MARKERS OF ACTIVE HIV RESERVOIR

REFERENCE TO AN ELECTRONIC SEQUENCE LISTING

The contents of the electronic sequence listing (“BROD-2920US-CON_ST26.xml”, size is 20,806 bytes, and it was created on Aug. 18, 2023) is herein incorporated by reference in its entirety.

TECHNICAL FIELD

The subject matter disclosed herein is generally directed to a cell atlas of different cell types in healthy and disease states. The subject matter further relates to novel cell specific and disease specific markers. This invention relates generally to compositions and methods identifying and exploiting target genes or target gene products that modulate, control or otherwise influence cell-cell communication, differential expression, immune response in a variety of therapeutic and/or diagnostic indications.

BACKGROUND

Immune systems play an essential role in ensuring our health. From decades of laboratory and clinical work, there has been a basic understanding of immune balance and its importance for a healthy immune system. For example, hyperactivity can lead to allergy, inflammation, tissue damage, autoimmune disease and excessive cellular death. On the other hand, immunodeficiency can lead to outgrowth of cancers and the inability to kill or suppress external invaders. The immune system has evolved multiple modalities and redundancies that balance the system, including but not limited to memory, exhaustion, anergy, and senescence. Despite this basic understanding, a comprehensive landscape of immune regulations remains missing. Given the importance of the immune system, a systematic understanding of immune regulations on cell, tissue, and organism levels is crucial for clinicians and researchers to efficiently diagnose and develop treatments for immune system related disease.

Different cells and tissues in a diseased organism are often not impacted at the same level. Analyzing immune regulations with a comprehensive approach allows for identification of cells and tissues that are impacted and that are representative of the disease, interaction between cells, as well as pathways that can be specifically targeted to restore diseased cell or tissues to a normal state. In practice, certain tissues or specimens, for example blood or body fluids, are more easily obtainable than others from a patient. A systematic understanding of immune responses allows clinicians to use easily obtainable tissues as a proxy to diagnose disease and monitor disease state through easily obtainable tissues, and may further allow for treatment or amelioration of symptoms by restoring the state of suppressed immune cells or eliminating severely infected cells, for example, cells impacted with a chronic infection such as HIV infected cells/MTB infected cells.

HIV is a member of the lentivirus family of animal retroviruses, which include the visna virus of sheep and the bovine, feline, and simian immunodeficiency viruses (SIV). HIV preferentially infects CD4 T cells, reverse transcribes its DNA, and integrates into the host genome. During early infection, the host cell experiences a spike in viral load of HIV. Because of such high viral load in plasma, as infected T cells migrate throughout the entire host organism, all tissues can be exposed to HIV, causing profound and often irreversible changes to the adaptive and innate immune systems and establishing a permanent pool of integrated HIV in T cells, known as the HIV reservoir. Standard of care for HIV infection treatment involves anti-retroviral therapies that block various stages of the HIV life cycle. This treatment increases CD4 T cell counts and can decrease HIV levels to below the limit of detection by clinical assays. However, integrated HIV in the HIV reservoir persist and maintain active replication, in low levels of HIV harboring cells and tissues. These persistent HIV reservoir cells remain a critical barrier to cure, and are responsible for ongoing inflammation and pathology even under treatment.

SUMMARY

In one aspect, the invention provides a method of modulating a cell or tissue comprising a latent HIV or anti-retroviral therapy (ART)-resistant HIV infection. The method may comprise contacting the cell or tissue with a modulating agent in an amount sufficient to modify the HIV latency or ART-resistance of the cell or tissue as compared to the HIV latency or ART-resistance in the absence of the modulating agent, whereby the HIV latency or ART-resistance of the cell directly influences the latent HIV or ART-resistant HIV infection.

In alternative embodiments, the invention comprises a method of modulating a cell or tissue comprising a hepatitis B or hepatitis C virus infection.

In some embodiments, the modulating of a cell or tissue comprises modulating an immune cell. In some embodiments, the modulating of a cell or tissue comprises modulating a lymph node immune cell. In some embodiments, the modulating of a cell or tissue comprises modulating a T cell or T cell subset. In some embodiments, the modulating of a cell or tissue comprises modulating a CD3⁺PCD4⁺PD1⁺PCXCR4⁺ T follicular helper cell or a CD45RA⁻ CCR7⁺PCD27⁺ memory T cell. In some embodiments, the modulating of a cell or tissue comprises modulating a gene or product of one or more genes that is enriched for expression in HIV⁺ cells. In some embodiments, the gene or gene product of two or more genes may be modulated. The one or more genes may be from Table 1 or Table 2.

The modulating of a cell or tissue may comprise modulating a gene or product of one or more genes that is enriched for expression in HIV⁻ cells. As such, the method may comprise modulating a gene or product of two or more genes. The one or more genes may be selected from the genes of Table 3.

The method may comprise modulating a gene or product of one or more genes that is enriched for expression in HIV⁺ cells and a gene or product of one or more genes that is enriched for expression in HIV⁻ cells.

The T cell or T cell subset may be a CD4+ T cell, and the modulating of a cell or tissue may comprise modulating a gene selected from the group consisting of genes involved in unfolded protein response, HTLV-1 infection, herpes simplex infection, interferon gamma signaling pathway, antigen processing and presentation via WIC class I, positive regulation of apoptotic processes, T cell receptor signaling, virion assembly, and viral transcription.

In another aspect, provided herein is a method of diagnosing a cell or tissue in a subject having a latent HIV or anti-retroviral therapy (ART)-resistant HIV infection. The method may comprise detecting a gene expression profile in one or more cells or tissues associated with latent HIV or ART-resistant HIV infection.

In yet another aspect, provided herein is a method of diagnosing a latent HIV or ART-resistant HIV infection in a cell or tissue, the method comprising detecting whether one or more genes from Table 1 or Table 2 is overexpressed compared to a cell that is HIV⁻.

In yet another aspect, provided herein is a method of diagnosing a latent HIV or anti-retroviral therapy (ART)-resistant HIV infection in a cell or tissue, the method comprising detecting whether one or more genes from Table 3 is underexpressed compared to a cell that is HIV⁻.

In yet another aspect, the invention provides a method of monitoring treatment of a latent HIV or anti-retroviral therapy (ART)-resistant HIV infection in a cell or tissue, the method comprising detecting whether one or more genes from Table 1 or Table 2 is overexpressed compared to a cell that is HIV⁻.

In another aspect, the invention provides a method of monitoring treatment of a latent HIV or anti-retroviral therapy (ART)-resistant HIV infection in a cell or tissue, the method comprising detecting whether one or more genes from Table 3 is underexpressed compared to a cell that is HIV⁻.

In another aspect, the invention provides a method of treating HIV comprising detecting one or more genes or gene signatures from Tables 1 or 2; determining whether the patient has a latent HIV or ART-resistant HIV infection based on the presence of one or more genes or gene signatures from Tables 1 or 2; and administering an anti-HIV therapeutic if one or more genes or gene signatures from Tables 1 or 2 are present.

In some embodiments, the step of detecting comprises detecting the presence of a marker using an immunological assay. The immunological assay may comprise detection of specific binding between an antibody and the marker. The marker may be a peptide, polypeptide, or protein.

In another aspect, the invention provides a method of monitoring HIV disease progression and/or treatment comprising detecting expression of one or more genes or gene products from Tables 1, 2 and 3 prior to administration of an anti-HIV therapy; administering a first round of an anti-HIV therapy; detecting expression of one or more genes or gene products from Tables 1, 2 and 3 after administration of the anti-HIV therapeutic; and administering an additional or alternative round of anti-HIV therapy if expression of one or more genes from Table 1 or 2 has increased or not decreased, or if expression of one or more genes in Table 3 has decreased relative to prior to administering the first anti-HIV therapy.

In some embodiments, the additional or alternative round of anti-HIV therapy comprises the same drug or combination of drugs as the first round of anti-HIV therapy. In alternative embodiments, the additional or alternative round of anti-HIV therapy comprises a different drug or combination of drugs than the first round of anti-HIV therapy.

These and other aspects, objects, features, and advantages of the example embodiments will become apparent to those having ordinary skill in the art upon consideration of the following detailed description of illustrated example embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

An understanding of the features and advantages of the present invention will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the invention may be utilized, and the accompanying drawings of which:

FIG. 1—Balance in the immune system determines health vs. disease. Hyperactivity can lead to tissue damage, allergy, inflammation, and cell death. Immunodeficiency can lead to outgrowth of cancers or external pathogens.

FIG. 2—Host-Pathogen Dynamics of HIV Infection. HIV preferentially infects CD4 T cells, reverse transcribes its DNA, and integrates into the host genome. Infection progresses through a spike in viral load, followed by a progressive decrease in CD4+ T cell count. Because of the high plasma viral load, and because T cells migrate throughout different locations, virtually all tissues can be exposed to the virus, causing profound, and often irreversible changes to the adaptive and innate immune systems, and establishing a permanent pool of integrated HIV termed the “reservoir.”

FIG. 3—Lymph node cells stain positive for HIV proteins such as p24 by flow cytometry indicating a significant fraction of cells are actively producing virus.

FIG. 4—Lymph node from an HIV-infected, antiretroviral-treated patient.

FIG. 5—HIV infection status of single cells. Detection of host mRNA and HIV-1 RNA from the same cell.

FIG. 6—HIV infection status of single cells. Detection of host mRNA and HIV-1 RNA from the same cell.

FIG. 7—Cellular identities of Active HIV Reservoir. Top: Single cell RNA detection distinguishes cells, including markers and pathways, that contribute to ongoing HIV replication. Bottom: Differential expression between HIV⁺ and HIV⁻ cells shown by gag-pol abundance identifies genes that drive HIV replication such as transcription factors that bind to HIV promoter regions. Genes associated with metabolism of anti-retroviral drugs are also detected and novel differentially expressed genes identified.

FIG. 8—Non-human primate model showing examples of cells and tissues useful for elaborating gene signatures associated with diseases and disorders.

FIG. 9—Single cell profiles define cells by tissue (left) and cell type (right).

FIG. 10—Single cell transcriptome expression profiles cluster by cell type.

FIG. 11—CD3E+ + CD3D+ + CD3G+ cells by tissue and cell type.

FIG. 12A—Tissue specific behavior of macrophages; FIG. 12B charts number of tissue specific cells of macrophages; FIG. 12C single cell transcriptomes of macrophages identify genes that define them. FIG. 12D single cell transcriptomes of macrophages identify tissue specific sub sets.

FIG. 13—Macrophage expression profiles correspond with tissues of origin.

FIG. 14—Single cell profiles define cells by tissue (left) and cell type (right).

FIG. 15—Identification of pneumocyte (FIG. 15A) and NK (FIG. 15B) cell clusters.

FIG. 16—Gene expression in pneumocytes indicates tissue-dependence.

FIG. 17—Gene expression in NK cells indicates common functions and potential differences driven by tissue-of-origin.

FIG. 18—Cell resolution looking at individual tissues.

FIG. 19—Cell expression profiles by tissue.

FIG. 20—Gene expression in PBMCs showing individual cell types and correlation with gene groups.

FIG. 21—Gene expression of cells in Ileum showing individual cell types and correlation with gene groups.

FIG. 22A-22C—Single cell genomics FIG. 22A Single cell genomics of cells from lymphoid tissue from healthy and SHIV-infected Rhesus macaques defines specific cell subsets. FIG. 22B Certain subsets have equal representation between healthy and SHIV, such as CD8 T cells or macrophages, while CD4 T cells and B cells, show major deviations due to prior SHIV infection. FIG. 22C Differential expression of genes in healthy and SHIV-infected CD4 T cells. As in humans, animals with suppressed viral replication as detected in blood show signatures in lymphoid resident T cells associated with ongoing viral replication and response to virus.

FIG. 23—Comparison of differentially expressed genes between HIV⁺ and HIV⁻ T cells in human lymph nodes with SHIV⁺ and SHIV⁻ T cells in non-human primates shows significant overlap.

FIG. 24A-24D—Impact of chronic SHIV infection on different tissue niches. FIG. 24A Single cell genomics of cells from lymphoid tissue and ileum compared. FIG. 24B In the mesenteric LN, T cells are affected by prior HIV infection, but in the ileum, a significant effect is not observed. FIG. 24C In the small intestine, T cells are more similar, but largest differential expression occurs among the epithelial enterocytes. FIG. 24D Identification of cell subsets altered by SHIV infection.

FIG. 25 shows the proposed experimental workflow using a lymph node sample from an HIV⁺ patient.

FIGS. 26A-26C show flow cytometry data illustrating that J3 and 10-1074 bnAbs are specific for HIV⁺ samples. FIG. 26A shows data for HIV⁻ PBMCs. FIG. 26B shows data for HIV⁺ (LN276) with stringent gating. FIG. 26C shows data for HIV⁺ (LN276) with non-stringent gating.

FIGS. 27A and 27B show flow cytometry plots illustrating confirmatory staining with intracellular HIV gag.

FIGS. 28A and 28B show that J3 and 10-1074 bnAbs successfully enrich for HIV⁺ cells.

FIG. 29 shows results of Seq-Well on lymph nodes from an HIV⁺, ARV-treated patient.

FIG. 30 shows results of Seq-Well on lymph nodes from an HIV⁺, ARV-treated patient.

FIG. 31 shows results of Seq-Well on lymph nodes from an HIV⁺, ARV-treated patient.

FIG. 32 shows a schematic of matched full-length sequencing of the HIV genome.

The figures herein are for illustrative purposes only and are not necessarily drawn to scale.

DETAILED DESCRIPTION OF THE EXAMPLE EMBODIMENTS
General Definitions

Unless defined otherwise, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure pertains. Definitions of common terms and techniques in molecular biology may be found in Molecular Cloning: A Laboratory Manual, 2^ndedition (1989) (Sambrook, Fritsch, and Maniatis); Molecular Cloning: A Laboratory Manual, 4^thedition (2012) (Green and Sambrook); Current Protocols in Molecular Biology (1987) (F. M. Ausubel et al. eds.); the series Methods in Enzymology (Academic Press, Inc.): PCR 2: A Practical Approach (1995) (M. J. MacPherson, B. D. Hames, and G. R. Taylor eds.): Antibodies, A Laboratory Manual (1988) (Harlow and Lane, eds.): Antibodies A Laboratory Manual, 2^ndedition 2013 (E. A. Greenfield ed.); Animal Cell Culture (1987) (R. I. Freshney, ed.); Benjamin Lewin, Genes IX, published by Jones and Bartlet, 2008 (ISBN 0763752223); Kendrew et al. (eds.), The Encyclopedia of Molecular Biology, published by Blackwell Science Ltd., 1994 (ISBN 0632021829); Robert A. Meyers (ed.), Molecular Biology and Biotechnology: a Comprehensive Desk Reference, published by VCH Publishers, Inc., 1995 (ISBN 9780471185710); Singleton et al., Dictionary of Microbiology and Molecular Biology 2nd ed., J. Wiley & Sons (New York, N.Y. 1994), March, Advanced Organic Chemistry Reactions, Mechanisms and Structure 4th ed., John Wiley & Sons (New York, N.Y. 1992); and Marten H. Hofker and Jan van Deursen, Transgenic Mouse Methods and Protocols, 2nd edition (2011).

As used herein, the singular forms “a”, “an”, and “the” include both singular and plural referents unless the context clearly dictates otherwise.

The term “optional” or “optionally” means that the subsequent described event, circumstance or substituent may or may not occur, and that the description includes instances where the event or circumstance occurs and instances where it does not.

The recitation of numerical ranges by endpoints includes all numbers and fractions subsumed within the respective ranges, as well as the recited endpoints.

The terms “about” or “approximately” as used herein when referring to a measurable value such as a parameter, an amount, a temporal duration, and the like, are meant to encompass variations of and from the specified value, such as variations of +/−10% or less, +/−5% or less, +/−1% or less, and +1-0.1% or less of and from the specified value, insofar such variations are appropriate to perform in the disclosed invention. It is to be understood that the value to which the modifier “about” or “approximately” refers is itself also specifically, and preferably, disclosed.

As used herein, a “biological sample” may contain whole cells and/or live cells and/or cell debris. The biological sample may contain (or be derived from) a “bodily fluid”. The present invention encompasses embodiments wherein the bodily fluid is selected from amniotic fluid, aqueous humour, vitreous humour, bile, blood serum, breast milk, cerebrospinal fluid, cerumen (earwax), chyle, chyme, endolymph, perilymph, exudates, feces, female ejaculate, gastric acid, gastric juice, lymph, mucus (including nasal drainage and phlegm), pericardial fluid, peritoneal fluid, pleural fluid, pus, rheum, saliva, sebum (skin oil), semen, sputum, synovial fluid, sweat, tears, urine, vaginal secretion, vomit and mixtures of one or more thereof. Biological samples include cell cultures, bodily fluids, cell cultures from bodily fluids. Bodily fluids may be obtained from a mammal organism, for example by puncture, or other collecting or sampling procedures.

The terms “subject,” “individual,” and “patient” are used interchangeably herein to refer to a vertebrate, preferably a mammal, more preferably a human. Mammals include, but are not limited to, murines, simians, humans, farm animals, sport animals, and pets. Tissues, cells and their progeny of a biological entity obtained in vivo or cultured in vitro are also encompassed.

Various embodiments are described hereinafter. It should be noted that the specific embodiments are not intended as an exhaustive description or as a limitation to the broader aspects discussed herein. One aspect described in conjunction with a particular embodiment is not necessarily limited to that embodiment and can be practiced with any other embodiment(s). Reference throughout this specification to “one embodiment”, “an embodiment,” “an example embodiment,” means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, appearances of the phrases “in one embodiment,” “in an embodiment,” or “an example embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment, but may. Furthermore, the particular features, structures or characteristics may be combined in any suitable manner, as would be apparent to a person skilled in the art from this disclosure, in one or more embodiments. Furthermore, while some embodiments described herein include some but not other features included in other embodiments, combinations of features of different embodiments are meant to be within the scope of the invention. For example, in the appended claims, any of the claimed embodiments can be used in any combination.

All publications, published patent documents, and patent applications cited herein are hereby incorporated by reference to the same extent as though each individual publication, published patent document, or patent application was specifically and individually indicated as being incorporated by reference.

Overview

Embodiments disclosed herein provide a pan-tissue cell from healthy and diseased subjects. The atlas was obtained by single cell sequencing. The present invention discloses novel markers for cell types. Moreover, genes associated with chronic infection and disease, including those associated with HIV infection are identified. The invention provides for diagnostic assays based on gene markers and cell composition, as well as therapeutic targets for controlling differentiation, proliferation, maintenance and/or function of the cell types disclosed herein. In addition, novel cell types and methods of quantitating, detecting and isolating the cell types are disclosed.

In certain example embodiments, using Seq-Well for massively parallel scRNA-seq (Shalek reference Re: Seq-well) of surgical resections from individuals infected by HIV (HIV+) and healthy individuals (HIV−), cells and tissues representative of infection states were located, and biomarkers related to (latent) infection in specific cells were identified.

Methods of Modulating

Methods as disclosed herein are directed to modulating a cell or tissue infected with a viral infection. Such infections include, but are not necessarily limited to, Hepatitis B, Hepatitis C, or HIV. In specific embodiments, the methods comprise contacting a cell or tissue with a modulating agent in an amount sufficient to modify the HIV latency or ART-resistance of the cell or tissue as compared to the HIV latency or ART-resistance in the absence of the modulating agent. The methods of modulating may include modulating one or more host genes, or product of one or more host genes, which may include increasing or decreasing expression of particular host genes or gene products. Modulating may be based on the gene expression detected, and may be determined by the gene whose expression is increased in a cell infected with HIV. The order of steps provided herein is exemplary, certain steps may be carried out simultaneously or in a different order.

Contacting

The contacting may take place in vitro, in vivo, ex vivo. In some instances contacting can be performed by incubating a cell or tissue having a certain phenotype with the candidate modulating agent. In some instances contacting can be performed by delivering the candidate modulating agent to a subject in need thereof. The step of contacting is performed under conditions and for a time sufficient to allow the modulating agent and the cell, tissue, gene, or gene product to interact.

In some embodiments, the cells or population of cells may be obtained from a biological sample. The biological sample may be obtained from a subject suffering from a disease. The biological sample may be a tumor sample. The tumor may be any tumor. This may include, without limitation, liquid tumors such as leukemia (e.g., acute leukemia, acute lymphocytic leukemia, acute myelocytic leukemia, acute myeloblastic leukemia, acute promyelocytic leukemia, acute myelomonocytic leukemia, acute monocytic leukemia, acute erythroleukemia, chronic leukemia, chronic myelocytic leukemia, chronic lymphocytic leukemia), polycythemia vera, lymphoma (e.g., Hodgkin's disease, non-Hodgkin's disease), Waldenstrom's macroglobulinemia, heavy chain disease, or multiple myeloma.

As used herein, a “biological sample” may contain whole cells and/or tissue and/or live cells and/or cell debris. The biological sample may contain (or be derived from) a “bodily fluid”. The present invention encompasses embodiments wherein the bodily fluid is selected from amniotic fluid, aqueous humour, vitreous humour, bile, blood serum, breast milk, cerebrospinal fluid, cerumen (earwax), chyle, chyme, endolymph, perilymph, exudates, feces, female ejaculate, gastric acid, gastric juice, lymph, mucus (including nasal drainage and phlegm), pericardial fluid, peritoneal fluid, pleural fluid, pus, rheum, saliva, sebum (skin oil), semen, sputum, synovial fluid, sweat, tears, urine, vaginal secretion, vomit and mixtures of one or more thereof. Biological samples include cell cultures, bodily fluids, cell cultures from bodily fluids. Bodily fluids may be obtained from a mammal organism, for example by puncture, or other collecting or sampling procedures.

Modulating Agent

The modulating agent can be any composition that induces, represses, or otherwise affects a gene or gene product. Modulating agents may be selected in some instances, based on a particular pathway, degree of infection, and/or a gene expression signature that may have been detected.

As used herein, modulating, or to modulate, generally means either reducing or inhibiting the expression or activity of, or alternatively increasing the expression or activity of a target gene. In particular, modulating can mean either reducing or inhibiting the activity of, or alternatively increasing a (relevant or intended) biological activity of, a target or antigen as measured using a suitable in vitro, cellular or in vivo assay (which will usually depend on the target involved), by at least 5%, at least 10%, at least 25%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, or more, compared to activity of the target in the same assay under the same conditions but without the presence of an agent. An increase or decrease refers to a statistically significant increase or decrease respectively. For the avoidance of doubt, an increase or decrease will be at least 10% relative to a reference, such as at least 10%, at least 20%, at least 30%, at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 95%, at least 97%, at least 98%, or more, up to and including at least 100% or more, in the case of an increase, for example, at least 2-fold, at least 3-fold, at least 4-fold, at least 5-fold, at least 6-fold, at least 7-fold, at least 8-fold, at least 9-fold, at least 10-fold, at least 50-fold, at least 100-fold, or more. Modulating can also involve effecting a change (which can either be an increase or a decrease) in affinity, avidity, specificity and/or selectivity of a target or antigen, such as a receptor and ligand. Modulating can also mean effecting a change with respect to one or more biological or physiological mechanisms, effects, responses, functions, pathways or activities in which the target or antigen (or in which its substrate(s), ligand(s) or pathway(s) are involved, such as its signaling pathway or metabolic pathway and their associated biological or physiological effects) is involved. Again, as will be clear to the skilled person, such an action as an agonist or an antagonist can be determined in any suitable manner and/or using any suitable assay known or described herein (e.g., in vitro or cellular assay), depending on the target or antigen involved. Accordingly, a modulating agent in an amount sufficient to modify the Mycobacterium tuberculosis infection in a cell or tissue would provide the agent in an amount to effect a change in the amount of infection compared to the amount of infection in the cell or tissue in the absence of modulating agent, or untreated. The amount of modulating agent will vary according to the pathway, gene, or gene product targeted, the host, the tissue or cell, and the amount or copy number of the TB infection.

Modulating can, for example, also involve allosteric modulation of the target and/or reducing or inhibiting the binding of the target to one of its substrates or ligands and/or competing with a natural ligand, substrate for binding to the target. Modulating can also involve activating the target or the mechanism or pathway in which it is involved. Modulating can for example also involve effecting a change in respect of the folding or confirmation of the target, or in respect of the ability of the target to fold, to change its conformation (for example, upon binding of a ligand), to associate with other (sub)units, or to disassociate. Modulating can for example also involve effecting a change in the ability of the target to signal, phosphorylate, dephosphorylate, and the like.

As used herein, an “agent” can refer to a protein-binding agent that permits modulation of activity of proteins or disrupts interactions of proteins and other biomolecules, such as but not limited to disrupting protein-protein interaction, ligand-receptor interaction, or protein-nucleic acid interaction. Agents can also refer to DNA targeting or RNA targeting agents. Agents may include a fragment, derivative and analog of an active agent. The terms “fragment,” “derivative” and “analog” when referring to polypeptides as used herein refers to polypeptides which either retain substantially the same biological function or activity as such polypeptides. An analog includes a proprotein which can be activated by cleavage of the proprotein portion to produce an active mature polypeptide. Such agents include, but are not limited to, antibodies (“antibodies” includes antigen-binding portions of antibodies such as epitope- or antigen-binding peptides, paratopes, functional CDRs; recombinant antibodies; chimeric antibodies; humanized antibodies; nanobodies; tribodies; midibodies; or antigen-binding derivatives, analogs, variants, portions, or fragments thereof), protein-binding agents, nucleic acid molecules, small molecules, recombinant protein, peptides, aptamers, avimers and protein-binding derivatives, portions or fragments thereof. An “agent” as used herein, may also refer to an agent that inhibits expression of a gene, such as but not limited to a DNA targeting agent (e.g., CRISPR system, TALE, Zinc finger protein) or RNA targeting agent (e.g., inhibitory nucleic acid molecules such as RNAi, miRNA, ribozyme).

The agents of the present invention may be modified, such that they acquire advantageous properties for therapeutic use (e.g., stability and specificity), but maintain their biological activity.

It is well known that the properties of certain proteins can be modulated by attachment of polyethylene glycol (PEG) polymers, which increases the hydrodynamic volume of the protein and thereby slows its clearance by kidney filtration. (See, e.g., Clark et al., J. Biol. Chem. 271: 21969-21977 (1996)). Therefore, it is envisioned that certain agents can be PEGylated (e.g., on peptide residues) to provide enhanced therapeutic benefits such as, for example, increased efficacy by extending half-life in vivo. In certain embodiments, PEGylation of the agents may be used to extend the serum half-life of the agents and allow for particular agents to be capable of crossing the blood-brain barrier.

In regards to peptide PEGylation methods, reference is made to Lu et al., Int. J. Pept. Protein Res. 43: 127-38 (1994); Lu et al., Pept. Res. 6: 140-6 (1993); Felix et al., Int. J. Pept. Protein Res. 46: 253-64 (1995); Gaertner et al., Bioconjug. Chem. 7: 38-44 (1996); Tsutsumi et al., Thromb. Haemost. 77: 168-73 (1997); Francis et al., hit. J. Hematol. 68: 1-18 (1998); Roberts et al., J. Pharm. Sci. 87: 1440-45 (1998); and Tan et al., Protein Expr. Purif. 12: 45-52 (1998). Polyethylene glycol or PEG is meant to encompass any of the forms of PEG that have been used to derivatize other proteins, including, but not limited to, mono-(C1-10) alkoxy or aryloxy-polyethylene glycol. Suitable PEG moieties include, for example, 40 kDa methoxy poly(ethylene glycol) propionaldehyde (Dow, Midland, Mich.); 60 kDa methoxy poly(ethylene glycol) propionaldehyde (Dow, Midland, Mich.); 40 kDa methoxy poly(ethylene glycol) maleimido-propionamide (Dow, Midland, Mich.); 31 kDa alpha-methyl-w-(3-oxopropoxy), polyoxyethylene (NOF Corporation, Tokyo); mPEG2-NHS-40k (Nektar); mPEG2-MAL-40k (Nektar), SUNBRIGHT GL2-400MA ((PEG)240 kDa) (NOF Corporation, Tokyo), SUNBRIGHT ME-200MA (PEG20 kDa) (NOF Corporation, Tokyo). The PEG groups are generally attached to the peptide (e.g., neuromedin U receptor agonists or antagonists) via acylation or alkylation through a reactive group on the PEG moiety (for example, a maleimide, an aldehyde, amino, thiol, or ester group) to a reactive group on the peptide (for example, an aldehyde, amino, thiol, a maleimide, or ester group).

The PEG molecule(s) may be covalently attached to any Lys, Cys, or K(CO(CH2)2SH) residues at any position in a peptide. In certain embodiments, the neuromedin U receptor agonists described herein can be PEGylated directly to any amino acid at the N-terminus by way of the N-terminal amino group. A “linker arm” may be added to a peptide to facilitate PEGylation. PEGylation at the thiol side-chain of cysteine has been widely reported (see, e.g., Caliceti & Veronese, Adv. Drug Deliv. Rev. 55: 1261-77 (2003)). If there is no cysteine residue in the peptide, a cysteine residue can be introduced through substitution or by adding a cysteine to the N-terminal amino acid.

As used herein the term “altered expression” may particularly denote altered production of the recited gene products by a cell. As used herein, the term “gene product(s)” includes RNA transcribed from a gene (e.g., mRNA), or a polypeptide encoded by a gene or translated from RNA. Also, “altered expression” as intended herein may encompass modulating the activity of one or more endogenous gene products. Accordingly, “altered expression”, “altering expression”, “modulating expression”, or “detecting expression” or similar may be used interchangeably with respectively “altered expression or activity”, “altering expression or activity”, “modulating expression or activity”, or “detecting expression or activity” or similar. As used herein, “modulating” or “to modulate” generally means either reducing or inhibiting the activity of a target or antigen, or alternatively increasing the activity of the target or antigen, as measured using a suitable in vitro, cellular or in vivo assay. In particular, “modulating” or “to modulate” can mean either reducing or inhibiting the (relevant or intended) activity of, or alternatively increasing the (relevant or intended) biological activity of the target or antigen, as measured using a suitable in vitro, cellular or in vivo assay (which will usually depend on the target or antigen involved), by at least 5%, at least 10%, at least 25%, at least 50%, at least 60%, at least 70%, at least 80%, or 90% or more, compared to activity of the target or antigen in the same assay under the same conditions but without the presence of the inhibitor/antagonist agents or activator/agonist agents described herein.

As will be clear to the skilled person, “modulating” can also involve affecting a change (which can either be an increase or a decrease) in affinity, avidity, specificity and/or selectivity of a target or antigen, for one or more of its targets compared to the same conditions but without the presence of a modulating agent. Again, this can be determined in any suitable manner and/or using any suitable assay known per se, depending on the target. In particular, an action as an inhibitor/antagonist or activator/agonist can be such that an intended biological or physiological activity is increased or decreased, respectively, by at least 5%, at least 10%, at least 25%, at least 50%, at least 60%, at least 70%, at least 80%, or 90% or more, compared to the biological or physiological activity in the same assay under the same conditions but without the presence of the inhibitor/antagonist agent or activator/agonist agent. Modulating can also involve activating the target or antigen or the mechanism or pathway in which it is involved.

As used herein, a “blocking” antibody or an antibody “antagonist” is one which inhibits or reduces biological activity of the antigen(s) it binds. In certain embodiments, the blocking antibodies or antagonist antibodies or portions thereof described herein completely inhibit the biological activity of the antigen(s).

Antibodies may act as agonists or antagonists of the recognized polypeptides. For example, the present invention includes antibodies which disrupt receptor/ligand interactions either partially or fully. The invention features both receptor-specific antibodies and ligand-specific antibodies. The invention also features receptor-specific antibodies which do not prevent ligand binding but prevent receptor activation. Receptor activation (i.e., signaling) may be determined by techniques described herein or otherwise known in the art. For example, receptor activation can be determined by detecting the phosphorylation (e.g., tyrosine or serine/threonine) of the receptor or of one of its down-stream substrates by immunoprecipitation followed by western blot analysis. In specific embodiments, antibodies are provided that inhibit ligand activity or receptor activity by at least 95%, at least 90%, at least 85%, at least 80%, at least 75%, at least 70%, at least 60%, or at least 50% of the activity in absence of the antibody.

Upon infection, HIV remains latent in infected cells, a state in which it is present, but not actively producing viral particles. Latent HIV reservoirs are established during the earliest stage of HIV infection. Although ART can reduce the level of HIV in the blood to an undetectable level, latent reservoirs of HIV continue to survive so that, when a latently infected cell is reactivated, the cell begins to produce viral particles again. Although ART can suppress HIV levels, the therapy cannot eliminate latent HIV reservoirs, and thus cannot cure the infection. Termination of ART leads to almost immediate reactivation and replication of HIV genes within a couple of weeks upon termination of therapy. Furthermore, certain viral strains are resistant to ART treatment, causing HIV treatment to fail in certain individuals. Such individuals are said to have an ART-resistant HIV infection.

The term “amount sufficient”, “effective amount”, or “therapeutically effective amount” refers to the amount of an agent that is sufficient to effect beneficial or desired results. The therapeutically effective amount may vary depending upon one or more of: the subject and disease condition being treated, the weight and age of the subject, the severity of the disease condition, the manner of administration and the like, which can readily be determined by one of ordinary skill in the art. The term also applies to a dose that will provide an image for detection by any one of the imaging methods described herein. The specific dose may vary depending on one or more of: the particular agent chosen, the dosing regimen to be followed, whether it is administered in combination with other compounds, timing of administration, the tissue to be imaged, and the physical delivery system in which it is carried.

For example, in methods for treating cancer in a subject, an effective amount of a combination of inhibitors targeting epigenetic genes is any amount that provides an anti-cancer effect, such as reduces or prevents proliferation of a cancer cell or is cytotoxic towards a cancer cell. In certain embodiments, the effective amount of an inhibitor targeting an epigenetic gene is reduced when an inhibitor is administered concomitantly or in combination with one or more additional inhibitors targeting epigenetic genes as compared to the effective amount of the inhibitor when administered in the absence of one or more additional inhibitors targeting epigenetic genes. In certain embodiments, the inhibitor targeting an epigenetic gene does not reduce or prevent proliferation of a cancer cell when administered in the absence of one or more additional inhibitors targeting epigenetic genes.

In specific embodiments, in methods for modulating a cell or tissue having a latent HIV or ART-resistant HIV infection, an amount of a modulating agent sufficient to modify the HIV latency or ART-resistance of the cell or tissue is any amount that increases or decreases the expression of genes or gene products from Tables 1, 2, or 3 in that cell or tissue relative to a cell or tissue not exposed to or contacted with that modulating agent.

The terms “increased” or “increase” or “upregulated” or “upregulate” as used herein generally mean an increase by a statically significant amount. For avoidance of doubt, “increased” means a statistically significant increase of at least 10% as compared to a reference level, including an increase of at least 20%, at least 30%, at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 100% or more, including, for example at least 2-fold, at least 3-fold, at least 4-fold, at least 5-fold, at least 10-fold increase or greater as compared to a reference level, as that term is defined herein.

The term “reduced” or “reduce” or “decrease” or “decreased” or “downregulate” or “downregulated” as used herein generally means a decrease by a statistically significant amount relative to a reference. For avoidance of doubt, “reduced” means statistically significant decrease of at least 10% as compared to a reference level, for example a decrease by at least 20%, at least 30%, at least 40%, at least 50%, or at least 60%, or at least 70%, or at least 80%, at least 90% or more, up to and including a 100% decrease (i.e., absent level as compared to a reference sample), or any decrease between 10-100% as compared to a reference level, as that.

In some embodiments, the viral or latent viral infection in the cell or tissue is a latent HIV or anti-ART-resistant HIV infection as described herein.

In some embodiments, the viral infection is a hepatitis infection. In specific embodiments, the hepatitis infection is hepatitis B or hepatitis C. The pathway by which hepatic viruses cause viral hepatitis is best understood in the case of hepatitis B and C. The viruses do not directly cause apoptosis (cell death), rather, infection of liver cells activates the innate and adaptive arms of the immune system leading to an inflammatory response which causes cellular damage and death (Nakamoto et al. Curr Molec Med 3(6):537-544; 2003). Depending on the strength of the immune response, the types of immune cells involved and the ability of the virus to evade the body's defense, infection can either lead to clearance (acute disease) or persistence (chronic disease) of the virus. The chronic presence of the virus within liver cells results in multiple waves of inflammation, injury and wound healing that over time lead to scarring or fibrosis and culminate in hepatocellular carcinoma (Nakamoto et al. Curr Molec Med 3(6):537-544 (2003); Wong Clin Molec Hepatol 20(3):228-236 (2014)). Individuals with an impaired immune response are at greater risk of developing chronic infection. Natural killer cells are the primary drivers of the initial innate response and create a cytokine environment that results in the recruitment of CD4 T-helper and CD8 cytotoxic T-cells (Rehermann Cell Molec Gastr Hepatol 1(6):578-588 (2015); Heim et al. J Hepatol 61 (1 Suppl): S14-25 (2014)). Type I interferons are the cytokines that drive the antiviral response (Heim et al. J Hepatol 61 (1 Suppl): S14-25 (2014)). In chronic Hepatitis B and C, natural killer cell function is impaired (Rehermann Cell Molec Gastr Hepatol 1(6):578-588 (2015)).

In some embodiments, the HIV latency or ART-resistance of the cell directly influences the latent HIV or ART-resistant HIV infection, in that the state of the cell has an effect or impact on the viral infection.

The term “immune cell” as used throughout this specification generally encompasses any cell derived from a hematopoietic stem cell that plays a role in the immune response. The term is intended to encompass immune cells both of the innate or adaptive immune system. The immune cell as referred to herein may be a leukocyte, at any stage of differentiation (e.g., a stem cell, a progenitor cell, a mature cell) or any activation stage. Immune cells include lymphocytes (such as natural killer cells, T-cells (including, e.g., thymocytes, Th or Tc; Th1, Th2, Th17, Thaβ, CD4⁺, CD8⁺, effector Th, memory Th, regulatory Th, CD4⁺/CD8⁺ thymocytes, CD4−/CD8− thymocytes, γδ T cells, etc.) or B-cells (including, e.g., pro-B cells, early pro-B cells, late pro-B cells, pre-B cells, large pre-B cells, small pre-B cells, immature or mature B-cells, producing antibodies of any isotype, T1 B-cells, T2 B-cells, naïve B-cells, GC B-cells, plasmablasts, memory B-cells, plasma cells, follicular B-cells, marginal zone B-cells, B-1 cells, B-2 cells, regulatory B cells, etc.), such as for instance, monocytes (including, e.g., classical, non-classical, or intermediate monocytes), (segmented or banded) neutrophils, eosinophils, basophils, mast cells, histiocytes, microglia, including various subtypes, maturation, differentiation, or activation stages, such as for instance hematopoietic stem cells, myeloid progenitors, lymphoid progenitors, myeloblasts, promyelocytes, myelocytes, metamyelocytes, monoblasts, promonocytes, lymphoblasts, prolymphocytes, small lymphocytes, macrophages (including, e.g., Kupffer cells, stellate macrophages, M1 or M2 macrophages), (myeloid or lymphoid) dendritic cells (including, e.g., Langerhans cells, conventional or myeloid dendritic cells, plasmacytoid dendritic cells, mDC-1, mDC-2, Mo-DC, HP-DC, veiled cells), granulocytes, polymorphonuclear cells, antigen-presenting cells (APC), etc.

As used throughout this specification, “immune response” refers to a response by a cell of the immune system, such as a B cell, T cell (CD4⁺ or CD8⁺), regulatory T cell, antigen-presenting cell, dendritic cell, monocyte, macrophage, NKT cell, NK cell, basophil, eosinophil, or neutrophil, to a stimulus. In some embodiments, the response is specific for a particular antigen (an “antigen-specific response”), and refers to a response by a CD4 T cell, CD8 T cell, or B cell via their antigen-specific receptor. In some embodiments, an immune response is a T cell response, such as a CD4⁺ response or a CD8⁺ response. Such responses by these cells can include, for example, cytotoxicity, proliferation, cytokine or chemokine production, trafficking, or phagocytosis, and can be dependent on the nature of the immune cell undergoing the response.

T cell response refers more specifically to an immune response in which T cells directly or indirectly mediate or otherwise contribute to an immune response in a subject. T cell-mediated response may be associated with cell mediated effects, cytokine mediated effects, and even effects associated with B cells if the B cells are stimulated, for example, by cytokines secreted by T cells. By means of an example but without limitation, effector functions of MEW class I restricted Cytotoxic T lymphocytes (CTLs), may include cytokine and/or cytolytic capabilities, such as lysis of target cells presenting an antigen peptide recognised by the T cell receptor (naturally-occurring TCR or genetically engineered TCR, e.g., chimeric antigen receptor, CAR), secretion of cytokines, preferably IFN gamma, TNF alpha and/or or more immunostimulatory cytokines, such as IL-2, and/or antigen peptide-induced secretion of cytotoxic effector molecules, such as granzymes, perforins or granulysin. By means of example but without limitation, for MEW class II restricted T helper (Th) cells, effector functions may be antigen peptide-induced secretion of cytokines, preferably, IFN gamma, TNF alpha, IL-4, IL5, IL-10, and/or IL-2. By means of example but without limitation, for T regulatory (Treg) cells, effector functions may be antigen peptide-induced secretion of cytokines, preferably, IL-10, IL-35, and/or TGF-beta. B cell response refers more specifically to an immune response in which B cells directly or indirectly mediate or otherwise contribute to an immune response in a subject. Effector functions of B cells may include in particular production and secretion of antigen-specific antibodies by B cells (e.g., polyclonal B cell response to a plurality of the epitopes of an antigen (antigen-specific antibody response)), antigen presentation, and/or cytokine secretion.

During persistent immune activation, such as during uncontrolled tumor growth or chronic infections, subpopulations of immune cells, particularly of CD8+ or CD4+ T cells, become compromised to different extents with respect to their cytokine and/or cytolytic capabilities. Such immune cells, particularly CD8+ or CD4+ T cells, are commonly referred to as “dysfunctional” or as “functionally exhausted” or “exhausted”. As used herein, the term “dysfunctional” or “functional exhaustion” refer to a state of a cell where the cell does not perform its usual function or activity in response to normal input signals, and includes refractivity of immune cells to stimulation, such as stimulation via an activating receptor or a cytokine. Such a function or activity includes, but is not limited to, proliferation (e.g., in response to a cytokine, such as IFN-gamma) or cell division, entrance into the cell cycle, cytokine production, cytotoxicity, migration and trafficking, phagocytotic activity, or any combination thereof. Normal input signals can include, but are not limited to, stimulation via a receptor (e.g., T cell receptor, B cell receptor, co-stimulatory receptor). Unresponsive immune cells can have a reduction of at least 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 95%, or even 100% in cytotoxic activity, cytokine production, proliferation, trafficking, phagocytotic activity, or any combination thereof, relative to a corresponding control immune cell of the same type. In some particular embodiments of the aspects described herein, a cell that is dysfunctional is a CD8+ T cell that expresses the CD8+ cell surface marker. Such CD8+ cells normally proliferate and produce cell killing enzymes, e.g., they can release the cytotoxins perforin, granzymes, and granulysin. However, exhausted/dysfunctional T cells do not respond adequately to TCR stimulation, and display poor effector function, sustained expression of inhibitory receptors and a transcriptional state distinct from that of functional effector or memory T cells. Dysfunction/exhaustion of T cells thus prevents optimal control of infection and tumors. Exhausted/dysfunctional immune cells, such as T cells, such as CD8+ T cells, may produce reduced amounts of IFN-gamma, TNF-alpha and/or one or more immunostimulatory cytokines, such as IL-2, compared to functional immune cells. Exhausted/dysfunctional immune cells, such as T cells, such as CD8+ T cells, may further produce (increased amounts of) one or more immunosuppressive transcription factors or cytokines, such as IL-10 and/or Foxp3, compared to functional immune cells, thereby contributing to local immunosuppression. Dysfunctional CD8+ T cells can be both protective and detrimental against disease control.

CD8+ T cell function is associated with their cytokine profiles. It has been reported that effector CD8+ T cells with the ability to simultaneously produce multiple cytokines (polyfunctional CD8+ T cells) are associated with protective immunity in patients with controlled chronic viral infections as well as cancer patients responsive to immune therapy (Spranger et al., 2014, J. Immunother. Cancer, vol. 2, 3). In the presence of persistent antigen CD8+ T cells were found to have lost cytolytic activity completely over time (Moskophidis et al., 1993, Nature, vol. 362, 758-761). It was subsequently found that dysfunctional T cells can differentially produce IL-2, TNFa and IFNg in a hierarchical order (Wherry et al., 2003, J. Virol., vol. 77, 4911-4927). Decoupled dysfunctional and activated CD8+ cell states have also been described (see, e.g., Singer, et al. (2016). A Distinct Gene Module for Dysfunction Uncoupled from Activation in Tumor-Infiltrating T Cells. Cell 166, 1500-1511 e1509; and WO/2017/075478).

The invention also provides compositions and methods for modulating T cell balance. The invention provides T cell modulating agents that modulate T cell balance. For example, in some embodiments, the invention provides T cell modulating agents and methods of using these T cell modulating agents to regulate, influence or otherwise impact the level of and/or balance between T cell types, e.g., between Th17 and other T cell types, for example, regulatory T cells (Tregs). For example, in some embodiments, the invention provides T cell modulating agents and methods of using these T cell modulating agents to regulate, influence or otherwise impact the level of and/or balance between Th17 activity and inflammatory potential. As used herein, terms such as “Th17 cell” and/or “Th17 phenotype” and all grammatical variations thereof refer to a differentiated T helper cell that expresses one or more cytokines selected from the group the consisting of interleukin 17A (IL-17A), interleukin 17F (IL-17F), and interleukin 17A/F heterodimer (IL17-AF). As used herein, terms such as “Th1 cell” and/or “Th1 phenotype” and all grammatical variations thereof refer to a differentiated T helper cell that expresses interferon gamma (IFNγ). As used herein, terms such as “Th2 cell” and/or “Th2 phenotype” and all grammatical variations thereof refer to a differentiated T helper cell that expresses one or more cytokines selected from the group the consisting of interleukin 4 (IL-4), interleukin 5 (IL-5) and interleukin 13 (IL-13). As used herein, terms such as “Treg cell” and/or “Treg phenotype” and all grammatical variations thereof refer to a differentiated T cell that expresses Foxp3.

In some embodiments, the modulating of a cell or tissue comprises modulating a lymph node immune cell. A lymph node is an organ of the lymphatic system and of the adaptive immune system, that is widely present throughout the body. Lymph nodes are linked by the lymphatic vessels as a part of the circulatory system and are major sites of B and T lymphocytes. The term “lymph node immune cell” as described herein, refers to B and T lymphocytes, and other white blood cells as described herein and listed above.

In some embodiments, the modulating of a cell or tissue as described herein comprises modulating a T cell or T cell subset. Specific subsets of T cells may include, but are not necessarily limited to, CD4+ T cells, CD8+ T cells, Tregs, T helper cells, NK cells. In specific embodiments, specific subsets of T cells as described herein, include, but are not necessarily limited to, CD3⁺CD4⁺PD1⁺CXCR4⁺ T follicular helper cells or CD45RA⁻CCR7⁺CD27⁺ memory T cells.

In some embodiments, the modulating of a cell or tissue may comprise modulating a gene or gene product that is enriched for expression in HIV⁺ cells. Such genes or gene products may be more prominently expressed in HIV⁺ cells, such as for example, but not necessarily limited to, the genes and gene products listed in Tables 1 and 2.

Identifying Modulating Agents

A further aspect of the invention relates to a method for identifying an agent capable of modulating one or more phenotypic aspects of a pathogen infected cell, comprising: a) applying a candidate agent to the cell or cell population; b) detecting modulation of one or more phenotypic aspects of the cell or cell population by the candidate agent, thereby identifying the agent.

The term “modulate” broadly denotes a qualitative and/or quantitative alteration, change or variation in that which is being modulated. Where modulation can be assessed quantitatively—for example, where modulation comprises or consists of a change in a quantifiable variable such as a quantifiable property of a cell or where a quantifiable variable provides a suitable surrogate for the modulation—modulation specifically encompasses both increase (e.g., activation) or decrease (e.g., inhibition) in the measured variable. The term encompasses any extent of such modulation, e.g., any extent of such increase or decrease, and may more particularly refer to statistically significant increase or decrease in the measured variable. By means of example, modulation may encompass an increase in the value of the measured variable by at least about 10%, e.g., by at least about 20%, preferably by at least about 30%, e.g., by at least about 40%, more preferably by at least about 50%, e.g., by at least about 75%, even more preferably by at least about 100%, e.g., by at least about 150%, 200%, 250%, 300%, 400% or by at least about 500%, compared to a reference situation without said modulation; or modulation may encompass a decrease or reduction in the value of the measured variable by at least about 10%, e.g., by at least about 20%, by at least about 30%, e.g., by at least about 40%, by at least about 50%, e.g., by at least about 60%, by at least about 70%, e.g., by at least about 80%, by at least about 90%, e.g., by at least about 95%, such as by at least about 96%, 97%, 98%, 99% or even by 100%, compared to a reference situation without said modulation. Preferably, modulation may be specific or selective, hence, one or more desired phenotypic aspects of a gut cell or gut cell population may be modulated without substantially altering other (unintended, undesired) phenotypic aspect(s).

The term “agent” broadly encompasses any condition, substance or agent capable of modulating one or more phenotypic aspects of cell or cell population as disclosed herein. Such conditions, substances or agents may be of physical, chemical, biochemical and/or biological nature. The term “candidate agent” refers to any condition, substance or agent that is being examined for the ability to modulate one or more phenotypic aspects of an gut cell or gut cell population as disclosed herein in a method comprising applying the candidate agent to the gut cell or gut cell population (e.g., exposing the gut cell or gut cell population to the candidate agent or contacting the gut cell or gut cell population with the candidate agent) and observing whether the desired modulation takes place.

Agents may include any potential class of biologically active conditions, substances or agents, such as for instance antibodies, proteins, peptides, nucleic acids, oligonucleotides, small molecules, or combinations thereof.

By means of example but without limitation, agents can include low molecular weight compounds, but may also be larger compounds, or any organic or inorganic molecule effective in the given situation, including modified and unmodified nucleic acids such as antisense nucleic acids, RNAi, such as siRNA or shRNA, CRISPR/Cas systems, peptides, peptidomimetics, receptors, ligands, and antibodies, aptamers, polypeptides, nucleic acid analogues or variants thereof. Examples include an oligomer of nucleic acids, amino acids, or carbohydrates including without limitation proteins, oligonucleotides, ribozymes, DNAzymes, glycoproteins, siRNAs, lipoproteins, aptamers, and modifications and combinations thereof. Agents can be selected from a group comprising: chemicals; small molecules; nucleic acid sequences; nucleic acid analogues; proteins; peptides; aptamers; antibodies; or fragments thereof. A nucleic acid sequence can be RNA or DNA, and can be single or double stranded, and can be selected from a group comprising; nucleic acid encoding a protein of interest, oligonucleotides, nucleic acid analogues, for example peptide-nucleic acid (PNA), pseudo-complementary PNA (pc-PNA), locked nucleic acid (LNA), modified RNA (mod-RNA), single guide RNA etc. Such nucleic acid sequences include, for example, but are not limited to, nucleic acid sequence encoding proteins, for example that act as transcriptional repressors, antisense molecules, ribozymes, small inhibitory nucleic acid sequences, for example but are not limited to RNAi, shRNAi, siRNA, micro RNAi (mRNAi), antisense oligonucleotides, CRISPR guide RNA, for example that target a CRISPR enzyme to a specific DNA target sequence etc. A protein and/or peptide or fragment thereof can be any protein of interest, for example, but are not limited to: mutated proteins; therapeutic proteins and truncated proteins, wherein the protein is normally absent or expressed at lower levels in the cell. Proteins can also be selected from a group comprising; mutated proteins, genetically engineered proteins, peptides, synthetic peptides, recombinant proteins, chimeric proteins, antibodies, midibodies, minibodies, triabodies, humanized proteins, humanized antibodies, chimeric antibodies, modified proteins and fragments thereof. Alternatively, the agent can be intracellular within the cell as a result of introduction of a nucleic acid sequence into the cell and its transcription resulting in the production of the nucleic acid and/or protein modulator of a gene within the cell. In some embodiments, the agent is any chemical, entity or moiety, including without limitation synthetic and naturally-occurring non-proteinaceous entities. In certain embodiments, the agent is a small molecule having a chemical moiety. Agents can be known to have a desired activity and/or property, or can be selected from a library of diverse compounds.

In certain embodiments, an agent may be a hormone, a cytokine, a lymphokine, a growth factor, a chemokine, a cell surface receptor ligand such as a cell surface receptor agonist or antagonist, or a mitogen.

Non-limiting examples of hormones include growth hormone (GH), adrenocorticotropic hormone (ACTH), dehydroepiandrosterone (DHEA), cortisol, epinephrine, thyroid hormone, estrogen, progesterone, testosterone, or combinations thereof.

Non-limiting examples of cytokines include lymphokines (e.g., interferon-γ, IL-2, IL-3, IL-4, IL-6, granulocyte-macrophage colony-stimulating factor (GM-CSF), interferon-y, leukocyte migration inhibitory factors (T-LIF, B-LIF), lymphotoxin-alpha, macrophage-activating factor (MAF), macrophage migration-inhibitory factor (MIF), neuroleukin, immunologic suppressor factors, transfer factors, or combinations thereof), monokines (e.g., IL-1, TNF-alpha, interferon-α, interferon-β, colony stimulating factors, e.g., CSF2, CSF3, macrophage CSF or GM-CSF, or combinations thereof), chemokines (e.g., beta-thromboglobulin, C chemokines, CC chemokines, CXC chemokines, CX3C chemokines, macrophage inflammatory protein (MIP), or combinations thereof), interleukins (e.g., IL-1, IL-2, IL-3, IL-4, IL-5, IL-6, IL-7, IL-8, IL-9, IL-10, IL-11, IL-12, IL-13, IL-14, IL-15, IL-17, IL-18, IL-19, IL-20, IL-21, IL-22, IL-23, IL-24, IL-25, IL-26, IL-27, IL-28, IL-29, IL-30, IL-31, IL-32, IL-33, IL-34, IL-35, IL-36, or combinations thereof), and several related signaling molecules, such as tumour necrosis factor (TNF) and interferons (e.g., interferon-α, interferon-β, interferon-γ, interferon-λ, or combinations thereof).

Non-limiting examples of growth factors include those of fibroblast growth factor (FGF) family, bone morphogenic protein (BMP) family, platelet derived growth factor (PDGF) family, transforming growth factor beta (TGFbeta) family, nerve growth factor (NGF) family, epidermal growth factor (EGF) family, insulin related growth factor (IGF) family, hepatocyte growth factor (HGF) family, hematopoietic growth factors (HeGFs), platelet-derived endothelial cell growth factor (PD-ECGF), angiopoietin, vascular endothelial growth factor (VEGF) family, glucocorticoids, or combinations thereof.

Non-limiting examples of mitogens include phytohaemagglutinin (PHA), concanavalin A (conA), lipopolysaccharide (LPS), pokeweed mitogen (PWM), phorbol ester such as phorbol myristate acetate (PMA) with or without ionomycin, or combinations thereof.

Non-limiting examples of cell surface receptors the ligands of which may act as agents include Toll-like receptors (TLRs) (e.g., TLR1, TLR2, TLR3, TLR4, TLR5, TLR6, TLR7, TLR8, TLR9, TLR10, TLR11, TLR12 or TLR13), CD80, CD86, CD40, CCR7, or C-type lectin receptors.

Particular screening applications of this invention relate to the testing of pharmaceutical compounds in drug research. The reader is referred generally to the standard textbook In vitro Methods in Pharmaceutical Research, Academic Press, 1997, and U.S. Pat. No. 5,030,015. In certain aspects of this invention, the culture of the invention is used to grow and differentiate a cachectic target cell to play the role of test cells for standard drug screening and toxicity assays. Assessment of the activity of candidate pharmaceutical compounds generally involves combining the target cell (e.g., a myocyte, an adipocyte, a cardiomyocyte or a hepatocyte) with the candidate compound, determining any change in the morphology, marker phenotype, or metabolic activity of the cells that is attributable to the candidate compound (compared with untreated cells or cells treated with an inert compound, such as vehicle), and then correlating the effect of the candidate compound with the observed change. The screening may be done because the candidate compound is designed to have a pharmacological effect on the target cell, or because a candidate compound may have unintended side effects on the target cell. Alternatively, libraries can be screened without any predetermined expectations in hopes of identifying compounds with desired effects.

Cytotoxicity can be determined in the first instance by the effect on cell viability and morphology. In certain embodiments, toxicity may be assessed by observation of vital staining techniques, ELISA assays, immunohistochemistry, and the like or by analyzing the cellular content of the culture, e.g., by total cell counts, and differential cell counts or by metabolic markers such as MTT and XTT.

Additional further uses of the culture of the invention include, but are not limited to, its use in research e.g., to elucidate mechanisms leading to the identification of novel targets for therapies, and to generate genotype-specific cells for disease modeling, including the generation of new therapies customized to different genotypes. Such customization can reduce adverse drug effects and help identify therapies appropriate to the patient's genotype.

In certain embodiments, the present invention provides method for high-throughput screening. “High-throughput screening” (HTS) refers to a process that uses a combination of modern robotics, data processing and control software, liquid handling devices, and/or sensitive detectors, to efficiently process a large amount of (e.g., thousands, hundreds of thousands, or millions of) samples in biochemical, genetic or pharmacological experiments, either in parallel or in sequence, within a reasonably short period of time (e.g., days). Preferably, the process is amenable to automation, such as robotic simultaneous handling of 96 samples, 384 samples, 1536 samples or more. A typical HTS robot tests up to 100,000 to a few hundred thousand compounds per day. The samples are often in small volumes, such as no more than 1 mL, 500 μl, 200 μl, 100 μl, 50 μl or less. Through this process, one can rapidly identify active compounds, small molecules, antibodies, proteins or polynucleotides which modulate a particular biomolecular/genetic pathway. The results of these experiments provide starting points for further drug design and for understanding the interaction or role of a particular biochemical process in biology. Thus “high-throughput screening” as used herein does not include handling large quantities of radioactive materials, slow and complicated operator-dependent screening steps, and/or prohibitively expensive reagent costs, etc.

In certain embodiments, the present invention provides for gene signature screening. The concept of signature screening was introduced by Stegmaier et al. (Gene expression-based high-throughput screening (GE-HTS) and application to leukemia differentiation. Nature Genet. 36, 257-263 (2004)), who realized that if a gene-expression signature was the proxy for a phenotype of interest, it could be used to find small molecules that effect that phenotype without knowledge of a validated drug target. The signatures of the present invention may be used to screen for drugs that induce or reduce the signature in immune cells as described herein. The signature may be used for GE-HTS (Gene Expression-based High-Throughput Screening). In certain embodiments, pharmacological screens may be used to identify drugs that selectively activate gut cells.

The Connectivity Map (cmap) is a collection of genome-wide transcriptional expression data from cultured human cells treated with bioactive small molecules and simple pattern-matching algorithms that together enable the discovery of functional connections between drugs, genes and diseases through the transitory feature of common gene-expression changes (see, Lamb et al., The Connectivity Map: Using Gene-Expression Signatures to Connect Small Molecules, Genes, and Disease. Science 29 Sep. 2006: Vol. 313, Issue 5795, pp. 1929-1935, DOI: 10.1126/science.1132939; and Lamb, J., The Connectivity Map: a new tool for biomedical research. Nature Reviews Cancer January 2007: Vol. 7, pp. 54-60). In certain embodiments, Cmap can be used to screen for small molecules capable of modulating a signature of the present invention in silico.

Genetic Modification

In certain embodiments, one or more endogenous genes may be modified using a nuclease. The term “nuclease” as used herein broadly refers to an agent, for example a protein or a small molecule, capable of cleaving a phosphodiester bond connecting nucleotide residues in a nucleic acid molecule. In some embodiments, a nuclease may be a protein, e.g., an enzyme that can bind a nucleic acid molecule and cleave a phosphodiester bond connecting nucleotide residues within the nucleic acid molecule. A nuclease may be an endonuclease, cleaving a phosphodiester bonds within a polynucleotide chain, or an exonuclease, cleaving a phosphodiester bond at the end of the polynucleotide chain. Preferably, the nuclease is an endonuclease. Preferably, the nuclease is a site-specific nuclease, binding and/or cleaving a specific phosphodiester bond within a specific nucleotide sequence, which may be referred to as “recognition sequence”, “nuclease target site”, or “target site”. In some embodiments, a nuclease may recognize a single stranded target site, in other embodiments a nuclease may recognize a double-stranded target site, for example a double-stranded DNA target site. Some endonucleases cut a double-stranded nucleic acid target site symmetrically, i.e., cutting both strands at the same position so that the ends comprise base-paired nucleotides, also known as blunt ends. Other endonucleases cut a double-stranded nucleic acid target sites asymmetrically, i.e., cutting each strand at a different position so that the ends comprise unpaired nucleotides. Unpaired nucleotides at the end of a double-stranded DNA molecule are also referred to as “overhangs”, e.g., “5′-overhang” or “3′-overhang”, depending on whether the unpaired nucleotide(s) form(s) the 5′ or the 5′ end of the respective DNA strand.

The nuclease may introduce one or more single-strand nicks and/or double-strand breaks in the endogenous gene, whereupon the sequence of the endogenous gene may be modified or mutated via non-homologous end joining (NHEJ) or homology-directed repair (HDR).

In certain embodiments, the nuclease may comprise (i) a DNA-binding portion configured to specifically bind to the endogenous gene and (ii) a DNA cleavage portion. Generally, the DNA cleavage portion will cleave the nucleic acid within or in the vicinity of the sequence to which the DNA-binding portion is configured to bind.

In certain embodiments, the DNA-binding portion may comprise a zinc finger protein or DNA-binding domain thereof, a transcription activator-like effector (TALE) protein or DNA-binding domain thereof, or an RNA-guided protein or DNA-binding domain thereof.

In certain embodiments, the DNA-binding portion may comprise (i) Cas9 or Cpf1 or any Cas protein described herein modified to eliminate its nuclease activity, or (ii) DNA-binding domain of Cas9 or Cpf1 or any Cas protein described herein.

In certain embodiments, the DNA cleavage portion comprises FokI or variant thereof or DNA cleavage domain of FokI or variant thereof.

In certain embodiments, the nuclease may be an RNA-guided nuclease, such as Cas9 or Cpf1 or any Cas protein described herein.

With respect to general information on CRISPR-Cas Systems, components thereof, and delivery of such components, including methods, materials, delivery vehicles, vectors, particles, AAV, and making and using thereof, including as to amounts and formulations, all useful in the practice of the instant invention, reference is made to: U.S. Pat. Nos. 8,999,641, 8,993,233, 8,945,839, 8,932,814, 8,906,616, 8,895,308, 8,889,418, 8,889,356, 8,871,445, 8,865,406, 8,795,965, 8,771,945 and 8,697,359; US Patent Publications US 2014-0310830 (U.S. application Ser. No. 14/105,031), US 2014-0287938 A1 (U.S. application Ser. No. 14/213,991), US 2014-0273234 A1 (U.S. application Ser. No. 14/293,674), US2014-0273232 A1 (U.S. application Ser. No. 14/290,575), US 2014-0273231 (U.S. application Ser. No. 14/259,420), US 2014-0256046 A1 (U.S. application Ser. No. 14/226,274), US 2014-0248702 A1 (U.S. application Ser. No. 14/258,458), US 2014-0242700 A1 (U.S. application Ser. No. 14/222,930), US 2014-0242699 A1 (U.S. application Ser. No. 14/183,512), US 2014-0242664 A1 (U.S. application Ser. No. 14/104,990), US 2014-0234972 A1 (U.S. application Ser. No. 14/183,471), US 2014-0227787 A1 (U.S. application Ser. No. 14/256,912), US 2014-0189896 A1 (U.S. application Ser. No. 14/105,035), US 2014-0186958 (U.S. application Ser. No. 14/105,017), US 2014-0186919 A1 (U.S. application Ser. No. 14/104,977), US 2014-0186843 A1 (U.S. application Ser. No. 14/104,900), US 2014-0179770 A1 (U.S. application Ser. No. 14/104,837) and US 2014-0179006 A1 (U.S. application Ser. No. 14/183,486), US 2014-0170753 (U.S. application Ser. No. 14/183,429); European Patents EP 2 784 162 B 1 and EP 2 771 468 B 1; European Patent Applications EP 2 771 468 (EP13818570.7), EP 2 764 103 (EP13824232.6), and EP 2 784 162 (EP14170383.5); and PCT Patent Publications PCT Patent Publications WO 2014/093661 (PCT/US2013/074743), WO 2014/093694 (PCT/US2013/074790), WO 2014/093595 (PCT/US2013/074611), WO 2014/093718 (PCT/US2013/074825), WO 2014/093709 (PCT/US2013/074812), WO 2014/093622 (PCT/US2013/074667), WO 2014/093635 (PCT/US2013/074691), WO 2014/093655 (PCT/US2013/074736), WO 2014/093712 (PCT/US2013/074819), WO2014/093701 (PCT/US2013/074800), WO2014/018423 (PCT/US2013/051418), WO 2014/204723 (PCT/US2014/041790), WO 2014/204724 (PCT/US2014/041800), WO 2014/204725 (PCT/US2014/041803), WO 2014/204726 (PCT/US2014/041804), WO 2014/204727 (PCT/US2014/041806), WO 2014/204728 (PCT/US2014/041808), WO 2014/204729 (PCT/US2014/041809). Reference is also made to U.S. provisional patent applications 61/758,468; 61/802,174; 61/806,375; 61/814,263; 61/819,803 and 61/828,130, filed on Jan. 30, 2013; Mar. 15, 2013; Mar. 28, 2013; Apr. 20, 2013; May 6, 2013 and May 28, 2013 respectively. Reference is also made to U.S. provisional patent application 61/836,123, filed on Jun. 17, 2013. Reference is additionally made to U.S. provisional patent applications 61/835,931, 61/835,936, 61/836,127, 61/836,101, 61/836,080 and 61/835,973, each filed Jun. 17, 2013. Further reference is made to U.S. provisional patent applications 61/862,468 and 61/862,355 filed on Aug. 5, 2013; 61/871,301 filed on Aug. 28, 2013; 61/960,777 filed on Sep. 25, 2013 and 61/961,980 filed on Oct. 28, 2013. Reference is yet further made to: PCT Patent applications Nos: PCT/US2014/041803, PCT/US2014/041800, PCT/US2014/041809, PCT/US2014/041804 and PCT/US2014/041806, each filed Jun. 10, 2014; PCT/US2014/041808 filed Jun. 11, 2014; and PCT/US2014/62558 filed Oct. 28, 2014, and U.S. Provisional Patent Applications Ser. Nos. 61/915,150, 61/915,301, 61/915,267 and 61/915,260, each filed Dec. 12, 2013; 61/757,972 and 61/768,959, filed on Jan. 29, 2013 and Feb. 25, 2013; 61/835,936, 61/836,127, 61/836,101, 61/836,080, 61/835,973, and 61/835,931, filed Jun. 17, 2013; 62/010,888 and 62/010,879, both filed Jun. 11, 2014; 62/010,329 and 62/010,441, each filed Jun. 10, 2014; 61/939,228 and 61/939,242, each filed Feb. 12, 2014; 61/980,012, filed Apr. 15, 2014; 62/038,358, filed Aug. 17, 2014; 62/054,490, 62/055,484, 62/055,460 and 62/055,487, each filed Sep. 25, 2014; and 62/069,243, filed Oct. 27, 2014. Reference is also made to U.S. provisional patent applications Nos. 62/055,484, 62/055,460, and 62/055,487, filed Sep. 25, 2014; U.S. provisional patent application 61/980,012, filed Apr. 15, 2014; and U.S. provisional patent application 61/939,242 filed Feb. 12, 2014. Reference is made to PCT application designating, inter alia, the United States, application No. PCT/US14/41806, filed Jun. 10, 2014. Reference is made to U.S. provisional patent application 61/930,214 filed on Jan. 22, 2014. Reference is made to U.S. provisional patent applications 61/915,251; 61/915,260 and 61/915,267, each filed on Dec. 12, 2013. Reference is made to US provisional patent application U.S. Ser. No. 61/980,012 filed Apr. 15, 2014. Reference is made to PCT application designating, inter alia, the United States, application No. PCT/US14/41806, filed Jun. 10, 2014. Reference is made to U.S. provisional patent application 61/930,214 filed on Jan. 22, 2014. Reference is made to U.S. provisional patent applications 61/915,251; 61/915,260 and 61/915,267, each filed on Dec. 12, 2013.

Mention is also made of U.S. application 62/091,455, filed, 12 Dec. 14, PROTECTED GUIDE RNAS (PGRNAS); U.S. application 62/096,708, 24 Dec. 14, PROTECTED GUIDE RNAS (PGRNAS); U.S. application 62/091,462, 12 Dec. 14, DEAD GUIDES FOR CRISPR TRANSCRIPTION FACTORS; U.S. application 62/096,324, 23 Dec. 14, DEAD GUIDES FOR CRISPR TRANSCRIPTION FACTORS; U.S. application 62/091,456, 12 Dec. 14, ESCORTED AND FUNCTIONALIZED GUIDES FOR CRISPR-CAS SYSTEMS; U.S. application 62/091,461, 12-Dec-14, DELIVERY, USE AND THERAPEUTIC APPLICATIONS OF THE CRISPR-CAS SYSTEMS AND COMPOSITIONS FOR GENOME EDITING AS TO HEMATOPOIETIC STEM CELLS (HSCs); U.S. application 62/094,903, 19 Dec. 14, UNBIASED IDENTIFICATION OF DOUBLE-STRAND BREAKS AND GENOMIC REARRANGEMENT BY GENOME-WISE INSERT CAPTURE SEQUENCING; U.S. application 62/096,761, 24 Dec. 14, ENGINEERING OF SYSTEMS, METHODS AND OPTIMIZED ENZYME AND GUIDE SCAFFOLDS FOR SEQUENCE MANIPULATION; U.S. application 62/098,059, 30 Dec. 14, RNA-TARGETING SYSTEM; U.S. application 62/096,656, 24-Dec-14, CRISPR HAVING OR ASSOCIATED WITH DESTABILIZATION DOMAINS; U.S. application 62/096,697, 24 Dec. 14, CRISPR HAVING OR ASSOCIATED WITH AAV; U.S. application 62/098,158, 30 Dec. 14, ENGINEERED CRISPR COMPLEX INSERTIONAL TARGETING SYSTEMS; U.S. application 62/151,052, 22 Apr. 15, CELLULAR TARGETING FOR EXTRACELLULAR EXOSOMAL REPORTING; U.S. application 62/054,490, 24 Sep. 14, DELIVERY, USE AND THERAPEUTIC APPLICATIONS OF THE CRISPR-CAS SYSTEMS AND COMPOSITIONS FOR TARGETING DISORDERS AND DISEASES USING PARTICLE DELIVERY COMPONENTS; U.S. application 62/055,484, 25 Sep. 14, SYSTEMS, METHODS AND COMPOSITIONS FOR SEQUENCE MANIPULATION WITH OPTIMIZED FUNCTIONAL CRISPR-CAS SYSTEMS; U.S. application 62/087,537, 4 Dec. 14, SYSTEMS, METHODS AND COMPOSITIONS FOR SEQUENCE MANIPULATION WITH OPTIMIZED FUNCTIONAL CRISPR-CAS SYSTEMS; U.S. application 62/054,651, 24 Sep. 14, DELIVERY, USE AND THERAPEUTIC APPLICATIONS OF THE CRISPR-CAS SYSTEMS AND COMPOSITIONS FOR MODELING COMPETITION OF MULTIPLE CANCER MUTATIONS IN VIVO; U.S. application 62/067,886, 23 Oct. 14, DELIVERY, USE AND THERAPEUTIC APPLICATIONS OF THE CRISPR-CAS SYSTEMS AND COMPOSITIONS FOR MODELING COMPETITION OF MULTIPLE CANCER MUTATIONS IN VIVO; U.S. application 62/054,675, 24 Sep. 14, DELIVERY, USE AND THERAPEUTIC APPLICATIONS OF THE CRISPR-CAS SYSTEMS AND COMPOSITIONS IN NEURONAL CELLS/TISSUES; U.S. application 62/054,528, 24 Sep. 14, DELIVERY, USE AND THERAPEUTIC APPLICATIONS OF THE CRISPR-CAS SYSTEMS AND COMPOSITIONS IN IMMUNE DISEASES OR DISORDERS; U.S. application 62/055,454, 25 Sep. 14, DELIVERY, USE AND THERAPEUTIC APPLICATIONS OF THE CRISPR-CAS SYSTEMS AND COMPOSITIONS FOR TARGETING DISORDERS AND DISEASES USING CELL PENETRATION PEPTIDES (CPP); U.S. application 62/055,460, 25 Sep. 14, MULTIFUNCTIONAL-CRISPR COMPLEXES AND/OR OPTIMIZED ENZYME LINKED FUNCTIONAL-CRISPR COMPLEXES; U.S. application 62/087,475, 4 Dec. 14, FUNCTIONAL SCREENING WITH OPTIMIZED FUNCTIONAL CRISPR-CAS SYSTEMS; U.S. application 62/055,487, 25 Sep. 14, FUNCTIONAL SCREENING WITH OPTIMIZED FUNCTIONAL CRISPR-CAS SYSTEMS; U.S. application 62/087,546, 4 Dec. 14, MULTIFUNCTIONAL CRISPR COMPLEXES AND/OR OPTIMIZED ENZYME LINKED FUNCTIONAL-CRISPR COMPLEXES; and U.S. application 62/098,285, 30 Dec. 14, CRISPR MEDIATED IN VIVO MODELING AND GENETIC SCREENING OF TUMOR GROWTH AND METASTASIS.

Each of these patents, patent publications, and applications, and all documents cited therein or during their prosecution (“appln cited documents”) and all documents cited or referenced in the appln cited documents, together with any instructions, descriptions, product specifications, and product sheets for any products mentioned therein or in any document therein and incorporated by reference herein, are hereby incorporated herein by reference, and may be employed in the practice of the invention. All documents (e.g., these patents, patent publications and applications and the appln cited documents) are incorporated herein by reference to the same extent as if each individual document was specifically and individually indicated to be incorporated by reference.

Also with respect to general information on CRISPR-Cas Systems, mention is made of the following (also hereby incorporated herein by reference):

Multiplex genome engineering using CRISPR/Cas systems. Cong, L., Ran, F. A., Cox, D., Lin, S., Barretto, R., Habib, N., Hsu, P. D., Wu, X., Jiang, W., Marraffini, L. A., & Zhang, F. Science February 15; 339(6121):819-23 (2013);
RNA-guided editing of bacterial genomes using CRISPR-Cas systems. Jiang W., Bikard D., Cox D., Zhang F, Marraffini L A. Nat Biotechnol March; 31(3):233-9 (2013);
One-Step Generation of Mice Carrying Mutations in Multiple Genes by CRISPR/Cas-Mediated Genome Engineering. Wang H., Yang H., Shivalila C S., Dawlaty M M., Cheng A W., Zhang F., Jaenisch R. Cell May 9; 153(4):910-8 (2013);
Optical control of mammalian endogenous transcription and epigenetic states. Konermann S, Brigham M D, Trevino A E, Hsu P D, Heidenreich M, Cong L, Platt R J, Scott D A, Church G M, Zhang F. Nature. August 22; 500(7463):472-6. doi: 10.1038/Nature12466. Epub 2013 Aug. 23 (2013);
Double Nicking by RNA-Guided CRISPR Cas9 for Enhanced Genome Editing Specificity. Ran, F A., Hsu, P D., Lin, C Y., Gootenberg, J S., Konermann, S., Trevino, A E., Scott, D A., Inoue, A., Matoba, S., Zhang, Y., & Zhang, F. Cell August 28. pii: S0092-8674(13)01015-5 (2013-A);
DNA targeting specificity of RNA-guided Cas9 nucleases. Hsu, P., Scott, D., Weinstein, J., Ran, F A., Konermann, S., Agarwala, V., Li, Y., Fine, E., Wu, X., Shalem, O., Cradick, T J., Marraffini, L A., Bao, G., & Zhang, F. Nat Biotechnol doi:10.1038/nbt.2647 (2013);
Genome engineering using the CRISPR-Cas9 system. Ran, F A., Hsu, P D., Wright, J., Agarwala, V., Scott, D A., Zhang, F. Nature Protocols November; 8(11):2281-308 (2013-B);
Genome-Scale CRISPR-Cas9 Knockout Screening in Human Cells. Shalem, O., Sanjana, N E., Hartenian, E., Shi, X., Scott, D A., Mikkelson, T., Heckl, D., Ebert, BL., Root, D E., Doench, J G., Zhang, F. Science December 12. (2013). [Epub ahead of print];
Crystal structure of cas9 in complex with guide RNA and target DNA. Nishimasu, H., Ran, F A., Hsu, P D., Konermann, S., Shehata, S I., Dohmae, N., Ishitani, R., Zhang, F., Nureki, O. Cell February 27, 156(5):935-49 (2014);
Genome-wide binding of the CRISPR endonuclease Cas9 in mammalian cells. Wu X., Scott D A., Kriz A J., Chiu A C., Hsu P D., Dadon D B., Cheng A W., Trevino A E., Konermann S., Chen S., Jaenisch R., Zhang F., Sharp P A. Nat Biotechnol. April 20. doi: 10.1038/nbt.2889 (2014);
CRISPR-Cas9 Knockin Mice for Genome Editing and Cancer Modeling. Platt R J, Chen S, Zhou Y, Yim M J, Swiech L, Kempton H R, Dahlman J E, Parnas O, Eisenhaure T M, Jovanovic M, Graham D B, Jhunjhunwala S, Heidenreich M, Xavier R J, Langer R, Anderson D G, Hacohen N, Regev A, Feng G, Sharp P A, Zhang F. Cell 159(2): 440-455 DOI: 10.1016/j.cell.2014.09.014 (2014);
Development and Applications of CRISPR-Cas9 for Genome Engineering, Hsu P D, Lander E S, Zhang F., Cell. June 5; 157(6):1262-78 (2014).
Genetic screens in human cells using the CRISPR/Cas9 system, Wang T, Wei J J, Sabatini D M, Lander E S., Science. January 3; 343(6166): 80-84. doi:10.1126/science.1246981 (2014);
Rational design of highly active sgRNAs for CRISPR-Cas9-mediated gene inactivation, Doench J G, Hartenian E, Graham D B, Tothova Z, Hegde M, Smith I, Sullender M, Ebert B L, Xavier R J, Root D E., (published online 3 Sep. 2014) Nat Biotechnol. December; 32(12):1262-7 (2014);
In vivo interrogation of gene function in the mammalian brain using CRISPR-Cas9, Swiech L, Heidenreich M, Banerjee A, Habib N, Li Y, Trombetta J, Sur M, Zhang F., (published online 19 Oct. 2014) Nat Biotechnol. January; 33(1):102-6 (2015);
Genome-scale transcriptional activation by an engineered CRISPR-Cas9 complex, Konermann S, Brigham M D, Trevino A E, Joung J, Abudayyeh O O, Barcena C, Hsu P D, Habib N, Gootenberg J S, Nishimasu H, Nureki O, Zhang F., Nature. January 29; 517(7536):583-8 (2015).
A split-Cas9 architecture for inducible genome editing and transcription modulation, Zetsche B, Volz S E, Zhang F., (published online 2 Feb. 2015) Nat Biotechnol. February; 33(2):139-42 (2015);
Genome-wide CRISPR Screen in a Mouse Model of Tumor Growth and Metastasis, Chen S, Sanjana N E, Zheng K, Shalem O, Lee K, Shi X, Scott D A, Song J, Pan J Q, Weissleder R, Lee H, Zhang F, Sharp P A. Cell 160, 1246-1260, Mar. 12, 2015 (multiplex screen in mouse), and
In vivo genome editing using Staphylococcus aureus Cas9, Ran F A, Cong L, Yan W X, Scott D A, Gootenberg J S, Kriz A J, Zetsche B, Shalem O, Wu X, Makarova K S, Koonin E V, Sharp P A, Zhang F., (published online 1 Apr. 2015), Nature. April 9; 520(7546):186-91 (2015).
Shalem et al., “High-throughput functional genomics using CRISPR-Cas9,” Nature Reviews Genetics 16, 299-311 (May 2015).
Xu et al., “Sequence determinants of improved CRISPR sgRNA design,” Genome Research 25, 1147-1157 (August 2015).
Parnas et al., “A Genome-wide CRISPR Screen in Primary Immune Cells to Dissect Regulatory Networks,” Cell 162, 675-686 (Jul. 30, 2015).
Ramanan et al., CRISPR/Cas9 cleavage of viral DNA efficiently suppresses hepatitis B virus,” Scientific Reports 5:10833. doi: 10.1038/srep10833 (Jun. 2, 2015)
Nishimasu et al., Crystal Structure of Staphylococcus aureus Cas9,” Cell 162, 1113-1126 (Aug. 27, 2015)
Zetsche et al., “Cpf1 Is a Single RNA-Guided Endonuclease of a Class 2 CRISPR-Cas System,” Cell 163, 1-13 (Oct. 22, 2015)
Shmakov et al., “Discovery and Functional Characterization of Diverse Class 2 CRISPR-Cas Systems,” Molecular Cell 60, 1-13 (Available online Oct. 22, 2015)
- each of which is incorporated herein by reference, may be considered in the practice of the instant invention, and discussed briefly below:

Cong et al. engineered type II CRISPR-Cas systems for use in eukaryotic cells based on both Streptococcus thermophilus Cas9 and also Streptococcus pyogenes Cas9 and demonstrated that Cas9 nucleases can be directed by short RNAs to induce precise cleavage of DNA in human and mouse cells. Their study further showed that Cas9 as converted into a nicking enzyme can be used to facilitate homology-directed repair in eukaryotic cells with minimal mutagenic activity. Additionally, their study demonstrated that multiple guide sequences can be encoded into a single CRISPR array to enable simultaneous editing of several at endogenous genomic loci sites within the mammalian genome, demonstrating easy programmability and wide applicability of the RNA-guided nuclease technology. This ability to use RNA to program sequence specific DNA cleavage in cells defined a new class of genome engineering tools. These studies further showed that other CRISPR loci are likely to be transplantable into mammalian cells and can also mediate mammalian genome cleavage. Importantly, it can be envisaged that several aspects of the CRISPR-Cas system can be further improved to increase its efficiency and versatility.

Jiang et al. used the clustered, regularly interspaced, short palindromic repeats (CRISPR)-associated Cas9 endonuclease complexed with dual-RNAs to introduce precise mutations in the genomes of Streptococcus pneumoniae and Escherichia coli. The approach relied on dual-RNA:Cas9-directed cleavage at the targeted genomic site to kill unmutated cells and circumvents the need for selectable markers or counter-selection systems. The study reported reprogramming dual-RNA:Cas9 specificity by changing the sequence of short CRISPR RNA (crRNA) to make single- and multinucleotide changes carried on editing templates. The study showed that simultaneous use of two crRNAs enabled multiplex mutagenesis. Furthermore, when the approach was used in combination with recombineering, in S. pneumoniae, nearly 100% of cells that were recovered using the described approach contained the desired mutation, and in E. coli, 65% that were recovered contained the mutation.

Wang et al. (2013) used the CRISPR/Cas system for the one-step generation of mice carrying mutations in multiple genes which were traditionally generated in multiple steps by sequential recombination in embryonic stem cells and/or time-consuming intercrossing of mice with a single mutation. The CRISPR/Cas system will greatly accelerate the in vivo study of functionally redundant genes and of epistatic gene interactions.

Konermann et al. (2013) addressed the need in the art for versatile and robust technologies that enable optical and chemical modulation of DNA-binding domains based CRISPR Cas9 enzyme and also Transcriptional Activator Like Effectors

Ran et al. (2013-A) described an approach that combined a Cas9 nickase mutant with paired guide RNAs to introduce targeted double-strand breaks. This addresses the issue of the Cas9 nuclease from the microbial CRISPR-Cas system being targeted to specific genomic loci by a guide sequence, which can tolerate certain mismatches to the DNA target and thereby promote undesired off-target mutagenesis. Because individual nicks in the genome are repaired with high fidelity, simultaneous nicking via appropriately offset guide RNAs is required for double-stranded breaks and extends the number of specifically recognized bases for target cleavage. The authors demonstrated that using paired nicking can reduce off-target activity by 50- to 1,500-fold in cell lines and to facilitate gene knockout in mouse zygotes without sacrificing on-target cleavage efficiency. This versatile strategy enables a wide variety of genome editing applications that require high specificity.

Hsu et al. (2013) characterized SpCas9 targeting specificity in human cells to inform the selection of target sites and avoid off-target effects. The study evaluated >700 guide RNA variants and SpCas9-induced indel mutation levels at >100 predicted genomic off-target loci in 293T and 293FT cells. The authors that SpCas9 tolerates mismatches between guide RNA and target DNA at different positions in a sequence-dependent manner, sensitive to the number, position and distribution of mismatches. The authors further showed that SpCas9-mediated cleavage is unaffected by DNA methylation and that the dosage of SpCas9 and sgRNA can be titrated to minimize off-target modification. Additionally, to facilitate mammalian genome engineering applications, the authors reported providing a web-based software tool to guide the selection and validation of target sequences as well as off-target analyses.

Ran et al. (2013-B) described a set of tools for Cas9-mediated genome editing via non-homologous end joining (NHEJ) or homology-directed repair (HDR) in mammalian cells, as well as generation of modified cell lines for downstream functional studies. To minimize off-target cleavage, the authors further described a double-nicking strategy using the Cas9 nickase mutant with paired guide RNAs. The protocol provided by the authors experimentally derived guidelines for the selection of target sites, evaluation of cleavage efficiency and analysis of off-target activity. The studies showed that beginning with target design, gene modifications can be achieved within as little as 1-2 weeks, and modified clonal cell lines can be derived within 2-3 weeks.

Shalem et al. described a new way to interrogate gene function on a genome-wide scale. Their studies showed that delivery of a genome-scale CRISPR-Cas9 knockout (GeCKO) library targeted 18,080 genes with 64,751 unique guide sequences enabled both negative and positive selection screening in human cells. First, the authors showed use of the GeCKO library to identify genes essential for cell viability in cancer and pluripotent stem cells. Next, in a melanoma model, the authors screened for genes whose loss is involved in resistance to vemurafenib, a therapeutic that inhibits mutant protein kinase BRAF. Their studies showed that the highest-ranking candidates included previously validated genes NF1 and MED12 as well as novel hits NF2, CUL3, TADA2B, and TADA1. The authors observed a high level of consistency between independent guide RNAs targeting the same gene and a high rate of hit confirmation, and thus demonstrated the promise of genome-scale screening with Cas9.

Nishimasu et al. reported the crystal structure of Streptococcus pyogenes Cas9 in complex with sgRNA and its target DNA at 2.5 A° resolution. The structure revealed a bilobed architecture composed of target recognition and nuclease lobes, accommodating the sgRNA:DNA heteroduplex in a positively charged groove at their interface. Whereas the recognition lobe is essential for binding sgRNA and DNA, the nuclease lobe contains the HNH and RuvC nuclease domains, which are properly positioned for cleavage of the complementary and non-complementary strands of the target DNA, respectively. The nuclease lobe also contains a carboxyl-terminal domain responsible for the interaction with the protospacer adjacent motif (PAM). This high-resolution structure and accompanying functional analyses have revealed the molecular mechanism of RNA-guided DNA targeting by Cas9, thus paving the way for the rational design of new, versatile genome-editing technologies.

Wu et al. mapped genome-wide binding sites of a catalytically inactive Cas9 (dCas9) from Streptococcus pyogenes loaded with single guide RNAs (sgRNAs) in mouse embryonic stem cells (mESCs). The authors showed that each of the four sgRNAs tested targets dCas9 to between tens and thousands of genomic sites, frequently characterized by a 5-nucleotide seed region in the sgRNA and an NGG protospacer adjacent motif (PAM). Chromatin inaccessibility decreases dCas9 binding to other sites with matching seed sequences; thus 70% of off-target sites are associated with genes. The authors showed that targeted sequencing of 295 dCas9 binding sites in mESCs transfected with catalytically active Cas9 identified only one site mutated above background levels. The authors proposed a two-state model for Cas9 binding and cleavage, in which a seed match triggers binding but extensive pairing with target DNA is required for cleavage.

Platt et al. established a Cre-dependent Cas9 knockin mouse. The authors demonstrated in vivo as well as ex vivo genome editing using adeno-associated virus (AAV)-, lentivirus-, or particle-mediated delivery of guide RNA in neurons, immune cells, and endothelial cells.

Hsu et al. (2014) is a review article that discusses generally CRISPR-Cas9 history from yogurt to genome editing, including genetic screening of cells.

Wang et al. (2014) relates to a pooled, loss-of-function genetic screening approach suitable for both positive and negative selection that uses a genome-scale lentiviral single guide RNA (sgRNA) library.

Doench et al. created a pool of sgRNAs, tiling across all possible target sites of a panel of six endogenous mouse and three endogenous human genes and quantitatively assessed their ability to produce null alleles of their target gene by antibody staining and flow cytometry. The authors showed that optimization of the PAM improved activity and also provided an on-line tool for designing sgRNAs.

Swiech et al. demonstrate that AAV-mediated SpCas9 genome editing can enable reverse genetic studies of gene function in the brain.

Konermann et al. (2015) discusses the ability to attach multiple effector domains, e.g., transcriptional activator, functional and epigenomic regulators at appropriate positions on the guide such as stem or tetraloop with and without linkers.

Zetsche et al. demonstrates that the Cas9 enzyme can be split into two and hence the assembly of Cas9 for activation can be controlled.

Chen et al. relates to multiplex screening by demonstrating that a genome-wide in vivo CRISPR-Cas9 screen in mice reveals genes regulating lung metastasis.

Ran et al. (2015) relates to SaCas9 and its ability to edit genomes and demonstrates that one cannot extrapolate from biochemical assays.

Shalem et al. (2015) described ways in which catalytically inactive Cas9 (dCas9) fusions are used to synthetically repress (CRISPRi) or activate (CRISPRa) expression, showing. advances using Cas9 for genome-scale screens, including arrayed and pooled screens, knockout approaches that inactivate genomic loci and strategies that modulate transcriptional activity.

Xu et al. (2015) assessed the DNA sequence features that contribute to single guide RNA (sgRNA) efficiency in CRISPR-based screens. The authors explored efficiency of CRISPR/Cas9 knockout and nucleotide preference at the cleavage site. The authors also found that the sequence preference for CRISPRi/a is substantially different from that for CRISPR/Cas9 knockout.

Parnas et al. (2015) introduced genome-wide pooled CRISPR-Cas9 libraries into dendritic cells (DCs) to identify genes that control the induction of tumor necrosis factor (Tnf) by bacterial lipopolysaccharide (LPS). Known regulators of Tlr4 signaling and previously unknown candidates were identified and classified into three functional modules with distinct effects on the canonical responses to LPS.

Ramanan et al (2015) demonstrated cleavage of viral episomal DNA (cccDNA) in infected cells. The HBV genome exists in the nuclei of infected hepatocytes as a 3.2 kb double-stranded episomal DNA species called covalently closed circular DNA (cccDNA), which is a key component in the HBV life cycle whose replication is not inhibited by current therapies. The authors showed that sgRNAs specifically targeting highly conserved regions of HBV robustly suppresses viral replication and depleted cccDNA.

Nishimasu et al. (2015) reported the crystal structures of SaCas9 in complex with a single guide RNA (sgRNA) and its double-stranded DNA targets, containing the 5′-TTGAAT-3′ PAM and the 5′-TTGGGT-3′ PAM. A structural comparison of SaCas9 with SpCas9 highlighted both structural conservation and divergence, explaining their distinct PAM specificities and orthologous sgRNA recognition.

Zetsche et al. (2015) reported the characterization of Cpf1, a putative class 2 CRISPR effector. It was demonstrated that Cpf1 mediates robust DNA interference with features distinct from Cas9. Identifying this mechanism of interference broadens our understanding of CRISPR-Cas systems and advances their genome editing applications.

Shmakov et al. (2015) reported the characterization of three distinct Class 2 CRISPR-Cas systems. The effectors of two of the identified systems, C2c1 and C2c3, contain RuvC like endonuclease domains distantly related to Cpf1. The third system, C2c2, contains an effector with two predicted HEPN RNase domains.

Also, “Dimeric CRISPR RNA-guided FokI nucleases for highly specific genome editing”, Shengdar Q. Tsai, Nicolas Wyvekens, Cyd Khayter, Jennifer A. Foden, Vishal Thapar, Deepak Reyon, Mathew J. Goodwin, Martin J. Aryee, J. Keith Joung Nature Biotechnology 32(6): 569-77 (2014), relates to dimeric RNA-guided FokI Nucleases that recognize extended sequences and can edit endogenous genes with high efficiencies in human cells.

In general, the CRISPR-Cas or CRISPR system is as used in the foregoing documents, such as WO 2014/093622 (PCT/US2013/074667) and refers collectively to transcripts and other elements involved in the expression of or directing the activity of CRISPR-associated (“Cas”) genes, including sequences encoding a Cas gene, a tracr (trans-activating CRISPR) sequence (e.g. tracrRNA or an active partial tracrRNA), a tracr-mate sequence (encompassing a “direct repeat” and a tracrRNA-processed partial direct repeat in the context of an endogenous CRISPR system), a guide sequence (also referred to as a “spacer” in the context of an endogenous CRISPR system), or “RNA(s)” as that term is herein used (e.g., RNA(s) to guide Cas, such as Cas9, e.g. CRISPR RNA and transactivating (tracr) RNA or a single guide RNA (sgRNA) (chimeric RNA)) or other sequences and transcripts from a CRISPR locus. In general, a CRISPR system is characterized by elements that promote the formation of a CRISPR complex at the site of a target sequence (also referred to as a protospacer in the context of an endogenous CRISPR system). In the context of formation of a CRISPR complex, “target sequence” refers to a sequence to which a guide sequence is designed to have complementarity, where hybridization between a target sequence and a guide sequence promotes the formation of a CRISPR complex. A target sequence may comprise any polynucleotide, such as DNA or RNA polynucleotides. In some embodiments, a target sequence is located in the nucleus or cytoplasm of a cell. In some embodiments, direct repeats may be identified in silico by searching for repetitive motifs that fulfill any or all of the following criteria: 1. found in a 2Kb window of genomic sequence flanking the type II CRISPR locus; 2. span from 20 to 50 bp; and 3. interspaced by 20 to 50 bp. In some embodiments, 2 of these criteria may be used, for instance 1 and 2, 2 and 3, or 1 and 3. In some embodiments, all 3 criteria may be used.

In embodiments of the invention the terms guide sequence and guide RNA, i.e. RNA capable of guiding Cas to a target genomic locus, are used interchangeably as in foregoing cited documents such as WO 2014/093622 (PCT/US2013/074667). In general, a guide sequence is any polynucleotide sequence having sufficient complementarity with a target polynucleotide sequence to hybridize with the target sequence and direct sequence-specific binding of a CRISPR complex to the target sequence. In some embodiments, the degree of complementarity between a guide sequence and its corresponding target sequence, when optimally aligned using a suitable alignment algorithm, is about or more than about 50%, 60%, 75%, 80%, 85%, 90%, 95%, 97.5%, 99%, or more. Optimal alignment may be determined with the use of any suitable algorithm for aligning sequences, non-limiting example of which include the Smith-Waterman algorithm, the Needleman-Wunsch algorithm, algorithms based on the Burrows-Wheeler Transform (e.g. the Burrows Wheeler Aligner), ClustalW, Clustal X, BLAT, Novoalign (Novocraft Technologies; available at www.novocraft.com), ELAND (Illumina, San Diego, CA), SOAP (available at soap.genomics.org.cn), and Maq (available at maq.sourceforge.net). In some embodiments, a guide sequence is about or more than about 5, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 35, 40, 45, 50, 75, or more nucleotides in length. In some embodiments, a guide sequence is less than about 75, 50, 45, 40, 35, 30, 25, 20, 15, 12, or fewer nucleotides in length. Preferably the guide sequence is 10 30 nucleotides long. The ability of a guide sequence to direct sequence-specific binding of a CRISPR complex to a target sequence may be assessed by any suitable assay. For example, the components of a CRISPR system sufficient to form a CRISPR complex, including the guide sequence to be tested, may be provided to a host cell having the corresponding target sequence, such as by transfection with vectors encoding the components of the CRISPR sequence, followed by an assessment of preferential cleavage within the target sequence, such as by Surveyor assay as described herein. Similarly, cleavage of a target polynucleotide sequence may be evaluated in a test tube by providing the target sequence, components of a CRISPR complex, including the guide sequence to be tested and a control guide sequence different from the test guide sequence, and comparing binding or rate of cleavage at the target sequence between the test and control guide sequence reactions. Other assays are possible, and will occur to those skilled in the art.

In a classic CRISPR-Cas system, the degree of complementarity between a guide sequence and its corresponding target sequence can be about or more than about 50%, 60%, 75%, 80%, 85%, 90%, 95%, 97.5%, 99%, or 100%; a guide or RNA or sgRNA can be about or more than about 5, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 35, 40, 45, 50, 75, or more nucleotides in length; or guide or RNA or sgRNA can be less than about 75, 50, 45, 40, 35, 30, 25, 20, 15, 12, or fewer nucleotides in length; and advantageously tracr RNA is 30 or 50 nucleotides in length. However, an aspect of the invention is to reduce off-target interactions, e.g., reduce the guide interacting with a target sequence having low complementarity. Indeed, in the examples, it is shown that the invention involves mutations that result in the CRISPR-Cas system being able to distinguish between target and off-target sequences that have greater than 80% to about 95% complementarity, e.g., 83%-84% or 88-89% or 94-95% complementarity (for instance, distinguishing between a target having 18 nucleotides from an off-target of 18 nucleotides having 1, 2 or 3 mismatches). Accordingly, in the context of the present invention the degree of complementarity between a guide sequence and its corresponding target sequence is greater than 94.5% or 95% or 95.5% or 96% or 96.5% or 97% or 97.5% or 98% or 98.5% or 99% or 99.5% or 99.9%, or 100%. Off target is less than 100% or 99.9% or 99.5% or 99% or 99% or 98.5% or 98% or 97.5% or 97% or 96.5% or 96% or 95.5% or 95% or 94.5% or 94% or 93% or 92% or 91% or 90% or 89% or 88% or 87% or 86% or 85% or 84% or 83% or 82% or 81% or 80% complementarity between the sequence and the guide, with it advantageous that off target is 100% or 99.9% or 99.5% or 99% or 99% or 98.5% or 98% or 97.5% or 97% or 96.5% or 96% or 95.5% or 95% or 94.5% complementarity between the sequence and the guide.

In particularly preferred embodiments according to the invention, the guide RNA (capable of guiding Cas to a target locus) may comprise (1) a guide sequence capable of hybridizing to a genomic target locus in the eukaryotic cell; (2) a tracr sequence; and (3) a tracr mate sequence. All (1) to (3) may reside in a single RNA, i.e. an sgRNA (arranged in a 5′ to 3′ orientation), or the tracr RNA may be a different RNA than the RNA containing the guide and tracr sequence. The tracr hybridizes to the tracr mate sequence and directs the CRISPR/Cas complex to the target sequence.

The methods according to the invention as described herein comprehend inducing one or more mutations in a eukaryotic cell (in vitro, i.e. in an isolated eukaryotic cell) as herein discussed comprising delivering to cell a vector as herein discussed. The mutation(s) can include the introduction, deletion, or substitution of one or more nucleotides at each target sequence of cell(s) via the guide(s) RNA(s) or sgRNA(s). The mutations can include the introduction, deletion, or substitution of 1-75 nucleotides at each target sequence of said cell(s) via the guide(s) RNA(s) or sgRNA(s). The mutations can include the introduction, deletion, or substitution of 1, 5, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 35, 40, 45, 50, or 75 nucleotides at each target sequence of said cell(s) via the guide(s) RNA(s) or sgRNA(s). The mutations can include the introduction, deletion, or substitution of 5, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 35, 40, 45, 50, or 75 nucleotides at each target sequence of said cell(s) via the guide(s) RNA(s) or sgRNA(s). The mutations include the introduction, deletion, or substitution of 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 35, 40, 45, 50, or 75 nucleotides at each target sequence of said cell(s) via the guide(s) RNA(s) or sgRNA(s). The mutations can include the introduction, deletion, or substitution of 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 35, 40, 45, 50, or 75 nucleotides at each target sequence of said cell(s) via the guide(s) RNA(s) or sgRNA(s). The mutations can include the introduction, deletion, or substitution of 40, 45, 50, 75, 100, 200, 300, 400 or 500 nucleotides at each target sequence of said cell(s) via the guide(s) RNA(s) or sgRNA(s).

For minimization of toxicity and off-target effect, it will be important to control the concentration of Cas mRNA and guide RNA delivered. Optimal concentrations of Cas mRNA and guide RNA can be determined by testing different concentrations in a cellular or non-human eukaryote animal model and using deep sequencing the analyze the extent of modification at potential off-target genomic loci. Alternatively, to minimize the level of toxicity and off-target effect, Cas nickase mRNA (for example S. pyogenes Cas9 with the D10A mutation) can be delivered with a pair of guide RNAs targeting a site of interest. Guide sequences and strategies to minimize toxicity and off-target effects can be as in WO 2014/093622 (PCT/US2013/074667); or, via mutation as herein.

Typically, in the context of an endogenous CRISPR system, formation of a CRISPR complex (comprising a guide sequence hybridized to a target sequence and complexed with one or more Cas proteins) results in cleavage of one or both strands in or near (e.g. within 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 20, 50, or more base pairs from) the target sequence. Without wishing to be bound by theory, the tracr sequence, which may comprise or consist of all or a portion of a wild-type tracr sequence (e.g. about or more than about 20, 26, 32, 45, 48, 54, 63, 67, 85, or more nucleotides of a wild-type tracr sequence), may also form part of a CRISPR complex, such as by hybridization along at least a portion of the tracr sequence to all or a portion of a tracr mate sequence that is operably linked to the guide sequence.

The nucleic acid molecule encoding a Cas is advantageously codon optimized Cas. An example of a codon optimized sequence, is in this instance a sequence optimized for expression in a eukaryote, e.g., humans (i.e. being optimized for expression in humans), or for another eukaryote, animal or mammal as herein discussed; see, e.g., SaCas9 human codon optimized sequence in WO 2014/093622 (PCT/US2013/074667). Whilst this is preferred, it will be appreciated that other examples are possible and codon optimization for a host species other than human, or for codon optimization for specific organs is known. In some embodiments, an enzyme coding sequence encoding a Cas is codon optimized for expression in particular cells, such as eukaryotic cells. The eukaryotic cells may be those of or derived from a particular organism, such as a mammal, including but not limited to human, or non-human eukaryote or animal or mammal as herein discussed, e.g., mouse, rat, rabbit, dog, livestock, or non-human mammal or primate. In some embodiments, processes for modifying the germ line genetic identity of human beings and/or processes for modifying the genetic identity of animals which are likely to cause them suffering without any substantial medical benefit to man or animal, and also animals resulting from such processes, may be excluded. In general, codon optimization refers to a process of modifying a nucleic acid sequence for enhanced expression in the host cells of interest by replacing at least one codon (e.g. about or more than about 1, 2, 3, 4, 5, 10, 15, 20, 25, 50, or more codons) of the native sequence with codons that are more frequently or most frequently used in the genes of that host cell while maintaining the native amino acid sequence. Various species exhibit particular bias for certain codons of a particular amino acid. Codon bias (differences in codon usage between organisms) often correlates with the efficiency of translation of messenger RNA (mRNA), which is in turn believed to be dependent on, among other things, the properties of the codons being translated and the availability of particular transfer RNA (tRNA) molecules. The predominance of selected tRNAs in a cell is generally a reflection of the codons used most frequently in peptide synthesis. Accordingly, genes can be tailored for optimal gene expression in a given organism based on codon optimization. Codon usage tables are readily available, for example, at the “Codon Usage Database” available at www.kazusa.or.jp/codon/ and these tables can be adapted in a number of ways. See Nakamura, Y., et al. “Codon usage tabulated from the international DNA sequence databases: status for the year 2000” Nucl. Acids Res. 28:292 (2000). Computer algorithms for codon optimizing a particular sequence for expression in a particular host cell are also available, such as Gene Forge (Aptagen; Jacobus, PA), are also available. In some embodiments, one or more codons (e.g. 1, 2, 3, 4, 5, 10, 15, 20, 25, 50, or more, or all codons) in a sequence encoding a Cas correspond to the most frequently used codon for a particular amino acid.

In certain embodiments, the methods as described herein may comprise providing a Cas transgenic cell in which one or more nucleic acids encoding one or more guide RNAs are provided or introduced operably connected in the cell with a regulatory element comprising a promoter of one or more gene of interest. As used herein, the term “Cas transgenic cell” refers to a cell, such as a eukaryotic cell, in which a Cas gene has been genomically integrated. The nature, type, or origin of the cell are not particularly limiting according to the present invention. Also, the way how the Cas transgene is introduced in the cell is may vary and can be any method as is known in the art. In certain embodiments, the Cas transgenic cell is obtained by introducing the Cas transgene in an isolated cell. In certain other embodiments, the Cas transgenic cell is obtained by isolating cells from a Cas transgenic organism. By means of example, and without limitation, the Cas transgenic cell as referred to herein may be derived from a Cas transgenic eukaryote, such as a Cas knock-in eukaryote. Reference is made to WO 2014/093622 (PCT/US13/74667), incorporated herein by reference. Methods of US Patent Publication Nos. 20120017290 and 20110265198 assigned to Sangamo BioSciences, Inc. directed to targeting the Rosa locus may be modified to utilize the CRISPR Cas system of the present invention. Methods of US Patent Publication No. 20130236946 assigned to Cellectis directed to targeting the Rosa locus may also be modified to utilize the CRISPR Cas system of the present invention. By means of further example reference is made to Platt et. al. (Cell; 159(2):440-455 (2014)), describing a Cas9 knock-in mouse, which is incorporated herein by reference. The Cas transgene can further comprise a Lox-Stop-polyA-Lox (LSL) cassette thereby rendering Cas expression inducible by Cre recombinase. Alternatively, the Cas transgenic cell may be obtained by introducing the Cas transgene in an isolated cell. Delivery systems for transgenes are well known in the art. By means of example, the Cas transgene may be delivered in for instance eukaryotic cell by means of vector (e.g., AAV, adenovirus, lentivirus) and/or particle and/or nanoparticle delivery, as also described herein elsewhere.

It will be understood by the skilled person that the cell, such as the Cas transgenic cell, as referred to herein may comprise further genomic alterations besides having an integrated Cas gene or the mutations arising from the sequence specific action of Cas when complexed with RNA capable of guiding Cas to a target locus, such as for instance one or more oncogenic mutations, as for instance and without limitation described in Platt et al. (2014), Chen et al., (2014) or Kumar et al. (2009).

In some embodiments, the Cas sequence is fused to one or more nuclear localization sequences (NLSs), such as about or more than about 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more NLSs. In some embodiments, the Cas comprises about or more than about 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more NLSs at or near the amino-terminus, about or more than about 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more NLSs at or near the carboxy-terminus, or a combination of these (e.g. zero or at least one or more NLS at the amino-terminus and zero or at one or more NLS at the carboxy terminus). When more than one NLS is present, each may be selected independently of the others, such that a single NLS may be present in more than one copy and/or in combination with one or more other NLSs present in one or more copies. In a preferred embodiment of the invention, the Cas comprises at most 6 NLSs. In some embodiments, an NLS is considered near the N- or C-terminus when the nearest amino acid of the NLS is within about 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 40, 50, or more amino acids along the polypeptide chain from the N- or C-terminus. Non-limiting examples of NLSs include an NLS sequence derived from: the NLS of the SV40 virus large T-antigen, having the amino acid sequence PKKKRKV (SEQ ID NO: 1); the NLS from nucleoplasmin (e.g. the nucleoplasmin bipartite NLS with the sequence KRPAATKKAGQAKKKK) (SEQ ID NO: 2); the c-myc NLS having the amino acid sequence PAAKRVKLD (SEQ ID NO: 3) or RQRRNELKRSP (SEQ ID NO: 4); the hRNPA1 M9 NLS having the sequence NQSSNFGPMKGGNFGGRSSGPYGGGGQYFAKPRNQGGY (SEQ ID NO: 5); the sequence RMRIZFKNKGKDTAELRRRRVEVSVELRKAKKDEQILKRRNV (SEQ ID NO: 6) of the IBB domain from importin-alpha; the sequences VSRKRPRP (SEQ ID NO: 7) and PPKKARED (SEQ ID NO: 8) of the myoma T protein; the sequence POPKKKPL (SEQ ID NO: 9) of human p53; the sequence SALIKKKKKMAP (SEQ ID NO: 10) of mouse c-abl IV; the sequences DRLRR (SEQ ID NO: 11) and PKQKKRK (SEQ ID NO: 12) of the influenza virus NS1; the sequence RKLKKKIKKL (SEQ ID NO: 13) of the Hepatitis virus delta antigen; the sequence REKKKFLKRR (SEQ ID NO: 14) of the mouse Mx1 protein; the sequence KRKGDEVDGVDEVAKKKSKK (SEQ ID NO: 15) of the human poly(ADP-ribose) polymerase; and the sequence RKCLQAGMNLEARKTKK (SEQ ID NO: 16) of the steroid hormone receptors (human) glucocorticoid. In general, the one or more NLSs are of sufficient strength to drive accumulation of the Cas in a detectable amount in the nucleus of a eukaryotic cell. In general, strength of nuclear localization activity may derive from the number of NLSs in the Cas, the particular NLS(s) used, or a combination of these factors. Detection of accumulation in the nucleus may be performed by any suitable technique. For example, a detectable marker may be fused to the Cas, such that location within a cell may be visualized, such as in combination with a means for detecting the location of the nucleus (e.g. a stain specific for the nucleus such as DAPI). Cell nuclei may also be isolated from cells, the contents of which may then be analyzed by any suitable process for detecting protein, such as immunohistochemistry, Western blot, or enzyme activity assay. Accumulation in the nucleus may also be determined indirectly, such as by an assay for the effect of CRISPR complex formation (e.g. assay for DNA cleavage or mutation at the target sequence, or assay for altered gene expression activity affected by CRISPR complex formation and/or Cas enzyme activity), as compared to a control no exposed to the Cas or complex, or exposed to a Cas lacking the one or more NLSs.

Zinc Finger and TALE

One type of programmable DNA-binding domain is provided by artificial zinc-finger (ZF) technology, which involves arrays of ZF modules to target new DNA-binding sites in the genome. Each finger module in a ZF array targets three DNA bases. A customized array of individual zinc finger domains is assembled into a ZF protein (ZFP).

ZFPs can comprise a functional domain. The first synthetic zinc finger nucleases (ZFNs) were developed by fusing a ZF protein to the catalytic domain of the Type IIS restriction enzyme FokI. (Kim, Y. G. et al., 1994, Chimeric restriction endonuclease, Proc. Natl. Acad. Sci. U.S.A. 91, 883-887; Kim, Y. G. et al., 1996, Hybrid restriction enzymes: zinc finger fusions to Fok I cleavage domain. Proc. Natl. Acad. Sci. U.S.A. 93, 1156-1160). Increased cleavage specificity can be attained with decreased off target activity by use of paired ZFN heterodimers, each targeting different nucleotide sequences separated by a short spacer. (Doyon, Y. et al., 2011, Enhancing zinc-finger-nuclease activity with improved obligate heterodimeric architectures. Nat. Methods 8, 74-79). ZFPs can also be designed as transcription activators and repressors and have been used to target many genes in a wide variety of organisms.

In advantageous embodiments of the invention, the methods provided herein use isolated, non-naturally occurring, recombinant or engineered DNA binding proteins that comprise TALE monomers or TALE monomers or half monomers as a part of their organizational structure that enable the targeting of nucleic acid sequences with improved efficiency and expanded specificity.

Naturally occurring TALEs or “wild type TALEs” are nucleic acid binding proteins secreted by numerous species of proteobacteria. TALE polypeptides contain a nucleic acid binding domain composed of tandem repeats of highly conserved monomer polypeptides that are predominantly 33, 34 or 35 amino acids in length and that differ from each other mainly in amino acid positions 12 and 13. In advantageous embodiments the nucleic acid is DNA. As used herein, the term “polypeptide monomers”, “TALE monomers” or “monomers” will be used to refer to the highly conserved repetitive polypeptide sequences within the TALE nucleic acid binding domain and the term “repeat variable di-residues” or “RVD” will be used to refer to the highly variable amino acids at positions 12 and 13 of the polypeptide monomers. As provided throughout the disclosure, the amino acid residues of the RVD are depicted using the IUPAC single letter code for amino acids. A general representation of a TALE monomer which is comprised within the DNA binding domain is X1-11-(X12X13)-X14-33 or 34 or 35, where the subscript indicates the amino acid position and X represents any amino acid. X12X13 indicate the RVDs. In some polypeptide monomers, the variable amino acid at position 13 is missing or absent and in such monomers, the RVD consists of a single amino acid. In such cases the RVD may be alternatively represented as X*, where X represents X12 and (*) indicates that X13 is absent. The DNA binding domain comprises several repeats of TALE monomers and this may be represented as (X1-11-(X12X13)-X14-33 or 34 or 35)z, where in an advantageous embodiment, z is at least 5 to 40. In a further advantageous embodiment, z is at least 10 to 26.

The TALE monomers have a nucleotide binding affinity that is determined by the identity of the amino acids in its RVD. For example, polypeptide monomers with an RVD of NI preferentially bind to adenine (A), monomers with an RVD of NG preferentially bind to thymine (T), monomers with an RVD of HD preferentially bind to cytosine (C) and monomers with an RVD of NN preferentially bind to both adenine (A) and guanine (G). In yet another embodiment of the invention, monomers with an RVD of IG preferentially bind to T. Thus, the number and order of the polypeptide monomer repeats in the nucleic acid binding domain of a TALE determines its nucleic acid target specificity. In still further embodiments of the invention, monomers with an RVD of NS recognize all four base pairs and may bind to A, T, G or C. The structure and function of TALEs is further described in, for example, Moscou et al., Science 326:1501 (2009); Boch et al., Science 326:1509-1512 (2009); and Zhang et al., Nature Biotechnology 29:149-153 (2011), each of which is incorporated by reference in its entirety.

The polypeptides used in methods of the invention are isolated, non-naturally occurring, recombinant or engineered nucleic acid-binding proteins that have nucleic acid or DNA binding regions containing polypeptide monomer repeats that are designed to target specific nucleic acid sequences.

As described herein, polypeptide monomers having an RVD of HN or NH preferentially bind to guanine and thereby allow the generation of TALE polypeptides with high binding specificity for guanine containing target nucleic acid sequences. In a preferred embodiment of the invention, polypeptide monomers having RVDs RN, NN, NK, SN, NH, KN, HN, NQ, HH, RG, KH, RH and SS preferentially bind to guanine. In a much more advantageous embodiment of the invention, polypeptide monomers having RVDs RN, NK, NQ, HH, KH, RH, SS and SN preferentially bind to guanine and thereby allow the generation of TALE polypeptides with high binding specificity for guanine containing target nucleic acid sequences. In an even more advantageous embodiment of the invention, polypeptide monomers having RVDs HH, KH, NH, NK, NQ, RH, RN and SS preferentially bind to guanine and thereby allow the generation of TALE polypeptides with high binding specificity for guanine containing target nucleic acid sequences. In a further advantageous embodiment, the RVDs that have high binding specificity for guanine are RN, NH RH and KH. Furthermore, polypeptide monomers having an RVD of NV preferentially bind to adenine and guanine. In more preferred embodiments of the invention, monomers having RVDs of H*, HA, KA, N*, NA, NC, NS, RA, and S* bind to adenine, guanine, cytosine and thymine with comparable affinity.

The predetermined N-terminal to C-terminal order of the one or more polypeptide monomers of the nucleic acid or DNA binding domain determines the corresponding predetermined target nucleic acid sequence to which the polypeptides of the invention will bind. As used herein the monomers and at least one or more half monomers are “specifically ordered to target” the genomic locus or gene of interest. In plant genomes, the natural TALE-binding sites always begin with a thymine (T), which may be specified by a cryptic signal within the non-repetitive N-terminus of the TALE polypeptide; in some cases, this region may be referred to as repeat 0. In animal genomes, TALE binding sites do not necessarily have to begin with a thymine (T) and polypeptides of the invention may target DNA sequences that begin with T, A, G or C. The tandem repeat of TALE monomers always ends with a half-length repeat or a stretch of sequence that may share identity with only the first 20 amino acids of a repetitive full length TALE monomer and this half repeat may be referred to as a half-monomer (FIG. 8). Therefore, it follows that the length of the nucleic acid or DNA being targeted is equal to the number of full monomers plus two.

As described in Zhang et al., Nature Biotechnology 29:149-153 (2011), TALE polypeptide binding efficiency may be increased by including amino acid sequences from the “capping regions” that are directly N-terminal or C-terminal of the DNA binding region of naturally occurring TALEs into the engineered TALEs at positions N-terminal or C-terminal of the engineered TALE DNA binding region. Thus, in certain embodiments, the TALE polypeptides described herein further comprise an N-terminal capping region and/or a C-terminal capping region.

An exemplary amino acid sequence of a N-terminal capping region is:

(SEQ ID NO: 17)

MDPIRSRTPSPARELLSGPQPDGVQPTADRGVSP

PAGGPLDGLPARRTMSRTRLPSPPAPSPAFSADS

FSDLLRQFDPSLFNTSLFDSLPPFGAHHTEAATG

EWDEVQSGLRAADAPPPTMRVAVTAARPPRAKPA

PRRRAAQPSDASPAAQVDLRTLGYSQQQQEKIKP

KVRSTVAQHHEALVGHGFTHAHIVALSQHPAALG

TVAVKYQDMIAALPEATHEAIVGVGKQWSGARAL

EALLTVAGELRGPPLQLDTGQLLKIAKRGGVTAV

EAVHAWRNALTGAPLN

An exemplary amino acid sequence of a C-terminal capping region is:

(SEQ ID NO: 18)

RPALESIVAQLSRPDPALAALTNDHLVALACLG

GRPALDAVKKGLPHAPALIKRTNRRIPERTSHR

VADHAQVVRVLGFFQCHSHPAQAFDDAMTQFGM

SRHGLLQLFRRVGVTELEARSGTLPPASQRWDR

ILQASGMKRAKPSPTSTQTPDQASLHAFADSLE

RDLDAPSPMHEGDQTRAS

As used herein the predetermined “N-terminus” to “C terminus” orientation of the N-terminal capping region, the DNA binding domain comprising the repeat TALE monomers and the C-terminal capping region provide structural basis for the organization of different domains in the d-TALEs or polypeptides of the invention.

The entire N-terminal and/or C-terminal capping regions are not necessary to enhance the binding activity of the DNA binding region. Therefore, in certain embodiments, fragments of the N-terminal and/or C-terminal capping regions are included in the TALE polypeptides described herein.

In certain embodiments, the TALE polypeptides described herein contain a N-terminal capping region fragment that included at least 10, 20, 30, 40, 50, 54, 60, 70, 80, 87, 90, 94, 100, 102, 110, 117, 120, 130, 140, 147, 150, 160, 170, 180, 190, 200, 210, 220, 230, 240, 250, 260 or 270 amino acids of an N-terminal capping region. In certain embodiments, the N-terminal capping region fragment amino acids are of the C-terminus (the DNA-binding region proximal end) of an N-terminal capping region. As described in Zhang et al., Nature Biotechnology 29:149-153 (2011), N-terminal capping region fragments that include the C-terminal 240 amino acids enhance binding activity equal to the full length capping region, while fragments that include the C-terminal 147 amino acids retain greater than 80% of the efficacy of the full length capping region, and fragments that include the C-terminal 117 amino acids retain greater than 50% of the activity of the full-length capping region.

In some embodiments, the TALE polypeptides described herein contain a C-terminal capping region fragment that included at least 6, 10, 20, 30, 37, 40, 50, 60, 68, 70, 80, 90, 100, 110, 120, 127, 130, 140, 150, 155, 160, 170, 180 amino acids of a C-terminal capping region. In certain embodiments, the C-terminal capping region fragment amino acids are of the N-terminus (the DNA-binding region proximal end) of a C-terminal capping region. As described in Zhang et al., Nature Biotechnology 29:149-153 (2011), C-terminal capping region fragments that include the C-terminal 68 amino acids enhance binding activity equal to the full length capping region, while fragments that include the C-terminal 20 amino acids retain greater than 50% of the efficacy of the full length capping region.

In certain embodiments, the capping regions of the TALE polypeptides described herein do not need to have identical sequences to the capping region sequences provided herein. Thus, in some embodiments, the capping region of the TALE polypeptides described herein have sequences that are at least 50%, 60%, 70%, 80%, 85%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98% or 99% identical or share identity to the capping region amino acid sequences provided herein. Sequence identity is related to sequence homology. Homology comparisons may be conducted by eye, or more usually, with the aid of readily available sequence comparison programs. These commercially available computer programs may calculate percent (%) homology between two or more sequences and may also calculate the sequence identity shared by two or more amino acid or nucleic acid sequences. In some preferred embodiments, the capping region of the TALE polypeptides described herein have sequences that are at least 95% identical or share identity to the capping region amino acid sequences provided herein.

Sequence homologies may be generated by any of a number of computer programs known in the art, which include but are not limited to BLAST or FASTA. Suitable computer program for carrying out alignments like the GCG Wisconsin Bestfit package may also be used. Once the software has produced an optimal alignment, it is possible to calculate % homology, preferably % sequence identity. The software typically does this as part of the sequence comparison and generates a numerical result.

In advantageous embodiments described herein, the TALE polypeptides of the invention include a nucleic acid binding domain linked to the one or more effector domains. The terms “effector domain” or “regulatory and functional domain” refer to a polypeptide sequence that has an activity other than binding to the nucleic acid sequence recognized by the nucleic acid binding domain. By combining a nucleic acid binding domain with one or more effector domains, the polypeptides of the invention may be used to target the one or more functions or activities mediated by the effector domain to a particular target DNA sequence to which the nucleic acid binding domain specifically binds.

In some embodiments of the TALE polypeptides described herein, the activity mediated by the effector domain is a biological activity. For example, in some embodiments the effector domain is a transcriptional inhibitor (i.e., a repressor domain), such as an mSin interaction domain (SID). SID4X domain or a Kruppel-associated box (KRAB) or fragments of the KRAB domain. In some embodiments the effector domain is an enhancer of transcription (i.e. an activation domain), such as the VP16, VP64 or p65 activation domain. In some embodiments, the nucleic acid binding is linked, for example, with an effector domain that includes but is not limited to a transposase, integrase, recombinase, resolvase, invertase, protease, DNA methyltransferase, DNA demethylase, histone acetylase, histone deacetylase, nuclease, transcriptional repressor, transcriptional activator, transcription factor recruiting, protein nuclear-localization signal or cellular uptake signal.

In some embodiments, the effector domain is a protein domain which exhibits activities which include but are not limited to transposase activity, integrase activity, recombinase activity, resolvase activity, invertase activity, protease activity, DNA methyltransferase activity, DNA demethylase activity, histone acetylase activity, histone deacetylase activity, nuclease activity, nuclear-localization signaling activity, transcriptional repressor activity, transcriptional activator activity, transcription factor recruiting activity, or cellular uptake signaling activity. Other preferred embodiments of the invention may include any combination the activities described herein.

Methods of Diagnosing

Also provided within the scope of the invention are methods of diagnosing viral or latent viral infections. Such infections include, but are not necessarily limited to, Hepatitis B, Hepatitis C, latent HIV or ART-resistant HIV infection in a cell or tissue in a subject. Such methods may comprise detecting a gene expression profile in one or more cells or tissues associated with latent HIV or ART-resistant HIV infection.

Gene Expression Profiles

The term “biomarker” is widespread in the art and commonly broadly denotes a biological molecule, more particularly an endogenous biological molecule, and/or a detectable portion thereof, whose qualitative and/or quantitative evaluation in a tested object (e.g., in or on a cell, cell population, tissue, organ, or organism, e.g., in a biological sample of a subject) is predictive or informative with respect to one or more aspects of the tested object's phenotype and/or genotype. The terms “marker” and “biomarker” may be used interchangeably throughout this specification. Biomarkers as intended herein may be nucleic acid-based or peptide-, polypeptide- and/or protein-based. For example, a marker may be comprised of peptide(s), polypeptide(s) and/or protein(s) encoded by a given gene, or of detectable portions thereof. Further, whereas the term “nucleic acid” generally encompasses DNA, RNA and DNA/RNA hybrid molecules, in the context of markers the term may typically refer to heterogeneous nuclear RNA (hnRNA), pre-mRNA, messenger RNA (mRNA), or complementary DNA (cDNA), or detectable portions thereof. Such nucleic acid species are particularly useful as markers, since they contain qualitative and/or quantitative information about the expression of the gene. Particularly preferably, a nucleic acid-based marker may encompass mRNA of a given gene, or cDNA made of the mRNA, or detectable portions thereof. Any such nucleic acid(s), peptide(s), polypeptide(s) and/or protein(s) encoded by or produced from a given gene are encompassed by the term “gene product(s)”.

Preferably, markers as intended herein may be extracellular or cell surface markers, as methods to measure extracellular or cell surface marker(s) need not disturb the integrity of the cell membrane and may not require fixation/permeabilization of the cells.

Unless otherwise apparent from the context, reference herein to any marker, such as a peptide, polypeptide, protein, or nucleic acid, may generally also encompass modified forms of said marker, such as bearing post-expression modifications including, for example, phosphorylation, glycosylation, lipidation, methylation, cysteinylation, sulphonation, glutathionylation, acetylation, oxidation of methionine to methionine sulphoxide or methionine sulphone, and the like.

The term “peptide” as used throughout this specification preferably refers to a polypeptide as used herein consisting essentially of 50 amino acids or less, e.g., 45 amino acids or less, preferably 40 amino acids or less, e.g., 35 amino acids or less, more preferably 30 amino acids or less, e.g., 25 or less, 20 or less, 15 or less, 10 or less or 5 or less amino acids.

The term “polypeptide” as used throughout this specification generally encompasses polymeric chains of amino acid residues linked by peptide bonds. Hence, insofar a protein is only composed of a single polypeptide chain, the terms “protein” and “polypeptide” may be used interchangeably herein to denote such a protein. The term is not limited to any minimum length of the polypeptide chain. The term may encompass naturally, recombinantly, semi-synthetically or synthetically produced polypeptides. The term also encompasses polypeptides that carry one or more co- or post-expression-type modifications of the polypeptide chain, such as, without limitation, glycosylation, acetylation, phosphorylation, sulfonation, methylation, ubiquitination, signal peptide removal, N-terminal Met removal, conversion of pro-enzymes or pre-hormones into active forms, etc. The term further also includes polypeptide variants or mutants which carry amino acid sequence variations vis-à-vis a corresponding native polypeptide, such as, e.g., amino acid deletions, additions and/or substitutions. The term contemplates both full-length polypeptides and polypeptide parts or fragments, e.g., naturally-occurring polypeptide parts that ensue from processing of such full-length polypeptides.

The term “protein” as used throughout this specification generally encompasses macromolecules comprising one or more polypeptide chains, i.e., polymeric chains of amino acid residues linked by peptide bonds. The term may encompass naturally, recombinantly, semi-synthetically or synthetically produced proteins. The term also encompasses proteins that carry one or more co- or post-expression-type modifications of the polypeptide chain(s), such as, without limitation, glycosylation, acetylation, phosphorylation, sulfonation, methylation, ubiquitination, signal peptide removal, N-terminal Met removal, conversion of pro-enzymes or pre-hormones into active forms, etc. The term further also includes protein variants or mutants which carry amino acid sequence variations vis-à-vis a corresponding native protein, such as, e.g., amino acid deletions, additions and/or substitutions. The term contemplates both full-length proteins and protein parts or fragments, e.g., naturally-occurring protein parts that ensue from processing of such full-length proteins.

The reference to any marker, including any peptide, polypeptide, protein, or nucleic acid, corresponds to the marker commonly known under the respective designations in the art. The terms encompass such markers of any organism where found, and particularly of animals, preferably warm-blooded animals, more preferably vertebrates, yet more preferably mammals, including humans and non-human mammals, still more preferably of humans.

The terms particularly encompass such markers, including any peptides, polypeptides, proteins, or nucleic acids, with a native sequence, i.e., ones of which the primary sequence is the same as that of the markers found in or derived from nature. A skilled person understands that native sequences may differ between different species due to genetic divergence between such species. Moreover, native sequences may differ between or within different individuals of the same species due to normal genetic diversity (variation) within a given species. Also, native sequences may differ between or even within different individuals of the same species due to somatic mutations, or post-transcriptional or post-translational modifications. Any such variants or isoforms of markers are intended herein. Accordingly, all sequences of markers found in or derived from nature are considered “native”. The terms encompass the markers when forming a part of a living organism, organ, tissue or cell, when forming a part of a biological sample, as well as when at least partly isolated from such sources. The terms also encompass markers when produced by recombinant or synthetic means.

In certain embodiments, markers, including any peptides, polypeptides, proteins, or nucleic acids, may be human, i.e., their primary sequence may be the same as a corresponding primary sequence of or present in a naturally occurring human markers. Hence, the qualifier “human” in this connection relates to the primary sequence of the respective markers, rather than to their origin or source. For example, such markers may be present in or isolated from samples of human subjects or may be obtained by other means (e.g., by recombinant expression, cell-free transcription or translation, or non-biological nucleic acid or peptide synthesis).

In certain embodiments, markers, including any peptides, polypeptides, proteins, or nucleic acids, may originate from non-human primates, i.e., their primary sequence may be the same as a corresponding primary sequence of or present in a naturally occurring non-human primate markers. Hence, the qualifier “non-human primate” in this connection relates to the primary sequence of the respective markers, rather than to their origin or source. For example, such markers may be present in or isolated from samples of non-human primate subjects or may be obtained by other means (e.g., by recombinant expression, cell-free transcription or translation, or non-biological nucleic acid or peptide synthesis).

The reference herein to any marker, including any peptide, polypeptide, protein, or nucleic acid, also encompasses fragments thereof. Hence, the reference herein to measuring (or measuring the quantity of) any one marker may encompass measuring the marker and/or measuring one or more fragments thereof.

For example, any marker and/or one or more fragments thereof may be measured collectively, such that the measured quantity corresponds to the sum amounts of the collectively measured species. In another example, any marker and/or one or more fragments thereof may be measured each individually. The terms encompass fragments arising by any mechanism, in vivo and/or in vitro, such as, without limitation, by alternative transcription or translation, exo- and/or endo-proteolysis, exo- and/or endo-nucleolysis, or degradation of the peptide, polypeptide, protein, or nucleic acid, such as, for example, by physical, chemical and/or enzymatic proteolysis or nucleolysis.

The term “fragment” as used throughout this specification with reference to a peptide, polypeptide, or protein generally denotes a portion of the peptide, polypeptide, or protein, such as typically an N- and/or C-terminally truncated form of the peptide, polypeptide, or protein. Preferably, a fragment may comprise at least about 30%, e.g., at least about 50% or at least about 70%, preferably at least about 80%, e.g., at least about 85%, more preferably at least about 90%, and yet more preferably at least about 95% or even about 99% of the amino acid sequence length of said peptide, polypeptide, or protein. For example, insofar not exceeding the length of the full-length peptide, polypeptide, or protein, a fragment may include a sequence of ≥5 consecutive amino acids, or ≥10 consecutive amino acids, or ≥20 consecutive amino acids, or ≥30 consecutive amino acids, e.g., AO consecutive amino acids, such as for example ≥50 consecutive amino acids, e.g., ¢60, ≥70, ≥80, ≥90, ≥100, ≥200, ≥300, ≥400, ≥500 or ≥600 consecutive amino acids of the corresponding full-length peptide, polypeptide, or protein.

The term “fragment” as used throughout this specification with reference to a nucleic acid (polynucleotide) generally denotes a 5′- and/or 3′-truncated form of a nucleic acid. Preferably, a fragment may comprise at least about 30%, e.g., at least about 50% or at least about 70%, preferably at least about 80%, e.g., at least about 85%, more preferably at least about 90%, and yet more preferably at least about 95% or even about 99% of the nucleic acid sequence length of said nucleic acid. For example, insofar not exceeding the length of the full-length nucleic acid, a fragment may include a sequence of ≥5 consecutive nucleotides, or ≥10 consecutive nucleotides, or ≥20 consecutive nucleotides, or ≥30 consecutive nucleotides, e.g., AO consecutive nucleotides, such as for example ≥50 consecutive nucleotides, e.g., ≥60, ≥70, ≥80, ≥90, ≥100, ≥200, ≥300, ≥400, ≥500 or ≥600 consecutive nucleotides of the corresponding full-length nucleic acid.

Cells such as central nerve system cells, stem cells, and immune cells as disclosed herein may in the context of the present specification be said to “comprise the expression” or conversely to “not express” one or more markers, such as one or more genes or gene products; or be described as “positive” or conversely as “negative” for one or more markers, such as one or more genes or gene products; or be said to “comprise” a defined “gene or gene product signature”.

Such terms are commonplace and well-understood by the skilled person when characterizing cell phenotypes. By means of additional guidance, when a cell is said to be positive for or to express or comprise expression of a given marker, such as a given gene or gene product, a skilled person would conclude the presence or evidence of a distinct signal for the marker when carrying out a measurement capable of detecting or quantifying the marker in or on the cell. Suitably, the presence or evidence of the distinct signal for the marker would be concluded based on a comparison of the measurement result obtained for the cell to a result of the same measurement carried out for a negative control (for example, a cell known to not express the marker) and/or a positive control (for example, a cell known to express the marker). Where the measurement method allows for a quantitative assessment of the marker, a positive cell may generate a signal for the marker that is at least 1.5-fold higher than a signal generated for the marker by a negative control cell or than an average signal generated for the marker by a population of negative control cells, e.g., at least 2-fold, at least 4-fold, at least 10-fold, at least 20-fold, at least 30-fold, at least 40-fold, at least 50-fold higher or even higher. Further, a positive cell may generate a signal for the marker that is 3.0 or more standard deviations, e.g., 3.5 or more, 4.0 or more, 4.5 or more, or 5.0 or more standard deviations, higher than an average signal generated for the marker by a population of negative control cells.

The present invention is also directed to signatures and uses thereof. As used herein a “signature” may encompass any gene or genes, protein or proteins, or epigenetic element(s) whose expression profile or whose occurrence is associated with a specific cell type, subtype, or cell state of a specific cell type or subtype within a population of cells. For ease of discussion, when discussing gene expression, any gene or genes, protein or proteins, or epigenetic element(s) may be substituted. Reference to a gene name throughout the specification encompasses the human gene, non-human primate gene, mouse gene and all other orthologues as known in the art in other organisms. As used herein, the terms “signature”, “expression profile”, or “expression program” may be used interchangeably. It is to be understood that also when referring to proteins (e.g. differentially expressed proteins), such may fall within the definition of “gene” signature. Levels of expression or activity or prevalence may be compared between different cells in order to characterize or identify for instance signatures specific for cell (sub)populations. Increased or decreased expression or activity of signature genes may be compared between different cells in order to characterize or identify for instance specific cell (sub)populations. The detection of a signature in single cells may be used to identify and quantitate for instance specific cell (sub)populations. A signature may include a gene or genes, protein or proteins, or epigenetic element(s) whose expression or occurrence is specific to a cell (sub)population, such that expression or occurrence is exclusive to the cell (sub)population. A gene signature as used herein, may thus refer to any set of up- and down-regulated genes that are representative of a cell type or subtype. A gene signature as used herein, may also refer to any set of up- and down-regulated genes between different cells or cell (sub)populations derived from a gene-expression profile. For example, a gene signature may comprise a list of genes differentially expressed in a distinction of interest.

The signature as defined herein (being it a gene signature, protein signature or other genetic or epigenetic signature) can be used to indicate the presence of a cell type, a subtype of the cell type, the state of the microenvironment of a population of cells, a particular cell type population or subpopulation, and/or the overall status of the entire cell (sub)population. Furthermore, the signature may be indicative of cells within a population of cells in vivo. The signature may also be used to suggest for instance particular therapies, or to follow up treatment, or to suggest ways to modulate immune systems. The signatures of the present invention may be discovered by analysis of expression profiles of single-cells within a population of cells from isolated samples (e.g. tumor samples), thus allowing the discovery of novel cell subtypes or cell states that were previously invisible or unrecognized. The presence of subtypes or cell states may be determined by subtype specific or cell state specific signatures. The presence of these specific cell (sub)types or cell states may be determined by applying the signature genes to bulk sequencing data in a sample. Not being bound by a theory the signatures of the present invention may be microenvironment specific, such as their expression in a particular spatio-temporal context. Not being bound by a theory, signatures as discussed herein are specific to a particular pathological context. Not being bound by a theory, a combination of cell subtypes having a particular signature may indicate an outcome. Not being bound by a theory, the signatures can be used to deconvolute the network of cells present in a particular pathological condition. Not being bound by a theory, the signatures can be used to indicate cell-cell interaction in a particular pathological or physiological condition. Not being bound by a theory, the signatures may be indicative of regulatory pathways in immune regulations. Not being bound by a theory, the presence of specific cells and cell subtypes are indicative of a particular response to treatment, such as including increased or decreased susceptibility to treatment. The signature may indicate the presence of one particular cell type.

The signature according to certain embodiments of the present invention may comprise or consist of one or more genes, proteins and/or epigenetic elements, such as for instance 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 or more. In certain embodiments, the signature may comprise or consist of two or more genes, proteins and/or epigenetic elements, such as for instance 2, 3, 4, 5, 6, 7, 8, 9, 10 or more. In certain embodiments, the signature may comprise or consist of three or more genes, proteins and/or epigenetic elements, such as for instance 3, 4, 5, 6, 7, 8, 9, 10 or more. In certain embodiments, the signature may comprise or consist of four or more genes, proteins and/or epigenetic elements, such as for instance 4, 5, 6, 7, 8, 9, 10 or more. In certain embodiments, the signature may comprise or consist of five or more genes, proteins and/or epigenetic elements, such as for instance 5, 6, 7, 8, 9, 10 or more. In certain embodiments, the signature may comprise or consist of six or more genes, proteins and/or epigenetic elements, such as for instance 6, 7, 8, 9, 10 or more. In certain embodiments, the signature may comprise or consist of seven or more genes, proteins and/or epigenetic elements, such as for instance 7, 8, 9, 10 or more. In certain embodiments, the signature may comprise or consist of eight or more genes, proteins and/or epigenetic elements, such as for instance 8, 9, 10 or more. In certain embodiments, the signature may comprise or consist of nine or more genes, proteins and/or epigenetic elements, such as for instance 9, 10 or more. In certain embodiments, the signature may comprise or consist of ten or more genes, proteins and/or epigenetic elements, such as for instance 10, 11, 12, 13, 14, 15, or more. It is to be understood that a signature according to the invention may for instance also include genes or proteins as well as epigenetic elements combined.

In certain embodiments, a signature is characterized as being specific for a particular cell or cell (sub)population state if it is upregulated or only present, detected or detectable in that particular cell or cell (sub)population state (e.g., disease or healthy), or alternatively is downregulated or only absent, or undetectable in that particular cell or cell (sub)population state. In this context, a signature consists of one or more differentially expressed genes/proteins or differential epigenetic elements when comparing different cells or cell (sub)populations, including comparing different gut cell or gut cell (sub)populations, as well as comparing gut cell or gut cell (sub)populations with healthy or disease (sub)populations. It is to be understood that “differentially expressed” genes/proteins include genes/proteins which are up- or down-regulated as well as genes/proteins which are turned on or off. When referring to up- or down-regulation, in certain embodiments, such up- or down-regulation is preferably at least two-fold, such as two-fold, three-fold, four-fold, five-fold, or more, such as for instance at least ten-fold, at least 20-fold, at least 30-fold, at least 40-fold, at least 50-fold, or more. Alternatively, or in addition, differential expression may be determined based on common statistical tests, as is known in the art.

As discussed herein, differentially expressed genes/proteins, or differential epigenetic elements may be differentially expressed on a single cell level, or may be differentially expressed on a cell population level. Preferably, the differentially expressed genes/proteins or epigenetic elements as discussed herein, such as constituting the gene signatures as discussed herein, when as to the cell population or subpopulation level, refer to genes that are differentially expressed in all or substantially all cells of the population or subpopulation (such as at least 80%, preferably at least 90%, such as at least 95% of the individual cells). This allows one to define a particular subpopulation of immune cells. As referred to herein, a “subpopulation” of cells preferably refers to a particular subset of cells of a particular cell type which can be distinguished or are uniquely identifiable and set apart from other cells of this cell type. The cell subpopulation may be phenotypically characterized, and is preferably characterized by the signature as discussed herein. A cell (sub)population as referred to herein may constitute of a (sub)population of cells of a particular cell type characterized by a specific cell state.

When referring to induction, or alternatively suppression of a particular signature, preferably it is meant: induction or alternatively suppression (or upregulation or downregulation) of at least one gene/protein and/or epigenetic element of the signature, such as for instance at least two, at least three, at least four, at least five, at least six, or all genes/proteins and/or epigenetic elements of the signature.

In certain embodiments, signature genes and biomarkers related to HIV-infection may be identified by comparing single cell expression profiles obtained from HIV-infected individuals with healthy individuals.

In certain embodiments, signature genes and biomarkers related to HIV-infection may be identified by comparing single cell expression profiles obtained from healthy individuals with cART treated HIV infected individuals. In another embodiment, signature genes and biomarkers related to HIV-infection may be identified by comparing single cell expression profiles obtained from healthy individuals and single cell expression profile from cells obtained from cART treated HIV infected individuals and further reactivated.

Various aspects and embodiments of the invention may involve analyzing gene signatures, protein signature, and/or other genetic or epigenetic signature based on single cell analyses (e.g. single cell RNA sequencing) or alternatively based on cell population analyses, as is defined herein elsewhere.

In certain example embodiments, the signature genes may be used to distinguish cell types, characterize individual cell phenotypes, cell signatures, cell expression profiles or expression programs, and identify cell-cell interaction in the network of cells within a sampled population present in HIV infected individual or cells based on comparing them to data from bulk analysis of HIV infected sample. In certain example embodiments, the presence of specific immune cells and immune cell subtypes may be indicative of HIV infection, latent HIV infection, and/or resistance to treatment. In certain example embodiments, induction or suppression of specific signature genes may be indicative of HIV infection, latent HIV infection, and/or resistance to treatment. In one example embodiment, detection of one or more signature genes may indicate the presence of a particular cell type or cell types. In certain example embodiments, the presence of immune cell types within HIV infected cell population may indicate that the cells will be sensitive to a treatment.

Detection of Cell Sub-Populations

In one embodiment, the method comprises detecting or quantifying HIV infected cells in a biological sample. A marker, for example a gene or gene product, for example a peptide, polypeptide, protein, or nucleic acid, or a group of two or more markers, is “detected” or “measured” in a tested object (e.g., in or on a cell, cell population, tissue, organ, or organism, e.g., in a biological sample of a subject) when the presence or absence and/or quantity of said marker or said group of markers is detected or determined in the tested object, preferably substantially to the exclusion of other molecules and analytes, e.g., other genes or gene products.

In one embodiment, the method comprises detecting or quantifying a sub-population of cells harboring persistent or latent HIV-infection in a biological sample. A marker, for example a gene or gene product, for example a peptide, polypeptide, protein, or nucleic acid, or a group of two or more markers, is “detected” or “measured” in a tested object (e.g., in or on a cell, cell population, tissue, organ, or organism, e.g., in a biological sample of a subject) when the presence or absence and/or quantity of said marker or said group of markers is detected or determined in the tested object, preferably substantially to the exclusion of other molecules and analytes, e.g., other genes or gene products.

In a preferred embodiment, the method comprises detecting or quantifying pathogen in an easily obtainable sample such as blood or body fluid as a proxy or surrogate indicative of infection states of the tested sub population of cells, a different sub population of cells, a different tissue, or the whole organism.

The terms “sample” or “biological sample” as used throughout this specification include any biological specimen obtained from a subject. Particularly useful samples are those known to comprise, or expected or predicted to comprise gut cells as taught herein. Preferably, a sample may be readily obtainable by minimally invasive methods, such as blood collection or tissue biopsy, allowing the removal/isolation/provision of the sample from the subject (e.g., colonoscopy).

The terms “quantity”, “amount” and “level” are synonymous and generally well-understood in the art. The terms as used throughout this specification may particularly refer to an absolute quantification of a marker in a tested object (e.g., in or on a cell, cell population, tissue, organ, or organism, e.g., in a biological sample of a subject), or to a relative quantification of a marker in a tested object, i.e., relative to another value such as relative to a reference value, or to a range of values indicating a base-line of the marker. Such values or ranges may be obtained as conventionally known.

An absolute quantity of a marker may be advantageously expressed as weight or as molar amount, or more commonly as a concentration, e.g., weight per volume or mol per volume. A relative quantity of a marker may be advantageously expressed as an increase or decrease or as a fold-increase or fold-decrease relative to said another value, such as relative to a reference value. Performing a relative comparison between first and second variables (e.g., first and second quantities) may but need not require determining first the absolute values of said first and second variables. For example, a measurement method may produce quantifiable readouts (such as, e.g., signal intensities) for said first and second variables, wherein said readouts are a function of the value of said variables, and wherein said readouts may be directly compared to produce a relative value for the first variable vs. the second variable, without the actual need to first convert the readouts to absolute values of the respective variables.

Reference values may be established according to known procedures previously employed for other cell populations, biomarkers and gene or gene product signatures. For example, a reference value may be established in an individual or a population of individuals characterized by a particular diagnosis, prediction and/or prognosis of said disease or condition (i.e., for whom said diagnosis, prediction and/or prognosis of the disease or condition holds true). Such population may comprise without limitation 2 or more, 10 or more, 100 or more, or even several hundred or more individuals.

A “deviation” of a first value from a second value may generally encompass any direction (e.g., increase: first value >second value; or decrease: first value <second value) and any extent of alteration.

For example, a deviation may encompass a decrease in a first value by, without limitation, at least about 10% (about 0.9-fold or less), or by at least about 20% (about 0.8-fold or less), or by at least about 30% (about 0.7-fold or less), or by at least about 40% (about 0.6-fold or less), or by at least about 50% (about 0.5-fold or less), or by at least about 60% (about 0.4-fold or less), or by at least about 70% (about 0.3-fold or less), or by at least about 80% (about 0.2-fold or less), or by at least about 90% (about 0.1-fold or less), relative to a second value with which a comparison is being made.

For example, a deviation may encompass an increase of a first value by, without limitation, at least about 10% (about 1.1-fold or more), or by at least about 20% (about 1.2-fold or more), or by at least about 30% (about 1.3-fold or more), or by at least about 40% (about 1.4-fold or more), or by at least about 50% (about 1.5-fold or more), or by at least about 60% (about 1.6-fold or more), or by at least about 70% (about 1.7-fold or more), or by at least about 80% (about 1.8-fold or more), or by at least about 90% (about 1.9-fold or more), or by at least about 100% (about 2-fold or more), or by at least about 150% (about 2.5-fold or more), or by at least about 200% (about 3-fold or more), or by at least about 500% (about 6-fold or more), or by at least about 700% (about 8-fold or more), or like, relative to a second value with which a comparison is being made.

Preferably, a deviation may refer to a statistically significant observed alteration. For example, a deviation may refer to an observed alteration which falls outside of error margins of reference values in a given population (as expressed, for example, by standard deviation or standard error, or by a predetermined multiple thereof, e.g., ±1×SD or ±2×SD or ±3×SD, or ±1×SE or ±2×SE or ±3×SE). Deviation may also refer to a value falling outside of a reference range defined by values in a given population (for example, outside of a range which comprises ≥40%, ≥50%, ≥60%, ≥70%, ≥75% or ≥80% or ≥85% or ≥90% or ≥95% or even ≥100% of values in said population).

In a further embodiment, a deviation may be concluded if an observed alteration is beyond a given threshold or cut-off. Such threshold or cut-off may be selected as generally known in the art to provide for a chosen sensitivity and/or specificity of the prediction methods, e.g., sensitivity and/or specificity of at least 50%, or at least 60%, or at least 70%, or at least 80%, or at least 85%, or at least 90%, or at least 95%.

For example, receiver-operating characteristic (ROC) curve analysis can be used to select an optimal cut-off value of the quantity of a given immune cell population, biomarker or gene or gene product signatures, for clinical use of the present diagnostic tests, based on acceptable sensitivity and specificity, or related performance measures which are well-known per se, such as positive predictive value (PPV), negative predictive value (NPV), positive likelihood ratio (LR+), negative likelihood ratio (LR−), Youden index, or similar.

The terms “diagnosis” and “monitoring” are commonplace and well-understood in medical practice. By means of further explanation and without limitation the term “diagnosis” generally refers to the process or act of recognizing, deciding on or concluding on a disease or condition in a subject on the basis of symptoms and signs and/or from results of various diagnostic procedures (such as, for example, from knowing the presence, absence and/or quantity of one or more biomarkers characteristic of the diagnosed disease or condition).

The term “monitoring” generally refers to the follow-up of a disease or a condition in a subject for any changes which may occur over time.

The terms “prognosing” or “prognosis” generally refer to an anticipation on the progression of a disease or condition and the prospect (e.g., the probability, duration, and/or extent) of recovery. A good prognosis of the diseases or conditions taught herein may generally encompass anticipation of a satisfactory partial or complete recovery from the diseases or conditions, preferably within an acceptable time period. A good prognosis of such may more commonly encompass anticipation of not further worsening or aggravating of such, preferably within a given time period. A poor prognosis of the diseases or conditions as taught herein may generally encompass anticipation of a substandard recovery and/or unsatisfactorily slow recovery, or to substantially no recovery or even further worsening of such.

The terms also encompass prediction of a disease. The terms “predicting” or “prediction” generally refer to an advance declaration, indication or foretelling of a disease or condition in a subject not (yet) having said disease or condition. For example, a prediction of a disease or condition in a subject may indicate a probability, chance or risk that the subject will develop said disease or condition, for example within a certain time period or by a certain age. Said probability, chance or risk may be indicated inter alia as an absolute value, range or statistics, or may be indicated relative to a suitable control subject or subject population (such as, e.g., relative to a general, normal or healthy subject or subject population). Hence, the probability, chance or risk that a subject will develop a disease or condition may be advantageously indicated as increased or decreased, or as fold-increased or fold-decreased relative to a suitable control subject or subject population. As used herein, the term “prediction” of the conditions or diseases as taught herein in a subject may also particularly mean that the subject has a ‘positive’ prediction of such, i.e., that the subject is at risk of having such (e.g., the risk is significantly increased vis-à-vis a control subject or subject population). The term “prediction of no” diseases or conditions as taught herein as described herein in a subject may particularly mean that the subject has a ‘negative’ prediction of such, i.e., that the subject's risk of having such is not significantly increased vis-à-vis a control subject or subject population.

Methods of Detection and Isolation of Cell Types Using Biomarkers

In certain embodiments, the cell types disclosed herein may be detected, quantified or isolated using a technique selected from the group consisting of flow cytometry, mass cytometry, fluorescence activated cell sorting (FACS), fluorescence microscopy, affinity separation, magnetic cell separation, microfluidic separation, RNA-seq (e.g., bulk or single cell), quantitative PCR, MERFISH (multiplex (in situ) RNA FISH) and combinations thereof. The technique may employ one or more agents capable of specifically binding to one or more gene products expressed or not expressed by the gut cells, preferably on the cell surface of the gut cells. The one or more agents may be one or more antibodies. Other methods including absorbance assays and colorimetric assays are known in the art and may be used herein.

Depending on factors that can be evaluated and decided on by a skilled person, such as, inter alia, the type of a marker (e.g., peptide, polypeptide, protein, or nucleic acid), the type of the tested object (e.g., a cell, cell population, tissue, organ, or organism, e.g., the type of biological sample of a subject, e.g., whole blood, plasma, serum, tissue biopsy), the expected abundance of the marker in the tested object, the type, robustness, sensitivity and/or specificity of the detection method used to detect the marker, etc., the marker may be measured directly in the tested object, or the tested object may be subjected to one or more processing steps aimed at achieving an adequate measurement of the marker.

In other example embodiments, detection of a marker may include immunological assay methods, wherein the ability of an assay to separate, detect and/or quantify a marker (such as, preferably, peptide, polypeptide, or protein) is conferred by specific binding between a separable, detectable and/or quantifiable immunological binding agent (antibody) and the marker. Immunological assay methods include without limitation immunohistochemistry, immunocytochemistry, flow cytometry, mass cytometry, fluorescence activated cell sorting (FACS), fluorescence microscopy, fluorescence based cell sorting using microfluidic systems, immunoaffinity adsorption based techniques such as affinity chromatography, magnetic particle separation, magnetic activated cell sorting or bead based cell sorting using microfluidic systems, enzyme-linked immunosorbent assay (ELISA) and ELISPOT based techniques, radioimmunoassay (MA), Western blot, etc.

In certain example embodiments, detection of a marker or signature may include biochemical assay methods, including inter alia assays of enzymatic activity, membrane channel activity, substance-binding activity, gene regulatory activity, or cell signaling activity of a marker, e.g., peptide, polypeptide, protein, or nucleic acid.

In other example embodiments, detection of a marker may include mass spectrometry analysis methods. Generally, any mass spectrometric (MS) techniques that are capable of obtaining precise information on the mass of peptides, and preferably also on fragmentation and/or (partial) amino acid sequence of selected peptides (e.g., in tandem mass spectrometry, MS/MS; or in post source decay, TOF MS), may be useful herein for separation, detection and/or quantification of markers (such as, preferably, peptides, polypeptides, or proteins). Suitable peptide MS and MS/MS techniques and systems are well-known per se (see, e.g., Methods in Molecular Biology, vol. 146: “Mass Spectrometry of Proteins and Peptides”, by Chapman, ed., Humana Press 2000, ISBN 089603609x; Biemann 1990. Methods Enzymol 193: 455-79; or Methods in Enzymology, vol. 402: “Biological Mass Spectrometry”, by Burlingame, ed., Academic Press 2005, ISBN 9780121828073) and may be used herein. MS arrangements, instruments and systems suitable for biomarker peptide analysis may include, without limitation, matrix-assisted laser desorption/ionisation time-of-flight (MALDI-TOF) MS; MALDI-TOF post-source-decay (PSD); MALDI-TOF/TOF; surface-enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF) MS; electrospray ionization mass spectrometry (ESI-MS); ESI-MS/MS; ESI-MS/(MS)n (n is an integer greater than zero); ESI 3D or linear (2D) ion trap MS; ESI triple quadrupole MS; ESI quadrupole orthogonal TOF (Q-TOF); ESI Fourier transform MS systems; desorption/ionization on silicon (DIOS); secondary ion mass spectrometry (SIMS); atmospheric pressure chemical ionization mass spectrometry (APCI-MS); APCI-MS/MS; APCI-(MS)n; atmospheric pressure photoionization mass spectrometry (APPI-MS); APPI-MS/MS; and APPI-(MS)n. Peptide ion fragmentation in tandem MS (MS/MS) arrangements may be achieved using manners established in the art, such as, e.g., collision induced dissociation (CID). Detection and quantification of markers by mass spectrometry may involve multiple reaction monitoring (MRM), such as described among others by Kuhn et al. 2004 (Proteomics 4: 1175-86). MS peptide analysis methods may be advantageously combined with upstream peptide or protein separation or fractionation methods, such as for example with the chromatographic and other methods.

In other example embodiments, detection of a marker may include chromatography methods. In a one example embodiment, chromatography refers to a process in which a mixture of substances (analytes) carried by a moving stream of liquid or gas (“mobile phase”) is separated into components as a result of differential distribution of the analytes, as they flow around or over a stationary liquid or solid phase (“stationary phase”), between said mobile phase and said stationary phase. The stationary phase may be usually a finely divided solid, a sheet of filter material, or a thin film of a liquid on the surface of a solid, or the like. Chromatography may be columnar. While particulars of chromatography are well known in the art, for further guidance see, e.g., Meyer M., 1998, ISBN: 047198373X, and “Practical HPLC Methodology and Applications”, Bidlingmeyer, B. A., John Wiley & Sons Inc., 1993. Exemplary types of chromatography include, without limitation, high-performance liquid chromatography (HPLC), normal phase HPLC (NP-HPLC), reversed phase HPLC (RP-HPLC), ion exchange chromatography (IEC), such as cation or anion exchange chromatography, hydrophilic interaction chromatography (HILIC), hydrophobic interaction chromatography (HIC), size exclusion chromatography (SEC) including gel filtration chromatography or gel permeation chromatography, chromatofocusing, affinity chromatography such as immunoaffinity, immobilised metal affinity chromatography, and the like.

In certain embodiments, further techniques for separating, detecting and/or quantifying markers may be used in conjunction with any of the above described detection methods. Such methods include, without limitation, chemical extraction partitioning, isoelectric focusing (IEF) including capillary isoelectric focusing (CLEF), capillary isotachophoresis (CITP), capillary electrochromatography (CEC), and the like, one-dimensional polyacrylamide gel electrophoresis (PAGE), two-dimensional polyacrylamide gel electrophoresis (2D-PAGE), capillary gel electrophoresis (CGE), capillary zone electrophoresis (CZE), micellar electrokinetic chromatography (MEKC), free flow electrophoresis (FFE), etc.

In certain examples, such methods may include separating, detecting and/or quantifying markers at the nucleic acid level, more particularly RNA level, e.g., at the level of hnRNA, pre-mRNA, mRNA, or cDNA. Standard quantitative RNA or cDNA measurement tools known in the art may be used. Non-limiting examples include hybridization-based analysis, microarray expression analysis, digital gene expression profiling (DGE), RNA-in-situ hybridization (RISH), Northern-blot analysis and the like; PCR, RT-PCR, RT-qPCR, end-point PCR, digital PCR or the like; supported oligonucleotide detection, pyrosequencing, polony cyclic sequencing by synthesis, simultaneous bi-directional sequencing, single-molecule sequencing, single molecule real time sequencing, true single molecule sequencing, hybridization-assisted nanopore sequencing, sequencing by synthesis, single-cell RNA sequencing (scRNA-seq), or the like. By means of an example, methods to profile the RNA content of large numbers of individual cells have been recently developed. The cell of origin is determined by a cellular barcode. In certain embodiments, special microfluidic devices have been developed to encapsulate each cell in an individual drop, associate the RNA of each cell with a ‘cell barcode’ unique to that cell/drop, measure the expression level of each RNA with sequencing, and then use the cell barcodes to determine which cell each RNA molecule came from. In these regards, reference is made to Macosko et al., 2015, “Highly Parallel Genome-wide Expression Profiling of Individual Cells Using Nanoliter Droplets” Cell 161, 1202-1214; International patent application number PCT/US2015/049178, published as WO2016/040476 on Mar. 17, 2016; Klein et al., 2015, “Droplet Barcoding for Single-Cell Transcriptomics Applied to Embryonic Stem Cells” Cell 161, 1187-1201; International patent application number PCT/US2016/027734, published as WO2016168584A1 on Oct. 20, 2016; Zheng, et al., 2016, “Haplotyping germline and cancer genomes with high-throughput linked-read sequencing” Nature Biotechnology 34, 303-311; Zheng, et al., 2017, “Massively parallel digital transcriptional profiling of single cells” Nat. Commun. 8, 14049 doi: 10.1038/ncomms14049; International patent publication number WO 2014210353 A2; Zilionis, et al., 2017, “Single-cell barcoding and sequencing using droplet microfluidics” Nat Protoc. January; 12(1):44-73; Cao et al., 2017, “Comprehensive single cell transcriptional profiling of a multicellular organism by combinatorial indexing” bioRxiv preprint first posted online Feb. 2, 2017, doi: dx.doi.org/10.1101/104844; and Rosenberg et al., 2017, “Scaling single cell transcriptomics through split pool barcoding” bioRxiv preprint first posted online Feb. 2, 2017, doi: dx.doi.org/10.1101/105163, all the contents and disclosure of each of which are herein incorporated by reference in their entirety.

In certain embodiments, the invention involves single nucleus RNA sequencing. In this regard, reference is made to Swiech et al., 2014, “In vivo interrogation of gene function in the mammalian brain using CRISPR-Cas9” Nature Biotechnology Vol. 33, pp. 102-106; and Habib et al., 2016, “Div-Seq: Single-nucleus RNA-Seq reveals dynamics of rare adult newborn neurons” Science, Vol. 353, Issue 6302, pp. 925-928, both of which are herein incorporated by reference in their entirety.

The terms “isolating” or “purifying” as used throughout this specification with reference to a particular component of a composition or mixture (e.g., the tested object such as the biological sample) encompass processes or techniques whereby such component is separated from one or more or (substantially) all other components of the composition or mixture (e.g., the tested object such as the biological sample). The terms do not require absolute purity. Instead, isolating or purifying the component will produce a discrete environment in which the abundance of the component relative to one or more or all other components is greater than in the starting composition or mixture (e.g., the tested object such as the biological sample). A discrete environment may denote a single medium, such as for example a single solution, dispersion, gel, precipitate, etc. Isolating or purifying the specified cells from the tested object such as the biological sample may increase the abundance of the specified cells relative to all other cells comprised in the tested object such as the biological sample, or relative to other cells of a select subset of the cells comprised in the tested object such as the biological sample, e.g., relative to other white blood cells, peripheral blood mononuclear cells, immune cells, antigen presenting cells, or dendritic cells comprised in the tested object such as the biological sample. By means of example, isolating or purifying the specified cells from the tested object such as the biological sample may yield a cell population, in which the specified cells constitute at least 40% (by number) of all cells of said cell population, for example, at least 45%, preferably at least 50%, at least 55%, more preferably at least 60%, at least 65%, still more preferably at least 70%, at least 75%, even more preferably at least 80%, at least 85%, and yet more preferably at least 90%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or even 100% of all cells of said cell population.

The method may allow a skilled person to detect or conclude the presence or absence of the specified cells in a tested object (e.g., in a cell population, tissue, organ, organism, or in a biological sample of a subject). The method may also allow a skilled person to quantify the specified cells in a tested object (e.g., in a cell population, tissue, organ, organism, or in a biological sample of a subject). The quantity of the specified cells in the tested object such as the biological sample may be suitably expressed for example as the number (count) of the specified immune cells per standard unit of volume (e.g., ml, μl or nl) or weight (e.g., g or mg or ng) of the tested object such as the biological sample. The quantity of the specified cells in the tested object such as the biological sample may also be suitably expressed as a percentage or fraction (by number) of all cells comprised in the tested object such as the biological sample, or as a percentage or fraction (by number) of a select subset of the cells comprised in the tested object such as the biological sample, e.g., as a percentage or fraction (by number) of white blood cells, peripheral blood mononuclear cells, immune cells, antigen presenting cells, or dendritic cells comprised in the tested object such as the biological sample. The quantity of the specified cells in the tested object such as the biological sample may also be suitably represented by an absolute or relative quantity of a suitable surrogate analyte, such as a peptide, polypeptide, protein, or nucleic acid expressed or comprised by the specified cells.

Where a marker is detected in or on a cell, the cell may be conventionally denoted as positive (+) or negative (−) for the marker. Semi-quantitative denotations of marker expression in cells are also commonplace in the art, such as particularly in flow cytometry quantifications, for example, “dim” vs. “bright”, or “low” vs. “medium”/“intermediate” vs. “high”, or “−” vs. “+” vs. “++”, commonly controlled in flow cytometry quantifications by setting of the gates. Where a marker is quantified in or on a cell, absolute quantity of the marker may also be expressed for example as the number of molecules of the marker comprised by the cell.

Where a marker is detected and/or quantified on a single cell level in a cell population, the quantity of the marker may also be expressed as a percentage or fraction (by number) of cells comprised in said population that are positive for said marker, or as percentages or fractions (by number) of cells comprised in said population that are “dim” or “bright”, or that are “low” or “medium”/“intermediate” or “high”, or that are “−” or “+” or “++”. By means of an example, a sizeable proportion of the tested cells of the cell population may be positive for the marker, e.g., at least about 20%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, at least about 90%, at least about 95%, or up to 100%.

Use of Specific Binding Agents

In certain embodiments, the aforementioned methods and techniques may employ agent(s) capable of specifically binding to one or more gene products, e.g., peptides, polypeptides, proteins, or nucleic acids, expressed or not expressed by the immune cells as taught herein. In certain preferred embodiments, such one or more gene products, e.g., peptides, polypeptides, or proteins, may be expressed on the cell surface of the immune cells (i.e., cell surface markers, e.g., transmembrane peptides, polypeptides or proteins, or secreted peptides, polypeptides or proteins which remain associated with the cell surface). Hence, further disclosed are binding agents capable of specifically binding to markers, such as genes or gene products, e.g., peptides, polypeptides, proteins, or nucleic acids as taught herein. Binding agents as intended throughout this specification may include inter alia antibodies, aptamers, spiegelmers (L-aptamers), photoaptamers, protein, peptides, peptidomimetics, nucleic acids such as oligonucleotides (e.g., hybridization probes or amplification or sequencing primers and primer pairs), small molecules, or combinations thereof.

The term “aptamer” refers to single-stranded or double-stranded oligo-DNA, oligo-RNA or oligo-DNA/RNA or any analogue thereof that specifically binds to a target molecule such as a peptide. Advantageously, aptamers display fairly high specificity and affinity (e.g., KA in the order 1×109 M−1) for their targets. Aptamer production is described inter alia in U.S. Pat. No. 5,270,163; Ellington & Szostak 1990 (Nature 346: 818-822); Tuerk & Gold 1990 (Science 249: 505-510); or “The Aptamer Handbook: Functional Oligonucleotides and Their Applications”, by Klussmann, ed., Wiley-VCH 2006, ISBN 3527310592, incorporated by reference herein. The term “photoaptamer” refers to an aptamer that contains one or more photoreactive functional groups that can covalently bind to or crosslink with a target molecule. The term “spiegelmer” refers to an aptamer which includes L-DNA, L-RNA, or other left-handed nucleotide derivatives or nucleotide-like molecules. Aptamers containing left-handed nucleotides are resistant to degradation by naturally occurring enzymes, which normally act on substrates containing right-handed nucleotides. The term “peptidomimetic” refers to a non-peptide agent that is a topological analogue of a corresponding peptide. Methods of rationally designing peptidomimetics of peptides are known in the art. For example, the rational design of three peptidomimetics based on the sulphated 8-mer peptide CCK26-33, and of two peptidomimetics based on the 11-mer peptide Substance P, and related peptidomimetic design principles, are described in Horwell 1995 (Trends Biotechnol 13: 132-134).

Binding agents may be in various forms, e.g., lyophilised, free in solution, or immobilised on a solid phase. They may be, e.g., provided in a multi-well plate or as an array or microarray, or they may be packaged separately, individually, or in combination.

The term “specifically bind” as used throughout this specification means that an agent (denoted herein also as “specific-binding agent”) binds to one or more desired molecules or analytes (e.g., peptides, polypeptides, proteins, or nucleic acids) substantially to the exclusion of other molecules which are random or unrelated, and optionally substantially to the exclusion of other molecules that are structurally related. The term “specifically bind” does not necessarily require that an agent binds exclusively to its intended target(s). For example, an agent may be said to specifically bind to target(s) of interest if its affinity for such intended target(s) under the conditions of binding is at least about 2-fold greater, preferably at least about 5-fold greater, more preferably at least about 10-fold greater, yet more preferably at least about 25-fold greater, still more preferably at least about 50-fold greater, and even more preferably at least about 100-fold, or at least about 1000-fold, or at least about 104-fold, or at least about 105-fold, or at least about 106-fold or more greater, than its affinity for a non-target molecule, such as for a suitable control molecule (e.g., bovine serum albumin, casein).

Preferably, the specific binding agent may bind to its intended target(s) with affinity constant (KA) of such binding KA≥1×106 M−1, more preferably KA≥1×107 M−1, yet more preferably KA≥1×108 M−1, even more preferably KA≥1×109 M−1, and still more preferably KA≥1×1010 M−1 or KA≥1×1011 M−1 or KA≥1×1012 M−1, wherein KA=[SBA_T]/[SBA][T], SBA denotes the specific-binding agent, T denotes the intended target. Determination of KA can be carried out by methods known in the art, such as for example, using equilibrium dialysis and Scatchard plot analysis.

In certain embodiments, the one or more binding agents may be one or more antibodies. As used herein, the term “antibody” is used in its broadest sense and generally refers to any immunologic binding agent. The term specifically encompasses intact monoclonal antibodies, polyclonal antibodies, multivalent (e.g., 2-, 3- or more-valent) and/or multi-specific antibodies (e.g., bi- or more-specific antibodies) formed from at least two intact antibodies, and antibody fragments insofar they exhibit the desired biological activity (particularly, ability to specifically bind an antigen of interest, i.e., antigen-binding fragments), as well as multivalent and/or multi-specific composites of such fragments. The term “antibody” is not only inclusive of antibodies generated by methods comprising immunization, but also includes any polypeptide, e.g., a recombinantly expressed polypeptide, which is made to encompass at least one complementarity-determining region (CDR) capable of specifically binding to an epitope on an antigen of interest. Hence, the term applies to such molecules regardless whether they are produced in vitro or in vivo. Antibodies also encompasses chimeric, humanized and fully humanized antibodies.

An antibody may be any of IgA, IgD, IgE, IgG and IgM classes, and preferably IgG class antibody. An antibody may be a polyclonal antibody, e.g., an antiserum or immunoglobulins purified there from (e.g., affinity-purified). An antibody may be a monoclonal antibody or a mixture of monoclonal antibodies. Monoclonal antibodies can target a particular antigen or a particular epitope within an antigen with greater selectivity and reproducibility. By means of example and not limitation, monoclonal antibodies may be made by the hybridoma method first described by Kohler et al. 1975 (Nature 256: 495), or may be made by recombinant DNA methods (e.g., as in U.S. Pat. No. 4,816,567). Monoclonal antibodies may also be isolated from phage antibody libraries using techniques as described by Clackson et al. 1991 (Nature 352: 624-628) and Marks et al. 1991 (J Mol Biol 222: 581-597), for example.

Antibody binding agents may be antibody fragments. “Antibody fragments” comprise a portion of an intact antibody, comprising the antigen-binding or variable region thereof. Examples of antibody fragments include Fab, Fab′, F(ab′)2, Fv and scFv fragments, single domain (sd) Fv, such as VH domains, VL domains and VHH domains; diabodies; linear antibodies; single-chain antibody molecules, in particular heavy-chain antibodies; and multivalent and/or multispecific antibodies formed from antibody fragment(s), e.g., dibodies, tribodies, and multibodies. The above designations Fab, Fab′, F(ab′)2, Fv, scFv etc. are intended to have their art-established meaning.

The term antibody includes antibodies originating from or comprising one or more portions derived from any animal species, preferably vertebrate species, including, e.g., birds and mammals. Without limitation, the antibodies may be chicken, turkey, goose, duck, guinea fowl, quail or pheasant. Also without limitation, the antibodies may be human, murine (e.g., mouse, rat, etc.), donkey, rabbit, goat, sheep, guinea pig, camel (e.g., Camelus bactrianus and Camelus dromedarius), llama (e.g., Lama pacos, Lama glama or Lama vicugna) or horse.

A skilled person will understand that an antibody can include one or more amino acid deletions, additions and/or substitutions (e.g., conservative substitutions), insofar such alterations preserve its binding of the respective antigen. An antibody may also include one or more native or artificial modifications of its constituent amino acid residues (e.g., glycosylation, etc.).

Methods of producing polyclonal and monoclonal antibodies as well as fragments thereof are well known in the art, as are methods to produce recombinant antibodies or fragments thereof (see for example, Harlow and Lane, “Antibodies: A Laboratory Manual”, Cold Spring Harbour Laboratory, New York, 1988; Harlow and Lane, “Using Antibodies: A Laboratory Manual”, Cold Spring Harbour Laboratory, New York, 1999, ISBN 0879695447; “Monoclonal Antibodies: A Manual of Techniques”, by Zola, ed., CRC Press 1987, ISBN 0849364760; “Monoclonal Antibodies: A Practical Approach”, by Dean & Shepherd, eds., Oxford University Press 2000, ISBN 0199637229; Methods in Molecular Biology, vol. 248: “Antibody Engineering: Methods and Protocols”, Lo, ed., Humana Press 2004, ISBN 1588290921).

Nucleic acid binding agents, such as oligonucleotide binding agents, are typically at least partly antisense to a target nucleic acid of interest. The term “antisense” generally refers to an agent (e.g., an oligonucleotide) configured to specifically anneal with (hybridise to) a given sequence in a target nucleic acid, such as for example in a target DNA, hnRNA, pre-mRNA or mRNA, and typically comprises, consist essentially of or consist of a nucleic acid sequence that is complementary or substantially complementary to said target nucleic acid sequence. Antisense agents suitable for use herein, such as hybridisation probes or amplification or sequencing primers and primer pairs) may typically be capable of annealing with (hybridizing to) the respective target nucleic acid sequences at high stringency conditions, and capable of hybridising specifically to the target under physiological conditions. The terms “complementary” or “complementarity” as used throughout this specification with reference to nucleic acids, refer to the normal binding of single-stranded nucleic acids under permissive salt (ionic strength) and temperature conditions by base pairing, preferably Watson-Crick base pairing. By means of example, complementary Watson-Crick base pairing occurs between the bases A and T, A and U or G and C. For example, the sequence 5′-A-G-U-3′ is complementary to sequence 5′-A-C-U-3′.

The reference to oligonucleotides may in particular but without limitation include hybridization probes and/or amplification primers and/or sequencing primers, etc., as commonly used in nucleic acid detection technologies.

Binding agents as discussed herein may suitably comprise a detectable label. The term “label” refers to any atom, molecule, moiety or biomolecule that may be used to provide a detectable and preferably quantifiable read-out or property, and that may be attached to or made part of an entity of interest, such as a binding agent. Labels may be suitably detectable by for example mass spectrometric, spectroscopic, optical, colorimetric, magnetic, photochemical, biochemical, immunochemical or chemical means. Labels include without limitation dyes; radiolabels such as 32P, 33P, 35S, 1251, 1311; electron-dense reagents; enzymes (e.g., horse-radish peroxidase or alkaline phosphatase as commonly used in immunoassays); binding moieties such as biotin-streptavidin; haptens such as digoxigenin; luminogenic, phosphorescent or fluorogenic moieties; mass tags; and fluorescent dyes alone or in combination with moieties that may suppress or shift emission spectra by fluorescence resonance energy transfer (FRET).

In some embodiments, binding agents may be provided with a tag that permits detection with another agent (e.g., with a probe binding partner). Such tags may be, for example, biotin, streptavidin, his-tag, myc tag, maltose, maltose binding protein or any other kind of tag known in the art that has a binding partner. Example of associations which may be utilised in the probe:binding partner arrangement may be any, and includes, for example biotin: streptavidin, his-tag:metal ion (e.g., Ni2+), maltose:maltose binding protein, etc.

The marker-binding agent conjugate may be associated with or attached to a detection agent to facilitate detection. Examples of detection agents include, but are not limited to, luminescent labels; colorimetric labels, such as dyes; fluorescent labels; or chemical labels, such as electroactive agents (e.g., ferrocyanide); enzymes; radioactive labels; or radiofrequency labels. The detection agent may be a particle. Examples of such particles include, but are not limited to, colloidal gold particles; colloidal sulphur particles; colloidal selenium particles; colloidal barium sulfate particles; colloidal iron sulfate particles; metal iodate particles; silver halide particles; silica particles; colloidal metal (hydrous) oxide particles; colloidal metal sulfide particles; colloidal lead selenide particles; colloidal cadmium selenide particles; colloidal metal phosphate particles; colloidal metal ferrite particles; any of the above-mentioned colloidal particles coated with organic or inorganic layers; protein or peptide molecules; liposomes; or organic polymer latex particles, such as polystyrene latex beads. Preferable particles may be colloidal gold particles.

In certain embodiments, the one or more binding agents are configured for use in a technique selected from the group consisting of flow cytometry, fluorescence activated cell sorting, mass cytometry, fluorescence microscopy, affinity separation, magnetic cell separation, microfluidic separation, and combinations thereof.

In some embodiments, provided herein are methods for diagnosing a latent HIV or ART-resistant HIV infection in a cell or tissue, the method comprising detecting whether one or more genes from Table 1 or Table 2 is overexpressed, or has a higher or increased level of expression compared to a cell that is HIV−.

In some embodiments, provided herein are methods for diagnosing a latent HIV or ART-resistant HIV infection in a cell or tissue, the method comprising detecting whether one or more genes from Table 3 is underexpressed, or has a lower or reduced level of expression compared to a cell that is HIV−.

Methods of Monitoring

Also provided within the scope of the invention are methods of monitoring treatment of a viral or latent viral infection. Such infections include, but are not necessarily limited to, Hepatitis B, Hepatitis C, HIV or ART-resistant HIV infection in a cell or tissue. Such methods may comprise detecting whether one or more genes from Table 1 or Table 2 is overexpressed, or has a higher or increased level of expression compared to a cell that is HIV−.

As described herein, the terms “increased” or “increase” or “upregulated” or “upregulate” as used herein generally mean an increase by a statically significant amount. For avoidance of doubt, “increased” means a statistically significant increase of at least 10% as compared to a reference level, including an increase of at least 20%, at least 30%, at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 100% or more, including, for example at least 2-fold, at least 3-fold, at least 4-fold, at least 5-fold, at least 10-fold increase or greater as compared to a reference level, as that term is defined herein.

In some embodiments, methods of monitoring are provided, comprising detecting whether one or more genes from Table 3 is underexpressed, or has a lower or reduced level of expression compared to a cell that is HIV⁻.

As described herein, the term “reduced” or “reduce” or “decrease” or “decreased” or “downregulate” or “downregulated” as used herein generally means a decrease by a statistically significant amount relative to a reference. For avoidance of doubt, “reduced” means statistically significant decrease of at least 10% as compared to a reference level, for example a decrease by at least 20%, at least 30%, at least 40%, at least 50%, or at least 60%, or at least 70%, or at least 80%, at least 90% or more, up to and including a 100% decrease (i.e., absent level as compared to a reference sample), or any decrease between 10-100% as compared to a reference level, as that.

Also provided within the scope of the invention are methods of monitoring HIV disease progression and/or treatment. Such methods may comprise detecting expression of one or more genes or gene products from Tables 1, 2 and 3 prior to administration of an anti-HIV therapy; administering a first round of an anti-HIV therapy; detecting expression of one or more genes or gene products from Tables 1, 2 and 3 after administration of the anti-HIV therapeutic; and administering an additional or alternative round or anti-HIV therapy if expression of one or more genes from Table 1 or 2 has increased or not decreased, or if expression of one or more genes in Table 3 has decreased relative to prior to administering the first anti-HIV therapy.

Anti-HIV therapy used within the scope of the invention includes, but is not necessarily limited to any anti-HIV therapy known in the art. Such therapies include entry or fusion inhibitors, nucleoside reverse transcriptase inhibitors (NRTI), non-nucleoside reverse transcriptase inhibitors (NNRTI), protease inhibitors (PI), or integrase inhibitors. Common entry inhibitors include, but are not necessarily limited to, maraviroc and enfuvirtide. Common NRTIs include, but are not necessarily limited to, zidovudine, abacavir, lamivudine, emtricitabine, and tenofovir. Common NNRTIs include, but are not necessarily limited to, nevirapine, efavirenz, etravirine, and rilpivirine. Common PIs include, but are not necessarily limited to, lopinavir, indinavir, nelfinavir, amprenavir, ritonavir, darunavir, atazanavir. Common integrase inhibitors include, but are not necessarily limited to, raltegravir, elvitegravir, and dolutegravir.

These therapies may be used in single doses, multiple doses, single drug, or combinations of drugs, in any combination. Fixed-dose combinations are multiple antiretroviral drugs combined into a single pill.

In some embodiments, the additional or alternative round of anti-HIV therapy may comprise the same drug or combination of drugs as the first round of anti-HIV therapy.

In alternative embodiments, the additional or alternative round of anti-HIV therapy may comprise a different drug or combination of drugs than the first round of anti-HIV therapy.

Methods of Treating

Provided herein are also methods of treating viral infections. Such viral infections may include, but are not necessarily limited to, HIV, by detecting one or more genes or gene signatures from Tables 1 or 2; determining whether the patient has a latent HIV or ART-resistant HIV infection based on the presence of one or more genes or gene signatures from Tables 1 or 2; and administering an anti-HIV therapeutic if one or more genes or gene signatures from Tables 1 or 2 are present.

Detection may be done by means of any of the methods know in the art or described herein. A marker, for example a gene or gene product, for example a peptide, polypeptide, protein, or nucleic acid, or a group of two or more markers, is “detected” or “measured” in a tested object (e.g., in or on a cell, cell population, tissue, organ, or organism, e.g., in a biological sample of a subject) when the presence or absence and/or quantity of said marker or said group of markers is detected or determined in the tested object, preferably substantially to the exclusion of other molecules and analytes, e.g., other genes or gene products.

Based on the detection of the presence of one or more genes or gene signatures from Tables 1 or 2, one may then determine or conclude whether the patient has a latent HIV or ART-resistant HIV infection, as described herein.

The patient may then be administered an anti-HIV therapeutic if one or more genes or gene signatures from Tables 1 or 2 are present.

It will be appreciated that administration of therapeutic entities in accordance with the invention will occur with suitable carriers, excipients, and other agents that are incorporated into formulations to provide improved transfer, delivery, tolerance, and the like. A multitude of appropriate formulations can be found in the formulary known to all pharmaceutical chemists: Remington's Pharmaceutical Sciences (15th ed, Mack Publishing Company, Easton, PA (1975)), particularly Chapter 87 by Blaug, Seymour, therein. These formulations include, for example, powders, pastes, ointments, jellies, waxes, oils, lipids, lipid (cationic or anionic) containing vesicles (such as Lipofectin™), DNA conjugates, anhydrous absorption pastes, oil-in-water and water-in-oil emulsions, emulsions carbowax (polyethylene glycols of various molecular weights), semi-solid gels, and semi-solid mixtures containing carbowax. Any of the foregoing mixtures may be appropriate in treatments and therapies in accordance with the present invention, provided that the active ingredient in the formulation is not inactivated by the formulation and the formulation is physiologically compatible and tolerable with the route of administration. See also Baldrick P. “Pharmaceutical excipient development: the need for preclinical guidance.” Regul. Toxicol Pharmacol. 32(2):210-8 (2000), Wang W. “Lyophilization and development of solid protein pharmaceuticals.” Int. J. Pharm. 203(1-2):1-60 (2000), Charman W N “Lipids, lipophilic drugs, and oral drug delivery-some emerging concepts.” J Pharm Sci. 89(8):967-78 (2000), Powell et al. “Compendium of excipients for parenteral formulations” PDA J Pharm Sci Technol. 52:238-311 (1998) and the citations therein for additional information related to formulations, excipients and carriers well known to pharmaceutical chemists.

The medicaments of the invention are prepared in a manner known to those skilled in the art, for example, by means of conventional dissolving, lyophilizing, mixing, granulating or confectioning processes. Methods well known in the art for making formulations are found, for example, in Remington: The Science and Practice of Pharmacy, 20th ed., ed. A. R. Gennaro, 2000, Lippincott Williams & Wilkins, Philadelphia, and Encyclopedia of Pharmaceutical Technology, eds. J. Swarbrick and J. C. Boylan, 1988-1999, Marcel Dekker, New York.

Administration of medicaments of the invention may be by any suitable means that results in a compound concentration that is effective for treating or inhibiting (e.g., by delaying) the development of a disease. The compound is admixed with a suitable carrier substance, e.g., a pharmaceutically acceptable excipient that preserves the therapeutic properties of the compound with which it is administered. One exemplary pharmaceutically acceptable excipient is physiological saline. The suitable carrier substance is generally present in an amount of 1-95% by weight of the total weight of the medicament. The medicament may be provided in a dosage form that is suitable for administration. Thus, the medicament may be in form of, e.g., tablets, capsules, pills, powders, granulates, suspensions, emulsions, solutions, gels including hydrogels, pastes, ointments, creams, plasters, drenches, delivery devices, injectables, implants, sprays, or aerosols.

The agents disclosed herein (e.g., antibodies) may be used in a pharmaceutical composition when combined with a pharmaceutically acceptable carrier. Such compositions comprise a therapeutically-effective amount of the agent and a pharmaceutically acceptable carrier. Such a composition may also further comprise (in addition to an agent and a carrier) diluents, fillers, salts, buffers, stabilizers, solubilizers, and other materials well known in the art. Compositions comprising the agent can be administered in the form of salts provided the salts are pharmaceutically acceptable. Salts may be prepared using standard procedures known to those skilled in the art of synthetic organic chemistry.

The term “pharmaceutically acceptable salts” refers to salts prepared from pharmaceutically acceptable non-toxic bases or acids including inorganic or organic bases and inorganic or organic acids. Salts derived from inorganic bases include aluminum, ammonium, calcium, copper, ferric, ferrous, lithium, magnesium, manganic salts, manganous, potassium, sodium, zinc, and the like. Particularly preferred are the ammonium, calcium, magnesium, potassium, and sodium salts. Salts derived from pharmaceutically acceptable organic non-toxic bases include salts of primary, secondary, and tertiary amines, substituted amines including naturally occurring substituted amines, cyclic amines, and basic ion exchange resins, such as arginine, betaine, caffeine, choline, N,N′-dibenzylethylenediamine, diethylamine, 2-diethylaminoethanol, 2-dimethylaminoethanol, ethanolamine, ethylenediamine, N-ethyl-morpholine, N-ethylpiperidine, glucamine, glucosamine, histidine, hydrabamine, isopropylamine, lysine, methylglucamine, morpholine, piperazine, piperidine, polyamine resins, procaine, purines, theobromine, triethylamine, trimethylamine, tripropylamine, tromethamine, and the like. The term “pharmaceutically acceptable salt” further includes all acceptable salts such as acetate, lactobionate, benzenesulfonate, laurate, benzoate, malate, bicarbonate, maleate, bisulfate, mandelate, bitartrate, mesylate, borate, methylbromide, bromide, methylnitrate, calcium edetate, methylsulfate, camsylate, mucate, carbonate, napsylate, chloride, nitrate, clavulanate, N-methylglucamine, citrate, ammonium salt, dihydrochloride, oleate, edetate, oxalate, edisylate, pamoate (embonate), estolate, palmitate, esylate, pantothenate, fumarate, phosphate/diphosphate, gluceptate, polygalacturonate, gluconate, salicylate, glutamate, stearate, glycolylarsanilate, sulfate, hexylresorcinate, subacetate, hydrabamine, succinate, hydrobromide, tannate, hydrochloride, tartrate, hydroxynaphthoate, teoclate, iodide, tosylate, isothionate, triethiodide, lactate, pamoate, valerate, and the like which can be used as a dosage form for modifying the solubility or hydrolysis characteristics or can be used in sustained release or pro-drug formulations. It will be understood that, as used herein, references to specific agents (e.g., neuromedin U receptor agonists or antagonists), also include the pharmaceutically acceptable salts thereof.

Methods of administering the pharmacological compositions, including agonists, antagonists, antibodies or fragments thereof, to an individual include, but are not limited to, intradermal, intrathecal, intramuscular, intraperitoneal, intravenous, subcutaneous, intranasal, epidural, by inhalation, and oral routes. The compositions can be administered by any convenient route, for example by infusion or bolus injection, by absorption through epithelial or mucocutaneous linings (for example, oral mucosa, rectal and intestinal mucosa, and the like), ocular, and the like and can be administered together with other biologically-active agents. Administration can be systemic or local. In addition, it may be advantageous to administer the composition into the central nervous system by any suitable route, including intraventricular and intrathecal injection. Pulmonary administration may also be employed by use of an inhaler or nebulizer, and formulation with an aerosolizing agent. It may also be desirable to administer the agent locally to the area in need of treatment; this may be achieved by, for example, and not by way of limitation, local infusion during surgery, topical application, by injection, by means of a catheter, by means of a suppository, or by means of an implant.

Various delivery systems are known and can be used to administer the pharmacological compositions including, but not limited to, encapsulation in liposomes, microparticles, microcapsules; minicells; polymers; capsules; tablets; and the like. In one embodiment, the agent may be delivered in a vesicle, in particular a liposome. In a liposome, the agent is combined, in addition to other pharmaceutically acceptable carriers, with amphipathic agents such as lipids which exist in aggregated form as micelles, insoluble monolayers, liquid crystals, or lamellar layers in aqueous solution. Suitable lipids for liposomal formulation include, without limitation, monoglycerides, diglycerides, sulfatides, lysolecithin, phospholipids, saponin, bile acids, and the like. Preparation of such liposomal formulations is within the level of skill in the art, as disclosed, for example, in U.S. Pat. Nos. 4,837,028 and 4,737,323. In yet another embodiment, the pharmacological compositions can be delivered in a controlled release system including, but not limited to: a delivery pump (See, for example, Saudek, et al., New Engl. J. Med. 321: 574 (1989) and a semi-permeable polymeric material (See, for example, Howard, et al., J. Neurosurg. 71: 105 (1989)). Additionally, the controlled release system can be placed in proximity of the therapeutic target (e.g., a tumor or infected tissue), thus requiring only a fraction of the systemic dose. See, for example, Goodson, In: Medical Applications of Controlled Release, 1984. (CRC Press, Boca Raton, Fla.).

The amount of the agents which will be effective in the treatment of a particular disorder or condition will depend on the nature of the disorder or condition, and may be determined by standard clinical techniques by those of skill within the art. In addition, in vitro assays may optionally be employed to help identify optimal dosage ranges. The precise dose to be employed in the formulation will also depend on the route of administration, and the overall seriousness of the disease or disorder, and should be decided according to the judgment of the practitioner and each patient's circumstances. Ultimately, the attending physician will decide the amount of the agent with which to treat each individual patient. In certain embodiments, the attending physician will administer low doses of the agent and observe the patient's response. Larger doses of the agent may be administered until the optimal therapeutic effect is obtained for the patient, and at that point the dosage is not increased further. In general, the daily dose range of a drug lie within the range known in the art for a particular drug or biologic. Effective doses may be extrapolated from dose-response curves derived from in vitro or animal model test systems. Ultimately the attending physician will decide on the appropriate duration of therapy using compositions of the present invention. Dosage will also vary according to the age, weight and response of the individual patient.

Methods for administering antibodies for therapeutic use is well known to one skilled in the art. In certain embodiments, small particle aerosols of antibodies or fragments thereof may be administered (see e.g., Piazza et al., J. Infect. Dis., Vol. 166, pp. 1422-1424, 1992; and Brown, Aerosol Science and Technology, Vol. 24, pp. 45-56, 1996). In certain embodiments, antibodies are administered in metered-dose propellant driven aerosols. In certain embodiments, antibodies may be administered in liposomes, i.e., immunoliposomes (see, e.g., Maruyama et al., Biochim. Biophys. Acta, Vol. 1234, pp. 74-80, 1995). In certain embodiments, immunoconjugates, immunoliposomes or immunomicrospheres containing an agent of the present invention is administered by inhalation.

In certain embodiments, antibodies may be topically administered to mucosa, such as the oropharynx, nasal cavity, respiratory tract, gastrointestinal tract, eye such as the conjunctival mucosa, vagina, urogenital mucosa, or for dermal application. In certain embodiments, antibodies are administered to the nasal, bronchial or pulmonary mucosa. In order to obtain optimal delivery of the antibodies to the pulmonary cavity in particular, it may be advantageous to add a surfactant such as a phosphoglyceride, e.g. phosphatidylcholine, and/or a hydrophilic or hydrophobic complex of a positively or negatively charged excipient and a charged antibody of the opposite charge.

Other excipients suitable for pharmaceutical compositions intended for delivery of antibodies to the respiratory tract mucosa may be a) carbohydrates, e.g., monosaccharides such as fructose, galactose, glucose. D-mannose, sorbose, and the like; disaccharides, such as lactose, trehalose, cellobiose, and the like; cyclodextrins, such as 2-hydroxypropyl-β-cyclodextrin; and polysaccharides, such as raffinose, maltodextrins, dextrans, and the like; b) amino acids, such as glycine, arginine, aspartic acid, glutamic acid, cysteine, lysine and the like; c) organic salts prepared from organic acids and bases, such as sodium citrate, sodium ascorbate, magnesium gluconate, sodium gluconate, tromethamine hydrochloride, and the like: d) peptides and proteins, such as aspartame, human serum albumin, gelatin, and the like; e) alditols, such mannitol, xylitol, and the like, and f) polycationic polymers, such as chitosan or a chitosan salt or derivative.

For dermal application, the antibodies of the present invention may suitably be formulated with one or more of the following excipients: solvents, buffering agents, preservatives, humectants, chelating agents, antioxidants, stabilizers, emulsifying agents, suspending agents, gel-forming agents, ointment bases, penetration enhancers, and skin protective agents.

Examples of solvents are e.g. water, alcohols, vegetable or marine oils (e.g. edible oils like almond oil, castor oil, cacao butter, coconut oil, corn oil, cottonseed oil, linseed oil, olive oil, palm oil, peanut oil, poppy seed oil, rapeseed oil, sesame oil, soybean oil, sunflower oil, and tea seed oil), mineral oils, fatty oils, liquid paraffin, polyethylene glycols, propylene glycols, glycerol, liquid polyalkylsiloxanes, and mixtures thereof.

Examples of buffering agents are e.g. citric acid, acetic acid, tartaric acid, lactic acid, hydrogenphosphoric acid, diethyl amine etc. Suitable examples of preservatives for use in compositions are parabens, such as methyl, ethyl, propyl p-hydroxybenzoate, butylparaben, isobutylparaben, isopropylparaben, potassium sorbate, sorbic acid, benzoic acid, methyl benzoate, phenoxyethanol, bronopol, bronidox, MDM hydantoin, iodopropynyl butylcarbamate, EDTA, benzalkonium chloride, and benzylalcohol, or mixtures of preservatives.

Examples of humectants are glycerin, propylene glycol, sorbitol, lactic acid, urea, and mixtures thereof.

Examples of antioxidants are butylated hydroxy anisole (BHA), ascorbic acid and derivatives thereof, tocopherol and derivatives thereof, cysteine, and mixtures thereof.

Examples of emulsifying agents are naturally occurring gums, e.g. gum acacia or gum tragacanth; naturally occurring phosphatides, e.g. soybean lecithin, sorbitan monooleate derivatives: wool fats; wool alcohols; sorbitan esters; monoglycerides; fatty alcohols; fatty acid esters (e.g. triglycerides of fatty acids); and mixtures thereof.

Examples of suspending agents are e.g. celluloses and cellulose derivatives such as, e.g., carboxymethyl cellulose, hydroxyethylcellulose, hydroxypropylcellulose, hydroxypropylmethylcellulose, carrageenan, acacia gum, arabic gum, tragacanth, and mixtures thereof.

Examples of gel bases, viscosity-increasing agents or components which are able to take up exudate from a wound are: liquid paraffin, polyethylene, fatty oils, colloidal silica or aluminum, zinc soaps, glycerol, propylene glycol, tragacanth, carboxyvinyl polymers, magnesium-aluminum silicates, Carbopol®, hydrophilic polymers such as, e.g. starch or cellulose derivatives such as, e.g., carboxymethylcellulose, hydroxyethylcellulose and other cellulose derivatives, water-swellable hydrocolloids, carrageenans, hyaluronates (e.g. hyaluronate gel optionally containing sodium chloride), and alginates including propylene glycol alginate.

Examples of ointment bases are e.g. beeswax, paraffin, cetanol, cetyl palmitate, vegetable oils, sorbitan esters of fatty acids (Span), polyethylene glycols, and condensation products between sorbitan esters of fatty acids and ethylene oxide, e.g. polyoxyethylene sorbitan monooleate (Tween).

Examples of hydrophobic or water-emulsifying ointment bases are paraffins, vegetable oils, animal fats, synthetic glycerides, waxes, lanolin, and liquid polyalkylsiloxanes. Examples of hydrophilic ointment bases are solid macrogols (polyethylene glycols). Other examples of ointment bases are triethanolamine soaps, sulphated fatty alcohol and polysorbates.

Examples of other excipients are polymers such as carmellose, sodium carmellose, hydroxypropylmethylcellulose, hydroxyethylcellulose, hydroxypropylcellulose, pectin, xanthan gum, locust bean gum, acacia gum, gelatin, carbomer, emulsifiers like vitamin E, glyceryl stearates, cetearyl glucoside, collagen, carrageenan, hyaluronates and alginates and chitosans.

There are a variety of techniques available for introducing nucleic acids into viable cells. The techniques vary depending upon whether the nucleic acid is transferred into cultured cells in vitro, or in vivo in the cells of the intended host. Techniques suitable for the transfer of nucleic acid into mammalian cells in vitro include the use of liposomes, electroporation, microinjection, cell fusion, DEAE-dextran, the calcium phosphate precipitation method, etc. The currently preferred in vivo gene transfer techniques include transduction with viral (typically lentivirus, adeno associated virus (AAV) and adenovirus) vectors.

The pharmaceutical composition can be applied parenterally, rectally, orally or topically. Preferably, the pharmaceutical composition may be used for intravenous, intramuscular, subcutaneous, peritoneal, peridural, rectal, nasal, pulmonary, mucosal, or oral application. In a preferred embodiment, the pharmaceutical composition according to the invention is intended to be used as an infuse. The skilled person will understand that compositions which are to be administered orally or topically will usually not comprise cells, although it may be envisioned for oral compositions to also comprise cells, for example when gastro-intestinal tract indications are treated. Each of the cells or active components (e.g., modulants, immunomodulants, antigens) as discussed herein may be administered by the same route or may be administered by a different route. By means of example, and without limitation, cells may be administered parenterally and other active components may be administered orally.

Liquid pharmaceutical compositions may generally include a liquid carrier such as water or a pharmaceutically acceptable aqueous solution. For example, physiological saline solution, tissue or cell culture media, dextrose or other saccharide solution or glycols such as ethylene glycol, propylene glycol or polyethylene glycol may be included. The composition may include one or more cell protective molecules, cell regenerative molecules, growth factors, anti-apoptotic factors or factors that regulate gene expression in the cells. Such substances may render the cells independent of their environment. Such pharmaceutical compositions may contain further components ensuring the viability of the cells therein. For example, the compositions may comprise a suitable buffer system (e.g., phosphate or carbonate buffer system) to achieve desirable pH, more usually near neutral pH, and may comprise sufficient salt to ensure isosmotic conditions for the cells to prevent osmotic stress. For example, suitable solution for these purposes may be phosphate-buffered saline (PBS), sodium chloride solution, Ringer's Injection or Lactated Ringer's Injection, as known in the art. Further, the composition may comprise a carrier protein, e.g., albumin (e.g., bovine or human albumin), which may increase the viability of the cells.

Further suitably pharmaceutically acceptable carriers or additives are well known to those skilled in the art and for instance may be selected from proteins such as collagen or gelatine, carbohydrates such as starch, polysaccharides, sugars (dextrose, glucose and sucrose), cellulose derivatives like sodium or calcium carboxymethylcellulose, hydroxypropyl cellulose or hydroxypropylmethyl cellulose, pregelatinized starches, pectin agar, carrageenan, clays, hydrophilic gums (acacia gum, guar gum, arabic gum and xanthan gum), alginic acid, alginates, hyaluronic acid, polyglycolic and polylactic acid, dextran, pectins, synthetic polymers such as water-soluble acrylic polymer or polyvinylpyrrolidone, proteoglycans, calcium phosphate and the like.

If desired, cell preparation can be administered on a support, scaffold, matrix or material to provide improved tissue regeneration. For example, the material can be a granular ceramic, or a biopolymer such as gelatine, collagen, or fibrinogen. Porous matrices can be synthesized according to standard techniques (e.g., Mikos et al., Biomaterials 14: 323, 1993; Mikos et al., Polymer 35:1068, 1994; Cook et al., J. Biomed. Mater. Res. 35:513, 1997). Such support, scaffold, matrix or material may be biodegradable or non-biodegradable. Hence, the cells may be transferred to and/or cultured on suitable substrate, such as porous or non-porous substrate, to provide for implants.

For example, cells that have proliferated, or that are being differentiated in culture dishes, can be transferred onto three-dimensional solid supports in order to cause them to multiply and/or continue the differentiation process by incubating the solid support in a liquid nutrient medium of the invention, if necessary. Cells can be transferred onto a three-dimensional solid support, e.g. by impregnating the support with a liquid suspension containing the cells. The impregnated supports obtained in this way can be implanted in a human subject. Such impregnated supports can also be re-cultured by immersing them in a liquid culture medium, prior to being finally implanted. The three-dimensional solid support needs to be biocompatible so as to enable it to be implanted in a human. It may be biodegradable or non-biodegradable.

The cells or cell populations can be administered in a manner that permits them to survive, grow, propagate and/or differentiate towards desired cell types (e.g. differentiation) or cell states. The cells or cell populations may be grafted to or may migrate to and engraft within the intended organ. In certain embodiments, a pharmaceutical cell preparation as taught herein may be administered in a form of liquid composition. In embodiments, the cells or pharmaceutical composition comprising such can be administered systemically, topically, within an organ or at a site of organ dysfunction or lesion.

The term “therapeutically effective amount” refers to an amount which can elicit a biological or medicinal response in a tissue, system, animal or human that is being sought by a researcher, veterinarian, medical doctor or other clinician, and in particular can prevent or alleviate one or more of the local or systemic symptoms or features of a disease or condition being treated.

A further aspect of the invention provides a modulating infection in a population of infected cells as taught herein. The terms “cell population” or “population” denote a set of cells having characteristics in common. The characteristics may include in particular the one or more marker(s) or gene or gene product signature(s) as taught herein. The cells as taught herein may be comprised in a cell population. By means of example, the specified cells may constitute at least 40% (by number) of all cells of the cell population, for example, at least 45%, preferably at least 50%, at least 55%, more preferably at least 60%, at least 65%, still more preferably at least 70%, at least 75%, even more preferably at least 80%, at least 85%, and yet more preferably at least 90%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or even 100% of all cells of the cell population.

The isolated cells, cells, or populations thereof as disclosed throughout this specification may be suitably cultured or cultivated in vitro. The term “in vitro” generally denotes outside, or external to, a body, e.g., an animal or human body. The term encompasses “ex vivo”. The terms “culturing” or “cell culture” are common in the art and broadly refer to maintenance of cells and potentially expansion (proliferation, propagation) of cells in vitro. Typically, animal cells, such as mammalian cells, such as human cells, are cultured by exposing them to (i.e., contacting them with) a suitable cell culture medium in a vessel or container adequate for the purpose (e.g., a 96-, 24-, or 6-well plate, a T-25, T-75, T-150 or T-225 flask, or a cell factory), at art-known conditions conducive to in vitro cell culture, such as temperature of 37° C., 5% v/v CO2 and >95% humidity. The term “medium” as used herein broadly encompasses any cell culture medium conducive to maintenance of cells, preferably conducive to proliferation of cells. Typically, the medium will be a liquid culture medium, which facilitates easy manipulation (e.g., decantation, pipetting, centrifugation, filtration, and such) thereof.

In some embodiments, patients may be administered an anti-HIV therapeutic for ART-resistant strains of HIV. Such regimens may include, but are not necessarily limited to, second-line ART or third-line ART (Global Action Plan on HIV Drug Resistance 2017-2021 (WHO) 2017). Second-line ART may include, but is not necessarily limited to, a boosted PI plus two NRTIs. Third-line ART may include, but is not necessarily limited to, integrase inhibitors and second-generation NNRTIs and PIs.

In some embodiments, the step of detecting one or more genes or gene signatures from Table 1 or Table 2 may comprise detecting the presence of a marker using an immunological assay as described herein. In some embodiments, the immunological assay may comprise detection of specific binding between an antibody and the marker. The marker may be a peptide, polypeptide, or protein as described herein.

Pharmaceuticals

Another aspect of the invention provides a composition, pharmaceutical composition or vaccine comprising the immune cells or populations thereof, as taught herein.

One aspect of the invention provides for a composition, pharmaceutical composition or vaccine directed to HIV-infected cells, including cells harbouring persistent HIV infections

One aspect of the invention provides for a composition, pharmaceutical composition or vaccine directed to Hepatitis B- or Hepatitis C-infected cells.

A “pharmaceutical composition” refers to a composition that usually contains an excipient, such as a pharmaceutically acceptable carrier that is conventional in the art and that is suitable for administration to cells or to a subject.

The term “pharmaceutically acceptable” as used throughout this specification is consistent with the art and means compatible with the other ingredients of a pharmaceutical composition and not deleterious to the recipient thereof.

As used herein, “carrier” or “excipient” includes any and all solvents, diluents, buffers (such as, e.g., neutral buffered saline or phosphate buffered saline), solubilisers, colloids, dispersion media, vehicles, fillers, chelating agents (such as, e.g., EDTA or glutathione), amino acids (such as, e.g., glycine), proteins, disintegrants, binders, lubricants, wetting agents, emulsifiers, sweeteners, colorants, flavourings, aromatisers, thickeners, agents for achieving a depot effect, coatings, antifungal agents, preservatives, stabilisers, antioxidants, tonicity controlling agents, absorption delaying agents, and the like. The use of such media and agents for pharmaceutical active components is well known in the art. Such materials should be non-toxic and should not interfere with the activity of the cells or active components.

The precise nature of the carrier or excipient or other material will depend on the route of administration. For example, the composition may be in the form of a parenterally acceptable aqueous solution, which is pyrogen-free and has suitable pH, isotonicity and stability. For general principles in medicinal formulation, the reader is referred to Cell Therapy: Stem Cell Transplantation, Gene Therapy, and Cellular Immunotherapy, by G. Morstyn & W. Sheridan eds., Cambridge University Press, 1996; and Hematopoietic Stem Cell Therapy, E. D. Ball, J. Lister & P. Law, Churchill Livingstone, 2000.

The composition may include one or more cell protective molecules, cell regenerative molecules, growth factors, anti-apoptotic factors or factors that regulate gene expression in the cells. Such substances may render the cells independent of their environment.

Such pharmaceutical compositions may contain further components ensuring the viability of the cells therein. For example, the compositions may comprise a suitable buffer system (e.g., phosphate or carbonate buffer system) to achieve desirable pH, more usually near neutral pH, and may comprise sufficient salt to ensure isosmotic conditions for the cells to prevent osmotic stress. For example, suitable solution for these purposes may be phosphate-buffered saline (PBS), sodium chloride solution, Ringer's Injection or Lactated Ringer's Injection, as known in the art. Further, the composition may comprise a carrier protein, e.g., albumin (e.g., bovine or human albumin), which may increase the viability of the cells.

In certain embodiments, a pharmaceutical cell preparation as taught herein may be administered in a form of liquid composition. In embodiments, the cells or pharmaceutical composition comprising such can be administered systemically, topically, within an organ or at a site of organ dysfunction or lesion.

Preferably, the pharmaceutical compositions may comprise a therapeutically effective amount of the specified intestinal epithelial cells, intestinal epithelial stem cells, or intestinal immune cells (preferably intestinal epithelial cells) and/or other active components. The term “therapeutically effective amount” refers to an amount which can elicit a biological or medicinal response in a tissue, system, animal or human that is being sought by a researcher, veterinarian, medical doctor or other clinician, and in particular can prevent or alleviate one or more of the local or systemic symptoms or features of a disease or condition being treated.

A further aspect of the invention provides a population of the epithelial cells, epithelial stem cells, or epithelial immune cells as taught herein. The terms “cell population” or “population” denote a set of cells having characteristics in common. The characteristics may include in particular the one or more marker(s) or gene or gene product signature(s) as taught herein. The epithelial cells, epithelial stem cells, or epithelial immune cells (preferably mucosal immune cells) cells as taught herein may be comprised in a cell population. By means of example, the specified cells may constitute at least 40% (by number) of all cells of the cell population, for example, at least 45%, preferably at least 50%, at least 55%, more preferably at least 60%, at least 65%, still more preferably at least 70%, at least 75%, even more preferably at least 80%, at least 85%, and yet more preferably at least 90%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or even 100% of all cells of the cell population.

The isolated intestinal epithelial cells, intestinal epithelial stem cells, or intestinal immune cells (preferably intestinal epithelial cells) of populations thereof as disclosed throughout this specification may be suitably cultured or cultivated in vitro. The term “in vitro” generally denotes outside, or external to, a body, e.g., an animal or human body. The term encompasses “ex vivo”.

The terms “culturing” or “cell culture” are common in the art and broadly refer to maintenance of cells and potentially expansion (proliferation, propagation) of cells in vitro. Typically, animal cells, such as mammalian cells, such as human cells, are cultured by exposing them to (i.e., contacting them with) a suitable cell culture medium in a vessel or container adequate for the purpose (e.g., a 96-, 24-, or 6-well plate, a T-25, T-75, T-150 or T-225 flask, or a cell factory), at art-known conditions conducive to in vitro cell culture, such as temperature of 37° C., 5% v/v CO2 and >95% humidity.

The term “medium” as used herein broadly encompasses any cell culture medium conducive to maintenance of cells, preferably conducive to proliferation of cells. Typically, the medium will be a liquid culture medium, which facilitates easy manipulation (e.g., decantation, pipetting, centrifugation, filtration, and such) thereof.

In certain example embodiments, the agent modulates HIV-infected cells by modulating one or more of the genes listed in Table 1. The genes identified in Table 1 and subsequent tables were determined using scRNA-seq analysis of a combination of healthy control, infected with HIV.

In certain example embodiments, the agent modulates HIV-infected cells by modulating one or more of the genes listed in Table 2. In another example embodiment, the agent modulates HIV-infected cells by modulating one or more of the genes listed in Table 2 (expression induced/increased in HIV+ cells) and/or Table 3 (expression suppressed/decreased in HIV+ cells). The cluster numbers in Table 2 and Table 3 refer to the clusters and cell types as labeled.

The invention having now been described by way of written description, those of skill in the art will recognize that the invention can be practiced in a variety of embodiments and that the foregoing description and examples below are for purposes of illustration and not limitation of the claims that follow.

Although the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined in the appended claims.

EXAMPLES
Example 1

HIV preferentially infects CD4+ T cells, reverse transcribes its DNA, and integrates into the host genome. Infection progresses through a spike in viral load, followed by a progressive decrease in CD4+ T cell count. Because of the high plasma viral load, and because T cells migrate throughout different locations, virtually all tissues can be exposed to the virus, causing profound, and often irreversible changes to the adaptive and innate immune systems, and establishing a permanent pool of integrated HIV termed the “reservoir.”

Patients treated with anti-retrovirals may have undetectable virus in peripheral blood, but demonstrate HIV viral production and replication in about 1% of cells in harvested lymph nodes. Lymph nodes from suppressed donors were thawed, “reactivated/reanimated” for 18 hours with PHA/IL2 and sorted into Seq-Well arrays and evaluated for gene expression.

FIG. 4 provides an expression profile from lymph node from an HIV-infected, antiretroviral-treated patient. FIG. 5 shows HIV infection of subsets of T Cells and APCs. FIG. 6 shows infection status of single cells and HIV infection of subsets of T Cells and APCs.

FIG. 7 demonstrates host cell gene expression in HIV infected cells of genes involved in anti-retroviral metabolism, HIV pathogenesis, as well as genes of unexplored function.

The following tables provide genes differentially expressed in HIV infected cell. Approximately 16,000 genes were evaluated for differential expression between HIV+ and HIV-cells. Table 1 identifies genes whose expression most positively correlated with HIV infection. Table 2 provides a larger list of genes positively correlated with HIV infection, though to a lesser extent (lower cutoff). Table 3 provides host genes most positively correlated with cells free of HIV.

TABLE 1

HIV+ high cutoff

Category
Count
Genes

Proteomics
57
TGOLN2, UTP18, CAPZA2, STOML2, TCEAL8, CNOT7, SKAP1, THADA,

identification

KLHL7, NDUFS6, GTF2E2, WDR73, NUDCD1, RAE1, MAPKAP1, EIF1AY,

PTBP3, BCL10, NCOA7, TOPBP1, MESDC2, CCDC137, ARL16, CCNC,

RBBP7, MFN2, PYCR1, DOK2, DCUNID1, NCOA4, ADSL, LRCH3, SNRPG,

SNX9, MEAF6, CRLF3, NOB1, PXK, ARF5, VARS, SRRT, CCDC124,

NFAT5, STK38L, USP33, TFDP1, PRPF40A, GPS1, GCDH, TMEM120B,

RBMX, PTPN11, PWP1, PSMG4, MRPL28, CUL4A, SNRNP25

Acetylation
28
MEAF6, SNX9, CRLF3, CAPZA2, STOML2, VARS, SRRT, NDUFS6,

GTF2E2, ATAD3B, MAPKAP1, NFAT5, PTBP3, DDA1, STK38L, PRPF40A,

TFDP1, STX6, GCDH, BCL10, NCOA7, RBBP7, RBMX, PTPN11, PYCR1,

DCUNID1, ADSL, HIGD2A

Phosphoprotein
43
TGOLN2, SNX9, MEAF6, UTP18, CAPZA2, NOC3L, NOB1, STOML2,

VARS, SKAP1, THADA, SRRT, GTF2E2, NUDCD1, RAE1, CCDC124,

MAPKAP1, NFAT5, PTBP3, DDA1, STK38L, USP33, TFDP1, PRPF40A,

STX6, GPS1, BCL10, EFCAB14, NCOA7, CCNC, CCDC137, TOPBP1,

RBBP7, RBMX, PWP1, NOC2L, PTPN11, MFN2, PYCR1, DOK2, CUL4A,

ADSL, LRCH3

nucleoplasm
22
TGOLN2, GPS1, MEAF6, UTP18, NOB1, TOPBP1, CCNC, CNOT7, RBBP7,

RBMX, NOC2L, KLHL7, SRRT, GTF2E2, CUL4A, MAPKAP1, NFAT5,

USP33, SNRNP25, TFDP1, SNRPG, PRPF40A

Nucleus
30
MEAF6, UTP18, NOC3L, NOB1, TCEAL8, CNOT7, SKAP1, KLHL7, SRRT,

GTF2E2, NUDCD1, RAE1, MAPKAP1, NFAT5, TFDP1, PRPF40A, GPS1,

TMEM120B, NCOA7, CCNC, TOPBP1, RBBP7, RBMX, PTPN11, NOC2L,

PWP1, DCUNID1, EIF5AL1, SNRNP25, SNRPG

GO: 0044822~poly
12
SRRT, GTF2E2, MRPL28, CCDC124, UTP18, NOC3L, PTBP3, CCDC137,

(A) RNA binding

RBMX, PRPF40A, NOC2L, SNRPG

GO: 0042101~T cell
3
BCL10, STOML2, SKAP1

receptor complex

Activator
8
SRRT, MEAF6, NCOA4, NFAT5, NCOA7, CCNC, RBMX, TFDP1

GO: 0000398~mRNA
5
SRRT, RBMX, SNRNP25, PRPF40A, SNRPG

splicing, via

spliceosome

SM00320: WD40
5
WDR73, UTP18, RAE1, RBBP7, PWP1

GO: 1901796~regulation
4
MEAF6, TOPBP1, RBBP7, NOC2L

of signal

transduction by p53

class mediator

mRNA splicing
5
PTBP3, RBMX, SNRNP25, PRPF40A, SNRPG

GO: 0005515~protein
31
SNX9, MEAF6, CRLF3, STOML2, ARF5, VARS, CNOT7, SKAP1, SRRT,

binding

GTF2E2, STK38L, USP33, TFDP1, PRPF40A, STX6, BCL10, ARL16, CCNC,

TOPBP1, RBBP7, RBMX, NOC2L, PTPN11, MFN2, PYCRI, DCUN1D1,

MRPL28, CUL4A, HSPA13, SNRNP25, SNRPG

repeat: WD 3
5
WDR73, UTP18, RAE1, RBBP7, PWP1

GO: 0003723~RNA
7
RAE1, PTBP3, CNOT7, RBBP7, RBMX, PRPF40A, SNRPG

binding

WD repeat
5
WDR73, UTP18, RAE1, RBBP7, PWP1

repeat: WD 2
5
WDR73, UTP18, RAE1, RBBP7, PWP1

repeat: WD 1
5
WDR73, UTP18, RAE1, RBBP7, PWP1

IPR001680: WD40
5
WDR73, UTP18, RAE1, RBBP7, PWP1

repeat

IPR019775: WD40
4
UTP18, RAE1, RBBP7, PWP1

repeat, conserved site

mRNA processing
5
PTBP3, RBMX, SNRNP25, PRPF40A, SNRPG

IPR017986: WD40-
5
WDR73, UTP18, RAE1, RBBP7, PWP1

repeat-containing

domain

Ubl conjugation
12
MFN2, SNX9, MEAF6, CUL4A, EIF1AY, NFAT5, ADSL, TOPBP1, RBBP7,

RBMX, USP33, PRPF40A

GO: 0005730~nucleolus
8
KLHL7, MEAF6, UTP18, RAE1, NOC3L, CCDC137, PWP1, NOC2L

GO: 0043130~ubiquit
3
BCL10, RAE1, USP33

in binding

IPR015943: WD40/Y
5
WDR73, UTP18, RAE1, RBBP7, PWP1

VTN repeat-like-

containing domain

GO: 0015629~actin
4
CAPZA2, STOML2, TOPBP1, STK38L

cytoskeleton

Repressor
6
CCNC, PTBP3, CNOT7, RBBP7, RBMX, NOC2L

IPR020472: G-protein
3
RAE1, RBBP7, PWP1

beta WD-40 repeat

IPR011991: Winged
4
GPS1, GTF2E2, CUL4A, TFDP1

helix-turn-helix

DNA-binding

domain

GO: 0005634~nucleus
26
UTP18, NOC3L, TCEAL8, PXK, CNOT7, SKAP1, KLHL7, GTF2E2,

NUDCD1, RAE1, MAPKAP1, NFAT5, PTBP3, TFDP1, BCL10, NCOA7,

TOPBP1, CCNC, RBBP7, RBMX, PWP1, NOC2L, PTPN11, DCUNID1,

NCOA4, SNRNP25

repeat: WD 4
4
UTP18, RAE1, RBBP7, PWP1

mutagenesis site
13
TGOLN2, GCDH, BCL10, NCOA7, PXK, SKAP1, PTPN11, MFN2, CUL4A,

NCOA4, EIF5AL1, USP33, STK38L

Mitochondrion inner
4
NDUFS6, ATAD3B, STOML2, HIGD2A

membrane

Coiled coil
16
STX6, MEAF6, CRLF3, TMEM120B, NOC3L, STOML2, NCOA7, CCDC137,

TCEAL8, ARF5, VARS, THADA, MFN2, SRRT, ATAD3B, CCDC124

GO: 0071004~U2-
2
PRPF40A, SNRPG

type prespliceosome

GO: 0045944~positive
8
CRLF3, NFAT5, NCOA7, CCNC, CNOT7, SKAP1, RBMX, TFDP1

regulation of

transcription from

RNA polymerase II

promoter

GO: 0005737~cytoplasm
25
GPS1, BCL10, SNX9, MEAF6, CRLF3, TOPBP1, PXK, ARF5, SKAP1,

PTPN11, NOC2L, KLHL7, SRRT, GTF2E2, NUDCD1, MRPL28, CCDC124,

RAE1, MAPKAP1, NFAT5, LRCH3, USP33, STK38L, SNRNP25, PRPF40A

GO: 0005685~U1
2
PRPF40A, SNRPG

snRNP

GO: 0070469~respiratory
2
NDUFS6, HIGD2A

chain

Spliceosome
3
RBMX, SNRNP25, SNRPG

GO: 0005743~
5
NDUFS6, ATAD3B, MRPL28, STOML2, HIGD2A

mitochondrial inner

membrane

Mitochondrion
8
MFN2, GCDH, PYCR1, NDUFS6, ATAD3B, MRPL28, STOML2, HIGD2A

Isopeptide bond
8
MEAF6, CUL4A, EIF1AY, NFAT5, ADSL, RBBP7, RBMX, PRPF40A

hsa03040: Spliceosome
3
RBMX, PRPF40A, SNRPG

GO: 0031625~ubiquitin
4
MFN2, BCL10, SNX9, CUL4A

protein ligase

binding

GO: 0005794~Golgi
7
TGOLN2, STX6, MAPKAP1, TOPBP1, ARF5, USP33, PWP1

apparatus

GO: 0005802~trans-
3
TGOLN2, STX6, SNX9

Golgi network

Transcription
13
SRRT, MEAF6, GTF2E2, NCOA4, NFAT5, NCOA7, CCNC, TCEAL8,

CNOT7, RBBP7, RBMX, NOC2L, TFDP1

GO: 0000715~nucleotide-
2
GPS1, CUL4A

excision repair,

DNA damage

recognition

GO: 0046580~negative
2
MFN2, MAPKAP1

regulation of Ras

protein signal

transduction

GO: 0005689~U12-
2
SNRNP25, SNRPG

type spliceosomal

complex

Protein biosynthesis
3
EIF5AL1, EIF1AY, VARS

Chromosomal
4
BCL10, MEAF6, NCOA4, THADA

rearrangement

GO: 0050852~T cell
3
BCL10, STOML2, SKAP1

receptor signaling

pathway

TABLE 2

HIV+ low cutoff

Category
Count
Genes

Enrichment Score: 5.645742662204743

Mitochondrion
43
HSD17B10, MRPS35, OXA1L, NDUFB6, MRPS33, COA3, FKBP4, TIMM10,

STOML2, PTRH2, MTIF3, HADHA, NDUFS6, MRPL13, ATAD3B, DDX3X,

TIMM9, REXO2, MRPL54, ABHD10, YRDC, APEX1, GCDH, MRPS26,

MRPL4, NDUFA2, MMADHC, HCLS1, AK2, TOMM40, TMEM126B, SOD2,

MFN2, PYCR1, MRPL22, MRPL28, PPM1K, CLPP, ATP5C1, MRPL48,

SLC25A39, BCO2, HIGD2A

GO: 0005743~mitochondrial
24
MRPS35, MRPS26, MRPL4, NDUFA2, OXAIL, MRPS33, NDUFB6, TIMM10,

inner membrane

STOML2, AK2, TMEM126B, HADHA, SOD2, NDUFS6, MRPL22, MRPL13,

ATAD3B, MRPL28, TIMM9, MRPL54, ATP5C1, MRPL48, SLC25A39,

HIGD2A

transit
20
GCDH, MRPS35, MRPS26, OXA1L, MMADHC, PTRH2, MTIF3, HADHA,

peptide:Mitochondrion

SOD2, NDUFS6, MRPL22, MRPL28, PPM1K, CLPP, REXO2, MRPL54,

ATP5C1, ABHD10, YRDC, MRPL48

Transit peptide
21
GCDH, MRPS35, MRPS26, OXA1L, MMADHC, STOML2, PTRH2, MTIF3,

HADHA, SOD2, NDUFS6, MRPL22, MRPL28, PPMIK, REXO2, CLPP,

MRPL54, ATP5C1, ABHD10, YRDC, MRPL48

Enrichment Score: 4.175905846577495

mRNA splicing
20
HNRNPA1L2, SRSF1, DDX39A, PRPF4B, YTHDC1, PRPF39, RBMX, GCFC2,

PRPF6, CIR1, CD2BP2, CDC40, DHX15, RBMXL1, PTBP3, SREKIIP1,

SNRNP25, THOC1, SNRPG, PRPF40A

mRNA processing
21
HNRNPA1L2, SRSF1, DDX39A, PRPF4B, YTHDC1, PRPF39, RBMX, GCFC2,

SLBP, PRPF6, CIR1, CD2BP2, CDC40, DHX15, RBMXL1, PTBP3, SREK1IP1,

SNRNP25, THOC1, SNRPG, PRPF40A

GO: 0000398~mRN
15
SRSF1, DDX39A, PRPF4B, POLR2K, CWC27, RBMX, PRPF6, SRRT,

A splicing, via

CD2BP2, HTATSF1, CDC40, DHX15, SNRNP25, SNRPG, PRPF40A

spliceosome

GO: 0008380~RNA
12
HNRNPA1L2, CIR1, PRPF4B, CDC40, DHX15, RBMXL1, PTBP3, SREK1IP1,

splicing

SNRNP25, THOC1, PRPF6, SNRPG

hsa03040: Spliceosome
10
HNRNPAIL2, SRSF1, CDC40, DHX15, RBMXL1, RBMX, THOC1, PRPF6,

PRPF40A, SNRPG

Spliceosome
8
HNRNPA1L2, SRSF1, PRPF4B, CDC40, RBMX, SNRNP25, PRPF6, SNRPG

GO: 0071013~catalytic
7
SRSF1, PRPF4B, CWC27, CDC40, RBMX, PRPF6, SNRPG

step 2

spliceosome

GO: 0005681~splice
5
HNRNPA1L2, DDX39A, CDC40, PRPF6, SNRPG

osomal complex

Enrichment Score: 3.1886930162792817

Protein biosynthesis
16
AARS, DENR, VARS, ETF1, MTIF3, EIF2S1, EIF5AL1, EIF3F, EIF1AY,

HARS, TCEB3, TCEA1, EIF1, SUPT5H, MCTS1, EIF4E2

Initiation factor
8
EIF2S1, EIF1AY, EIF3F, EIF1, DENR, MCTS1, MTIF3, EIF4E2

GO: 0003743~translation
8
EIF2S1, EIF1AY, EIF3F, EIF1, DENR, MCTS1, MTIF3, EIF4E2

initiation factor

activity

GO: 0032790~ribosome
3
DENR, MCTS1, MTIF3

disassembly

hsa03013: RNA
10
NXT1, NUP62, RAE1, EIF2S1, EIF1AY, PABPC4, EIF3F, EIF1, EIF4E2,

transport

THOC1

GO: 0006413~translational
7
EIF2S1, EIF1AY, EIF3F, RPL35, EIF1, RPL39, EIF4E2

initiation

GO: 0001731~formation
3
EIF3F, DENR, MCTS1

of translation

preinitiation

complex

GO: 0008135~translation
3
EIF1, MTIF3, EIF4E2

factor activity,

RNA binding

Enrichment Score: 3.1727290299421798

Ribonucleoprotein
18
HNRNPA1L2, MRPS35, MRPS26, MRPL4, MRPS33, RPL35, RPL39, SRP19,

RBMX, RPS19BP1, SLBP, MRPL22, MRPL13, MRPL28, MRPL54, RBMXL1,

MRPL48, SNRPG

GO: 0070125~
9
MRPS35, MRPS26, MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, MRPL54,

mitochondrial

MRPL48

translational

elongation

GO: 0070126~
9
MRPS35, MRPS26, MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, MRPL54,

mitochondrial

MRPL48

translational

termination

Ribosomal protein
12
MRPS35, MRPS26, MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, MRPL54,

RPL35, MRPL48, RPL39, RPS19BP1

GO: 0006412~translation
10
MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, PABPC4, HARS, RPL35,

SLC25A39, RPL39

GO: 0003735~structural
9
MRPS35, MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, RPL35, SLC25A39,

constituent of

RPL39

ribosome

hsa03010: Ribosome
6
MRPL22, MRPL4, MRPL13, MRPL28, RPL35, RPL39

Enrichment Score: 2.5160173816834086

GO: 0006406~mRNA
9
NXT1, SRSF1, DDX39A, NUP62, RAE1, CDC40, SMG1, SLBP, THOC1

export from

nucleus

GO: 0006405~RNA
6
NXT1, SRSF1, DDX39A, NUP62, CDC40, THOC1

export from nucleus

GO: 0006369~termination
6
SRSF1, DDX39A, CDC40, SLBP, THOC1, SNRPG

of RNA

polymerase II

transcription

GO: 0031124~mRNA
4
SRSF1, DDX39A, CDC40, THOC1

3′-end processing

Enrichment Score: 2.126966020626473

GO: 0006368~transcription
7
TAF11, ADRM1, GTF2E2, POLR2K, TCEB3, TCEA1, SUPT5H

elongation

from RNA

polymerase II

promoter

Elongation factor
4
EIF5AL1, TCEB3, TCEA1, SUPT5H

GO: 0003746~translation
4
EIF5AL1, TCEB3, TCEA1, SUPT5H

elongation

factor activity

Enrichment Score: 1.874526987901123

DNA repair
12
UBE2N, PSMD14, CUL4A, BABAM1, SMG1, PRKDC, TOPBP1, USP10,

APEX1, SMC3, TRIP12, BODIL1

DNA damage
13
PRKDC, SMG1, TOPBP1, SMC3, BODIL1, UBE2N, PSMD14, CUL4A,

BABAM1, USP10, APEX1, MCTS1, TRIP12

GO: 0006281~DNA
7
SMG1, TOPBP1, APEX1, ASFIA, SMC3, TRIP12, BODIL1

repair

Enrichment Score: 1.8713442584451319

Neuropathy
7
MFN2, AARS, LMNA, HARS, WNK1, DNMT1, DNM2

Charcot-Marie-
5
MFN2, AARS, LMNA, HARS, DNM2

Tooth disease

Neurodegeneration
7
MFN2, ELOVL5, AARS, LMNA, HARS, WNK1, DNM2

Enrichment Score: 1.8468573086564095

Cell division
13
SNX9, ATAD3B, GNAI2, CCDC124, IST1, CDC40, CKS2, CENPV, BABAM1,

SMC2, SMC3, MCM5, PRPF40A

Cell cycle
18
SNX9, USP8, GNAI2, SMC2, MCM4, SMC3, MCM5, ATAD3B, CSNK2A1,

CCDC124, IST1, CDC40, BABAM1, CENPV, CKS2, MCTS1, TFDP1,

PRPF40A

GO: 0051301~cell
12
ATAD3B, GNAI2, CCDC124, IST1, CDC40, CKS2, CENPV, BABAM1, SMC2,

division

MCM5, SMC3, PRPF40A

Enrichment Score: 1.679241294734509

Isomerase
7
TOP1, FKBP4, CWC27, PPID, FKBP3, TOPBP1, TSTA3

Rotamase
4
FKBP4, CWC27, PPID, FKBP3

GO: 0061077~chaper
4
CSNK2A1, FKBP4, PPID, FKBP3

one-mediated

protein folding

GO: 0000413~protein
4
FKBP4, CWC27, PPID, FKBP3

peptidyl-prolyl

isomerization

GO: 0003755~peptidyl-
4
FKBP4, CWC27, PPID, FKBP3

prolyl cis-trans

isomerase activity

Enrichment Score: 1.6747845841936386

Repressor
20
RCOR1, CCNC, NFKB2, MAF1, CNOT7, RBBP7, RBMX, GCFC2, NOC2L,

SUZ12, KDMIA, CIR1, SP3, MLX, DNMT1, PTBP3, SUPT5H, APEX1, C1D,

KAT6A

Activator
19
MEAF6, FOX01, NCOA7, PHF11, CCNC, NFKB2, RBMX, PURA, SRRT,

NCOA4, SP3, HTATSF1, MLX, NFAT5, DNMT1, SUPT5H, APEX1, KAT6A,

TFDP1

Transcription
46
MEAF6, POLR2K, FOXO1, TCEAL8, NFKB2, MAF1, CNOT7, VPS72, PRIM1,

regulation

SRRT, KDMIA, GTF2E2, CSNK2A1, CIR1, DDX3X, HTATSF1, GTF3C6,

NFAT5, TCEA1, SUPT5H, ASFIA, APEX1, TFDP1, CHD3, RCOR1, NCOA7,

POLR1C, CCNC, PHF11, RBBP7, UBE2L3, RBMX, GCFC2, PURA, NOC2L,

TAF11, SUZ12, NCOA4, MLX, SP3, TCEB3, DNMT1, MCTS1, THOC1,

KAT6A, C1D

Transcription
41
MEAF6, FOXO1, TCEAL8, NFKB2, CNOT7, MAF1, VPS72, SRRT, KDM1A,

regulation

GTF2E2, CSNK2A1, CIR1, DDX3X, HTATSF1, NFAT5, TCEA1, SUPT5H,

ASF1A, APEX1, TFDP1, CHD3, RCOR1, NCOA7, CCNC, PHF11, RBBP7,

UBE2L3, GCFC2, PURA, NOC2L, TAF11, SUZ12, NCOA4, MLX, SP3,

TCEB3, DNMT1, MCTS1, THOC1, KAT6A, C1D

GO:0006351~transcription,
38
MEAF6, POLR2K, FOXO1, TCEAL8, CNOT7, MAF1, VPS72, KDMIA, CIR1,

DNA-

CSNK2A1, DDX3X, HTATSF1, GTF3C6, TCEA1, ASFIA, APEX1, TFDP1,

templated

CHD3, RCOR1, NCOA7, POLR1C, PHF11, RBBP7, UBE2L3, GCFC2, PURA,

PWP1, NOC2L, SUZ12, NUP62, NCOA4, MLX, SP3, DNMT1, TCEB3,

MCTS1, KAT6A, C1D

Enrichment Score: 1.6402823990813864

Nucleotide-binding
40
PRPF4B, GNAI2, DTYMK, CTPS1, RAB1B, UBA6, PRKDC, ASNS, ARF5,

VARS, HPRT1, ATAD3B, CSNK2A1, DDX3X, DHX15, STK38L, CHD3,

DDX39A, ITK, AARS, ATP11B, WNK1, AK2, SMG1, ACLY, ARL16,

UBE2L3, MCM4, SMC2, MCM5, SMC3, MFN2, UBE2N, HYOU1, PSMC4,

RFK, ARF3, HARS, HSPA13, DNM2

ATP-binding
32
PRPF4B, DTYMK, CTPS1, UBA6, PRKDC, ASNS, VARS, ATAD3B,

CSNK2A1, DDX3X, DHX15, STK38L, CHD3, DDX39A, ITK, AARS, ATP11B,

WNK1, SMG1, AK2, ACLY, UBE2L3, SMC2, MCM4, MCM5, SMC3, UBE2N,

HYOU1, PSMC4, RFK, HARS, HSPA13

GO: 0005524~ATP
35
PRPF4B, FKBP4, DTYMK, CTPS1, UBA6, PRKDC, ASNS, PXK, VARS,

binding

ATAD3B, CSNK2A1, DDX3X, DHX15, STK38L, CHD3, DDX39A, ITK,

SMCHD1, AARS, ATP11B, WNK1, SMG1, AK2, ACLY, UBE2L3, SMC2,

MCM4, MCM5, SMC3, UBE2N, HYOU1, PSMC4, RFK, HARS, HSPA13

nucleotide
19
DDX39A, ITK, PRPF4B, DTYMK, WNK1, UBA6, AK2, ACLY, SMC2, MCM4,

phosphate-binding

SMC3, MCM5, ATAD3B, CSNK2A1, DDX3X, PSMC4, DHX15, STK38L,

region: ATP

CHD3

Enrichment Score: 1.5505018585302555

GO: 0006890~retrograde
7
COPB2, KDELR2, ARF3, TMED10, RAB1B, LMAN2, ARF5

vesicle-

mediated transport,

Golgi to ER

GO:0030133~transp
6
TGOLN2, COPB2, KDELR2, ERP29, TMED10, RAB1B

ort vesicle

GO: 0033116~endoplasmic
4
TMED10, RAB1B, LMAN2, ERGIC3

reticulum-

Golgi intermediate

compartment

membrane

GO: 0006888~ER to
5
HYOUI, COPB2, TMED10, RABIB, LMAN2

Golgi vesicle-

mediated transport

Enrichment Score: 1.3417297598441402

GO: 0006270~DNA
5
PRIM1, TOPBP1, MCM4, MCM5, PURA

replication initiation

hsa03030: DNA
4
PRIM1, POLE4, MCM4, MCM5

replication

GO: 0000082~G1/S
5
PRIM1, CUL4A, CRLF3, MCM4, MCM5

transition of mitotic

cell cycle

DNA replication
4
PRIM1, RBBP7, MCM4, MCM5

GO: 0006260~DNA replication
5
TOP1, TOPBP1, RBBP7, MCM4, MCM5

Enrichment Score: 1.312801362788877

hsa00240: Pyrimidine
7
PRIM1, POLE4, POLR2K, DTYMK, CTPS1, POLR1C, ENTPD4

metabolism

hsa00230: Purine
8
PRIM1, POLE4, POLR2K, ADSL, AK2, POLRIC, ENTPD4, HPRT1

metabolism

DNA-directed RNA
3
PRIM1, POLR2K, POLR1C

polymerase

Enrichment Score: 1.3089793413612678

SM00320: WD40
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

PWP1

repeat: WD 3
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

PWP1

WD repeat
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

PWP1

repeat: WD 1
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

PWP1

repeat: WD 2
10
COPB2, WDR36, WDR73, UTP18, RAEI, CDC40, AAMP, WDR4, RBBP7,

PWP1

IPR001680: WD40
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

repeat

PWP1

repeat: WD 4
9
COPB2, WDR36, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7, PWP1

IPR019775: WD40
7
WDR36, UTP18, RAE1, CDC40, AAMP, RBBP7, PWP1

repeat, conserved

site

IPR017986: WD40-
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

repeat-containing

PWP1

domain

IPR015943: WD40/
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

YVTN repeat-like-

PWP1

containing domain

repeat: WD 5
7
COPB2, WDR36, UTP18, CDC40, AAMP, RBBP7, PWP1

repeat: WD 6
6
COPB2, WDR36, UTP18, CDC40, AAMP, RBBP7

IPR020472: G-
4
COPB2, RAE1, RBBP7, PWP1

protein beta WD-40

repeat

repeat: WD 7
5
COPB2, WDR36, CDC40, AAMP, RBBP7

repeat: WD 8
3
COPB2, WDR36, AAMP

Enrichment Score: 1.2247677909485253

SM00360: RRM
8
HNRNPA1L2, SRSF1, HTATSF1, PABPC4, RBMXL1, RBM6, PTBP3, RBMX

SM00361: RRM_1
3
PABPC4, RBMXL1, RBMX

IPR012677: Nucleotide-
9
HNRNPA1L2, SRSF1, SRRT, HTATSF1, PABPC4, RBMXL1, RBM6, PTBP3,

binding, alpha-

RBMX

beta plait

GO: 0000166~nucleotide
11
HNRNPA1L2, SRSF1, SRRT, HTATSF1, PABPC4, RBMXL1, RBM6, PTBP3,

binding

PXK, HPRT1, RBMX

IPR003954: RNA
3
PABPC4, RBMXL1, RBMX

recognition motif

domain, eukaryote

recognition motif

IPR000504: RNA
8
HNRNPA1L2, SRSF1, HTATSF1, PABPC4, RBMXL1, RBM6, PTBP3, RBMX

domain

GO: 0030529~
6
HNRNPA1L2, NUP62, PABPC4, RBMXL1, RBMX, SLBP

intracellular

ribonucleoprotein

complex

domain: RRM 1
5
HNRNPA1L2, SRSF1, HTATSF1, PABPC4, PTBP3

domain: RRM 2
5
HNRNPA1L2, SRSF1, HTATSF1, PABPC4, PTBP3

Enrichment Score: 1.1799339425906339

GO: 0050852~T cell
9
UBE2N, ITK, BCL10, PSMB4, PSMD14, PSMB7, PSMC4, STOML2, SKAP1

receptor signaling

pathway

GO: 0038061~NIK/
6
PSMB4, PSMD14, PSMB7, PSMC4, NFKB2, PPP4C

NF-kappaB

signaling

Proteasome
5
PSMB4, ADRM1, PSMD14, PSMB7, PSMC4

GO: 0000502~proteasome
5
PSMB4, ADRM1, PSMD14, PSMB7, PSMC4

complex

GO: 0038095~Fc-
8
UBE2N, ITK, BCL10, PSMB4, PSMD14, PSMB7, PSMC4, PPP3R1

epsilon receptor

signaling pathway

GO: 0002223~stimulatory
6
UBE2N, BCL10, PSMB4, PSMD14, PSMB7, PSMC4

C-type lectin

receptor signaling

pathway

GO:0006521~regulation
4
PSMB4, PSMD14, PSMB7, PSMC4

of cellular

amino acid

metabolic process

hsa03050: Proteasome
4
PSMB4, PSMD14, PSMB7, PSMC4

GO: 0000209~protein
7
PSMB4, PSMD14, PSMB7, PSMC4, UBE2V2, UBE2L3, TRIP12

polyubiquitination

GO: 0002479~antigen
4
PSMB4, PSMD14, PSMB7, PSMC4

processing and

presentation of

exogenous peptide

antigen via MHC

class I, TAP-

dependent

GO: 0043488~regulation
5
PSMB4, PSMD14, PSMB7, PSMC4, APEX1

of mRNA

stability

GO: 0051436~negative
4
PSMB4, PSMD14, PSMB7, PSMC4

regulation of

ubiquitin-protein

ligase activity

involved in mitotic

cell cycle

GO: 0051437~positive
4
PSMB4, PSMD14, PSMB7, PSMC4

regulation of

ubiquitin-protein

ligase activity

involved in

regulation of mitotic

cell cycle transition

GO: 0031145~anaphase-
4
PSMB4, PSMD14, PSMB7, PSMC4

promoting

complex-dependent

catabolic process

GO: 0060071~Wnt
4
PSMB4, PSMD14, PSMB7, PSMC4

signaling pathway,

planar cell polarity

pathway

GO: 0090090~negative
5
PSMB4, PSMD14, PSMB7, PSMC4, FOXO1

regulation of

canonical Wnt

signaling pathway

GO:0033209~tumor
4
PSMB4, PSMD14, PSMB7, PSMC4

necrosis factor-

mediated signaling

pathway

GO:0090263~positive
4
PSMB4, PSMD14, PSMB7, PSMC4

regulation of

canonical Wnt

signaling pathway

GO:0043161~proteasome-
5
PSMB4, PSMD14, PSMB7, CUL4A, PSMC4

mediated

ubiquitin-dependent

protein catabolic

process

GO: 0000165~MAP
5
PSMB4, PSMD14, PSMB7, PSMC4, CCL5

K cascade

Enrichment Score: 0.9835956335357907

GO: 0005643~nuclear
5
NXT1, NUP62, RAE1, EIF5AL1, KPNA3

pore

GO: 0075733~
3
NUP62, RAE1, KPNA3

intracellular transport of

virus

GO: 0006606~protein
3
NUP62, RAE1, KPNA3

import into

nucleus

Enrichment Score: 0.9465955034396142

GO: 0032981~
5
NDUFS6, NDUFA2, OXAIL, NDUFB6, TMEM126B

mitochondrial respiratory

chain complex I

assembly

hsa05010: Alzheimer's
8
HSD17B10, NDUFS6, NDUFA2, CASP3, NDUFB6, PPP3R1, ATP5C1, ITPR3

disease

Respiratory chain
4
NDUFS6, NDUFA2, NDUFB6, HIGD2A

hsa05012: Parkinson's
7
NDUFS6, NDUFA2, CASP3, NDUFB6, GNAI2, ATP5C1, UBE2L3

disease

hsa05016: Huntington's
8
NDUFS6, NDUFA2, CASP3, NDUFB6, POLR2K, RCOR1, ATP5C1, SOD2

disease

GO: 0005747~mitoc
3
NDUFS6, NDUFA2, NDUFB6

hondrial respiratory

chain complex I

hsa04932: Non-
6
NDUFS6, NDUFA2, CASP3, NDUFB6, EIF2S1, MLX

alcoholic fatty liver

disease (NAFLD)

GO: 0008137~NADH
3
NDUFS6, NDUFA2, NDUFB6

dehydrogenase

(ubiquinone) activity

GO:0006120~mitochondrial
3
NDUFS6, NDUFA2, NDUFB6

electron

transport, NADH to

ubiquinone

Electron transport
4
NDUFS6, NDUFA2, NDUFB6, HIGD2A

hsa00190: Oxidative
4
NDUFS6, NDUFA2, NDUFB6, ATP5C1

phosphorylation

Enrichment Score: 0.9077271811850836

h_tnfr1Pathway: TN
3
CASP3, LMNA, PRKDC

FR1 Signaling

Pathway

h_fasPathway: FAS
3
CASP3, LMNA, PRKDC

signaling pathway (CD95)

h_hivnefPathway:HI
3
CASP3, LMNA, PRKDC

V-I Nef: negative

effector of Fas and

TNF

Enrichment Score: 0.8974242711787185

Helicase
6
DDX39A, DDX3X, DHX15, MCM4, MCM5, CHD3

GO: 0004003~ATP-
3
DDX3X, MCM4, CHD3

dependent DNA

helicase activity

GO:0004386~helicase
3
DDX3X, MCM4, CHD3

activity

Enrichment Score: 0.8844871978021877

GO: 0005794~Golgi
23
TGOLN2, STX6, KDELR2, USP8, ATP11B, NDFIP2, RABIB, TOPBP1, ARF5,

apparatus

LMAN2, ERGIC3, PWP1, TAF11, EI24, SP3, ARF3, MAPKAP1, STX16,

TMED10, USP33, FGD3, DNM2, KAT6A

Golgi apparatus
15
TGOLN2, STX6, SNX9, ATP11B, NDFIP2, ARF5, LMAN2, UXS1, ERGIC3,

COPB2, ARF3, STX16, TMED10, ENTPD4, USP33

GO: 0000139~Golgi
10
STX6, COPB2, KDELR2, ARF3, STX16, NDFIP2, TMED10, RAB1B, LMAN2,

membrane

DNM2

Enrichment Score: 0.8697007217508498

IPR016135: Ubiquitin-
4
UBE2N, UFC1, UBE2V2, UBE2L3

conjugating

enzyme/RWD-like

GO: 0061631~ubiquitin
3
UBE2N, UBE2V2, UBE2L3

conjugating

enzyme activity

IPR000608: Ubiquitin-
3
UBE2N, UBE2V2, UBE2L3

conjugating

enzyme, E2

GO:0016567~protein
7
KLHL7, UBE2N, NUB1, UBA6, UBE2V2, UBE2L3, TRAF4

ubiquitination

Enrichment Score: 0.8007359177589985

SM00312: PX
3
SNX9, PXK, SNX10

domain: PX
3
SNX9, PXK, SNX10

GO:0035091~
4
SNX9, PXK, ITPR3, SNX10

phosphatidylinositol

binding

IPR001683: Phox
3
SNX9, PXK, SNX10

homologous domain

Enrichment Score: 0.7905595110088506

Thiol protease
6
CASP3, USP8, EIF3F, USP10, USP33, ALG13

GO: 0004197~cysteine-type
4
CASP3, USP8, USP10, USP33

endopeptidase

activity

GO: 0004843~thiol-
4
USP8, EIF3F, USP10, USP33

dependent ubiquitin-

specific protease

activity

GO: 0016579~protein
4
USP8, EIF3F, USP10, USP33

deubiquitination

IPR018200: Peptidase
3
USP8, USP10, USP33

e C19, ubiquitin

carboxyl-terminal

hydrolase 2,

conserved site

IPR001394: Peptidase
3
USP8, USP10, USP33

C19, ubiquitin

carboxyl-terminal

hydrolase 2

Enrichment Score: 0.7329253582520423

active site: Glycyl
5
UBE2N, UFC1, UBA6, UBE2L3, TRIP12

thioester

intermediate

GO: 0042787~protein
5
KLHL7, CUL4A, UBA6, UBE2L3, TRIP12

ubiquitination

involved in

ubiquitin-dependent

protein catabolic

process

GO: 0006464~cellular protein
4
UBE2N, UBA6, PRKDC, UBE2L3

modification process

hsa04120: Ubiquitin
5
UBE2N, CUL4A, UBA6, UBE2L3, TRIP 12

mediated proteolysis

GO: 0004842~ubiquitin-
6
KLHL7, UBE2N, UBE2L3, TTC3, TRIP12, TRAF4

protein

transferase activity

Enrichment Score: 0.7159098666001777

Helicase
6
DDX39A, DDX3X, DHX15, MCM4, MCM5, CHD3

SM00490: HELICc
4
DDX39A, DDX3X, DHX15, CHD3

SM00487: DEXDc
4
DDX39A, DDX3X, DHX15, CHD3

domain: Helicase C-
4
DDX39A, DDX3X, DHX15, CHD3

terminal

domain: Helicase
4
DDX39A, DDX3X, DHX15, CHD3

ATP-binding

IPR001650: Helicase,
4
DDX39A, DDX3X, DHX15, CHD3

C-terminal

IPR014001: Helicase
4
DDX39A, DDX3X, DHX15, CHD3

superfamily 1/2,

ATP-binding

domain

GO:0004004~ATP-
3
DDX39A, DDX3X, DHX15

dependent RNA

helicase activity

IPR011545: DNA/R
3
DDX39A, DDX3X, DHX15

NA helicase,

DEAD/DEAH box

type, N-terminal

Enrichment Score: 0.69498312277083

Aminoacyl-tRNA
3
AARS, HARS, VARS

synthetase

GO: 0006418~RNA
3
AARS, HARS, VARS

aminoacylation for

protein translation

Ligase
8
AARS, HARS, UBA6, CTPS1, ASNS, VARS, TTC3, TRIP12

hsa00970: Aminoacy
3
AARS, HARS, VARS

1-tRNA biosynthesis

Enrichment Score: 0.5293095748164424

lipid moiety-binding
5
HPCAL1, GNAI2, ARF3, PPP3R1, ARF5

region: N-myristoyl

glycine

Myristate
5
HPCAL1, GNAI2, ARF3, PPP3R1, ARF5

GO: 0003924~GTPase
6
MFN2, DDX3X, GNAI2, ARF3, ARF5, DNM2

activity

Lipoprotein
10
RGS10, HPCALI, S1PRI, GNAI2, ARF3, PPP3R1, LMNA, RAB1B, STOML2,

ARF5

Enrichment Score: 0.5161555683114979

IPR024156: Small
3
ARF3, ARL16, ARF5

GTPase superfamily,

ARF type

IPR006689: Small
3
ARF3, ARL16, ARF5

GTPase superfamily,

ARF/SAR type

nucleotide
7
MFN2, GNAI2, ARF3, RAB1B, ARL16, ARF5, DNM2

phosphate-binding

region:GTP

GO: 0003924~GTPase
6
MFN2, DDX3X, GNAI2, ARF3, ARF5, DNM2

activity

GTP-binding
7
MFN2, GNAI2, ARF3, RAB1B, ARL16, ARF5, DNM2

GO: 0005525~GTP
8
MFN2, GNAI2, FKBP4, ARF3, RABIB, ARL16, ARF5, DNM2

binding

IPR005225: Small
3
ARF3, RAB1B, ARF5

GTP-binding protein

domain

GO: 0007264~small
4
ARF3, RABIB, ARL16, ARF5

GTPase mediated

signal transduction

Enrichment Score: 0.49661457171690665

IPR011990: Tetratric
7
GPS1, NUB1, FKBP4, PPID, PRPF39, TTC3, PRPF6

opeptide-like helical

SM00028: TPR
4
FKBP4, PPID, TTC3, PRPF6

IPR013026: Tetratric
4
FKBP4, PPID, TTC3, PRPF6

opeptide repeat-

containing domain

IPR019734: Tetratric
4
FKBP4, PPID, TTC3, PRPF6

opeptide repeat

repeat: TPR 3
4
FKBP4, PPID, PRKDC, TTC3

TPR repeat
4
FKBP4, PPID, PRKDC, TTC3

repeat: TPR 2
4
FKBP4, PPID, PRKDC, TTC3

repeat: TPR 1
4
FKBP4, PPID, PRKDC, TTC3

Enrichment Score: 0.46491176000453827

IPR002909: Cell
3
NFAT5, NFKB2, EXOC2

surface receptor

IPT/TIG

IPR014756: Immuno
3
NFAT5, NFKB2, EXOC2

globulin E-set

IPR013783: Immuno
4
CRLF3, NFAT5, NFKB2, EXOC2

globulin-like fold

Enrichment Score: 0.4285527179810236

GO: 0016491~oxidor
6
HSD17B10, KDM1A, AKR1A1, TSTA3, KIAA1191, APEX1

eductase activity

GO: 0055114~oxidation-
12
GLRX3, HSD17B10, KDMIA, PYCR1, OXA1L, AKR1A1, TSTA3, KIAA1191,

reduction

APEX1, BCO2, HIGD2A, SOD2

process

Oxidoreductase
10
GCDH, HSD17B10, KDM1A, PYCR1, AKR1A1, TSTA3, KIAA1191, HADHA,

BCO2, SOD2

NADP
4
PYCR1, AKR1A1, TSTA3, KIAA1191

Enrichment Score: 0.36591445625467517

SM00249: PHD
3
PHF11, CHD3, KAT6A

IPR011011: Zinc
4
PHF11, FGD3, CHD3, KAT6A

finger, FYVE/PHD-

type

IPR001965: Zinc
3
PHF11, CHD3, KAT6A

finger, PHD-type

IPR013083: Zinc
7
PHF11, USP33, TTC3, TRAF4, FGD3, CHD3, KAT6A

finger,

RING/FYVE/PHD-

type

Enrichment Score: 0.25507693482602034

domain: SH3
4
ITK, SNX9, HCLS1, SKAP1

SM00326: SH3
4
ITK, SNX9, HCLS1, SKAP1

SH3 domain
4
ITK, SNX9, HCLS1, SKAP1

IPR001452: Src
4
ITK, SNX9, HCLS1, SKAP1

homology-3 domain

Enrichment Score: 0.2406171678396523

SM00233: PH
5
ITK, DOK2, SKAP1, FGD3, DNM2

domain: PH
5
ITK, ADRM1, DOK2, SKAP1, DNM2

IPR001849: Pleckstrin
5
ITK, DOK2, SKAP1, FGD3, DNM2

homology domain

IPR011993: Pleckstrin
6
ITK, DOK2, EPB41, SKAP1, FGD3, DNM2

homology-like

domain

Enrichment Score: 0.1905601056044362

hsa04924: Renin
3
GNAI2, PPP3R1, ITPR3

secretion

hsa04724: Glutamatergic
3
GNAI2, PPP3R1, ITPR3

synapse

hsa04921: Oxytocin
3
GNAI2, PPP3R1, ITPR3

signaling pathway

hsa04022: cGMP-
3
GNAI2, PPP3R1, ITPR3

PKG signaling

pathway

Enrichment Score: 0.1700736372529799

Kinase
13
ITK, PRPF4B, DTYMK, WNK1, SMG1, PRKDC, AK2, PXK, DOK2,

CSNK2A1, RFK, MAPKAP1, STK38L

GO: 0004672~protein
8
PRPF4B, CSNK2A1, WNK1, SMG1, PRKDC, PXK, CCL5, STK38L

kinase activity

GO: 0004674~protein
8
PRPF4B, CSNK2A1, WNK1, SMG1, PRKDC, CCNC, CPNE3, STK38L

serine/threonine

kinase activity

GO: 0018105~peptidyl-
3
SMG1, PRKDC, STK38L

serine

phosphorylation

Serine/threonine-
6
PRPF4B, CSNK2A1, WNK1, SMG1, PRKDC, STK38L

protein kinase

IPR011009: Protein
8
ITK, PRPF4B, CSNK2A1, WNK1, SMG1, PRKDC, PXK, STK38L

kinase-like domain

GO:0006468~protein
7
PRPF4B, CSNK2A1, WNK1, CCNC, CPNE3, PXK, STK38L

phosphorylation

active site: Proton
9
GCDH, HSD17B10, ITK, PRPF4B, CSNK2A1, WNK1, ADSL, APEX1, STK38L

acceptor

binding site: ATP
7
ITK, PRPF4B, CSNK2A1, RFK, WNK1, VARS, STK38L

domain:Protein
6
ITK, PRPF4B, CSNK2A1, WNK1, PXK, STK38L

kinase

SM00220: S_TKc
4
PRPF4B, CSNK2A1, WNK1, STK38L

IPR008271: Serine/
4
PRPF4B, CSNK2A1, WNK1, STK38L

threonine-protein

kinase, active site

IPR000719: Protein
6
ITK, PRPF4B, CSNK2A1, WNK1, PXK, STK38L

kinase, catalytic

domain

IPR017441:Protein
3
ITK, CSNK2A1, STK38L

kinase, ATP binding

site

Enrichment Score: 0.11135414381747946

topological
10
KDELR2, SEC11A, ALG5, TMED10, SPCS1, LMAN2, ENTPD4, UXS1, SSR2,

domain: Lumenal

ERGIC3

topological
21
TGOLN2, STX6, KDELR2, SEC11A, GPR171, ATP11B, ALG5, CD99,

domain: Cytoplasmic

LMAN2, ITPR3, UXS1, ERGIC3, MFN2, SIPR1, STX16, TMEM170A,

TMED10, SPCS1, ENTPD4, SSR2, HIGD2A

signal peptide
15
TGOLN2, HYOUI, CST7, ERP29, CNPY3, CCDC47, TMED10, CD99, LRCH3,

MESDC2, HSPA13, LMAN2, CCL5, SSR2, SOD2

Glycoprotein
23
TGOLN2, EPB41, CWC27, GPR171, WNK1, CNPY3, ALG5, CCDC47, CD99,

MESDC2, LMAN2, CCL5, UXS1, RBMX, ERGIC3, HYOU1, SIPRI, NUP62,

CST7, TMEM170A, TMED10, ENTPD4, SSR2

Signal
18
TGOLN2, ERP29, WNK1, CNPY3, CCDC47, CD99, MESDC2, LMAN2, CCL5,

HYOU1, RAE1, CST7, TMED10, ABHD10, LRCH3, HSPA13, BCO2, SSR2

glycosylation site:N-
17
TGOLN2, CWC27, GPR171, CNPY3, ALG5, CCDC47, MESDC2, LMAN2,

linked (GlcNAc . . . )

UXS1, ERGIC3, HYOU1, S1PR1, CST7, TMEM170A, TMED10, ENTPD4,

SSR2

Enrichment Score: 0.0903744092851981

repeat: 5
3
TGOLN2, NUP62, DNMT1

repeat: 4
3
TGOLN2, NUP62, DNMT1

repeat: 3
3
TGOLN2, NUP62, DNMT1

repeat: 1
3
TGOLN2, NUP62, DNMT1

repeat: 2
3
TGOLN2, NUP62, DNMT1

GO: 0098609~cell-
4
SNX9, USP8, DDX3X, IST1

cell adhesion

GO: 0098641~cadher
4
SNX9, USP8, DDX3X, IST1

in binding involved

in cell-cell adhesion

GO: 0005913~cell-
4
SNX9, USP8, DDX3X, IST1

cell adherens

junction

Enrichment Score: 0.05747010288539574

domain: EF-hand 2
3
HPCAL1, EFCAB14, PPP3R1

domain: EF-hand 1
3
HPCAL1, EFCAB14, PPP3R1

IPR002048: EF-hand
3
HPCAL1, EFCAB14, PPP3R1

domain

IPR011992: EF-
3
HPCAL1, EFCAB14, PPP3R1

hand-like domain

Calcium
7
HPCAL1, EFCAB14, PPP3R1, TKT, LMAN2, ENTPD4, ITPR3

GO:0005509~calcium
5
HPCAL1, EFCAB14, PPP3R1, CCDC47, ITPR3

ion binding

Enrichment Score: 0.04306870373594361

IPR013083: Zinc
7
PHF11, USP33, TTC3, TRAF4, FGD3, CHD3, KAT6A

finger,

RING/FYVE/PHD-

type

GO: 0008270~zinc
13
POLR2K, TIMM9, AARS, TIMM10, DNMT1, PHF11, TCEA1, SREK1IP1,

ion binding

USP33, TTC3, TRAF4, CHD3, KAT6A

Zinc
24
VPS29, ITK, POLR2K, AARS, TIMM10, NOB1, PHF11, TTC3, SUZ12, PRIMI,

LAP3, PSMD14, RFK, SP3, TIMM9, DNMT1, TCEA1, SREK1IP1, USP33,

FGD3, TRAF4, GPATCH8, CHD3, KAT6A

Zinc-finger
15
ITK, POLR2K, PHF11, TTC3, SUZ12, SP3, DNMT1, TCEA1, SREK1IP1,

USP33, TRAF4, GPATCH8, FGD3, CHD3, KAT6A

Enrichment Score: 9.170272943712669E-6

Membrane
78
TGOLN2, OXA1L, COA3, UTP18, CAPZA2, DNAJB14, ALG5, STOML2,

RAB1B, LINC00116, SKAP1, UXSI, THADA, NDUFS6, COPB2, ATAD3B,

S1PR1, ELOVL5, DNAJC9, MAPKAP1, TIMM9, YRDC, STX6, KDELR2,

BCL10, GPR171, CCDC47, TMEM126B, ERGIC3, MFN2, EIF5AL1,

TMEM170A, ATP5C1, AAMP, LRCH3, SLC25A39, VPS26B, SNX10,

HIGD2A, VPS29, SNX9, USP8, NDUFB6, GNAI2, CRLF3, PPP3R1, TIMM10,

UBA6, ARF5, LMAN2, PXK, PTRH2, DDX3X, STX16, NFAT5, TMED10,

ENTPD4, STK38L, TRAF4, NDUFA2, HPCALI, SMCHD1, FIBP, HCLS1,

SEC11A, TMEM120B, FDPS, ATP11B, CD99, TOMM40, NDFIP2, ITPR3,

EI24, SPCS1, CPNE3, TEX10, SSR2, DNM2

GO: 0016021~integral
46
TGOLN2, OXA1L, NDUFB6, COA3, CRLF3, UTP18, CAPZA2, DNAJB14,

component of

UBA6, ALG5, LINC00116, PTRH2, UXS1, THADA, SIPRI, ELOVL5, STX16,

membrane

NFAT5, TMED10, ENTPD4, STX6, KDELR2, SMCHD1, SEC11A, GPR171,

TMEM120B, ATP11B, FDPS, NDFIP2, CCDC47, TOMM40, CD99,

TMEM126B, ITPR3, ERGIC3, MFN2, EI24, TMEM170A, TCEB3, LRCH3,

SPCS1, SLC25A39, VPS26B, TEX10, SSR2, HIGD2A

Transmembrane
46
TGOLN2, OXAIL, NDUFB6, COA3, CRLF3, UTP18, CAPZA2, DNAJB14,

UBA6, ALG5, LINC00116, LMAN2, PTRH2, UXSI, THADA, SIPRI,

ELOVL5, STX16, NFAT5, TMED10, ENTPD4, STX6, KDELR2, SMCHD1,

SEC11A, GPR171, TMEM120B, ATP11B, FDPS, NDFIP2, CCDC47, TOMM40,

CD99, TMEM126B, ITPR3, ERGIC3, MFN2, EI24, TMEM170A, LRCH3,

SPCS1, SLC25A39, VPS26B, TEX10, SSR2, HIGD2A

Transmembrane
45
TGOLN2, OXA1L, NDUFB6, COA3, UTP18, CRLF3, CAPZA2, DNAJB14,

helix

UBA6, ALG5, LINC00116, LMAN2, PTRH2, UXS1, THADA, S1PR1,

ELOVL5, STX16, NFAT5, TMED10, ENTPD4, STX6, KDELR2, SMCHD1,

SEC11A, GPR171, TMEM120B, ATP11B, FDPS, NDFIP2, CCDC47, CD99,

TMEM126B, ITPR3, ERGIC3, MFN2, EI24, TMEM170A, LRCH3, SPCS1,

SLC25A39, VPS26B, TEX10, SSR2, HIGD2A

topological
21
TGOLN2, STX6, KDELR2, SEC11A, GPR171, ATP11B, ALG5, CD99,

domain: Cytoplasmic

LMAN2, ITPR3, UXS1, ERGIC3, MFN2, SIPRI, STX16, TMEM170A,

TMED10, SPCS1, ENTPD4, SSR2, HIGD2A

transmembrane
35
TGOLN2, OXA1L, NDUFB6, COA3, DNAJB14, ALG5, LINC00116, LMAN2,

region

UXS1, S1PR1, ELOVL5, STX16, TMED10, ENTPD4, SREK1IP1, STX6,

KDELR2, SEC11A, GPR171, TMEM120B, ATP11B, NDFIP2, CCDC47, CD99,

TMEM126B, ITPR3, ERGIC3, MFN2, EI24, TMEM170A, SPCS1, SLC25A39,

SSR2, TEX10, HIGD2A

Acetylation
143
MRPS33, PRPF4B, CAPZA2, DTYMK, RAB1B, STOML2, FOXO1, PRIM1,

TOP1, GTF2E2, SIPR1, ELOVL5, VPS13D, TIMM9, EIF1, PTBP3, PPP4C,

SUPT5H, DDX39A, BCL10, AARS, ERGIC3, ADRM1, PYCRI, DCUNID1,

EIF2S1, CLPP, ATP5C1, HARS, ADSL, HIGD2A, SNX9, MEAF6, HSD17B10,

UBA6, CTPS1, UBE2V2, BANF1, HADHA, PSMB4, POLE4, DDX3X,

HTATSF1, MTPN, EIF3F, STK38L, TFDP1, PRPF40A, GCDH, ARL14EP,

SMCHD1, FIBP, CCDC25, MMADHC, FDPS, AK2, SMG1, TKT, DENR,

TPD52L2, UBE2L3, RBMX, PTPN11, HYOU1, EI24, NUP62, PSMC4, PPID,

METTL10, WDR4, BABAM1, RBMXL1, DNMT1, EIF4E2, GPATCH8,

KAT6A, SRSF1, HNRNPAIL2, COA3, TCOF1, BOD1L1, COPB2, NDUFS6,

CASP3, ATAD3B, MAPKAP1, USP10, DDA1, STX6, NCOA7, POLR1C,

RBBP7, MCM4, MCM5, PURA, UBE2N, TAF11, LAP3, KPNA3, THOC1,

VPS29, GLRX3, NXT1, NDUFB6, CRLF3, FKBP4, FKBP3, RNH1, RPL35,

PRKDC, ASNS, VARS, HPRT1, SRRT, MRPL13, FAM107B, AKR1A1,

CD2BP2, REXO2, DHX15, NFAT5, GTF3C6, TCEA1, APEX1, EXOC2,

TRIP12, NDUFA2, CWC27, HCLS1, LMNA, ACLY, ETF1, COTL1, SMC2,

SMC3, SOD2, PPP1R2, SP3, CKS2, TCEB3, PSAT1, SSNA1, DNM2

Proteomics
235
TGOLN2, OXA1L, DNAJB14, RAB1B, STOML2, UXS1, PRIMI, C1ORF109,

identification

WDR73, VPS13D, RAE1, EIF1AY, PTBP3, SREK1IP1, SUPT5H, RCOR1,

AARS, WNK1, CCDC137, ERGIC3, EIF2S1, HARS, ADSL, LRCH3, MRPL48,

CPSF3L, HSD17B10, GNAI2, PABPC4, UBA6, PXK, ARF5, BANF1, HADHA,

HTATSF1, STX16, CDC40, TMED10, PRPF40A, GCDH, HPCAL1,

TMEM120B, ATP11B, NDFIP2, YTHDC1, TKT, TPD52L2, GCFC2, PTPN11,

HYOU1, EI24, NUP62, MLX, METTL10, UTP14A, SNRNP25, ALG13, BCO2,

KAT6A, SRSF1, UTP18, TCOF1, NFKB2, RPS19BP1, BOD1L1, COPB2,

WDR36, USP10, KDELR2, MRPL4, CNPY3, PRPF39, POLRIC, CCNC,

MESDC2, RBBP7, DOK2, THOC1, USP8, POLR2K, NOB1, RPL35, SRRT,

MRPL13, CIR1, REXO2, TCEA1, TSTA3, USP33, EXOC2, TRIP12, NUB1,

CWC27, HCLS1, LMNA, ACLY, PHF11, ETF1, SOD2, PSMD14, MRPL22,

PPP1R2, MRPL28, IST1, TCEB3, SSNA1, SSR2, TEX10, DNM2, MRPS35,

MRPS33, PRPF4B, CAPZA2, DTYMK, RBM6, TCEAL8, SRP19, CNOT7,

MAF1, KLHL7, KDMIA, GTF2E2, CSNK2A1, NUDCD1, ELOVL5, TIMM9,

EIF1, PPP4C, IFRD2, DDX39A, BCL10, ERP29, HMCES, ARL16, TOPBP1,

TMEM126B, SUZ12, ADRMI, PYCR1, DCUNID1, SMARCE1, RFK, CLPP,

SLC25A39, VPS26B, SNRPG, SNX9, MEAF6, UBE2V2, LMAN2, PTRH2,

CCL5, FAM207A, TTC3, PSMB7, DDX3X, MTPN, EIF3F, ENTPD4, STK38L,

TRAF4, TFDP1, ITK, ARL14EP, SMCHD1, FIBP, CCDC25, EPB41,

MMADHC, SEC11A, FDPS, AK2, TOMM40, SMG1, THUMPD2, DENR,

RBMX, PPID, BABAM1, DNMT1, CPNE3, SPCS1, EIF4E2, GPATCH8, COA3,

SKAP1, THADA, NDUFS6, CASP3, MAPKAP1, ABHD10, FTSJ3, METTL5,

CCDC47, NCOA7, MCM4, MCM5, LAP3, MFN2, UBE2N, NCOA4, PPMIK,

AAMP, KPNA3, KIAA1191, SNX10, C1D, VPS29, NDUFB6, CRLF3, FKBP4,

FKBP3, PPP3R1, RNH1, PRKDC, ASNS, VARS, AKRIA1, FAM107B, UFM1,

CCDC124, NFAT5, APEX1, CHD3, GPS1, CD99, COTL1, SMC2, RSBN1,

SLBP, PWP1, PSMG4, CUL4A, SP3, CENPV

Phosphoprotein
193
TGOLN2, OXA1L, STOML2, RAB1B, UXS1, S1PR1, RAE1, VPS13D, PTBP3,

SUPT5H, SREK1IP1, EFCAB14, RCOR1, AARS, WNK1, KRT10, CCDC137,

ERGIC3, EIF2S1, HARS, ATP5C1, ADSL, LRCH3, MCTS1, NOC3L, PABPC4,

UBA6, BANFI, HADHA, VPS72, HTATSF1, CDC40, STX16, PRPF40A,

ATP11B, NDFIP2, YTHDC1, TKT, TPD52L2, GCFC2, PTPN11, HYOU1, EI24,

NUP62, MLX, METTL10, RBMXL1, UTP14A, KAT6A, SRSF1, UTP18,

TCOF1, NFKB2, RPS19BP1, BOD1L1, COPB2, WDR36, USP10, STX6,

PRPF39, CCNC, POLRIC, RBBP7, NOC2L, DOK2, THOC1, USP8, RPL35,

NOB1, HPRT1, NUFIP2, SRRT, CIR1, CD2BP2, REXO2, DHX15, TCEA1,

USP33, TRIP12, EXOC2, HCLS1, CWC27, LMNA, ACLY, ITPR3, ETF1,

PSMD 14, PPPIR2, IST1, TCEB3, PSAT1, TEX10, DNM2, PRPF4B, CAPZA2,

FOXO1, RBM6, MAF1, TOP1, KDMIA, GTF2E2, CSNK2A1, ELOVL5,

NUDCD1, DNAJC9, EIF1, DDX39A, BCL10, ERP29, HMCES, TMEM126B,

TOPBP1, SUZ12, PYCR1, ADRM1, SMARCE1, VPS26B, MEAF6, SNX9,

CTPS1, TTC3, FAM207A, PSMB4, POLE4, DDX3X, MTPN, EIF3F, ASF1A,

STK38L, TRAF4, FGD3, TFDP1, ARL14EP, ITK, SMCHD1, CCDC25, EPB41,

SMG1, AK2, DENR, RBMX, PSMC4, PPID, BABAMI, WDR4, DNMT1,

CPNE3, GPATCH8, EIF4E2, HNRNPA1L2, SKAP1, THADA, CASP3,

MAPKAP1, YRDC, DDA1, FTSJ3, NCOA7, MCM4, MCM5, PRPF6, PURA,

LAP3, MFN2, PPMIK, AAMP, KIAA1191, KPNA3, CID, GLRX3, FKBP4,

FKBP3, PPP3R1, RNH1, PRKDC, ASNS, VARS, RGS10, AKR1A1, CCDC124,

GTF3C6, NFAT5, APEX1, CHD3, GPS1, CD99, RSBN1, SMC3, PWP1, SLBP,

CUL4A, SP3, CENPV

GO: 0044822~poly(A) RNA binding
63
SRSF1, MRPS35, PRPF4B, UTP18, TCOF1, RBM6, SRP19, RPS19BP1, TOP1,

GTF2E2, WDR36, USP10, PTBP3, EIF1, SUPT5H, FTSJ3, DDX39A, MRPL4,

CCDC47, CCDC137, PURA, NOC2L, PRPF6, UBE2N, EIF2S1, ATP5C1,

SNRPG, GLRX3, HSD17B10, FKBP4, NOC3L, FKBP3, PABPC4, RPL35,

PRKDC, NUFIP2, SRRT, MRPL13, DDX3X, CCDC124, HTATSF1, CDC40,

MRPL54, DHX15, APEX1, CHD3, PRPF40A, MRPS26, FDPS, SMG1,

YTHDC1, TPD52L2, ETF1, UBE2L3, RBMX, SLBP, MRPL22, MRPL28,

CPNE3, UTP14A, ALG13, EIF4E2, GPATCH8

GO: 0005654~nucleoplasm
100
TGOLN2, PRPF4B, FOXO1, MAF1, CNOT7, KLHL7, PRIMI, TOP1, KDM1A,

GTF2E2, CSNK2A1, SUPT5H, PPP4C, DDX39A, RCOR1, TOPBP1, SUZ12,

ADRM1, SMARCE1, SNRPG, CPSF3L, MEAF6, GNAI2, UBE2V2, BANF1,

VPS72, PSMB4, PSMB7, HTATSF1, CDC40, ASFIA, TFDP1, PRPF40A,

MRPS26, FDPS, TOMM40, TKT, RBMX, GCFC2, PSMC4, PPID, BABAM1,

WDR4, DNMT1, UTP14A, SNRNP25, KAT6A, SRSF1, UTP18, NFKB2,

RPS19BP1, BOD1L1, CASP3, WDR36, MAPKAP1, USP10, CCNC, POLR1C,

RBBP7, MCM4, MCM5, PRPF6, NOC2L, UBE2N, TAF11, LAP3, KPNA3,

CID, THOC1, NXT1, NDUFB6, USP8, POLR2K, FKBP4, RNH1, NOB1,

PPP3R1, PRKDC, SRRT, CD2BP2, GTF3C6, NFAT5, TCEA1, APEX1, USP33,

TRIP12, CHD3, GPS1, LMNA, ACLY, ITPR3, SMC2, SMC3, SLBP, PSMD14,

CUL4A, SP3, CENPV, TCEB3, TEX10

Nucleus
128
PRPF4B, RBM6, FOXO1, TCEAL8, CNOT7, MAF1, KLHL7, KDMIA, TOP1,

GTF2E2, CSNK2A1, NUDCD1, RAE1, DNAJC9, PPP4C, SUPT5H, DDX39A,

RCOR1, TOPBP1, SUZ12, ADRMI, DCUNID1, SMARCEI, TMEM170A,

SNRPG, CPSF3L, MEAF6, NOC3L, BANF1, TTC3, VPS72, PSMB4, POLE4,

PSMB7, DDX3X, MTPN, HTATSF1, CDC40, ASFIA, TRAF4, TFDP1,

PRPF40A, FIBP, EPB41, TMEM120B, YTHDC1, SMG1, UBE2L3, RBMX,

GCFC2, PTPN11, EI24, NUP62, PSMC4, PPID, MLX, WDR4, BABAM1,

RBMXL1, DNMT1, CPNE3, UTP14A, SNRNP25, KAT6A, HNRNPA1L2,

SRSF1, UTP18, TCOF1, NFKB2, SKAP1, RPS19BP1, WDR36, MAPKAP1,

USP10, FTSJ3, NCOA7, PRPF39, CCNC, POLR1C, RBBP7, MCM4, MCM5,

PURA, PRPF6, NOC2L, UBE2N, TAF11, EIF5AL1, KPNA3, THOCI, C1D,

NXT1, USP8, POLR2K, FKBP4, FKBP3, NOB1, PRKDC, NUFIP2, RGS10,

SRRT, CIR1, CD2BP2, UFM1, REXO2, DHX15, NFAT5, GTF3C6, TCEA1,

APEX1, TRIP12, CHD3, GPS1, NUB1, LMNA, PHF11, COTL1, SMC2, SMC3,

RSBN1, SLBP, PWP1, IST1, SP3, CENPV, TCEB3, SSNA1, TEX10

Ubl conjugation
59
SRSF1, PRPF4B, TCOF1, RBM6, FOXO1, NFKB2, MAF1, BOD1L1, TOP1,

EIF1AY, USP10, SUPT5H, DDX39A, AARS, WNK1, HMCES, TOPBP1,

RBBP7, MCM4, UBE2N, SUZ12, MFN2, ADRMI, SMARCEI, ADSL, C1D,

THOC1, SNX9, MEAF6, USP8, FKBP4, PRKDC, PTRH2, HPRT1, NUFIP2,

DDX3X, UFM1, NFAT5, TCEA1, USP33, APEX1, TRAF4, CHD3, PRPF40A,

ITK, SMCHD1, LMNA, NDFIP2, YTHDC1, ACLY, UBE2L3, RBMX, RSBN1,

CUL4A, SP3, DNMT1, RBMXL1, UTP14A, EIF4E2

GO: 0005737~cytoplasm
127
MRPS35, FOXO1, SRP19, MAF1, KLHL7, GTF2E2, NUDCD1, RAE1,

DNAJC9, EIF1, PDRG1, PPP4C, DDX39A, BCL10, AARS, WNK1, KRT10,

TOPBP1, ADRM1, RFK, CST7, EIF2S1, HARS, LRCH3, MCTS1, CPSF3L,

SNX9, MEAF6, HSD17B10, GNAI2, PABPC4, UBA6, UBE2V2, ARF5, PXK,

CCL5, BANF1, TTC3, PSMB4, PSMB7, DDX3X, STX16, STK38L, TRAF4,

FGD3, PRPF40A, ARL14EP, EPB41, MMADHC, FDPS, NDFIP2, TOMM40,

SMG1, TPD52L2, UBE2L3, PTPN11, EI24, NUP62, PSMC4, PPID, MLX,

METTL10, WDR4, BABAM1, DNMT1, CPNE3, EIF4E2, SNRNP25, SRSF1,

HNRNPA1L2, TCOF1, UFC1, NFKB2, SKAP1, RPS19BP1, CASP3,

MAPKAP1, USP10, YRDC, PURA, NOC2L, UBE2N, LAP3, AAMP, KPNA3,

KIAA1191, THOC1, CID, VPS29, NXT1, USP8, CRLF3, FKBP4, RNH1,

RPL35, HPRT1, NUFIP2, SRRT, CIR1, CCDC124, CD2BP2, UFM1, DHX15,

NFAT5, TSTA3, USP33, APEX1, TRIP12, CHD3, GPS1, NUB1, HCLS1,

LMNA, CD99, ACLY, COTL1, ITPR3, ETF1, SMC2, SMC3, SLBP, MRPL28,

SP3, CENPV, PSAT1, TEX10, DNM2

Protein biosynthesis
16
AARS, DENR, VARS, ETF1, MTIF3, EIF2S1, EIF5AL1, EIF3F, EIF1AY,

HARS, TCEB3, TCEA1, EIF1, SUPT5H, MCTS1, EIF4E2

mRNA splicing
20
HNRNPA1L2, SRSF1, DDX39A, PRPF4B, YTHDC1, PRPF39, RBMX, GCFC2,

PRPF6, CIR1, CD2BP2, CDC40, DHX15, RBMXL1, PTBP3, SREKIIP1,

SNRNP25, THOC1, SNRPG, PRPF40A

Mitochondrion
43
HSD17B10, MRPS35, OXAIL, NDUFB6, MRPS33, COA3, FKBP4, TIMM10,

STOML2, PTRH2, MTIF3, HADHA, NDUFS6, MRPL13, ATAD3B, DDX3X,

TIMM9, REXO2, MRPL54, ABHD10, YRDC, APEX1, GCDH, MRPS26,

MRPL4, NDUFA2, MMADHC, HCLS1, AK2, TOMM40, TMEM126B, SOD2,

MFN2, PYCR1, MRPL22, MRPL28, PPMIK, CLPP, ATP5C1, MRPL48,

SLC25A39, BCO2, HIGD2A

Isopeptide bond
43
SRSF1, MEAF6, PRPF4B, FKBP4, TCOF1, RBM6, NFKB2, PTRH2, MAF1,

HPRT1, NUFIP2, BODIL1, TOP1, DDX3X, UFM1, EIF1AY, NFAT5, TCEA1,

SUPT5H, PRPF40A, CHD3, DDX39A, SMCHD1, HMCES, LMNA, YTHDC1,

ACLY, RBBP7, RBMX, RSBNI, UBE2N, SUZ12, ADRMI, CUL4A,

SMARCE1, SP3, RBMXL1, ADSL, DNMT1, UTP14A, EIF4E2, THOC1, C1D

GO: 0005515~protein
145
OXA1L, PRPF4B, RABIB, STOML2, FOXO1, CNOT7, KDMIA, C1ORF109,

binding

TOP1, GTF2E2, CSNK2A1, ELOVL5, PPP4C, SUPT5H, SREK1IP1, DDX39A,

BCL10, RCOR1, ARL16, TOPBP1, SUZ12, ADRM1, PYCR1, DCUNID1,

SMARCE1, EIF2S1, CLPP, TMEM170A, MRPL48, SNRPG, CPSF3L, SNX9,

MEAF6, HSD17B10, GNAI2, UBA6, UBE2V2, ARF5, PTRH2, CCL5, BANF1,

TTC3, VPS72, POLE4, PSMB7, DDX3X, STX16, EIF3F, TMED 10, STK38L,

ASF1A, TRAF4, TFDP1, PRPF40A, ITK, HPCAL1, EPB41, TSR2, MMADHC,

ATP11B, YTHDC1, NDFIP2, SMG1, UBE2L3, RBMX, PTPN11, PSMC4,

NUP62, PPID, WDR4, BABAM1, DNMT1, SPCS1, CPNE3, HSPA13, EIF4E2,

SNRNP25, KAT6A, SRSF1, COA3, UFC1, NFKB2, SKAP1, RPS19BP1,

CASP3, USP10, STX6, CCNC, POLR1C, RBBP7, MCM4, MCM5, PURA,

PRPF6, NOC2L, MFN2, UBE2N, TAF11, PPMIK, KPNA3, SNX10, THOC1,

CID, VPS29, GLRX3, NXT1, USP8, CRLF3, FKBP4, RNH1, PPP3R1, PRKDC,

HPRT1, VARS, NUFIP2, SRRT, MRPL13, CIR1, CD2BP2, DHX15, GTF3C6,

USP33, APEX1, EXOC2, TRIP12, CHD3, NUB1, HCLS1, LMNA, ACLY,

ITPR3, ETF1, SMC2, SMC3, SLBP, PSMD14, PPPIR2, CUL4A, MRPL28,

IST1, SP3, CKS2, TCEB3, SSNA1, DNM2

mRNA processing
21
HNRNPA1L2, SRSF1, DDX39A, PRPF4B, YTHDC1, PRPF39, RBMX, GCFC2,

SLBP, PRPF6, CIR1, CD2BP2, CDC40, DHX15, RBMXL1, PTBP3, SREK1IP1,

SNRNP25, THOC1, SNRPG, PRPF40A

GO: 0005739~mitochondrion
47
HSD17B10, MRPS35, OXA1L, NDUFB6, MRPS33, COA3, FKBP4, DTYMK,

PPP3R1, TIMM10, FOXO1, RAB1B, PTRH2, SRP19, VARS, UXS1, MTIF3,

HADHA, TIMM9, REXO2, ABHD10, YRDC, APEX1, TFDP1, GCDH,

MRPS26, MRPL4, FIBP, MMADHC, HCLS1, AARS, NDFIP2, TOMM40,

PTPN11, SOD2, MFN2, LAP3, PYCR1, MRPL22, MRPL28, RFK, PPM1K,

CLPP, HARS, ATP5C1, ADSL, BCO2

GO: 0005743~
24
MRPS35, MRPS26, MRPL4, NDUFA2, OXA1L, MRPS33, NDUFB6, TIMM10,

mitochondrial inner

STOML2, AK2, TMEM126B, HADHA, SOD2, NDUFS6, MRPL22, MRPL13,

membrane

ATAD3B, MRPL28, TIMM9, MRPL54, ATP5C1, MRPL48, SLC25A39,

HIGD2A

Cytoplasm
106
RAB1B, STOML2, FOXO1, CNOT7, MAF1, SRP19, WDR73, NUDCD1, RAE1,

DNAJC9, PDRG1, PPP4C, DDX39A, BCL10, AARS, WNK1, TOPBP1,

ADRM1, RFK, CST7, HARS, VPS26B, MCTS1, SNRPG, CPSF3L, SNX9,

GNAI2, PABPC4, ARF5, PXK, BANF1, PSMB4, PSMB7, DDX3X, MTPN,

EIF3F, STX16, STK38L, TRAF4, FGD3, ARL14EP, ITK, EPB41, MMADHC,

FDPS, SMG1, UBE2L3, PTPN11, EI24, NUP62, PSMC4, PPID, ARF3, MLX,

METTL10, BABAM1, CPNE3, HNRNPA1L2, SRSF1, NFKB2, SKAP1, COPB2,

CASP3, USP10, UBE2N, LAP3, EIF5AL1, AAMP, KPNA3, KIAA1191, SNX10,

THOC1, CID, VPS29, GLRX3, NXT1, USP8, CRLF3, FKBP4, RNH1, PPP3R1,

HPRT1, NUFIP2, RGS10, SRRT, CIR1, CCDC124, CD2BP2, UFM1, REXO2,

NFAT5, APEX1, USP33, CHD3, GPS1, HCLSI, ACLY, COTL1, ETF1, SMC2,

SLBP, IST1, CENPV, SSNA1, TEX10, DNM2

GO: 0005634~nucleus
122
DTYMK, RBM6, FOXO1, TCEAL8, SRP19, CNOT7, MAF1, KLHL7, KDM1A,

TOP1, GTF2E2, CSNK2A1, NUDCD1, RAE1, DNAJC9, PTBP3, EIF1, PPP4C,

SUPT5H, IFRD2, DDX39A, BCL10, RCOR1, KRT10, TOPBP1, SUZ12,

ADRMI, DCUNID1, SMARCE1, EIF2S1, PABPC4, NOC3L, UBE2V2, PXK,

BANF1, TTC3, VPS72, PSMB4, POLE4, PSMB7, DDX3X, MTPN, HTATSF1,

ASFIA, TRAF4, TFDP1, EPB41, FIBP, TSR2, YTHDC1, SMG1, TKT,

UBE2L3, RBMX, GCFC2, PTPN11, PSMC4, PPID, MLX, WDR4, BABAM1,

RBMXL1, DNMT1, CPNE3, SNRNP25, KAT6A, SRSF1, UTP18, TCOF1,

NFKB2, SKAP1, CASP3, MAPKAP1, USP10, FTSJ3, NCOA7, CCNC, RBBP7,

MCM4, MCM5, PURA, PRPF6, NOC2L, UBE2N, LAP3, NCOA4, KPNA3,

SNX10, THOC1, C1D, GLRX3, POLR2K, FKBP3, NUFIP2, RGS10, CIRI,

CD2BP2, UFM1, REXO2, DHX15, NFAT5, TCEA1, APEX1, TRIP12, CHD3,

NUB1, HCLS1, LMNA, PHF11, COTL1, ETF1, SMC2, SMC3, RSBN1, SLBP,

PWP1, PSMD14, SP3, CENPV, TCEB3, SSNA1, DNM2

Chaperone
15
FKBP4, TIMM10, DNAJB14, CNPY3, MESDC2, TMEM126B, RBBP7, COTL1,

HYOU1, PSMG4, DNAJC9, PPID, TIMM9, PDRG1, ASF1A

Ribonucleoprotein
18
HNRNPA1L2, MRPS35, MRPS26, MRPL4, MRPS33, RPL35, RPL39, SRP19,

RBMX, RPS19BP1, SLBP, MRPL22, MRPL13, MRPL28, MRPL54, RBMXL1,

MRPL48, SNRPG

GO: 0005730~nucleolus
34
MEAF6, UTP18, NOC3L, TCOF1, RPL35, PRKDC, SRP19, MAF1, RPS19BP1,

TTC3, KLHL7, TOP1, WDR36, RAE1, REXO2, DHX15, TCEAI, APEX1,

FTSJ3, CHD3, NUB1, CCDC137, ITPR3, SMC2, GCFC2, PWP1, NOC2L,

SUZ12, UBE2N, PPID, UTP14A, TEX10, KAT6A, C1D

GO: 0003723~RNA
27
HNRNPAIL2, SRSF1, PABPC4, RBM6, CNOT7, RPL39, NUFIP2, DDX3X,

binding

RAE1, HTATSF1, PTBP3, PRPF40A, MRPL4, YTHDC1, THUMPD2, ETF1,

RBBP7, RBMX, PRPF6, PURA, SUZ12, SMARCE1, DNMT1, RBMXL1,

THOC1, C1D, SNRPG

GO: 0005829~cytosol
83
TGOLN2, CAPZA2, DTYMK, FOXO1, NFKB2, SRP19, MAF1, CNOT7,

SKAP1, COPB2, CASP3, WDR73, CSNK2A1, SIPR1, MAPKAP1, ABHD10,

STX6, BCL10, AARS, WNK1, POLR1C, MFN2, UBE2N, DOK2, RFK, EIF2S1,

HARS, ADSL, VPS26B, KPNA3, SNRPG, VPS29, NXT1, USP8, GNAI2,

POLR2K, FKBP4, PPP3R1, NOB1, RPL35, UBA6, CTPS1, PRKDC, ASNS,

HPRT1, VARS, RPL39, PTRH2, BANF1, PSMB4, RGS10, PSMB7, AKR1A1,

MTPN, EIF3F, STX16, TSTA3, EXOC2, TRIP12, FGD3, ITK, MMADHC,

LMNA, FDPS, AK2, SMG1, TKT, ACLY, ITPR3, ETF1, SMC2, SMC3,

PTPN11, SLBP, PSMD14, PSMC4, IST1, WDR4, CPNE3, PSAT1, SSNA1,

EIF4E2, DNM2

GO: 0000398~mRN
15
SRSF1, DDX39A, PRPF4B, POLR2K, CWC27, RBMX, PRPF6, SRRT,

A splicing, via

CD2BP2, HTATSF1, CDC40, DHX15, SNRNP25, SNRPG, PRPF40A

spliceosome

Initiation factor
8
EIF2S1, EIF1AY, EIF3F, EIF1, DENR, MCTS1, MTIF3, EIF4E2

GO: 0003743~translation
8
EIF2S1, EIF1AY, EIF3F, EIF1, DENR, MCTS1, MTIF3, EIF4E2

initiation factor

activity

GO: 0070125~
9
MRPS35, MRPS26, MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, MRPL54,

mitochondrial

MRPL48

translational

elongation

mutagenesis site
55
SRSF1, TGOLN2, FOXO1, UFC1, RAB1B, NFKB2, SKAP1, KDM1A, TOP1,

S1PR1, USP10, SUPT5H, PPP4C, BCL10, NCOA7, UBE2N, MFN2, PPM1K,

NCOA4, EIF5AL1, MCTS1, THOC1, CPSF3L, VPS29, NXT1, PRKDC, UBA6,

ASNS, PXK, BANF1, DDX3X, AKRIA1, UFM1, HTATSF1, REXO2, ASFIA,

STK38L, USP33, APEX1, GCDH, EPB41, NUB1, LMNA, SMG1, COTL1,

SLBP, PTPN11, SOD2, CUL4A, SP3, IST1, CENPV, DNMT1, EIF4E2, KAT6A

GO: 0070126~
9
MRPS35, MRPS26, MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, MRPL54,

mitochondrial

MRPL48

translational

termination

Ribosomal protein
12
MRPS35, MRPS26, MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, MRPL54,

RPL35, MRPL48, RPL39, RPS19BP1

transit
20
GCDH, MRPS35, MRPS26, OXA1L, MMADHC, PTRH2, MTIF3, HADHA,

peptide: Mitochondrion

SOD2, NDUFS6, MRPL22, MRPL28, PPMIK, CLPP, REXO2, MRPL54,

ATP5C1, ABHD10, YRDC, MRPL48

RNA-binding
24
HNRNPA1L2, DDX39A, SRSF1, PABPC4, AARS, YTHDC1, RBM6,

THUMPD2, CNOT7, SRP19, RBMX, NUFIP2, SLBP, DDX3X, EIF5AL1,

HTATSF1, EIF2S1, RBMXL1, PTBP3, APEX1, EIF4E2, THOC1, C1D, SNRPG

Transit peptide
21
GCDH, MRPS35, MRPS26, OXAIL, MMADHC, STOML2, PTRH2, MTIF3,

HADHA, SOD2, NDUFS6, MRPL22, MRPL28, PPM1K, REXO2, CLPP,

MRPL54, ATP5C1, ABHD10, YRDC, MRPL48

GO: 0008380~RNA
12
HNRNPA1L2, CIR1, PRPF4B, CDC40, DHX15, RBMXL1, PTBP3, SREK1IP1,

splicing

SNRNP25, THOC1, PRPF6, SNRPG

Protein transport
22
VPS29, NXT1, STX6, SNX9, KDELR2, TIMM10, RAB1B, TOMM40, ARF5,

LMAN2, COPB2, NUP62, PPID, EIF5AL1, ARF3, STX16, TIMM9, TMED10,

VPS26B, KPNA3, SNX10, EXOC2

GO: 0006406~mRN
9
NXT1, SRSF1, DDX39A, NUP62, RAE1, CDC40, SMG1, SLBP, THOC1

A export from

nucleus

GO: 0016607~nuclear
12
NXT1, SRSF1, CIR1, DDX3X, CD2BP2, NOC3L, LMNA, YTHDC1, APEX1,

speck

THOC1, PRPF6, PRPF40A

Coiled coil
65
MRPS35, COA3, TCOF1, RBM6, STOML2, TCEAL8, NFKB2, THADA,

COPB2, KDM1A, TOP1, ATAD3B, DNAJC9, SREK1IP1, SUPT5H, FTSJ3,

STX6, RCOR1, WNK1, CNPY3, CCDC47, NCOA7, KRT10, CCDC137, PURA,

MFN2, SMARCE1, EIF2S1, HARS, MEAF6, USP8, CRLF3, FKBP4, NOC3L,

ARF5, VARS, TTC3, SRRT, FAM107B, CCDC124, STX16, EXOC2, TRAF4,

CHD3, SMCHD1, CCDC25, NUB1, CWC27, HCLS1, TMEM120B, LMNA,

SMG1, YTHDC1, TPD52L2, ITPR3, SMC2, GCFC2, SMC3, NUP62, PSMC4,

IST1, MLX, UTP14A, SSNA1, GPATCH8

GO: 0003682~chromatin
17
NOC3L, FOXO1, NFKB2, RBMX, SMC3, MCM5, NOC2L, KDMIA, TOP1,

binding

SMARCE1, NUP62, SP3, CKS2, DNMT1, SUPT5H, ASF1A, TEX10

Repressor
20
RCOR1, CCNC, NFKB2, MAF1, CNOT7, RBBP7, RBMX, GCFC2, NOC2L,

SUZ12, KDMIA, CIR1, SP3, MLX, DNMT1, PTBP3, SUPT5H, APEX1, C1D,

KAT6A

hsa03040: Spliceosome
10
HNRNPA1L2, SRSF1, CDC40, DHX15, RBMXL1, RBMX, THOC1, PRPF6,

PRPF40A, SNRPG

GO: 0032784~regulation
4
HTATSF1, TCEA1, SUPT5H, THOC1

of DNA-

templated

transcription,

elongation

hsa03008: Ribosome
8
NXT1, WDR36, CSNK2A1, UTP18, REXO2, TCOF1, NOB1, UTP14A

biogenesis in

eukaryotes

Mitochondrion inner
12
NDUFS6, NDUFA2, OXA1L, NDUFB6, ATAD3B, COA3, TIMM9, TIMM10,

membrane

ATP5C1, STOML2, SLC25A39, HIGD2A

GO: 0006270~DNA
5
PRIM1, TOPBP1, MCM4, MCM5, PURA

replication initiation

Neuropathy
7
MFN2, AARS, LMNA, HARS, WNK1, DNMT1, DNM2

GO: 0006890~retrograde
7
COPB2, KDELR2, ARF3, TMED10, RAB1B, LMAN2, ARF5

vesicle-

mediated transport,

Golgi to ER

GO: 0006405~RNA
6
NXT1, SRSF1, DDX39A, NUP62, CDC40, THOC1

export from nucleus

Spliceosome
8
HNRNPA1L2, SRSF1, PRPF4B, CDC40, RBMX, SNRNP25, PRPF6, SNRPG

SM00968: SM00968
3
SMCHD1, SMC2, SMC3

GO: 0006368~transcription
7
TAF11, ADRM1, GTF2E2, POLR2K, TCEB3, TCEA1, SUPT5H

elongation

from RNA

polymerase II

promoter

Chromatin regulator
12
SUZ12, KDMIA, MEAF6, SMARCE1, RCOR1, BABAM1, DNMT1, RBBP7,

ASFIA, VPS72, CHD3, KAT6A

GO: 0071013~catalytic
7
SRSF1, PRPF4B, CWC27, CDC40, RBMX, PRPF6, SNRPG

step 2

spliceosome

GO: 0006511~ubiquitin-
10
UBE2N, PSMD14, USP8, CUL4A, NUB1, UBA6, USP10, UBE2L3, USP33,

dependent

TTC3

protein catabolic

process

DNA repair
12
UBE2N, PSMD14, CUL4A, BABAM1, SMG1, PRKDC, TOPBP1, USP10,

APEX1, SMC3, TRIP12, BOD1L1

GO: 0050852~T cell
9
UBE2N, ITK, BCL10, PSMB4, PSMD14, PSMB7, PSMC4, STOML2, SKAP1

receptor signaling

pathway

IPR010935: SMCs
3
SMCHD1, SMC2, SMC3

flexible hinge

GO: 0006369~termination
6
SRSF1, DDX39A, CDC40, SLBP, THOC1, SNRPG

of RNA

polymerase II

transcription

GO: 0000784~nuclear
8
KDMIA, SMCHD1, PRKDC, APEX1, MCM4, MCM5, THOC1, PURA

chromosome,

telomeric region

DNA damage
13
PRKDC, SMG1, TOPBP1, SMC3, BOD1L1, UBE2N, PSMD14, CUL4A,

BABAM1, USP10, APEX1, MCTS1, TRIP12

GO: 1901796~regulation
8
TAF11, MEAF6, CSNK2A1, TOPBP1, RBBP7, CHD3, KAT6A, NOC2L

of signal

transduction by p53

class mediator

GO: 0038061~NIK/
6
PSMB4, PSMD14, PSMB7, PSMC4, NFKB2, PPP4C

NF-kappaB

signaling

Nucleotide-binding
40
PRPF4B, GNAI2, DTYMK, CTPS1, RABIB, UBA6, PRKDC, ASNS, ARF5,

VARS, HPRT1, ATAD3B, CSNK2A1, DDX3X, DHX15, STK38L, CHD3,

DDX39A, ITK, AARS, ATP11B, WNK1, AK2, SMG1, ACLY, ARL16,

UBE2L3, MCM4, SMC2, MCM5, SMC3, MFN2, UBE2N, HYOU1, PSMC4,

RFK, ARF3, HARS, HSPA13, DNM2

GO: 0043234~protein
15
BCL10, OXA1L, EPB41, FKBP4, PXK, VPS72, PTPN11, UBE2N, KDM1A,

complex

SMARCE1, NUP62, DNMT1, USP10, ASF1A, DNM2

Translation,
6
CPSF3L, METTL5, EIF2S1, HARS, MCTS1, MTIF3

ribosomal structure

and biogenesis

GO: 0005694~chromosome
7
TOP1, PRPF4B, SMCHD1, CCDC137, TOPBP1, SMC3, BOD1L1

Charcot-Marie-
5
MFN2, AARS, LMNA, HARS, DNM2

Tooth disease

GO: 0005758~mitochondrial
6
DTYMK, REXO2, TIMM9, TIMM10, AK2, STOML2

intermembrane space

GO: 0070536~protein
4
PSMD14, USP8, BABAMI, USP33

K63-linked

deubiquitination

Activator
19
MEAF6, FOXO1, NCOA7, PHF11, CCNC, NFKB2, RBMX, PURA, SRRT,

NCOA4, SP3, HTATSF1, MLX, NFAT5, DNMT1, SUPT5H, APEX1, KAT6A,

TFDP1

Proteasome
5
PSMB4, ADRM1, PSMD14, PSMB7, PSMC4

GO: 0032790~ribosome
3
DENR, MCTS1, MTIF3

disassembly

hsa03013: RNA
10
NXT1, NUP62, RAE1, EIF2S1, EIF1AY, PABPC4, EIF3F, EIF1, EIF4E2,

transport

THOC1

GO: 0043130~ubiquitin
6
UBE2N, BCL10, NUP62, RAE1, CKS2, USP33

binding

GO: 0043022~ribosome
5
EIF5AL1, EIF2S1, SPCS1, ETF1, MTIF3

binding

Isomerase
7
TOP1, FKBP4, CWC27, PPID, FKBP3, TOPBP1, TSTA3

Ubl conjugation
19
USP8, UFC1, UBA6, UBE2V2, UBE2L3, TTC3, UBE2N, KLHL7, DCUN1D1,

pathway

PSMD14, CUL4A, UFM1, EIF3F, BABAM1, DDA1, USP10, USP33, ALG13,

TRIP12

Elongation factor
4
EIF5AL1, TCEB3, TCEA1, SUPT5H

ATP-binding
32
PRPF4B, DTYMK, CTPS1, UBA6, PRKDC, ASNS, VARS, ATAD3B,

CSNK2A1, DDX3X, DHX15, STK38L, CHD3, DDX39A, ITK, AARS, ATP11B,

WNK1, SMG1, AK2, ACLY, UBE2L3, SMC2, MCM4, MCM5, SMC3, UBE2N,

HYOU1, PSMC4, RFK, HARS, HSPA13

Cell division
13
SNX9, ATAD3B, GNAI2, CCDC124, IST1, CDC40, CKS2, CENPV, BABAM1,

SMC2, SMC3, MCM5, PRPF40A

SM00320: WD40
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

PWP1

hsa01130: Biosynthesis
11
GCDH, HSD17B10, PYCR1, AKRIA1, FDPS, ADSL, AK2, ACLY, TKT,

of antibiotics

PSAT1, HADHA

GO: 0006457~protein
9
CSNK2A1, GNAI2, FKBP4, CWC27, PPID, ERP29, AARS, MESDC2, PDRG1

folding

hsa03060: Protein export
4
OXA1L, SEC11A, SPCS1, SRP19

ER-Golgi transport
6
COPB2, KDELR2, ARF3, TMED10, ARF5, ERGIC3

Cell cycle
18
SNX9, USP8, GNAI2, SMC2, MCM4, SMC3, MCM5, ATAD3B, CSNK2A1,

CCDC124, IST1, CDC40, BABAM1, CENPV, CKS2, MCTS1, TFDP1,

PRPF40A

GO: 0045739~positive
4
UBE2N, BABAM1, UBE2V2, APEX1

regulation of

DNA repair

GO: 0050699~WW
4
NDFIP2, TCEAL8, TRAF4, DNM2

domain binding

GO: 0000502~proteasome
5
PSMB4, ADRM1, PSMD14, PSMB7, PSMC4

complex

GO: 0005794~Golgi
23
TGOLN2, STX6, KDELR2, USP8, ATP11B, NDFIP2, RABIB, TOPBP1, ARF5,

apparatus

LMAN2, ERGIC3, PWP1, TAF11, EI24, SP3, ARF3, MAPKAP1, STX16,

TMED10, USP33, FGD3, DNM2, KAT6A

GO: 0038095~Fc-
8
UBE2N, ITK, BCL10, PSMB4, PSMD14, PSMB7, PSMC4, PPP3R1

epsilon receptor

signaling pathway

GO:0005840~ribosome
8
MRPL4, MRPL13, MRPS33, EIF2S1, MRPL54, RPL35, APEX1, RPS19BP1

Rotamase
4
FKBP4, CWC27, PPID, FKBP3

GO: 0030133~transport
6
TGOLN2, COPB2, KDELR2, ERP29, TMED10, RAB1B

vesicle

hsa00240: Pyrimidine
7
PRIM1, POLE4, POLR2K, DTYMK, CTPS1, POLR1C, ENTPD4

metabolism

repeat: WD 3
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

PWP1

GO: 0010494~cytoplasmic
4
DDX3X, EIF2S1, PABPC4, NUFIP2

stress granule

GO: 0003746~translation
4
EIF5AL1, TCEB3, TCEA1, SUPT5H

elongation

factor activity

GO: 0006303~double-
5
UBE2N, PSMD14, BABAM1, PRKDC, UBE2V2

strand break repair

via nonhomologous

end joining

GO: 0006626~protein
4
MFN2, TIMM9, TIMM10, TOMM40

targeting to

mitochondrion

GO: 0032981~mitochondrial
5
NDUFS6, NDUFA2, OXA1L, NDUFB6, TMEM126B

respiratory

chain complex I

assembly

WD repeat
10
COPB2, WDR36, WDR73, UTP18, RAEI, CDC40, AAMP, WDR4, RBBP7,

PWP1

active site: Glycyl
5
UBE2N, UFC1, UBA6, UBE2L3, TRIP12

thioester

intermediate

GO: 0061077~chaperone-
4
CSNK2A1, FKBP4, PPID, FKBP3

mediated

protein folding

GO: 0003713~transcription
10
TAF11, BCL10, SMARCE1, NCOA4, NFKB2, UBE2L3, APEX1, PRPF6,

coactivator

KAT6A, TFDP1

activity

repeat: WD 1
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

PWP1

repeat: WD 2
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

PWP1

Chromosomal
11
SUZ12, HSD17B10, BCL10, TOP1, MEAF6, NCOA4, FOXO1, TCEA1,

rearrangement

NFKB2, THADA, KAT6A

GO: 0006974~cellular
9
DDX39A, CASP3, CUL4A, FOXO1, TOPBP1, USP10, MCTS1, TRIP12,

response to DNA

BODIL1

damage stimulus

IPR001680: WD40
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

repeat

PWP1

SM00360: RRM
8
HNRNPAIL2, SRSF1, HTATSF1, PABPC4, RBMXL1, RBM6, PTBP3, RBMX

GO:0005643~nuclear
5
NXT1, NUP62, RAE1, EIF5AL1, KPNA3

pore

GO: 0006412~translation
10
MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, PABPC4, HARS, RPL35,

SLC25A39, RPL39

GO: 0006450~regulation
3
AARS, YRDC, VARS

of translational

fidelity

GO: 0004407~histone
4
KDMIA, RCOR1, RBBP7, CHD3

deacetylase

activity

GO: 0006413~translational
7
EIF2S1, EIF1AY, EIF3F, RPL35, EIF1, RPL39, EIF4E2

initiation

GO: 0051301~cell
12
ATAD3B, GNAI2, CCDC124, IST1, CDC40, CKS2, CENPV, BABAM1, SMC2,

division

MCM5, SMC3, PRPF40A

GO: 0042795~snRN
5
TAF11, CPSF3L, SRRT, GTF2E2, POLR2K

A transcription from

RNA polymerase II

promoter

GO: 0005682~U5
3
CD2BP2, PRPF6, SNRPG

snRNP

GO: 0071004~U2-
3
PRPF39, PRPF40A, SNRPG

type prespliceosome

GO: 0002223~stimulatory
6
UBE2N, BCL10, PSMB4, PSMD14, PSMB7, PSMC4

C-type lectin

receptor signaling

pathway

GO: 0031072~heat
4
FKBP4, DNAJC9, PPID, LMAN2

shock protein

binding

GO: 0005759~mitochondrial
11
GCDH, HSD17B10, PYCR1, PPM1K, DTYMK, REXO2, CLPP, ATP5C1,

matrix

ABHD10, BCO2, SOD2

GO: 0008565~protein
5
VPS29, TIMM9, TIMM10, KPNA3, VPS26B

transporter activity

GO: 0031372~UBC1
2
UBE2N, UBE2V2

3-MMS2 complex

GO: 0042101~T cell
3
BCL10, STOML2, SKAP1

receptor complex

GO: 0016581~NuRD
3
CSNK2A1, RBBP7, CHD3

complex

GO: 0006376~mRN
3
SRSF1, YTHDC1, RBMXL1

A splice site

selection

GO: 0051262~protein
4
OXA1L, ADSL, CCL5, UXS1

tetramerization

GO: 0005524~ATP
35
PRPF4B, FKBP4, DTYMK, CTPS1, UBA6, PRKDC, ASNS, PXK, VARS,

binding

ATAD3B, CSNK2A1, DDX3X, DHX15, STK38L, CHD3, DDX39A, ITK,

SMCHD1, AARS, ATP11B, WNK1, SMG1, AK2, ACLY, UBE2L3, SMC2,

MCM4, MCM5, SMC3, UBE2N, HYOU1, PSMC4, RFK, HARS, HSPA13

GO: 0003735~structural
9
MRPS35, MRPL22, MRPL4, MRPL13, MRPS33, MRPL28, RPL35, SLC25A39,

constituent of

RPL39

ribosome

Transcription
46
MEAF6, POLR2K, FOXO1, TCEAL8, NFKB2, MAF1, CNOT7, VPS72, PRIM1,

SRRT, KDMIA, GTF2E2, CSNK2A1, CIR1, DDX3X, HTATSF1, GTF3C6,

NFAT5, TCEA1, SUPT5H, ASFIA, APEX1, TFDP1, CHD3, RCOR1, NCOA7,

POLRIC, CCNC, PHF11, RBBP7, UBE2L3, RBMX, GCFC2, PURA, NOC2L,

TAF11, SUZ12, NCOA4, MLX, SP3, TCEB3, DNMT1, MCTS1, THOC1,

KAT6A, CID

GO: 0000413~protein
4
FKBP4, CWC27, PPID, FKBP3

peptidyl-prolyl

isomerization

repeat: WD 4
9
COPB2, WDR36, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7, PWP1

GO: 0005685~U1
3
PRPF39, PRPF40A, SNRPG

snRNP

hsa03030: DNA
4
PRIM1, POLE4, MCM4, MCM5

replication

rRNA processing
5
WDR36, TSR2, UTP18, FTSJ3, C1D

GO: 0007077~mitotic
4
NUP62, RAE1, LMNA, BANF1

nuclear envelope disassembly

IPR012340: Nucleic
5
EIF5AL1, EIF2S1, EIF1AY, MCM4, MCM5

acid-binding, OB-fold

GO:0048037~cofactor
3
ACLY, TKT, ASNS

binding

compositionally
8
HTATSF1, TCOF1, MRPL48, TTC3, RSBN1, THADA, CHD3, KAT6A

biased region:Poly-Lys

GO: 0006886~intracellular
9
STX6, VPS29, SNX9, COPB2, KDELR2, STX16, ERP29, TMED10, VPS26B

protein transport

GO: 0005545~1-
3
SNX9, EPB41, SNX10

phosphatidylinositol

binding

IPR019775: WD40
7
WDR36, UTP18, RAE1, CDC40, AAMP, RBBP7, PWP1

repeat, conserved

site

GO: 0003755~peptidyl-
4
FKBP4, CWC27, PPID, FKBP3

prolyl cis-trans

isomerase activity

GO: 0031625~ubiquitin
10
MFN2, UBE2N, BCL10, SNX9, CUL4A, FOXO1, UBE2V2, UBE2L3, EIF4E2,

protein ligase

TRAF4

binding

GO: 0008134~transcription
10
KDM1A, BCL10, DDX3X, RCOR1, PPID, MLX, PRKDC, KAT6A, TFDP1,

factor

PURA

binding

GO: 0071008~U2-
2
DHX15, GCFC2

type post-mRNA

release spliceosomal

complex

GO: 1900087~positive
3
DDX3X, CUL4A, APEX1

regulation of

G1/S transition of

mitotic cell cycle

SM00361: RRM_1
3
PABPC4, RBMXL1, RBMX

IPR017986: WD40-
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

repeat-containing

PWP1

domain

GO: 0031124~mRNA
4
SRSF1, DDX39A, CDC40, THOC1

3′-end processing

Protease
14
LAP3, PSMB4, PSMD14, CASP3, PSMB7, USP8, SEC11A, EIF3F, CLPP,

HMCES, SPCS1, USP10, USP33, ALG13

GO: 0051443~positive
3
UBE2N, DCUNID1, UBE2L3

regulation of

ubiquitin-protein

transferase activity

GO: 0006521~regulation
4
PSMB4, PSMD14, PSMB7, PSMC4

of cellular

amino acid

metabolic process

GO: 0032481~positive
4
POLR2K, PRKDC, POLRIC, NFKB2

regulation of type

I interferon

production

hsa05010: Alzheimer's
8
HSD17B10, NDUFS6, NDUFA2, CASP3, NDUFB6, PPP3R1, ATP5C1, ITPR3

disease

Amino-acid
3
PYCR1, ASNS, PSAT1

biosynthesis

GO: 0017053~transcriptional
4
SMARCE1, RCOR1, SP3, C1D

repressor complex

Hydrolase
33
CPSF3L, USP8, PTRH2, CNOT7, PSMB4, CASP3, PSMB7, DDX3X, REXO2,

EIF3F, DHX15, ABHD10, USP10, ENTPD4, PPP4C, USP33, APEX1, CHD3,

DDX39A, SEC11A, HMCES, ATP11B, MCM4, MCM5, PTPN11, LAP3, MFN2,

PSMD14, PPMIK, CLPP, SPCS1, ALG13, DNM2

IPR012677: Nucleotide-
9
HNRNPAIL2, SRSF1, SRRT, HTATSF1, PABPC4, RBMXL1, RBM6, PTBP3,

binding, alpha-beta plait

RBMX

GO: 0001731~formation
3
EIF3F, DENR, MCTS1

of translation preinitiation complex

Helicase
6
DDX39A, DDX3X, DHX15, MCM4, MCM5, CHD3

GO: 0005802~trans-
6
TGOLN2, STX6, LAP3, SNX9, STX16, DNM2

Golgi network

IPR016135: Ubiquitin-
4
UBE2N, UFC1, UBE2V2, UBE2L3

conjugating

enzyme/RWD-like

GO: 0006357~regulation
13
TCEAL8, NFKB2, PURA, SOD2, KDMIA, CIR1, SMARCE1, HTATSF1,

of transcription

TCEB3, TCEA1, SUPT5H, CHD3, TFDP1

from RNA

polymerase II promoter

GO: 0032403~protein
8
CASP3, IST1, HCLS1, TMED10, APEX1, SKAP1, HADHA, DNM2

complex binding

GO: 0005763~mitochondrial
3
MRPS35, MRPS26, MRPS33

small ribosomal subunit

hsa03050: Proteasome
4
PSMB4, PSMD14, PSMB7, PSMC4

GO: 0005681~spliceosomal
5
HNRNPAIL2, DDX39A, CDC40, PRPF6, SNRPG

complex

GO: 0000166~nucleotide
11
HNRNPA1L2, SRSF1, SRRT, HTATSF1, PABPC4, RBMXL1, RBM6, PTBP3,

binding

PXK, HPRT1, RBMX

Proto-oncogene
8
SUZ12, TOP1, DCUNID1, CSNK2A1, NCOA4, FOXO1, NFKB2, KAT6A

IPR016040: NAD(P)-
7
HSD17B10, PYCR1, UBA6, ACLY, TSTA3, UXSI, HADHA

binding domain

IPR024969: Rpn11/E
2
PSMD14, EIF3F

IF3F C-terminal domain

IPR001950: Translation
2
EIF1, DENR

initiation factor SUI1

GO: 1990391~DNA
2
KDM1A, RCOR1

repair complex

GO: 0030906~retromer,
2
VPS29, VPS26B

cargo-selective complex

IPR003954: RNA
3
PABPC4, RBMXL1, RBMX

recognition motif

domain, eukaryote

GO: 0005689~U12-
3
DHX15, SNRNP25, SNRPG

type spliceosomal

complex

GO: 0009055~electron
5
GLRX3, GCDH, NDUFS6, AKR1A1, TSTA3

carrier activity

GO:0070062~extracellular
54
SRSF1, CAPZA2, RABIB, UFC1, UXS1, VPS13D, KDELR2, ERP29, AARS,

exosome

KRT10, LAP3, UBE2N, EIF2S1, ATP5C1, VPS29, GLRX3, SNX9, GNAI2,

FKBP4, RNH1, UBE2V2, LMAN2, ARF5, HPRT1, BANF1, PSMB4, PSMB7,

AKR1A1, DDX3X, UFM1, MTPN, TMED10, TSTA3, HPCAL1, FIBP,

CCDC25, SEC11A, AK2, TOMM40, ACLY, TKT, UBE2L3, COTL1, SMC2,

RBMX, SOD2, HYOU1, PSMD14, IST1, ARF3, CPNE3, HSPA13, PSAT1,

DNM2

Respiratory chain
4
NDUFS6, NDUFA2, NDUFB6, HIGD2A

GO: 0015031~protein
12
VPS29, KDELR2, IST1, ARF3, EIF5AL1, PPID, TIMM9, RAB1B, LMAN2,

transport

ARF5, SNX10, EXOC2

IPR000504: RNA
8
HNRNPA1L2, SRSF1, HTATSF1, PABPC4, RBMXL1, RBM6, PTBP3, RBMX

recognition motif domain

hsa00230: Purine
8
PRIM1, POLE4, POLR2K, ADSL, AK2, POLRIC, ENTPD4, HPRT1

metabolism

Mental retardation
9
HSD17B10, WDR73, DDX3X, SMARCE1, ASNS, RBMX, SMC3, KAT6A,

PURA

GO: 0015949~nucleo
3
DTYMK, CTPS1, AK2

base-containing

small molecule interconversion

GO: 0046580~negative
3
MFN2, NUP62, MAPKAP1

regulation of Ras

protein signal transduction

GO: 0030529~intracellular
6
HNRNPA1L2, NUP62, PABPC4, RBMXL1, RBMX, SLBP

ribonucleoprotein

complex

hsa05012: Parkinson's disease
7
NDUFS6, NDUFA2, CASP3, NDUFB6, GNAI2, ATP5C1, UBE2L3

Thiol protease
6
CASP3, USP8, EIF3F, USP10, USP33, ALG13

Ribosome biogenesis
4
WDR36, DDX3X, UTP14A, FTSJ3

GO: 0006364~IRNA
8
WDR36, UTP18, NOB1, RPL35, RPL39, UTP14A, TEX10, C1D

processing

GO: 0045070~positive
3
DDX3X, PPID, CCL5

regulation of viral

genome replication

GO: 0000245~spliceosomal
3
GCFC2, PRPF6, SNRPG

complex assembly

mRNA transport
5
HNRNPAIL2, SRSF1, NUP62, EIF5AL1, THOC1

GO: 0005761~mitochondrial
3
MRPL13, MRPL28, MRPL48

ribosome

GO: 0014823~response
4
DNMT1, PRKDC, CCL5, SOD2

to activity

IPR015943: WD40/
10
COPB2, WDR36, WDR73, UTP18, RAE1, CDC40, AAMP, WDR4, RBBP7,

YVTN repeat-like-

PWP1

containing domain

GO: 0051879~Hsp90
3
CSNK2A1, NUP62, PPID

protein binding

GO: 0046966~thyroid
3
TAF11, NUP62, TRIP12

hormone receptor binding

GO: 0030687~preribosome,
3
AAMP, FTSJ3, TEX10

large subunit

precursor

IPR024704: Structural
2
SMC2, SMC3

maintenance of chromosomes

protein

IPR001509: NAD-dependent
2
TSTA3, UXS1

epimerase/dehydratase

GO: 0042719~mitochondrial
2
TIMM9, TIMM10

intermembrane space protein

transporter complex

GO: 0031313~extrinsic
2
USP8, SNX10

component of endosome

membrane

GO: 0047485~protein
5
TAF11, CSNK2A1, SMARCE1, BANF1, EXOC2

N-terminus binding

GO: 0006397~mRNA processing
7
HNRNPAIL2, SRSF1, CIR1, DHX15, RBMXL1, PTBP3, SREK1IP1

GO: 0033116~endoplasmic
4
TMED10, RAB1B, LMAN2, ERGIC3

reticulum-Golgi intermediate

compartment membrane

GO: 0048471~perinuclear
16
STX6, BCL10, FKBP4, LMNA, NDFIP2, ARF5, TPD52L2, MAF1, ITPR3,

region of cytoplasm

ARF3, MTPN, STX16, APEX1, USP33, TRAF4, DNM2

GO: 0051881~regulation of
3
PYCR1, BCO2, SOD2

mitochondrial

membrane potential

SM01343: SM01343
2
SMG1, PRKDC

GO: 0004197~cysteine-type
4
CASP3, USP8, USP10, USP33

endopeptidase activity

GO: 0002192~IRES-dependent
2
DENR, MCTS1

translational initiation

GO: 0071569~protein ufmylation
2
UFM1, UFC1

GO: 1990592~protein K69-linked
2
UFM1, UFC1

ufmylation

GO: 0051169~nuclear transport
2
NUP62, BANF1

GO: 0042531~positive
2
HCLS1, CCL5

regulation of tyrosine

phosphorylation of

STAT protein

GO: 0045039~protein
2
TIMM9, TIMM10

import into

mitochondrial inner

membrane

GO: 0008283~cell
11
SRRT, KDMIA, USP8, GNAI2, DTYMK, CKS2, PRKDC, UBE2V2, RBBP7,

proliferation

UBE2L3, TFDP1

GO: 0000209~protein
7
PSMB4, PSMD14, PSMB7, PSMC4, UBE2V2, UBE2L3, TRIP12

polyubiquitination

GO: 0061631~ubiquitin
3
UBE2N, UBE2V2, UBE2L3

conjugating

enzyme activity

GO: 0008135~translation
3
EIF1, MTIF3, EIF4E2

factor activity,

RNA binding

h_tnfr1Pathway: TN
3
CASP3, LMNA, PRKDC

FR1 Signaling Pathway

Endoplasmic
22
KDELR2, SEC11A, ERP29, ATP11B, DNAJB14, CNPY3, ALG5, MESDC2,

reticulum

LMAN2, ITPR3, ERGIC3, HYOU1, EI24, ELOVL5, EIF5AL1, TMEM170A,

TMED10, SPCS1, HSPA13, APEX1, ALG13, SSR2

IPR002909: Cell
3
NFAT5, NFKB2, EXOC2

surface receptor IPT/TIG

GO: 0016020~membrane
43
GNAI2, CAPZA2, RPL35, DNAJB14, PRKDC, CTPS1, STOML2, ALG5,

LMAN2, CNOT7, PTRH2, NUFIP2, PRIM1, ELOVL5, STX16, EIF3F, YRDC,

STK38L, EXOC2, PRPF40A, DDX39A, HPCAL1, FIBP, HCLSI, ERP29,

AARS, ATP11B, WNK1, CCDC47, KRT10, ACLY, ITPR3, MCM4, RBMX,

MCM5, PRPF6, ERGIC3, ADRMI, HYOU1, EI24, PSMC4, EIF2S1, ATP5C1

GO: 0002479~antigen
4
PSMB4, PSMD14, PSMB7, PSMC4

processing and

presentation of

exogenous peptide

antigen via MHC

class I, TAP-dependent

domain: FATC
2
SMG1, PRKDC

domain: FAT
2
SMG1, PRKDC

short sequence
2
TIMM9, TIMM10

motif: Twin CX3C motif

IPR027417: P-loop
20
DDX39A, GNAI2, DTYMK, AK2, RABIB, CTPS1, ARL16, ARF5, SMC2,

containing nucleoside

MCM4, SMC3, MCM5, MFN2, ATAD3B, DDX3X, PSMC4, ARF3, DHX15,

triphosphate hydrolase

CHD3, DNM2

GO: 0000082~G1/S
5
PRIM1, CUL4A, CRLF3, MCM4, MCM5

transition of mitotic

cell cycle

IPR024156: Small
3
ARF3, ARL16, ARF5

GTPase superfamily,

ARF type

GO: 0005762~mitochondrial
3
MRPL22, MRPL13, MRPL28

large

ribosomal subunit

Apoptosis
13
BCL10, FOXO1, PTRH2, NOC2L, MFN2, EI24, CASP3, CSNK2A1, DDX3X,

PPID, TRAF4, CID, THOC1

GO: 0043488~regulation
5
PSMB4, PSMD14, PSMB7, PSMC4, APEX1

of mRNA stability

IPR004217: Tim10/
2
TIMM9, TIMM10

DDP family zinc finger

IPR003152: PIK-
2
SMG1, PRKDC

related kinase,

FATC

IPR014009: PIK-
2
SMG1, PRKDC

related kinase

IPR018525: Mini-chromosome
2
MCM4, MCM5

maintenance,

conserved site

hsa05016: Huntington's
8
NDUFS6, NDUFA2, CASP3, NDUFB6, POLR2K, RCOR1, ATP5C1, SOD2

disease

lipid moiety-binding
5
HPCAL1, GNAI2, ARF3, PPP3R1, ARF5

region: N-myristoyl

glycine

GO: 0004003~ATP-
3
DDX3X, MCM4, CHD3

dependent DNA

helicase activity

h_fasPathway: FAS
3
CASP3, LMNA, PRKDC

signaling pathway (CD95)

GO: 0051573~negative
2
KDM1A, DNMT1

regulation of

histone H3-K9

methylation

GO: 0000395~mRNA
2
SRSF1, PRPF39

5′-splice site

recognition

GO: 0019076~viral
2
IST1, PPID

release from host cell

GO: 0046939~nucleotide
2
DTYMK, AK2

phosphorylation

GO: 0061133~
2
ADRM1, PSMD14

endopeptidase activator

activity

GO: 0007032~endosome
3
STX6, USP8, SNX10

organization

GO: 0070911~global
3
UBE2N, CUL4A, UBE2V2

genome nucleotide-

excision repair

IPR006689: Small
3
ARF3, ARL16, ARF5

GTPase superfamily,

ARF/SAR type

Magnesium
13
GNAI2, FDPS, ATP11B, TKT, ACLY, HPRT1, CNOT7, LAP3, PPMIK, RFK,

ENTPD4, APEX1, STK38L

repeat: HAT 7
2
PRPF39, PRPF6

region of
2
SMC2, SMC3

interest: Flexible hinge

PIRSF005719: structural
2
SMC2, SMC3

maintenance of

chromosomes protein

GO:0042147~retrograde
4
STX6, VPS29, STX16, VPS26B

transport,

endosome to Golgi

TABLE 3

HIV- low cutoff

Category
Count
Genes

Enrichment Score:

8.518413481739762

Zinc-finger
282
UTRN, RP9, RNF216, RORA, ZNF638, ZNRF1, BRPF1, CUL9, ZFP90,

ZNF106, ZNF394, ZNF101, ZNF43, ESCO1, POLK, RNF220, ZC3HC1, PAN3,

ZNF44, ROCK1, ZNF644, RXRB, ROCK2, ZHX1, VPS41, UBR2, OPTN,

BRAP, ZNF37A, UHRF2, UBR7, PIAS4, PARP12, MTF2, MLLT10, TRMT13,

ACAP1, ACAP2, PRDM2, AMFR, PIAS1, ZNHIT3, ZNF131, ZNF511, ASAP1,

MYO9B, RFFL, DIDO1, NR1H2, TCF20, ARIH2, RCHY1, PLAGL2, ASXL2,

IKZF5, DNMT3A, ESRRA, ZNF529, IKZF2, ZC3H18, KLF13, ZNF121, KLF10,

CREBBP, RYBP, ZBTB40, CBLB, RNF4, IRF2BPL, JAZF1, HGS, KAT6B,

RERE, TAFIB, ZNF292, ZNF534, ZMAT5, ZNF675, HELZ, ZEB1, ZBTB38,

SMAP1, MBTD1, ASH2L, ZNF148, NSMCE1, NSMCE2, USP16, ZNF493,

ZFP36, ZCCHC10, BRF1, ZC3H7A, BRF2, POGZ, ZC3H7B, APTX, GTF2H3,

HERC2, MBD1, GTF2B, PJA2, ASHIL, ZNF277, USP22, ZNF746, ZNF740,

REV3L, ZNF276, ZNF275, ZNF274, USP3, ZBTB10, ZBTB11, WRNIP1, USP5,

PML, TRIM14, EEA1, CBLL1, ZNF780B, ZNF780A, POLR2B, MYCBP2,

ZFP36L2, DGKE, MORC3, GATAD2A, ZSCAN25, THAP1, THAP2, MLLT6,

BAZ2B, ZNF268, BAZ2A, RASA2, RBM22, BRD1, ZNF28, TRIM27, TRIM26,

PPP1R10, PHF10, DGKH, TRIM25, SF3A2, ATMIN, TRIM22, ZNF664,

ZNF672, PLEKHF2, PHF14, YAF2, ARAF, WHSCIL1, MEX3C, DGKZ,

ZBTB2, ZNF764, ZNF766, BARD1, MKRNI, ZNF583, ZC3HAVI, GATA3,

RBCK1, RNF149, RBM10, RNF146, PHRF1, MTA2, NEIL2, ZNF814, ZNF7,

TRERF1, TRIM38, EP300, TRIM33, KDM2A, MIB2, NBR1, RNF139, RNF138,

SLU7, PYGO2, AKAP8, ZNF587, FBXO11, ZNF586, ZFAND6, TRAF2,

ARFGAP2, ZFAND5, ZNF430, AGFG2, ZFAND1, ZNF330, CXXC1, RNF166,

TRIM69, RNF168, RNF10, RNF167, RUNX1, TRAF5, TRAF3, ZMYM2,

TRIP4, VAV3, ZMYM4, ZMYM5, NR4A1, KAT5, FOXP3, VAV1, MSL2,

PHF3, PDZD8, PHF1, HIVEP2, HIVEP1, CTCF, ZKSCAN1, CBFA2T2, ZZEF1,

TRIM4, PCGF5, PEX2, RSPRY1, ZNF721, RANBP2, ZCCHC6, KDM5B,

KDM5C, ZCCHC7, NFX1, INO80B, EGR1, ZCCHC3, ZFX, PRKCI, PRKCH,

IRF2BP2, PRKCD, PRKCB, XPA, BPTF, ZFAND2A, ZFAND2B, CPSF4,

JMJDIC, MDM4, PRKD3, DPF2, ING4, ING3, ING2, KMT2A, XIAP, KMT2C,

ZNF800, EGLN1, RNF125, RPA1, RNF126, MAP3K1, XAF1, ZC3H12D,

DUS3L, L3MBTL2, CBL, RAF1, TAB3, ZBED2, RNF115, RPAP2, SP1,

ZBED5, KDM4C, ARAP2, RNF113A, RNF111

Zinc
339
UTRN, RP9, RNF216, RORA, ZNF638, ZNRF1, BRPF1, CUL9, ZFP90, ERAPI,

ZNF106, ZNF394, ZNF101, ZNF43, ESCO1, POLK, RNF220, PAN3, ZC3HC1,

ZNF44, ROCK1, ZNF644, RXRB, ROCK2, ZHX1, VPS41, UBR2, OPTN,

BRAP, ZNF37A, UHRF2, UBR7, PIAS4, PARP12, MTF2, MLLT10, TRMT13,

ACAP1, ACAP2, PRDM2, PIAS1, AMFR, ZNHIT3, MOB4, ZNF131, ZNF511,

ASAP1, UBA5, MYO9B, DUSP12, RFFL, DIDO1, NR1H2, TCF20, ARIH2,

RCHY1, PLAGL2, IKZF5, ASXL2, DNMT3A, ESRRA, ZNF529, IKZF2,

ZC3H18, KLF13, ZNF121, KLF10, CREBBP, RYBP, ZBTB40, SMAD3,

CSRP1, CBLB, RNF4, LASP1, IRF2BPL, JAZF1, HGS, KAT6B, RERE, TAFIB,

SPG7, LIMA1, ZNF292, ZNF534, FAM96A, ZMAT5, ZNF675, HELZ, ZEB1,

ZBTB38, LNPEP, SMAP1, MBTD1, ASH2L, ZNF148, NSMCE1, NSMCE2,

USP16, ZNF493, ZFP36, ZCCHC10, BRF1, POGZ, BRF2, ZC3H7A, ZC3H7B,

POLRIA, GTF2H3, APTX, HERC2, GTF2B, MBD1, RAD50, PJA2, ASHIL,

ZNF277, USP22, ZNF746, ZNF740, REV3L, ZNF276, ZNF275, LIMS1,

ZNF274, USP3, ZBTB10, YPEL5, ZBTB11, WRNIP1, USP5, YPEL3, USP4,

MKNK2, PML, TRIM14, EEA1, CBLL1, QTRT1, ZNF780B, ZNF780A,

POLR2B, MYCBP2, ZFP36L2, LPXN, DGKE, MORC3, PITRMI, GATAD2A,

PPP3CB, ZSCAN25, THAP1, THAP2, MLLT6, BAZ2B, ZNF268, BAZ2A,

RASA2, RBM22, BRD1, ZNF28, TRIM27, TRIM26, PHF10, MSRB1, PPPIR10,

DGKH, TRIM25, SF3A2, ATMIN, TRIM22, MTIX, ZNF664, DNPEP, ZNF672,

PLEKHF2, PHF14, YAF2, ARAF, WHSCIL1, MEX3C, DGKZ, NLN, ZBTB2,

ZNF764, ZNF766, BARD1, MKRN1, ZNF583, ZC3HAVI, IDE, APOBEC3G,

APOBEC3C, APOBEC3D, GATA3, RBCK1, RNF149, RBM10, RNF146,

PHRF1, PDXK, MTA2, NEIL2, ZNF814, ZNF7, TRERF1, TIMM8A, TRIM38,

EP300, TRIM33, KDM2A, MIB2, NBR1, RNF139, RNF138, SLU7, PYGO2,

AKAP8, ZNF587, FBXO11, ZNF586, ZFAND6, TRAF2, ARFGAP2, ZFAND5,

ZNF430, ELAC2, AGFG2, ZFAND1, ZNF330, CXXC1, RNF166, TRIM69,

STAMBPL1, SLC30A5, RNF168, RNF10, RNF167, RUNX1, TRAF5, TRAF3,

SETDB1, ZMYM2, TRIP4, VAV3, EHMT1, RABIF, ZMYM4, ZMYM5,

NR4A1, KAT5, FOXP3, VAVI, MSL2, PDZD8, PHF3, PHF1, MTR, HIVEP2,

HIVEP1, UTY, CTCF, ZKSCAN1, CBFA2T2, ZZEF1, TRIM4, PCGF5, PEX2,

RSPRY1, MOB3A, ZYX, ZNF721, RANBP2, ZCCHC6, KDM5B, KDM5C,

ZCCHC7, NFX1, INO80B, EGR1, ZCCHC3, ZFX, PRKCI, PRKCH, IRF2BP2,

PRKCD, PRKCB, HAGH, XPA, BPTF, ZFAND2A, ZFAND2B, MDM4, CPSF4,

JMJDIC, CPSF3, PRKD3, ABLIM1, DPF2, ING4, ING3, MOB1B, ING2,

KMT2A, XIAP, KMT2C, MGMT, ZNF800, EGLN1, NGLY1, RNF125, RPA1,

RNF126, MAP3K1, SLC39A6, CCS, XAF1, SLC39A3, ZC3H12D, DUS3L,

STAMBP, DCTD, L3MBTL2, CBL, SAMHD1, RAF1, SIRT6, SIRT7, TAB3,

SIRT2, ZBED2, RNF115, RPAP2, SP1, ZBED5, KDM4C, ARAP2, RNF113A,

RNF111

GO:0008270~zinc
202
UTRN, ZNF638, RORA, ZNRF1, BRPF1, CUL9, ERAPI, ZC3HC1, RNF220,

ion binding

RXRB, UBR2, VPS41, BRAP, UHRF2, PIAS4, UBR7, MTF2, MLLT10,

PRDM2, AMFR, PIAS1, DUSP12, OAS1, MYO9B, OAS2, RFFL, DIDO1,

NR1H2, TCF20, ARIH2, RCHY1, ESRRA, CREBBP, RYBP, SMAD3, CSRP1,

CBLB, RNF4, LASP1, KAT6B, RERE, LIMA1, SPG7, ZMAT5, ZNF675, ZEB1,

PTER, LNPEP, MBTD1, NSMCE1, NSMCE2, USP16, ZCCHC10, BRF1,

ZDHHC3, BRF2, ZDHHC8, POLRIA, HERC2, MBD1, GTF2B, TTF2, PJA2,

CHMP1A, ZDHHC16, ASHIL, ZDHHC12, USP22, ZNF276, LIMS1, USP3,

USP5, TRIM14, PML, EEA1, CBLL1, MYCBP2, LPXN, MORC3, PITRMI,

GATAD2A, THAP1, BAZ2B, MLLT6, BAZ2A, BRD1, TRIM27, TRIM26,

MSRB1, PHF10, TRIM25, SF3A2, TRIM22, MTIX, DNPEP, PHF14, YAF2,

WHSCIL1, MEX3C, BARD1, MKRN1, CNDP2, IDE, APOBEC3G,

APOBEC3C, APOBEC3D, GATA3, RBCK1, RNF149, RBM10, RNF146,

PHRF1, PDXK, MTA2, NEIL2, TRIM38, EP300, KDM2A, TRIM33, MIB2,

NBR1, RNF139, PYGO2, SLU7, RNF138, AKAP8, FBXO11, TRAFI, ZFAND6,

TRAF2, ZFAND5, ZFAND1, ZNF330, CXXC1, RNF166, TRIM69, SLC30A5,

RNF10, RNF168, RNF167, TRAF5, TRAF3, SETDB1, ZMYM2, EHMTI,

TRIP4, ZMYM4, RABIF, ZMYM5, NR4A1, MSL2, PHF3, PHF1, MTR,

CRYZL1, UQCRC1, CTCF, ZZEF1, TRIM4, PCGF5, RSPRY1, PEX2,

RANBP2, ZYX, KDM5B, ZCCHC6, ZCCHC7, KDM5C, NFX1, EGR1,

ZCCHC3, PRKCB, BPTF, ZFAND2A, ZFAND2B, COMMD3, CPSF4, MDM4,

DPF2, ABLIMI, ING4, ING3, ING2, XIAP, KMT2A, KMT2C, RNF125,

RNF126, MAP3K1, CCS, XAF1, DCTD, L3MBTL2, CBL, SAMHD1, SIRT6,

SIRT2, TAB3, RNF115, KDM4C, RNF113A, RNF111

Metal-binding
467
RP9, ZNF638, RORA, OGDH, CIAPIN1, BRPF1, PGP, CUL9, ZNF106,

ZNF394, MAP2K7, ZNF101, ZNF43, ZNF44, ROCK1, ZNF644, RXRB,

ROCK2, ZHX1, VPS41, BRAP, MARK2, ZNF37A, NME3, ZNHIT3, MOB4,

ZNF131, ZNF511, UBA5, DUSP12, DIDO1, ARIH2, RCHY1, ASXL2,

DNMT3A, MGAT4A, ESRRA, ZNF529, ZC3H18, KLF13, ZNF121, KLF10,

ATP11A, HSPB11, LASP1, HGS, RERE, TAFIB, LIMA1, ZNF292, ZNF534,

ZNF675, LATS1, LNPEP, SMAP1, ZNF148, USP16, ZNF493, BRF1, ZC3H7A,

BRF2, ZC3H7B, GTF2H3, PAPD5, PJA2, ZNF277, CHSY1, ZNF746, USP22,

ZNF740, ZNF276, ZNF275, ZNF274, REPS1, WRNIP1, MKNK2, PML,

TRIM14, EEA1, ERI3, CBLL1, QTRT1, ZNF780B, HSCB, ZNF780A,

MYCBP2, SNRK, DGKE, PITRM1, PPP2CB, PPP3CB, ILVBL, ZSCAN25,

ZNF268, CIGALT1, RASA2, BRD1, MAT2A, ZNF28, TRIM27, TRIM26,

PPP1R10, PHF10, DGKH, TRIM25, SF3A2, PCK2, TRIM22, MT1X, ZNF664,

RPS6KA3, ZNF672, PLEKHF2, PHF14, SDHC, ARAF, MCFD2, WHSCIL1,

DGKZ, ZBTB2, ZNF764, ZNF766, BARD1, GNA13, ZNF583, CNOT8,

NT5C3A, ATOXI, CNDP2, IDE, IDH3G, PDE4B, CTDSP1, ENOPH1, RNF149,

SARIB, RNF146, PHRF1, NUDTI, PDXK, NUDT4, ACTN4, MTA2, NUDT5,

NEIL2, STIM1, PDE4D, ZNF7, TATDN3, EP300, KDM2A, MIB2, RNF139,

RNF138, ZNF587, FBXO11, ZNF586, ARFGAP2, TRAF2, ZNF430, ELAC2,

ME2, ZNF330, CXXC1, RNF166, RNF168, LIAS, RNF167, TRAF5, SDF4,

TRAF3, B4GALT3, VAV3, TRIP4, EHMTI, SYT11, IREB2, NR4A1, HDDC3,

VAV1, FURIN, PDZD8, PDE7A, NDUFV2, HIVEP2, HIVEP1, ABL2, DICER1,

CTCF, ZKSCAN1, TRIM4, PEX2, CDK5RAP1, KDM5B, ZCCHC6, NDUFS1,

KDM5C, ZCCHC7, NFX1, INO80B, ZCCHC3, ZFX, IRF2BP2, CDK2, ARL3,

HAGH, ZFAND2A, ZFAND2B, CPSF4, JMJDIC, CPSF3, ABLIM1, DPF2,

GALNT2, KMT2A, ETHE1, KMT2C, PPMIA, EGLN1, NGLY1, RNF125,

RNF126, CCS, XAF1, EHD1, EHD4, ALKBH7, CBL, ANXA1, SAMHD1,

RAF1, TAB3, ADI1, ZBED2, RNF115, ZBED5, KDM4C, JAK2, ALKBH5,

RNF113A, RNF111, RCN2, S100A4, ADCY7, UTRN, RNASEH1, RNF216,

ZNRF1, ATP2B4, ZFP90, ERAPI, YDJC, ESCO1, POLK, RNF220, ZC3HC1,

PAN3, CAPNS1, TRABD2A, PIMI, POLB, UBR2, OPTN, MGAT1, UHRF2,

UBR7, PIAS4, PARP12, ATP2C1, MTF2, TRMT13, ACAP1, MLLT10, PGM1,

ACAP2, FBXL5, PRDM2, AMFR, PIAS1, ASAP1, OASI, MYO9B, RFFL,

OAS2, PPAT, NR1H2, TCF20, KRAS, IDH2, PLAGL2, IKZF5, IKZF2,

CREBBP, S100A11, RYBP, ZBTB40, SMAD3, OXSR1, CSRP1, CBLB,

ATP13A1, RNF4, IRF2BPL, DCP2, JAZF1, KAT6B, SPG7, FAM96A, ZMAT5,

HELZ, ZEB1, ZBTB38, EFHD2, PTER, MBTD1, ASH2L, NSMCE1, NSMCE2,

TOP2B, NT5C, ZFP36, ZCCHC10, POGZ, POLRIA, APTX, CYB5A, HERC2,

MBD1, GTF2B, RAD50, ASHIL, MAP3K13, REV3L, LIMS1, USP3, ZBTB10,

YPEL5, ZBTB11, USP5, USP4, YPEL3, CETN2, POLR2B, ZFP36L2, LPXN,

GNPTAB, MORC3, TYW1, GATAD2A, AGO2, THAP1, PRKAA1, THAP2,

NENF, MLLT6, BAZ2B, BAZ2A, RBM22, MSRB1, ATMIN, DNPEP, JMJD6,

YAF2, MEX3C, NLN, MKRN1, ZC3HAVI, APOBEC3G, APOBEC3C,

APOBEC3D, GATA3, RBCK1, RBM10, ZNF814, CHP1, PPP1CB, TRERF1,

TIMM8A, TRIM38, TRIM33, NBR1, SLU7, PYGO2, AKAP8, PRPS2, PRPS1,

ZFAND6, ZFAND5, AGFG2, ITGAE, AGMAT, ZFAND1, ITGB1, PEF1,

TRIM69, CNOT6L, STAMBPL1, RNF10, RUNX1, SETDB1, ZMYM2, RABIF,

ZMYM4, ZMYM5, KAT5, FOXP3, MSL2, PHF3, PHF1, MTR, RHOT1,

RHOT2, UTY, FOXK2, UQCRFSI, ZZEF1, CBFA2T2, GSS, PCGF5, TPP1,

RSPRY1, MOB3A, DBR1, ATP8B2, ZYX, ZNF721, RANBP2, EGR1, PFKL,

PRKCI, PRKCH, PRKCD, PRKCB, NUCB1, XPA, BPTF, NUCB2, COMMD1,

MDM4, PRKD3, ING4, GLRX5, MOBIB, ING3, ING2, XIAP, MGMT,

ZNF800, RSAD2, GLRX2, RPA1, MTHFS, MAP3K3, MAP3K1, ZC3H12D,

SCO2, DUS3L, STAMBP, DCTD, L3MBTL2, SIRT6, SIRT7, SIRT2, RPAP2,

SP1, TDP2, ARAP2

Enrichment Score:

6.51824669041824

IPR019787: Zinc
31
DPF2, ING4, ING3, ING2, KMT2A, KMT2C, DIDO1, CXXCI, BRPF1, BAZ2B,

finger, PHD-finger

MLLT6, KDM5B, BAZ2A, KDM5C, NFX1, BRD1, PHRF1, PHF10, PHF3,

UHRF2, KDM2A, PHF14, BPTF, TRIM33, PHF1, MTF2, MLLT10, WHSCILI,

ASHIL, PYGO2, KAT6B

SM00249: PHD
32
DPF2, ING4, ING3, ING2, KMT2A, KMT2C, DIDO1, CXXC1, TCF20, BRPF1,

BAZ2B, MLLT6, KDM5B, BAZ2A, KDM5C, BRD1, PHRF1, PHF10, PHF3,

UHRF2, KDM2A, BPTF, TRIM33, PHF14, PHF1, MTF2, MLLT10, WHSCIL1,

ASHIL, KDM4C, PYGO2, KAT6B

IPR001965: Zinc
32
DPF2, ING4, ING3, ING2, KMT2A, KMT2C, DIDO1, CXXCI, TCF20, BRPF1,

finger, PHD-type

BAZ2B, MLLT6, KDM5B, BAZ2A, KDM5C, BRD1, PHRF1, PHF10, PHF3,

UHRF2, KDM2A, BPTF, TRIM33, PHF14, PHF1, MTF2, MLLT10, WHSCIL1,

ASHIL, KDM4C, PYGO2, KAT6B

IPR011011: Zinc
38
DPF2, ING4, ING3, ING2, KMT2A, KMT2C, EEA1, RFFL, DIDO1, CXXC1,

finger, FYVE/PHD-

BRPF1, BAZ2B, MLLT6, KDM5B, BAZ2A, KDM5C, BRD1, PHRF1, CREBBP,

type

PHF10, PHF3, PLEKHF2, UHRF2, KDM2A, UBR7, BPTF, TRIM33, PHF14,

PHF1, MTF2, MLLT10, WHSCIL1, ASHIL, KDM4C, HGS, PYGO2, SYTL3,

KAT6B

IPR019786: Zinc
23
ING4, BRD1, PHRF1, ING3, ING2, DIDO1, CXXC1, BRPF1, PHF3, PHF14,

finger, PHD-type,

KDM2A, BPTF, PHF1, TRIM33, MTF2, MLLT10, WHSCIL1, ASHIL, PYGO2,

conserved site

MLLT6, KDM5B, KDM5C, NFX1

zinc finger
14
DPF2, PHF14, BPTF, KMT2A, PHF1, MTF2, MLLT10, KMT2C, WHSCIL1,

region: PHD-type 2

KDM4C, KAT6B, MLLT6, KDM5B, KDM5C

zinc finger
14
DPF2, PHF14, BPTF, KMT2A, PHF1, MTF2, MLLT10, KMT2C, WHSCIL1,

region: PHD-type 1

KDM4C, KAT6B, MLLT6, KDM5B, KDM5C

zinc finger
16
BRD1, ING4, PHRF1, ING3, ING2, DIDO1, CXXC1, BRPF1, PHF3, UHRF2,

region: PHD-type

KDM2A, TRIM33, ASHIL, PYGO2, BAZ2B, BAZ2A

Enrichment Score:

6.341978088960009

Ubl conjugation
142
MKRN1, RNF216, SAE1, ZNRF1, CUL3, CUL2, CUL9, KLHL9, FBXO25,

pathway

RBCK1, RNF149, RNF146, ZC3HC1, RNF220, SOCS3, ANAPC4, SOCS1,

UBE2J1, UBR2, UBE2J2, BRAP, TRIM38, UHRF2, KDM2A, UBR7, PIAS4,

TRIM33, MIB2, FBXL5, RNF139, RNF138, PIAS1, AMFR, FBXO11, TRAF2,

ZFAND5, UBA5, ANAPC10, KEAP1, RFFL, COMMD9, UBACI, COMMD10,

UBE2D4, FBXW7, ARIH2, KRAS, FBXW5, TRIM69, FBX06, STAMBPL1,

FBXW2, HECTD4, RNF168, RCHY1, RNF167, TRAF3, HECTD1, SPOP,

PELI1, KIAA1586, CDC23, MALTI, CDC27, ATE1, MSL2, CBLB, RNF4,

UBA3, SMURF2, FBXO34, UBE2E1, UBE2G1, BAP1, TRIM4, NSMCE2,

RANBP2, USP16, FBXL15, USP15, DCAF16, DCAF15, NFX1, VCPIP1,

TBL1XR1, UBE2A, HERC6, HERC5, HERC2, PJA2, WDR48, UFL1, ATG4B,

MED8, DDB2, COMMD3, UBE2W, COMMD1, UCHL3, CAND1, USP22,

USP24, OTUD5, UBE2Z, USP3, XIAP, USP5, USP4, CBLL1, FEMIB, STUB1,

FEMIA, UBE2R2, MYCBP2, PRPF19, RNF125, RNF126, USP36, USP34,

FBXW11, STAMBP, WDTC1, USP40, UBE4A, VHL, LRRC41, CBL, TRIM27,

BIRC6, TRIM25, TRIM22, NAE1, WSB1, RNF115, USP47, MEX3C,

TRPC4AP, CUL4B, TBLIX, USP42, RNF111, BARD1

IPR013083:Zinc
96
MKRN1, ZNRF1, TRIM4, PCGF5, BRPF1, PEX2, RSPRY1, NSMCE2, RBCK1,

finger,

RNF149, USP16, KDM5B, KDM5C, RNF146, PHRF1, RNF220, VPS41, BRAP,

RING/FYVE/PHD-

PJA2, TRIM38, UHRF2, KDM2A, PIAS4, TRIM33, BPTF, UBR7, MTF2, MIB2,

type

MLLT10, ASHIL, COMMD3, RNF139, PYGO2, RNF138, MDM4, USP22,

AMFR, ZNHIT3, DPF2, TRAF2, ING4, ING3, ING2, KMT2A, USP3, USP5,

KMT2C, PML, EEA1, RFFL, CBLL1, STUB1, DIDO1, CXXC1, MYCBP2,

RNF125, PRPF19, RNF126, ARIH2, RNF166, TRIM69, MAP3K1, RNF10,

RNF168, RNF167, RCHY1, MLLT6, BAZ2B, TRAF5, BAZ2A, TRAF3, BRD1,

UBE4A, CBL, CREBBP, TRIM27, TRIM26, PHF10, TRIM25, TRIM22, CBLB,

PHF3, RNF115, PLEKHF2, PHF1, PHF14, RNF4, WHSCIL1, MEX3C, HGS,

KDM4C, SYTL3, KAT6B, RNF113A, BARD1, RNF111

Ligase
76
MKRN1, SAE1, RNF216, ZNRF1, GSS, TRIM4, NSMCE1, RBCK1, NSMCE2,

RNF149, RANBP2, RNF146, NFX1, RNF220, HERC6, HERC5, UBR2, HERC2,

GMPS, BRAP, UFL1, PJA2, TRIM38, GLUL, UHRF2, PIAS4, TRIM33, UBR7,

MIB2, FARSB, RNF139, RNF138, AMFR, YARS2, PIAS1, PCCB, TRAF2,

XIAP, FARS2, WARS2, RFFL, CBLL1, STUB1, MYCBP2, RNF125, PRPF19,

MTHFS, RNF126, ARIH2, TRIM69, HECTD4, RNF168, RNF167, RCHY1,

ACSL4, ACSL3, ACSL5, TRAF3, HECTD1, PELII, KIAA1586, UBE4A, CBL,

TRIM27, BIRC6, TRIM25, TRIM22, MSL2, CBLB, RNF115, RNF4, UBA3,

MEX3C, SMURF2, BARD1, RNF111

GO: 0016874~ligase
63
MKRN1, RNF216, ZNRF1, TRIM4, NSMCE1, RBCK1, NSMCE2, RNF149,

activity

RANBP2, RNF146, NFX1, RNF220, HERC6, HERC5, UBR2, HERC2, BRAP,

PJA2, UFL1, TRIM38, UHRF2, PIAS4, TRIM33, UBR7, MIB2, RNF139,

RNF138, AMFR, PIAS1, PCCB, TRAF2, XIAP, RFFL, CBLL1, STUB1,

MYCBP2, PRPF19, RNF125, RNF126, ARIH2, TRIM69, HECTD4, RNF168,

RNF167, RCHY1, ACSL3, TRAF3, HECTD1, PELII, KIAA1586, UBE4A, CBL,

TRIM27, BIRC6, TRIM22, MSL2, CBLB, RNF115, RNF4, MEX3C, SMURF2,

BARD1, RNF111

GO: 0004842~ubiquitin-
71
MKRN1, BACH2, UBE2G1, RNF216, ZNRF1, CUL3, NSMCE1, KLHL9,

protein

FBXO25, RBCK1, KLHL24, FBXL15, RNF146, UBE2A, RNF220, HERC6,

transferase activity

ANAPC4, HERC5, UBR2, HERC2, BRAP, PJA2, UHRF2, TRIM33, MIB2,

DDB2, RNF139, FBXL5, UBE2W, AMFR, FBXO11, TRAF2, XIAP, KEAP1,

CBLL1, FEMIB, STUB1, FEMIA, UBE2R2, PRPF19, UBE2D4, ARIH2,

FBXW7, KBTBD2, TRIM69, FBXO6, FBXW2, HECTD4, RNF10, RNF168,

RNF167, RCHY1, TRAF5, FBXW11, TRAF3, HECTD1, VHL, CBL, TRIM27,

CDC23, BIRC6, MALT1, TRIM25, TSPAN17, WSB1, CBLB, RNF115, RNF4,

SMURF2, UBE2E1, BARD1

GO: 0016567~protein
73
BACH2, SAE1, CUL3, TRIM4, NSMCE1, CUL9, KLHL9, FBXO25, KLHL24,

ubiquitination

RNF149, FBXL15, DCAF16, VCPIP1, DCAF15, ZC3HC1, RNF220, SOCS3,

SOCS1, UBE2J1, MED11, HERC2, TMEM189, BRAP, PJA2, UHRF2, TRIM33,

UBR7, MED17, MED8, FBXL5, RNF139, RNF138, CAND1, NFE2L2, MDM4,

MED1, FBXO11, XIAP, KEAPI, CBLLI, UBACI, FEMIB, STUB1, FEMIA,

MYCBP2, UBE2D4, ARIH2, FBXW7, KBTBD2, FBXW5, FBXW2, RNF168,

RCHY1, TRAF5, FBXW11, TRAF3, WDTC1, VHL, LRRC41, SPSB3, CBL,

BIRC6, MALT1, TSPAN17, TRIM22, WSB1, MED31, MSL2, RNF4,

TRPC4AP, UBE2E1, BARD1, RNF111

IPR001841: Zinc
58
MKRN1, ZNRF1, TRIM4, PCGF5, RSPRY1, PEX2, CUL9, NSMCE1, RBCK1,

finger, RING-type

RNF149, RNF146, NFX1, PHRF1, RNF220, VPS41, BRAP, PJA2, TRIM38,

UHRF2, TRIM33, MIB2, COMMD3, RNF139, RNF138, AMFR, MDM4,

TRAF2, XIAP, KMT2C, PML, RFFL, CBLL1, MYCBP2, RNF125, RNF126,

ARIH2, RNF166, TRIM69, MAP3K1, RNF168, RNF10, RCHY1, RNF167,

TRAF5, TRAF3, CBL, TRIM27, TRIM26, TRIM25, TRIM22, MSL2, CBLB,

RNF115, RNF4, MEX3C, RNF113A, RNF111, BARD1

SM00184: RING
48
MKRN1, TRAF2, XIAP, KMT2C, PML, RFFL, ZNRF1, MYCBP2, TRIM4,

RNF125, PCGF5, RNF126, ARIH2, RNF166, RSPRY1, PEX2, TRIM69,

RBCK1, RNF168, RNF10, RCHY1, RNF149, RNF167, TRAF5, RNF146, NFX1,

PHRF1, CBL, TRIM27, TRIM26, TRIM25, TRIM22, BRAP, PJA2, TRIM38,

CBLB, UHRF2, RNF115, TRIM33, RNF4, MIB2, COMMD3, MEX3C, RNF139,

RNF138, AMFR, RNF113A, RNF111

zinc finger
44
MKRN1, TRAF2, CHMP3, XIAP, KMT2C, PML, RFFL, CBLL1, TRIM4,

region: RING-type

RNF125, PCGF5, RNF126, RNF166, RSPRY1, PEX2, TRIM69, MAP3K1,

RBCK1, RNF168, RNF10, RCHY1, TRAF5, RNF146, TRAF3, RNF220, CBL,

TRIM27, TRIM26, TRIM25, TRIM22, BRAP, TRIM38, MSL2, CBLB, UHRF2,

RNF115, TRIM33, RNF4, MEX3C, RNF138, MDM4, AMFR, RNF113A,

BARD1

IPR017907: Zinc
30
MKRN1, TRAF2, PML, CBLL1, RNF125, TRIM4, PCGF5, ARIH2, RNF166,

finger, RING-type,

PEX2, TRIM69, CUL9, RBCK1, RNF10, TRAF5, RNF146, TRAF3, PHRF1,

conserved site

CBL, TRIM27, TRIM25, TRIM22, TRIM38, CBLB, UHRF2, TRIM33, RNF4,

COMMD3, BARD1, RNF113A

Enrichment Score:

5.35889838477318

GO: 0051607~defense
43
ABCF3, CD8A, IFITM1, ZC3HAVI, IFITM2, UNC93B1, PML, BNIP3, RSAD2,

response to virus

OAS1, APOBEC3G, OAS2, APOBEC3C, APOBEC3D, SERINC3, NLRC5,

BCL2, C19ORF66, IFNG, PYCARD, MX1, MX2, POLR3F, POLR3H, RELA,

FAM111A, EXOSC5, HERC5, SAMHD1, FADD, TRIM25, POLR3C, TRIM22,

POLR3E, IFNAR1, IFIT3, IFNAR2, PLSCR1, UNC13D, IFIT5, BNIP3L, IRF3,

GBP3

Antiviral defense
31
ABCF3, IFITM1, ZC3HAVI, IFITM2, UNC93B1, PML, RSAD2, OASI,

APOBEC3G, OAS2, APOBEC3C, APOBEC3D, SERINC3, C19ORF66, IFNG,

MX1, MX2, POLR3F, POLR3H, FAM111A, HERC5, SAMHD1, TRIM25,

POLR3C, TRIM22, POLR3E, IFIT3, PLSCR1, IFIT5, IRF3, GBP3

Innate immunity
50
ZC3HAVI, APOBEC3G, APOBEC3C, APOBEC3D, TRIM4, NLRC5,

ANKRD17, GATA3, MX1, MX2, IRAK1, LY96, HERC5, FADD, ECSIT, CD84,

TRIM38, CHID1, RIPK2, AKAP8, IFITM1, IFITM2, CSF1, PML, UNC93B1,

RSAD2, OASI, OAS2, SEC14L1, SERINC3, IRAK4, PSTPIP1, PYCARD, MR1,

TBKBP1, POLR3F, POLR3H, ANXA1, MSRB1, SAMHD1, TRIM25, SLAMF7,

POLR3C, POLR3E, SIRT2, IFIT3, CD55, IFIT5, JAK2, IRF3

Enrichment Score:

5.143098283847529

Cell cycle
120
ITGB3BP, CHMP3, MAU2, KNTC1, INO80, CASP8AP2, KLHL9, RALB,

VPS4A, TLK1, CDCA4, STAG1, ESCO1, ZC3HC1, ANAPC4, RINT1, PIMI,

HMG20B, PPP1CB, MAPK1, UHRF2, EP300, RCC2, MAPK6, PRCC, BIN3,

CDCA7L, PDCD6IP, ARL8B, MPLKIP, CACUL1, STK10, AHCTF1, ARF6,

CEP164, ANAPC10, CCNG1, CCNG2, NIPBL, PPP2R2D, SSSCA1, CINP,

WDR6, CDC23, PMF1, CDC27, ATM, CDKNIB, DMTF1, UBA3, CCNT2,

E2F3, E2F4, TSG101, CCNTI, LATS1, NDE1, NSMCE2, CDK10, USP16,

CDK13, ARL2, RBBP4, POGZ, CCNH, DYNLT3, PKN2, DYNLT1, PAPD5,

BANP, CDK7, PRKCD, RAD50, CDK2, MCM6, ARL3, GAK, SASS6,

CHMP1A, NSL1, CDK11B, MAPRE2, WASL, USP22, MAPRE1, PDCD2L,

SPAST, HAUS3, ING4, HAUS6, RABGAP1, ASUN, USP3, HAUS2, HAUS1,

CETN2, NUMA1, MAP10, TSPYL2, MDC1, RBICCI, NPAT, PAFAHIB1,

THAP1, FBXW11, TERF2, TERFI, CSNK1A1, BOD1, PDS5B, SMC5, BIRC6,

RGS14, SIRT2, NAE1, SMC4, RPS6KA3, MAPK13, CUL4B, C9ORF69

Cell division
73
ITGB3BP, CCNT2, CHMP3, MAU2, TSG101, CCNT1, KNTC1, INO80, LATS1,

NDE1, KLHL9, RALB, VPS4A, NSMCE2, CDK10, USP16, CDCA4, CDK13,

STAG1, ZC3HC1, POGZ, ANAPC4, PKN2, DYNLT3, DYNLT1, PAPD5,

CDK7, PPP1CB, CDK2, ARL3, CHMP1A, RCC2, NSL1, BIN3, CDK11B,

MAPRE2, CDCA7L, ARL8B, WASL, MAPRE1, PDCD6IP, SPAST, HAUS3,

HAUS6, ASUN, MPLKIP, HAUS2, HAUS1, CETN2, AHCTF1, ARF6,

ANAPC10, CEP164, CCNG1, CCNG2, NUMA1, MAP10, PAFAHIB1,

PPP2R2D, TERFI, CSNK1A1, SSSCA1, BOD1, PDS5B, CINP, SMC5, CDC23,

BIRC6, PMF1, CDC27, SIRT2, RGS14, SMC4

GO: 0051301~cell
66
ITGB3BP, CCNT2, MAU2, TSG101, CCNT1, KNTC1, INO80, LATS1, NDE1,

division

NSMCE2, VPS4A, CDK10, TUBAIA, USP16, CDCA4, TUBAIC, CDK13,

STAG1, ZC3HC1, POGZ, ANAPC4, PKN2, DYNLT3, PAPD5, DYNLT1,

CDK7, PPP1CB, CDK2, CHMP1A, RCC2, NSL1, CDK11B, MAPRE2,

CDCA7L, ARL8B, WASL, MAPRE1, HAUS3, HAUS6, ASUN, MPLKIP,

HAUS2, HAUS1, CETN2, ARF6, ANAPC10, CEP164, CCNG1, CCNG2,

NUMA1, MAP10, PPP2R2D, TERFI, CSNK1A1, SSSCA1, BOD1, PDS5B,

CINP, SMC5, CDC23, BIRC6, PMF1, CDC27, SIRT2, RGS14, SMC4

GO: 0007067~mitotic
49
ITGB3BP, HAUS3, HAUS6, ASUN, MPLKIP, HAUS2, HAUS1, KNTC1,

nuclear division

CETN2, ANAPC10, CEP164, CLTC, CCNG1, CCNG2, LATS1, OFD1,

NUMA1, FBXW5, KLHL9, NSMCE2, PAFAHIBI, USP16, PPP2R2D, STAGI,

TERFI, VCPIP1, CSNKIA1, SSSCA1, BOD1, ZC3HC1, TADA2A, ANAPC4,

SMC5, DYNLT3, CDC23, BIRC6, PAPD5, DYNLT1, PMF1, SIRT2, RGS14,

CDK2, RCC2, NSL1, CDK11B, MAPRE2, MAPRE1, WASL, AKAP8

Mitosis
46
ITGB3BP, HAUS3, HAUS6, ASUN, MPLKIP, MAU2, HAUS2, HAUS1,

KNTC1, INO80, CETN2, CEP164, ANAPC10, CCNG1, CCNG2, LATS1,

NUMA1, NDE1, KLHL9, NSMCE2, PAFAHIB1, USP16, PPP2R2D, STAGI,

TERF1, CSNK1A1, SSSCA1, BOD1, ZC3HC1, PDS5B, ANAPC4, SMC5,

DYNLT3, CDC23, BIRC6, PAPD5, DYNLT1, PMF1, SIRT2, CDK2, SMC4,

RCC2, NSL1, MAPRE2, MAPRE1, WASL

Enrichment Score:

5.023865225499397

DNA damage
68
RAD51C, INO80, NSMCE1, AEN, NSMCE2, TLK1, BRD4, INO80D, INO80C,

INO80B, POLK, UBE2A, NEIL2, FMR1, APTX, GTF2H3, CDK9, MBD4,

POLB, HERC2, CDK7, CDK2, RAD50, RAD1, XPA, NABP1, XPC, HIPK2,

DDB2, RNF138, UBE2W, PSME4, REV3L, USP3, WRNIP1, HUS1, MGMT,

CETN2, MUM1, CEP164, MAPKAPK2, STUB1, XAB2, PRPF19, RPA1,

CHDIL, MDC1, FBX06, RNF168, ACTL6A, ERCC3, MSH6, MSH2, TAOK1,

TP53BP1, CINP, SMC5, SMC6, ATMIN, UIMCI, ATM, MPG, PHF1, TDP2,

USP47, CUL4B, OGGI, BARD1

DNA repair
56
RAD51C, INO80, NSMCE1, NSMCE2, INO80D, INO80C, INO80B, POLK,

UBE2A, NEIL2, APTX, GTF2H3, CDK9, MBD4, POLB, HERC2, CDK7,

CDK2, RAD50, RAD1, XPA, NABP1, XPC, DDB2, UBE2W, RNF138, PSME4,

REV3L, MGMT, CETN2, MUM1, CEP164, STUB1, XAB2, RPA1, PRPF19,

CHDIL, MDC1, FBX06, RNF168, ACTL6A, ERCC3, MSH6, TAOK1, MSH2,

TP53BP1, CINP, SMC5, SMC6, UIMC1, MPG, TDP2, USP47, CUL4B, OGGI,

BARD1

GO: 0006281~DNA
49
RAD51C, USP3, MGMT, HUS1, INO80, MUM1, HSPAIA, CEP164, TRRAP,

repair

STUB1, RPA1, CHDIL, NSMCE1, FBX06, ACTL6A, ERCC3, INO80D,

INO80C, INO80B, POLK, MSH6, UBE2A, NUDTI, PDS5B, TAOK1, MSH2,

NEIL2, CINP, APTX, GTF2H3, CDK9, MBD4, POLB, ATM, RAD50, CDK2,

RAD1, XPA, RECQL, NABP1, XPC, CSNKID, BTG2, CSNKIE, DDB2,

UBE2W, PSME4, PARP4, OGGI

Enrichment Score:

4.995051000869093

Nucleotide-binding
267
RAD51C, DYNCILI2, ADCY7, ATP2B4, PSKHI, CLK2, CUL9, CLK4, ILK,

DHX34, VPS4A, TLK1, DDX10, MAP2K7, PAN3, TNIK, ROCK1, ROCK2,

PIM1, UBE2J1, UBE2J2, MARK2, MAPK1, GLUL, NME3, RAB18, MAPK6,

DHX29, CAMK4, ATP2C1, RFC2, MAPK8, ARL8B, CLCN3, PFKFB3, FARS2,

UBA5, WARS2, HSPAIA, OAS1, MYO9B, ARF6, OAS2, MTIF2, NAGK,

UHMK1, MOV10, KRAS, VRK3, RACI, ZAP70, NAT10, KIF3B, MOCS2,

TAOK1, MAP2K4, ATP11A, OXSR1, ATM, ATP13A1, UBA3, ARF4, RITI,

SPG7, ABCF3, RAB5B, RAB5C, FASTK, UBE2G1, GTPBP10, GNL3L, HELZ,

PMVK, LATS1, ATAD3A, LONP1, ARL5A, DYNCIH1, TOP2B, NT5C,

SRPK2, RAP2C, PIK3C2A, PI4KB, DGUOK, GMPS, SRPK1, RAD50, TTF2,

CBWD2, TRAP1, RIPK1, RRMI, RAB5A, FARSB, CDK11B, MAP3K14,

ARL4C, MAP3K13, ARL4A, WRNIP1, MKNK2, KTI12, SNRK, DGKE,

STK40, DDX19A, TYW1, RAB11B, DHX16, PRKAA1, CERK, ACSL4,

ACSL3, SPATA5, ACSL5, CSNK1A1, DNM3, MAT2A, PDK3, DGKH, PCK2,

NRAS, RPS6KA3, RAB30, CSNKID, CSNKIE, MAPK13, RAB35, GSK3B,

ARAF, DGKZ, GNA13, NT5C3A, IDE, PASK, HBSIL, INO80, DSTYK,

PI4K2B, NLRC5, PRKAR2A, IDH3G, DDX23, AAK1, ORC4, RALB,

PRKACB, SARIB, MX1, MX2, MATK, PDXK, CSNK1G2, EFTUD2, RIPK2,

CSNK1G3, YARS2, SMARCA2, PCCB, GBP3, PRPS2, PRPS1, GPN3, MVD,

STK10, MAPKAPK5, MAP4K1, MAPKAPK2, RRAGC, IRAK4, UBE2D4,

GFM2, FICD, GFM1, DDX42, NIN, RYK, MYO1G, ABCB7, RAB33A,

RAB33B, PSMC5, PSMC2, ULK3, DYRKIA, GTF2F2, DDX50, RHOT1,

RHOT2, ABL2, DDX51, UBE2E1, ATL3, PRKAG2, DICER1, HINT2, PPIP5K2,

SKIV2L2, SLFN5, PIP5K1A, GSS, SLK, CDK12, MKKS, ATP8B2, CDK10,

TUBA1A, RHOF, CHUK, TUBAIC, CDK13, AKT2, ARL2, IRAK1, UBE2A,

PFKL, PRKCI, PKN2, PRKCH, CDK9, CDK7, PRKCD, CDK2, ARL3, PRKCB,

GAK, MCM6, TOR2A, PANK4, RECQL, PANK2, HIPK1, HIPK2, UBE2W,

PRKD3, SPAST, NKIRAS2, BTAF1, PGS1, UBE2Z, DCK, UBE2R2, N4BP2,

MTHFS, CHD9, CHD7, CHDIL, MAP3K3, MAP3K1, UCK1, HSPA4, ERCC3,

EHD1, CHD6, EHD4, MSH6, GIMAP5, MSH2, SMC5, SMC6, RAF1, DRG1,

DRG2, SMC4, GIMAP1, JAK2

SM00220: S_TKc
74
PASK, DSTYK, LATS1, PSKHI, SLK, CLK2, AAKI, CLK4, CDK12, TLK1,

CDK10, PRKACB, MAP2K7, CHUK, CDK13, AKT2, SRPK2, IRAK1, TNIK,

ROCK1, CSNK1G2, ROCK2, PRKCI, PKN2, PIM1, PRKCH, CDK9, CDK7,

PRKCD, SRPK1, CDK2, MARK2, GAK, PRKCB, MAPK1, MAPK6, CAMK4,

HIPK1, RIPK1, HIPK2, RIPK2, CDK11B, MAPK8, CSNK1G3, MAP3K14,

MAP3K13, PRKD3, STK10, MAPKAPK5, MKNK2, MAP4K1, MAPKAPK2,

UHMK1, TRIB2, IRAK4, MAP3K3, VRK3, SNRK, STK40, MAP3K1,

PRKAA1, CSNK1A1, TAOK1, MAP2K4, RAF1, OXSR1, RPS6KA3, CSNKID,

CSNKIE, MAPK13, GSK3B, ARAF, ULK3, DYRKIA

ATP-binding
210
RAD51C, DYNCILI2, ADCY7, ATP2B4, PSKHI, CLK2, CUL9, CLK4, ILK,

DHX34, VPS4A, TLK1, DDX10, MAP2K7, PAN3, TNIK, ROCK1, ROCK2,

UBE2J1, PIM1, UBE2J2, MARK2, MAPK1, GLUL, NME3, MAPK6, DHX29,

CAMK4, RFC2, ATP2C1, MAPK8, CLCN3, PFKFB3, FARS2, UBA5, WARS2,

HSPA1A, OAS1, MYO9B, OAS2, NAGK, UHMK1, MOV10, KRAS, ZAP70,

NAT10, KIF3B, TAOK1, MAP2K4, ATP11A, OXSR1, ATM, ATP13A1, UBA3,

ABCF3, SPG7, FASTK, UBE2G1, HELZ, PMVK, LATS1, LONP1, ATAD3A,

DYNC1H1, TOP2B, SRPK2, PIK3C2A, DGUOK, PI4KB, GMPS, SRPK1,

RAD50, TTF2, CBWD2, TRAP1, RIPK1, RRMI, FARSB, CDK11B, MAP3K14,

MAP3K13, WRNIP1, MKNK2, SNRK, DGKE, STK40, KTI12, DDX19A,

DHX16, PRKAA1, CERK, ACSL4, ACSL3, SPATA5, ACSL5, CSNKIA1,

MAT2A, PDK3, DGKH, RPS6KA3, CSNKID, CSNKIE, MAPK13, GSK3B,

ARAF, DGKZ, PASK, IDE, DSTYK, INO80, PI4K2B, NLRC5, IDH3G, DDX23,

AAK1, ORC4, PRKACB, MATK, PDXK, CSNK1G2, RIPK2, CSNK1G3,

YARS2, PCCB, SMARCA2, PRPS2, PRPS1, MVD, STK10, MAPKAPK5,

MAP4K1, MAPKAPK2, IRAK4, UBE2D4, FICD, DDX42, RYK, MYO1G,

ABCB7, PSMC5, PSMC2, ULK3, DYRKIA, GTF2F2, DDX50, ABL2, DDX51,

UBE2E1, DICER1, PRKAG2, PPIP5K2, SKIV2L2, SLFN5, PIP5K1A, GSS,

SLK, CDK12, MKKS, ATP8B2, CDK10, CHUK, CDK13, AKT2, IRAK1,

UBE2A, PFKL, PRKCI, PKN2, PRKCH, CDK9, CDK7, PRKCD, CDK2,

PRKCB, GAK, MCM6, TOR2A, PANK4, RECQL, PANK2, HIPK1, HIPK2,

UBE2W, PRKD3, SPAST, BTAF1, PGS1, UBE2Z, DCK, UBE2R2, N4BP2,

CHD9, MTHFS, CHDIL, CHD7, MAP3K3, MAP3K1, UCK1, HSPA4, CHD6,

ERCC3, EHD1, EHD4, MSH6, MSH2, SMC5, SMC6, RAF1, SMC4, JAK2

IPR008271: Serine/
66
PASK, DSTYK, LATS1, PSKHI, SLK, CLK2, AAKI, CLK4, CDK12, TLK1,

threonine-protein

CDK10, PRKACB, MAP2K7, CHUK, CDK13, AKT2, SRPK2, IRAK1, TNIK,

kinase, active site

ROCK1, CSNK1G2, ROCK2, PRKCI, PKN2, PIMI, PRKCH, CDK9, CDK7,

PRKCD, SRPK1, CDK2, MARK2, GAK, PRKCB, MAPK1, MAPK6, CAMK4,

HIPK1, RIPK1, HIPK2, RIPK2, CDK11B, MAPK8, CSNKIG3, MAP3K14,

MAP3K13, PRKD3, MAPKAPK5, STK10, MKNK2, MAPKAPK2, SNRK.

STK40, MAP3K1, PRKAAI, CSNKIA1, TAOK1, MAP2K4, RAF1, RPS6KA3,

CSNKID, CSNKIE, GSK3B, ARAF, ULK3, DYRKIA

Serine/threonine-
75
FASTK, PASK, DSTYK, LATS1, PSKHI, SLK, CLK2, AAK1, CLK4, ILK,

protein kinase

CDK12, TLK1, CDK10, PRKACB, MAP2K7, CHUK, CDK13, AKT2, SRPK2,

IRAK1, TNIK, ROCK1, CSNK1G2, ROCK2, PRKCI, PKN2, PIMI, PRKCH,

CDK9, CDK7, PRKCD, SRPK1, CDK2, MARK2, GAK, PRKCB, MAPK1,

MAPK6, CAMK4, HIPK1, RIPK1, HIPK2, RIPK2, CDK11B, MAPK8,

CSNK1G3, MAP3K14, MAP3K13, PRKD3, MAPKAPK5, STK10, MKNK2,

MAP4K1, MAPKAPK2, UHMK1, IRAK4, MAP3K3, SNRK, STK40, MAP3K1,

PRKAA1, CSNK1A1, TAOK1, MAP2K4, RAF1, OXSR1, ATM, RPS6KA3,

CSNKID, CSNKIE, MAPK13, GSK3B, ARAF, ULK3, DYRKIA

nucleotide
156
RAD51C, DYNCILI2, PASK, INO80, DSTYK, NLRC5, PSKHI, IDH3G,

phosphate-binding

DDX23, CLK2, CUL9, AAK1, CLK4, ILK, DHX34, ORC4, VPS4A, TLK1,

region: ATP

PRKACB, DDX10, MAP2K7, MATK, TNIK, PDXK, ROCK1, CSNK1G2,

ROCK2, PIM1, MARK2, MAPK1, MAPK6, DHX29, CAMK4, RFC2, RIPK2,

MAPK8, CSNK1G3, SMARCA2, PRPS2, PRPS1, CLCN3, PFKFB3,

MAPKAPK5, STK10, MAP4K1, MYO9B, MAPKAPK2, NAGK, UHMK1,

IRAK4, MOV10, VRK3, ZAP70, NAT10, DDX42, KIF3B, RYK, TAOK1,

MAP2K4, OXSR1, ABCB7, PSMC5, PSMC2, UBA3, GTF2F2, DYRKIA,

ULK3, DDX50, ABL2, DDX51, SPG7, DICER1, HELZ, SKIV2L2, SLFN5,

PMVK, LATS1, GSS, ATAD3A, LONP1, SLK, CDK12, MKKS, CDK10,

TOP2B, DYNC1H1, CHUK, CDK13, AKT2, SRPK2, IRAK1, PFKL, PRKCI,

PKN2, PRKCH, CDK9, DGUOK, CDK7, GMPS, PRKCD, SRPK1, CDK2,

RAD50, TTF2, PRKCB, MCM6, CBWD2, TOR2A, RECQL, HIPK1, RIPK1,

HIPK2, CDK11B, MAP3K14, MAP3K13, PRKD3, SPAST, BTAF1, PGS1,

WRNIP1, MKNK2, DCK, N4BP2, CHD9, MTHFS, CHDIL, CHD7, KTI12,

STK40, MAP3K3, SNRK, DDX19A, MAP3K1, DHX16, PRKAA1, UCK1,

CHD6, EHD1, ERCC3, EHD4, CSNK1A1, MSH6, MAT2A, MSH2, PDK3,

SMC5, SMC6, RAF1, SMC4, RPS6KA3, CSNKID, CSNKIE, MAPK13,

GSK3B, ARAF, JAK2

Kinase
120
PASK, NELL2, DSTYK, PI4K2B, PRKAR2A, PSKHI, CLK2, AAK1, CLK4,

ILK, TLK1, PRKACB, MAP2K7, MATK, TNIK, PDXK, ROCK1, CSNK1G2,

ROCK2, PRKAB1, PIM1, PKIA, MARK2, WDR83, MAPK1, NME3, CAMK4,

MAPK6, RIPK2, MAPK8, CSNK1G3, PRPS2, PRPS1, PHKA2, PFKFB3,

STK10, MAPKAPK5, MAP4K1, AKAP10, MAPKAPK2, NAGK, UHMK1,

IRAK4, VRK3, PRKRA, ZAP70, TAOK1, RYK, CINP, MAP2K4, FN3KRP,

OXSR1, ATM, CDKNIB, DYRKIA, ULK3, HGS, ABL2, FASTK, PRKAG2,

PPIP5K2, PIP5K1A, PMVK, LATS1, SLK, CDK12, CDK10, CHUK, CDK13,

AKT2, SRPK2, IRAK1, PFKL, PIK3C2A, PKN2, PRKCI, CDK9, PRKCH,

DGUOK, PI4KB, CDK7, PRKCD, SRPK1, CDK2, GAK, PRKCB, PANK4,

PANK2, HIPK1, RIPK1, HIPK2, CDK11B, MAP3K14, MAP3K13, PRKD3,

MOB1B, DCK, MKNK2, MAP3K3, STK40, DGKE, SNRK, MAP3K1, UCK1,

PRKAA1, CERK, PIK3R1, CSNK1A1, PDK3, RAF1, DGKH, PCK2, RPS6KA3,

CSNKID, CSNKIE, MAPK13, GSK3B, ARAF, DGKZ, JAK2

binding site: ATP
94
SPG7, PASK, DSTYK, PMVK, LATS1, GSS, PSKHI, SLK, CLK2, AAK1,

CLK4, ILK, CDK12, TLK1, CDK10, PRKACB, MAP2K7, CHUK, CDK13,

AKT2, MATK, SRPK2, IRAK1, TNIK, ROCK1, CSNK1G2, ROCK2, PIMI,

PKN2, PRKCI, CDK9, PRKCH, CDK7, PRKCD, SRPK1, CDK2, MARK2,

PRKCB, TRAP1, MAPK1, NME3, HIPK1, CAMK4, MAPK6, RIPK1, HIPK2,

RIPK2, CDK11B, MAPK8, CSNK1G3, YARS2, MAP3K14, MAP3K13, PRKD3,

PRPS2, PRPS1, STK10, MAPKAPK5, MKNK2, MAP4K1, UBA5, MAPKAPK2,

NAGK, UHMK1, IRAK4, MTHFS, MAP3K3, VRK3, SNRK, STK40, MAP3K1,

ZAP70, PRKAA1, UCK1, EHD1, EHD4, CSNK1A1, MAT2A, RYK, TAOK1,

PDK3, MAP2K4, RAF1, OXSR1, RPS6KA3, CSNKID, CSNKIE, MAPK13,

GSK3B, ARAF, ULK3, DYRKIA, JAK2, ABL2

GO: 0004674~protein
72
CCNT2, FASTK, PASK, CCNTI, DSTYK, LATS1, PSKH1, SLK, CLK2,

serine/threonine

AAK1, CLK4, ILK, TLK1, CDK10, PRKACB, CDK13, AKT2, SRPK2, IRAK1,

kinase activity

TNIK, ROCK1, CSNK1G2, ROCK2, PRKCI, PKN2, PIMI, PRKCH, CDK9,

CDK7, PRKCD, SRPK1, CDK2, MARK2, GAK, PRKCB, MAPK1, MAPK6,

HIPK1, RIPK1, HIPK2, RIPK2, CDK11B, MAPK8, CSNK1G3, MAP3K14,

MAP3K13, MAPKAPK5, STK10, MKNK2, MAP4K1, MAPKAPK2, UHMK1,

IRAK4, VRK3, SNRK, STK40, MAP3K1, PRKAA1, CSNK1A1, TAOK1,

PDK3, RAF1, OXSR1, ATM, RPS6KA3, CSNKID, CSNKIE, MAPK13,

GSK3B, ARAF, ULK3, DYRKIA

GO: 0006468~protein
83
CCNT2, FASTK, PRKAG2, PASK, CCNT1, LATS1, ST3GAL1, PSKH1, CLK2,

phosphorylation

AAK1, ILK, TLK1, CDK10, PRKACB, CHUK, MATK, SRPK2, IRAK1,

CTBP1, PAN3, TNIK, ROCK1, CSNK1G2, ROCK2, CCNH, PIMI, PRKCI,

PKN2, PRKAB1, PRKCH, CDK9, DGUOK, CDK7, PRKCD, SRPK1, MARK2,

GAK, HCST, PRKCB, MAPK1, MAPK6, CAMK4, HIPK1, HIPK2, CDK11B,

MAPK8, MAP3K13, PRKD3, PHKA2, STK10, HUS1, MKNK2, MAP4K1,

MAPKAPK2, NPRL2, TRIB2, SNRK, STK40, MORC3, MAP3K1, PRKRA,

PPP3CB, ZAP70, PRKAA1, ERCC3, PIK3R1, CSNK1A1, FYB, TAOK1, RYK,

CREB1, RAF1, BIRC6, OXSR1, ATM, GMFB, RPS6KA3, CSNK1D, CSNK1E,

RSRC1, GSK3B, DYRKIA, JAK2

active site: Proton
105
CNDP2, PASK, IDE, DSTYK, PSKHI, CLK2, AAK1, CLK4, TLK1, PRKACB,

acceptor

MAP2K7, MATK, TNIK, ROCK1, CSNK1G2, ROCK2, PIMI, MARK2,

MAPK1, CAMK4, MAPK6, RIPK2, KDSR, MAPK8, CSNK1G3, MDH1,

HSD17B11, ME2, STK10, MAPKAPK5, MAP4K1, MAPKAPK2, ACAT2,

UHMK1, IRAK4, GALM, VRK3, IVD, ZAP70, TAOK1, RYK, MAP2K4,

OXSR1, ULK3, DYRKIA, ABL2, DCXR, HTATIP2, DHRSX, LATS1, SLK,

CDK12, CDK10, CHUK, CDK13, AKT2, IRAK1, SRPK2, PFKL, PKN2,

PRKCI, CDK9, PRKCH, CDK7, PRKCD, CDK2, SRPK1, GAK, DHRS7,

PRKCB, G6PD, HIPK1, RIPK1, TGDS, HIPK2, RRM1, TXNRD1, CDK11B,

MAP3K14, MAP3K13, PRKD3, ALDH9A1, MKNK2, ERI3, MAP3K3, STK40,

SNRK, MAP3K1, PITRM1, PRKAA1, HSD17B8, CSNK1A1, RAF1, SIRT6,

SIRT7, SIRT2, SDHA, RPS6KA3, CSNKID, CSNKIE, TDP2, MAPK13,

GSK3B, ARAF, JAK2

GO: 0004672~protein
67
FASTK, PASK, CLK2, AAK1, ILK, CDK12, CDK10, MAP2K7, CHUK,

kinase activity

CDK13, AKT2, SRPK2, IRAK1, TNIK, PAN3, ROCK1, CSNK1G2, PRKCI,

PKN2, PRKAB1, GTF2H3, PRKCH, CDK9, CDK7, PRKCD, SRPKI, CDK2,

MARK2, GAK, PRKCB, CAMK4, HIPK1, RIPK1, HIPK2, CDK11B,

CSNK1G3, MAP3K14, CCL3, MAPKAPK5, MKNK2, MAP4K1, MAPKAPK2,

NPRL2, TRIB2, IRAK4, VRK3, SNRK, MAP3K3, MAP3K1, PRKAA1, ERCC3,

CSNK1A1, TAOK1, RYK, PDK3, MAP2K4, RAF1, RPS6KA3, CSNKID,

CSNKIE, MAPK13, GSK3B, ARAF, ULK3, DYRKIA, JAK2, ABL2

domain: Protein
79
PASK, DSTYK, LATS1, PSKHI, SLK, CLK2, AAK1, CLK4, ILK, CDK12,

kinase

TLK1, CDK10, PRKACB, MAP2K7, CHUK, CDK13, AKT2, MATK, SRPK2,

IRAK1, PAN3, TNIK, ROCK1, CSNK1G2, ROCK2, PIMI, PRKCI, PKN2,

PRKCH, CDK9, CDK7, PRKCD, SRPK1, CDK2, MARK2, GAK, PRKCB,

MAPK1, MAPK6, CAMK4, HIPK1, RIPK1, HIPK2, RIPK2, CDK11B, MAPK8,

CSNK1G3, MAP3K14, MAP3K13, PRKD3, STK10, MAPKAPK5, MKNK2,

MAP4K1, MAPKAPK2, UHMK1, TRIB2, IRAK4, MAP3K3, VRK3, SNRK,

STK40, MAP3K1, ZAP70, PRKAAI, CSNK1A1, TAOK1, RYK, MAP2K4,

RAF1, OXSR1, CSNKID, CSNKIE, MAPK13, GSK3B, ARAF, ULK3,

DYRKIA, ABL2

IPR000719: Protein
81
PASK, DSTYK, LATS1, PSKHI, SLK, CLK2, AAK1, CLK4, ILK, CDK12,

kinase, catalytic

TLK1, CDK10, PRKACB, MAP2K7, CHUK, CDK13, AKT2, MATK, SRPK2,

domain

IRAK1, PAN3, TNIK, ROCK1, CSNK1G2, ROCK2, PIMI, PRKCI, PKN2,

PRKCH, CDK9, CDK7, PRKCD, SRPK1, CDK2, MARK2, GAK, PRKCB,

MAPK1, CAMK4, MAPK6, HIPK1, RIPK1, HIPK2, RIPK2, CDK11B, MAPK8,

CSNK1G3, MAP3K14, MAP3K13, PRKD3, STK10, MAPKAPK5, MKNK2,

MAP4K1, MAPKAPK2, UHMK1, TRIB2, IRAK4, MAP3K3, VRK3, SNRK,

STK40, MAP3K1, ZAP70, PRKAAI, CSNKIAI, TAOKI, RYK, MAP2K4,

RAF1, OXSR1, RPS6KA3, CSNKID, CSNKIE, MAPK13, GSK3B, ARAF,

ULK3, DYRKIA, JAK2, ABL2

IPR011009: Protein
86
PASK, DSTYK, LATS1, PSKHI, SLK, CLK2, AAK1, CLK4, ILK, CDK12,

kinase-like domain
216
TLK1, CDK10, PRKACB, MAP2K7, CHUK, CDK13, AKT2, MATK, SRPK2,

GO: 0005524~ATP

IRAK1, PAN3, TNIK, ROCK1, CSNK1G2, ROCK2, PIK3C2A, PIMI, PRKCI,

binding

PKN2, CDK9, PRKCH, PI4KB, CDK7, PRKCD, SRPK1, CDK2, GAK, MARK2,

PRKCB, MAPK1, CAMK4, MAPK6, HIPK1, RIPK1, HIPK2, RIPK2, CDK11B,

MAPK8, CSNK1G3, MAP3K14, MAP3K13, PRKD3, STK10, MAPKAPK5,

MKNK2, MAP4K1, MAPKAPK2, TRRAP, UHMK1, TRIB2, IRAK4, MAP3K3,

VRK3, SNRK, STK40, MAP3K1, ZAP70, PRKAAI, CSNKIA1, TAOKI, RYK,

MAP2K4, RAF1, FN3KRP, OXSR1, ATM, RPS6KA3, CSNKID, CSNKIE,

MAPK13, GSK3B, ARAF, ULK3, DYRKIA, JAK2, ABL2

RAD51C, DYNCILI2, ADCY7, ATP2B4, PSKHI, CLK2, CUL9, CLK4, ILK,

DHX34, VPS4A, TLK1, DDX10, MAP2K7, PAN3, TNIK, ROCK1, ROCK2,

UBE2J1, PIM1, UBE2J2, MARK2, MAPK1, GLUL, NME3, MAPK6, DHX29,

CAMK4, ATP2C1, RFC2, MAPK8, CLCN3, PFKFB3, FARS2, UBA5, WARS2,

HSPA1A, OAS1, MYO9B, OAS2, NAGK, UHMK1, MOV10, KRAS, VRK3,

ZAP70, NAT10, KIF3B, TAOK1, MAP2K4, ATP11A, OXSRI, ATM,

ATP13A1, UBA3, ABCF3, SPG7, FASTK, UBE2G1, HELZ, PMVK, LATS1,

LONP1, ATAD3A, DYNCIH1, TOP2B, SRPK2, PIK3C2A, DGUOK, PI4KB,

GMPS, SRPK1, RAD50, TTF2, CBWD2, TRAP1, RIPK1, RRMI, FARSB,

CDK11B, MAP3K14, MAP3K13, WRNIP1, MKNK2, SNRK, DGKE, STK40,

KTI12, DDX19A, DHX16, PRKAAI, CERK, ACSL4, ACSL3, SPATA5,

ACSL5, CSNK1A1, PDS5B, MAT2A, PDK3, DGKH, RPS6KA3, CSNKID,

CSNKIE, MAPK13, GSK3B, ARAF, DGKZ, PASK, IDE, DSTYK, INO80,

PI4K2B, NLRC5, IDH3G, DDX23, AAK1, ORC4, PRKACB, MATK, PDXK,

CSNK1G2, PNPLA8, RIPK2, CSNK1G3, YARS2, SLFN12L, SMARCA2,

PCCB, PRPS2, PRPS1, MVD, STK10, MAPKAPK5, MAP4K1, MAPKAPK2,

IRAK4, UBE2D4, FICD, RUNX1, DDX42, RYK, MYO1G, ABCB7, PSMC5,

PSMC2, ULK3, DYRKIA, GTF2F2, DDX50, ABL2, DDX51, UBE2E1,

DICER1, PRKAG2, PPIP5K2, SKIV2L2, SLFN5, PIP5K1A, GSS, SLK, CDK12,

MKKS, ATP8B2, CDK10, CHUK, CDK13, AKT2, IRAK1, UBE2A, PFKL,

PRKCI, PKN2, PRKCH, CDK9, CDK7, PRKCD, CDK2, PRKCB, GAK, MCM6,

TOR2A, PANK4, RECQL, PANK2, HIPK1, HIPK2, UBE2W, PRKD3, SPAST,

BTAF1, PGS1, UBE2Z, DCK, TRIB2, UBE2R2, N4BP2, CHD9, MTHFS,

CHDIL, CHD7, MAP3K3, MAP3K1, UCK1, HSPA4, CHD6, ERCC3, EHD1,

EHD4, MSH6, MSH2, SMC5, SMC6, RAF1, SMC4, JAK2

IPR017441: Protein
62
PASK, DSTYK, PSKHI, SLK, CLK2, CLK4, CDK12, TLK1, CDK10,

kinase, ATP binding

PRKACB, CHUK, CDK13, MATK, AKT2, IRAK1, SRPK2, TNIK, ROCK1,

site

CSNK1G2, ROCK2, PRKCI, PKN2, PIMI, PRKCH, CDK9, CDK7, PRKCD,

CDK2, SRPK1, MARK2, PRKCB, MAPK1, MAPK6, CAMK4, HIPK1, HIPK2,

CSNK1G3, MAP3K14, PRKD3, STK10, MKNK2, MAP4K1, MAPKAPK2,

SNRK, MAP3K1, ZAP70, PRKAAI, CSNKIAI, TAOKI, MAP2K4, RAFI,

OXSR1, RPS6KA3, CSNKID, CSNKIE, MAPK13, GSK3B, ARAF, ULK3,

DYRKIA, JAK2, ABL2

Enrichment Score:

4.4354405219010475

Mitochondrion
173
RAD51C, TSPO, MRPL42, CMC2, MALSUI, GFER, MPV17, TMEM11,

OGDH, CIAPIN1, FAM210A, HIBADH, MFF, IDH3G, VPS13C, CASP8AP2,

CPOX, SLC25A28, MRPL34, MRPL35, TIMMDC1, CRLS1, NUDTI,

BCL2L11, TIMM8A, NFU1, SLC25A32, GLUL, SLC25A38, YARS2, TFBIM,

PCCB, MTFMT, MPST, MRPL44, ME2, ELAC2, MRPS14, MCL1, GLUD2,

TXN2, FARS2, MRPS11, SFXN4, WARS2, AKAP10, OAS1, CHCHD4, OAS2,

RBFA, PIN4, AGMAT, MTIF2, SDHAF1, FAM65B, SLC11A2, FIS1, GFM2,

C12ORF10, IVD, GFM1, BLOC1S1, IDH2, MRPL55, LIAS, TRAF3, FH,

MRPS23, MRPS25, C21ORF33, MPC1, MPC2, GLOD4, MRRF, ABCB7, PPIF,

TEFM, NDUFV3, METTL12, SYNE2, BBC3, NDUFV2, RHOT1, RHOT2,

SLC25A16, C19ORF12, PHYKPL, METTL17, NDUFAF4, SPG7, COX11,

UQCRC1, FASTK, HINT2, BNIP3, UQCRFS1, ARL2BP, ACOT9, LONP1,

DNAJC15, ATAD3A, PARL, DNAJC11, ATP5H, NDUFS1, ARL2, SQRDL,

AIFM1, DGUOK, PI4KB, ECSIT, RHBDD1, NDUFA10, MRPS2, TIMM22,

IMMPIL, HAGH, TRAP1, PANK2, MRPS9, BNIP1, TCHP, ATPAF1,

C7ORF73, GLRX5, PGS1, BCAT2, NDUFB7, ETHE1, RSAD2, QTRT1, HSCB,

TACO1, GLRX2, NUDT9, BCL2, PITRM1, MRPL16, PYCARD, XAF1,

ACSL4, LACTB, PDHX, ACSL3, SPATA5, SCO2, ACSL5, ETFA, C14ORF119,

HSD17B8, ECI1, DLST, ALKBH7, ECI2, GIMAP5, IMMT, NDUFA9, PDK3,

RAF1, BAD, PCK2, IFIT3, SDHA, MPG, APOPT1, SDHC, TSFM, MTFP1,

BNIP3L, NLN, OGGI, SCP2, SLC25A53

Transit peptide
87
COX11, MRPL42, UQCRC1, HINT2, OGDH, UQCRFS1, HIBADH, ACOT9,

LONP1, IDH3G, PARL, CPOX, MRPL34, NDUFS1, MRPL35, SQRDL,

NUDT1, AIFM1, DGUOK, NDUFA10, ECSIT, HAGH, TRAP1, NFUI, PANK2,

MRPS9, YARS2, TFBIM, ATPAF1, PCCB, MTFMT, MRPL44, PGS1, GLRX5,

BCAT2, ELAC2, ME2, TXN2, GLUD2, FARS2, ETHE1, MRPS11, WARS2,

AKAP10, RBFA, MTIF2, AGMAT, HSCB, GLRX2, GFM2, C12ORF10,

NUDT9, IVD, GFM1, MRPL16, PITRM1, IDH2, MRPL55, LIAS, LACTB,

PDHX, SCO2, ETFA, FH, ECI1, ECI2, DLST, ALKBH7, NDUFA9, IMMT,

PDK3, C21ORF33, PCK2, MRRF, ABCB7, NDUFV3, TEFM, PPIF, SDHA,

METTL 12, MPG, APOPT1, SDHC, TSFM, NDUFV2, NLN, METTL17

transit
80
COX11, MRPL42, UQCRC1, HINT2, OGDH, UQCRFS1, HIBADH, ACOT9,

peptide: Mitochondrion

LONP1, IDH3G, PARL, CPOX, MRPL34, NDUFS1, MRPL35, SQRDL, AIFMI,

DGUOK, NDUFA10, ECSIT, HAGH, TRAP1, NFUI, PANK2, MRPS9, YARS2,

TFB1M, ATPAF1, PCCB, MTFMT, MRPL44, PGS1, BCAT2, ME2, TXN2,

GLUD2, FARS2, ETHE1, MRPS11, WARS2, AKAP10, RBFA, MTIF2,

AGMAT, HSCB, GLRX2, GFM2, C12ORF10, NUDT9, IVD, GFM1, MRPL16,

PITRM1, IDH2, MRPL55, LIAS, LACTB, PDHX, SCO2, ETFA, FH, ECI1,

DLST, ECI2, NDUFA9, PDK3, C21ORF33, PCK2, MRRF, ABCB7, NDUFV3,

PPIF, SDHA, METTL12, TXNDC12, SDHC, TSFM, NDUFV2, NLN, METTL 17

GO: 0005759~
57
FASTK, MALSUI, OGDH, HIBADH, ARL2BP, ACOT9, GPX1, LONP1,

mitochondrial matrix

IDH3G, NDUFS1, ARL2, NUDTI, DGUOK, NDUFA10, HAGH, TRAP1,

YARS2, TFBIM, PCCB, GLRX5, ME2, ELAC2, BCAT2, MCL1, TXN2,

ETHE1, FARS2, WARS2, PIN4, SDHAF1, GLRX2, MTHFS, GFM2, NUDT9,

IVD, GFM1, PITRM1, BLOC1S1, IDH2, LIAS, PDHX, SCO2, ETFA,

HSD17B8, FH, ECI1, ALKBH7, DLST, NDUFA9, CREB1, PDK3, MRRF,

PCK2, TEFM, PPIF, TSFM, PHYKPL

Enrichment Score:

4.367762624189855

domain: MBD
8
SETDB1, MECP2, MBD6, MBD5, MBD4, BAZ2B, MBD1, BAZ2A

SM00391: MBD
8
SETDB1, MECP2, MBD6, MBD5, MBD4, BAZ2B, MBD1, BAZ2A

binding, integrase-

IPR016177: DNA-
8
SETDB1, MECP2, MBD6, MBD5, MBD4, BAZ2B, MBD1, BAZ2A

binding, integrase-

type

IPR001739: Methyl-
8
SETDB1, MECP2, MBD6, MBD5, MBD4, BAZ2B, MBD1, BAZ2A

CpG DNA binding

Enrichment Score:

4.255632723903859

SM00320: WD40
55
COPA, SEC31B, SEC31A, STRN, TSSC1, WDR74, SHKBP1, WDR77, ZNF106,

MLST8, NSMAF, TBL1XR1, ELP2, RBBP4, GNBIL, STRN3, TLE3, PRPF4,

ARPCIA, WDR48, WDR83, EML3, SMU1, MED16, NOL10, DDB2, THOC6,

DYNC112, WDR45, WDR60, LRBA, WDR45B, PRPF19, PHIP, FBXW7,

NUP214, WDR54, FBXW5, FBXW2, WDR12, PAFAHIB1, FBXW11,

PPP2R2D, GEMIN5, WDTC1, WDR5, WDR6, WIPI2, PWP2, WSB1, POCIB,

WDR26, WRAP73, TBLIX, CSTF1

IPR017986: WD40-
62
COPA, TAFIC, SEC31B, SEC31A, KNTC1, STRN, TSSC1, WDR74, SHKBP1,

repeat-containing

WDR77, ZNF106, MLST8, NSMAF, ITFG2, TBL1XR1, ELP2, RBBP4, GNBIL,

domain

STRN3, ANAPC4, TLE3, VPS41, PRPF4, ARPCIA, WDR48, WDR83, EML3,

SMU1, MED16, DDB2, NOL10, THOC6, NOL11, DYNC112, WDR45, LRBA,

WDR60, SF3B3, WDR45B, PRPF19, PHIP, FBXW7, WDR54, FBXW5,

WDR12, FBXW2, PAFAHIB1, FBXW11, VPS39, PPP2R2D, GEMIN5,

WDTC1, WDR5, WDR6, WIPI2, PWP2, WSB1, POCIB, WDR26, WRAP73,

TBL1X, CSTF1

repeat: WD 3
54
COPA, SEC31B, SEC31A, STRN, TSSC1, WDR74, SHKBP1, WDR77, ZNF106,

MLST8, NSMAF, TBL1XR1, ELP2, RBBP4, GNBIL, STRN3, TLE3, HERC2,

PRPF4, ARPCIA, WDR48, WDR83, EML3, SMU1, MED16, NOL10, DDB2,

THOC6, DYNC1I2, WDR45, WDR60, LRBA, PRPF19, PHIP, FBXW7, WDR54,

FBXW5, FBXW2, WDR12, PAFAH1B1, FBXW11, PPP2R2D, GEMIN5,

WDTC1, WDR5, WDR6, WIPI2, PWP2, WSB1, POCIB, WDR26, WRAP73,

TBL1X, CSTF1

IPR001680: WD40
55
COPA, SEC31B, SEC31A, STRN, TSSC1, WDR74, SHKBP1, WDR77, ZNF106,

repeat

MLST8, NSMAF, TBL1XR1, ELP2, RBBP4, GNBIL, STRN3, TLE3, PRPF4,

ARPCIA, WDR48, WDR83, EML3, SMU1, MED16, NOL10, DDB2, THOC6,

DYNC112, WDR45, WDR60, LRBA, WDR45B, PRPF19, PHIP, FBXW7,

NUP214, WDR54, FBXW5, FBXW2, WDR12, PAFAHIB1, FBXW11,

PPP2R2D, GEMIN5, WDTC1, WDR5, WDR6, WIPI2, PWP2, WSB1, POCIB,

WDR26, WRAP73, TBLIX, CSTF1

repeat: WD 1
55
COPA, SEC31B, SEC31A, STRN, TSSC1, WDR74, SHKBP1, WDR77, ZNF106,

MLST8, NSMAF, TBL1XR1, ELP2, RBBP4, GNBIL, STRN3, TLE3, HERC2,

PRPF4, ARPCIA, WDR48, WDR83, EML3, SMU1, MED16, NOL10, DDB2,

THOC6, DYNC112, WDR45, WDR60, LRBA, WDR45B, PRPF19, PHIP,

FBXW7, WDR54, FBXW5, FBXW2, WDR12, PAFAHIB1, FBXW11,

PPP2R2D, GEMIN5, WDTC1, WDR5, WDR6, WIPI2, PWP2, WSB1, POCIB,

WDR26, WRAP73, TBLIX, CSTF1

repeat: WD 2
55
COPA, SEC31B, SEC31A, STRN, TSSC1, WDR74, SHKBP1, WDR77, ZNF106,

MLST8, NSMAF, TBL1XR1, ELP2, RBBP4, GNBIL, STRN3, TLE3, HERC2,

PRPF4, ARPCIA, WDR48, WDR83, EML3, SMU1, MED16, NOL10, DDB2,

THOC6, DYNC1I2, WDR45, WDR60, LRBA, WDR45B, PRPF19, PHIP,

FBXW7, WDR54, FBXW5, FBXW2, WDR12, PAFAHIB1, FBXW11,

PPP2R2D, GEMIN5, WDTC1, WDR5, WDR6, WIPI2, PWP2, WSB1, POCIB,

WDR26, WRAP73, TBLIX, CSTF1

repeat: WD 4
51
COPA, SEC31B, SEC31A, STRN, TSSC1, SHKBP1, WDR74, WDR77, ZNF106,

MLST8, NSMAF, TBL1XR1, ELP2, RBBP4, GNBIL, STRN3, TLE3, HERC2,

PRPF4, ARPCIA, WDR48, WDR83, EML3, SMU1, MED16, NOL10, DDB2,

THOC6, DYNC112, WDR60, LRBA, PRPF19, PHIP, FBXW7, WDR54,

FBXW2, WDR12, PAFAH1B1, FBXW11, PPP2R2D, GEMIN5, WDTC1,

WDR5, WDR6, PWP2, WSB1, POCIB, WDR26, WRAP73, TBLIX, CSTF1

WD repeat
54
COPA, SEC31B, SEC31A, STRN, TSSC1, WDR74, SHKBP1, WDR77, ZNF106,

MLST8, NSMAF, TBL1XR1, ELP2, RBBP4, GNBIL, STRN3, TLE3, PRPF4,

ARPCIA, WDR48, WDR83, EML3, SMU1, MED16, NOL10, DDB2, THOC6,

DYNC112, WDR45, WDR60, LRBA, WDR45B, PRPF19, PHIP, FBXW7,

WDR54, FBXW5, FBXW2, WDR12, PAFAHIB1, FBXW11, PPP2R2D,

GEMIN5, WDTC1, WDR5, WDR6, WIPI2, PWP2, WSB1, POCIB, WDR26,

WRAP73, TBLIX, CSTF1

repeat: WD 6
42
COPA, SEC31B, SEC31A, LRBA, STRN, WDR74, PRPF19, PHIP, FBXW7,

WDR12, ZNF106, PAFAHIB1, MLST8, NSMAF, FBXW11, PPP2R2D,

GEMIN5, TBL1XR1, ELP2, WDTC1, RBBP4, GNBIL, STRN3, WDR5, WDR6,

TLE3, HERC2, PRPF4, PWP2, WDR48, ARPCIA, WSB1, WDR83, EML3,

SMU1, POCIB, WDR26, WRAP73, THOC6, TBLIX, CSTF1, DYNC1I2

repeat: WD 5
48
COPA, SEC31B, SEC31A, LRBA, STRN, TSSC1, WDR74, PRPF19, SHKBP1,

PHIP, FBXW7, WDR77, WDR12, PAFAHIB1, ZNF106, MLST8, NSMAF,

FBXW11, PPP2R2D, GEMIN5, TBL1XR1, ELP2, WDTC1, RBBP4, GNBIL,

STRN3, WDR5, WDR6, TLE3, HERC2, PRPF4, PWP2, WDR48, ARPCIA,

WSB1, WDR83, EML3, SMU1, POCIB, WDR26, WRAP73, MED16, NOL10,

THOC6, DDB2, TBLIX, CSTF1, DYNC1I2

IPR020472: G-
24
COPA, TBL1XR1, RBBP4, STRN3, WDR5, STRN, PRPF4, PWP2, WDR48,

protein beta WD-40

WDR83, PRPF19, WSB1, SMU1, FBXW7, POCIB, WDR26, FBXW2, WDR12,

repeat

PAFAHIB1, MLST8, TBLIX, CSTF1, FBXW11, GEMIN5

IPR015943: WD40/
58
COPA, SEC31B, SEC31A, STRN, TSSC1, WDR74, SHKBP1, WDR77, ZNF106,

YVTN repeat-like-

MLST8, NSMAF, TBL1XR1, ELP2, RBBP4, GNBIL, STRN3, ANAPC4, TLE3,

containing domain

VPS41, PRPF4, ARPCIA, WDR48, WDR83, EML3, SMU1, MED16, NOL10,

DDB2, THOC6, DYNC1I2, WDR45, WDR60, LRBA, WDR45B, PRPF19, PHIP,

FBXW7, NUP214, WDR54, FBXW5, WDR12, FBXW2, PAFAHIB1, FBXW11,

PPP2R2D, GEMIN5, WDTC1, WDR5, WDR6, BIRC6, WIPI2, PWP2, WSB1,

POC1B, WDR26, WRAP73, TBLIX, CSTF1

IPR019775: WD40
31
COPA, SEC31B, STRN, TSSC1, PRPF19, PHIP, FBXW7, WDR77, FBXW2,

repeat, conserved

WDR12, PAFAHIB1, MLST8, FBXW11, GEMIN5, TBL1XR1, RBBP4,

site

GNBIL, WDR5, STRN3, TLE3, PRPF4, PWP2, WDR48, WDR83, WSB1,

SMU1, POCIB, THOC6, DDB2, TBLIX, CSTF1

repeat: WD 7
26
SEC31B, SEC31A, PHIP, PRPF19, FBXW7, WDR12, PAFAHIB1, MLST8,

FBXW11, PPP2R2D, GEMIN5, TBL1XR1, WDTC1, ELP2, WDR5, WDR6,

TLE3, PRPF4, PWP2, WDR48, WDR83, EML3, POCIB, THOC6, TBLIX,

DYNC1I2

Enrichment Score:

3.829453652617158

Transcription
336
ITGB3BP, MEF2A, BBX, MED23, RORA, ZNF638, MXI1, TBPL2, BRPF1,

SIN3A, ZFP90, ZNF394, TBPL1, ZNF101, ZNF43, ZNF44, TADA2A, ZNF644,

RXRB, PCBD1, ZHX1, MECP2, MED11, HMG20B, MED13, PPARGCIA,

ZNF37A, MED19, MAPK1, PIAS4, ASCC2, HES4, MED16, MLLT10, JUN,

MED17, PRDM2, CDCA7L, PIAS1, SUDS3, CRTC3, CRTC2, ZNF131, TAF9B,

ZNF511, XAB2, NR1H2, MOV10, TCF20, LEO1, TCF3, PLAGL2, IKZF5,

ASXL2, TCF7, ESRRA, ZNF529, IKZF2, NRBF2, KLF13, TP53BP1, ZNF121,

KLF10, CREBBP, RYBP, ZBTB40, SMAD3, PMF1, RNF4, DMTF1, PPRCI,

JAZF1, HOPX, KAT6B, RERE, NCOR2, NKAP, CCNT2, CREBRF, TAFIB,

TAF1C, ZNF292, ELF2, BACH2, ZNF534, EZH1, CCNT1, COPRS, ZNF675,

ZEB1, RFXANK, DAXX, ZBTB38, DNAJC17, MBTD1, ASH2L, ZNF148,

BRD4, USP16, TWISTNB, MYB, DEDD2, ZNF493, SERTAD2, BRD8,

ATF7IP, NFKBIZ, CTBP1, BRF1, RBBP4, POLRIE, BRF2, CCNH, POLRIA,

TLE3, GTF2H3, SPEN, MBD1, GTF2B, TTF2, MXD4, TAF10, TAF13,

CHMP1A, GTF2I, MED8, ASHIL, ZNF277, NOL11, CNOT11, USP22,

ZNF746, ZNF740, MED1, ZNF276, ZNF275, ETV7, ZNF274, ZBTB10,

ZBTB11, PML, ZNF780B, ZNF780A, POLR2B, MYCBP2, STAT6, LPXN,

RB1CC1, NPAT, GATAD2A, ZSCAN25, BCL3, AGO2, THAP1, ACTL6A,

PRKAA1, HBP1, BAZ2B, ZNF268, BAZ2A, POLR3F, POLR3H, ZNF28,

PPHLN1, TRIM27, PHF10, POLR3C, ATMIN, TRIM22, POLR3E, IWS1,

ZNF664, ZNF672, BRMS1, JMJD6, YAF2, MAPK13, WHSCIL1, ZBTB2,

ZNF764, ZNF766, RALY, ZNF583, CNOT8, IL16, TBP, CBX7, TCEAL4,

GABPB1, DPY30, CASP8AP2, CGGBP1, MDFIC, TARDBP, GATA3, RELA,

ZNF7, ARID1B, TRERF1, EP300, TRIM33, KDM2A, NFE2L2, AKAP8,

NFE2L3, ZNF587, TFBIM, SMARCA2, ZNF586, CAMTA2, ZNF430, LITAF,

SETDIA, KEAP1, C14ORF166, ELK3, TRRAP, COMMD9, SRF, COMMD10,

CXXC1, PELP1, CNOT6L, RNF10, RUNX1, SETDB1, ZMYM2, TRIP4,

CREBZF, TAF6, RFX5, WDR5, ZMYM5, NR4A1, SNW1, KAT5, MED13L,

FOXP3, ATF7IP2, UIMC1, SAFB2, SREBF2, CTR9, TEFM, ATF6, ATF5,

NRF1, PHF1, GTF2F1, GTF2F2, CPNE1, HIVEP2, HIVEP1, E2F3, E2F4,

ARID4A, GPBP1, YLPM1, FOXK2, CTCF, ZKSCAN1, CBFA2T2, PCGF5,

GTF2A1, ZNF721, INO80D, KDM5B, INO80C, KDM5C, NFX1, INO80B,

ELMSAN1, EGR1, TBL1XR1, ELP2, SSBP3, LRIF1, ELP6, ELP5, ARID5A,

ZFX, PKN2, CDK9, IRF2BP2, BANP, CDK7, FOXJ3, LPINI, NRIP1, PRKCB,

NCOA1, NCOA2, BTG2, BPTF, HIPK1, FAM120B, HIPK2, KHSRP,

COMMD3, COMMD1, WASL, JMJDIC, DPF2, ING3, SBNO2, ING2, KMT2A,

FRYL, KMT2C, ZNF800, NFYC, NFYB, PAXBP1, CHD9, CHD7, TSPYL2,

ECD, NFATC2, ERCC3, CHD6, GTF3C1, GTF3C3, L3MBTL2, L3MBTL3,

CREB1, SIRT7, MRGBP, SIRT2, MED31, RPAP2, SP1, DR1, KDM4C, IRF3,

TBL1X, VPS25

Transcription
324
ITGB3BP, MEF2A, BBX, MED23, RORA, ZNF638, MXI1, TBPL2, BRPF1,

regulation

SIN3A, ZFP90, ZNF394, TBPL1, ZNF101, ZNF43, ZNF44, TADA2A, ZNF644,

RXRB, PCBD1, ZHX1, MECP2, MED11, HMG20B, MED13, PPARGCIA,

ZNF37A, MED19, MAPK1, PIAS4, ASCC2, HES4, MED16, MLLT10, JUN,

MED17, PRDM2, CDCA7L, PIAS1, SUDS3, CRTC3, CRTC2, ZNF131, TAF9B,

ZNF511, NR1H2, MOV10, TCF20, LEO1, TCF3, PLAGL2, IKZF5, ASXL2,

TCF7, ESRRA, ZNF529, IKZF2, NRBF2, KLF13, TP53BP1, ZNF121, KLF10,

CREBBP, RYBP, ZBTB40, SMAD3, PMF1, RNF4, DMTF1, PPRCI, JAZF1,

HOPX, KAT6B, RERE, NCOR2, NKAP, CCNT2, CREBRF, TAFIB, TAFIC,

ZNF292, ELF2, ZNF534, BACH2, EZH1, CCNTI, COPRS, ZNF675, ZEB1,

RFXANK, DAXX, ZBTB38, DNAJC17, MBTD1, ASH2L, ZNF148, BRD4,

USP16, MYB, DEDD2, ZNF493, SERTAD2, BRD8, ATF7IP, NFKBIZ, CTBP1,

BRF1, RBBP4, BRF2, CCNH, TLE3, GTF2H3, SPEN, MBD1, GTF2B, TTF2,

MXD4, TAF10, TAF13, CHMP1A, GTF2I, MED8, ASHIL, ZNF277, NOL11,

CNOT11, USP22, ZNF746, ZNF740, MED1, ZNF276, ZNF275, ETV7, ZNF274,

ZBTB10, ZBTB11, PML, ZNF780B, ZNF780A, MYCBP2, STAT6, LPXN,

RB1CC1, NPAT, GATAD2A, ZSCAN25, BCL3, AGO2, THAP1, ACTL6A,

PRKAA1, HBP1, BAZ2B, ZNF268, BAZ2A, ZNF28, PPHLN1, TRIM27,

PHF10, ATMIN, TRIM22, IWS1, ZNF664, ZNF672, BRMS1, JMJD6, YAF2,

MAPK13, WHSCIL1, ZBTB2, ZNF764, ZNF766, RALY, ZNF583, CNOT8,

IL16, TBP, CBX7, TCEAL4, GABPB1, DPY30, CASP8AP2, CGGBP1, MDFIC,

TARDBP, GATA3, RELA, ZNF7, ARID1B, TRERF1, EP300, TRIM33,

KDM2A, NFE2L2, AKAP8, NFE2L3, ZNF587, TFBIM, SMARCA2, ZNF586,

CAMTA2, ZNF430, LITAF, SETDIA, KEAP1, C14ORF166, ELK3, TRRAP,

COMMD9, SRF, COMMD10, CXXC1, CNOT6L, RNF10, RUNX1, SETDB1,

ZMYM2, TRIP4, CREBZF, TAF6, RFX5, WDR5, ZMYM5, NR4A1, SNW1,

KAT5, MED13L, FOXP3, ATF7IP2, UIMC1, SAFB2, SREBF2, CTR9, ATF6,

TEFM, ATF5, NRF1, PHF1, GTF2F1, GTF2F2, CPNE1, HIVEP2, HIVEP1,

E2F3, E2F4, ARID4A, GPBP1, YLPM1, FOXK2, CTCF, ZKSCAN1, CBFA2T2,

PCGF5, GTF2A1, ZNF721, INO80D, KDM5B, INO80C, KDM5C, NFX1,

INO80B, ELMSAN1, EGR1, TBL1XR1, ELP2, SSBP3, LRIF1, ELP6, ELP5,

ZFX, ARID5A, PKN2, CDK9, IRF2BP2, BANP, CDK7, FOXJ3, LPINI, NRIP1,

PRKCB, NCOA1, NCOA2, BTG2, BPTF, HIPK1, FAM120B, HIPK2, KHSRP,

COMMD3, COMMD1, WASL, JMJDIC, DPF2, ING3, SBNO2, ING2, KMT2A,

FRYL, KMT2C, ZNF800, NFYC, NFYB, PAXBP1, CHD9, CHD7, TSPYL2,

ECD, NFATC2, ERCC3, CHD6, L3MBTL2, L3MBTL3, CREB1, SIRT7,

MRGBP, SIRT2, MED31, RPAP2, SP1, DR1, KDM4C, IRF3, TBLIX, VPS25

GO: 0006351~
271
ITGB3BP, MEF2A, BBX, RORA, ZNF638, MXI1, BRPF1, SIN3A, ZFP90,

transcription, DNA-

ZNF394, ZNF101, ZNF43, ZNF44, ZNF644, RXRB, PCBD1, ZHX1, MECP2,

templated

MED11, HMG20B, ZNF37A, MED19, MAPK1, PIAS4, ASCC2, HES4,

MLLT10, PRDM2, CDCA7L, PIAS1, SUDS3, CRTC3, CRTC2, NFKBIB,

ZNF131, ZNF511, DIDO1, XAB2, NR1H2, MOV10, TCF20, TCF3, ASXL2,

IKZF5, ESRRA, TCF7, ZNF529, IKZF2, TP53BP1, ZNF121, KLF10, RYBP,

ZBTB40, SMAD3, RNF4, DMTF1, HOPX, JAZF1, PPRC1, KAT6B, RERE,

NCOR2, NKAP, CCNT2, CREBRF, TAFIB, ELF2, ZNF534, EZH1, CCNTI,

COPRS, ZNF675, ZEB1, RFXANK, DAXX, ZBTB38, DNAJC17, MBTD1,

ASH2L, BRD4, USP16, DEDD2, ZNF493, BRD8, SERTAD2, ATF7IP,

NFKBIZ, CTBP1, RBBP4, POLRIE, LIN52, CCNH, POLRIA, TLE3, SPEN,

MXD4, CHMP1A, ZNF277, NOL11, CNOT11, USP22, ZNF746, ZNF740,

ZNF276, ZNF275, ZNF274, ZBTB10, ZBTB11, PML, ZNF780B, ZNF780A,

POLR2B, MYCBP2, STAT6, LPXN, RBICC1, NPAT, GATAD2A, ZSCAN25,

BCL3, AGO2, THAP1, ACTL6A, PRKAA1, HBP1, BAZ2B, ZNF268, BAZ2A,

POLR3H, ZNF28, PPHLN1, TRIM27, PPPIR10, PHF10, POLR3C, ATMIN,

TRIM22, POLR3E, IWS1, ZNF664, ZNF672, BRMS1, JMJD6, YAF2, MAPK13,

WHSCIL1, ZBTB2, ZNF764, ZNF766, RALY, ZNF583, CNOT8, IL16, INO80,

CBX7, TCEAL4, GABPB1, DPY30, CASP8AP2, MDFIC, CGGBP1, ZNF7,

ARIDIB, TRERF1, TRIM33, KDM2A, NFE2L2, AKAP8, NFE2L3, ZNF587,

TFBIM, SMARCA2, ZNF586, ZNF430, LITAF, SETDIA, KEAP1,

C14ORF166, TRRAP, COMMD9, COMMD10, RRAGC, CXXC1, PELPI,

CNOT6L, RNF10, SETDB1, ZMYM2, TRIP4, CREBZF, RFX5, WDR5,

ZMYM5, NR4A1, KAT5, MED 13L, FOXP3, ATF7IP2, UIMC1, SAFB2,

SREBF2, CTR9, ATF6, PHF3, PHF1, CPNE1, E2F3, E2F4, GPBP1, YLPMI,

ZKSCAN1, CBFA2T2, PCGF5, ZNF721, INO80D, KDM5B, KDM5C, INO80C,

ELMSAN1, INO80B, TBL1XR1, SSBP3, LRIF1, ELP6, LDB1, ELP5, ZFX,

ARID5A, PKN2, BANP, IRF2BP2, FOXJ3, LPINI, NRIP1, PRKCB, NCOA1,

NCOA2, BPTF, HIPK1, BTG2, FAM120B, HIPK2, COMMD3, KHSRP,

COMMD1, WASL, JMJDIC, DPF2, ING3, SBNO2, ING2, FRYL, KMT2C,

ZNF800, NFYB, PAXBP1, CHD9, CHD7, TSPYL2, CHD6, GTF3C1, GTF3C3,

L3MBTL2, L3MBTL3, DRG1, MRGBP, SIRT2, DR1, KDM4C, TBLIX, VPS25

GO:0006355~regulation
196
ITGB3BP, MEF2A, BBX, MED23, ZNF638, RORA, MXI1, SIN3A, ZFP90,

of transcription,

ZNF394, TBPL1, ZNF101, ZNF43, ZNF44, ZNF644, RXRB, HMG20B,

DNA-templated

PPARGCIA, ZNF37A, ASCC2, HES4, CDCA7L, PRDM2, ZNHIT3, ZNF131,

ZNF511, AHCTF1, TCF20, MOV10, TCF3, ASXL2, IKZF5, ZNF529, ESRRA,

NRBF2, ZNF121, CREBBP, ZBTB40, SMAD3, PMF1, DMTF1, KAT6B,

TAFIB, CREBRF, TAFIC, ZNF534, COPRS, ZNF675, DAXX, MBTD1,

ASH2L, MYB, ZNF493, BRD8, RBBP4, BRF1, BRF2, TLE3, GTF2H3, GTF2B,

TTF2, TAF10, POGK, ZNF277, CNOT11, CDK11B, ZNF746, ZNF740, ZNF276,

ZNF275, ZNF274, ZBTB10, ZBTB11, PML, ZNF780B, ZNF780A, MLF2,

MYCBP2, ZFP36L2, LPXN, RBICCI, ZSCAN25, PRKAA1, HBP1, THAP1,

ZNF268, BAZ2B, USP34, MLLT6, BAZ2A, ZNF28, PPHLN1, PHF10, AFF1,

TRIM22, IWS1, ZNF664, ZNF672, MAPK13, JMJD6, WHSCIL1, ZBTB2,

ZNF764, OGGI, ZNF766, GOLGB1, RALY, CNOT8, ZNF583, IL16,

AKAP17A, CASP8AP2, ZNF814, ZNF7, RALGAPA1, EP300, KDM2A,

AKAP8, TFBIM, ZNF587, SMARCA2, ZNF586, ZNF430, SETDIA, KEAP1,

TRRAP, COMMD9, CXXCI, COMMD10, CNOT6L, TRIP4, RFX5, FOXP3,

KAT5, VAVI, ATF7IP2, CTR9, SAFB2, TEFM, ATF5, PHF1, CDKN2AIP,

CPNE1, HIVEP2, GPBP1, FOXK2, YLPM1, ZKSCAN1, GTF2A1, RBAK-

RBAKDN, ZNF721, ZNF720, INO80D, INO80C, INO80B, SSBP2, LRIF1,

LDB1, ZFX, ELP5, PKN2, IRF2BP2, NCOA1, NCOA2, HIPK1, BPTF,

FAM120B, COMMD3, KHSRP, JMJDIC, WASL, DPF2, SBNO1, SBNO2,

ING3, ING2, FRYL, KMT2C, ZNF800, NFYC, NFYB, GLRX2, CHD9,

TSC22D3, TSPYL2, CHD7, NFATC2, L3MBTL2, L3MBTL3, VHL, CREB1,

CBL, RGS19, SP1, POFUT1, VPS25

DNA-binding
227
RAD51C, HMGN3, MEF2A, BBX, HIFX, ZNF638, RORA, MXI1, HMGN4,

TBPL2, BRPF1, ZFP90, ZNF394, TBPL1, ZNF101, ZNF43, POLK, ZNF44,

ZNF644, TADA2A, RXRB, ZHX1, MECP2, HMG20B, POLB, TOX4, ZNF37A,

MAPK1, UHRF2, PIAS4, MTF2, HES4, MLLT10, JUN, PRDM2, PIAS1,

ZNF131, AHCTF1, ZNF511, PIN4, NR1H2, TCF20, TCF3, PLAGL2, IKZF5,

DNMT3A, ZNF529, ESRRA, TCF7, IKZF2, KLF13, ZNF121, KLF10, TP53BP1,

RYBP, ZBTB40, SMAD3, ATM, RNF4, DMTF1, H3F3A, NCOR2, TAFIB,

TAF1C, ZNF292, ELF2, ZNF534, BACH2, ZNF675, ZEB1, RFXANK, ZBTB38,

LONP1, ASH2L, ZNF148, TOP2B, MYB, DEDD2, ZNF493, ZFP36, POGZ,

AIFM1, APTX, MBD4, PAPD5, SPEN, MBD1, TTF2, MXD4, POGK, GTF2I,

ZNF277, ZNF746, MED1, REV3L, ZNF276, ZNF275, ETV7, ZNF274, ZBTB10,

ZBTB11, PML, ZNF780B, ZNF780A, STAT6, ZFP36L2, ZSCAN25, THAP1,

HBP1, THAP2, BAZ2B, ZNF268, BAZ2A, ZNF28, TRIM27, PPPIR10, ZNF664,

PLSCR1, ZNF672, ZBTB2, ZNF764, ZNF766, ZNF583, INO80, TBP, CGGBP1,

TARDBP, GATA3, ORC4, RELA, MTA2, NEIL2, ZNF7, ARIDIB, TRERF1,

NABP1, TRIM33, KDM2A, RNF138, AKAP8, NFE2L2, TFBIM, ZNF587,

NFE2L3, SMARCA2, ZNF586, ZNF430, CERS6, CERS4, ELK3, SRF, CXXC1,

POLE3, CERS2, RNF10, RUNX1, RFX5, NR4A1, TSN, FOXP3, SAFB2,

SREBF2, ATF6, ATF5, NRF1, GTF2F1, GTF2F2, HIVEP2, HIVEP1, GLYR1,

IER2, HIST4H4, E2F3, E2F4, GPBP1, FOXK2, ZKSCAN1, CTCF, FOS,

ZNF721, NFX1, ELMSAN1, EGRI, SSBP3, SSBP2, ZFX, ARID5A, BANP,

FOXJ3, MCM6, NUCB1, XPA, RECQL, XPC, HIPK1, HIPK2, NUCB2, DDB2,

KHSRP, BTAF1, KMT2A, KMT2C, MGMT, ZNF800, NFYC, NFYB, PAXBP1,

APLP2, RPA1, CHD9, CHD7, HMGXB4, HMGXB3, NFATC2, ERCC3, CHD6,

GTF3C1, TERF2, GTF3C3, TERF1, MSH6, MSH2, CREB1, TOX, SP1, DR1,

IRF3

Enrichment Score:

3.4484346569016893

Immunity
81
CD8A, ZC3HAVI, CD8B, PTPN22, APOBEC3G, PDCD1, APOBEC3C,

APOBEC3D, TRIM4, ANKRD17, NLRC5, GATA3, IL4R, ERAPI, JAGNI,

MX1, MX2, DBNL, IRAK1, SITI, LY96, HERC5, FADD, ECSIT, PRKCB,

CD84, TRIM38, BTN3A1, CHID1, TNFSF13B, CAMK4, RIPK2, LRMP, HLA-

DPA1, AKAP8, GBP3, BTN3A2, ORAI1, IFITM1, IFITM2, CSF1, UNC93B1,

PML, RSAD2, OAS1, OAS2, SEC14L1, RNF125, IRAK4, SERINC3, PYCARD,

ZAP70, PSTPIP1, HLA-DPB1, INPP5D, MR1, TBKBP1, TRAF3, POLR3F,

POLR3H, MYO1G, CTLA4, ANXA1, SAMHD1, MSRB1, TRIM25, PIBF1,

SLAMF7, POLR3C, LGALS9, POLR3E, SIRT2, IFIT3, BTLA, CD55, IFIT5,

CD79B, JAK2, IRF3, TAPBPL, IL2

Innate immunity
50
ZC3HAVI, APOBEC3G, APOBEC3C, APOBEC3D, TRIM4, NLRC5,

ANKRD17, GATA3, MX1, MX2, IRAK1, LY96, HERC5, FADD, ECSIT, CD84,

TRIM38, CHID1, RIPK2, AKAP8, IFITM1, IFITM2, CSF1, PML, UNC93B1,

RSAD2, OAS1, OAS2, SEC14L1, SERINC3, IRAK4, PSTPIP1, PYCARD, MR1,

TBKBP1, POLR3F, POLR3H, ANXA1, MSRB1, SAMHD1, TRIM25, SLAMF7,

POLR3C, POLR3E, SIRT2, IFIT3, CD55, IFIT5, JAK2, IRF3

GO: 0045087~innate
56
ZC3HAVI, APOBEC3G, IGHM, APOBEC3C, APOBEC3D, TRIM4, NLRC5,

immune response

ANKRD17, GATA3, MX1, KLRD1, MX2, CHUK, MATK, IRAK1, SRPK2,

LY96, HERC5, FADD, ECSIT, SRPK1, CD84, CHID1, IPO7, RIPK2, AKAP8,

CSF1, PML, TRIM14, UNC93B1, TRDC, SEC14L1, SERINC3, IRAK4,

PSTPIP1, ZAP70, PYCARD, MR1, TBKBP1, TRAF3, POLR3F, POLR3H,

TRIM27, ANXA1, TRIM26, MSRB1, MALT1, TRIM25, POLR3C, POLR3E,

SIRT2, CD55, APOL1, IFIT5, JAK2, ABL2

Enrichment Score:

3.4148927968910225

hsa04668: TNF
31
TRAF1, CSF2, TRAF2, CSF1, LIF, TNFRSFIA, BAG4, FOS, CASP7, CASP8,

signaling pathway

BCL3, MAP2K7, TRAF5, CHUK, PIK3R1, AKT2, TRAF3, ICAMI, IL18R1,

SOCS3, CREB1, RELA, MAP2K4, FADD, TAB3, MAPK1, MAPK13, JUN,

RIPK1, MAPK8, MAP3K14

hsa04620: Toll-like
24
IRAK1, CCL3, LY96, RELA, MAP2K4, FADD, CCL4, IFNAR1, IRAK4,

receptor signaling

MAPK1, FOS, IFNAR2, MAPK13, JUN, RIPK1, CASP8, RACI, IRF3, MAPK8,

pathway

MAP2K7, CHUK, PIK3R1, AKT2, TRAF3

hsa04380: Osteoclast
25
TRAF2, CSF1, FOS, TNFRSFIA, IFNG, RAC1, PPP3CB, NFATC2, MAP2K7,

differentiation

IFNGR2, PIK3R1, CHUK, AKT2, SOCS3, RELA, CREB1, SOCS1, IFNAR1,

MAPK1, IFNAR2, CAMK4, MAPK13, JUN, MAPK8, MAP3K14

Enrichment Score:

3.2064615359892623

Bromodomain
14
BRD1, KMT2A, CREBBP, PHIP, BRPF1, EP300, TRIM33, BPTF, ASHIL,

BRD4, BAZ2B, BAZ2A, SMARCA2, BRD8

SM00297: BROMO
14
BRD1, KMT2A, CREBBP, PHIP, BRPF1, EP300, TRIM33, BPTF, ASHIL,

BRD4, BAZ2B, BAZ2A, SMARCA2, BRD8

IPR001487:
14
BRD1, KMT2A, CREBBP, PHIP, BRPF1, EP300, TRIM33, BPTF, ASHIL,

Bromodomain

BRD4, BAZ2B, BAZ2A, SMARCA2, BRD8

IPR018359:
10
PHIP, BRD1, BRPF1, EP300, BPTF, CREBBP, BRD4, BAZ2B, SMARCA2,

Bromodomain,

BAZ2A

conserved site

domain:Bromo
10
BRD1, BRPF1, EP300, TRIM33, BPTF, CREBBP, ASHIL, BAZ2B, SMARCA2,

BAZ2A

Enrichment Score:

3.1111268555872935

mRNA processing
63
RALY, SCAFI, CRNKL1, ZMAT5, U2AF2, SKIV2L2, SART3, SARTI,

AKAP17A, DDX23, TARDBP, CDK12, QKI, DBR1, LSM3, RBM10, LSM1,

TSEN2, CDK13, SRPK2, SYMPK, PAN3, EFTUD2, FMR1, PAPD5, CSTF2T,

PRPF4, SRPK1, TTF2, WDR83, PCF11, KHSRP, THOC6, SLU7, CPSF4,

CPSF3, FIPIL1, XAB2, SF3B4, SF3B3, PRPF19, CNOT6L, ECD, ISY1,

DHX16, GEMIN6, RBM28, GEMIN5, RBM22, TSEN54, SREK1, ALYREF,

SNW1, CASC3, SF3A2, IWS1, SUGP1, CLASRP, JMJD6, RSRC1, LSM10,

RNPC3, CSTF1

mRNA splicing
50
RALY, SCAF1, ZMAT5, CRNKL1, U2AF2, SKIV2L2, SART3, SARTI,

AKAP17A, DDX23, TARDBP, CDK12, QKI, LSM3, LSMI, RBM10, CDK13,

SRPK2, EFTUD2, FMR1, PRPF4, TTF2, SRPK1, WDR83, KHSRP, THOC6,

SLU7, XAB2, SF3B4, SF3B3, PRPF19, ECD, ISY1, DHX16, GEMIN6, RBM28,

GEMIN5, RBM22, SREK1, ALYREF, SNW1, CASC3, SF3A2, IWS1, SUGP1,

CLASRP, JMJD6, RSRC1, LSM10, RNPC3

GO: 0008380~RNA
36
SCAF1, ZMAT5, RP9, ZNF638, IVNSIABP, SF3B4, SF3B3, RRAGC,

splicing

AKAP17A, DDX23, TARDBP, ECD, CDK12, QKI, DHX16, RBM10, LSMI,

RBM28, SRPK2, EFTUD2, SREK1, FMR1, SF3A2, PPARGCIA, PRPF4, IWS1,

TTF2, SRPK1, PPIG, CLASRP, JMJD6, RSRC1, KHSRP, THOC6, LSM10,

RNPC3

GO: 0000398~mRNA
44
RALY, FIPIL1, ZMAT5, CRNKL1, U2AF2, SKIV2L2, SART3, SF3B4, XAB2,

splicing, via

SART1, SF3B3, POLR2B, PRPF19, METTL3, DDX23, ISY1, DHX16, DBR1,

spliceosome

LSM3, GEMIN6, GEMIN5, RBM22, EFTUD2, ALYREF, ELAVL1, SNW1,

CASC3, SPEN, SF3A2, PRPF4, WDR83, PCF11, HNRNPH2, UPF3B, SUGP1,

GTF2F1, RSRC1, GTF2F2, RBMX2, SLU7, RNPC3, CPSF3, RBM15, CSTF1

Spliceosome
27
RALY, ZMAT5, CRNKL1, U2AF2, SKIV2L2, SF3B4, XAB2, SARTI, SF3B3,

PRPF19, AKAP17A, DDX23, ISY1, LSM3, RBM28, RBM22, SREK1, EFTUD2,

ALYREF, SNW1, SF3A2, PRPF4, TTF2, WDR83, SUGP1, SLU7, RNPC3

GO: 0006397~mRNA
37
SCAF1, U2AF2, HNRNPLL, SF3B4, SF3B3, AKAP17A, METTL3, CNOT6L,

processing

TARDBP, ECD, CDK12, QKI, LSM3, TSEN2, RBM10, LSM1, RBM28, PHRF1,

TSEN54, RBM23, PAN3, EFTUD2, SREK1, FMR1, PAPD5, CASC3, SF3A2,

PPARGCIA, IWS1, TTF2, SRPK1, CLASRP, JMJD6, KHSRP, LSM10, CPSF4,

ALKBH5

GO:0071013~catalytic
18
RBM22, RALY, CRNKL1, EFTUD2, ALYREF, SKIV2L2, SNW1, SF3A2,

step 2

XAB2, SARTI, SF3B3, WDR83, PRPF19, DDX23, ISY1, RBMX2, SLU7,

spliceosome

LSM3

hsa03040: Spliceosome
22
RBM22, CHERP, CRNKL1, CCDC12, U2AF2, EFTUD2, ALYREF, SNW1,

HSPA1A, SF3A2, PRPF4, XAB2, SF3B4, SART1, SF3B3, PRPF19, DDX23,

ISY1, SLU7, DHX16, LSM3, DDX42

Enrichment Score:

3.0807772438702044

hsa03022: Basal
16
TAF6, CCNH, TAF9B, GTF2H3, TBP, CDK7, GTF2B, TBPL2, TAF10, TAF13,

transcription factors

GTF2A1, GTF2I, GTF2F1, GTF2F2, ERCC3, TBPL1

GO: 0006367~
33
E2F3, TAF9B, MED23, TBP, RORA, POLR2B, NR1H2, GTF2A1, ERCC3,

transcription initiation

ESRRA, NRBF2, TAF6, CCNH, RXRB, CREBBP, GTF2H3, CDK9, NR4A1,

from RNA

SNW1, MED13, CDK7, GTF2B, PPARGCIA, MED31, TAF10, TAF13, GTF2I,

polymerase II

MED16, GTF2F1, MED8, MED17, GTF2F2, MED1

promoter

GO: 0006368~
19
CCNT2, ELP2, TAF6, CCNH, CCNT1, TAF9B, GTF2H3, CDK9, TBP, CDK7,

transcription elongation

GTF2B, POLR2B, TAF10, TAF13, GTF2A1, GTF2F1, GTF2F2, LEO1, ERCC3

from RNA

polymerase II

promoter

Enrichment Score:

3.020215334274786

hsa04662: B cell
22
VAV3, NFKBIB, RELA, RAFI, MALTI, VAVI, NRAS, MAPK1, FOS, KRAS,

receptor signaling

JUN, GSK3B, SOS1, CD81, RAC1, PPP3CB, CD79B, INPP5D, NFATC2,

pathway

CHUK, PIK3R1, AKT2

h_fcerlPathway: Fc
14
MAP2K4, RAF1, VAVI, PRKCB, MAPK1, FOS, MAP3K1, SOS1, JUN,

Epsilon Receptor I

PPP3CB, MAPK8, NFATC2, MAP2K7, PIK3R1

Signaling in Mast

Cells

GO: 0038095~Fc-
30
PSMB10, FOS, KRAS, MAP3K1, SOS1, RAC1, PPP3CB, PSMD3, PSMD5,

epsilon receptor

NFATC2, MAP2K7, FBXW11, CHUK, PIK3R1, VAV3, RELA, MAP2K4,

signaling pathway

MALT1, VAVI, TAB3, NRAS, MAPK1, PSMC5, PSMD13, PSMD12, JUN,

PSMC2, MAPK8, PSME4, GRAP2

Enrichment Score:

2.697299540563712

hsa04722: Neurotrophin
30
ZNF274, NFKBIB, MAPKAPK2, IRAK4, KRAS, MAP3K3, BCL2, SOS1,

signaling

MAP3K1, RAC1, MAP2K7, RAPGEF1, PIK3R1, MATK, AKT2, IRAK1,

pathway

RELA, RAF1, BAD, PRKCD, NRAS, MAPK1, RPS6KA3, CRKL, CAMK4,

MAPK13, JUN, GSK3B, RIPK2, MAPK8

hsa04012: ErbB
21
MAP2K4, CBL, RAF1, BAD, PRKCB, NRAS, MAPK1, NCK2, CBLB, CRKL,

signaling pathway

KRAS, CDKNIB, JUN, GSK3B, SOS1, ARAF, MAPK8, MAP2K7, ABL2,

PIK3R1, AKT2

hsa04912: GnRH
17
ADCY7, MAP2K4, RAF1, PRKCD, PRKCB, ITPR2, NRAS, MAPK1, KRAS,

signaling pathway

MAP3K3, MAPK13, JUN, MAP3K1, SOS1, MAPK8, PRKACB, MAP2K7

Enrichment Score:

2.6555136612397368

domain: LisH
10
OFD1, TBL1XR1, SMU1, MKLN1, SSBP3, SSBP2, WDR26, NPAT,

PAFAHIB1, TBLIX

SM00667: LisH
9
OFD1, TBL1XR1, SMU1, MKLN1, SSBP3, SSBP2, NPAT, PAFAHIB1,

TBL1X

IPR006594: LisH
10
OFD1, TBL1XR1, SMU1, MKLN1, SSBP3, SSBP2, WDR26, NPAT,

dimerisation motif

PAFAHIB1, TBLIX

Enrichment Score:

2.5486858895909723

Nuclear pore
17
NUP98, NUP160, AHCTF1, NUP93, NUP85, NUP188, PARP11, NUP155,

complex

NDC1, NUP214, DDX19A, NUP210, RANBP2, XPO7, MX2, EIF5A2, MVP

GO: 0016925~protein
30
NUP98, NUP160, PML, NUP93, CETN2, SAE1, NUP188, RANGAP1, NDC1,

umoylation

RPA1, NUP214, MDC1, NUP210, NSMCE1, NSMCE2, RNF168, RANBP2,

TOP2B, STAG1, L3MBTL2, KIAA1586, TP53BP1, SMC5, SMC6, NUP85,

HERC2, NUP155, XPC, PIAS4, PIAS1

GO: 1900034~regulation
22
NUP98, NUP160, CREBBP, NUP93, NUP85, NUP188, HSPAIA, MAPKAPK2,

of cellular

NUP155, ATM, NDC1, RPA1, BAG5, BAG4, MAPK1, NUP214, EP300,

response to heat

GSK3B, NUP210, MLST8, RANBP2, DNAJB6

mRNA transport
26
NUP98, NUP160, NUP93, AHCTF1, NUP188, NDC1, NUP214, DDX19A,

NUP210, QKI, RANBP2, MX2, FMR1, ALYREF, NUP85, PARP11, CASC3,

NUP155, IWS1, UPF3B, POLDIP3, THOC6, KHSRP, XPO7, EIF5A2, MVP

Translocation
21
NUP98, NUP160, AHCTF1, NUP93, NUP85, NUP188, PARP11, CHCHD4,

NUP155, TIMM22, TIMM8A, NDC1, NUP214, DNAJC15, DDX19A, NUP210,

RANBP2, XPO7, MX2, EIF5A2, MVP

GO: 0005643~nuclear
19
NUP98, NUP160, AHCTF1, NUP93, PARP11, RANGAP1, NUP155, NDC1,

pore

IPO7, DDX19A, NUP210, KPNA6, NUTF2, RANBP2, XPO7, MX2, EIF5A2,

KPNA1, MVP

GO: 0006406~mRNA
24
NUP98, FIPIL1, NUP160, SMG5, U2AF2, ALYREF, NUP93, NUP85, NUP188,

export from

CASC3, NUP155, NDC1, NUP214, UPF3B, EIF4E, DDX19A, POLDIP3,

nucleus

NUP210, RBMX2, THOC6, SLU7, RANBP2, CPSF3, ALKBH5

GO: 0007077~mitotic
13
NDC1, NUP214, NUP98, NUP160, NUP210, NUP93, CNEPIR1, NUP85,

nuclear envelope

NUP188, RANBP2, NUP155, LPINI, PRKCB

disassembly

hsa03013: RNA
32
RPP38, NUP98, ELAC2, NUP160, NUP93, RANGAP1, NUP188, NDC1,

transport

NUP214, EIF4EBP2, NUP210, RANBP2, GEMIN6, EIF2B4, EIF2B5, GEMIN5,

ALYREF, FMR1, NUP85, EIFIB, CASC3, FXR2, NUP155, TACC3, EIF2B1,

EIF4G3, EIF4E, UPF3B, THOC6, POP4, POP5, POP7

GO: 0006409~tRNA
10
NDC1, NUP214, NUP98, NUP160, NUP210, NUP93, NUP85, NUP188,

export from nucleus

RANBP2, NUP155

GO: 0010827~regulation
10
NDC1, NUP214, NUP98, NUP160, NUP210, NUP93, NUP85, NUP188,

of glucose

RANBP2, NUP155

transport

GO: 0075733~
13
NDC1, NUP214, NUP98, NUP160, TSG101, NUP210, NUP93, VPS37B,

intracellular transport

NUP85, NUP188, RANBP2, NUP155, KPNA1

of virus

GO :0017056~structural
7
NDC1, NUP214, NUP98, NUP93, NUP85, NUP188, NUP155

constituent of

nuclear pore

GO: 0031047~gene
21
NUP98, HIST4H4, NUP160, FMR1, DICER1, NUP93, NUP85, NUP188, TSN,

silencing by RNA

NUP155, POLR2B, NDC1, NUP214, CNOT6L, NUP210, PRKRA, CNOT11,

H3F3A, AGO2, RANBP2, TNRC6A

GO: 0006606~protein
11
NUP214, IPO7, PTTGIIP, NUP93, KPNA6, PPPIR10, NUP85, NUTF2,

import into

NUP188, NUP155, KPNA1

nucleus

GO: 0019083~viral
11
NDC1, RPL17, NUP214, NUP98, NUP160, NUP210, NUP93, NUP85, NUP188,

transcription

RANBP2, NUP155

Enrichment Score:

2.3663661637495768

IPR009060: UBA-
18
USP5, CBL, UBACI, LATS1, N4BP2, CBLB, C6ORF106, ASCC2, TDP2,

like

NBR1, TSFM, UBAP2L, FAF2, UBASH3A, SPATS2L, UBAP2, USP24, UBAP1

IPR015940: Ubiquitin-
13
USP5, CBL, UBACI, LATS1, MARK2, CBLB, SNRK, NBR1, UBAP2L,

associated/

UBASH3A, UBAP2, USP24, UBAP1

translation

elongation factor

EF1B, N-terminal,

eukaryote

domain: UBA
11
CBLB, SNRK, NBR1, CBL, UBAP2L, UBASH3A, FAF2, UBAP2, USP24,

LATS1, MARK2

SM00165: UBA
7
CBLB, USP5, CBL, UBAP2L, UBACI, UBAP2, MARK2

Enrichment Score:

2.185234142205886

GO: 1904115~axon
13
KIF3B, SPG7, NDEL1, BLOC1S5, AP3M2, AP3M1, BLOC1S1, AP3S1,

cytoplasm

SNAPIN, RANGAP1, PAFAHIB1, DTNBP1, SPAST

GO: 0008089~anterograde
10
SPG7, KIF3B, BLOC1S5, AP3M2, AP3M1, BLOC1S1, AP3S1, SNAPIN,

xonal

DTNBP1, SPAST

transport

GO: 0048490~anterograde
7
BLOC1S5, AP3M2, AP3M1, BLOC1S1, AP3S1, SNAPIN, DTNBP1

synaptic

vesicle transport

GO: 0031083~BLOC-1
6
BLOC1S5, KXD1, BLOC1S1, KIAA1033, SNAPIN, DTNBP1

complex

GO: 0032438~
5
BLOC1S5, AP1G1, BLOC1S1, SNAPIN, DTNBP1

melanosome organization

Enrichment Score:

2.109254171296502

IPR004939: Anaphase-
6
HSPB11, CUL9, ANAPC10, HERC2, ZZEF1, MYCBP2

promoting

complex, subunit

10/DOC domain

SM01337: SM01337
5
CUL9, ANAPC10, HERC2, ZZEF1, MYCBP2

domain: DOC
5
CUL9, ANAPC10, HERC2, ZZEF1, MYCBP2

IPR008979: Galactose-
13
ANAPC10, HERC2, FURIN, ZZEF1, MYCBP2, NGLY1, MKLN1, HSPB11,

binding domain-like

CUL9, FBXO6, PCSK7, HECTD1, SUCO

Enrichment Score:

2.052960731204601

GO: 0005913~cell-
54
RTN4, ABCF3, LIMA1, ZC3HAVI, VAPB, HIFX, RANGAP1, EFHD2, SLK,

cell adherens

LRRC59, ZYX, DBNL, BSG, PKN2, TXNDC9, CLIC1, FLNA, MARK2, CRKL,

junction

DHX29, USO1, SDCBP, MAPRE1, UBAP2, CD226, ADD1, SNX2, ASAP1,

KEAP1, HSPAIA, ITGB1, SH3GLB2, RAB11B, FASN, CNN2, CCS, EHD1,

EHD4, PLEC, APC, CBL, ARFIP2, S100A11, ANXA1, TRIM25, GLOD4,

TMEM2, ANXA2, TIGIT, CSNKID, LASP1, AHSAI, YKT6, CD200

GO: 0098641~cadherin
48
RTN4, ABCF3, LIMA1, ZC3HAVI, VAPB, SNX2, ASAP1, HIFX, HSPAIA,

binding involved

RANGAP1, ITGB1, EFHD2, SLK, SH3GLB2, LRRC59, FASN, RAB11B,

in cell-cell adhesion

CNN2, CCS, EHD1, PLEC, EHD4, DBNL, BSG, CBL, ANXA1, S100A11,

ARFIP2, PKN2, TRIM25, TXNDC9, CLIC1, GLOD4, FLNA, ANXA2, MARK2,

TMEM2, CRKL, CSNKID, DHX29, LASP1, USO1, SDCBP, MAPRE1, UBAP2,

YKT6, AHSA1, ADD1

GO: 0098609~cell-
45
RTN4, LIMA1, ABCF3, ZC3HAVI, VAPB, SNX2, ASAP1, HIFX, HSPAIA,

cell adhesion

RANGAP1, EFHD2, SLK, SH3GLB2, LRRC59, FASN, RAB11B, CNN2, CCS,

EHD1, PLEC, EHD4, DBNL, BSG, CREBBP, CBL, S100A11, ARFIP2, PKN2,

TRIM25, TXNDC9, GLOD4, ANXA2, MARK2, TMEM2, CRKL, CSNKID,

DHX29, LASP1, USO1, SDCBP, MAPRE1, UBAP2, YKT6, AHSA1, ADD1

Enrichment Score:

1.9864300666381447

IPR005225: Small
34
RAB5B, RAB5C, ARF6, MTIF2, GFM2, ARL5A, KRAS, GFMI, RACI, RALB,

GTP-binding protein

RAB11B, SARIB, RHOF, ARL2, RAP2C, EFTUD2, DRG1, DRG2, RAB33A,

domain

RAB33B, ARL3, NRAS, RAB30, RAB18, RAB35, ARF4, RHOT1, RAB5A,

RHOT2, RIT1, ARL8B, ARL4C, NKIRAS2, ARL4A

GO: 0007264~small
47
RAB5B, RAB5C, RGL4, IQGAP2, ARF6, RRAGC, DOCK2, ARL5A, KRAS,

GTPase mediated

SOS1, RAC1, RAPGEF6, RAB11B, DOCK10, RAPGEF1, RHOF, ARL2,

signal transduction

RAP2C, VAV3, RABIF, RALBP1, ARFIP2, RGS19, CHP1, DOCK8, VAVI,

RAB33A, RALGDS, RAB33B, ARL3, ARHGAP30, NRAS, SH2D3C, RAB30,

SH2D3A, RAB18, RAB35, KRITI, ARF4, RAB5A, RHOT1, RHOT2, RIT1,

ARL8B, ARL4C, NKIRAS2, ARL4A

GO: 0003924~GTPase
41
GNA13, RAB5B, RAB5C, HBSIL, GTPBP10, ATL3, GNL3L, ARF6, MTIF2,

activity

RRAGC, GFM2, KRAS, GFM1, RAC1, RAB11B, RALB, TUBAIA, MX1,

SARIB, RHOF, MX2, TUBAIC, ARL2, DNM3, NUDT1, EFTUD2, RAB33A,

RAB33B, ARL3, RAB30, RAB18, RAB35, ARF4, RAB5A, RHOT1, RHOT2,

RIT1, ARL8B, ARL4C, GBP3, NKIRAS2

nucleotide
48
GNA13, GPN3, RAB5B, RAB5C, HBSIL, GTPBP10, ATL3, GNL3L, ARF6,

phosphate-binding

MTIF2, RRAGC, GFM2, ARL5A, KRAS, GFM1, RAC1, RAB11B, RALB,

region: GTP

TUBAIA, MX1, SARIB, RHOF, MX2, TUBAIC, ARL2, DNM3, RAP2C,

GIMAP5, NIN, EFTUD2, DRG1, DRG2, PCK2, RAB33A, RAB33B, ARL3,

NRAS, RAB30, RAB18, RAB35, ARF4, RAB5A, RITI, ARL8B, ARL4C, GBP3,

NKIRAS2, ARL4A

GTP-binding
51
GNA13, RAB5B, RAB5C, GTPBP10, ATL3, HBSIL, GNL3L, ARL5A, RALB,

SARIB, MX1, TUBAIA, RHOF, MX2, TUBAIC, ARL2, RAP2C, EFTUD2,

ARL3, RAB18, RAB5A, ARL8B, GBP3, ARL4C, NKIRAS2, ARL4A, GPN3,

ARF6, MTIF2, RRAGC, GFM2, KRAS, GFM1, RACI, RAB11B, DNM3,

GIMAP5, NIN, DRG1, DRG2, PCK2, RAB33A, RAB33B, GIMAP1, NRAS,

RAB30, RAB35, ARF4, RHOT1, RHOT2, RIT1

IPR027417: P-loop
119
GNA13, RAD51C, DYNCILI2, HBSIL, IQGAP2, INO80, NLRC5, DDX23,

containing

DHX34, RALB, AAGAB, ORC4, VPS4A, DDX10, MX1, SARIB, MX2,

nucleoside

EFTUD2, IFI44, DHX29, RAB18, RFC2, ARL8B, GBP3, SMARCA2, GPN3,

triphosphate

PFKFB3, MYO9B, ARF6, MTIF2, RRAGC, GFM2, MOV10, KRAS, GFM1,

hydrolase

RAC1, DDX42, SMG9, KIF3B, MYO1G, ABCB7, RAB33A, RAB33B, PSMC5,

PSMC2, ARF4, RHOT1, DDX50, RHOT2, RIT1, DDX51, ABCF3, SPG7,

RAB5B, RAB5C, ATL3, GTPBP10, DICER1, YLPM1, GNL3L, HELZ,

SKIV2L2, SLFN5, PMVK, ARL5A, ATAD3A, LONP1, DYNC1H1, RHOF,

ARL2, RAP2C, MPP6, DGUOK, NDUFA10, TTF2, RAD50, MCM6, ARL3,

TOR2A, CBWD2, RECQL, RAB5A, ARL4C, NKIRAS2, SPAST, ARL4A,

BTAF1, SBNO1, SBNO2, WRNIP1, DCK, N4BP2, CHD9, CHDIL, CHD7,

KTI12, DDX19A, RAB11B, DHX16, UCK1, CHD6, EHD1, ERCC3, SPATA5,

EHD4, DNM3, MSH6, GIMAP5, MSH2, SMC5, SMC6, DRG1, DRG2,

GIMAP1, SMC4, NRAS, RAB30, RAB35, SAMD9

GO:0005525~GTP
58
GNA13, RAB5B, RAB5C, HBSIL, GTPBP10, ATL3, GNL3L, ARL5A, RALB,

binding

TUBAIA, SARIB, MX1, RHOF, MX2, TUBAIC, ARL2, RAP2C, EFTUD2,

ARL3, RAB18, RAB5A, ARL8B, IRGQ, GBP3, ARL4C, NKIRAS2, ARL4A,

GPN3, GLUD2, ARF6, MTIF2, RRAGC, GFM2, KRAS, GFM1, RACI,

RAB11B, ERCC3, EHD1, EHD4, DNM3, GIMAP5, NIN, ARFIP2, DRG1,

DRG2, PCK2, RAB33A, GIMAP1, RAB33B, NRAS, RAB30, RAB35, ARF4,

RHOT1, RHOT2, RIT1, C9ORF69

IPR001806: Small
19
RAP2C, RAB5B, RAB5C, RAB33A, RAB33B, NRAS, RAB30, KRAS, RAB18,

GTPase superfamily

RAB35, RAC1, RALB, RAB11B, RHOT1, RAB5A, RHOT2, RITI, RHOF,

NKIRAS2

Enrichment Score:

1.9444899254576018

GO: 0097296~activation
7
TNFRSF10A, TRAF2, RIPK1, CASP8, SMAD3, FADD, JAK2

of cysteine-type

endopeptidase

activity involved in

apoptotic signaling

pathway

GO: 0097191~
11
TNFRSF10A, HIPK1, RIPK1, CASP8, IFNG, PML, SMAD3, FADD, JAK2,

extrinsic apoptotic

BAD, CD27

signaling pathway

GO: 0006919~activation
17
TRAF2, AIFM1, PML, SMAD3, FADD, BAD, BCL2L11, TNFRSF10A,

of cysteine-type

SLC11A2, CDKNIB, CASP8AP2, BBC3, RIPK1, CASP8, PYCARD, JAK2,

endopeptidase

DAP

activity involved in

apoptotic process

Enrichment Score:

1.9286031923588833

SM00291: ZnF_ZZ
7
EP300, NBR1, MIB2, UTRN, CREBBP, HERC2, ZZEF1

IPR000433: Zinc
7
EP300, NBR1, MIB2, UTRN, CREBBP, HERC2, ZZEF1

finger, ZZ-type

zinc finger
6
EP300, NBR1, MIB2, UTRN, CREBBP, HERC2

region: ZZ-type

Enrichment Score:

1.9043308100071867

IPR000571: Zinc
17
ZFP36, RBM22, MKRN1, PAN3, ZC3H7A, ZMAT5, ZC3HAVI, ZC3H18,

finger, CCCH-type

ZC3H7B, PPPIR10, HELZ, ZFP36L2, PARP12, CPSF4, ZC3H12D, RNF113A,

DUS3L

SM00356: ZnF C3H1
14
ZFP36, MKRN1, RBM22, PAN3, ZMAT5, ZC3H18, ZC3H7A, ZC3H7B,

PPP1R10, HELZ, ZFP36L2, PARP12, CPSF4, RNF113A

zinc finger
9
ZFP36, MKRN1, ZFP36L2, ZC3H7A, ZC3HAVI, PARP12, ZC3H7B, CPSF4,

region: C3H1-type 2

DUS3L

zinc finger
9
ZFP36, MKRN1, ZFP36L2, ZC3H7A, ZC3HAVI, PARP12, ZC3H7B, CPSF4,

region: C3H1-type 1

DUS3L

zinc finger
7
RBM22, ZC3H18, ZMAT5, PPPIR10, HELZ, ZC3H12D, RNF113A

region: C3H1-type

zinc finger
5
MKRN1, ZC3HAVI, PARP12, ZC3H7B, CPSF4

region: C3H1-type 4

zinc finger
6
MKRN1, ZC3H7A, ZC3HAVI, PARP12, ZC3H7B, CPSF4

region: C3H1-type 3

Enrichment Score:

1.889023537159269

active site: Glycyl
18
UBE2A, UBE2Z, UBE2G1, HERC6, UBE2J1, HERC5, BIRC6, UBA5, HERC2,

thioester

UBE2J2, UBE2R2, UBE2D4, UBA3, UBE2W, SMURF2, HECTD4, HECTD1,

intermediate

UBE2E1

IPR016135: Ubiquitin-
14
UBE2A, UBE2Z, TSG101, UBE2G1, IMPACT, UBE2J1, BIRC6, UBE2J2,

conjugating

UBE2R2, UBE2D4, KRAS, UBE2W, RWDD3, UBE2E1

enzyme/RWD-like

GO: 0061631~ubiquitin
9
UBE2D4, UBE2A, UBE2Z, UBE2G1, UBE2J1, BIRC6, UBE2J2, UBE2E1,

conjugating

UBE2R2

enzyme activity

IPR000608:Ubiquitin-
11
UBE2D4, UBE2A, UBE2Z, KRAS, UBE2G1, UBE2J1, UBE2W, BIRC6,

conjugating

UBE2J2, UBE2E1, UBE2R2

enzyme, E2

IPR023313: Ubiquitin-
6
UBE2D4, UBE2A, KRAS, UBE2G1, UBE2E1, UBE2R2

conjugating

enzyme, active site

Enrichment Score:

1.888346683338545

IPR000313: PWWP
8
BRD1, DNMT3A, MSH6, BRPF1, PWWP2A, WHSCIL1, MBD5, GLYR1

domain: PWWP
7
BRD1, DNMT3A, MSH6, BRPF1, PWWP2A, MBD5, GLYR1

SM00293: PWWP
7
BRD1, DNMT3A, MSH6, BRPF1, PWWP2A, WHSCIL1, GLYR1

Enrichment Score:

1.8759534254878043

short sequence
9
ASXL2, CHD9, NCOA1, NCOA2, PELP1, MED13, MED13L, NRIP1, MED1

motif: LXXLL motif 1

short sequence
9
ASXL2, CHD9, NCOA1, NCOA2, PELP1, MED13, MED13L, NRIP1, MED1

motif: LXXLL motif 2

short sequence
5
CHD9, NCOA1, NCOA2, PELP1, NRIP1

motif: LXXLL motif 4

short sequence
5
CHD9, NCOA1, NCOA2, PELP1, NRIP1

motif: LXXLL motif 3

short sequence
4
CHD9, NCOA1, PELP1, NRIP1

motif:LXXLL motif 5

short sequence
3
NCOA1, PELP1, NRIP1

motif: LXXLL motif 7

GO: 0035257~nuclear
7
NCOA1, NCOA2, EP300, ACTN4, SNW1, NRIP1, MED1

hormone receptor

binding

short sequence
3
NCOA1, PELP1, NRIP1

motif:LXXLL motif 6

Enrichment Score:

1.8475951130819195

GO: 0036258~
14
CHMP3, TSG101, VTA1, CHMP6, CHMP4A, STAM2, CHMP7, VPS37B,

multivesicular body

CHMP1A, VPS4A, HGS, STAM, PDCD6IP, VPS25

assembly

GO: 0016197~
19
CHMP3, TSG101, STAM2, CHMP6, VTA1, CHMP4A, CHMP7, KIAA0196,

endosomal transport

VPS37B, WAS, DPY30, RAB35, BLOC1S1, KIAA1033, VPS4A, HGS, STAM,

AP5M1, VPS25

GO: 0006997~nucleus
10
NUMA1, CHMP1A, CHMP3, CHMP4A, CHMP6, CHMP7, VPS4A, H3F3A,

organization

PDCD6IP, BIN1

GO: 0039702~viral
9
CHMP1A, CHMP3, TSG101, CHMP4A, CHMP6, CHMP7, VPS4A, VPS37B,

budding via host

PDCD6IP

ESCRT complex

GO: 0000815~ESCRT
6
CHMP1A, CHMP3, CHMP4A, CHMP6, CHMP7, VPS4A

III complex

GO: 0019058~viral
10
CHMP3, TSG101, CHMP4A, CHMP6, VTA1, CHMP7, VPS4A, VPS37B,

life cycle

PDCD6IP, FURIN

GO: 0000920~cell
7
CHMP1A, CHMP3, CHMP4A, CHMP6, CHMP7, VPS4A, PDCD6IP

separation after

cytokinesis

GO: 0007080~mitotic
10
CUL3, CHMP1A, CHMP3, CHMP4A, CHMP6, CHMP7, VPS4A, CDC23,

metaphase plate

PIBF1, PDCD6IP

congression

GO: 1903774~positive
3
TSG101, VPS4A, VPS37B

regulation of viral

budding via host

ESCRT complex

IPR005024: Snf7
5
CHMP1A, CHMP3, CHMP4A, CHMP6, CHMP7

GO:0007034~vacuolar
5
CHMP1A, CHMP4A, CHMP6, CHMP7, ATP6VOD1

transport

GO:1904903~ESCRT
4
CHMP1A, VTA1, CHMP7, VPS4A

III complex

disassembly

GO: 1902188~positive
4
CHMP3, TSG101, VPS4A, VPS37B

regulation of viral

release from host

cell

GO: 0010824~regulation
4
CHMP1A, CHMP3, FBXW5, PDCD6IP

of centrosome

duplication

GO: 1901673~regulation
3
CHMP1A, CHMP3, PDCD6IP

of mitotic

spindle assembly

Enrichment Score:

1.827917602900078

GO:0003684~damaged
19
MSH6, POLK, MSH2, CREBBP, NEIL2, MGMT, APTX, GTF2H3, POLB,

DNA binding

RAD1, RPA1, XPA, MPG, XPC, EP300, DDB2, CUL4B, OGGI, ERCC3

GO: 0006294~nucleotide-
11
RPA1, XPA, XPC, CHDIL, CCNH, DDB2, GTF2H3, CETN2, CDK7, CUL4B,

excision repair,

ERCC3

preincision complex

assembly

GO: 0000717~nucleotide-
8
XPA, XPC, CHDIL, DDB2, GTF2H3, CETN2, CUL4B, ERCC3

excision repair,

DNA duplex

unwinding

GO: 0006283~
17
POLK, CCNH, COPS7A, GTF2H3, COPS7B, CDK7, COPS8, XAB2, POLR2B,

transcription-coupled

PRPF19, RPA1, XPA, EP300, RFC2, ISY1, CUL4B, ERCC3

nucleotide-excision

repair

GO: 0000715~nucleotide-
8
XPA, XPC, DDB2, COPS7A, CETN2, COPS7B, COPS8, CUL4B

excision repair,

DNA damage

recognition

hsa03420: Nucleotide
12
RPA1, XPA, XPC, CCNH, POLE3, RFC2, DDB2, GTF2H3, CETN2, CDK7,

excision repair

CUL4B, ERCC3

GO: 0070911~global
9
XPA, XPC, CHDIL, DDB2, GTF2H3, CETN2, CUL4B, ERCC3, RNF111

genome nucleotide-

excision repair

GO: 0033683~nucleotide-
10
RPA1, XPA, POLK, CHDIL, RFC2, DDB2, GTF2H3, CUL4B, OGGI, ERCC3

excision repair,

DNA incision

GO: 0006293~
7
RPA1, XPA, CHDIL, DDB2, GTF2H3, CUL4B, ERCC3

nucleotide-excision repair,

preincision complex

stabilization

GO: 0070914~UV-
5
XPA, XPC, DDB2, INO80, CUL4B

damage excision

repair

GO: 0006295~nucleo
7
RPA1, XPA, CHD1L, DDB2, GTF2H3, CUL4B, ERCC3

tide-excision repair,

DNA incision, 3'-to

lesion

GO: 0006289~
10
RPA1, XPA, XPC, NEIL2, HUS1, DDB2, GTF2H3, CETN2, OGGI, ERCC3

nucleotide-excision repair

GO:0006296~nucleo
9
RPA1, XPA, POLK, CHDIL, RFC2, DDB2, GTF2H3, CUL4B, ERCC3

tide-excision repair,

DNA incision, 5'-to

lesion

Xeroderma
4
XPA, XPC, DDB2, ERCC3

pigmentosum

Enrichment Score:

1.8167726915130153

SM00154: ZnF_AN1
5
ZFAND6, ZFAND5, ZFAND2A, ZFAND2B, ZFAND1

IPR000058: Zinc
5
ZFAND6, ZFAND5, ZFAND2A, ZFAND2B, ZFAND1

finger, AN1-type

zinc finger
3
ZFAND2A, ZFAND2B, ZFAND1

region: AN1-type 2

zinc finger
3
ZFAND2A, ZFAND2B, ZFAND1

region: AN1-type 1

Enrichment Score:

1.8153950109695944

Centromere
27
ITGB3BP, ZNF276, PPP2R5A, KNTC1, AHCTF1, CTCF, RANGAP1, DAXX,

ZNF330, NDE1, PPP2CB, STAGI, CSNKIA1, BOD1, CENPM, KANSLI,

TP53BP1, FMR1, DYNLT3, NUP85, DCTN5, PMF1, DCTN6, NDEL1, RCC2,

NSL1, NGDN

Kinetochore
18
CSNK1A1, ZNF276, ITGB3BP, BOD1, CENPM, KANSLI, TP53BP1, KNTC1,

DYNLT3, AHCTF1, NUP85, DCTN5, RANGAP1, PMF1, DCTN6, NDE1,

NDEL1, NSL1

GO: 0000777~
16
CSNK1A1, ITGB3BP, ZNF276, BOD1, CENPM, KANSL1, TP53BP1, KNTC1,

condensed chromosome

DYNLT3, AHCTF1, NUP85, DCTN5, RANGAP1, DCTN6, NDE1, NDEL1

kinetochore

Enrichment Score:

1.7131033299195293

hsa05210: Colorectal
19
MSH6, TCF7, MSH2, RAF1, SMAD3, BAD, RALGDS, MAPK1, FOS, KRAS,

cancer

JUN, BCL2, GSK3B, ARAF, RAC1, MAPK8, PIK3R1, AKT2, APC

hsa05211: Renal cell
18
VHL, CREBBP, RAF1, EGLN1, CUL2, NRAS, MAPK1, EP300, CRKL, KRAS,

carcinoma

JUN, SOS1, RAC1, ARAF, RAPGEF1, PIK3R1, AKT2, FH

hsa04012: ErbB
21
MAP2K4, CBL, RAF1, BAD, PRKCB, NRAS, MAPK1, NCK2, CBLB, CRKL,

signaling pathway

KRAS, CDKNIB, JUN, GSK3B, SOS1, ARAF, MAPK8, MAP2K7, ABL2,

PIK3R1, AKT2

hsa05215: Prostate
21
E2F3, TCF7, CREB1, RELA, CREBBP, RAF1, BAD, PTEN, CDK2, NRAS,

cancer

MAPK1, EP300, KRAS, CDKNIB, BCL2, GSK3B, SOS1, ARAF, CHUK,

PIK3R1, AKT2

hsa05160: Hepatitis C
28
TRAF2, OAS1, OAS2, TNFRSFIA, KRAS, SOS1, PPP2CB, PPP2R2D, PIK3R1,

CHUK, AKT2, TRAF3, SOCS3, RELA, RAF1, BAD, IFNAR1, NRAS, MAPKI,

IFNAR2, MAPK13, GSK3B, RIPK1, ARAF, CD81, IRF3, MAPK8, PIAS1

hsa05220: Chronic
18
CTBP1, E2F3, RELA, CBL, RAF1, BAD, NRAS, MAPKI, CBLB, CRKL,

myeloid leukemia

KRAS, CDKNIB, SOS1, ARAF, RUNX1, CHUK, PIK3R1, AKT2

hsa05221: Acute
15
TCF7, RELA, PML, PIM1, RAF1, BAD, NRAS, MAPK1, KRAS, SOS1, ARAF,

myeloid leukemia

RUNX1, PIK3R1, CHUK, AKT2

hsa04664: Fc epsilon
17
CSF2, VAV3, MAP2K4, RAF1, VAVI, PRKCB, NRAS, MAPK1, KRAS,

RI signaling

MAPK13, SOS1, RAC1, MAPK8, INPP5D, MAP2K7, PIK3R1, AKT2

pathway

hsa05213: Endometrial
14
TCF7, RAF1, BAD, PTEN, NRAS, MAPK1, KRAS, SOS1, GSK3B, ARAF, ILK,

cancer

PIK3R1, AKT2, APC

hsa05212: Pancreatic
16
E2F3, RALBP1, RELA, RAF1, SMAD3, BAD, RALGDS, MAPK1, KRAS,

cancer

ARAF, RACI, RALB, MAPK8, PIK3R1, CHUK, AKT2

hsa04370: VEGF
15
RAF1, BAD, MAPKAPK2, PRKCB, SH2D2A, NRAS, MAPK1, KRAS,

signaling pathway

MAPK13, RAC1, PPP3CB, HSPB1, NFATC2, PIK3R1, AKT2

hsa04917: Prolactin
16
SOCS3, RELA, SOCS1, LHCGR, RAF1, NRAS, MAPK1, FOS, KRAS,

signaling pathway

MAPK13, SOS1, GSK3B, MAPK8, JAK2, PIK3R1, AKT2

hsa05223: Non-small
12
MAPK1, NRAS, E2F3, KRAS, RXRB, SOS1, ARAF, RAF1, BAD, PIK3R1,

cell lung cancer

PRKCB, AKT2

hsa05214: Glioma
11
MAPK1, NRAS, E2F3, KRAS, SOS1, ARAF, RAF1, PTEN, PIK3R1, PRKCB,

AKT2

hsa05230: Central
10
MAPK1, NRAS, KRAS, G6PD, PFKL, RAF1, SIRT6, PTEN, PIK3R1, AKT2

carbon metabolism

in cancer

hsa04730: Long-term
9
GNA13, MAPK1, NRAS, KRAS, PPP2CB, ARAF, RAF1, PRKCB, ITPR2

depression

hsa05218: Melanoma
10
MAPK1, NRAS, E2F3, KRAS, ARAF, RAFI, BAD, PTEN, PIK3R1, AKT2

hsa05219: Bladder
6
MAPK1, NRAS, E2F3, KRAS, ARAF, RAF1

cancer

hsa04550: Signaling
16
SETDB1, IL6ST, RAF1, SMAD3, LIF, PCGF5, NRAS, MAPK1, KRAS,

pathways regulating

MAPK13, GSK3B, JAK2, TCF3, PIK3R1, AKT2, APC

pluripotency of stem

cells

hsa04726: Serotoner
8
MAPK1, NRAS, KRAS, ARAF, RAF1, PRKACB, PRKCB, ITPR2

gic synapse

Enrichment Score:

1.6875120920381086

GO: 0015035~protein
9
GLRX5, ENOX2, TXN2, GFER, CCS, TXNRD1, CHCHD4, GLRX2, GLRX

disulfide

oxidoreductase

activity

Redox-active center
12
TXNDC12, GLRX5, TXNDC11, TXN2, TMX3, TXNRDI, CHCHD4, PDIA4,

MIEN1, GLRX2, GLRX, MPST

domain: Glutaredoxin
4
GLRX5, TXNRD1, GLRX2, GLRX

IPR002109: Glutaredoxin
4
GLRX5, TXNRD1, GLRX2, GLRX

Enrichment Score:

1.6621257484122156

GO: 0006406~mRNA
24
NUP98, FIPIL1, NUP160, SMG5, U2AF2, ALYREF, NUP93, NUP85, NUP188,

export from

CASC3, NUP155, NDC1, NUP214, UPF3B, EIF4E, DDX19A, POLDIP3,

nucleus

NUP210, RBMX2, THOC6, SLU7, RANBP2, CPSF3, ALKBH5

GO: 0006405~RNA
12
NUP214, NUP98, EIF4E, UPF3B, POLDIP3, U2AF2, ALYREF, THOC6, SLU7,

export from nucleus

NUP188, CASC3, NUP155

GO: 0031124~mRNA
11
PCF11, FIP1L1, UPF3B, POLDIP3, U2AF2, ALYREF, THOC6, SLU7, CASC3,

3′-end processing

CPSF3, CSTF1

GO:0006369~termin
13
PCF11, FIPIL1, UPF3B, POLDIP3, U2AF2, ALYREF, THOC6, SLU7, LSM10,

ation of RNA

CASC3, CPSF3, CSTF1, TTF2

polymerase II

transcription

Enrichment Score:

1.6151522301062358

IPR012677: Nucleotide-
48
RALY, RBM33, ENOX2, U2AF2, SETDIA, KIAA0430, TMEM63A, ZNF638,

binding, alpha-

HNRNPLL, SART3, SF3B4, UHMK1, DNAJC17, R3HCCIL, AKAP17A, TIA1,

beta plait

TARDBP, PPIL4, MSI2, RBM10, RBM28, TNRC6A, RBM22, R3HCC1,

RBM42, RBM23, SREK1, ALYREF, ELAVL1, MTHFSD, SPEN, CSTF2T,

RCAN3, PPARGCIA, LARP4B, BRAP, SAFB2, TRNAUIAP, HNRNPH2,

UPF3B, POLDIP3, RBM18, PPRC1, RBMX2, DDX50, RBM19, RNPC3,

RBM15

SM00360: RRM
37
RALY, RBM33, ENOX2, U2AF2, KIAA0430, SETDIA, ZNF638, HNRNPLL,

SART3, SF3B4, UHMK1, TARDBP, TIA1, PPIL4, MSI2, RBM10, RBM28,

RBM22, RBM42, RBM23, SREK1, ALYREF, ELAVL1, MTHFSD, SPEN,

CSTF2T, PPARGCIA, SAFB2, TRNAUIAP, HNRNPH2, POLDIP3, RBM18,

PPRC1, RBMX2, RBM19, RNPC3, RBM15

IPR000504: RNA
38
RALY, RBM33, ENOX2, U2AF2, KIAA0430, SETDIA, ZNF638, HNRNPLL,

recognition motif

SART3, SF3B4, UHMK1, DNAJC17, TARDBP, TIA1, PPIL4, MSI2, RBM10,

domain

RBM28, RBM22, RBM42, RBM23, SREK1, ALYREF, ELAVL1, MTHFSD,

SPEN, CSTF2T, PPARGCIA, SAFB2, TRNAUIAP, HNRNPH2, POLDIP3,

RBM18, PPRC1, RBMX2, RBM19, RNPC3, RBM15

GO: 0000166~nucleotide
54
RALY, ENOX2, NT5C3A, U2AF2, KIAA0430, HINT2, HNRNPLL, ZNF638,

binding

SART3, DNAJC17, AKAP17A, TIA1, TARDBP, ORC4, RBM10, R3HCC1,

RBM42, SPEN, CSTF2T, PPARGCIA, BRAP, TRNAUIAP, RBMX2, REV3L,

RBM33, SETDIA, TMEM63A, SF3B4, TRIB2, EXOSC10, R3HCCIL, CHDIL,

PPIL4, MSI2, RBM28, TNRC6A, RBM22, RBM23, MOCS2, SREK1, ALYREF,

ELAVL1, MTHFSD, RCAN3, LARP4B, SAFB2, HNRNPH2, UPF3B, POLDIP3,

PPRC1, RBM18, RBM19, RNPC3, RBM15

domain: RRM
23
RBM22, RALY, RBM33, RBM42, ENOX2, SREK1, ALYREF, KIAA0430,

SETDIA, MTHFSD, CSTF2T, PPARGCIA, LARP4B, UHMK1, SAFB2,

DNAJC17, AKAP17A, POLDIP3, PPIL4, RBM18, PPRC1, RBMX2, TNRC6A

domain: RRM 2
19
RBM23, U2AF2, ELAVL1, ZNF638, HNRNPLL, SPEN, SART3, SF3B4,

TRNAUIAP, HNRNPH2, TARDBP, TIA1, CPNE1, RBM19, MSI2, RNPC3,

RBM10, RBM28, RBM15

domain: RRM 1
19
RBM23, U2AF2, ELAVL1, ZNF638, HNRNPLL, SPEN, SART3, SF3B4,

TRNAUIAP, HNRNPH2, TARDBP, TIA1, CPNEI, RBM19, MSI2, RNPC3,

RBM10, RBM28, RBM15

domain: RRM 3
10
HNRNPH2, TIA1, U2AF2, CPNE1, ELAVL1, RBM19, SPEN, HNRNPLL,

RBM28, RBM15

Enrichment Score:

1.6134569375887315

GO: 0006362~
10
TAFIB, TAF1C, POLRIE, CCNH, POLRIA, GTF2H3, TBP, CDK7, TWISTNB,

transcription elongation

ERCC3

from RNA

polymerase I

promoter

GO: 0006363~
10
TAFIB, TAFIC, POLRIE, CCNH, POLRIA, GTF2H3, TBP, CDK7, TWISTNB,

termination of RNA

ERCC3

polymerase I

transcription

GO: 0006361~
10
TAFIB, TAFIC, POLRIE, CCNH, POLRIA, GTF2H3, TBP, CDK7, TWISTNB,

transcription initiation

ERCC3

from RNA

polymerase I

promoter

GO: 0005675~holo
5
CCNH, GTF2F2, GTF2H3, CDK7, ERCC3

TFIIH complex

GO:0045815~positive
9
TAFIB, TAFIC, HIST4H4, EP300, POLRIE, POLRIA, H3F3A, TBP,

regulation of

TWISTNB

gene expression,

epigenetic

Enrichment Score:

1.611575588162036

GO: 0000178~exosome
10
DIS3, ZFP36, EXOSC10, EXOSC6, EXOSC7, EXOSC5, KHSRP, EXOSC3,

(RNase

SKIV2L2, MPHOSPH6

complex)

hsa03018: RNA
21
CNOT8, PAN3, PFKL, EXOSC6, EXOSC7, TTC37, EXOSC5, EXOSC3,

degradation

SKIV2L2, PAPD5, EXOSC10, DIS3, BTG2, CNOT6L, DCP2, DCP1A, LSM3,

MPHOSPH6, LSM1, TOB2, ZCCHC7

rRNA processing
20
EXOSC6, EXOSC7, EXOSC5, EXOSC3, LASIL, SKIV2L2, PAPD5, RBFA,

RPF1, EXOSC10, DIS3, CHD7, NOL11, WDR12, NAT10, TFBIM,

MPHOSPH6, UTP20, NSUN5, DDX51

GO: 0000176~nuclear
7
DIS3, EXOSC10, EXOSC6, EXOSC7, EXOSC5, EXOSC3, MPHOSPH6

exosome (RNase

complex)

GO: 0043928~
10
DIS3, CNOT8, EXOSC6, DCP2, EXOSC7, DCP1A, EXOSC5, EXOSC3, LSM3,

exonucleolytic nuclear-

LSM1

transcribed mRNA

catabolic process

involved in

deadenylation-

dependent decay

Exosome
6
DIS3, EXOSC10, EXOSC6, EXOSC7, EXOSC5, EXOSC3

GO: 0000175~3′-5′-
7
DIS3, EXOSC10, CNOT8, EXOSC7, EXOSC5, EXOSC3, ISG20L2

exoribonuclease

activity

GO:0000177~
5
DIS3, EXOSC6, EXOSC7, EXOSC5, EXOSC3

cytoplasmic exosome

(RNase complex)

GO: 0034475~U4
4
EXOSC6, EXOSC7, EXOSC5, EXOSC3

snRNA 3′-end

processing

GO: 0045006~DNA
3
EXOSC6, EXOSC5, EXOSC3

deamination

GO: 0071034~CUT
3
DIS3, EXOSC10, EXOSC3

catabolic process

GO: 0004532~
5
EXOSC10, EXOSC6, EXOSC7, EXOSC5, EXOSC3

exoribonuclease activity

GO:0034427~nuclear-
4
EXOSC6, EXOSC7, EXOSC5, EXOSC3

transcribed mRNA

catabolic process,

exonucleolytic, 3′-5′

GO:0071028~nuclear
4
EXOSC10, EXOSC6, EXOSC7, EXOSC5

mRNA

surveillance

GO: 0035327~
6
EXOSC10, PELP1, EXOSC5, TTC37, EXOSC3, CTR9

transcriptionally active

chromatin

GO:0071051~
3
EXOSC6, EXOSC5, EXOSC3

polyadenylation-

dependent snoRNA

3′-end processing

GO: 0016075~IRNA
4
DIS3, EXOSC6, EXOSC5, DEDD2

catabolic process

IPR027408: PNPase/
3
EXOSC6, EXOSC7, EXOSC5

RNase PH domain

GO: 0071035~nuclear
3
EXOSC10, EXOSC7, EXOSC3

polyadenylation-

dependent rRNA

catabolic process

IPR001247:
3
EXOSC6, EXOSC7, EXOSC5

Exoribonuclease,

phosphorolytic

domain 1

IPR015847:
3
EXOSC6, EXOSC7, EXOSC5

Exoribonuclease,

phosphorolytic

domain 2

Enrichment Score:

1.610351623898193

h_tnfr1Pathway: TN
12
TRAF2, TNFRSFIA, BAG4, LMNB2, MADD, JUN, RIPK1, MAP3K1, CASP8,

FR1 Signaling

MAP2K4, MAPK8, FADD

Pathway

h_fasPathway: FAS
11
LMNB2, CASP7, JUN, MAP3K1, CASP8, MAP2K4, RIPK2, MAPK8, FADD,

signaling pathway (CD95)

FAF1, DAXX

77.IkBa Kinase JN
4
JUN, MAP3K1, MAP2K4, MAPK8

K_MEKK1

Enrichment Score:

1.591424971929435

IPR002219: Protein
17
VAV3, ROCK1, ROCK2, PRKCI, PRKCH, RAF1, DGKH, MYO9B, PRKCD,

kinase C-like,

VAV1, PRKCB, PDZD8, DGKE, NSMCE1, ARAF, DGKZ, PRKD3

phorbol

ester/diacylglycerol

binding

SM00109: C1
16
VAV3, ROCK1, ROCK2, PRKCI, PRKCH, RAF1, DGKH, MYO9B, VAVI,

PRKCD, PRKCB, PDZD8, DGKE, ARAF, DGKZ, PRKD3

GO: 0004697~protein
6
PRKCI, PKN2, PRKCH, PRKCD, PRKD3, PRKCB

kinase C activity

zinc finger
7
DGKE, DGKZ, PRKCH, DGKH, PRKCD, PRKD3, PRKCB

region: Phorbol-

ester/DAG-type 2

zinc finger
7
DGKE, DGKZ, PRKCH, DGKH, PRKCD, PRKD3, PRKCB

region:Phorbol-

ester/DAG-type 1

IPR020454:
7
ARAF, PRKCI, PRKCH, RAF1, PRKCD, PRKD3, PRKCB

Diacylglycerol/phorbol-

ester binding

zinc finger
9
PDZD8, VAV3, ROCK1, ROCK2, ARAF, PRKCI, RAF1, MYO9B, VAVI

region: Phorbol-

ester/DAG-type

GO: 0030168~platelet
17
GNA13, VAV3, PRKCH, RAF1, DGKH, PRKCD, VAVI, SRF, FLNA, PRKCB,

activation

ITPR2, PLSCR1, MAPK1, DGKE, RACI, DGKZ, PIK3R1

Enrichment Score:

1.5519301743432432

h_PPARgPathway:
6
NCOA1, NCOA2, EP300, CREBBP, PPARGCIA, MED1

Role of PPAR-gamma

Coactivators in

Obesity and

Thermogenesis

IPR009110: Nuclear
4
NCOA1, NCOA2, EP300, CREBBP

receptor coactivator,

interlocking

GO: 0035257~nuclear
7
NCOA1, NCOA2, EP300, ACTN4, SNW1, NRIP1, MED1

hormone receptor

binding

h_vdrPathway:Contr
7
NCOA1, NCOA2, EP300, CREBBP, ACTL6A, TOP2B, MED1

ol of Gene

Expression by

Vitamin D Receptor

Enrichment Score:

1.5475594146838438

GO: 0042800~histone
8
DPY30, ASH2L, KMT2A, KMT2C, WDR5, SETDIA, ASHIL, CXXCI

methyltransferase

activity (H3-K4

specific)

hsa00310: Lysine
14
SETDB1, DLST, EHMT1, KMT2A, KMT2C, SETDIA, OGDH, ACAT2,

degradation

COLGALT1, ALDH3A2, WHSCIL1, ASHIL, PHYKPL, ALDH9A1

GO: 0051568~histone
8
DPY30, ASH2L, KMT2A, KMT2C, WDR5, SETDIA, ASHIL, CXXC1

H3-K4

methylation

Methyltransferase
33
KMT2A, EZH1, KMT2C, MGMT, TRMT2B, SETDIA, VCPKMT, ASH2L,

METTL3, ASMTL, NSUN3, NSUN5, SETDB1, DNMT3A, EHMTI, METTL6,

METTL2A, METTL2B, METTL 12, METTL13, KDM2A, JMJD6, TRMT13,

WHSCIL1, MTR, ASHIL, SETD6, PCMTD1, PRDM2, TFBIM, SETD4,

METTL17, COMTD1

GO: 0018024~histone-
11
SETDB1, DPY30, EHMT1, ASH2L, KMT2A, EZH1, KMT2C, WDR5,

lysine N-

WHSCIL1, SETDIA, PRDM2

methyltransferase

activity

domain:Post-SET
6
SETDB1, KMT2A, KMT2C, WHSCIL1, SETDIA, ASHIL

IPR003616:Post-
6
SETDB1, KMT2A, KMT2C, WHSCIL1, SETDIA, ASHIL

SET domain

GO:0048188~Set1C
5
DPY30, ASH2L, WDR5, SETDIA, CXXC1

/COMPASS

complex

S-adenosy1-L-
28
KMT2A, KMT2C, EZH1, TRMT2B, SETDIA, RSAD2, VCPKMT, METTL3,

methionine

TYW1, ASMTL, LIAS, NSUN3, CDK5RAP1, NSUN5, SETDB1, DNMT3A,

EHMT1, METTL2A, METTL2B, TRMT13, WHSCIL1, MTR, ASHIL, SETD6,

PRDM2, TFB1M, SETD4, COMTD1

domain: SET
11
SETDB1, EHMT1, KMT2A, EZH1, KMT2C, WHSCIL1, SETDIA, ASHIL,

SETD6, PRDM2, SETD4

GO: 0035097~histone
7
DPY30, ASH2L, KMT2A, KMT2C, WDR5, SETDIA, CXXC1

methyltransferase

complex

SM00317:SET
9
SETDB1, EHMT1, KMT2A, EZH1, KMT2C, WHSCIL1, SETDIA, ASHIL,

PRDM2

IPR001214:SET
11
SETDB1, EHMT1, KMT2A, EZH1, KMT2C, WHSCIL1, SETDIA, ASHIL,

domain

SETD6, PRDM2, SETD4

GO: 0018026~peptidyl-
4
EHMT1, KMT2A, SETD6, SETD4

lysine

monomethylation

GO: 0044666~MLL3/4
4
DPY30, ASH2L, KMT2C, WDR5

complex

region: PHD-type 3

zinc finger
4
KMT2A, KMT2C, WHSCIL1, KDM5B

region: PHD-type 3

SM00508: PostSET
4
KMT2A, KMT2C, WHSCIL1, SETDIA

GO: 0034968~histone
4
SETDB1, WHSCIL1, SETD6, PRDM2

lysine methylation

Enrichment Score:

1.4904218811914152

h_ceramidePathway:
15
TRAF2, AIFM1, RELA, MAP2K4, RAF1, FADD, BAD, MAPK1, TNFRSFIA,

Ceramide Signaling

MAP3K1, BCL2, RIPK1, CASP8, MAPK8, NSMAF

Pathway

GO: 0071550~death-
6
TRAF2, TNFRSFIA, RIPK1, CASP8, RAF1, FADD

inducing signaling

complex assembly

GO: 0097296~activation
7
TNFRSF10A, TRAF2, RIPK1, CASP8, SMAD3, FADD, JAK2

of cysteine-type

endopeptidase

activity involved in

apoptotic signaling

pathway

h_tnfr1Pathway: TN
12
TRAF2, TNFRSFIA, BAG4, LMNB2, MADD, JUN, RIPK1, MAP3K1, CASP8,

FR1 Signaling

MAP2K4, MAPK8, FADD

Pathway

GO: 0005123~death
7
CASP8AP2, MADD, RIPK1, CASP8, FADD, TMBIM1, FEMIB

receptor binding

GO: 0010803~
10
TRAF1, TRAF2, TNFRSFIA, HIPK1, MADD, RIPK1, CASP8, PYCARD,

regulation of tumor

RBCK1, CHUK

necrosis factor-

mediated signaling

pathway

GO: 1902041~
7
TNFRSF10A, TRAF2, MADD, RIPKI, CASP8, FADD, FEMIB

regulation of extrinsic

apoptotic signaling

pathway via death

domain receptors

GO: 1902042~
10
TNFRSF10A, ICAM1, TRAF2, GPX1, RIPK1, CASP8, RAF1, FADD, TMBIMI,

negative regulation of

RFFL

extrinsic apoptotic

signaling pathway

via death domain

receptors

h_soddPathway: SO
6
TRAF2, TNFRSFIA, BAG4, RIPKI, CASP8, FADD

DD/TNFR1

Signaling Pathway

99.NF-
9
IRAK1, TRAF2, TNFRSFIA, RELA, BCL2, CREBBP, FADD, MAP3K14,

kB activation

TRAF5

h_deathPathway:
11
TNFRSF10A, TRAF2, XIAP, CASP7, RELA, RIPK1, BCL2, CASP8, FADD,

Induction of apoptosis

MAP3K14, CHUK

through DR3 and

DR4/5 Death

Receptors

h_relaPathway:
7
TNFRSF1A, EP300, RELA, RIPK1, CREBBP, FADD, CHUK

Acetylation and

Deacetylation of

RelA in The

Nucleus

GO: 0036462~TRAIL-
3
TNFRSF10A, CASP8, FADD

activated

apoptotic signaling

pathway

GO: 0045651~positive
5
LIF, CSF1, RIPK1, CASP8, FADD

regulation of

macrophage

differentiation

h_nfkbPathway: NF-
8
IRAK1, TNFRSFIA, RELA, RIPK1, MAP3K1, FADD, MAP3K14, CHUK

kB Signaling

Pathway

GO: 2001238~positive
7
TRAF2, RIPK1, PML, PYCARD, RBCKI, FADD, DEDD2

regulation of

extrinsic apoptotic

signaling pathway

46.P13K PTEN
6
TNFRSF1A, CASP7, BCL2, CASP8, FADD, BAD

GO: 0035666~TRIF-
7
LY96, RIPK1, CASP8, FADD, IRF3, CHUK, TRAF3

dependent toll-like

receptor signaling

pathway

40.Deg_of_Chrom
5
TRAF2, TNFRSFIA, RIPK1, CASP8, FADD

DNA TNF-

ind_apoptosis

44.Sig_Trans_TNFR
4
TRAF2, RIPK1, CASP8, FADD

1-DR3-DR4 DR5

GO: 0010939~
4
PPIF, TRAF2, RIPK1, CASP8

regulation of necrotic cell

death

domain: Death
7
TNFRSF10A, IRAK4, TNFRSFIA, MADD, RIPKI, FADD, MALT1

GO: 0031264~death-
3
RIPK1, CASP8, FADD

inducing signaling

complex

GO: 0097342~
3
RIPK1, CASP8, FADD

ripoptosome

72.IAP interaction
5
TNFRSF1A, XIAP, CASP7, CASP8, FADD

with_cell death_pathways

IPR011029: Death-
12
TNFRSF10A, IRAK4, IRAK1, TNFRSFIA, CARD16, RIPK1, CASP8,

like domain

PYCARD, RIPK2, FADD, MALT1, DEDD2

150.caspase_and_N
5
TNFRSF1A, RELA, RIPK1, CASP8, FADD

FKB activation

IPR000488: Death
5
TNFRSF10A, IRAK1, TNFRSFIA, RIPKI, FADD

domain

SM00005: DEATH
4
TNFRSF10A, TNFRSFIA, RIPKI, FADD

Enrichment Score:

1.45222941807591

domain: VHS
5
STAM2, HGS, STAM, GGA1, GGA3

SM00288: VHS
5
STAM2, HGS, STAM, GGA1, GGA3

IPR002014: VHS
5
STAM2, HGS, STAM, GGA1, GGA3

GO: 0033565~
3
STAM2, HGS, STAM

ESCRT-0 complex

repeat: UIM
4
RNF166, STAM2, HGS, STAM

IPR008942: ENTH/
7
PCF11, CHERP, STAM2, HGS, STAM, GGA1, GGA3

VHS

IPR003903: Ubiquitin
6
STAM2, ZFAND2B, HGS, DNAJB2, STAM, UIMC1

interacting motif

GO: 0042059~negative
8
RNF126, RNF115, TSG101, AP2A1, STAM2, CBL, HGS, STAM

regulation of

epidermal growth

factor receptor

signaling pathway

Enrichment Score:

1.419973773347531

hsa04130: SNARE
12
SNAP29, BNIP1, STX17, BET1, VAMP5, USE1, SEC22B, BETIL, SNAP23,

interactions in

VAMP2, STX10, YKT6

vesicular transport

GO: 0061025~
13
SNAP29, DNM3, RABIF, UBXN2A, UBXN2B, STX17, USO1, CHP1, BETIL,

membrane fusion

NAPA, SNAP23, VAMP2, STX10

GO: 0031201~SNAR
14
SNAP29, BET1, STXBP2, NAPA, SNX4, BNIP1, STX17, VAMP5, SEC22B,

E complex

BETIL, VAMP2, SNAP23, STX10, YKT6

GO: 0005484~SNAP
10
SNAP29, BNIP1, STX17, VAMP5, SEC22B, BETIL, SNAP23, VAMP2, STX10,

receptor activity

YKT6

IPR000727: Target
6
SNAP29, STX17, BET1, BETIL, SNAP23, STX10

SNARE coiled-coil

domain

domain: t-SNARE
5
SNAP29, STX17, BET1, BETIL, STX10

coiled-coil

homology

SM00397: t SNARE
5
SNAP29, STX17, BET1, SNAP23, STX10

GO: 0019905~syntax
9
SNAP29, SYT11, BET1, SEC22B, NAPA, SYTL3, SNAP23, VAMP2, STX10

in binding

Enrichment Score:

1.4061663679110412

h_41BBPathway: The
9
TRAF2, TNFRSF9, RELA, JUN, MAP3K1, IFNG, MAPK8, CHUK, IL2

4-1BB-dependent

immune response

h_tall1Pathway: TA
8
TRAF2, TNFSF13B, RELA, MAPK8, MAP3K14, TRAF5, CHUK, TRAF3

CI and BCMA

stimulation of B cell

immune responses.

h_stressPathway: TN
10
TRAF2, TNFRSFIA, RELA, JUN, RIPK1, MAP3K1, MAP2K4, MAPK8,

F/Stress Related

MAP3K14, CHUK

Signaling

h_tnfr2Pathway: TN
8
TRAF1, TRAF2, RELA, RIPK1, MAP3K1, MAP3K14, CHUK, TRAF3

FR2 Signaling

Pathway

h_nfkbPathway: NF-
8
IRAK1, TNFRSFIA, RELA, RIPK1, MAP3K1, FADD, MAP3K14, CHUK

kB Signaling

Pathway

h_tollPathway: Toll-
11
IRAK1, FOS, LY96, RELA, JUN, MAP3K1, MAP2K4, MAPK8, MAP3K14,

Like Receptor

ECSIT, CHUK

Pathway

h_cd40Pathway: CD
5
RELA, MAP3K1, MAP3K14, CHUK, TRAF3

40L Signaling

Pathway

h_illrPathway: Signal
8
IRAK1, RELA, JUN, MAP3K1, MAPK8, MAP3K14, ECSIT, CHUK

transduction

through ILIR

h_rnaPathway: Double
3
RELA, MAP3K14, CHUK

Stranded RNA

Induced Gene

Expression

Enrichment Score:

1.3724915407975329

GO: 0000781~
12
DPY30, TP53BP1, NSMCE1, SMC5, NSMCE2, SMC6, TINF2, SIRT2, TERF2,

chromosome, telomeric

ATM, CDK2, TERFI

region

GO: 0090398~cellular
8
ULK3, PML, SMC5, NSMCE2, SMC6, PRKCD, SRF, TERF2

senescence

GO: 0030915~Smc5-
4
NSMCE1, SMC5, NSMCE2, SMC6

Smc6 complex

Telomere
8
NSMCE1, SMC5, NSMCE2, SMC6, TINF2, TERF2, RAD50, TERFI

GO: 0000722~telomere
7
RPA1, RAD51C, RFC2, SMC5, NSMCE2, SMC6, RAD50

maintenance via

recombination

Enrichment Score:

1.3688179640343465

Biological rhythms
25
ENOX2, KMT2A, ROCK2, CREB1, KLF10, CREBBP, PML, RORA,

PPARGCIA, PPP1CB, NRIP1, EP300, NCOA2, SIN3A, SP1, CSNKID,

METTL3, CSNKIE, GSK3B, GFPT1, MAPK8, PRKAA1, KDM5B, FBXW11,

KDM5C

GO:0042752~
10
CSNKID, CSNKIE, ROCK2, CREB1, KLF10, PML, PRKAA1, MAPK8,

regulation of circadian

PPARGCIA, PPP1CB

rhythm

GO: 0032922~
10
NCOA2, CSNKID, KMT2A, CSNKIE, GFPT1, PML, RORA, PPARGCIA,

circadian regulation of

PPP1CB, NRIP1

gene expression

Enrichment Score:

1.341911280785786

repeat: RCC1 1
7
IBTK, SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

repeat: RCC1 2
7
IBTK, SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

repeat: RCC1 3
7
IBTK, SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

IPR000408: Regulator
7
IBTK, SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

of chromosome

condensation, RCC1

IPR009091: Regulator
7
IBTK, SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

of chromosome

condensation 1/beta-

lactamase-inhibitor

protein II

repeat: RCC1 5
6
SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

repeat: RCC1 4
6
SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

Cell division and
7
IBTK, SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

chromosome

partitioning /

Cytoskeleton

repeat :RCC1 7
3
SERGEF, RCC2, HERC2

repeat: RCC1 6
3
SERGEF, RCC2, HERC2

Enrichment Score:

1.3338979660581836

SM00490: HELICc
21
BTAF1, DICER1, INO80, SKIV2L2, TTF2, CHD9, RECQL, CHD7, CHDIL,

DHX29, DDX23, DDX19A, DHX34, DDX50, DHX16, DDX10, CHD6, ERCC3,

SMARCA2, DDX51, DDX42

domain: Helicase C-
21
BTAF1, DICER1, INO80, SKIV2L2, TTF2, CHD9, RECQL, CHD7, CHDIL,

terminal

DHX29, DDX23, DDX19A, DHX34, DDX50, DHX16, DDX10, CHD6, ERCC3,

SMARCA2, DDX51, DDX42

SM00487: DEXDc
21
BTAF1, DICER1, INO80, SKIV2L2, TTF2, CHD9, RECQL, CHD7, CHDIL,

DHX29, DDX23, DDX19A, DHX34, DDX50, DHX16, DDX10, CHD6, ERCC3,

SMARCA2, DDX51, DDX42

Helicase
25
BTAF1, DICER1, INO80, HELZ, SKIV2L2, CHD9, MOV10, CHDIL, CHD7,

DDX23, DDX19A, DHX34, DHX16, DDX10, ERCC3, CHD6, DDX42, TTF2,

MCM6, RECQL, DHX29, GTF2F2, DDX50, SMARCA2, DDX51

IPR001650: Helicase,
21
BTAF1, DICER1, INO80, SKIV2L2, TTF2, CHD9, RECQL, CHD7, CHDIL,

C-terminal

DHX29, DDX23, DDX19A, DHX34, DDX50, DHX16, DDX10, CHD6, ERCC3,

SMARCA2, DDX51, DDX42

IPR014001: Helicase,
21
BTAF1, DICER1, INO80, SKIV2L2, TTF2, CHD9, RECQL, CHD7, CHDIL,

superfamily ½,

DHX29, DDX23, DDX19A, DHX34, DDX50, DHX16, DDX10, CHD6, ERCC3,

ATP-binding

SMARCA2, DDX51, DDX42

domain

domain: Helicase
21
BTAF1, DICER1, INO80, SKIV2L2, TTF2, CHD9, RECQL, CHD7, CHDIL,

ATP-binding

DHX29, DDX23, DDX19A, DHX34, DDX50, DHX16, DDX10, CHD6, ERCC3,

SMARCA2, DDX51, DDX42

GO: 0004386~helicase
17
BTAF1, DICER1, ANXA1, HELZ, CHD9, MOV10, CHD7, DDX23, DDX19A,

activity

GTF2F2, DHX34, DDX50, DDX10, ERCC3, SMARCA2, DDX51, DDX42

IPR000330: SNF2-
8
CHD9, BTAF1, CHD7, CHDIL, INO80, CHD6, SMARCA2, TTF2

related

GO: 0008026~ATP-
7
RECQL, CHDIL, DDX23, DHX29, DHX16, CHD6, TTF2

dependent helicase

activity

IPR011545: DNA/R
12
RECQL, DDX23, DHX29, DDX19A, DICER1, DHX34, DDX50, DHX16,

NA helicase,

SKIV2L2, DDX10, DDX51, DDX42

DEAD/DEAH box

type, N-terminal

IPR002464: DNA/RANA
5
CHDIL, DHX29, DHX16, CHD6, TTF2

helicase, ATP-

dependent, DEAH-

box type, conserved

site

short sequence
7
CHD9, CHD7, CHDIL, DHX29, DHX16, CHD6, TTF2

motif: DEAH box

GO: 0004004~ATP-
9
DDX23, DHX29, DDX19A, DHX34, DDX50, DHX16, DDX10, DDX51,

dependent RNA

DDX42

helicase activity

Enrichment Score:

1.3229064054856214

domain: PCI
7
PSMD13, PSMD12, PCID2, COPS7A, PSMD3, COPS7B, COPS8

IPR000717: Proteasome
6
PSMD13, PSMD12, PCID2, COPS7A, PSMD3, COPS7B

component (PCI)

domain

GO: 0022624~proteasome
6
PSMD13, PSMC5, PSMD12, PSMC2, PSMD3, PSMD5

accessory

complex

SM00088: PINT
5
PSMD13, PSMD12, COPS7A, PSMD3, COPS7B

GO:0008541~
3
PSMD13, PSMD12, PSMD3

proteasome regulatory

particle, lid

subcomplex

Enrichment Score:

1.318551447098944

Iron-sulfur
13
GLRX5, TYW1, NDUFV2, IREB2, RSAD2, LIAS, UQCRFS1, CDK5RAP1,

CIAPINI, NDUFS1, PPAT, GLRX2, REV3L

2Fe-2S
6
GLRX5, NDUFV2, UQCRFS1, CIAPIN1, NDUFS1, GLRX2

GO: 0051537~2 iron,
6
GLRX5, NDUFV2, UQCRFS1, CIAPINI, NDUFS1, GLRX2

2 sulfur cluster

binding

Enrichment Score:

1.309987729796792

IPR016159: Cullin
6
CUL3, CUL2, EXOC7, CACUL1, VPS51, CUL4B

repeat-like-

containing domain

IPR001373: Cullin,
5
CUL3, CUL2, CACULI, CUL9, CUL4B

N-terminal

IPR016157: Cullin,
4
CUL3, CUL2, CUL9, CUL4B

conserved site

SM00884: SM00884
4
CUL3, CUL2, CUL9, CUL4B

IPR019559: Cullin
4
CUL3, CUL2, CUL9, CUL4B

protein, neddylation

domain

IPR016158: Cullin
4
CUL3, CUL2, CUL9, CUL4B

homology

GO: 0031461~cullin-
4
CUL3, CUL2, CUL9, CAND1

RING ubiquitin

ligase complex

cross-link: Glycyl
3
CUL3, CUL2, CUL4B

lysine isopeptide

(Lys-Gly)

(interchain with G-

Cter in NEDD8)

SM00182: CULLIN
3
CUL3, CUL2, CUL4B

Enrichment Score:

1.3095823857533413

zinc finger
6
YAF2, RYBP, RBCK1, MDM4, RBM10, TAB3

region: RanBP2-type

IPR001876: Zinc
7
YAF2, RYBP, RBCK1, MDM4, RANBP2, RBM10, TAB3

finger, RanBP2-type

SM00547: ZnF RBZ
6
YAF2, RYBP, RBCK1, RANBP2, RBM10, TAB3

Enrichment Score:

1.3076994990472324

active site: Glycyl
18
UBE2A, UBE2Z, UBE2G1, HERC6, UBE2J1, HERC5, BIRC6, UBA5, HERC2,

thioester

UBE2J2, UBE2R2, UBE2D4, UBA3, UBE2W, SMURF2, HECTD4, HECTD1,

intermediate

UBE2E1

repeat: RCC1 5
6
SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

repeat: RCC1 4
6
SERGEF, RCC2, HERC6, HERC5, HERC2, MYCBP2

domain: HECT
6
HERC6, HERC5, HECTD4, SMURF2, HERC2, HECTD1

SM00119: HECTc
6
HERC6, HERC5, HECTD4, SMURF2, HERC2, HECTD1

IPR000569: HECT
6
HERC6, HERC5, HECTD4, SMURF2, HERC2, HECTD1

Enrichment Score:

1.303394556655991

h_metPathway: Sign
13
MAP4K1, RAF1, ITGB1, PTEN, FOS, MAPK1, CRKL, SOS1, JUN, MAPK8,

aling of Hepatocyte

RAPGEF1, RASA1, PIK3R1

Growth Factor

Receptor

h_integrinPathway:
11
MAPK1, CAPNS1, CRKL, ROCK1, JUN, SOS1, RAF1, MAPK8, ZYX,

Integrin Signaling

RAPGEF1, ITGB1

Pathway

hsa04510: Focal
27
XIAP, ITGB1, PTEN, SOS1, BCL2, ILK, RACI, ZYX, RAPGEF1, PIK3R1,

adhesion

AKT2, PARVG, VAV3, ACTN4, ROCK1, ROCK2, RAF1, BAD, VAVI,

PPP1CB, FLNA, PRKCB, MAPK1, CRKL, JUN, GSK3B, MAPK8

Enrichment Score:

1.3018570193497914

GO: 0000175~3′-5′-
7
DIS3, EXOSC10, CNOT8, EXOSC7, EXOSC5, EXOSC3, ISG20L2

exoribonuclease

activity

GO: 0090503~RNA
8
DIS3, EXOSC10, CNOT8, PAN3, CNOT6L, DCP2, EXOSC5, ISG20L2

phosphodiester bond

hydrolysis,

exonucleolytic

Exonuclease
9
DIS3, EXOSC10, RADI, CNOT8, CNOT6L, AEN, REXO1, ERI3, ISG20L2

Enrichment Score:

1.3001157372818273

domain: J
12
DNAJC17, DNAJC15, DNAJC16, DNAJB9, DNAJC11, SACS, DNAJC5,

DNAJB2, HSCB, DNAJB6, DNAJC30, GAK

IPR001623: DnaJ
12
DNAJC17, DNAJC15, DNAJC16, DNAJB9, DNAJC11, SACS, DNAJC5,

domain

DNAJB2, HSCB, DNAJB6, DNAJC30, GAK

SM00271: DnaJ
10
DNAJC17, DNAJC15, DNAJC16, DNAJB9, DNAJC11, DNAJC5, DNAJB2,

DNAJB6, DNAJC30, GAK

IPR018253: DnaJ
6
DNAJC16, DNAJB9, DNAJC11, DNAJC5, DNAJB2, DNAJB6

domain, conserved

site

Enrichment Score:

1.296835482359286

hsa04130: SNARE
12
SNAP29, BNIP1, STX17, BET1, VAMP5, USE1, SEC22B, BETIL, SNAP23,

interactions in

VAMP2, STX10, YKT6

vesicular transport

GO: 0005484~SNAP
10
SNAP29, BNIP1, STX17, VAMP5, SEC22B, BETIL, SNAP23, VAMP2, STX10,

receptor activity

YKT6

domain: v-SNARE
4
VAMP5, SEC22B, VAMP2, YKT6

coiled-coil

homology

IPR001388: Synapto
4
VAMP5, SEC22B, VAMP2, YKT6

brevin

GO:0000149~SNARE
7
GABARAPL2, STX17, VAMP5, SEC22B, SNAPIN, VAMP2, YKT6

binding

Enrichment Score:

1.2920732660982135

GO:0016578~histone
6
TAF10, USP3, USP22, TRRAP, USP16, USP34

deubiquitination

zinc finger
5
USP3, USP5, USP22, USP16, BRAP

region: UBP-type

IPR001607: Zinc
5
USP3, USP5, USP22, USP16, BRAP

finger, UBP-type

SM00290: ZnF UBP
4
USP3, USP5, USP16, BRAP

Enrichment Score:

1.271806287569803

GO:0042809~vitamin
6
MED16, MED17, SNW1, MED13, TOB2, MED1

D receptor binding

GO:0046966~thyroid
8
HMGN3, MED16, MED17, JMJDIC, MED13, GTF2B, MED1, ZNHIT3

hormone receptor

binding

GO: 0016592~mediator
9
MED31, MED19, MED16, MED8, MED17, MED11, MED13, MED13L, MED1

complex

GO: 0030518~
4
MED16, MED17, MED13, MED1

intracellular steroid

hormone receptor

signaling pathway

Enrichment Score:

1.271330707752596

zinc finger
3
BRF1, BRF2, GTF2B

region: TFIIB-type

IPR000812:
3
BRF1, BRF2, GTF2B

Transcription factor TFIIB

IPR013137: Zinc
3
BRF1, BRF2, GTF2B

finger, TFIIB-type

IPR013763:Cyclin-
9
CCNT2, BRF1, BRF2, CCNH, CCNT1, CCNG1, CCNG2, GTF2B, CASD1

like

Enrichment Score:

1.269935983244461

h_tcrPathway: T Cell
18
PTPN7, RELA, CD247, MAP2K4, RAF1, VAVI, PRKCB, FOS, JUN, MAP3K1,

Receptor Signaling

SOS1, RAC1, ZAP70, PPP3CB, MAPK8, NFATC2, RASA1, PIK3R1

Pathway

h_gleevecPathway:I
11
FOS, CRKL, JUN, SOS1, MAP3K1, MAP2K4, RAF1, MAPK8, JAK2, BAD,

nhibition of Cellular

PIK3R1

Proliferation by

Gleevec

h_fcer1Pathway: Fc
14
MAP2K4, RAF1, VAVI, PRKCB, MAPK1, FOS, MAP3K1, SOS1, JUN,

Epsilon Receptor I

PPP3CB, MAPK8, NFATC2, MAP2K7, PIK3R1

Signaling in Mast

Cells

h_egfPathway: EGF
11
FOS, JUN, SOS1, MAP3K1, MAP2K4, RAF1, MAPK8, SRF, PIK3R1, RASA1,

Signaling Pathway

PRKCB

h_metPathway:
13
MAP4K1, RAF1, ITGB1, PTEN, FOS, MAPK1, CRKL, SOS1, JUN, MAPK8,

Signaling of Hepatocyte

RAPGEF1, RASA1, PIK3R1

Growth Factor

Receptor

h_pdgfPathway: PD
11
FOS, JUN, SOS1, MAP3K1, MAP2K4, RAF1, MAPK8, SRF, PIK3R1, RASA1,

GF Signaling

PRKCB

Pathway

h_arenrf2Pathway:
9
MAPK1, FOS, JUN, CREB1, AKR7A2, MAPK8, KEAP1, NFE2L2, PRKCB

Oxidative Stress

Induced Gene

Expression Via Nrf2

h_bcrPathway: BCR
12
FOS, JUN, SOS1, MAP3K1, RAC1, PPP3CB, RAF1, MAPK8, CD79B,

Signaling Pathway

NFATC2, VAVI, PRKCB

h_pyk2Pathway:
10
MAPK1, CRKL, JUN, SOS1, MAP3K1, RAC1, MAP2K4, RAF1, MAPK8,

Links between Pyk2

PRKCB

and Map Kinases

h_insulinPathway:
8
FOS, JUN, SOS1, RAF1, MAPK8, SRF, PIK3R1, RASA1

Insulin Signaling

Pathway

h_igf1Pathway: IGF-
8
FOS, JUN, SOS1, RAF1, MAPK8, SRF, PIK3R1, RASA1

1 Signaling Pathway

hsa04912: GnRH
17
ADCY7, MAP2K4, RAF1, PRKCD, PRKCB, ITPR2, NRAS, MAPK1, KRAS,

signaling pathway

MAP3K3, MAPK13, JUN, MAP3K1, SOS1, MAPK8, PRKACB, MAP2K7

h_at1rPathway:
10
MAPK1, MEF2A, JUN, SOS1, MAP3K1, RACI, MAP2K4, RAF1, MAPK8,

Angiotensin II mediated

PRKCB

activation of JNK

Pathway via Pyk2

dependent signaling

h_malPathway: Role
7
MAPK1, ROCK1, MAP3K1, RACI, RAF1, MAPK8, SRF

of MAL in Rho-

Mediated Activation

of SRF

h_tpoPathway: TPO
8
FOS, JUN, SOS1, RAF1, JAK2, PIK3R1, RASA1, PRKCB

Signaling Pathway

102.Cholesterol
4
MAP3K1, RAC1, RAF1, MAPK8

Stress Response

67.Ikaros_and_
9
MAPK1, FOS, CD8A, JUN, SOS1, RAF1, NFATC2, VAVI, IL2

signaling inhibitors

h_i16Pathway: IL 6
7
FOS, IL6ST, JUN, SOS1, RAF1, JAK2, SRF

signaling pathway

h_cdmacPathway:Ca
6
MAPK1, FOS, RELA, JUN, RAF1, PRKCB

dmium induces

DNA synthesis and

proliferation in

macrophages

h_ccr5Pathway:
6
FOS, CXCR4, JUN, MAPK8, CCL4, PRKCB

Pertussis toxin-

insensitive CCR5

Signaling in

Macrophage

h_il2Pathway: IL 2
7
FOS, IL2RB, JUN, SOS1, RAF1, MAPK8, IL2

signaling pathway

h_crebPathway:
8
MAPK1, PRKAR2A, CREB1, SOS1, RAC1, PRKACB, PIK3R1, PRKCB

Transcription factor

CREB and its

extracellular signals

h_ghPathway:
8
MAPK1, SOS1, SOCS1, RAF1, JAK2, SRF, PIK3R1, PRKCB

Growth Hormone

Signaling Pathway

68.Mitogen_signalin
4
MAPK1, SOS1, MAP3K1, RAF1

g in growth_control

GO: 0051090~
6
MAPK1, FOS, TAF6, CREBZF, JUN, MAPK8

regulation of sequence-

specific DNA

binding transcription

factor activity

h_epoPathway: EPO
6
FOS, JUN, SOS1, RAF1, MAPK8, JAK2

Signaling Pathway

77.IkBa Kinase JN
4
JUN, MAP3K1, MAP2K4, MAPK8

K MEKK1

h_ngfPathway: Nerve
6
FOS, JUN, SOS1, RAF1, MAPK8, PIK3R1

growth factor

pathway (NGF)

3.T_cell receptor
7
FOS, JUN, CTLA4, ZAP70, MAPK8, VAV1, IL2

GO: 0035994~response
4
FOS, RELA, JUN, RAF1

to muscle stretch

100.MAPK_signalin
7
MAPK1, MAP3K3, MAP3K1, MAP2K4, RAF1, MAPK8, MAP2K7

g_cascades

h_il3Pathway:IL 3
4
FOS, SOS1, RAF1, JAK2

signaling pathway

GO: 0061029~eyelid
3
JUN, SOS1, SRF

development in

camera-type eye

h_trkaPathway: Trka
3
SOS1, PIK3R1, PRKCB

Receptor Signaling

Pathway

Enrichment Score:

1.263372828431808

h_tall1Pathway: TACI
8
TRAF2, TNFSF13B, RELA, MAPK8, MAP3K14, TRAF5, CHUK, TRAF3

and BCMA

stimulation of B cell

immune responses.

h_tnfr2Pathway: TN
8
TRAF1, TRAF2, RELA, RIPK1, MAP3K1, MAP3K14, CHUK, TRAF3

FR2 Signaling

Pathway

GO: 0031996~
6
TRAF1, TRAF2, RAC1, ARF6, TRAF5, TRAF3

thioesterase binding

IPR012227:TNF
4
TRAF1, TRAF2, TRAF5, TRAF3

receptor-associated

factor TRAF

PIRSF015614: TNF
4
TRAF1, TRAF2, TRAF5, TRAF3

receptor-associated

factor (TRAF)

domain: MATH
5
TRAF1, TRAF2, TRAF5, SPOP, TRAF3

SM00061: MATH
5
TRAF1, TRAF2, TRAF5, SPOP, TRAF3

IPR002083: MATH
5
TRAF1, TRAF2, TRAF5, SPOP, TRAF3

zinc finger
3
TRAF2, TRAF5, TRAF3

region: TRAF-type 1

zinc finger
3
TRAF2, TRAF5, TRAF3

region: TRAF-type 2

GO: 0005164~tumor
7
TRAF1, TRAF2, TRAP1, TNFSF13B, CASP8, FADD, TRAF3

necrosis factor

receptor binding

GO: 0035631~CD40
4
TRAF2, TRAF5, CHUK, TRAF3

receptor complex

IPR008974: TRAF-
6
TRAF1, TRAF2, XAF1, TRAF5, SPOP, TRAF3

like

IPR001293: Zinc
4
TRAF2, XAF1, TRAF5, TRAF3

finger, TRAF-type

51.CD40_and_EBV
4
TRAF1, TRAF2, MAPK8, TRAF3

IPR018957: Zinc
5
MKRN1, TRAF2, PEX2, TRAF5, TRAF3

finger, C3HC4

RING-type

Enrichment Score:

1.261550763230275

DNA-binding
5
PDS5B, KMT2A, ASHIL, MECP2, BAZ2A

region: A. T hook 2

DNA-binding
5
PDS5B, KMT2A, ASHIL, MECP2, BAZ2A

region: A. T hook 1

DNA-binding
4
PDS5B, KMT2A, ASHIL, BAZ2A

region: A.T hook 3

Enrichment Score:

1.2578929146832885

Redox-active center
12
TXNDC12, GLRX5, TXNDC11, TXN2, TMX3, TXNRDI, CHCHD4, PDIA4,

MIEN1, GLRX2, GLRX, MPST

GO: 0045454~cell
17
TMX2, GLRX5, TXN2, AIFM1, TMX3, TXNDC9, PDIA4, GLRX2, GPX1,

redox homeostasis

TXNDC12, TXNDC11, DNAJC16, KRITI, TXNRD1, NFE2L2, SCO2, GLRX

IPR012336: Thiored
24
TMX2, GLRX5, TXN2, MRPS25, TMX3, TXNDC9, PDIA4, CLIC1, AAED1,

oxin-like fold

MIEN1, GLRX2, GPX1, SH3BGRL, TXNDC12, TXNDC11, DNAJC16,

EEF1E1, NDUFV2, FAF2, TXNRD1, FAF1, GPX7, SCO2, GLRX

IPR013766: Thioredoxin
9
TMX2, TXNDC12, TXNDC11, DNAJC16, TXN2, TMX3, TXNDC9, PDIA4,

domain

SCO2

domain: Thioredoxin
6
TMX2, DNAJC16, TXN2, TMX3, TXNDC9, SCO2

GO: 0005623~cell
13
TMX2, TXNDC11, DNAJC16, AIFM1, TXN2, NELL2, TMX3, MCPH1,

SLC41A1, TXNRD1, PDIA4, XCL1, GLRX2

Enrichment Score:

GO: 0035267~NuA4
6
ING3, ACTL6A, TRRAP, KAT5, MRGBP, BRD8

histone

acetyltransferase

complex

GO: 0040008~
12
ING3, ING2, ENOX2, SOCS3, NELL2, SOCS1, CD81, IFNG, ACTL6A, KAT5,

regulation of growth

MRGBP, BRD8

Growth regulation
11
ING3, ING2, ENOX2, TSG101, SOCS3, SOCS1, IFNG, ACTL6A, KAT5,

MRGBP, BRD8

Enrichment Score:

1.2449747006931964

GO: 0008536~Ran
9
XPO6, IPO7, RANGAP1, NUTF2, RANGRF, RANBP2, TNPO2, XPO7, TNPO1

GTPase binding

domain: Importin N-
5
XPO6, IPO7, TNPO2, XPO7, TNPO1

terminal

SM00913: SM00913
5
XPO6, IPO7, TNPO2, XPO7, TNPO1

IPR001494:
5
XPO6, IPO7, TNPO2, XPO7, TNPO1

Importin-beta, N-terminal

Enrichment Score:

1.219152476389818

SM00455: RBD
4
TIAM1, ARAF, RAF1, RGS14

IPR003116: Raf-like
4
TIAMI, ARAF, RAF1, RGS14

Ras-binding

GO: 0005057~
9
BAG4, IFITM1, TIAM1, IL4R, ARAF, RAF1, NSMAF, DAXX, RGS14

receptor signaling protein

activity

domain: RBD
3
TIAM1, ARAF, RAF1

Enrichment Score:

1.2191033373017977

GO: 0000974~Prp19
6
RBM22, PRPF19, CRNKL1, U2AF2, ISY1, XAB2

complex

GO: 0071014~post-
3
CRNKL1, ISY1, XAB2

mRNA release

spliceosomal

complex

GO: 0071012~catalytic
3
CRNKL1, ISY1, XAB2

step 1

spliceosome

Enrichment Score:

1.2188361598202275

IPR000814: TATA-
3
TBPL2, TBP, TBPL1

box binding protein

GO:0006352~DNA-
9
TBPL2, TAF10, TAF13, HIST4H4, BRF2, TAF6, TBP, GTF2B, TBPL1

templated

transcription,

initiation

IPR012295: Beta2-
3
TBPL2, TBP, TBPL1

adaptin/TBP, C-

terminal domain

Enrichment Score:

1.2120424551901947

GO: 0004697~protein
6
PRKCI, PKN2, PRKCH, PRKCD, PRKD3, PRKCB

kinase C activity

GO: 0034351~negative
4
TRAF2, PRKCI, PRKCH, PRKCD

regulation of glial

cell apoptotic

process

IPR020454:
7
ARAF, PRKCI, PRKCH, RAF1, PRKCD, PRKD3, PRKCB

Diacylglycerol/phorbol-

ester binding

domain: AGC-kinase
11
RPS6KA3, ROCK1, ROCK2, PRKCI, PKN2, PRKCH, PRKACB, PRKCD,

C-terminal

LATS1, PRKCB, AKT2

SM00133:S_TK_X
10
RPS6KA3, ROCK1, ROCK2, PRKCI, PKN2, PRKCH, PRKACB, PRKCD,

PRKCB, AKT2

IPR000961: AGC-
11
RPS6KA3, ROCK1, ROCK2, PRKCI, PKN2, PRKCH, PRKACB, PRKCD,

kinase, C-terminal

LATS1, PRKCB, AKT2

IPR017892: Protein
7
RPS6KA3, PRKCI, PKN2, PRKCH, PRKCD, PRKCB, AKT2

kinase, C-terminal

Enrichment Score:

1.1705954418260636

IPR027267: Arfaptin
9
ICA1, SH3GLB2, ACAP1, ACAP2, ARFIP2, ASAP1, ARHGAP17, BIN3, BIN1

homology (AH)

domain/BAR

domain

domain: BAR
6
SH3GLB2, ACAP1, ACAP2, ARHGAP17, BIN3, BIN1

SM00721: BAR
4
SH3GLB2, ARHGAP17, BIN3, BIN1

IPR004148: BAR
4
SH3GLB2, ARHGAP17, BIN3, BIN1

domain

Enrichment Score:

1.167006763733174

IPR006689: Small
9
ARL2, ARL5A, ARF4, ARF6, ARL8B, SARIB, ARL4C, ARL3, ARL4A

GTPase superfamily,

ARF/SAR type

IPR024156: Small
8
ARL2, ARL5A, ARF4, ARF6, ARL8B, ARL4C, ARL3, ARL4A

GTPase superfamily,

ARF type

binding site: GTP;
3
ARL2, ARL5A, ARL3

via amide nitrogen

Enrichment Score:

1.1575764161081228

GO: 0009165~
6
DCTD, DCK, DGUOK, PRPS2, PRPS1, PRPSAP2

nucleotide biosynthetic

process

Nucleotide
4
DCTD, PRPS2, PRPS1, PRPSAP2

biosynthesis

IPR005946: Ribose-
3
PRPS2, PRPS1, PRPSAP2

phosphate

diphosphokinase

GO: 0004749~ribose
3
PRPS2, PRPS1, PRPSAP2

phosphate

diphosphokinase

activity

IPR000836:
4
PRPS2, PPAT, PRPS1, PRPSAP2

Phosphoribosyltransferase

domain

Enrichment Score:

1.1356123741363102

domain: ARID
5
ARID4A, ARID5A, ARID1B, KDM5B, KDM5C

SM00501: BRIGHT
5
ARID4A, ARID5A, ARID1B, KDM5B, KDM5C

IPR001606: ARID/B
5
ARID4A, ARID5A, ARID1B, KDM5B, KDM5C

RIGHT DNA-

binding domain

Enrichment Score:

1.1355492828606781

hsa00020: Citrate
9
SDHA, DLST, IDH3G, SDHC, IDH2, PCK2, OGDH, MDH1, FH

cycle (TCA cycle)

Tricarboxylic acid
7
SDHA, DLST, IDH3G, SDHC, IDH2, MDH1, FH

cycle

GO: 0006099~
8
SDHA, DLST, IDH3G, SDHC, IDH2, OGDH, MDH1, FH

tricarboxylic acid cycle

GO: 0006734~NADH
4
DLST, IDH3G, OGDH, MDH1

metabolic process

hsa01200: Carbon
18
DLST, ME2, PFKL, GLUD2, OGDH, ACAT2, SDHA, PGP, G6PD, IDH3G,

metabolism

SDHC, PHGDH, IDH2, PCCB, PRPS2, MDH1, FH, PRPS1

GO: 0006103~2-
4
DLST, IDH3G, IDH2, OGDH

oxoglutarate

metabolic process

Enrichment Score:

1.1310275733652524

hsa05212: Pancreatic
16
E2F3, RALBP1, RELA, RAF1, SMAD3, BAD, RALGDS, MAPK1, KRAS,

cancer

ARAF, RACI, RALB, MAPK8, PIK3R1, CHUK, AKT2

h_rasPathway: Ras
8
RALBP1, RELA, RACI, RAFI, BAD, PIK3R1, CHUK, RALGDS

Signaling Pathway

h_raccycdPathway:
8
MAPK1, CDKNIB, RELA, RACI, RAF1, PIK3R1, CHUK, CDK2

Influence of Ras and

Rho proteins on G1

to S Transition

h_aktPathway: AKT
4
RELA, BAD, PIK3R1, CHUK

Signaling Pathway

Enrichment Score:

1.1043180593977402

zinc finger
16
ARFGAP2, TRIP4, AGFG2, GTF2H3, ASAP1, POLR2B, RPA1, BRPF1,

region: C4-type

SMAP1, ASH2L, ACAP1, MLLT10, ACAP2, MLLT6, ARAP2, REV3L

domain: Arf-GAP
7
ARFGAP2, SMAP1, AGFG2, ACAP1, ACAP2, ASAP1, ARAP2

SM00105: ArfGap
7
ARFGAP2, SMAP1, AGFG2, ACAP1, ACAP2, ASAP1, ARAP2

IPR001164: Arf
7
ARFGAP2, SMAP1, AGFG2, ACAP1, ACAP2, ASAP1, ARAP2

GTPase activating

protein

Enrichment Score:

1.0984383664834843

GO: 0060334~
6
SOCS3, SOCS1, IFNG, JAK2, PIAS1, IFNGR2

regulation of interferon-

gamma-mediated

signaling pathway

h_tidPathway:
6
TNFRSF1A, RELA, IFNG, HSPA1A, JAK2, IFNGR2

Chaperones modulate

interferon Signaling

Pathway

h_ifngPathway: IFN
3
IFNG, JAK2, IFNGR2

gamma signaling

pathway

Enrichment Score:

1.0873412249855727
4
MOAP1, BBC3, BAD, BCL2L11

GO: 0001844~protein

insertion into

mitochondrial

membrane involved

in apoptotic

signaling pathway

GO: 2001244~positive
8
FIS1, BBC3, BCL2, PRKRA, BAD, BCL2L11, PLAGL2, BCAP31

regulation of

intrinsic apoptotic

signaling pathway

short sequence
5
MCL1, BBC3, BCL2, BAD, BCL2L11

motif: BH3

GO: 1900740~positive
7
BBC3, BCL2, CASP8, MAPK8, GZMB, BAD, BCL2L11

regulation of

protein insertion into

mitochondrial

membrane involved

in apoptotic

signaling pathway

Enrichment Score:

1.0840410197958643

TPR repeat
29
MAU2, UTY, FKBP5, FEMIB, FEMIA, STUB1, FIS1, FICD, KLC1, VPS13A,

RANBP2, GTF3C3, TTC31, TTC14, WDTC1, ZC3H7A, ZC3H7B, TTC37,

CDC23, NAA25, CLUH, CDC27, SGTB, TTC17, CTR9, IFIT3, RPAP3, IFIT5,

EMC2

IPR011990: Tetratric
37
CRNKL1, MAU2, FKBP5, UTY, NAPA, HELZ, TRRAP, CLTC, SART3,

opeptide-like helical

STUB1, FEMIA, XAB2, FIS1, FICD, KLC1, PSMD3, RANBP2, GTF3C3,

TTC31, TTC14, WDTC1, ZC3H7A, ZC3H7B, SMG5, TTC37, NAA25, CDC23,

CLUH, VPS41, TTC17, CDC27, SGTB, CTR9, IFIT3, RPAP3, IFIT5, EMC2

IPR013026: Tetratric
24
TTC31, TTC14, WDTC1, CRNKL1, ZC3H7B, UTY, FKBP5, TTC37, NAA25,

opeptide repeat-

CDC23, CDC27, TTC17, XAB2, SGTB, STUB1, CTR9, IFIT3, RPAP3, FICD,

containing domain

KLC1, IFIT5, EMC2, RANBP2, GTF3C3

SM00028: TPR
22
TTC31, TTC14, WDTC1, MAU2, ZC3H7B, UTY, FKBP5, TTC37, CDC23,

CDC27, TTC17, STUB1, XAB2, SGTB, CTR9, IFIT3, RPAP3, KLC1, IFIT5,

EMC2, RANBP2, GTF3C3

repeat: TPR 1
26
MAU2, FKBP5, UTY, STUB1, FEMIA, FICD, KLC1, VPS13A, GTF3C3,

TTC31, WDTC1, TTC14, ZC3H7A, ZC3H7B, TTC37, CDC23, NAA25, CLUH,

SGTB, TTC17, CDC27, CTR9, RPAP3, IFIT3, IFIT5, EMC2

repeat: TPR 2
26
MAU2, FKBP5, UTY, STUB1, FEMIA, FICD, KLC1, VPS13A, GTF3C3,

TTC31, WDTC1, TTC14, ZC3H7A, ZC3H7B, TTC37, CDC23, NAA25, CLUH,

SGTB, TTC17, CDC27, CTR9, RPAP3, IFIT3, IFIT5, EMC2

IPR019734: Tetratric
23
TTC31, TTC14, WDTC1, MAU2, ZC3H7B, UTY, FKBP5, TTC37, CDC23,

opeptide repeat

CDC27, TTC17, STUB1, XAB2, SGTB, CTR9, IFIT3, RPAP3, FICD, KLC1,

IFIT5, EMC2, RANBP2, GTF3C3

repeat: TPR 4
17
TTC14, MAU2, UTY, TTC37, CDC23, NAA25, CLUH, CDC27, SGTB, TTC17,

CTR9, IFIT3, RPAP3, KLC1, IFIT5, VPS13A, GTF3C3

repeat: TPR 3
23
TTC31, TTC14, ZC3H7A, MAU2, ZC3H7B, UTY, FKBP5, TTC37, NAA25,

CDC23, CLUH, CDC27, TTC17, SGTB, STUB1, CTR9, IFIT3, RPAP3, KLC1,

IFIT5, VPS13A, EMC2, GTF3C3

repeat: TPR 6
12
RPAP3, IFIT3, UTY, KLC1, IFIT5, TTC37, CDC23, VPS13A, CDC27, TTC17,

GTF3C3, CTR9

repeat: TPR 8
9
IFIT3, UTY, IFIT5, TTC37, CDC23, VPS13A, CDC27, GTF3C3, CTR9

repeat: TPR 7
10
RPAP3, IFIT3, UTY, IFIT5, TTC37, CDC23, VPS13A, CDC27, GTF3C3, CTR9

repeat: TPR 5
12
RPAP3, IFIT3, UTY, KLC1, IFIT5, TTC37, CDC23, VPS13A, CDC27, TTC17,

GTF3C3, CTR9

repeat: TPR 9
6
TTC37, CDC23, VPS13A, CDC27, GTF3C3, CTR9

repeat: TPR 10
4
TTC37, VPS13A, GTF3C3, CTR9

repeat: TPR 11
3
TTC37, GTF3C3, CTR9

Enrichment Score:

1.081204540174882

GO: 0051287~NAD
11
CTBP1, ME2, IDH3G, PHGDH, IDH2, AHCYL1, GRHPR, GLYR1, HIBADH,

binding

ALDH9A1, MDH1

nucleotide
15
CTBP1, ME2, SIRT6, SIRT7, HIBADH, ALDH3A2, SIRT2, DHRS7, IDH3G,

phosphate-binding

PHGDH, OXNAD1, GLYR1, ALDH9A1, MDH1, HSD17B8

region: NAD

binding site:NAD
6
CTBP1, ME2, PHGDH, GLYR1, HIBADH, MDH1

Enrichment Score:

1.0596664654758672

GO: 0032481~positive
13
IRAK1, POLR3F, POLR3H, ZC3HAVI, RELA, CREBBP, PTPN22, POLR3GL,

regulation of type

POLR3C, POLR3E, STAT6, EP300, IRF3

I interferon

production

hsa00240: Pyrimidine
21
DCTD, POLR3F, POLR3H, NT5C3A, POLRIE, POLRIA, UPP1, DCK,

metabolism

POLR3GL, POLR3C, PNP, POLR2B, POLR3E, NME3, POLE3, RRMI,

ENTPD6, TXNRD1, UCK1, TWISTNB, NT5C

hsa03020: RNA
9
POLR3F, POLR3H, POLRIE, POLRIA, POLR3GL, TWISTNB, POLR3C,

polymerase

POLR2B, POLR3E

GO: 0006383~
9
POLR3F, POLR3H, BRF1, TBP, IVNSIABP, POLR3C, GTF3C1, POLR3E,

transcription from RNA

GTF3C3

polymerase III

promoter

DNA-directed RNA
8
POLR3F, POLR3H, POLRIE, POLRIA, TWISTNB, POLR3C, POLR2B,

polymerase

POLR3E

hsa04623: Cytosolic
12
POLR3F, POLR3H, RELA, NFKBIB, RIPK1, PYCARD, POLR3GL, IRF3,

DNA-sensing

POLR3C, CCL4, CHUK, POLR3E

pathway

GO: 0006359~
4
POLR3F, BRF2, POLR3GL, POLR3C

regulaion of transcription

from RNA

polymerase III

promoter

GO: 0003899~DNA-
8
POLR3F, POLR3H, POLRIE, POLRIA, TWISTNB, POLR3C, POLR2B,

directed RNA

POLR3E

polymerase activity

GO: 0001056~RNA
5
POLR3F, POLR3H, POLR3GL, POLR3C, POLR3E

polymerase III

activity

GO: 0005666~DNA-
5
POLR3F, POLR3H, POLR3GL, POLR3C, POLR3E

directed RNA

polymerase III

complex

GO: 0001054~RNA
3
POLRIE, POLRIA, TWISTNB

polymerase I activity

GO: 0005736~DNA-
3
POLRIE, POLRIA, TWISTNB

directed RNA

polymerase I

complex

Enrichment Score:

1.0231268518510328

GO: 0051536~iron-
7
NFU1, TYW1, RSAD2, CDK5RAP1, CIAPIN1, NDUFS1, PPAT

sulfur cluster

binding

Iron-sulfur
13
GLRX5, TYW1, NDUFV2, IREB2, RSAD2, LIAS, UQCRFS1, CDK5RAP1,

CIAPIN1, NDUFS1, PPAT, GLRX2, REV3L

IPR007197: Radical
4
TYW1, RSAD2, LIAS, CDK5RAP1

SAM

4Fe-4S
8
TYW1, IREB2, RSAD2, LIAS, CDK5RAP1, NDUFS1, PPAT, REV3L

GO: 0051539~4 iron,
9
NFU1, TYW1, IREB2, RSAD2, LIAS, CDK5RAP1, NDUFS1, PPAT, REV3L

4 sulfur cluster

binding

metal ion-binding
3
TYW1, RSAD2, CDK5RAP1

site: Iron-sulfur (4Fe-

4S-S-AdoMet)

SM00729: Elp3
3
RSAD2, LIAS, CDK5RAP1

IPR006638: Elongator
3
RSAD2, LIAS, CDK5RAP1

protein

3/MiaB/NifB

metal ion-binding
3
IREB2, CDK5RAP1, PPAT

site: Iron-sulfur (4Fe-

4S)

Enrichment Score:

1.0174059112189755

SM00800: uDENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

SM00799: DENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

SM00801: dDENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

IPR005113: uDENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

domain

IPR001194: DENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

domain

IPR005112: dDENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

domain

domain: uDENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

domain: DENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

domain:dDENN
5
DENND5A, SBF1, MADD, DENND4B, DENND2D

GO:0017112~Rab
7
RAB3GAP2, DENND5A, SBF1, MADD, TRAPPC4, DENND4B, DENND2D

guany1-nucleotide

exchange factor

activity

Enrichment Score:

1.013340358660417

SM00809: Alpha_
4
AP1G1, AP2A1, GGA1, GGA3

adaptinC2

IPR008152: Clathrin
4
APIG1, AP2A1, GGA1, GGA3

adaptor,

alpha/beta/gamma-

adaptin, appendage,

Ig-like subdomain

domain: GAE
3
APIG1, GGA1, GGA3

GO: 0030131~clathrin
5
AP3M2, AP1G1, AP3M1, GGA1, GGA3

adaptor complex

IPR008153: Clathrin
3
AP1G1, GGA1, GGA3

adaptor, gamma-

adaptin, appendage

IPR013041: Coatomer/
4
AP1G1, AP2A1, GGA1, GGA3

r/clathrin adaptor

appendage, Ig-like

subdomain

Enrichment Score:

0.997471155798655

domain: CUE
4
N4BP2, ASCC2, AMFR, TAB3

IPR003892: Ubiquitin
4
N4BP2, ASCC2, AMFR, TAB3

system component

Cue

SM00546: CUE
3
ASCC2, AMFR, TAB3

Enrichment Score:

0.9788942570619484

GO: 0035267~NuA4
6
ING3, ACTL6A, TRRAP, KAT5, MRGBP, BRD8

histone

acetyltransferase

complex

GO: 0000812~Swr1
4
ING3, TRRAP, KAT5, BRD8

complex

GO:0043967~histone
7
ING3, NCOA1, EP300, ACTL6A, USP22, TRRAP, BRD8

H4 acetylation

GO: 0043968~histone
4
ING3, ACTL6A, TRRAP, BRD8

H2A acetylation

Enrichment Score:

0.9757250476428545

IPR005225: Small
34
RAB5B, RAB5C, ARF6, MTIF2, GFM2, ARL5A, KRAS, GFMI, RAC1, RALB,

GTP-binding protein

RAB11B, SARIB, RHOF, ARL2, RAP2C, EFTUD2, DRG1, DRG2, RAB33A,

domain

RAB33B, ARL3, NRAS, RAB30, RAB18, RAB35, ARF4, RHOT1, RAB5A,

RHOT2, RIT1, ARL8B, ARL4C, NKIRAS2, ARL4A

GO: 0019003~GDP
13
RAP2C, RAB5B, RAB5C, RRAGC, ARL3, KRAS, RAB18, RAB35, RALB,

binding

RAB11B, RAB5A, ARL8B, PRPS1

IPR001806: Small
19
RAP2C, RAB5B, RAB5C, RAB33A, RAB33B, NRAS, RAB30, KRAS, RAB18,

GTPase superfamily

RAB35, RACI, RALB, RAB11B, RHOT1, RAB5A, RHOT2, RIT1, RHOF,

NKIRAS2

short sequence
14
RAP2C, RAB5B, RAB5C, NRAS, RAB30, KRAS, RAB18, RAB35, RAC1,

motif: Effector

RAB11B, RAB5A, RALB, RHOF, NKIRAS2

region

Prenylation
21
PHKA2, RAP2C, RAB5B, RAB5C, LMNB2, BROX, MIENI, RAB33A,

RAB33B, NRAS, RAB30, KRAS, RAB18, PEX19, RAB35, RAC1, RALB,

RAB11B, RAB5A, YKT6, RHOF

lipid moiety-binding
13
RAP2C, RAB30, RAB18, RAB5B, RAB5C, RAB35, RACI, RALB, RAB5A,

region: S-

RAB11B, RHOF, RAB33A, RAB33B

geranylgeranyl

cysteine

propeptide: Removed
13
PSMB10, NRAS, CD55, RAP2C, KRAS, RAB30, RAB18, TPP1, CD59, RAC1,

in mature form

RALB, RAB11B, RHOF

Enrichment Score:

0.9749120956358032

GO: 0005777~
20
MVD, IDE, KIAA0430, MPV17, AKAP11, SZT2, PEX3, PMVK, ALDH3A2,

peroxisome

ACBD5, FAR1, MFF, FIS1, PNPLA8, GBF1, PEX19, PEX16, IDH2, GNPAT,

SCP2

GO: 0016557~
3
PEX19, PEX16, PEX3

peroxisome membrane

biogenesis

Peroxisome
4
PEX19, PEX2, PEX16, PEX3

biogenesis

Peroxisome
16
ECI2, KIAA0430, SZT2, PEX3, PMVK, ACBD5, FAR1, MFF, FIS1, PEX19,

PEX2, PEX16, GNPAT, ACSL4, ACSL3, SCP2

GO: 0005778~
11
FAR1, PNPLA8, PEX19, PEX2, PEX16, GNPAT, PEX3, ACSL4, ACSL3,

peroxisomal membrane

ALDH3A2, ACBD5

Zellweger syndrome
4
PEX19, PEX2, PEX16, PEX3

GO: 0045046~protein
3
PEX19, PEX16, PEX3

import into

peroxisome

membrane

GO: 0007031~
5
PEX19, PEX2, PEX16, PEX3, SCP2

peroxisome organization

hsa04146: Peroxisome
14
ECI2, MPV17, PEX3, PMVK, FAR1, PEX19, PEX2, PEX16, IDH2, GNPAT,

ACSL4, ACSL3, SCP2, ACSL5

GO: 0005779~integral
4
FIS1, PEX2, PEX16, PEX3

component of

peroxisomal

membrane

Peroxisome
4
PEX19, PEX2, PEX16, PEX3

biogenesis disorder

Enrichment Score:

0.9705769247177995

SM00571: DDT
3
BPTF, BAZ2B, BAZ2A

IPR018501: DDT
3
BPTF, BAZ2B, BAZ2A

domain superfamily

domain: DDT
3
BPTF, BAZ2B, BAZ2A

Enrichment Score:

0.9586769438708357

GO: 0043015~gamma-
7
OFD1, TUBGCP5, CEP57, PDE4B, B9D2, MZT1, TUBGCP2

tubulin binding

GO: 0000923~
3
TUBGCP5, MZT1, TUBGCP2

equatorial microtubule

organizing center

GO: 0051415~
3
TUBGCP5, MZT1, TUBGCP2

interphase microtubule

nucleation by

interphase

microtubule

organizing center

Enrichment Score:

0.9480710390828481

compositionally
4
SMC5, SMC6, RAD50, SMC4

biased

region: Ala/Asp-rich

(DA-box)

region of
3
SMC5, SMC6, SMC4

interest: Flexible

hinge

IPR003395: RecF/RecN/
3
SMC5, SMC6, SMC4

SMC

Enrichment Score:

0.9463520308175999

SM00592: BRK
4
CHD9, CHD7, CHD6, SMARCA2

IPR006576: BRK
4
CHD9, CHD7, CHD6, SMARCA2

domain

IPR000330: SNF2-
8
CHD9, BTAF1, CHD7, CHDIL, INO80, CHD6, SMARCA2, TTF2

related

IPR016197: Chromo
7
CHD9, CHD7, ARID4A, CBX1, KAT5, CHD6, CBX7

domain-like

SM00298: CHROMO
7
CHD9, CHD7, ARID4A, CBX1, KAT5, CHD6, CBX7

IPR000953: Chromo
7
CHD9, CHD7, ARID4A, CBX1, KAT5, CHD6, CBX7

domain/shadow

domain: Chromo 1
4
CHD9, CHD7, CBX1, CHD6

domain: Chromo 2
3
CHD9, CHD7, CHD6

short sequence
7
CHD9, CHD7, CHDIL, DHX29, DHX16, CHD6, TTF2

motif: DEAH box

IPR023780: Chromo
5
CHD9, CHD7, CBX1, CHD6, CBX7

domain

Enrichment Score:

0.9456837667749796

domain: PCI
7
PSMD13, PSMD12, PCID2, COPS7A, PSMD3, COPS7B, COPS8

Signalosome
4
COPS7A, COPS7B, COPS8, TESPA1

GO: 0010388~cullin
3
COPS7A, COPS7B, COPS8

deneddylation

GO: 0008180~COP9
5
WDR6, COPS7A, COPS7B, COPS8, TESPA1

signalosome

Enrichment Score:

0.9432970300617087

GO: 0003950~NAD +
7
ZC3HAVI, PARP12, PARP8, PARP11, SIRT6, PARP4, SIRT2

ADP-

ribosyltransferase

activity

domain: PARP
5
ZC3HAVI, PARP12, PARP8, PARP11, PARP4

catalytic

IPR012317: Poly(AD
5
ZC3HAVI, PARP12, PARP8, PARP11, PARP4

P-ribose)

polymerase,

catalytic domain

IPR004170: WWE
4
ZC3HAVI, PARP12, PARP11, RNF146

domain

Enrichment Score:

0.916012864240317

active site: Schiff-
3
NEIL2, POLB, OGGI

base intermediate

with DNA

GO: 0006284~base-
8
RPA1, XPA, MPG, NEIL2, USP47, SIRT6, POLB, OGGI

excision repair

hsa03410: Base
7
MPG, POLE3, NEIL2, MBD4, POLB, PARP4, OGGI

excision repair

Enrichment Score:

0.9063741277695219

Protein biosynthesis
25
FARS2, HBSIL, WARS2, MTIF2, TCEAL4, GFM2, EIF4EBP2, GFM1, EIF2B4,

EIF2B5, EIF4ENIF1, BRF1, EIF1B, MRRF, EIF2B1, EIF4G3, TRNAUIAP,

EIF4E, DHX29, TSFM, EEF1E1, FARSB, YARS2, EIF5A2, MTFMT

Initiation factor
11
EIF4ENIF1, EIF4G3, EIF4EBP2, EIF4E, BRF1, DHX29, EIFIB, MTIF2,

EIF2B1, EIF2B4, EIF2B5

GO: 0003743~
12
EIF4ENIF1, EIF4G3, EIF4EBP2, EIF4E, BRF1, DHX29, AGO2, EIFIB, MTIF2,

translation initiation

EIF2B1, EIF2B4, EIF2B5

factor activity

GO: 0006413~
10
RPL17, EIF4G3, EIF4E, DHX29, AGO2, EIFIB, EIF2B1, MTFMT, EIF2B4,

translational initiation

EIF2B5

Enrichment Score:

0.9057102063061746

IPR014721: Ribosom
7
GFM2, LONP1, MRPS9, MVD, GFM1, EFTUD2, TOP2B

al protein S5 domain

2-type fold,

subgroup

GO: 0032790~ribosome
4
GFM2, HBS1L, MTIF2, MRRF

disassembly

SM00889: SM00889
3
GFM2, GFM1, EFTUD2

IPR005517: Translation
3
GFM2, GFM1, EFTUD2

elongation factor

EFG/EF2, domain

IV

SM00838: SM00838
3
GFM2, GFM1, EFTUD2

IPR000640: Translation
3
GFM2, GFM1, EFTUD2

elongation factor

EFG, V domain

IPR009022: Elongation
3
GFM2, GFM1, EFTUD2

factor G, III-V

domain

IPR000795: Elongation
5
GFM2, GFM1, EFTUD2, HBS1L, MTIF2

factor, GTP-

binding domain

GO: 0003746~
7
GFM2, TSFM, EEF1E1, GFM1, HBSIL, EIF5A2, TCEAL4

translation elongation

factor activity

Elongation factor
6
GFM2, TSFM, GFM1, HBSIL, EIF5A2, TCEAL4

IPR004161: Translation
4
GFM2, GFM1, EFTUD2, HBS1L

elongation factor

EFTu/EF1A, domain 2

IPR009000: Translation
5
GFM2, GFM1, EFTUD2, HBS1L, MTIF2

elongation/initiation

factor/Ribosomal,

beta-barrel

Enrichment Score:

0.9035692912975634

GO: 0070652~HAUS
4
HAUS3, HAUS6, HAUS2, HAUS1

complex

GO: 0051297~
7
ARL2, HAUS3, HAUS6, CEP120, BNIP2, HAUS2, HAUS1

centrosome organization

GO: 0051225~spindle
6
HAUS3, HAUS6, CSNKID, HAUS2, HAUS1, INO80

assembly

Enrichment Score:

0.9019097275135531

GO: 0090630~
19
TBC1D10C, RABGAP1, RALGAPB, RABGAPIL, PIP5K1A, TBC1D22B,

activation of GTPase

TBC1D15, RALGAPA1, NDEL1, TSC1, RCC2, SGSM2, TIAMI, SIPAIL1,

activity

TBC1D13, TBC1D4, TBC1D1, AKT2, TBC1D9B

GO: 0031338~
10
TBC1D15, RABGAP1, TBC1D10C, SGSM2, TBC1D13, TBC1D4, RABGAPIL,

regulation of vesicle fusion

TBC1D1, TBC1D22B, TBC1D9B

domain: Rab-GAP
10
TBC1D15, RABGAP1, TBC1D10C, SGSM2, TBCID13, TBC1D4, RABGAPIL,

TBC

TBC1D1, TBC1D22B, TBC1D9B

GO: 0017137~Rab
22
RAB3GAP2, DENND5A, TBC1D10C, RABGAP1, APIG1, RABGAPIL, OPTN,

GTPase binding

TBC1D22B, ANXA2, TBC1D15, UNC13D, PDE6D, SGSM2, AP3M1,

TBC1D13, RAC1, ACAP2, TBC1D4, SYTL3, EHD1, TBC1D1, TBC1D9B

GO: 0012505~endo
19
RABGAP1, TBC1D10C, TBC1D22B, BCL2L11, RTN3, TBC1D15, DOCK2,

membrane system

CHMP1A, SGSM2, PGRMC1, PGRMC2, TBC1D13, TBC1D4, RNF167,

NSMAF, TBCID1, NENF, CDC42EP3, TBC1D9B

SM00164:TBC
10
TBC1D15, RABGAP1, TBCID10C, SGSM2, TBC1D13, TBC1D4, RABGAPIL,

TBC1D1, TBC1D22B, TBC1D9B

IPR000195: Rab-
10
TBC1D15, RABGAP1, TBC1D10C, SGSM2, TBCID13, TBC1D4, RABGAPIL,

GTPase-TBC

TBC1D1, TBC1D22B, TBC1D9B

domain

GO: 1902017~
7
TBC1D15, RABGAP1, TBC1D10C, TBC1D13, TBC1D1, TBCID22B,

regulation of cilium

TBC1D9B

assembly

domain: PID
4
ANKSIA, RABGAP1, RABGAPIL, TBC1D1

SM00462: PTB
5
ANKSIA, RABGAP1, TBC1D4, RABGAPIL, TBC1D1

IPR006020:Phospho-
5
ANKS1A, RABGAP1, TBC1D4, RABGAPIL, TBCID1

tyrosine interaction

domain

Enrichment Score:

0.8869149577293349

SM00717: SANT
11
TADA2A, DMTF1, MTA2, EZH1, MYB, TRERF1, NCOR2, RERE, TERF2,

ELMSAN1, TERFI

IPR001005: SANT/
11
TADA2A, DMTF1, MTA2, EZH1, MYB, TRERF1, NCOR2, RERE, TERF2,

Myb domain

ELMSAN1, TERFI

IPR017930:Myb
4
DMTF1, MYB, TERF2, TERFI

domain

GO: 0000118~histone
8
TBL1XR1, MTA2, TBLIX, TRERF1, NCOR2, RERE, NRIP1, ELMSANI

deacetylase

complex

domain: SANT
5
TADA2A, MTA2, TRERF1, RERE, ELMSAN1

IPR017884: SANT
6
TADA2A, MTA2, TRERF1, NCOR2, RERE, ELMSANI

domain

domain: ELM2
4
MTA2, TRERF1, RERE, ELMSAN1

SM01189: SM01189
4
MTA2, TRERF1, RERE, ELMSAN1

IPR000949: ELM2
4
MTA2, TRERF1, RERE, ELMSAN1

domain

domain: HTH myb-
3
DMTF1, TERF2, TERFI

type

DNA-binding
4
DMTF1, MYB, TERF2, TERFI

region: H-T-H motif

IPR009057:
20
RABGAP1, POGZ, TADA2A, MTA2, ZHX1, CERS6, CERS4, ZEB1, TRERF1,

Homeodomain-like

CASP8AP2, POGK, CERS2, DMTF1, HOPX, MYB, NCOR2, TERF2, RERE,

ELMSAN1, TERF1

Enrichment Score:

0.8828129877584019

GO:0070979~protein
8
UBE2D4, UBE2A, RNF4, ANAPC4, UBE2W, CDC23, ANAPC10, CDC27

K11-linked

ubiquitination

GO: 0051439~regulation
6
ANAPC4, CDC23, ANAPC10, CDC27, CDK2, UBE2E1

of ubiquitin-

protein ligase

activity involved in

mitotic cell cycle

GO: 0005680~anaphase-
5
CACUL1, ANAPC4, CDC23, ANAPC10, CDC27

promoting

complex

GO: 0030071~
3
ANAPC4, CDC23, ANAPC10

regulation of mitotic

metaphase/anaphase

transition

Enrichment Score:

0.8760120979730552

domain: Cytochrome
5
PGRMC1, PGRMC2, CYB5A, HERC2, NENF

b5 heme-binding

SM01117: SM01117
5
PGRMC1, PGRMC2, CYB5A, HERC2, NENF

IPR001199:
5
PGRMC1, PGRMC2, CYB5A, HERC2, NENF

Cytochrome b5-like

heme/steroid

binding domain

GO: 0020037~
5
PGRMC1, SDHC, PGRMC2, CYB5A, JAK2

hemebinding

Enrichment Score:

0.8696720280102501

domain: EH
3
SYNRG, EHD1, EHD4

SM00027: EH
4
SYNRG, REPS1, EHD1, EHD4

IPR000261: EPS15
4
SYNRG, REPS1, EHD1, EHD4

homology (EH)

domain: EF-hand
7
GNPTAB, REPS1, STIM1, EHD1, ZZEF1, EHD4, TBC1D9B

Enrichment Score:

GO: 0045862~positive
6
EP300, CASP8, FADD, BAD, FBXW11, CLN6

regulation of

proteolysis

46.P13K PTEN
6
TNFRSF1A, CASP7, BCL2, CASP8, FADD, BAD

GO: 0097202~activation
4
CASP8, PYCARD, FADD, BAD

of cysteine-type

endopeptidase

activity

86.Apoptosis_Nema
4
BCL2, CASP8, FADD, BAD

tode& Vert

Enrichment Score:

0.8578437407621964

IPR020850: GTPase
4
DNM3, CREBZF, MX1, MX2

effector domain,

GED

IPR022812: Dynamin
5
DNM3, MX1, EHD1, MX2, EHD4

SM00302: GED
3
DNM3, MX1, MX2

IPR019762: Dynamin,
3
DNM3, MX1, MX2

GTPase region,

conserved site

IPR000375: Dynamin
3
DNM3, MX1, MX2

central domain

domain: GED
3
DNM3, MX1, MX2

SM00053: DYNc
3
DNM3, MX1, MX2

IPR003130: Dynamin
3
DNM3, MX1, MX2

GTPase effector

IPR001401:Dynamin,
3
DNM3, MX1, MX2

GTPase domain

Enrichment Score:

0.85187387805759

GO: 0000422~
11
ATG2B, GABARAPL2, FIS1, ATG4B, RB1CC1, BNIP3, WIPI2, PPARGCIA,

mitophagy

WDR45B, WDR45, MARK2

GO: 0034045~pre-
5
ATG2B, RB1CC1, WIPI2, WDR45B, WDR45

autophagosomal

structure membrane

GO: 0044804~
5
ATG2B, ATG4B, WIPI2, WDR45B, WDR45

nucleophagy

GO: 0034497~protein
4
STX17, WIPI2, WDR45B, WDR45

localization to pre-

autophagosomal

structure

GO: 0080025~
5
GBF1, COMMD1, WIPI2, WDR45B, WDR45

phosphatidylinositol-3,5-

bisphosphate

binding

GO: 0000045~
7
ATG2B, GABARAPL2, ATG4B, RB1CC1, WIPI2, WDR45B, WDR45

autophagosome assembly

GO: 0006497~protein
3
WIPI2, WDR45B, WDR45

lipidation

GO: 0032266~
5
SNX19, WIPI2, SNX13, WDR45B, WDR45

phosphatidylinositol-3-

phosphate binding

Enrichment Score:

0.842501378699483

GO:0061158~3′-
5
ZFP36, ZFP36L2, KHSRP, QKI, ZC3H12D

UTR-mediated

mRNA

destabilization

GO: 0017091~AU-
5
ZFP36, ZFP36L2, EXOSC7, TIA1, ELAVL1

rich element binding

GO: 0035925~mRN
4
ZFP36, ZFP36L2, KHSRP, ELAVL1

A 3′-UTR AU-rich

region binding

GO: 0006402~mRNA
5
DIS3, ZFP36, ZFP36L2, DCP2, KHSRP

catabolic process

GO: 0003730~mRNA
7
ZFP36, ZFP36L2, TARDBP, FMR1, KHSRP, PUM1, ELAVL1

3′-UTR binding

Enrichment Score:

0.8299126897208382

IPR000980: SH2
21
VAV3, SOCS3, SOCS1, CBL, VAVI, STAT6, NCK2, SH2D3C, SH2D2A,

domain

CBLB, SH2D3A, CRKL, RINL, ZAP70, JAK2, INPP5D, GRAP2, ABL2,

RASA1, PIK3R1, MATK

SM00252: SH2
18
VAV3, SOCS3, SOCS1, VAVI, STAT6, NCK2, SH2D3C, SH2D2A, SH2D3A,

CRKL, ZAP70, JAK2, INPP5D, GRAP2, ABL2, RASA1, PIK3R1, MATK

SH2 domain
18
VAV3, SOCS3, SOCS1, VAVI, STAT6, NCK2, SH2D3C, SH2D2A, SH2D3A,

CRKL, ZAP70, JAK2, INPP5D, GRAP2, ABL2, RASA1, PIK3R1, MATK

GO: 0005070~SH3/S
10
SH2D2A, NCK2, SH2D3C, SH3BGRL, VAV3, CRKL, SH2D3A, LASP1,

H2 adaptor activity

STAM, GRAP2

domain: SH2
14
VAV3, SOCS3, SOCS1, VAVI, STAT6, SH2D3C, SH2D2A, NCK2, SH2D3A,

CRKL, INPP5D, GRAP2, ABL2, MATK

domain: SH3 1
5
NCK2, VAV3, CRKL, GRAP2, VAVI

domain: SH3 2
5
NCK2, VAV3, CRKL, GRAP2, VAV1

Enrichment Score:

0.8204630664582663

GO: 0050072~m7G(5′)
5
NUDT1, NUDT4, DCP2, NUDT5, NUDT16L1

pppN

diphosphatase

activity

domain: Nudix
6
NUDT1, NUDT4, DCP2, NUDT9, NUDT22, NUDT5

hydrolase

IPR020084: NUDIX
4
NUDT1, NUDT4, DCP2, NUDT5

hydrolase, conserved

site

IPR000086: NUDIX
6
NUDT1, NUDT4, DCP2, NUDT9, NUDT22, NUDT5

hydrolase domain

GO: 0034656~nucleo
3
NUDT1, NUDT9, NUDT5

base-containing

small molecule

catabolic process

IPR015797: NUDIX
6
NUDT1, NUDT4, DCP2, NUDT9, NUDT5, NUDT16L1

hydrolase domain-

like

short sequence
5
NUDT1, NUDT4, DCP2, NUDT9, NUDT5

motif: Nudix box

GO: 0030515~snoRNA
5
NUDT1, NUDT4, NUDT5, NUDT16L1, PWP2

binding

Enrichment Score:

0.8167271376205175

zinc finger
3
ZMYM2, ZMYM4, ZMYM5

region: MYM-type 2

zinc finger
3
ZMYM2, ZMYM4, ZMYM5

region: MYM-type 3

zinc finger
3
ZMYM2, ZMYM4, ZMYM5

region: MYM-type 1

zinc finger
3
ZMYM2, ZMYM4, ZMYM5

region: MYM-type 4

IPR010507: Zinc
3
ZMYM2, ZMYM4, ZMYM5

finger, MYM-type

SM00746: TRASH
3
ZMYM2, ZMYM4, ZMYM5

IPR011017: TRASH
3
ZMYM2, ZMYM4, ZMYM5

domain

Enrichment Score:

0.8116396013515808

repeat: HAT 6
4
CRNKL1, SFI1, SART3, XAB2

repeat:HAT 5
4
CRNKL1, SFI1, SART3, XAB2

repeat: HAT 8
3
CRNKL1, SART3, XAB2

repeat: HAT 4
4
CRNKL1, SFI1, SART3, XAB2

repeat: HAT 2
4
CRNKL1, SFI1, SART3, XAB2

repeat: HAT 1
4
CRNKL1, SFI1, SART3, XAB2

repeat: HAT 3
4
CRNKL1, SFI1, SART3, XAB2

repeat: HAT 7
3
CRNKL1, SART3, XAB2

SM00386: HAT
3
CRNKL1, SART3, XAB2

IPR003107: RNA-
3
CRNKL1, SART3, XAB2

processing protein,

HAT helix

Enrichment Score:

0.8053738526498081

GO: 0005655~nucleolar
4
RPP38, POP4, POP5, POP7

ribonuclease P

complex

GO:n0004526~
4
RPP38, POP4, POP5, POP7

ribonuclease P activity

GO:0001682~tRNA
4
RPP38, POP4, POP5, POP7

5′-leader removal

hsa03008: Ribosome
10
RPP38, REXO1, GNL3L, NAT10, POP4, POP5, SPATA5, RBM28, POP7, PWP2

biogenesis in

eukaryotes

Enrichment Score:

0.80359331380945122

GO: 0004722~protein
12
MTMR14, RPAP2, PPP2CB, PPP3CB, DUSP23, PPMIA, MTMR6, PPP1R15B,

serine/threonine

UBLCP1, PTEN, PPP1CB, PPP2R2D

phosphatase activity

Protein phosphatase
20
PTPN7, PTPRE, PTPRA, STYX, DUSP23, PPMIA, DUSP22, PTPN22,

DUSP12, PPP1CB, PTEN, DUSP4, DUSP28, PGP, RPAP2, PPP2CB, DUSP16,

PPP3CB, CTDSP1, UBLCP1

GO: 0006470~protein
16
PTPN7, PTPRE, STYX, PPMIA, DUSP22, PTPN22, PPP1CB, PTEN, SBF1,

dephosphorylation

BCL2, PPP2CB, PPP3CB, CTDSP1, UBLCP1, MTMR6, FBXW11

Enrichment Score:

0.8010857129206969

GO: 0034450~ubiquitin-
5
PRPF19, PELI1, UBE4A, AMFR, STUB1

ubiquitin ligase

activity

domain: U-box
3
PRPF19, UBE4A, STUB1

SM00504: Ubox
3
PRPF19, UBE4A, STUB1

IPR003613: U box
3
PRPF19, UBE4A, STUB1

domain

Enrichment Score:

0.7901368844841442

GO: 0005868~
8
DYNCILI2, DYNLT3, SNX4, DYNLT1, DYNC1H1, DYNLRB1, BCL2L11,

cytoplasmic dynein

DYNC1I2

complex

Dynein
6
DYNCILI2, DYNLT3, DYNLT1, DYNC1H1, DYNLRB1, DYNC1I2

GO: 0007018~
9
KIF3B, DYNCILI2, SNX29, AP2A1, KLC1, DYNCIH1, DYNLRB1, DYNC112,

microtubule-based

ACTR10

movement

GO: 0003777~
7
KIF3B, DYNCILI2, SNX29, KLC1, DYNCIH1, DYNLRB1, DYNC1I2

microtubule motor activity

Motor protein
11
DNM3, KIF3B, DYNCILI2, KLC1, MYO1G, DYNLT3, MYO9B, DYNLT1,

DYNCIH1, DYNLRB1, DYNC112

Enrichment Score:

0.7810728163809908

domain: Leucine-
23
E2F3, BACH2, E2F4, CREBZF, CREB1, TSN, MED13L, FOXP3, SREBF2,

zipper

ATF6, ATF5, FOS, TSC22D3, TCF20, JUN, MLLT10, NFE2L2, MLLT6, MYB,

NFE2L3, TCF3, CHUK, API5

IPR004827: Basic-
10
CREBRF, ATF6, ATF5, FOS, BACH2, CREBZF, JUN, CREB1, NFE2L2,

leucine zipper

NFE2L3

domain

IPR008917: Eukaryotic
4
BACH2, JUN, NFE2L2, NFE2L3

transcription

factor, Skn-1-like,

DNA-binding

SM00338: BRLZ
8
ATF6, ATF5, FOS, BACH2, JUN, CREB1, NFE2L2, NFE2L3

IPR004826: Basic
3
BACH2, NFE2L2, NFE2L3

leucine zipper

domain, Maf-type

DNA-binding
16
BACH2, CREBZF, CREB1, MXI1, MXD4, SREBF2, ATF6, ATF5, FOS,

region: Basic motif

NCOA1, NCOA2, HES4, JUN, NFE2L2, NFE2L3, TCF3

Enrichment Score:

0.7790223053007594

IPR018503: Tetraspanin,
6
CD37, TSPAN5, CD81, CD63, CD151, TSPAN17

conserved site

PIRSF002419:
7
CD37, TSPAN31, TSPAN5, CD81, CD63, CD151, TSPAN17

tetraspanin

IPR000301: Tetraspanin
7
CD37, TSPAN31, TSPAN5, CD81, CD63, CD151, TSPAN17

IPR018499: Tetraspanin/
7
CD37, TSPAN31, TSPAN5, CD81, CD63, CD151, TSPAN17

Peripherin

IPR008952: Tetraspanin,
6
CD37, TSPAN5, CD81, CD63, CD151, TSPAN17

EC2 domain

73.Integrins_and_ot
4
CD37, CD81, CD63, CD151

her cell-

surface_receptors

Enrichment Score:

0.7789647933825644

Steroid biosynthesis
9
HSD17B11, EBP, MSMO1, MVD, HINT2, HMGCS1, PRKAA1, PMVK,

HSD17B8

Sterol biosynthesis
6
EBP, MSMO1, MVD, HMGCS1, PRKAA1, PMVK

Cholesterol
5
EBP, MVD, HMGCS1, PRKAA1, PMVK

biosynthesis

Cholesterol
10
SOAT1, EBP, APOL1, NPC2, INSIG2, MVD, HMGCS1, PRKAA1, PMVK,

metabolism

SREBF2

GO:0006695~
8
EBP, MSMO1, G6PD, INSIG2, MVD, HMGCS1, PRKAA1, PMVK

cholesterol biosynthetic

process

Sterol metabolism
11
SOAT1, EBP, APOL1, MSMO1, NPC2, INSIG2, MVD, HMGCS1, PRKAA1,

PMVK, SREBF2

hsa00900: Terpenoid
5
NUS1, MVD, HMGCS1, PMVK, ACAT2

backbone

biosynthesis

Steroid metabolism
11
SOAT1, EBP, APOL1, MSMO1, NPC2, INSIG2, MVD, HMGCS1, PRKAA1,

PMVK, SREBF2

GO: 0008203~
9
STARD3, SOAT1, APOL2, EBP, APOLI, NPC2, INSIG2, CLN6, SREBF2

cholesterol metabolic

process

Enrichment Score:

0.7599731845015745

zinc finger
3
UBR7, UBR2, FBXO11

region: UBR-type

SM00396: ZnF_UBR1
3
UBR7, UBR2, FBXO11

IPR003126: Zinc
3
UBR7, UBR2, FBXO11

finger, N-recognin

Enrichment Score:

0.7582256458667048

GO: 0008654~
11
CDIPT, CRLS1, PGS1, DGKE, LPGAT1, SERINC1, HEXB, MBOAT1,

phospholipid biosynthetic

PCYTIA, PIP5K1A, PTDSS1

process

Phospholipid
9
CDIPT, CRLS1, PGS1, LPGAT1, SERINCI, MBOAT1, ABHD3, PCYTIA,

metabolism

PTDSS1

GO: 0016780~
3
CDIPT, CRLS1, PGS1

phosphotransferase

activity, for other

substituted

phosphate groups

Phospholipid
8
CDIPT, CRLS1, PGS1, LPGATI, SERINC1, MBOAT1, PCYTIA, PTDSS1

biosynthesis

GO: 0047144~2-
3
CRLS1, LPGATI, MBOAT1

acylglycerol-3-

phosphate O-

acyltransferase

activity

hsa00564:
13
PLD3, CDIPT, CRLS1, PGS1, DGKE, LPGAT1, MBOAT1, DGKZ, GNPAT,

Glycerophospholipid

DGKH, PCYTIA, PTDSS1, LPINI

metabolism

GO: 0003841~1-
3
CRLS1, LPGATI, MBOAT1

acylglycerol-3-

phosphate O-

acyltransferase activity

Enrichment Score:

0.7529768935912621

GO: 0000123~histone
7
ING4, ELP2, EP300, KANSLI, WDR5, CREBBP, TRRAP

acetyltransferase

complex

GO: 0043984~histone
6
MSL2, ING4, KANSLI, KMT2A, MSL1, WDR5

H4-K16

acetylation

GO: 0043981~histone
3
ING4, KANSLI, WDR5

H4-K5 acetylation

GO: 0043982~histone
3
ING4, KANSLI, WDR5

H4-K8 acetylation

Enrichment Score:

0.7505920508733883

GO: 0000724~double-
14
RAD51C, HUS1, SMC5, INO80, SMC6, RAD50, ATM, WDR48, RPA1,

strand break repair

RECQL, NABP1, NSMCE1, RNF138, NSMCE2

via homologous

recombination

GO: 0000722~telomere
7
RPA1, RAD51C, RFC2, SMC5, NSMCE2, SMC6, RAD50

maintenance via

recombination

DNA recombination
11
RPA1, RAD51C, NSMCE1, SMC5, INO80, NSMCE2, SMC6, ACTL6A,

INO80D, INO80C, INO80B

Enrichment Score:

0.7363395749707299

GO: 0030422~
3
PRKRA, DICER1, MRPL44

production of siRNA

involved in RNA

interference

GO: 0031054~pre-
4
PRKRA, DICER1, AGO2, MRPL44

miRNA processing

IPR014720: Double-
6
CDKN2AIP, PRKRA, DICER1, STAU2, STAU1, MRPL44

stranded RNA-

binding-like domain

Enrichment Score:

0.7343641660048325

repeat: HEAT 5
8
BTAF1, EIF4G3, NIPBL, KIAA0368, CAND1, PSME4, TNPO2, TNPO1

repeat: HEAT 3
10
HEATR6, BTAF1, EIF4G3, NIPBL, KIAA0368, TBCD, CAND1, PSME4,

TNPO2, TNPO1

repeat: HEAT 4
9
HEATR6, BTAF1, EIF4G3, NIPBL, KIAA0368, CAND1, PSME4, TNPO2,

TNPO1

repeat: HEAT 2
11
HEATR6, BTAF1, EIF4G3, NIPBL, KIAA0368, TBCD, CAND1, PSME4,

TNPO2, UTP20, TNPO1

repeat: HEAT 1
11
HEATR6, BTAF1, EIF4G3, NIPBL, KIAA0368, TBCD, CAND1, PSME4,

TNPO2, UTP20, TNPO1

repeat: HEAT 8
5
BTAF1, KIAA0368, CAND1, TNPO2, TNPO1

repeat: HEAT 6
6
BTAF1, KIAA0368, CAND1, PSME4, TNPO2, TNPO1

repeat: HEAT 7
5
BTAF1, KIAA0368, CAND1, TNPO2, TNPO1

repeat: HEAT 13
3
KIAA0368, CAND1, TNPO2

repeat:HEAT 12
3
KIAA0368, CAND1, TNPO2

repeat: HEAT 11
3
KIAA0368, CAND1, TNPO2

repeat: HEAT 10
3
KIAA0368, CAND1, TNPO2

repeat: HEAT 9
3
KIAA0368, CAND1, TNPO2

Enrichment Score:

0.7306880194943396

GO: 0070555~response
8
IRAK1, RELA, IGBP1, CREBBP, ANXA1, PRKCI, RIPK2, LGALS9

to interleukin-1

GO: 0034134~toll-
3
IRAK1, RIPK2, LGALS9

like receptor 2

signaling pathway

GO: 0034142~toll-
4
IRAK1, LY96, RIPK2, LGALS9

like receptor 4

signaling pathway

Enrichment Score:

0.7265386581976017

domain: JmjC
8
KDM2A, UTY, JMJD6, JMJD8, KDM4C, JMJDIC, KDM5B, KDM5C

IPR003347: JmjC
8
KDM2A, UTY, JMJD6, JMJD8, KDM4C, JMJDIC, KDM5B, KDM5C

domain

SM00558:JmjC
7
KDM2A, UTY, JMJD6, KDM4C, JMJDIC, KDM5B, KDM5C

GO:0032452~histone
6
KDM2A, UTY, JMJD6, KDM4C, KDM5B, KDM5C

demethylase

activity

domain: JmjN
3
KDM4C, KDM5B, KDM5C

Dioxygenase
12
ADI1, ALKBH7, KDM2A, UTY, JMJD6, ETHE1, KDM4C, EGLN1, JMJDIC,

KDM5B, ALKBH5, KDM5C

SM00545: JmjN
3
KDM4C, KDM5B, KDM5C

IPR003349:
3
KDM4C, KDM5B, KDM5C

Transcription factor jumonji,

JmjN

GO: 0051213~
4
ALKBH7, UTY, KDM4C, JMJDIC

dioxygenase activity

metal ion-binding
4
KDM2A, JMJD6, KDM4C, JMJDIC

site: Iron; catalytic

Enrichment Score:

0.7246856105034599

zinc finger
3
PIAS4, NSMCE2, PIAS1

region: SP-RING-

type

IPR004181: Zinc
3
PIAS4, NSMCE2, PIAS1

finger, MIZ-type

GO: 0019789~SUM
4
PIAS4, NSMCE2, PIAS1, RANBP2

O transferase activity

Enrichment Score:

0.7213724303242848

GO: 0002223~
21
PSMB10, RELA, CREBBP, ICAM3, RAF1, MALT1, PRKCD, TAB3, NRAS,

stimulatory C-type lectin

PSMD13, PSMC5, EP300, KRAS, PSMD12, PSMC2, PSMD3, PRKACB,

receptor signaling

PSMD5, PSME4, FBXW11, CHUK

pathway

GO: 0022624~
6
PSMD13, PSMC5, PSMD12, PSMC2, PSMD3, PSMD5

proteasome accessory

complex

GO: 0033209~tumor
20
PSMB10, TRAF2, TNFRSF10A, TNFRSFIA, BAG4, TNFRSF9, PSMD13,

necrosis factor-

PSMC5, PSMD12, TNFSF13B, PSMC2, RIPK1, PYCARD, PSMD3, JAK2,

mediated signaling

PSMD5, PSME4, MAP3K14, CD27, TRAF3

pathway

GO: 0051436~negative
13
PSMB10, ANAPC4, CDC23, ANAPC10, CDC27, CDK2, PSMD13, PSMC5,

regulation of

PSMD12, PSMC2, PSMD3, PSMD5, UBE2E1

ubiquitin-protein

ligase activity

involved in mitotic

cell cycle

GO: 0031145~
14
PSMB10, ANAPC4, CDC23, ANAPC10, CDC27, CUL3, PSMD13, PSMC5,

anaphase-promoting

PSMD12, PSMC2, PSMD3, PSMD5, PSME4, UBE2E1

complex-dependent

catabolic process

GO: 0038061~NIK/
12
PSMB10, PSMD13, PSMC5, PSMD12, PSMC2, UBA3, PSMD3, PSME4,

NF-kappaB

PSMD5, MAP3K14, FBXW11, CHUK

signaling

GO: 0000502~
11
PSMB10, PSMD13, PSMC5, PSMD12, KIAA0368, ZFAND2A, PSMC2,

proteasome complex

HSPB1, PSMD3, PSME4, PSMD5

GO: 0051437~positive
13
PSMB10, ANAPC4, CDC23, ANAPC10, CDC27, PSMD13, PSMC5, PSMD 12,

regulation of

PSMC2, PSMD3, PSMD5, PSME4, UBE2E1

ubiquitin-protein

ligase activity

involved in

regulation of mitotic

cell cycle transition

GO:0008541~
3
PSMD13, PSMD12, PSMD3

proteasome regulatory

particle, lid

subcomplex

GO: 0031595~nuclear
3
PSMC5, PSMD12, PSMC2

proteasome

complex

GO: 0006521~regulation
9
PSMB10, PSMD13, PSMC5, PSMD12, PSMC2, PSMD3, AZIN1, PSME4,

of cellular

PSMD5

amino acid

metabolic process

hsa03050: Proteasome
8
PSMB10, PSMD13, PSMC5, PSMD12, PSMC2, IFNG, PSMD3, PSME4

Proteasome
8
PSMB10, PSMD13, PSMC5, PSMD12, KIAA0368, PSMC2, PSMD3, PSME4

GO: 0060071~Wnt
13
PSMB10, PSMD13, PSMC5, PSMD12, TIAMI, AP2A1, PSMC2, RACI,

signaling pathway,

PSMD3, SMURF2, PSME4, PSMD5, CLTC

planar cell polarity

pathway

GO: 0008540~
3
PSMC5, PSMC2, PSMD5

proteasome regulatory

particle, base

subcomplex

GO: 0090263~
16
PSMB10, RNF220, XIAP, PSMD13, PSMC5, PSMD12, CSNKID, CSNKIE,

positive regulation of

PSMC2, ILK, PSMD3, SMURF2, PSMD5, PSME4, USP34, RNF146

canonical Wnt

signaling pathway

GO: 0002479~antigen
8
PSMB10, PSMD13, PSMC5, PSMD12, PSMC2, PSMD3, PSME4, PSMD5

processing and

presentation of

exogenous peptide

antigen via MHC

class I, TAP-

dependent

GO: 0090090~negative
17
CSNK1A1, PSMB10, EGR1, RGS19, LATS1, CUL3, PSMD13, PSMC5,

regulation of

PSMD12, GSK3B, PSMC2, KIAA0922, PSMD3, PSMD5, PSME4, RAPGEF1,

canonical Wnt

APC

signaling pathway

Enrichment Score:

0.7193769298441833

domain: UBX
4
UBXN2A, UBXN2B, FAF2, FAF1

IPR001012: UBX
4
UBXN2A, UBXN2B, FAF2, FAF1

SM00166: UBX
3
UBXN2A, UBXN2B, FAF1

Enrichment Score:

0.7013692853684937

GO: 0004843~thiol-
15
STAMBP, OTUD5, USP3, USP5, USP4, BAP1, USP47, USP36, UCHL3, USP22,

dependent ubiquitin-

USP34, USP16, USP15, USP42, VCPIP1

specific protease

activity

Thiol protease
23
CAPN7, OTUD5, USP40, USPL1, USP3, USP5, USP4, BAP1, CTSL, ATG4B,

CASP7, CASP8, USP47, USP36, CTSC, UCHL3, USP22, USP34, USP16,

USP24, USP15, USP42, VCPIP1

IPR018200: Peptidase
12
USP40, USP3, USP5, USP4, USP47, USP36, USP22, USP16, USP34, USP24,

C19, ubiquitin

USP42, USP15

carboxyl-terminal

hydrolase 2,

conserved site

GO: 0016579~protein
15
STAMBP, OTUD5, USP40, USP3, USP5, USP4, BAP1, WDR48, UCHL3,

deubiquitination

USP36, USP22, USP34, USP24, USP15, USP42

IPR001394: Peptidase
12
USP40, USP3, USP5, USP4, USP47, USP36, USP22, USP16, USP34, USP24,

C19, ubiquitin

USP42, USP15

carboxyl-terminal

hydrolase 2

GO: 0036459~thiol-
9
USP40, USP3, USP4, USP36, USP22, USP34, USP24, USP42, USP15

dependent

ubiquitinyl

hydrolase activity

Enrichment Score:

0.694228209931004

Category
Count
Genes

Glucose metabolism
5
G6PD, PDK3, PGM1, DCXR, AKT2

Carbohydrate
14
PHKA2, GNPDA2, PDK3, PPP1CB, GALM, PGP, G6PD, GSK3B, PGM1,

metabolism

POFUT1, DCXR, YDJC, AKT2, PYGB

GO:0006006~glucose
11
GALM, WDTC1, G6PD, GNPDA2, PDK3, PGM1, HECTD4, PRKAA1, OAS1,

metabolic process

DCXR, AKT2

Enrichment Score:

0.6913577368544611

zinc finger
7
DGKE, DGKZ, PRKCH, DGKH, PRKCD, PRKD3, PRKCB

region: Phorbol-

ester/DAG-type 2

zinc finger
7
DGKE, DGKZ, PRKCH, DGKH, PRKCD, PRKD3, PRKCB

region: Phorbol-

ester/DAG-type 1

SM00046: DAGKc
4
DGKE, DGKZ, DGKH, CERK

domain: DAGKc
4
DGKE, DGKZ, DGKH, CERK

IPR001206: Diacylgl
4
DGKE, DGKZ, DGKH, CERK

ycerol kinase,

catalytic domain

IPR016064: ATP-
4
DGKE, DGKZ, DGKH, CERK

NAD kinase-like

domain

SM00045: DAGKa
3
DGKE, DGKZ, DGKH

IPR000756: Diacylgl
3
DGKE, DGKZ, DGKH

ycerol kinase,

accessory domain

hsa00561:Glycerolipid
9
DGKE, GLA, AKRIB1, MBOAT1, DGKZ, DGKH, LPINI, ALDH3A2,

metabolism

ALDH9A1

GO: 0004143~diacyl
3
DGKE, DGKZ, DGKH

glycerol kinase

activity

GO: 0046834~lipid
3
DGKE, DGKZ, CERK

phosphory lation

GO: 0007205~protein
5
DGKE, DGKZ, DGKH, PRKD3, IL2

kinase C-

activating G-protein

coupled receptor

signaling pathway

Enrichment Score:

0.6727450347449508

domain: Exonuclease
4
AEN, REXO1, ERI3, ISG20L2

Exonuclease
9
DIS3, EXOSC10, RAD1, CNOT8, CNOT6L, AEN, REXO1, ERI3, ISG20L2

SM00479: EXOIII
4
AEN, REXO1, ERI3, ISG20L2

IPR013520:Exonucl
4
AEN, REXO1, ERI3, ISG20L2

ease, RNase T/DNA

polymerase III

IPR012337: Ribonuc
12
EXOSC10, TEFM, CNOT8, KIAA1586, ZBED5, AEN, REXO1, AGO2,

lease H-like domain

RNASEH1, ERI3, ISG20L2, REV3L

GO: 0004527~
3
AEN, REXO1, ERI3

exonuclease activity

Enrichment Score:

0.6697712403636995

domain: BRCT 2
4
MDC1, TP53BP1, MCPH1, BARD1

domain: BRCT 1
4
MDC1, TP53BP1, MCPH1, BARD1

SM00292: BRCT
4
TP53BP1, MCPH1, PARP4, BARD1

IPR001357: BRCT
5
MDC1, TP53BP1, MCPH1, PARP4, BARD1

domain

Enrichment Score:

0.667787729765459

Category
Count
Genes

GO: 0031146~SCF-
6
FBXW7, FBXW5, FBXO6, FBXL5, FBXL15, FBXW11

dependent

proteasomal

ubiquitin-dependent

protein catabolic

process

GO: 0019005~SCF
9
FBXW7, FBXW5, FBXO6, USP47, FBXL5, FBXO25, FBXL15, FBXW11,

ubiquitin ligase

SPOP

complex

SM00256: FBOX
7
FBXW7, FBXW5, FBXO6, FBXL5, FBXW2, FBXW11, FBXO11

domain: F-box
11
FBXW7, KDM2A, FBXW5, FBXO6, FBXL5, FBXO25, FBXW2, FBXO34,

FBXL15, FBXW11, FBXO11

IPR001810: F-box
11
FBXW7, KDM2A, FBXW5, FBXO6, FBXL5, FBXO25, FBXW2, FBXO34,

domain, cyclin-like

FBXL15, FBXW11, FBXO11

Enrichment Score:

0.6636972705479839

GO: 1904354~negative
3
TERF2, ATM, RAD50

regulation of

telomere capping

Telomere
8
NSMCE1, SMC5, NSMCE2, SMC6, TINF2, TERF2, RAD50, TERFI

GO: 0003691~double-
3
TERF2, RAD50, TERFI

stranded telomeric

DNA binding

GO: 0007004~telomere
4
TERF2, ATM, RAD50, TERF1

maintenance via

telomerase

GO: 0000723~telomere
6
RPA1, HSPAIA, TERF2, ATM, RAD50, TERFI

maintenance

Enrichment Score:

0.6493097279002905

domain: Deacetylase
3
SIRT6, SIRT7, SIRT2

sirtuin-type

IPR003000: Sirtuin
3
SIRT6, SIRT7, SIRT2

family

IPR026590: Sirtuin
3
SIRT6, SIRT7, SIRT2

family, catalytic

core domain

GO:0070403~NAD +
3
SIRT6, SIRT7, SIRT2

binding

Enrichment Score:

0.633804002670718

domain: PI3K/PI4K
5
PIK3C2A, PI4K2B, TRRAP, PI4KB, ATM

IPR000403: Phospha-
5
PIK3C2A, PI4K2B, TRRAP, PI4KB, ATM

tidylinositol 3-/4-

kinase, catalytic

domain

SM00146: PI3Kc
4
PIK3C2A, TRRAP, PI4KB, ATM

IPR018936: Phospha-
3
PIK3C2A, PI4KB, ATM

tidylinositol 3/4-

kinase, conserved

site

Enrichment Score:

0.6336349362349432

SM00147: RasGEF
7
SH2D3C, SH2D3A, SOS1, RAPGEF6, RGL4, RAPGEF1, RALGDS

IPR023578: Ras
7
SH2D3C, SH2D3A, SOS1, RAPGEF6, RGL4, RAPGEF1, RALGDS

guanine nucleotide

exchange factor,

domain

IPR001895: Guanine-
7
SH2D3C, SH2D3A, SOS1, RAPGEF6, RGL4, RAPGEF1, RALGDS

nucleotide

dissociation

stimulator CDC25

domain: Ras-GEF
6
SH2D3C, SOS1, RAPGEF6, RGL4, RAPGEF1, RALGDS

SM00229: RasGEFN
4
SOS1, RAPGEF6, RAPGEF1, RALGDS

domain: N-terminal
4
SOS1, RAPGEF6, RAPGEF1, RALGDS

Ras-GEF

IPR000651: Ras-like
4
SOS1, RAPGEF6, RAPGEF1, RALGDS

guanine nucleotide

exchange factor, N-

terminal

IPR019804: Ras
3
SOS1, RAPGEF1, RALGDS

guanine-nucleotide

exchange factor,

conserved site

Enrichment Score:

0.6315415331478075

GO: 0005086~ARF
6
NCK2, GBF1, ARF4, PSD4, CYTH2, ARFGEF2

guany1-nucleotide

exchange factor

activity

h_arapPathway: ADP-
6
COPA, GBF1, ASAP1, CYTH2, ARFGEF2, ARAP2

Ribosylation Factor

IPR023394: SEC7-
4
GBF1, PSD4, CYTH2, ARFGEF2

like, alpha

orthogonal bundle

SM00222: Sec7
4
GBF1, PSD4, CYTH2, ARFGEF2

IPR000904: SEC7-
4
GBF1, PSD4, CYTH2, ARFGEF2

like

domain: SEC7
4
GBF1, PSD4, CYTH2, ARFGEF2

GO: 0032012~
4
GBF1, PSD4, CYTH2, ARFGEF2

regulation of ARF protein

signal transduction

Enrichment Score:

0.6256109532042883

repeat: MBT 3
3
MBTD1, L3MBTL2, L3MBTL3

repeat: MBT 2
3
MBTD1, L3MBTL2, L3MBTL3

repeat: MBT 1
3
MBTD1, L3MBTL2, L3MBTL3

SM00561: MBT
3
MBTD1, L3MBTL2, L3MBTL3

IPR004092: Mbt
3
MBTD1, L3MBTL2, L3MBTL3

repeat

Enrichment Score:

0.6246957617788174

DNA-binding
8
TOX, TCF7, HMGXB4, BBX, HMGXB3, HMG20B, HBP1, TOX4

region: HMG box

SM00398: HMG
9
TOX, TCF7, HMGXB4, KMT2C, BBX, HMGXB3, HMG20B, HBP1, TOX4

IPR009071: High
9
TOX, TCF7, HMGXB4, KMT2C, BBX, HMGXB3, HMG20B, HBP1, TOX4

mobility group

(HMG) box domain

Enrichment Score:

0.6234949961410196

GO: 0031588~
5
PRKAR2A, PRKAG2, PRKAB1, PRKAA1, SESN2

nucleotide-activated

protein kinase

complex

hsa04710: Circadian
8
CSNKID, CSNKIE, CREB1, PRKAG2, PRKAB1, PRKAA1, RORA, FBXW11

rhythm

GO: 0004679~AMP-
3
PRKAG2, PRKAB1, PRKAA1

activated protein

kinase activity

GO:0006633~fatty
9
ELOVL1, MSMO1, PRKAG2, PRKAB1, FASN, PRKAA1, ACSL3, PCCB,

acid biosynthetic

HSD17B8

process

h_chrebpPathway: C
5
PRKAR2A, PRKAG2, PRKAB1, PRKAA1, PRKACB

hREBP regulation

by carbohydrates

and cAMP

h_leptinPathway: Re
3
PRKAG2, PRKAB1, PRKAA1

versal of Insulin

Resistance by Leptin

Fatty acid
6
ELOVL1, PRKAG2, PRKAB1, FASN, PRKAA1, HSD17B8

biosynthesis

hsa05410: Hypertrophic
4
PRKAG2, PRKAB1, PRKAA1, ITGB1

cardiomyopathy

(HCM)

Enrichment Score:

0.6150311927361685

Isomerase
19
ECI1, FUOM, ECI2, EBP, FKBP5, TMX3, PDIA4, PIN4, PMM2, PUS7, NKTR,

PPIF, GALM, PPIG, PGM1, PPIL4, TOP2B, FKBP11, TRUB2

Cyclosporin
3
PPIF, PPIG, NKTR

GO: 0016018~cyclosporin
3
PPIF, PPIG, NKTR

A binding

Rotamase
7
PPIF, PPIG, FKBP5, PPIL4, PIN4, FKBP11, NKTR

GO: 0000413~protein
8
PPIF, PPIG, FKBP5, PPIL4, RANBP2, PIN4, FKBP11, NKTR

peptidy1-prolyl

isomerization

domain:PPIase
5
PPIF, PPIG, PPIL4, RANBP2, NKTR

cyclophilin-type

IPR002130:
5
PPIF, PPIG, PPIL4, RANBP2, NKTR

Cyclophilin-like peptidyl-

prolyl cis-trans

isomerase domain

GO: 0003755~peptidyl-
8
PPIF, PPIG, FKBP5, PPIL4, RANBP2, PIN4, FKBP11, NKTR

prolyl cis-trans

isomerase activity

IPR020892: Cyclophilin-
4
PPIF, PPIG, RANBP2, NKTR

type peptidy1-

prolyl cis-trans

isomerase,

conserved site

IPR024936: Cyclophilin-
4
PPIF, PPIG, PPIL4, NKTR

type peptidyl-

prolyl cis-trans

isomerase

Enrichment Score:

0.6145856221059713

SM00666: PB1
4
MAP3K3, NBR1, PRKCI, TFG

IPR000270: Phox/Be
4
MAP3K3, NBR1, PRKCI, TFG

m1p

domain: OPR
3
MAP3K3, NBR1, PRKCI

Enrichment Score:

0.6107555591477245

GO: 0000159~protein
6
PPP2R5A, STRN3, PPP2CB, STRN, PPP2R5E, PPP2R2D

phosphatase type

2A complex

GO: 0008601~protein
4
PPP2R5A, IGBP1, PPP2R5E, PPP2R2D

phosphatase type

2A regulator activity

GO: 0034047~
4
PPP2R5A, IGBP1, PPP2R5E, PPP2R2D

regulation of protein

phosphatase type 2A

activity

Enrichment Score:

0.6081273857570164

domain: DRBM 3
3
PRKRA, STAU2, STAU1

IPR014720:Double-
6
CDKN2AIP, PRKRA, DICER1, STAU2, STAU1, MRPL44

stranded RNA-

binding-like domain

SM00358: DSRM
4
PRKRA, DICER1, STAU2, STAU1

domain: DRBM 2
3
PRKRA, STAU2, STAU1

domain: DRBM 1
3
PRKRA, STAU2, STAU1

Enrichment Score:

0.6034239543605878

GO: 0070412~R-
6
FOS, TRIM33, JUN, PPMIA, SMAD3, LDLRAD4

SMAD binding

GO: 1902895~positive
5
FOS, RELA, JUN, SMAD3, SRF

regulation of pri-

miRNA

transcription from

RNA polymerase II

promoter

GO: 0060395~SMAD
6
LNPEP, FOS, JUN, HIPK2, NUP93, SMAD3

protein signal

transduction

Enrichment Score:

0.5981131911799106

GO: 0008625~extrinsic
12
TNFRSF10A, TNFRSF9, TNFRSFIA, MOAP1, CASP8AP2, BCL2, FADD,

apoptotic

BAD, DAXX, PIK3R1, DEDD2, CD27

signaling pathway

via death domain

receptors

SM00208: TNFR
4
TNFRSF10A, TNFRSF9, TNFRSFIA, CD27

repeat: TNFR-Cys 3
4
TNFRSF10A, TNFRSF9, TNFRSF1A, CD27

IPR001368: TNFR/
4
TNFRSF10A, TNFRSF9, TNFRSFIA, CD27

NGFR cysteine-rich

region

GO: 0005031~tumor
4
TNFRSF10A, TNFRSF9, TNFRSFIA, CD27

necrosis factor-

activated receptor

activity

repeat: TNFR-Cys 2
4
TNFRSF10A, TNFRSF9, TNFRSF1A, CD27

repeat: TNFR-Cys 1
4
TNFRSF10A, TNFRSF9, TNFRSFIA, CD27

Enrichment Score:

0.5972512359197256

GO: 0006661~
12
CDIPT, SH3YL1, MTMR14, PIK3C2A, INPP5D, PI4K2B, PIP5K1A, PI4KB,

phosphatidylinositol

MTMR6, PTEN, PIK3R1, SACMIL

biosynthetic process

hsa04070:
17
CDIPT, PIK3C2A, PPIP5K2, DGKH, PI4K2B, PIP5K1A, PI4KB, PTEN,

Phosphatidylinositol

TMEM55B, PRKCB, ITPR2, MTMR14, DGKE, DGKZ, INPP5D, MTMR6,

signaling system

PIK3R1

hsa00562:Inositol
9
CDIPT, MTMR14, PIK3C2A, INPP5D, PI4K2B, PIP5K1A, PI4KB, MTMR6,

phosphate

PTEN

metabolism

GO: 0046854~
6
PIK3C2A, PI4K2B, PIP5K1A, PI4KB, VAVI, PIK3R1

phosphatidylinositol

phosphorylation

Enrichment Score:

0.5959966330149766

IPR011249:
3
UQCRC1, IDE, PITRMI

Metalloenzyme, LuxS/M16

peptidase-like

IPR011237: Peptidase
3
UQCRC1, IDE, PITRMI

M16 domain

IPR011765: Peptidase
3
UQCRC1, IDE, PITRM1

M16, N-terminal

IPR007863: Peptidase
3
UQCRC1, IDE, PITRMI

M16, C-terminal

domain

GO: 0004222~
6
SPG7, UQCRC1, TRABD2A, IDE, PITRMI, NLN

metalloendopeptidase

activity

Enrichment Score:

0.5695312810104746

IPR003903: Ubiquitin
6
STAM2, ZFAND2B, HGS, DNAJB2, STAM, UIMC1

interacting motif

SM00726: UIM
4
STAM2, ZFAND2B, DNAJB2, UIMC1

repeat: UIM 2
3
ZFAND2B, DNAJB2, UIMC1

repeat: UIM 1
3
ZFAND2B, DNAJB2, UIMC1

Enrichment Score:

0.5600728887088808

Telomere
8
NSMCE1, SMC5, NSMCE2, SMC6, TINF2, TERF2, RAD50, TERFI

GO: 0070187~telosome
3
TINF2, TERF2, TERFI

GO: 0000783~nuclear
3
TINF2, TERF2, TERFI

telomere cap

complex

GO: 0016233~telomere
4
HIST4H4, TINF2, TERF2, TERF1

capping

GO: 0042162~telomeric
4
SMG5, TINF2, TERF2, TERFI

DNA binding

Enrichment Score:

0.5582412750967661

2.Cytokine_Receptors
5
MAPK1, SOS1, RAF1, VAVI, PIK3R1

h_il2rbPathway:IL-2
12
MAPK1, FOS, IL2RB, CRKL, SOCS3, BCL2, SOS1, SOCS1, CBL, RAF1, BAD,

Receptor Beta Chain

PIK3R1

in T cell Activation

h_ptenPathway: PTE
7
MAPK1, CDKNIB, SOS1, ILK, PTEN, ITGB1, PIK3R1

N dependent cell

cycle arrest and

apoptosis

h_cdmacPathway:
6
MAPK1, FOS, RELA, JUN, RAF1, PRKCB

Cadmium induces

DNA synthesis and

proliferation in

macrophages

h_ghPathway: Growth
8
MAPK1, SOS1, SOCS1, RAF1, JAK2, SRF, PIK3R1, PRKCB

Hormone

Signaling Pathway

68.Mitogen_signaling_
4
MAPK1, SOS1, MAP3K1, RAF1

in_growth_control

h_igf1rPathway:
7
MAPK1, PRKAR2A, SOS1, RAF1, PRKACB, BAD, PIK3R1

Multiple antiapoptotic

pathways from IGF-

1R signaling lead to

BAD

phosphorylation

82.TCR_and_Cap_or_
5
MAPK1, ZAP70, MAPK8, VAVI, WAS

SMAC

h_ngfPathway: Nerve
6
FOS, JUN, SOS1, RAF1, MAPK8, PIK3R1

growth factor

pathway (NGF)

h_her2Pathway: Role
6
MAPK1, EP300, IL6ST, SOS1, RAF1, PIK3R1

of ERBB2 in Signal

Transduction and

Oncology

54.T-cell anergy
6
MAPK1, SOS1, ZAP70, RAF1, MAPK8, IL2

h_spryPathway: Sprouty
5
MAPK1, SOS1, CBL, RAF1, RASA1

regulation of

tyrosine kinase

signals

h_cxcr4Pathway: CX
6
MAPK1, CXCR4, RELA, RAF1, PIK3R1, PRKCB

CR4 Signaling

Pathway

107.mRNA translation-
5
MAPK1, EIF4E, RAF1, EIF2B1, PIK3R1

protein synthesis

63.LAT_couples_T-
5
MAPK1, SOS1, ZAP70, VAVI, PIK3R1

cell_receptor

h_ecmPathway: Erk
5
MAPK1, ROCK1, RAF1, ITGB1, PIK3R1

and PI-3 Kinase Are

Necessary for

Collagen Binding in

Corneal Epithelia

106.Glycogen_synth
3
MAPK1, RAF1, PIK3R1

ase-synthesis

h_tffPathway: Trefoil
5
MAPK1, SOS1, BAD, ITGB1, PIK3R1

Factors Initiate

Mucosal Healing

h_sppaPathway:Aspi
4
MAPK1, RAF1, ITGB1, PRKCB

rin Blocks Signaling

Pathway Involved in

Platelet Activation

105.Signaling_gluco
3
MAPK1, RAF1, PIK3R1

se_uptake

h_erkPathway: Erk1/
5
MAPK1, SOS1, MKNK2, RAF1, ITGB1

Erk2 Mapk

Signaling pathway

h_ccr3Pathway: CCR
4
MAPK1, ROCK2, RAF1, PRKCB

3 signaling in

Eosinophils

h_biopeptidesPathw
6
MAPK1, SOS1, RAF1, MAPK8, JAK2, PRKCB

ay: Bioactive Peptide

Induced Signaling

Pathway

104.Insulin_signaling
4
MAPK1, SOS1, RAF1, PIK3R1

GO: 0014066~regulation
5
MAPK1, C3ORF58, PIP5KIA, VAV1, PIK3R1

of

phosphatidylinositol

3-kinase signaling

Enrichment Score:

0.5573531878002459

zinc finger
4
ARIH2, CUL9, MIB2, RNF216

region: RING-type 2

IPR002867: Zinc
4
ARIH2, CUL9, RBCK1, RNF216

finger, C6HC-type

zinc finger
3
ARIH2, CUL9, RNF216

region: IBR-type

SM00647: IBR
3
ARIH2, CUL9, RNF216

Enrichment Score:

0.5552661855962138

h_crebPathway:
8
MAPK1, PRKAR2A, CREB1, SOS1, RAC1, PRKACB, PIK3R1, PRKCB

Transcription factor

CREB and its

extracellular signals

h_igf1rPathway:
7
MAPK1, PRKAR2A, SOS1, RAF1, PRKACB, BAD, PIK3R1

Multiple antiapoptotic

pathways from IGF-

1R signaling lead to

BAD

phosphorylation

h_badPathway:
6
MAPK1, PRKAR2A, BCL2, PRKACB, BAD, PIK3R1

Regulation of BAD

phosphory lation

h_mPRPathway:
4
ARPCIA, MAPK1, PRKAR2A, PRKACB

How Progesterone

Initiates the Oocyte

Maturation

Enrichment Score:

0.5494432470362846

SM00568: GRAM
4
SBF1, NSMAF, GRAMDIA, TBC1D9B

domain: GRAM
4
TSC22D3, SBF1, NSMAF, GRAMDIA

IPR004182: GRAM
4
SBF1, NSMAF, GRAMDIA, TBCID9B

Enrichment Score:

0.547117417296358

GO: 1904885~beta-
3
CSNK1A1, GSK3B, APC

catenin destruction

complex assembly

GO: 0030877~beta-
4
CSNK1A1, GSK3B, RGS19, APC

catenin destruction

complex

h_wntPathway: WN
6
CSNK1A1, CTBP1, CSNKID, GSK3B, CREBBP, APC

T Signaling Pathway

GO: 1904886~beta-
3
CSNK1A1, GSK3B, APC

catenin destruction

complex

disassembly

Enrichment Score:

0.5364694676464031

IPR013763: Cyclin-
9
CCNT2, BRF1, BRF2, CCNH, CCNT1, CCNG1, CCNG2, GTF2B, CASD1

like

GO: 0000079~
8
CCNT2, CDKNIB, CCNT1, HERC5, CNPPD1, CDK7, CCNG1, PTEN

regulation of cyclin-

dependent protein

serine/threonine

kinase activity

SM00385: CYCLIN
7
CCNT2, BRF1, CCNH, CCNT1, CCNG1, CCNG2, GTF2B

GO: 1901409~
3
CCNT2, CCNH, CCNT1

positive regulation of

phosphorylation of

RNA polymerase II

C-terminal domain

Cyclin
6
CCNT2, CDKNIB, CCNH, CCNT1, CCNG1, CCNG2

GO: 0016538~cyclin-
3
CCNT2, CCNH, CCNT1

dependent protein

serine/threonine

kinase regulator

activity

IPR006671 :Cyclin,
5
CCNT2, CCNH, CCNT1, CCNG1, CCNG2

N-terminal

GO: 0045737~positive
4
CCNT2, CDKNIB, CCNH, CCNT1

regulation of

cyclin-dependent

protein

serine/threonine

kinase activity

Enrichment Score:

0.5349369033767776

IPR016192: APOBE
4
DCTD, APOBEC3G, APOBEC3C, APOBEC3D

C/CMP deaminase,

zinc-binding

GO: 0010529~
3
APOBEC3G, APOBEC3C, APOBEC3D

negative regulation of

transposition

IPR016193: Cytidine
4
DCTD, APOBEC3G, APOBEC3C, APOBEC3D

deaminase-like

IPR002125: CMP/dC
4
DCTD, APOBEC3G, APOBEC3C, APOBEC3D

MP deaminase, zinc-

binding

GO: 0016814~
3
APOBEC3G, APOBEC3C, APOBEC3D

hydrolase activity, acting

on carbon-nitrogen

(but not peptide)

bonds, in cyclic

amidines

IPR013158: APOBE
3
APOBEC3G, APOBEC3C, APOBEC3D

C-like, N-terminal

Enrichment Score:

0.5346599394830712

SM00233: PH
34
OSBP, ASAP1, CYTH2, ARHGAP15, APBBIIP, TIAMI, SOS1, SNTB1,

RTKN2, IPCEF1, DOCK10, RASA1, RASA2, AKT2, DNM3, ARHGEF3,

OSBPL3, VAV3, ARHGEF1, ROCK1, ROCK2, PSD4, DGKH, VAVI,

PLEKHA3, PLEKHF2, SBF1, DEF6, ACAP1, ACAP2, OSBPL11, ARAP2,

PRKD3, PLEKHA1

IPR011993: Pleckstrin
53
OSBP, ARHGAP15, TIAMI, NECAP2, SNTB1, NECAP1, MSN, RANBP2,

homology-like

NSMAF, DOCK10, AKT2, ARHGEF3, ANKSIA, ARHGEF1, ROCK, ROCK2,

domain

PSD4, WAS, MTMR12, SBF1, DEF6, ACAP1, FRMD4B, ACAP2, OSBPL11,

WASL, PRKD3, RABGAP1, LRBA, ASAP1, RABGAPIL, CYTH2, APBBIIP,

SOS1, RTKN2, TBC1D4, IPCEF1, TBC1D1, MTMR6, RASA1, RASA2, DNM3,

OSBPL3, VAV3, EVL, DGKH, VAV1, PLEKHA3, PLEKHF2, DCP1A, JAK2,

ARAP2, PLEKHAI

domain: PH
30
OSBP, ASAP1, CYTH2, ARHGAP15, APBBIIP, SOS1, RTKN2, IPCEF1,

DOCK10, RASA1, RASA2, AKT2, DNM3, ARHGEF3, OSBPL3, VAV3,

ARHGEF1, ROCK1, ROCK2, PSD4, DGKH, VAVI, PLEKHA3, PLEKHF2,

SBF1, DEF6, ACAP1, ACAP2, OSBPL11, PRKD3

IPR001849: Pleckstrin
34
OSBP, ASAP1, CYTH2, ARHGAP15, APBBIIP, TIAMI, SOS1, SNTB1,

homology domain

RTKN2, IPCEF1, DOCK10, RASA1, RASA2, AKT2, DNM3, ARHGEF3,

OSBPL3, VAV3, ARHGEF1, ROCK1, ROCK2, PSD4, DGKH, VAVI,

PLEKHA3, PLEKHF2, SBF1, DEF6, ACAP1, ACAP2, OSBPL11, ARAP2,

PRKD3, PLEKHA1

Enrichment Score:

0.5310103373589384

domain: Ubiquitin-
9
DDI2, HERPUD1, UHRF2, UBL4A, RBCK1, TMUB1, UBACI, UBLCP1,

like

HERPUD2

IPR000626:Ubiquitin
9
DDI2, HERPUD1, UHRF2, UBL4A, SACS, RBCK1, TMUB1, UBLCP1,

SM00213: UBQ
5
HERPUD1, UHRF2, UBL4A, UBLCP1, HERPUD2

Enrichment Score:

0.5255766583646028

GO: 0004386~helicase
17
BTAF1, DICER1, ANXA1, HELZ, CHD9, MOV10, CHD7, DDX23, DDX19A,

activity

GTF2F2, DHX34, DDX50, DDX10, ERCC3, SMARCA2, DDX51, DDX42

IPR011545: DNA/RNA
12
RECQL, DDX23, DHX29, DDX19A, DICER1, DHX34, DDX50, DHX16,

helicase,

SKIV2L2, DDX10, DDX51, DDX42

DEAD/DEAH box

type, N-terminal

IPR000629: RNA
5
DDX23, CETN2, DDX10, DDX51, DDX42

helicase, ATP-

dependent, DEAD-

box, conserved site

GO: 0010501~RNA
7
DDX23, DDX19A, DDX50, AGO2, DDX10, DDX51, DDX42

secondary structure

unwinding

short sequence
6
DDX23, DDX19A, DDX50, DDX10, DDX51, DDX42

motif: Q motif

GO: 0004004~ATP-
9
DDX23, DHX29, DDX19A, DHX34, DDX50, DHX16, DDX10, DDX51,

dependent RNA

DDX42

helicase activity

short sequence
5
DDX23, DDX19A, DDX10, DDX51, DDX42

motif: DEAD box

IPR014014: RNA
5
DDX23, DDX19A, DDX50, DDX10, DDX42

helicase, DEAD-box

type, Q motif

Enrichment Score:

0.5235257150362578

IPR003959: ATPase,
11
SPG7, LONP1, ATAD3A, PSMC5, RFC2, PSMC2, WRNIP1, ORC4, VPS4A,

AAA-type, core

SPATA5, SPAST

IPR003960: ATPase,
5
PSMC5, PSMC2, VPS4A, SPATA5, SPAST

AAA-type,

conserved site

SM00382: AAA
15
ABCF3, SPG7, WRNIP1, ABCB7, TOR2A, ATAD3A, LONP1, PSMC5, RFC2,

PSMC2, ORC4, VPS4A, DYNC1H1, SPATA5, SPAST

IPR003593: AAA+
15
ABCF3, SPG7, WRNIP1, ABCB7, TOR2A, ATAD3A, LONP1, PSMC5, RFC2,

ATPase domain

PSMC2, ORC4, VPS4A, DYNCIH1, SPATA5, SPAST

Enrichment Score:

0.5084367621409388

GO: 0002230~positive
20
TMEM203, TNIK, CRNKL1, PML, PTPN22, MBD5, NUP93, APOBEC3G,

regulation of

PEX3, FXR2, ANXA5, MRPS2, FAM13B, SIN3A, CD93, DNAAF2, RBM18,

defense response to

PYCARD, ALKBH5, MDH1

virus by host

GO: 0098792~
16
TMEM203, TNIK, CRNKL1, MBD5, NUP93, OPTN, PEX3, ANXA5, FXR2,

xenophagy

FAM13B, MRPS2, CD93, DNAAF2, RBM18, ALKBH5, MDH1

GO: 0098779~
15
TMEM203, CRNKL1, MBD5, NUP93, LARPIB, PEX3, ANXA5, FAM13B,

mitophagy in response to

MRPS2, CD93, DNAAF2, BLOCIS1, MEX3C, KRCC1, MDH1

mitochondrial

depolarization

Enrichment Score:

0.505808532604712

domain: BAH
3
MTA2, ASHIL, RERE

SM00439: BAH
3
MTA2, ASHIL, RERE

IPR001025: Bromo
3
MTA2, ASHIL, RERE

adjacent homology

(BAH) domain

Enrichment Score:

0.4971762083345744

GO: 0019706~protein-
6
GOLGA7, ZDHHC16, ZDHHC3, ZDHHC8, ZDHHC12, YKT6

cysteine S-

palmitoyltransferase

activity

zinc finger
5
ZDHHC16, ZDHHC3, KMT2C, ZDHHC8, ZDHHC12

region: DHHC-type

GO: 0016409~
4
ZDHHC16, ZDHHC3, ZDHHC8, ZDHHC12

palmitoyltransferase

activity

IPR001594: Zinc
5
ZDHHC16, ZDHHC3, KMT2C, ZDHHC8, ZDHHC12

finger, DHHC-type,

palmitoyltransferase

GO: 0018345~protein
4
ZDHHC16, ZDHHC3, ZDHHC8, ZDHHC12

palmitoylation

Enrichment Score:

0.48722466637005296

short sequence
4
MAPK1, MAPK6, MAPK13, MAPK8

motif: TXY

GO: 0004707~MAP
4
MAPK1, MAPK6, MAPK13, MAPK8

kinase activity

IPR003527:Mitogen-
3
MAPK1, MAPK13, MAPK8

activated protein

(MAP) kinase,

conserved site

hsa04723: Retrograde
7
MAPK1, ADCY7, MAPK13, MAPK8, PRKACB, PRKCB, ITPR2

endocannabinoid

signaling

Enrichment Score:

0.4869638417073476

h_cdmacPathway:
6
MAPK1, FOS, RELA, JUN, RAF1, PRKCB

Cadmium induces

DNA synthesis and

proliferation in

macrophages

GO: 1902895~positive
5
FOS, RELA, JUN, SMAD3, SRF

regulation of pri-

miRNA

transcription from

RNA polymerase II

promoter

GO: 0035994~
4
FOS, RELA, JUN, RAF1

response to muscle stretch

h_cardiacEGFPathw
4
FOS, RELA, JUN, PRKCB

ay:Role of EGF

Receptor

Transactivation by

GPCRs in Cardiac

Hypertrophy

GO: 0051591~
5
FOS, BSG, RELA, JUN, CDK2

response to CAMP

Enrichment Score:

0.48175618712662555

GO: 0016791~
9
DUSP4, DUSP28, DUSP16, DUSP23, CTDSP1, PTPN22, DUSP12, PPP1CB,

phosphatase activity

SACMIL

Protein phosphatase
20
PTPN7, PTPRE, PTPRA, STYX, DUSP23, PPMIA, DUSP22, PTPN22,

DUSP12, PPP1CB, PTEN, DUSP4, DUSP28, PGP, RPAP2, PPP2CB, DUSP16,

PPP3CB, CTDSP1, UBLCP1

SM00195: DSPc
7
DUSP4, DUSP28, DUSP16, STYX, DUSP23, DUSP22, DUSP12

IPR000340: Dual
8
DUSP4, DUSP28, DUSP16, STYX, DUSP23, DUSP22, DUSP12, PTEN

specificity

phosphatase,

catalytic domain

IPR020422: Dual
7
DUSP4, DUSP28, DUSP16, STYX, DUSP23, DUSP22, DUSP12

specificity

phosphatase,

subgroup, catalytic

domain

GO:0008138~protein
7
DUSP28, SBF1, STYX, DUSP23, DUSP22, DUSP12, PTEN

tyrosine/serine/threo

nine phosphatase

activity

IPR024950: Dual
6
DUSP4, DUSP28, DUSP16, STYX, DUSP22, DUSP12

specificity

phosphatase

active
12
PTPN7, DUSP4, DUSP28, PTPRE, PTPRA, DUSP16, DUSP23, DUSP22,

site: Phosphocysteine

PTPN22, DUSP12, MTMR6, PTEN

intermediate

domain: Tyrosine-
9
PTPN7, DUSP4, DUSP28, DUSP16, STYX, DUSP23, DUSP22, PTPN22,

protein phosphatase

DUSP12

GO: 0035335~
14
PTPN7, PTPRE, PTPRA, DUSP23, PTPN22, DUSP22, DUSP12, PTEN, DUSP4,

peptidyl-tyrosine

MTMR14, PGP, DUSP28, DUSP16, MTMR6

dephosphorylation

GO: 0004725~protein
14
PTPN7, PTPRE, PTPRA, DUSP23, PTPN22, DUSP22, DUSP12, PTEN, DUSP4,

tyrosine

MTMR14, PGP, DUSP28, DUSP16, MTMR6

phosphatase activity

IPR000387: Protein-
11
PTPN7, DUSP4, DUSP28, PTPRE, PTPRA, DUSP16, STYX, DUSP23, DUSP22,

tyrosine/Dual

PTPN22, DUSP12

specificity

phosphatase

IPR016130: Protein-
10
PTPN7, DUSP4, MTMR14, PTPRE, PTPRA, DUSP16, DUSP23, PTPN22,

tyrosine

MTMR6, PTEN

phosphatase, active

site

SM00404: PTPc_motif
8
PTPN7, DUSP4, PTPRE, PTPRA, DUSP23, PTPN22, MTMR6, PTEN

IPR003595:Protein-
8
PTPN7, DUSP4, PTPRE, PTPRA, DUSP23, PTPN22, MTMR6, PTEN

tyrosine

phosphatase,

catalytic

GO: 0000188~
4
DUSP4, DUSP16, DUSP22, GPS2

inactivation of MAPK

activity

SM00194: PTPc
4
PTPN7, PTPRE, PTPRA, PTPN22

IPR000242:Protein-
4
PTPN7, PTPRE, PTPRA, PTPN22

tyrosine

phosphatase,

receptor/non-

receptor type

Enrichment Score:

0.480513926399985

IPR001715: Calponin
14
PARVG, VAV3, ACTN4, CEP95, UTRN, IQGAP2, VAVI, FLNA, SYNE2,

homology domain

CAMSAP1, MAPRE2, CNN2, MAPRE1, PLEC

domain: CH 2
6
PARVG, SYNE2, ACTN4, UTRN, FLNA, PLEC

domain: CH 1
6
PARVG, SYNE2, ACTN4, UTRN, FLNA, PLEC

domain: Actin-
5
SYNE2, ACTN4, UTRN, FLNA, PLEC

binding

IPR001589: Actinin-
5
SYNE2, ACTN4, UTRN, FLNA, PLEC

type, actin-binding,

conserved site

SM00033: CH
10
PARVG, VAV3, SYNE2, ACTN4, UTRN, IQGAP2, CNN2, VAVI, FLNA,

PLEC

repeat: Spectrin 4
4
SYNE2, ACTN4, UTRN, PLEC

repeat: Spectrin 3
4
SYNE2, ACTN4, UTRN, PLEC

domain: CH
6
VAV3, IQGAP2, MAPRE2, CNN2, MAPRE1, VAVI

repeat: Spectrin 2
4
SYNE2, ACTN4, UTRN, PLEC

repeat: Spectrin 1
4
SYNE2, ACTN4, UTRN, PLEC

SM00150: SPEC
4
SYNE2, ACTN4, UTRN, PLEC

IPR018159: Spectrin/
4
SYNE2, ACTN4, UTRN, PLEC

alpha-actinin

IPR002017: Spectrin
3
SYNE2, ACTN4, UTRN

repeat

Enrichment Score:

0.46920356835197363

hsa04720: Long-term
14
CREBBP, RAF1, PPP1CB, PRKCB, ITPR2, NRAS, MAPK1, RPS6KA3, EP300,

potentiation

KRAS, CAMK4, ARAF, PPP3CB, PRKACB

hsa05223: Non-small
12
MAPK1, NRAS, E2F3, KRAS, RXRB, SOS1, ARAF, RAF1, BAD, PIK3R1,

cell lung cancer

PRKCB, AKT2

hsa05214: Glioma
11
MAPK1, NRAS, E2F3, KRAS, SOS1, ARAF, RAF1, PTEN, PIK3R1, PRKCB,

AKT2

65.Integrin_affinity
3
MAPK1, NRAS, KRAS

modulation

hsa04730: Long-term
9
GNA13, MAPK1, NRAS, KRAS, PPP2CB, ARAF, RAF1, PRKCB, ITPR2

depression

hsa05218: Melanoma
10
MAPK1, NRAS, E2F3, KRAS, ARAF, RAF1, BAD, PTEN, PIK3R1, AKT2

hsa04540: Gap
12
MAPK1, NRAS, KRAS, CSNKID, ADCY7, SOS1, RAF1, PRKACB, TUBAIA,

junction

TUBA1C, PRKCB, ITPR2

hsa04921: Oxytocin
20
ROCK1, ADCY7, ROCK2, PRKAG2, PRKAB1, RAF1, PPP1CB, PRKCB,

signaling pathway

ITPR2, FOS, NRAS, MAPK1, KRAS, CAMK4, JUN, PPP3CB, PRKAA1,

PRKACB, NFATC2, PIK3R1

hsa05219: Bladder
6
MAPK1, NRAS, E2F3, KRAS, ARAF, RAF1

cancer

hsa04725: Cholinergic
14
ADCY7, CREB1, PRKCB, ITPR2, NRAS, MAPK1, FOS, KRAS, CAMK4,

synapse

BCL2, JAK2, PRKACB, PIK3R1, AKT2

hsa04916: Melanogenesis
12
MAPK1, NRAS, TCF7, KRAS, EP300, ADCY7, CREB1, GSK3B, CREBBP,

RAF1, PRKACB, PRKCB

hsa04726: Serotonergic
8
MAPK1, NRAS, KRAS, ARAF, RAF1, PRKACB, PRKCB, ITPR2

synapse

hsa05034: Alcoholism
12
MAPK1, NRAS, HIST4H4, KRAS, CAMK4, CREB1, SOS1, ARAF, RAF1,

H3F3A, PKIA, PPP1CB

Enrichment Score:

0.4584026793393616

domain: DHR-2
3
DOCK2, DOCK8, DOCK 10

domain: DHR-1
3
DOCK2, DOCK8, DOCK10

IPR027357: DHR-2
3
DOCK2, DOCK8, DOCK10

domain

IPR027007: DHR-1
3
DOCK2, DOCK8, DOCK 10

domain

IPR026791: Dedicator
3
DOCK2, DOCK8, DOCK10

of cytokinesis

IPR010703: Dedicator
3
DOCK2, DOCK8, DOCK10

of cytokinesis C-

terminal

Enrichment Score:

0.45728497291694326

Nucleotidy ltransferase
13
POLK, FICD, CMAS, POLE3, POLRIA, OAS1, POLB, PCYTIA, PAPD5,

OAS2, ZCCHC6, POLR2B, REV3L

DNA-directed DNA
5
POLK, POLE3, POLB, PAPD5, REV3L

polymerase

GO: 0003887~DNA-
5
POLK, POLE3, POLB, PAPD5, REV3L

directed DNA

polymerase activity

GO: 0071897~DNA
3
POLE3, POLB, PAPD5

biosynthetic process

Enrichment Score:

0.44605748185239036

Signal transduction
9
RGS1, SOCS3, GSK3B, SOCS1, RGS19, SNX13, LDLRAD4, RGS14, SEC14L1

inhibitor

GO: 0001965~G-
5
NUCB1, RGS1, IGF2R, RGS19, RGS14

protein alpha-

subunit binding

IPR016137: Regulator
6
ARHGEF1, RGS1, RGS19, AKAP10, SNX13, RGS14

of G protein

signalling

superfamily

SM00315: RGS
5
RGS1, RGS19, AKAP10, SNX13, RGS14

domain: RGS
4
RGS1, RGS19, SNX13, RGS14

IPR024066: Regulator
3
RGS1, RGS19, RGS14

of G-protein

signaling, domain 1

Enrichment Score:

0.4417241398856797

GO: 0000729~DNA
4
KAT5, ATM, RAD50, BARD1

double-strand break

processing

GO: 0000732~strand
5
RAD51C, KAT5, ATM, RAD50, BARD1

displacement

GO: 0000731~DNA
6
RAD51C, WRNIP1, KAT5, ATM, RAD50, BARD1

synthesis involved in

DNA repair

GO: 0007131~
5
RAD51C, MSH6, MSH2, ATM, RAD50

reciprocal meiotic

recombination

Enrichment Score:

0.4412701245717094

zinc finger
3
ZCCHC3, ZCCHC6, ZCCHC7

region: CCHC-type 3

zinc finger
3
ZCCHC3, ZCCHC6, ZCCHC7

region: CCHC-type 2

zinc finger
3
ZCCHC3, ZCCHC6, ZCCHC7

region: CCHC-type 1

SM00343: ZnF C2HC
4
ZCCHC3, CPSF4, ZCCHC6, ZCCHC7

IPR001878: Zinc
5
ZCCHC3, ZCCHC10, CPSF4, ZCCHC6, ZCCHC7

finger, CCHC-type

Enrichment Score:

0.42704739477485376

h_crebPathway:
8
MAPK1, PRKAR2A, CREB1, SOS1, RAC1, PRKACB, PIK3R1, PRKCB

Transcription factor

CREB and its

extracellular signals

h_agpcrPathway:
3
PRKAR2A, PRKACB, PRKCB

Attenuation of GPCR

Signaling

h_nos1Pathway:
4
PRKAR2A, PPP3CB, PRKACB, PRKCB

Nitric Oxide Signaling

Pathway

Enrichment Score:

0.42570578914927665

h_gpcrPathway:
10
FOS, PRKAR2A, RPS6KA3, JUN, CREB1, PPP3CB, RAF1, PRKACB,

Signaling Pathway from

NFATC2, PRKCB

G-Protein Families

h_dreamPathway:
5
FOS, PRKAR2A, JUN, CREB1, PRKACB

Repression of Pain

Sensation by the

Transcriptional

Regulator DREAM

hsa05031:
8
FOS, CAMK4, JUN, CREB1, PPP3CB, PRKACB, PPP1CB, PRKCB

Amphetamine addiction

hsa05030: Cocaine
4
RELA, JUN, CREB1, PRKACB

addiction

hsa04713: Circadian
6
MAPK1, FOS, ADCY7, CREB1, PRKACB, PRKCB

entrainment

Enrichment Score:

0.4211948096599511

GO: 0000132~
6
NUMA1, NDE1, NDEL1, MCPH1, PAFAH1B1, DYNLTI

establishment of mitotic

spindle orientation

GO: 2000574~
3
NDE1, NDEL1, PAFAHIBI

regulation of microtubule

motor activity

GO: 0047496~
3
NDE1, NDEL1, PAFAHIB1

vesicle transport along

microtubule

GO: 0001764~
9
NDE1, NDEL1, CXCR4, CCR4, GATA3, PAFAHIB1, TOP2B, SRF, MARK2

neuron migration

GO: 0005871~
4
NDE1, NDEL1, KLC1, PAFAHIBI

kinesin complex

Enrichment Score:

0.4188790271143383

domain: Ras-
6
RASSF3, RAPGEF6, MYO9B, APBBIIP, ARAP2, RALGDS

associating

SM00314: RA
5
RASSF3, RAPGEF6, MYO9B, APBBIIP, RALGDS

IPR000159: Ras-
6
RASSF3, RAPGEF6, MYO9B, APBBIIP, ARAP2, RALGDS

association

Enrichment Score:

0.41763318415020556

GO: 0030148~
10
ELOVL1, SPTLC2, CSNK1G2, VAPB, CERS2, CERS6, SPTSSA, KDSR,

sphingolipid biosynthetic

CERS4, ALDH3A2

process

IPR016439: Longevity
3
CERS2, CERS6, CERS4

assurance,

LAGI/LAC1

PIRSF005225:
3
CERS2, CERS6, CERS4

longevity assurance

protein LAGI/LAC1

GO: 0046513~
6
SAMD8, SPTLC2, CERS2, CERS6, SPTSSA, CERS4

ceramide biosynthetic

process

GO: 0050291~
3
CERS2, CERS6, CERS4

sphingosine N-

acyltransferase

activity

hsa00600:
8
SPTLC2, GLA, CERS2, CERS6, KDSR, CERS4, CERK, ASAHI

Sphingolipid metabolism

domain: TLC
3
CERS2, CERS6, CERS4

SM00724: TLC
3
CERS2, CERS6, CERS4

IPR006634: TRAM/
3
CERS2, CERS6, CERS4

LAG1/CLN8

homology domain

Homeobox
8
HIPK1, CERS2, ZHX1, HIPK2, HOPX, CERS6, CERS4, ZEB1

DNA-binding
3
CERS2, CERS6, CERS4

region: Homeobox

IPR001356:
6
CERS2, ZHX1, HOPX, CERS6, CERS4, ZEB1

Homeodomain

SM00389: HOX
3
ZHX1, HOPX, ZEB1

Enrichment Score:

0.41325609345633085

IPR023214: HAD-
15
NT5C3A, CMAS, ATP11A, CECR5, LPINI, PMM2, PGP, ATP13A1, ATP2B4,

like domain

ATP2C1, ATP8B2, CTDSP1, ENOPH1, UBLCP1, NT5C

active site:4-
6
ATP13A1, ATP2B4, ATP2C1, ATP11A, ATP8B2, CTDSP1

aspartylphosphate

intermediate

IPR018303: P-type
5
ATP13A1, ATP2B4, ATP2C1, ATP11A, ATP8B2

ATPase,

phosphorylation site

IPR023299: P-type
5
ATP13A1, ATP2B4, ATP2C1, ATP11A, ATP8B2

ATPase,

cytoplasmic domain N

IPR008250: P-type
5
ATP13A1, ATP2B4, ATP2C1, ATP11A, ATP8B2

ATPase, A domain

IPR001757: Cation-
5
ATP13A1, ATP2B4, ATP2C1, ATP11A, ATP8B2

transporting P-type

ATPase

Enrichment Score:

0.40955924999908333

IPR016181: Acyl-
8
NAT6, SAT2, MGEA5, NAT10, KAT6B, KAT5, NAT9, ATE1

COA N-

acyltransferase

GO: 0008080~N-
5
ESCO1, NAT6, SAT2, NAT10, NAT9

acetyltransferase

activity

domain: N-
4
NAT6, SAT2, NAT10, NAT9

acetyltransferase

IPR000182: GNAT
4
NAT6, SAT2, NAT10, NAT9

domain

Enrichment Score:

0.4082289580528521

IPR001180: Citron-
4
TNIK, MAP4K1, VPS39, WDR45

like

SM00036: CNH
3
TNIK, MAP4K1, VPS39

domain: CNH
3
TNIK, MAP4K1, VPS39

Enrichment Score:

0.3922449877254785

repeat: ANK 25
3
ANKRD52, ANKRD17, ANKRD44

repeat:ANK 24
3
ANKRD52, ANKRD17, ANKRD44

repeat:ANK 22
3
ANKRD52, ANKRD17, ANKRD44

repeat:ANK 23
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 20
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 21
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 7
9
ANKRD52, ANKRD17, ANKRD44, NFKBIZ, EHMT1, MIB2, BCL3, FEMIB,

FEMIA

repeat: ANK 17
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 18
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 19
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 8
7
ANKRD52, ANKRD17, ANKRD44, EHMT1, MIB2, FEMIB, FEMIA

repeat: ANK 16
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 13
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 14
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 15
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 12
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 9
5
ANKRD52, ANKRD17, ANKRD44, MIB2, FEMIA

repeat: ANK 11
3
ANKRD52, ANKRD17, ANKRD44

repeat: ANK 10
3
ANKRD52, ANKRD17, ANKRD44

Enrichment Score:

0.38403808705196346

domain: CRIB
4
CDC42SE1, WASL, CDC42EP3, WAS

IPR000095: PAK-
4
CDC42SE1, WASL, CDC42EP3, WAS

box/P21-Rho-

binding

SM00285: PBD
3
WASL, CDC42EP3, WAS

Enrichment Score:

0.37683206426825694

Host cell receptor
9
ICAM1, LAMP1, CD55, CXCR4, SLC20A2, IDE, HSPAIA, SLC52A2, ITGB1

for virus entry

GO: 0001618~virus
10
ICAMI, LAMP1, CD55, CXCR4, SLC20A2, IDE, HSPAIA, SLC52A2, ITGB1,

receptor activity

DPP4

GO: 0046718~viral
11
ICAM1, LAMP1, CD55, SLC20A2, IDE, CD81, DYNLT1, HSPAIA, SLC52A2,

entry into host cell

ITGB1, DPP4

Enrichment Score:

0.37484614935515076

SM00461: WH1
3
EVL, WASL, WAS

IPR000697: EVH1
3
EVL, WASL, WAS

domain: WH1
3
EVL, WASL, WAS

GO:0008154~actin
3
EVL, WASL, WAS

polymerization or

depolymerization

GO:0007015~actin
9
NCK2, BCL2, PRKCI, BIN3, EVL, WASL, RHOF, WAS, WHAMM

filament

organization

Enrichment Score:

0.3728731212996016

h_eif4Pathway:
6
MAPK1, EIF4G3, EIF4E, PTEN, PIK3R1, PRKCB

Regulation of eIF4e and

p70 S6 Kinase

h_igf1mtorPathway:
5
EIF4E, GSK3B, PTEN, PIK3R1, EIF2B5

Skeletal muscle

hypertrophy is

regulated via

AKT/mTOR

pathway

h_mtorPathway: mT
5
EIF4G3, EIF4E, TSC1, PTEN, PIK3R1

OR Signaling

Pathway

Enrichment Score:

0.3673728728107017

GO: 1902187~
5
CHMP3, PML, TRIM27, TRIM26, TRIM25

negative regulation of viral

release from host

cell

GO: 0070206~protein
3
TRIM4, TRIM27, TRIM22

trimerization

SM00449:SPRY
13
TRIM4, TRIM38, BTN3A1, ASH2L, RSPRY1, TRIM69, SPSB3, TRIM27,

TRIM14, TRIM26, TRIM25, TRIM22, SPRYD4

domain: B30.2/SPRY
13
TRIM4, TRIM38, BTN3A1, ASH2L, RSPRY1, TRIM69, SPSB3, TRIM27,

TRIM14, TRIM26, TRIM25, TRIM22, SPRYD4

IPR003877: SPla/RY
13
TRIM4, TRIM38, BTN3A1, ASH2L, RSPRY1, TRIM69, SPSB3, TRIM27,

anodine receptor

TRIM14, TRIM26, TRIM25, TRIM22, SPRYD4

SPRY

IPR003879:
10
TRIM4, TRIM38, BTN3A1, TRIM69, TRIM14, TRIM27, TRIM26, TRIM25,

Butyrophylin-like

TRIM22, SPRYD4

SM00589: PRY
7
TRIM38, BTN3A1, TRIM69, TRIM14, TRIM27, TRIM26, TRIM25

IPR001870: B30.2/
13
TRIM4, TRIM38, BTN3A1, ASH2L, RSPRY1, TRIM69, SPSB3, TRIM27,

SPRY domain

TRIM14, TRIM26, TRIM25, TRIM22, SPRYD4

IPR006574: SPRY-
7
TRIM38, BTN3A1, TRIM69, TRIM14, TRIM27, TRIM26, TRIM25

associated

zinc finger region: B
8
TRIM4, TRIM38, TRIM14, TRIM27, RBCK1, TRIM26, TRIM22, MYCBP2

box-type

SM00336: BBOX
8
TRIM4, TRIM38, TRIM33, TRIM14, PML, TRIM27, TRIM26, TRIM22

IPR000315: Zinc
9
TRIM4, TRIM38, TRIM33, TRIM69, TRIM14, PML, TRIM27, TRIM26,

finger, B-box

TRIM22

IPR013320:
18
TSPEAR, SPSB3, NELL2, CLSTN1, TRIM27, LRBA, TRIM14, TRIM26,

Concanavalin A-like

TRIM25, TRIM22, SPRYD4, LGALS9, TRIM4, TRIM38, BTN3A1, ASH2L,

lectin/glucanase,

TRIM69, RSPRY1

subgroup

Enrichment Score:

0.3661268358100964

hsa04611: Platelet
18
GNA13, ORAII, ARHGEF1, ROCK1, ADCY7, ROCK2, PRKCI, STIM1,

activation

APBB1IP, PPP1CB, ITGB1, ITPR2, MAPK1, MAPK13, SNAP23, PRKACB,

PIK3R1, AKT2

hsa05205:
26
ITGB1, KRAS, TIAMI, SOS1, RAC1, NUDT16L1, PRKACB, MSN, PIK3R1,

Proteoglycans in cancer

AKT2, ARHGEF1, ROCK1, ROCK2, CBL, RAF1, CD63, PPP1CB, FLNA,

PRKCB, ITPR2, CTSL, NRAS, MAPK1, CBLB, MAPK13, ARAF

hsa04270: Vascular
14
GNA13, ARHGEF1, ROCK1, ADCY7, ROCK2, PRKCH, RAF1, PPP1CB,

smooth muscle

PRKCD, PRKCB, ITPR2, MAPK1, ARAF, PRKACB

contraction

Enrichment Score:

0.3655181734902265

IPR004088: K
7
ANKRD17, FMR1, KHSRP, MEX3C, EXOSC3, QKI, FXR2

Homology domain,

type 1

SM00322: KH
6
ANKRD17, FMR1, KHSRP, MEX3C, QKI, FXR2

IPR004087: K
6
ANKRD17, FMR1, KHSRP, MEX3C, QKI, FXR2

Homology domain

domain: KH 2
4
FMR1, KHSRP, MEX3C, FXR2

domain: KH 1
4
FMR1, KHSRP, MEX3C, FXR2

Enrichment Score:

0.3643845176662146

Electron transport
17
ENOX2, UQCRC1, NDUFB7, NDUFA9, TXN2, CYB5A, NDUFA10,

UQCRFS1, GLRX2, NDUFV3, SDHA, SDHC, NDUFV2, TXNRD1, NDUFS1,

ETFA, GLRX

hsa05016: Huntington's
27
UQCRC1, NDUFB7, TBP, CLTC, UQCRFS1, POLR2B, TBPL2, SIN3A,

disease

CASP8, ATP5H, NDUFS1, TBPL1, NDUFA9, CREB1, CREBBP, NDUFA10,

PPARGCIA, SDHA, PPIF, NDUFV3, NRF1, EP300, SP1, BBC3, AP2A1,

SDHC, NDUFV2

hsa05010: Alzheimer's
24
UQCRC1, APHIA, NDUFB7, NDUFA9, IDE, FADD, BAD, NDUFA10,

disease

UQCRFS1, NAE1, ITPR2, NDUFV3, ATF6, SDHA, TNFRSFIA, MAPK1,

CASP7, GSK3B, SDHC, CASP8, NDUFV2, PPP3CB, ATP5H, NDUFS1

GO: 0032981~
10
NDUFAF4, NDUFV3, TIMMDC1, NDUFB7, AIFM1, NDUFA9, NDUFV2,

mitochondrial respiratory

ECSIT, NDUFA10, NDUFS1

chain complex I

assembly

Respiratory chain
8
NDUFV3, UQCRC1, NDUFB7, NDUFA9, NDUFV2, UQCRFS1, NDUFA10,

NDUFS1

hsa00190: Oxidative
16
COX11, UQCRC1, NDUFB7, NDUFA9, ATP6VIH, NDUFA10, UQCRFS1,

phosphorylation

ATP6VIF, NDUFV3, SDHA, SDHC, ATP6VIE1, NDUFV2, ATP6VOD1,

ATP5H, NDUFS1

GO:0005747~
6
NDUFV3, NDUFB7, NDUFA9, NDUFV2, NDUFA10, NDUFS1

mitochondrial respiratory

chain complex I

GO: 0008137~NADH
6
NDUFV3, NDUFB7, NDUFA9, NDUFV2, NDUFA10, NDUFS1

dehydrogenase

(ubiquinone) activity

hsa05012: Parkinson's
16
UQCRC1, NDUFB7, NDUFA9, UBE2G1, UBE2J1, UBE2J2, NDUFA10,

disease

UQCRFS1, NDUFV3, PPIF, SDHA, SDHC, NDUFV2, PRKACB, ATP5H,

NDUFS1

GO: 0006120~
6
NDUFV3, NDUFB7, NDUFA9, NDUFV2, NDUFA10, NDUFS1

mitochondrial electron

transport, NADH to

ubiquinone

Ubiquinone
3
NDUFV2, NDUFA10, NDUFS1

Enrichment Score:

0.35390729447514874

IPR000209: Peptidase
4
TPP1, TPP2, PCSK7, FURIN

S8/S53 domain

IPR023828: Peptidase
3
TPP2, PCSK7, FURIN

S8, subtilisin, Ser-

active site

IPR022398: Peptidase
3
TPP2, PCSK7, FURIN

S8, subtilisin, His-

active site

IPR015500: Peptidase
3
TPP2, PCSK7, FURIN

S8, subtilisin-

related

IPR009020: Proteinase
3
TPP1, PCSK7, FURIN

inhibitor,

propeptide

Serine protease
9
LONP1, PARL, TPP1, TPP2, GZMB, PCSK7, RHBDD1, FURIN, DPP4

active site: Charge
11
APEH, CES2, ABHD17B, TPP1, TPP2, ABHD3, ABHD2, GZMB, PCSK7,

relay system

FURIN, DPP4

GO:0004252~serine-
14
GZMB, RHBDD1, FURIN, RHBDD2, IMMPIL, CTSL, APEH, LONP1, PARL,

type endopeptidase

TPP1, TPP2, CTSC, PCSK7, DPP4

activity

Enrichment Score:

0.3488604922902843

SM00849: SM00849
3
HAGH, ETHE1, CPSF3

IPR001279: Beta-
4
HAGH, ELAC2, ETHE1, CPSF3

lactamase-like

metal ion-binding
8
HAGH, EHMT1, ETHE1, ARAF, PML, RAF1, USP16, CPSF3

site: Zinc 1

Enrichment Score:

0.3388633674945358

GO: 0005851~
3
EIF2B1, EIF2B4, EIF2B5

eukaryotic translation

initiation factor 2B

complex

GO: 0043434~response
9
CD55, BSG, CDKNIB, BTG2, SOCS1, ANXA1, EIF2B1, EIF2B4, EIF2B5

to peptide

hormone

h_vegfPathway:
7
VHL, ELAVL1, EIF2B1, PIK3R1, EIF2B4, PRKCB, EIF2B5

VEGF, Hypoxia, and

Angiogenesis

GO: 0014003~
3
EIF2B1, EIF2B4, EIF2B5

oligodendrocyte

development

Leukodystrophy
3
EIF2B1, EIF2B4, EIF2B5

GO: 0009408~response
6
SOCS3, HSPAIA, MAP2K7, EIF2B1, EIF2B4, EIF2B5

to heat

Enrichment Score:

0.3332483915134039

IPR020103:
3
RPUSD3, TRUB2, PUS7

Pseudouridine synthase,

catalytic domain

GO: 0009982~
3
RPUSD3, TRUB2, PUS7

pseudouridine synthase

activity

GO: 0001522~
3
RPUSD3, TRUB2, PUS7

pseudouridine synthesis

Enrichment Score:

0.3283640348823858

SM00312: PX
7
SNX19, SNX29, PIK3C2A, SNX2, SNX4, SNX13, SNX11

GO: 0035091~
12
SNX19, SH3YL1, SNX29, ING2, PIK3C2A, PASK, SNX2, SNX4, PITPNC1,

phosphatidylinositol

SNX13, SNX11, ITPR2

binding

domain: PX
7
SNX19, SNX29, PIK3C2A, SNX2, SNX4, SNX13, SNX11

IPR001683:
7
SNX19, SNX29, PIK3C2A, SNX2, SNX4, SNX13, SNX11

Phoxhomologous domain

GO: 0016050~
4
SNX2, SNX4, WASL, SNX11

vesicle organization

Enrichment Score:

0.3248740734594386

72.IAP_interaction
5
TNFRSF1A, XIAP, CASP7, CASP8, FADD

with_cell_death_

pathways

h_mitochondriaPathway:
5
XIAP, AIFMI, CASP7, BCL2, CASP8

Role of

Mitochondria in

Apoptotic Signaling

h_caspasePathway:
5
XIAP, LMNB2, CASP7, CASP8, GZMB

Caspase Cascade in

Apoptosis

Enrichment Score:

0.3159225008635777

GO: 0004859~
3
ANXA1, ANXA5, ANXA2

phospholipase inhibitor

activity

Annexin
3
ANXA1, ANXA5, ANXA2

SM00335: ANX
3
ANXA1, ANXA5, ANXA2

IPR018502: Annexin
3
ANXA1, ANXA5, ANXA2

repeat

IPR018252: Annexin
3
ANXA1, ANXA5, ANXA2

repeat, conserved

site

IPR001464: Annexin
3
ANXA1, ANXA5, ANXA2

Calcium/
3
ANXA1, ANXA5, ANXA2

phospholipid-binding

repeat: Annexin 1
3
ANXA1, ANXA5, ANXA2

repeat: Annexin 3
3
ANXA1, ANXA5, ANXA2

repeat: Annexin 2
3
ANXA1, ANXA5, ANXA2

repeat: Annexin 4
3
ANXA1, ANXA5, ANXA2

GO: 0005544~calcium-
7
C2CD5, SYT11, ANXA1, CPNE1, SYTL3, ANXA5, ANXA2

dependent phospholipid

binding

Enrichment Score:

0.31228187414723185

h_cxcr4Pathway: CX
6
MAPK1, CXCR4, RELA, RAF1, PIK3R1, PRKCB

CR4 Signaling

Pathway

h_eif4Pathway:
6
MAPK1, EIF4G3, EIF4E, PTEN, PIK3R1, PRKCB

Regulation of eIF4e and

p70 S6 Kinase

h_edg1Pathway:
5
MAPK1, RAC1, PIK3R1, ASAHI, PRKCB

Phospholipids as

signalling

intermediaries

hsa04960:
4
MAPK1, KRAS, PIK3R1, PRKCB

Aldosterone-regulated

sodium reabsorption

Enrichment Score:

0.3071399535752837

SM00323: RasGAP
3
IQGAP2, RASA1, RASA2

IPR023152: Ras
3
IQGAP2, RASA1, RASA2

GTPase-activating

protein, conserved

site

domain: Ras-GAP
3
IQGAP2, RASA1, RASA2

IPR001936: Ras
3
IQGAP2, RASA1, RASA2

GTPase-activating

protein

Enrichment Score:

0.2948433234633509

IPR000225: Armadillo
7
USO1, KPNA6, ARMCX3, ARMC6, KPNA1, ARMC1, APC

repeat: ARM 3
6
USO1, KPNA6, ARMCX3, ARMC6, KPNA1, APC

repeat: ARM 2
6
USO1, KPNA6, ARMCX3, ARMC6, KPNA1, APC

repeat: ARM 4
5
USO1, KPNA6, ARMC6, KPNA1, APC

repeat: ARM 7
4
USO1, KPNA6, KPNA1, APC

repeat: ARM 6
4
USO1, KPNA6, KPNA1, APC

repeat: ARM 9
3
USO1, KPNA6, KPNA1

repeat: ARM 5
4
USO1, KPNA6, KPNA1, APC

SM00185:ARM
5
USO1, KPNA6, ARMC6, KPNA1, APC

repeat: ARM 1
4
USO1, ARMCX3, ARMC6, APC

repeat: ARM 8
3
USO1, KPNA6, KPNA1

Enrichment Score:

0.29256414347139453

IPR010920: Like-Sm
5
LSM14A, LSM14B, LSM3, LSM10, LSM1

(LSM) domain

SM00651: Sm
3
LSM3, LSM10, LSM1

leoprotein LSM

IPR001163: Ribonuc
3
LSM3, LSM10, LSM1

leoprotein LSM

domain

Enrichment Score:

0.28416826259197325

SM00450: RHOD
4
DUSP4, DUSP16, TSTD1, MPST

IPR001763: Rhodanese-
4
DUSP4, DUSP16, TSTD1, MPST

like domain

domain: Rhodanese
3
DUSP4, DUSP16, TSTD1

Enrichment Score:

0.2825610876287823

hsa00061: Fatty acid
4
FASN, ACSL4, ACSL3, ACSL5

biosynthesis

GO: 0102391~
3
ACSL4, ACSL3, ACSL5

decanoate -- CoA ligase

activity

hsa00071: Fatty acid
8
ECI1, ECI2, ACSL4, ACAT2, ACSL3, ALDH3A2, ALDH9A1, ACSL5

degradation

GO: 0004467~long-
3
ACSL4, ACSL3, ACSL5

chain fatty acid-CoA

ligase activity

GO: 0035338~long-
6
ELOVL1, ACOT9, FASN, ACSL4, ACSL3, ACSL5

chain fatty-acyl-

CoA biosynthetic

process

GO: 0001676~long-
3
ACSL4, ACSL3, ACSL5

chain fatty acid

metabolic process

hsa03320: PPAR
7
RXRB, ILK, ACSL4, PCK2, ACSL3, SCP2, ACSL5

signaling pathway

IPR020845: AMP-
3
ACSL4, ACSL3, ACSL5

binding, conserved

site

hsa01212: Fatty acid
5
FASN, ACSL4, ACAT2, ACSL3, ACSL5

metabolism

Fatty acid
11
ECI1, ELOVL1, PRKAG2, PRKAB1, FASN, PRKAAI, ACSL4, LPINI, ACSL3,

metabolism

ACSL5, HSD17B8

IPR000873: AMP-
3
ACSL4, ACSL3, ACSL5

dependent

synthetase/ligase

Enrichment Score:

0.2825385029515912

GO: 0051056~
19
ARHGEF3, VAV3, RALBP1, RALGAPB, ARHGAP17, MYO9B, ARHGAP15,

regulation of small

VAV1, FAM13B, ARHGAP30, RALGAPA1, TIAMI, SOS1, SIPAIL1, RAC1,

GTPase mediated

RHOT1, RHOT2, ARAP2, RHOF

signal transduction

FAM13B

SM00324: RhoGAP
8
ARHGAP30, RALBP1, MYO9B, ARHGAP17, ARHGAP15, ARAP2, PIK3R1,

FAM13B

IPR008936: Rho
11
ARHGAP30, RALBP1, IQGAP2, MYO9B, ARHGAP17, ARHGAP15, ARAP2,

GTPase activation

PIK3R1, RASA1, FAM13B, RASA2

protein

domain: Rho-GAP
8
ARHGAP30, RALBP1, MYO9B, ARHGAP17, ARHGAP15, ARAP2, PIK3R1,

FAM13B

IPR000198: Rho
8
ARHGAP30, RALBP1, MYO9B, ARHGAP17, ARHGAP15, ARAP2, PIK3R1,

GTPase-activating

FAM13B

protein domain

Enrichment Score:

0.27812245787260176

repeat: ANK 7
9
ANKRD52, ANKRD17, ANKRD44, NFKBIZ, EHMT1, MIB2, BCL3, FEMIB,

FEMIA

repeat: ANK 3
25
CAMTA2, OSTF1, NFKBID, NFKBIB, FEMIB, FEMIA, RFXANK,

ANKRD36, ANKRD52, ANKRD17, GABPB1, ILK, ANKRD37, BCL3,

HECTD1, IBTK, NFKBIZ, ANKSIA, EHMT1, ANKRD44, ACAP1, KRITI,

MIB2, ACAP2, BARD1

repeat: ANK 1
29
CAMTA2, OSTF1, NFKBID, NFKBIB, ASAP1, FEMIB, FEMIA, RFXANK,

ANKRD36, ANKRD52, ANKRD17, GABPB1, ILK, ANKRD37, BCL3,

HECTD1, IBTK, NFKBIZ, ANKSIA, EHMT1, GPANK1, ANKRD40,

ANKRD44, ACAP1, MIB2, KRITI, ACAP2, DGKZ, BARD1

repeat: ANK 2
29
CAMTA2, OSTF1, NFKBID, NFKBIB, ASAP1, FEMIB, FEMIA, RFXANK,

ANKRD36, ANKRD52, ANKRD17, GABPB1, ILK, ANKRD37, BCL3,

HECTD1, IBTK, NFKBIZ, ANKSIA, EHMT1, GPANK1, ANKRD40,

ANKRD44, ACAP1, MIB2, KRITI, ACAP2, DGKZ, BARD1

repeat: ANK 6
12
ANKRD52, ANKRD17, ANKRD44, NFKBIZ, ANKSIA, EHMTI, NFKBID,

MIB2, NFKBIB, BCL3, FEMIB, FEMIA

ANK repeat
29
CAMTA2, OSTF1, NFKBID, NFKBIB, ASAP1, FEMIB, FEMIA, RFXANK,

ANKRD36, ANKRD52, ANKRD17, GABPB1, ILK, ANKRD37, BCL3,

HECTD1, IBTK, NFKBIZ, ANKSIA, EHMT1, GPANK1, ANKRD40,

ANKRD44, ACAP1, MIB2, KRITI, ACAP2, DGKZ, BARD1

SM00248: ANK
27
OSTF1, NFKBID, NFKBIB, ASAP1, FEMIB, FEMIA, RFXANK, ANKRD36,

ANKRD52, ANKRD17, GABPB1, ILK, ANKRD37, BCL3, HECTD1, IBTK,

NFKBIZ, ANKS1A, EHMT1, ANKRD40, ANKRD44, ACAP1, MIB2, KRITI,

ACAP2, DGKZ, BARD1

IPR020683: Ankyrin
29
CAMTA2, OSTF1, NFKBID, NFKBIB, ASAP1, FEMIB, FEMIA, RFXANK,

repeat-containing

ANKRD36, ANKRD52, ANKRD17, GABPB1, ILK, ANKRD37, BCL3,

domain

HECTD1, IBTK, NFKBIZ, ANKSIA, EHMT1, GPANKI, ANKRD40,

ANKRD44, ACAP1, MIB2, KRITI, ACAP2, DGKZ, BARD1

repeat: ANK 4
18
NFKBIZ, ANKSIA, EHMT1, NFKBID, NFKBIB, FEMIB, FEMIA, RFXANK,

ANKRD36, ANKRD52, ANKRD17, GABPB1, ANKRD44, MIB2, KRITI, ILK,

BCL3, HECTD 1

repeat: ANK 5
15
NFKBIZ, ANKSIA, EHMT1, NFKBID, NFKBIB, FEMIB, RFXANK, FEMIA,

ANKRD52, ANKRD17, ANKRD44, GABPB1, MIB2, ILK, BCL3

IPR002110: Ankyrin
27
OSTF1, NFKBID, NFKBIB, ASAP1, FEMIB, FEMIA, RFXANK, ANKRD36,

repeat

ANKRD52, ANKRD17, GABPB1, ILK, ANKRD37, BCL3, HECTD1, IBTK,

NFKBIZ, ANKSIA, EHMT1, ANKRD40, ANKRD44, ACAP1, MIB2, KRITI,

ACAP2, DGKZ, BARD1

Enrichment Score:

0.2668097961653456

GO: 0042276~error-
4
RPA1, POLK, RFC2, REV3L

prone translesion

synthesis

DNA replication
12
RPA1, POLK, RBBP4, RFC2, WRNIP1, FAM111A, RRMI, CINP, ORC4,

POLB, MCM6, REV3L

GO: 0006297~
4
RPA1, POLK, RFC2, POLB

nucleotide-excision repair,

DNA gap filling

GO: 0019985~
5
RPA1, POLK, RFC2, TRIM25, REV3L

translesion synthesis

hsa03460: Fanconi
5
WDR48, RPA1, RAD51C, POLK, REV3L

anemia pathway

Enrichment Score:

0.25720288166374317

GO: 0004114~3′,5′-
5
PDE6D, PDE7A, PDE4B, PDE4D, RUNX1

cyclic-nucleotide

phosphodiesterase

activity

IPR002073: 3′5′-
4
PDE7A, PDE4B, PDE4D, RUNX1

cyclic nucleotide

phosphodiesterase,

catalytic domain

CAMP
5
PRKAR2A, PDE7A, PDE4B, PDE4D, PRKACB

GO: 0004115~3′,5′-
3
PDE7A, PDE4B, PDE4D

cyclic-AMP

phosphodiesterase

activity

GO: 0006198~CAMP
3
PDE7A, PDE4B, PDE4D

catabolic process

metal ion-binding
4
PTER, PDE7A, PDE4B, PDE4D

site: Divalent metal

cation 1

metal ion-binding
4
PTER, PDE7A, PDE4B, PDE4D

site: Divalent metal

cation 2

IPR023088:3′5′-
3
PDE7A, PDE4B, PDE4D

cyclic nucleotide

phosphodiesterase

IPR023174: 3′5′-
3
PDE7A, PDE4B, PDE4D

cyclic nucleotide

phosphodiesterase,

conserved site

hsa05032: Morphine
6
ADCY7, PDE7A, PDE4B, PDE4D, PRKACB, PRKCB

addiction

Enrichment Score:

0.24930966068454638

SM00326: SH3
24
FYB, DBNL, OSTF1, VAV3, STAM2, MPP6, ASAP1, VAVI, NCK2, DOCK2,

SH3YL1, CRKL, SH3GLB2, LASP1, PSTPIP1, STAM, UBASH3A, GRAP2,

BIN1, ABL2, RASA1, SASH3, PIK3R1, MATK

SH3 domain
24
FYB, DBNL, OSTF1, VAV3, STAM2, MPP6, ASAP1, VAVI, NCK2, DOCK2,

SH3YL1, CRKL, SH3GLB2, LASP1, PSTPIP1, STAM, UBASH3A, GRAP2,

BIN1, ABL2, RASA1, SASH3, PIK3R1, MATK

domain: SH3
19
FYB, DBNL, OSTF1, STAM2, MPP6, ASAP1, DOCK2, SH3YL1, SH3GLB2,

LASP1, PSTPIP1, UBASH3A, STAM, BINI, ABL2, RASA1, SASH3, PIK3R1,

MATK

IPR001452: Src
24
FYB, DBNL, OSTF1, VAV3, STAM2, MPP6, ASAP1, VAVI, NCK2, DOCK2,

homology-3 domain

SH3YL1, CRKL, SH3GLB2, LASP1, PSTPIP1, STAM, UBASH3A, GRAP2,

BIN1, ABL2, RASA1, SASH3, PIK3R1, MATK

Enrichment Score:

0.24872976470051114

GO: 0004004~ATP-
9
DDX23, DHX29, DDX19A, DHX34, DDX50, DHX16, DDX10, DDX51,

dependent RNA

DDX42

helicase activity

IPR011709: Domain
3
DHX29, DHX34, DHX16

of unknown function

DUF1605

SM00847: SM00847
3
DHX29, DHX34, DHX16

IPR007502: Helicase-
3
DHX29, DHX34, DHX16

associated domain

Enrichment Score:

0.23256970544677066

binding site: NADP
5
G6PD, AKR7A2, IDH2, GRHPR, DCXR

nucleotide
9
HSD17B11, HTATIP2, G6PD, AKRIB1, AKR7A2, IDH2, KDSR, GRHPR,

phosphate-binding

DCXR

region: NADP

NADP
15
HSD17B11, HTATIP2, GLUD2, PYROXDI, GRHPR, FARI, G6PD, AKRIB1,

AKR7A2, FASN, IDH2, KDSR, TXNRD1, DCXR, CRYZLI

Enrichment Score:

0.23055832452848027

GO: 0070125~
14
MRPL42, MRPS14, MRPS23, MRPS25, MRPS11, GFM2, MRPS9, TSFM,

mitochondrial

GFM1, MRPL16, MRPL55, MRPL34, MRPL44, MRPL35

translational

elongation

GO: 0070126~
13
MRPL42, MRPS23, MRPS14, MRPS25, MRPS11, MRRF, GFM2, MRPS9,

mitochondrial

MRPL16, MRPL55, MRPL34, MRPL44, MRPL35

translational

termination

GO: 0005763~
5
MRPL42, MRPS9, MRPS14, MRPS11, MRPS2

mitochondrial small

ribosomal subunit

Ribonucleoprotein
31
RALY, RPL17, MRPL42, MRPS14, MRPS11, LARPIB, HNRNPLL, LSM14A,

LSM14B, MRPL16, MRPL55, AGO2, LSM3, LSM1, MRPL34, MRPL35,

MRPS23, RXRB, MRPS25, EFTUD2, FMR1, MRPS2, RPS6KA3, HNRNPH2,

MRPS9, LSM10, PARP4, CPSF3, METTL 17, MVP, MRPL44

GO: 0006412~
25
RPL17, MRPL42, MRPS14, MRPS11, HBSIL, EIF4EBP2, MRPL16, AGO2,

translation

MRPL55, SLC25A28, MRPL34, MRPL35, MRPS23, EFTUD2, GTF2H3,

MRRF, MRPS2, SLC25A32, MRPS9, SLC25A38, FARSB, YARS2, SLC25A16,

SLC25A53, METTL17

Ribosomal protein
16
RPL17, MRPL42, MRPS14, MRPS23, RXRB, MRPS25, MRPS11, MRPS2,

RPS6KA3, MRPS9, MRPL16, MRPL55, MRPL34, METTL17, MRPL44,

MRPL35

GO: 0005840~ribosome
15
MRPL42, MRPS14, MRPS23, RXRB, MRPS25, MRPS11, MRPS2, RPS6KA3,

MRPS9, MRPL16, MRPL55, MRPL34, METTL 17, MRPL44, MRPL35

GO: 0003735~
17
RPL17, MRPL42, MRPS14, MRPS23, MRPS25, MRPS11, MRPS2, SLC25A32,

structural constituent of

MRPS9, MRPL16, SLC25A38, SLC25A28, MRPL55, SLC25A16, MRPL34,

ribosome

SLC25A53, MRPL35

hsa03010: Ribosome
8
RPL17, MRPS9, MRPS14, MRPL16, MRPS11, MRPL34, MRPS2, MRPL35

Enrichment Score:

0.23040649502848873

repeat: WD 8
9
WDR48, PHIP, TBL1XR1, EML3, ELP2, WDR6, TBLIX, PWP2, GEMIN5

repeat: WD 13
3
ELP2, PWP2, GEMIN5

repeat: WD 11
4
ELP2, WDR6, PWP2, GEMIN5

repeat: WD 10
4
ELP2, WDR6, PWP2, GEMIN5

repeat: WD 12
3
ELP2, PWP2, GEMIN5

repeat: WD 9
5
EML3, ELP2, WDR6, PWP2, GEMIN5

Enrichment Score:

0.2297546707824956

GO: 0033572~
7
SLC11A2, ATP6VIE1, RAB11B, ATP6VIH, CLTC, ATP6VOD1, ATP6VIF

transferrin transport

GO: 0016241~
7
CAPNS1, EXOC7, ATP6VIE1, ATP6VIH, MAPK8, ATP6VOD1, VPS26A

regulation of

macroautophagy

hsa04721: Synaptic
9
DNM3, AP2A1, ATP6VIE1, ATP6VIH, NAPA, VAMP2, CLTC, ATP6VOD1,

vesicle cycle

ATP6VIF

GO: 0046961~proton-
4
ATP6VIE1, ATP6VIH, ATP6VOD1, ATP6VIF

transporting

ATPase activity,

rotational

mechanism

hsa05110: Vibrio
7
ATP6VIE1, ATP6VIH, PRKACB, PDIA4, ATP6VOD1, ATP6VIF, PRKCB

cholerae infection

GO: 0090383~
4
ATP6VIE1, ATP6VIH, ATP6VOD1, ATP6VIF

phagosome acidification

GO: 0015991~ATP
4
ATP6VIE1, ATP6VIH, ATP6VOD1, ATP6VIF

hydrolysis coupled

proton transport

GO: 0015078~
4
SLC11A2, ATP6VOD1, ATP5H, ATP6VIF

hydrogen ion

transmembrane

transporter activity

Hydrogen ion
5
ATP6VIE1, ATP6VIH, ATP6VOD1, ATP5H, ATP6VIF

transport

hsa04966: Collecting
3
ATP6VIE1, ATP6VOD1, ATP6VIF

duct acid secretion

GO: 0015992~proton
4
ATP6VIE1, HVCN1, ATP6VOD1, ATP6VIF

transport

Enrichment Score:

0.22901571749480087

SM00156: PP2Ac
3
PPP2CB, PPP3CB, PPP1CB

IPR006186: Serine/
3
PPP2CB, PPP3CB, PPP1CB

threonine-specific

protein

phosphatase/bis(5-

nucleosy1)-

tetraphosphatase

IPR004843:
4
PPP2CB, PPP3CB, DBR1, PPP1CB

Metallophosphoesterase

domain

GO: 0004721~
6
PGP, PPP2CB, DUSP16, PPP3CB, PTEN, PPP1CB

phosphoprotein

phosphatase activity

metal ion-binding
4
PPP2CB, PPP3CB, EGLN1, PPP1CB

site: Iron

Enrichment Score:

0.219815162312881

domain: G-patch
4
CHERP, SUGP1, GPANK1, RBM10

SM00443: G_patch
4
CHERP, SUGP1, GPANK1, RBM10

IPR000467: G-patch
4
CHERP, SUGP1, GPANK1, RBM10

domain

Enrichment Score:

0.21462490830549383

SM00516: SEC14
4
TTPAL, GDAP2, BNIP2, SEC14L1

domain: CRAL-
4
TTPAL, GDAP2, BNIP2, SEC14L1

TRIO

IPR001251: CRAL-
4
TTPAL, GDAP2, BNIP2, SEC14L1

TRIO domain

Enrichment Score:

0.21380660245611388

GO: 0005385~zinc
4
SLC11A2, SLC30A5, SLC39A6, SLC39A3

ion transmembrane

transporter activity

GO: 0071577~zinc II
3
SLC30A5, SLC39A6, SLC39A3

ion transmembrane

transport

Zinc transport
3
SLC30A5, SLC39A6, SLC39A3

Enrichment Score:

0.2125851179351233

domain: BTB
18
BACH2, ZBTB10, ZBTB11, ZNF131, ZBTB40, KCTD20, KEAP1, KCTD2,

IVNS1ABP, KCTD6, ZBTB38, SHKBP1, KBTBD2, KLHL9, KCTD18, ZBTB2,

KLHL24, SPOP

SM00225: BTB
19
IBTK, BACH2, ZBTB10, ZBTB11, ZNF131, BTBD7, ZBTB40, KCTD20,

KEAP1, KCTD2, IVNSIABP, KCTD6, ZBTB38, SHKBP1, KBTBD2, KLHL9,

ZBTB2, KLHL24, SPOP

GO: 0031463~Cul3-
8
CUL3, KBTBD2, BACH2, KLHL9, KEAP1, KLHL24, KCTD2, SPOP

RING ubiquitin

ligase complex

IPR000210: BTB/PO
19
IBTK, BACH2, ZBTB10, ZBTB11, ZNF131, BTBD7, ZBTB40, KCTD20,

Z-like

KEAP1, KCTD2, IVNSIABP, KCTD6, ZBTB38, SHKBP1, KBTBD2, KLHL9,

ZBTB2, KLHL24, SPOP

IPR011333: BTB/PO
20
IBTK, BACH2, ZBTB10, ZBTB11, ZNF131, BTBD7, ZBTB40, KCTD20,

Z fold

KEAP1, KCTD2, IVNSIABP, ZBTB38, KCTD6, SHKBP1, KBTBD2, KLHL9,

KCTD18, ZBTB2, KLHL24, SPOP

Enrichment Score:

0.20376403779805952

Aminopeptidase
5
LNPEP, TPP2, ERAP1, DPP4, DNPEP

GO: 0004177~amino
4
LNPEP, TPP2, ERAPI, DNPEP

peptidase activity

GO: 0070006~
3
LNPEP, ERAPI, DNPEP

metalloaminopeptidase

activity

GO: 0008237~
7
STAMBP, LNPEP, CHMPIA, CNDP2, STAMBPL1, ERAPI, DNPEP

metallopeptidase activity

Enrichment Score:

0.195467663648754

h_cdc42racPathway:
4
ARPCIA, RAC1, WASL, PIK3R1

Role of PI3K

subunit p85 in

regulation of Actin

Organization and

Cell Migration

h_salmonellaPathway:
3
ARPCIA, RAC1, WASL

How does

salmonella hijack a

cell

h_actinYPathway:Y
3
ARPCIA, RACI, WASL

branching of actin

filaments

Enrichment Score:

0.19234790118499914

GO: 0030676~
4
DOCK2, VAV3, TIAMI, VAVI

Racguanyl-nucleotide

exchange factor

activity

IPR001331: Guanine-
4
ARHGEF3, VAV3, TIAMI, VAVI

nucleotide

dissociation

stimulator, CDC24,

conserved site

GO: 0035023~
8
ARHGEF3, VAV3, ARHGEF1, TIAMI, SOS1, RAF1, MYO9B, VAVI

regulation of Rho protein

signal transduction

domain: DH
6
ARHGEF3, VAV3, ARHGEF1, TIAMI, SOS1, VAVI

SM00325: RhoGEF
6
ARHGEF3, VAV3, ARHGEF1, TIAMI, SOS1, VAVI

IPR000219: Dbl
6
ARHGEF3, VAV3, ARHGEF1, TIAMI, SOS1, VAVI

homology (DH)

domain

GO: 0005089~
6
ARHGEF3, VAV3, ARHGEF1, TIAMI, SOS1, VAVI

Rhoguanyl-nucleotide

exchange factor

activity

Enrichment Score:

0.1850282990952521

region of
5
NR1H2, RXRB, NR4A1, RORA, MR1

interest: Ligand-

binding

IPR013088: Zinc
8
NR1H2, ESRRA, RXRB, GATA3, GATAD2A, NR4A1, RORA, RERE

finger, NHR/GATA-

type

GO: 0030522~
6
ESRRA, NCOA1, NCOA2, NR4A1, RORA, BRD8

intracellular receptor

signaling pathway

GO: 0004879~RNA
5
NR1H2, ESRRA, RXRB, NR4A1, RORA

polymerase II

transcription factor

activity, ligand-

activated sequence-

specific DNA

binding

GO: 0003707~
7
NR1H2, ESRRA, RXRB, PGRMC2, NR4A1, ABHD2, RORA

steroid hormone receptor

activity

GO: 0043401~
7
NR1H2, ESRRA, RXRB, PGRMC2, NR4A1, ABHD2, RORA

steroid hormone mediated

signaling pathway

DNA-binding
5
NR1H2, ESRRA, RXRB, NR4A1, RORA

region: Nuclear

receptor

zinc finger
5
NR1H2, ESRRA, RXRB, NR4A1, RORA

region: NR C4-type

SM00399: ZnF_C4
5
NR1H2, ESRRA, RXRB, NR4A1, RORA

IPR001628: Zinc
5
NR1H2, ESRRA, RXRB, NR4A1, RORA

finger, nuclear

hormone receptor-

type

SM00430: HOLI
5
NR1H2, ESRRA, RXRB, NR4A1, RORA

IPR001723: Steroid
5
NR1H2, ESRRA, RXRB, NR4A1, RORA

hormone receptor

IPR000536: Nuclear
5
NR1H2, ESRRA, RXRB, NR4A1, RORA

hormone receptor,

ligand-binding, core

Enrichment Score:

0.18471285738684817

IPR008984: SMAD/
7
MDC1, SLMAP, FOXK2, APTX, TIFA, SMAD3, IRF3

FHA domain

IPR000253: Forkhead-
5
MDC1, SLMAP, FOXK2, APTX, TIFA

associated (FHA)

domain

SM00240: FHA
3
MDC1, SLMAP, FOXK2

domain: FHA
4
MDC1, SLMAP, FOXK2, TIFA

Enrichment Score:

0.18296343468740298

GO:2000503~positive
3
CCL3, XCL1, CCL4

regulation of

natural killer cell

chemotaxis

GO: 0030593~
11
CCL3, VAV3, GBF1, PDE4B, CKLF, IFNG, PDE4D, XCLI, VAVI, CCL4,

neutrophil chemotaxis

XCL2

Chemotaxis
11
CCL3, IL16, CKLF, CMTM7, PLGRKT, CXCR3, XCL1, CMTM3, CCL4,

XCL2, LGALS9

GO: 0002548~
5
CCL3, ANXA1, XCL1, CCL4, XCL2

monocyte chemotaxis

GO: 0050729~
8
TNFRSF1A, CCL3, MAPK13, JAK2, XCL1, CCL4, XCL2, IL2

positive regulation of

inflammatory

response

GO: 0071346~
6
CCL3, HLA-DPA1, XCL1, CCL4, XCL2, LGALS9

cellular response to

interferon-gamma

GO: 0008009~chemo
5
CCL3, CKLF, XCL1, CCL4, XCL2

kine activity

GO: 0070098~chemo
7
CCL3, CXCR4, CCR4, CXCR3, XCL1, CCL4, XCL2

kine-mediated

signaling pathway

GO: 0071347~cellular
8
ICAM1, CCL3, RELA, PYCARD, RORA, XCL1, CCL4, XCL2

response to

interleukin-1

SM00199: SCY
4
CCL3, XCL1, CCL4, XCL2

IPR001811:
4
CCL3, XCL1, CCL4, XCL2

Chemokine interleukin-8-

like domain

GO: 0070374~
13
ICAM1, FBXW7, CCL3, JUN, PYCARD, RIPK2, DSTYK, PTPN22, XCL1,

positive regulation of

PTEN, CCL4, XCL2, LGALS9

ERK1 and ERK2

cascade

Enrichment Score:

0.17552852657218157

Pharmaceutical
9
LIF, CSF2, GLA, SOCS3, IFNG, MS4A1, ANXA1, CTLA4, IL2

h_stemPathway:
4
CSF2, CD8A, CSF1, IL2

Regulation of

hematopoiesis by

cytokines

88.Alternatively_
3
CSF2, CSF1, IFNG

Activated APC

h_inflamPathway:
4
CSF2, CSF1, IFNG, IL2

Cytokines and

Inflammatory

Response

IPR009079: Four-
5
LIF, CSF2, CSF1, IFNG, IL2

helical cytokine-like,

core

IPR012351: Four-
4
LIF, CSF2, IFNG, IL2

helical cytokine,

core

Growth factor
7
LIF, GMFB, CSF2, CD320, CSF1, GFER, IL2

GO: 0005125~
11
LIF, CSF2, IL16, TNFSF13B, FAM3C, CSF1, IFNG, CMTM7, CMTM3, CCL4,

cytokine activity

IL2

GO:0008083~
8
LIF, GMFB, CSF2, CD320, CSF1, GFER, NENF, IL2

growth factor activity

Enrichment Score:

0.1745910687704443

domain: LIM zinc-
3
ABLIMI, LPXN, LIMS1

binding 4

domain: LIM zinc-
4
ABLIMI, LPXN, LIMS1, ZYX

binding 3

LIM domain
7
ABLIMI, LIMA1, LPXN, LIMS1, LASP1, CSRP1, ZYX

domain:LIM zinc-
5
ABLIMI, LPXN, LIMS1, CSRP1, ZYX

binding 1

domain: LIM zinc-
5
ABLIMI, LPXN, LIMS1, CSRP1, ZYX

binding 2

SM00132: LIM
7
ABLIM1, LIMA1, LPXN, LIMS1, LASP1, CSRP1, ZYX

IPR001781: Zinc
7
ABLIMI, LIMA1, LPXN, LIMS1, LASP1, CSRP1, ZYX

finger, LIM-type

Enrichment Score:

0.16053907483471863

GO: 0051603~
7
PSMB10, CTSL, LONP1, CASP8, IDE, CTSA, CTSC

proteolysis involved in

cellular protein

catabolic process

GO: 0008234~
5
CTSL, ATG4B, CASP7, CASP8, CTSC

cysteine-type peptidase

activity

Zymogen
11
PSMB10, CTSL, TPP1, CASP7, CASP8, HEXB, CTSA, CTSC, GZMB, PCSK7,

FURIN

Enrichment Score:

0.15875242349997273

domain: EF-hand 5
5
PEF1, CAPNS1, NIN, SDF4, RCN2

calcium-binding
13
NUCB1, EFHD2, PEF1, CAPNS1, ACTN4, MCFD2, NUCB2, RHOT1, RHOT2,

region: 2

CETN2, CHP1, SDF4, RCN2

domain: EF-hand 4
7
PEF1, CAPNS1, NIN, CETN2, CHP1, SDF4, RCN2

IPR011992: EF-
30
S100A4, MCL1, REPS1, SPOCK2, UTRN, CETN2, ZZEF1, EFHD2, STAT6,

hand-like domain

PEF1, EHD1, SDF4, EHD4, TBC1D9B, SYNRG, CAPNS1, ACTN4, NIN, CBL,

S100A11, S100A10, CHP1, NUCB1, CBLB, DEF6, NUCB2, MCFD2, RHOT1,

RHOT2, RCN2

calcium-binding
13
NUCB1, EFHD2, PEF1, CAPNS1, ACTN4, MCFD2, NUCB2, RHOT1, RHOT2,

region: 1

CETN2, CHP1, SDF4, RCN2

IPR018247: EF-
17
S100A4, CAPNS1, ACTN4, REPS1, S100A11, CETN2, NUCB1, PEF1,

Hand 1, calcium-

GNPTAB, NUCB2, MCFD2, RHOT1, RHOT2, EHD1, SDF4, RCN2, EHD4

binding site

IPR002048: EF-hand
22
S100A4, CAPNS1, ACTN4, NIN, REPS1, S100A11, CHP1, CETN2, ZZEF1,

domain

EFHD2, NUCB1, PEF1, GNPTAB, NUCB2, MCFD2, RHOT1, RHOT2, EHD1,

SDF4, RCN2, TBC1D9B, EHD4

domain: EF-hand 2
16
S100A4, CAPNS1, NIN, ACTN4, S100A11, CHP1, CETN2, EFHD2, NUCB1,

PEF1, MCFD2, NUCB2, RHOT1, RHOT2, SDF4, RCN2

SM00054: EFh
12
S100A4, EFHD2, PEF1, ACTN4, NUCB2, RHOT1, S100A11, CETN2, CHP1,

ZZEF1, SDF4, RCN2

domain: EF-hand 1
15
S100A4, NIN, ACTN4, S100A11, CHP1, CETN2, EFHD2, NUCB1, PEF1,

MCFD2, NUCB2, RHOT1, RHOT2, SDF4, RCN2

domain: EF-hand 3
7
PEF1, CAPNS1, NIN, CETN2, CHP1, SDF4, RCN2

GO: 0005509~calcium
46
S100A4, PGS1, ME2, SPOCK2, REPS1, MGMT, CLSTN1, NELL2, CETN2,

ion binding

ZZEF1, EFHD2, PEF1, CD93, GNPTAB, PPP3CB, RUNX1, EHD1, SDF4,

EHD4, TBC1D9B, CAPNS1, NIN, ACTN4, C2CD5, SYT11, CBL, ANXA1,

S100A11, S100A10, CHP1, STIM1, ANXA5, ANXA2, ITPR2, NUCB1,

PLSCR1, CBLB, BNIP2, ATP2C1, MCFD2, NUCB2, RHOT1, CPNE1, RHOT2,

SYTL3, RCN2

Calcium
49
S100A4, ORAI1, SPOCK2, REPS1, ITGAE, CLSTN1, NELL2, UTRN,

TMEM63A, CETN2, OGDH, ITGB1, EFHD2, PEF1, ATP2B4, GNPTAB, TPP1,

SNTB1, ENTPD6, CERK, EHD1, SDF4, EHD4, CAPNS1, ACTN4, C2CD5,

SYT11, CBL, ANXA1, S100A11, CHP1, STIM1, ANXA5, FURIN, ANXA2,

PRKCB, ITPR2, NUCB1, PLSCR1, CBLB, HSPB11, CAMK4, ATP2C1,

MCFD2, NUCB2, RHOT1, RHOT2, TMCO1, RCN2

Enrichment Score:

0.1459899659776129

GO: 1904355~
3
MAPK1, MAPKAPK5, MAP2K7

positive regulation of

telomere capping

GO: 0032212~
4
MAPK1, MAPKAPK5, MAP2K7, ATM

positive regulation of

telomere

maintenance via

telomerase

GO: 0051973~
3
MAPK1, MAPKAPK5, MAP2K7

positive regulation of

telomerase activity

Enrichment Score:

0.14095903672022314

hsa05332: Graft-
5
IFNG, GZMB, HLA-DPA1, HLA-DPB1, IL2

versus-host disease

hsa05330: Allograft
5
IFNG, GZMB, HLA-DPA1, HLA-DPB1, IL2

rejection

hsa04672: Intestinal
6
TNFSF13B, CXCR4, HLA-DPA1, HLA-DPB1, MAP3K14, IL2

immune network for

IgA production

hsa04940: Type I
5
IFNG, GZMB, HLA-DPA1, HLA-DPB1, IL2

diabetes mellitus

hsa05320: Autoimmune
5
CTLA4, GZMB, HLA-DPA1, HLA-DPB1, IL2

thyroid disease

hsa05322: Systemic
6
HIST4H4, ACTN4, IFNG, H3F3A, HLA-DPA1, HLA-DPB1

lupus erythematosus

Enrichment Score:

0.1385599701644631

hsa00330: Arginine
6
CNDP2, SAT2, AGMAT, SMS, ALDH3A2, ALDH9A1

and proline

metabolism

hsa00410: beta-
4
CNDP2, SMS, ALDH3A2, ALDH9A1

Alanine metabolism

hsa00340: Histidine
3
CNDP2, ALDH3A2, ALDH9A1

metabolism

Enrichment Score:

0.13496059793813844

15.T-
5
CXCR4, CCR4, IFNG, CXCR3, TSN

cell_polarization-

chemokine_receptors

IPR000355:Chemokine
3
CXCR4, CCR4, CXCR3

receptor family

14.chemokine_recep
3
CXCR4, CCR4, CXCR3

tor-ligand

GO: 0070098~
7
CCL3, CXCR4, CCR4, CXCR3, XCL1, CCL4, XCL2

chemokine-mediated

signaling pathway

IPR000276: G
9
P2RY8, P2RY10, RABGAP1, HRH2, CXCR4, LPAR6, CCR4, LHCGR, CXCR3

protein-coupled

receptor, rhodopsin-

like

IPR017452: GPCR,
9
P2RY8, P2RY10, RABGAP1, HRH2, CXCR4, LPAR6, CCR4, LHCGR, CXCR3

rhodopsin-like, 7TM

Enrichment Score:

0.12648159925240066

domain: SAM
9
SAMD8, L3MBTL3, SAMD9, STIM1, SAMHD1, DGKH, ARAP2, SAMD9L,

SASH3

SM00454: SAM
9
SAMD8, ANKSIA, L3MBTL3, SAMD9, STIMI, SAMHD1, DGKH, ARAP2,

SASH3

IPR001660: Sterile
10
SAMD8, ANKSIA, L3MBTL3, SAMD9, STIM1, SAMHD1, DGKH, ARAP2,

alpha motif domain

SAMD9L, SASH3

IPR013761: Sterile
11
SAMD8, ETV7, ANKSIA, L3MBTL3, SAMD9, STIM1, SAMHD1, DGKH,

alpha motif/pointed

ARAP2, SAMD9L, SASH3

domain

Enrichment Score:

0.12568460664505718

SM00513: SAP
3
PIAS4, PIAS1, SAFB2

domain: SAP
3
PIAS4, PIAS1, SAFB2

IPR003034: SAP
3
PIAS4, PIAS1, SAFB2

domain

Enrichment Score:

0.12346097305495686

domain: C2
9
C2CD5, PIK3C2A, PKN2, PRKCH, WWC2, SMURF2, PRKCD, RASA1,

PRKCB

IPR000008: C2
17
CEP120, C2CD5, PIK3C2A, SYT11, PKN2, WWC2, PRKCH, PTEN, PRKCD,

calcium-dependent

PRKCB, GAK, UNC13D, CPNE1, SMURF2, SYTL3, RASA1, RASA2

membrane targeting

SM00239: C2
12
UNC13D, C2CD5, PIK3C2A, SYT11, PKN2, CPNE1, PRKCH, SMURF2,

SYTL3, RASA1, RASA2, PRKCB

Enrichment Score:

0.1227848794008889

repeat: 2-1
4
HNRNPH2, PRRC2A, CSTF2T, COIL

repeat: 2-2
4
HNRNPH2, PRRC2A, CSTF2T, COIL

repeat: 1-1
4
HNRNPH2, PRRC2A, CSTF2T, COIL

repeat: 1-2
3
HNRNPH2, PRRC2A, COIL

Enrichment Score:

0.1141619803729114

SM00253: SOCS
3
WSB1, SOCS3, SOCS1

domain: SOCS box
4
WSB1, SOCS3, SPSB3, SOCS1

SM00969: SM00969
4
WSB1, SOCS3, SPSB3, SOCS1

IPR001496: SOCS
4
WSB1, SOCS3, SPSB3, SOCS1

protein, C-terminal

Enrichment Score:

0.1035300297726019

GO: 0050660~flavin
8
SDHA, IVD, AIFMI, GFER, TXNRDI, DUSIL, ETFA, DUS3L

adenine dinucleotide

binding

Flavoprotein
12
SDHA, SQRDL, IVD, AIFM1, NDUFA9, PYROXD1, GFER, TXNRDI,

NDUFA10, DUSIL, ETFA, DUS3L

nucleotide
6
SDHA, TXNDC12, IVD, AIFM1, TXNRD1, ETFA

phosphate-binding

region: FAD

FAD
10
SDHA, SQRDL, IVD, AIFM1, NDUFA9, PYROXD1, GFER, TXNRDI,

NDUFA10, ETFA

IPR023753: Pyridine
5
SDHA, SQRDL, AIFMI, PYROXD1, TXNRD1

nucleotide-

disulphide

oxidoreductase,

FAD/NAD(P)-

binding domain

Enrichment Score:

0.09911308677931861

IPR001202: WW
6
UTRN, FNBP4, WWC2, IQGAP2, SMURF2, CEP164

domain

SM00456: WW
5
UTRN, FNBP4, WWC2, SMURF2, CEP164

domain: WW 2
3
FNBP4, WWC2, SMURF2

domain: WW 1
3
FNBP4, WWC2, SMURF2

Enrichment Score:

0.09869704499668493

IPR014352: FERM/
6
ECI2, FRMD8, KRIT1, FRMD4B, MSN, ACBD5

acyl-CoA-binding

protein, 3-helical

bundle

domain: FERM
5
FRMD8, KRITI, FRMD4B, JAK2, MSN

SM00295: B41
5
FRMD8, KRITI, FRMD4B, JAK2, MSN

IPR000299: FERM
5
FRMD8, KRIT1, FRMD4B, JAK2, MSN

domain

IPR019749: Band 4.1
5
FRMD8, KRITI, FRMD4B, JAK2, MSN

domain

IPR019748: FERM
5
FRMD8, KRIT1, FRMD4B, JAK2, MSN

central domain

Enrichment Score:

0.09404515348769645

GO: 0004623~
5
RARRES3, PNPLA8, ABHD3, PAFAHIB1, PAFAHIB2

phospholipase A2 activity

GO:0016042~lipid
7
PLD3, RARRES3, TBL1XR1, DDHD1, PAFAHIB1, PAFAHIB2, IAH1

catabolic process

Lipid degradation
8
PLD3, RARRES3, PNPLA8, DDHD1, ABHD2, PAFAHIBI, PAFAHIB2, IAH1

hsa00565: Ether lipid
3
PLD3, PAFAHIB1, PAFAHIB2

metabolism

Enrichment Score:

0.09224012967461757

GO: 0006418~tRNA
5
EEF1E1, FARS2, FARSB, WARS2, YARS2

aminoacylation for

protein translation

Aminoacy1-tRNA
4
FARS2, FARSB, WARS2, YARS2

synthetase

hsa00970: Aminoacyl-
5
FARS2, FARSB, WARS2, YARS2, MTFMT

tRNA biosynthesis

Enrichment Score:

0.09104106578512094

domain: BACK
4
KLHL9, KEAP1, KLHL24, IVNS1ABP

IPR015916: Galactose
4
KLHL9, KEAP1, KLHL24, IVNS1ABP

oxidase, beta-

propeller

GO: 0031463~Cul3-
8
CUL3, KBTBD2, BACH2, KLHL9, KEAP1, KLHL24, KCTD2, SPOP

RING ubiquitin

ligase complex

IPR017096: Kelch-
5
KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

like protein,

gigaxonin

PIRSF037037: kelch-
5
KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

like protein,

gigaxonin type

SM00875: SM00875
6
KBTBD2, KLHL9, BTBD7, KEAP1, KLHL24, IVNS1ABP

IPR011705: BTB/
6
KBTBD2, KLHL9, BTBD7, KEAP1, KLHL24, IVNS1ABP

KeIch-associated

repeat: Kelch 6
5
MKLN1, KLHL9, KEAP1, KLHL24, IVNS1ABP

repeat: Kelch 5
6
MKLN1, KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

IPR006652: Kelch
6
MKLN1, KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

repeat type 1

repeat: Kelch 4
6
MKLN1, KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

SM00612: Kelch
5
KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

Kelch repeat
6
MKLN1, KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

repeat: Kelch 2
6
MKLN1, KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

repeat: Kelch 3
6
MKLN1, KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

repeat: Kelch 1
6
MKLN1, KBTBD2, KLHL9, KEAP1, KLHL24, IVNS1ABP

IPR015915: Kelch-
3
MKLN1, KBTBD2, KEAP1

type beta propeller

Enrichment Score:

0.09096561156622553

GO: 0008037~cell
4
TIGIT, CD5, CD200, CD226

recognition

GO: 0050839~cell
5
TIGIT, MSN, CD200, ITGB1, CD226

adhesion molecule

binding

GO: 0007157~
4
TIGIT, ICAMI, CD200, CD226

heterophilic cell-cell

adhesion via plasma

membrane cell

adhesion molecules

GO: 0007156~
7
CD84, TIGIT, ME2, CLSTN1, CD200, ITGB1, CD226

homophilic cell adhesion

via plasma

membrane adhesion

molecules

Enrichment Score:

0.08637800045583548

GO: 0005544~
7
C2CD5, SYT11, ANXA1, CPNEI, SYTL3, ANXA5, ANXA2

calcium-dependent

phospholipid

binding

SM00239:C2
12
UNC13D, C2CD5, PIK3C2A, SYT11, PKN2, CPNE1, PRKCH, SMURF2,

SYTL3, RASA1, RASA2, PRKCB

domain: C2 2
5
UNC13D, SYT11, CPNE1, SYTL3, RASA2

domain: C2 1
5
UNC13D, SYT11, CPNE1, SYTL3, RASA2

Enrichment Score:

0.08611979646447755

IPR001751: S100/
3
S100A4, S100A11, S100A10

Calbindin-D9k,

conserved site

SM01394: SM01394
3
S100A4, S100A11, S100A10

IPR013787: S100/Ca
3
S100A4, S100A11, S100A10

BP-9k-type, calcium

binding, subdomain

Enrichment Score:

0.08562305074820027

GO: 0034199~activation
3
PRKAR2A, ADCY7, PRKACB

of protein kinase

A activity

GO: 0003091~renal
3
PRKAR2A, ADCY7, PRKACB

water homeostasis

GO: 0071377~cellular
3
PRKAR2A, ADCY7, PRKACB

response to

glucagon stimulus

Enrichment Score:

0.0850459219054058

DNA-binding
3
ETV7, ELF2, ELK3

region: ETS

SM00413: ETS
3
ETV7, ELF2, ELK3

IPR000418: Ets
3
ETV7, ELF2, ELK3

domain

Enrichment Score:

0.08339481617003926

GO: 0004715~non-
7
DYRKIA, ZAP70, RIPK2, JAK2, ABL2, PRKCD, MATK

membrane spanning

protein tyrosine

kinase activity

IPR001245: Serine-
15
IRAK1, RYK, DSTYK, RAFI, GAK, IRAK4, RIPK1, ARAF, ILK, ZAP70,

threonine/tyrosine-

RIPK2, JAK2, ABL2, MAP3K13, MATK

protein kinase

catalytic domain

Tyrosine-protein
11
CLK2, RYK, DYRKIA, CLK4, MAP2K4, ZAP70, DSTYK, JAK2, MAP2K7,

kinase

ABL2, MATK

GO: 0031234~extrinsic
7
KRAS, RGS1, TIAMI, ZAP70, JAK2, ABL2, MATK

component of

cytoplasmic side of

plasma membrane

GO: 0038083~peptidyl-
4
ZAP70, JAK2, ABL2, MATK

tyrosine

autophosphory lation

GO: 0004713~protein
13
CSF2, ZMYM2, CLK2, RYK, DYRKIA, CLK4, MAP2K4, ZAP70, DSTYK,

tyrosine kinase

JAK2, MAP2K7, ABL2, MATK

activity

GO: 0018108~peptidyl-
15
CSF2, ZMYM2, RYK, MAP2K4, TRIM27, DSTYK, PRKCD, CLK2, CLK4,

tyrosine

DYRKIA, ZAP70, RIPK2, JAK2, MAP2K7, ABL2

phosphorylation

GO: 0007169~trans
7
CD8A, CD8B, CSF1, ZAP70, RAPGEF1, ABL2, MATK

membrane receptor

protein tyrosine

kinase signaling

pathway

SM00219: TyrKc
5
RYK, ZAP70, JAK2, ABL2, MATK

IPR020635: Tyrosine-
5
RYK, ZAP70, JAK2, ABL2, MATK

protein kinase,

catalytic domain

IPR008266: Tyrosine-
5
RYK, ZAP70, JAK2, ABL2, MATK

protein kinase,

active site

Enrichment Score:

0.07308177427976495

GO: 0004553~
4
CHID1, GLA, HEXB, HEXDC

hydrolase activity,

hydrolyzing O-

glycosyl compounds

IPR017853: Glycoside
5
CHID1, GLA, HEXB, MGEA5, HEXDC

hydrolase,

superfamily

Glycosidase
7
GLA, NEIL2, HEXB, MGEA5, MOGS, OGGI, HEXDC

IPR013781: Glycoside
3
CHID1, HEXB, HEXDC

hydrolase,

catalytic domain

Enrichment Score:

0.07228030757809481

repeat: Solcar 3
5
SLC25A32, SLC25A38, SLC25A28, SLC25A16, SLC25A53

repeat: Solcar 1
5
SLC25A32, SLC25A38, SLC25A28, SLC25A16, SLC25A53

repeat: Solcar 2
5
SLC25A32, SLC25A38, SLC25A28, SLC25A16, SLC25A53

IPR023395: Mitochondrial
5
SLC25A32, SLC25A38, SLC25A28, SLC25A16, SLC25A53

carrier domain

IPR018108:
5
SLC25A32, SLC25A38, SLC25A28, SLC25A16, SLC25A53

Mitochondrial

substrate/solute

carrier

Enrichment Score:

0.07048632895684756

Viral nucleoprotein
3
EFTUD2, LARPIB, HNRNPLL

GO: 0019013~viral
3
EFTUD2, LARP1B, HNRNPLL

nucleocapsid

Virion
4
ERVK13-1, EFTUD2, LARPIB, HNRNPLL

Enrichment Score:

0.07022853299749594

zinc finger
4
PLEKHF2, HGS, EEA1, RFFL

region: FYVE-type

SM00064: FYVE
3
PLEKHF2, HGS, EEA1

IPR000306: Zinc
3
PLEKHF2, HGS, EEA1

finger, FYVE-type

IPR017455: Zinc
3
PLEKHF2, HGS, EEA1

finger, FYVE-

related

Enrichment Score:

0.06811532390904307

zinc finger
11
ZNF43, ZNF529, ZNF44, ZNF28, ZNF121, ZNF675, ZNF766, ATMIN, ZNF586,

region: C2H2-type 2;

ZBTB38, ZNF37A

degenerate

zinc finger
5
ZNF43, ZNF28, ZNF131, ZNF675, ZNF493

region: C2H2-type 4;

degenerate

zinc finger
4
ZNF43, ZNF721, ZNF268, ZNF493

region: C2H2-type

22

zinc finger
4
ZNF43, ZNF268, ZNF780B, ZNF493

region: C2H2-type

21

GO:0003676~nucleic
112
RALY, ZNF583, CNOT8, RNASEH1, ZNF638, SART3, DDX23, ZFP90, TIA1,

acid binding

TARDBP, DHX34, RBM10, ZNF101, ZNF43, R3HCC1, ZNF44, ZNF644,

ZNF814, ZNF7, DHX29, ZNF587, ZNF586, ZNF430, SETDIA, ZNF131, RAC1,

PPIL4, DDX42, ZNF529, IKZF2, KIAA1586, KLF13, SREK1, ZNF121,

ZBTB40, MTHFSD, ENDOD1, SAFB2, JAZF1, PPRC1, HIVEP1, RNPC3,

POP7, DDX51, ZNF292, ZNF534, ENOX2, KIAA0430, ZNF675, ZKSCAN1,

HNRNPLL, ZEB1, ZBTB38, ZNF148, AEN, RBAK-RBAKDN, ZNF721,

ZNF720, TSEN2, ZCCHC6, ZNF493, ZCCHC7, ZCCHC10, RBM42, ZFX,

SPEN, TTF2, RECQL, POGK, RBMX2, ZNF746, CPSF4, ZNF740, ZNF276,

ZNF275, ZNF274, RBM33, ZBTB10, ZBTB11, CBLL1, ERI3, ZNF780B,

ZNF780A, SF3B4, SF3B3, CHDIL, DDX19A, REXO1, AGO2, DHX16,

ZSCAN25, MSI2, THAP1, ZNF268, RBM28, EHD4, TTC14, RBM23, ZNF28,

ALYREF, TRIM27, RAF1, GPANK1, SAMHD1, SF3A2, ZNF664, ZNF672,

POLDIP3, RBM19, ZNF764, ZNF766, RBM15

zinc finger
4
ZNF43, ZNF268, ZNF780B, ZNF493

region: C2H2-type

20

zinc finger
12
ZNF529, ZNF44, ZNF28, ZNF121, ZNF800, ZNF675, ZNF746, ZNF721,

region: C2H2-type 1;

ZNF766, ZNF493, ZNF586, ZNF37A

degenerate

zinc finger
8
ZNF43, ZNF44, ZNF28, ZNF721, ZNF268, ZNF780B, ZNF780A, ZNF493

region: C2H2-type

17

zinc finger
6
ZNF43, ZNF28, ZNF721, ZNF268, ZNF780B, ZNF493

region: C2H2-type

18

zinc finger
5
ZNF43, ZNF721, ZNF268, ZNF780B, ZNF493

region: C2H2-type

19

zinc finger
11
ZNF43, ZNF44, ZNF534, ZNF28, ZNF675, ZNF7, ZNF721, ZNF268, ZNF780B,

region: C2H2-type

ZNF780A, ZNF493

15

zinc finger
8
ZNF43, ZNF44, ZNF28, ZNF721, ZNF268, ZNF780B, ZNF780A, ZNF493

region: C2H2-type

16

zinc finger
12
ZNF43, ZNF44, ZNF672, ZNF534, ZNF28, ZNF675, ZNF7, ZNF721, ZNF268,

region: C2H2-type

ZNF780B, ZNF780A, ZNF493

14

zinc finger
49
ZNF276, ZNF275, ZNF430, ZNF274, ZNF292, ZNF534, ZNF583, ZBTB10,

region: C2H2-type 1

ZBTB11, ZNF131, ZNF511, CTCF, ZKSCAN1, ZEB1, ZNF780B, ZNF780A,

ZBTB38, ZNF148, ZFP90, ZSCAN25, ZNF394, ZNF268, ZNF101, PLAGL2,

IKZF5, ZNF43, EGR1, IKZF2, ZNF644, KLF13, KLF10, ZHX1, ZFX, ZBTB40,

ZNF7, ATMIN, TRERF1, ZNF664, ZNF672, SP1, ZNF277, JAZF1, HIVEP2,

PRDM2, ZBTB2, HIVEP1, ZNF764, ZNF587, ZNF740

zinc finger
28
ZNF275, ZNF430, ZNF583, ZNF534, ZBTB11, ZNF675, CTCF, ZNF780B,

region: C2H2-type 10

ZNF780A, ZBTB38, ZFP90, ZNF721, ZNF268, ZNF493, ZNF101, ZNF43,

ZNF529, ZNF44, ZNF28, ZNF121, ZFX, ZBTB40, ZNF7, ZNF37A, ZNF672,

ZNF587, ZNF766, ZNF586

zinc finger
31
ZNF275, ZNF292, ZNF430, ZNF583, ZNF534, ZBTB11, ZNF675, CTCF,

region: C2H2-type 9

ZNF780B, ZNF780A, ZBTB38, ZFP90, ZNF721, ZNF268, ZNF493, ZNF101,

ZNF43, ZNF529, ZNF44, ZNF28, POGZ, ZNF121, ZFX, ZBTB40, ZNF7,

ZNF37A, ZNF664, ZNF672, ZNF587, ZNF766, ZNF586

zinc finger
23
ZNF43, ZNF275, ZNF529, ZNF430, ZNF44, ZNF583, ZNF534, ZNF28,

region: C2H2-type 11

ZNF121, ZBTB11, ZFX, ZNF675, ZNF7, ZNF780B, ZNF780A, ZNF37A,

ZNF672, ZFP90, ZNF721, ZNF268, ZNF587, ZNF493, ZNF586

zinc finger
19
ZNF43, ZNF44, ZNF583, ZNF534, ZNF28, ZBTB11, ZFX, ZBTB40, ZNF675,

region:C2H2-type 12

ZNF7, ZNF780B, ZNF780A, ZNF37A, ZNF672, ZFP90, ZNF721, ZNF268,

ZNF587, ZNF493

zinc finger
52
ZNF292, ZNF583, ZNF534, ZKSCAN1, CTCF, ZEB1, ZNF148, ZFP90,

region: C2H2-type 2

ZNF394, ZNF721, ZNF493, ZNF101, EGR1, ZNF44, ZNF644, POGZ, ZHX1,

ZFX, ZNF7, TRERF1, ZNF277, PRDM2, ZNF746, ZNF587, ZNF740, ZNF276,

ZNF275, ZNF274, ZNF430, ZBTB10, ZBTB11, ZNF131, ZNF800, ZNF511,

ZNF780B, ZNF780A, ZSCAN25, ZNF268, PLAGL2, IKZF5, IKZF2, KLF13,

KLF10, ZBTB40, ZNF664, ZNF672, SP1, JAZF1, HIVEP2, HIVEP1, ZBTB2,

ZNF764

zinc finger
41
ZNF275, ZNF430, ZNF292, ZNF583, ZNF534, ZBTB11, ZNF131, ZNF800,

region: C2H2-type 6

ZNF675, ZKSCAN1, CTCF, ZEB1, ZNF780B, ZNF780A, ZBTB38, ZFP90,

ZSCAN25, ZNF721, ZNF394, ZNF268, ZNF101, PLAGL2, ZNF43, ZNF529,

ZNF44, IKZF2, ZNF644, ZNF28, POGZ, ZNF121, ZFX, ZBTB40, ZNF7,

ZNF664, ZNF37A, ZNF672, PRDM2, ZNF764, ZNF587, ZNF766, ZNF586

IPR007087: Zinc
72
ZNF292, ZNF534, ZNF583, ZNF675, CTCF, ZKSCAN1, ZEB1, ZNF638,

finger, C2H2

ZBTB38, BRPF1, ZNF148, ZFP90, ZNF106, ZNF721, ZNF394, RBM10,

ZNF493, ZNF101, ZNF43, EGR1, ZNF44, ZNF644, POGZ, ZFX, ZHX1,

ZNF814, APTX, ZNF7, TRERF1, ZNF37A, ZNF277, PRDM2, ZNF746,

ZNF587, ZNF740, ZNF586, ZNF276, DPF2, ZNF275, ZNF430, ZNF274,

ZBTB10, ZBTB11, ZNF131, ZNF800, ZNF511, DUSP12, EEA1, ZNF780B,

ZNF780A, ZSCAN25, ZNF268, PLAGL2, IKZF5, ZNF529, IKZF2, ZNF28,

KLF13, ZNF121, KLF10, ZBTB40, FOXP3, ATMIN, ZNF664, ZNF672, SP1,

JAZF1, HIVEP2, HIVEP1, ZBTB2, ZNF764, ZNF766

SM00355: ZnF_C2H
66
ZNF292, ZNF534, ZNF583, ZNF675, CTCF, ZKSCAN1, ZEB1, ZNF638,

2

ZBTB38, ZNF148, ZFP90, ZNF106, ZNF721, ZNF394, ZNF493, ZNF101,

ZNF43, EGR1, ZNF44, ZNF644, POGZ, ZFX, ZHX1, ZNF814, ZNF7, TRERF1,

ZNF37A, ZNF277, PRDM2, ZNF746, ZNF587, ZNF740, ZNF586, ZNF276,

DPF2, ZNF275, ZNF430, ZNF274, ZBTB10, ZBTB11, ZNF131, ZNF800,

ZNF511, ZNF780B, ZNF780A, ZSCAN25, ZNF268, PLAGL2, IKZF5, ZNF529,

IKZF2, ZNF28, KLF13, ZNF121, KLF10, ZBTB40, ATMIN, ZNF664, ZNF672,

SP1, JAZF1, HIVEP2, HIVEP1, ZBTB2, ZNF764, ZNF766

zinc finger
14
ZNF43, ZNF44, ZNF534, ZNF28, ZFX, ZNF675, ZNF7, ZNF780B, ZNF780A,

region: C2H2-type 13

ZNF672, ZFP90, ZNF268, ZNF587, ZNF493

zinc finger
44
ZNF276, ZNF275, ZNF430, ZNF274, ZNF292, ZNF583, ZNF534, ZBTB11,

region: C2H2-type 5

ZNF131, ZNF800, ZNF675, ZKSCAN1, CTCF, ZEB1, ZNF780B, ZNF780A,

ZBTB38, ZFP90, ZSCAN25, ZNF394, ZNF268, ZNF493, ZNF101, PLAGL2,

IKZF5, ZNF43, ZNF529, ZNF44, IKZF2, ZNF644, ZNF28, POGZ, ZNF121,

ZFX, ZBTB40, ZNF7, ZNF664, ZNF37A, PRDM2, HIVEP1, ZNF764, ZNF587,

ZNF766, ZNF586

domain: KRAB
25
ZNF275, ZNF430, ZNF534, ZNF583, ZNF675, ZKSCAN1, ZNF780B,

ZNF780A, ZFP90, ZNF394, ZNF268, ZNF720, ZNF101, ZNF43, ZNF529,

ZNF44, ZNF28, ZNF7, ZNF37A, POGK, ZNF764, ZNF746, ZNF587, ZNF766,

ZNF586

IPR015880: Zinc
66
ZNF292, ZNF534, ZNF583, ZNF675, CTCF, ZKSCAN1, ZEB1, ZNF638,

finger, C2H2-like

ZBTB38, ZNF148, ZFP90, ZNF106, ZNF721, ZNF394, ZNF493, ZNF101,

ZNF43, EGR1, ZNF44, ZNF644, POGZ, ZFX, ZHX1, ZNF814, ZNF7, TRERF1,

ZNF37A, ZNF277, PRDM2, ZNF746, ZNF587, ZNF740, ZNF586, ZNF276,

DPF2, ZNF275, ZNF430, ZNF274, ZBTB10, ZBTB11, ZNF131, ZNF800,

ZNF511, ZNF780B, ZNF780A, ZSCAN25, ZNF268, PLAGL2, IKZF5, ZNF529,

IKZF2, ZNF28, KLF13, ZNF121, KLF10, ZBTB40, ATMIN, ZNF664, ZNF672,

SP1, JAZF1, HIVEP2, HIVEP1, ZBTB2, ZNF764, ZNF766

SM00349: KRAB
29
ZNF274, ZNF430, ZNF583, ZNF534, ZNF675, ZKSCAN1, ZNF780B,

ZNF780A, ZFP90, RBAK-RBAKDN, ZNF394, ZNF721, ZNF268, ZNF720,

ZNF493, ZNF101, ZNF43, ZNF529, ZNF44, ZNF28, ZNF814, ZNF7, ZNF37A,

POGK, ZNF764, ZNF746, ZNF587, ZNF766, ZNF586

IPR013087: Zinc
60
ZNF292, ZNF583, ZNF534, ZNF675, ZKSCANI, CTCF, ZEB1, ZBTB38,

finger C2H2-

ZNF148, ZFP90, ZNF721, ZNF394, ZNF493, ZNF101, ZNF43, EGR1, ZNF44,

type/integrase DNA-

ZNF644, ZFX, ZNF814, ZNF7, ZNF37A, PRDM2, ZNF746, ZNF587, ZNF740,

binding domain

ZNF586, ZNF276, ZNF275, ZNF430, ZNF274, ZBTB10, ZBTB11, ZNF131,

ZNF800, ZNF511, CBLL1, ZNF780B, ZNF780A, ZSCAN25, ZNF268, PLAGL2,

IKZF5, ZNF529, IKZF2, ZNF28, KLF13, ZNF121, KLF10, ZBTB40, FOXP3,

ZNF664, ZNF672, SP1, JAZF1, HIVEP2, HIVEP1, ZBTB2, ZNF764, ZNF766

zinc finger
50
ZNF292, ZNF583, ZNF534, ZKSCAN1, CTCF, ZEB1, ZBTB38, ZNF148,

region:C2H2-type 3

ZFP90, ZNF394, ZNF493, EGR1, ZNF44, ZNF644, POGZ, ZFX, ZNF7,

TRERF1, ZNF37A, PRDM2, ZNF746, ZNF587, ZNF276, ZNF275, ZNF274,

ZNF430, ZBTB11, ZNF131, ZNF800, ZNF511, ZNF780B, ZNF780A,

ZSCAN25, ZNF268, PLAGL2, IKZF5, ZNF529, IKZF2, ZNF28, KLF13,

ZNF121, KLF10, ZBTB40, ZNF664, ZNF672, SP1, HIVEP2, HIVEP1, ZNF764,

ZNF766

IPR001909: Krueppel-
30
ZNF274, ZNF430, ZNF583, ZNF534, ZNF675, ZKSCAN1, ZNF780B,

associated box

ZNF780A, ZFP90, ZSCAN25, RBAK-RBAKDN, ZNF394, ZNF721, ZNF268,

ZNF720, ZNF493, ZNF101, ZNF43, ZNF529, ZNF44, ZNF28, ZNF814, ZNF7,

ZNF37A, POGK, ZNF746, ZNF764, ZNF587, ZNF766, ZNF586

zinc finger
34
ZNF275, ZNF430, ZNF292, ZNF583, ZNF534, ZBTB11, ZNF800, ZNF675,

region: C2H2-type 7

CTCF, ZNF780B, ZNF780A, ZBTB38, ZFP90, ZNF721, ZNF394, ZNF268,

ZNF101, ZNF43, ZNF529, ZNF44, ZNF644, ZNF28, POGZ, ZNF121, ZFX,

ZBTB40, ZNF7, ZNF37A, ZNF664, ZNF672, ZNF764, ZNF587, ZNF766,

ZNF586

zinc finger
30
ZNF275, ZNF292, ZNF430, ZNF583, ZNF534, ZBTB11, ZNF675, CTCF,

region: C2H2-type 8

ZNF780B, ZNF780A, ZBTB38, ZFP90, ZNF721, ZNF268, ZNF101, ZNF43,

ZNF529, ZNF44, ZNF28, POGZ, ZNF121, ZFX, ZBTB40, ZNF7, ZNF37A,

ZNF664, ZNF672, ZNF587, ZNF766, ZNF586

zinc finger
43
ZNF276, ZNF275, ZNF430, ZNF274, ZNF292, ZNF583, ZNF534, ZBTB11,

region: C2H2-type 4

ZNF800, ZKSCAN1, CTCF, ZNF780B, ZNF780A, ZBTB38, ZNF148, ZFP90,

ZSCAN25, ZNF721, ZNF394, ZNF268, ZNF101, PLAGL2, IKZF5, ZNF529,

ZNF44, IKZF2, ZNF644, POGZ, ZNF121, ZFX, ZBTB40, ZNF7, ZNF37A,

ZNF664, ZNF672, HIVEP2, PRDM2, HIVEP1, ZNF746, ZNF764, ZNF587,

ZNF766, ZNF586

Enrichment Score:

0.06745858636176846

short sequence
3
IL2RB, IL6ST, IL4R

motif: Box 1 motif

short sequence
3
IL2RB, IL6ST, IL4R

motif: WSXWS

motif

IPR003961:Fibronectin,
9
ATF7IP, IFNAR2, IL2RB, IL6ST, IL4R, LRRN3, IFNGR2, ATF7IP2, IFNARI

type III

Enrichment Score:

0.06738194626763314

domain: Ig-like C1-
4
HLA-DPA1, MR1, HLA-DPB1, TAPBPL

type

region of
4
HLA-DPA1, MR1, HLA-DPB1, CRYBB2

interest: Connecting

peptide

GO: 0042605~peptide
3
HLA-DPA1, MR1, HLA-DPB1

antigen binding

IPR003597:
6
HLA-DPA1, MR1, HLA-DPB1, TRDC, TAPBPL, IGHM

Immunoglobulin C1-set

IPR003006:
5
HLA-DPA1, MR1, HLA-DPB1, TAPBPL, IGHM

Immunoglobulin/major

histocompatibility

complex, conserved

site

SM00407: IGc1
5
HLA-DPA1, MR1, HLA-DPB1, TAPBPL, IGHM

IPR011162: MHC
3
HLA-DPA1, MR1, HLA-DPB1

classes I/II-like

antigen recognition

protein

Enrichment Score:

0.0547491368027546

IPR023415: Low-
4
DGCR2, CD320, LRP10, LDLRAD4

density lipoprotein

(LDL) receptor class

A, conserved site

SM00192: LDLa
4
DGCR2, CD320, LRP10, LDLRAD4

IPR002172: Low-
4
DGCR2, CD320, LRP10, LDLRAD4

density lipoprotein

(LDL) receptor class

A repeat

Enrichment Score:

0.05398774065645578

metal ion-binding
3
SYT11, PMF1, PRKCB

site: Calcium 3

metal ion-binding
5
ATP2C1, SYT11, PMF1, FURIN, PRKCB

site: Calcium 2

metal ion-binding
4
SYT11, PMF1, FURIN, PRKCB

site: Calcium 1

Enrichment Score:

0.05304803073201943

Thiol protease
4
XIAP, CARD16, CSTB, BIRC6

inhibitor

GO: 0004869~
3
CARD16, CSTB, BIRC6

cysteine-type

endopeptidase

inhibitor activity

GO: 0010951~negative
8
SERPINB9, CARD16, SPOCK2, CSTB, SERPINB1, BIRC6, FURIN, APLP2

regulation of

endopeptidase

activity

Protease inhibitor
7
SERPINB9, XIAP, CARD16, CSTB, SERPINB1, BIRC6, APLP2

Serine protease
3
SERPINB9, SERPINB1, APLP2

inhibitor

GO:0004867~serine-
4
SERPINB9, SERPINB1, FURIN, APLP2

type endopeptidase

inhibitor activity

Enrichment Score:

0.04732472305636867

GO: 0046983~protein
16
E2F3, E2F4, AIFM1, PEX3, MXII, ATM, MXD4, SREBF2, PEF1, NCOA1,

dimerization

NCOA2, HES4, NUP210, GATA3, PPP3CB, FBXW11

activity

DNA-binding
16
BACH2, CREBZF, CREB1, MXI1, MXD4, SREBF2, ATF6, ATF5, FOS,

region: Basic motif

NCOA1, NCOA2, HES4, JUN, NFE2L2, NFE2L3, TCF3

SM00353: HLH
7
NCOA1, NCOA2, HES4, MXI1, TCF3, MXD4, SREBF2

domain: Helix-loop-
7
NCOA1, NCOA2, HES4, MXI1, TCF3, MXD4, SREBF2

helix motif

IPR011598: Myc-
7
NCOA1, NCOA2, HES4, MXI1, TCF3, MXD4, SREBF2

type, basic helix-

loop-helix (bHLH)

domain

Enrichment Score:

0.040170084423871

hsa04918: Thyroid
9
GPX1, ADCY7, CREB1, PRKACB, PDIA4, GPX7, TTF2, PRKCB, ITPR2

hormone synthesis

hsa04925: Aldosterone
9
ORAII, CAMK4, ADCY7, CREB1, NR4A1, PRKACB, PRKD3, PRKCB, ITPR2

synthesis and

secretion

hsa04750: Inflammatory
10
ADCY7, MAPK13, PRKCH, MAPK8, PRKACB, PRKCD, PPP1CB, PIK3R1,

mediator

PRKCB, ITPR2

regulation of TRP

channels

hsa04971: Gastric
5
ADCY7, HRH2, PRKACB, PRKCB, ITPR2

acid secretion

hsa04970: Salivary
6
ATP2B4, ADCY7, PRKACB, VAMP2, PRKCB, ITPR2

secretion

hsa04723: Retrograde
7
MAPK1, ADCY7, MAPK13, MAPK8, PRKACB, PRKCB, ITPR2

endocannabinoid

signaling

hsa04724: Glutamatergic
8
MAPK1, GRM4, GLUL, ADCY7, PPP3CB, PRKACB, PRKCB, ITPR2

synapse

addiction

hsa05032: Morphine
6
ADCY7, PDE7A, PDE4B, PDE4D, PRKACB, PRKCB

addiction

hsa04713: Circadian
6
MAPK1, FOS, ADCY7, CREB1, PRKACB, PRKCB

entrainment

hsa04020: Calcium
13
PHKA2, PPIF, ORAII, ATP2B4, CAMK4, ADCY7, HRH2, LHCGR, PPP3CB,

signaling pathway

STIM1, PRKACB, PRKCB, ITPR2

hsa04911: Insulin
5
ADCY7, CREB1, PRKACB, VAMP2, PRKCB

secretion

hsa04727: GABAergic
5
GABARAPL2, GLUL, ADCY7, PRKACB, PRKCB

synapse

hsa04972: Pancreatic
5
ATP2B4, ADCY7, RAC1, PRKCB, ITPR2

secretion

Enrichment Score:

0.03512913972098621

domain: IQ 1
3
CAMTA2, IQGAP2, MYO9B

domain: IQ 2
3
CAMTA2, IQGAP2, MYO9B

IPR000048: IQ
3
CAMTA2, IQGAP2, MYO9B

motif, EF-hand

binding site

Enrichment Score:

0.03283703716156655

GO: 0035025~positive
4
P2RY8, P2RY10, LPAR6, RAC1

regulation of Rho

protein signal

transduction

GO: 0051482~positive
3
P2RY8, P2RY10, LPAR6

regulation of

cytosolic calcium

ion concentration

involved in

phospholipase C-

activating G-protein

coupled signaling

pathway

hsa04080: Neuroactive
7
P2RY8, GRM4, TSPO, P2RY10, HRH2, LPAR6, LHCGR

ligand-receptor

interaction

IPR000276: G
9
P2RY8, P2RY10, RABGAP1, HRH2, CXCR4, LPAR6, CCR4, LHCGR, CXCR3

protein-coupled

receptor, rhodopsin-

like

G-protein coupled
10
P2RY8, GRM4, P2RY10, RABGAP1, HRH2, CXCR4, LPAR6, CCR4, LHCGR,

receptor

CXCR3

IPR017452: GPCR,
9
P2RY8, P2RY10, RABGAP1, HRH2, CXCR4, LPAR6, CCR4, LHCGR, CXCR3

rhodopsin-like, 7TM

GO: 0004930~G-
9
P2RY8, GRM4, P2RY10, RABGAP1, TM2D1, CXCR4, LPAR6, IGF2R, TPRA1

protein coupled

receptor activity

Transducer
11
GNA13, P2RY8, GRM4, P2RY10, RABGAP1, HRH2, CXCR4, LPAR6, CCR4,

LHCGR, CXCR3

Enrichment Score:

0.015490657362452302

domain: Ig-like V-
13
TIGIT, BTLA, BSG, CD8A, CD8B, CTLA4, CD79B, TAPBPL, CD200,

type

BTN3A2, LSR, LAG3, PDCD1

Immunoglobulin
29
CD8A, CD8B, IL6ST, IGHM, LSR, PDCD1, EMB, MR1, LAG3, ICAMI,

domain

IL18R1, C10ORF54, BSG, LRRN3, ICAM3, CTLA4, MALT1, SLAMF7, TIGIT,

BTLA, CD84, IGSF8, BTN3A1, CD79B, MFAP3, TAPBPL, BTN3A2, CD200,

CD226

SM00409: IG
27
CD8A, CD8B, IGHM, LSR, PDCD1, EMB, LAG3, ICAM1, IL18R1, C10ORF54,

BSG, LRRN3, ICAM3, CTLA4, MALT1, TIGIT, BTLA, CD84, IGSF8,

BTN3A1, SP1, CD79B, MFAP3, TAPBPL, CD200, BTN3A2, CD226

IPR003599:
27
CD8A, CD8B, IGHM, LSR, PDCD1, EMB, LAG3, ICAM1, IL18R1, C10ORF54,

Immunoglobulin subtype

BSG, LRRN3, ICAM3, CTLA4, MALT1, TIGIT, BTLA, CD84, IGSF8,

BTN3A1, SP1, CD79B, MFAP3, TAPBPL, CD200, BTN3A2, CD226

SM00406: IGv
8
BTN3A1, CD8A, CD8B, CTLA4, IGHM, BTN3A2, CD200, PDCD1

IPR013106:
16
C10ORF54, CD8A, CD8B, CTLA4, SLAMF7, IGHM, PDCD1, TIGIT, BTN3A1,

Immunoglobulin V-set

IGSF8, SP1, CD79B, TAPBPL, CD200, CD226, BTN3A2

IPR007110:
33
CD8A, IL6ST, CD8B, TRDC, IGHM, LSR, PDCD1, HLA-DPB1, EMB, MR1,

Immunoglobulin-like

LAG3, ICAM1, IL18R1, C10ORF54, BSG, ICAM3, LRRN3, CTLA4, MALT1,

domain

SLAMF7, TIGIT, BTLA, CD84, IGSF8, BTN3A1, SP1, CD79B, HLA-DPA1,

MFAP3, TAPBPL, BTN3A2, CD200, CD226

IPR013783:
43
CD8A, IL6ST, CD8B, TRDC, IGHM, LSR, PDCD1, MYCBP2, IL4R, HLA-

Immunoglobulin-like

DPB1, EMB, MR1, NFATC2, IFNGR2, LAG3, ATF7IP, ICAMI, C10ORF54,

fold

IL18R1, IL2RB, BSG, RELA, ICAM3, LRRN3, CTLA4, MALT1, SLAMF7,

FLNA, IFNAR1, CD84, TIGIT, BTLA, IFNAR2, BTN3A1, IGSF8, SP1, CD79B,

HLA-DPA1, MFAP3, TAPBPL, BTN3A2, CD200, CD226

Enrichment Score:

0.012624733221056823

SM00431: SCAN
4
ZNF274, ZSCAN25, ZKSCAN1, ZNF394

domain: SCAN box
4
ZNF274, ZSCAN25, ZKSCAN1, ZNF394

IPR003309:
4
ZNF274, ZSCAN25, ZKSCAN1, ZNF394

Transcription regulator

SCAN

IPR008916: Retrovir
4
ZNF274, ZSCAN25, ZKSCAN1, ZNF394

us capsid, C-

terminal

Enrichment Score:

0.01039742026464367

domain: VWFA
5
ITGAE, INTS6, CPNE1, PARP4, ITGB1

IPR002035: von
5
ITGAE, INTS6, CPNE1, PARP4, ITGB1

Willebrand factor,

type A

SM00327: VWA
3
ITGAE, CPNE1, PARP4

Enrichment Score:

0.010098512996503222

SM00339: FH
3
FOXK2, FOXJ3, FOXP3

DNA-binding
3
FOXK2, FOXJ3, FOXP3

region: Fork-head

IPR001766:
3
FOXK2, FOXJ3, FOXP3

Transcription factor,

fork head

Enrichment Score:

0.009453656970068324

GO: 0014069~postsy
15
DBNL, LZTS3, DNM3, SYT11, FMR1, RGS19, STRN, DTNBP1, RGS14, PJA2,

naptic density

NCOA2, SIPAIL1, SOS1, PDE4B, GOPC

Postsynaptic cell
11
PJA2, PRR7, LZTS3, SIPAIL1, FMR1, UTRN, CLSTNI, GOPC, TMUB1,

membrane

DTNBP1, RGS14

Cell junction
51
LZTS3, LIMA1, UTRN, CLSTN1, DSTYK, ARHGAP17, ZNRF1, MFF,

CXCR4, TIAMI, GOPC, ILK, SNTB1, TMUB1, ZYX, DPP4, PARVG, SYMPK,

DBNL, ACTN4, FMR1, PKN2, VEZT, GAK, PJA2, SIPAIL1, KRITI, TBCD,

ASHIL, TCHP, SDCBP, VAMP2, MPST, LIMS1, ARFGEF2, ITGB1, APBBIIP,

DTNBP1, PRR7, LPXN, RAB11B, SNAP23, EMB, PLEC, APC, FYB, ICA1,

SYT11, SNAPIN, RGS14, SYNE2

GO: 0045211~postsy
13
LZTS3, FMR1, CLSTN1, UTRN, STRN, PTEN, DTNBP1, RGS14, PRR7, PJA2,

naptic membrane

SIPAIL1, GOPC, TMUB1

Synapse
23
LZTS3, DBNL, ICA1, SYT11, FMR1, UTRN, CLSTN1, SNAPIN, ZNRF1,

ARFGEF2, DTNBP1, RGS14, PJA2, PRR7, MFF, SIPAIL1, GOPC, RAB11B,

TMUB1, VAMP2, SNAP23, EMB, MPST

GO: 0030054~cell
32
LZTS3, OSBP, UTRN, CLSTN1, DSTYK, ZNRF1, ARFGEF2, DTNBP1, PRR7,

junction

MFF, CXCR4, GOPC, ILK, RAB11B, TMUB1, EMB, FYB, ICA1, SYT11,

FMR1, PKN2, SMC5, SNAPIN, RGS14, NRIP1, PJA2, DCP2, GTF2F1,

SIPAIL1, DDB2, VAMP2, MPST

Enrichment Score:

0.004733778950614591

GO: 0005244~voltage-
3
TMEM109, CLIC1, HVCNI

gated ion channel

activity

GO: 0034765~
3
TMEM109, CLIC1, HVCN1

regulation of ion

transmembrane

transport

Voltage-gated
3
TMEM109, CLIC1, HVCNI

channel

Enrichment Score:

0.0031554828769724845

domain: PDZ
7
PDZD8, TIAM1, SIPAIL1, GOPC, RAPGEF6, SNTB1, MPP6

SM00228: PDZ
9
PDZD8, IL16, TIAM1, SIPAIL1, GOPC, RAPGEF6, SNTB1, SDCBP, MPP6

IPR001478: PDZ
9
PDZD8, IL16, TIAMI, SIPAIL1, GOPC, RAPGEF6, SNTB1, SDCBP, MPP6

domain

Enrichment Score:

0.0017938227712904558

repeat: LRR 12
6
NLRC5, SYNE2, LRRC8B, LRRN3, LRRC8D, SHOC2

repeat: LRR 11
6
NLRC5, SYNE2, LRRC8B, LRRN3, LRRC8D, SHOC2

repeat: LRR 10
7
NLRC5, SYNE2, PPPIR7, LRRC8B, LRRN3, LRRC8D, SHOC2

repeat: LRR 13
4
NLRC5, SYNE2, LRRC8B, SHOC2

repeat: LRR 9
7
NLRC5, SYNE2, PPP1R7, LRRC8B, LRRN3, LRRC8D, SHOC2

repeat: LRR 7
10
NLRC5, RSU1, SYNE2, PPPIR7, LRRC8B, LRRC41, LRRN3, LRRC8D,

LHCGR, SHOC2

repeat: LRR 6
12
NLRC5, RSU1, SYNE2, PPPIR7, LRRC8B, LRRC41, LRRN3, LRRC8D,

LHCGR, SHOC2, RANGAP1, XRRA1

repeat: LRR 8
7
NLRC5, SYNE2, PPPIR7, LRRC8B, LRRN3, LRRC8D, SHOC2

repeat: LRR 5
13
NLRC5, RSU1, SYNE2, PPPIR7, LRRC8B, LRRC41, LRRN3, LRRC8D,

LRRC59, LHCGR, SHOC2, RANGAP1, XRRA1

SM00369: LRR TYP
9
RSU1, PPPIR7, LRRC8B, CNOT6L, LRRN3, LRRC8D, LRRC59, SHOC2,

XRRA1

IPR003591: Leucine-
9
RSU1, PPPIR7, LRRC8B, CNOT6L, LRRN3, LRRC8D, LRRC59, SHOC2,

rich repeat, typical

XRRA1

subtype

repeat: LRR 4
14
NLRC5, RSU1, SYNE2, PPPIR7, LRRC8B, LRRC41, LRRN3, LRRC8D,

LRRC59, LHCGR, FBXL5, SHOC2, RANGAP1, XRRA1

repeat: LRR 3
16
RSU1, LRRC8B, LRRC41, LRRC8D, LHCGR, LRRN3, SHOC2, RANGAP1,

XRRA1, NLRC5, SYNE2, PPPIR7, KDM2A, CNOT6L, LRRC59, FBXL5

Leucine-rich repeat
16
RSU1, LRRC8B, LRRC41, LRRC8D, LHCGR, LRRN3, SHOC2, RANGAPI,

XRRA1, NLRC5, PPPIR7, KDM2A, CNOT6L, LRRC59, FBXL5, FBXL15

repeat: LRR 1
17
RSU1, LRRC8B, LRRC41, LRRC8D, LHCGR, LRRN3, SHOC2, RANGAPI,

XRRA1, NLRC5, SYNE2, KDM2A, PPPIR7, CNOT6L, LRRC59, FBXL5,

HECTD4

repeat: LRR 2
17
RSU1, LRRC8B, LRRC41, LRRC8D, LHCGR, LRRN3, SHOC2, RANGAP1,

XRRA1, NLRC5, SYNE2, KDM2A, PPPIR7, CNOT6L, LRRC59, FBXL5,

HECTD4

IPR001611: Leucine-
13
RSU1, LRRC8B, LRRN3, LRRC8D, SHOC2, RANGAP1, XRRA1, NLRC5,

rich repeat

PPP1R7, CNOT6L, LRRC59, FBXL5, FBXL15

Enrichment Score:

5.610490263279422E-4

GO: 0006814~sodium
4
NDUFA9, COMMD3, SLC38A10, COMMD9

ion transport

Sodium
5
SLC20A2, COMMD3, SLC38A10, POLB, COMMD9

Sodium transport
4
SLC20A2, COMMD3, SLC38A10, COMMD9

Enrichment Score:

2.1717103654966732E-4

domain: Ig-like C2-
3
ICAM1, IGSF8, ICAM3

type 4

domain: Ig-like C2-
5
ICAMI, IL18R1, IGSF8, ICAM3, LAG3

type 3

domain: Ig-like C2-
7
ICAM1, IL18R1, IGSF8, ICAM3, MALT1, CD226, LAG3

type 1

domain: Ig-like C2-
7
ICAM1, IL18R1, IGSF8, ICAM3, MALT1, CD226, LAG3

type 2

Enrichment Score:

1.8372944146090797E-4

domain: C-type
3
DGCR2, CD93, KLRD1

lectin

SM00034: CLECT
3
DGCR2, CD93, KLRD1

IPR016186: C-type
4
DGCR2, CLECL1, CD93, KLRD1

lectin-like

IPR001304: C-type
3
DGCR2, CD93, KLRD1

lectin

IPR016187: C-type
4
DGCR2, CLECL1, CD93, KLRD1

lectin fold

Lectin
7
GALNT2, BSG, DGCR2, CLECL1, CD93, KLRD1, LGALS9

Enrichment Score:

1.3260097487500437E-4

repeat: 1
16
BRF1, BRF2, VHL, TBP, GTF2B, IWS1, GLTP, PEF1, CCDC6, IGF2R,

KHSRP, HIVEP2, PCYTIA, PIAS1, RANBP2, NFATC2

repeat: 2
15
BRF1, BRF2, VHL, TBP, GTF2B, GLTP, IWS1, PEF1, CCDC6, IGF2R,

KHSRP, HIVEP2, RANBP2, PIAS1, NFATC2

repeat: 8
4
PEF1, VHL, IGF2R, HIVEP2

repeat: 9
3
PEF1, IGF2R, HIVEP2

repeat: 7
4
PEF1, VHL, IGF2R, HIVEP2

repeat: 5
5
PEF1, CCDC6, VHL, IGF2R, HIVEP2

repeat: 6
4
PEF1, VHL, IGF2R, HIVEP2

repeat: 3
7
PEF1, CCDC6, VHL, IGF2R, KHSRP, HIVEP2, PCYTIA

repeat: 4
5
PEF1, VHL, IGF2R, KHSRP, HIVEP2

Enrichment Score:

3.460852670649958E-5

Vision
4
UNC119, PDE6D, MKKS, CRYBB2

GO: 0007601~visual
8
ABLIMI, ATF6, UNC119, DRAM2, PDE6D, MKKS, CLN6, CRYBB2

perception

Sensory transduction
5
UNC119, PDE6D, MKKS, DTNBP1, CRYBB2

Enrichment Score:

8.483999996378984E-6

Membrane
712
CCZ1B, CDIPT, USE1, VPS53, STRN, MPV17, RANGAP1, SLC52A2, IGHM,

FAM210A, TESPA1, ACBD5, TMEM140, TMEM147, ILK, VPS4A, JAGNI,

TMEM14B, GOLGA8A, KLRD1, IBTK, TIMMDC1, BSG, ROCK1, ROCK2,

UBE2J1, VPS41, UBE2J2, PIK3IP1, ERGICI, BCL2L11, MARK2, TMEM131,

UNC13D, CD320, TMEM138, SIPAIL1, HLA-DPA1, ARL8B, CD226, ORAII,

KIAA1109, MOB4, C16ORF91, RER1, CCDC91, ARF6, ARFGEF2, SLC29A1,

TMEM50B, SYPL1, RAC1, CKLF, ZAP70, HLA-DPB1, CDC42EP3, MGAT4A,

LAPTM4A, ATP11A, SPTSSA, MPC1, MPC2, APOL2, TMEM115, SYNE2,

APOL1, RGS1, ERVK13-1, ARF4, HGS, SMURF2, SYTL3, TMEM41A,

TMEM41B, C19ORF12, CD200, RTN4, LZTS3, ENOX2, SLC20A2, TSG101,

BNIP3, AP3S1, FAM169A, RTN3, OFD1, LNPEP, APIS3, FAM168B,

TMEM109, SMAP1, SLMAP, IL4R, SPG21, CLDND1, MYB, LAG3, DPP4,

BRD8, PARVG, SYMPK, FMNL3, ZDHHC3, ARHGEF1, RAP2C, PIK3C2A,

AIFM1, ZDHHC8, KCTD20, GLCCI1, CLIC1, PI4KB, PJA2, BNIP1, BNIP2,

RIPK1, RRM1, TCHP, LRMP, OSBPL11, CHSY1, EIF5A2, ARL4C,

GRAMDIA, TMCO1, WDR45, ARL4A, CLN6, SNAP29, MFSD6, RABGAP1,

EXOC7, REPS1, CSF1, MFSD5, PML, ABHD3, EEA1, ABHD2, APBBIIP,

DGKE, DDX19A, NUP210, MPDU1, RAB11B, IL VBL, ARMCX3, CERK,

SNAP23, PCSK7, ACSL4, TRIP11, ACSL3, CIGALTI, ACSL5, SOAT1,

NBPF10, VTA1, CTLA4, DGKH, TMEM5, TTC17, TMEM2, NAE1, SDHA,

PLSCR1, MPHOSPH9, NRAS, P2RY10, PLEKHF2, CSNKID, GSK3B, SDHC,

BNIP3L, CMTM7, DGKZ, TAPBPL, YKT6, CMTM3, NCLN, GNA13, AP1G1,

ATP6AP2, UNC50, HBSIL, TSPAN5, IDE, SLC7A6, ELOVL1, ST3GAL1,

MFF, PRKAR2A, SMIM7, PGRMC1, AAK1, SMIM8, PGRMC2, LRRC59,

RALB, DNAJC5, RNF149, SARIB, DDOST, MATK, TMEM205, TMEM203,

SPTLC2, FMR1, STIM1, PSD4, ZNF7, PDE4D, TMEM208, HCST, PNPLA8,

TMEM106B, RNF139, VAMP5, PCMTD1, VAMP2, MFAP3, SLFN12L,

DCUNID5, PHKA2, ARFGAP2, LITAF, IFITM1, TMEM214, IFITM2, STK10,

STAM2, LRBA, CERS6, TMEM219, SLC38A10, CDC42SE1, CERS4, TRDC,

P2RY8, DOCK2, FICD, PDE6D, CERS2, PCYTIA, RNF167, FKRP, SDF4,

TMEM30A, LYSMD3, TMEM223, HERPUD1, B4GALT3, PHACTR2, PRAF2,

TMEM222, MSMO1, SYT11, MYO1G, NIPA2, SNAPIN, PLGRKT, WIPI2,

ABCB7, FURIN, HERPUD2, NDUFV3, ATF6, TIGIT, LAMP1, LAMP2, TSC1,

NDUFV2, TRAF3IP3, PTTGIIP, NDUFAF4, LRRC8B, ATL3, LRRC8D,

CLSTN1, TMEM237, MFSD2A, PEX3, PIP5K1A, MBP, PEX2, SNTB1, VPS16,

AP5M1, CCDC107, PTDSS1, RHOF, NDUFS1, EBAG9, TBL1XR1, SITI,

AVL9, C17ORF62, PKN2, STXBP2, TMEM248, BANP, NUP85, LPINI, M6PR,

TMEM245, TIMM22, TMEM243, ARL3, SH2D3C, TNFSF13B, DEF6, TBCD,

IGF2R, GINM1, SLC35E1, SLC41A1, MFSD10, EMC1, SNX13, SNX11,

SNX19, GALNT2, TAPTI, NUP98, APHIA, TPRA1, PPMIA, NUP93,

TMEM259, ALDH3A2, APLP2, RNF125, NDC1, AP3M2, AP3M1, HRH2,

TSPAN31, SHISA5, SLC35B4, TMED1, SEC22B, PAFAHIBI, CCS, INPP5D,

EHD1, CD5, VPS39, EHD4, GTF3C3, EBP, VHL, ATRAID, CBL, ANXA1,

RAF1, DPYSL2, BAD, TSPAN17, TMEM55B, ADI1, CLPTMI, LMBRIL,

IFIT5, JAK2, FAF1, GGA1, GGA3, VPS25, RARRES3, SEC31B, TMEM19,

MRPL42, CHMP3, SEC31A, B3GALT6, ADCY7, IL6ST, VAPB, CHMP6,

NELL2, LHCGR, UTRN, CNPPD1, TMEM11, ZNRF1, PSKHI, ATP2B4,

VPS13C, GBF1, INSIG2, RAPGEF6, ERAP1, TMUB1, STAM, C6ORF136,

SAYSD1, TBC1D9B, PLD3, DBNL, GPR137, CRLS1, CAPNS1, STRN3,

TRABD2A, RINT1, PIMI, NKTR, MGAT1, MGAT2, CD37, BTN3A1, RAB18,

ATP2C1, CCR4, LPAR6, ACAPI, ACAP2, CDCA7L, AMFR, TMEM184C,

ADD3, BTN3A2, ADD1, SUCO, TMX2, GPATCH2L, GLG1, CLCN3, LMNB2,

TMX3, BROX, NPIPB4, ASAP1, SFXN4, AKAP10, RFFL, PPAT, FAM65B,

SERINC3, SLC11A2, KRAS, SERINC1, STX17, EMB, STX10, GPR155,

ST6GAL1, OSBPL3, TM2D1, S100A10, SLAMF7, CD63, CDC27, BTLA,

CD55, ATP13A1, RNF4, CD59, KIAA0922, CNIH4, BETIL, RITI, SPG7,

COX11, RAB5B, RAB5C, VPS37B, HELZ, CD151, HVCNI, ATG2B, FARI,

EFHD2, ATAD3A, DNAJC15, GOLGA7, DNAJC16, PARL, GNPAT,

ATP6VOD1, ATP5H, C10ORF54, ICAMI, LPGAT1, JKAMP, ICAM3, VEZT,

CYB5A, FAM76B, RHBDD1, METTL2B, MIEN1, RHBDD2, TNFRSF10A,

GRM4, TRAP1, CHMP1A, ZDHHC16, NUS1, ZDHHC12, RAB5A, CNEPIR1,

ORMDL3, MOSPD1, FKBP11, MAP3K13, LIMS1, BET1, DNAJC30, SFT2D2,

LPXN, STT3A, PEX19, GNPTAB, TYW1, BCL2, PEX16, IPCEF1, CD27,

IL18R1, IMMT, LRRN3, BIRC6, ITPR2, SAMD8, COG3, COG5, DRAM2,

RAB30, SLC16A7, AP2A1, EEF1E1, MTFP1, RAB35, MBOAT1, RBM15,

FAM126B, GOLGB1, TSPO, CHMP4A, DSTYK, PI4K2B, STARD3, GLT8D1,

TIAM1, CPOX, MS4A1, SLC25A28, PRKACB, LEPROT, MCOLN2, MX1,

SPN, TORIAIP2, SCAMP3, SMIM15, MADD, C2CD5, TORIAIP1, CHP1,

FAM118A, MOGS, TIMM8A, BCAP31, SLC25A32, IGSF8, LRP10, USO1,

SLC25A38, SDCBP, KDSR, SMIM20, VPS26A, GBP3, DERL1, MCL1, ITGAE,

CEP95, TMEM63A, UNC93B1, SNX2, RABGAPIL, NAPA, SNX4, MUM1,

ITGB1, CASD1, PRR7, PEF1, FIS1, SLC30A5, ENTPD6, HECTD4, B3GNT2,

RUNX1, YIPF6, RYK, RAB33A, SREBF2, RAB33B, REEP5, PLEKHA3,

TXNDC11, RHOT1, CPNE1, RHOT2, CD79B, AHCYL1, SLC25A16, IFI6,

DCXR, PLEKHAI, COPA, OSBP, UQCRC1, CD8A, CD8B, UTY, ECHDC1,

ARHGAP17, CXCR3, CLTC, UQCRFS1, ARHGAP15, LSR, WHAMM,

PDCD1, DGCR2, CD93, PIGF, CXCR4, GOPC, NECAP2, NECAP1, ATP8B2,

MKKS, RANBP2, MSN, TM9SF4, IFNGR2, AKT2, TM9SF2, CCDC88B,

SYNRG, RALBP1, ELP6, PRKCI, MPP6, PIGS, TMEM189, LDLRAD4,

PRKCD, PRKCB, SACMIL, IFNARI, IMMPIL, CD84, FAM134B, NUCB1,

TNFRSF9, FAM134C, IFNAR2, C5ORF15, CLECL1, KRITI, TMEM69, CD81,

NUCB2, UBE2W, COMMD1, C16ORF54, SPAST, PRKD3, C7ORF73, GPR108,

FAM173B, FAM173A, NDUFB7, CD247, RSAD2, CYTH2, DTNBP1,

TNFRSF1A, PSTPIP1, TMEM87A, SLC39A6, APMAP, MR1, CCZ1, SLC39A3,

APC, STAMBP, IL2RB, ICA1, PTPRE, GIMAP5, PTPRA, SUN2, RGS19,

TMBIM1, NUP155, SLC10A3, RGS14, SIRT2, CYSTMI, GIMAP1, MPG,

TMEM43, SLC6A6, SLC25A53, C9ORF69, COMTD1

Transmembrane
455
CDIPT, USE1, MPV17, SLC52A2, IGHM, FAM210A, ACBD5, TMEM140,

TMEM147, JAGN1, TMEM14B, KLRD1, TIMMDC1, BSG, UBE2J1, UBE2J2,

PIK3IP1, ERGIC1, TMEM131, CD320, TMEM138, HLA-DPA1, CD226,

ORAI1, KIAA1109, C16ORF91, RER1, SLC29A1, TMEM50B, SYPL1, CKLF,

HLA-DPB1, MGAT4A, LAPTM4A, ATP11A, MPC1, SPTSSA, MPC2, APOL2,

TMEM115, SYNE2, APOL1, ERVK13-1, ARF4, SMURF2, TMEM41A,

C19ORF12, TMEM41B, CD200, RTN4, SLC20A2, BNIP3, RTN3, FAM168B,

LNPEP, OFD1, TMEM109, IL4R, SLMAP, CLDND1, MYB, LAG3, DPP4,

BRD8, ZDHHC3, AIFM1, ZDHHC8, KCTD20, CLIC1, GLCCI1, BNIP1,

BNIP2, RRMI, LRMP, CHSY1, TMCO1, GRAMDIA, WDR45, CLN6, MFSD6,

RABGAP1, CSF1, MFSD5, ABHD3, ABHD2, DGKE, NUP210, MPDU1,

ILVBL, ARMCX3, SNAP23, PCSK7, ACSL4, ACSL3, CIGALTI, ACSL5,

SOAT1, NBPF10, CTLA4, TMEM5, TMEM2, PLSCR1, P2RY10, SDHC,

BNIP3L, CMTM7, TAPBPL, CMTM3, NCLN, ATP6AP2, UNC50, TSPAN5,

HBSIL, SLC7A6, ST3GAL1, ELOVL1, MFF, SMIM7, PGRMC1, SMIM8,

LRRC59, PGRMC2, DNAJC5, RNF149, DDOST, TMEM205, TMEM203,

SPTLC2, STIM1, ZNF7, HCST, TMEM208, TMEM106B, PNPLA8, RNF139,

VAMP5, MFAP3, VAMP2, SLFN12L, DCUNID5, TMEM214, IFITM1, LITAF,

IFITM2, LRBA, CERS6, TMEM219, SLC38A10, CERS4, TRDC, P2RY8, FICD,

CERS2, RNF167, FKRP, TMEM30A, LYSMD3, TMEM223, HERPUD1,

B4GALT3, PRAF2, MSMO1, TMEM222, SYT11, NIPA2, PLGRKT, ABCB7,

HERPUD2, FURIN, TIGIT, ATF6, LAMP1, LAMP2, TRAF3IP3, PTTGIIP,

LRRC8B, ATL3, LRRC8D, CLSTN1, TMEM237, MFSD2A, PEX3, PEX2,

PTDSS1, CCDC107, EBAG9, TBL1XR1, SITI, AVL9, C17ORF62, PKN2,

STXBP2, TMEM248, BANP, TMEM245, M6PR, TMEM243, TIMM22,

TNFSF13B, IGF2R, GINMI, SLC35E1, SLC41A1, MFSD10, EMC1, SNX13,

TAPTI, GALNT2, APHIA, TPRA1, PPMIA, TMEM259, APLP2, ALDH3A2,

NDC1, HRH2, TSPAN31, SLC35B4, SHISA5, TMED1, SEC22B, CCS, CD5,

GTF3C3, EBP, ATRAID, TSPAN17, TMEM55B, CLPTM1, LMBRIL, FAF1,

RARRES3, MRPL42, TMEM19, ADCY7, B3GALT6, IL6ST, VAPB, NELL2,

LHCGR, CNPPD1, TMEM11, ATP2B4, INSIG2, TMUB1, ERAP1, C6ORF136,

SAYSD1, TBCID9B, PLD3, GPR137, CRLS1, TRABD2A, MGATI, MGAT2,

CD37, BTN3A1, ATP2C1, LPAR6, CCR4, CDCA7L, AMFR, TMEM184C,

BTN3A2, SUCO, GPATCH2L, GLG1, TMX2, CLCN3, TMX3, NPIPB4,

ASAP1, SFXN4, PPAT, SERINC3, SLC11A2, STX17, SERINCI, EMB, STX10,

GPR155, ST6GAL1, TM2D1, S100A10, SLAMF7, CD63, CDC27, BTLA,

ATP13A1, RNF4, KIAA0922, CNIH4, BETIL, SPG7, COX11, HELZ, CD151,

HVCN1, FAR1, DNAJC15, ATAD3A, DNAJC16, PARL, C10ORF54, ICAMI,

JKAMP, LPGAT1, ICAM3, CYB5A, VEZT, FAM76B, METTL2B, RHBDD1,

RHBDD2, TNFRSF10A, GRM4, ZDHHC16, NUSI, ZDHHC12, CNEPIR1,

ORMDL3, MOSPD1, FKBP11, BET1, DNAJC30, SFT2D2, STT3A, GNPTAB,

BCL2, TYW1, PEX16, CD27, IL18R1, IMMT, LRRN3, ITPR2, SAMD8,

DRAM2, SLC16A7, MTFP1, EEF1E1, MBOAT1, GOLGB1, TSPO, STARD3,

GLT8D1, CPOX, MS4A1, SLC25A28, MCOLN2, LEPROT, SPN, TORIAIP2,

SCAMP3, SMIM15, TORIAIP1, FAM118A, MOGS, BCAP31, SLC25A32,

IGSF8, LRP10, SLC25A38, SDCBP, KDSR, SMIM20, DERLI, MCL1, CEP95,

ITGAE, TMEM63A, UNC93B1, RABGAPIL, MUMI, ITGB1, CASD1, PRR7,

FIS1, SLC30A5, ENTPD6, HECTD4, B3GNT2, RUNX1, YIPF6, RYK, SREBF2,

REEP5, TXNDC11, RHOT1, RHOT2, CD79B, SLC25A16, IFI6, CD8A, CD8B,

UTY, ECHDC1, CXCR3, UQCRFS1, LSR, PDCD1, DGCR2, CD93, PIGF,

CXCR4, MKKS, ATP8B2, TM9SF4, IFNGR2, TM9SF2, ELP6, PIGS,

TMEM189, LDLRAD4, IFNAR1, SACMIL, FAM134B, CD84, IFNAR2,

FAM134C, C5ORF15, TNFRSF9, CLECL1, TMEM69, CD81, UBE2W,

C16ORF54, SPAST, C7ORF73, GPR108, FAM173B, FAM173A, CD247,

TNFRSFIA, TMEM87A, SLC39A6, MR1, APMAP, SLC39A3, IL2RB, ICA1,

PTPRE, GIMAP5, PTPRA, SUN2, TMBIMI, SLC10A3, CYSTM1, GIMAP1,

MPG, TMEM43, SLC6A6, C9ORF69, SLC25A53, COMTD1

Transmembrane
453
CDIPT, USE1, MPV17, SLC52A2, FAM210A, ACBD5, TMEM140, TMEM147,

helix

JAGNI, TMEM14B, KLRD1, TIMMDC1, BSG, UBE2J1, UBE2J2, PIK3IP1,

ERGICI, TMEM131, CD320, TMEM138, HLA-DPA1, CD226, ORAII,

KIAA1109, C16ORF91, RER1, SLC29A1, TMEM50B, SYPL1, CKLF, HLA-

DPB1, MGAT4A, LAPTM4A, ATP11A, MPC1, SPTSSA, MPC2, APOL2,

TMEM115, SYNE2, APOL1, ERVK13-1, ARF4, SMURF2, TMEM41A,

C19ORF12, TMEM41B, CD200, RTN4, SLC20A2, BNIP3, RTN3, FAM168B,

LNPEP, OFD1, TMEM109, IL4R, SLMAP, CLDND1, MYB, LAG3, DPP4,

BRD8, ZDHHC3, AIFM1, ZDHHC8, KCTD20, CLIC1, GLCCI1, BNIP1,

BNIP2, RRMI, LRMP, CHSY1, TMCO1, GRAMDIA, WDR45, CLN6, MFSD6,

RABGAP1, CSF1, MFSD5, ABHD3, ABHD2, DGKE, NUP210, MPDU1,

ILVBL, ARMCX3, SNAP23, PCSK7, ACSL4, ACSL3, CIGALTI, ACSL5,

SOAT1, NBPF10, CTLA4, TMEM5, TMEM2, PLSCR1, P2RY10, SDHC,

BNIP3L, CMTM7, TAPBPL, CMTM3, NCLN, ATP6AP2, UNC50, TSPAN5,

HBS1L, SLC7A6, ST3GAL1, ELOVL1, MFF, SMIM7, PGRMC1, SMIM8,

LRRC59, PGRMC2, DNAJC5, RNF149, DDOST, TMEM205, TMEM203,

SPTLC2, STIM1, ZNF7, HCST, TMEM208, TMEM106B, PNPLA8, RNF139,

VAMP5, MFAP3, VAMP2, SLFN12L, DCUNID5, TMEM214, IFITM1, LITAF,

IFITM2, LRBA, CERS6, TMEM219, SLC38A10, CERS4, TRDC, P2RY8, FICD,

CERS2, RNF167, FKRP, TMEM30A, LYSMD3, TMEM223, HERPUD1,

B4GALT3, PRAF2, MSMO1, TMEM222, SYT11, NIPA2, PLGRKT, ABCB7,

HERPUD2, FURIN, TIGIT, ATF6, LAMP1, LAMP2, TRAF3IP3, PTTGIIP,

LRRC8B, ATL3, LRRC8D, CLSTN1, TMEM237, MFSD2A, PEX3, PEX2,

PTDSS1, CCDC107, EBAG9, TBL1XR1, SITI, AVL9, C17ORF62, PKN2,

STXBP2, TMEM248, BANP, TMEM245, M6PR, TMEM243, TIMM22,

TNFSF13B, IGF2R, GINM1, SLC35E1, SLC41A1, MFSD10, EMC1, SNX13,

TAPTI, GALNT2, APHIA, TPRA1, PPMIA, TMEM259, APLP2, ALDH3A2,

NDC1, HRH2, TSPAN31, SLC35B4, SHISA5, TMED1, SEC22B, CCS, CD5,

GTF3C3, EBP, ATRAID, TSPAN17, TMEM55B, CLPTM1, LMBRIL, FAF1,

RARRES3, MRPL42, TMEM19, ADCY7, B3GALT6, IL6ST, VAPB, NELL2,

LHCGR, CNPPD1, TMEM11, ATP2B4, INSIG2, TMUB1, ERAPI, C6ORF136,

SAYSD1, TBC1D9B, PLD3, GPR137, CRLS1, TRABD2A, MGATI, MGAT2,

CD37, BTN3A1, ATP2C1, LPAR6, CCR4, CDCA7L, AMFR, TMEM184C,

BTN3A2, SUCO, GPATCH2L, GLG1, TMX2, CLCN3, TMX3, NPIPB4,

ASAP1, SFXN4, PPAT, SERINC3, SLC11A2, STX17, SERINCI, EMB, STX10,

GPR155, ST6GAL1, TM2D1, S100A10, SLAMF7, CD63, CDC27, BTLA,

ATP13A1, RNF4, KIAA0922, CNIH4, BETIL, SPG7, COX11, HELZ, CD151,

HVCN1, FAR1, DNAJC15, ATAD3A, DNAJC16, PARL, C10ORF54, ICAMI,

JKAMP, LPGAT1, ICAM3, CYB5A, VEZT, FAM76B, METTL2B, RHBDD1,

RHBDD2, TNFRSF10A, GRM4, ZDHHC16, NUS1, ZDHHC12, CNEPIR1,

ORMDL3, MOSPD1, FKBP11, BET1, DNAJC30, SFT2D2, STT3A, GNPTAB,

BCL2, TYW1, PEX16, CD27, IL18R1, IMMT, LRRN3, ITPR2, SAMD8,

DRAM2, SLC16A7, MTFP1, EEF1E1, MBOATI, GOLGB1, TSPO, STARD3,

GLT8D1, CPOX, MS4A1, SLC25A28, MCOLN2, LEPROT, SPN, TORIAIP2,

SCAMP3, SMIM15, TORIAIP1, FAM118A, MOGS, BCAP31, SLC25A32,

IGSF8, LRP10, SLC25A38, SDCBP, KDSR, SMIM20, DERLI, MCL1, CEP95,

ITGAE, TMEM63A, UNC93B1, RABGAPIL, MUMI, ITGB1, CASD1, PRR7,

FIS1, SLC30A5, ENTPD6, HECTD4, B3GNT2, YIPF6, RYK, SREBF2, REEP5,

TXNDC11, RHOT1, RHOT2, CD79B, SLC25A16, IFI6, CD8A, CD8B, UTY,

ECHDC1, CXCR3, UQCRFSI, LSR, PDCD1, DGCR2, CD93, PIGF, CXCR4,

MKKS, ATP8B2, TM9SF4, IFNGR2, TM9SF2, ELP6, PIGS, TMEM189,

LDLRAD4, IFNAR1, SACMIL, FAM134B, CD84, IFNAR2, FAM134C,

C5ORF15, TNFRSF9, CLECL1, TMEM69, CD81, UBE2W, C16ORF54, SPAST,

C7ORF73, GPR108, FAM173B, FAM173A, CD247, TNFRSFIA, TMEM87A,

SLC39A6, MR1, APMAP, SLC39A3, IL2RB, ICA1, PTPRE, GIMAP5, PTPRA,

SUN2, TMBIM1, SLC10A3, CYSTMI, GIMAP1, MPG, TMEM43, SLC6A6,

C9ORF69, SLC25A53, COMTD1

GO: 0016021~integral
431
CDIPT, USE1, MPV17, VPS51, IGHM, FAM210A, ACBD5, TMEM140,

component of

TMEM147, JAGN1, TMEM14B, KLRD1, TIMMDC1, BSG, UBE2J1, UBE2J2,

membrane

PIK3IP1, ERGICI, TMEM131, CD320, TMEM138, HLA-DPA1, CD226,

ORAI1, KIAA1109, C16ORF91, RER1, TMEM50B, SYPL1, CKLF, HLA-

DPB1, MGAT4A, LAPTM4A, ATP11A, MPC1, SPTSSA, MPC2, APOL2,

TMEM115, SYNE2, APOL1, ERVK13-1, ARF4, SMURF2, TMEM41A,

C19ORF12, TMEM41B, CD200, RTN4, SLC20A2, BNIP3, RTN3, FAM168B,

OFD1, TMEM109, IL4R, SLMAP, CLDND1, MYB, LAG3, DPP4, BRD8,

ZDHHC3, AIFM1, ZDHHC8, KCTD20, GLCCI1, BNIP2, RRMI, LRMP,

CHSY1, TMCO1, GRAMDIA, WDR45, CLN6, MFSD6, RABGAP1, MFSD5,

CSF1, ABHD3, ABHD2, DGKE, NUP210, MPDU1, IL VBL, ARMCX3, PCSK7,

SNAP23, CERK, ACSL4, ACSL3, CIGALTI, ACSL5, SOAT1, NBPF10,

CTLA4, TMEM5, TMEM2, P2RY10, SDHC, BNIP3L, CMTM7, TAPBPL,

CMTM3, YKT6, NCLN, ATP6AP2, UNC50, TSPAN5, HBSIL, SLC7A6,

ST3GAL1, ELOVL1, MFF, SMIM7, PGRMC1, LRRC59, PGRMC2, SMIM8,

DNAJC5, RNF149, DDOST, TMEM205, TMEM203, SPTLC2, ZNF7, HCST,

TMEM208, TMEM106B, PNPLA8, RNF139, MFAP3, VAMP2, SLFN12L,

DCUNID5, TMEM214, IFITM1, LITAF, IFITM2, LRBA, CERS6, TMEM219,

SLC38A10, CERS4, TRDC, P2RY8, FICD, CERS2, RNF167, FKRP,

TMEM30A, LYSMD3, TMEM223, HERPUD1, B4GALT3, PRAF2, MSMO1,

TMEM222, NIPA2, ABCB7, HERPUD2, FURIN, TIGIT, LAMP1, LAMP2,

TRAF3IP3, PTTGIIP, LRRC8B, ATL3, LRRC8D, CLSTNI, TMEM237,

MFSD2A, PEX2, PTDSS1, CCDC107, EBAG9, TBL1XR1, SIT1, AVL9,

C17ORF62, PKN2, STXBP2, TMEM248, BANP, TMEM245, M6PR,

TMEM243, TIMM22, TNFSF13B, IGF2R, GINM1, SLC35E1, MFSD10,

SLC41A1, EMC1, SNX13, TAPTI, GALNT2, APHIA, TPRA1, PPMIA,

TMEM259, APLP2, ALDH3A2, NDC1, TSPAN31, SLC35B4, SHISA5, TMED1,

SEC22B, CCS, CD5, GTF3C3, EBP, ATRAID, TSPAN17, TMED8, TMEM55B,

CLPTM1, LMBRIL, FAF1, RARRES3, MRPL42, TMEM19, ADCY7,

B3GALT6, IL6ST, VAPB, NELL2, LHCGR, CNPPD1, ATP2B4, INSIG2,

TMUB1, ERAP1, C6ORF136, SAYSD1, TBC1D9B, PLD3, GPR137, CRLS1,

MGAT1, MGAT2, BTN3A1, CD37, ATP2C1, LPAR6, CCR4, CDCA7L, AMFR,

TMEM184C, BTN3A2, SUCO, GPATCH2L, GLG1, TMX2, CLCN3, TMX3,

NPIPB4, SFXN4, ASAP1, PPAT, SERINC3, SLC11A2, STX17, SERINCI,

EMB, STX10, GPR155, ST6GAL1, TM2D1, S100A10, SLAMF7, CD63,

CDC27, BTLA, ATP13A1, RNF4, KIAA0922, CNIH4, BETIL, COX11, SPG7,

HELZ, CD151, HVCN1, FAR1, DNAJC15, ATAD3A, DNAJC16, PARL,

C10ORF54, ICAM1, JKAMP, LPGAT1, ICAM3, CYB5A, VEZT, FAM76B,

METTL2B, RHBDD1, RHBDD2, TNFRSF10A, GRM4, ZDHHC16, NUS1,

ZDHHC12, CNEPIR1, ORMDL3, MOSPD1, FKBP11, BET1, SEC14L1,

DNAJC30, SFT2D2, STT3A, GNPTAB, PEX19, BCL2, TYW1, IL18R1, IMMT,

LRRN3, ITPR2, SAMD8, DRAM2, MTFP1, EEF1E1, MBOATI, GOLGB1,

TSPO, STARD3, GLT8D1, CPOX, SLC25A28, MCOLN2, LEPROT, SPN,

TORIAIP2, SCAMP3, SMIM15, MADD, TORIAIP1, FAM118A, MOGS,

BCAP31, SLC25A32, IGSF8, LRP10, SLC25A38, SDCBP, KDSR, SMIM20,

DERL1, MCL1, CEP95, TMEM63A, UNC93B1, RABGAPIL, MUMI, CASD1,

PRR7, SLC30A5, ENTPD6, HECTD4, B3GNT2, RUNX1, YIPF6, RYK, REEP5,

TXNDC11, RHOT1, SLC25A16, IFI6, CD8A, CD8B, UTY, ECHDC1, CXCR3,

LSR, PDCD1, DGCR2, PIGF, CD93, CXCR4, MKKS, ATP8B2, TM9SF4,

IFNGR2, TM9SF2, ELP6, TMEM189, LDLRAD4, SACMIL, IFNAR2,

FAM134C, C5ORF15, TNFRSF9, CLECL1, SBF1, TMEM69, CD81, UBE2W,

C16ORF54, SPAST, C7ORF73, GPR108, FAM173B, FAM173A, CD247,

TNFRSFIA, TMEM87A, SLC39A6, MR1, APMAP, SLC39A3, ICA1, PTPRE,

GIMAP5, PTPRA, TMBIM1, SLC10A3, CYSTMI, GIMAP1, MPG, TMEM43,

SLC6A6, C9ORF69, SLC25A53, COMTD1

transmembrane
387
CDIPT, USE1, MPV17, SLC52A2, FAM210A, ACBD5, TMEM140, TMEM147,

region

JAGN1, TMEM14B, KLRD1, TIMMDC1, BSG, UBE2J1, UBE2J2, PIK3IP1,

ERGIC1, TMEM131, CD320, TMEM138, HLA-DPA1, CD226, ORAII,

KIAA1109, C16ORF91, RER1, TMEM50B, SLC29A1, SYPL1, CKLF, HLA-

DPB1, MGAT4A, LAPTM4A, SPTSSA, ATP11A, TMEM115, SYNE2,

TMEM41A, C19ORF12, TMEM41B, CD200, RTN4, SLC20A2, BNIP3, RTN3,

LNPEP, TMEM109, IL4R, SLMAP, CLDND1, DPP4, LAG3, ZDHHC3,

ZDHHC8, CLIC1, BNIP1, LRMP, CHSY1, TMCO1, GRAMDIA, CLN6,

MFSD6, MFSD5, CSF1, ABHD3, ABHD2, DGKE, NUP210, MPDU1,

ARMCX3, IL VBL, PCSK7, ACSL4, ACSL3, CIGALTI, ACSL5, SOAT1,

CTLA4, TMEM5, TMEM2, PLSCR1, P2RY10, SDHC, BNIP3L, CMTM7,

TAPBPL, CMTM3, NCLN, ATP6AP2, TSPAN5, UNC50, SLC7A6, ST3GAL1,

ELOVL1, MFF, SMIM7, PGRMC1, LRRC59, PGRMC2, SMIM8, RNF149,

DDOST, TMEM205, TMEM203, SPTLC2, STIM1, HCST, TMEM208,

TMEM106B, PNPLA8, VAMP5, RNF139, MFAP3, VAMP2, TMEM214,

IFITM1, IFITM2, CERS6, LRBA, SLC38A10, TMEM219, CERS4, P2RY8,

FICD, CERS2, RNF167, TMEM30A, LYSMD3, TMEM223, HERPUD1, PRAF2,

B4GALT3, MSMO1, TMEM222, SYT11, NIPA2, PLGRKT, ABCB7,

HERPUD2, FURIN, TIGIT, ATF6, LAMP1, LAMP2, TRAF3IP3, PTTGIIP,

LRRC8B, CLSTN1, LRRC8D, ATL3, TMEM237, MFSD2A, PEX3, PEX2,

PTDSS1, CCDC107, EBAG9, SIT1, AVL9, C17ORF62, TMEM248, TMEM245,

M6PR, TMEM243, TIMM22, TNFSF13B, GINMI, IGF2R, SLC35E1, MFSD10,

SLC41A1, EMC1, TAPTI, GALNT2, APHIA, TPRAI, TMEM259, APLP2,

ALDH3A2, NDC1, TSC22D3, HRH2, TSPAN31, TMED1, SLC35B4, SHISA5,

SEC22B, CD5, EBP, ATRAID, TSPAN17, TMEM55B, CLPTMI, LMBRIL,

ALKBH5, TMEM19, CHMP3, ADCY7, B3GALT6, VAPB, IL6ST, LHCGR,

CNPPD1, TMEM11, ATP2B4, INSIG2, TMUB1, ERAPI, SAYSD1, TBCID9B,

PLD3, GPR137, CRLS1, TRABD2A, MGATI, MGAT2, BTN3A1, CD37,

LPAR6, CCR4, ATP2C1, TMEM184C, AMFR, BTN3A2, SUCO, GPATCH2L,

GLG1, TMX2, CLCN3, TMX3, SFXN4, SERINC3, SLC11A2, STX17,

SERINC1, EMB, STX10, GPR155, ST6GAL1, TM2D1, SLAMF7, CD63, BTLA,

ATP13A1, CNIH4, KIAA0922, BETIL, COX11, SPG7, HVCNI, CD151, FARI,

DNAJC15, DNAJC16, PARL, ICAMI, C10ORF54, JKAMP, LPGAT1, ICAM3,

CYB5A, VEZT, RHBDD1, RHBDD2, TNFRSF10A, GRM4, ZDHHC16, NUS1,

ZDHHC12, CNEPIR1, MOSPD1, ORMDL3, FKBP11, BET1, SFT2D2, STT3A,

GNPTAB, BCL2, PEX16, CD27, IL18R1, EPB41L4A-AS1, IMMT, LRRN3,

ITPR2, SAMD8, DRAM2, MBOATI, GOLGB1, TSPO, STARD3, GLT8D1,

MS4A1, SLC25A28, MCOLN2, LEPROT, SPN, TORIAIP2, SCAMP3,

SMIM15, MADD, TORIAIP1, FAM118A, MOGS, BCAP31, SLC25A32, IGSF8,

LRP10, SLC25A38, KDSR, SMIM20, GBP3, DERL1, MCL1, ITGAE,

UNC93B1, TMEM63A, ITGB1, CASD1, PRR7, FIS1, ENTPD6, SLC30A5,

HECTD4, B3GNT2, YIPF6, RYK, REEP5, SREBF2, TXNDC11, RHOT1,

RHOT2, CD79B, SLC25A16, IFI6, CD8A, CD8B, CXCR3, LSR, PDCDI,

DGCR2, PIGF, CD93, CXCR4, ATP8B2, TM9SF4, IFNGR2, TM9SF2, PIGS,

TMEM189, LDLRAD4, IFNAR1, SACMIL, FAM134B, CD84, IFNAR2,

FAM134C, C5ORF15, TNFRSF9, CLECL1, TMEM69, CD81, C16ORF54,

SPAST, GPR108, FAM173B, FAM173A, CD247, TNFRSFIA, SLC39A6,

TMEM87A, MR1, APMAP, SLC39A3, IL2RB, GIMAP5, PTPRE, PTPRA,

SUN2, TMBIM1, SLC10A3, GIMAP1, RPAP2, TMEM43, SLC6A6, SLC25A53,

COMTD1

topological
213
B3GALT6, ADCY7, VAPB, IL6ST, LHCGR, USE1, TMEM140, ATP2B4,

domain: Cytoplasmic

ERAP1, JAGN1, KLRD1, PLD3, GPR137, BSG, TRABD2A, UBE2J1, UBE2J2,

PIK3IP1, ERGICI, MGATI, MGAT2, CD37, BTN3A1, CD320, ATP2C1, CCR4,

LPAR6, HLA-DPA1, AMFR, CD226, BTN3A2, GLG1, TMX2, ORAII, CLCN3,

C16ORF91, TMX3, SLC11A2, SERINC3, SLC29A1, SYPL1, STX17, SERINC1,

HLA-DPB1, EMB, STX10, MGAT4A, ST6GAL1, SPTSSA, ATP11A, SLAMF7,

CD63, BTLA, ATP13A1, SYNE2, KIAA0922, BETIL, CD200, RTN4,

SLC20A2, CD151, HVCN1, LNPEP, DNAJC16, IL4R, SLMAP, LAG3, DPP4,

ICAM1, C10ORF54, ZDHHC3, JKAMP, ZDHHC8, ICAM3, TNFRSF10A,

GRM4, ZDHHC16, BNIP1, NUS1, LRMP, CHSY1, CSF1, BET1, SFT2D2,

STT3A, NUP210, PEX16, PCSK7, ACSL4, ACSL3, CIGALTI, CD27, ACSL5,

IL18R1, EPB41L4A-AS1, LRRN3, CTLA4, TMEM5, ITPR2, SAMD8, PLSCR1,

P2RY10, TAPBPL, NCLN, GOLGB1, ATP6AP2, UNC50, TSPAN5, SLC7A6,

ST3GAL1, GLT8D1, STARD3, MFF, SMIM7, LRRC59, MS4A1, DDOST, SPN,

SCAMP3, STIM1, MOGS, HCST, BCAP31, IGSF8, LRP10, VAMP5, KDSR,

VAMP2, MFAP3, DERLI, ITGAE, CERS6, ITGB1, PRR7, P2RY8, FIS1,

CERS2, ENTPD6, SLC30A5, B3GNT2, LYSMD3, PRAF2, B4GALT3,

TMEM222, RYK, SYT11, NIPA2, SREBF2, ATF6, TIGIT, LAMP1, LAMP2,

TRAF3IP3, PTTGIIP, RHOT1, RHOT2, CD79B, CD8A, CD8B, ATL3,

CLSTN1, PEX3, CXCR3, LSR, PDCD1, DGCR2, CD93, CXCR4, ATP8B2,

IFNGR2, EBAG9, TM9SF2, SIT1, PIGS, M6PR, LDLRAD4, IFNAR1, CD84,

TNFRSF9, C5ORF15, IFNAR2, TNFSF13B, CLECL1, GINMI, IGF2R, CD81,

EMC1, GALNT2, CD247, ALDH3A2, APLP2, NDC1, TNFRSFIA, HRH2,

TSPAN31, TMED1, SHISA5, SEC22B, SLC39A6, MR1, APMAP, SLC39A3,

CD5, IL2RB, PTPRE, GIMAP5, ATRAID, PTPRA, TSPAN17, GIMAP1,

CLPTM1, LMBRIL, SLC6A6

Enrichment Score:

6.831574760707297E-6

IPR003961: Fibronectin,
9
ATF7IP, IFNAR2, IL2RB, IL6ST, IL4R, LRRN3, IFNGR2, ATF7IP2, IFNAR1

type III

domain: Fibronectin
3
IL6ST, IFNGR2, IFNAR1

type-III 2

domain: Fibronectin
3
IL6ST, IFNGR2, IFNAR1

type-III 1

Enrichment Score:

1.9767078533785107E-10

IPR013032: EGF-
3
CD93, ATRAID, NELL2

like, conserved site

EGF-like domain
3
CD93, ATRAID, NELL2

IPR000742: Epiderm
3
CD93, ATRAID, NELL2

al growth factor-like

domain

Enrichment Score:

−0.0

disulfide bond
121
IL6ST, LHCGR, NELL2, GFER, IGHM, ST3GAL1, MS4A1, KLRD1, BSG,

PMCH, PIK3IP1, TIMM8A, IGSF8, BTN3A1, NPC2, CD320, LRP10, LPAR6,

CCR4, HLA-DPA1, MFAP3, CD226, BTN3A2, CCL3, TXN2, ITGAE, TMX3,

CTSA, CCL4, ITGB1, LIF, BLOCIS5, ENTPD6, PCYTIA, HLA-DPB1, EMB,

ST6GAL1, B4GALT3, S100A11, MALTI, SLAMF7, PMF1, FURIN, TIGIT,

DNASE2, BTLA, TXNDC12, LAMP1, CD55, TXNDC11, LAMP2, CD59,

CD79B, XCL1, CD200, XCL2, CD8A, FAM3C, CD8B, HEXB, PDIA4, CXCR3,

UQCRFS1, LSR, PDCD1, DGCR2, CD93, CXCR4, IL4R, LAG3, DPP4, ICAMI,

C10ORF54, SIT1, AIFMI, LY96, ICAM3, GZMB, CLIC1, LDLRAD4, MIENI,

IFNAR1, CD84, TNFRSF10A, TNFRSF9, IFNAR2, CTSL, TNFSF13B, IGF2R,

CD81, RRM1, MGEA5, TXNRDI, CTSC, CSF2, GALNT2, SPOCK2, CSF1,

CD247, APLP2, GLRX2, TNFRSFIA, GNPTAB, HRH2, PITRMI, CCS, MR1,

CD5, CD27, GLRX, IL18R1, CES2, IL2RB, ATRAID, LRRN3, CTLA4,

P2RY10, GLA, IRF3, TAPBPL, IL2

Disulfide bond
145
IL6ST, LHCGR, NELL2, PTPN22, GFER, IGHM, SLC7A6, ST3GAL1, MS4A1,

ERAP1, KLRD1, BSG, PMCH, PIK3IP1, TIMM8A, HCST, MGATI, IGSF8,

BTN3A1, UHRF2, NPC2, CD320, LRP10, LPAR6, CCR4, HLA-DPA1, MFAP3,

CD226, BTN3A2, MPST, CCL3, TXN2, ITGAE, TMX3, CTSA, CHCHD4,

TRDC, HEXDC, CCL4, ITGB1, LIF, RAC1, ENTPD6, HLA-DPB1, EMB,

FKRP, ST6GAL1, B4GALT3, S100A11, MALT1, SLAMF7, FURIN, BTLA,

TIGIT, DNASE2, TXNDC12, LAMP1, LAMP2, CD55, TXNDC11, ERVK13-1,

CD59, CD79B, XCL1, CD200, XCL2, BACH2, CD8A, FAM3C, CD8B, HEXB,

CXCR3, PDIA4, UQCRFS1, LSR, PDCD1, DGCR2, CD93, TPP1, CXCR4,

IL4R, RANBP2, LAG3, DPP4, AKT2, ICAM1, C10ORF54, SITI, LY96,

ICAM3, GZMB, CLIC1, LDLRAD4, MIEN1, IFNAR1, CD84, TNFRSF10A,

TNFRSF9, GRM4, CTSL, IFNAR2, TNFSF13B, IGF2R, CD81, RRMI,

TXNRD1, CTSC, CSF2, GALNT2, NDUFB7, SPOCK2, CSF1, USP5, CD247,

APLP2, GLRX2, MYCBP2, TNFRSFIA, GNPTAB, HRH2, PITRMI, CCS,

MR1, CD5, CIGALTI, CD27, GLRX, SOAT1, IL18R1, CES2, IL2RB,

ATRAID, LRRN3, ANXA1, CTLA4, RAF1, NUP155, P2RY10, GLA, IRF3,

TAPBPL, POFUT1, FEZ2, GOLGB1, IL2

signal peptide
165
ATP6AP2, IL6ST, NELL2, LHCGR, SLC52A2, IGHM, SMIM7, IFNG, RNF149,

DDOST, IZUMO4, SPN, GPR137, BSG, PMCH, TRABD2A, STIM1, PIK3IP1,

CECR5, HCST, IGSF8, ABHD17B, BTN3A1, CHID1, NPC2, LRP10, CD320,

HLA-DPA1, KDSR, MFAP3, AMFR, CD226, UGGT1, BTN3A2, SUCO,

HSD17B11, GLG1, TMX2, CCL3, C16ORF91, ITGAE, TMX3, CTSA, CCL4,

ITGB1, CASD1, LIF, BLOCIS5, CIORF56, HLA-DPB1, RNF167, EMB, SDF4,

FKRP, SDF2, TM2D1, RYK, ENDOD1, SLAMF7, PMF1, FURIN, BTLA,

DNASE2, TIGIT, LAMP1, TXNDC12, LAMP2, CD55, APOLI, CD59,

KIAA0922, PTTGIIP, CD79B, TMEM41A, XCLI, CD200, XCL2, IFI6, CD8A,

CD8B, FAM3C, HEXB, CLSTN1, PDIA4, DHRSX, ASAHI, PDCDI,

TMEM109, DGCR2, DNAJC16, CD93, TPP1, RSPRY1, IL4R, GPX7, TM9SF4,

CCDC107, IFNGR2, LAG3, ICAM1, TM9SF2, C10ORF54, SIT1, AIFM1, LY96,

ICAM3, GZMB, M6PR, DHRS7, IFNAR1, KIAA0100, CD84, TNFRSF10A,

NUCB1, TOR2A, TNFRSF9, GRM4, CTSL, IFNAR2, C5ORF15, NUSI,

GINM1, IGF2R, NUCB2, OXNAD1, EMC1, CTSC, FKBP11, CSF2, GPR108,

TSPEAR, SPOCK2, CSF1, CD247, COLGALT1, APLP2, TNFRSFIA,

C12ORF49, NUP210, TMED1, SHISA5, TMEM87A, SLC39A6, PCSK7, MR1,

NENF, CD5, CD27, IL18R1, ALKBH7, IL2RB, CES2, PTPRE, ATRAID,

PTPRA, LRRN3, CTLA4, C3ORF58, GLA, MCFD2, TAPBPL, POFUT1,

NCLN, IL2, RCN2

Enrichment Score:

−0.0

Glycoprotein
208
B3GALT6, ADCY7, IL6ST, LHCGR, NELL2, IGHM, TMEM140, IFNG,

ERAP1, KLRD1, IZUMO4, PLD3, GPR137, BSG, TRABD2A, PIK3IP1,

ERGIC1, TMEM131, MGAT2, CD37, BTN3A1, NPC2, CAMK4, CD320, CCR4,

TMEM138, LPAR6, HLA-DPA1, CD226, BTN3A2, SUCO, GLG1, ORAII,

CLCN3, TMX3, OAS2, SLC11A2, SERINC3, LIF, SLC29A1, SYPL1,

SERINC1, RAC1, HLA-DPB1, EMB, MGAT4A, GPR155, ST6GAL1, TM2D1,

SLAMF7, CD63, BTLA, CD55, APOL1, ATP13A1, CD59, KIAA0922,

TMEM41A, CD200, ENOX2, SLC20A2, APIAR, CD151, ASAHI, LNPEP,

DNAJC16, IL4R, CLDND1, DPP4, LAG3, ICAMI, C10ORF54, LY96, ICAM3,

GZMB, TNFRSF10A, GRM4, MTMR14, NUS1, CHSY1, CSF2, CSF1, ABHD2,

COLGALT1, NUP214, NUMA1, STT3A, GNPTAB, C12ORF49, NUP210,

PCSK7, CD27, IL18R1, CES2, LRRN3, CTLA4, TMEM2, P2RY10, GLA,

NCLN, IL2, TSPAN5, ST3GAL1, GLT8D1, RNF149, SPN, TORIAIP2,

TORIAIP1, STIM1, MOGS, HCST, PNPLA8, TMEM106B, IGSF8, LRP10,

MFAP3, UGGT1, TMEM214, ITGAE, CERS6, UNC93B1, TMEM219, CTSA,

TRDC, ITGB1, SRF, P2RY8, CERS2, ENTPD6, RNF167, B3GNT2, FKRP,

SDF4, TMEM30A, LYSMD3, B4GALT3, YIPF6, RYK, FURIN, ATF6,

DNASE2, TIGIT, LAMP1, LAMP2, PTTGIIP, CD79B, LRRC8B, CD8B,

HEXB, CLSTN1, MFSD2A, CXCR3, PDCD1, DGCR2, CD93, TPP1, RSPRY1,

CXCR4, IFNGR2, AKT2, SIT1, PFKL, PIGS, M6PR, TMEM245, MCM6,

IFNAR1, KIAA0100, CD84, NUCB1, TOR2A, TNFRSF9, C5ORF15, IFNAR2,

CTSL, TNFSF13B, CLECL1, GINM1, IGF2R, EMC1, CTSC, C16ORF54,

GPR108, FAM173A, TSPEAR, SPOCK2, TPRA1, TMEM259, APLP2,

TNFRSFIA, HRH2, TSPAN31, TMEM87A, SLC39A6, MR1, APMAP, CD5,

IL2RB, PTPRE, ATRAID, PTPRA, SUN2, NUP155, TSPAN17, CLPTM1, SP1,

SLC6A6, POFUT1

signal peptide
165
ATP6AP2, IL6ST, NELL2, LHCGR, SLC52A2, IGHM, SMIM7, IFNG, RNF149,

DDOST, IZUMO4, SPN, GPR137, BSG, PMCH, TRABD2A, STIM1, PIK3IP1,

CECR5, HCST, IGSF8, ABHD17B, BTN3A1, CHID1, NPC2, LRP10, CD320,

HLA-DPA1, KDSR, MFAP3, AMFR, CD226, UGGT1, BTN3A2, SUCO,

HSD17B11, GLG1, TMX2, CCL3, C16ORF91, ITGAE, TMX3, CTSA, CCL4,

ITGB1, CASD1, LIF, BLOC1S5, CIORF56, HLA-DPB1, RNF167, EMB, SDF4,

FKRP, SDF2, TM2D1, RYK, ENDOD1, SLAMF7, PMF1, FURIN, BTLA,

DNASE2, TIGIT, LAMP1, TXNDC12, LAMP2, CD55, APOLI, CD59,

KIAA0922, PTTGIIP, CD79B, TMEM41A, XCL1, CD200, XCL2, IFI6, CD8A,

CD8B, FAM3C, HEXB, CLSTN1, PDIA4, DHRSX, ASAHI, PDCDI,

TMEM109, DGCR2, DNAJC16, CD93, TPP1, RSPRY1, IL4R, GPX7, TM9SF4,

CCDC107, IFNGR2, LAG3, ICAM1, TM9SF2, C10ORF54, SITI, AIFMI, LY96,

ICAM3, GZMB, M6PR, DHRS7, IFNAR1, KIAA0100, CD84, TNFRSF10A,

NUCB1, TOR2A, TNFRSF9, GRM4, CTSL, IFNAR2, C5ORF15, NUS1,

GINM1, IGF2R, NUCB2, OXNAD1, EMC1, CTSC, FKBP11, CSF2, GPR108,

TSPEAR, SPOCK2, CSF1, CD247, COLGALT1, APLP2, TNFRSFIA,

C12ORF49, NUP210, TMED1, SHISA5, TMEM87A, SLC39A6, PCSK7, MR1,

NENF, CD5, CD27, IL18R1, ALKBH7, IL2RB, CES2, PTPRE, ATRAID,

PTPRA, LRRN3, CTLA4, C3ORF58, GLA, MCFD2, TAPBPL, POFUT1,

NCLN, IL2, RCN2

glycosylation site: N-
189
ADCY7, B3GALT6, IL6ST, NELL2, TSPAN5, LHCGR, IGHM, TMEM140,

linked (GlcNAc . . . )

ST3GAL1, GLT8D1, IFNG, ERAP1, RNF149, KLRD1, IZUMO4, SPN,

TORIAIP2, PLD3, GPR137, BSG, TRABD2A, TORIAIP1, STIM1, MOGS,

ERGICI, TMEM131, MGAT2, PNPLA8, TMEM106B, BTN3A1, CD37, IGSF8,

NPC2, LRP10, CD320, CCR4, LPAR6, TMEM138, HLA-DPA1, MFAP3,

AMFR, BTN3A2, CD226, UGGT1, SUCO, GLG1, ORAII, CLCN3, TMEM214,

ITGAE, TMX3, TMEM63A, CERS6, UNC93B1, TMEM219, CTSA, ITGB1,

SLC29A1, SERINC3, SLC11A2, P2RY8, LIF, SYPL1, CERS2, SERINCI,

ENTPD6, HLA-DPB1, EMB, RNF167, B3GNT2, FKRP, SDF4, TMEM30A,

LYSMD3, MGAT4A, GPR155, ST6GAL1, B4GALT3, YIPF6, TM2D1, RYK,

SLAMF7, CD63, FURIN, BTLA, ATF6, DNASE2, TIGIT, LAMP1, LAMP2,

CD55, APOLI, ATP13A1, CD59, KIAA0922, PTTGIIP, CD79B, TMEM41A,

CD200, LRRC8B, CD8B, SLC20A2, APIAR, HEXB, LRRC8D, CLSTNI,

CXCR3, CD151, ASAHI, PDCD1, LNPEP, DGCR2, DNAJC16, CD93, TPP1,

RSPRY1, CXCR4, IL4R, CLDND1, IFNGR2, LAG3, DPP4, ICAMI,

C10ORF54, SIT1, LY96, ICAM3, PIGS, GZMB, TMEM245, M6PR, IFNAR1,

KIAA0100, CD84, TNFRSF10A, TOR2A, TNFRSF9, GRM4, CTSL, IFNAR2,

C5ORF15, MTMR14, CLECL1, TNFSF13B, GINM1, IGF2R, EMC1, CHSY1,

CTSC, CSF2, GPR108, FAM173A, TSPEAR, SPOCK2, CSF1, TPRAI,

TMEM259, COLGALT1, TNFRSFIA, STT3A, GNPTAB, C12ORF49, HRH2,

NUP210, TSPAN31, TMEM87A, SLC39A6, PCSK7, MR1, APMAP, CD5,

CD27, IL18R1, IL2RB, CES2, PTPRE, ATRAID, PTPRA, LRRN3, CTLA4,

SUN2, TSPAN17, TMEM2, CLPTM1, P2RY10, GLA, SLC6A6, POFUT1,

NCLN

Signal
235
CDIPT, TMEM19, SEC31A, IL6ST, LHCGR, NELL2, MPV17, SLC52A2,

HIBADH, SHKBP1, PGP, IFNG, ERAPI, IZUMO4, TIMMDC1, BSG, CAPNS1,

PMCH, TRABD2A, UBR2, PIK3IP1, TMEM131, BTN3A1, NPC2, CD320,

HLA-DPA1, FAM177A1, CD226, BTN3A2, SUCO, TMX2, HSD17B11, GLG1,

C16ORF91, TMX3, NPIPB4, AKAP10, LIF, CIORF56, RAC1, HLA-DPB1,

EMB, GPR155, LAPTM4A, TM2D1, SLAMF7, BTLA, APOL3, CD55, APOLI,

ATP13A1, CD59, KIAA0922, TMEM41A, CD200, METTL 17, FAM96A,

FAM3C, VPS37B, PDIA4, ASAHI, TMEM109, DNAJC16, IL4R, GPX7,

CLDND1, LAG3, ICAM1, C10ORF54, LY96, ICAM3, GZMB, ECSIT,

TNFRSF10A, GRM4, MTMR14, FKBP11, CSF2, EXOC7, USP3, CSF1,

COLGALT1, DNAJC30, STAU1, NUP214, C12ORF49, NUP210, PCSK7,

NENF, CD27, IL18R1, CES2, LRRN3, CTLA4, DNPEP, SDHA, FAM78A,

GLA, MCFD2, JMJD8, PHGDH, TAPBPL, OGGI, NCLN, GOLGB1, IL2,

RALY, TSPO, ATP6AP2, HBSIL, RGL4, SMIM7, RNF149, DDOST, SPN,

TMEM205, STIM1, CECR5, HCST, RALGAPA1, IGSF8, ABHD17B, CHID1,

LRP10, KDSR, MFAP3, SMARCA2, UGGTI, PCCB, CCL3, ITGAE,

TMEM219, MUM1, CTSA, ITGB1, CCL4, CASD1, FBXW7, C12ORF10,

RNF167, SDF4, SDF2, RYK, C21ORF33, ENDOD1, ABCB7, FURIN, DNASE2,

TIGIT, TXNDC12, LAMP1, LAMP2, TXNDC11, DNAJB9, PDE7A, PTTGIIP,

CD79B, XCL1, XCL2, IFI6, CD8A, CD8B, YLPM1, HEXB, CLSTN1, DHRSX,

LSR, ZZEF1, PDCD1, DGCR2, CD93, RSPRY1, TPP1, CCDC107, TM9SF4,

IFNGR2, EBAG9, TM9SF2, ELP2, CCDC88B, SIT1, DYNLT3, M6PR,

IFNAR1, DHRS7, KIAA0100, NUCB1, CD84, TOR2A, CTSL, C5ORF15,

TNFRSF9, IFNAR2, PANK2, HIPK1, GINMI, IGF2R, CD81, HIPK2, DDT,

NUCB2, OXNAD1, CTSC, EMC1, KPNA1, C7ORF73, GPR108, TSPEAR,

SPOCK2, CD247, APLP2, TNFRSFIA, NUDT9, TSPAN31, TMED1, SHISA5,

TMEM87A, SLC39A6, MR1, CD5, IL2RB, PTPRE, ATRAID, PTPRA, CBL,

RAF1, SLC10A3, GORAB, WSB1, ADI1, C3ORF58, TDP2, SLC6A6, POFUT1,

RCN2

topological
213
B3GALT6, ADCY7, VAPB, IL6ST, LHCGR, USE1, TMEM140, ATP2B4,

domain: Cytoplasmic

ERAPI, JAGN1, KLRD1, PLD3, GPR137, BSG, TRABD2A, UBE2J1, UBE2J2,

PIK3IP1, ERGICI, MGATI, MGAT2, CD37, BTN3A1, CD320, ATP2C1, CCR4,

LPAR6, HLA-DPA1, AMFR, CD226, BTN3A2, GLG1, TMX2, ORAII, CLCN3,

C16ORF91, TMX3, SLC11A2, SERINC3, SLC29A1, SYPL1, STX17, SERINCI,

HLA-DPB1, EMB, STX10, MGAT4A, ST6GAL1, SPTSSA, ATP11A, SLAMF7,

CD63, BTLA, ATP13A1, SYNE2, KIAA0922, BETIL, CD200, RTN4,

SLC20A2, CD151, HVCN1, LNPEP, DNAJC16, IL4R, SLMAP, LAG3, DPP4,

ICAM1, C10ORF54, ZDHHC3, JKAMP, ZDHHC8, ICAM3, TNFRSF10A,

GRM4, ZDHHC16, BNIP1, NUS1, LRMP, CHSY1, CSF1, BET1, SFT2D2,

STT3A, NUP210, PEX16, PCSK7, ACSL4, ACSL3, CIGALTI, CD27, ACSL5,

IL18R1, EPB41L4A-AS1, LRRN3, CTLA4, TMEM5, ITPR2, SAMD8, PLSCR1,

P2RY10, TAPBPL, NCLN, GOLGB1, ATP6AP2, UNC50, TSPAN5, SLC7A6,

ST3GAL1, GLT8D1, STARD3, MFF, SMIM7, LRRC59, MS4A1, DDOST, SPN,

SCAMP3, STIM1, MOGS, HCST, BCAP31, IGSF8, LRP10, VAMP5, KDSR,

VAMP2, MFAP3, DERL1, ITGAE, CERS6, ITGB1, PRR7, P2RY8, FIS1,

CERS2, ENTPD6, SLC30A5, B3GNT2, LYSMD3, PRAF2, B4GALT3,

TMEM222, RYK, SYT11, NIPA2, SREBF2, ATF6, TIGIT, LAMP1, LAMP2,

TRAF3IP3, PTTGIIP, RHOT1, RHOT2, CD79B, CD8A, CD8B, ATL3,

CLSTN1, PEX3, CXCR3, LSR, PDCD1, DGCR2, CD93, CXCR4, ATP8B2,

IFNGR2, EBAG9, TM9SF2, SIT1, PIGS, M6PR, LDLRAD4, IFNARI, CD84,

TNFRSF9, C5ORF15, IFNAR2, TNFSF13B, CLECL1, GINMI, IGF2R, CD81,

EMC1, GALNT2, CD247, ALDH3A2, APLP2, NDC1, TNFRSFIA, HRH2,

TSPAN31, TMED1, SHISA5, SEC22B, SLC39A6, MR1, APMAP, SLC39A3,

CD5, IL2RB, PTPRE, GIMAP5, ATRAID, PTPRA, TSPAN17, GIMAP1,

CLPTM1, LMBRIL, SLC6A6

topological
130
IL6ST, ATP6AP2, LHCGR, TSPAN5, SLC7A6, TMEM140, STARD3, ATP2B4,

domain: Extracellular

SMIM7, KLRD1, SPN, GPR137, BSG, TRABD2A, STIM1, PIK3IP1, HCST,

IGSF8, CD37, BTN3A1, CD320, LRP10, LPAR6, CCR4, HLA-DPA1, AMFR,

MFAP3, CD226, BTN3A2, GLG1, TMX2, ORAI1, C16ORF91, ITGAE, ITGB1,

P2RY8, SERINC3, SLC11A2, SLC29A1, PRR7, SERINCI, SLC30A5, HLA-

DPB1, EMB, LYSMD3, PRAF2, TMEM222, RYK, ATP11A, NIPA2, SLAMF7,

CD63, BTLA, TIGIT, ATP13A1, KIAA0922, TRAF3IP3, PTTGIIP, CD79B,

CD200, CD8A, SLC20A2, CD8B, CLSTNI, CXCR3, CD151, HVCNI, LSR,

PDCD1, LNPEP, DGCR2, DNAJC16, CD93, CXCR4, IL4R, SLMAP, ATP8B2,

IFNGR2, LAG3, DPP4, EBAG9, ICAMI, C10ORF54, SIT1, ICAM3,

LDLRAD4, IFNAR1, CD84, TNFRSF10A, TNFRSF9, GRM4, C5ORF15,

IFNAR2, NUS1, TNFSF13B, CLECL1, GINMI, CD81, EMC1, CD247, APLP2,

TNFRSF1A, HRH2, TSPAN31, TMED1, SHISA5, SLC39A6, PCSK7, APMAP,

MR1, SLC39A3, CD5, CD27, IL 18R1, IL2RB, PTPRE, GIMAP5, ATRAID,

PTPRA, LRRN3, CTLA4, TMEM5, TSPAN17, GIMAP1, ITPR2, CLPTM1,

LMBRIL, PLSCR1, P2RY10, SLC6A6

Example 2. A Comprehensive Single Cell Atlas of Non-human Primate Cells During Homeostasis and Pathogenic Infection

As the gene-expression program of a given cell closely reflects both its identity and function (Heinz et al., 2015), a systematic atlas of single-cell RNA profiles can help address many questions about immune regulations, their networks and molecular processes, and the response to pathogenic stimuli. Given the importance of the immune system, a systematic understanding of immune regulations on cell, tissue, and organism levels is crucial for clinicians and researchers to efficiently diagnose and develop treatments for immune system related disease.

Here, using scRNA-seq, this study identified gene signatures involved in SHIV-infection and immune responses, characterized cellular heterogeneity within specific cell-types, and demonstrated how these cell types and states change dynamically at different states of infection. More importantly, this study provides a resourceful pan-tissue database of expression profiles of healthy non-human primates that serves as a detailed reference data set for follow up studies regarding HIV as well as more diseases and pathogenic states. Given the resemblance between HIV and SHIV, and the kinship between human and non-human primates, the atlas disclosed by this study also allows for parallel comparison and identifications of specific sub cell types as well as differentially regulated genes involved in human HIV infection.

Four Rhesus Macaques were sacrificed with full necropsy. Single cells from 12 distinct tissues were collected and single cell RNA-Sequencing was performed on these cells. Three Rhesus Macaques were infected with SHIV for 6 months, anti-retroviral therapy was applied for 6 months, and the animals were then sacrificed with full necropsy. Eight distinct tissues per SHIV+ animal were collected for single cell RNA-Sequencing. Tissues were collected as population controls in multiple forms, including RNALater, paraffin embedded, live cells frozen, lysed post dissociation and saved for control experiments and validations.

Single cell sequencing data were partitioned and annotated with supervised clustering, the results of which were visualized using tSNE (Amir el et al., 2013; Shekhar et al., 2016; van der Maaten and Hinton, 2008a). Based on expression profiles, individual cells are clustered and defined by tissues and cell types (FIGS. 9 and 10). Particularly, this study identifies tissue specific phenotypes and behaviors of T cells (CD3E+, CD3D+, and CD3G+ cells), neutrophils, microglia, B cells, glandular epithelia, enterocytes, fibroblasts, megakaryocytes, erythroid precursor, DC, NK, macrophages, pneumocytes, eosinophil, and basophil cells are differentiated by expression profiles in axillary lymph nodes, central nerve system, colon, ileum, liver, lung, mesenteric lymph nodes, blood, spleen, thymus, and tonsil tissues, as illustrated in FIGS. 11-21. Specifically, in macrophages from different tissues, gene expression (S100A8, HBB, MNP1A, CAMP, LOC710097, gene 24745, gene 18845, LOC703853, LOC706282, RTD1B, LOC106994075, PLACE, CLEC9A, GZMB, IRF8, FCER1A, KNG1, IGFBP6, CCDC50, NCOA7, C1QB, SEPP1, FABP4, C1QC, GPNMB, APOE, ACP5, YMRM176B, ADAMDEC1, CCDC 152, S100A6, FCGR3, VCAN, FGR, LILRB1, FCN1, AHNAK, FN1, C5AR1, TIMP1) distinguishes individual cells by their tissue of origins (FIG. 13).

By comparing single cell profiles of healthy subjects with SHIV infected ones, this study identified subsets of cells in specific tissues differentially respond to SHIV infection (FIGS. 22A and 22B). In lymphoid tissue, certain immune cells such as CD8+ T cells and macrophages appear to be equally represented in both healthy and SHIV infected cells, while other cells such as CD4+ T cells and B cells show marked difference between the two states. The comparison further identifies pathways and genes that are differentially expressed in healthy and SHIV infected cells. In CD4+ T cells, genes involved in cyclin dependent signaling, chemokine signaling, RNA helicase, mRNA export from nucleus, DNA damage, spliceosome mRNA processing, and transcription regulation are identified as correlated with healthy cells, and genes involved in unfolded protein response, HTLV-1 infection, herpes simplex infection, interferon gamma signaling pathway, antigen processing and presentation via MHC class I, positive regulation of apoptotic processes, T cell receptor signaling, virion assembly, and viral transcription are associated with HIV infection (FIGS. 22C and 22D). More comprehensively, this study identified gene markers that are differentially expressed in SHIV infected cells. This study also validated the close relationship between SHIV and HIV infection in non-human primate and human cells, by comparing differentially expressed genes between HIV infected and healthy human lymph node cells with SHIV infected and healthy T cells in non-human primates. The significant overlap of the two sets of differentially expressed genes (FIG. 23) confirm that biomarkers identified in this study can further be used in diagnosis, monitoring, and treatment of human HIV related disease.

Example 3—Host-Pathogen Interactions Observed in the Lymph Node of a Human HIV⁺ Patient

FIG. 25 shows the proposed experimental workflow. The ideal dataset is as follows:

- 4 HIV+LN, ARV-treated, suppressed
- 2-3 HIV+LN, virologic failure
- 2-3 HIV−LN
- ˜4 arrays per patient
- Matched uninfected PBMCs as staining controls

FIGS. 26A-26C illustrate that J3 and 10-1074 bnAbs are specific for HIV⁺ samples. Env antibody staining was done using 10-1074 (NIH) and J3 llama nanobody from Kiera Clayton (Walker lab) (originally developed by Robin Weiss at UCL).

FIGS. 28A and 28B illustrate that J3 and 10-1074 bnAbs successfully enrich for HIV+ cells. The protocol was as follows:

- 1. Prepare in vitro HIV-1 infected (NL-AD8) and uninfected PBMCs
- 2. Stain with J3, 10-1074
- 3. Sort 5 populations into RLT+1% BME (1000 cells each)
- 1. Uninfected cells
- 2. HIV+J3− 10-1074−
- 3. HIV+J3− 10-1074+
- 4. HIV+J3+ 10-1074−
- 5. HIV+J3+ 10-1074+
- 4. RT, PCR for Clade B rev

FIG. 29 shows results of Seq-Well on a lymph node sample from an HIV+, ARV-treated patient. The protocol was as follows:

- 1. Thawed LN276 (HIV+) and PBMCs (HIV−)
- 2. Saved 15,000 cells from unstained LN276 (HIV+) for Seq-Well
- 3. Stained with J3 (A647), 10-1074 (A488)
- 4. Sorted Env− (J3− 10-1074−) and Env+ (5000 J3 or 10-1074 single positive, ˜5000 J3/10-1074 double positive)
- 5. Ran 3 Seq-Well Arrays (most up-to-date protocol)
- 1. Unsorted
- 2. Env positive
- 3. Env negative

FIG. 31 shows results of Seq-Well on a lymph node sample from an HIV+, ARV-treated patient. Applicants concluded that high quality libraries were generated from samples, including live cells and successful Seq-Well data. They also determined the following points:

- Cell type specific depletion Sorted vs. Unsorted samples
- Depletion of gag+env+ subset after sorting—fragility of infected cells?
- Low relative yield single cells from Env+ fraction
- Env− loaded ˜20,000: yield ˜1500 cells
- Env+ loaded ˜10,000: yield ˜250 cells
- Env+ cells show modest enrichment for HIV mRNA, are largely CD4+ monocytes/macrophages

Various modifications and variations of the described methods, pharmaceutical compositions, and kits of the invention will be apparent to those skilled in the art without departing from the scope and spirit of the invention. Although the invention has been described in connection with specific embodiments, it will be understood that it is capable of further modifications and that the invention as claimed should not be unduly limited to such specific embodiments. Indeed, various modifications of the described modes for carrying out the invention that are obvious to those skilled in the art are intended to be within the scope of the invention. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure come within known customary practice within the art to which the invention pertains and may be applied to the essential features herein before set forth.

	Number	Date	Country
Parent	16756573	Apr 2020	US
Child	18452789		US

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