAATCCCGGAGAAGCTCGAAGACGGTCTGGTGTTGAACGCACACGTGGACTCCATTTCATT

ACCACCTTGCAGCTCTTGCGCCACGGAGGCTGCTGCTGCCCGGCGGCTGCTACCCACCGAGACCCACGTGGCCCCTCCCCAGG

GGTGTAGGGGTGACGGTTGTCTTCTGGTGACAGCAGAGGTGTTGGGTTTGCGACTGATCTCTAACGAGCTTGAGGCGCAAACC

TAGGATTCCCTGAGTGTTGGGGTGCGGCGGGGGGGCAAGCAAGGTGGGACGACGCCTGCCTGGTTTCCCTGACTAGTTGCGGG

GGGTGGGGGCCGGCTCTCAGGGGCCACCAGAAGCTGGGTGGGTGTACAGGAAAATATTTTTCTCCTGCCGTGTTTGGCTTTTT

CCTGGCATTTTTGCCCAGGGCGAAGAACTGTCGCGCGGGGCAGCTCCACCGCGGAGGGAGAGGGGTCGCGAGGCTGGCGCGGG

AAGCGCTGTAGGTGGCAGTCATCCGTCCACGCCGCACAGGCCGTCTGCGCCGTCGGACCATCGGGAGGTCTGCAGCAACTTTG

TCCCGGCCAGTCCCCTTGTCCGGGAAGGGGCTGAGCTTCCCGACACTCTACCCTCCCCCTCTTGAAAATCCCCTGGAAAATCT

GTTTGCAATGGGTGTTTCCGCGGCGTCCAGGTCTGGGCTGCCGGGGGAGGCCGAGCGGCTGCTGCAGCCTCCCTGCTGCCAGG

GGCGTCGGACTCCGCTTCGCTCACTACGCCCAGGCCCCTCAGGGGCCCACGCTCAGGACTTCGGGGCCACACAGCAGGACCCG

GTGCCCCGACGACGAGTTTGCGCAGGACCCGGGCTGGGCCAGCCGCGGAGCTGGGGAGGAAGGGGCGGGGGTCGGTGCAGCGG

ATCTTTTCTGTTGCTGCCTGTGCGGCGGCAGGAAGCGTCTTGAGGCTCCCCAAGACTACCTGAGGGGCCGCCCAAGCACTTCA

GAAGCCCAAGGAGCCCCCGGCCACCCCCGCTCCTGGCCTTTTTGCCAACGACTTTGAAAGTGAAATGCACAAGCACCAGCAAT

TGACTTCCCTTCCGTGGTTATTTATTTTGTCTTTGTGGATGGTGGGCAGATGGGGAGAGAGGCCCCTACCTAACCTCGGTGGC

TGGTCCCTAGACCACCCCTGCCAGCCGGTGTGGGGAGGAGCTCAGGTCCGCGGGAGAGCGAATGGGCGCCAGGAGGTGGGACA

GAATCCTGGGAAGGTACAGCGGACGCCCTGGAAGCTCCCCTGATGCCCCAGAGGGCCCTTCCTGGGAAACCTCCCGGGGGGGT

GCCCCATACCATCCCACCCGGCTGTCTTGGCCCCTCCCAGGGAGCCGCAGGAGAAACTAGCCCTACACCTGGGATTCCCAGAG

CCTTCTGCTGGGGCTCCTGCCCCCGACTTCGGATAACCAGCTCCGCACAGGTCCCCGAGAAGGGCCGCTGGCCTGCTTATTTG

ATACTGCCCCCTCCCAGACAGGGGCTGGTCGAGCCCCTGGTTCTGCTGCCAGACTGAAGCCTTCCAGACGCCACCTCGGTTTG

GGCCCCCAGGGCCCTCAGGGGCCCCAGGAGAGGAGAGCTGCTATCTAGCTCAGCCACAGGCTCGCTCCTGGTGGGGGCCAGGC

TGAAGGAGTGGACCCTGGAGAGGTCGGGAACCTTTTAACAGCCGTGGGCTGGAGGGTGGCTACTAAGTGTTCGGTCTGGGAAG

AGGCATGACCCGCACCATCCCGGGGAAATAAACGACTTCTTAAGGGAATCTTCTCGCTGAGCGGGTGCTCTGGGCCAGGAGAT

TGCCACCGCCAGCCCACGGAACCCAGATTTGGGCTCTGCCTTGAGCGGGCCGCCTGTGGCTTCCCGGGTCGCTCCCCCGACTC

AGAAAGCTCTCAAGTTGGTATCGTTTTCCCGGCCCTCGGAGGTGGATTGCAGATCACCGAGAGGGGATTTACCAGTAACCACT

ACAGAATCTACCCGGGCTTTAACAAGCGCTCATTTCTCTCCCTTGTCCTTAGAAAAACTTCGCGCTGGCGTTGATCATATCGT

ACTTGTAGCGGCAGCTTAGGGGCAGCGGAACTGGTGGGGTTGTGCGTGCAGGGGGAGGCTGTGAGGGAGCCCTGCACTCCGCC

CCTCCACCCTTCTGGAGGAGTGGCTTTGTTTCTAAGGGTGCCCCCCCAACCCCCGGGTCCCCACTTCAATGTTTCTGCTCTTT

GTCCCACCGCCCGTGAAAGCTCGGCTTTCATTTGGTCGGCGAAGCCTCCGACGCCCCCGAGTCCCACCCTAGCGGGCCGCGCG

GCACTGCAGCCGGGGGTTCCTGCGGACTGGCCCGACAGGGTGCGCGGACGGGGACGCGGGCCCCGAGCACCGCGACGCCAGGG

TCCTTTGGCAGGGCCCAAGCACCCCT

59
EDG6
TGGCGGCCGGCGGGCACAGCCGGCTCATTGTTCTGCACTACAACCACTCGGGCCGGCTGGCCGGGCGCGGGGGGCCGGAGGAT

GGCGGCCTGGGGGCCCTGCGGGGGCTGTCGGTGGCCGCCAGCTGCCTGGTGGTGCTGGAGAACTTGCTGGTGCTGGCGGCCAT

CACCAGCCACATGCGGTCGCGACGCTGGGTCTACTATTGCCTGGTGAACATCACGCTGAGTGACCTGCTCACGGGCGCGGCCT

ACCTGGCCAACGTGCTGCTGTCGGGGGCCCGCACCTTCCGTCTGGCGCCCGCCCAGTGGTTCCTACGGGAGGGCCTGCTCTTC

ACCGCCCTGGCCGCCTCCACCTTCAGCCTGCTCTTCACTGCAGGGGAGCGCTTTGCCACCATGGTGCGGCCGGTGGCCGAGAG

CGGGGCCACCAAGACCAGCCGCGTCTACGGCTTCATCGGCCTCTGCTGGCTGCTGGCCGCGCTGCTGGGGATGCTGCCTTTGC

TGGGCTGGAACTGCCTGTGCGCCTTTGACCGCTGCTCCAGCCTTCTGCCCCTCTACTCCAAGCGCTACATCCTCTTCTGCCTG

GTGATCTTCGCCGGCGTCCTGGCCACCATCATGGGCCTCTATGGGGCCATCTTCCGCCTGGTGCAGGCCAGCGGGCAGAAGGC

CCCACGCCCAGCGGCCCGCCGCAAGGCCCGCCGCCTGCTGAAGACGGTGCTGATGATCCTGCTGGCCTTCCTGGTGTGCTGGG

GCCCACTCTTCGGGCTGCTGCTGGCCGACGTCTTTGGCTCCAACCTCTGGGCCCAGGAGTACCTGCGGGGCATGGACTGGATC

CTGGCCCTGGCCGTCCTCAACTCGGCGGTCAACCCCATCATCTACTCCTTCCGCAGCAGGGAGGTGTGCAGAGCCGTGCTCAG

CTTCCTCTGCTGCGGGTGTCTCCGGCTGGGCATGCGAGGGCCCGGGGACTGCCTGGCCCGGGCCGTCGAGGCTCACTCCGGAG

CTTCCACCACCGACAGCTCTCTGAGGCCAAGGGACAGCTTTC

60
chr13
TAGTAAGGCACCGAGGGGTGGCTCCTCTCCCTGCAGCGGCTGTCGCTTACCATCCTGTAGACCGTGACCTCCTCACACAGCGC

group-
CAGGACGAGGATCGCGGTGAGCCAGCAGGTGACTGCGATCCTGGAGCTGGTCGCAGCAGGCCATCCTGCACGCGGTGGAGGCG

00005
CCCCCTGCAGGCCGCAGCGCATCCCCAGCTTCTGGACGCACTGCACTTGGCCCCATGGATCTCTGTGCCCAGGGCTCAGCCAG

GCATCTGGCCGCTAAAGGTTT

61
CRYL1
TCTCATCTGAGCGCTGTCTTTCACCAGAGCTCTGTAGGACTGAGGCAGTAGCGCTGGCCCGCCTGCGAGAGCCCGACCGTGGA

CGATGCGTCGCGCCCTTCCCATCGCGGCCTGGGCGGGCCCGCCTGCCCTCGGCTGAGCCCGGTTTCCCTACCCCGGGGCACCT

CCCCTCGCCCGCACCCGGCCCCAGTCCCTCCCAGGCTTGCGGGTAGAGCCTGTCTTTGCCCAGAAGGCCGTCTCCAAGCT

62
IL17D
CAGTCCCCGAGGCCCTCCCCGGTGACTCTAACCAGGGATTTCAGCGCGCGGCGCGGGGCTGCCCCCAGGCGTGACCTCACCCG

TGCTCTCTCCCTGCAGAATCTCCTACGACCCGGCGAGGTACCCCAGGTACCTGCCTGAAGCCTACTGCCTGTGCCGGGGCTGC

CTGACCGGGCTGTTCGGCGAGGAGGACGTGCGCTTCCGCAGCGCCCCTGTCTACAT

63
IRS2
AGAGAGACATTTTCCACGGAGGCCGAGTTGTGGCGCTTGGGGTTGTGGGCGAAGGACGGGGACACGGGGGTGACCGTCGTGGT

GGAGGAGAAGGTCTCGGAACTGTGGCGGCGGCGGCCCCCCTGCGGGTCTGCGCGGATGACCTTGGCGCCGCGGTGGGGGTCCG

GGGGCTGGCTGGCCTGCAGGAAGGCCTCGACTCCCGACACCTGCTCCATGAGGCTCAGCCTCTTCACGCCCGACGTCGGGCTG

GCCACGCGGGCAGCTTCTGGCTTCGGGGGGGCCGCGATAGGTTGCGGCGGGGTGGCGGCCACACCAAAAGCCATCTCGGTGTA

GTCACCATTGTCCCCGGTGTCCGAGGACAACGATGAGGCGGCGCCCGGGCCCTGGGCGGTGGCAACGGCCGAGGCGGGGGGCA

GGCGGTACAGCTCCCCCGGGGCCGGCGGCGGTGGCGGCGGCTGCAGAGACGACGACGGGGACGCGGACGGACGCGGGGGCAAC

GGCGGATACGGGGAGGAGGCCTCGGGGGACAGGAGGCCGTCCAAGGAGCCCACGGGGTGGCCGCTCGGGGCGCCCGGCTTAGG

AGACTTGGGGGAGCTGAAGTCGAGGTTCATGTAGTCGGAGAGCGGAGACCGCTGCCGGCTGTCGCTGCTGGTGCCCGGGGTGC

CTGAGCCCAGCGACGAGGCCGGGCTGCTGGCGGACAAGAGCGAGGAGGACGAGGCCGCCGACGCCAGCAGGGGAGGCGCGGGC

GGCGACAGGCGGGCCCCGGGCTCGCCAAAGTCGATGTTGATGTACTCGCCGGGGCTCTTGGGCTCCGGTGGCAGTGGGTACTC

GTGCATGCTGGGCAGGCTGGGCAGCCCCTCCAGGGACAGGCGCGTGGGCCTCACCGCCCGGCCGCGCTGGCCCAAGAAGCCCT

CCGGGCGGCCGCCGCTAGGCCGCACGGGCGAAGGCACTACAGGGTGAGGGGGCTGCGTGGGGCCGGCCCCGAAGGCGCTGGCC

GCCTGGCTGGGCCCTGGCGTGGCCTGAGGCTCCAGACGCTCCTCCTCCAGGATGCGCCCCACGGGGGAGCTCATGAGCACGTA

CTGGTCGCTGTCCCCGCCACAGGTGTAGGGGGCCTTGTAGGAGCGGGGCAAGGAGCTGTAGCAGCAGCCGGGAACGCCCCTGA

GCGGCTCCCCGCCGGGGTGCAGGGCTGCGGAGAAGAAGTCGGGCGGGGTGCCCGTGGTGACCGCGTCGCTGGGGGACACGTTG

AGGTAGTCCCCGTTGGGCAGCAGCTTGCCATCTGCATGCTCCATGGACAGCTTGGAACCGCACCACATGCGCATGTACCCACT

GTCCTCGGGGGAGCTCTCGGCGGGCGAGCTGGCCTTGTAGCCGCCCCCGCTCGCCGGGAATGTCCTGCCCGCCGCAGAGGTGG

GTGCTGGCCCCGCAGGCCCCGCAGAAGGCACGGCGGCGGCGGCGGCGGCGGCGGCCCTGGGCTGCAAGATCTGCTTGGGGGCG

GACACGCTGGCGGGGCTCATGGGCATGTAGTCGTCGCTCCTGCAGCTGCCGCTCCCACTGCCCGCGAGGGCCGCGCCGGGCGT

CATGGGCATGTAGCCGTCGTCTGCCCCCAGGTTGCTGCTGGAGCTCCTGTGGGAGCCGATCTCGATGTCTCCGTAGTCCTCTG

GGTAGGGGTGGTAGGCCACCTTGGGAGAGGACGCGGGGCAGGACGGGCAGAGGCGGCCCGCGCTGCCCGAGAAGGTGGCCCGC

ATCAGGGTGTATTCATCCAGCGAGGCAGAGGAGGGCTGGGGCACCGGCCGCTGCCGGGCTGGCGTGGTCAGGGAGTAGGTCCT

CTTGCGCAGCCCTCGGTCCAGGTCCTGGGCCGCGTCCCCCGAGACCCGGCGGTAGGAGCGGCCACAGTGGCTCAGGGGCCTGT

CCATGGTCATGTACCCGTAGAACTCACCGCCGCCGCCGCCGTCTCGGGCCGGGGGCGTCTCCGCGATGGACTCGGGCGTGTTG

CTTCGGTGGCTGCAGAAGGCGCGCAGGTCGCCTGGGCTGGAGCCGTACTCGTCCAGGGACATGAAGCCGGGGTCGCTGGGGGA

GCCCGAGGCGGAGGCGCTGCCGCTGGAGGGCCGCTGGCCGGGGCCGTGGTGCAGCGGATGCGGCAGAGGCGGGTGCGGGCCGG

GCGGCGGCGGGTAGGAGCCCGAGCCGTGGCCGCTGCTGGACGACAGGGAGC

64
chr13
TAACCTAAAGAATGAAGTCATGCCCCGGCCTGCACCCGGGAAACTGCACACAGCGAAAGATCGCCACTGAGATAAAGAGCTGA

group-
AAGCTATTCCCCAATTCAGCTGTTTCAGCCGTGCGGTCTCACAATGGGCTCACAGACGGCAGCATC

00350

65
MCF2L
GTTTCCACAATCCACCTCGTAGCTGGGGCGTGCCGCTTGCCTCGGCTTGTCCCGGCAGAACACTCTTACCTTTAATGGCGACT

GAAAAGTTGCCACGAGTTCCTGATCATTGTGGTAGGTGCTGCGTGAAGCTGAGACGTGCGTGAGCCACATCCCAGGGGGCTTT

GAGCCCCCACCGCGGCGGCGGCTGAGGGGAGGCTTGTCGTACTCGCACAGGAGGACACAGGGCTGCAGTGTTCACTCCAGGGC

CTCTTATCATTGGGATCTGAGGAATTTTCCGAGAGGAAGTGCGAATTAACAATGATGAAAGGTTTGTGAGTGAGTGACAGGCA

CGTTCTATTGAGCACTGCATGGGGCATTATGTGCCACCAGAGACGGGGGCAGAGGTCAAGAGCCCTCGAGGGCTGGGAGAGTT

CGGAGGATAGAAGTCATCAGAGCACAATGAAGCCAGACCCTGCAGCCGCCTTCCCCTTCGGGGGCTTCCTTAGAATGCAGCAT

TGCGGGGACTGAGCTGTCCCAGGTGAAGGGGGGCCGTCACGGTGTGTGGACGCCCCTCGGCTCAGCCCTCTAAGAGACTCGGC

AGCCAGGATGGGCTCAAGGCATGAGCCCTCAAAGGAGGTTAGGAAGGAGCGAGGGAGAAAAGATATGCTTGTGTGACGTCCTG

GCCGAAGTGAGAACAATTGTATCAGATAATGAGTCATGTCCCATTGAGGGGTGCCGACAAGGACTCGGGAGGAGGCCACGGAG

CCCTGTACTGAGGAGACGCCCACAGGGAGCCTCGGGGGCCCAGCGTCCCGGGATCACTGGATGGTAAAGCCGCCCTGCCTGGC

GT

66
F7
TCCAGCTGCAGCGAGGGCGGCCAGGCCCCCTTCTCCGACCTGCAGGGGTAGCGCGGCCTCGGCGCCGGAGACCCGCGCGCTGT

CTGGGGCTGCGGTGGCGTGGGGAGGGCGCGGCCCCCGGACGCCCCGAGGAAGGGGCACCTCACCGCCCCCACCCAGAGCGCCT

GGCCGTGCGGGCTGCAGAGGACCCCTCCGGGGCAGAGGCAGGTTCCACGGAAGACCCCGGCCCGCTGGGGCTTCCCCGGAGAC

TCCAGAG

67
chr18
ACTTACTGCTTCCAAAAGCGCTGGGCACAGCCTTATATGACTGACCCCGCCCCCGAGTCCCAGGCCGCCCCATGCAACCGCCC

group-
AACCGCCCAACCGCCACTCCAAAGGTCACCAACCACTGCTCCAGGCCACGGGCTGCCTCTCCCCACGGCTCTAGGGCCCTTCC

00039
CCTCCACCGCAGGCTGAC

68
C18orf1
TGCCACACCCAGGTACCGCCCGCCCGCGCGAGAGCCGGGCAGGTGGGCCGCGGATGCTCCCAGAGGCCGGCCCAGCAGAGCGA

TGGACTTGGACAGGCTAAGATGGAAGTGACCTGAG

69
CD33L3
TCGCCAGCGCAGCGCTGGTCCATGCAGGTGCCACCCGAGGTGAGCGCGGAGGCAGGCGACGCGGCAGTGCTGCCCTGCACCTT

CACGCACCCGCACCGCCACTACGACGGGCCGCTGACGGCCATCTGGCGCGCGGGCGAGCCCTATGCGGGCCCGCAGGTGTTCC

GCTGCGCTGCGGCGCGGGGCAGCGAGCTCTGCCAGACGGCGCTGAGCCTGCACGGCCGCTTCCGGCTGCTGGGCAACCCGCGC

CGCAACGACCTCTCGCTGCGCGTCGAGCGCCTCGCCCTGGCTGACGACCGCCGCTACTTCTGCCGCGTCGAGTTCGCCGGCGA

CGTCCATGACCGCTACGAGAGCCGCCACGGCGTCCGGCTGCACGTGACAGGCGAGGCGGCGTGGGAGCGGGTCCCCGGCCTCC

CTTCCCGCCCTCCCGCCTGCCCCGCCCCAAGGGCTACGTGGGTGCCAGGCGCTGTGCTGAGCCAGGAAGGGCAACGAGACCCA

GCCCTCTCCTCTACCCCAGGGATCTCACACCTGGGGGTAGTTTAGGACCACCTGGGAGCTTGACACAAATGCAGAATCCAGGT

CCCAGGAAGGGCTGAGGTGGGCCCGGGAATAGGCATTGCCGTGACTCTCGTAGAGTGACTGTCCCCAGTGGCTCTCAGACGAA

GAGGCGAGAAAGACAAGTGAATGGCAATCCTAAATATGCCAAGAGGTGCAATGTGGTGTGTGCTACCAGCCCGGAAAGACACT

CGCAGCCCCTCTACCCAGGGGTGCACAGACAGCCCACCAAGTAGTGCCTAGCACTTTGCCAGACCCTGATATACAAAGATGCC

TGAACCAGGGTCCCGTCCCTAGAGCAGTGGCTCTCCACTCTAGCCCCCACCCTGCTCTGCGACAATAATGGCCACTTAGCATT

TGCTAGGGAGCCGGGACCTAGTCCAAGCACCCACAAGCATGAATTTGCCAAATCTTTTCAGCAACCTCTTAAGGCAACTGCTA

TCATGATCCTCACTTTACACATGGAGAAGCAGAAGCAGAGATGATAGAATCTTTCGCCCAAGGCCACATCTGTATTGGGACGG

GGGCAGCCTGGCACCCAAGTGCCCATTCCTCCCTTCTGACCAGCCCCCACCCCTCCGGCTCTGGCGTCCAAAGGGCTAAGGGG

AGGGGTGCCCTTGTGACAGTCACCCGCCTTCTCCCCTGCAGCCGCGCCGCGGATCGTCAACATCTCGGTGCTGCCCAGTCCGG

CTCACGCCTTCCGCGCGCTCTGCACTGCCGAAGGGGAGCCGCCGCCCGCCCTCGCCTGGTCCGGCCCGGCCCTGGGCAACAGC

TTGGCAGCCGTGCGGAGCCCGCGTGAGGGTCACGGCCACCTAGTGACCGCCGAACTGCCCGCACTGACCCATGACGGCCGCTA

CACGTGTACGGCCGCCAACAGCCTGGGCCGCTCCGAGGCCAGCGTCTACCTGTTCCGCTTCCATGGCGCCAGCGGGGCCTCGA

CGGTCGCCCTCCTGCTCGGCGCTCTCGGCTTCAAGGCGCT

70
TNFRSF
ATGAACTTCAAGGGCGACATCATCGTGGTCTACGTCAGCCAGACCTCGCAGGAGGGCGCGGCGGCGGCTGCGGAGCCCATGGG

11A
CCGCCCGGTGCAGGAGGAGACCCTGGCGCGCCGAGACTCCTTCGCGGGGAACGGCCCGCGCTTCCCGGACCCGTGCGGCGGCC

CCGAGGGGCTGCGGGAGCCGGAGAAGGCCTCGAGGCCGGTGCAGGAGCAAGGCGGGGCCAAGGCTTGAGCGCCCCCCATGGCT

GGGAGCCCGAAGCTCGGAGC

71
ZNF236
TCAGTGTTATGTGGGGAGCGCTAGATCGTGCACACAGTAGGCGTCAGGAAGTGTTTTCCCCAGTAATTTATTCTCCATGGTAC

TTTGCTAAAGTCATGAAATAACTCAGATTTTGTTTTCCAAGGAAGGAGAAAGGCCCAGAATTTAAGAGCAGGCAGACACACAA

CCGGGCACCCCCAGACCCTGGCCCTTCCAGCAGTCAGGAATTGACTTGCCTTCCAAAGCCCCAGCCCGGAGCTTGAGGAACGG

ACTTTCCTGCGCAGGGGGATCGGGGCGCACTCG

72
chr18
GTGGAAACACAACCTGCCTTCCATTGTCTGCGCCTCCAAAACACACCCCCCGCGCATCCGTGAAGCTGTGTGTTTCTGTGTTA

group-
CTACAGGGGCCGGCTGTGGAAATCCCACGCTCCAGACCGCGTGCCGGGCAGGCCCAGCC

00342

73
OLIG2
TCCACACCTCGGGCAGTCACTAGGAAAAGGGTCGCCAACTGAAAGGCCTGCAGGAACCAGGATGATACCTGCGTCAGTCCCGC

GGCTGCTGCGAGTGCGCGCTCTCCTGCCAGGGGGACCTCAGACCCTCCTTTACAGCACACCGAGGGCCCTGCAGACACGCGAG

CGGGCCTTCAGTTTGCAAACCCTGAAAGCGGGCGCGGTCCACCAGGACGATCTGGCAGGGCTCTGGGTGAGGAGGCCGCGTCT

TTATTTGGGGTCCTCGGGCAGCCACGTTGCAGCTCTGGGGGAAGACTGCTTAAGGAACCCGCTCTGAACTGCGCGCTGGTGTC

CTCTCCGGCCCTCGCTTCCCCGACCCCGCACAGGCTAACGGGAGACGCGCAGGCCCACCCCACCGGCTGGAGACCCCGGCACG

GCCCGCATCCGCCAGGATTGAAGCAGCTGGCTTGGACGCGCGCAGTTTTCCTTTGGCGACATTGCAGCGTCGGTGCGGCCACA

ATCCGTCCACTGGTTGTGGGAACGGTTGGAGGTCCCCCAAGAAGGAGACACGCAGAGCTCTCCAGAACCGCCTACATGCGCAT

GGGGCCCAAACAGCCTCCCAAGGAGCACCCAGGTCCATGCACCCGAGCCCAAAATCACAGACCCGCTACGGGCTTTTGCACAT

CAGCTCCAAACACCTGAGTCCACGTGCACAGGCTCTCGCACAGGGGACTCACGCACCTGAGTTCGCGCTCACAGATC

74
RUNX1
CTGCCCTCGCGGATCTCCCCCGGCCTCGCCGGCCTCCGCCTGTCCTCCCACCACCCTCTCCGGGCCAGTACCTTGAAAGCGAT

GGGCAGGGTCTTGTTGCAGCGCCAGTGCGTAGGCAGCACGGAGCAGAGGAAGTTGGGGCTGTCGGTGCGCACCAGCTCGCCCG

GGTGGTCGGCCAGCACCTCCACCATGCTGCGGTCGCCGCTCCTCAGCTTGCCGGCCAGGGCAGCGCCGGCGTCCGGGGCGCCC

AGCGGCAACGCCTCGCTCATCTTGCCTGGGCTCAGCGCGGTGGAAGGCGGCGTGAAGCGGCGGCTCGTGCTGGCATCTACGGG

GATACGCATCACAACAAGCCGATTGAGTTAGGACCCTGCAAACAGCTCCTACCAGACGGCGACAGGGGCGCGGATCTTCAGCA

AGCAGCTCCCGGGAGACCAACATACACGTTCAGGGGCCTTTATTACTGCGGGGGGTGGGGGGGGGCGGGGGTGGTTAGGGGAG

GAGGGAGACTAAGTTACTAACAGTCCAGGAGGGGAAAACGTTCTGGTTCTGCGGATCGGCCTCTGACCCAGGATGGGCTCCTA

GCAACCGATTGCTTAGTGCATTAAAAAGTGGAGACTATCTTCCACGAATCTTGCTTGCAGAGGTTAAGTTCTGTCTTTGGCTG

TTAGAAAAGTTCCTGAAGGCAAAATTCTCATACACTTCCTAAAATATTTATGCGAAGAGTAAAACGATCAGCAAACACATTAT

TTGGAAGTTCCAGTAGTTAATGCCTGTCAGTTTTTTGCAGGTGAGTTTTGTCTAAAGTCCCAACAGAACACAATTATCTCCCG

TAACAAGGCCACTTTTATCATGCAAAACTGGCTTCAGTCCCGAAAAGCAAGAGCTGAGACTTCCAAAGGTAGTGCTACTAATG

TATGTGCACGTATATATAAATATATACATATGCTCTACTTCATAAAATATTTACAATACAATCTGTGGAGAATTTAAACACAA

CAGAAATCCATTAATGTACGCTGCAGATTTTTTTAAGTAGCCTTGAAAATCAGCTTCAGTAGTTGGAGCAGTGCTGAGCTAGA

AGTACTTGTCATGTTCTCTGTTCTCTCAATGAATTCTGTCAAAACGCTCAGTGCAGAAAATTCAGCGTTTCAGAGATCTTCAG

CTAATCTTAAAACAACAATCATAAGAAGGCCCAGTCGATGACACTCAGGGTTCTACAGCTCTCCCACATCTGTGAACTCGGGT

TTGGGGATGTTGGTTAAGTTTGTGGCTGGTCCTCTGGTTTGTTGGGAGTTGAGCAGCCGCAGAGTCACACACATGCAAACACG

CACTCTTCGGAAGGCAGCCACTGTCTACATCAGCTGGGTGACTCAGCCCTGACTCGGGCAGCAGCGAGACGATACTCCTCCAC

CGTCGCCCAGCACCCGCCGGTTAGCTGCTCCGAGGCACGAACACCCACGAGCGCCGCGTAACCGCAGCAGGTGGAGCGGGCCT

TGAGGGAGGGCTCCGCGGCGCAGATCGAAACAGATCGGGCGGCTCGGGTTACACACGCACGCACATCCTGCCACGCACACTGC

CACGCACACGCAACTTCACGGCTCGCCTCGGACCACAGAGCACTTTCTCCCCCTGTTGTAAAAGGAAAACAATTGGGGAAAAG

TTCGCAGCCAGGAAAGAAGTTGAAAACATCCAGCCAAGAAGCCAGTTAATTCAAAAGGAAGAAAGGGGAAAAACAAAAAAAAA

CAACAAAAAAAGGAAGGTCCAACGCAGGCCAAGGAGAAGCAGCAGAGGTTGACTTCCTTCTGGCGTCCCTAGGAGCCCCGGAA

AGAAGTGCCTGGCGGCGCAGGGCCGGGCAGCGTGGTGCCCTGGCTGGGTCCGGCCGCGGGGCGCCCGTCCCGCCCGCGCCCGC

TGGCTCTATGAATGAGAGTGCCTGGAAATGAACGTGCTTTTACTGTAAGCCCGGCCGGAGGAATTCCATTCCCTCAGCTCGTT

TGCATAGGGGCGGCCGGCGGCCAATCACAGGCCTTTCCGGTATCAGCCAGGGCGCGGCTCGCCGCCGCCGGCTCCTGGAATTG

GCCCGCGCGCCCCCGCCGCCGCGCCGCGCGCTACTGTACGCAGCCCGGGCGGGGAGTCGGAGGCCACCCCCGCGCCCCGCATC

CAAGCCTGCATGCTGGCCCGGGGCCCCGCCCGCGTGCGGACCCCTTTCCGCAGCCACACGCAGGCTTGTGCGGCTCCGCGAGT

GGCCACGGTCCGGAGACCTGGAAAAAGAAAGCAGGCCCCGCCGGCCCGAGGAGGACCCGGCCGGCGCGCCGCACCCGGAGAGG

CCCGGCCCCGCGAGCCGCTGCAGGCAGGCGCAGTGGCCGCCACGAGGCTCCCGAACCGGGCTGCAGCCCGCGGACGGCCCCAG

ATCCTGCGCGGCCGCCCAGGGCCAGGCCTCCGCTTCCAGGGCGGGGGTGCGATTTGGCCGCGGGGCCCGGGGGAGCCACTCCG

CGCTCCTGCACCGTCCGGCTGGCAGCTGCGGCGAAGCGGCGCTGATTCCTTGCATGAGGCCGGACGGCGTCCGCGCGTGCCGT

TTGCTCTCAGCGTCTTCCCTTGGGTCGGTTTCTGTAATGGGTGTTTTTTACCGCTGCGCCCGGGCCGCGGCTCGATCCCTCCG

CGCGTCTCACTTGCTGCGTGCGTCAGCGGCCAGCGAAGAGTTTCCTAGTCAGGAAAGACCCCAAGAACGCGCGGCTGGAAGGA

AAGTTGAAAGCAGCCACGCGGCTTGCTCCCGGGCCTTGTAGCGCCGGCACCCGCAGCAGCCGGACAGCCTGCCCGGGCCCCGC

GTCTCCCCTCCGGCTCCCCGGAAGCGGCCCCCGCTCCTCTCCCCGCCCCCGTGCGCTCGAGCGGCCCCAGGTGCGGAACCCAC

CCCGGCTTCGCGTGCGGGCGGCCGCTTCCCCCTGCGCCGGTCCCCGCGGTGCTGCGGGCATTTTCGCGGAGCTCGGAGGGCCC

CGCCCCCGGTCCGGCGTGCGCTGCCAACTCCGACCCCGCCCGGCGGGGCTCCCTCCCAGCGGAGGCTGCTCCCGTCACCATGA

GTCCCTCCACGCCCTCCCTGCCGGGCCCTGCACCTCCCGGGGCCTCTCATCCACCCCGGGGCTGCAACCCAGTCCCCGGATCC

CGGCCCCGTTCCACCGCGGGCTGCTTTGTGGTCCCCGCGGAGCCCCTCAATTAAGCTCCCCGGCGCGGGGGTCCCTCGCCGAC

CTCACGGGGCCCCTGACGCCCGCTCCTCCCTCCCCCAGGGCTAGGGTGCTGTGGCCGCTGCCGCGCAGGGACTGTCCCCGGGC

GTTGCCGCGGGCCCGGACGCAGGAGGGGGCCGGGGTTGACTGGCGTGGAGGCCTTTCCCGGGCGGGCCCGGACTGCGCGGAGC

TGTCGGGACGCGCCGCGGGCTCTGGCGGACGCCAGGGGGCAGCAGCCGCCCTCCCTGGACGCCGCGCGCAGTCCCCGGAGCTC

CCGGAACGCCCCCGACGGCGCGGGGCTGTGCGGCCCGCCTCGTGGCCTTCGGGTCGCCCGGGAAGAACTAGCGTTCGAGGATA

AAAGACAGGAAGCCGCCCCAGAGCCCACTTGAGCTGGAACGGCCAAGGCGCGTTTCCGAGGTTCCAATATAGAGTCGCAGCCG

GCCAGGTGGGGACTCTCGGACCAGGCCTCCCCGCTGTGCGGCCCGGTCGGGGTCTCTTCCCGAAGCCCCTGTTCCTGGGGCTT

GACTCGGGCCGCTCTTGGCTATCTGTGCTTCAGGAGCCCGGGCTTCCGGGGGGCTAAGGCGGGCGGCCCGCGGCCTCAACCCT

CTCCGCCTCCGCTCCCCCTGGGCACTGCCAGCACCCGAGTTCAGTTTTGTTTTAATGGACCTGGGGTCTCGGAAAGAAAACTT

ACTACATTTTTCTTTTAAAATGATTTTTTTAAGCCTAATTCCAGTTGTAAATCCCCCCCTCCCCCCGCCCAAACGTCCACTTT

CTAACTCTGTCCCTGAGAAGAGTGCATCGCGCGCGCCCGCCCGCCCGCAGGGGCCGCAGCGCCTTTGCCTGCGGGTTCGGACG

CGGCCCGCTCTAGAGGCAAGTTCTGGGCAAGGGAAACCTTTTCGCCTGGTCTCCAATGCATTTCCCCGAGATCCCACCCAGGG

CTCCTGGGGCCACCCCCACGTGCATCCCCCGGAACCCCCGAGATGCGGGAGGGAGCACGAGGGTGTGGCGGCTCCAAAAGTAG

GCTTTTGACTCCAGGGGAAATAGCAGACTCGGGTGATTTGCCCCTCGGAAAGGTCCAGGGAGGCTCCTCTGGGTCTCGGGCCG

CTTGCCTAAAACCCTAAACCCCGCGACGGGGGCTGCGAGTCGGACTCGGGCTGCGGTCTCCCAGGAGGGAGTCAAGTTCCTTT

ATCGAGTAAGGAAAGTTGGTCCCAGCCTTGCATGCACCGAGTTTAGCCGTCAGAGGCAGCGTCGTGGGAGCTGCTCAGCTAGG

AGTTTCAACCGATAAA

75
AIRE
TTCGGAAGTGAGAGTTCTCTGAGTCCCGCACAGAGCGAGTCTCTGTCCCCAGCCCCCAAGGCAGCTGCCCTGGTGGGTGAGTC

AGGCCAGGCCCGGAGACTTCCCGAGAGCGAGGGAGGGACAGCAGCGCCTCCATCACAGGGAAGTGTCCCTGCGGGAGGCCCTG

GCCCTGATTGGGCGCCGGGGCGGAGCGGCCTTTGCTCTTTGCGTGGTCGCGGGGGTATAACAGCGGCGCGCGTGGCTCGCAGA

CCGGGGAGACGGGCGGGCGCACAGCCGGCGCGGAGGCCCCACAGCCCCGCCGGGACCCGAGGCCAAGCGAGGGGCTGCCAGTG

TCCCGGGACCCACCGCGTCCGCCCCAGCCCCGGGTCCCCGCGCCCACCCCATGGCGACGGACGCGGCGCTACGCCGGCTTCTG

AGGCTGCACCGCACGGAGATCGCGGTGGCCGTGGACAG

76
SUMO3
ACGCACACTGGGGGTGTGATGGAAAGGGGGACGCGATGGATAGGGGTGGGCGCACACTGGGGGACGCGACGGGGAGGGGTGAG

CACACACTGGGGGTGTGATGGAGAGGGCGACGCAATAGGGAGGGGTGGGCGCACACCAGGGACGCGATGATGGGGACGGGTGG

GCGCACACCAGGTGGCATGATGGGGAGGAGTGGGTACACACCATGGGGGGCGTGATGGGGAGGCGTGGGCGTACACCGGGGGG

CGCGATGGGGAGGGGTGGGCGCACACCGGGGGACGCGATGGAGGCGGTGGGTGCACACGGGGCGCGATGGGTGGGAGTAGGTG

CACACTGAGGGCACGATTGGGGAGACACGAAGGAGAGGGGTGGGCGCACACTGGGGGACGCGATGGCCGGGACACGATGCGGA

GAAGTGGGTGAATACCGGGGTCGCGATGGGCGCCCTGGAAGGACGGCAGTGCTGCTCACAGGGGCCAGGCCCCTCAGAGCGCG

CCCCTTGGGGGTAACCCCAGACGCTTGTTCCCGAGCCGACTCCGTGCACTCGACACAGGATC

77
C21orf70
CCACAGGGTGGGGTGCGCCCACCTGCCCTGTCCATGTGGCCTTGGGCCTGCGGGGGAGAGGGAATCAGGACCCACAGGGCGAG

CCCCCTCCGTAGCCCGCGGCACCGACTGGATCTCAGTGAACACCCGTCAGCCCATCCAGAGGCTAGAAGGGGGA

78
C21orf123
TTGAGGTCTCTGTGCATGCTTGTGCGTACCCTGGACTTTGCCGTGAGGGGTGGCCAGTGCTCTGGGTGCCTTTGCCAGACAAC

TGGTCTGCCGGGCCGAGCATTCATGCTGGTC

79
COL18A1
TGACGCGCCCCTCTCCCCGCAGCTCCACCTGGTTGCGCTCAACAGCCCCCTGTCAGGCGGCATGCGGGGCATCCGCGGGGCCG

ACTTCCAGTGCTTCCAGCAGG

80
PRRT3
AACACACTGTCTCGCACTAGGTGCTCGCGGAAGAGCGCGGCGTCGATGCTGCGGCTCAGGTTGATGGGCGATGGCGGCCGCAG

ATCCAGCTCGCTCAGCGATGGCGCCGGTCCCACACCGTTGCGGGACAGTCCCGGGCCACCCTGGGGTCCGCGACCCAACGACG

CAGCCGAGCCCCAGGCGCCTGAACTGGGCGTGGCCAGCTGCCCACTCTCCGCCGGGTTGCGGATGAGGCTCTTGCTGATGTCC

AAGCTGCCTGCACCAACGTTGCTGGGCCCTGCATAGCAGTTATTGGGTCGCTCCGGCACCTCGCTCTTTCCTGACGGCGCCGG

GCACGCCAGACGCATCAGCTTAGCCCAGCAAGCGTGCTCCGTGGGCGGCCTGGGTCTCGCGGCAGCCACCGCGGCCAACGCCA

GGGCGAGCGCCCATGTCAGCTCCAGGAGGCGCAGCCAGAAGTGGACACCCCACCAGGCCCACGAGAAGCGGCCCACGCGGCCT

GGGCCCGGGTACAGCCAGAGCGCAGCCGCCAGCTGCAAGCCGCTAGCCAGCAGCCCCAGCGCGCCCGCCACAGCCAACAGCCG

AGGGCCCGGGCTGGCATCCCAGCCCCGTGGGCCGTCCAGCAGGCGGCGACGGCACAGGCAGAGCGTGCCCAGAGCCAC

81
MGC29
GTCTGCACGAAGCCCGCGGCGGCCTGCAGGGGGCCCAGCGACTCGTCCAGGGAACCGGTGCGCAGGAGCAGCCGGGGGCGCGG

506
CGCGCCGGCCGCCCTTGGGGGACTCTGGGGCCGGGGGCGCAGCTCGATCTGACGCTTGGGCACTGTCCGGGGCCTGGCGGGCG

CGGCGCCCTCCTCCAGAGCCACCTCCACACACTCGAACTGCGCTGGGGCGGCAGGACTTGGCCCACGGGGCCGCAGCTCTAGG

TAGGTGGCCCAGCGGGAGCCACCATCGGGGACCTGGGACTGGCGTGGGACCGCGGCGGGAGACGCTGGCCCCGGCGGCAAGGG

GCTGATGAAGGCCGGCTCCGTGAACTGTTGTTGCGCCTCGCGATCGTCTGCGCCGGAGCAGCCGAACAGGGGTCCGACGCCGA

AGATGACTTCCATCTCCCCCGACGGCAGCGTGCGCAGCTGGGGCTGGGGTGGCCGTGGGCCGGAACCTGGGCCTCGCGGGAAA

CCCGAGCCGGGCCCGTGCCGCTGGCGGCTATTCTGGGCGCTGACGGACAGGCGAGGCTGCGCGCCCGCCCCCCGCCCAGGAGC

CACCCAGGGCCAATTCGCTGGGCCTTTCGCGTCCGGCCCAACGTCCGGGGGCTCCGGAGAACCTGGAGCCGTGTAGTAGGAGC

CTGACGAACCGGAGGAGTCCTGGCGCCGCGCGGGGGCCGTGGGCAGCTGCCTCGGGATCCCAGGCAGGGCTGGCGGGGCGAGC

GCGGTCAGCATGGTGGGGCCGGACGCCGTGCACTATCTCCCTCGCATTCGCCTCCGCTGGTGGCGC

82
TEAD3
CTGGAGAGAACTATACGGGCTGTGGGAGTCACCGGGCGACTATCACCGGGCCTCCTTTCCACATCCTCCTCCGGGAAGGGACC

CCGTTCCGGGCCTCGACCGGCGCAGACTGGGCTGACCCACTTTCTTGGGCCCACTGAGTCACCTCGAAACCTCCAGGCCGGTA

GCGGGGAGGAGAGGAGGAGCAGGCGGGGGTGCCAAGGTGTGGGCTGCGCCCTGGTTAGGGGGCGAGCCCGGCTTGTTTATGAG

GAGGAGCGCGGAGGAGGATCCAGACACACAGGCTTGCGCGCCCAGACTCGCCCGGCCAGCGGCTGGCGGCCTCCGACGTCACC

AAACCGGTTGGGTGAGAGGGCAGAGAGCAGGGGGAAGGGCCGCAGTCCCGCCCGCGCCCCCCGGCACGCACCGTACATCTTGC

CCTCGTCTGACAGGATGATCTTCCG

83
chr12
GAGTGCGGAGTGAAGGGGTGCACTGGGCACTCAGCGCGGCCCTTGGGAGGCAGGGCCGCCCCAGCCTGCCCTCCTGTCTGGGA

group-
AGGCCGTCCAGAAGCAGGAGCCCCGGGGAAAACAACTGGCTGGACGGGGCGGCCTTCAGTGTCTCTCCCAGCCTGAGAGTCGC

00022
TTCCCACCACCTGGGCACGAACCTGCTCTGCGATCTCCGGCAAGTTCCTGCGCCTCCTGTCGGTAAAATGCAGATCGTGGCGT

CTT

84
CENTG1
TCTTCTTTCCGCCCCTAGGGGGCACAAGCGGGCATGTCCAAGCGCCTAGGAGCCCGTACCGCTGGGGACCTCCCCTTCCGCGA

ACCCCGAGCGGGTAGACCCAGAGCAATCCGAGTGTGGAAACAATGGAGAGGGGGCGTGTTGAGCTGGGGTCTCCATGCCTCGT

TGGGGAGAGGGAGGTGAGTTTGTGTCTTCTGGAAGGCGTGGGGGCTGTGCCCTCGTGGGGGTAGGAAGTGCTCCCGTGGGGCG

GGGTGCGGATCGGAGAGGTGAGTGGGTGCGTCTGTCCAGCGGTCCGCCCGGTGTGGTCGTGCCCGGCCCGCGTGGGGATGGGG

GTGTCTCTCCCGCTGGGCAACTATACCAGCGCAACCGGGGCGTCGGCGCGGCCCACGCTAGCGGCGCTGCTCCGGCGGCGGGG

GCTGGGCGTGGCGGTGATGCTGGGCGTGGTGGCCGCGCTGGGCGTGGTGGCCGCGCTGCCGCCCTCACCCGGGCAGCCGTGCT

GGAGAAGGATGTCGGCGCACAGCTGGCTTCCAGCCTGGCGGGCGTAGAACAGCGCCGTGCGGCCCTGGGCGTCACGGGCCGCC

ACGTCCGCGCCGTACTAGAGGGCGGAAACGGCCGCGTGACCGCGCGTCCCCAGGGCGCCCACACCCGGCGCCGCCTCCCCCAC

ATGGCCAAGCCTACTTCCGGGGTCCCTCTGGGAATTTCGGGCTTTCCCGCGCCAGGCGTTTTCCGAGATGAAGCCTCAAAGAC

CCCCTTTCCTCCCCCCAGCTCACGTACCCACAGCAGCAGTTGCGTGATGACGACGTGGGCGAGCTCGGCCGCCAGGTGGAGTG

GGGAGCGCAGCTGTGGGTCCTCTACGCTGGTGTCGAGCGGCCCGTGTCGCGCATGGGCCAAAAGCAGGAGAACGGTAGCCACG

TCCTGGGCCTGCACGGCGGCCCACAGCTGGCGGCCCAGCGGCTCCTCCGAGGTGCTCAGCGGCGCCAGGAACAGTAGCTGCTC

GTACTTGGCGCGAATCCACGACTCGCGCTCCTCCCTGCAAGACCAGGGATCAACGGAAAAGGCTCTAGGGACCCCCAGCCAGG

ACTTCTGCCCCTACCCACGGGACCGTCTCAGGTTCGCACACCCTCAGCAACCCTCCCCCCGCTCTGTTCCCTCACGCTTACCG

CGAAGAGTCCCGCGAGGGCTTGGCACGGCCTCGCGTGTCGCTTTCCCACACGCGGTTGGCCGTGTCGTTGCCAATAGCCGTCA

GCACCAGGGTCAGCTCCCGTGGCCAGTCGTCCAAGTCCAGCGAGCGAACGCGGGACAGGTGTGTGCCCAGGTTGCGGTGGATG

CCAGAACACTCGATGCAGATGAGGGCGCCCAGGTTCAAGCTGGCCCACGTGGGGTCTGCGGAAGGAGCGTAGAGGTCGGCTCC

CAGCCGGGCAGCACAGGCACCCCGGCATTCACTACACTCCCTAGCCCCTCCGCTGCCTCCTGGCACTCACTGGGGGCCCCGCA

GTCCACGCAGATTGAATTCCCCTTGGCGTTCCGGATCGCCTGGAT

85
CENTG1
AGCCAGGTCCAGCCCCCGCGCCTGACACCGGCCGGACGTTCCCGGGGCGCCGCAGCTGCGGCGGGAACTCTGGGATCCGGAGC

CATCTGCTCCCACCCGCTCCGGAGCCAAACCCCGGGGGCCGCCTCCGCTCCCGGACCCGCCTCCTCTCCCGGGAGTGTGAGCC

GAACCAAGAGTCTCCTGCCTATCTCCTCCAGTAGGAAAATAGTAATAATAATAGACACCCTGCCCCCGTAAAAAACACTACCT

TCCCCGTACCGCCTCCCAAGTCTCCCGGGGTACGGATTGCCTTTGCAGCAGTTCCGCCCCACCTGACTCACTCCAGGGTCAGC

CCCGGGTGGGTTTCAATGCGGCTCTGGGGAGGGGGTGGGCAGTGGGGGAAGTGAGGCTTCCTATCCGCCCCCTCTCACTTCAC

ATTTAAATATTCTGCACGTTCCAGCCCCCGCGGACTCGCGTACCGCCCAATCCGCCTTCACCGCACGAAAAACATCACTAGCC

TGCTCTCAGCCCAGGGGACGACTAGTCCCTGGCGAGAAGCTGCCTGCAAGGTCACTGTCATGCCACCTGCCCCAAGTGCTCAG

GGGAAACTGAGGCTTCCTCATCCCCTTCACCTTCAACGTCGCTCTAAACACGGCAAAGCCCCGTTTCCATGCTCCCAGAGTTC

AGCTGAGGCTGGAAGTGGGGTCCTGGGCTTCTCTGGGAGCAATTTTCTAGTCACTCTGATCAAGGACGTTACTTTCCCAGAAA

GCTCTGAGGCTGAGTCCCTCTGAAATCAAGTCCTTTCTCCTGTCGCACAATGTAGCTACTCGCCCCGCTTCAGGACTCCTATT

CTTTGCCCCAATCCTTGACAGAGGGGTGAGCTTGGTTCATCCGCCCACCCCAGAGAAAAGCTTCCCTAGTTTCCTGGACCTCG

CTCCTCCACCCCAAGCTGAGCATTCCAGGTACCCTTCCCTCCCTGTTCTCAAGCCCTGACTCAACTCACTAGGGGAAGCGCGG

AGCTCGGCGCCCAGCAGCTCCCTGGACCCGCTGCCAGAAGACAGGCTGGGGGGTCCGGGAAGGGGCCCGGAGCCAGGAGGCCC

TCCTGTGCTCTTGGTGAAGATGCCGCTGATAAACTTGAGCATCTTGCGGTCACGAGTGGATGCTCGGCCCCCCTCCCGGCCCC

GTTTCAGCCCCGGAGCTGGAGGCTCCAGAGTGATTGGAGGTGCAGGCCCGGGGGGCTGCGCGGAAGCAGCGGTGACAGCAGTG

GCTGGACTCGGAGTTGGTGGGAGGGTTAGCGGAGGAGGAGAGCCGGCAGGCGGTCCCGGATGCAAGTCACTGTTGTCCAAGGT

CTTACTCTTGCCTTTCCGAGGGGACAACTTCCCTCGGGCTCCAGCCCCAGCCCCGACCCCACCAGAGGTCGAAGCTGTAGAGC

CCCCTCCCCCGGCGGCGGCGGCGGTGGCGGCGGCAGAGACCGAAGCTCCAGTCCCGGCGCTGCTCTTTGACCCCTTGACCCTG

GGCTTGCCCTCGCTTTCGGGCCATGACAGGCGGCTACCCGCGCCCTTGCCCCCGCCGGCTTTGGCTCCACTCGTGGTCACGGT

CTTGCAAGGCTTGGGAGCCGGCGGAGGAGGCGCCACCTTGAGCCTCCGGCTGCCGGTGCCAGGGTGCGGAGAGGATGAGCCAG

GGATGCCGCCGCCCGCCCGGCCTTCGGGCTCCGGGCCGCCCCAGCTCGGGCTGCTGAGCAGGGGGCGCCGGGAGGAGGTGGGG

GCGCCCCCAGGCTTGGGGTCGGGGCTCAGTCCCCCGGAGAGCGGGGGTCCCGGAGGGACGGCCCAGAGGGAGAGGCGGCGGCC

GGGAGCGGGGGAGACTGGGCGGGCCGGACTGGCCGGAGCCGGGGACAGGGCTGGGGGCTCCGCGCCCCCGGTGCCCGCGCTGC

TCGTGCTGATCCACAGCGCATCCTGCCGGTGGAAGAGACGTTCGTGCCGCTTCTTGCCCGGCTCCTCCGCGCCTCGGGGGCTG

CCAGGATCCCCAGTCTCGGAGCCTCTGGCACCGGCGGCGCCGGCCGCGGCCGCAGACGGAGAAGGCGGCGGCGGAGGCACCGA

CTCGAGCTTAACCAGGGTCAGCGAGATGAGGTAGGTCGTTGTCCGGCGCTGAAGCGCGCCCGCGCCCCGGCTCATGGGGCCCG

GAGACCCCCGAGCTGGGGAGGGGAGGGGACTCCCCCGGACTGCCTCAGGGGGGCCCGGCCATGGGGCCGCCCTGCTCGCTGCC

CCCAGCCCCCGGACCCCGCTGAGCCCCCGGCCCGGCTCCGCTGTCGCCGCCGCCTCCGCCGCCTCCGCTTGCGCCCCCCTCCC

ATCACATGGGGCGCCCCCTCCCCATGCTCCCCGCCCTGCGCCCCCACCCTCTTGGAGCCCCGGGACCTTGGTGCTGCTCCAGG

GAGGCGCGCCGGACCGTCCACCCCGGCCTGGGTGGGGGCGCTGAGATGGGTGGGGGAGGGCGGGGAGGACAGTAGTGGGGGCA

AATGGGGGAGAGAGAGGAAAAGGGAGCAGAAAAGGGGACCGGAGGCTAGGGGAAACGAACCTGTGCGGGGGAGGCAGGGGCGG

GGAATTGGGACTCAAGGGACAGGGGCCGCGGATGCGGTCGGAAAGAGGGTCTAGAGGAGGGTGGGAAGCTAGTGG

86
chr18
AGGAGCGCAAGGCTTGCAGGGCATGCTGGGAGAGCGCAGGGAACGCTGGGAGAGCGCGGGAAATACTGGGATTGGCTCCCGAG

group-
GGCTGTGAGGAGGGCACGAGGGGACACTCCGATGAAGGCAGGGCACGCGGGGCGAGCCGGGAGCGTCTCCTGAGGGCAGCGAG

00304
GAGGGAGCTGAGGCACGCGGGCTCTCAATCGACGCCCCACAGAGACCAAGAGGCCTGGCCTTGGGGGGCAGCTGCTTGAAGGA

GGCAGAGCGGAAGCGAGGGAGACTGCTGGAGGCCCTGCCGCCCACCCGCCCTTTCCTCCCCCTGAGGAGACGCCTGACGCATC

TGCAGTGCAGGAGGCCGTGGGCGTTAGAAGTGTTGCTTTTCCAGTTTGTAAGACCATTTTCCTGATTCTCTTCCCCACGGTTG

CGGAGGAGCAGGTCAGGGCCGCCATGAGGGCAGGATC

87
TSHZ1
TCGACCGCTACTATTATGAAAACAGCGACCAGCCCATTGACTTAACCAAGTCCAAGAACAAGCCGCTGGTGTCCAGCGTGGCT

GATTCGGTGGCATCACCTCTGCGGGAGAGCGCACTCATGGACATCTCCGACATGGTGAAAAACCTCACAGGCCGCCTGACGCC

CAAGTCCTCCACGCCCTCCACAGTTTCAGAGAAGTCCGATGCTGATGGCAGCAGCTTTGAGGAGGC

88
CTDP1
TGTGCCGTCGCACACAGACGCCCTCAACGTCGGAGAGCTGTGAGCGGGGCCGTGCTCTTGGGATGGGAGCCCCCGGGAGAGCT

GCCCGCCAACACCACTCCGACGTGATCCATGCTGGACATAAAGTGCTCTTCCCTCCGCTAGTCATCGGCCGAGCGGGCCCCTC

GCTCCTGGGTGTAAGTTCTTTCTGTGCGTCCTTCTCCCATCTCCGTGCAGTTCAG

89
KCNG2
CCATGCGCCGCTGCGCGCGCGAGTTCGGGCTGCTGCTGCTGTTCCTCTGCGTGGCCATGGCGCTCTTCGCGCCACTGGTGCAC

CTGGCCGAGCGCGAGCTGGGCGCGCGCCGCGACTTCTCCAGCGTGCCCGCCAGCTATTGGTGGGCCGTCATCTCCATGACCAC

CGTGGGCTACGGCGACATGGTCCCGCGCAGCCTGCCCGGGCAGGTGGTGGCGCTCAGCAGCATCCTCAGCGGCATCCTGCTCA

TGGCCTTCCCGGTCACCTCCATCTTCCACACCTTTTCGCGCTCCTACTCCGAGCTCAAGGAGCAGCAGCAGCGCGCGGCCAGC

CCCGAGCCGGCCCTGCAGGAGGACAGCACGCACTCGGCCACAGCCACCGAGGACAGCTCGCAGGGCCCCGACAGCGCGGGCCT

GGCCGACGACTCCGCGGATGCGCTGTGGGTGCGGGCAGGGCGCTGACGCCTGCGCCGCCCAC

TABLE 4B

SEQ

ID
GENE

NO
NAME
SEQUENCE

90
TFAP2E
GTCCTAACATCCCAGGTGGCGGCGCGCTGGCTCCCTGGAGCGGGGCGGGACGCGGCCGCGCGGACTCACGTGCACAACCGCGCGG

GACGGGGCCACGCGGACTCACGTGCACAACCGCGGGACCCCAGCGCCAGCGGGACCCCAGCGCCAGCGGGACCCCAGCGCCAGCG

GGACCCCAGCGCCAGCGGGACCCCAGCGCCAGCGGGACCCCAGCGCCAGCGGGACCCCAGCGCCAGCGGGTCTGTGGCCCAGTGG

AGCGAGTGGAGCGCTGGCGACCTGAGCGGAGACTGCGCCCTGGACGCCCCAGCCTAGACGTCAAGTTACAGCCCGCGCAGCAGCA

GCAAAGGGGAAGGGGCAGGAGCCGGGCACAGTTGGATCCGGAGGTCGTGACCCAGGGGAAAGCGTGGGCGGTCGACCCAGGGCAG

CTGCGGCGGCGAGGCAGGTGGGCTCCTTGCTCCCTGGAGCCGCCCCTCCCCACACCTGCCCTCGGCGCCCCCAGCAGTTTTCACC

TTGGCCCTCCGCGGTCACTGCGGGATTCGGCGTTGCCGCCAGCCCAGTGGGGAGTGAATTAGCGCCCTCCTTCGTCCTCGGCCCT

TCCGACGGCACGAGGAACTCCTGTCCTGCCCCACAGACCTTCGGCCTCCGCCGAGTGCGGTACTGGAGCCTGCCCCGCCAGGGCC

CTGGAATCAGAGAAAGTCGCTCTTTGGCCACCTGAAGCGTCGGATCCCTACAGTGCCTCCCAGCCTGGGCGGGAGCGGCGGCTGC

GTCGCTGAAGGTTGGGGTCCTTGGTGCGAAAGGGAGGCAGCTGCAGCCTCAGCCCCACCCCAGAAGCGGCCTTCGCATCGCTGCG

GTGGGCGTTCTCGGGCTTCGACTTCGCCAGCGCCGCGGGGCAGAGGCACCTGGAGCTCGCAGGGCCCAGACCTGGGTTGGAAAAG

CTTCGCTGACTGCAGGCAAGCGTCCGGGAGGGGCGGCCAGGCGAAGCCCCGGCGCTTTACCACACACTTCCGGGTCCCATGCCAG

TTGCATCCGCGGTATTGGGCAGGAAATGGCAGGGCTGAGGCCGACCCTAGGAGTATAAGGGAGCCCTCCATTTCCTGCCCACATT

TGTCACCTCCAGTTTTGCAACCTATCCCAGACACACAGAAAGCAAGCAGGACTGGTGGGGAGACGGAGCTTAACAGGAATATTTT

CCAGCAGTGA

91
LRRC8D
CACCTTCCCCGAGGTAATTATTTTCTGGGGGGTAGGGGTGGGGGTTGGGAGGGTGAAGAAAGGAAGAAAAAGAAGGCCGATCACA

CTGGGCACCGGCGGAGGAAGCGTGGAGTCCATTGATCTAGGTACTTGTGGGGAGGGGAGAACCCGAGCAGCAGCTGCAAACGGAA

GGGCTGTGAGCGAGCGGGCGGGCGGGTGGCTGGCAGCGAGGCCACCAGCAGGGGGGGCCCGGGCCGAGGCCGCGCCACCTCGGCA

CCACGCGGGCAGCCGGTGCGGCGGGGTCGCCACGGCCAGGGGAGCGCTGGGTGCCCACCATGGCAGTTATGCAAGCGGTGACCCC

CTGGTCTTGCCTCCCCGCCGCCCTGCACTCCTTCCTCCCCGCTGCCGACACTTGGATCTCTCTAGCTCTTTCTCTCCCCTGTGTT

TTCAAACAGGAAGTGCACGGCTGTCTATAACGTGCTGCCGGGTCTCAGGATGGAGGAGTGAAGTCTCCTGTCGCCGTGGTTCCAG

CCTCCGGAGCTCGCCCAAGCCGCGTCCCCAGAGAGCGCCCTGAGAGAACAGGGTGGCCGCTTGGTCCAGGTGCGCGGGGTCGGGT

CTGGGTCCAGGGAGCGGGTCGGGAAGTCTGCGGCACGGAGCACTGCTAGTGTCGGATCTGCATCTCCAGCTCTGTGCTGCAGCTT

CACTTGCCCGCCCCCCACCACTGGCTTCTCACCCGGGGTCTCTGCCAAACTCTGGCTGCTGCCGCCCTGGGTTCGGGCCGGCGGA

AGGCCCTGGGCGTGCGCTGCGGAGCCGCCTGCGAGGACTCCACTAGGGCGCTTTCCAGGCTGGACTGCCCCGGGCTGCGCTGGAG

CTGCCAGTGCTCGGGGAGTCTTCCTGGAGTCCCCAGCTGCCCTCTCCACC

92
TBX15
CTCTTCCCAAGTTACGCCACCGGTCGAGGACGGCAGGAGACCCCCGAGTGCAGAGAAAGCTCAAACCGGCAGCGAAGTCGGTCCT

AGCCAAGCTGAAAAAACGTCTCGGATTTCGCGGACAGCGGCCTAGACACAGCCCGATCTTCCAGTCCTAGTGCCCTGGTCGAGAC

GGTTCTATCCTTTTGCAAAGAAGCCGGAAA

93
C1orf51
TCTCGGTTGCAATCCCCACCCTCCTCACCCAGCAGGGCAGGAGGCACCCAACTTGGAGGAGAAAGGGGTGGGGGAGGTGAAACAG

AGACCGGAGAGTCACGAGGGCTGGGCCGCCGAGAGCAGGAGAATATACCGTGTCACACACCTCCATTCTCTCACACACGTTGCAG

ACACAAATCACTGACGGTTTCCACGTGCTGCGCTCGTGAGCGGAGGTGTTCAAAGAGGGGGCAGATGAGTTACTTCCCGAGACGG

AACCGGGGGTCCCACGTCCGCCGCCTTCAGTAGCACAACCAATCTCTGAACACTCAAACCGCGCATCTCTGGCGCATCACCATCC

TATTTAAGGCCACGGGCTCCGCCCTTTTCCTCCCCTCCCTTCTTTTCCACTCTTTTTCCA

94
chr1:
CTGCCAGAGATGTGTCTGTCTTGCGCCCCGCATGCACTGCCTGCGGGGCTGCGCTGCACTCCCCGGCGGCGCCACGGGTCTGGCC

179553900-
CCCGCGCTTCTACGTGTTGGGGGGATGCATGGACCTTGGAGATCCGTAGTTGGCCCTAACCTTCTCGGAATCTCCTCTGCACGCG

179554600
CTGCCTGTTCCTCCTCTGCACGCTCTGTCCGTTCCTTTGCAACTTCTGTGGGAATTGTCCTGGCGTGGGAAACGCCCCCGCGCTC

TTTGGCACTTAGGGTGTGAGTGTTGCGCCCCTTGCCGCAGCGCTCAGGGCAGCATCCCGCTCGAGGATGCAGGGTTCTCACCAAG

CAGTGAGGGGGACTCACGCGCCGCCGGGGAGCGGAGCCAGGCTCCGAGAAGGGAGCAGGCTCGAGCCGCTGGGTTTTCGCAAGCC

TTGGGGCCTCTGGCCGCCCTTCCATGCCTCCGGGCGCGGGCGGCTCAGCAGGTCCCCGGCTTCGGGAAGTTTTGTGCGCGGATCG

CTGGTGGGGAGGGCGCGCGGGCCAGTGGCTGAGCTTGCAGCGAAGTTTCCGTGAAGGAAACTGCATGTGCCTTTGGAGGCGACTC

GGGACTGCTGTAGGGTGGACTGGGTGTCTATGGAGTTGCGGGTCAGAGCGAGTAGGGTGGGTCCTTTCCTGGGACAGGACTGGGA

ATTGGGGCTCGAAGTAGGGG

95
ZFP36L2
AGGGGTGTCCTCCAACATCTCTGAACCGCCTTCCCTTCCTCCTCACTGGCGCCCTCTTGCCTCAGTCGTCGGAGATGGAGAGGCG

GCTGAAGATTGGCAGGCGGCGGCCAGGGTCGAGGCTGGGAGACTCAGAGCCGCTGAGGCTGCCGGAGCTCAGGGAGCCGCTTAGG

TAGCTGTCGCGGTCCGACAGCGAGTCCGGG

96
SIX2
TCTGACTCTCGGGCTGGAGCAGCCGAGACAGCGCTCCCCAGCGGGACTACAGAATCCCGGGTGTCGGCCTGGGGGCCCTGGATTG

GCAGTGGTGGAGTCTTCTGAGCCTAACAGCTACTAGGAATGACAGAGTTGCAGATGGCTTTGTCGCCCGCGGGGCGGCTCAAGCG

TCCTGGGTCCCAGGCCTCTGTCCTACGGCCAGGCCGCCGGCTCAACGGGCCGAAGGGAATCGGGCTGACCAGTCCTAAGGTCCCA

CGCTCCCCTGACCTCAGGGCCCAGAGCCTCGCATTACCCCGAGCAGTGCGTTGGTTACTCTCCCTGGAAAGCCGCCCCCGCCGGG

GCAAGTGGGAGTTGCTGCACTGCGGTCTTTGGAGGCCTAGGTCGCCCAGAGTAGGCGGAGCCCTGTATCCCTCCTGGAGCCGGCC

TGCGGTGAGGTCGGTACCCAGTACTTAGGGAGGGAGGACGCGCTTGGTGCTCAGGGTAGGCTGGGCCGCTGCTAGCTCTTGATTT

AGTCTCATGTCCGCCTTTGTGCCGGCCTCTCCGATTTGTGGGTCCTTCCAAGAAAGAGTCCTCTAGGGCAGCTAGGGTCGTCTCT

TGGGTCTGGCGAGGCGGCAGGCCTTCTTCGGACCTATCCCCAGAGGTGTAACGGAGACTTTCTCCACTGCAGGGCGGCCTGGGGC

GGGCATCTGCCAGGCGAGGGAGCTGCCCTGCCGCCGAGATTGTGGGGAAACGGCGTGGAAGACACCCCATCGGAGGGCACCCAAT

CTGCCTCTGCACTCGATTCCATCCTGCAACCCAGGAGAAACCATTTCCGAGTTCCAGCCGCAGAGGCACCCGCGGAGTTGCCAAA

AGAGACTCCCGCGAGGTCGCTCGGAACCTTGACCCTGACACCTGGACGCGAGGTCTTTCAGGACCAGTCTCGGCTCGGTAGCCTG

GTCCCCGACCACCGCGACCAGGAGTTCCTTCTTCCCTTCCTGCTCACCAGCCGGCCGCCGGCAGCGGCTCCAGGAAGGAGCACCA

ACCCGCGCTGGGGGCGGAGGTTCAGGCGGCAGGAATGGAGAGGCTGATCCTCCTCTAGCCCCGGCGCATTCACTTAGGTGCGGGA

GCCCTGAGGTTCAGCCTGACTTTCCCGACTCCGCCGGGCGCTTGGTGGGCTCCTGGGCTTCTGGGCTCACCCTTACACCTGTGTA

CTAAAGGGCTGCTACCCTCCCGAGGTGTACGTCCGCCGCCTCGGCGCTCATCGGGGTGTTTTTTCACCCTCTCGCGGTGCACGCT

TTTTCTCTCACGTCAGCTCACATCTTTCAGTACACAGCCACTGGGTCTCCCTGCCCCTCCAGCCTTTCCTAGGCAGCTTTGAGGG

CCCAGACGACTGAAGTCTTACTGCTAGGATGGGAACACGATGAAAAAGGAAGGGGCCCAGTCAAAAGTCCTCTCCTCTTCGGTTT

TTCTTCAACTGTCCTTCACAAAAACATTTATTTCTGTCCCAGCGCCCTGGCGGATTTCGGCAGATGGGCCCTAGGGGGTTGTGGA

GGCCAAATTCCCAGGATGCTGGTCCTGCCTTTTTCATTGGCCAAAACTGTATTTCCTACAACGACTAAAGATAACCAAGAACTGA

GTAGACCCTGTTCTCTCACCAGATCTCCCTGGCTCTGTTTAACTTTTCCTGGTGCAATGCGATGGCACCACCAGCTCCCCAGGCA

GGCACCACTCCCTCAAGATACCATTTGGGGTAGGGATTTGAGTCCTGGAGAGGGTCAGCGGGGCGCCGGGGTGGGGGTGGGAAGG

AGACTGACAGGGACACACCGCGAGCTCCGCATACTCTCCTCTGCCCCCTGTAGCCCGGGGCTTTAATGACCCCAAGCAGATTTCC

TGTCTCTGGTCTAGCCAGCTGCCCCTAGGGCTGGATTTTATTTCTTCATGGGGTTTCACCCTAAAGGGCCCCCTGGTCATGGGAC

CTGGTTGGGAACAAATGAAAGATGTCTTGTAGCAAATGCTTTCAGGGGAGCAGAAAAGAAGATTGGGCACTTCCAGTCACTTGGT

CACTTTAGGTGGCTGGAACAAAACTGGTGACTTTCACGACTGCTACAGGGTGAGGGGGTGAAGGGTGGCAGAGAGGTGACAAGCC

ACTGGGAATCCTATTCAGTGGGGATGCCGACAGGGAGTGGCTGTAATCAACTGAGCAACATCTGTGTGAATGTTATTCACAGGTC

AGGACAGCAGCTTGGTCTTCCCAGGTGAGGAACTGAGGACTGGCCTGCATAGATTTGTGCAGTAGGTGAGTAGCTTCCAAATTTA

TTTTCAGAACTTCCATGTAGTACCTGCCTCTCCATTTAAATATTTTTTAAAATTTTATTTATTTAAATATTTTCTTGGTTAGCTT

TCCAAGAGGGAGGAAAAGAGGGGAGTTGCAACAAGTAGTGCCCCTATGCTGGGATTCATTTTCCAGAGTAAAGCCTGGGACTGGC

ACCCTGACCCCTACCGGCAGGTGAAAACTCCAGGCAAACTGCTGAGATCCCACCTGGGCTGGCTGAGATAGTGCCTGGGGTGCAT

CCCTCAGCAGCTGCCACCTGGGCCCTGGGGCCATCTCTTTCTCTGGCATCAAGCAGCCAGGTGTCAAGGCCTTCCCAGCAATCCA

TGCTGCATGGCTGGGTCTTGTTCTAGCAGGTCGATGGGCAGGGACTGGTAGCTTAGCCAGGGCACCAGTGCGTGGCTGTGGGTTT

GTGTGCTTCTGTGGAGAAGCATGATGTGTATGTGTGTGTGTGGGCACAGGCATGAGGAAGGGTTCATTTGTGCAGGTATCTCCCA

TGTATATCAGTGTGGGAGAGTGCCTGAGGATGTGTTTGTGTGTCTGAAAATGGGCGGAGGGTCTGTTGTGCTAATGTGTGCAGGG

GTGAACATGTGTGTGACAGTCTGTGTGTTTCCCTGAGTGGTGGCTGCGTGAGAGGGTGAGGGGATTTGGTGTTGTCTACCATGCC

CGGCACATAGCAGGCTCTTAATAATCTTGAATTTAATTAATGTTAAATGTGTATGTTCCCATCCTTGTGGAAGTTGGTATAGAGC

CTGTTTTCCTGTGATTGTGAGACTGGAAAATGGGGGACGGGCAGGGGCGAGACAGGATACAGAGGCTACTGTTTTCTTCCTCCCT

AGAAGTAAGTACATAGAAGAGTGGGCTCTGGCACCTCACGGGACATCACCAAGTCCTGTGTGGCTGGCTAGGCTGTCCCAAGGTG

GCTTCAGGCATCACTTGAATCTTTTGAGACCTTCAGGCAGTAGCCTGCCATTCACCCTGTCAGTCAGCAGAAGTTGGGCCCACAC

AGGCCATAGAAACACAGAGCAGTTCCCGGGAGGACCTGAGCTGTCCCTGAGAGCAGAGCTTCCAGGAGAGGCCGCAGGAACTGCC

TTGACCGGAATTCCTCTTGGGGTGCAAAGGTGGAGGGACACATGGTGCGACCCCAGGCAGAGGACTGCAGCCACTCCGTGCAGTC

CCAGCCTCTGGGGTAGCCCCTTGACCTCCAGGCCTGCACAGATCCAAGGCCGAGGTCCAGGCTCCAGCGCCAAATTAGCTGGCCT

AGCAGCCTGCAGCCGCTCTAATCTCAACTAGGAAGGAATCCTTGCGCTTAGAAAGTCCAAGCGAAAGGGTATTCTGATTTTATCC

CGGTTTTACCAGAAAATGCTGAAAGGAAAAGCCCCGAGAGGACACAGTGCTCTAGGAACTCGGGGCGCCACGAGCGCCTCATCCC

CTCCCTTCCGCCCGGCCGCGGTGCCCTGGTCGCTGAGGGACGCGGTCAGTACCTACCGCCACTGCGACCCGAGAAGGGAAAGCCT

CAACTTCTTCCTCTCGGAGTCCTGCCCACTACGGATCTGCCTGGACTGGTTCAGATGCGTCGTTTAAAGGGGGGGGCTGGCACTC

CAGAGAGGAGGGGGCGCTGCAGGTTAATTGATAGCCACGGAAGCACCTAGGCGCCCCATGCGCGGAGCCGGAGCCGCCAGCTCAG

TCTGACCCCTGTCTTTTCTCTCCTCTTCCCTCTCCCACCCCTCACTCCGGGAAAGCGAGGGCCGAGGTAGGGGCAGATAGATCAC

CAGACAGGCGGAGAAGGACAGGAGTACAGATGGAGGGACCAGGACACAGAATGCAAAAGACTGGCAGGTGAGAAGAAGGGAGAAA

CAGAGGGAGAGAGAAAGGGAGAAACAGAGCAGAGGCGGCCGCCGGCCCGGCCGCCCTGAGTCCGATTTCCCTCCTTCCCTGACCC

TTCAGTTTCACTGCAAATCCACAGAAGCAGGTTTGCGAGCTCGAATACCTTTGCTCCACTGCCACACGCAGCACCGGGACTGGGC

GTCTGGAGCTTAAGTCTGGGGGTCTGAGCCTGGGACCGGCAAATCCGCGCAGCGCATCGCGCCCAGTCTCGGAGACTGCAACCAC

CGCCAAGGAGTACGCGCGGCAGGAAACTTCTGCGGCCCAATTTCTTCCCCAGCTTTGGCATCTCCGAAGGCACGTACCCGCCCTC

GGCACAAGCTCTCTCGTCTTCCACTTCGACCTCGAGGTGGAGAAAGAGGCTGGCAAGGGCTGTGCGCGTCGCTGGTGTGGGGAGG

GCAGCAGGCTGCCCCTCCCCGCTTCTGCAGCGAGTTTTCCCAGCCAGGAAAAGGGAGGGAGCTGTTTCAGGAATTTCAGTGCCTT

CACCTAGCGACTGACACAAGTCGTGTGTATAGGAAGGCGTCTGGCTGTTTCGGGACTCACCAGAGAGCATCGCCAACCAGAACGG

CCCACCCGGGGTGTCGAGTCTTGGTAGGGAAATCAGACACAGCTGCACTCCCGGCCCGCGGGCCTTGTGGCATATAACCATTTAT

ATATTTATGATTTCTAATTTTATTATAAAATAAAAGCAGAAATATTTCCCGAAGAACATTCACATGAGGGCATTACGGGGAGACG

GCAAGTCGGCGGCTCGGGGGGCGCGCTCAGCCGGGAGCGCTGTAGTCACAGTCCCGGGAGGAAGAGCGCG

97
chr2:
TGGAACAAGTGTCAGAGAGTAAGCAAACGACTTTCTGAGCTGTGACTCTGCTCCTCGACTGCCCACGTGCTCTCCGCTGTCTGCA

137238500-
CTCCTGCCTCACCTGGGCTGACTCGGACTCTCCACCTCCTTTGCTGCTTCCGGCATGAGCTACCCAGGAGCCTAAGGCGCTCCTT

137240000
CCCGCAACTCCGGTCCCCGCGCCCCGGGACTGCAAATCCTTTAAACAGAGGCCCCAGAGCTAGGGGTTTTCCCAGGCTCTGGTGG

GCGTGGGCTGACAGTCGCTGGGAGCCCCGCAACAGGGGGGATGTCCAGGCAGGTATGCACCCAGCTCCCGGCGTTTCCCGGAGTC

ACCACAATGTTTCCCTTTCTCTCTCCCCCACGTATGCTGCTAGGGGTACTCCCCAGATAGGATTTTCTTTGTCTTTTCTCCTAGT

AACACCGAAGCCCTCTCGTGCCCGGGGACTGCAGAGGAACGCCAGACCATCCGGACCTTGCGGGATGGCTCGGTGTGTGTGTTTT

ACTGTGTGTCGGAGTGTCGCGCATGTGTGCGTGTTGGGGCGCGTTATCAACAGGGGCCTAGGGCACCCCCACTCTTTCTTGCTCT

CTTCCCCCATCACTTCATGGACCTCCGAGGCGCAAAGCGCTCGACCCTCTCCTGGGCTCAGTGGCTTGGGTACTCCGGGCTGAGC

TCAGCTGGGGAGTCCCCTTACCCAGCCCGCACCGGCACCCCGAAGCTTCAAAGTTGCGGCAAACAGTTGCGGGGAGCAGAGGAAC

TGAGGTCCAGGCCAGCGCGCCCGCGGTCGCTCGCCTTGGGGAGCAGGCTGAGCCGAGGGTCGTGCGGGTGCGCGGCAGAGGCGGT

AGGAGGCGGAGGAGAGGGGGGAGAAAGAGGGGGCGGTGGGGAACAGCTGCCGGGGTAGGCGAGGCGCAAGGTGGCTCCCCGCGGC

CCCGCGCCCCGCGGCTCTCGGACGCACCAGGCAGCCAATGGCTGCGCAGAGGTGTACAGCAGATGGCGTCTGACTGCGCCGTTCC

TTCCTCCTCCTCCTCCTCCTCCTTCTCTTCCTCCTCCTCCTTCTCTTCCTCCTCCTCCTCCTTCAGTGCTGAGGAGCCAGAGTCG

CCGCCGGGTTGCCAGACGCTGGAATGGGTGGTCTTCCGACACACACCACCATCTTTCTTGCGCTCGGGAAGCTCGGGGCTCAGCG

GCTCCCAGAGGTTACGGCGGCGGCTCTGGCGAGACGGGTGAGTGCAAGCACGCGGAGCCCCGAGTCGGGGATGCCGGGCCCCCTG

GCCGGCCGACTGGGGCGCGGGGTGGCAGCGCCGGGGAAGGGGGCGCGCTGCCGGCGCAGACTTTGCTCTTTCCTCGCCGGACAGC

CATCGTCGCCCCTTCTCCCAGCCAGACGCGGGAACTTGGAAGCGGATCTTCTCGGACGCCTCTGGCTTGGGGCTGCGGGAAGCGT

GGGCTGCCCGGGGCGCAGTGTGCGGAGACCCTCTAGGCGGGCGGGGACGCCCCAC

98
MAP1D
GTTATTATCCACGGGGTCCTAATTAAAGCTTGATTAAAATGCCCTTCTTTCTCTAAAAAATTACGAACTAGGCAACTTCATACAT

TTTGAATGGCGCAGTGTTTCCTCTTCCAACTGTTTAGTTTGTAGTATACTATGTAAGCAACATCAATTATCAACCCTTGCAAGAT

GACAACATGAGCCTGTGGGGGAAGCACTTGAGGGGAGGGAGGAGAAACTTCTCTTTTTTAATAATCAGCCGGAAACAATGTTTAA

CAAGAATCTGATGAGGTCACTGCAGTAAATATTTTTCCTCTTACAGAGCCAATCATCACGGAGGGATCCCCTGAATTTAAAGTCC

TGGAGGATGCATGGACTGTGGTCTCCCTAGACAATCAAAGGTGTTTGCTTTCTGCTCTGTTGCTTTTAAATTGTATGGGAAAGGA

AGATTGGTCCGACGGCGCGCTTGTGGCCCGGCCGGAGCTTGCGTGCGCGTTCTGACGGCTGGGTGCTGTGTTACAGGTCGGCGCA

GTTCGAGCACACGGTTCTGATCACGTCGAGGGGCGCGCAGATCCTGACCAAACTACCCCATGAGGCCTGAGGAGCCGCCCGAAGG

TCGCGGTGACCTGGTGCCTTTTTAAATAAATTGCTGAAATTTGGCTGGAGAACTTTTAGAAGAAACAGGGAAATGACCGGTGGTG

CGGTAACCTGCGTGGCTCCTGATAGCGTTTGGAAGAACGCGGGGGAGACTGAAGAGCAACTGGGAACTCGGATCTGAAGCCCTGC

TGGGGTCGCGCGGCTTTGGAAAAACAAATCCTGGC

99
WNT6
TCCCTGCTGTGGGACCCGAGGAGAGGAGAACTGGTTCGCT

100
INPP5D
TCTCTCTCTCTCTCTTGCTTGGTTTCTGTAATGAGGAAGTTCTCCGCAGCTCAGTTTCCTTTCCCTCACTGAGCGCCTGAAACAG

GAAGTCAGTCAGTTAAGCTGGTGGCAGCAGCCGAGGCCACCAAGAGGCAACGGGCGGCAGGTTGCAGTGGAGGGGCCTCCGCTCC

CCTCGGTGGTGTGTGGGTCCTGGGGGTGCCTGCCGGCCCGGCCGAGGAGGCCCACGCCCACCATGGTCCCCTGCTGGAACCATGG

CAACATCACCCGCTCCAAGGCGGAGGAGCTGCTTTCCAGGACAGGCAAGGACGGGAGCTTCCTCGTGCGTGCCAGCGAGTCCATC

TCCCGGGCATACGCGCTCTGCGTGCTGTGAGTACAACCTGCTCCCTCCCCGGGCACAGATATGACAGAGGGGCTTAGAGGGGGCC

CAGCTTTGAGATGGGTTGTTCTTATGTCACAGGACAGAGTGATCTGACATGCACACTTCCCCGCCACCCTGTCAT

101
chr2:
TGTCCTCGAAGAAGGGCCTGAGCAGCAGCAGAGGACCCCAGGCGACCGTGCCTGAGCCGGGCGCCGACGACGACTGAGCACCTGA

241211100-
TATGTCCCCGGCACTCGCAGCCCCGCGGCCGGAGTCGCTGTGGGTGAGCGGTCGTCGAGCTTCACAGAGGCCGGGCTCTGTGCCA

241211600
GGGCCCCGACAGGGCAGGAAGCAGATAGAGTCCCACAAGCACAAGCCCAGTGCGCAGAAAGGGTTACTTAAAAAATAAGTTCTGT

GATAAAATCAAACAGGGTGAAGGGCTGGAAACAGGTCATGAGGGCGCAAACAGGTCGTGAGGGCGCAAACAGGTCGTGAGGGCGC

AAACAGGTCGTGAGGGCGCAAACAGGTCGTGAGGGCGCAAACAGGTCGTGAGGGCGCAAACAGATCGTGAGGGCGCAAACAGGTC

GTGAGGGCGCAAACAGGTCGTGAGGGTGCAAACAGGTCGTGAGGGCGCAAACAGGTCGTGAGGGTGCAAACAGGT

102
WNT5A
AAATGAGACCTCTGGGGAGACTGTCAACCCCAGGGGTAAAACAAAAATTCTGATCAGAAACTGAGTTTCCCAAAGAAGGGGCTAA

ATGTTTTCCAACACTTTCGGGGCTCAGGGAAGATGACTCTGTAAGGACACTGAGAATCTTCCTCGCGTGCCACGGGGAGGAGGAC

TGGGGGCGTTTGAGGGGCTCAGCGCACCAGAGGAGTGAGGTGGAGGAGGGCGTTCCCGCGTCCTCCTCTTCAATCCAGAGCAGCT

CAACGACGTGGCTCCCTTTCTATGTATCCCTCAAAGCCTTCGCGT

103
chr3:
TAGGCTCTAGTGGACCTAGCAGTGGGAGAGCTACTTGGGCTGGTTTCTTTCCTGACGCTGCAGGGATGGGCATCGGCCTGGAACC

138971600-
AGAAGCGCAGGAGCTGGGCCACGGCAGAGTAATTAAGAAAATAATGAAATTGATGGCGGATGGGGGCGCTAGAAATCCTGGGGCG

138972200
TCTACTTAAAACCAGAGATTCGCGGTCGGCCCCACGGAATCCCGGCTCTGTGTGCGCCCAGGTTCCGGGGCTTGGGCGTTGCCGG

TTCTCACACTAGGAAGGAGCCTGAAGTCAGAAAAGATGGGGCCTCGTTACTCACTTTCTGCGGGTCGGGGACGTCCCTTGGCTGC

CACCCCTGATTCTGCATCCTTTTCGCTCGAATCCCTGCGCTAGGCATCCTCCCCGATCCCCCAAAAGCCCAAGCACTGGGTCTGG

GTTGAGGAAGGGAACGGGTGCCCAGGCCGGACAGAGGCTGAAAGGAGGCCTCAAGGTTCCTCTTTGCTACA

104
ZIC4
GAGGTTGCTGACTCAGGAGCCAGGAGCTGAGAAACTCCTAGGCTAGCAGCCGTTGAGCCTAATTTTATTTTCTGGCTTTCTCCGA

AATGTCTCGTTTCCCTCATCTTTCTGGTCCTTTTCGTCTCTCTTATTTTCCCCAAAACGTCTACCTCACTTCGTCTTCCTTTCTC

CTCCCCTCCCCCTCTCTTTCCTCTATACTCTCTTCCCATTTAGCCTTGCAGGCCCCTCCTCCCCGGTGTTGGAGAGCTCAAAGAC

GCGCGAAACTCAAGGATCTGGCCCTGACCAGGGACGGGATTAGGCGGGAAGTGGTGACGGCCTGAAAAGGCTGGGCTCGAACCCG

TGCCTTCCTGAAAGGACTCTCCCCGCCACAAGTCACACCCACCCGCAGGCCTGCTGGCCAAAGAAACAAAGGAGTCGGGCGTGGA

TCCAGGAGAAACAGGTTTTCGCTCTCGGATCTCCCTGGGCAAATCAGGGATCCTGAGCGCTATACCCCGCAGTCGTACGGAGCCT

CTGGGAAAGGGGATTTAAGGGTGACTTCCACTTTCAGCTTCGGCTACTTGTTGCCTGCGGTCCAAGCCTTCTCTGCTTCCTCCTA

CCTCGTCTTAGGCCTCTGTAGAAAGTGCACGCCGCGTTTCCCCTTCCAGGCTCTGAGAGGGCCTGCAGGCCCGTGGCCGCCTCCG

ACAAGATGCCTTCCAGTGCTAGGGGGGCCACTTTGGCGGGATGGGGGTCGGTTGGTTAAAAAAAACTTAAGTTCTGGCTCAGTCG

AGTGTGGCAAAAGCCGAGGGTCGGGGGTTGGGGGG

105
FGF12
TACTGACCTGGTCTCCGCCTCACCGGCCTCTTGCGGCCGCTGCAGAAGCGCACTTTGCTGAACACCCCGAGGACGTGCCTCTCGC

ACAGGGAGCGCCCGTCTTTGCTGGGGCTGGAGCGGCGCTTGGAGGCCGACACTCGGTCGCTGTTGGACTCCCTCGCCTGCCGCTT

CTGCCGGATCAAGGAGCTGGCTATCGCCGCAGCCATAGCTGCTCAGCGAGGGCCTCAGGCCCCAGCCTCTACTGCGCCCTCCGGC

TTGCGCTCCGCCGGGGCGAGGGCAGGACCTGGGCGGCCAGGGAAAGGGCAGTCGCGGGGAGGCAGTGCTAAAATTTGAGGAGGCT

GCAGTATCGAAAACCCGGCGCTCACAAGGTTAGTCAAAGTCTGGGCAGTGGCGACAAAATGTGTGAAAATCCAGATGTAAACTTC

CCCAACCTCTGGCGGCCGGGGGGCGGGGCGGGGCGGTCCCAGGCCCTCTTGCGAAGTAGACGTTTGCACCCCAAACTTGCACCCC

AAGGCGATCGGCGTCCAAGGGGCAGTGGGGAGTTTAGTCACACTGCGTTCGGGGTACCAAGTGGAAGGGGAAGAACGATGCCCAA

AATAACAAGACGTGCCTCTGTTGGAGAGGCGCAAGCGTTGTAAGGTGTCCAAAGTATACCTACACATACATACATAGAAAACCCG

TTTACAAAGCAGAGTCTGGACCCAGGCGGGTAGCGCGCCCCCGGTAGAAAATACTAAAAAGTGAATAAAACGTTCCTTTAGAAAA

CAAGCCACCAACCGCACGAGAGAAGGAGAGGAAGGCAGCAATTTAACTCCCTGCGGCCCGCGGTTCTGAAGATTAGGAGGTCCGT

CCCAGCAGGGTGAGGTCTACAGAATGCATCGCGCCGGCTGCGGCTTTCCAGGGGCCGGCCACCCGAGTTCTGGAATTCCGAGAGG

CGCGAAGTGGGAGCGGTTACCCGGAGTCTGGGTAGGGGCGCGGGGCGGGGGCAGCTGTTTCCAGCTGCGGTGAGAGCAACTCCCG

GCCAGCAGCACTGCAAAGAGAGCGGGAGGCGAGGGAGGGGGGAGGGCGCGAGGGAGGGAGGGAGATCCTCGAGGGCCAAGCACCC

CTCGGGGAGAAACCAGCGAGAGGCGATCTGCGGGGTCCCAAGAGTGGGCGCTCTTTCTCTTTCCGCTTGCTTTCCGGCACGAGAC

GGGCACAGTTGGTGATTATTTAGGGAATCCTAAATCTGGAATGACTCAGTAGTTTAAATAAGCCCCCTCAAAAGGCAGCGATGCC

GAAGGTGTCCTCTCCAGCTCGGCGCCCACACGCCTTTAACTGGAGCTCCCCGCCATGGTCCACCCGGGGCCGCCGCACCGAGCTG

GTCTCCGCACAGGCTCAGAGGGAGCGAGGGAAGGGAGGGAAGGAAGGGGCGCCCTGGCGGGCTCGGGATCAGGTCATCGCCGCGC

TGCTGCCCGTGCCCCCTAGGCTCGCGCGCCCCGGCAGTCAGCAGCTCACAGGCAGCAGATCAGATGGGGATTACCCGCCGGACGC

AAGGCCGATCACTCAGTCCCGCGCCGCCCATCCCGGCCGAGGAAGGAAGTGACCCGCGCGCTGCGAATACCCGCGCGTCCGCTCG

GGTGGGGCGGGGGCTGGCTGCAGGCGATGTTGGCTCGCGGCGGCTGAGGCTCCTGGCCGGAGCTGCCCACCATGGTCTGGCGCCA

GGGGCGCAGGCGGGGCCCCTAGGCCTCCTGGGGCTACCTCGCGAGGCAGCCGAGGGCGCAACCCGGGCGCTTGGGGCCGGAGGCG

GAATCAGGGGCCGGGGCCAGGAGGCAGGTGCAGGCGGCTGCCAACTCGCCCAACTTGCTGCGCGGGTGGCCGCTCAGAGCCGCGG

GCTTGCGGGGCGCCCCCCGCCGCCGCGCCGCCGCCTCCCCAGGCCCGGGAGGGGGCGCTCAGGGTGGAGTCCCATTCATGGGCTG

AGGCTCTGGGCGCGCGGAGCCGCCGCCGCCCCTCCGGCTGGCTCA

106
GP5
GGGGGACACAGAGAGGAGGGGTTGCGGGCCTGTGAGAATGAAGAGCACAGAGCGGAGAGGGGGAGGAGGAGGGAAAGGAAGGCGT

GGCAGTGAGAGAGAAGAGGAAGAAGAGAGGAGGAGTGGGGAGGGGAGGGAGAGCAAGACAGCAGCGGGTCTGGATTCCCCTCCGA

GCCACATCTGGTCAGGTTCTAAGTAATTAGAAGATTTTCCCATTGGTTTACCCAAGGGCTCTCTCTCTGATTAATTTTCGAAAGA

GTTGGCCAATTTTAATCATAGCAAACACGATGATCACGGTGATCATGGCCTGAACAGCTAAAAGCAGAAAATAAAACCCCCAGAA

CGGACTATGATCTTGACCTTTGCCCGTGGTCACCGGCTGGGCCCACACCCAGGGTTCTGAGCTGTTGGGAGCCAAGGCTGGGTGG

ACAGGGGCTTCCGAGGAGCTGTCCGCAGCGGGGCGGGGAGGCGGGCCCCGGGGGCCCGGGCACTCCGCGTCACCCCCCGGCAGGG

CCCAGAGCGGCAGGCCGGCGTGCGCCCCAGGGCCTGCGCACCGTGGGGGCTCTTCCCCGCCCACGAGGCCTAGGTGCTGCCGCAG

CCACCCCAGGAAGGGCCCCAGGCCACAGTCGCAGCGCCAGGAGTTGTGCCCCAACAGGACCTCCGTCAGCCGGGGCAGAGCCCCA

AACACGTCGCCAGGCAGGGTCTCCAGCTGGTTGTGGTCGAGCTGGACGCTCTCCAGGCTGCTGAGATTGCGGAAGAGGGCACGGG

GCAGGGCGCGCAGCCTGTTGCGGCGCAGGGACACC

107
MSX1
GCCCCGGTGCACCGCGCGTCCAGCCGGCCCAACTCGAGCTAGAAGCCCCAACCACTGCCCAGTGCCTGAGTTGCAGTCTTGGGTC

CTTTAGAAACCTGGAGATGTGCGTAAAATTCAGATGCCGGTATTCCCGAACTTCCCCAGGCCTCAGCATATCTCGGCGGCCTGTG

GACAGATGGGAGGCTACCAATCGCTCCGGCGTCCGCAGCCCGACCCCTGCCGCCAGACCCCGGACGTCTTCCGGATAATAAAGTT

CCCGCTCTAATTCATTTTCCCTAATCTGGACGCCCCTAATCTACAGCTTTTATTGCGCCCAGTTAAAAGTCGAGGGAATTCGCTG

TCCCTCCGCGCTCGGATAATTACCCCTAAATGGCCACGGCAGCCCCTTGTGTTTCCTGGAGATTAGAACCCCGCAGTCATCAATG

GCAGGGCCGAGTGAGCCGCCAATCACCTCCGCTCACTCCCTGAGAGCCGCTGGCCTGGGCCGCAGGAGGAGAGGCCATAAAGCGA

CAGGCGCAGAAAATGGCCAAGCCCCGACCCCGCTTCAGGC

108
NKX3-2
AGGGTGCCTCTGTTCAAATTAGAAAAAGGCGCCCCCTCAGGGCAGACTCAGCCCAGCTGCCAGGGGACAAGTCCTGGCTAACGGG

AGCTGGAGCTGGGTTTCACCTCCAGGTGCCTCCTTGGCGGGGCGCCCCGTGCAGGCTACAGCCTACAGCTGTCAGCGCCGGTCCG

GAGCCGGAGCGCGGGAATCACTCGCTGCCTCAGCCCAAGCGGGTTCACTGGGTGCCTGCGGCAGCTGCGCAGGTGGAGAGCGCCC

AGCCTGGGAGGCAGTAGTACGGGTAATAGTAGGAGGGCTGCAGTGGCAGAAGCGAGGGTGGCCGCAGCACTTCGCCGGGCAGGTA

TTGTCTCTGGTCGTCGCGCACCAGCACCTTTACGGCCACCTTCTTGGCGGCGGGCGCCGAGGCCAGCAGGTCGGCTGCCATCTGC

CGGCGCTTTGTCTTGTAGCGACGGTTCTGGAACCAGATTTTCACCTGCGTCTCGGTGAGCTTCAGCGACGCGGCCAGGTCTGCGC

GCTCGGGCCCGGACAGGTAGCGCTGGTGGTTAAAGCGGCGCTCCAGCTCGAAGACCTGCGCGTGGGAGAAAGCGGCCCGCGAGCG

CTTCTTGCGTGGCTTGGGCGCCGCCGGCTCCTCCTCCTCCTCCGCGACGCCTGCCGGCCCGCTGCCGCCCCCGCCGCCGGCCCCG

CTGCACAGCGCGGACACGTGTGCACCTCTGGGGCCAACACCGTCGTCCTCGGTCCTTGGGCTGCGGTCGCCTGCGGACCCCGGTG

GGAACAGAAACAAGAGACTGTCAGCGCCACAGACGAGGTGAGGCCGGGCCTCAACTGCAGGGGTCACGGGAGTGGGGCGGAAATA

CACTTTGATCCCACTCAAGCGGAGCGGAGGTCTGGGAGGCCCTGGGCCCGGGAGACCAGTCTTAGACTCTTGCCCCACTGGGTAT

CCCATCTAGGCCTCTTCTGGGGAGGGCGGCAGACTCAGCCGCTGTGTCAACGCTGTGTTGTCGAGACCAGCTCCCCACCCTCTCT

GGGCCCCAGGCTCCCCTCAGTAACTTGGGGCACTCGACCCGAGCATCCGCGAAAGCCCTCCCGGCTCTCAGCGTTGAGCATTGGG

ATTCTAGACTGCATTTCCGTCTCTCTGCTTGGGTTCACGCGCCTCTCCACACTTAGTTCACACGCACACACGCGCGCGTCCTCGC

AGCACACACTTGTCTGGTGCAGGTAAGGGAAGGTGGAGGCGGATCCTGGGGCCAAAGGTATTTAGAATCTTTCACCCTCAGCCGC

CTGGGATTGCTGTGAGAGACATGGAAACAGGCTGAGCCGAGGCCTTAGATGAGAGGATGGACTGGAGAGTAAAGAGGGAGGGTTG

CCCCTGCATCGAGTTTTTGGACCCTGATCCCACACCAGCTTCTCGGTCTCGTACCCGCCCTTCCGAAGAACTCCAGCAGAAAGGT

CCAGCGGTCCCCTGTGCTTGAGGCCTACAGAAGCTTGTACCCAACTAGGGCAGGCACCCGGGTCTTCCAGACCACAGGACAGGAC

AGGCCACGGCTGAGGAGGCCTCTCTCCTGCCTCCAGGATGAACTAAAGACCCAATCCGGGATCTTCGGCCTAGGGCTGCTCTCCC

AGACCTGGGGTCTGAGAAAGCCAAACCAGCCCTTTCCCCAAAGCTCTAGTTCTGCAGATTCTCAGCTCTGGCCCACTCGGAGGTG

TTCTTCACCACCTATCCACCTACTGTGGGGCCCGGCCCTGGGACCTTGAACTGGCAGGTCTCTGGTCCAGAGCTAGGTCACTGGC

TACCTGAGGTCTCTGAACCCCTCACTTTTCCGCTTCCCTGATTTTGGGGATTTGGGGACAGACACGGCAGAAAGCACTGGCGACG

AACTCAAAAACTCCCGAACGCAAGGGGCAGCGGTTCTCCCAACCCAGTCTAATGCACATTGGCCCAGGATGTCTCAGGCCTCACC

CCAGGACGTAGGGCTCTGAGGAGCTACTCCGGTCTCTCGCGGGCT

109
chr4:
GAGAAGGGATGTGGCGGGGGGCTCCTCCGGCCCTGGACTCCCTGGGTGGACTAGAAAAGGGCAAAGAAGTGGTCACATCTGTGGG

111752000-
CCAGACTGGTGCGCGATCTTTGGAGGCGCAGCAGCAAGGCCGCGCCAGGGCTGAGCCCAGACCGCCCACGAGGAGGCCCGCCAGG

111753000
CCCGGAGCAGCGGCGCGTGCGGGGGCGTGCCGAGCGCAGGCTCTAGGGCCCCTGCTTCGCCCCAGCTGGACCCCGCGGGCGGTCG

GTGCAGCTCGAGCGTGTGGGCTGCGATGCCCTGCCTGAGACTTCGGGCTAGGGATGCGGGCGGGAAGTGGGGGTGCGGCGGCAGC

TGCAGATTAGATTCCTTTTTTTTTTGGCCGGAGGGACGTGCAAACTTCTAGTGCCCGGGCCAAGAGGGCGACCCCGGAGGTGCGT

AGGTGGCCCTCCGGGTTCCCGCTTCTCCTAGTGCCTCTGAAAATACCGTCAGGGTAAAGGGAGACAGGCAGTAAGTCTTACCACC

ACCGCCCTTTCCCCATGTCATTGGCCAAAAACTGAACATTAAGATAAAGCAGCTGTTTCAGTCAATGGAAAGCGGTAGGGCGAGG

TTGTACCCAAAACCCGGTTTAGACGGCCAATGAAGTCCTAGGAAAAGCCGCCCCGGGGGCACGTTCAGGTGGAGCGGCTGCACCT

CGGGTCGTTCTAAGGGATGGGCTGCGTGGTACCCACGGAATTCATGGGTCCAAAAGGTCCTGGTCACCTGTCCAAACATCCATCC

CCTGGCGCATGGCGGTTGACAAGATGGCCCGGCCACCCAGAGGAAGGAGGATCCGGGACGGGGAACTTCGCGCCGGGAAGCTGTA

GCCCAGAGCTGCAGCTCAGCATTCGCAAGAGATTCATCTTTTTTTTCTCTCGTGTTCGGAGAAACAGATAAACAAGACACCGCCT

CATCAGATAAGAACGTCTCCTTCGATGTCACGGATTTCAAGAGGTAGCTGGAGAAACTGACGTCA

110
SFRP2
CAGGTCAGGCAGAACTTCTGCCCTTCCCGCTACTGGCACCCCAAGCAGGGATGCACTGGGATGCGTGGCAGGGGCGGGATCTCCT

GGGAGCGTCTCAGCCCAGCAGGGAGTGGGGAAGCAAGAGGGAAGGCTTACCTTCCTCGGTGGCTGGCAGGAGGTGGTCGCTGCTA

GCGAGGGGGATGCAAAGGTCGTTGTCCTGGGGGAAACGGTCGCACTCAAGCATGTCGGGCCAGGGGAAGCCGAAGGCGGACATGA

CCGGGGCGCAGCGGTCCTTCACCTGCACGCAGAGCGAGTGGCATGGCTGGATGGTCTCGTCTAGGTCATCGAGGCAGACGGGGGC

GAAGAGCGAGCACAGGAACTTCTTGGTGTCCGGGTGGCACTGCTTCATGACCAGCGGGATCCAAGCGCCGGCCTGCTCCAGCACC

TCCTTCATGGTCTCGTGGCCCAGCAGGTTGGGCAGCCGCATGTTCTGGTATTCGATGCCGTGGCACAGCTGCAGGTTGGCAGGGA

TGGGCTTGCAATTGCTGCGCTTGTAGGAGAAGTCGGGCTGGCCAAAGAGGAAGAGCCCGCGCGCCGAGCCCAGGCAGCAGTGCGA

GGCGAGGAAGAGCAGCAGCAGCGAGCCAGGGCCCTGCAGCATCGTGGGCGCGCGACCCCGAGGGGGCAGAGGGAGCGGAGCCGGG

GAAGGGCGAGGCGGCCGGAGTTCGAGCTTGTCCCGGGCCCGCTCTCTTCGCTGGGTGCGACTCGGGGCCCCGAAAAGCTGGCAGC

CGGCGGCTGGGGCGCGGAGAAGCGGGACACCGGGAGGACAGCGCGGGCGAGGCGCTGCAAGCCCGCGCGCAGCTCCGGGGGGCTC

CGACCCGGGGGAGCAGAATGAGCCGTTGCTGGGGCACAGCCAGAGTTTTCTTGGCCTTTTTTATGCAAATCTGGAGGGTGGGGGG

AGCAAGGGAGGAGCCAATGAAGGGTAATCCGAGGAGGGCTGGTCACTACTTTCTGGGTCTGGTTTTGCGTTGAGAATGCCCCTCA

CGCGCTTGCTGGAAGGGAATTCTGGCTGCGCCCCCTCCCCTAGATGCCGCCGCTCGCCCGCCCTAGGATTTCTTTAAACAACAAA

CAGAGAAGCCTGGCCGCTGCGCCCCCACAGTGAGCGAGCAGGGCGCGGGCTGCGGGAGTGGGGGGCACGCAGGGCACCCCGCGAG

CGGCCTCGCGACCAGGTACTGGCGGGAACGCGCCTAGCCCCGCGTGCCGCCGGGGCCCGGGCTTGTTTTGCCCCAGTCCGAAGTT

TCTGCTGGGTTGCCAGGCATGAGTG

111
chr4:
TGCGATCATTAAAATCAGTTCCTTCCCTCCTGTCCTGAGGGTAGGGGCGGGCAGATTTTATTACTTCTCTTTTCCTGATAGCAGA

174664300-
ACTGAGGCGGGGTTGTGGAGGAGCGACGGAGGACCACCTCTAACTTCCCTTCACTTCCTGGATTTGAAGCCTCAGGGCCACCGGC

174664800
CTCAGTCCTGTTACGGTGGCGGACTCGCGAGGTTTTCCAGCAGCTCATTCCGGGACGGCGGTGTCTAGTCCAGTCCAGGGTAACT

GGGCTCTCTGAGAGTCCGACCTCCATCGGTCTGGGAGCGAGTGGTTCGAGTTCAGATGCTGGGAACCGTCGCTTCTCCCCGGCCG

GGCTCGCTGTTTTCTCCTCCGCTCGCCGTCATCAAGCCCGGCTATGAGCAGGGCTTTAAATCCTCCCTCCCTCACCCGCAGGTTT

ACCGAGCAGCCCCGGAGCTCTCAGACATGCTGCGCTGCGGCGGCCAGAGGAGGGGTGGGGGCATTGCCCTCTGCA

112
chr4:
GGGCTTGGGCCGCAGGCTTCCCTGGACTTCCGCAGTCCCCCTTCTCCCCATTCCAGAACCTGCCGAGCCCCTGCTGCATCTGGGA

174676300-
CCCGCCTTCACCGTTTCCCAATCCCAGCGGTTAGCCCCTGCGCCCCCTTTTTGGTCTCCACTTTGCCGTTCGAAAATGCCTAGGT

174676800
TGGTGGATCGACCCTCCGCGGAGCAAAGACGGATGGCTGGCAGGAGCAGGTTCAGGAGCTGGGCCAAGGTATTCTCTGCTTCCGC

CTTTGTGTCCGCCCCCCCGCCCCCTGCTCCCCGCTTCCCGCCAGCATCTCTCCTTTTCTGCTCAGGAGTGTTTGGCCCGGCGGTC

CACCCCGGCTTCCCGAGATACGCTAGAGTTGCCCCCACGTCCTGTCCGCCGCGCCCCTACCCACCGGGTTGCCTTCGGGGCCCTT

CGGTGCTGTGTAGTCGGCGTGGCGCTGTGAGCTAGGCGAACAGGAACCCCCAGGCCCGCCACGTCTACGCTATTA

113
SORBS2
TTCTGGGGCCTGGATGGGTGCGAGCGGGACCCGGGGGAGTGGGAGTCGCCAGGCTCTGAGCAAGCAAGGGCTGCACCTGCACCTC

TGCCGGGCATGAAGAAAGGTAAGGAAGGAAGGAGCTCACCCGGGTGGGAGACAGAGCCGGGGCGCGCGAGCTTGGTGTGGGGGCG

CCACTCCGGGGCGGAGGGGAGGGGCTACCAGTGACTTCTCCGAGTCGGGAGCTAGAAAGAGGCTTCCGGCCAGGTTCCCTTGGAA

CAGGTGTCGGAGTTGTTGGGAGAGGGGGCTGCAAGAAAGAGGGGTGCAGAAACTGGTTCATTAGATGGAGGCTCTGGGCGGAACC

GCGAGGACACCCTGGCAGCGCGCTGTGCCTGCGTTAGGCCGGGAGGGGAGAGGCCTCCGGACGGCGAAGTGTCCCTAGGGACCCA

GACGCCTCGGGAGCGATCCGGGCCGCTGCGAAGCCCTGCCCACCAGGAGTGGATCCCCAGGATTCACCTCCCGGCTGCCTGCTCT

GAGCTGAGAAGGGGATCTGGTTCTTCACAATACCGTGGATGGCGGGGAAGGGGAGGGAGCCTGGGGTAAAATCCCATCTTGGTTT

CCTCG

114
chr5:
TGTCACAGAAACCCCAGCAGCGCAGCCACCGGACTGGGTTCTGGAGGCCGAGCCGCAGTCCGTGCGGCGGCGCTGGGAAGAGAAG

42986900-
GCGCCCCGGCAGCTCCCCTGCCACCGGCCCCGAGGAGCGGCTGGCTCCCCCAGCCCAGCGCCGCCGCCGCCCGGTAACTCCAGGC

42988200
GCAACTGGGCGCAACTGGGGCAGCTGCGACACCGAATCCCTCACATCTGCAACCTGGGTGCTGCGGCCACTGAGAAAATGGAGGC

GCAGACCAACGAGCGGTGCCGCGACCGAGAGACCTCGGCTGGCGAAATGGTGGTGCCGGGAGCCTGCGAGTGACGCCAGCCGGCG

GGGTTGTCAAGGACAACATTCGTTTTGACGCAGCCAATGGCGCCGTCACCAAGAAACCATCGACTCTGAGAAAAAAGAGAGGTTC

GGCCACCGAGAAACTCCGTACGACAAGTGCTGTGGCAGAAAAACCGCCTACTCCGCGCCACAGGCAAAACAGCCAATGGAAACCC

CAGGTGCTGCGACCGTGACACCGGCACTAGAGGGTCTCGGATGGAGAAAGCGGCGCACGGAGACCAGGAAACTATGTGTAGCACA

ACTAGCAGAAAACCGTCTGGTCGGCCATCCGGGAGAAAGCGCGGATCAGAAACAAGCGACTTCGATGCAGGGAACCGCGCAGCCA

CTGAAGAAAGTGACCCACGTGGCAGTGGTGCCAGCGAAACACTGCAGTTTGGACGGCAGCTGTGGGGATGCCACAGAGAAACATG

CACTGCCACTGAAGTACATCCAGCTCCGCGGAGCTAGTGTTCATATGATCAAGAAACCGCCAGTTGGGCTCTGCTAGAAACTTTT

AGTCCTCCCTTAACGGCTATCCTACCCACAACAGACAATGCCTTTACCCAGCACCTAGCGGTGCTGAGACCCGCCTGGGCCAGCA

CAGAGCGCAGAGCAGTACGGGTACGGAGAAACGCCGGACTCAGTGAAACCAGCCTTGCCTCCAGCGGATTCCCCGGCTTCGCCGG

ACGCCACAGGCAGAGTGCCGCGGGGAAACCTCTGGCTCCCTAAACCGATTAGATTGTGGGAGTGGGGGGGACACTCACAAGTTGT

GTGGAAGGGAACCAGCGGCAATGGGACCCGGCGAGCACTTGCCCGCAGCAAATGCCTGCGCTGCTGCAAAAAAAACAACTTTTGG

CGCAAAGAATGTTGCGGCCAGAGAGCATCCGCTGTCGCTGACAAAGGAGTAGCAATGGCAATGAGAAACCGCCGGCGCCACGGCC

GACCGCGGCGGCTCACGCCTATGAT

115
chr5:
CAAACGCTGAGAGACAAAAAGACACCAACACCCACCAGGACTGCGTCCTGCCAGCTCTTCACTCCGCTGACCTGACCTTCCACGC

72712000-
CCCTAGTCCTCGAGCGGACTTGACCTGTGGGGGAGTACCGAACCGTCCCCATGAGGCCCTCCAAGCGGCCAGGTGGCCTCCGCCA

72714100
CTCTCTCCACCCCCACCTCCTCCACCCCCCAGCCCATCGGTCCATCTTCGATCTGCAAAACACGCCGGGTCAGCGACGCATCGGT

CCCAGGCTTGTGACCACCTCTTTCTCTGTTACTTGGGGAGCCAGGCCCACCGCTCAGGATCACAGTGAGGAGAAAAAAGACACAA

ACGCCAGGACAGGGCGGCTGGGGAAGGAAACTGCTAGGGACCGCTCATTGTCAGCCTGGCGTGTCCCACGGATCGCAGGACCCGT

CGAGGCTTTGCTCTCTGCGACCCGAATACTCCTGGGCCTCTCGACCTCCTCCTCGGACTCAGGCGTCCGCGTCTCCGGTCATCAC

GGGAGACCAATTGGTTTACAAATAGTGATGATAAACCTGGGACCGACCTTGGGGCTGTGTAAAAGTCTACTGACAGATGTAATGG

AGGGTTGTTAGCAGTCACAAAGCCTGTCGGACCCGTAGCATTAGTTCAAGAGACTATTTTCGTGTCGCACCAAAATTACTGCGCG

TGTAAACCAATTTCCCCGACGGAAGAATAAACAGAGATTCGTTTGAAGCGCGAGATGAAAACAGATGGGGTATCGCAAACAGTTC

CCCAAAATACAACAGACTTCTGGGCCAATTACACGTGGTTAGCTCTGAATGGCAGAGGAAATAGTTTTCTTTGCTGCTAAATGTC

ACAAAAGTCACCTAAAGGCACAGAGGAGGCCGCTCTGTTTTTGCGAAACTTGCTAAAATTAATCTGCGCTGGGCCACTTGCAGAA

AGCAGAACCACCTCCCGCCCCCACCTCGCCTCCAGCCGCCGGGGTTCAGGCGTTTGTGAAAGACAGAACCTTTGGGCTAGGGACC

CGGGCACTGGTGCTTCGAAGTCCGAATCCGCCGGCCGAGAAAACGACAAGAGAAAGAAAATCCAGCGGGCGCTCTCTCCAGCGCC

AGGCCGGTGTAGGAGGGCGCTGGGGCTCGGCCTGCCACCCCTACCCGACATTGGGAAGCAGCCCCTGCGCTCCCGCGGCGCCTCA

GCCTCCGGTCCCCGCCCCGAGGTGCGCGTTCCTCCTCCCGCATGCCCGTCTCGGGCCCCACGGAGCAAGAAGATAGACGATGACG

AGGCGCGCCCATCCATCCGGGCCGACGAGGTCAGGCCCGCGCCACAGGCAAAAATTGCGCAAGCCCGGCCGCAGGGATTTCGCGG

GCGCCTGGGTCCCAGGTGCGCGGCCGAAATCCTCAGGGAAAATCCCGAGGGGCCAACGGTCTAGGCCACAGGGCTGCTGGGCCCG

GGCCTGGCTCAGAGCGCATTCGGGCGGGGAGGCCGCACGCCGCACCCGGGCCTCTCCTCCGAGCCCGAGGCAGGCACTGAGCTCC

GGGCCAGCCAGGTGCCTCCCGGCTGGTGCGAGACCCCGGGCCTGCTGGGAGGCGTGGGCAGGGCAGGGCAGGGCTGAACCCCAGC

GACTGAATCTCGAAGGCAGGAGGCCTCGGAGGTCATCGGCCCAGCTCGCCTGAAACTGTCCCTGCTCGTGCCAGGGCGCGGGCAG

AGGAGAAAGGACAGGGCGGAGCAAGCCCACTGCAGAACTGCGGTCGGTGGCTGCGAAGGGTCCGGGTCACCGCGCTCCCGGACGC

CGGAAGCCGCGCTGGCGGGGCCGCGGGGAGGGAGGCTGGGTACCGGGGCCGTCCGGCCGGAGGAAGCGGCTCCGGCCGCGCTGTC

CGCGCTTGGGAGCCGCGTGCAGGGTTCAGCCGTGTTTCAGTTGCCCTCTGACCTGACCCCGGGCGCACAAAGGCCTCCCGGGTGC

GCCGCCATGGCCCAGTCTTCCAGTCGCTGCCAAATTAATGAGCCCACGTCAGGTTGGGTTTACAGCTCGGCCGGGAAGCAGCCGA

GTGGAAAATGAGCTCGGGGCCGCTCCAGAGGCTCCCGCACAACTGCAGAGGCTGCCCGCG

116
chr5:
TTTCCAAGACAGAAGGAGGGAACTAGGCGCCTTTTTTCCACTCCGCTGACCCCAACGTCTGGGCTGTGCGTTGTAACGCAGTTGG

72767550-
CGGGGCCTTCAGCTTGGGATGAGGGCGAAGGGGCTCGGGATGGGTGGGAAAGCAAGGACCGGGCAACAGGTGGGGAGGTGGCGGA

72767800
CTTTTGTCTCGGGGAAGGAAATCGGCTGTGCTGAAAGGGCGGAAAGCAGTAGCGCACAGAACTAGTGTCTGCGGGGTCCC

117
NR2F1
CCCTCCTGTGGCTGCTTGGGCAGACGCCTGTGGCCTGTCGGATGCGGCCCACATCGAGAGCCTGCAGGAGAAGTCGCAGTGCGCA

CTGGAGGAGTACGTGAGGAGCCAGTACCCCAACCAGCCCAGCCGTTTTGGCAAACTGCTGCTGCGACTGCCCTCGCTGCGCACCG

TGTCCTCCTCCGTCATCGAGCAGCTCTTCTTCGTCCGTTTGGTAGGTAAAACCCCCATCGAAACTCTCATCCGCGATATG

118
PCDHG
TCCTCCTTTGTGTATGTCAACCCAGAGGATGGACGGATCTTTGCCCAGCGTACCTTTGACTATGAATTGCTGCAGATGCTGCAGA

A1
TTGTGGTGGGGGTTCGAGACTCCGGCTCTCCCCCATTGCATGCCAACACATCTCTGCATGTGTTTGTCCTAGACGAGAATGATAA

TGCCCCAGCTGTGCTGCACCCACGGCCAGACTGGGAACACTCAGCCCCCCAGCGTCTCCCTCGCTCTGCTCCTCCTGGCTCCTTG

GTCACCAAGGTGACAGCCGTGGATGCTGATGCAGGCCACAATGCGTGGCTCTCCTACTCACTGTTGCCACAGTCCACAGCCCCAG

GACTGTTCCTCGTGTCTACACACACTGGTGAGGTGCGCACAGCCCGGGCCTTACTGGAGGATGACTCTGACACCCAGCAGGTGGT

GGTCCTGGTGAGGGACAATGGTGACCCTTCACTCTCCTCCACAGCCACAGTGCTGCTGGTTCTGGAGGATGAGGACCCTGAGGAA

ATGCCCAAATCCAGTGACTTCCTCATACACCCTCCTGAGCGTTCAGACCTTACCCTTTACCTCATTGTGGCTCTAGCGACCGTCA

GTCTCTTATCCCTAGTCACCTTCACCTTTCTGTCAGCGAAGTGCCTTCAGGGAAACGCAGACGGGGACGGGGGTGGAGGGCAGTG

CTGCAGGCGCCAGGACTCACCCTCCCCGGACTTCTATAAGCAGTCCAGCCCCAACCTGCAGGTGAGCTCGGACGGCACGCTCAAG

TACATGGAGGTGACGCTGCGGCCCACAGACTCGCAGAGCCACTGCTACAGGACGTGCTTTTCACCGGCCTCGGACGGCAGTGACT

TCACTTTTCTAAGACCCCTCAGCGTTCAGCAGCCCACAGCTCTGGCGCTGGAGCCTGACGCCATCCGGTCCCGCTCTAATACGCT

GCGGGAGCGGAGCCAGGTGAGGGGCTCGGCGCCGCCCCGGGCGACCCCTGGGGGCGGCACTGGAGAAGCCGCCCGTCCTCATAAG

GGATTGAACTTGCATCCACTCCTCTCCGGCCGGCTTGGTCGCTGGCTGCGCTCCACCCGATTCTCGGGATCATTGGACCGTTTGC

GCGAAACCAGAGTGGCCGATTAAGGGATGGGGCTCCGAGCACCGGGGGTGGTGGCGACTGTGGGCGAGGGGAGGTGGGACCGACC

CCCACCCCTACACTCAAAAAAGGCCGGGGCCTCCTTCGAGCTTCCGGTGAATTTCGGGCGATTTCCGCGGGTGTCGGGGGTCCCG

GGAGGAGGCAGTCACAGATCCACCCCTGCAGCCAGCCTCCTAGGCGCCGGCTCCGGCACGCTTCGCCGGTCTGTAGATTTCCTCT

TCGATTTCTCCCCAGCTCCCAGCATCTGTGACTTCACTGTTACCCTCCCTATCCCCGCATCACCCAACCGCACCTGTCTGCGGGA

CTTAGGTGTGCGCGCGGGGCTCATGCGTGTCCTCCCTGCTGGCCACCCCCACGGCCCACACAAGTTGCACGGGCTCGCCACGCCC

CGCCAACACGTGCGCGGACGCACGCACGCACTCCTCGCACGTGGGCTTACGCGAATACCAGCTTTCACTGCCACTCGCTCGCGGC

CAGATTCACAGGCCTGTTCCGGTCCACTCGCAGCTCCCCTCTGCCGCTCCCTCCGCCGGGCTCAGGAGTACTCGTAGCTGATTGT

GCGCGCCTGAGGGTCCCAGATCGCGGCCGCCCAGGACCAGGCGAGGACTCCGGAGCCTCCTCTCACCTCTCCCACCTGCGCCCCG

GGCTGGGCCGGGTCGCCTGGGGGGCGGCCTGAGCGAGGCGCGGGGCCAGGAGCGCTGGAGCGACTGCCGCTCTAAGTGCCGGGCG

GGCAGGACTCTACGATCCTTGGGCCAGAGGTCCGGATGGTCCCGGGACTCCGTCTCAAGGGTCGGCGACCCCTCAACCCAGAAGC

CTCGAGCAGGCGGACAGGCAGAGCTGCCCAGTGGCCGAGGCGCGG

119
chr6:
ATTTGTCGTTGTGCCATTGCTGCCACTGTTGTTCTTGTCCAGGGAAACACCGGTGGCCAACCCAGATCGGATACAATGGTGCGGC

10489100-
TCTGGACTGAGCCTCCAACCACATTAGCCATGGGCAGCATTGTTGCTGCCGCTGCTGTTATTTTAATTATGATTGTACGTTAACC

10490200
ACCACCTTCCTTCCTCTGCCTCCCTTCAGCTGCAATGATGTATGTTACTTTTTGGTAACTGGATTTCATTAACATTTATGAACTC

TCATAAAGTAGTAGAAAAAGCAATTTGTGTGGAAGAATTTTCCACCTCATTAAACAGTGTTCTTTTGGGGGTCAAGCTGATATTT

TTTTTGTTGTTAGATTTTTTTTATAGGTCCTTTGTCCTTCCCTAAGCCCTGGGGGATGAAAGGAGAGCCGTCCACCCAGCGAGGG

GCTTGTGTGCCCTAGAGGGCGCTGGGCCCCGCGCGCTTTCCTGGCTGTCCCCGCCGGCTTTCCACCCTCCCCAAAGCCCAGGTGC

CCACCGTGGGTCGCTGCGGCCTTTCCCCTTCTTGGCCAAATCCGATTACTTCGCAGCCTGCAGATGGCATCGCCGGCTAAGGGCA

GCCTGCGGCAGGTCCCCGAGCCTGAGCACTCCTCCTATCTGGGGCCTGAGAGGACGCTCTGGGCTTTTTCCCAGGCCCAGGGTGC

GCGGCCTGCTAGCGCCTTTCGAGGCACAGTCCCAAGATAGGCTCTTGTCCTTCGACGCCCCCTTGGCACAAGCGCACTGGCGCCC

TCCGCTCAACCCACCTTGCCTTTGGGGCGGGCTTCAACCCTGGGAAGACAGGCCTGGGGGAAGCGAGAGGAGAGGCCCGAATAGA

GGTTCCGGCTCAATCTTTCCCAGACGGAGGCCTGGTGTTTCCAGCTCAGTTGCATCTTCCAGCCGCGGGCTCCTGGCCCAAACAG

AATGTGTTTGCTTTCACACCGGGACGGCAAGCGGAGTCCGCCTCAGTGAGCAGCGAGCTGCGCAGTCCGGACGGGTGTCGCCCCC

AGAGACTCGCCAGCCGCCCCCAGACACTCGCCAGCCGTCCCCATCTCTAATCCACCGTCCAGGCCCGGGCCCTGGGAAGA

120
FOXP4
CCGTGTCTCCCTTAAGAACTGGGGCCTCATCTCCACTCCAGCTGCGCGTGCACGTGTGCTCCCGGCAGGACGCGCGCCCAGGAGC

GCGCTGGGGGCTGCCCCGCCCCTCTCTCCCTCCCCCGCGGGTAAACTCCGGGCATCCATCAGTCTGTTAATTGCACTAATTAGAG

ATCGCAGAGGTGTTAATTGGAAAACCCTGGTATTGTGCCTGTTTGGGGGAAGAAAACGTCAATAAAAATTAATTGATGAGTTGGC

AGGGCGGGCGGTGCGGGTTCGCGGCGAGGCGCAGGGTGTCATGGCAAATGTTACGGCTCAGATTAAGCGATTGTTAATTAAAAAG

CGACGGTAATTAATACTCGCTACGCCATATGGGCCCGTGAAAAGGCACAAAAGGTTTCTCCGCATGTGGGGTTCCCCTTCTCTTT

TCTCCTTCCACAAAAGCACCCCAGCCCGTGGGTCCCCCCTTTGGCCCCAAGGTAGGTGGAACTCGTCACTTCCGGCCAGGGAGGG

GATGGGGCGGTCTCCGGCGAGTTCCAAGGGCGTCCCTCGTTGCGCACTCGCCCGCCCAGGTTCTTTGAAGAGCCAGGAGCCTCCG

GGGAAGTGGGAGCCCCCAGCGGCCCGCAGACTGCCTCAGAGCGGAAGAGGCAGCCGCGGCTTTGACCCAGCTTCCTTCCGACGGC

ATCTGCAGGAGCCTCTAGGCCTGACATAGGCTCCGAGGTGCCCTGGCTCCCCCACGGGGAATGCTGAGGGTTGGGCCACTAGGTC

CTGCCTAAGTGCAGGACCTGAGCCTCAGACAAATC

121
chr7:
GGGATTGCCGGCTTTGAGAAAATATGAAGAAACCGATTTCTCCTTCCACTTTGCCAGTGCACTTTCCTTCCACTTTCACTGGTGC

19118400-
TGGGGGCGGCGCACTCTTTACGACATATAAGCGGAAAATTCTGCAAAAGTGGCCCCCGGGGATCCCCGCCCGACCCCTGTCTGTC

19118700
GCTAATGTGGGCCTGTCTCCGGAAATTCGAGGTTGGGCCTTTGCCTGAATCTGTTGCTATTGCTCCCCTTGCTACCGCTGACACT

TGGCACCGCCGCCTCCTAGCAGCGGCCAGACGCGGGGCTGGGGGC

122
chr7:
GTTGCGAGCGCGGCACAGGTTGCTGGTAGCTTCTGGACTCTGGAGGCTTGGCCTTCCTTCTAAGCCGATGGCGGGGAAAGAACCT

27258000-
CGTTTCCACAGCTTCCCCGACCCCCGCCGCTTGCCATTTGGGGACGGGAAGCGCGCCCGGGTCGCTTCACGTCCCTCTGGGCCGG

27258400
AGCCCTTTCCATGGCTGGCTCCTCTGGGGGCCCTTGGGCCTGTGAGCAGCGTCTACTTCCCTCAGAGAAGAATCCTTTCCTTCCC

CCATCGAAGTGTCCCTTTCTGTATCCTGAAATAACCCCTCCTGGGTGAGGCCAGTTCCCCTCTGTCGCCCTCCTCCCGCAGGCGT

CCGGGAGCCTCGTGAGGACCCCGTGCAGTTGAGTCCAGGCGACAGGTGCCTCCCCAGGTG

123
TBX20
CAGTGCGCCCCTTACCGGAGCACCCATGGCCTCCCGCGTTACCCCAAATTTTGTAGGCAGACTGTCAGAGTTCGAAGCCAGCTGT

GTCCTCTGCGGGCCGTGTGACCCTAGGCTATCTGGGCTGCTCGGAGCCTTAGTTTCCCTAGTTGTGAAGAGGGAGGGTGTGACCA

TGGCCCGGAGCTCTCCGAAAGGCTGTGCGGATTGCTCGGTGGCGGGATGTGGAGCGCGTCTTCTATGATGCCAGGTGCTGGCCAA

GCGCTCGATGCAGGCTGCTCCAGTTAGGTCGATGCGATGGCGGGAAGCACTTTCCTCTGCAATGGAGAGACGCCGACACCCCGAG

CCCGAAGGCTTGCAAGGCGCGCTCTCGCCACTGGGGTCGGGGATCCGTGGGTTCTCTATCCCGCTTACCCACTCCATCCTTAGCA

GCTGTCGTCGGTCCCAGACCTCTACCTTGGAGAGACCAAGGCGGCCCAGAGCCCAGGAGACTACTGCGCGGTACGCCAGGATCCA

GAAGTGGATTCTGACTTCTAAAGACCCCTCCCAAGCCAACGCTATCAGGGTCCCTGCAAGCGGTTGACTGTGGCGGAGGCAGAAC

CAAAACCTTTGCTCTGCCCGCGGCGCTCCAGCCTCTCACCCAGGACAGTGCTCTGGGCTCCAGCCGCTGCAGTGGGGTCGGGACA

CAGACGCCGAGTTAGAAGCCCCGCCGCTGCAGGTCCCTGCTTGGTCGGCGCGGTGACGGTGTCGCTGGCGGCGGCGGGGGCCTTC

CTTTGGCTGCCCGGCCATTTAATCAGAGCTATTAT

124
AGBL3
TTTAGTATTTAAGGAGAAAAGCCTCATTTTCCAGAATCGAATAAGCGAATTAATCGCACAATTGTGTAGAATGGAACTCAGTCTG

TAAAAAATCAAGACCAACGTACTTTTTAATATTCTAACATCTCCAAGTAGTAGTTACAAGTATTGTACCCATGAAGTCCAGGTAA

TTAATTTGTTCAATGTCACACTGTTAAAAGTCAGGTGGGCTCCAAAGCACAGTCCTAACCAGCATGCTCTACTGCCTCCTCTGAG

GCAACAGCCGAAGTGCAGACCACTGGGAATAAATAGCTGCCCGGTCTTCCCCACTCCTAAATTCTCCCGACAGACCCCAAAGCCT

CTCTGAGAGCCTCTCTGACCGCCCTGCGGCCCACCCCGAGTTCCCGGCATCCTCTGGGATCCCTCTTCCTGGAGCCAAAACCTAC

GCAGGCTCCTTTCCTCCGAGCTGGTTGCTAGGTGATCTCCGAAGGCTGTCCGAAGTCTCGCGAGGGCGGACCCGTTGCCTGATGA

CGAGAGTTGGGAGTGTGGCTGGGGCTGCGGATCTCCAGCAGTGGCGTTACTTCTAGCGGCTGGATACCGGGTTCTCCGCGAGATC

GCGAGATCCCGAGATATTCTCCCCGCACGGAAGCGACGACTGGCCTGGCCAGAGGACTCGCGTGGGAGCGAGGTGCCGGCCCCGA

CAGGACGGTGAGGTATGCAGAAGTAAGGCGGGGCGCCCCCTGCGGGAAGCGAGCGCGCCCCGGAAAATGAGCGCCTCCCCACACC

AAGGTGTCCAGGAGTGAGTGCGGGAAGGAACTCGGCCGCCCGGAGTTGTGGCCTCATCGTGCTTCCCGCCAAAAACGCCTTGGTA

CTGTCGGGACGCGGCTAAGCGTGGACGCGCCCGCATCTGCCCCTCCTCCGCAGTGGTGGAAGACACCCGCGGAGCGCCGGTGGAT

AAGGGCCGTTTCCTGAGACCAGAGCTGTATCCGCAGCAGGTCAGCACTTCGTGCGCCCTGTGTGC

125
XPO7
AGCGGCGCTGTTCCCGGGCTGGGTGCAGCTGCTAAGGACAAGGCCCCTGCTCCGAAGAACGCGGTGGCTCGGGGATACCCTGAAA

GGGACGGCCATGGCGCACATGGGATGCCCTAGGGTTCGTGGGAGGGCATGCAGGCGCAGCCCCCGCAGGGGTTGGCCTGCCAGAG

AAGGCAGGGGAGAGCACTCGGGGCTGCACAAATGGTGTGGCCGGAGGGAAGGTGCAGCCTTGTGTGTGTCTGGATGAGGGCTGGG

CATAGGAGCTTGGTATTTGATCCTGAAAGCTCTGCGTTTCCAAAG

126
chr8:
GAGTCATACTTGTAGTCACATCCTTTTCCTTTCTCCAACCCACTGGTTAATCATGAAAGGCTCTTCTGATTGGCTGCCTCCTGGC

41543400-
AGTAGTGCCTCAGCGCGACGGTTCGGGAGCAAATAAATAATTCCCGCTGGGAAGCTGTTTCTCAGACAGGAGCAGCGACACCCCT

41544000
GCCACGCCTGCCGCCTGGAGTTGAGTGGGGTAAGCACGCCGGCCTCCAGGAATCGACGGTGCCACGTGGTTCTTCTTGCACTTCT

CTTCTTCTCCAGTTTCAGGGGACACCGTGGGGTGTGCGAGCCCGGGGGAGCGCAGGGAAGGGCGGGTTGGGCTGCAGGTGGGAAT

GTGCGGTCCTTCTGCGCCCTCAACAGAGCTTCCTTCCTTTTTGCCAAGGTCCCCGTGCCGCCTTCAGCGCGCCTCCTTATGCACC

TCTACCTCTGCTGCAGCGTACCTCTTCCGCAGCCCTAGCGGCCTCCCCGAGGGGCGCCGCGGCCTCGGCTGTCCCTCCCCTGCCT

GGCACGACCACCTGACCCCCAGCGACCCAAGAAGCAAGTTGTGTTTGCAGACGCAAAGGGGCTGTCGTTGGTATCGGTGCACTGG

TTTGA

127
GDF6
ACACTTTCTGTGTGGGAGGGCACAAGACATGGGCTATGACATGGCCAGAGACCCCACCTTCTTTACACATGTAAAAACCAACCAA

ATCAAGATGCGTCAACGGTGATTCTTCCTCCCACATTGTTTCCCTTTTTAAACTGTTATTTTTTCAATCCATGGAGCAGTTGAGA

AACGGGTATGCATCTCTCCTCCCCTCCCCTTCTATCAAAGCCTGTAAGACACATAAGGAAATCCAAAGCCACAGTAATAGAGAGA

GAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAAAACAGAACAAAAGAAATCCTCCTTGGCTTGTTTTTCCAGGGTGG

CCAGGCAAGGTGTGAAAATCCATATTTCCCTCTGGGCTGGCAGGTAGAAGTTACTGGGAAGGCTGCGCTCCCTTCTCTCCCACCG

GCTCTCACATCCAGGCTGTTCCCTCACCCTCAGCCTCCCCCAGCGCCAGCTTCCTCCTCCGCCTCTCTGCAGCCAGGCCTCCCCT

GCAAGGCGGACCTTGGCCCACCTTGGTTCCGGGCCAAGGCGGCGGGAAAGGCACCGCTACCTGCAGCCGCACGACTCCACCACCA

TGTCCTCGTACTGCTTGTAGACCACATTATTGCCCGCGTCGATGTATAGAATGCTGATGGGAGTCAATTTGGTGGGCACGCAGCA

GCTGGGCGGGGTGGAGCCGGGGTCCATGGAGTTCATCAGCGTCTGGATGATGGCGTGGTTGGTGGGCTCCAGGTGCGAGCGCAGC

GGGAAGTCGCATACACCCTCGCAGTGATAGGCCTCGTACTCCAGGGGCGCGATAATCCAGTCGTCCCAGCCCAGCTCCTTGAAGT

TCACGTGCAGGGGCTTCTTGCTGCAGCGTAGCCTGGACTTCTTGCCGTGCCGCTTGCCATGGCGACTGGCGAAGGCCGTGCGCCG

CCGCCGGCGGCCGGGCGAGGGCAGCCAAGGCCTGGCATCCGGGGCGCCCGACGGCGGCGGCCACGACCCCTCGGCGCCCGCGCCC

GGGCCCGCAGCCTCGGCCGAGCCCAGCTGCTCGCGCATCTCTGCGAACAGGTTCTTGCGCTGGGATCTGGTGAATACCACCAGCA

GGGCCCGCTCCTGGGGAGGCCGCACCCTCCGGCCGAAGCCCAGACTCCGCAGGTCCGGGGGCGGCGGTTGCTGGGGTCCCCGCGC

GCGCGCCTCGGCCTCCCCGGCGTCCAGCTCGCCCCATGCGGCCCGCAGCTCCAAGCACAGCTGCTTCCAGGGCTGGTGGCGCAGG

CCCTGCCACACGTCGAAGACTTCCCAGCCGGCCGGCGGCGCCCCCTGCGGGTCCAGGGTCCGCGCGTCCAGCAGTAGGGGCGAAA

GGCAAGGGAAGAGCTGCACGTGGAGCGGCCCGGCTGGTGGCCCCCAGGGCGCTGAGGGCGCCTGGCGAAAGAGCCGCAGCTCCGC

GCCCACCAGCTCTTCTTTGTCTGAGAGCATGGACACATCAAACAAATACTTCTGTCTCCGGAGAGGAGTGTGCGAGAGATCGTCT

GCGAGATAAAAAATAATTACAGTCAGTTTCACTTAAGGGGGAGATCAGCCCGGTGCTCTTCGGCCGCCCCGGGAGGAAAAGGGCG

GGGAGTGGGGGCAGGTCGGCCGGGCAGTCCAGCTTGCCCGGCCCAGGGCCTGACCACCCCGGCTCCCCATCTGGCTGGTGCATGG

128
OSR2
GCCCGCTGTGAATGTAGGTGAGGTGATCCCGGGAACCTGGGTCTGAAATCAGACCTGTGTTGCCATTGGGAGCACGGAGAGAGGG

GAAGCGCCCTGCTTAGGCCCAGGCCGGGCGTCCTGGTGGTGGGACCGCAGCCGCACTCACCTCCAGGCCAACGGACAAGGTTCCT

GCAAGCCAGCAGGGCCACTCTGTGCTTGGCCTACTGCAGCTCCCCTGCAGCTCCTTTCCTCTCCCTCCCCGGAGCGCTCTCCTCT

CTCCTCTCCCCTCTCTTCTCTCTCCTCTCTCGTCTCCTGGGGCATCCCGGGTGGAGGGATGTAGGGGTCGCTCCTCGGTGCCAGG

CCGGGAAGCAGCTCAGGCCTCCCAAGAGCTTGGCGCTCAGTCTGGGAAAAGGGGTTCCTCTGGCCTCAGGGACGTTCTCCGCCCC

CACCCCACCCCCTGGGAGCCTGAACCATCTGGAAGGGATCTTAGTCGGGGGTTGGGAGGAGAGCCCGTGGATAGGAGGAGGGGGC

GATTCTAGGCCGAATCCAGCCCCTGAGGTGTCACTTTTCTTTCCTGCGGCCCGTCACCGCTGATAGATGGGGCTGAGGGCAGAGG

AAGGAAAAAGAAAACCTCCGAGGTCAGTGCGGGGCGAGGTGAGCCCCTCCCAGGGCCCTCTGGCCCAGGAGGATGAAGCGCGCCG

GCTTCGCTCTTGCACGCCGGCTTGCCATCCGGGTAAGCGCGGGAAAGGCGGCCACAGGGCGCGGCGGCAGCGCAGCGCGTGGGAT

CTCACGACCCATCCGTTAACCCACCGTTCCCAGGAGCTCCGAGGCGCAGCGGCGACAGAGGTTCGCCCCGGCCTGCTAGCATTGG

CATTGCGGTTGACTGAGCTTCGCCTAACAGGCTTGGGGAGGGTGGGCTGGGCTGGGCTGGGCTGGGCTGGGTGCTGCCCGGCTGT

CCGCCTTTCGTTTTCCTGGGACCGAGGAGTCTTCCGCTCCGTATCTGCCTAGAGTCTGAATCCGACTTTCTTTCCTTTGGGCACG

CGCTCGCCAGTGGAGCACTTCTTGTTCTGGCCCCGGGCTGATCTGCACGCGGACTTGAGCAGGTGCCAAGGTGCCACGCAGTCCC

CTCACGGCTTTCGGGGGGTCTTGGAGTCGGGTGGGGAGGGAGACTTAGGTGTGGTAACCTGCGCAGGTGCCAAAGGGCAGAAGGA

GCAGCCTTGGATTATAGTCACGGTCTCTCCCTCTCTTCCCTGCCATTTTTAGGGCTTTCTCTACGTGCTGTTGTCTCACTGGGTT

TTTGTCGGAGCCCCACGCCCTCCGGCCTCTGATTCCTGGAAGAAAGGGTTGGTCCCCTCAGCACCCCCAGCATCCCGGAAAATGG

GGAGCAAGGCTCTGCCAGCGCCCATCCCGCTCCACCCGTCGCTGCAGCTCACCAATTACTCCTTCCTGCAGGCCGTGAACACCTT

CCCGGCCACGGTGGACCACCTGCAGGGCCTGTACGGTCTCAGCGCGGTACAGACCATGCACATGAACCACTGGACGCTGGGGTAT

CCCAATGTGCACGAGATCACCCGCTCCACCATCACGGAGATGGCGGCGGCGCAGGGCCTCGTGGACGCGCGCTTCCCCTTCCCGG

CCCTGCCTTTTACCACCCACCTATTCCACCCCAAGCAGGGGGCCATTGCCCACGTCCTCCCAGCCCTGCACAAGGACCGGCCCCG

TTTTGACTTTGCCAATTTGGCGGTGGCTGCCACGCAAGAGGATCCGCCTAAGATGGGAGACCTGAGCAAGCTGAGCCCAGGACTG

GGTAGCCCCATCTCGGGCCTCAGTAAATTGACTCCGGACAGAAAGCCCTCTCGAGGAAGGTTGCCCTCCAAAACGAAAAAAGAGT

TTATCTGCAAGTTTTGCGGCAGACACTTTACCAAATCCTACAATTTGCTCATCCATGAGAGGACCCACACGGACGAGAGGCCGTA

CACGTGTGACATCTGCCACAAGGCCTTCCGGAGGCAAGATCACCT

129
GLIS3
CACTCCCCCGCCGCCTCCGCCCCTAACCCTCGGCCCCGTGCGCGAGCGAGCGAGGGAGCGAACGCAGCGCAACAAAACAAACTAG

TGCCGGCTTCCTGTTGTGCAACTCGCTCCTGAGTGAGTCGGGGGCCGAAAGGGTGCTGCGGCTGGGAAGCCCGGGCGCCGGGGAC

CTGCGCGCGCTGCCCGGCCTGGCCGGAGCCTGTAGCCCGGGGGCGCCACGGCCGGGCTCGCAGTCCCCCCACGCCGGCCCCCCGG

TCCCCGCCGAGCCAGTGTCCTCACCCTGTGGTTTCCTTTCGCTTCTCGCCTCCCAAACACCTCCAGCAAGTCGGAGGGCGCGAAC

GCGGAGCCAGAAACCCTTCCCCAAAGTTTCTCCCGCCAGGTACCTAATTGAATCATCCATAGGATGACAAATCAGCCAGGGCCAA

GATTTCCAGACACTTGAGTGACTTCCCGGTCCCCGAGGTGACTTGTCAGCTCCAGTGAGTAACTTGGAACTGTCGCTCGGGGCAA

GGTGTGTGTCTAGGAGAGAGCCGGCGGCTCACTCACGCTTTCCAGAGAGCGACCCGGGCCGACTTCAAAATACACACAGGGTCAT

TTATAGGGACTGGAGCCGCGCGCAGGACAACGTCTCCGAGACTGAGACATTTTCCAAACAGTGCTGACATTTTGTCGGGCCCCAT

AAAAAATGTAAACGCGAGGTGACGAACCCGGCGGGGAGGGTTCGTGTCTGGCTGTGTCTGCGTCCTGGCGGCGTGGGAGGTTATA

GTTCCAGACCTGGCGGCTGCGGATCGCCGGGCCGGTACCCGCGAGGAGTGTAGGTACCCTCAGCCCGACCACCTCCCGCAATCAT

GGGGACACCGGCTTGGATGAGACACAGGCGTGGAAAACAGCCTTCGTGAAACTCCACAAACACGTGGAACTTGAAAAGACAACTA

CAGCCCCGCGTGTGCGCGAGAGACCTCACGTCACCCCATCAGTTCCCACTTCGCCAAAGTTTCCCTTCAGTGGGGACTCCAGAGT

GGTGCGCCCCATGCCCGTGCGTCCTGTAACGTGCCCTGATTGTGTACCCCTCTGCCCGCTCTACTTGAAATGAAAACACAAAAAC

TGTTCCGAATTAGCGCAACTTTAAAGCCCCGTTATCTGTCTTCTACACTGGGCGCTCTTAGGCCACTGACAGAAACATGGTTTGA

ACCCTAATTGTTGCTATCAGTCTCAGTCAGCGCAGGTCTCTCAGTGACCTGTGACGCCGGGAGTTGAGGTGCGCGTATCCTTAAA

CCCGCGCGAACGCCACCGGCTCAGCGTAGAAAACTATTTGTAATCCCTAGTTTGCGTCTCTGAGCTTTAACTCCCCCACACTCTC

AAGCGCCCGGTTTCTCCTCGTCTCTCGCCTGCGAGCAAAGTTCCTATGGCATCCACTTACCAGGTAACCGGGATTTCCACAACAA

AGCCCGGCGTGCGGGTCCCTTCCCCCGGCCGGCCAGCGCGAGTGACAGCGGGCGGCCGGCGCTGGCGAGGAGTAACTTGGGGCTC

CAGCCCTTCAGAGCGCTCCGCGGGCTGTGCCTCCTTCGGAAATGAAAACCCCCATCCAAACGGGGGGACGGAGCGCGGAAACCCG

GCCCAAGTGCCGTGTGTGCGCGCGCGTCTGCGAGGGCAGCGGCGGCAGGGGGAGGAGGAGGCAGAGGCGGGGTGGCTGGACCCTC

GGCATCAGCTCATTCTCCCCTGCTACACACATACACACACAAATAATGTTTCTAAAAAGTTCAGTTGCGACTTTGTGCCTCGCCT

GTCCTGTTCATCCTCGTCCTGGGCCGGGGAATGCTTCTGGGGGCCGACCCCGGGATGCTGGCTAATTGCTGCCGGCGGGTTCCGT

CGCCGGTGTGACCCTGGACGGCGCGGACGGCGTACAGGGGGTCCCGGGAGGGGCAGTGGCCGCGGCACTCGCCGCCGGTGCCCGT

GCGCGCCGCGCTCTGGGCTGCCCGGGCGGCGCAGTGTGGACGCGG

130
NOTCH
CTGAAAAGCCGTCAGGGAAACCACACATGTTCAACCCCTGGCGGCTCCCCCAAACCTCTCATTTCCAGTAACTGTGTGTTTCCGC

1
TCGTCAACAGCTGAAACCGAGCGGAACTTGGGGGGCCCCACCACGCGGCCCTGCTGTGCGGCACGGGGCTCATCTGTCCCCCGGC

TGCGGGGAGTCAGCTCTCACCGCCCACCTCCTTCCCAGATAGTCTCTGTGCCCACTCGACGGCCCGGCAAGCCCAGCCCCTGCCT

GCCACGGCCACAGCAGCCTCAGAGAGCTGCCCTCTCTGGCCAGGGTCAGGGCCTGAGCTGCTGCCTCCCGCAGGGTCGAGGGCAG

GACACTTGTCTGAGGCTTGGGTGGGGCAATGGCACCTCCTCAGGGCCTCAGCCCCCGGGCAGGCTCGGTGACCATGGGCCTACAG

CAGGGAAAATTCTGGGCCAAAAGCTCCAGCCTCCTACTAGGGCATCTGTCTGCAAATGCACCTTAACCTGACCGCTTGGGCTGTG

GGGGAGCCTGTTTCAGGGAAAGTGAGGGACGCGCCAGTTTCCTCCTTTGGACTTGATGAGGCACGAACGCATCTCTAATAAAGCC

AGGTCTCCCCGCCGTGGCTCCCTGGGCGGGTGCCTGTGGCTCGGGCCATGAGTCACGCTGGGTAACCCCACTACGGGGAAGAGGG

CAGGAAGCTGGGAGCCACCGCCTCTGTGCCCGGTTGTCATCTCGGCACGAGGGCGACCGTCGGCTTCGTCCTGCCCTCATGGCTG

AGGGCTTTTGGGATGTGGCGGGAGACGGGGGAGTC

131
EGFL7
AAATCATCAGAATGGCTAAAATGAAAAAGACAGACAACAGCAAGTGCTGACAAGGGTGTGGGGCGGCCAAATGCTCCTGCACTGC

TGGCAGGGGACCTGAGAACTGCAGGGCATTCCCTGGCTTCCTGCCCCTCCTGGGACTGGGGACCCCCCAGGGACAGCCTAAGGGA

ACTGCATTTATCTTCACGTCTGCCAAAAGATAACACGAAGATGTTCAAAGCTAAGCCCCCAGGCTGGTAAGAGCTCCAAGGCACC

AGCAGTGTGTGCAGAACTGGGGGGAGTCTGTTCTCCCAGGGATGCTCCCATCACCTGCTGCCAGCAGTGGGGCATGCCGGTCCCC

TGGGGTGTGGCCAAGGGGCTGTGTCTCCTGCCCGGGCTGCCGGCCCCTCTCAGGTTCACTTTCCCATCTCTAAGCCCACGTCTCG

CTGCAGTTCAAGTTTGCCAGGCCACCAACGGGTGACACGCCCGGCGCAGTGGGGGACTCCGCACTTTCTGCGCAC

132
CELF2
ACCCTTTGTGCCTGGGTCCCATAAACAATGTGCTTTTTAAAGGGGAGCCCCCTCCCAGCTCCGGCCTTTTTCTCCAGCGTGGGCA

GCCAATCAGCTGCGCAGAGCTGCATAGCTGGACCGCTTTCCATTCTGAGTAGCAACAACGTACTAATTTGATGCACACATGGATG

CCTCGCGCACTCTGCAAATTCATCACCCGCATCTTGCATTAGTCATCTGACGGACTGCCAAGTGTTTCATTTTCTTTCCATGTGA

CTTTATTATTACCACCTCTCTCCTCTCTTCCAAAAACCTCCCAAAAAGGGCGGTGGGGCGGGGGGCGGGGCAGGGAGAGGGAGAG

AAATCCAGCAGACATCTAGCTCTGCCTTTCTTTCCCAGCCACAGCCAGGGTAGGGCTGATAAGGCGCTGATGCGTTGATGGCAGC

CTTGCAGAGCTAGACCTGCACTTAACTTGCAGCTGCCTCCCGAGCCTCCAAGATGTCCACGCCCTGGGTGACAGGCGGCAGGGCG

CTGCCCCGTGCTCCCCCGGCTCTGCTCGACAGCAGCACGCAGTGAGAGCCTCGCCGCCGCCGAGGAGCAACTCATGGTGCCTCCG

CTTTGTTTTAGTTCATCAAATTTCTACGACTCATTAGGCACTTTGCCACTGCTCTTCTTCCTCCTCCTTCCGCCTCCCCGCTCCC

CCACCCCCACTATTTTTTCTTCCTGTCCCTCATCGTGCCGCCCTAACTCTGGCTCCCGGTTCCGTTTTTGACAGTAACGGCACAG

CCAACAAGATGAACGGAGCTTTGGATCACTCAGACCAACCAGACCCAGATGCCATTAAGATGTTTGTCGGACAGATCCCCCGGTC

ATGGTCGGAAAAGGAGCTGAAAGAACTTTTTGAGCCTTACGGAGCCGTCTACCAGATCAACGTCCTCCGGGACCGGAGTCAGAAC

CCTCCGCAGAGTAAAGGTACAGAGCGCGGGGCGGGGGTCGCCAGGCGTCCAGGTGGGCGTCGCGGGGCACTGGGGCTGTCCGAGC

CCCCAGCCTGCAGGAGGAAGGGCGGGTAGGCAGGAGGGCTGGAAGCAGCCGGTGCTGGCGGCCCCTGTGCTCCAGGGGCTGCTCC

CGACTCCTCCCCGCACCCCCGCCCGCCTGCCCGCCGGGACAGGTTGGAGGCGGGAGAGAGGGACCGAGGCAGGGCGGGAGCGCAG

AGGCTCGGTC

133
HHEX
TAACAAATAAGCCGCCCGTGGTCCGCGCTGTGGGTGACCCTTGGCGCCTTCGAGGTCTGGAGCCCTAGGGTAAATAAGGAAACGG

GGCGCCTCTAGAGTTTTAAATGAACTCTGTTATTGGAAGCTTCAGTAGGGACCCTGAAAACAATTAACGTCTTAATTAGCATTTT

AATGTCTCCATTATTACGGCGCGGGCTCTAGCTCAGCCCTTTACCTTACCTTCTCACCGTTAACAGGGGAGGGGGATTGTATTTT

TAGTTCATCTTTTTATGTTTTTGAGTTGTTATCCTGTCTGTCTGATTCCAGCCTCGAGGGTTTGATGATGCGGCCCGAGCCTGGC

TGTGGTCGCCTGTCGGGGCTGGAGCGGGACCCTCAGCCGGGCCGGGCCTGGGGGCTAACGTTTTCACAGTGCGCCCTGAGTTTCC

TTGGGTTACTGCTGGGACCGCGCAGGAGGAAGCAAAGAGTTTTTCGAGCTAGACCAACAGGAAACACATTGACGGAAATGTTGCC

ATAGCCCATGGGGTGGCTTTAACTGGCCGCCCCCGCGGGCTGGGTGTGAAATCAGAGGAGGCCGCGGCTCCCCCGGCCAGGATTG

GAGGCTCCTCGCGCAACCTAATGCGGGTGTCCGGGCCCGAGCGCTTCCCGCGCAGCCAGGCCTTGTCGGTGCAGCAGCCCCGCTC

CTCCCCAACACGCACACACCCGGTGTTCGCAAGTGCGGCTCACCAAGGGAGATCCAAGGGGGCAAAAAGTTATGTATAAATCCGA

GAGCCACTGGGGAAAGAGGGTCGTGGTATTGTAAG

134
DOCK1/
CTACCCTGTGCTATCCTGAGCTGTAGTCTTCTGAAATGATCGTTTGGCTTCCCAGCCAAGGCAGGGCTCCCCCAAAGTTCATTCC

FAM19
CACTCTTGCAGTTTCACCTCGGGATGCTTCCGCAGAATTTCAGCGCCTAAGCAGACAAGGTCAAAGTAAACCGCTTCACCGCTGC

6A
TTCTGGCGCAGGGGCCCAGAGCGCGTGCAGCTCCCCAGCACAGACCAACAGCAGGAGAGGGGTCCGGGCGGGAGCCCTGGGCTGT

AGATAAGCAAAACGCACCCATTTTCTCTCCTATTTACTCCAGAGGCACCTCTCCTCCCCCACTCCTGGCATCTCTTTATCACTGG

CTCCCTCTCCCTGTGGCATATTTTTGGGTAGTAGAATGCTGAGGTCACAGGGAGCGGCTCTTTATCCAAGCAGTGGGGACATCAG

CCTGGAGCCCTGAGCATGAACCAGCAAGATGCAGACTCTCGCTCTTGACTTTGGGCTCCAGGAGCTGCCCCGACC

135
PAX6
CAGTGCTCCGCTCCGGGAAATTGCATCGTCACGACAAACGGGACCGTGATAAAACGACCCTTTCCGTCCTTATTTGTAGATCACT

CAGACGAGATTGAACTGCACTTGTTTCCCCTTCGAGGGGAGCCGCGTTTTCAGGGTAGCCGAAGGCTTGGGGCTGAGGGGGGGCC

CTCACCAAGGCGCGGGTGGGGGCCGGAGCCTCAACTCGATGAGAAGTGACAGGCGTTTGGGGGATCTGGGCTCCGGCCGGGACCA

GCGCAAGCAGGGACTTTGCGGGGACACCGCTTCTCCAACAGAGCAAGGCCTGGCCCACGTTTCCGGTTTCTCCTAACTTCCTTTT

ATTGCCTTCCTTTGCTTCGCAAGTTCCATCTACCCCTCCAGCTACAGAGCCCCACCTCTAGGCACAGGAAGCTTCCCGGAAAAAG

AAAGGCTGTCCCAGAAAGAGACCGAGAGAGACTTTCCAAACTTCGGGCATAGCCACGGCAATTCCCAGTCTGCTAATGCCAAGGC

GGGCGCGTAAGGCCGCCTAAATCTAGACCTCCCTCCTCACTCATTTCAAAAAATAACAACGTGCCAGCCACCTCCGCAGATACCG

CCGGCTGGTGCTTGCCCAGGAGACGCCAGGGCCAGAGCGCCACTCCCAGCATCGAAATGGCAGAGAGAAAGCGCAGCTCCAAATT

CCCCTTCAGAGGTTAAGCCTCAATCATTGTGTCCCTTCCCTAGGGACTGCTGGCGCTCTCGCCCACTGGCGATGATTATGCGCCT

AGAACTCGACCGCGAAGCAACTAATAGGAAAACATATGGTGTCAATTTGGATGCTCCGCGCCTCGCGCACACCCGGGAACGAGCG

GCACAAAGCCCTGCCGGCCGGCCCGCGACCCCGCGCCCCTCGGGGCCTGCCAGCCGGGCCGCAGCGACAAACGCTCAGGGCTGCG

CGCCCTGGCTGGGGCCCGCCCGAGAGACAGCCTGCGGCTGGGGAGTCTGAGCTCCAAGGGGAGAGCCCAGCCGCCGAAGGCGAGC

CTACCGGCCAAGCCCTGGGGTCCGGCAGGTTCTGCACAACTACTCCCGCAAAGCTCGCCACCTTTGTGCCCTTTCCTCAG

136
FERMT3
GGGCCCTCGCGGCTCAAGCGCCAGCGCTGGAGAGAGAGTCTGAGGGTACCACGGGCGTGCTGGCCTGGGTGCTCACTCCCGCCCT

CCTTCATGAGCGGCTTTCCTCTGGGTGTGTCCAGGGCATCACAGAGCTCTTCTGCCCAAACCCGGAGGCCTACCAGGGCCTGCCC

ACCTTGCCTCCTTCCACACTCTCTGTAGCAGCAGCCGCAGCCATGGCGGGGATGAAGACAGCCTCCGGGGACTACATCGACTCGT

CATGGGAGCTGCGGGTGTTTGTGGGAGAGGAGGACCCAGAGGCCGAGTCGGTCACCCTGCGGGTCACTGGGGAGTCGCACATCGG

CGGGGTGCTCCTGAAGATTGTGGAGCAGATCAGTGAGTGTCCGCTGCCCGCTTGCTGAACTCGGCACCATGGGCGGCCGCCACGG

GTGTCTCTGGGCACTTCCGGGCCATCCCTGCTGCTCAGCTCCCGATAATGGTGTCACGGTGACTCAGGCATTAGC

137
PKNOX2
TGTTTACGGAATCGGGATCGAGGGGCCGATAAGTAGTTTACACGCCGGCCAGAGCAGAGGGCTGGAGGTCGGAGTTGGGGGCTGG

AGGAACGGGTGGCGTTTTTAGGATTCAGTAACAGGATCACAGCTTTTTCTTGTGGTGGAAGCTATTGGAATTTGGGGAGGGTAGC

ACGAGGGGTCCTGCAGCTCCGCGTGTGAAAAAGCGTTTAGGTAGGCGATGAAAGTAGTTGATCTGAGCCATGGCAGGCGAGCCCC

GAATTTTTGCTGCTTCCCCCTGAAAGTGTTTCTTTAGGAGGAGAGGACTTGGGCCACACAGGACCCGGTCCTAAGAGAGCGATTC

CGGGAAGCGGACAGATCGAAGAGACCTTCTGGGCGAAGCGGCAGGGCAGCCTCGCGGGGCTGGGAGTGGATCTGAGGTCCCGACC

CAGGCGGCTCGGAGTGCTCCAGGAGCCACCTGGGTCTGCGGGCGCAGCGCGGCGGGGCGGGAGCGGTGGCCCGCAGGGGCCGCGG

CCTGCGATGAAGGCCGGGGGGCAGCGCTAGCAGCGAGGTGCCACAGTGGGCCGAGGAGTCTGGGCTGTGGCCCAGGGTAGGACCG

GCTCA

138
KIRREL3
ACCTAAACCAAGCTCTCCCTCCCTGCCGTCTCCTTCCCTGGCCTGGGTCTGAAGGAGAGGAGGTGCCCAGAAGTTCAGAGCGGCA

TAACCACAGAGATACTACCTAATTAACATACCAGAAGCATAAAGAACTCATTTGCATTGGAGAGT

139
BCAT1
ATAACTACGGGGGTGGGGGTGGGGAAGGAAGAGATCCAAGGAGGCAGAAGGCTGCGGTCAAAATATTTTGGGGTGGCAGAGTCAC

GTAGGATGTGGCTGTGGGTTCTGGCAGCCCAGAGATTCAGCTCCCGCCTCCTCCCTCAGAGCGAGTCCATAGCTACCCTCACGTC

CCCCGTGGCGGTCCTCGCCACGCTCCGGAGCGGGTTACCCATGAGGGTGCTAGACCTGGGCAGCGGGAACCTCGAAGAGGTGGAG

ATTGCAGGCTGGGACTCCAGATTTCGGGCAGGGATGCGGGGAAGGGAAGACGCCTCGCTGGAGGCGGAATGGAGGGCAAGGCGAA

GGAGGATGGTGCAGGAAACGGCGACAAGGCGCCCGGCCAGGCCCGCGAGCTACCGAGACCCGGGTTCCAATCCTCCCCCCTTCCG

CAAACGCCCGGGTTCGAGGTACCTGGCGGGCAAGGGCCGCAGCGGAGCGAAGCGGGCTGGCCATGGGGAGGCTGCGGGGACGCGG

GGCTGCAGAGAGCGGCAGTGGCACGGAGCGCGCGGCTGGAAGCGAAAGCAGGCGGTGTGGCCAAGCCCCGGCGCACGGCCCATAG

GGCGCTGGGTACCACGACCTGGGGCCGCGCGCCAGGGCCAGGCGCAGGGTACGACGCAACCCCTCCAGCATCCCTTGGGGAGGAG

CCTCCAACCGTCTCGTCCCAGTCTGTCTGCAGTCGCTAAAACCGAAGCGGTTGTCCCTGTCACCGGGGTCGCTTGCGGAGGCCCG

AGAATGCGCGCCACGAACGAGCGCCTTTCCAAGCGCAGATATTTCGCGAGCATCCTTGTTTATTAAACAACCTCTAGGTGAATGG

CCGGGAAGCGCCCCTCGGTCAAGGCTAAGGAAACCTCGGAGAAACTACAT

140
HOXC13
CAGTCCAGCCGCTTGCCTCACTTCTTCCCGCTTGCCTTATCTCCCCGCAGACGTGGTTCCCCTGCAGCCCGAGGTGAGCAGCTAC

CGGCGCGGGCGCAAGAAACGCGTGCCCTACACTAAGGTGCAGCTGAAGGAGCTAGAGAAGGAATACGCGGCTAGCAAGTTCATCA

CCAAAGAGAAGCGCCGGCGCATCTCCGCCACCACGAACCTCTCTGAGCGCCAGGTAACCATCTGGTTCCAGAACCGGCGGGTCAA

AGAGAAGAAGGTGGTCAGCAAATCGAAAGCGCCTCATCTCCACTCCACCTGACCACCCACCCGCTGCTTGCCCCATCTATTTATG

TCTCCGCTTTGTACCATAACCGAACCCACGGAAAGACGCTGCGCGGGTGCAGAAGAGTATTTAATGTTAAGGAAAGAGAAGAACC

GCGCCGCCCGGAGGCAGAGAGGCTCCATGGCCGTGCTGCTGGGCCATCCCCAACTCCCTATCCCATCCCCAGCCTCCACCCCCAT

CCAGATGGGACTCACGTGGCTTCAACAGCTTTGGAAATGGGTCCCGAGTGGGCCGTGCGAGGAAGGCTGTCGACCTCTACTCCTC

CTTGC

141
TBX5
CAAGATCGACTTTCTTAGGAAGGGGGAGAGGAGGGAACTCTTCACGAAGGGAGGTGGGAGTCCACCTCAGACCTCTATTGGAAGG

AAATCGAGTTGTTCCGGGGGACTGAGGTCTCTTGCATAAGGCATGGGATCCTTATTATTATTATTATTATTTTTAAATCCCCCGC

GGAGGAGCTCTGGGCAAATGAATACCGAGGCGCCGCTCTAGCTGGTTAGGCTTGGGATGCGATAACTCAGTGCCCTCTTGCAGAC

TTGCATAGAAATAATTACTGGGTTGTCGTGGAGGGGACACGAGACAGAGGGAGTTCTCCGTAATGTGCCTTGCGGAGAGAAAGGT

CCAAGAATGCAATTCGTCCCAGAGTGGCCCGGCAGGGGCGGGGTGCGAGTGGGTGGTGGAGTAGGGGTGGGAGTGGAGAGAGGTG

GTTTCTGTAGAGAATAATTATTGTACCAGGGCCCGCCGAGGCACGAGGCACTCTATTTTGTTTTGTAATCACGACGACTATTATT

TTTAGTCTGATCAATGGGCACAATTTCTAAGCAGCGCAGTGGTGGATGCTCGCAAACTTTTGCGCACCGCTGGAAACCCACTAGG

TTGAGTTGCAAAACGTACCGCGTAGACGCCCCTGGTGGCGCCGAGAGAAGAGCTAGGCCTGCCCAGCACAGAGCCGGAGAGCGTC

GGGCCTTCCGGAAGGGTAAGTTCTCCGCCAAGGGGTCCCGAGGGAGCTGGACGTCTGAATCTGGACTTGCCCCCAGCTTCGGGGT

TCGATTCTGGGTTTTGCGCGTCCCCAACCCCCAGGGCTTTCCGAAGCATGGCCTGGCTCCAGGCCCGGTCCTGTAAGGACTGGAA

CGGCAGCAAAATGTGCAGGGAGGCAGTCGGCCGGCAGAGCTGCGGCGGGAGCCAAGGTCAGGCCCGCGGGGAGAGCGGGCAGCTT

CCAGCGCCGGCCACAAGCTCCCAGGCCAGCTGGGCCGCAGACCCCTTTGCTTCCAGAGAGCACAACCCGCGTCCTTTCTCTCAGC

CAGGCTGCAGTGGCTGCCCCGAGCTTCGCTTTCGTTTCCCAAGCTGTTAATAACGATATGTCCCCAAATCCGAGGCTCGTGTTTG

CTCCCAGATGCCAAGAACGCAACCCGAAATCCTTCTCCCAAACCCTAGGTCGACGAGATGAGTTCCTACTTGACCTCTGAGCCGA

GGTGGGCCGGAAACCGAGGCCTAGGCCCCGCCGGGGCTGCAAGGAAAAGGGGAAACTCCGAGCGTAGCGTCTTTTCCTTGTGGTT

CCTTTCTCCGGCATCCCGGACTGCGGGCCCTGCAGCCACCTGGACCGGCATTCAAAGGATTCTGCAAGTCCAGCTTCACAGACTG

GCTTTCCCAGACGCTCCGAAGCCCGCACCACGAACAGAATAAAGGAGAGACGAGAGATCGCAACTAGATTTGAGAATCCTCGTTC

TTTTCCCCAATCGTTCGGGCAGTAAACTCCGGAGCCGGCTACAGCGCGCATCCTC

142
TBX3
ACTGTCCTCCTCCCTCAATTGCCTATTTTTTGCCCATAGCTCTAACTTAACCCTGTGATCACCCCAGATCGCTACTTCTGACCCC

CATCTCCTCTCCCACACCAACCTCCAGCGCGCGAAGCAGAGAACGAGAGGAAAGTTTGCGGGGTTCGAATCGAAAATGTCGACAT

CTTGCTAATGGTCTGCAAACTTCCGCCAATTATGACTGACCTCCCAGACTCGGCCCCAGGAGGCTCGTATTAGGCAGGGAGGCCG

CCGTAATTCTGGGATCAAAAGCGGGAAGGTGCGAACTCCTCTTTGTCTCTGCGTGCCCGGCGCGCCCCCCTCCCGGTGGGTGATA

AACCCACTCTGGCGCCGGCCATGCGCTGGGTGATTAATTTGCGAACAAACAAAAGCGGCCTGGTGGCCACTGCATTCGGGTTAAA

CATTGGCCAGCGTGTTCCGAAGGCTTGTGCTGGGCCTGGCCTCCAGGAGAACCCACGAGGCCAGCGCTCCCCGGA

143
chr12:
CTCAGGGAATCACATGTCCGCCTGGCCTGGCCTGGTACCAAATGTTTATAGACAGGACGAGGGTCGCTGGAATCGCCTCGCTCCT

113622100-
TTCAGCTTGGCGCTAAGGCGCGAATCTCGATCCTCCTAGTATTTCTCTGGCGTCTGTCTCTATCTCAGTCTCTGCTTTTGTCTCT

113623000
TTCTCCCTCCCTCCGCCCCAGTCTTTCCGTCTCTTTTTCCTCGAATGCACGTGGAATTCGGAATTGAAAATTGAGGTCAGAATCT

CCCTTTTTCTTCCAGTTATCCGCGCCGCTGCCCCACGCCTAGCGGCTTGGATCTGCATAGACATCTATCTACCCGCAACAAGATC

CGAGCTGCAGAAGCAAACCTAATCTGTCTCCGCACCATCCCCTGCTCTGTAGACCCACTGCCCCATCCCACGCCACATCCTTGAG

GTTCAAGTAGCGACTCCAGCGGATGATTCGGAGAATGCCCTGCTTTCCAAAGGCCCCAACCCGTGTTTTTATTTTCTTTTTCCTT

TGCCCGCTTGACCAACTTTGGTTTCTTTCAGGGCCCGGAGGTGCCTGCGCCGCGCTTGGCTTTGCTTTCCGCCGCCCCAGGAGAC

CCGGGACTGTGGTTTCCGCTCGCCACATCCCAGCCTGGTGCGCACACAAGAGCCTGGCGAGCTTCCCTCGCGCGCTTACAGTCAA

CTACTTTGGGCCTCGGTTTCCCTGCTCCTTGTAGATCAGAGAAGGGACGGGCGAAATGCCTGCGAGGGAGGGTTGGCGAATGGGT

TGGTTGGTGGCAAGACTGCAGTTCTTGTACATGGACGGGGGTTGGGGGGTCAACACTGGAAGAACTCCTGCCTGACGCCAAGAGC

CACCCGCTTTCCAGCTCGTCCCACTCCGCGGATGTTTACCCACCTTCATG

144
chr12:
TTTGGGGCACCCAACCCTTCCCAAGCCTCGGTTTTCCCGATCTTGTGGGATCCTTGCGGCGCGAATGGGGTTGGAAGCACCTTGG

113657800-
AAGCTACAGAGTACCGGGTCGGGACAATTTCCGGCACTGCCCCAGTTCAGTGGTTTATAGAAAATTTCTTTCTCTCTCTCAGGTC

113658300
CACTAAGACCGAGAGAGAGAGAGAAGTCGACTCTGGCACACCCGGGCGAGGGGCTGCCGGGATTCGGGAGCTGGCGCGGTTGATT

TTTTCCGAGAATCCTCCACTTGGGGTGACGTCGGGCAGCGCGCGCGGGCCGTGAGGTTAATGCCCAGGCTTTTCTCTAAAGCGTC

CGGGAATGATCCGGCGAATAAAACGGGTGTCTGCAAAGTTAATGAATTGTACAAGGAGGCTGAGGGTGGGGACTTCGACCCGGGG

AGCCAGAGGCGGTTCTGGTGGACGCTTCCCCGTGCGCCTAGGGGTGCGCTGGGCTTTCCCAGCCGAGGTCTGCAG

145
THEM233
CCAGACAGTTAAGGTAAAACGTTGAAGTCAAGAGGAAGTAGTGAGTCTGTTGCCAACTGGATAGGGTTGGTCCTGTCCCATCTAA

ATGTATTAGAATTAAGTGGCTTTTAAAAATGAGCTGGTCATCTTCAGCCCACGGGCTGGCCAATTTGGAACTTAATGGGCCTTTG

CGTCCTCCTTCCCTGAGCCTCCTTTTATTCCAGACTTCTCAGTGTGAGTCTGTGCGTCCCTCCGACGATCTCAGGGAGTGGGGTG

CCTTCATCTGCCTGTTCCCTGTTCCTCAGGCTGACGCTCCCGCTGTCCTCCCCGCCTCCCCTCACTCCTTTTCTCCCTCCCTTCC

TCCTTGTGGGGAGGCTCTTGGCCAGGGTCCCTGAGCCCGGGCGGGTGCTGGCAGAGGACGCAGAAGGGGTGAGGTCACGTCTCCC

TTGAGCCCCGAGCCGCTGGCTTTTCAGAGCCTCGCCACAAGCCGGCGGCCAGAGCCCCAGACCACACAGACCGTGCGCTCCTCCG

CCCTCCCGGCGCCGCCGGCCTCGCCCATGTCTCAGTACGCCCCTAGCCCGGACTTCAAGAGGGCTTTGGACAGCAGTCCCGAGGC

CAACACTGAAGATGACAAGACCGAGGAGGACGTGCCCATGCCCAAGAACTACCTGTGGCTCACCATCGTCTCGTGTTTTTGCCCT

GCGTACCCCATCAACATCGTGGCTTTGGTCTTTTCCATCATGGTGAGTGAATCACGGCCAGAGGCAGCCTGGGAGGAGAGACCCG

GGCGGCTTTGAGCCCCTGCAGGGGAGTCCGCGCGCTCTCTGCGGCTCCCTTCCTCACGGCCCGGCCCGCGCTAGGTGTTCTTTGT

CCTCGCACCTCCTCCTCACCTTTCTCGGGCTCTCAGAGCTCTCCCCGCAATCATCAGCACCTCCTCTGCACTCCTCGTGGTACTC

AGAGCCCTGATCAAGCTTCCCCCAGGCTAGCTTTCCTCTTCTTTCCAGCTCCCAGGGTGCGTTTCCTCTCCAACCCGGGGAAGTT

CTTCCGTGGACTTTGCTGACTCCTCTGACCTTCCTAGGCACTTGCCCGGGGCTTCTCAACCCTCTTTTCTAGAGCCCCAGTGCGC

GCCACCCTAGCGAGCGCAGTAAGCTCATACCCCGAGCATGCAGGCTCTACGTTCCTTTCCCTGCCGCTCCGGGGGCTCCTGCTCT

CCAGCGCCCAGGACTGTCTCTATCTCAGCCTGTGCTCCCTTCTCTCTTTGCTGCGCCCAAGGGCACCGCTTCCGCCACTCTCCGG

GGGGTCCCCAGGCGATTCCTGATGCCCCCTCCTTGATCCCGTTTCCGCGCTTTGGCACGGCACGCTCTGTCCAGGCAACAGTTTC

CTCTCGCTTCTTCCTACACCCAACTTCCTCTCCTTGCCTCCCTCCGGCGCCCCCTTTTTAACGCGCCCGAGGCTGGCTCACACCC

ACTACCTCTTTAGGCCTTTCTTAGGCTCCCCGTGTGCCCCCCTCACCAGCAAAGTGGGTGCGCCTCTCTTACTCTTTCTACCCAG

CGCGTCGTAGTTCCTCCCCGTTTGCTGCGCACTGGCCCTAACCTCTCTTCTCTTGGTGTCCCCCAGAGCTCCCAGGCGCCCCTCC

ACCGCTCTGTCCTGCGCCCGGGGCTCTCCCGGGAATGAACTAGGGGATTCCACGCAACGTGCGGCTCCGCCCGCCCTCTGCGCTC

AGACCTCCCGAGCTGCCCGCCTCTCTAGGAGTGGCCGCTGGGGCCTCTAGTCCGCCCTTCCGGAGCTCAGCTCCCTAGCCCTCTT

CAACCCTGGTAGGAACACCCGAGCGAACCCCACCAGGAGGGCGACGAGCGCCTGCTAGGCCCTCGCCTTATTGACTGCAGCAGCT

GGCCCGGGGGTGGCGGCGGGGTGAGGTTCGTACCGGCACTGTCCCGGGACAACCCTTGCAGTTGCGCTCCCTCCCCCACCGGCTC

ACCTCGCCTGCAGCTGGGCCACGGAACTCCCCGGCCACAGACGCA

146
NCOR2
CTCTCTGGGCCTTAGGAAAATGGAAATGACACCTGTACCTGCCCTTCCAGGACTGACAGGAGGGGCTGCTCCATGAAACCTCACT

GCTGCGGTCATAATGTCATTATCTTTTGCCTTAAAGGGATTTCTTCTGCACCAGCACCTAAAGTGGCAGCCCCTTACCCTTGGCC

ATCAGCTGGACCCTGGTGCTCTCCTGGAGCCCAAAACCTCTGTTTTGTGTTGCATCCTGCTGACCAGCCACAGTCCACACCCATC

TGAGTGTCTGAGCAGAACAGCCCAGAGGCCACACCAGGATGGCTTTCCACCGGTCACCTTCCCCCACCCACTCATAAACCCTGCG

TCTCTGGGGGAGAGGGTGGCGAGGTCCCCTCCCCACATAGATGGAAACACTGAGGCCTGATTCATGGTGCCCCCTGTGAAGCGCC

TCATGGCCAGCACCGGGGGGCAGCAGGCCAGGGCGGGGACACATACCCGGTTCTCGTCGTAGATGATCTGCACCAGGCTGCGGTG

CTTCGACTCGATGGGCGGCGGTGACACGGGCTTCTCAGGCTCGGGCGGCTTGGCAGCCTCCTCCTCCAGCTGTTGCTGTGGGGAG

AGGCA

147
THEM1
CTTGAAAACTCCCAGCCCCCTTTGTCCAGATGGGGATGGAGGTGGCCAGGCTGCCCCGTTGATTGTGTGCCGAGGAGCCCTCCCC

32C
GGGAAGGCTGTGATTTATACGCGCAGGCTTGTCACGGGGTGAAAGGAAGGGCCACTTTTTCATTTTGATCCAATGTTAGGTTTGA

AAGCCACCCACTGCTGTAAACTCAGCTGGATCCGCGGGCCGTGATTAAACACATTGCCCGCTTTGTTGCCGAGATGGTGTTTCGG

AAGGCGCTGTGAATGCACTTCCCTTTGCGGGGCTCACACAGACAAGATGTGTGTTGCAAGGATGAGGCGCCTGCTCGGCCTCCAG

CCCAGGGCCGGGAAGGGAGAAGGTGCTGTGCGTCGCTGCCTGTGTCGCCCGCGGCTCTCC

148
PTGDR
CGCGTCAGGGCCGAGCTCTTCACTGGCCTGCTCCGCGCTCTTCAATGCCAGCGCCAGGCGCTCACCCTGCAGAGCGTCCCGCCTC

TCAAAGAGGGGTGTGACCCGCGAGTTTAGATAGGAGGTTCCTGCCGTGGGGAACACCCCGCCGCCCTCGGAGCTTTTTCTGTGGC

GCAGCTTCTCCGCCCGAGCCGCGCGCGGAGCTGCCGGGGGCTCCTTAGCACCCGGGCGCCGGGGCCCTCGCCCTTCCGCAGCCTT

CACTCCAGCCCTCTGCTCCCGCACGCCATGAAGTCGCCGTTCTACCGCTGCCAGAACACCACCTCTGTGGAAAAAGGCAACTCGG

CGGTGATGGGCGGGGTGCTCTTCAGCACCGGCCTCCTGGGCAACCTGCTGGCCCTGGGGCTGCTGGCGCGCTCGGGGCTGGGGTG

GTGCTCGCGGCGTCCACTGCGCCCGCTGCCCTCGGTCTTCTACATGCTGGTGTGTGGCCTGACGGTCACCGACTTGCTGGGCAAG

TGCCTCCTAAGCCCGGTGGTGCTGGCTGCCTACGCTCAGAACCGGAGTCTGCGGGTGCTTGCGCCCGCATTGGACAACTCGTTGT

GCCAAGCCTTCGCCTTCTTCATGTCCTTCTTTGGGCTCTCCTCGACACTGCAACTCCTGGCCATGGCACTGGAGTGCTGGCTCTC

CCTAGGGCACCCTTTCTTCTACCGACGGCACATCACCCTGCGCCTGGGCGCACTGGTGGCCCCGGTGGTGAGCGCCTTCTCCCTG

GCTTTCTGCGCGCTACCTTTCATGGGCTTCGGGAAGTTCGTGCAGTACTGCCCCGGCACCTGGTGCTTTATCCAGATGGTCCACG

AGGAGGGCTCGCTGTCGGTGCTGGGGTACTCTGTGCTCTACTCCAGCCTCATGGCGCTGCTGGTCCTCGCCACCGTGCTGTGCAA

CCTCGGCGCCATGCGCAACCTCTATGCGATGCACCGGCGGCTGCAGCGGCACCCGCGCTCCTGCACCAGGGACTGTGCCGAGCCG

CGCGCGGACGGGAGGGAAGCGTCCCCTCAGCCCCTGGAGGAGCTGGATCACCTCCTGCTGCTGGCGCTGATGACCGTGCTCTTCA

CTATGTGTTCTCTGCCCGTAATTGTGAGTCCCCGGGCCCCGAGGCAGCAGGGCACTGAGACTGTCCGGCCGCGGATGCGGGGCGG

GAAGGGTGGA

149
ISL2
CTTCCGCCGCGGTATCTGCGTGCCCTTTTCTGGGCGAGCCCTGGGAGATCCAGGGAGAACTGGGCGCTCCAGATGGTGTATGTCT

GTACCTTCACAGCAAGGCTTCCCTTGGATTTGAGGCTTCCTATTTTGTCTGGGATCGGGGTTTCTCCTTGTCCCAGTGGCAGCCC

CGCGTTGCGGGTTCCGGGCGCTGCGCGGAGCCCAAGGCTGCATGGCAGTGTGCAGCGCCCGCCAGTCGGGCTGGTGGGTTGTGCA

CTCCGTCGGCAGCTGCAGAAAGGTGGGAGTGCAGGTCTTGCCTTTCCTCACCGGGCGGTTGGCTTCCAGCACCGAGGCTGACCTA

TCGTGGCAAGTTTGCGGCCCCCGCAGATCCCCAGTGGAGAAAGAGGGCTCTTCCGATGCGATCGAGTGTGCGCCTCCCCGCAAAG

CAATGCAGACCCTAAATCACTCAAGGCCTGGAGCTCCAGTCTCAAAGGTGGCAGAAAAGGCCAGACCTAACTCGAGCACCTACTG

CCTTCTGCTTGCCCCGCAGAGCCTTCAGGGACTGACTGGGACGCCCCTGGTGGCGGGCAGTCCCATCCGCCATGAGAACGCCGTG

CAGGGCAGCGCAGTGGAGGTGCAGACGTACCAGCCGCCGTGGAAGGCGCTCAGCGAGTTTGCCCTCCAGAGCGACCTGGACCAAC

CCGCCTTCCAACAGCTGGTGAGGCCCTGCCCTACCCGCCCCGACCTCGGGACTCTGCGGGTTGGGGATTTAGCCACTTAGCCTGG

CAGAGAGGGGAGGGGGTGGCCTTGGGCTGAGGGGCTGGGTACAGCCCTAGGCGGTGGGGGAGGGGGAACAGTGGCGGGCTCTGAA

ACCTCACCTCGGCCCATTACGCGCCCTAAACCAGGTCTCCCTGGATTAAAGTGCTCACAAGAGAGGTCGCAGGATTAACCAACCC

GCTCCCCCGCCCTAATCCCCCCCTCGTGCGCCTGGGGACCTGGCCTCCTTCTCCGCAGGGCTTGCTCTCAGCTGGCGGCCGGTCC

CCAAGGGACACTTTCCGACTCGGAGCACGCGGCCCTGGAGCACCAGCTCGCGTGCCTCTTCACCTGCCTCTTCCCGGTGTTTCCG

CCGCCCCAGGTCTCCTTCTCCGAGTCCGGCTCCCTAGGCAACTCCTCCGGCAGCGACGTGACCTCCCTGTCCTCGCAGCTCCCGG

ACACCCCCAACAGTATGGTGCCGAGTCCCGTGGAGACGTGAGGGGGACCCCTCCCTGCCAGCCCGCGGACCTCGCATGCTCCCTG

CATGAGACTCACCCATGCTCAGGCCATTCCAGTTCCGAAAGCTCTCTCGCCTTCGTAATTATTCTATTGTTATTTATGAGAGAGT

ACCGAGAGACACGGTCTGGACAGCCCAAGGCGCCAGGATGCAACCTGCTTTCACCAGACTGCAGACCCCTGCTCCGAGGACTCTT

AGTTTTTCAAAACCAGAATCTGGGACTTACCAGGGTTAGCTCTGCCCTCTCCTCTCCTCTCTACGTGGCCGCCGCTCTGTCTCTC

CACGCCCCACCTGTGTCCCCATCTCGGCCGGCCCGGAGCTCGCCCACGCGGACCCCCGCCCTGCCCCAGCTCAGCGCTCCCTGGC

GGCTTCGCCCGGGCTCCTAGCGGGGAAAAGGAAGGGGATAACTCAGAGGAACAGACACTCAAACTCCCAAAGCGCATGATTGCTG

GGAAACAGTAGAAACCAGACTTGCCTTGAAAGTGTTTAAGTTATTCGACGGAGGACAGAGTATGTGAGCCTTTGCCGAACAAACA

AACGTAAGTTATTGTTATTTATTGTGAGAACAGCCAGTTCATAGTGGGACTTGTATTTTGATCTTAATAAAAAATAATAACCCGG

GGCGACGCCACTCCTCTGTGCTGTTGGCGCGGCGGGAGGGCCGGCGGAGGCCAGTTCAGGGGTCAGGCTGGCGTCGGCTGCCGGG

GCTCCGCGTGCTGCGGGCGGGGCGGGCCCGGTGGGGATTGGGCGC

150
chr15:
AGTTTGGGGAGCCTTTTCTCCATTTGAGAAAAAACAAACTTACAGCGAGGGGTGAGGGGTTAGGGTTTGGGATTGGGGAAAATGT

87750000-
GGGTGGGGAGCCCCCCCAAGGAAGTGAGGAGGGGGCTGCAAGGATTACACCTGGGCATACGTTTCCCTAGAAATCACATTCATTG

87751000
TATTTTTATAATTTATTCTAAATCTTTCATGCGAAGAAAGTCAGTAGTGAGTGTTAGTACTGGTGGCCCTCCTGATCACACTTGC

ATCTCTTGAGTGTGCCTTAAAGGTCTTGGGAATGGAAAATATAAAAACTGCTTCGTGATGCGTCATCTTTATCCCCCACTCCCCC

ACCCATTCCAATATATTTTCTACTTCCAGCCTAAATTCGGGGCCCCCTACCGAGGCCGGCCATGATCTTGAGGGCGGCATAGGGG

AGGCCGCGCTCTGTCCACCCCAGCCTGGTGATGCCGTTCGCTTCTTGTGCCCGGTATTGTGGGCTACATGCCTTTCCGGCGTACG

GAGCTGAGCGTCCAGGCCAGTGCCCCTCAACCTCTCAGTAATGTTTACCCGAGGCCGTCGTGCAATGAGACTATTCGCATGGCAT

TGTCAACGCGGCGGCGCGCGCGTCTCGGCCCTCCGCGGCTTGCCAGACTGTCCTGCAAACCACCTCACCCGTCTCTTTGGCGCAG

GAGACTCAGGCTGTAACCGGAGAAAACACTTCACCCTGGAACCCTAACTCAGGTCCTGGCAAAAGATGCGAGAGGAAGACTTGCT

CTCTTAATAAATCTCGGCCGCCCGCACATCTGGCCCCTAGACCTGCTCGGTAGAGGACTGGCTGGTGGATGCGCGGTCCAGGCCG

TGGGCACTCGACCCACCTCTATTTTCCTTCCCGAGGCGCCCCTGGATTACCACTTTCGGTTTGCGCTTACATCCGGGATGTCGAA

TTTCCCAGGGAATCATAATTATTTTATCTATAATTTATTCTAACCCCAAGGTTCCAAGAAAATCT

151
chr15:
ACATTCCTTCTAAAATGTGGGCTTTCTGTGTACATGGGCGCGCATTCCCAGGACTCGGTTCCCTGGGTGGAATTCACCCAGGAAT

87753000-
ACAATCGATTTTCTGAACCTGCGTAAGGCCACAGGCAGCTCTGAAAATGAAAGCGTTTGCTAAGTGGGGGAGATCTCACCGATCG

87754100
AACGTTTAAAAATGGCTTTGTCTTCATTCAGCTCTCCCGATTTATTCTGTGTTTTACAAATAGAAGCTCAGAGCTTCTGTCGCCC

AGTCCTTGCATGACTCATGGCGGTGGCCACACGGGTTTCAGGGATAACGGGATGTTTAGAAAATCGCTGCATATCGGAGTTTCCT

AGCACGTTCCATTTATACTGAACGCAGGCGGCCGCTGAAAATCCAGCCTCGACTCTTGCTAATGACTGGGTAGGACCCTCGGGGT

CCTGCGACGGTGCTGGAGGGTGTTCCCGGCTCCGATGTGGGGAGGCCTGCGCGGGGACTAGGTTCTCGAGAGGCGAGCGGGCGCG

CCAGAGAACCCGAGACTGCTGCGGGGCCGGATGCGGGATCCCTGGGCTGCGGTTCTACGCAGAAACGCCAATGGCCATGCCTCCC

CAGCTCCTCCCAGCCCCAGTCACTAGGCCGGCGCCTGGCCCGGAGATCCTCCCAGAGCCCTGGCGGTGCCATCATGCCGGAGAAG

ACAAGCTCGGCCCCGCTGGAATTCGCTCCAAACACAGATGCTCATTTTTGGAATATTCTAGAAAAATAACAAGATCTTGTTTGTC

GTTATGATTCACGGGAGGTAACTGATGGGAGGGCCATTTACATGAGGGCAGACACTGTGGGGCGAAGGTGACTTCTGGACGTAGG

CTTTAAAGTAGGAACGGCTCCAAATTCCCAATATCTCCGGCCTTACCGGTTGCAAATCGGACCCCTGCGGGAAAACCAGACACTT

CTGTTTCGTGGCTTTCGGGCTGCCTCCAGCCCACGCAGGCTCGTTTAGTCCCCGTGGAGTCAGCCCCGAGCCTTCCTAGTCCTGG

AACAAGGGCTCCAGGTCGCGGCCGCGGGAAGCCGCCAAGAGGGCGGGGAGTAGGGATTCCCTCCAGCTCCGCAGGGCATC

152
NR2F2
TCCTCCTCGGCCTCAGATGTCGTCCCACCTGCCCACGAGCAGGGAACCTGGAACCCACTCTCCCGGCAGTCCCCAGCGGGTTCCG

CCACCCGGCGGCCGCCCCTGACACCGAGTGGGTGGGAGGAAGAGGCAGCTGGCGGGGATGGGCCATTGAGACCTCTTGAAAAATA

TTAAAAGACAGGATGGGTAGAGATTTCTCCGGGAGAAAGTTCGAGGGTGCATCGGGTCGCGGCTGGGAGGAGTACCCGAAATGCC

AGCAGGAGAAATGCAACCTGTTTAGGCCACACCTTCAATCCCCGAGGCTGTCTGGAGAGACTGCGTGCGGGGGACTTGCCGGCGT

TCCCACACCGCGCCTGCAATCCACTCCCGCGGCTGCCTGGCCTCTGCCACTCGCGGCTTGAAGCCAGTGGCTCTCAAGCCCTCGG

CCCCGCGGCGGCCCGCGCAGCCTTCACCCGGCGCCGGCACCACGAAGCCTGGCCGCAGTGGACTCCCCGCAGCTCGCTGCGCCCT

GGCGTCTCCCGTCGAGGAGGGAGGGACGGAGGCCTGAGCCGGGAGCTCCCTGGCGGTGGTCGGGCCGCCCCCCTTGAGGCCTGCT

CCCCCCTCTCGGCCTCGCCAAATCCCTGAAAGCCCAGTCCCCCTTCGTCACCCCGGGGGCTTCTAATCACTCGGTATCGATTTCC

CTAACTCTTTTCATCCTGTTGAAGACACATCTTAAAACACTCCAGCCCGGAGTGTGCTCTGGGCTTTATCCACACTAATAAAATG

ATTTACCCTTCTCTCCGCGCTCTCCTCACAGAGGAAAATCGTTCGAGCCCCGGCTATTTGTGTGTGATCAGTAAATATTTAGTGC

GCTGACATCCTTAGCTGGGCTTCGGATCGATTCGGGGCCCACCGGGAGGTGCGCACGGTCCGGGCGGGGCCGCGCCGAGCTCGCC

GAGGGGGCTCCTCCCGCCCTCGCCGCCGGCCGCTGATTTACGGCCCCTGCAACCAGCTAAGGGGGGCGAAAGCGCGCCTGGAAAA

TTGGCTTTTCAACCTTTTACTTTTGACATTCAGCCACTTCCCCAGGCTCTAATTCTCGCCCGCACTCCTCCCTCCCGCCCTACTA

AGGGTTGCCCTGTGCGCCCTGCGAGCCCTTCCAGCAGCAACGCGCGGCGCTCGCGCCCCCTCGGCCCGGGGACCACCTATCACAG

CCCTGAGCCGCGACGCGGGGAGGCCCCGGCCCCTGCTATGGGGGTCGCCTCCTTCGAGGAGAGATGCTCTCCGCCCGCCCACACC

TCTGAGGGAGGAGAGGGGGTGGAGAAGCCCAGAGCTGCATCTGCTGGATGACGAGCCGCTCTCCCTGCTACCCTTTCTCCGACCC

GTCGGCCTTTCTCCTACTCTGGAGACTGATCCTCGACGTCCATCGGGCCGGATGGCGTCGGGTGGAAGCGTTACTTTCCTCGCAG

AAAAACTCCTCCTCTTTCCTAAGATCAGAAAAAGCGCTTAGCTTGGAATTGTTAG

153
chr16:
CCTAGGCATTCTCAGCCCGTTTTGCTGGAGGGGGCATTTGAGGCCTGGCCAGCTTAGCCAGCCTACAAGGAGTGTTACTGGGGTG

11234300-
AAAACAGCCAGCGGGGACCAGTCTGCTTGTGGCCCGCCAGGTGCCTGGGATGGGGAAGCAGCAAATGCCCACCTTCCTGCCCAAC

11234900
CCCCTCCTCCCTCTTCATGGGGGGAACTGGGGGTGGCAGCGGCTGCCGGGTGCGAGCGGGCTCAGGCCTGTGGCCCTGCCTGACG

TTGGTCCCCATCAAGCCATGTGACGAGACCAGGCCACAAGAAAGAGGTTTCAACAAGCGCTGCCTCCGCGGCCGCGTCTATCTCA

GTCTGACTACCTGGAAGCAGCACTCCACCCTCCAGCCCAGCGGCCCTCGGCTCAGCTGCCAGGTCACCGGCAACCCCGGGAGCGG

TGGGGCAGGGGCTGCTCCGCCAGCCTCTGTGATGTTCAGGCCGGGCTGCACCAGCCCGGGACCCCTAGGTG

154
SPN
GCACTGGTTCCCCTTTACCTGAGCCAACAACCTACCAGGAAGTTTCCATCAAGATGTCATCAGTGCCCCAGGAAACCCCTCATGC

AACCAGTCATCCTGCTGTTCCCATAACAGCAAACTCTCTAGGATCCCACACCGTGACAGGTGGAACCATAACAACGAACTCTCCA

GAAACCTCCAGTAGGACCAGTGGAGCCCCTGTTACCACGGCAGCTAGCTCTCTGGAGACCTCCAGAGGCACCTCTGGACCCCCTC

TTACCATGGCAACTGTCTCTCTGGAGACTTCCAAAGGCACCTCTGGACCCCCTGTTACCATGGCAACTGACTCTCTGGAGACCTC

CACTGGGACCACTGGACCCCCTGTTACCATGACAACTGGCTCTCTGGAGCCCTCCAGCGGGGCCAGTGGACCCCAGGTCTCTAGC

GTAAAACTATCTACAATGATGTCTCCAACGACCTCCACCAACGCAAGCACTGTGCCCTTCCGGAACCCAGATGAGAACTCACGAG

GCATGCTGCCAGTGGCTGTGCTTGTGGCCCTGCTGGCGGTCATAGTCCTCGTGGCTCTGCTCCTGCTGTGGCGCCGGCGGCAGAA

GCGGCGGACTGGGGCCCTCGTGCTGAGCAGAGGCGGCAAGCGTAACGGGGTGGTGGACGCCTGGGCTGGGCCAGCCCAGGTCCCT

GAGGAGGGGGCCGTGACAGT

155
chr16:
TGTCCGACAGGCACACAGAGCGCCGCCAGGCACGGCCCTCATTCTTCACCCCGAGCTCCCGCAAGGTCGGCGAGGAGGCTGGAGC

85469900-
AGCGGGTAGGAAGCGGGCCGAGGCTCCCCCGACGCTGGGCCGCAACTGTCATCGCAGATCCCTGAAAAACGAGCTCTGTAATCGT

85470200
TGCCGTCAGCGGGTGTACAATTGCAGCCTTATGTTTCCTGCCGCTGTTTACCTTCCTGAGCGGCGCCCAGAGATGCACACACGCT

GCCCTGAAGCGGGACGTGACCTCTGGGCACCTGTGAGGTCCTGGG

156
SLFN11
GTCGGCTCCTGCGCTCCCAACGGGGTGGCCGTTTCCTTCCTCGCACCCTCTTCTCTCCCGGTGCCTGCGGTCCCACCTTCCAGAT

ACCCCTCGGAGAGTCCAGCTGAGCTCTCGCCAGAGCTTTCCCCTTCCAACCCGCTCGACTTGCCCAGATCCCAAGCTGGGCTTCT

CTCTCCATCGCCCCAGAAAGTGGGTCTTGGAGACCGAGGCAAGAATTTGGGCCTCCGCTTCTGTTCCAGACCCCGGACCCCTTGC

CAAAATGCGGCAGATGTGCAGATTGGGCCGCGCTTGGTTCCTGGCTGGGTTTATGGAGCCTGCGGCTGAGGCAGGCTCCGCAGAC

CCCGAGCCAGAGTGGGATTTAACGGCGGCCGGTGCGCTGTGCTTGGTCAACCCCGGTAACCGTCACGCTGCTAGTGATATGAAAA

AAACCTGCCAGCGTTCTGCTTTTCTGCCCCGCTGCAGTCTTTAGCACCCGCCAGGATTCTGTCCGAGTGTTTGGA

157
DLX4
TTTAGTGTGTGCATAAAACATCCCAGCTAATCTCAAATAGACTTTTCCTGAGCAGAGGCTGAAATTTGCAAGTAATGCAAAGAAG

ACTCCGGGAGAGCGTCGCCGATGGTGGAGCGGGAGACGGGCGTGGGGAGCCCCACTGCAGTGCTGGGATCGAAGTGGTGCTGACC

CCAAGACCTCTCCCCTCCTCCTCCCCCGGGAGCTTCTCCAGGGTTATTTGGGAAATGAGGGGGAACTCCAATCCCTGAGAAAGCG

CTCAGGGGCTTGCTGAGGTGAGCGCAAATGGAAGCACAAGGCCGGGCTGGCCGTGGGCTCAGTAACCAGTCGGCTGCCCGGCTTG

CGCCAGCACTAAATGCTCGATCAGAAAGAGAAAAAGAGGCGCAATAATTCCAAATTTCAGGAAAAGTCAAATCGGAGAGGGGGGA

CGCAGGTCTCTTCAGACTGCCCATTCTCCGGGCCTCGCTGAATGCGGGGGCTCTATCCACAGCGCGCGGGGCCGAGCTCAGGCAG

GCTGGGGCGAAGATCTGATTCTTTCCTTCCCGCCGCCAAACCGAATTAATCAGTTTCTTCAACCTGAGTTACTAAGAAAGAAAGG

TCCTTCCAAATAAAACTGAAAATCACTGCGAATGACAATACTATACTACAAGTTCGTTTTGGGGCCGGTGGGTGGGATGGAGGAG

AAAGGGCACGGATAATCCCGGAGGGCCGCGGAGTGAGGAGGACTATGGTCGCGGTGGAATCTCTGTTCCGCTGGCACATCCGCGC

AGGTGCGGCTCTGAGTGCTGGCTCGGGGTTACAGACCTCGGCATCCGGCTGCAGGGGCAGACAGAGACCTCCTCTGCTAGGGCGT

GCGGTAGGCATCGTATGGAGCCCAGAGACTGCCGAGAGCACTGCGCACTCACCAAGTGTTAGGGGTGCCCGTGATAGACCGCCAG

GGAAGGGGCTGGTTCGGAGGGAATTCCCGCTACCGGGAAGGTCGGAACTCGGGGTGATCAAACAA

158
SLC38A
CATGGTGCTTCAGGAAGGGAGGGGACGAGAGCCCTGGGCTTGTGGTGTCCACGTGGACAGCTAATGAGGAGCCTTGCCGATGAGG

10
AGCATGCGTTCCCGACGGGGCGGCCGAATGCGGAAGGAGCCGCCATTCTCTCCGCCCTGACCGCGGGATTCTCTGCAGCAGATGA

GAAACGGCGCTGACTCAGCAGGGTCCCTCCCAGGCCCCGAGCGGTCATCTGGTGACCCCCGCGCTTCCCCCACGGCCCAGCCGGA

GAAGGGCAAAGGGAAGTCCCGGCTCCAAGGCGCACCCAGAGATGCGGTGCATGTGGCAGGATGGCCCAGCCCCGTCGGCAGCCCC

AGCTTCCTGCCCCTGGTTTCCTTCCTCCCACGGGCTACAGGCCTCTGATGAGCTTTGGAAAGCAGGAAACACACAGGCTAGTAAC

TATGAATGGGTCCAAAAAACACTCCTTATTACTTTAAACTACTTAGGAAGAAGCACAGCGTTGCCAAACGCCAGA

159
S1PR4
GCGCGGGGGGCCGGAGGATGGCGGCCTGGGGGCCCTGCGGGGGCTGTCGGTGGCCGCCAGCTGCCTGGTGGTGCTGGAGAACTTG

CTGGTGCTGGCGGCCATCACCAGCCACATGCGGTCGCGACGCTGGGTCTACTATTGCCTGGTGAACATCACGCTGAGTGACCTGC

TCACGGGCGCGGCCTACCTGGCCAACGTGCTGCTGTCGGGGGCCCGCACCTTCCGTCTGGCGCCCGCCCAGTGGTTCCTACGGGA

GGGCCTGCTCTTCACCGCCCTGGCCGCCTCCACCTTCAGCCTGCTCTTCACTGCAGGGGAGCGCTTTGCCACCATGGTGCGGCCG

GTGGCCGAGAGCGGGGCCACCAAGACCAGCCGCGTCTACGGCTTCATCGGCCTCTGCTGGCTGCTGGCCGCGCTGCTGGGGATGC

TGCCTTTGCTGGGCTGGAACTGCCTGTGCGCCTTTGACCGCTGCTCCAGCCTTCTGCCCCTCTACTCCAAGCGCTACATCCTCTT

CTGCCTGGTGATCTTCGCCGGCGTCCTGGCCACCATCATGGGCCTCTATGGGGCCATCTTCCGCCTGGTGCAGGCCAGCGGGCAG

AAGGCCCCACGCCCAGCGGCCCGCCGCAAGGCCCGCCGCCTGCTGAAGACGGTGCTGATGATCCTGCTGGCCTTCCTGGTGTGCT

GGGGCCCACTCTTCGGGCTGCTGCTGGCCGACGTCTTTGGCTCCAACCTCTGGGCCCAGGAGTACCTGCGGGGCATGGACTGGAT

CCTGGCCCTGGCCGTCCTCAACTCGGCGGTCAACCCCATCATCTACTCCTTCCGCAGCAGGGAGGTGTGCAGAGCCGTGCTCAGC

TTCCTCTGCTGCGGGTGTCTCCGGCTGGGCATGCGAGGGCCCGGGGACTGCCTGGCCCGGGCCGTCGAGGCTCACTCCGGAGCTT

CCACCACCGACAGCTCTCTGAGGCCAAGGGACAGCTTTCGCGGCTCCCGCTCGCTCAGCTTTCGGATGCGGGAGCCCCTGTCCAG

CATCTCCAGCGTGCGGAGCATCTGAAGTTGCAGTCTTGCGTGTGGATGGTGCAGCCACCGGGTGCGTGCCAGGCAGGCCCTCCTG

GGGTACAGGAAGCTGTGTGCACGCAGCCTCGCCTGTATGGGGAGCAGGGAACGGGACAGGCCCCCATGGTCTTCCCGGTGGCCTC

TCGGGGCTTC

160
MAP2K
GGGCGGGTTGCCACACTGTCCCCTTTCTGCATGGGAGGAAGGGGGCTCGAGAACTGAGTCAGCCACACAAAACGAGGATGGACAG

2
AACTCCTGAGTAGCGAGGGTGCCTGCCGGGCGCGAGGAGGAGGGGGAAGACGAGGAAGACGAGGAGGAGGAATAGGGAGCACCAC

ATGACAGAGGGGCTGCCTCAGACCACAAAGCGCTTCCTCATCCTTTCCTCGCCCTTTGATGCCGCCGGCAACGTGACTCTGCGAG

CAGCGGGGCAGACGCCAGGTCTCCCTCGCAGGCGGGAAAGGGGCTCCAAGGCGGGTGCTGCCTTGCTCGGGTCACATGGCTACGT

GGGGGCCTTGCTCAAATTCACTTCCTGCCTTCATTACAAAACTGTCAAAGGGGATCGCACGTTTGCAGGGTGTCACCCAAGCATT

CTGGTTTTGCAAACGACGCTGTGCGGCAGGCGGTCTGATACCTGATGAGCTCGGTGTGGCGGGGTCGGCAGCATTTCCTCCGGGG

TTTTGAGCTCTGGCCACTTCTCCTTTTGTTCCACCCAATCTCACCCACTTCTGGGCTTCGAGGCCAGAGTGTCTTAACAAGGGGG

CACGT

161
UHRF1
GAGCGAGACTTTGTCTCAAAAAAAAAAAAAACCAAATAAATTGAAAGCTGAGAAATTCAGAGCACAAGAAGACAAGCGCGCCCCC

TCTTTTAGCTGTCAACATGGCGGAGCCGTCCCTGGTGACGCAGCCTCCAAAGGCCTCCCTGTGCCCTCCTGAGACCGCAAGAGGG

AAAGTGGCAGCGACAGTGATCGTGGTGTCTTTGTGGCGGTTGTGTTGACCTCACTGACCCCCGAAGTGCCGCTCTAGGGTCTGTC

CTCAGCGGTGACCCGGCCGGGTCGAAGGGCAGAGTTCCGCTGTCACTAGCCCTCCACCCGTCCTGTGTGCTGGGATGCCCTCGCG

GCGCCGTCCACGCCACCGCCGCCCCCTCTTGTGGGTTCTGTCTCCTCCGTGTCTAGGATCCTCCTGCATCCGTTTTTCCTTCCTC

CCTTCTCTCCCTCCGTCTGTCTTGCCCGCACCTGAGGTTGTCGCAGAGGCGCTGAGACGGGCCAGCAGGAGCTGT

162
DEDD2
TGCTGTCCCGGTCCTGTCGCAGTCCTCAAAGATGCTAGAGTGACAGTCCTCTAGGGGTAGAGATGGTCGTCCTCCCAGGAGAAGG

TGGCCCGGAGACTTGGAGGTGGGATCAATCCTGCCAGTCCTGGATCAGGAGGCCTCTGTCGGGCGCCGCCCCCCTTCCTCCTCCA

TCAGCAACAGGCGGCGCCGGCCAGCCTCATAGTCAGCCTCATCCACACTGACCAGCAGGCGAACAGCCTCCCGGCCCACAGCCTC

TCGCAGGGCCTCAGTCAGGAACACGCCCCGCAGGGCCTGCAGCAGGGCGCCACTCAGGTAGTCGCCCCAGAAGGCGTCCAGATAG

GAGAGCTCTGAGAACTTGATGTCACAAACCACAGAGCCCAGGTCCCTTGAGCGCAGCACTGCGGTGGCCTGCCCAAACACGTCCA

GCTGCCGCGCCAGCGCCTGGGGCCGCCGGGATGCCACGCCCTGCTCCAAGGCTGGCCCATGCTCGCAGTACTCTGCTCGAACCCG

GAGCCGGATGTCTGCAGGGGAAGGAGGGATTTGTCAGGGAGGGGGCCAACACTAGACACACTTATGGGGAACGCCACCCTTCCTC

CCTCC

163
CDC42E
TGATGCCCGGCCCCCAGGGGGGCAGAGGCGCCGCCACCATGAGCCTGGGCAAGCTCTCGCCTGTGGGCTGGGTGTCCAGTTCACA

P1
GGGAAAGAGGCGGCTGACTGCAGACATGATCAGCCACCCACTCGGGGACTTCCGCCACACCATGCATGTGGGCCGTGGCGGGGAT

GTCTTCGGGGACACGTCCTTCCTCAGCAACCACGGTGGCAGCTCCGGGAGCACCCATCGCTCACCCCGCAGCTTCCTGGCCAAGA

AGCTGCAGCTGGTGCGGAGGGTGGGGGCGCCCCCCCGGAGGATGGCATCTCCCCCTGCACCCTCCCCGGCTCCACCGGCCATCTC

CCCCATCATCAAGAACGCCATCTCCCTGCCCCAGCTCAACCAGGCCGCCTACGACAGCCTCGTGGTTGGCAAGCTCAGCTTCGAC

AGCAGCCCCACCAGCTCCACGGACGGCCACTCCAGCTACGGTGAGGGCCTGGGCCATCTTGGCCCACTTTTCAGA

TABLE 4C

SEQ

ID
GENE

NO
NAME
SEQUENCE

164
chr21:
GGCCGGGCAAAAAGCCGCCGCAACAAAAAGCTGCGCTGACGGGCGGAAAAAGCCGCGGCGGCGGAGCCAAAAAGCCGGGGCGGCA

9906600-
AAAAGCCACGGTGGCGGGCGCAAACAGCCGCAAAAAGCCGCGGTGGTGGGGGCAAAATCAGTGGGAGCAGGGGCAAAAAAACACA

9906800
AAAAGCCGCGGCGGCGGGGGCAAAAAGCCA

165
chr21:
TGGCTTTGCTGGAGTGTGATGTGATAGGAAATGTGCAGCCAAAGACAAAAGAAGATGTAAGTAGGCTTGACTCATTGCAGCTAAG

9907000-
AACCCAGATGTTACCTTGAGGGTATTAACTAATAAGCAGTTTAAATCAGAATGGCACATTCTGATTTGTTTTTTGTATGTTCACA

9907400
TTTGGCAGGCATAGATACTGTTTGAAAAGAGAAAAGTCAGTACATAGAGGTAACAAGCTTAAATATGTGCCAAGTCTAGAAACAA

GAGACTAGGGGGATAAGGACCTTTCGAAATTAAATGCAAGATTTGAAAACTGATTGGCTGGGGGATGAGGCAAAGGCAGGTCTTT

AAGGTCAATCCCTGTTTTGCTTTAAGTTGTTAGCGGGTGGTTTTATCATATATTGTAGAA

166
chr21:
TTCCTGGGAATGTCAGCTAACCTGAGCCTAGGGGCCTGAGCCCAAGGGCAGACTGAGGCTCCCCCAGCACAGGGAGGTGCTGCCT

9917800-
GTGACAAGGGGTAGTGCTGGCACAGTGCAGGCTACTCCCTAGAAAGATCAGCTTGAATATGCAGGAAGAGCAGGACCCTCGGGCT

9918450
GAGGCAGAGGTGGAATGGGAAGTGCATGGTGGTAATTTAGTTCTCCAGAGGCCAGAAGTAGGAGGAGCGGTTGGAATGCTGATGG

CCCAAAGGGAAACCCTGGACTACCCTGGCCTCCCACAGGACTCTCATAGTAATTGCGGCTCCCTGCAGTGGTGAGGCCAGAAGGA

GTGTTGCCCAATGCTGTCATCATCCAGTCCACCCCCCACCCACCATCAACAGATGAGTATGGTCATGAGTGTGGTCACCTCATCA

GTCATTTGCTCAGTTGTGAAAAAGAAATTGTTCAGAGAAGAGCAAAGTGTTTTTCCATGAGCCAAAGGTCAGCCAAGTTATGCTA

ATGAGGAGGACTGGAGACAGCGTGTCACAGACACCGAGAAGGAGCACTGGGCAAGGGCACTTCTCCCAGGGCAGAGCCCACAAGA

AGCGTCCTGGCACCAGACACTCAGGGAACTGAAGGCTGGCAGGGGCCCGCCCAGT

167
TPTE
TCCCCCCAGCTGGGTATAAGCAAACTTTCCTGTCTATGGGCCGCAGAGACCACCATCTAGTTCCCCCGCCAAAACTTTACATGAT

TTTAATTCTCCTGATGAAGATGAGAGGATAACAGCCAACAGAGAGGGCAGAGGATGGGATGGGACTCCCTTGCTCAGAGACCTCA

CCTCTAGGTCTTTACCTCCTATTGAGAATAAGTCAGTTCTGTAGTAAGAACTCTGTGTCCACGGCAACCCCAAACAGAATCCTAG

CGCTCTTGTGATTCTTGTAGAATGGGGAATAGAACGAGCTTGGCCCAAGACTGCACAGACTTAAAAACATACTATTCTTTGAAAA

TGGCAATCATTAAAAAGTCAGGAAACAACAGGTGCTGGAGAGGATGTGGAGAAATAGGAACACTTTTACACTGTTGGTGGGACTG

TAAACTAGTTCAACCATGGTGGAAGTCAGTGTGGCGATTCCTCAGGGATCTAGAACTAGAAATACCATTTGACCCAGCCATCCCA

TTACTGGGTATATACCCAAAGGACTATAAATCATGCTGCTATACAGACACATGCACACGTATGTTTACTGCAGCACTATTCACAA

TAGCAAAGACTTGGAACCAACCCAAATGTCCAACAATGATAGACTGGATTAAGAAAATGTGGCACATATACACCATGGAATACTA

TGCAGCCATAAAAAATGATGAGTTCATGTCCTTTGTAGGGACATGGATGAAATTGGAAATCATTCTCAGTAAACTATCGCAAGAA

CAAAAAACCAAACACTGCATATTCTCACTCATAGGTGGGAACTGAACAATGAGAACACGTGGACCCAGGAAGGGGAACATCACAC

TCTGGGGACTGTTGTGGGGTGGGGGGAGGGGGGAGGGATAGCATTGGGAGATATACCAAATGCTAGATGAGGAGTTTGTGGGTGC

AGCGCACCAGCATGTCACACGTTTACATATGTAACTAACCTGCACATTGTGCACATGTACCCTAAAACTTAAAGTATAATAAAAA

AAATACTGTTCTGCCATACATACAGATACTCATTAAAGATGAGGGAGAAGGGCATGGGGTGGGGGAGAATGTACCAAAACCAAAG

ACCACAGGATAATAACCTCAGAGCAGAGACTATCTCTCTAGTTATTTTTTCTTTTGTATGTAATGGAGAGGATTATTATTTACTC

TGATGAAGAAGTTTACATCAAGTGTTCAGCTTCCTTTGTGGGTTACAGAGAATAACCAGAGGGCTCAGTTATGCTCTCTGAATAA

CTATGTTTGCTTAGTGTTTTCTAAACAATATTAAATTTCACTAAAATAGACAAGGTTGATAGGACTTGGGGGCATAACTCATTGA

CTCAAGCTATCATTTTATAGGATTGTGAGAAAACAAATAGATGAACATTTAAAATACACTCATATTCTCGCTAGAAAAGAGGATT

TTGAATATTCTTACATCAAAGACATGGTAAATGTTTAAGGCAATGAATATGCTAATTACCATGATTTGATCATTATGCAATGTAA

AATGTACTGAAACATCACATTGTACCTCATAAATATGTACAATTTATTATGTGCGAATTAAAATTTTGAGTATAAGAAAAAATAA

ACTTCAATTGTAAGAAAACAACCCAACTTTTAAAAAACGGGCAAAATACGTGAACAGATACTTCACTAATAGAGATTTGCAACTG

GCAAATAAGCAAATGAAAAACTGGTCATCATCACTATCTATTAGAGAAATGCAGATTAAAACTACAATAAGAAACAATGCTGCCC

GTCCAGACGCATTGTTTTGACCGTTTCCAACTTGTCCCAGCCCTTCCCGGGGCATCGCTGGGGACCCTACGCCGACGTCCCCCCT

CCGCCCGCGCCCCAAGGGCCGACTGGGCAAATTGGGAGACCCGCCCCGCGGGGCGACCCAACTTTTCGGAACAGCACCCCACCGC

CCACCCCCGCAGACCCCCGGACCCCCGCTCCCGGCGGAGACTCAGGGAACCCCGCACCCCAAGCCCTTCTAAATCGTGCAGCGTG

AGTGTGACGGCCAAGAGCGGATGCAGCCCGGGATCGCCCGCACCTTCCCGTGGGCGGAAGCGCAGGAGCCAGCTGGGGAGGGGGC

GCCCTAGAGGAGCGGCTAGAAAGCAGACACGGGGAACTCAGGTCATCCTGGGGGGGGACAAGACAACGAGAGCCGGGCGCCTCGG

GGGCGGCGCGGGAGCCTCCGCAGGACCGGGCGGGCGCCCCGGCTGGCGCGGGCGGGGGGCGCGCCCCCTTTACCTGCGGCTCCGG

CTCCTAGGCCATTTCCTCACGCGGCGGCGGCCGGGACTGAGCTAACACCACTCAGGCCGGCCGGGTTTGAATGAGGAGGAGCGGG

CGCGGAGAGGAGGGGACGGGGAGGGCGGAGGGAGGGAGGGAGGCGTCGCGGAGTTTTTCTCGGCCTTTTGTGCGGACACCTCCCG

GATTCCGCGCCCGCACCCGGCCCCCCAAAAGACACGGGGAGCCGCGGGCGAGGGGTTCAGCCATCCGCCGAGGCGCCTAGTGCCT

TCGCGCCTCCAAGACCCCCCCCCAACAAAAAGGAGCGTCCCCCACCCCTACCCCCGCCCGGAGGACTTAGGGCCTGGGCTCACCT

CGGGCGCGGAGCTAAGTGTAGGCGCCGGGGGTCCCTAGAGCCGCCGGGGCGCAGCGAGTCCGGCGCTGGGTAACTGTTGGGTCAG

AAACTGTTCAGGTAGCAGCTGTTGTGCCCTCCCTTGGCCCCGCCGCTCGGAGACGCCCCGCCCCCTGCCTTGAACGGCCGCCCGG

CCCCGCCCCAGCGCCCACGTGACTAGCATAGGCGCGCCCCCGTTCCGCCCGCCGCCGCAGACTCCGCCTCCGGGACGCGAGCGAG

CGGCGAGCGCGCGCACTACCAGTTCTTGCTCGGCGACTCCCGCGCACGCGCGCGCCGTGCCACCCTCCCCGCACCCCTCCTCCCG

CCATCCGGCTTAACGTGGCGGGCGCGCGCCGCGGCAGTAGCCGTGACAGGTACCCGGCGGGGCGGGGGGGGAGGGGGTTGGCCCG

CGAGGGTGTGCGCAGGCACAGACCCGGGTCCTGTCCCCGCCGCCCCCTCCTCTGCAAGGTGTGCCTGGGCGAGGGGAGGGGCCCG

CGGCCCGAACCCCTGGGTCACCCCCGAATTACAAACAAAAACCTTAACGCCATTGCTCGCGGGTTAGAAGGCAGCTGTGCGTGCT

CAGGAAAAGAAGCCACGCACAAGAGACCGCACGCGGCGTGGATACAGTGACACGAAACACCCAAAATCTCTTTTGAAAGGGAAAC

CAGGCACAGTGGCTCATGCCTATAATCCCAGCACTTTCGGGGGCCAAGGCGCTCACCTAAACCCGAGAGTTCAAGACCAGCCTGG

GCAATACAGCGAAACCCTGTCTCTACGAAAAATATAAAAATTAGCTGGGCATAGGGCTGGGCACGGTGGCTCACGCCTGTAATCC

CAGCATTTTGGAGGCCGAGGCGGGCGGATCACGAGGTCAGGAGTTCCAGACCATCCTGGCTAACACAGTGAAACCTTCTCTCTAC

TAAAAATACAAAAAAAATTAGCCGGGCGTGGTGGCAGGTGCCTGTAGTCCTAGCTACTTGGGAGGTTGAGGCAGGAGAATGGCAT

GAATCAGGGAGCGGAGGCTGCAGTGAGCTGAGATTGCGCCACTGCACTCCAGCCTGGGGGACAGAGTGAGACTCCGTCTCAAAAA

AAAAAATAATAATTAGCTGGGCATGGTGGCTGGCACACATGGTCCCAGCTACTCAGGAGGCTGAGGTGGAAGGATCTCTTGATCC

CGGGGAGGTCAAGGCTGCAGTGAGCCAAGATGGCATCACCGCACTCCAGCCTGGGCCACAGACCCTGTCTCAAAAAAAAAAGAGA

AAGTGGGGAAGAAAATGTAATACAAATTAATATACCAACAGCAATTAGTGAGTACTTTTTCCATGGAGCTGGGAGAGGGAATAAA

TGTTTGTAAAATTAAAATGTTCTACGCTAGAAATCAACTTTCCTTCTATGCTTTCTTTACTTCACCCCTTATAGCTACTTAGTAA

ATCTCACAAATCCTATCCTTCTGATCTCTCTGAAATGTATGTACCCTTTCCCTTCTATTCTCACCACCCATGTTTCTTTGTTTCC

TTCTAGCCTGTGTAATAATCTCATAATCGCACCTCCTGTACCTGCCTTCTTTCTAGTCCAGAATACGTTTTCCTAAATTCCACCA

ATAACCATCCTGCTACTGCTTTGTGTGAAATTCTCCAAAAAAAATTTTACTTTTCCAAAATAAGTCAGGCTCCCTCTCTTAGGAT

ACAAAACCACACCATGGTCCCAGCCAATCTTTCAGCCTGATTCACTCAGTATATATTTATTGACCTCTCCTTTCTCCCAAGCACT

TGGCTAGATAATAATTAAAGAGTGCGGCACAAAACAAATTGGATTCCTCCCCTCATGGAGCTTGTATTTTCACAGGAAGCACAGA

CATTAAATAAATTAAAACACAAAAAAATAGACAAGCATATAATTACAGTATGTATCCTAGAGAAATATCACTCATGCAGAAAGCA

TACACAAGGATGCAGCACTGTTTCCAATAGCGAAAAGCTAGAAACAACCTACATGTTCACCAAAAGAAAATGGCCACATAAACTA

TACCATATCCAAATTATCCAAATTTTAGAATATAGACAACAGGTTGGGCGCGGTGGCTCACACCTGTAATCCCAGCACTTTGGGA

AGCCGAGGCGGGTGGATCACAAGGTCAGGAGTTCAAGACCAGCCTGGCCAACATGGTGAAACCCCGTCTCCTCTAAAAAAACAAA

AAAATCAGCTGGGCACTGTGGCAGGAGCCTGTAATCCCAGCTACTGAGGAGACTGAGGCAGGAGAATCGCTTGAACCCTGGAGGC

AGAGGTTGCAGTGAGCCAAGATCGCGCCACTGCACTCTAGCCTGGGTGACAGAGCAAGACTCCATCTCAG

168
chr21:
TGTAGGAGTCCTCCGGTGCTGGAGTCCAGAGCACAGTGAGGCTGGGTCCTCCCGTGCCATAGTGTAGGGCATGGCGGGACAGGGA

13974500-
TCCTGCCCTGCGATAGTCCAGTGCTTGAGTCCGCAGTAAGGCAATGGTCCTCCAATGCTGGAGTTCACGGCGTTGTGGGGTCGGG

13976000
GTCCTTTGGTGACTTAGTCCAGGGCGTACCAGGGCGGGGGTCCACAGTTGCCATAGTGAGGATCTTGGAGGAAGGTGGTTCCTGC

CTTGCTGTAGTCCGGGGAGCAGGGGGCAGGGGTCCTCTCTTGTCAGAGTCTCTGGCGCGGGGTGGGGGTGGAGGTGGGGGTTTTC

CTATGCGATAGCCCACGGGTCGGTGAAGCCGGGTCCTCCCGTGCCTTTGTCCAGGGCGCAGGGGGGCGAGGGTCTTCGGTGGTGG

AGTCCGCGGAGCGGCAGGACGGGGGTCCTCCAGTGCCATATTCCAGGGCGCGGCGGAGTGGGGGACCTGTCCTGCAGTGGTCCAG

GGCATGTGGGAGTGGTGGTCCTGCTGTGCCTCAGTCCAGTGCGCGGTGGGACGGCGGTCCTGCTGTGCTGTAGTGCAGGACGCGG

TGGCGCAGGGGTAGTCCAGAGAGCGCCGTGGCAGGGGGTCCTCCAGTGCTGGAATCCAGTGCAAGGCGGGTCAGGGGTCTTACCG

TGCCGAAGTCGGTGGCAAGGGTCCTCCCGTGCCATAGTCTAGGGGGCGACGGGGCAGGGTTCTCTAGTGCAGGTGTCCAGGGTGT

GGCAGGGCAGGAGTCCTCTTGTGCAGGAGTCCAGGACGTAGCCGAGGAGTCCTCCAATGTCAGAGTCCAGGGCTCTGCGGGGCCG

GGTTCCCCCATGCCAGAGTGTAGGGCGCGTTCAGGTGAGGGTCTTGGCGTGCAGTAATCCAGGGTGCGGTGGGGCAGGGGTAGTC

CAGACCTCCATGGCGGGCGTCCCTCTGTGCAGGAGCCCAGTGCCTGGCGGATCGGGGGTCCTTCTGTGCTGTAGTCCAGGGCACC

GCAAGGTGTGGGTCCTCTGGTGCCCTAGTCCAGGGGGCGGCGAGTCAGAGGTTCTCCCGTGTCTCAGTCTAGGGCCTGGTAGGAC

TGGGGTCCTGGAGTCCACGTGGTAGCCCAAGTTGCCGCAGGACCAGGTACTCTGGAACCACAGTCCAGGGCGCTGAGGGGCAGGA

GTAGTTCAGGGCGAGCCGGGGCCCAGGTCCTCGGGAGCCAGAGTCCAGGGTGTGGAGGGGTGGGGGTTCTGCAGTGGCACAGTCC

AGGACACCGCGGGGCGGGACAGGGCGGGGATCCTCCCGTGCCTTAGTCCAGGGCTGAGCCGCGGGAGAGGTCCTTCAGTAGCACA

GTCTAGCGCACGGCGTTGCAGGTGTCCTCCAGTGCCTGAGGCCACGGCAGGTCGCGGGTCCCACTGTGCTCTAGTTCAGGGCGGA

GTGGGTCTGAGGTCTTCTCCTGCCTCAGTCTAGGGCGCTGGAGAGCGGGGATCCT

169
chr21:
GGGTTGGTCCTAGAAAGCGTGAGGATCGCCGAGTGCACTGCCCTCCCAGCCTAGGGTCCACTCTTCCTTGGCCCGAGCCCAGAGC

13989500-
TCGGGGTTTCAGGCGCTGGGCCCTGTGCAGCTGCCCAGAATAGGCTGAGCGGCAGGTTCCCGCCCTGGCAAGGGATCCAGCAGTG

13992000
GAATCCTCACTGCTGTTGGCTGCGGGCAAGGTCAGCGGGGTTTCCATCGCTGCTGGTGGGAGCCACCTGGCGGTGGTAGCTGCAA

GTGAGCGCGTGGCAGAGACTGGCAGGGCTGGTCCCAGACACCCTGAGGGTCTCTGGGTGCATCGCCCTACCACCCTAGGGTCTGC

TCTTCCTTAGCCTGCTCCCAGGACGCGGTGTACGAGGGCTAGACTCTGAGCAGCCTCCAGGATGGGGCTGAGCAGCGGATTCCTG

CCCTGCTGCAGCTACAGTCTGAATTAGGCGCCACCGCAGTATCTGGCCCTGGGGTACGTGCTACTGGGTGGCATGGACAGAGATG

GGGGCTGCCACAGCTGCTATGGGGCTGAGCAGCCGATTCTCGCCCTGCTGCAGCGGGCGACCGCTGCAATCCCCAGCGCTATGGG

ACCGACCACCTGACTTAGATGCCTTGGAGGCATCCGGTCCTGGGGTCTTGCTGCTGGTGTCTGCGGGCAGGGTCACGGCTGCCAC

TACTACTGCTGTGCGCCATGGGCAGGTGCCAGCTGCAGCTGAGTCCGAGGCAGATGCTGTCAGGGCTGGTCTGAGGTTGCCTAAG

GGTGGCTGAGTGCACCACGCTTCCACCCCAGGGTCCGTTATTCCTAGGCCGGCTCCCAGATTGCAGGGTTGTGGGCGTTGGACAC

TGTGCAGCCATGAGGATCTGGTTGGGTGCAGATTCCCGCCCTCCTGCAGCTGAGAAGCCAATCTCATAACAGGCGCTGCAGTGAC

CTCTGGCTCTGCGGTCCGCGCTGCTGCTGGAGCTGGCAGAGAACAGAGCTGCCACCGCTGCTGCTTCCAGGAGTGTGCAGCTGGC

AGCTGCAGCTGAGCCCGTGGCGGAGGCTGGAAGGCCTTATTCCAGAAGCCTTGAGGGTCCCCGAATGCACCGCCCTCCCACCCTA

AGGTCCAGTCTTCCTTGCCCGCGCCCAGAGAGTTGGATTGCAGGCGCTGAGCACAGTGCAGGTGCTGGGATGGGGCTAAGCTGAA

AGTTTCCGCCCTCTGGCTGCTGCGGGGCCGACAGCCTGAGTTATGCGCCGCGGCGGCTTTTGGTCATGGGATCCGCACTGCCGGT

GGCTTGCACAGGGTCGGGGGCTGCCACAGCTGCTATAGTTCACCGTGTGCACGTGGCAGCCGCCCCTGAGCCCACCGCTGAGGCT

GCAGGGCTGGTCCGGTCCCAGACGGCCTGAGGGCCATTTGCCCGCGCCCAGATCCGGGTGGCTGCGCTGGGCACTGTGCAGCCTC

CCGGAATCCGCTGAAGGGCACGTTCCCGCTCTCCTACAGCTGTGGGCCGACTGCCTGATTTTGGCCACTAGGTGGAGTCTGGCTC

TAGGGTTTCGAGGCCGCTGGTGTTGGTGGGCGGAGTCCGGGTTTGCCACCGCTGCGCTCCATGAGCAGGTAGCAGCTGCAGCGGA

GCTTTAGACCGAGGCTGGCAGGGCTGGCCCCAGACGGCCTGAGGGTCAGGGAGTGCAGGGTCCTCCCACCCTAGGTCCGCTCTTC

CTTTCCCCTTACCCAGAGCGGGTTGTGCGGGCTCTGGGCTCTGTGCCGGCGCTGGGCTCTGTGCAGCCGCCGAGATGGGGCTGAG

CAGCGGATTTCCTCCCTGCTGCAGCTGGAGGACGATTACCTGCACTAGCCGCTGAGGCGGCATCTGGCCCTGGGTTACTGCAGCT

GGTGACGCGGGCAGGGTCAGGGTTGGTTGCAGGTGGCAGCTGCTGCTAAACCCATTGCGAGCCTCAGGGTCACCAAGTTCACCGT

CCTTTCATCATAGTATCTGATCTTTGGCCCGCGCCCAGAGTGCGGACTGGCCTGCGCTGGGGACTGCATAGCTTCTGGGGGCCGG

TCAGCGCCAGTTTCACGTCCTCCTGCAGCTGCGTGGCCTAAGGTCTTAGGCGCCGCGGCGCTATCTGGCCCTGCTGTCGACGCTG

CTGGTGGTGGGGACAGGGTCAAGGGTTGCCACTGCTGCTCCCGTGCGCCATCGGCAGGTGGCAGTTGCAGATGAGCCCACAATTG

AGGCTGTTGGGGCTGCTCCCAGGTTGTTAGAGGGTCGCCGAGTTCACCGACATGCCACCCTAGGTTACGCTCTTGGCCCGCACCC

AGAGCGCCGGGTTACGGGTCCTGGGCCCTGTGCAGCCACGGGGATGGTGCTGAGTGCAGGTTCCCGTCTTCCTGAGATGCGGGGC

GACCACTGGAATTAGCCTCTGTGGTGGTATCTGACCCTAGGGTCCGAGCTGCTGGTGGCGTGGGCGGGGTCGAAGTCGCCTCTGT

TGCTGCGGCGTGCCATTTGCACCGTCCTCTGGTAC

170
chr21:
AAATACTCTACTGAAAAAACAGAAATAGTAAATGAATACAGTAAAGTTTTAGAATACAAAATCAGCATAGAAAAATCAGTCGCAT

13998500-
TTCTATACCCAACAGCATACCATCTGAAAAAGGAATCAAGAAACCAATCCCATTTAAAATAGCTATAAAAAAATGCCTGGGAATA

14000100
AACTAAGCCAAATAAATATGTCTAAAATGAAAACTATAAAACATTGATAAAAATCAATTGAAAAAGATACAAATAAAGGGAAAGT

TATCCCATTTTTATGAATTAGAAGTATTAATACTGTTAAAATGACCATCATACTCAAATCAGTCTATAGGTCCAATACAATCTCT

AACAAATTTCCAATGTAATTCTTCAGAGATGTTAAAAAAGGTTTTAAAAATCGTTCTGCGGATGTTAAAAGGATTTTTAAAACGC

TTTTTTCGTTCTGCAGGCGAAGGCTGTGGCCGTGCTCCCGCCGGCCAGTTCCCAGCAGCAGCGCATTGCCCCTGCTCCACGCCTT

CGCTCCAGGCCCGCAGGGGCGCAGCCCCGCGGGAATCAGCACTGAGCCGGTCCCGCCGCCGCCCCAGTGTCCGGGCTGCGACTGC

GGGGAGCCGATCGCCCAGCGATTGGAGGAGGGCGACGAGGCCTTCCGCCAGAGCGAGTACCAGAAAGCAGCCGGGCTCTTCCGCT

CCACGCTGGCCCGGCTGGCGCAGCCCGACCGCGGTCAGTGCCTGAGGCTGGGGAACGCGCTGGCCCGCGCCGACCGCCTCCCGGT

GGCCCTGGGCGCGTTCTGTGTCGCCCTGCGGCTCGAGGCGCTGCGGCCGGAGGAGCTGGGAGAGCTGGCAGAGCTGGCGGGCGGC

CTGGTGTGCCCCGGCCTGCGCGAACGGCCACTGTTCACGGGGAAGCCGGGCGGCGAGCTTGAGGCGCCAGGCTAGGGAGGGCCGG

CCCTGGAGCCCGGCGCGCCCCGCGACCTGCTCGGCTGCCCGCGGCTGCTGCACAAGCCGGTGACACTGCCCTGCGGGCTCACGGT

CTGCAAGCGCTGCGTGGAGCCGGGGCCGAGCGGCCACAGGCGCTGCGCGTGAACGTGGTGCTGAGCCGCAAGCTGGAGAGGTGCT

TCCCGGCCAAGTGCCCGCTGCTCAGGCTGGAGGGTCAGGCGCGGAGCCTGCAGCGCCAGCAGCAGCCCGAGGCCGCGCTGCTCAG

GTGCGACCAGGCCCTGTAGCTGTGACTTGGCTGTGGGGCTGGCCCGCCTCCCTGACCCCTGTCAGGCGGAGCAGCTGGAGCTGAC

CCACGGGCCTGGGCTTTCGAGCGCTTTGTCCAGGCGCTAATGATGGGAAGGTGAAAGGTGGGGGTGGCCACACCCTGCAGTCAGG

GTGGCAGGTGTCAGAGGCCACATGCAACCCACTGGTTTTGTCTTTTCCAGGATGCTGATAAGTTTCCCGCGGCCCCCGGAGCAGC

TCTGTAAGGCCCTGTAATTGCCTTTCGTTCCCTTCTGCTCTATTGAGGAGTGGGAAGATGACAAAGTGTTTTTGCTCAACCCGAA

GGAAAATGCACATGGGAGGACACACCGGGTTACTATTTGAGTAGCCCAGACAGGAGAGCAGCGGTCTGCT

171
chr21:
TGGGTGGATTGCTTGAGCCCAGGAGTTCGAGACCAGCCTGGACAAAATGGCAGAAACTCCATGTCTACAAAAAATACAAAAATTA

14017000-
GCCGGGCATGATGTTCTGCGCCTGTAGTCCCAGCTACTCAGGAGGCTGAGGTGGGAGGATCGCTTGAGCCCAGGAGGCGGAGTTT

14018500
GCAGTGAGCTGAGATGTCACTGCATTCCAGCCTGGGAGACAGAGCCAGACTCTGTCTCAAAAGAAAAAAAAAAAAGAAAAAAAGA

AAAGAAAAAACGAAATTGTATTCTGAATACATCTTCTAAAACACTACATTTACTTGCACTATATTAAACTGGTTTTATCCTGACC

ACAATTGCAGGTGAAAGATACCACTGTTGTTCTATTTTTCTGGTAAGTAGAGTGAGCCATGTCTTCCCCAGGGAAAGACGCCTCC

TAAAAATTTGTAGGACCACCTTTGGTTTTCTTCCAGATATTTTTTTTGTCATCGCTTTTCCTGCGCCCAATTCCCATCTGTCTAG

CCCTTCTGCCTCCGCTGGTCTTTTTCGCGAGCCTCTCCCCAGCCGCAGGTATTCGTCTGGGCTGCAGCCCCTCCCATCTCCTGGG

GCGTGACCACCTGTCCAGGCCCCGCGCGCTCTGTGTGGTCGCTGCTGCAGTGTTGTTGTGGCTGTGAGAAGGCGGCGGCGGCGGC

GGAGCAGCAGCCGGACCAGACTCCCTAGTAGCTCAGGCGCTGCCCTGCGCCGGCCCTGGCAGGGAGCCTGGTGAGATGGTGGAGG

AGGAGGCTGTGCCGTGGCTGGCCTTGCTGTGTCCTGCTGCCTGGTTAGAACCCCATCCCCGTCCCCCGTCTCCTCCGGGGGGTGA

GGAGGAGCTGGAAGAGGGGCCGGCCTCTGTCCGGCCCGGCCAGGCGGCAGTCACCCTCTGAGGAGGCAGCGCCCGGGGAGGGGCC

TCCCAGGCGGCCGCCGCCGCCAGGGGGAGGCGCTGGGAGTGGGAGTGGGAGCGGGACCTCAGCTGCCAAGCTCGGCCCGGACCCT

AGGTGCGGGGGAGGCGGGGTCCCGGGCTCGGGCTGCCTGCCCGGACCTGGCGGGGATGGGCCCGTGCGGCTCCGGGTGTGGGACG

TACCCTCAGAGCGCCCGGGGTTATTCCCACTGACTCCAGGGAGGTGAGTGTGCGCCCTTCGCTCCCTGCCGTGTCTGTGAGGGTC

CATCGTTGCCGGAGACTGGAGGTCGGGGGCCATGGGAGCCCCGGGGCGAACGGTGCGGACATGGGCCTTGTGGAAAGGAGGAGTG

ACCGCCTGAGCGTGCAGCAGGACATCTTCCTGACCTGGTAATAATTAGGTGAGAAGGATGGTTGGGGGCGGTCGGCGTAACTCAG

GGAACACTGGTCAGGCTGCTCCCCAAACGATTACGGT

172
chr21:
GTCTCTAGGACACCCTAAGATGGCGGCGAGGGAGACGGTGAAGGTTGGCTCCCGCCTGTCTGGGCTCTGATCCTCTGTCTCCCCC

14056400-
TCCCCCTGCGGCCGGCTCATGGCCTGGCGGAGGCCCGAACCAAAGACCTCCGCACCGCCGTGTACAACGCCGCCCGTGACGGCAA

14058100
GGGGGCAGCTGCTCCAGAAGCTGCTCAGCAGCCGGAGCCGGGAGGAACTGGACGAGCTGACTGGCTAGGTGGCCGGCGGGGGGAC

GCCGCTGCTCATCGCCGCCTGCTACGGCCACCTGGACGTGGTGGAGTACCTGGTGGACCCGTGCGGCGCGAGCGTGGAGGCCGGT

GGCTCGGTGCACTTCGATGGCGAGACCATGGAGGGTGCGCCGCCGCTGTGGGCGCGGACCACCTGGACGTGGTGCGGAGCCTGCT

GCGCCGCGGGGCCTCGGTGAACTGCACCACGCGCACCAACTCCACGCCCCTCCGCGCCGCCTGCTTCGAGGGCCTCCTGGAGGTG

GTGCGCTACCTGGTCGGCGAGCACCAGGCCAACCTGGAGGTGGCCAACCGGCACGGCCACATGTGCCTCATGATCTCGTGCTACA

AGGGCCACCGTGAGATCGCCCGCTACCTGCTGGAGCAGGGCGCCCAGGTGAACTGGCGCAGCGCCAAGGGCAACACGGCCCTGCA

CAACTGTGCCGAGACCAGCAGCCTGGAGATCCTGCAGCTGCTGCTGGGGTGCAAGGCCAGCATGGAACGTGATAGCTACGGCATG

ACCCCGTTGCTCCCGGCCAGCGTGACGGGCCACACCAACATCGTGGAGTACCTCATCCAGGAGCAGCCCGGCCAGGAGCAGCTCA

TAGGGGTAGAGGCTCAGCTTAGGCTGCCCCAAGAAGGCTCCTCCACCAGCCAGGGGTGTGCGCAGCCTCAGGGGGCTCCGTGCTG

CATCTTCTCCCCTGAGGTACTGAACGGGGAATCTTACCAAAGCTGCTGTCCCACCAGCCGGGAAGCTGCCATGGAAGCCTTGGAA

TTGCTGGGATCTACCTATGTGGATAAGAAACGAGATCTGCTTGGGGCCCTTAAACACTGGAGGCGGGCCATGGAGCTGCGTCACC

AGGGGGGTGAGTACCTGCCCAAACTGGAGCCCCCACAGCTGGTCCTGGCCTATGACTATTCCAGGGAGGTCAACACCACCGAGGA

GCTGGAGGCGCTGATCACCGACGCCGATGAGATGCGTATGCAGGCCTTGTTGATCCGGGAGCGCATCCTCAGTCCCTCGCACCCC

GACACTTCCTATTGTATCCGTTACAGGGGCGCAGTGTACGCCGACTCGGGGAATATCGAGTGCTACATCCGCTTGTGGAAGTACG

CCCTGGACATGCAACAGAGCAACCTGGAGCCTCTGAGCCCCATGAGCGCCAGCAGCTTCCTCTCCTTCGCCGAACTCTTCTCCTA

CGTGCTGCAGGACCCGGCTGCCAAAGGCAGCCTGGGCACCCAGATCGGCTTTGCAGACCTCATGGGGGTCCTCACCAAAGGGGTC

CGGGAAGTGGAATGGGCCCTGCAGCTGCTCAGGGAGCCTAGAGACTCGGCCCAGTTCAACAAGGCGCTGGCCATCATCCTCCACC

TGCTCTACCTGCTGGAGAAAGTGGAGTGCACCCCCAGCCAGGAGCACCTGAAGCACCAGACCATCTATCGCCTGCTCAAGTGCGC

173
chr21:
TAAAAATAAATTGTAATAAATATGCCGGCGGATGGTAGAGATGCCGACCCTACCGAGGAGCAGATGGCAGAAACAGAGAGAAACG

14070250-
ACGAGGAGCAGTTCGAATGCCAGGAACGGCTCAAGTGCCAGGTGCAGGTGGGGGCCCCCGAGGAGGAGGAGGAGGACGCGGGCCT

14070550
GGTGGCCAAGGCCGAGGCCGTGGCTGCAGGCTGGATGCTCGATTTCCTCCGCTTCTCTCTTTGCCGAGCTTTCCGCGACGGCCGC

TCGGAGGACTTCTGCAGGATCCGCAACAGGGCAGAGGCTATTATT

174
chr21:
CGCCACCACGTGCGGGTAGCGCCGCATCGCCCCAGCCGTGTTCCTTGGTCTCCGTCTCCGCCGCGCCCGCCTGGTGAACTGGAGC

14119800-
ACAGGGACCATAGTTCTGGAAATTTATCCTTTTTCTCTCCATGGATTCAGCAGCAGTGTCTAAAAGAAAAAAATTCATCAATCAT

14120400
TTATGTATATTTTAATATAAAGGTAAAACACTGCGAACCAGTGGAACCGGATAGAAAGTAATTCAGTTTTACAGAACACAACTGT

TTTTCAGGCTCTTTTATTAAATATAAAAGAGCCATATATATTTCTGTGGAATTCAAAATTCAACATTTTATTTTATTTTTGAGAT

GGAGTCTCGCTCTGTCGCCCAGGCTGTAGTGCAGTGGCGCGATCTCGGCTCACTGCAACCTCAGCCTCCCGGGTTTAAGGAATTC

TCTGCTTCAGCCTCCTGAATAGCTGGGATTACAGGCGCATGCCACCAAGCCCAGCTAATTTTTTTTGTATTT

175
chr21:
CCCTGAACAGTCAGAGTTTACTGCCCACTTTTGCTGGAGGAGAAGCTCCTGAACAACTAGAGAGACTGTGGTTCCCAAAGAGCAG

14304800-
CCTGTAGGCCTGAGGACTGCTCTATGACCGGCGTCAGTCCCTGCCTCCCTCCCTCCGTCCCTCCTTCCCTCCTTCCTTCCCAGGC

14306100
CTTCTCTGACTACCAGATCCAGCAGATGACGGCCAACTTTGTGGATCAGTTTGGCTTCAATGATGAGGAGTTTGCAGACCATGAC

AACAACATCAAGTGAGTCCACTTGGATGCCCCCTGCACGAGGCACGACTCCCCCTCCTCGCTGCTGAAGTCCCATGGGGGCAGCT

CCCTTAGTCCTTGCCGGGAGATAACAGGTGTTTCCAGTTGCATGAGGGTGCTGAGGCCCCCAGTGAGAACCAGGGGAGGAGCACT

GAGGCCTCAGATGAGCACCGGGGGAGGAGCCCTGAGGCCCCAGATGAGCACCAGGGGAGGAGCACTGAGGCCCCAGATGAGCACC

GGGGGAGGAGCGTTGAAGCCCCAGATGAGCACCAGAGGAGGAGAGCTGAGGCCCCAGATGAGCCCCGGGGGAGGAGCTCTGAGGC

CCCAGACGAGCACCGGGGGAGGAGCGCCGAGGCCCCAGATGAGCACCGGGGGAGGAGCGCCGAGGCCCCAGATGAGCAGTGGGGG

AGGAGCCCCGAGGCCCCCAGATGAGCAGTGGGCGGGGCAGGGAGCGCCGAGGCCATCCCCCTTGCTCTTGCAGCGCCCCATTTGA

CAGGATCGCGGAGATCAACTTCAACATCGACACTGACGAGGACAGTGTGAGCGAGCGGGGCTGTGCGGGGTCATGCAGGCACCCT

GTTCCCAGGCAGCTCAGGCCGCGCCCATGGCTCGGTCTGTGGTGGGCCTGTGCGGTGGGGCTGGGAGAGGCCCCTCTGTGGAGCT

AGGAACAGTCGCTTTTCTTGACCCTCCCCATCATGCCCTCCAGCCCATGGCGCCCACATCCTGAACTAAGCCCCTCTGGGAGCCC

TGTGGGGAGAGCGCCTCCTGTCTCCCCCAGACCCTCTGGAAACTGACCTTGGCGTTTTACTCTGCAGCCCAGCGCGGCTCTGAGG

CCTGCTGCAGCGACCGCATCCAGCACTTTGATGAGAACGAGGACATCTCGGAGGACAGCGACACTTGCTGTGCTGCCCAGGTGAA

GGCCAGAGCCAGGTGCGGGGCCTGCCCATCCCCCCAAAGCCTCTGCCGAGGAGGTGCAGCCCCCAGAACACCCGTCAGATGCCCA

GACGCCCTGCTGTTTGTTATGCCGG

176
chr21:
TTTGGGCCACGAGGCAAGTTCAAAGCGGGAGACTTTTGTTTTATAAAATGATGGTGAGCAGCTCCGGTTTTATGTCAAACATCAG

15649340-
GGTTTCGTGCAGGATATAAACATTT

15649450

177
C21orf34
ATTGCCGTACTTTGCTTCCCTTTGTATGTATTTCTTGTATGCTGCCGAGTCACTGATGGCTAGCTCTGTCTGGCAAGTAATTCAA

AAATGCTGTTTATGTAGAAAGGAAAGGTAGGGACTTTACCACACTCTGTCATTAAAGGGAGCAATTGAAGAACAAAGGAACTGAG

TAAATACCTATATATTGCCTTTTGTGTTGCGAAACACTGTAGCACAAACACATTTGTGTTCAGCCAAATGTTTTACTTCCTTTTG

TAATAACGCATATAGTAGGTTGTCTCCACATATGTACAAGAATCCATATTTTATTTAAACGTATATAGTCAATTGTTCATATTTA

TAGGCTGCAAACATTTCTCAATCTCAAAGACTTTTACATATCCACTCCCACACAGCTATTTGTTATTATTTTAAAGTTCTTAAAT

TAAAAAAAAAAAATAAAATATACTAATATCTCTGTTGGTTGATTTTATTAAGCAACTTAGGATTTCAACACAGTTTAAATCATAT

TGATGACTCAGATCCTGGCAGGTCTTACAATTCCTGTGAAATGAGAGCACAGCTAATAAAAATATTAAGCAATTACTTTTATTAA

AATCATAGGGTTTTTTTCATTATCACATAGAAATGATTGATCTATACAGATTGGTCTCACTCATGTGTCTTTTGGGCTGCTTGGG

AGCTTCATGTAGAAGTGGAAAGTCCCCTTTGCTCTTCCTTCGACCAAGGTGGGGAAAATGAAGGCATAGAATACAATCTAGGGCT

ATTAAAGAATTGCTGGCATTACTTCTCTCTATCACGTGTGAGCCTGGCTGCCTGCTTCCTGAGGTAGGGGATCCAGGATGAGACT

GTGCCGGAGCCTGTTTCCACAACTGCATTTGGAGATCCGTCTTATTGATTAGCGGGGGAAAGGGGTGGGGATCAGGAGTGTGAGG

TGAGGGGAGGACCAACTGACGACTGGCTCAATGAAGCACAAGACATTTTCTTCCGGAAAGATGTCAAACAACTGAGAAACAGCCA

GAGAGGAAGTAGAAAGGTGGAAAAATGAGGAGACCCTGGAAGAAATGAAGGCATTTCCTATGAGACAGCCTTGGGGCTTTTTTCT

TTTCTTTCTTTTTTTTTGCTTCCATCATCTGACCTGCAAAGGCTAGAGTGACAGCGTCATGCAAATGCTGCAGTCCAGCAGGTCT

GGGAGAGGGTGGATGCTAGACTGTGAGTTAATGTTAATGATGAGCGCAGTGAAAATACCAGCCGCTGCCACCCCCTGCTCACAGA

AGCGCTCTGAGTCAGCATCAGATGCTTTGCCTCGCCTCTCGCTGTGTATCTGTATGCCTGTGTGCGCGCGCGTGCTCGCTCGGGC

ATCCGTGTCTAGCCGAGGGGAGGGGGTGGCGTGTGAGTGCGTGGAGGGTAAAAGCCAGTCAGTCAGTGAGAAGCAAAGGTACGTT

GGAGAGCAACTAAAATCTGACTGATTTCCATCTTTGGAGCATCAGATGTATTCCC

178
BTG3
GCAGCCTCCTCCTGAAAAATGTAAGCCATTTCCACTTTGTAAAGCTACGTTTATATTCCACCACGATACGATGGAAAAGAAAACC

CAAGGCAATTTAATATACGGGTTGGGAAGAAAGTTTTGCTGATGGAACTACATTAGCCTCCACTCCAGCAAAGCAAACAAGGAAC

CACACTAAAGAAATGTACTGAATCTTTTAA

179
CHODL
TGCCTGAGCGCAGAGCGGCTGCTGCTGCTGTGATCCAGGACCAGGGCGCACCGGCTCAGCCTCTCACTTGTCAGAGGCCGGGGAA

GAGAAGCAAAGCGCAACGGTGTGGTCCAAGCCGGGGCTTCTGCTTCGCCTCTAGGACATACACGGGACCCCCTAACTTCAGTCCC

CCAAACGCGCACCCTCGAAGTCTTGAACTCCAGCCCCGCACATCCACGCGCGGCACAGGCGCGGCAGGCGGCAGGTCCCGGCCGA

AGGCGATGCGCGCAGGGGGTCGGGCAGCTGGGCTCGGGCGGCGGGAGTAGGGCCCGGCAGGGAGGCAGGGAGGCTGCAGAGTCAG

AGTCGCGGGCTGCGCCCTGGGCAGAGGCCGCCCTCGCTCCACGCAACACCTGCTGCTGCCACCGCGCCGCGATGAGCCGCGTGGT

CTCGCTGCTGCTGGGCGCCGCGCTGCTCTGCGGCCACGGAGCCTTCTGCCGCCGCGTGGTCAGCGGTGAGTCAGGGGCCGTCTCC

CCGAAGAACGAGCGGGGAGAGGGGACCACGGGGCGCGGCGGGCAGCCTGTTCTCGGGCGGAGGCTCTCCGGGGCGTTGGAAACCT

GCATGGTGTAAGGACCCGGGAGGAGGCGGGGAGAAATTGATTGTGCTGTTCTCCTCCCTCTCTTCTCTAACACACACGCAGAAAA

GTTTAAATTTTTGTGAAGCGCTTGCTTACGTAGCTGCGGAGCGAGCCTCTGCTTCATTACGAGCGGCATAGCCTTTTTCAGGAGT

GATTTCCACTTTCTTTGTGAGAGAGTTGACCACAC

180
NCAM2
TTCAATTTACACTCGCACACGCGGGTACGTGGGTGTTCGGGGTAGGGCACTGATCTGGGGAAGGTCTCCCCCCCGCGACCCAACT

CATCTTTGCACATTTGCAGTCCTCCCTCGGTGCACTCCTGGCGGGGATCTGGCCAGTGCAGCGCACTGGGACCGAGGGCAGAGCC

CGCGGAGTGAGGCCAGGAGAGACTTCAGGCCTCTAAGGACACAGCTGAGGCTAAGGCTGAGTTGAACGCAGCCCCTCCCGCGGCT

CGTCCCCTCTCCAGTGTCTCTCCCGTAAGGTGCCGCTCCCAACAGCAATGGGTCGAGATGTAGAGGAAACACTCTGTACGTTATT

TTTCCGCCCACCCTTTAGCGCCTGAGGAGACAGACAGTGTAGACTTTAGGGTACAATTGCTTCCCCTCTGTCGCGGCGGGGTGGG

GAGCGTGGGAAGGGGACAGCCGCGCAAGGGGCCAGCCTGCTCCAGGTTTGAGCGAGAGAGGGAGAAGGAGGTCCACGGAGAGACA

AGAATCTCCCTCCTCCCACGCCCAAAAGGAATAAGCTGCGGGGCACACCGCCCGCCTCCAGATCCCCCATTCACGTTGAGCCGGG

GCGCG

181
chr21:
TCATTATCCGATTGATTTTCCTGGTATCACATCACTTAAGTTTAAGTAGCTCTTATGTTACTTAGTAATGACTGCAAAACACGAG

23574000-
TTGTGATGCGGGCAATTTGGATACAACAAAAAGAAGCCATTAAGTTTGTTCGTTAGTTAACAGGTGAAAGCTCTCAAGTTATTAA

23574600
GGATAAAAATGCTAGTATATATATATATGGTTTGGAACTATACTGCGGATTTTGGATCATATCCGCCATGGATAAGGGAGGAATA

CTATAATCAGGTTTGTTTTAAATTCCATGTCTAATGACTTCGTTATCTAGATCACCTGTAGAGCTGTTTTTATTGTAGGAGTTTT

CCTTGGTTTTAATCTTTTGATTTGTTTTTCATGTTAATACTGAAATTTTTAAAAATTGCATATTGTACTTCCTATATGAAAATTT

TACTATGTATTTTTATTTTTATTTTCCTTTTCCTTTAGGAAGAATTAGTTTGTTCCCTGACAGAGTTAGAGTAAGGGCAAATTAC

TTGTCTCTATAAACAACTCAGATGTTTTGAGCCGGTGTTGTAGGGGTTATCTTTTTCTGGTTTTGCATTTTATTATAGGACATAG

TGCTT

182
chr21:
AGAAAGAAGAAATCCGGTAAAAGGATGTGTTATTGAGTTTGCAGTTGGTGTTTGATCTTGCACAGATTTTCTCAGGGGCCTTAAG

24366920-
ACCGGTGCCTTGGAACTGCCATCTGGGCATAGACAGAAGGGAGCATTTATACGCC

24367060

183
chr21:
CGAAGATGGCGGAGGTGCAGGTCCTGGTGCTCGATGGTCGAGGCCATCTCCTGGTCCGCCTGGCGGCCATCGTGGCTAAACAGGT

25656000-
ACTGCTGGGCCGGAAAGTGGTGGTCGTACGCTGCGAAGGCATCAACATTTCTGGCAATTTCTACAGAAACAAGTTGAAGTACCTG

25656900
GGTTTCCTCCGCAAGCGGATGAACACCCACCTTTCCCGAGGTCCCTACCACTTCCGGGCCCCCCAGCCGCATCTTCTGGCGGACC

GTGCGAGGTATGCCGCCCCACAAGACCAAGCGAGGCCAGGCTTCTCTGGACCGCCTCAAGGTGTTTGACCGCATCCCACCGCCCT

ACGACAAGAAAAAGCGGATGGTGTTCCTGCTCCCTCAAGGTTGTGCGTCTGAAGCCTACAAGAAAGTTTGCCTATCTGGGGCGCC

TGGCTCACGAGGTTGGCTGGAAGTACCAGGCAGTGACAGCCACCCTGGAGGAGAAGAGGAAAGAGAAAGCCAAGATCCACTACCG

GAAGAAGAAACAGCTCATGAGGCTACGGAAACAGGCCGAGAAGAACATGGAGAAGAAAATTGACAAATACACAGAGGTCCTCAAG

ACCCACAGACTCCTGGTCTGAGCCCAATAAAGACTGTTAATTCCTCATGCGTGGCCTGCCCTTCCTCCATCGTCGCCCTGGAATG

TACGGGACCCAGGGGCAGCAGCAGTCCAGGCGCCACAGGCAGCCTCGGACACAGGAAGCTGGGAGCAAGGAAAGGGTCTTAGTCA

CTGCCTCCCGAAGTTGCTTGAAAGCACTCGGAGAACTGTGCAGGTGTCATTTATCTATGACCAATAGGAAGAGCAACCAGTTACT

ATTAGTGAAAGGGAGCCAGAAGACTGATTGGAGGGCCCTATCTTGTGAGC

184
MIR155HG
GCCTGAAGACCATTTCTTCCTCTCTTAGGGACCTGCTGGTCTCCAGCTGATTCGGTCCAGGAGGAAAAACCTCCCACTTGCTCCT

CTCGGGCTCCCTGCAAGGAGAGAGTAGAGACACTCCTGCCACCCAGTTGCAAGAAGTCGCCACTTCCCCCTCCAGCCGACTGAAA

GTTCGGGCGACGTCTGGGCCGTCATTTGAAGGCGTTTCCTTTTCTTTAAGAACAAAGGTTGGAGCCCAAGCCTTGCGGCGCGGTG

CAGGAAAGTACACGGCGTGTGTTGAGAGAAAAAAAATACACACACGCAATGACCCACGAGAAAGGGAAAGGGGAAAACACCAACT

ACCCGGGCGCTGGGCTTTTTCGACTTTTCCTTTAAAAAGAAAAAAGTTTTTCAAGCTGTAGGTTCCAAGAACAGGCAGGAGGGGG

GAGAAGGGGGGGGGGGTTGCAGAAAAGGCGCCTGGTCGGTTATGAGTCACAAGTGAGTTATAAAAGGGTCGCACGTTCGCAGGCG

CGGGCTTCCTGTGCGCGGCCGAGCCCGGGCCCAGCGCCGCCTGCAGCCTCGGGAAGGGAGCGGATAGCGGAGCCCCGAGCCGCCC

GCAGAGCAAGCGCGGGGAACCAAGGAGACGCTCCTGGCACTGCAGGTACGCCGACTTCAGTCTCGCGCTCCCGCCCGCCTTTCCT

CTCTTGAACGTGGCAGGGACGCCGGGGGACTTCGGTGCGAGGGTCACCGCCGGGTTAACTGGCGAGGCAAGGCGGGGGCAGCGCG

CACGTGGCCGTGGAGCCCGGCCTGGTCCCGCGCGCGCCTGCGGGTGCCCCCTGGGGACTCAGTGGTGTCGCCTCGCCCGGGACCA

GAGATTGCGCTGGATGGATTCCCGCGGGCAGAGGCAGGGGGAAGGAGGGGTGTTCGAAACCTAATACTTGAGCTTCTTTGCAAAG

TTTCCTTGGATGGTTGGGGACGTACCTGTATAATGGCCCTGGACCAGCTTCCCTGTTGGAGTGGCCAGAGAAGTGTGTAAAACAC

ACTAGAGGGGCAGGGTGGAAAAAGAGACTGCCTTCAAAACTTGTATCTTTTCGATTTCATTTTGAAAAATAACTACAAATCTATT

TTAATTTTACAAAGTTAGACTCATAGCATTTTAGATATCAATGTCTTCATTTAACAGAAGTGAAGATGGAGCAAACGCTCAATCA

GCGTCTGTATTTATTCGCTCCTGTTGTGCCAGGGTGCGTTTTTGCCGAGCGGTTGCCTTTCTTTACTCACAAAACCCCCTTGATG

TCTGTCCTCCACGTTTTACGAGGGAGAGCCGGATCTTTTGAAGTTTGTATCATCTAAAGCAGGTATATTGGGATGACTATGGATA

GAATTTAACCTGAAAACACTGAAGTTGACAGCTGACAAAG

185
CYYR1
CATAACAAGAGTCATTCTAATGTGATTATAAAGGACCCGAAGCTTTGCTTTTAAAATTCAATACTTAGGTAGAAAGAAAATGATA

ACTTTTTCCCTTTGATTTTTATTCACTATTTTTATAACACTAGCAGCCCTGAGACACCGGATTGGAAATATCTATGCCTCTTGAT

GTTACCTGGGCACCACTGCATCACAGTCCT

186
chr21:
AATAGTAATTGCCAACAGTCAAGATATGTACTACCACCAAATTCCGTGTTATTTGTGATCAAAAGATATACACAGATACTTGAAA

26938800-
ACTGATTTCTACGTTGCATATGGGAAAAATACCTCATTTTTCTCAGCTGTCCATTATTTTTGAGATATTATGTGCAGTGATAGTA

26939200
AGAACAAGCAGATTTGGAACACATCAGCAATAATTTTTTCAATCAGAGTCCTGCCAAAATGAAAGAATTTGACAGTATCCGGCAC

CCTGTACTCATGCTTGGCTTCTGTAGAAACTGTGGCTTGCAAAAGGGCAGCTGGGTACTGTGTTTTGGTACCTCATTCTTTAAAC

GTATAATGGGAATCTGGTTGGTTCAGGAAAACCCTTGCCTACTTATTATTACTCTGTTTT

187
GRIK1
GGCCCATACTTAATGTATTTTTAAACGTTTTAACATTTACTAATATAGAACCTTCTATTGCCTATTTCCTTCTGGTTTATTCCCT

TTCCTTCTGTCATTGAAGAAATGGTTCTAGTGGTAGAAATACTCCACGATTGAGAAGAATGTGGGAAGAAAGGAGGGCTGGTGGG

TAAGAATTGCTCATGATGTCTCCCTCTGAATTCTGTGCTCTCACAATGACACTCCAATGTGTGGTTTGACGCCTGGAAGA

188
chr21:
TGCTTCAACCGGAAATGTGGTTGAATTACCCTTACAGTGAACCTGATCAGTGGTAACAGGAGATGCTAGAACAGGAAAAGACAAG

30741350-
TTTCCCCTTTCCTCCCTATCCCATCAATTACTTTGAGGTGTATTTTTTCTTTGCAACCCCTCCAGAGAAGTCGGCAATGTTTAAC

30741600
GAGCATGCCTGCCAAGTGGCTTGCCTTATACCTCATTATGAAGTGATACTCAGGGCCACTAACACATCGCACAGCATTGC

189
TIAM1
TATGATTCCCTCGATTTCCCTCAATCTTAACCATTGTGGATCACAGCAGGAGGGCCAGAAAGTGAGCTTCAGCCTGGCACCGGGA

CCTCAGCCTCTCCCTTAAACTTTCCCTAATCCTCGGAGCTAGTGTTACTCAAGTGACTCCACAGTGTTGCCCGATCCCTTCAGAC

ATGGCCTTGATGATCTCCAAAACTCATGCTACCTTTGCCAGCCTAAAGCATCCACTCTGTGCCCCAAAACGTGAATGTCAAATAC

CCTTCAAGGCAGAAGGCTATTTCTATTTTTGTTTGTTTCTGTTTAAGGCAACAATCACCAACATTTGGTACACATGAGCCATCCT

GTGAAACATCAAGGCGCTTCGTTGGCAGCAAGTCAACTTCGGTTTCAGAAGAAAGCTGCACTATTTCCTGAGGTTAGAGGTTTAA

ACCAAAACAAGACAACCACATTTTAACCCCAAATCTGCCGACTGAGGGTAACCATGATCCTTCCTTCACAGCACC

190
TIAM1
TACTAAATCAACCCAAACCCGAGAACCCGGTCATGGAGAAATAAATGATAGTAATCTATGCTGTTCATCTGTTCCATCACTCACT

CACTCTCTTGCTGAACAAGAAAGGGCCACCCATGTAGCAAACCACATGTAAAGAGCCGGGAAGAC

191
TIAM1
TATTATTTTGTTCAAAGTAGACGGGTATACTAACATCTGTGGGCAAGTTTACCACACGCCACTTAAAACAGGCTAACAGGGTCAT

ATGCCAAAACGTTCAGGTTTGCATTTTTGAAAAGCTCAGAGATCTGACAGATGTGTTCCGGCCGCGATTTAACATGCGGCTCCAG

TGAGAAGGAAGCAGATATGACAAATGGTTCACTTATTTCAGAACTAAAACCCCAGAGGAGCAGCCTGAGCCAAAAAGGGAAGTGA

TCAATGGAAAAGACGGTCGAATCTGCTCACAGGCAAGGCAAGGGG

192
SOD1
AAGACCTGGAGTTTCCATTACACCGAATTGGCACTTAATAACTGTTGTCGGAGCATTTCTTAAGCCACATTTTCGTAAAGTGGCT

TTAAAATTGCTCTGCCAGTAGGCAGGTTGCTAAGATGGTCAGAGACAAACTTCTGAACGACTCTTGTAAAATATACAGAAATATT

TTCAGAACTTTTATCAGTAAAATTACAAAACGTGTTGCAAGGAAGGTGCTTGTGATAACACTGTCCCCAGAACCTTAGTGAAGTT

ACCAACTGGTGGAAAATTTTCTCTTGCACTCGGCTTAAAAATCAT

193
HUNK
GCAGGGGTGACTGGTCCTCTCTCTCTGCACCTCGCAGGATTTCTCTGGAAGATCTGAGCCCGAGCGTCGTGCTGCACATGACCGA

GAAGCTGGGTTACAAGAACAGCGACGTGATCAACACTGTGCTCTCCAACCGCGCCTGCCACATCCTGGCCATCTACTTCCTCTTA

AACAAGAAACTGGAGCGCTATTTGTCAGGGGTAAGTGCGACCCTAGAGGCGATCGTCTCTGCTGTCTGTGGAAAAAAGAGCTCCT

ACACCCAAAGTGCTTCTCAGTTGCTGACACTTGATCCAAGCTGCTAATTTAATCTAATGTGAGGCTGAGTTTTCTGAATGTGGGA

TAAAGTCGTAGCTAAACCTGCTTCTCAGGGAGTGCCTTTTATCTGCAATGTTTTTCAAAT

194
chr21:
AAGTAACGGGATCAAATTAATTATTATTTTGGTGGCCGCCTCTCTTCTCCACCCCAAGCCAGGCAAGACTCACCCTCGGCCCTGC

33272200-
CCGCCCCAGCATTTCAAATGGAATACCTAGGTGGCCCAGGGGGACCCCTGACCCCTATATCCTGTTTCTTTCTGCCTGCTTTGCT

33273300
ACTTTTCTCCTTGATAAAAGGAGAGAGTGAGAGATAATTAACAAAAAACATGGCCCCAGGACAATGAAACAACTGGCCTTGGCCG

GCCAGAAATGTATCCTGGTTTTCTAGGTGAACTTTCTCCCATCAATCTTTCCTTTAACCTCTCTGTTAGTGGAAGCAATAGGAAC

ACCCCTCCCCTCCCCTGAGCAAATGCTTTCTTTTGACTGGAAACAAAACAGGGGCTCGGCGAAGGCTGAGGTGAAATCTGGGTGG

CATGGGCGCCGCACAATGGGGCCGCTGTTCCCCGGCCCGGGCTTGTGTTTTACAACAGGGGAGGGGCGGGCGTGAATGGTCTGAT

GATTGGAACAATCCCCCCGATTCAGGCCTACAAACGCATCTTCTGTTCCACACCGAGGGGACAGAAAGGAGAAAAGTGACAAAGA

ACGCGGGGCGGGGGGAATTAAAACAAAATGCGCTCGACTAAAAAATCTCTCATATCCTGCATATTCCAGAAAGCGGCTCTATGGA

GAGAGCCTTCAGGAGGCCTCAGCCATATCTGAATGGCTTTCTCTGGCCTCTGATTTATTGATGAAGCTGAAGCGACTTGCTGGAG

AAAGGCCTGGAGCCTTCTTTGTCTCCGAGATGAAGTACAATAGGCCACAGGGCGGAGATCTCTTGTGATGCTCTCGGGTCCTGCC

TTTCTCTTGCCCTCTCCTCCCTGCAAATACCAGCAGCGGTGACAAACGATTGGTGGTGTGCCTGGGAGAGCCGGTGACAAGACTG

GGCCACTTGAGGTCTCCTTAAGAGGGTATTATGGCCAGGGCGACGTTTGTGCTGTGAAGATGGCACACTCCATTTTGTCAATGGC

TCTCATCGGCCCAGATAATCGCCCCCTGCCTGCCTGTCAGGGGCGCAGCCGGCCGATTCATGGCGCCCTCGGAGAAAGTA

195
OLIG2
GTCTTTCCCGCCCCCTTGTCTAAACTCAAAACCGAGTCCGGGCGCGCCTTGCAGGGCGCCCGAGCTCTGCAGCGGCGTTGCGGGC

TGAACCCATCCGGCACAAACTGCGGGCCACTGGCCCCTCACACCTGGGAGTTTGCGGCGCTGGCCTGCAGCCCGGGGCCCACGTG

GCGGAAGCTTTCCCGGGCGCGCGCTGCGCAGCCCCGCGGGGCCGGGGAGACACCGCTCGGGAGTCCTCCGCTCGGCTGCAGAATC

TTTATCAGCTGCACTTTACCGCAGCCCTGGCTAGGACGCTAGGCGGTGGAGCGCCCTATCCAGGTGCGCCGCCGCACCATGGATC

ACCGCGCCCGGTCCCGCAGTCCCGCCATGGCCTGGGGAGGCCCGAAGCCCGGGGACAGTGGCCGGCCCATCTCCGGCTCCGCGGA

CCCCCGGCTCAGGCGGGAGGGCAGGCGGGTCCCTGCAGGCCCCCAGGGAGCCCGGGAGCCTCTCTCTGGCGTCATTCAGTCCCGG

GGCAACCTGAAGCGCGGTAGATATTGGAGAGGGGGCGTCTGTTGGGGGGACCTGGCGTCATTACTGATGGCTAGCAGGGAGGAGG

GAACGGGTTGTCACCTCGGCCTCATAAGGCCGTGAGTGAGTAGTCCAGGGCCTCTTCAGGCATTTTTGAAACTGGATTAACTAGG

GGGGAAATTGTAGCACTGAAGCCACCGTGACTGTCTTTTGCGCTGTGTGGAAACTCCGGTAAAACTCTTTGGGCAACAGTCTTAT

CACCAGCTCTTCAACGTGTGCAGCCCTTCTGGTCCTGTCCCTGTTCTGGGCCCCAGGAATGCAAAGCAGGTCCAGGCACTGTGAA

GACCCTGGCGGTGGAGGAAGAGGCTTCCCGGCTGTGGAGGAAGCCAGACCCTTACAACACAAGACGAGAACCAGACCTGCGTGGG

GGAGCTCTGGATGCTACAGGGGCTCAAGGAGGGGTGGAGGGGCCTTCCCAGGCCAACCCCTGAACGGCTTGGACAAGATGCTCAG

ATGGACGGGAGGAACGGCGTGTGGGATGGGGGAGCTGGAGGCGGGTGGGTGGGGGGGGGAGGATGGGGAAAGCGCTGGCCCACCC

AGTGTGGGAGGGGTAGAGGAAAAGCCCGCAGGGGCCAGGTTGGGACCCCGTAGGCCGGGTTAGAGGGCTTGGACTTGATCCTGAC

AGGCGACAGGGAGACATATTGCTACTTATTATGTGCACAGTGGCCAGATCTCTAAAGAAAACACCATCCCCCACCCCCACCCCCC

ATATAGTAAACCAGGTGGTCCGCCCAGTGCTCCCAGGGAGGTGATGGGAAATCCCACTCCATACCCTGCGGTGAGGGGTTCCATG

CCCTCCACGTGTGCAACTACTCCGGGCCCAGGGAAACACTGGGCCCCATCCGGTAACCCCCGGCCCAGTCGGGTTTCCCAGTTCA

CATTATAACCAAACGGTCTTGCCAGCTAGACAGACAGACACCCCTGACCTGTTTACCCTGATCCTCTGCTCTCAGGATTAATCAC

AACTTGTCGAAGGGGGTGGCTTCCAGTGGGGTGGACCGCTCTGTCAATGCCAGCGTGTGTCTAGCATCTCCTGGGGTGGGGGTGT

GGGGAAGGGAGGTGTAGGATGAAGCCCTAGAAGCCTCAGGCAATTGTGATCCGGTGGGCTGGATACTGAAGCCCACCCCTGCCTT

GACCTCAATTTTCAGTATCTTCATCTGTAAAATGGGAACAACCTGCCTTCCTCCTAGCCCTAAAGGGGCTGCTGTCAAGATTGGC

TGAGATAGCTGTTTGCAAGCTGAGCTCAATGAAAGTTCATTGTGTCCCCCTCAGTCCTATCCCAATATCGTCTCACTGCAAAGGT

GGGGGGCAGCTTAACTTCAAGGGCACTTCAAGGATAGCCAGGTGGCTGTCAGCCCAGCTTTCCAGGATGGGAGCAGGATCTTGAC

AGAAGGGTTGACTGGGAGGGGCAGTTGCTGGTTTGGGCTTCGTTAGGTTGCATTTTTGTTTGTTGTCCTTTCATTTCCCTGGGGC

AGCACCCCTTCCTGCAAGCTCCAGGCCTTCCTCTGGAATGCTCCTAGAGCCCAACCTCTGCTGGTGCCTGAGCTTAAGCCAGGCC

AGCTAAGGGGATCCTGGATTCACACGGCCTCACAGTCACTCAGATTGTTAGCAGAAGACAAAAATTACAAGGGGAGGGCGTCATG

TGATTCTTACACACCCTCCAAATCCAGCAGACACCTTGGAAGCCACAGGTAGCTTCAAGAAACCCATTTTACGGATGAGAACCTG

AGATGGAGAAAGGACAACTGGAGATCTCTGAGTCTCTGAGCCCACACTCCCTACCTCCCTGCACCTCCAGGCACTCTGCTGGCAG

GATCTTGGGCAAATGCCCACAGCTCTCTGAGAGTCAGTTTTCCTGTCTGTAAAATGGGAGTCATACCTTCCTCCTATGGCCGGTG

AGAGACTAAATTAAACTATGTCTGTCAAGACACCTGAAACTCCTGGCACAATTTAGGTTGCCTTCAAGTGGTCACAGTTGTCATT

AGGTGGAAGTCAACACCCCAATCATTGTAAAGGTGCCCATATACCCCAAGATCCAGATTACAGCTCTCACAGTTTATTATATACA

GCGAAAAAACACATAACACACCTTTGCCCACATTTACATGTATTTTACGGACCATGTTTCACATCAGTCCGCATGCACATCTGCA

CGTGTGTGCATTCGGCAGTATTTACCAAGCACCTGCCAAGTGCCAGGGCCTGTCCTCCGCACCCGGCGTGAACTGTCCTGGACCA

GTCCCGGGAGCCGCGGTTCTGACCAGCCGTGCTGACCCTGGACGACTCCATGAGCTGTTTTGTGAGAAAGACACGCCATTTGTTT

GCAGAGTTCTGACTTCTGAGGGGTCATGTAGCACATGTTTGGTAGCCAAACGCTGTCATTCACGACCAGGAGCGATGGCTGCAAT

GCCTTTTTCTTTGCTTTGCTTTCCGGTGCCGGGAGCCTTGCCTCCCGCCGCCACCCCTGGTCAGCTCTGCGCAAGAACGTCGTTC

TGTTTGGCAGCCAGGCCGAGACGCAGCCTGAATGTGAGCAGGAACTCGGAGAAGGGAAGGGAGAGAATCAGAAAGAAGGCCCGGG

AGGGACCCGGGAAGCAGTGGGAGGTCTGCGCCCTGGAGCCCCGCGAGAGCCCGCCGGTTTGGCACGGGCTCCTCCCGGGCCGCCC

GGCGGTCCAACAAAGGCCGGCCCCGACACGCACCCGGTCTTTTGTGGGAGAGAAACACAAAGAAGAGGGAAAAACACGGAGGAGG

CCAACAGCACCAGGACGCGGGGGCCAACCAGGAACTCCCGGAGCCGGGGCCCATTAGCCTCTGCAAATGAGCACTCCATTCCCCA

GGAAGGGGCCCCAGCTGCGCGCGCTGGTGGGAACCGCAGTGCCTGGGACCCGCCCAGGTCGCCCACCCCGGGCGCCGGGCGCAGG

ACCCGGACAAGTCCTGGGGACGCCTCCAGGACGCACCAGGGCAAGCTTGGGCACCGGGATCTAATTTCTAGTTATTCCTGGGACG

GGGTGGGGAGGCATAGGAGACACACCGAGAGGTACTCAGCATCCGATTGGCACCAGGGCCAAGGGAGCCCAGGGGCGACACAGAC

CTCCCCGACCTCCCAAGCTACTCCGGCGACGGGAGGATGTTGAGGGAAGCCTGCCAGGTGAAGAAGGGGCCAGCAGCAGCACAGA

GCTTCCGACTTTGCCTTCCAGGCTCTAGACTCGCGCCATGCCAAGACGGGCCCCTCGACTTTCACCCCTGACTCCCAACTCCAGC

CACTGGACCGAGCGCGCAAAGAACCTGAGACCGCTTGCTCTCACCGCCGCAAGTCGGTCGCAGGACAGACACCAGTGGGCAGCAA

CAAAAAAAGAAACCGGGTTCCGGGACACGTGCCGGCGGCTGGACTAACCTCAGCGGCTGCAACCAAGGAGCGCGCACGTTGCGCC

TGCTGGTGTTTATTAGCTACACTGGCAGGCGCACAACTCCGCGCCCCGACTGGTGGCCCCACAGCGCGCACCACACATGGCCTCG

CTGCTGTTGGCGGGGTAGGCCCGAAGGAGGCATCTACAAATGCCCGAGCCCTTTCTGATCCCCACCCCCCCGCTCCCTGCGTCGT

CCGAGTGACAGATTCTACTAATTGAACGGTTATGGGTCATCCTTGTAACCGTTGGACGACATAACACCACGCTTCAGTTCTTCAT

GTTTTAAATACATATTTAACGGATGGCTGCAGAGCCAGCTGGGAAACACGCGGATTGAAAAATAATGCTCCAGAAGGCACGAGAC

TGGGGCGAAGGCGAGAGCGGGCTGGGCTTCTAGCGGAGACCGCAGAGGGAGACATATCTCAGAACTAGGGGCAATAACGTGGGTT

TCTCTTTGTATTTGTTTATTTTGTAACTTTGCTACTTGAAGACCAATTATTTACTATGCTAATTTGTTTGCTTGTTTTTAAAACC

GTACTTGCACAGTAAAAGTTCCCCAACAACGGAAGTAACCCGACGTTCCTCACACTCCCTAGGAGACTGTGTGCGTGTGTGCCCG

CGCGTGCGCTCACAGTGTCAAGTGCTAGCATCCGAGATCTGCAGAAACAAATGTCTGAATTCGAAATGTATGGGTGTGAGAAATT

CAGCTCGGGGAAGAGATTAGGGACTGGGGGAGACAGGTGGCTGCCTGTACTATAAGGAACCGCCAACGCCAGCATCTGTAGTCCA

AGCAGGGCTGCTCTGTAAAGGCTTAGCAATTTTTTCTGTAGGCTTGCTGCACACGGTCTCTGGCTTTTCCCATCTGTAAAATGGG

TGAATGCATCCGTACCTCAGCTACCTCCGTGAGGTGCTTCTCCAGTTCGGGCTTAATTCCTCATCGTCAAGAGTTTTCAGGTTTC

AGAGCCAGCCTGCAATCGGTAAAACATGTCCCAACGCGGTCGCGAGTGGTTCCATCTCGCTGTCTGGCCCACAGCGTGGAGAAGC

CTTGCCCAGGCCTGAAACTTCTCTTTGCAGTTCCAGAAAGCAGGCGACTGGGACGGAAGGCTCTTTGCTAACCTTTTACAGCGGA

GCCCTGCTTGGACTACAGATGCCAGCGTTGCCCCTGCCCCAAGGCGTGTGGTGATCACAAAGACGACACTGAAAATACTTACTAT

CATCCGGCTCCCCTGCTAATAAATGGAGGGGTGTTTAACTACAGGCACGACCCTGCCCTTGTGCTAGCGCGGTTACCGTGCGGAA

ATAACTCGTCCCTGTACCCACACCATCCTCAACCTAAAGGAGAGTTGTGAATTCTTTCAAAACACTCTTCTGGAGTCCGTCCCCT

CCCTCCTTGCCCGCCCTCTACCCCTCAAGTCCCTGCCCCCAGCTGGGGGCGCTACCGGCTGCCGTCGGAGCTGCAGCCACGGCCA

TCTCCTAGACGCGCGAGTAGAGCACCAAGATAGTGGGGACTTTGTGCCTGGGCATCGTTTACATTTGGGGCGCCAAATGCCCACG

TGTTGATGAAACCAGTGAGATGGGAACAGGCGGCGGGAAACCAGACAGAGGAAGAGCTAGGGAGGAGACCCCAGCCCCGGATCCT

GGGTCGCCAGGGTTTTCCGCGCGCATCCCAAAAGGTGCGGCTGCGTGGGGCATCAGGTTAGTTTGTTAGACTCTGCAGAGTCTCC

AAACCATCCCATCCCCCAACCTGACTCTGTGGTGGCCGTATTTTTTACAGAAATTTGACCACGTTCCCTTTCTCCCTTGGTCCCA

AGCGCGCTCAGCCCTCCCTCCATCCCCCTTGAGCCGCCCTTCTCCTCCCCCTCGCCTCCTCGGGTCCCTCCTCCAGTCCCTCCCC

AAGAATCTCCCGGCCACGGGCGCCCATTGGTTGTGCGCAGGGAGGAGGCGTGTGCCCGGCCTGGCGAGTTTCATTGAGCGGAATT

AGCCCGGATGACATCAGCTTCCCAGCCCCCCGGCGGGCCCAGCTCATTGGCGAGGCAGCCCCTCCAGGACACGCACATTGTTCCC

CGCCCCCGCCCCCGCCACCGCTGCCGCCGTCGCCGCTGCCACCGGGCTATAAAAACCGGCCGAGCCCCTAAAGGTGCGGATGCTT

ATTATAGATCGACGCGACACCAGCGCCCGGTGCCAGGTTCTCCCCTGAGGCTTTTCGGAGCGAGCTCCTCAAATCGCATCCAGAG

TAAGTGTCCCCGCCCCACAGCAGCCGCAGCCTAGATCCCAGGGACAGACTCTCCTCAACTCGGCTGTGACCCAGAATGCTCCGAT

ACAGGGGGTCTGGATCCCTACTCTGCGGGCCATTTCTCCAGAGCGACTTTGCTCTTCTGTCCTCCCCACACTCACCGCTGCATCT

CCCTCACCAAAAGCGAGAAGTCGGAGCGACAACAGCTCTTTCTGCCCAAGCCCCAGTCAGCTGGTGAGCTCCCCGTGGTCTCCAG

ATGCAGCACATGGACTCTGGGCCCCGCGCCGGCTCTGGGTGCATGTGCGTGTGCGTGTGTTTGCTGCGTGGTGTCGATGGAGATA

AGGTGGATCCGTTTGAGGAACCAAATCATTAGTTCTCTATCTAGATCTCCATTCTCCCCAAAGAAAGGCCCTCACTTCCCACTCG

TTTATTCCAGCCCGGGGGCTCAGTTTTCCCACACCTAACTGAAAGCCCGAAGCCTCTAGAATGCCACCCGCACCCCGAGGGTCAC

CAACGCTCCCTGAAATAACCTGTTGCATGAGAGCAGAGGGGAGATAGAGAGAGCTTAATTATAGGTACCCGCGTGCAGCTAAAAG

GAGGGCCAGAGATAGTAGCGAGGGGGACGAGGAGCCACGGGCCACCTGTGCCGGGACCCCGCGCTGTGGTACTGCGGTGCAGGCG

GGAGCAGCTTTTCTGTCTCTCACTGACTCACTCTCTCTCTCTCTCCCTCTCTCTCTCTCTCATTCTCTCTCTTTTCTCCTCCTCT

CCTGGAAGTTTTCGGGTCCGAGGGAAGGAGGACCCTGCGAAAGCTGCGACGACTATCTTCCCCTGGGGCCATGGACTCGGACGCC

AGCCTGGTGTCCAGCCGCCCGTCGTCGCCAGAGCCCGATGACCTTTTTCTGCCGGCCCGGAGTAAGGGCAGCAGCGGCAGCGCCT

TCACTGGGGGCACCGTGTCCTCGTCCACCCCGAGTGACTGCCCGCCGGAGCTGAGCGCCGAGCTGCGCGGCGCTATGGGCTCTGC

GGGCGCGCATCCTGGGGACAAGCTAGGAGGCAGTGGCTTCAAGTCATCCTCGTCCAGCACCTCGTCGTCTACGTCGTCGGCGGCT

GCGTCGTCCACCAAGAAGGACAAGAAGCAAATGACAGAGCCGGAGCTGCAGCAGCTGCGTCTCAAGATCAACAGCCGCGAGCGCA

AGCGCATGCACGACCTCAACATCGCCATGGATGGCCTCCGCGAGGTCATGCCGTACGCACACGGCCCTTCGGTGCGCAAGCTTTC

CAAGATCGCCACGCTGCTGCTGGCGCGCAACTACATCCTCATGCTCACCAACTCGCTGGAGGAGATGAAGCGACTGGTGAGCGAG

ATCTACGGGGGCCACCACGCTGGCTTCCACCCGTCGGCCTGCGGCGGCCTGGCGCACTCCGCGCCCCTGCCCGCCGCCACCGCGC

ACCCGGCAGCAGCAGCGCACGCCGCACATCACCCCGCGGTGCACCACCCCATCCTGCCGCCCGCCGCCGCAGCGGCTGCTGCCGC

CGCTGCAGCCGCGGCTGTGTCCAGCGCCTCTCTGCCCGGATCCGGGCTGCCGTCGGTCGGCTCCATCCGTCCACCGCACGGCCTA

CTCAAGTCTCCGTCTGCTGCCGCGGCCGCCCCGCTGGGGGGCGGGGGCGGCGGCAGTGGGGCGAGCGGGGGCTTCCAGCACTGGG

GCGGCATGCCCTGCCCCTGCAGCATGTGCCAGGTGCCGCCGCCGCACCACCACGTGTCGGCTATGGGCGCCGGCAGCCTGCCGCG

CCTCACCTCCGACGCCAAGTGAGCCGACTGGCGCCGGCGCGTTCTGGCGACAGGGGAGCCAGGGGCCGCGGGGAAGCGAGGACTG

GCCTGCGCTGGGCTCGGGAGCTCTGTCGCGAGGAGGGGCGCAGGACCATGGACTGGGGGTGGGGCATGGTGGGGATTCCAGCATC

TGCGAACCCAAGCAATGGGGGCGCCCACAGAGCAGTGGGGAGTGAGGGGATGTTCTCTCCGGGACCTGATCGAGCGCTGTCTGGC

TTTAACCTGAGCTGGTCCAGTAGACATCGTTTTATGAAAAGGTACCGCTGTGTGCATTCCTCACTAGAACTCATCCGACCCCCGA

CCCCCACCTCCGGGAAAAGATTCTAAAAACTTCTTTCCCTGAGAGCGTGGCCTGACTTGCAGACTCGGCTTGGGCAGCACTTCGG

GGGGGGAGGGGGTGTTATGGGAGGGGGACACATTGGGGCCTTGCTCCTCTTCCTCCTTTCTTGGCGGGTGGGAGACTCCGGGTAG

CCGCACTGCAGAAGCAACAGCCCGACCGCGCCCTCCAGGGTCGTCCCTGGCCCAAGGCCAGGGGCCACAAGTTAGTTGGAAGCCG

GCGTTCGGTATCAGAAGCGCTGATGGTCATATCCAATCTCAATATCTGGGTCAATCCACACCCTCTTAGAACTGTGGCCGTTCCT

CCCTGTCTCTCGTTGATTTGGGAGAATATGGTTTTCTAATAAATCTGTGGATGTTCCTTCTTCAACAGTATGAGCAAGTTTATAG

ACATTCAGAGTAGAACCACTTGTGGATTGGAATAACCCAAAACTGCCGATTTCAGGGGCGGGTGCATTGTAGTTATTATTTTAAA

ATAGAAACTACCCCACCGACTCATCTTTCCTTCTCTAAGCACAAAGTGATTTGGTTATTTTGGTACCTGAGAACGTAACAGAATT

AAAAGGCAGTTGCTGTGGAAACAGTTTGGGTTATTTGGGGGTTCTGTTGGCTTTTTAAAATTTTCTTTTTTGGATGTGTAAATTT

ATCAATGATGAGGTAAGTGCGCAATGCTAAGCTGTTTGCTCACGTGACTGCCAGCCCCATCGGAGTCTAAGCCGGCTTTCCTCTA

TTTTGGTTTATTTTTGCCACGTTTAACACAAATGGTAAACTCCTCCACGTGCTTCCTGCGTTCCGTGCAAGCCGCCTCGGCGCTG

CCTGCGTTGCAAACTGGGCTTTGTAGCGTCTGCCGTGTAACACCCTTCCTCTGATCGCACCGCCCCTCGCAGAGAGTGTATCATC

TGTTTTATTTTTGTAAAAACAAAGTGCTAAATAATATTTATTACTTGTTTGGTTGCAAAAACGGAATAAATGACTGAGTGTTGAG

ATTTTAAATAAAATTTAAAGTAAAGTCGGGGGATTTCCATCCGTGTGCCACCCCGAAAAGGGGTTCAGGACGCGATACCTTGGGA

CCGGATTTGGGGATCGTTCCCCCAGTTTGGCACTAGAGACACACATGCATTATCTTTCAAACATGTTCCGGGCAAATCCTCCGGG

TCTTTTTCACAACTTGCTTGTCCTTATTTTTATTTTCTGACGCCTAACCCGGAACTGCCTTTCTCTTCAGTTGAGTATTGAGCTC

CTTTATAAGCAGACATTTCCTTCCCGGAGCATCGGACTTTGGGACTTGCAGGGTGAGGGCTGCGCCTTTGGCTGGGGGTCTGGGC

TCTCAGGAGTCCTCTACTGCTCGATTTTTAGATTTTTATTTCCTTTCTGCTCAGAGGCGGTCTCCCGTCACCACCTTCCCCCTGC

GGGTTTCCTTGGCTTCAGCTGCGGACCTGGATTCTGCGGAGCCGTAGCGTTCCCAGCAAAGCGCTTGGGGAGTGCTTGGTGCAGA

ATCTACTAACCCTTCCATTCCTTTTCAGCCATCTCCACTACCCTCCCCCAGCGGCCACCCCCGCCTTGAGCTGCAAAGGATCAGG

TGCTCCGCACCTCTGGAGGAGCACTGGCAGCGCTTTGGCCTCTGTGCTCTTTCCT

196
OLIG2
CCGGCACGGCCCGCATCCGCCAGGATTGAAGCAGCTGGCTTGGACGCGCGCAGTTTTCCTTTGGCGACATTGCAGCGTCGGTGCG

GCCACAATCCGTCCACTGGTTGTGGGAACGGTTGGAGGTCCCCCAAGAAGGAGACACGCAGAGCTCTCCAGAACCGCCTACATGC

GCATGGGGCCCAAACAGCCTCCCAAGGAGCACCCAGGTCCATGCACCCGAGCCCAAAATCACAGACCCGCTACGGGCTTTTGCAC

ATCAGCTCCAAACACCTGAGTCCACGTGCACAGGCTCTCGCACAGGGGACTCACGCACCTGAGTTCGCGCTCACAGATCCACGCA

CACCGGTGCTTGCACACGCAAGGGCCTAGAACTGCAAAGCAGCGGCCTCTCTGGACCGCCTCCCTCCGGCCCTCCTGAGCCCTAC

TGAGCCCTGCTGAGTCCTGGAGGCCCTGTGACCCGGTGTCCTTGGACCGCAAGCATCCTGGTTTACCATCCCTAC

197
RUNX1
GGACGCGGCCCGCTCTAGAGGCAAGTTCTGGGCAAGGGAAACCTTTTCGCCTGGTCTCCAATGCATTTCCCCGAGATCCCACCCA

GGGCTCCTGGGGCCACCCCCACGTGCATCCCCCGGAACCCCCGAGATGCGGGAGGGAGCACGAGGGTGTGGCGGCTCCAAAAGTA

GGCTTTTGACTCCAGGGGAAATAGCAGACTCGGGTGATTTGCCCCTCGGAAAGGTCCAGGGAGGCTCCTCTGGGTCTCGGGCCGC

TTGCCTAAAACCCTAAACCCCGCGACGGGGGCTGCGAGTCGGACTCGGGCTGCGGTCTCCCAGGAGGGAGTCAAGTTCCTTTATC

GAGTAAGGAAAGTTGGTCCCAGCCTTGCATGCACCGAGTTTAGCCGTCAGAGGCAGCGTCGTGGGAGCTGCTCAGCTAGGAGTTT

CAACCGATAAACCCCGAGTTTGAAGCCCGACAAAAAGCTGATAGCAATCACAGCTTTTGCTCCTTGACTCGATGGGATCGCGGGA

CATTTGGGTTTCCCCGGAGCGGCGCAGGCTGTTAACTGCGCAGCGCGGTGCCCTCTTGAAAAGAAGAAACAGACCAACCTCTGCC

CTTCCTTACTGAGGATCTAAAATGAATGGAAAGAGGCAGGGGCTCCGGGGAAAGGGAACCCCTTAGTCGGCCGGGCATTTTACGG

AGCCTGCACTTTCAAGGACAGCCACAGCGTGTACGAAGTGAGGAATTCCTTTCCACCAAGAGCGCTCATTTTAGCGACAATACAG

AATTCCCCTTCCTTTGCCTAAGGGAGAAAGGAAAGGAAACATTACCAGGTTCATTCCCAGTGTTTCCCTGGAGTAATGCTAGAAT

TTACTTTTGTCATAATGCAAAATTAAAAAAAAAAAAAATACAACGAAGCGATACGTTGGGCGGATGCTACGTGACAGATTTTTCC

AAATTTTGTTGCGGGGAGAGGGAGGGAGGAGAATTGAAAACGGCTCACAACAGGAATGAAATGTA

198
RUNX1
TTTTTAATGCTCAGAGAAGTTCGTATTACTGATTCGGGAACACTGAGTTTTTCAGCTCCTGTAAAACTATTTTCAGGTTTATTTT

CAAGTACATTCTTTA

199
RUNX1
CACCCTAGAGGCAAGGACGGGGTCTGTGTCAAGAGGCTTCCCAGAGAAGTGAAAACTCTGCAGGTGCAGCCGCTGGGAGAGCATC

AAGAAGGGCAGGGTGGAGGGGCAGGGGGCGAAGGGAGGGGGTGAAGCCCGCACCCTACCCCCACATGAAACTGATTCCACTACCC

CATCTCTGCAAGCGTCCAGAGGCAGAGAGGCCAACATTTCGGGGACAGCTTGGAGGCGGGAGATTTAGGCAGGGCTCCTTAAACT

TTTATGTGCATGAAAATCAGGCCAATCACGGGGCTCTTGAGCAAATGGGGACGATGATTCAGCAGGTCTGGGCTGAGGCCTCAGA

TTCTGCACTTCTAACAAGTTCCCAGGTGGTAGTGATGCTGCCAGTCCAAAGACCACACTG

200
RUNX1
TGCTTCAGTGGGGTAAACTTGAACCGCTGAGAAGACAAGCAGGGAGTCGGTCTCGCTGAGATTTTTACCTGTGGTTCTAGGAACG

CAGAGGCATGTGAGTGTTCAGGCTTTGCATAGACCACTAAGCCACTTCTAAGAACAAGGCTACCTGAGCCATTTTGCAAAAATAT

GTACGTGCCGAGGCTTTTCCTCCCCACACCTACCTCAACTCTTTCTGCCGACACACTGCACTTTTCAAGGGAACCCAAGTTTGGG

TTCGGCAAGAATTGTACGTTGCACACCGTGTGTGATAATTCCAGGGAATTTCAATCGCATCTTGTCTTCCTTCCTAAGCAAATTC

GGTGGGAACCTGGTGTGGTGTGATAGAAAAAGCCCCGAGTTCTCTGTGGTAGACCACATCAATTTCATGTGCCAGTCTCTCAGAC

TCCGGCTTGCCTCTCTCAAGGAAGGGAACAATGGTTTGCTTGGCTTCACTCCTCTCTTTCCCCCCAATTTCCACATGGGTATCTG

GCTAAAAATGAGTTACAGGTTTCCTTCTGTGAGAATTGCATGGACTGATAAAGTACCATCCCAGGAAGAAAACAAAGATGCTGTC

TTCCCTTTCGGCTCACAGTTGCCGTTGGGGAGGGAACACACGCTGTAAATTATAGGCAGCCAGAAGTGACCGCATTGACCACTGC

GAGTGGCCCAGCTATGGCAACAGGCTGAGAACTCTGGGGGAGAGCCATTTGTTGGCAGGGATGGTGATTCTTCTAGCATCAAGCT

CTAAGATGATGACCAAACGGTATCAAAAGAAATGATATTTTGCTACCTCTCCGGCTTGGGTGAATGATGTGGACAGTTAACCTGG

ACAATTTAAACCTTTATGTTGATGGATCACTTGGATGAAATTAACCAGGAAATTGCCAAGATTTCACTTGGCCCTCTGACATCAA

ATCTCAATATTATATTACCAAATTAGAGATTCTAAAGAACCCTGAGTTCCTTTCACTGAAAGGAAGGAGTGGAAAAACCTTTCCA

GATGATCCCTTTTGAGTCTTGGTGCGAGCTCAGGCCCTCCCTACACTGCCTCCGTGAAAGCTAACCGACCCTTGTTCCTAACCTA

GCGCAGGTCAGCTGAGTGTCCATCGGGCACAGGAGCCCTGGGCTTGTCCGGGAGATAGCCAGACTCCTGCTATTTCCTGATGTCT

GCATAGCTCAGCGTGTCCCTCACCATCTTTGCCGTTGGCCAGTAAGGAGAGCCCCAGGGGCCAGCACTGCACACTGAAACCCAAC

CTATTGCTCAATGGAATGCTTAAAAATTTCCTGAATCTGCCTTCCTGAGTTGATAAAATAGGAAACAATACACGTTCTGAGGGGG

TACTGAAAGCAGAGTAAAGCCAGGAAGATCTTTTTTTTCTGTTATTCTATACAAATATTGCTTCCTCTGCTTGTTAGCAGCCCAG

AGGAAATGCAGCCAGGGAGCCGTTTGCAGCTTTTCACCAGTGGCCGGTGTCTCTGTGTTACCAACCAAACGACGCTGCAAGACTA

GTGACTAACGCACGTCTGCATGATTCAACTTCACTAAAATTCCCTCTGCTGCCAGTAAAGAAGCACTTGAAAACTCTTTAATTTG

AAACTTGAGCTTGGTTAATGACTTGTTTTCTTCTCTTTCTCTTTAACTTCTCTCTTGCCATCTCCAACACACACACACACACACA

CACACACACACACACACACACACACACACTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCATCAAGTTTTTTAATTTCAG

GGACCCGGAAACATACAGCCCCGTGCATTCACAATAGCATTTGCTGTGATAAAGTGGCCGGCAAGCCCTCTGCATTCCCCTGCTC

ACTTAGCTGTATGAATAAATAATGAGTCACAGATACAATTTGGGTGCTCAAGAGAGTTTGTAGCCAGAAAATTAATTATTCTCCC

ATCCCAGCCCACTCCATCTCAGCTTTGCCAAACCATCAAGATACACTTTGCAGGCACTGGTCAGAGTGCGTGCCCCGACGCACAC

GGCAATGCCTTTGAGACATTTTATGTTATTATTTTTGTTTGTTTAAGCACAGCCCTCTTTTACCACGAAAGATACACAAGACGCA

CATGCACACACATACTCACACACTCACAGCTCAACCACAGCTTTGTCCATTTCAAGAGGCTGGTTTCAAAAATGGAGACAGGTTT

TCCACCCTGGCTGTTCCTATTCATAAGCCTGTAATCTAACGACTTAAGCTGCGAGAATGCTTAACTCGGGAAACTTCTCTATTGC

CCTTTTCCAGAGAGACCTCGGTATGCCACAATTTGCTTCCTTTCTCTCTTGAAAGATGCTGGTTGTCTCTTTGCATTGAGGCTAC

AAGGAAAAACACAGCACAGCCCCATGCTGATGATTTTAACCTAACCAAGTCTGTCAGTCTCCTGTACTCTCTGCCTTATAGAGAC

AGCTGCCTTGCCACTTTGGCCCTGAAGTCCCCAGGCTGGTGCAAGGCTATCTGAGAGCCTCCGCCTCCTGCCCCACACTGGCACC

AGCCCTCCTGGCTGGCTCTGTGCATGTGCCTGCTAAGCCCCAGGGCAGGCTGCATTCTGGGCCACACAGCATGCCGAGTTAAGGA

TAACTCAGACACAGGCATTCCGGGCAAGGGACAGCAAAATAAAACCCAGGGAGCTTCGTGCAAGCTTCATAATCTCTAAGCCTTT

AAACAAGACCAGCACAACTTACTCGCACTTGACAAAGTTCTCACGCACCGACTGAACACTCCAACAGCATAACTAAGTATTTATT

AAAACATTTCTGAAGAGCTTCCATCTGATTAGTAAGTAATCCAATAGACTTGTAATCATATGCCTCAGTTTGAATTCCTCTCACA

AACAAGACAGGGAACTGGCAGGCACCGAGGCATCTCTGCACCGAGGTGAAACAAGCTGCCATTTCATTACAGGCAAAGCTGAGCA

AAAGTAGATATTACAAGACCAGCATGTACTCACCTCTCATGAAGCACTGTGGGTACGAAGGAAATGACTCAAATATGCTGTCTGA

AGCCATCGCTTCCTCCTGAAAATGCACCCTCTTCTGAAGGCGGGGGACTCAATGATTTCTTTTACCTTCGGAGCGAAAACCAAGA

CAGGTCACTGTTTCAGCCTCACCCCTCTAGCCCTACATCTCTCTTTCTTCTCCCCTCTGCTGGATACCTCTGGGACTCCCCAAGC

CCTATTAAAAAATGCACCTTTGTAAAAACAAATATTCAAATTGTTAAAGATTAAAAAAAAAAAAAAAGCCAGCGCCGCCTTGGCT

GTGGGTTGGTGATGCTCACCACGCTGCGAAACCCTGTGGTTTGCATTCAGTGTGATTCGTCCTGCCTGCTGACCACTATGCTGGG

TTCAGACTTCTGACACTGCCAGGCTACCCAACTTGTGGTTCTGTGGTTGTTTATGAGGCCCAAAGAAGTTTTCACACAACCCAAA

TTACAAATTTAACTGTTCCCCTTTCCACAGCCCATCTCAATTGGTTCTTGCCAATCATGTGACTTAAGTGATGTCAATTTTTTTT

TTTCTTTTCTGAGCAATGCCCTTCCTTCCCTCCACCTGCCCTCCCCCAGGCTGTGCAAGAAAATAGCCGAGTAGACTTTGCAAGA

GGGGGGGATGTAGAAAAAAGTGACTCAGTCACTTATTATATCTCAATGGTCTTTGCTGATTTAGTACAACTCGGCTCCTGTTGTT

ATTTGTGGTTTTTGGAACTACTGATTATTTTGATAAAGATTTCATTGCTGCTTATTCAATAGTAATTCAACGCTGGCATCAAGCC

GCTGCTCCGACAGGATGTGGATCCCATCATTTAAAATGCTAGGCATCAGCTCCGGGAGAGTTAAGTCCTTGGTAACGTCTATCAT

GGCATAAGTGAAACTATAAAAGGGAAAAATAAATAAAAAGAAATGTTTTGGTGAGAGTCTGACCCCTACAACGGGCTGGCAACTC

ACAGGTATTTTAAAGCCTGGGAAAGGGAAAGAATTTTACTTTTGAAATAAAAGGACTGTTTTAATGAAACCAAAATTATGTGGTT

TTATTCCCCCTAAATGGACAACTTTAGTATGTATCTCTTTCAGTAAAGAGATAAAATCATAGTACAGTCTTAACACACACACACA

CACACACACACACACACACACACACACAAATTAGGAAGCTAAAGGAAAACAAAGCAGAGAGAATTTCTGTATTTGGGACAAAGCA

GTGGTTACTCTGCAGATGTTTATTTGTATTGTCACTTGGGAAAGCTCCCTGTATTGCCTTTCTCTAGTTCAATTCAAATCAATAG

GCTAATTTACACCTGTAGGTAAAACTACACTTTGAGCACATGAGGATGCCACAATAGAAGGGGAACCAGGAGGAGACACTTCTCC

TGGGGCTGACTAATGAATATTATATAGCGCGTCCTCTACCTTAGAAAGACATGCCTGTTTGAAGATGCTAAAAACAGGATAATTT

TGTAAGTGGGCAAACCACTGTGGTCACACGTATTTCATTTTCCGGCCCCACTGGCTTTACCTGCTGACAACTAAAACGTCATTTT

GTTTTGTAGTTCCAAGATGAAGAAAGGCTTATTTTCCTGATTTACTACCTTATTCATTTGGCTCTGCTCTGCCTACATCCGCCAT

AGCACTCTGCGCACGTGAAATTTCGACACATAGGGTCAAGAGAACCTGTGTGATGATGGGTTGTAAATGCCAGTCCTGGATTCTA

AGCTGCAGTAGCCAGCACAGGCACTTCAGAAAGGCTGAACTCCCACAACACTCCCTCGGTTTTCCCTCATCCACTTAATTTCACA

CACACAAAGACCCACAACGATAGTAGCTTCCATGGCACAAGTCTTTCAAAAGGAACAGACACAATTTTTACTTACTCCTGTTTTG

ACTAAAGCAGGAATTGAAACTCAACAGACCGCTTTCTCTTACACTTGTGAGAAGTTAGCTGGCCACATGT

201
chr21:
AGGGAAAAGAGATAACGAAAGAAAGAAAGAAAAAAAAAAGGGCCGGCAATTTCATGTACATTTGTTTTGGCATTCGCTGAATTCT

35499200-
AGAGATGAAAACAATCTCCTGCTTTTAATTCAGTCCACGTGCAACAAAGTTGTACGTTGGGAGATCTGGCTTTTAATAAGAACGA

35499700
TTAACAAGCGTTTTTGATCACAGGAAGTTGAGAAGAGTCGCTGCTTCTAAGAATACAATAAACATTGACTAGCAGTTAGACGGTC

CATCTTTCTCTATCAGCCGTTTAGCAGCCTCTACTTTGATTTGGGGCAAATGCGAGATGGGACCAGGAGAGAGCTCCCCACACCC

CCACCACCACGTGGGCAGTGGTTCTGTTCCAGAGCGCCTTCCTTCCTGTCCAGGGAGGCAGGCTGCTGAGGCCGTTTCTGGGCAA

GAGGCCATTGTCGGGATATTTGCTTTAGATAGCTTGCAGCTGGGCTGAGTGGGTGTTTCATTCAGACTCAACACA

202
chr21:
AGCCTGGCGCACCCGCCCTAATTTGAGTCAGGGACCCTAGGCGCCTGCAGCTCCGGTTCGGGTTGAGTGCCTCCTGTCAGGATGT

35822800-
GAAGCTGCTGTCCCCCCCGGGGGCCTCCAGCACTGCTGAGGACTCAGCAGTCAGCCTCTCCTCCCACTTGGGCTCATTTACAGAG

35823500
AGCATCTCCAGGAATCAGTCATGGGGAAAGGGGAAACGCGGAGTGACAACACAACACGTAGAAAGTTCTCTGCCGCCTTGGTCAG

GCTTGTCAGCCTCACAGCCCATCCTGCTCCTGCGGGAGGAAAAGTGAGCAGAACTCAGCCCGGAGATGAGCCGCAGGCCGGCAGC

CCCTGCCTCTGCCCTGCTTGTTGTGACTGCAATGCAAGGCTCTCTGTAGGTGCGGGGGATTCGGGTTAAATGGGTCTCCAGTGGT

CCAGCGCTCCCAGCAAAGGCCGACCACAAGAATTAGCGGGCTAGTTATTTACCATAACCATATACAAAACCACAAGCATCAGCGT

TCCCTCAAATACATCCGAGACGCTGTATATCTCTTTATTAAAGCCTGTCAGGGTTTGTTATTGCACAGCTTGGCCTTGAACCCCA

ACTAAACCAGGCTGCTTGAGCAAAGAACCAAGCAATGCAAGCATTCAGGCAGGACCATTATAACCCTGAGGCCAAAGGCAGAAGC

AGGGAGAGGAGACGTCTTCC

203
CBR1
AGACCAGCCTCGGTCTTCGGCCTGCGGGTTCTGCAAAGTCAGGCTAGCTGGCTCTCCGCCTGCTCCGCACCCCGGCGAGGTTCCG

GTGGGGAGGGGTAGGGATGGTTCAGCCCCGCCCCGCTAGGGCGGGGCCTGCGCCTGCGCGCTCAGCGGCCGGGCGTGTAACCCAC

GGGTGCGCGCCCACGACCGCCAGACTCGAGCAGTCTCTGGAACACGCTGCGGGGCTCCCGGGCCTGAGCCAGGTCTGTTCTCCAC

GCAGGTGTTCCGCGCGCCCCGTTCAGCCATGTCGTCCGGCATCCATGTAGCGCTGGTGACTGGAGGCAACAAGGGCATCGGCTTG

GCCATCGTGCGCGACCTGTGCCGGCTGTTCTCGGGGGACGTGGTGCTCACGGCGCGGGACGTGACGCGGGGCCAGGCGGCCGTAC

AGCAGCTGCAGGCGGAGGGCCTGAGCCCGCGCTTCCACCAGCTGGACATCGACGATCTGCAGAGCATCCGCGCCC

204
DOPEY2
AAACGTTTAAAATATATTTCTAAACAGAATGGGCCAATTCAGTCACAGTAACTGTTGATCTCCATAGCAGAGCAACCCACAAAGA

CAGAACTGATTTTTTTCCCATAATCAGGGGTGAAAAATATACAACTTGTTTCTGAACCAAAACCACAATTTCTGCAGTTTAAAAT

GTTTCACTGCTAATATGGCCCTGGTAGAAATTATGTAGTTTCTTTTCTTCTTTAAAAAAAAAAAAAATTAAAAAAATTTCCTAAG

ACACTAAATGCTCCATCTGGAATGTAGATTCTGATCACAAAGCAGCTCAGTTAACCTAAAAAATAAAAAATTCCCATCACCTGTC

TCAGTAGGGCCTGAGAGTAGTGTGGGGAACCCCAGCTTTGGTATGGAGAGTCATGGCCCCTTGAACCAGATAGAGACCTTGAATA

GCCATAGCTGGTGCTTCTCTCAGGATAAACTCTGATGTAGGAAGTATCACCCTCATGAGAGTGGAATTTGGTCATCCAGTTGACG

CAGGGCATATTCCATGTCTTCTTTTCTGAGACACCCAACCATCCCCACTCCATCCTTCTGCACATCCGTGTAACAGGCATCCCCA

GCTTCTCGCGTGTGATCCTTCAGGTCCTGCCAGCTGCCTGATGGAAGAAGTCCATTTCTTCCATAAATAGCATCCTCTGCATCTC

GAGGGTCCTCGAAGCGCACGGAGGCGAAGGGCACAAGGCCGTACCGGCTCTTGAGCTCGATCTCGCGGATGCGGCTGTACTTGTA

GAACAGGTCCTGCGGCTCCTTCTCGCGCACGTGGGTCGGAAGGTTTCCCCACGTAGATGCACCCGTCGCCCTCCCAGCCGCGCTC

GTGTCCGCCCAGCCGGACAACCGCACCGCCCGACGCTGCTGGCCAGCCGCAGCCCGCATCCGCCCGTATCGCCGCCGCTGCCGCC

TCAGCACGGCTGCCCCCGCAGCGTCTGTTTTGTTTTATTCTAACAGGGTCTCTCTCTGTCGCCCAGGCTGGAGTGCAGTGGCGTG

ATCTTGGCTCCCTGCAACCTCTGCCTCCCGGGTTCAAGCGATTCACCTGCCTCAGCCTCCCAAGTAGTGGGCATTATAGGTGCCA

GCTAACCATGGCCGGCTAATTTTTTTTTTTTTTTTTTTTTTTTTTTGAGACAGAGTCTTGCTCTGTCACCCAGGCTGGAGTGCAG

TGGCGCGATCTCGGCTCCCTGCAACCTCCGCCTCCTGGGTTCAAGCGATTCTCCTGCCTCAGCCTCCTGAGTAGCTGGGATTACA

GCTATGTACAGCGATGTCTGCAAAGATAGGGATTTAACAGCACTCATATCTTCATGTTCATAAAAAAGTCCTACACGCGTGATGT

ACGTCTAGATCTTTCCTTTTGTCACAGGATATAGCACGGTAGTTACGGATATAGTCTCCGCAGTGCCTGGGTTTGACTCAGCTTC

CCCACGTACTGTCCTGCGCATATTTTGTGTCTCAGTTTCCTCATCTTTAAGGTAG

205
SIM2
CACGCGCCCCGGCCTGGCTGGAGGGGCCAACCCAGCGGGGCCCGCCTGCCCGCCGGCCTTTCTGTAACTTTCTCTCTTTAAACTT

CCAATGAATGAACGTGCCTCTTCTTACGGATTTGTTTAGATTAGGGAATAGATTCCTCGCTGATAGCGTTGCTTTGCAAATAAGA

CCTCCTATATTATTCAAACCAAACGAGTTTGTGTCTTTAAAGGACTATAGCAGCCCCATTCTATGTTAAGGGTTGGCTATTACAA

TTATTATATGCTTAGGGAAAAAATGTAAGCCCCGTAGTTTGTGCTTTTCTTGATGTACAGAAAGGTTTATCTTAGGTGGATAGGT

TTTGTTTTGTTTCTTAAATGGGATTTTTTTGGTTCGTGTCTTTGAAGGGCTGTTTCGCGACGTCATTAATGAACTAATCGGTTTT

CAGATTTCAAGACGGTGTGTAATTGATGTAACCACTGAGGAATTTCAGTGCACACCAGACTAAGACTCTTCCAGCGCAGGGGATT

CCAGATGCTTCTTGGGCCCTCTGGAAGCCATGGGGATGTTTCCAGACCGAAAGGAGGGCTTTGCTGGGGAGCAGATGTGCTGCCT

CTCCCCGACCCAGGATTTTGAGGCCATGTTTCCGTTAATCTGGACCGAGAGCCCTCTGGGAGAGGGAGGCAGGTCGTAGGGGGCG

GGGGTGAGGGGGAGCGAGATGAGGTCGTCGCTGGACGCTGGGCTCCCTTGTCGTTGTCCTTTTCCCCAGAATCCATGGTCAGGCC

TAGGGAGCCACCCCTGGGTGCTCGAGATGAGTCCCCACCCTCACTGAAGGTCGGTCACTGGATGTTTGTGTGCATCGTAAGGGGC

CCACCGAAGTCCCGAAGCCTTCTCAGGGACCAGCGAGAAAGAGGAGCAGGCTTGGGAGACAGGGAAGGAAAATGCAGGGGAAAGG

GCTCACCCCTCGACCCCAGGTAAAATTAGAAGGAACGTGTGGCAACCCAGGTGCAGCTTTGGTCGCTCGCTCAAGGACTTTGCTA

GTCACTACCATTAATTAATTAATCACTATCATTAACTACCAAGGACACCGTTTTTATTCCCCTAAAAGCGTCACCTTGAGGGGAA

TGGAGAATTGGGCAGCAGCTATGCAAATCCTGGGACAGGAGACACTGCCTGAGGACCCTCTCTCACTCCCAATCCCAGAACCCGA

AGTTATCCCCGACAACCAAGTCCAAGCACATGAACCAAGACGATCAGCTTCAGGCAGCTCCTTACCCCCACAAGCGGCCCAGGAG

GTGGGCATTATCCCCCACCCCTGGGATTTCTCCATCCCTCCCTCTTCTCTCCTGCGGGAGAGAGAGCTGTGGTCACCCAGTTGGG

CGCGATGGCTCTGGACTAATGGGGTCTCTAGACCCAGGGCACAAAGGCCAATCTGCCAGGGGTTACTGCATGTAATGAGATAATC

AGACATGTTGACCAACCTAAAAGAAAAGACTCTCCCAGGGAGTAACTCCCAGTGAAATAATTTATTAAAAAAAGCAAAAAAGAGA

CATAAATTTCTCTCTACTACTTGAGGAAACAGCAAACAGAACGAATTAGGGTCTTGGCCTCTGCAGGAATAAATTATTTCCGACT

TGGTCTGGATACCTGTAATTATTTGTAAGCTGTGGGTAGTAATACTGTAATTGTCCCCCGGTCCTTTCTGGAAGTAGCAATGACC

CCAAGGACAATTGGTGACGTCTCCACAGGGTTTACACATGGAAAGGAGTGAAAAATCGAGGAATTCTTTCAGATAGCCCAGACCA

AAAATCCTCTCAGCCATGAAAAGGTCATATATGTGATGCTGGGCCAAGCGGACTTTTCTGGAGTAACCATATCATAACTGATTGC

GGATGTAGACAAGAGCGTATAAACCAAATAGGCTTGAATCAACGCAGTCCTGGATTTTCTGTTGCCTCTGCTTGCTGGGGCAGTG

GAAGTTCTTAAACTCCACTTCAGAGGTTGGAAATTCTTCCCCCTCCCCCACCTCCTTAGTGACAAGGTCTCTGATCTCCTGCTGC

CACTGCAATAGCCTCTCCCATCCCGCGGGGAACGGCCGGAGTTCTTCCCTTGATCTCTCCCGAGTCGGCTTCCGCTGGGGATGGA

TCGCAGGTAGGCGCCGGCGCGGCCTGGGGAAGAACAGTTGCGGAGCATCTGAAGCGGAAAATCCAAGCAGATGTGAGGCGATCCG

GGCCCGCCTCGTTCCTCTTGGGGCCTGAATTTCTTCCAGATAAGTTTCCTAATGGAACATTTCTAAGAGGTGGGGTACGAGGCGG

CTTGCTCGCACGCGCAGTGGGACAGACTGCGGGTGGGGACGTACTGAGAGGTCCGGACCTCAATGCGTCCGACCCGTCTCCACAC

CGCCCTTTTCCAGCCCCCAGTCTCCTTTCATTCCCTACTCTTCAGGCTCCTTTGGGGCCAGTGGGTGAACCGCCATTTAGAACGG

TGCCTCGGACTCGGGGGTCGTGCGCTCCATCTCTGCCTCCCCCCTGGGGCCCGCGAGGCTGGTCCGGGCTTTCTGAGCTGGGCGT

TCGGCTTTAGGCCCAATACCTGGACCAGGAATTTCTTCTCCCCGCGCCAGAAGGGAAAGACATAGGAGGTGTCCCAATCTGCGGT

CACCGCCGATGCTCCTGACCACTCTAGTGAGCACCTGCCCGGTACTTTTCCATTCCAACAGAGCTTCCAGCTTCATACTAACTAT

CCCACATACGGCCTGTGGGTATTAGCTCTAAGTGTCCTTTTCCGAGGGCCCGAGGCTCCCCCTCCAGCAGGGAGAGCTCCGGGAC

GGCCCCCACCAAGGGTTGGGTTTCTTCCTTCACAATTCCACAGAGGCATCCCTGTCCTTCCTACCTGGGAAACCTCGAGGTGCGG

TGCCCGTGTACTTCTGGTACTTTGCGTGGTGCCATCAGGGACCCCAGAGCCACAGCTGCGTGTGTGTGTGGATGTGTGTGTGTGT

GTGCGCGCGCGCGCGTGTACGGCGAAAGGATGTGCTTGGGGGAGCCGAGTACACAACGTCTGCTTGGGCAGCTGCTGGGCAGGCG

TTGGGCCTGGAGGTATCTCACACCCACGTATCTTCCAGTCTTCAAACACGGCATTGCTCTGCCTCCCGTAGCGCGCTTCGAACCT

GCCTCGCGGACACGTGAACAGAGGCTGTCCCTGGGAAGATAAGTGCGCTTTCCCGTAAAATCCGGGAAATTTGCCTTGAGGAAAG

TTTCCGTTCTTGTTACTTGTCGGGTTTCTCCCACTTCCACTTAGCCATGTTTCTGCGATCTGGGTAATCCCTTTCAAGCCCAGGA

GGAATTCTCCCGGGTCCATAATTGAGGGTCGGAAGCCGTGGGGGTGAGAAACGCATTAAATCCTCCCGAAGCCCAGGAGGTGCCA

GAGCGGGCTCAGGGGGCCGCCTGCGGAAGCTGCGGCAGGGGCTGGGTCCGTAGCCTCTAACCCCTTGGAGCTCCTTCTCCCAGAG

GCCCGGAGCCGGCAGCTGTCAGCGCAGCCAGGAGCGGGATCCTGGGCGCGGAGGTGGGTCCGACTCGCCAGGCTTGGGCATTGGA

GACCCGCGCCGCTAGCCCATGGCCCTCTGCTCAAGCCGCTGCAACAGGAAAGCGCTCCTGGATCCGAAACCCCAAAGGAAAGCGC

TGTTACTCTGTGCGTCCGGCTCGCGTGGCGTCGCGGTTTCGGAGCACCAAGCCTGCGAGCCCTGGCCACGATGTGGACTCCGCAA

GGGGCTAGGGACAGGCAGGGGGAGAGCCCGGGTTTGCGCACACCTTCCAGCCCCTGGAGGGAGCCTGCTCGGCTTCGAACGCCTT

CGAACTTTTGACCTTCAAAGGAGTCCCTGGAAAAGGTCAGGAGCGCCTGCTGCAGGCACGGTTGCCGAAGGCCAGGCCTTCCTGG

CGCAGGGGAGGGCCAGGGGAGGGAAGCGGATACTCAGTCGCTGTCCGACGGCGAGTTTTCGGAGCAGCAGGCTCATGATCCCGGG

CCAGTGGCGAGAGCAGTGACACCGAGAACCCAAATCTCCGCGCCCCCATCCGCGGCCCGGTGTCCTCCCGGCCCCTGCTGACCTC

CAGGTCACGCACCCCACTGCTCCACGGCTCTGCAGCCTGTGGCACACGGCCGAGAGTCCCCACATGATCTCGACGCCAAGGTAAG

GAATTGCCCTGCGTCCTCTGAGCCTGTCTCTGGCCTGGGGGGCCGGGAAAGCTGCACTCCTGGAAGAGGTGGGGTTATGTGACCG

CCGCTGCAGGGGTGCGCGGAGGACTCCTGGGCCGCACACCCATTTCCAGGCTGCGGGAGCCGGACAGGGGAGGGCAGAGGGGGGA

CAAAAGGACTCTTTAGGTCCAAAATGACCCTGAAGGAGAGTCCAGAATGCCCAGTGGCCGCGTCTGCAACGGAGTCTTCTTTCTC

CAATTGCCTTCTGCCCCATCACCATGGGCCCCACCTGCGCCACCTGCGCCCACCCTGTGACCCTGGCTCAGCGACCTTGGCCCTT

AATCGCCCAACGCCGATTCCTCAAAATTCCGGCTGCGCTGAATCGGGCTGCTTTTGCCGCCGCCCCGGCAGTTGGGCCCTGTTTC

CGCCGGCGCCCTGGGAGAGGCCTCACCACTCGGCTGGGCTCCCTGGCCCCTCCCTTCCCCTGGCCTGAGCGCCCCTGCGGCCTCC

CGCTCCTCCTGAGAAGGCGACAATCTCTTTGCACCTTAGTGTTTCGAGGACAGAAAGGGCAGAAGGGTCACTTCGGAGCCACTCG

CGCCGTTTTCACGTGTGTGTGTAATGGGGGGAGGGGGGCTCCCGGCTTTCCCCTTTTCAGCTCTTGGACCTGCAACACCGGGAGG

GCGAGGACGCGGGACCAGCGCACCCTCGGAAGGCTCGATCCTCCCCGGCAGGGCGCCTGGCCAACGAGTCGCGCCGCCTCCTCTC

GGCCGCGCCTGCTGGTGACCTTCCCGAGAGCCACAGGGGCGGCCTCGGCACCCCTCCTTCCCTCGCCCTCCCTGCCGCCCATCCT

AGCTCCGGGGTCCGGCGACCGGCGCTCAGGAGCGGGTCCCCGCGGCGCGCCGTGTGCACTCACCGCGACTTCCCCGAACCCGGGA

GCGCGCGGGTCTCTCCCGGGAGAGTCCCTGGAGGCAGCGACGCGGAGGCGCGCCTGTGACTCCAGGGCCGCGGCGGGGTCGGAGG

CAAGATTCGCCGCCCCCGCCCCCGCCGCGGTCCCTCCCCCCTCCCGCTCCCCCCTCCGGGACCCAGGCGGCCAGTGCTCCGCCCG

AAGGCGGGTCTGCCATAAACAAACGCGGCTCGGCCGCACGTGGACAGCGGAGGTGCTGCGCCTAGCCACACATCGCGGGCTCCGG

CGCTGCGTCTCCAGGCACAGGGAGCCGCCAGGAAGGGCAGGAGAGCGCGCCCGGGCCAGGGCCCGGCCCCAGCCGCCTGCGACTC

GCTCCCCTCCGCTGGGCTCCCGCTCCATGGCTCCGCGGCCACCGCCGCCCCTGTCGCCCTCCGGTCCGGAGGGGCCTTGCCGCAG

CCGGTTCGAGCACTCGACGAAGGAGTAAGCAGCGCCTCCGCCTCCGCGCCGGCCGCCCCCACCCCCCAGGAAGGCCGAGGCAGGA

GAGGCAGGAGGGAGGAAACAGGAGCGAGCAGGAACGGGGCTCCGGTTGCTGCAGGACGGTCCAGCCCGGAGGAGGCTGCGCTCCG

GGCAGCGGCGGGCGGCGCCGCCGGGTTGCTCGGAGCTCAGGCCCGGCGGCTGCGGGGAGGCGTCTCGGAACCCCGGGAGGCCCCC

CGCACCTGCCCGCGGCCCACTCCGCGGACTCACCTGGCTCCCGGCTCCCCCTTCCCCATCCCCGCCGCCGCAGCCCGAGCGGGGC

TCCGCGGGCCTGGAGCACGGCCGGGTCTAATATGCCCGGAGCCGAGGCGCGATGAAGGAGAAGTCCAAGAATGCGGCCAAGACCA

GGAGGGAGAAGGAAAATGGCGAGTTTTACGAGCTTGCCAAGCTGCTCCCGCTGCCGTCGGCCATCACTTCGCAGCTGGACAAAGC

GTCCATCATCCGCCTCACCACGAGCTACCTGAAGATGCGCGCCGTCTTCCCCGAAGGTGAGGCCTCAGGTGGGCGGCCGGGGACG

CTGGGGAGCCCGGCGGCCCCGGCCCAGGCGGGAAGCGCAAGCCAGCCCGCCCAGAGGGGTTGCCGCGGCCTGGCGTCCAGAGCTG

GGGCGTCTGAGGGAGGTTGCGTGAGGGTCTTCGGCTTCGGCGCTGGCTTGGGGCGAGGGGCCAGGGCCTTGGCGGCCCAGGCGAC

CAAACCCTCTCCTGGTCCAGGGCTGGGTGAGGGCGAATTACGAATTGTTCCAGGGGCAGGCAGTCCCCCAGCCCGCACGGCCAGC

GAGTTCTTTCTGGTTTTGTTCTTTCTCCCTTTCCTCCTTCCTTCCTTCGCCAGTGCATTCTGGTTTGGTTTGGATTTTTTTCTCT

CTTTCTTTCCTTTCTTTCTTTCTTTCTCTTTCTTTTTCTTTCTTTCTTCCTCTTTCTTTCATTCTCCCCTTCCTTCCTTCCTTGG

CCCCCTCTCTCCCTCCCTCCTTCCTTCCTTCCTTTGCCAATGCATTGGTTTGTTTTCTTTCCTTTTCTGCTTTCCTTCCTTTCTT

TGGAAGTTCACTCTGGTTTTGCTTTCTTTCTTTCCCCATCCCTTCCTTTCTTTATCCCTCCTTCCCTTCCTCCTTTTCTTTCTAC

GATTCCCTTTATTTTTCCTTCATTCCTCCCTCTTTTTGTCTCTTCTGGAGGAGGTGAAGGAGGGTCAGCTTCAGGCGCTGCGAGT

CAGCGGGGATCACGGTGAGGCCCAAGCACTGCAGGCTGAGGCCACAGAGCGAACACTTGTGCTGAGCCGGGCCCTCTCGTGAGGC

TGGGGTGCGGGAAGTCCGGGCAGGAGAGACCCGCCCCCGCCGTTGCTGAGCTGAGACCCGGCTGAAAGAGAGGGGTCCGATTAAT

TCGAAAATGGCAGACAGAGCTGAGCGCTGCCGTTCTTTTCAGGATTGAAAATGTGCCAGTGGGCCAGGGGCGCTGGGACCCGCGG

TGCGGAAGACTCGGAACAGGAAGAAATAGTGGCGCGCTGGGTGGGCTGCCCCGCCGCCCACGCCGGTTGCCGCTGGTGACAGTGG

CTGCCCGGCCAGGCACCTCCGAGCAGCAGGTCTGAGCGTTTTTGGCGTCCCAAGCGTTCCGGGCCGCGTCTTCCAGAGCCTCTGC

TCCCAGCGGGGTCGCTGCGGCCTGGCCCGAAGGATTTGACTCTTTGCTGGGAGGCGCGCTGCTCAGGGTTCTGGTGGGTCCTCTG

GGCCCAGGAGCTGGGAGGGCTGCGCCGGCCTCTGGAGCCCCGGGAGCCAGTGCCGAGGTAGGGAGACAACTTCCGCCGCAGGGCG

CCGGACGGTCGGGGCAGAGCAGGCGACAGGTGTCCCTAGGCCGCAGGGCGCTTCCATAGCGCCATCCCCACCAGGCACTCTACTC

GAAATCGGAAAGCTCGACCTTTTGCGTTCGCCTCTGCCAAGCCTGTTATTTGTGCTGGCCGCTGGGTCTGGAGCTGCGCTTCTCG

GCCCCTCCCCGGTGGAGCGCAGAGGGCTGGTCTGCAAGCGCGGCCTCCAGCCCCGCGGCTCCCCGGCCCAGGAGCCAGGCGCGGG

CTGACCCGGGAGCACCCGGCAGCGGAGGGGGCTGGAAGCGGACCCTAGGCCTCTCCTGTGCCACCCGGCCCTACCGCGCGGCCGC

GGGGCGCTCTCCTCTCGGGCGCAGCGGTCCTTCAGCCCAGGGCAGGTTCCTCCCTTTCCTACTCGGAACGTGGCAAAGATACCCC

AGTCCCAGCCCCTCCAGCTGAGAGCTGTTGCCCAAGGTCGTCGCTACTTGTCCGCTCAATGGTGACCCCTTGGCAGAGAACTAGG

GATGATTCCACTCCGGTTGATGTTTTAGGGGAAATTAAAAGAACATTCGGTTTTCTGAGTCTCCTTCCGGGGAGGCGTGGTGGTA

ACTGGTTTGCTGGGAAGAGCCGTTCCTTAACCGCATGCAACAAAGCAGGTGTGGAATCCGGACGAGAGGGCACTCACTGCCTTCT

GCCCCCTTTGGAAATAGAAAAAGCCTTCGAAGCAGCAATCCAAAGATCAAATGATTTGCGGTCAATGATTTCAATTAAACCAGAA

ATTAGTAAGGGAGGGCCGAGAAGACACGGCTGCTCAGAAGCTGTTCGCTGTTTGAGGGATTTCCCGGAGAGCCTGTTAAAAGATG

CGAAGTGGTGGGTGTACCGCTCAGCCACCTTTAAACCGGCTCTGTGCGTTCTGGCTCTGGAAAGCAAGTCTCCAGGCATTTGGGC

TCAGAATTGCTGGGCCCCGAGTTTGGGCGGGGGTGGTCCTTCTGGGGGTCAGGCCTTGAGCAGCTTGCACTGGTGGCAGGTTTGG

GAGCAGTTGAGGGGCTTCCTGTGTGTCTTTTGGAGGGGGTGACCCTGGAAGTTGGCACTCTGGAAGGGAGCTGTTTGGCCCTAGA

GTTTTGGAAAGGGCCCTGAACCTGTTCGGTCCCCCTCGGAAAGGGAAGGGAGCAGTGGCTTAGTCCCTCCCTCCTCCATTCGTGC

AATGCCTGGGGTAGGGGTAGACCTGGAGCCGGTGGACTCATATCCTTGGAATTCGTCAGGACAGCTGCTCCGGGGCCTTGGCCCT

CAGTCAGTCTGGGGCTGAGGAGTAGGGAAGCTGGGAACTTGGGGCAGAGGAAGAAGATGCGTTTAGAAAGACCTCCATTATGCAA

ACTGGAGTCCATTTATGCAAACTGGTCACCCTTCCAGTAGCTCCAAAGAGTGGCAGTGGAGTGGCATCTTGATTGATTTAACCTC

TTCTCAGGGGACCTGGGTCTGCGAGGGAGGATATGGCTGCGGGGTTGGAATAGGATCTGTCTGAGCTGCCAGGGTCAGGGTGGTG

GCCCTAGGGAGGTTTTAGGGCCAGGGTGGTCCCGGGCTGTGGCAGGGGCTCTCAGATCGCCTCGGGCTCTCAGCTGCAAGGTGAA

AAATACCATGAGGAATTGATCTGCCAAGGGCGGTCTTGTCTCAAAGCAAGTGGATTGCTGGGGTAAAGAATCTAGAGACCAGCTT

AGGACTCTGGGAGGAAGAAAAAAAAAAAAAGAATAGCATAGTCCTAAGGAACTGCAAGGATCACCAGATTAACCCTTCATACCTG

GGGAAATTAAGGCCAGACATGACACAGGCCTTTCCCAAGGCTCTGTAGCAAGGGCAATAGCAGGCCAGTTGCTGCCACTGCGGTC

CTGTGGGGCATGTTCTCACTCCACTGCACCCAGGAGGCTGCCAGCCTCTGTTCCTTTTAACATAGATCTCCTCAGTTGTTAAGAC

AGAAAGAGGAACTCAGAGGGGTCCCTGTGTGCAAGGCAGAGGGAGACCACCAGAACCAGGGTAAGCACCCCACTTGGTAGCCAGT

TCAAGGACTTGGGGATGTTTTCAACATTTACAGCGAGGTTTGAGGCCCCATTGTCATGCAGCGCTACTCGGCCTTGGTCTCCTTA

TCTGTAAAATGGGCCCATTAGCAATGCACAGGGTTGCTGTGATGAAGGGTGAGGTCCCACAAGCAAAAGCTGTGCAGTGAGGGGG

GAATCCTAAGCATTGTTCCTATGCCATTCACCCCTTCCTGTGAGCTCCCCATATTCCCTGGCTCAAAGGAGTCTTGAATGGCAGG

GATGGAGGACTCACTGCCTGGACTTTGAAGACCCCTGCTTTCTGGGTGACCACCTTTTCTTCCCTTTGACAGTGAACTAATACAT

TGGAGGTAGATAGTGCTGGGAAGAGGACAGGAGACCACGGCTGACTTTGGACATGGGCTCGAAATTGATAACTTGATGAGTCTTG

GAGGGTGGTTAAGATAAGCTCGGGGCTGGGGCAGCGCTGAGGTCTGATGGTCAGCCAGCCCTCCCCAAAGTGTGGCCCTCCGTTC

TGGAGATAGGGGCTTTGGAAACTGCAAAAGCGTCCTGGCAGGCCAGCTCTGGTTGCTCCCTGGCCATAGCTGCTCTGACTACAGG

CAGCAGGACGCAGGTCGGCCTCTGCCCATCGGAGGTCAGAGGCAGGGCCTCCAGCACCAGACTCAGCAGTGCCACTGCAAACCTG

GCACAACAGGCTGGTCCCAGGACTCAGCTCAGCAGTGAAGTTGGAAACCAAGGTTGAGTCTCCCCATCTCCCTTTCCCCAACCCG

AAAGACCCAAGATGGGTGTGGGTGAAAGAGGGAGAAAGAATTGCTACTCCAGAAACTGTCATTTGCCCACACGAAACGAGGTGGG

GTTCAAGGTCTGAACTCTTCCAGTGCCTGGGTGCCTTTGGGTTTAAATTCAGCTGCAGGTGCCCCCATCACCACTTCCACCTGAG

CACACCACGAGAAGCCAGGTTATCTTAGAAACTGTTTCCCGGAATCAAAGCGACTTGATTTGGAGAGTTGGGTGAGGAGAAACTC

ACCCCTATACCCCTCAGGGCGTCAGAGATGTGAGGCAATTCTCTACCTCCGCTGGAAAAAATGCAGATTTATTAAAGGTCGACTG

TTTAGCAGAACAACGTAGATTTTTTACAACGCTTTCCCCGTCTCTGCTTTGAAGCCTGCCAGGCTGCAGCTGGGGATCCAGGAGG

GAAAGCCCGCAGGCGCAGAGGGGACAATCCGGGAAGTGGTAAAGGGGACACCCGGGCACAGGGCCTGTGCTTTCGTTGCAGGCGA

GGAAGTGGAGCGCGCGCTGCAGATTCAGCGCGGGGCTAGAGGAGGGGACCTGGATCCCTGAACCCCGGGGCGGAAAGGGAGCCTC

CGGGCGGCTGTGGGTGCCGCGCTCCTCGGAGCCAGCAGCTGCTGGGGCGGCGTCCGAACTCCCCAGGTCTGCGCACGGCAATGGG

GGCACCGGGCCTTCTGTCTGTCCTCAGAATACGTAGGATACCCGCGGGCGACAAGCCGGGCCAGGCTAGGAGCCTCCTTCCCTGC

CCCTCCCCATCGGCCGCGGGAGGCTTTCTTGGGGCGTCCCCACGACCACCCCCTTCTCACCCGGTCCCCAGTTTGGAAAAAGGCG

CAAGAAGCGGGCTTTTCAGGGACCCCGGGGAGAACACGAGGGCTCCGACGCGGGAGAAGGATTGAAGCGTGCAGAGGCGCCCCAA

ATTGCGACAATTTACTGGGATCCTTTTGTGGGGAAAGGAGGCTTAGAGGCTCAAGCTATAGGCTGTCCTAGAGCAACTAGGCGAG

AACCTGGCCCCAAACTCCCTCCTTACGCCCTGGCACAGGTTCCCGGCGACTGGTGTTCCCAAGGGAGCCCCCTGAGCCTACCGCC

CTTGCAGGGGGTCGTGCTGCGGCTTCTGGGTCATAAACGCCGAGGTCGGGGGTGGCGGAGCTGTAGAGGCTGCCCGCGCAGAAAG

CTCCAGGATCCCAATATGTGCTTGCGTGGAGCAGGGAGCGGAAGAGGCAGCCGGTCCTCACCCTCCTCTCCCGCCACGCACATAT

CCTTCTTGACTTCGAAGTGGTTTGCAATCCGAAAGTGAGACCTTGAGTCCTCAGATGGCCGGCAACGCGCCGAGGTCACGCTCCC

CAGAAACACCCCTCTCCCCTCCCCTACCCCAGCTCCCCCTGGGGCGGGTGGTAATTGGGGGAGGAGAGGCCGCAGGCAGGGAAGG

GGTGGGAAAGCCAGAGAGGGAGGCACAAAGTGATGGCAGCCCGGCAAACACTGGGGCTTCGGGCTGGGCCGCGCTCGTTTAATCC

CACAAAAATCCCATTTTGGAGGTGAGAAATAGAGGTTAGAGGTCGGGCCCTTCTGGAGATCAGACCGAGGAGACGGGCCCAGCTG

GCGTCTTAAAGCAAGGAGGGGGAGTCGGGAGGAGGTGAGACCCCTGCACCCAGGTGGGGCTCCCAAACCGTTCTGGATTTACCAC

ACTCCCAGGTCCGATTTTCCATGGAGGGCTGGGGTTAGGGACTGGCACCTTCTTGTTGTTAACCGCATTTGATATTCACAAGAAC

CCTGTGAGGAGACTTTGTCACCGTTTTTAGATGCCTGAGGTTGCCGGAGGGGCAGTGAGAGAATCGTCTAACCTGGTGTTCCTAC

CACAGTCCAGGCCCTGTGTCCTGGGCTGGACCCACAGCCCCTGCCACCACCCAGAGGAAGGCGCGAAGCTGGCTGCCTCCTTTAC

GGGTCTCCCTTAGGTGCCCTCATGAAGGGGGACGGCCACCTCACAGTGCAGGAACTATCTCCCCGTTTGCTCCCAAATAGTCTTC

TTGGTGTGGTGCTGTCTATGGTCTGTGACCTGCATCTGGAGTTACCCCCAGGACCAGCTTCGGAAGAGGAGGGATCGCTTGGAGG

CCGTGCAGTGTGAGGAACGGCAGGCAGGGTGTGGGACCAACATGCACACACTCGCAGGTGCTGGGGCCAGGGAGGAATGAGGCGC

TGGCTCCCTTTCCCTCCATTTCTCCCTGGGGGTCCCAGCAACCTGGCCATCCCTGACTTCCAACAGCACAGCGTCCCCACAGGTC

CTGCAGTGCTCTGCAGGGGTGCAGGGAGCTCCCCTCCCCCCAGCCGCAACCTCACCTTCCTCACCCCCACCCCTCCGGCAGGAAA

CCACAGGCTGGGTTGGGGACCCCTGGTGCTCCAAGAGAGCAGTGAGTGCTGGGAGCCGCTAACCCCGAGGCGCCTAGCACAGACT

CTTCTCACCCCTTATTTCTGAAATAAAGCCCTTCCTTAGGTCCAGATGAGGACCACGTGCTCAGTGCCTCACTTTCGTGGGAGTG

TATATCACTTTACAGTATCAAGACAATTTTCTTTCGTTACAAATCTTTATTTAGTCTCTGCGTTTAGACCAAAGTAGATTTTTAT

GGGCTGAGTGAAAAAACCTCGCCCGCATTGGTTTCTGATGGAACAGCTGGCAGCGCCACGGCCCCGGGTGGGGTGGCCTAGAGGC

AGGGGTGCTTGGGAGGAACATCTAGCACCCGACCACCTCCACCAGGTGGGAAAGGGACGTTTGCACCAAATCTCCGCCGGCAAAG

CAGAGGCTTTGGGGAATTACAGAAAAACTATAATGATCTAAAAGAGAACAAGTTATCTTGAACTGTGCGGGTATTTGAATCATAC

AGAAAATTGTCCTGTGTGCCCAATGCACTTTTGCATGTAGAGCCAGGGCCTTCGAGGAAGCTTTCAGGAGATCCCGGGCAGCGGA

GTCTGGTCTGGAGTTTCATTTCCGTAGGTGCAGATTTCTCCCCAAGTCTTCCCGCCATGGGCTTTGCAAGAAGCCAGGGCCCAGA

GGCCACGCTCACCGTTAACACTGCACAGGGCAAAGGTGGCTCCAGGACAACTGCCCAACCCCAGGAACGACCCAGCAGCAGAGAA

AAGGACAGCTGCCAGGGTGCCTTTGTCGCTTTTTGGAAATCAGAATTCCTGGGTCCTTAGTTAAGTCTTACTTCACCAAATCCCA

GGACCTTCACATTTTGGTTCTTGCCATTGCTAACAGTTGTAAATGCTGCCGCCACGAGGCCTGGGAGGAAGGACCCGCTGGTGAG

AGCACAGGGAGTGCTGCTGTGATCACGGTGGTGATGCGGGGTGAGCGCGATTTCCCGGGATTAAAAAGCCACCGCTGCCCCCGTG

GTGGAGGCTGGGGGCCCCCGAATAATGAGCTGTGATTGTATTCCCGGGATCGTGTATGTGGAAATTAGCCACCTCCTCAGCCAGG

ATAAGCCCCTAATTCCTTGAGCCCAGGAGGAGAAATTAAAGGTCATCCCTTTTTAAATTGAGGAATAGTGGTTTTTTTTAACTTT

TTTTTTTTTAGGTTTTTAGTTGCCGAATAGGGAAGGGTTTGCGAAGCCGCTGCCCTGGGCCGAGGTGCATTTTACGCTTCCAGAG

GTCGAGGCCTCCAGAGACCGCGATGCCCAGGGCGTTCCCGGGGAGGCTGAGAGACCCAGGGTGCTCTGGGTGACTGCACGGCGAC

TCCTCGGGAACCCACTCGTGGCTGCCCGCTTGGAAGGGCTTTGCGGCCCCGGGAACGATCTCCAGGATCTCCACGGCTGGTCAGG

TTCCCCGTCCCTCGTATCCCGCGCTGCCCGGGGGCTCCTGCCTTTGGTTCAGTGCTCGCGGCACCACCGCACTCAGGACGGCAGT

GGGGGGCTGGGGCTGGGGCTGGGCCTGGCCCAGCGTGGGTTGGGGCGGGGGACGCGCCAGCAGCGCCCGCAGCTCGCTCCGCAGG

GGTCGCAGCCAGGGGTCGGGAGCTAGGCTCGTGGGCCGGGAGACGCCGGGCGCGTTGTCCTCCGGGGAGGTTGGGGTGCAGGCGG

TGCACCGACCCTCGCCATCTGGCGCTGCAGCCACCAGCCACGGCGCTTAGTGGAGGGTCTGCGGCCAGGCTCCCGGCGGAAAGAT

TCCGGGGAGGGCTCGGGGGTTGTCCCAGCCCGCGCTAAGCGCCGCAGCCTCGCCCGGCTTTCCTGCTTCCTCGGACTGTGCAGGG

GAAGCCTGGGGTCTCGCGGGGCGCAGCAGTCAGGTCGAGGGTGCAGCAGGAGGGGAGTCCTGACGGGCAGGTCCCTCTTTCCCCT

GGTGCGCAACACTGGTTGGTAGCTTTTGCGGAGGTGGTGAAGAAGGGCAGGAGGCCTGTTGAGCGGAGGAGTCCGGGGATCCCTA

ATTATGTGACAGGAGACCCTTTCCAGTTCGGCCTGTGGCCCATCCCTCTCTCACCGCCGGCAGATTGGAGTCTGCTCTCGGGGAG

CCCCCAGGTAAACCCCTCACAGGGAGAAGGTTTCGGATTGGAAGGAGGACCGCGCTCGTGGGGCGCCTGTGAGAGCTGGGAAGCC

CAAGGGGTAGCGTGTAGGGGGTTTTTTATGCGGGAGGAGCTGCCTCCTGGGCGGCGGGGACTTTCTGTCTCAGCCTGTCTGCCTT

TGGGAAAACAAGGAGTTGCCGGAGAAGCAGGGAAAGAAAGGAGGGAGGGAAGGAGGGTCCTTGGGGGAATATTTGCGGGTCAAAT

CGATATCCCCGTTTGGCCACGAGAATGGCGATTTCAAAGCAGATTAGATTACTTTGTGGCATTTCAAATAAAACGGCAATTTCAG

GGCCATGAGCACGTGGGCGACCCGCGGGAGCTGTGGGCCTGGCAGGCTCGCACAGGCGCCCGGGCTGCCGGCCGCTGCGGGGATT

TCTCCCCCAGCCTTTTCTTTTTAACAGAGGGCAAAGGGGCGACGGCGAGAGCACAGATGGCGGCTGCGGAGCCGGGGAGGCGGCG

GGGAGACGCGCGGGACTCGTGGGGAGGGCTGGCAGGGTGCAGGGGTTCCGCGTGACCTGCCCGGCTCCCAGGCATCGGGCTGGGC

GCTGCAGTTTACCGATTTGCTTTCGTCCCTCGTCCAGGTTTAGGAGACGCGTGGGGACAGCCGAGCCGCGCCGGGCCCCTGGACG

GCGTCGCCAAGGAGCTGGGATCGCACTTGCTGCAGGTAGAGCGGCCTCGCCGGGGGAGGAGCGCAGCCGCCGCAGGCTCCCTTCC

CACCCCGCCACCCCAGCCTCCAGGCGTCCCTTCCCCAGGAGCGCCAGGCAGATCCAGAGGCTGCCGGGGGCTGGGGATGGGGTGG

TCCCCACTGCGGAGGGATGGACGCTTAGCATGTCGGATGCGGCCTGCGGCCAACCCTACCCTAACCCTACGTCTGCCCCCACACC

CCGCCGAAGGCCCCAGGACTCCCCAGGCCACCTGAGACCTACGCCAGGGGCGCCTCCCGAGCGTGGTCAAGTGCTTTCCAATCTC

ACTTCCCTCAGCAGGTTCCACCCAGCGCTTGCTCTGTGCCAGGCGCCAGGGCTGGAGCAGCAGAAATGATTGGGCTGCTCTGAGC

TCTGAAGCATTCGGCCGCTGTGTGTGTGCAAGGGGCGCAAGGACGGAGAGACAGCATCAATAATACAATATTAACAGGAGCACTT

GTCCAGAGCTTACTGCAAGCCACATTCAGTTCCGGACCTTATTGACTTCCCCCTCCCATCTAGAGTGGATTCTGGTTTTTCAATT

TGTTTTGTTTTGTTTTTTGTTTGTTTGTTTGTTTTTGAGACGGAGTCTCACTCTGTGGCCCAGGCTAGAGTGCAATGGCGCGATC

TCGGCTCACTCCAACCTCCGCCTCCCGGGTTCAAGCGATTCTCCCGCTTCAGCCTCCCGAGTAGCCAGGATTGCAGGCACCCGCC

ATCATGCCTGGCTAATTTTTGTAGAGACAGGGTTTCACCCAGGCTGGTCTCGATCTCCTGACCTCCGATGATCCGCCCACCTCAG

CCTTCCAAAGTGTTGGGATTACAGGCGTGAGCCAACGCGTCCTGCCTTGATTCTGTTTTTAACTCCATTTTTTAGAGGAGGAAAT

TGAGGCACAGAGAGGTTAAATAACATGTCTAAGGTCACACAGCAAGGGGTGGAGCGGAGTTAGCCCACTGGCCTAGCTCTAGAGC

CCACCCGGATAACCAGAACTTGGTGAGGCCTCCGGGCTCTTGCTTGGTTTGGAGCCAGGTGCTTAGCGCCCCGAGCCCGGGGCCA

TTCACCCTGCAGGAGCTGCACGCGCCCCTGACCTCGGCTTTTCCCTGGCAGCAGAGGGGCTTTGCGGGTCGGCCGGGTAGCCCTG

AGCACAGCTCGCCACTTCCAGGTGGGCTGTTGGCGCTGGCTGGGGACACATCCCGATCTTTCAAATGCCCTTTACAGAGCCTCAT

CAACGACCCGATTCATTCCCCCCTCCTGTCATTTGTCTCTGCCATCGAAAAATGCCTACCGAGAGCTGCTCTGCATTTCCGCCCT

CTATTTTGTGTTTTACTTTAAAATAATAATAAAAAAAATGTTGGCTGCAGGACGCCATGACTTAGGTCAGCGAGTCAGCCGCTAG

CTCTGCATTTCCAAAAAGCAGATCTTTTCACAACTCTCTTGCCCCAAGTGCCCTGGTGTGGTTTATTTTTTAAAATGCATGCCTG

CGGAAGAGAAGACCCGGGGAATATTCGAAACCCCGAGCTTTTACAACATAAAGCGCATGGTGTGGCCGCGGCGAGTAATGGCGCT

206
HLCS
CAAATCACTTGAACTCAAGTTCAAGACCAGCCTGGGCAACATGGTGAAACCACATCTCTACAAAAGTAAAGAAAATTAGCCAGGC

ATGGTGCTGTGTGCCTGTAGTTCCAGCTACTCCTGGGGAGGTCGAGGCTGCAGTGAGCCGCAATCACGCCACTTGTACTCCAGCC

TGGGCGACAGAGCAAGTCCCCATCTCAAAAAAAAAAAAAAAAAAAAAAAAAAAAGGCTGGGTGTGGTGGTCCCAGATACTCAGAG

GCTGAAAAGGGAGGATTGCTTGAGCCCAGGAGTTCAAGGCTGCAGTGAGCTGCGATCACATCAATGCACTCCATCCAGCCTGAGC

AATGGAGTGAGACCCTGACTATATTTAAAAAAAAAAAAAATAGGAAGAAACAACTCAACCACAGGGCTAGTATGTTACTCGGTTA

TAAAATGATAAAGCCCTAAACAGAGAATTAGCCCGTTTCCAGAAGAGGCCAAGAACAGATGATACAGCTGAACTGAACTCCTGCC

TGTACAGCTCGTTTTCTACAAGATTCCAGACCTGGAAGATGATGGCATCCAGCCCCCATTGAAGCACCTCGAACAAGAAAAACGC

CGAGTCCGAAGAGCCAGGCCTTGAACACACGATTCCTGTCTATAAATAACTCCCCCTGGGGAATAAAAAGCAGGATCCAAGGCAG

GAAACCCGAGCCGTGGAATCTGGTAAGTTCTTAGGAAACCCACTCACGGGCCTGAGTCCCCCGTGGAAGCGGCGACTTCGGCACC

TGGACACCCGAGTCCCCAGAGCCCCGGGCGGCCGCGCGTCCCTACCTGCAGGCCTGATACCGGCCGCGGAGCGCTCCTGGCCCCG

CTCCCGCCAGGCTCCGGGACCGCTGAAACGCACCCAGGGGGGTGAAGGCGTAGTCGCCAAGGACAGCGCAGATGGCAGCGGAGGC

ATGGGAGCCGGAACCTACCGTGGCAAAGGGCCAGGTCGGGACGCCCCTCGGCGCAGCCCCAAATCCTGCCCGCGCCCCAGCCCCG

CTCAGGCCGCGCCCCTGCCACCTCTGGCCACACGGGCTGAGACGTCTGGCTCCTGCACAGCGCACTTCCCGCTGCCCTTCTCCAC

TGGCTGCTCAGGCCCTGCCTCGCCAGCACGGCATCCGCGGGGGATCCCTACCTGTCCTTTAGGGCTTGCCTCATAGGTCAAACGT

CACCTCCCAGGGAGGTATGGCCTGCCCCCTGGCCAGGTGGGCCCCTTCCACGCTCGCCTGCAACACCACCCACCCACCTTGATAA

CTGCTTGTAAAGGTTGTACTGCTTTCCCCCTTGAGACTGCAAACCTTCAAGGGCAGGAAATGGGTCTGTTTTCCTGGCAAAATAA

TGAAGTTGGCTTAAGGTTTTGCTGAATAAAATGAGTGACAGACAAAAGTAGCCAAATTTGGCACTCCTGATGGGTTATTTGATGA

AGGAGGTGCAATGTATGGGCTTAACTAGTTATTCTGGATTTCTTTCCCCATGTTA

207
DSCR6
CAAGGCCGGTGCACGCGGACCCGAGGATTCGGTAGATGTCCCCGAAGACCCGCTGCCGCTCTAAGGCGGTGGAAGCGAGATTCTC

CGGAAACCCAGGGAATCCGATGCTCGCACAGGACCAAAGCCCGAGGCCGCGGGGACCACAGAGGGACGGAGAAGCCGGGACTCCT

CACATCCCACATCCGGCAGGGGAAGCCCAG

208
DSCR3
CTGATAATAAAGTTTTACCATTTTATAATTTAAAAATGTAAATATGGAGTTGGGCATGGTGGTTGGGAGGCTGAGACCAGAAGAT

CGCTTGAGCCCAGGGGTTTGAGACCAGCCTGGGCAACATGCAGAAACCCTGTCTCTACAAATAAAAAATTAGCCAAGCGTGGTAG

CACGCACCTGTAATCCCAGCTACTCGGGAGGCTGAGGCAGGAGAATCGCTTGAGCCTGGGAGGTGGAGGCTGCAGTGAGCTGAGA

CTGTACCACTGCACTCCAGCCTGGGTGACAGAGTGAGGCTCTGTCTCAAAAAAACAAAACACAAAAAAACAAACAAAAAAAAGCA

AATATATGTAAAAATAGGAAGTGCGGTTTCCCAAAATGAGGTCTGTAAACAACTGATCTAGAAAATGTTCTGGAAAAAGTAAAAA

AGGATCAGGATCTGAGGTCAACTGACCTCTCCCTGCGCTCTGGACAGGCAAACAGGCAAGGTTCCCTCTGAGGCCGTAGCGGCTT

CTCGTGGGCGAGTCCCTGTTCGCAGGTGACGTGTGGACCACGCTCTTCCGAAGCGTCTGGCCTGTGTGCTCTCGGGGAGGGGACG

CAGGTCAGCCCACCTAGCCGATGGCTAACAAGTCAGTTTGTTTTCTGAACGGAAGCTTAAACCTAGAAAAGTAACTGGGTTGGGG

TGGGGGTGTAGCCACATGCAGTAAAAGCACTGCCTGTCTGTATAACAACGACCTGATGAAAAAAGGAACGCGTGAAATGGGGAGT

GTTAGGGCGTCACAAACTCCAGTGTGGTTGAAATGAAAGCAGAAAGCAAATGGCAAGCTGGCTTCCCCTTCCAGCTTTTCACAAC

CCTGCCTTGCTCATGGTCAGCCCCAAGCACGGGCGGAAGAAAGGACTGGAGGGGAGGGAAAGGGGTGGGGAGCGAGGGTACCAGA

GGCGTGGGAGGACGGGGACAAAGGGGCAGCAAGGGACCGGCGGAAAGGAAAGTCGGCGTTAGCTGGATTGGAAACAGTCCAGACA

GAACGATGGGCTCTGCTGCCTCCGGGTGGGGCACCAAGCGGGGAGCGGGGCCACGAGGCAGGGGACAGTGAAGCACCATGCAGCG

CCCACCAGCCGGCAGCGCCCACCAGCCTGCGCTGCGCTGCACATGGTACCCGCGGCCCCAGCTGGCCAGTGTGTGGCGGAGATGA

GACCCTCGTGAAGAGACTAAGCGGCCACAGCAGGGGGAAGGGTTGCTCACATAACCCCATACTGCTCACACTACGAGGTTAACTG

CCGTGAGATCTGCCTGCAGCCAGCAGAAACCCGTTCTAGGAAAACGTTGCCCAGTGACTTCAGTGAGTGCCACTGACCCGGGCGC

CTCCGCCCCGGCGTCCGGCAGCAGCACCGATTGCGCAGGAGGCACCTTGCAAACAACCTTTCCTGATCCGCGCTGCAGTTCCCAG

GCCGGTTGCAGCCGTTTCACAGAGACTGCGCACACAAAGCGTCTCCGTGCCCTGCCATTCACCTTTCGACACAGCCGCAACCCCT

CTTTTCAGTGTTAAAACCTGGCGCCAAAAGGAACATGCGATGTGACGTGTTACCTCTGCGCATGCGCCGGGCATTCCCAGCGCCC

CGAACCTGATGAACGCGCGGTGGGGACCCCAGGCTTCCGTGCTTTCGTTTTCCTGGAAGCTACGTGTCCTCAGTCTACATATTGT

TACCTGGAAAATAAAGTTTTCTCCTTTTTTCTTCCTTTGTTAACAGGCAGAAGGTGTAGGCTGCAGGTTTCGGGCCTAAGAGAGG

GCATGGCTGGCGACACGGAGTAGACTCCTAGATGACATAACGGAGGCGAGTCTGCACCGGGGACTCGGCATTAGGAGGAGGCAGA

GGAAAAGCCCACCACCGTGGCCGAGGGAGATCTAGCAAGCAGCTTGCAGGGGGTGAAGTGTGTGCAAAGCAGGCTGAGACCTGTC

CAGTATCGAAACACGCCGCGGTGGTCAAGCAGGCTTTACCATGCT

209
chr21:
TGAGGCTCAAAACAGGTGTCTGTGAGCTTCACAGGCGGTAAGGCCGTGTCTACATGGCCGGGACATGCATCCCGGGGCTGCCCCT

37841100-
GCCGTGCTGCCCGAGTGCACGGGGGATGAGGACCTGACAAGGCCATTGATCTTGCGGGAGCTTCCTGAACTACTCCAGCGTGAAA

37841800
ATCTTCCAGAAGGATTCTCCACAGGGCAATGAGGCAAGAAATTTACAGCTTAGCCTGATTAATGGGCCAGGCAGTTAAGAGTTCT

TTGCCAAGCTATGAGCATAATTTATAGTCATCACGGCAGGAGGAAAGGCCACATAACTCACATCCTTAAAGGGCCCTTAGAACAA

GAGACACGCCGGATCATTGAAAACGTCTCCACTCCTGGCGCCAAAAGAGATCGGCACGTTTCTGGGTATTCTGGTCAAAGAACAG

GGAGTCTGGATTAATATACACGGCAGAAAAAAGCGAAGAAAAGACACACAGGTCATATATTTCTGACTGATATTCCGTTTGTTGT

TTTCGGAGGGACTTGGTATTTATTTAACCACATTCTCACTTGACACGCCCCCTCCCCACACCTTGTAAATGCCTTCCTCTTTAGC

CGAGTCATTTTTCATCACATAGAATTGAAATGTTGCCAGGAAGGCGGTTTATGAGATTGTAGAAATGGCACTAGAGAAAGCAGTG

TGAAAAGAGGCCTAGAACGT

210
ERG
TCTCTACATGCTATCTACTAAAAACTTAGGCAAGGAAATGCATCAGACCAAACACCCCACAGCACAGAGAACCGACCGGCCATTG

CTTTCCAATCTCCGCAAACCTAACCATTGCTGGAAGAAATCTTACTCACAGTGCACAGACAGTAGGTATTTTATTGAAGATAAAC

ATATAGTGGAACAAACCAAATTACCCCCATTTGAGTTACGTGAGCACTCAGTTCTCAGCGTGGATGTCCCACAAATCAAGTCAAC

ATTTGCGTCCCATTACCAGCAGCCACTTGCCGAGTATCTCTTCGCTTCCACTGGGACTGCCTGGCATCCCTGATGCTAAGGAGCC

ACTGAAGAGCCTCCAAATGTCTGACATTCACAAACGCATCTTTTGCTTTGACCCGACCCTTCAACCTCTCCGAGTCTGCTGCCTT

TTCTCAGACACACATCCAGGCACCGTTAGGGATAGTTAGAGAATCTGAAAATTCAGAAGCGCTCCGAAAAGCCTTTCCAAAAGTA

ATCCACAGCACTCAACAGTGAATTTAGAAACCCCAATTTTTTTCTGAGTTTGAAGTTTTTAAGCCTTGCGGATGGTTGGAGTAGG

AAAAA

211
chr21:
TCAGACAAGCTCTGTGCAGTCGGAATTTTTTAAAGATGCACTGTCACTTGAGGAAGACAGGTGATCTTCCTGCGGCACAAATAGA

39278700-
AGCAAAGAGATTTCTCTTCTTCTCTGTAGAGCAACACAATTGATAAATGGCCGATAATCTCCACCAAATTGGCAGCAGTAGGCTG

39279800
CCCGAAGGCAGCAGGCATATTCGTCTTTGTGAATTGTTTTACTATGATGCTGTCACATTTCCAGGAATAAGACGGTTAAAATGAT

ATATTGTTGTGGTTTGGCATTTGCAGCTTTGCTCTGACTTCCCTGGTAACTGCCAACATCTGCAAATTATTATGTGCTTAAAAAA

AAAATCAACCGCCACCGCAGGCTGCCCCCACGGTCCCTGGCTGGGCCAGGCCTCCTGCCAGGCCACAGGGCAGAGTTCTTGGACC

AGGAGGCAGCAGGGTCAAAACCCAGGTTGCCTAGGAAGCCCCCAAAGACAGTTATGGATAGAGCTGGGAGCCCGAAACACATGCG

GCAGTCTCTCAGTTTCCAGGTACCGGTTCTCACATCATCCATGCATGTGTTTGAGGAAAAACAAAAAAAAATTGATGGTTGCCAA

AAACAAAAATGCTTCCATATCAAAGTTTATCAGTGTCAATGTCAAGAGACTTCTGGTTCGTAGACTCATTTTGGCTTGAGGCCAC

CAGAAGTGAACTCTGGTTTCTAAATGCAGAAGCAGAGGCACTGGCCGATCATGGAAGATGCAGGGAACTGTTCAAGAGGCCCAAG

CCTGGTGCTCAGAAACTTGGCAGGATCAAGCATCTCGCCCAGGAATTCATCCCCTGCTTGTCTAAGCCGGCTGGCTCTCGTGACT

GACTCGGAACAACAGAGCAGATGTTTGCGTGGGAGGCAAGCCTCACCCAACATCTGTCCTGCGGCGGGAAGGCCTGGGTGTTCAC

AGATAGAGCTGGAGTTCCCCGGTGGGTGGCACAGACAATTAGCTGGGGCTGCCTCACATGTAATCTAATTACAGGGGAAACAGGC

TCAAACACCGGGTGATAAGCAGCGCAACTGTTTCGGGTGACTCTGTAATTTTTCCTCCATTAATTTTCTCCATAACGCAC

212
C21orf129
GTTGCCTGGGATATGCTTATATCAAAAACTTACGTGTCACTTACCTAGCATTTGCATTTCACTGGGCCTCCTAAATTCTGTGTGG

TAACCGACTGCCACCGGACATGCTGTTTACTTCTCTATCCTCACGCAGCCAGTTGCCACATTCAACATAACACTGCAAATATTGC

CGGTGGATCCTGACTTCCTCGTGGACCCTACTGTGTCGGGAAAAACAAACAAACGAACCCTGGAAGGAAACACCATGAGT

213
C2CD2
TCATAAATATTTCCAAATGTATTCCTATTTGTCTCTACAGAGTCTAACAGACATAAATAGCGAATTGAAGGTTCTGTCTTAAAAC

CCAGCAGAAAGAAAAACAATGACCAGAAAAAAAAAACAATTGTCTTTGGCTTCCCAAGAACAGCATCGGATTTCAACTGGAACCA

CAGATGGTCCGTTGATAGAAGCGACTACTTTTTAGCTCTGGAGGACGACAAAAGGAACCAGCTTCTTCCTGTGGGTGTCACAGCG

AGGTCGCCTGGCCACATCAGGTACCAGAGCGAGCGCCCTCACCTGATAGGCCCTGTACAACCTCAGCCACAGCACTGTCAGGAGG

AACACGCGGAACTAGCAACCTAGGAGGGTAAAGGCGGAGTTGGGAGGGAACACGAGGCAGGCAGGTCGGCTGGCTGCTGAGCTAC

AGGCTGCACTCCTAGGACGTCTACGTGTAATTGAGAAAAATAAGACAAAAATAACTTACTGTGCAGGCAATTAATTCTGGTTGGC

ATAGCGATCCTCTTAAGTTAAAGGGAATGAGCATGAGATGAAGAGAAGTAAGAGGCAGAAAGAATTATGCAAGAGCAACATCAGA

GTGGA

214
UMODL1
ACGCCGAGCCGCCTCTGCAGGGGAAACCGAAGCAGATGTGGTGAGATAATACATCCAACCCTGAGTGCTACTCTAACCTGCCAGA

GGCGGAGGGTTCTCAGTGAGATGAAAGCATTACAGATGCGTTAGATCTAAGGGAGGGGCCTGCAGATGCGCAGCTGGCAGAGAAA

CCAGGGAGGGGCTGAACTGTCAGTCGCGACCACCAGGGATCTGAATCAGTTCACCGACAGCCTTGGGGACATTCACCTTGGGCTC

CACAACCTGTCAGAAATGCCCCCAAGCCCAAAGGCGTCGAGAGAATGGCCAGGTTGTTTCAGATTGACACATATCCTAATGTACA

AGTCAGCCCACACACCCCACGTGCACTGAGCGTCTCTTGTTGTTCACCCCAAATAAACTCTGCCGGAACTGGGGCGGGACTCGCA

GGGGCGGAGAAGGGGGGAGACGGGCAGAGGGCAGAAGTGGATGGTGAGAAGAGCCAATGGAGGGGCCCCGTGAGAGTGAGCAAGG

CTGCACCCCTAACCGACGTCCTGGGGCTACTGTACAAACAAAGAACCACAGGCTGGGAGGCTGAACAACAGACCTGCACTCTCTC

GCAGCTCGGAGGCTGCAGGTCTGAAATCGAGGGGCTGACAGCGCTGGTTTCCTCTGGAGGCTGCGAGGGAGAAACCGTCCCCTGC

CTCTCCCAGGCTCTGGGGTGAGCCCTTCCTGGCATCCCGGGCTCATTGTAGATGGATCACTCCAATCTCCATGGCTTCTCAGGGC

TTCCCTCCATGCACCTCAAATCTCTCTCTCCTTCCTTTTGTAAGGATGCCAGTCATTGGATTTAGGTTCACCTTAAATCCAGGAT

GATCTCATCTAAATTACATCTGCAAAAAGACCCTTTTTCCAAGTAAGTTGACATTCACAGGTACCTGGGGTTAGGATTGGACATA

TCTTTTGCAGGGGTGCAGGGGGCTGCCACTGAGCCCGCTGCACAGGGTGACCTGGGCCAAGGGCCCTTCACTTTCACTTCCTCAT

TGGCAAGCTGCCCTGTGTTTGGACTGGGTCGAGGCTGTCAACCTTGCTGCCCCTCGGAGTCCCCCCTGGTGTCCCCCAAACAGAT

TCTAAGCTGCTTTCCTGGGGCTGGAGGCCAGGCATTGGGATTTTTTAAAGAGCTTCCCAGCAGGTGAGCAGCCTTTCATGGGTAT

CAGGAGACCTTCCTGGCAAATGTGGTGAAGGTCCTTCCTCCTGAGCGATGCCTTAGACCCAGGAGCCCAGGGAGGCTGCTCACCT

GATCGTTAGGACAGGAGCAGTGGAAACCTCTGGCCTCAGACCCCCTGGAGGAATCCCTCCCTCTAAGACTCTGGGACTGGTGCAC

GCAAGGAGCTATCGTGAACATTGCTCCCAACTGGCCGCTTGCTTGTCCCCCGGCTCCCCTTGGCCCCAGTGGCGGCTTTGCCTGA

ATTAGAGGGCGTGAGAGCCACCTGTGTCTCAGCACTGCAATTAAAGCAGGAAGCCCTTTCGGAAGCAGCCGTGTGCACCAGCCTC

CCATGGGTGGAGCAGAGCAAACCACCCACTTCTGCCCTCTGCCCTTCTTCCCTTTTCTCGACACCCTGCGGCCCCCCAGTTTCAG

CAGAGTTTATTTGGGGTGAAAAACAAGAGATGCTCAGCGCCTGTGGGATGTGTGGGCTGACTCGTACATTAGGATGTGTGTCAAT

CTGAAATAACCTGGCCGTTATATGGATGCCTTGGGGCTTGGGGGGTTTCTGGCAGTCTGTCGAGCCCGAGGTGAATGTCCCCAAG

GCTGCTGGTGAATCAGATCCCTGGCGTTCTCCGTTGGCAGTTCAGCCCAACAGTTTCTCTGCCGGCCGTGCCTCTGCAGGTCCCT

CCTCTGATCTGATTGGATTAATATTTGAATCAATAGACTGAGTCAAGCAGAATGTGGGTGGGCCTCATGCAATCAGCTGAAGCCC

TGAAAAGAGCAAAAGGGCTGCCCCTTCCCCCGAGGAGGAGAGAAC

215
UMODL1/
CACATTTCAGAGCTGAGGTGCTGGTGCGGGCAGGTCTCCTGAGCTGGGGGGTCAGCTGTGTGGCCAGTGATGGTGACGCCTCAGG

C21orf128
CCGTGCATGGCCGGGGAGGCGGCCCTGCCTCTGCACTCTTTTGACTCCATGACTACTGGTGTCTTCGGACGCCAGAGTCGGGGGA

GCAACCATGGGGCACCGCCCCTGCCTGGGGAGGCAGCACGAGGCCTGAGCCCAGCTTACAGGGGGACATCCACCCCCGCTGAGAG

CCCCACCTTCACGGCGAGGATCTGTAGAAGAAGACATTTGATATTACTCGGCAAAAAAAACAAGAAACGAAAACACAAAAAGAGC

TCCTCTGAAGAAGAAAAGGTATTTGCGCTGTGGTCCACCTAGAAATAATGTTGTTGGCACAACTAGAGCATTCCTCAGTCATTCA

GGAGCACTCCCTGCCGGTGCGTCCACATGTCCCAACCCCGATAGATGAGGCGCTGTTCGCCCGTGGAGGGGTCAGGTTGTCGTGA

CCTTATCTTTACCCTTAGGCCGTCCATCCCGGGGCCTGGGGTTTCCTGCGCCAGTCACGGTGGGCTGTGTAGGTGGCCATGTGTT

CGGTCTTTCCCCAGGAGGTACGTACCATGTGCTGGGAGGCCTGGAGGCTGAGCCGCCCCCCGCGCCTATGAGTTGCACCCTCACA

GCGGCGGCCAAACCTCCTGC

216
ABCG1
CAGGCTTGAGCGGTGACTGGGAGACCCCGGGAATGGAAATGGCGCTCAAATGCTGGTGTGGTGTCCGCAGGGGAACGGCCCGCGG

GTGTGTGGAGTCTGCGCCCCTGTGGCTTCAGCTGCGTCGGGGGACTGCGGGAATCTTCCAGACTCCAGTTTAAATCAGAGAGGTG

TGTCCACGAAAAGAGTCAAACTAAAACATT

217
chr21:
AACGAGACAGTGCAAAAAGCCGCTGCCTGGTGACCTGGCATGCAGACTCGGCCCTCCCACTTGCACGGTGATCCACTGAAGACAA

42598300-
CAGCTGCCTCTGTACTCACGCTCCCCCACACTCCCCTCCTTCCTGCCCTGGTTTCTCCATCCCTAGATGCCATCCCATGCCCCAA

42599600
ACCATCCGCCAAGCACAATAACCTCGCCCCCACCCACCCCATGAGGTCACTCGAGTTGACAACCAGATAACAGTTTTTGTTTTGT

TTTGTTTTGTTTTGTTTTGTTTGTTTTTGAGACGGGGTCTCGCTCTGTTGCCCAGGCTGGAGTGCAATGACGTTATCTCGGCTCA

CCACAACCTCCGCCTCCCGGGTTCAAGAGATTCTTCTGCCTCAGCTGCCTGAGTAGCTGGGACTACAGGCGCGTGCCACCATTCT

CAGCTAACTTTTGTATTTTTAGTAGAGACAGGGTTTCATTATATTGGCCAGGCTGGTCTCGAACTCCTGACCTCTTGATCCGCCC

ACCTCAGCCTCTCAAAGTGCAGGGATTACAGGCGTGAGCCACCGCGCCCAATAGCAATTTGATGACCCATCCCCTCCACTGCTGG

GAAAAGGCTGGGCACCGCCCACACTCCATGCAGCTCTCTTTCCCTGGCTCGGAATCGCTGCAGGCGCCACAGACCAGACGCGCAC

TGTTCCCCACTCCTGCTTATCGGCCGCGCGGCATCCCCTTGTCGCAGCACTCCAGCATCCATGCAGCCGCGCGGCACCCCGTCTT

CGGAGCACTCCAGAATCCATGCAGAGCGCAGCACCCCACATCCAGAGCGCTCCAGAATCCATGAAGCACGCGGCACCCCCTCGTC

AGAGTGCTCCAGAATCCATGAAGTGCGCAGCACCCCTTAATCGGAGCGCTCTAGAACCCGTGCAGCGAGCAGCACCCCACACCCG

GAGCGCTCCAGAATCCATGAAGCCAGCAGCACCCCACACCCGGAGTGCTCCAGAATCCACGCAGCACGTGGCATCTCCTCGTCAT

AGCGTTCTAGAATCCATGCAGCGAGCAGTACCCCACACCGGGAGCGCTCCAGAATCCACGCAGCGTCTGGCACATCTTTATCAGA

GCGCTCCAGAGTCCATGCAGCCACAGTCCTCCAACGGACCCTGAGATTGTTTCTGCAAAAGGCCATGCCTTCATAAATCTGAAAA

TTTGGAAAACATCCTTCTACTTATATCCTTACAACCCACCATTCAAGCTGTAGAAGCCTTTCTGGAACCCCAAGCAGAAGGATAT

CCAAAATGTAAAAACGGTGGGGCCT

218
chr21:
ATAGTGCGACTGTTCCGAAGTCTTTATCACAGTTACTGGTGATGCTTTTTTCCAGATGTCCTCGACGTGCACCCATGAAGGGCTC

42910000-
CACCTGAGAGTGCCAGGGTCCTCCGTGGGATGGGGCTGGAGGGGGTGCTCTTGCCGTCCTGGGCTCCCAAGCAGCCATAGGAACA

42911000
ATAGGGTGATGGGGTCCCAGAGATAGAGGCCAGTGACAGCAGCGCTTTGAACCCCTCACACGGGCACGGGCCCTCTGGCAGGGAT

GGGCGTCCCGGTCACACGGAGATGGGGGCTGCTGCTGCCTGCAGGTAGAGGAAGGGACGTGTTTGGCAGTCCTGTGACCCCTGGG

CACCTCGCCTCCCCCACGGCCGGCTCTGCTTGTAAACAGACAAGTGCACAAGCGCAGCCCGGTGAAGGCACAGCGGTCCCAGGAG

GCATCTGGGCTGCACCCCAGCGAGCCGCCCATACACGTGGAGATGCCGGCCAAGGCCCTGCAGCACACGGCAGAGGAAGGCGCGA

TGGGAGCCATGCTGGGCCCGGAAGGTGCCGCCGCCCGGAGCTGTAGCCATCACTCCAGCTCTTCTTTTAAGTGTTCCCAGAAATT

GTGACCCACCAAAATCTGAGAGCACCCGACAGTAAGCCAGAGGACCTTGATGTGAGATCCCAGCACGGTGTGGGGGCGGACTGTG

GTGGGTGCTGTCTCGGCCCCCACCCCTTCCACAGGTCGGTGTGCACATCCCACGGCGCCTGCTAAGCTGCAGTCTTCTCCAAAGG

GGTCACTCTCCGTGGGAAGGGAGCCACCCGCCCCCGGGTGATGTCCCCAGTCAGTGACTGACGACAGTCCCCAGCCGAGGTGAGG

GACCAGCTCCTGCATCCCTCACTCCGGGGCTTGCCTGTGGGCCAGGGTGGGGGCGAGCCTCAGCAGAGACCGCGTCCCCCTTGCC

TGTCCTGCCCTGCCTCCCCTGCCTCCCCCGCGCCTCTGCTGAGCACGCCCAGAGGGAGCTGCTTG

219
PDE9A
CACTTGAAAAGCACAACTCATGGTGCCAAAGCTCTGACACGGACTCCACTGGAGCTGTGGGCAGGGGGTGCCAAGGTACCGAGTT

CCAAGCCGTTGTTATTTGAGAGCGTGCCCCCCGCCATGAGAGCAGGTGGGGGGACATAAAGTGACACAGGATGGACTGGCCAAAG

GCTGAGGACGATCACTTACCTCACAGGATGATGCCACCCCCACGGACAGGCAAGGAGCTCTCACCTTCCCCAGGACCCCAGCTGC

CACCAGAGCTCCAGATGGCCCTGGGGGTGTCTGTAAAGCCTGTGACCGTCCACCAGGTGGAGACCAGGCTGGCCAGGGGAGGGAG

AGGAAGTGACCACTGGCCCTGGCACTGGCTGGCCGGCTCCAGCAGGCCCGAAGGGGAGGGAGGAGCCTGGGTGCACCAGACTCTC

TCAATAAGCAGCACCCAGACACTTAACAGATGGAAAGCGGTGGCTTGGAACTCACTTCCAACGAAACAATAGCAC

220
PDE9A
AGCACCTCCTACCCCACCCTCCCCATTCCTGCCATCCCCAGGGTCCAGGGAGCCCAGATTCCAGGGAAGGGTTGCATTAGCTCCC

ACTCGGAGTCCTGATGCAGCAGAGACAGACAGAGGCCCTGGGAGAAGTGAGCATGAATTATTAAGACAAGACAAGGGTGAGGCCC

CAGAGAGGGGGTGGCGGAAGGGTCATGTTCATGCAGCGAGAGTTGCTTCGAGCTTGAACCGCGTATCCAGGAGTCAAGCAGATTG

CAACTGGCGAGAGGCCTTCAGAAATGCCCCGTGAGAGTCCTGTGTGCAGAGCTCCATCTCAGCACACTTCCTGTTCTTTTGGTTC

GTCGATTTTTGCATTTTCAGTCCCCTGTGATCCATTATTTATAACAGTGGAGATTGGCCTCAGACACTAGCAGTGAGGAAAACAA

AAGCGAAGCTACGCAGAAAAATGACAAGAGTGATGAGCACAGCAGTCATGACAAATGAGCCCTGTGCGGAGGCCCGGGATCCGCG

CAGATGCCGGCGCGGGGGAAATGGGCCCTGAAATCCCACCGTCAGGCCAGGCAGCTCTGAGCGTGACCTGGAGGGCTGTTCAGAC

GGTCTGGGTAGCCGTGTCCTGCGCATGAACATCCTCCGTCGGGAGAGGAATTCCCCACGGATTATCAGAGCTGCTCCCTCCACCC

CCCGCCACGTCCCACGCGGGCCACATCAACTCCCTCTGCAGCCTCTGGCCAGCGGCTGAGCCCTCCGTGTCTCCCCTCGTTAATG

CCTCCTTCACCATCCCCTCCTGAAGTTTCCCCCATTGCATACACGCGCTGAGGCCCACCCGGTATCAAGGACTCCCATTGCTTGC

GAAAAAGATTCCACCCCTCTTAGAACAGAGACCAGGGCCGCTGTAGCAAATGGCCATAAATGCCACAGCTTAAAACAACAGAAAC

GGATTATCTCGCAGCTCTGGAGGATGGAGTCCAAAATCTGAATCGCTGGGCTGAAATCCAGGTGTGGGCAGGGCCGCGCTCCCTC

TAGAGGCTCCCCCGGAGATTCCCTTCCTTGCCTCTTCCAGCTGCTGGTGGCTGCCAGCAGTTTGGGAATTGCGGCCGCATCACAC

CACCTTTCTGTTTGTTGTTGACATCCCCGCCTCCCCTGCCTGCGGGGTCTTAGATGTCTCTCTCCTTCCCACTGAGTTTCACTCC

ACATTTGAATTGGATTAACTCATGCCATGTTAGGCAAACGTGCCCCTCAAATCCTTCCACTTAACAGACATTTATTGAAGGTTCC

TGTGTGCGGGGCCCAAGAGAAGGGA

221
PDE9A
GAATGTTCAAAGAAAGAGCCCTCCTTGCCTTCCTCTTCTTCCACCCCTGCCCTCTGCAGACTGGGGTTCTGTAGACCCCCAAAGT

AAGTCCGCCACACCGGAAGGAAGTGAGTTACACAGGGGCCCACATGGGAACCGCTTTTTGTCCTGTCTTGGTGGGAAAATGGCCA

CGACCCCAGCCCAGGCTCTGCCACGCCACA

222
PDE9A
CCATCTTCCTAGGCCTGCGTTTCCCCCACACCGGGGACTTGTGCTGGAAAGAAAAGCTGCGTTGGCAGCCAGGAGCCGGGGAAAC

TGTCCAGGGAGGCATCCTCTGCGATGAAGGCGGGGCCTCGGCGTGGCCCGTTCCGCGCTCTGTCCAGCCCTGGAGAAGCCCCACC

CTCACCGAGCTCGAAATACCCCCTCCCTGAGAGCCGAGACTCATGGCCGGGACCCCTTGGACAGAAGATGCGGATGCTAACCCGG

CGCTTCCACCACAGCCCCGGCGGCACTGGGGAGCGAGCGCGGCCATCCCGCGCGTAGGTGGTGTTTCTCTGCAGGCGCCAGTTTC

ACCGCGGGCGCCCAGGATCCTCAACGGTTCTGTTGTGATGTGATTCCCCTCTTCGACTTCGTCATTCAGCCTCAGTCCCTCAGTC

CCCAAATACCGAAAGGCAGTCTTTTTTTTTTTTTTTTGAGACGGAGTTTCACTCTTGTTGCCCAGGCTGGAGTGCAATGGTGCGA

TCTCGGTTCACTGCAACCTCCGTCTCCCTGGCTCAAGCGATTCTCCCGGCTCAGCCTCCCGAGTAGCTGGGATTACAGGCACCTG

CCACCACGCCCGGCTAATTTTTTGTATTTTTAGTAGAGACGGGGTTTCACCATGTTGGCCAGGATGGTCTGGAACTCCTGATCTC

AGGTGATCCACCCGCCTCTGCCTCCCAAAGTGCTGGGATTACAGGCGTGAGCCACCGCGCCCGGCCTTTTTTTCTTTTTTCTTTT

GAAGTTAATGAACTTGAATTTTATTTTATTTACAGAATAGCCCCCATGAGATACTTGAAGACCCGGTGCCAAGCGACAGTGTTGA

CCCCAGGTGGTCAGTCCTGCCTGGCCCCTTCCGAGGGATGCGCCTTCACCATAACCATGTCACGGACAGGCGTGTGGGCAAGGGG

GCATCGCTGTATTTTTCACAACTCTTTCCACTGAACACGACAATGACATTTTTCACCACCCGTATGCATCAACCAAATGAAAAGA

TGAGCCTGTGACATTCCCGTGCGTAGAGTTACAGCTTTTCTTTTCAAAACGAACCTTCAGTTTGGAGCCGAAGCGGAAGCACGTG

GCGTCTGACGTCTCCAGGGAGACCCGCCGCCCTCGCTGCCGCCTCACCGCGCTTCTGTTTTGCAGGTAATCTTCAGCAAGTACTG

CAACTCCAGCGACATCATGGACCTGTTCTGCATCGCCACCGGCCTGCCTCGGTGAGTGCGCGCTGCGGGCTCTGCCCGGTGACGC

CACGCGGCCTCCTCGCCTTTTCGGGATGGCTGGGAGGGGCGGGAAGAGGCGCTGAAGGGCCCGAGGCACCGGCCTTCTACAAGGG

GCTCTTCGAAATCAATCAATGCGCAGAATCCCGAGGGAGGCTCAGCCGCCCTCCGGGCCTCTCTGCCTCCACAGGTGATGGCTGT

GTCCACAAGGAGGAAACCGTCGGGCTGAATTAAACAGAACCGCCCTCCTAAGAGTGTGGGTTTTTCTGCCGGGCGTGGTGTCTCA

CACCTGTAATCCCAACACTTTGAGAGGCCGAGGTGGGCAGATCACCTGAGGTCAGGAGTTCGAGACCAGC

223
PDE9A
AGGCAGCAGGGTTAGGACTTCAACATACAACTTTTGGGGGGAGATGTACTTCAGCCCATAACACACCACGTGGGAGGATAACACC

GATTTCAGAGCTTGCAGAGGAAGCCGCCAGGAACTCCAGTGAGACATCAGCCCCCAGGTGCCTGTCAGGCACGCCGGGCTGTGGG

GGGCACCTGGGCCCATCTGAGTAACGGAGGCGCATCCGCACTTCCCCCAGGAGTACATTTTTAGAACCCACAGCGCCATAAACCA

AAGACAAGGAGACTTCCTGGTGCCCCGTCAGCTTCTGGAGGCGACGTTCTCGGCTGACAGCTCTGGCAGCCTCCCCTGTAGGTGA

GAGACAGGTAAATGGGACTCTTGCTTCCAAAACGGAACAGGGTAAAAATTCTCAAGCGTT

224
chr21:
TGCTGCACCCCCGCTGCCCTCCCTCCCGCTGGCCGGCAGCACCTTCTCCACCCGGGCCCCTCTGCTCACAGCGCTCCCCGCCCCC

43130800-
GTCTCCCCGAGGGGCGGGGAGCCAGGACATGGCCCTGAAAGCCTAGCCCTGGCCTTGACCTCCCCAGAGCGCCCTCCCCACCCTC

43131500
CGCCCTCTGCCAACCCTGGCCCCTGCCCTGGCCCCGTCCTTGTCCTCTGCTGCTGGCCTTGGGGTCGCGCCCCGCAGACTGGGCT

GTGCGTGGGGGTCCTGGCGGCCTGTGCCGTCCCACGCCTACGGGGATGGGCGAGGTCCTTCTTGGGGCTTCTCTTACCCACTCTC

CAGTCACCTGAGGGCGCTGCTTCCCTGCGGCCACCCCAGGTTTCTGTGCAGCCGAAGCCTCTGCCTCTGCGGCCGGGTGATCCCA

AGACCCCGGGGTCCAGGGAGGCACGGGATCTGCTCCCCCGGTCCCAAATGCACCGGCTGCGCCTTAGGAGGGACGGCCTCCACCC

ATGGCGCTGGCGCCCAGGGGCCGCTCCTCGGACTACAGCACTTGCTCGTCGCCCTGCGCCCTGTTTAGTTCTCATCACCAGCAGC

CTGGACTAGGGCCCTGGTCCTTCTGGCCTCCTTCCACAGCCCGCTGCACATCTCACCCACTTCCCCGAGGTGCTGTCATTGTTTA

GCTGGGCCCCTCAGCCTCCG

225
U2AF1
TTAAAGGGGAGTGGTTGTATGAAGAGTTCCTCAGTCAAAGGTGTGCAGCTGGGAAGCCCACCCCACCTAAGAGGGAGGTCTGACA

AACTGTCCACACTGAACCACTCAGACCTGCATCAGGGCCCCGTTTCTTCCATAAGCCGCCAAGTACAGCCCTGAGTCAACTGAAC

TCAGGCCTGGGAGGCTTCCCAAAGCTGACTTGACTCAGCTTTGAACTGAAATGACCGTACCATGACAACCCTGATGAAAAGCTAA

ACTGAGCCCAATTATTCAACAGTAAAATTCAGTTGGTCTCACTCA

226
U2AF1
TGCTACCAGCTGCTTGGGCTTGGGCAAGTCACCCTAGCTCTCAGATGTCATCTGTAAATGATGACAATGCCAATGTGGCACTGTT

CTGAGAGTCAGACAGAACGTATGTGTGCTTCACATATGGTGCTCATGAAGTGCTATCATTATCTAAGGAAAACAGAAAACGAAGT

TCAGAGTCTCTCTAAACGCATGACACCAGACCAACAGGGAGTTTCAAAAAATAGGTCTGAAGTAAATCAATTCTCCTGGTCTCAA

TACACTGAAAACAAACTATTAGGGGACTGACCGAACCCACCTTAGGAACCACCTTACGTCACCTTCTGTCTCTACTGCAAAACCC

TCCCTTAATACTGTTCAAATACGCTGACAATCCAGATCCATATCCAATGGAACCAGCAATCATGCCTGTGTGCCAGCAATGTCAG

GGAGGGAAGCCGATCTCTGATGAAT

227
chr21:
CAGGTGCCGGCCACCACACCCGGCTAATTTTTGTGTTTTTAGTGGAGACAGGGTTTCGCCATGTTGGCCGGGCTGGTCTCAAACT

43446600-
CCTGACCTCATGTGATCCACCCGCCTCGGCCTTCCAAAGTGCTGGGATTACAAGTGTAAGCCACTGCGCCCGGCCAAGAGTGAAG

43447600
TTCTGATAGCTGGGGTAAGAAAGGCCGTGGGAACAGCCGGTTTCAGACACGCTGGGTCTAAGACGCTGCGTCTGGCGCTGCTCGG

CATCCAATGGGAGCCGTGGAGAAGCCAGGCGAGTGCGTAGGGCGGAGCCAGCGCACAGGAAATAGGACGTGATGAGGTCAACCGG

CTGGTCCAAGTGTGGACGGAAGTAGAGGATGCAAGCACCGAGCCCCGGGGCCCCCAGCATTGGCGGGGAGGAGCTCGCGGTGCGG

GAGAAGCAGGGGACCGCGCATCCTGGAGACCAGGTGGAGCCAGTGCGCCCGGAAGGGGCGTGGCCCGCTGACAGCCGCCCAGGAG

GCCGGGGGAGGCCTGGAGCCGAGGGCCGCGCGTGGCAATGTGGAGAGACATTTTGGTGGAGTCATGGGGCCACAGCCTGATTGGT

GAGAACAGGAAGGGAAATTGCAGATGGGCCTGGGCCCCCTGGCTCCCGCATACTCCAGGACCAGGGCTGAGTCATCGTTCACCGT

GTGTGACCAGGGCCCCGTGTGGCCGGCTGTCACTCGGTATCCAGTTACCCTGGGCAGACCACTGGCGGCACCCCCCAGCCAGAGG

CCGCAGCAACACACACGCCTGCAGGCGACCAGGCCGGACTGCATGCCCCGTGGGGGAACTGAGGGCGTTTCAGTAACAGAGTGTT

AGGGGACACGGGTTGGGTGGCTTGGAAAGGGCCTAAGGTGGGGTTTGTTTTAGATTGGGGTGGTGAGGGCGCAGGGGCCCGGTAG

GATTCTCTAACAGGGCAGCAGCCACTCATTTAGCAACAGGAGAGGCGTCCAGCGTTTCGTGGGCT

228
CRYAA
ACCCAACCACAGGCCTCCTCTCTGAGCCACGGGTGAGCGGTGCAGGTTCTGCTGTTCTGGAGGGCCTGAGTCCCACCCAGCACCT

CATAAACAGGGTCCTCCCCAGGGCTGCTGCAGTAGGCATCAACGCCAGGGTGCAAAATGCCTCAGGGAGCCAAGGCTGAGCCAGG

GGAGTGAGAAGGAGCATGTGGAAGTGCGTTTTGGAGAGGCAGCTGCGCAGGCTGTCAGCAGGCTCCGGCCGCTTCTATAGACAGC

ATGACACCAAGGGCAGTGACCTCATTCCACAGGCTGAGTCCAGCCAGCCAGCCAAGCATCACCAGCCAGACGATTGACCCTAACG

GACCAACCAACCCGTAACGACCCCTCCTACCATAACCAGTAGCCAGCCAGCCCATAACCAGCCAACTTATCTATAACCAGCCACC

TGACCATAGCCAAACAACCAGCCGGCCCACCAGTAGCATTCAGCCCCTCAGCTGGCCCTGAGGGTTTGGAGACAGGTCGAGGGTC

ATGCCTGTCTGTCCAGGAGACAGTCACAGGCCCCCGAAAGCTCTGCCCCACTTGGTGTGTGGGAGAAGAGGCCGGCAGGTGACCG

AAGCATCTCTGTTCTGATAACCGGGACCCGCCCTGTCTCTGCCAACCCCAGCAGGGACGGCACCCTCTGGGCAGCTCCACATGGC

ACGTTTGGATTTCAGGTTCGATCCGACCGGGACAAGTTCGTCATCTTCCTCGATGTGAAGCACTTCTCCCCGGAGGACCTCACCG

TGAAGGTGCAGGACGACTTTGTGGAGATCCACGGAAAGCACAACGAGCGCCAGGTGAGCCCAGGCACTGAGAGGTGGGAGAGGGG

GGCGAGTTGGGCGCGAGGACAAGGGGGTCACGGCGGGCACGACCGGGCCTGCACACCTGCACCATGCCTTCAACCCTGGGAGAGG

GACGCTCTCCAGGGGACCCCGAATCAGGCCTGGCTTTTCCCCAAGGGAGGGGCCGTGCCCACCTGAGCACAGCCAGCCCCTCCCG

GTGACAGAGGTCACCATTCCCGAGCTAATGTGGCTCAGGGATCCAGGTTAGGGTCCCTTCCCGGGCTGCACCCAGCCGTCGCCAG

CTCCATCCCTGTCACCTGGATGCCAGGGTGGTCTTAGAAAGAACCCCAGGAAGTGGGAGTGCCCCGGGTGGCCGCCTCCTAGCCA

GTGTACATCTTCACATGAACCCTACCTGAGGAAGCCAGTCCCCGACGGCATAGCTGCATCCGCTTGGAATGCTTTACAGGCATTG

ACACCTTCGCCTCACAGCAGCACTTTGGAACCAGTGTCCTCATTATTCCAGGGCACGGCTGGGGAACAAGGGGGTCCTCAGCCTG

CTGGGTCCCACAGCTAGTACCGGGCAGGTGGACGGGAGCTTCTCCCCACAGTCACCCTGATGCCCCGCTCTTGCTCGGCTGGAGG

CCTCGGATCTCCGTGGTGTTGAGGGAGCCGGGGCACTGGAGCCCTGGTGACCTGCATCTCCTGGCGGAGCCGGGAAGAGCTCATG

GACTGTCACAGATGGACAGTGCCCCGCGGGGGCTGGAGAGCAGAGTGGGGCTGGAAGGTGGAACTCTTAGCCAAAGTCTTGGTTT

CTTTTGGCCAGGGTCCTCTTTCAATGGCTGGAGAAGGTGGTGCTGGGGGGTGAACGCTGACCTCCTCATGTGCTGCCCCTCCCTC

GCCTGGGCCCGGTAAAGCCCCCACGTAGCCCCAGCCAGCCTGGAACATGCTTCCTGAGCTCCCAGCTCTTGGTCTTTGCACCCAG

TGGAGGAGGAGGTCAGCCCAGGGAGCTGAGTCTGCGGTTTAGGGCGTCCAGGGGACGTGGAAGCATGTGGGTCGTCTGGCCACAT

TAGGTAGGGCTGCAGAGACCTGGGCTAGAGCAGTCCTGCGGGGTCTGGAAGGGGAAGACTGGCTGAGGTGCGGGGCCTGGTCTGG

AATGATCCTGCGATTTTGGAGTGAAGCCATGGAGCGGGAAGAGACAACCCCCCGCGGGGAATAGCCCGGCAAGTGGCCACGAGGC

CAGGCTGAGGTCCAGAGAAGCAGGGGCATGAATCCATAAATCCCAGGGGGCCTGGCCATGGGATGTGCTGGCTGCACCCGGCCCC

TGTGAGAGCCCCCGCAGGCTGGCCCCCTTCTGCAGTCAGTGGGGCTGGGGCAGCTTCTCTGGCATGGGGCGAGGCAGCCGCCTGC

ACAGTGGCCCCCCTGACTGTGCGCCCCCACCCTCTCCAGGACGACCACGGCTACATTTCCCGTGAGTTCCACCGCCGCTACCGCC

TGCCGTCCAACGTGGACCAGTCGGCCCTCTCTTGCTCCCTGTCTGCCGATGGCATGCTGACCTTCTGTGGCCCCAAGATCCAGAC

TGGCCTGGATGCCACCCACGCCGAGCGAGCCATCCCCGTGTCGCGGGAGGAGAAGCCCACCTCGGCTCCCTCGTCCTAAGCAGGC

ATTGCCTCGGCTGGCTCCCCTGCAGCCCTGGCCCATCATGGGGGGAGCACCCTGAGGGCGGGGTGTCTGTCTTCCTTTGCTTCCC

TTTTTTCCTTTCCACCTTCTCACATGGAATGAGGGTTTGAGAGAGCAGCCAGGAGAGCTTAGGGTCTCAGGGTGTCCCAGACCCC

GACACCGGCCAGTGGCGGAAGTGACCGCACCTCACACTCCTTTAGATAGCAGCCTGGCTCCCCTGGGGTGCAGGCGCCTCAACTC

TGCTGAGGGTCCAGAAGGAGGGGGTGACCTCCGGCCAGGTGCCTCCTGACACACCTGCAGCCTCCCTCCGCGGCGGGCCCTGCCC

ACACCTCCTGGGGCGCGTGAGGCCCGTGGGGCCGGGGCTTCTGTGCACCTGGGCTCTCGCGGCCTCTTCTCTCAGACCGTCTTCC

TCCAACCCCTCTATGTAGTGCCGCTCTTGGGGACATGGGTCGCCCATGAGAGCGCAGCCCGCGGCAATCAATAAACAGCAGGTGA

TACAAGCAACCCGCCGTCTGCTGGTGCTGTCTCCATCAGGGGCGCGAGGGGCAGGAGGGCGGCGCCGGGAGGGAGGACAGCGGGG

TCTCCTGCTCGCGTTGGACCCGGTGGCCTCGGAACGATGG

229
chr21:
TTTTTGTGTTTTTAGTAGAGATGGGATTTCACCATGTTGGCCAGGCTGGTCTCAAACTCCTGGCCTCATGCAATCCTCCTGCCTC

43545000-
AGTAGTAGTAGTTGGGATTACAGGTGTGAGCTGCCATGCCCAGCTGCAGGTGCGGAAGCTGGGGGCCTCAGAGACTGTGGACTCC

43546000
TGGCCGGTGAGGAGCGGCATGGGCCGGGAGAGCTGACTCTTCAGCGGGACTGAGGTGGCTGGAGCGTGACCCTTTCCTGAGGGCA

AACAGGGAGGGCCTTGGAGCCCGGCGCTCAGGACAGGCCCCTGCTGGCCCGGCAGCCTGAGCTTCCACACTTTTCCAGGGCGTCT

CGAGTTCGCCCACAGAGCTGTTGTTTCAGGATAAAAAATGCCCTTGTATTCCACGTTCCAGTTCAGAGGCCCGTCTGTTCCCAAG

AGCGGAGGCGTCAGCCGCATGAGTCCCACCGGAAGCCGGGTTGCCGGGTCCCCGTCCCTGCCCTGCAGACGACGCATTCCGGAGC

CCCCTGTGGGCGTGTGCCTGGGGCCCGAGCTCAGGAGCAAGGCCTGCGTGGACCTGTTGTCTGAAACAAGCCAGTAGACAGCTGC

GTCAATGCAGGCAAGCTGAACAGGGCTGCTTTTTCAGCCTGACAACCCCAGGGGCTGAACAGGAGCTGGGGGAGGAGCAAGGGGC

CGTTCCCCTGCCCCACAGCACAGCACACGACCCCGCCTTGGAACCTGGGGCCCGGGGTGAATCGAGGGTCCTGGAGCAAGAGGGG

CTGCTCCACAGGAGAGCCTGTCCCGCCACCCCTCAGCCACCAGATTCGGGGCTGCTGGACTTGTTCTCAAACCTGCACAGTGAGT

GACAGCTGCTGAGACGGAGGTCTCAGGCAGTGCAGGTGAATCAGCAT

230
chr21:
TCCTTATTTTTTAGTTCTCAAGCCCTGTAGGGTGTTTTCGGTCGCAGTTGTTTGGGCTGTGGTCCTGACCCTCCTGAGTTCCAGT

43606000-
GGCTCTGTTCAGGAGAGCTGCCTGGGGCCGGGACTTCTGAAACACACACTGAGCCACAGGCCGGCCCGGCGGCTTGGGTTCACCG

43606500
CCGCCTCTTTGTGTGTGATGTCCTGGGATAGGCCCGTGCACGTTCAGATGACACTGTACATATAAATAACTTGTAGCCGAGAACA

GGATGGGGCGGGGAGGAGGGGAGGGCAGAACGTACCACAGCAGCAGAAGTCACTGTGGATGCCTTCGTAAGTTGCATGGAAGGTT

TTTAAACCTAGCCCTGCCGAGCAGCCCTCTCCTGGTCCGGGAGAACGATGGGGAGAGAGCTGGCGTTCAGCTTTCATCACTGGAG

CCGTTCCTTCTTCCGGCCCCCCGAGGGCCTGTCCATGATCACACTTTGTCTTGTTTCGGGGGTGGCCCCTGTGAC

231
chr21:
CAAGCCTGTGGTAGGGACCAGGTCAGAGTAAACAGGAAGACAGCTTTCGGCCAGGCGGTGCACCTCGGTGCCGGTGAGTGTGAGC

43643000-
GTGTGTGCGTGTGCACGTGTGCAGATGTGTGTGGACGCTCCCTTCTCCGCAGCAGCTCCTGACCCCCTGCAGGTGACCCTCAGCC

43644300
AGCCCCAGGGCTGCCCCCACTCTCCCCTGTGGACACCTACCTCATTTGGGGTGAAGTGGGGGGACTGGGGTGTGAGGGGTGCTTT

GGGGGGCACACTTCGACCCCTCTCTCTGCAGGCCAAGTCCTGAGGCTCAGTTTCCTCCTCTGTGCCCCGGCGACGTGGTGCAGGC

CTCGCGAGTGACGTGAGGGTTCATGACCCAGGTGTGGGCAGCCAGCCCTTCACGGGAGGCCACCCACCTGGCCACAGTGCCTGGG

AATTTAGGTCGGGCACTGCCGATATGTCGCCTTCCACAAGGCGGGCCCGGGCCTCTGCTGACCGTGCACCGGTCCTGGGGCTGGG

TAATTCTGCAGCAGCAGCGCAGCCCATGCCGGGGAATTTGCGGGCAGAGGAGACAGTGAGGCCCGCGTTCTGTGCGGGAACTCCC

GAGCTCACAGAGCCCAAGACCACACGGCTGCATCTGCTTGGCTGACTGGGCCAGGCCCACGCGTAGTAACCCGGACGTCTCTCTC

TCACAGTCCCCTTGCGTCTGGCCAGGGAGCTGCCAGGCTGCACCCCGCGGTGGGGATCGGGAGAGGGGCAGTGTCGCCCATCCCC

GGAAGGCTGAGCCTGGTGCAGCCAGGGAGTGAGGGGGCGGGAAGCCGGGGTGCTGCCCTGAGGGTGCCCCGACACGCTCTCCTGG

GGCCCTGAGCGGCTGCCACGTGCGTCCAGGGTTCTGGCCACAGGGTGGGCAGGGGCCCTGTGCTCCTCACTGGAGGCCCCTGAGG

CTCTGGAACTGAGACCATCCACCCGCCGGCCCCCTCTCGCCGGCTCCGGCACCCCTGCCTACTGTGACTTCCTGCCCCGGACTCG

CTCTGCCAGCTTGGGGCAAACCACTTCCCTCTGGGGTTTTCACTTCCCTCTTTCCCAAGTGGGGAAAGACCACCTGTCCCCGACC

CAGAAAGGGCCCCTGCCCGAGGGCAGCAGCAGTGCCAGGCTGGCATGTGAGGCTTGGGGCAGGCCCGGCCCCCAGAGGCACAGGG

CGATGCTCTGTGGGACGCTGTGTCGTTTCTAAGTACAAGGTCAGGAGAGGAGCCCCCTGACCCCGGAGGGGAGGAGAGGCAGGGC

AGGAAACCGCCACCATCTCAGCCCA

232
C21orf125
GCCCACTGTGGGTGTGCCCGTGTGTGTGGCTGTGAGGCGTGAGTGCAGGCGTGAAGTGTCTGGGAGTGGGAGCGGGCATGAGTGT

GTGCCACGGGCCTGCTGTTGGGTCCTTGGAGGCCACGGTTGCCCCTGAAGGGACTGCAAGCTCTTTTTTGATTTGTAGTTATTTG

AGAAGTCTATACAGGAAGAAAATTAAACCG

233
C21orf125
AGCGCCCAGCGCAGGGCCGGGACCCAGAGTGGACTCTACCGTGGGGCTGCCTCAAAGAAATCTCAGCAAACACAGGAAGCCAGCC

CACCCGTGCAGCCATGGGGCCAGGAAGCCCGCCCTTTACCAAGTCATTTGGGCATTTTTTCTCTGTGCTAACAGCCCAGATGGAG

CCATAGCCTCAACCTCTGTGTTCTGATAACACCAAGCTGGGACGCCGGAGCCATGCAGGGGACAGTGCCCGGCCTGAGGCTGCAG

CCTGGGTCTGGATGCCTTTCTAATTCAGGGCCTCCTCATGGCCTGGTTCCATAAATGGTCAAATGCAGCCTGACAGCGCAGCCTC

CTATCAGCGCTGGGCTCCGTACCGCCACACAGCCCACATACCCCGTTCCCCAGGAGACGCCCGCAGGTGGGCAGCGTCACTCCCA

CCCGCCGAGCACACGCTGTCCCCGTCTCGTGTCCCGAGGAGCCGGAAGCAGCTGCTTCCTCCCAGCCTGAAAGCTGCACCTCGGG

CTGCACTCGGCTCCCCGAACCCGCCCTCCGCTGCCCTGCAATTCGCCAAGGGAGCTACCCTTCCCATATAAAAATTTCACCTCCA

TTTCCTTGTAGAGAAGAAACATTTCTGACAGCAAGGAAGATTCTAATTTGAAAAGCAAGTGATTCATCTCCCGGTGCCAAACAGC

AGACGCAGGCGTTACCAGTCTGGGTGGGGCGCCCGAGCTGGGGACCTGGGGTCCTCTGGGAGGGGCAAGAAGGCAGCGATGCTGG

CCCCCGCCTCCATCTGCCCATCCCATCTGCTTCCACACACCGCCCTGCCGTAGCTGCTTGCAGCCCTTCTCTGTCAGTTTCTCCA

TCTTTTGGTTTGGTGATAAATGAGAGTTCCCATCGGGTGTGCCACCCTCTGTGTGACGGGGAGCAGAGAAGACCCTGCGTCCAAG

TCCTCCTGGGGGAAGAGCGAAGATGCTGGGACCAGCCCCAGCTGTCAGGGGGTCTCCAATCCCAG

234
HSF2BP
GGAACGGAGAGCCGCCAGGCCCAAACCTCCCAGAATTTGCGCAGTATTCTCGGCCTAGAGAGCGAGGAGTGGCCTTGGCGAGGTC

CCTCTTTGGCTCTTCTGGCTTAGCCGGGGTTTTAAACTTGTTATCTGCAAAGCAGAAGGAAAGTCAGCCCCTGATGTAAGTGTCA

AGTAAAATAAATCGGATGGGTCCTTTCCTGTTTGGCGAGGAATGCTACACTAAGGGGGACTGCGTTCAAATGGGCAGTCTTTGCT

GGAAACCTCGCCTCCGCGCGCCTTCCCTCGCTCGGATTCAGGCGCTTTTACGTTAAGGGTTGAATTTTTGTGTCAACAGGCACCT

CGGGAGGTCGCCTAGACAACTGAGCGGAGCAACTGAGATAACCCCCGCTACGTGTGGAGTGACCTAGTCCATTAACTTGCCCCAG

CACGCCCGCTGAGTCCGCAAAATATAGGATGGCCTCGGGTTTTAGATGAACCCAAAGCTAAGATTTCTTCCCTCTCTGGAATTAG

CAAGCAGCCCGCCCTGCCCAACTCCCCTGGAAGCGCGCGTGCTCGCCAGGCCTCGGGACGCCTGCGCGGGCGCCCTTGCACTGGC

ACCAGGGCTCCGGGGTAGGGGCGCACCGATCTGCCCAAGCCTCTGCAGGCACTGGAGGAAGGCGAGCCCTCCACCCGCTCAACAG

GCCCCAGTGCCGGCCTTTCCTTCCAGTCTCAACTCCACCCGGGGGCCCGGGGGCTCCACAGTTAAAAACTCCACGCCACGGAGAT

CGCAGGTAAGCTGCTGGCTCAACGAGGTGTGCTAAATGGGATTAAAGATCCTGGACCGTGGCCAGGCGCGGCGGCTCAAGCCTGT

AATCCCAGCGATCAGGGAGGCCGCCGCGGGAGGATTGCTTGAGCCCAGGAGTTTGAGACCAGCTTGGGCAACATAGCGAGACACC

GTCTCTACAAAAAAATAACAAATAGTGGGGCGTGATGGCGCGCGCCTGTAGTCTCAGCTACTTGGGCGGTCGAGATGGGAGGATC

GATCGAGTCTGGGAGGTCGAGGCTGCAGTGAGCCAGGATCACCGCCAAGATCGCGCCACTGCATTCCAGCCTGGGCGACAGAGGG

AGACCCTGTCTCAAAAACAAACAAAAAATCCTAGACCGTTTACAAACAGCCTTCCGTCTCTTCCTGGTCAAGTCCTAACCCTGGC

TAACCTCGCCGTCTACAGCCTGAATTTTGGCAACCGAAAGGCAGCGCCGGCGCCACGTGCACACGGGCTGGGCCGCTCCGCCAGC

TGCCAGGGCCACTGCCGCGCTCACT

235
AGPAT3
CGCACACACAGCACAGACGCCTGCATCTTCCCATGCGTGGTTTCTGCTCTTGCCTCTCTGGGTTTTTGTTTCACTTCGGTCGAGT

TTTTGGTGGTGTTGAGCGGATAGCCGGGGAAGTTGGAGTCTTGTTTGTGGCCGCCTCGTGCTCGTGTCTGTATCTAAGATCCTCA

GGCTGCTCCTTTTTGGGTAAGGTCTGTTGCTTCTCTAGGAACAGTGACGGTGGCAGAGCCCGTGGCCCCTCTCTCCTGTCCCAGA

GCCAAGCTGTTTCCTCTCCCCACTCCCGGGCACCCTGCGGGCAAG

236
chr21:
CACAGCCCAGCTTCAAGCCTGGCCGACCAGGGGTTTGGCATGAAGACCCCGGCAGGGCTGGGGCTGTGCTGGAATCCACCCGGAA

44446500-
GTTTCCTGCCCCTTGGGCTGCCCACCAGGTCCCCTTTCTGCTCTGATCAAGCTGGACAAAACGTCGTGGGGCCACAGCACAGGGG

44447500
GCCAACGCAAGCTGGGATCGTCAGACGTTAGGAAATCCCAAGGAAGAAGAGAAAGGGGACACATTCGGGAGACGTCGGCACACGC

TCGAAGCAGCGGACAGGCACCTCTCTGTGGACAAGGCAGACTGGGCGGCCGAGATTCCGCATAGATGCCTGCTTCCTCCACGACC

TCCACGTGTGGCTGGCCCAGTCCGGGTCCCCCTCACCTCCTCTGTCTGTCTTGGTGGCCTCACGCCGTGGGCTGTGATGCCGGCT

ACGCTGCTTGGGTGGCCAAGGGTCTGAGCTGCAAGACGCCCAGCCTGGGTCTCTCCCGAGCTCTCCCACGTCCTGTCTGCTCCTC

CTCCGAGCTCCCGGTTGACTCTCACGACTGCACCAGCCTCTCCCCCAGGAAGGCGTGGAAACAACCTCCTTCTCCCAGGCCCGCT

CTGCCTCCTGCGTTTCAAGGCAAATCCGTTCCTCCAGGAGATGATGCAACCACATCCTGTTGGAGCCCAGAGAAGTGCGGATGCA

GCCCGGGGCTCTTTCTTTCCTAGAACCCTGCCTGGGAGTGGCTTCCCTGAACTAAGGACAGAGACTTTGTCTTCGTTGCCTCTCG

GCCTGTGGGCACTGAGCATACAGTAGGTGCTCAGTAAATGCTTGCAGGCCGATGCCCAGAGCCATTAGCCCTCATCATGGTGAGC

TCGGCAGCCGGTGTTGGGGCTGGGCTGGGCCTAGGTGTGCGTGGGGGCGGTGCTGGTCTGCTTTGCTGGGAGCCATGGACACCGG

AGGAACAGGGCCCCATCAGTGCGGTCAGAGTGCAAACTCGGAGCGTCCTTCTCTGGAAAACGAAT

237
TRPM2
GGGAGGGGGCGTGGCCAGCAGGCAGCTGGGTGGGGCTGAGCCAGGGCGATCCGACCCCGAACCGGAGCTTTTAGCACTTTGAGTC

CCTGTACTCAGAGGTCTCCTGCAGCCGGGAATCCCACTGTGCTGTGGTCCCTGGCAGCCAGCACCCACCCCCAGCTTCTCCGTCA

AGGTTGAGGACGGAGCACTCCTGCCTCTGATTAACTGGACGCAGGAGAAGCAGTTGCTTTAATCCGGAGCCTTGAGTTGGGACAG

ATAATGAGTCATTCAACCAGATTTTCCAAGGACACACTAACTTTGGTATGATGCGTGTGTGCCCCTGAATCCACGTGGTCAGGAA

AGCCCAGGGAACACTGGCCTGTGACTCACTGAGCAGGTTCCCTTGTTACCCCGAGGGGTGATTTACTCCTCTGACAGTGACACGG

ACACTGTGCGTCCATTCCCCGGGCGGGCAGAGGACACTCCCAGATGCCCACGAGGGGCCCAGCAAGCACTGGCCA

238
C21orf29
CTGCAGGACCTGCTCGTTCACAGATGTTCTCCTAGAAGCAGAAGCTGTTTCTTGTTGCAAACAAATTTGCTGTGTCCTGTCTTAG

GAGTCTCACCTGAATTTACCAAGGATGCATCTGTGCTTGGGGATGGCTCGGTTTGAGGGGTCTGAGGAGCGGCTCCCCTGGATCC

TTTCCTCCCCAGGAGCCCACCTGCCGAGCTGTCAGCGTCAGCCCCACATCTCAAGATGAGGAAATGGAGGTCGAAGCCATGCACA

CGCAGGCGTCCTGCTGACATGCAGGCCAGGCGGGTGCCTCTGTATTCAGCAGCCTCAGGGCTGTGGCCAGTTCAGGCAGCAGAGG

GGCCTCATCCCGGTGCTTCCCTGCAGGCAGTTGTGGGGCCGGCCTGCAGCAGGGGCTCAGACAGGGCCTTGGGAGAGGGAGGGAT

CACAGAGGTGTCCAGTGACAGGCAGGGCGGGCAGAGCCCATGGGGCCTTGGGCTCCTCACTCCTTCGGTCAGTCAGGGTGACATC

TGGAGCCACCTCCATTAATGGTGGGTTATGATTTGGTTCCCATGCAGCCCGTGCCAGCTCGCTGGGAGGAGGACGAGGACGCCTG

TGATC

239
C21orf29
AAGAGGAAATTCCCACCTAATAAATTTTGGTCAGACCGGTTGATCTCAAAACCCTGTCTCCTGATAAGATGTTATCAATGACAAT

GGTGCCCGAAACTTCATTAGCAATTTTAATTTCGCCTTGGAGCTGTGGTCCTGTGATCTCGCCCTGCCTCCACTGGCCTTGTGAT

ATTCTATTACCCTGTTAAGTACTTGCTGTCTGTCACCCACACCTATTCGCACACTCCTTCCCCTTTTGAAACTCCCTAATAAAAA

CTTGCTGGTTTTTGCGGCTTGTGGGGCATCACAGATCCTACCAACGTGTGATGTCTCCCCCGGACGCCCAGCTTTAAAATTTCTC

TCTTTTGTACTCTGTCCCTTTATTTCTCAAGCCAGTCGATGCTTAGGAAAATAGAAAAGAACCTACGTGATTATCGGGGCAGGTC

CCCCGATAACCCCCAGCTGCAGATCGAGGCCTAGTGCGAGCACAGGTCCCCCCAGACCCTTCCCAGTGCCCACCAACCGGCGGCC

TAGGCCAGGTAGAACTGGCAGCGCCTCCCCTGCTGCAACACCAGGCTCTGGTAGAAACTTCAGAAAACATGCACCGGCAAAACCA

AGGAAGGGTGGCTGCGTCCCGGGTTCTTCCGCGCAGCTGTGTGTACACGCATGCACACACCCACACGCACACACCCACGTGCACA

CCCCCATGCACACGCACCCACTTGCACGCCCATGCACGCACACACGCGCGTGCACCCATGCGCACGCACCCATGCACACACACGC

GCGCACACACCCACGTGCGCACCCACATGTACACACCCACGTGCACACACCCACGCGTACACACCCACGCGCACACACCGCTGTC

CCCAGCCGTGCAGAACGATCCTCCCTGAGTCCCCGGCTCCGACCCACACGCAGCACTCGCTAAACGCTTCCCACGCAGTCGTTTT

GCTGGGTTGCGCTTCACCCACTTCTCAGAGGGGGCGGCCGAGGCAGAGGTGTCGGGGATCGAGCAGCTCCGGGCCTCAGGGGTCG

CCCCGCCACCGTTTTCCTTTCCCAGATGCTGGGACGGGGGCAGGGAGGGGCTCCCCAGGCTGAACCCGACTAGGTCACCCTAGAA

GCGAGGCGAGCTTCTCTTCTGTTTTTCTTCGGCGCCCCTGAGCCCCTGACAGTGCCCAAGCTGCCCATGGGATTGGATTCGCCAG

AGCCTCCTACGCAGACCCCACCCAGGGCCAAAGCCAACCCCAAGCCCCACCACCTTGGTGGTGTGGGATGAAAAGTGAGCCATCG

AGAGATGGGGTCCCCCCACCCCCAACCCCTCCAAGGACAAAGGCGGGCTGGGAAGCACCCGCTTTCACGTCCGCCCCTGCCCGGC

TTTCCTAGCGGAATTGGCGCCGGCATCAGTTGGGGGTTGTGGGATCAGTGAGGAATCCCGTGGGGTCGCCTCCATTTATCAGTTG

TGTGGGGTTGGGCGAGCACCCCTAGCCCCAGCCCAGGCGATCAGGGCGCGAAGCCCACTGGACGCGGATTTGGGATTAGGACGGG

GGTGACAGCCAGGAGGACCGCACCTGCCCTCCCCACTCCTGCCGCTCCACCCCTGCCCCCACCGCAACACCAAGGTCTCCACCAG

GAAGATGGGGGTGGGGAAAGGACGCGGGGTGGGGGGGGGTGCGGGGAGAGAGGACACAGGGTCGGAAGGGTGAGGGGTAGTGGCA

GAGGCGGAGGCCGAGGCCACGCAGCTGCGGGGCGCAGGGAGGGGCAGAGGAGGGGCGTTCAGATGGGAACCTAGTCCAGACCCGT

CGGGGCCCTCGTGTGCGGCTCGTTATCCTGGAACCAGAGAGGCTGGAGACCCTTGGCTTGTCTGGAGCGGAACCGTAGTGTCCAA

TAGAGTGTGTGGGGCTCAGCCCTAAAGCTAAACATTCTTTATTTCCTGATGACCATGGGGGCGGAGCGGGGGAAAAGCCCTGGCC

TTATAGTTTAGAATTTTATAAAAGGAAAGGCGTGGCCACTGACAATTTGCGCTTCAGGAGTCCCAGAGTGACCGCCTGGCTCGGA

GCAGGGAATGAGGGGGTCCTTAACTCTGAGATTTGTTTTCTGAGAGACAAAGGTGATGGGTGAGGCGGCTAAGCCTCTGATTCTC

TATAGGTGGCGGTCATTCATTTCAGAACATGAATGGATTCAGTAAATAAACATGATAGAAAAATGCCACAAGCCCTAGGCCCATT

GGAGTGGACTGGACAGTCTGTTCCCAGTGTGTCCCTCAGCCTCGGTCCCCCACCCTTCCCGGAGCCCTGGGGGTCACACACATCC

CTCCTGGCTGCCTAGCCTGTGCCCCCCGATTCCCCCCCTCCCCGCCCCGCGCGTGCACACACACACACACACACACACACACACA

CACACACACCACACAGCACGAGGCGACAGAGATATGAGAGAGAGCGAGCGAGAGAGGACGGGAGAGAGAGGGAGTGCAAGTGTGC

GCTGGGGGTAACCCGTGCATGCATGCATTGGGGGTAACAGGCTGGAGCTCAGATCCCTCCCCCAGCCCCCAGCAGGGGGGACTGC

AGGCTCCTGGTCTGAGTGGGGAGCTGGGCCCCCTGGACAGAGGACTGGGCTGCGGGGTCAGGAATGGGCACACTTCCTAACTGCA

GGACACTCTAAGGGCTTTGGTCATGCACACGCAGCCAAGAGAAGGTGTCGCTGGCACACAGCCTTCCAGGAGCGGACTTGGAGAC

CTCGCCAAGGACCAGGACTCCCCAGCACTCACACTCCCTTAGGCGCTGAAGTCCAGAGGACAGAGGTTGAGGGCAGAGCTCCTGG

GAGCACCAGTGGAAGTAGGAGGGCTGGGCTGGAAAACCTCCCCCAACCTCCTATTGCAAAGAGGCTCCAGCCAGCAGCCTCCACA

CCCCAGTGATCTTTTAAGATGCAAATCTGCGCCATCATTTATTTCCTCAGTGCCTTCTCCAGCTCCTGGGATGCACACTGCCCGT

CCCCAGGCCCAGAGACCTGACCACCCTCATTCCTCCCTCAGCCCACCCTGGGGTCTCTCCACCAGCTGACAGCCTTCCTGCAGTC

CCCTCCCCGAATGCTGCTCCCTGAGGCCCTCCTGGACACCTGCAGGGCAGGCACAGCCCGCGGGACCTCACAGCACTTGCTCCGG

GCAGAGCTGCAGTTTGGCCAAGTTGCCAGCTCCGTGTGGGCAGGGGCCCTGGCCTGTGGCTGCCACATCCCGGGTGGGGGCACGG

CCTTTCCTGGCGTGGATGCTGAGCAAACGTAGGGGGAAGGGGAGTGAATGAGGAGAGCCAGGTAGCTCAGGGGCTGAGGCCTCAC

TGAGCAGGGTCCCGCGTGACCGGTCCCCACCGCTGACGGTTCCTGGGGTAACACTCAGGACAGGGAGAGGCAATGGAAAGAGACG

TGGCCGCCCTCGCATCCTGCAGCTCCCGCACTCCCAGCCTCCCAGCCTCCCACCCAGCCCCCCAGAGCCCACCAGTGACCCCGCC

CACTGGGTCCTCAGATGGCTCCCACGGGATCTCCTGCCTTGATCTCCTGTCCACATGGAGGTGAAGTGGGTTGCTCTGAATGAGG

GGTGCCGAGCCTAGGGCGCAGCCCACTCTCCTGGGTCCGCAGCATCACGCAGCCCGGACCACAGGCTCCTTACAAGAATCGGAAG

GGTCCCTGCAATCGCCCTTCGCACTGAGGCTTCCTACTGTGTGGTGTAAAAACACAGGCTTGTCCTCCCTTGCTGCCCACGGGGC

TGGAGCCGCCTGAAAATCCCAGCCCACAACTTCCCCAAAGCCTGGCAGTCACTTGAATAGCCAAATGAGTCCTAGAAAGCGAGAG

ACGAGAGGGGAATGAGCGCCGAAAATCAAAGCAGGTTCCCCTCCTGACAACTCCAGAGAAGGCGCATGGGCCCCGTGGCAGACCC

GAACCCCCAGCCTCGCGACCGCCTGTGACCTGCGGGTCAACCACCCGCCGCGGCTCCACGCCGTGGGCACAGACTCAGGGAGCAG

GATGAGAAAGCTGAGACGGCGCAGCCACGGCCCGGTGCCTTCACGCGCACAGCGACACAGCCCCAGCCAGCGGGGCCCACGCTAA

GGCGGAATCCCACAGAAGCCTACAGAGCGAGCGCGCGCCTGTGCTTCCCAAAACGGAATGGAACCAAGGTGACTTCTACAGAACG

ATCTGAAGCCCTGGCTGGCCCTTATGCTAGTCTCTTGGGAGCGTTCCAAATGCAGCTCAATATTACTTACTTGACTTTTATCTTT

CCTCCCTGGTTCGTGGTATTTATAACTGGGTCATCTTTTAACTATTTGCAACGTAGCTTCAGGGGAGAGGGGGAGGGCTTTATAA

ATAACCTGTATTATTATTATGCAGGTTGATTCTGTTCCCTGAGCTAAAGGGAACATGAAAATACATGTCTGTGACTCATGCCCCC

CCACCCCCACTCCAGGGTGTGCTGAGGAGTCTCTCAGCTGCCCCGGGGTCCTCGAGCAGGGGAGGGAGAAAGGCTGGCGCTGCGC

CCTCCATCGCGTGAAGCCAGGGGATTTTGCTCTGCGACAAGCTGACTTGGCTCTCGTATTGTTTGCAGAATCACCCAGTTCCAAG

GCAGTCCCTGCGGGCAGGTGCAGCTGTGCGGGAGCTTCAGTCCTGTCCCCAACACCCAGGCAGTAATGGTTCCAGCACGGAAGGT

CTACCTACCTCCCACTGCACAGCCCGAGGGCTGTCCTGGAGGCACAGCCATCCGTCCCTGGGTGGGCAGGCACGTTTATGACCCC

CACCCCCACCCCCACCCCCCACGCGAGTCAGCACGTTCCATACTCGGGTGATCGTGCTCATCCCCTGGTCATGTCATCGGGATCT

GAGTGCCATCCGAGCAGAGAGCTGTGGCCCGGTGCCGGGGGTGGACTTCATCTATTCCAGGGAACCAAGGATGCATGATTTGCAA

ACAAAACCAGAAGCGCAAGCCATCTCCTCGCCTCCCCTGATAGCCGTGCTGCGGAGCCTGAGTGCTGGAG

240
ITGB2
CAGGAACCACGGGACCTGCTGCCTAGCGGCCCTGTTCCACCCTTGGCCGCTCGCAAAATGTTTAGGCTTCATAAGGTTTGCCCAG

GGTCACAAATTTAACTCACAGCAAACAATGAAATCAGCGCATGATTTTCGAGCCCTCGTGGTCACCCTCCCTTCCTCCTGCCCTT

TCCTGCATGGGCAGCAGCAGGGTGAGGAGCTGCTCTCCCCAGGCCCAGGCTGGAGTCCCTCAGACGACCTGCCGGCCAGGGTACC

CCCCTGCCCCCACACAGCGCCTGACAGAGCCCCCCACACTGGGGGAACGTGGGGACCCAAGCAGGGGCAGCGGCCTCACCGGGCA

GGCGGCGACCTGCATCATGGCGTCCAGCCCACCCTCGGGTGCATCCAGGTTTCCGGAAATCAGCTGCTTCCCGACCTCGGTCTGA

AACTGGTTGGAGTTGTTGGTCAGCTTCAGCACGTGCCTGAAGGCAAACGGGGGCTGGCACTCTTTCTCCTTGTTGGGGCATGGGT

TTCGCAGCTTATCAGGGTGCGTGTTCACGAACGGCAGCACGGTCTTGTCCACGAAGGACCCGAAGCCTGCAGGGCACATGGAGGG

GCTGG

241
ITGB2
TGCGTTTAGTGTAAAAATATCAGGTGTGGCTGCACGGAGTGAAAAATCACAGGCTCCACGGAGCCGGGAGGCCTGCTGCCCTGCC

CTCTTGCTTTGATGAGGAAATGGCGACCGCAGAAGGAAATGTAGCAGCACCGGCAACCGGCATCCGTGGGGCCACGCCGGGCTGC

TTCCCAGGGCCCTCCAGCCAAGCAGCCACAGGAAAGAGTAGATGTTGATCCCAAGCTAGGACTGAGGAGTCCGTCCCTAAGAGCC

GAGGGAGTCAGGTGGGCGAAACTGGCCGCATGTCTGGGTACAACTGCTCAGGGTTTCTCATCTGCTGAATCACCAAGCTAGGTTC

TGAAGCCAGGCGTGAGTGAGCAGGACTGGAGCAGGATTCTGGGAACAATCTTTTCCCTCC

242
POFUT2
GCTGGGGAACTGAAGGAAGGGCTGTGGAGCCTGAAGCCTGGGCCTGGCCTGTGCTGCGGCCGCACCGCTGGGTGATGCAGGAGCC

ACTCCACCTCCCTGGCACCCCAGCCTCATCCGGCAACCTGGGAGCGTGGGCCTCCTGCCCCTCCAGGGAGGCCCTGGCCGTGTCC

TCATGGGGCCCCTCCAGGTCCTTGTGGCTCCAGGTCGGGACAGTGGCTGTGAGATCTGACCCTCCCGTTCCCCCTCCACCAAGTA

GGAGAAACCCCGGAGCATGAGCCCTCGTCCTTCACCGTCCCGGGGACAGGGGGACCCCCAGATGCTGCACGGCTGACAGGCCAAC

GTGGCAGAAGCTCCAGCTTCACAGGAAGCCAGTGACCATGAGAGTCTGTAGCTGTAACGAAGCCACAGAGCTGTGGCTTTCTTTC

CCCTTCAGCTCTAGGAAAGGTTATCTGCCCTGCACAGATCTCCGGAGGCCTGGCTGGGCTCTGAGAGCATCAGACTGATTATCGT

AAGAAAATAATCTCTGCAGACACATTCCTTGCTAGAAGCAGGGGACAAAGCCCAGCTTCAAAGACAATTCCACACACGCCCTCCC

TGCCCTGCACAGCTGCCTGCCGGGTGGGAGCAGAGCCCTTGCAGCCGGGCTCAGGGGCCTGGGCAGGGACAGCGTGTGGCAGGGG

CACAGCTGAGACAGGAGCCTCAAAGCGACACCAACCCGACGTGAAGCTACAGTTGAGGAGACACAGCTGCCCCCATTCCCGGGCC

TCATCTCCACAGTGAGACGCTGGACTCTCTCCCTGACCCACCGTCTCTTAGAACCTCCCCTCCATCCGGAGCAGTTCGGCAGCCC

CAGGGCAGCCAGGGGAACCCTGCCGAGTGCCTCTGGGCCGCCACAGACCGCAGAGCCCGCGGGAGCCTTGCTCACACAGCCTCAG

GTCCACTGTGGTCTTGGGGGAAAGCCCTGTCCTGGGACAGGGGAGCCGGGGGTCCTGGCCCTGGACCACCATCTGGGGACCACGT

TGTCACGCCTGCAAAGCTCCCTGCCCCACCCCCATGTGCCGGCTGGTGTTGACACCTTTGTAGAGTGGGAACCTGCCTCCGACCC

CAGCCTGCAGCCACAGGGCAGGTTATAGACCAGGTGAGAGGGCGCCGCGCCCAGAACCAAGGAGCACAAGTCCGCAGTGCCCATG

AGATCCTCATGCTGGCCGGCGCAGGAGCCATCCTCGGCCTCTGCAGGTCCTCGTGGGAAACCGCGGGGGCACGTGGGGCGGCTGC

AGGGTCCGCAAAGCCGGCTGTTTGCGAAGGGCGCAGCTCCACCTGGAACAGCCGAGGCCGCCCACGCGCTTCCCGCGGGATCAGA

GCAGCCTCCACGGCTGTTGTCTCAGGCACCACGGGATGCCTTTCTTCGTTTCAATAGCTGTGGGAAAGCCTCAATCGGTCCTGAA

AGAACCCAGATGTGCAGCAATGACAAGGCCTTCTCTGAGACTCTAGAACCTTCTGCCATCTCAGACAGGAGGGAGCCGTGAGGCA

GGCGGGAGATTTGCAGTCAGCAAAGGACGGGCAGGTGGGGCAGCTGCACACCCAGGGCCCTCTCCACGGTCTTCCCGGGCCCACC

CCTCCCGCGGTCCTGGGTCATCCACCTGCTGGCCTCACTCTGCCCACGCGGCCAGGTCCCACCGGCCCCTGAGCTCAACAGACCA

AAGCTGGCCCGACCCCACCCCCAAGAAGAATGAAACAATTTTTTTTTACCTCTTGCAGAAAAGTAAAAGATCATTTATTCATTCT

GTTTCTAGATAGCAAAACTAAGTGTCAAAAGCACCTTCTGCACACAGTCTGCACACACTGGCCGGTGGTCCTGTTCCCGCAAGGT

TGAGCTGTGTTCCAGAGACATGGGTCCTCCGGGTGATGAGGAGCCGCTGGAGGGCCCTGAGCTGCACGTGCTAATGATTAACGCC

CCGTCCGTGCTGGCCGGTTTCTCAAATGCCTCCTGACGATTGCGC

243
chr21:
GGCCTGAGGAGTCAAACGGTGCAAACCCTGCCCCACTCTGTTTGGGAAGCACCTGCTGTGTGGCAGGCGCTGCGCTTGGTGCTGG

45571500-
GGATAGACCATGGGGAAGAAACACACAGAACCTGCCCTGCTCTCAAGGAACAGGCCCTGGGGGCGGCCAGGGGCAGAGACCCAAG

45573700
GCAGACACCCACACAGTGGCGTAATGACAGTGCTTATGGTGGGGACCTGGCTGCACAGCAGGTCAGCAAGGGGATGTTCAGGTGA

CACTGGGGGCACGGAGACCCAGGGGAGAGTGGATTGACAGAGGGGACGCTGGGCAAATGTCCCGAGGCTGAGGTGGAGTTGCGGG

AAGGAGGAGGCTGCCGGGCAGAGGCGCAGAGAGCTTTGCAGGTGTTGGCAGAGACCAGCAGGCCCTGCGAGGCCTGGGGTGTGTC

CTCAGCTGGGAGGGCCATAGAAGGATCTGGGCTTGCAGATGCTGGTGCAGACTGGAGGCCTGGGGTGTGAGAGTCCAGGCGGGGC

TCCTGCCAACACCCAGGGGAGTGGGCCTGGGCCAGGTGGACCGGGAGCTGGCACGGTGGTCAGGTGCTTGGAGGCTGCGTGCCAC

GCTGGGGACCTGGAGGTGTGTGAGGAGGTGTCTGTTGCTCCTGGGGCTGCCGCCTGCAGGGCTGGGTGTGCAGCAGTGCGGGGCA

ATGAAGTGGGCGGGTTCTGGGATGGTGGACGTTCCCTTTGTTGGGAACGTGTTGGTGCCAAGCTGCCATTTGAGTTTGGCTCTGA

GGGGTCTGGGCAGGGGACACACAGGGAATCACACAGGATGGAGTGAGTTCCCAGGGACCCAGGGTGGCTTGGCCTGAGAACAGCT

CCCACTCCCAGATGTGTGGGAAGCCCTCGGCACCAAGCCTCAGCCTCTCCATCTGTGAAATGGAGACAACGTCACTGGACTTGCA

GGCTGTCCATGAGGGTGATGCGATCAGAAAGGGTGGAGTTCCTGAACGCCCCGGGGTCGGGGTCTCACAGCAGGAGCTTAGCTGG

TGTCGGCATCTCCTGGACCCGTCCTCAGCTCCGAGCGCCCAGTCCTGCCACCTGTGTCCAAGTCTGCACTGTGCCCACGAGGCCC

TCAAGGCCGCAGACAGCCCCACACTTCTCGGACGCCGCCCCAGCACGGTCCTTGTGTGAGGTGGACACTCCTTCTGGACGCCGCC

CCAGCACGGTCCTTGTGTGAGGTGGACACTCCTTCTGGACGCCGCCCCAGTACGGTCCTTGTGTGAGGTGGACACTCCTTCTAGG

GAAGGAGTAGTAACTCTTGGGTGGTCGGGTAGTTGCCATGGAAAGGGGCAGTAATGCCCAGGTATTGCCGTGGCAACCGTAAACT

GACATGGCGCACTGGAGGGCGTGCCTCATGGAAAGCTACCTGTGCCCCTGCCCTGTGTTAGCTAGGCCTCAATGTGGTCCAGTAT

CTGAGCACCGCCTCCTGCCTCAGATGTTCCCGTCTGTCACCCCATTACCAGGGCGGCACTTCGGGTCCTTTCCAGCCATCATTGT

CCTGGCATTGCCACAGTGGACACTGCCACACAGGCTTGTGTGCTTGCGCGTACCCAGGTCCTCACCTCTCTGGGATAAACCAGGC

ACGTGGCGGCCGCCCCATTTTCCACCCGCCAGCGGTGGAGGAGTTGCCCAGCCTTGCAGGAAAACAGCTCTCATGCCAGCAGCGG

AGCATCCTATTCAAGTTTTCTCAGGGCTGCCAGCACAAATGCTGCATGCCGGGCGGCTTCCTCAGCAGACCGTTGTTTCTCTGCG

TCCTGGAGGCTGGACGTCCCAGGTCCCCGTGTGGCAGGCCCGGTTCCTCCCGCAGCCTCTCCTTGGCTTGTGGGCGGCGTCTCCT

CCCTGGGTCCTCGCAGGGCCACCCCTCCGTGTGTCTGTGTCCTCCCTCCCCTTATAAGGACCCCAGGCAGACTGGATCAGGGCCT

GCCCTAAGGACTGAATTTTACCTTAATCACCTCTTTAAAAGCTGTCTCCAAATACAGTCACCTTCTGGGGTCCTGGCTGTTAGGG

CTTTGATGCATGGATTTGGGGGACACCGCTCAGCCCCTAACAGCCCCCATCCTCTGCCTGCCTTTACCATGGGGCTGAGCCCAGC

CCTGCAGGAGTCCCCTGGTTTGATGTCTGCTGTGGCCACGGCGACCCTCAGGCTGCTCCAGCCGCACTTGTGCTT

244
chr21:
GGGGAGTCTCCAGGGGCTGGGGCTGGAGCCGCATCAGAGAGGAAAGGGGTGTTTGAAAAAGGGGCAGGGCCTGGGACCCAGGAAA

45609000-
CTGTTCTTCCAGAGACACCCGTGAAGCTGAGCTTTGCCTCTCAGGGAAGCTGTGACCCCACGGGTGCTGCCCAGAGAGATCGGGC

45610600
CAGGTGGAGCCAAGATGGACTGGAATTCCCCGACGGGGACAAGGGGCCGGACGAGGCTGACTTGCCCTGTCTGATGAATGGTCAG

GTTTGCTTTTTCTCCTGAAAACACGAGGCAGTGATCCCGGCCAGCTAATTCCAGCAGACTGGAGACGGGATGGTGGAGAATGAGG

CTGTGGGCGGGAAGAGCAGATGGGACTCGCCAGCATCCTCACGGCAGGGCCGCGCTATTGCCCTCCCTCCCCTCCTACTCTCTGG

GGTCCCAGGAGCCCCAGATACGCAATGCTGCCAGGCGATTTCTGGCGCCCCGCAGACCCCTGCCCCTGGAGTTGGGCCAGGTCCC

GGCTGGAGCAAAGGGGGCTCCTTCAAGCCCGCTCCTCCCTGTCAAACCCGAGGAGCCTGACAGGCGCAGCGTCACCAGCGTCACC

GGGCCATAGTGAGCGGCCAAGCCAGCGTCACCGGGCCATAGTGAGCGGCCAAGCCAGCGTCACCGGGCCATAGTGAGCCGCCAAG

CCAGCGTCACCGGGCCATAGTGAGCCGCCAAGCCAGTGTCACCGGGCCATAGTGAGCGGCCAAGCCTTGGTCTGCCAGAGCCGGC

CGCACCAGAAGGATTTCTGGGTCCCCAGTCCTGGAGGAGCACACGGTTTACACCAGGCCTTGGGAGGGGAAGAGGCAAGGCGTGG

GCCCAGCCCTCACTCCCCAGGAGAAACCCTGTTTGAGCGGCAGAGGAGACTGGAGAGACCCCAGGGCGGGGATCCCTGAGAGGAG

AGAAACCCGGAATTCATCCACGGAGGCGTTCACCCAGAGGAGACCCGGAGCTTCTCCAGGAGAGGCTGGATTGCTCCAACAGGGG

CCCTGAGGAGCTGATGGCAAGAGCGGAAGGCAGCTCTGACTCGTGCGTCTGACTCCAGGTGTGGCCGTTGGGGCTACAGTGGGAC

CAGCCTGTTGTCACTGAACCCACAAAGTGCCTCCGAGCGCGGGTGGAGAGAGGGGGACCTCCCACCGTCTGCTGGCCTTGAATCT

TGAATCTAATTCCCGTCTGTGCTTTGATGGGAGAGGCACTGGGAGCGGGCGGCTTTTTCAGTTCCTTTTATCTTGAATGGCCTTT

GGGGGATTTTCACAGATTCTGAGTTCAAAGCCCAGGGAGGTGTGGGAACGTGACATTCCTCACCGCATTCCTCACCGCATTCCTC

TGTAAACCAGGCGGTGTTGGCACCCATGAGCCTGTGTCTTCTATGACATCAGGAGTTTTATCCCTCACGTCAGAAATCAGGGTTC

CAGGCGCCTTGGTTTTTCTTGGCGCCAGCGGCTTGGCTATAGAAGAAAAACTGAAGGGGCCAGGTGCGGTGGCTCACACCTGTAA

TCCCAGCACTTTGGAAGGCCAAGGCGGGTGGATCACGAGGTCAGGGGTTCGAGACCAGCCAACATGGCAA

245
COL18A1
GCTCCTCAGGGGGAGGTTCGGGGCCTTTGGTCTCTGGACTTGGGCAGCAGAAAGGAAACATCCCTGGGGGCCTGTGGTGACCCCC

ATCCTCCCCAGGGTGGTCTGGCAGGGGACACTGTTTTCCAAAGCAAAGCCAGAGCGCCAAGGGCTCTCGGGATTCACGAGATCCA

CATTTATCCCAAGTTAGAACAGCACATCTGTGCGTGCAAACTTCATTCTGACTTCGGCCGGCTGTCCTTCTTGCCCAAAGCACCG

TGAGGCCTCATCCCTGCATCCCTGTTGCTTCTTTCATGTGGGATGAGAACCCAGGAAGGGGCTGAGTGTGACTCCTCTGGTTTTT

AGAGAGCACTGCCCCCGCCCCGCCCCCTCCTGCTTCCCCACCTTTTCACAGTTGCCTGGCTGGGGCGTAAGTGAATTGACAGCAT

TTAGTTTGAGTGACTTTCGAGTTACTTTTTTTCTTTTTTTGAGACAGAGTCTCGCTCTGTCGCCCAGGGTGGACTGCAGTGGTGT

AATCTTGGCTCACTGCAACCTCTACCTCCCGGGTTCAAGCGATTCTCACATCTCAGCCTCTGGAGTAGCTGGAATTACAGGCGCC

CGCCACCACACCTGGCTAATTTTTGTGTTTTTAGTAGAGATGGGGTTTCACCATGTTGGCCAGGCTGGTCTCGAACTCCTGACCT

CAGGTGATCCGCCTGCCTTGGCCTCCCAAAGTGCTGGGATTACAGGTGTGAGCCACCGAGCCTGGCCTGGAGTTATTTTGGGAGA

GGGCAGCCCCTGGTTCAGCGTGGCGAGGCTGCGCTTGCTCTCCCGGGCGGGCGTCCACACCCTCCTCGCCGAGATGGAGAAGCCC

AAACCCCTGCAGCGCTCCCCCATCACGTCCGGCCCTGGAAGCCCCCGGAAACCCTGCCACGCCCTGAGTGGGAGAGCGCAGGTCC

CTTTCCGGCCCTGGAAGCCCCCAGAAACCCTTGGGTGCCAGGCCTGGCCGGGACAGCAGCGACACTGCATGCTCAGCCCTTGCGT

GAGACCACGGGAGTGTCCGCCCTCTGCACGTGCTGCTGATTGCCCACTTCGTCCAGCAGGTTTGGGAGCTTGTGGCTGCATCCTC

CTGCAGACACTTGCCCATTCTGGGGCCTCCTCTCTGTCTTTTCTCCTCTGTTGAGGGGTCTGGGAGGGAGGCCTTGGAGGGTACC

CATGCTGCTGGGACTGATGCTCCCCGCGGTGGAAGGAGCTGCCTCTTGAACAGCAGGGGGCTGAGCAGAGGGGAGGGGATGCGGG

GGTGCCGTGCACACAGGTGCTCTCAGGACGCAGGGGCTTCTCAGCCCTGCTGTCCCAGGGCTGCACTCCAGCAGGGCAGACTCCT

GAGGTGCAGACACCCCAGCTTCACGCTCACACTTCTGGAAGGCGATGTCTGTGCGTTTGCTTTCTGCTGCAGTTTAAAAAGCCGG

GCTCTCTCCGGAGCGTGTGTAGGGCCTGGTCACTGGAATATCTGGACTCAGTGTTAATGGCAGCCACGCTGGGGGCTGGGCCCAG

CTTTCTGTTCTCCGTGTGGGTGCCATATCCACCTCCATCGCAGCCCTTTCTCTCTCGACCTTTTAAATCACAGTGTCACCTCCCC

CTGCTGTCCTGCCAGTGGCCCCTGGAGGCTTCTCCCCACCCCTTTCTTCTGGGGCAATTCTTAAGGCTGGCATTGAATCAGGAGG

CCAGATGTGGCCCCTAGTAACTCACCAGCAGTCCCTGAGGCTTCTGGCTCCCCTGGCCCACCAGCCTCCCATGTCTGCCTCAGGC

CTCTTGACCCGCCTGGCACTGACCAGACTGTGTGCCCGGGTGCCGTGCCCATGGGCTCCGCCTCCCCCAGGCAGGCCCCCTCTTG

CTCCGCGGCCACCCCTGCTCTTGACCTCACACCTCTGCGGTGTGTCTGGACACACCAGCACCACGGCGGGCGGGGAGCGGAATTC

TCCAGGTGGGGTGGGCAGGCCGGCGGGTGTTGAGGTCTCTGTGCATGCTTGTGCGTACCCTGGACTTTGCCGTGAGGGGTGGCCA

GTGCTCTGGGTGCCTTTGCCAGACAACTGGTCTGCCGGGCCGAGCATTCATGCTGGTCGCCATCACGTGACTCCCATGCGCCCTG

GCCCTGGGGTTGGGTCTGCAGGACTGAGAACCAGCGGAAGGGGGGCGAGGCCTCGGGAATGCGCCGGCAACTGGCGATGAGCTCA

GGCCTGACTAATGAGCCCAGGTGACTCATACACCCGGGGCCTGGATGAGTCTGACTGGGTCAGGACTTCCCTGCTTGTTCTGTCC

TGGGAGATGTTGTCCCTGGCCCTGCAGAGCCGGGAGGACACGAGGCCTCCTGGGTCACAGCCAACGCAGCCTACTCCTGCCCACT

GCTCGCGCCGGCCAAGGCCCGTCGGCACCACCTCCTCCATGAAGCCTTCCTGACTGCCCCCATCCCTCTGTGGGCAGCTCGAGTG

TGCATCTTGAGTGCTGTGCAGGTTGGGGTCCGGCGCTCCTGCAGGCAGGCGGCGTCTGGGCCTGGGGGCTCTCAGAGTTTGAGGA

GCGTGTGGTGAGGGTGGCCTCGGGCCTCAAAGACGCAGCGCTGTGGGAACCGGGAGACTGGCTGAGCCCGCTCTGAGGAAGGTGG

GGCCAGGGGCACCCTCAGCTGACCCGGCGTGCAGGGGTGACCAGCCAGGCGTGGCCAAGGATGGGGTCTCTGGGATCAGGAGACT

TCAGTAGCAGCCAGGACCGAGGCCACCAGTTTCCACCCTGGCATTTTCCATCTTTTGAAGGACTGGAAACGATTGGATTCTTTAA

CTTTTTTAAGTTGAGGTGAAATTCACAACGCATAAAATTAACCATCTTAAAGCGAACAATTCGGTGACATTTAGTACAGCCAGAA

GGCTGTGCAGCCATCACCACTGCCCAACTCTAGAACATTCACACGCCGGAGAGAGGGAGCCCTGGGCCATCACGCAGCCACCGCC

CGGCCCCAAGAACCTGCGAGTCCACTTTCCACCTCTGGATCGGCGGTTCTGGACGTTCATGCAGGTGGTTCCCGCAGTGCGAGGC

CTTTTGTTTCGGGCTCCTCTCACAAGCCTCACGTTTCCAGGTACGTCGTGGTGTTGTGCAGACCCACAATTCATCCCTTTTCATG

GGTGTGTAATAGTCCACCATAGATTCTCTACGTTTTAAAGCATGTTTTATGTGCCTGAAATGTCTCTGCACTCGAGACTATAGCT

TGCTTTCTTTCTTTTCTTTTTTTTTTTTTAATTTGAGACGGAGTCTTGCTCTGTTTTCAGGCTGGAGTGCAGTGGTGCGATCTCG

GCTCACTATAACCTCTGCCTCCCAGGTTCAACTGATTCTTTTGCCTCAGCCTCCCGAGTAGCTGGGACTATAGGCGCGCCACCCC

ACCCGGCCAATTTTTTTGTATTTTTAGTAGAGATGGGGTTTCATCATGTTGGCCAGGATGGTCTCGATCTTCCGACCTTGTGATC

TGCCCGCCTCGGCCTCCCAAATTGTTGGGATTACAGGCGTGAGCCACCGCGCCCAGCCGAGACTACAGCTTTCTTTAACTGCATC

CCTGGAGGGATCTGAGAGTCTCTTTCCCTGTCTCCTTTCCTTTGGAAAACATTTCAGCCAGGGCTCCCCAAGATGAAAGGCCAGA

GTCCCAGGCATGGGCGTTGCAGGTGCACAGTTGCCACGGGGAGCTGTGGGTGATGGTCGCTGTCAGCGATGGCTGCTGCAGGTCC

CTGTGAGGAAGGGGCAGTGCCACAGCAGGAGGAGAGGGAGTCAGCGGACGTTGATTGGCAGTGCCCGCCCATTCCATCATTCAGT

CACCCACTGTGCACCCAGCACCCAGGCTCGGCTGCATAGAACATGGCCCAGGAAGGCTCCACTTCCTGTCTCCTCTTCTCCCCTC

TCCAGTCTCATGATGGGGCTGGAGGCATCTTCTAGTTTTGAGTTCTGAGCTAATGAACATGCTCATGAGCAGGCGGCAGGATCCC

AGGACGGTGGAGCTGGGAGCCTGACTGCGGGTGACGGACAGGCTCTGGCAGCCCCTGTCAGCATCCTCTCCAGGGCATGTGAAAG

CCAGTGTGTCCTCAGCTGCCAGTGCCCCCTCCCCACCTCCTCTGGGCCCATGTGCACGGGACCTGGGCTCCCCCAACCAAGCCTG

CCCGCCTTGGTTCAGCAGAACGGCTCCTGTCTCTACAGCGGTGCCAGGCCAGGAGTGCTGTGTCTGTGAAGCGGGGTCATGGTTT

TGGGGCCCTCATCTCCCTCGCGCCCTCTCATTGGGGACCCCCCGTCTCCCTAGCGCCCTCTCGTCCTCTCCTGCATGTGCTGTGT

CTGTGAAGCGGGGTCATGGTTTTGGGGCCCCCCGTCTCCCTAGCGTTCTCTCGCCCTCTCCAGCATGTGAAGTGGGGTCATGGTT

TGGGGGCCCCCATCTCCCTAGCGCCCTCTCGTTGGGGACCCCCCGTCTCCCTAGCGCCCTCTCGCCCTCGCCTGCATGTGCTGTG

TCCATGAAGTGGGGTCATGGTTTGGGGGCCCCCTATCTTTCTAGCACCCTCTCGCCCTCTCCTGTATGTGAAGTGGGGTCATGGT

TTGGGGGCCGCCATCTTTCTAGCGCCCTCTCGCCTTCTCCTGAGCGTGTGGAACTCTGTGGTGGTCAGAGCTAAGGTTCTGAATA

GGTCGAAGCACCTCCCCGGTGCCTCTCACCCTGAATGCTCTGGGAGGACACAGCCTTTTCATAGGCTACGACTGACATGGCAGGA

GGGGCCTGCCTGCCACCCGGGTCCTCTGCTGCCTGCTGCTTGCTGGGGAGGGGGCTCGAGACTGGGATCCTGGGCTTCTGCTCCA

GCTGTGCCCAAGGGAGCTGCTGAGGAGGGACCGGGTGGGGCATCCACTCTGGGCAGGTTCAGGGTCATTCTTGGTGACCCCGGGT

CCGGTTACAAAGGCTGATGGAGCGCGTGGGTGGCTGCCTAAGTCTCTGGAAGCCCAAGAATGTGGAGATGGCGCGTCTCGGCCCG

GGGTCTCGTGGCTGGTCTGGGAGAACTTGCCTTTATTTCTAGGCAGGAGGCTGCACTGCAAGGGAGCGTCAGTGGCCCGGCTGGC

TTTCCCCGGCCCTCAGCCCGCACTCGTCCACCAAAGCAAGCTCCTTTGTGGGGCTGCCCTGGGAAGCCGGGATCACGAGGCTCTG

CCGGCCGTGGTCACCCCATGAGGCAGGGTCAGCTCGGGAGCAAGGCGGATCAGATGGAACAGAACACGTAGACCACCTCGCCCGC

CCTTAGTCAGCTGGGCCATTGAAAATCAAGTCCGTAGAAAGACCTAGAAATAAGTCCCGGGGTGCCCTTGCCTGTTGACGGGCGG

GCCGAGCAGGACTGTTCTCAGGCAGGCACTGGTCTCTTGGCTTCCAGGTGGTTTGTTTGCTGGTTTGAGGCTGGGGGTGACGCTC

CTGTGCGGGAGGAGGTCGCATTCCATTCATAGCGGCTTATCTGGGCTGTCAGGCAGGCCTGGGAGGGAGCCTGCCTCTGTGCTCT

CCAAGGGTGGGCGACGGACAGACAGGGTGTCCCACCCCTTCTGGGCCAAGGACAGAGGGTCAGTGTTTGCAGAGACCTGGGGAGG

CCCAGGTGACCTCCACCGAGCACCTGCTGTGTGCAGGGCCAGTGCTGGCTGCAGAGACAGCGGAGCGTGTGTGGACCCGGCGGCC

CAGGGGAGGGGGGCAGGCAGGACCCGGCGGCCCAGGGGAGGGGGGCAGGCAGGACCCGGCGGCCCAGGGGAGGTGGGCAGGCAGG

ACCCGGCGGCCCAGGGGAGGGGGGCAGGCAGGACCCGGCGGCCCAGGGGAGGGGGCAGGCAGGACCCGGCGGCCCAGGGGAGGGG

GGCAGGCAGGACTCGGCGGCCCAGGGGAGGGGGGCAGGCAGGACCAGGCGGCCCTGGGGGTCAGGGGTGGAGGCCAGGCCTAGAC

GGCCCACAGGAGGGTGGACTCATTCTGACCGATTCCTGGAAGCCCCCGGAAAGTGGTGATGTTCTGGAGGGCCCAGCAGACCCCA

AGGCCCCCAAGACAATCCCAGCTGGCTCTCTGCGGCTCTCGGTGTCTGCCATTTGAGACAATTTGGGCACAGGCAGGGCAGGCCG

TCGCGGACGGTCTAAGCCGCGCGCATTGGTGGGGGCAGCAGAGCCCCTGCTCTCAGCTCCTCGGGGTACAGCGGGGGTACCAGGC

GGGTGAGTGGGTGGGTGGTCACTGCTCCTGCCAAGGGCAGCCCTGGTTTGGTTTGCACTTGCTGCCCTGGTGACGGCTGCTCTCA

TTCCTGCCCCATTGCTAACAAGGGTGTCATAAGCTACTTTCCCGGCCCACATCCTATTAAGCCCATGGAGACCCTCCCACAGCTG

AGCCTGCTGTGGGCTGCAGGCCCTGGGCGGTGCCCACCTCGGTCCCCACTGGCCTCCTTCCAGCACTTTAGAGCAGACACAGGTT

GGAGATAAGGAAAGTTCCAGAGCACAGACTGGAACAAGCCCCAGGCCTCTCCCTGCCCCAGCAGGGCCTCCCTGGATTTGGGGGA

CAGGTGCCCTCATGGGGGGTCCTGAAGGTCAGAGCTGGGGCTGGGGCTGGGCTGGCGGAGGTGGCCTTGGCGGAGGCCACATTCC

AGGGTCTCAGTGAGAGTCTGTGGCAGGCAGCCTTGCAGATGCCGCTGAGGGACCCCCCACTTCATGTTGTGGGTGATGTGGTCCA

TTGATTGCCTCCAGGTTTAAATCAGGTGGATATTTACCTAGCGGCCTCCTCTCCCTCTGCACAGGGCCTGGAGTGGGATGGACTG

GGGTGCTCAGCTGGAGGCTCTGCAGACACAGCCCCCTGGGCTATGCAGGCCCTGCTGGGAGCCACATTGCCATTTTTCATCACCC

ACTTTTTGGGTGAGAACCCCCTCGAGTCCTAACATCTGCCGCATCTCAGAGCCTGTGGCTCCAGTCAGAGCATCTGGACCATACT

GCTGGGGTCAGAGCGCGGCAGGACAATGGC

246
COL18A1
TGCCACCACCATCTTCAGGTAGAGCTTCTCTCTCCTCCTTGCTGGGCGGGGCCCCTCCCTGGGGAAGCCTGCAGGACCCAGACAG

CCAAGGACTCTCGCCCGCCGCAGCCGCTCCCAGCCAGCAGCTCCAACGCCCTGACGTCCGCCTGCGCACGCCACTTCTGCACCCC

CTGGTGATGGGCTCCCTGGGCAAGCACGCGGCCCCCTCCGCCTTCTCCTCTGGGCTCCCGGGCGCACTGTCTCAGGTCGCAGTCA

CCACTTTAACCAGGGACAGCGGTGCTTGGGTCTCCCACGTGGCTAACTCTGTGGGGCCGGGTCTTGCTAATAACTCTGCCCTGCT

CGGGGCTGACCCCGAGGCCCCCGCCGGTCGCTGCCTGCCCCTGCCACCCTCCCTGCCAGTCTGCGGCCACCTGGGCATCTCACGC

TTCTGGCTGCCCAACCACCTCCACCACGAGAGCGGCGAGCAGGTGCGGGCCGGGGCACGGGCGTGGGGGGGCCTGCTGCAGACGC

ACTGCCACCCCTTCCTCGCCTGGTTCTTCTGCCTGCTGCTGGTCCCCCCATGCGGCAGCGTCCCGCCGCCCGCCCCGCCACCCTG

CTGCCAGTTCTGCGAGGCCCTGCAGGATGCGTGTTGGAGCCGCCTGGGCGGGGGCCGGCTGCCCGTCGCCTGTGCCTCGCTCCCG

ACCCAGGAGGATGGGTACTGTGTGCTCATTGGGCCGGCTGCAGGTAACTGGCCGGCCCCGATCTCCCCACCCTTTCCTTTTTGCC

TTGCCAGGTAAGTGTGGGCGGGGCTGACGTGAGCCTGGTACAGGTTCCCCCCACATCGAATCTCTACGTTCAGGGGCCCGTGGCC

CTCGGGAGGTGGGAGAGCTGGGAGTGAGGCCTCCTGTGTGGGGAGGAGGCCGGCGTCTGGACAGGAAGAGGGCTGGATGAACCGC

AGCCGATGTGTCCAGGTGCCACCTGGGCCTGGAGCTCCCTGAGCATTTTAGCGCATTTAGTCCTCAGCACGGTCCCGAGATACCC

TGCCATGCCCCGAGTCACAGAGGGGAAACTGAGGCGTGGGGCAGTGGCGTGACTCACCCCAGGGAGCCGAGATTCCCGCTCAGGT

GTGGCTGCATCGACCTTGCTCCGGTCACTAAGCTGCACGGTTCGATGCGCTTCCTGGGAGCCCCAGCGTGCTCGGGCCAAGGGTG

CTGCCGCGTGGGCAGTGCAGAGACCCTACCAGCGTGGGGACCAGGGAGGTCTGCAGGGCCCGTCCTGAGAGGGAGCCTTTCATGT

CCCCCTCCCCATCCTGAAGCACACAGCCTCCCTGCCACAGTGGGGGCCGCTTCTGGGCCCAGGGGACGTTGCCCCATCACCGTGT

GGCCTGGCCTTGTTGCTGGCTGGACAGTTGGGGGCAGGAAGAGGAGGGAAAGGGGGACTCTTTAACCTCCTGGGGGCAGGGGCAG

CCCAGAAAGGACCCCAGCAGATCCCTCCTCTGTGTCCGGGAGTAGACGGGGCCCC

247
COL18A1
GGGCTCCACAGCGGCCTGTCTCCTCACAGGGTTCAGCCCAGTCTGCTCTCACTCATTTGCTGATTCATTCTTTCATTCAGCCAGT

CAATAGTCATGGCCCCTCCTGTGTGCCGGGTGGCCATGGATATTGCCCTGGGTAACACACAGCCTGGCCCTGTGGAGCAGACAGT

GGGGACAGCCATGTGGACAGGGTGCAGGTGGATGGCAATGGCAGCTGGGTCAGGAGGGGCTGAGGGCCGTGGGGAAAGGTGCAGA

ATCAATAGGGGCATCCGGACTGGGGTGCAGGCCTGGGGGCTGGGATTTCTAGGGTGGAGGTCACCTCTGAGGGAGACAGAGCAAG

GCCCTGGGAGATTAGAAGGTCGAAGGTCGCCGTGTTGAGGTCAGGGGCCCTGAATTGGAGCCGCGGCAAAGGAGAGGGCAGGTCA

GGGCACGTGGTGAGTGATTGCTGCGGCTTCTGAGCACGGCTGGGTCTGTGGGGCCTGAGCAGAGGTGACCCGCGATCCGGCGCCA

CGGCAGGCAGGACTCCCCACCCTTGCTGCTGCCTACACCCCCAGGGCAGCCCCAGAGTCGGGGGCGCAGCTCCCTGCTTGCCAGT

TCAGAGCCCAGCCCCTCTCACCCAGCCCAGAGGAGGACACAGATGGAGGAGGGGCACCCGGAGGGTCCCCCCGCCGACAGGCCCC

ACGTCTCCCACCTGCAGGACAATGAAGTGGCCGCCTTGCAGCCCCCCGTGGTGCAGCTGCACGACAGCAACCCCTACCCGCGGCG

GGAGCACCCCCACCCCACCGCGCGGCCCTGGCGGGCAGATGACATCCTGGCCAGCCCCCCTCGCCTGCCCGAGCCCCAGCCCTAC

CCCGGAGCCCCGCACCACAGCTCCTACGTGCACCTGCGGCCGGCGCGACCCACAAGCCCACCCGCCCACAGCCACCGCGACTTCC

AGCCGGTGGTGAGTGCCCCCCCAAAGTGGGCTTGGCTCCATCTAGCCCCTCGGCTCTCGGCAGCAGAAGAGGGCCCAGCCCCTGC

AGAGCTGCTGGGGGTCCCAGGCTTCGGCCATGGGTGGGGGTCTGGCGGCTCAGGGCCACTCAGGGCGGCTTGGCTGGCCCTGGGA

CTTGCCCTCTGGTGGCCAAGCAGTGGTCATGAAAGTCCAGCCGCTGTCACATCCTTGAGGAACCGGCGTACCTCCGCCTACAGCG

GCAGCTGGGGGCACCCACGTGGCCCGGGGCTGCTCTGACCTGGCAGCGTATGGGGGCTGCTGCCTGGGCCCCTCAGTGTGTCACT

TGCGCGCCTCCCGCTCAGCGCCCCTCGGCCGTGCCTGTCCACACAGGTGCGGGGCCGGGGTGGTGCGCCCGGGGCCTGGGTGCAG

GGGGCAGCGTGGGACACAGCCCGTGACGCGCCCCTCTCCCCGCAGCTCCACCTGGTTGCGCTCAACAGCCCCCTGTCAGGCGGCA

TGCGGGGCATCCGCGGGGCCGACTTCCAGTGCTTCCAGCAGGCGCGGGCCGTGGGGCTGGCGGGCACCTTCCGCGCCTTCCTGTC

CTCGCGCCTGCAGGACCTGTACAGCATCGTGCGCCGTGCCGACCGCGCAGCCGTGCCCATCGTCAACCTCAAGGTGGGTCAGTCC

AGTCCTGAGGGCGCGGGCTCCTCGGCCCCCACTTGACCTCTGGGGTGAACTCCCAGCGGGGAGCTCCCCTCTAGGGCCTCTGGAG

GCCACCATGTTACAGACACTGGCGCCTAGGCTGGCGACTTCAGGGCAGGCTCCGGGTGGGTCACACCCCTCCAGGCTCAGGCCAG

GCCTCTGCATCCCTGGGCACTGCCACGTCCCCCAGGGCATCCCATGAGGCCCCCCCGTGGCCCCCTGACCCCCCGCTCCCCCGGC

AGTGCCCCTCAGAGGGTCCCATGCTGCTGGACCAAGTGTCCACACAGGTGATAGGGCTCACATACAAGCCTGGAATCAGGAACCG

TCCTTTGGGCCTCTAGTGCCATGCGGGCTGGTGGCCCCTCTGCCA

248
chr21:
GCCTGGAGTGTAGTCCTGCTGAAGGCCAGAGACCACACACTCCACCCAGACTCCGGATCTCCCTCCCCAGCAGGGGGATGGAGGC

45885000-
CCTGCCGCTGGGAGTGCTGGTGTTATGTGGAAGGGCTGGGCTTCTCCAGGGCTCCTGGGAGGCCTAAACATCTTGCAAGGTTTTG

45887000
ACGTTAATTACTATTATGATTGCTTTCTGTGTGTTACTGTTTTCCCCACACTTTAGCCAGCTAATGTGGAGCTACAGAAGGCCCT

CGCCCCTACCCCTCCAGATGTCCCAGCCCATGACAAGCAGGAAGGCCGGGTGCTGGGAGACTTCCTGGGGCTGGATCTGACATCA

TTCCAAGCAGATGATAACCTGCCTTCCCGATTTCCAAACCCACAGCAAGACACCCTGGAGTTATTTATAAATGCGAGCCCCTGGG

TGCACTTCTGACGGGACCAGCACCCTGACGGCCATGAGAGGGTGGAGACAGCGCACCCCGAGCTCAGGGAGGCAGGAAACTCTGG

ACCTGGAGGCCGGGCACCATGAGGGACACGCTGCAGGCCCAGCTGCTGCCGCCTGGGGCGGGGCTGCCCTGCAGGCTCCGGGAAA

ACCCAGAACCAGGCCGGATCAGCGTGTGTCAAGAGGCGGGGCGTGAGAGATGAGCTGCTTTTTTTCTTCACAGGGTTGGCAGGAA

CTGCAAATAATAGAAAGTCTTTAGGGTCTAACACGCTGCCCTGAAAACACTATCATTACTTTCCTAATGACTAACTGTGTCTTTC

AGCCGGCGGGGCAGGCAGCTGAGGCCGCAGGCTCCCGCAGAGGACCGGGGGAGGCTGGCAGCCTGTAATCTGGGGGCGCTGACAG

TGCTCTGCCCAGACCCTCGCGCCAGCTCCAGCTCCAGCACAGCAGCCCTGGGTCCCTCTGGCCCCCTGCCCGCAGAGTCCAGGTG

TGGCAGAGGCCGCCCAGTATCCCTTCTCCTCCTCCTTTTCTAAAAACAGAGTCTCACGATGTTTCCCATGCGGGTCTCCAACGCC

TGGGCTCAAGCGATCCTTCTGCCTCGGCCTCCCAAAGCGTTGGGATTAAGGGGCGAGCCACCGCGCCCGGCCCACCTTCCCTTCT

GGTTCATTTCCAGTAAGGTCCTGTCCACAGCGTCCTTCCCAGCATTCCCACCAGGCTGCAGGCCTTGGCCTCCCTCCCCTCCATT

CTCATTCTCCCCGAAACCGCCAAGCGCGTCCAAAGCACGGGTTCGCCAAGCGCCCCCCCCGCCCCACTCCACATTCCCTTCCCCG

CCGACTCAGCCTCCGTAGCTCGCGGACGGCCCCTCCTCACGCCAGCCCAGGCTTTTTTTTTTTTTTTTTCTTCTATTTTAAGGTT

GTCTTTTAATGACACAAGCGACATTTGGAGACAAAAGGACACATCTCTTCCTGACCCACCTCCAACCCCAGCTGACGGCCGCCCT

GAGCCTGGCGTAGACGGCCCGGAACGTTCCCTGCGTGGGTTCCGTCCATCCCGAACCCCTGTCCCCGCGCCGGCTCCGGGGGTGC

TCGGGGGGCCGCGTGGGGTCTGTGACGTCGCCTCGAGGCTGCATCCCGGTGACCCGGCAGCCCCTGGCGCTCGCGGGAGGCGGGC

GGGCGCGGACCCCAGGCTTTAGGGCGCGATTCCTGCAGCTGGCTGCCGGCCCGAGGTTCTGGGGTGTCTGAGGTCTCGGGCGGGG

CGAGGACGTTTCTCCGGCTCAGCCCCCCCACCTCCTGCCCTGCCGCCCCCCACACCCAGCTCCCCACGGACGCCAAGAGGCGCCT

CCCACCCCGGCGAGGACCCGCGGGGAAACGGGGCCCAGGCGCGGCGACTGCGGAGGACGCGCCTCGGCCCCAGCGCCCTGGTCCT

CGGGGCGTCCGGCTGCCCTTGCCCGAGGCCGGGGCGGGCGCTCAGCGCCGCGGAAGAAACGCCCGGGCGGGGACGCACAGCGAGG

CGGGCTCCGCGGGAAGTACCGGGAAAACGGCGCGGAGCGGAACAG

249
PCBP3
TGGAGCAATCCCAGAGAGGCTGAGGTGTTCAGGCTGGCCCCAGATGCACACGAGCGTGAAGCCTGTTCAGAAGCCAGCTCCTCAC

ACCCTCTCCCCTGCCAGAGGCTCCAGCACCCCCTCCCCTCTCCTCTCCCCTCCCTTCCCTGTGGTCCTCCTGCCCACCCCACCCC

CGTCTGCATGTGCACCGTCACGGAGATGCGTGTACTAGGGCGGAGGTCGGGGACAGTCGTCAGAAGGACACAGGAAAGAAGGGAA

CAGGAATCCCATAACAGAACATTATCCGGCAGGAGTAATTAACACAGGCAGGACTGGAGGCTTTGTTTTGTTTTGCTTAAAAAAC

AGTGGTATTTAAATTAATGGGCATGGGAAGACTATTCAGTGAAAGACATCGGTCATTGAGGTATCTATTCAAAAACACGGTTTAG

TACTCTGCCACACACCGAACGCAACGCCACAGCAGCCATAGAAGCGTGTGTGGCTGTTTAACGTGGTCTTTTTGGGGAGGGCATC

CTAGGCAGAGCAGGCGTGGAAGGGAAGGCGGCGGACGGAACAAAACGCGGGCACGCAACGGCTGCTGCGCCGGATCTGAGGCAGG

GCCAGCCTGTGGGAGCAGCAACATCGCTCGCAGGACAGCGATGGAGCCCCCACGAATCCGCGTGAAAGCAGCAACCACCTAGAAA

TGAACGTACAGCTGCTTAGAAACAGAATACGGATGACCCGAAAGACTTCCCGATGGTAGTCACCAGCATACAGGACCTGACACGG

GCGTGCGGGCAGGGTGTGCCGCTACGGGGTCCCTGGCGCACCTGCTACCCCTGCTACCCGCATTCACCGCACGCGGAGGGTGCGG

GCCGTGAAGGTTATACATGCAAATATCCTTCCACCAGCCAGTTCTCCTTCCAGGAATCTGCCACCCGACCCTTGTGTTGTGCACA

GACATGGTCCAGGTGTTTGCGACGTGATTGTTTATCAGAGAGAGAGAAGGGAAATCTCCAGGCTCGCTGTAGCTGCAGGAGCTCT

GGGGGCTGCGCCCATCGTGGAGACGGATAGCTGTCTCTCATGAACACAGGACAGCAAGTCCGGCTGCGGCCACAGAAGACTCGCC

CTCCTGGACGCAGCGTCTTCCTTCCTCAGCCCCACACTGGAGGTGGCCAGTGCCATCCACAGCAGAAGGGGCCAGCCGGGACCAG

GCTCACGCCGTGGAATTCTGCTCTGTGGTAAGAGGAAGAGCGATAGCTGGAACCCAGCGCCGTCGCACACACAGCGGGGAAGAGT

CTCAGAAATGTTACTTTGAGTCAAAAAGCTGGACAAAAAAAGGCGCAAGCCAGATGGTGCTGAAGAGGCCACAGGAGGCTGGCAG

CCAGGGGGTCTGGCACCTCACTCGGAGGCGCAGTGGGCCCGTCCGGAATTAGTGGCCATACGGCAAGTGCCGAGTGGACATCAAA

CCGTCACTTCAGACTCCTGCGCTTCACTGCCTGTCGGTTATGCCTGGGTTTTGAAATCAAGTCACAGAACACCTGGAATGTGGTG

TTTACGCAGAACAAAGCGGGTGCCTCGGAGGAGAGAGCCTAGGGACAGGGGCACCTCCCGGTGTGGGTGCCCAGGGTTGCAGGGT

GGCTTCCTCTGTCTGCGCGGTTTTCAGAGCCCCAGGGTCCTGCCTGCCCGGCTGCCTGGAGGCGGCCCACATCCTGCTCTGCGCC

GCCGAATCTCAGCCTGAACAGCTTCGCTGGTGTTTGTGTTGACTTATTTGTTCTTTTTTTTTTTTTTTTTTTTTAAATAAAGGAT

TCCGATGCTGTTACAGTCAATAAAAGCCACAGGTCTGGGTGACCTACAAATGTGTGTGTCTGACTTTCTGCAGTTTAAATCGCCA

CTGAGCCTTAAGGCGTCTGGCCCGCGCATTGAGGAATCCACGTGGGTCTCGGGGTCCCCATGCCTGCCCAGCTCCCTGCTTCAGC

CTGGGCGGGTCTGGCGGGCATTTCTGCGAGCCTGTCCCTGGGCCCGCCTCCTGGCCAGACTTCCAGAAACATTGTCCACATCCCC

GTTGCACGTCCCCCCGTCACCGGAAACTGCAGCCCACAGCACTGGGAAGAACCCGGGAGGCAGGCGTTAGGACGGGGTGGCCGAG

ACAGGGAAGGGAGCCATGGCGGACGTCCTCACCCAAGCCAGGGCTTCCTGCCCCTGTGGTACTGACAGGAGCCCCGCAGGACGTG

GGGTTGGCTTTGGGCAGCTCGGTGGACACTTCTCTTTCAGATCCTGCCACAGCAAAGCTCACGAGACTCACTTCTTCCCATTGGA

ATTCACTAAGAACAAATTCAACAATTCAGACGCCCCAGCTGGAGGTTTATTTTATGGATTTTACCTGTGCGGTATTTAGGGTTGT

GTTTATGAATAAAGGTGTGCGTTCTGGCAAGTAGAAATACAGAGCTTGTCTTTCACCCAAGTATCTGTAACTTTCTCCAATGCAG

ACACTAAAATGCAATAAAAACAAACCAAACCCATTAAACATGAATTAGATGAGGCAGGCTGATGGGAGGTTGTGGGATTAACAGG

CCGTCAGCGGATTGAAGCTGCGCACATCGCTGGGATGCTGCTGCGGGAGGATTCGGTCTAATCCGGGAGCATCTGGCTGGGCAGT

GGGCAGCGTCTGCAGTCGTGGCTGCTTGAAGGTATGAAGGTTGTGGCCTTTGCTTCCCCCCATCAGGCTGCCCCACCCTGGACCC

CACCCAGACCCCTCGGGCACCCTGGGGTCATCTTCAGCTCCCCCTTCTCTTCCTTCCTTCTCTTCCGCCTGGGCCCCTACTGTGA

CCCGAGGTCAGCAGAGGACCCTGGCAGGTGGCTGCTCCCTGGGACTCGACTGTGCAGGTGAGGCTTGGGGTGACCGCTGCTCCTG

CTCCTGCTCCTCTCGCCGTCCCCACCCTCCTCCATCATGCTGTCAACATGCATGTGGGCTGCAGCCCTCAGCCTGCAGGACGCTG

TCAGTGCAGCTCCTCAGTGGCCAGG

250
PCBP3
ATCTTGTCTTCCTTGTCCCAGTCCTGGAACCAGCCACTGCCCCAGCAGCTCCTGTGTGTGGTGGCATGTTCTGGAAGCCAGGATG

CATGGTGCTCCTGGGCTGCTGTGGGTCCTGGGCTGCTGTGGGTCCCGAGCTGCTGTGGGTCCTGGGCTGCACCCCTGCAGAACAC

TTCCTTCCATGTTCAGCTCCCTATATGGAACCCCAGTTCCAGCCCCACAGCACAGGGTCCCCCAGTTCTTCCTGCCTCAGGTGTG

CACCACGAGGAATCCAACTGCCAGTATCTGTGCGTGGCCTCCCGCCGGGAGGAGGCTGCCGGAGGCTCTGAGCTCTAGCCCCACA

GCACTGGCACATCCTAGATTTCCGGGAAGACACGGCCTCCTCCCCAGGGGAAGGTGGTGGTGCCCACACCCAGAGCATTCATTCC

TGCAGTGGAGACAGAGGGACCTGCCTCTCCAACTGTGGGTGTCAGGAGCCAAGGCGCATGGTAAATGGGGCTCTCTGTGAGGCCA

GGTGCACGGCCCCATCTCCAGCAGCAGCGGCCATGCCACCCAGCTGCACTCTGTGGGGGAGGTGCCATGATTGACGGGGGCCCCT

CCCTGTGTCCAGTGTCCTCCTCCCTCCACGGGCCCCTCTGCACACCGTCCTCACAGTCTCCCTCTGCACACCGTCCTCACAGCCT

CCCTCTGCACACCATCCTCATGGTCTCCCTCTGCACACCGTCCTCACAGCCTCCCTCTGCACACCGTCCTCACAGCCTCCCTCTG

CACACCGTCCTCACAGCCTCCCTCTGCACACCATCCTCATGGTCTCCCTCTCCTTCCACAGACCCCTCTGCTCGCCATCCTGACG

GCCTCCCTCTCCCTCCACGGACCCCTCTACACACTGTCCTCCCAGCCTCCCTCTACACGCCATCCTCACAGCCTCCCTCTCCCTC

CACGGGCCCCTCTACACACCGTCCTCACGGCCTCCCTCTCCCTCCACGGGCCCCTCTGCACACCGTCCTCACAGCCTCCCTCTCC

CTCCACGGGCCCCTCTGCACGCCGTCCTCACGGCCTCCCTCTGCCTCCACGGGCCCCTCTGCACGCCGTCCTCACGGCCTCCCTC

TGCCTCCACGGGCCCCTCTGCATGCCGTCCTCACGGCCTCCCTCTCTCTCCACGGGCCCCTCTGCACGCCGTCCTCACGGCCTCC

CTCTCTCTCCACGGGCCCCTCTGCACGCCGTCCTCACAGCCTTCCTCTTTTTCCACAGACCCCTCTGCACGCCGTCCTCACGGCC

TCCCTCTCCCTCCACGGGCCCCTCTGCATGCCGTCCTCACAGCCTCACCGACGTCACCATTGCTGGCCCCGCTTCAGGTGACAGG

CCACAGTAGCACCTGTCAGCTCTGTCCCGCTGCTGGACAGGGAGATACTGGGCCACTCAGCCCAGCGGGGAACGTGTGTCCCGAA

ACTGCCTTGGGCTCGCCATCAGAACTGTGGCAGCATCTTCCAGCGTTCCTTTTAACAGGCTGCCGTTGGAATAGGAGTCACGGAG

CAATTGCAGTGCTAAGTTTTCTTTAAGTCACACAATTGAAGGAGGCTTTATTTTTCACACATTTCTTCCAGAGTTTCCTGGTAGC

CTGAGTGCATGGGTGATGCCCCCTGAGTTATTTATCAGGGGCAGCCAGCTGCCCTCCCCCGGGGCACTTACAGTCAGCCCATCTC

TGTCCTGGTCAGGTGGGCGCCAAGGAAGACCCGGCTCAGGGCCTCTGTATGGGCAGCCTGGCTTGTACACACACCCCTCCCCACC

AGCAGATTCTGAATTCTCCCTTCTTCATGCACACCGGGAAGGTCCCTTCTGCACTCATACCGGGAAGGTAGGCAGGTTTCGGTAG

TGTCTGCCTCCAGTGTTTTCCTCCTCCTGCTCTATGACATCATCTTTCTGTGATTTTTTTTTTCTTGCAGGAAGTTGGAAGCATC

ATCGGGAAGGTAATTATTGATTGAATCTCTGCCTCTCCTGGGGTCTCTGTAAGGGGATGGTGAGGATGGCAGCCTCCCTGGGTAC

TAGGTGGCACCCAGTAGGTGCGCCTTTCCCAGTTGGTGGGTGGTCTGTGTTCCATGAAGACAGGACCCCAGAGGTGTCGCCTTTA

TGCTGTATGACATTGAAGCTGGTCCCTGGCTCTGCGTGGCCTGAGGGGAAGGGGTTCACTCCAGCTGGTCACCTCGCTGCCCCCT

GCCCGTGGCCTTGGTGGCCAGTCCTTCTTTCCCGGTTGAAGACCCCACGAAGAATGATTTCTCACGCCTTCTTCAGCCGGCTGTG

TAGTCTGGGTGGTCTCCAGGAGTGCCAGTGGAGGCAGCAGCCCCCAGACAATTCCTTTCCAAATCAGGGCTGGCCCGGGGGAAGT

AAGGCCCAGTTTGGAAGCCTGCTGCCCCGGGAGGCCGAGCAGTGAGGGCCACCTCCCTGTCTTCATCACATTTTCACCGCTTCCG

GGGGTCCTTCCCCTCAGTCCCACCATGGGGGCGCC

251
COL6A1
GCTGGACACCTCTGAGAGCGTGGCCCTGAGGCTGAAGCCCTACGGGGCCCTCGTGGACAAAGTCAAGTCCTTCACCAAGCGCTTC

ATCGACAACCTGAGGGACAGGTAGGAGGGACGCCCCGTGACCTTCCTCCTGTGCTTCTGGGCCTCTTGGAGGGAGGGGTGGGGGC

CCAGGGGAACACGGGTGCGACGGCCTCAACCTCCTAAGGTTGGGCGAGCGTTGCCCTGACCGGGGCCCCTCCCGGCGCCCTCCAG

AGTGAGGCCGGGGCCCTTTCCGGCGCCCTCCAGAGTGAGCTGGTCTGAGCCTCTCCCAGCGCCTTCCAGAGTGAGCTGGTTTGAG

ACCCTGCTCGCGGGGGTGGCACCTGTTCAGCAGGGCCGAGGTGACAGTGAGGCTGAGATGTAGGGAAGAGAGGCTCCCGCAGGCT

GACCGAGAGGGCTCAGCGCACTGGCCCAGACACGCAGTCCTGCCTGGTGCGCGGGAGCCCCTCACTAACCACCTGGACCCTGGTT

TGTTCCGTGGGCAGTGAGAGCCTCTACCTGGGTCCTGGATCCCACGTTCTGAAGGTCCCCGACTCGGGAGCCAGGAGGGGTGTCG

CTCTGCAGCCCCAGGGCCCCCAGGCTTGGTTCTGGGCTTGGGACACGGCACCCTCTGCTCCACGTTCCTCCATCTGTGCGTGTGG

CTGAGGACAGACCGGGGGGAGAGGGGAGTCGGTCCTGTGGGTGCACAGGGCCGCTGAGGGGGGGGCATGTAGAACGGGGCTCCCC

CACTGAGACGGGTCCTGGCAGTGGGGACACAGCTTAGCCGGCGTAGGAACCCCCGTCCTCCTTGACCCTGCTGACTGGCCGCTGG

GCCGGAGCCTCCCGCCACCAGAAGGGGCACAGTCAGAGGCTGCCGGTAACAGCAGGGTGGACCTTCCAGCCCACACCGTGCCCAG

CAGGAGCCATTGGTACCAGGAACCCTGAGCTTAGTGGACATGGCCAGGCCCGTGCGGCAGTGTTTGGGGGGGGGTCTGGCTGTGG

ATGGCACCGGGGAGGGGCGGCCGCGTGGCCCAGCGTCCCCCGAGTCGCCCTTGTTGCCTTTACTCAGTCTCCCCATGACTCAGTT

TCCCACCTGTGAAATGGGGCGGAGTCATCCCCATGTCGCTGCCACTGGATTCCTGCAGGCGCCGTGGTCACTCTGCTGAATGGAT

GGGAGGGTGGGTGGGGCAGAGGTGGGCCCACCCCAGGCTGGGGCAGAGCAGACCCCTGAGAGCCTCAGGCTCAGGTGCTCAGAGG

GCAGCGAGGGGGCTGCTCAGATCCCCGGGGTGCCTCCTTCCCCCACTGTCATGCTGCCCCACTGCAGGCCCAAGGACCCCACCCC

AGCAGGGCCACACACTCAGGGCTCCTGGTCTGAGGGCCTGAGGGATCGGGGCGCAGGTCGCTTGCTGGCCACACCCGCCTGCACA

GCCTTCCAGGAGGGCCGGCCTCAGGGCCACAGGGCAAGTCCAGCTGTGTGTCAGCCACGGCCAGGGTGGGGCAGCCTGTCCATCT

GGGTGACGTCGCGCCCTGGGACGGGTAGCGATGGCGCCAGGGGCCGCCCGCCTCACGCCCGCCGTGCCTGTTCCTGGCAGGTACT

ACCGCTGTGACCGAAACCTGGTGTGGAACGCAGGCGCGCTGCACTACAGTGACGAGGTGGAGATCATCCAAGGCCTCACGCGCAT

GCCTGGCGGCCGCGACGCACTCAAAAGCAGCGTGGACGCGGTCAAGTACTTTGGGAAGGGCACCTACACCGACTGCGCTATCAAG

AAGGGGCTGGAGCAGCTCCTCGTGGGGTGAGTGGCCCCCAGCCTCCTGCCCACGCCAGTTCTCACGCGTGGTACCCAGCCTGGGC

TGGGGTTGGCCTGGGGTCCCTGTGCGGCTTCAGCTGCAGCCTCCCTGTTCTCTTGGAGGCTGCACGGCCTCCCTGACCCACTTTG

TGGGCAGGAAAGAGACGGAGACAGACAGAGACAGAGAGAAACAGAAACAGGGAGAAACAGACACAGAGAGAGACAGAGACAGAGA

GAGATAGAGACAGAGACAGAGAGAGACAGAGACAAAGAGTGACAGAGGGACCAAGACAGGCAGACAGAGACAAACAGAGACAGAG

ACAGAGACACAGAGAGAGACACAGAGAGACAGAGACGGGAACAGAGACAGGCAGACAGAGACAGAGAGAGACAGAGACAGAAACA

GAGACAGAGGGACAGAGACAGGCAGAGAGAGACAGAGAGACAGAGACAGAGACAGACAAACAGAGACAGAGAGACAGAAACAGGG

ACAGAGACAGAAAGAGAGAGAGACAGAGGGAAACAGAGAGAGACAGAGACAGATAGAAAAAGACAGAGGCAGAGAGAAGCAGAGA

CAGAGAAACAAAGACAGTCAGAGACAGACAGAGACAGAGACAGAAACAGAGACAGAGAGACAGAGACAGAGGGGCAGAGACAGGC

AGACAGAGAGACAGAGACAGAGACAGCGAAACAGAGACAGAAACATACAGAGACAGAGAGACAGAGAGAAGCAGAGACAGACAGA

GGCAGAGAGACAGAGAGAAGCAGAGACAGGGACAGAGACAGAGACAGAAATAGAGAGATAGAGACAGAGGGACAGAGACAGAGAG

ATAGAGACAGAGAGGGAGACAGAGAGATAGAAGCAGAGAGAGAGAGACAAAGACAGAGGCAGAGAGACAGAGAGAGAAGCACAGA

CAGAGACAGACAGAGAGACAGGGACAGACAGAGACAGAGAGACCGGAAACAGAGGCAGAGAGACTGAGAGACTGAGAGAGACGGG

GTGGTTTTCCCCACAGCATCAACACCAAGCAGGGCTAGGATCACTGAAACAGACTCATCAGACCCGAAGCATGCGCTTTCTCGGG

GTTTTTCTGGACTGAGGGGTTTCCTCTCATCCCAGTGTCCAGCTGTGGGGACGCAGGGGCCGCAAGCCCCGGAGTGTCCAGAGGG

GAACGTGGCCTCCCCACACCCAGCCCTTCACGAGGCCTCAGGATCCCAGTGGGGGTACCCGAGGCTGCCCTGTCCAGCCAGGCGG

TGCGGGGGGTTTGGGGAGAGCCTCTCCCCGAGGTCGGTCTCAGAGGGCCACATGGCCGGTGTGGGCCGGACATTCCCTTTCCAAT

GGTTGTGCCCACTTCCCTCCAGAGTTGGTGCCAAGCTGGGACCTGGGGGACTTGGAGTCTCAGGAAGTCGTCCGCTGTCTGCAGG

GGGTGCATGGGGGATGTGGCCACACACGTCAGAGTGCGGCCCCCTGTGGAAGCCACAGACAGACACGACTCCCCTAAATGAGCTC

GCCCTTCTGGCCGAGATGCTCAGCGTCCCCAGCAGGCTGCCCGACTGCCCTGCGATACTGCCCTCCTTCCTGCTGCTCCCACTTT

CCCTTTCGGGGGGTTGGATTTGGGGCATTCAGGGATCGCCCTGTTGTTTGCTCATCACACCCATTTCCTGCAAGAGCCACGGTGA

CCGAGCAGCCTTGAGTTGAGGCAGCTTGTGGGTAGACGCGGCGGGCATCTCGGAGGGGCACGCTCCCTGCCACCCTCAGCCTCCA

CTCACTGGTCAGGGGCTTTGCGCCCCAGGGCACCCCAGGAACCGAGCCTCCTTTGGGGTCATGGGTGCCTCTCCTGGGAGGGCGT

GGATTTTCCAAAGCAGTTTAGAGAAATGAGACCCACAGGCGTTATTTCCCATGGTGAGGTTCTTTTCAGTAACCCCCACCGTATA

GCCAGGATCAGCAAAGAGAGGCGGCTCCTCCCGGTGAGACAGGGACCAGCACCTCCCGGACAGGCTTGGGTCTCCCTCCAGTTCC

CCCACCTAGTCTCGAGGTCTCACGCTGCCCTCTCCTGTCCAGGGGCTCCCACCTGAAGGAGAATAAGTACCTGATTGTGGTGACC

GACGGGCACCCCCTGGAGGGCTACAAGGAACCCTGTGGGGGGCTGGAGGATGCTGTGAACGAGGCCAAGCACCTGGGCGTCAAAG

TCTTCTCGGTGGCCATCACACCCGACCACCTGGTAGGCACCGGCCCCCCCCGGCAGATGCCCCCAACCACAGGGAGTGGCGGCTG

CAAGGCCCCCGGCAGCTGGGACCGTCTTTTGGTCCTCGGGAGGGTGTGGGTTCTCCAGCCGGCCACCCTTGCCCCTGAGAGGCCA

GCCCCTCCTGCTGAGGAGCCTGGAGCGCCCCAGCCCAGCCTCCCCTCTGGCCCTGTGGGAAGCGGCCCCGGCCGTCAGGGGTCCC

AGCCCTGCTCAGCCCACCCTGAACACTGCCCCCAGGAGCCGCGTCTGAGCATCATCGCCACGGACCACACGTACCGGCGCAACTT

CACGGCGGCTGACTGGGGCCAGAGCCGCGACGCAGAGGAGGCCATCAGCCAGACCATCGACACCATCGTGGACATGATCGTGAGG

CCCCTGCCCAGGAGACGGGGAGGCCCGCGGCGGCCGCAGGTGGAAAGTAATTCTGCGTTTCCATTTCTCTTTCCAGAAAAATAAC

GTGGAGCAAGTGGTAAGAGCCCTCCCCACCACCCCCAGCCGTGAGTCTGCACACGTCCACCCACACGTCCACCTGTGTGTTCAGG

ACGCATGTCCCTATGCATATCCGCCCATGTGCCCGGGACACATGTCCCCTGCGTGTCTGCCCGTGTGCCCGGGATGTGTGTCCCC

CTGCGTGTCCACCTGTGTGTCTGCCCATGTGCCTGGGACATGTGTCCGCCTGTGCGTCCATCCGTGTGTCCGTCTGCCCATGTGC

CTGGGTCGCATGTCACCCTGTGTCCCAGCCGTATGTCCGTGGCTTTCCCACTGACTCGTCTCCATGCTTTCCCCCCACAGTGCTG

CTCCTTCGAATGCCAGGTGAGTGTGCCCCCCGACCCCTGACCCCGCGCCCTGCACCCTGGGAACCTGAGTCTGGGGTCCTGGCTG

ACCGTCCCCTCTGCCTTGCAGCCTGCAAGAGGACCTCCGGGGCTCCGGGGCGACCCCGGCTTTGAGGTGAGTGGTGACTCCTGCT

CCTCCCATGTGTTGTGGGGCCTGGGAGTGGGGGTGGCAGGACCAAAGCCTCCTGGGCACCCAAGTCCACCATGAGGATCCAGAGG

GGACGGCGGGGGTCCAGATGGAGGGGACGGCGGGGGTCCAGATGGAGGGGACGGCGGGAGTCCAGATGGAGGGGATGGCGGGGTC

CAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGATGGCGGGGTCCAGATGGAGGGGACGG

CGGGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGACGTCGGGGCTCCAGATGGAGGGGACGGCGGGAGTCCAGATGG

AGGGGACGGCGGGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGACGTCGGGGCT

CCAGATGGAGGGGACGGCGGGAGTCCAGATGGAGGGGACGGCGTGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGAC

GTCGGGGCTCCAGATGGAGGGGACGGCGGGGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGACGGCGGGGTCCAGAT

GGAGGGGACGGCGGGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGACGGCGGGA

GTCCAGATGGAGGGGACGGCGTGGTCCAGATGGAGGGGACGGCGGGGTCCAGATGGAGGGGACGTCGGGGCTCCAGATGGAGGGG

ACGGCGGGGTCCAGATGGAGGGGATGTCGGGGTCCAGATGGAAGGGACGGCGGGGTCCAGCAGGCAGGCTCCGGCCGTGCAGGGT

GTGGACTGTCCCGGGGGCGCTGGGGGCTTCTGAGGGTGTCTCTGTCCGCCCTGCCCTCAGCCGCACTCTGTTCAGAAGGACCTTT

CTGGAGGTAGGAGGGTGAGAATGTGGGTCCCCTGCTTCTGTGTGGCTCAC

252
COL6A1
GGCCGGGGAGGCGGGGAGGCTGCCCCAAGAGTAAAAGCCTTTCTGACGTGCGCAGGACGCGGCCCTGACTGGTCTAACTGACTCT

TTCTCTTCTCCTCAGCTTGCTGTGGTGAGACCCAGGCTCTAGCTCCTGAGAGAATGGATCCCGGGGGTCGGGGAGCGAGGCCTGG

GTCCCACACATGTCACAGGACAGCACATGGCACTCTGGTCCCCGCCCGCAGCTCCCTGCACCTGCCCGCCCCCTCTGGGGCCTGC

TCCAAGCCAGCAGGGTTCCCGGGTGTTGGGCTGGGCCCCGCCCTCTTTCACCCATAACTGAAATAACCAGGAGCAGGCTTGGGGG

GGTCCCTGCTCCATCATTCTGGCCCACAGGCCCCACCCTAGCCTGGCTGAGCAACGCCAGCCCTGACCAGCCGCCGGACAGAGCA

GCCTTTACGGGGCCATGGGAGGGGGTGGGCTTTTCTGGGGCTGAGACGGGGGGACCCCAACGTGTCAGGTGAGGATGTGGCAGCC

AAGGAGGGGCCAGGGCGGTGGAGGGGAGGGGCCAGGGCACTGGAGGGGAGGGGCGTGCTCTGCTGACACCGCCCCCGCCTGCAGA

ATGCAAGTGCGGCCCCATCGACCTCCTGTTCGTGCTGGACAGCTCAGAGAGCATTGGCCTGCAGAACTTCGAGATTGCCAAGGAC

TTCGTCGTCAAGGTCATCGACCGGCTGAGCCGGGACGAGCTGGTCAAGGTGAGGCCTCGCCCCGCCCGGCTTTCTCAAGCCCAGG

TGCACCCCGACCCTGCCGGCCGCCCCTGCCCGCGCCAGACCTCAGCCTCCCGAGGCCACCGCTGCATCCCTGTGACTTCCCTACT

CATGACAAGGATGCCAGGCACGCGCCAGCCCGTCCAGGCCTCCAGCTCCACCTGGCGAGGCTGGCCCATTGTACACAGGCGCCCC

AGATGAGGGAGGGTCTCCCCCTCTCCTTGAAGGGCGGTAGTCTGGGGTCCTGAGTGCTGGGTGTGGGCTTGTCCCTCGTGGACAG

AACCCAGGAGGGCTTCATCCACCAAGGAAGATTGCTTTGCAGGGTACCCAGGTCCCGGGGGCTGTGCCACCCTCTGGGCACCCGG

AGCCAATCGCAGGGTACCCAGGTCCCGGGGGCTGTGCCACCCTCTGTGCACCCAGAGCCAATCGCAGGGGACCCAGGTCCTGAGG

TCCTGGGGGCCATGCCACCCTCTGGGCACCCGCAGCCAATAGAGTCACCCTTGGGAAGCTTATGCGGACCTGGGGCAGCACTCGC

GTCCTGACCCCGGTGCCGGTCCCACAGTTCGAGCCAGGGCAGTCGTACGCGGGTGTGGTGCAGTACAGCCACAGCCAGATGCAGG

AGCACGTGAGCCTGCGCAGCCCCAGCATCCGGAACGTGCAGGAGCTCAAGGAGTGAGTGCCCCACGCGGCCAGGACCCTCCCACC

CCTCGCCCCGACCGCTGTTCCCACGGCAGGTCGGCCCTGACCCCTGATCCCAGGTGGGCTCGGCCCCGCGGCAGGCCTGGCCCCA

ACCGGCCCTTCCTGCCCTTTGCTATGCAGAGCCATCAAGAGCCTGCAGTGGATGGCGGGCGGCACCTTCACGGGGGAGGCCCTGC

AGTACACGCGGGACCAGCTGCTGCCGCCCAGCCCGAACAACCGCATCGCCCTGGTCATCACTGACGGGCGCTCAGACACTCAGAG

GGACACCACACCGCTCAACGTGCTCTGCAGCCCCGGCATCCAGGTGGGGTGGCCACCCCCAGGCTGCACCTGCCCCGCCTAGGGC

GCCCCGCCAGCCAGGGTGGCCTTGTCCCCAGAAAGACGAGGGCAGAGCAGGCTGCGCCACACCGATACTGTCTGTCCCCACAGGT

GGTCTCCGTGGGCATCAAAGACGTGTTTGACTTCATCCCAGGCTCAGACCAGCTCAATGTCATTTCTTGCCAAGGCCTGGCACCA

TCCCAGGGCCGGCCCGGCCTCTCGCTGGTCAAGGAGAACTATGCAGAGCTGCTGGAGGATGCCTTCCTGAAGAATGTCACCGCCC

AGATCTGCATAGGTGCGCATGGGGCCACCCGGGCAGTCCCAGATCTGCGTAGGTGCGCGCGGGGCCGCCCGGGCAGTCCCAGATC

TGCGTAGGTGCACGCGGGGCCGCCCGGGCAGTCCCAGATCTGCGTAGGTGCACGCGGGGCCGCCCAGGGCCGTCCCAGATCTGTG

TAGGTGCGCGCAGGCGCCCAGGGCTGTCCCAGAGGCCTCCTCCCAGCTCACTGTTACCTCCAGGGGCACGGCCACCCTGTAGGTG

CGCACGGGGCCGCCTGGGGCTGTCCCACAGGCATCCTCCTCCCGGCTCGCTGTGACTTCCGGGGGCACGGCCACCCCTGTGCTCG

GCCGGGAGGTCCTGTGACATCTCCTTGCGGGGTTATAGGTGGAGCAGTGGGCTCACACTGCACGGCTTTTCTCTTTTACAGACAA

GAAGTGTCCAGATTACACCTGCCCCAGTGAGTACCTCGGCGGCCGGGACACGTGGGGAGGAGGGCACCGTGGTTGGGGCGAGGGC

TCTGAGAGGACGGGGCTCTGGGAGGAGGGCCTGGCGGTCACGAGAGTAGGTGCATGGCTCACTCCGGTGGCTGAGCACCACCGTG

CCGTGCCCTCTCTGGGGAGCTTAGACGCTCTCTGGCCGGCCCACTGCGGCTGCATCACCAGGGCCTCATGCTAACGGCTGCCCAC

CCCGCCCCGCAGTCACGTTCTCCTCCCCGGCTGACATCACCATCCTGCTGGACGGCTCCGCCAGCGTGGGCAGCCACAACTTTGA

CACCACCAAGCGCTTCGCCAAGCGCCTGGCCGAGCGCTTCCTCACAGCGGGCAGGACGGACCCCGCCCACGACGTGCGGGTGGCG

GTGGTGCAGTACAGCGGCACGGGCCAGCAGCGCCCAGAGCGGGCGTCGCTGCAGTTCCTGCAGAACTACACGGCCCTGGCCAGTG

CCGTCGATGCCATGGACTTTATCAACGACGCCACCGACGTCAACGATGCCCTGGGCTATGTGACCCGCTTCTACCGCGAGGCCTC

GTCCGGCGCTGCCAAGAAGAGGCTGCTGCTCTTCTCAGATGGCAACTCGCAGGGCGCCACGCCCGCTGCCATCGAGAAGGCCGTG

CAGGAAGCCCAGCGGGCAGGCATCGAGATCTTCGTGGTGGTCGTGGGCCGCCAGGTGAATGAGCCCCACATCCGCGTCCTGGTCA

CCGGCAAGACGGCCGAGTACGACGTGGCCTACGGCGAGAGCCACCTGTTCCGTGTCCCCAGCTACCAGGCCCTGCTCCGCGGTGT

CTTCCACCAGACAGTCTCCAGGAAGGTGGCGCTGGGCTAGCCCACCCTGCACGCCGGCACCAAACCCTGTCCTCCCACCCCTCCC

CACTCATCACTAAACAGAGTAAAATGTGATGCGAATTTTCCCGACCAACCTGATTCGCTAGATTTTTTTTAAGGAAAAGCTTGGA

AAGCCAGGACACAACGCTGCTGCCTGCTTTGTGCAGGGTCCTCCGGGGCTCAGCCCTGAGTTGGCATCACCTGCGCAGGGCCCTC

TGGGGCTCAGCCCTGAGCTAGTGTCACCTGCACAGGGCCCTCTGAGGCTCAGCCCTGAGCTGGCGTCACCTGTGCAGGGCCCTCT

GGGGCTCAGCCCTGAGCTGGCCTCACCTGGGTTCCCCACCCCGGGCTCTCCTGCCCTGCCCTCCTGCCCGCCCTCCCTCCTGCCT

GCGCAGCTCCTTCCCTAGGCACCTCTGTGCTGCATCCCACCAGCCTGAGCAAGACGCCCTCTCGGGGCCTGTGCCGCACTAGCCT

CCCTCTCCTCTGTCCCCATAGCTGGTTTTTCCCACCAATCCTCACCTAACAGTTACTTTACAATTAAACTCAAAGCAAGCTCTTC

TCCTCAGCTTGGGGCAGCCATTGGCCTCTGTCTCGTTTTGGGAAACCAAGGTCAGGAGGCCGTTGCAGACATAAATCTCGGCGAC

TCGGCCCCGTCTCCTGAGGGTCCTGCTGGTGACCGGCCTGGACCTTGGCCCTACAGCCCTGGAGGCCGCTGCTGACCAGCACTGA

CCCCGACCTCAGAGAGTACTCGCAGGGGCGCTGGCTGCACTCAAGACCCTCGAGATTAACGGTGCTAACCCCGTCTGCTCCTCCC

TCCCGCAGAGACTGGGGCCTGGACTGGACATGAGAGCCCCTTGGTGCCACAGAGGGCTGTGTCTTACTAGAAACAACGCAAACCT

CTCCTTCCTCAGAATAGTGATGTGTTCGACGTTTTATCAAAGGCCCCCTTTCTATGTTCATGTTAGTTTTGCTCCTTCTGTGTTT

TTTTCTGAACCATATCCATGTTGCTGACTTTTCCAAATAAAGGTTTTCACTCCTCTCCCTGTGGTTATCTTCCCCACAAAGTAAA

ATCCTGCCGTGTGCCCCAAAGGAGCAGTCACAGGAGGTTGGGGGGCGTGTGCGTGCGTGCTCACTCCCAACCCCCATCACCACCA

GTCCCAGGCCAGAACCAGGGCTGCCCTTGGCTACAGCTGTCCATCCATGCCCCTTATCTGCGTCTGCGTCGGTGACATGGAGACC

ATGCTGCACCTGTGGACAGAGAGGAGCTGAGAAGGCAACACCCTGGGCTTTGGGGTCGGGAGCAGATCAGGCCTCAGTGGGCTGG

GGCCGGCCACATCCACCGAGGTCAACCACAGAGGCCGGCCACAGGTTCTAGGCTTGGTACTGAAATACCCCTGGGAGCTCGGAAG

GGGAGTTGAGATACTGCAGGGCCCATAGGAAGAAGTCTTGGGAGGCTCCACCTTTGGGGCAGAGGAAGAAGTCTTGGGAGGCTCC

ACCTTTGGGGCAGAGCAAGAAGAGGGCGGAGGGCAGAGGCAGCGAGGGCTCATCCTCAAAAGAAAGAAGTTAGTGGCCCCTGAAT

CCCAGAATCCGGGGTGCACGGCTGTTCTGGGGGCCGCTAGGGGACTAAGAGGATCGGCCGAGGGCTGGGCTGGAGGAGGGCAGCA

GGGATGGGCGGCGAGGGTGAGGGTGGGGCTTCCTGAAGGCCTTCACCTGCGGGGACCCCGGCGAGCCCCTCAGGTGCCACAGGCA

GGGACACGCCTCGCTCGATGCGTCACACCATGTGGCCACCAGAGCTGCGGGAAAATGCTGGGGACCCTGCATTTCCGTTTCAGGT

GGCGAACAAGCGCCCCTCACAGAACTGCAGGTAGAGACGGGCCCGGGGCAGACGCAGTGAGGCGGTGGGCGGGGCCCGGGGCAGA

TGCAGTGAGGCGGTGGGCGGGGCCCGGGGCAGAGGCAGCGAGCGGTGGGCGGGGCCCGGGGCAGACGCAGTGAGGCGGTGGGCGG

GGCCCGGGGCAGAGGCAGCGGGTGGTGGCCGGGGCCCGGGGCAGACGCAGTGAGGCGGTGGGCGGGGCCCGGGGTAGTCGCAGTA

GGTGGTGGGCGGGGCCCGGGGCAGACGCAGTGAGGTGGTGGGCGGGGCCCGGGGCAGACGCAGTGAGGCGGTGGGAGGGGCCCGG

GGCAGACGCAGTGAGGCGGTGGGCGGGGCCCGGGTCAGAGGCAACGGGTGGTGGGCGGGGCCCGGGGCAGACGCAGTGAGGCGGT

GGGCGGGGCCCGGGGCAGATGCAGTGAGGCGGTGGGCGGGGCCCGGGGCAGATGCAGTGAGGCGGTGGGAGGGGCCCGGGGCAGA

CGCAGTGAGGCGGTGGGCGGGGCCCGGGGCAGACGCAGTGAGGCGGTGGGCGGGGCCCGGGGCAGACGCAGTGAGGCAGTTGCCA

GCCTCTCTCAGCTGCCTCATGGGATTCGCACTGCAGCTGCGGCCCTGGCGCGACAAGGGCTGGACTTGGCCAGCGGGACGGTCCC

TCACGGCGCTGAGGCCCACACTCTGCGTGGAGCCTCCCCGTGCCCAGGCTACCCTGCAAGGTCCTCGGAGAGGCTTCCTCCAGCC

CCAGCCCCCACACAGCTCCGGCCCAGGCCCGCTCTTCCCCATCCCAGTTGCTTTGCGCTGTATACGGCCAGGTGACCCCGAGCCG

GCCCTGAGCCCTCGTCCCGGCTTCCTCCCCTGTAAGCTGGGTGAAGGACTCCATGGCACCCACCTGAGAGGGTTGTGGCGAGGCC

CAGGCCCCTCGTGCCCACACGGCCGGCGGCCCATGCCTGGCAGGGGCTGGGAGGAGGCTGGGGCGACCAGAGGGGAGCGGCCTGT

CCTGGAGGAGGCCCAGGGACCCTGGTGAGAGGGTCTCTCCCAAGTGCTCTCTATGGGACCCCCTTCCTCTGCGCCCGTCCTTCAC

GGACCTCTCCGGGTCACCCCTGGGCTGCACACTGGGTTCAGGGGGGCCTTGAGGTGGGGCCCCTGTTCCCAAGTCCCGGCGGGGT

TTCTCCTGAACCTCAACCCATCCTCACCTGCGGGCATTCCCATCCCCCAACGCCTGGGTCACCAGGATTCCAGGCAGGAGGGGCG

GTGGGGGTTACCAAGGCCCGGGTTGCCATGCAGAACCCCCAGCCACCACGCAGACCCCCACGGGGCCCAGGGAAGCTCCTGGTCT

CACACTGCACCTCACACTTCCTGTGGGGGCAGACTCCAAGGTCCCGGCCTCTCATCTTGTAGAAACTGAGGCACAGGAGGGACAC

ACACTCCCACGGCCGGTCACCGTGGCCCCCACACCTCCCACTGGACTGACACCTGGCCAGGCTCCGGACACCCGTGGCACAGCCT

CAGCCCCTGCGGCCCCTGCTCCGTGGCCCCCAGGCCCCAGCTCCCATGTGCACGTCCTGCCTCAGGCCTGGAGGCCCCTCGGCCC

CAAATAATCAGACAATTCAACAGCAAAACTACTTTTTTCAGGCTGGCAGGACTCTGGGCAACCCCCTGCAACAGCCCCCTGCCCT

ATCACAGCCACCCTTGCCTCCCAGGCACGGAGACCCCACCATCAGGTCCCAGCCTTGGTTCATCCCCAAGCACCCTGTGTGTTGG

GATGGCGATGCTGGCTGAGCCCCTGCATCC

253
chr21:
AGGGCGTTTGGGAACACCCCTCCCGGAGGGGTGAGGCGGCCCAGCCTGCGGCTGCCAGAGGACACAGGTTCTGCTGCGGAACCTG

46280500-
CAGACATGGCCATAACAGGCCACAGTGCTCGGGCCCACACAGCCTGGACCCACATGGCCCTGTGTCACCTCCTCAGGGGCAGGCT

46283000
TCAGGGCCTCGACCCTAGAGGCTGCCCCTCGGTTCTGCTCCATGGACGGCGCAGGCAGGCCCAGGCCTGTGACGAGTTCACGGAA

GCTCCAGGATGACCCCCGCTCTGCGCCCTCCTCCAGCATTCCAGACCACAAACCACTCTGGGCTAAAACGAGGCATCGCCAGAGC

ATCCCACTTCCTCGGAAAGCTGCGGTCTGGGGACGCGTCTTGGCCCTGAAGAGGCTCCAGATGGCTCCCATCAGGCCTCTCCGCC

TACGTGCGGCCGACATGGAGTGACAGAGCGTCGGGGACACAGAATTCAGAGCTGGGCCTGGGGCTGCTTTGAGATACTGATGGCT

GCCAGGGGGCACAGAGACCCGTCCTGCAGACAGGGCTGTGAGGGCCACAGGGGGCCTCGGGGAGAGGCAGTGGGAGGGAGGACAG

TGGGGGCCTCCAGCTGGGTGAGCAGCTGGAGCGAGGGGGGCCCGGGGCTTGTGATGGTGCTGCCGACCCTAGAGGTGCCGGCCCC

ACGATGGAGAGCACGTAGTGCCCCCCGGGAGTCAGGAGGCCGGGCCTGACCTCGGGGGCTGCAGCCAGGGGAGGCCGGCACCCCA

GATAACCCCCAAAGAACTGCAGGCCCTGAGGCGAGGCCAGAGTGGGGGCGGGGGCAGGTCCCAGCCGAGGAGGTGCTCCGTGCTG

CCTCAGCAGAACCCATGATGGGCTGGCCCAAGGCTCTGAAGGTGGAAAGGCCTCACACATTCTGCCCCGGCTGACGCCTTCCTTG

GGCCAGTGCTCGGGGGTGTGTAACAAACGCCAAGACGCATTGTAAAGAAGGAAGCCTGCGTTTCCATCACCGGCTTAATATCAAA

CAAAAGTGCAATTTTGAAAATGTAGTCCAAGGTTTTCTGTGGTGCGGAAATGGCCAGGCCAGACCTCCGTGGGTGGTCCTTCGTG

TCCACGTCAGCGCCCTACATCCACACTGTGGGCACCATGACCTCACATGCGGAGCGGAGCAGGGCCGGCGCCCGGAGAGCCAGGC

TGGTCACGAACGAGGCCTAGAGGGCGTCAGGCCCCAAAGCACTCACAGGCTTCTCCTCTGTCCTCGGGGCCTTCAGACACCTGCA

TGCGCCGATTCAGCCACCCGCGCGCGCCGATTCCCCTGGCCATGGGGTTTCCAAAGTGTGTGCTCAGAGGACAGTTTCCTCCAGG

ATGACCTGTCAGTGGCTCTCTGTGCCGGGGACGTCGCGTGCTGGGTCCCGGTCTGAATGCTTCCTAACGATTTACCCAGTTCCTT

TTCTCCACTCAGGAGGCGTTTGCTGAGAGGCACAGGCTGAGCCCCCGTGCTGATGCCACGACCGAGGGAACGGGTCTCCCTGTCG

GCGTGAACTGACCCGGCCAGGCGTCCACTGCCACTCGGACTGTCTCCCAGGCACGTGGCGCCCACACGGGCAGAACACGCCCTCC

ACACACGCGGCTTCGGGCAGAACACGAGGCGCCCTCCACACACGCGGCTTCGGGGCTTGTCATGAAAAAAGCTGAATGCTGGGGG

TGCAGCTTTCACCAACAGAATCCCGTTTGGAAGGGACGCGGTGAGACATGATCCACCCTAAGTTGTGATCCTGGGTGAGCCGCCG

TCCACACCCTGCTGAGGGTCCCTTCACCCACTTTATTCTCCAGAAAACCCTGCCCATCAGGGCTGAGTCCCACGCCTTCCCTCTC

CGTCCAGGCCTGGCTTTGACCTCTGGGGTCGTGTGGGGCACAGGGGACACCCTATCCAGGCAGAGGCCCTACGGCTATCTGGAGG

AAGTGGTGGGAGCTGGGCTTCTGCCTGGAGGATGCACCCAGAGGGGTCACAGTCCACACAGAGACACACGGGTGCCTTCCAGATG

GCTGAGCCAGTCCAGCCCAGAAGGGCCTGGGGGTTGGGGGCTGCACCTGGCCTGTCCCCACCAGCAGGGCTCAGGGCTTCCCAAG

GTGTGTGGGGGACGGGGCAGCACCTCTCAACCAGGTCACCTGAAACCCGAACTGAAAGGCATCCTAAGTTAAGACATTAACTCCC

ATTGTCAAGGTGCCATCGTCAATTCTGTCTCCAAATCCTTCTTTGTTATTTCATGTATTCACAGAGTGACGCTCCGTGTTTCGTT

CAGCCTGCAGGCCTGCAGAAGCTGCATCTCGGGATGGCCAAGAGCCCGGCCAGGCCCCACGGCTGCACCCAGGACGGGATTCATG

CCCCATGCCTGGCTTCTCACGACCACAGAGTGCCTTTCCCGGGACTGGATGGAGGCAGAGTGAGAGAAGAGCCTGGAGCAAGTGT

TTTGGACCACAGTGATCAAACACGGAGCCCGTGGG

254
COL6A2
AAGAAAGGCCAGACCGGGCACGGTGGCTCACGCCTGTAATCCCAACACTTGGGGAGGCCGAGGCGGGCAGATCACCTGAGGTCAG

GAGTTCGAGACCAGCCTGGCCAACAGGGTGAAACCCCGTCTCTACTAAAAATACAAAAAAAAATTAGCCGGGCGTGGTGGCAGGC

ACCTGTAATCCCAGCTAATCGGGAGGCTGAGGCAGGAGAAAATCACTTGAACCTGGGAGGCGGAGGCTGCAGTGAGCTGAGATCG

CGCCACTGCACTCCAGCCTGGGTGAGGGAGCGAGACTGTCTCAAAAAAAAAAAAAAAAAAAAAAAAAAAGGAAAGAAAGGCCCGG

TGAGATGCTTTCTCTTAAACACGGCCCTGCACGTTGAGTTGCTGCCTCCTGTGGCCTATTTCACGTTTATGCAAAGTCGGGCGCC

TGATGCGGGGCTCACCCGCCACAAGCAGGGGTCCTGGTGCTGCTCATGGAAGGGGCCCTACCCAGCCCGCGGGGCACTGGCTGGG

ACGGGGCTGCCCAGGTCCGCCCAGGATCCAAACACCCAGCCCCGCCCAGCGGCCCTTCCTGGCCTGCAGTGGAGGCTGTAATGGG

CAGGGGTGGTGGGAATCCCAGCTCACAGGGCGCCTGCTCTTAGAAGGGCGGCATCTGGGTCCAGAGGTCAGAAACGTCAGATGCC

CATCCCAGAAGTGGCGGGGA

255
COL6A2
GGGTGAATGAGTAGATGTATGGGTGAGTAGGTGGGTAGGTGGGTAGATGGATGGGTGGGTGGGCGAGTGTGTGGTTAGATGATGG

ATGGCTGAATGGATGAGTGGGGGGATGGATGGGTGAGTGGGTGTATGTATGGATGGGTTAGTGGGTGGGTGGATGAATGGATGGG

TGCATAAAGGATGGATGGATGAATGAGTTAGTGGGTTGGCAGATGGATGGATGGGTGAGTCAGTGGATAGATGGATGGGTGGGTG

GATAGAGGATGGATGGTTGGGTAGGTGATGGGTGGATGAGTGGATAGATGGGTATGTGAGTGAGTGGGGGGATGGGTAGGTGGGT

GGATGGATGGTTAGGTGAATGAGTGGATGGACAGACGGACAGTGGGTGGATGGATGAGTGAACGGATGGACCGATGGATGAATGG

GTGGGTGGGTAGAGGATGGACGGACAGGTGAGTGGGTGGGTGGATGGATAGATGGGTAAGTGAGTGGATAGATAGATGGGTGGGT

GGACAGAGGATGGGTGGATGAATGGATGGGTTAGTGGGTGGCTGGGTGGATGGATGATGGATGGGTGACTGGGTGGATGGATGGA

TGGGTTAGTGGGTGGCTGGGTGGATAGATGGATGGGTGATTGGGCGAATGGGCGAATGGGTGGATGGGTGGGCGTGGAGTTGGTG

GGTACATGATAATGGGGTGGAATACCCATGGATTGGAATGAGCTGTTTTGGCTGCTATTTCTGGGACACCCAGCTCTGCCAGGCC

CCTACCCCTCTGGTGGGCCAGGCTCTGACGGTGGCCACTCATGGCCTTTCTAGCTCTGGTGCCAGCATAGGGAAGGAGGAGGCAC

AGCCTTGTCTTACTCCTTGCACCTGTTAGCCCCCCCCCCCGCCAAGGGAGGACCCGTGGTTGGGGACAGCACAGGGGGCCCTGCT

GTGTGCAGGGACTGTCCCTGGGGCCACTGAAGCCCACCTGTTCTTGTTCCTTCTCAGGCGGATCCTGGTCCCCCTGGTGAGCCAG

GCCCTCGGGGGCCAAGAGGAGTCCCAGGACCCGAGGTAGGTTGGTGGCCAGTCCCCATGCCCTCCCCCCAACCTGCCAGGCCAAC

ACACACCCAAGCCTCGTGGTTCTGCCCACGGTGGACCCACGTATCAGTGGGCAGTGGCCTGGGAGAGACTCAGCCACCCAGCCTT

GGCCCCAGAGTCTCAGCCTCATCCTTCCTTCCCCAGGGTGAGCCCGGCCCCCCTGGAGACCCCGGTCTCACGGTAGGTGTCACAT

GGGGCAGAACCAGTGTCCTTCTCCTGCCAAAACTAGACACCAAGAGCAGCAGGGGTGGGGGAAGGTCAGCTGGCACGGTCAGAGA

GCAAGATCAGTGGAGGAGGTCAGAGGGCAAGGTCAGAGAGCAAGCTTGGTTGGGGAAGGTCACAGGGCAAGGTTGGTGGGGGGAG

GAGGGTGGCAGCGAGGTTGGTAGGGACAGGACCCGCCAGCCTCCCCGCATGGCTGCCTCCACACGTGGGCTGGAATGTCCCGGGA

CCCCCAGGCCAGGACCTTGCTGTGGAAACTCTTCTGGGGCCCCGGGGGGACTACCCTGCCTGCCGTGTGCATTGCAGGAGTGTGA

CGTCATGACCTACGTGAGGGAGACCTGCGGGTGCTGCGGTGAGGCACTGCCCACGGCAGGGTCGGGGCCCATGCACCGGGTGGAG

GGCGGGAGTGCAGCAGGGCTGGGTCATCGCTGGGTCCTGCATGTGCACGTGACCCTAGGGTCTGAGGTCTCCCCGGTACCCCCCG

ATGACCCTGCCACCCCCCCAGACTGTGAGAAGCGCTGTGGCGCCCTGGACGTGGTCTTCGTCATCGACAGCTCCGAGAGCATTGG

GTACACCAACTTCACACTGGAGAAGAACTTCGTCATCAACGTGGTCAACAGGCTGGGTGCCATCGCTAAGGACCCCAAGTCCGAG

ACAGGTCAGCGGGGCAGGGGCGGGTGCAGCATTGCGGGGGGCCGGGCGGGGCGTGGGAGGCGATGAGATGGGAGAAGTCCAGACG

CGTCCCTCCAACGAGGGCCTCTGCATGGCTGGGGATGCCCCAGACCCCGAGGCCTCTGGCAACGACCTCACGCGTGCGGCTTGCA

GGGACGCGTGTGGGCGTGGTGCAGTACAGCCACGAGGGCACCTTTGAGGCCATCCAGCTGGACGACGAACGTATCGACTCCCTGT

CGAGCTTCAAGGAGGCTGTCAAGAACCTCGAGTGGATTGCGGGCGGCACCTGGACACCCTCAGCCCTCAAGTTTGCCTACGACCG

CCTCATCAAGGAGAGCCGGCGCCAGAAGACACGTGTGTTTGCGGTGGTCATCACGGACGGGCGCCACGACCCTCGGGACGATGAC

CTCAACTTGCGGGCGCTGTGCGACCGCGACGTCACAGTGACGGCCATCGGCATCGGGGACATGTTCCACGAGAAGCACGAGAGTG

AAAACCTCTACTCCATCGCCTGCGACAAGCCACAGCAGGTGCGCAACATGACGCTGTTCTCCGACCTGGTCGCTGAGAAGTTCAT

CGATGACATGGAGGACGTCCTCTGCCCGGGTGAGCGTGTGGGCGCGGGGCAGTCGGCCGAGGAGCAGCAGGCCCCAGCCGCTGTC

TAGCGTGAGCCCCAGGGACACCCCTCACCTGAGGGATGAATGTGCAGCCCAGGATCTTGGGCTGTGGGTGGGAAGGGGTCGGGCC

CTCTCGGGGCTGCAGGGCAGAGGCCAGCTGCACCCTGAGCCTGTCTAGGCAGATCAGTGAACGGCCGCTGAGGGTTCGCTAGGGA

CTGACCCTGGCCTGGCCCGGCCTCTCTCCTCTCTTCCAGACCCTCAGATCGTGTGCCCAGACCTTCCCTGCCAAACAGGTAATGC

AGGGCACCCTGAGCCACCACCCCAGACTAGCAAAGCAGCCCTGGTGTCCTTCCTCCTCGAGGGCCGGGCTGGGGGAGGGGCCGTG

CAGGGACCCGGGGGGCGGCGGAGCCACTGCGGAGGCTGCTCCTTAGGGAGATGGCCCCAGGATGGCAGCACAGGGGAGGAGGGGC

TTGGGGAAGGCAGGCTCCCAGGAACGCAGGAACAGCATCACGAGGCCATGAGGTGGGTGCTGCTAGCCTGGCGCTGTGCTCGGCA

TGTGGCCACTGGTCTTGAAGGCCCACCATGGGCCTTGCAGTCTCCCTCAGCTGCCGCCCAGCTCCCATGGGCTGGCCGTGCATGT

GCCACTCGGAGGAAGCCCTGGATTCAGTGAGTGAAACCATCCCGGGGTGGAAGCACTGACACCCCCCAGCACCAGCAGGTCTTGC

TCCAACCCTGGCCTGCCTCGGAGCTGCAGCTGCGGCTCTCACATCTCTGGGAGTGGGGGAGCCCATGTCCCGGATGTGGCCCACG

TGGGTGTGAAGCTGGAGCTGGGGGTGCCGTCCAGGCTCTGCTGGACGTGGTGCTGCCCCCATGGTGCACTGCTGCACCGTACCTG

GGCCCACAGGAGGTCCCCGGGGGCGTTAGGAGCTGAGTCCCCCTCAGTGAGCCGTCCCCTCCAGGAGTGTGAGGGTAGGGATGCC

ATGGAGACAGGGTGGGAGGGTCCGACCTGGAGGACCACAGGGAGGAAACCTCAGGGTCTGCGGTACGAAGTCAGCGCTTCCTCAG

CACGCGGGTCGCGGTGTGCGTTCGGGCGTTCCATGGGGAGCTCCCGGTGGGTGAGCTGGGCCACTGAGCACATTCACAGGCCCTG

AGGCTGCCCCAGGGGAGGAGCCGTGGACTCAGAGCCGAGGTTCCCCATACGTGCTGCGACAGAGAACCTAGGGCTTGCACCTGGG

TCTGGCTGCCCTTCAGCAGGCGGGCAGCCTCTGGCCCCACAACAGTGGGCTGTGCTTCTGCCGCCAAGGTGCAGGCGTCCTCCCC

CAGGGTCCACATCAGCAGCAGGGGCACCTGGACCCTGAGGGCAGGAACCAGACCTTGGCTCCTCCACCCACCCCCTCGTTCCTGA

TGGGGCAGGGAAGTCTCGGGACCCCATGATGGGCGACATGGCGATGGTCACTGTGGGTGCTTTGCTATCAGGTGGGGGGCCTTCC

TCTCCACTCTGGGTCCAGTGTGAGTGGCCGCTATGGCTTCCCCTCCACTCCAGGTTCTATCGTGAGTGGGTGGGTGCTGCGTCTG

TGGATGTCACGTGACCTTTCCTCTTTAGCCTATCATTGTAGTTGGGAGTTAGTTAGCCCGTTGAGCGTCATTGAATTTCCAGTGT

TGAGCCAGCCCTGCGTGCCCGGGATAAACCCACCTGGCCGTGGTGTGTGGCCCTGTTTATGCACGTGGGCCCTGATTCGCTGATG

CCTGCCTGAGGGTTTGCGCTTATCGGCGACATCAGCCTGCACTTTTCTTTTCTCGTGATCTCTCTGGTTCTGGCCTCAGGGTGAC

GTGGGCCTCGTAGGGTCCTGTGGTGGCTCCTCCCCAGACGGTGACATGGAGTGAGCCCATTCTCCCTCCTGGGAGTGGGTCACTC

AGGCCACCAGAGCACCACAGGGAAAGCAGCCAGGGAGGACACGGAGGCCCTTGAAGCTCTGGCCTCTTCTGAGGCCTCCAGGACC

TGACAGTGAGTGGGAGCAGCCCTGGCAGAACCCCTCCCCTCCTCTCGGCCGCCCTGACACCTCATCCCCGACACTCAGAGCTCAT

CCTCCTTCCCAGCTGTTTCCAATTTCAAAGTGAACTCGACCTTGTGGCTCCAGGAGATGCAGCAGGGACAGTGTTAAATCGGCTT

TCACCAGCCCACACGGCCAGGCATCCTCCTCGGCCCTCCTGGGCACTGGGTGGACACCACTGGCTGTGGCCTGGCCCTGGCCTTC

TCCAGACAGCCCTGTCCACCCCAAAGCCCAGCCACCCTGGGCCTGCAGCAGGCCTGTGGAGTTCTCAGTTGCGTGGGGACCAGAG

GGTGCTGGAGAAACAAACCAGACGCAGCTGAAGGCAGTCAGGGCAGGGCGCAATCAGCGATAAGAGCTGCATAGGGGCCACAGCG

TAACCTGAGCTCCAGTCGGTGGAAAGAAAAGGCAGAGACGTTGCAGAGGCCAGGTCTGCTCAGGGGAAGACAGTTCTGGGTGTAG

AGGACTCACATCCCAGAGAGGCTGAGGAAGGGTTTACCACCGCAAGCTTTCTCAGGCGGGCTCTTGAGGGGTGGCTGGGGTCTTC

CTGGCGACGGGCCTGCGGCACTGGAAGCCCTACTGGAGTTTGGCCTGTCTCCGGCACAGGTTTGGACGGAGCTGTTTTGTGCTGA

AAGGTTTTCTCGGGGTCCGTGGTGTCCCCCAAAGGTGCCACCGTGCGGGTCTCCTAGCTCCCTGCCAGCTTCCTGTCCCTGTGCT

CACTGCCCCCACGCCTCCTGCCAAGGCCGAGCCACACACCCGCTCCACCTGCATTTCCTCTACCGACTCGCCAGCCCAAATGCCG

CTCTTCACTCTGGCCTCGCTGAGCGGCTGCCCGAGGAGGAGCTCTAGGCCGACGCCCACCGCAGGCCTTACAGTCTTCTCTGGAC

GCTCCCTTGCAGATGCACCGTGGCCTGGCGGCGAGCCCCCGGTCACCTTCCTCCGCACGGAAGAGGGGCCGGACGCCACCTTCCC

CAGGACCATTCCCCTGATCCAACAGTTGCTAAACGCCACGGAGCTCACGCAGGACCCGGCCGCCTACTCCCAGCTGGTGGCCGTG

CTGGTCTACACCGCCGAGCGGGCCAAGTTCGCCACCGGGGTAGAGCGGCAGGACTGGATGGAGCTGTTCATTGACACCTTTAAGC

TGGTGCACAGGGACATCGTGGGGGACCCCGAGACCGCGCTGGCCCTCTGCTAAAGCCCGGGCACCCGCCCAGCCGGGCTGGGCCC

TCCCTGCCACACTAGCTTCCCAGGGCTGCCCCCGACAGGCTGGCTCTCAGTGGAGGCCAGAGATCTGGAATCGGGGTCAGCGGGG

CTACAGTCCTTCCAGGGGCTCTGGGGCAGCTCCCAGCCTCTTCCCATGCTGGTGGCCACCGTGTCCCTTGCTGCGGCTGCATCTT

CCAGTCTCTCCTCCGTCTTCCTGTGGCCGCTCTCTTTATAAGAACCCTGGTCATTGAATTTAAGGCCCACCCCAAGTCCAGAATG

ACCTCGCAAGACCCTTAACTCACTCCCGTCTGCAGAGTCCTTCTTTGCTGCATCAGGTCACCCTCACAGGCTCCAGGGTTTGGGT

GTGGAAGTCTTTGGAGGCCCTTACTTAGCGGCCCAGCTGGGCTGCCGTGCGTCTGGGATGGGGCTGAGGGAGGGTGCTGCCCAGG

TGCTGGAGGATGTTCCAGCACCAGGTTCCAGCGGAGCCTCGGAAACAGGCCCCAGAGGCTGGTGAGCCTCGCTGGGTGTGGGCAC

TAATCCCGTGCATGGTGACTCGTGGGCGCTCACGGCCCACCTGGTGGCAGGTGAAGGCTTCCGGTTGGGCAGCAGATAGTCCTGG

GGGAAGCTGGCAGTCCTGGCACCATGACGTATCTGGGCTGGTGTCATGCACAGTAGGGCGAATGGCCACAGCTGCCTGCCAGCAG

CCCTGATCCCGGGGTGTCTGCACCCTTCCAGCCCAACCTCTGGGTCTCCAAAAGCACAGTCGGGGGAGCATCCACCAGGCACAAC

CTCTGCGGTCCTCAGAGGACTGAGCAGAGAATCCCAGGGTCCACAATGTTGGGGAGCGGCAGGGATCACCATCCAAAGGGAGCGG

CCCCCACGGCGAGCTGACCCCGACGTTCTGACTGCAGGAGCCCTCATCCAGGCTGGGCTCCTGCCGGGCACGGCTGTGACCATTT

CTCAGGGCCAGGTTCTCGTCCCCACACCCACTGCACAGGGCAGGCCAGGCTGGTCTTCCCACTGTGGGGATGAAGGATCCTCCAC

AGGAGGAGGAGAGCAGAGTCCACAGACATCCCAACAGCCTCAGCCTCCCTGTGCCTGGCCGGCCCCCACAGCTTCCCCGTCTCCT

CCAGGCCCCACAGACACTGATGAATGGACAGAGACCCCCAAAACCAGCTGCCCCTTGCATGTCTGTCTCCATATGTTTGGTGACA

GCAGTGAAAATGTTATTAGTTTTGAGGGGGTTTGGGAAGCCCAGCGGTACCTGAGGAGTTTCTGGACATTTAAGCCGGTTCCTAG

GTGTGGCCTTAACAGGGAGGCTGCCCTTCCTTTCACTGAATGAGCTGCGTCACTCATAAGCTCACTGAGGGAACCCCATCTGCCA

GCTCGTGCGTGCTCAGACGGCGTCCATGTCTCAAGCGTTCTGTGAAGGCTGCGGTGCAGCGTGAGGTCACCCTGCTGTGTTCAGA

GCTTTGCTCACTGCCTGCGGGGCTGGACCGTTGCACCTCCAGGGCCCCCAGAAACCGAGTTTCGGGTCAGGGTCCTCTGTGTGCA

TTCCTGGGGGTCCATGTACCAGCTGTGACGACGTCCAGGGGTTGGGCTGAGAAGCAGACACCCTTGGGGAAACTGGCTCTGTCCC

TCCCCTCCCCCATCCCAGGAGCTGAGGTCTTGGTGAGGCCACAGGGCCAGGTCCACGCAAGGACTGTCCGTGTCCTGTCCTGTGG

TCTCTGGCCCCACGTGACACCCACACGTGTGGTAGGCAGCCTGGCCTGGGTTGTGGCTATGGCCAGGCCCCCAAGCTGTCCCCGA

TGCCCAGGGCTGGTGACCACCCAGGCAGGTGGGGGCCCCACTTGGTAACAGAGTCATAGGGCAGAACCCACCTGGGCTGCCACAG

AAGGTCTGGCTGCCCCTGTGCCCACTGCTCCCCACCATGGCCAATCAGAAGAGTCAGGGGCTCCTGGTCTTTCCGGGAGGGACGT

GGCCCAGCCAGCTCTAGGTGTTCTGAGCAGCTCTGGGACCCAGCGATTGAGGGGTCAGGCTGGGGGTGTCAGAGCCAGGGTCCTC

CTTAAGTACCTCCCACACTACACAGACAGTGGCCCTTTTGTGGGCAGCAAATTCTTGAGCCATGAAAGGATGCTTTGGGCCCCTT

CCCTCCCAGGAGGGCAGCCTGTGCAGGGATGGTGCTCAGCAGGTGGACAGGGCCTGGGGCCTGTGTCAGGGTCTCAGGCCTGGGA

GCACCAGCAGAGGAGATGGCGGCTCCCAGCAGTGCCGCCTGAAAGTGTCTTGGGCTAAGGACCCACACCCAGGGCTGCCCTGCAG

AAACGCCCCCGCAGAGCCCAGTGGTCTGTGAGGTTGCAGGCAGGGTGCGAATGGAAGGGCACAGGTGCGGGGCTGGCACCTGCCC

GGTCCTGCCCACCTCCCCTCCGCCCAGCCCGCACCTGCGTCTCCCCACAGAGCTGTCCGTGGCACAGTGCACGCAGCGGCCCGTG

GACATCGTCTTCCTGCTGGACGGCTCCGAGCGGCTGGGTGAGCAGAACTTCCACAAGGCCCGGCGCTTCGTGGAGCAGGTGGCGC

GGCGGCTGACGCTGGCCCGGAGGGACGACGACCCTCTCAACGCACGCGTGGCGCTGCTGCAGTTTGGTGGCCCCGGCGAGCAGCA

GGTGGCCTTCCCGCTGAGCCACAACCTCACGGCCATCCACGAGGCGCTGGAGACCACACAATACCTGAACTCCTTCTCGCACGTG

GGCGCAGGCGTGGTGCACGCCATCAATGCCATCGTGCGCAGCCCGCGTGGCGGGGCCCGGAGGCACGCAGAGCTGTCCTTCGTGT

TCCTCACGGACGGCGTCACGGGCAACGACAGTCTGCACGAGTCGGCGCACTCCATGCGCAAGCAGAACGTGGTACCCACCGTGCT

GGCCTTGGGCAGCGACGTGGACATGGACGTGCTCACCACGCTCAGCCTGGGTGACCGCGCCGCCGTGTTCCACGAGAAGGACTAT

GACAGCCTGGCGCAACCCGGCTTCTTCGACCGCTTCATCCGCTGGATCTGCTAGCGCCGCCGCCCGGGCCCCGCAGTCGAGGGTC

GTGAGCCCACCCCGTCCATGGTGCTAAGCGGGCCCGGGTCCCACACGGCCAGCACCGCTGCTCACTCGGACGACGCCCTGGGCCT

GCACCTCTCCAGCTCCTCCCACGGGGTCCCCGTAGCCCCGGCCCCCGCCCAGCCCCAGGTCTCCCCAGGCCCTCCGCAGGCTGCC

CGGCCTCCCTCCCCCTGCAGCCATCCCAAGGCTCCTGACCTACCTGGCCCCTGAGCTCTGGAGCAAGCCCTGACCCAATAAAGGC

TTTGAACCCATTGCGTGCCTGCTTGCGAGCTTCTGTGCGCAGGAGAGACCTCAAAGGTGTCTTGTGGCCAGGAGGGAAACACTGC

AGCTGTCGCTCGCCCACCAGGGTCAATGGCTCCCCCGGGCCCAGCCCTGACCTCCTAGGACATCAACTGCAGGTGCTGGCTGACC

CCGCCTGTGCAGACCCCACAGCCTTGATCAGCAAACTCTCCCTCCAGCCCCAGCCAGGCCCAAAGTGCTCTAAGAAGTGTCACCA

TGGCTGAGGGTCTTCTGTGGGTGGACGCATGATTAACACTAGACGGGGAGACAGCAGGTGCTGAGCCTGTTGTGTTCTGTGTGGA

GATCTCAGTGAGTTTTTGCTGTTCAGACCCCAGGGTCCTTCAGGCTCAGCTCAGGAGCCCCACAGTGAACCAGAGGCTCCACAGG

CAGGTGCTGACCTGACAGGAGTGGGCTTGGTGGCCATCACAGGGCACCACAGACACAGCTTGAACAACTACCAGTATCGGCCACA

GGCCTGGAGGCATCAGCCGGGCCATGCTTCCTCTGGAGGGCTAGAGGAGGACTAGAGAAGGGCCTGCCCCGGCCTCTCCCCAGCA

TCCCAGGGTTCCTGATCTCCTGGATAAGGATACAAGTCACCACACTGGACTGGGGCTCAGCCTGCTCTAGAATACCTCACCTAAG

TCACAGTGGACCAGGCTCAGCCTGCTCTAAGGTGAGCTTACCCGAGACACTGGACCAGAGATCAGCCTATCCTGGGATAAGCTCA

CCCGAGTCACACTGGACCAGGGCTCAGCCTATTCCGGGATGAGCTCACCCGAGTC

256
C21orf56
GACACTTCCATGACTGCAGCTGACCAGTCCACCTGCCAGCGGTTGACCACTCCCACTTCGCCAGCGACCGAAGGGGAGGGGAGGG

GCCTCACCTGAGGGCAACAGCAGAACCCACCACCTGGTCTTGCTTTACTCAGACCTGAGGGTGTGAAAGGTGCCCGTGACCTCCC

GCATCAGGGAGCTGGCCGCCACCCTCGACTCCCGGGGAGCAGGCGTCCCGCGACCCCCTCATCTACCAGGCCATCTGAGCTGGGC

GGCGCCTCACCTCCGCTCCCGGGGGAGCCGGCCTCAGGGTAGGCATGCGCCCTGGGTGGGAGCAGGTCGTGGCCGCCGCCCTCCT

GGCAGCTCTGGCTGAGCAGCCGCCGCAGCATCTGATTCTCCTTCAGGAGGCGCACCTGCTTCTTCAGGTCCGCGTTCTCGCTCAG

GAGCCGGCTCATCAGCTCGCCGCCTTCAGCCATGGCGGGTGCGTCCCTCCTTGTCCCTCACGGCTCCTGCAGCCCCATGGAGGTG

GGAGCCCAGAGCCCGCAGGCACCACAGAAACAGCCCAGGCACGGAGTTCCGTAGCCACCACCGCCTTCCACGCCTTGTGATGTCA

CTGCCCTAGTGATGAGGTGCCCAGCACCCTGCCTGCCCCCGCGATGGCTCATGGCCCCGTTGAGGCAGTGAAGCTGGAGGCCCGT

GGCGTGCACAGGCAGCCACTCCCACATTATGACCAGGGCCCGAGAATGCCAAGGACATTAGGCAGCTACGGGATGTAGCGACTGT

ACTCCAAGAGGGGCGTCCAAGCCACTCCCCATTGA

257
C21orf57
AGGTGGAGGTTGCAGTGAGCCCTCCTCCCCTCCTCCCCCTTCCCTTCCCACCTCCCATGCCCCCCTTTCTTCCTCCCACTCCCCT

CCCGAGGCCCCGCTTATTCTCCCGGCCTGTGGCGGTTCGTGCACTCGCTGAGCTCAGGTTCTGGTGAAGGTGCCCGGAGCCGGGT

CCCGCCTTCGGCCTGAGCTAGAGCCGCGCGGGCGGCCGGCTTCCCCCAAACCCTGTGGGAGGGGCATCCCGAGGAGGCGACCCCA

GAGAGTGGGGCGCGGACACCTTCCCTGGGGAGGGCCAG

258
C21orf57
CCTTCCAGATGTTCCAGAAGGAGAAGGCGGTGCTGGACGAGCTGGGCCGACGCACGGGGACCCGGCTGCAGCCCCTGACCCGGGG

CCTCTTCGGAGGGAGCTGAGGGCCGCGTTCCTTCTGAAAGCGGGACGCGGGAGGGGTGGAGGCTGCGGGGAGCCGGGGTCGCACA

CGAATAAATAACGAATGAACGTACGAGGGGAACCTCCTCTTATTTCCTTCACGTTGCATCGGGTATTTTTCGTTATTGTAAATAA

AACGGTTCCGAGCCGTGGCATCGAGAGGGCGTCTGGAGTTCAGGGAACGCGTGGCCCCCGCCCGGGAGCACCGCGCAGCGCTCGC

CTCTCGCCCTTCAAGGGGGTCCCTGCCCGGAGCCTGCGCCCCCGGAGAGGAAGGGGCTCGAGGGGCTTGGGTGCCGCAGCGCGTC

CTTCCGTAGAAAAGGCTTGCGTCAGTATTTCCTGCTTTTACCTCCTGAG

259
C21orf57
CAGTATTTCCTGCTTTTACCTCCTGAGTATTGGAATATTCGAGTAAACCCTGGAGTTTCAGCGCCAGCGCACGCCTCTTCATCAG

GGCAGCGCGTCGCGAGCGCGCTGGTTCCCCGGGGCCTCCCGGCCACGGACACCGCTCTAGCCAGGGCCACGGCGAGGCCGCCGAG

CAGCACCTCAGAGACCTGCGTGAGTTCTAAAGCCTGGGGCTACTACAATTCTGCTCATCTGTTTGTCCTGTGAAATGATTCAGGG

ACATGAAAATGCCTTCCCACTGACTTGCGTCCTGTCTTAGCCTGGACTTGTCCCCTTGGGAACACGGGCCAGGCCCCTCTGTTCC

TGAAGT

260
C21orf58
ATGTCTGCAGGGAAGAAGCAGGGGGACCCTGAATAAAGTTTCCGTTTTTCCTATTTGTTAAAGTGATAGAGCATTATAGGACCAG

AGAACAGGTGTGTCTGTACACTGTGCAGGTCCCCGGGGCAGGCTCTGAGTCCGTCTGCACACGGTGCGGGTCCCCGGGGCGCGCC

CTGAGCCCGTCTGCACACGGTGCGGGTCCCCGGGGCGCGCCCTGAGCCCGTCTGCACACGGTGCGGGTCCCCGGGGCGCGCCCTG

AGCCCGTCTGCACACGGTGCGGGTCCCCGGGGCGCGCCCTGAGCCCGTCTGCACACGGTGCGGGTCCCCGGGGCGCGCCCTGAGC

CCGTCTGCACACGGTGCGGGTCCCCGGGGCGCGCCCTGAGCCCGTCTGTACACGGTGCGGGTCCCCGGGGCGCGCCCTGAGTCTC

TACTAAAAATACAAAAATTAGCCAGGCGTGGTGGTTCAAGCCTGTAATCCCAGCTCCTTGGGAGG

261
PRMT2
CATACATGGTTATTAGAAAAGGCATCTCATCCAAATGTGGTGGCTCGTGCTTGTAATCCCAGTGCTTCAGGAGGCCAAGGGAGGA

GGATTACTTGAGCCTAAGAGTTTGAGACCAGCCTGGGCAACACAACAAGACCTTGCCTCTACAAAAAACTTAAAAACTAGCTGGG

TATGATGGTGCACACCTGTAGTCCCAGCTACTTGGGAGGCGGAGGCGGGCAGATCGCCTGAGGTCAGGAGTTCGAGACCAGCCTG

GCCAACATGATGAAACCCCGTCTCTACTAAAAATACAAAAATTAGCCGAGTGTGGTGGTGCATGCCTGTAATCCCAGCTACTCAG

GAGGCTGAGGCAGGAGAATCACTTGAACCCGGGAGGCGGAGGTTGCCATGAGCCGAGATCACGTCACTGCACTCCAGCCTGGGTG

ACAGAGCACAAAAGACAGGCATGACTTTGTACTTAACTGCTCAGCTTTGTAATCACTGGGGGCCCAGATGCTCACTTGGATTCTA

ACTTTGTTGGCATCTGGGCCTAAAAGCCGTGATGCAGGTGAGCAATGATGCAGAGGGCTCTGTGCGCCTGGCGGGCTCTGTTTGC

CTGCTGGGCTCTGTGCGCCTGCTGGGCTCTGTGCGCCCGGGAAGGTGCGGCCACCCTCACGCGGAAGGCGGCCAGCGGATCCCGG

TGCGCGCAGCTCCCAGCGCTGGGGTTCCAGCGCCCCGCCTCTTCCTATAGCAACCAGCGGGACCTGCCGTCCCCCGGGGCACCCC

GAGGGGTCTGCGCCCGCTTCTTTCCGAAACGGGAAGGCGCTGGGGGCTCGGCAGCCAGAGGGACGGGTTCAGGGAGCGTCCGGTG

AGCCTAAGACGCGCCTTTGCCGGGGTTGCCGGGTGTCTGCCTCTCACTTAGGTATTAGGAACCGTGGCACAAATCTGTAGGTTTT

CCTCTGGGGGTGGGCGGAGGCTCCAAACCGGACGGTTTTCTCCTGGAGGACTGTGTTCAGACAGATACTGGTTTCCTTATCCGCA

GGTGTGCGCGGCGCTCGCAAGTGGTCAGCATAACGCCGGGCGAATTCGGAAAGCCCGTGCGTCCGTGGACGACCCACTTGGAAGG

AGTTGGGAGAAGTCCTTGTTCCCACGCGCGGACGCTTCCCTCCGTGTGTCCTTCGAGCCACAAAAAGCCCAGACCCTAACCCGCT

CCTTTCTCCCGCCGCGTCCATGCAGAACTCCGCCGTTCCTGGGAGGGGAAGCCCGCGAGGCGTCGGGAGAGGCACGTCCTCCGTG

AGCAAAGAGCTCCTCCGAGCGCGCGGCGGGGACGCTGGGCCGACAGGGGACCGCGGGGGCAGGGCGGAGAGGACCCGCCCTCGAG

TCGGCCCAGCCCTAACACTCAGGACCGCCTCCAGCCGGAGGTCTGCGCCCTTCTGAGGACCCTGCCTGGGGGAGCTTATTGCGGT

TCTTTTGCAAATACCCGCTGCGCTTGGACGGAGGAAGCGCCCACGCGTCGACCCCGGAAACGAAGGCCTCCCTGATGGGAACGCA

TGCGTCCAGGAGCCTTTATTTACTCTTAATTCTGCCCGATGCTTGTACGTGTGTGAAATGCTTCAGATGCTTTTGGGAGCGAGGT

GTTACATAAATCATGGAAATGCCTCCTGGTCTCACCACACCCAGGGTGACAGCTGAGATGCGGCTTCTCCAGGGTGGAGCCTCCT

CGTTTTCCAGAGCTGCTTGTTGAAGTCTTCCCAGGGCCCCTGACTTGCACTGGAAACTGCTCACCTTGGCATCGGGATGTGGAGC

AAGAAATGCTTTTGTTTTCATTCATCCTAGTGTTCATAAAATGGAAAACAAATAAGGACATACAAAAACATTAATAAAATAAATT

AATGGAACTAGATTTTTCAGAAAGCACAACAAACACAAAATCCAAGTATTGCCATGTCAGCAACACATTCCTACTTTAAGTTTTA

TGAAGTTAATTGGAGTAGTGGAGAACAAAAGTGGATGTGGGGCAG

The entirety of each patent, patent application, publication and document referenced herein hereby is incorporated by reference. Citation of the above patents, patent applications, publications and documents is not an admission that any of the foregoing is pertinent prior art, nor does it constitute any admission as to the contents or date of these publications or documents.

Modifications may be made to the foregoing without departing from the basic aspects of the technology. Although the technology has been described in substantial detail with reference to one or more specific embodiments, those of ordinary skill in the art will recognize that changes may be made to the embodiments specifically disclosed in this application, yet these modifications and improvements are within the scope and spirit of the technology.

The technology illustratively described herein suitably may be practiced in the absence of any element(s) not specifically disclosed herein. Thus, for example, in each instance herein any of the terms “comprising,” “consisting essentially of,” and “consisting of” may be replaced with either of the other two terms. The terms and expressions which have been employed are used as terms of description and not of limitation, and use of such terms and expressions do not exclude any equivalents of the features shown and described or portions thereof, and various modifications are possible within the scope of the technology claimed. The term “a” or “an” can refer to one of or a plurality of the elements it modifies (e.g., “a reagent” can mean one or more reagents) unless it is contextually clear either one of the elements or more than one of the elements is described. The term “about” as used herein refers to a value within 10% of the underlying parameter (i.e., plus or minus 10%), and use of the term “about” at the beginning of a string of values modifies each of the values (i.e., “about 1, 2 and 3” refers to about 1, about 2 and about 3). For example, a weight of “about 100 grams” can include weights between 90 grams and 110 grams. Further, when a listing of values is described herein (e.g., about 50%, 60%, 70%, 80%, 85% or 86%) the listing includes all intermediate and fractional values thereof (e.g., 54%, 85.4%). Thus, it should be understood that although the present technology has been specifically disclosed by representative embodiments and optional features, modification and variation of the concepts herein disclosed may be resorted to by those skilled in the art, and such modifications and variations are considered within the scope of this technology.

Certain embodiments of the technology are set forth in the claims that follow.

	Number	Date	Country
Parent	12727198	Mar 2010	US
Child	13791466		US

	Number	Date	Country
Parent	13791466	Mar 2013	US
Child	15428659		US

	Number	Date	Country
Parent	12561241	Sep 2009	US
Child	12727198		US

PROCESSES AND COMPOSITIONS FOR METHYLATION-BASED ENRICHMENT OF FETAL NUCLEIC ACID FROM A MATERNAL SAMPLE USEFUL FOR NON-INVASIVE PRENATAL DIAGNOSES

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