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KRUITHOF E; DE RYCKE L; VANDOOREN B; WYNS B ET AL.: \"Diagnostic classification of spondylarthropathy and rheumatoid arthritis by synovial histopathology: a prospective study in 154 consecutive patients\", ARTHRITIS RHEUM, vol. 50, 2004, pages 2931 - 41","npl_type":"s","external_id":["15457462","10.1002/art.20476"],"record_lens_id":"001-276-673-933-176","lens_id":["190-641-103-179-024","001-276-673-933-176","074-315-004-468-219"],"sequence":15,"category":[],"us_category":[],"cited_phase":"APP","cited_date":"2012-05-04","rel_claims":[]}},{"npl":{"num":16,"text":"KRUITHOF E; BAETEN D; DE RYCKE L; VANDOOREN B; FOELL D ET AL.: \"Synovial histopathology of psoriatic arthritis, both oligo- and polyarticular, resembles spondyloarthropathy more than it does rheumatoid arthritis\", ARTHRITIS RS THER, vol. 7, 2005, pages R569 - 80","npl_type":"s","external_id":["15899044","pmc1174942"],"record_lens_id":"185-880-098-467-087","lens_id":["185-880-098-467-087"],"sequence":16,"category":[],"us_category":[],"cited_phase":"APP","cited_date":"2012-05-04","rel_claims":[]}},{"npl":{"num":17,"text":"DE RYCKE L; BAETEN D; FOELL D; KRUITHOF E; VEYS EM; ROTH J; DE KEYSER F.: \"Differential expression and response to anti-TNFalpha treatment of infiltrating versus resident tissue macrophage subsets in autoimmune arthritis\", J PATHOL, vol. 206, 2005, pages 17 - 27","npl_type":"s","external_id":["10.1002/path.1758","15809977"],"record_lens_id":"063-403-403-447-651","lens_id":["069-551-736-669-845","063-403-403-447-651","196-429-186-051-009"],"sequence":17,"category":[],"us_category":[],"cited_phase":"APP","cited_date":"2012-05-04","rel_claims":[]}}],"reference_cited.source":"DOCDB","reference_cited.patent_count":0,"cites_patent":false,"reference_cited.npl_count":26,"reference_cited.npl_resolved_count":26,"cites_npl":true,"cites_resolved_npl":true,"cited_by":{"patent_count":1,"patent":[{"lens_id":"164-979-293-963-797","document_id":{"jurisdiction":"CN","doc_number":"103305599","kind":"A"}}]},"cited_by_patent":true,"family":{"simple":{"size":2,"id":193801768,"member":[{"lens_id":"050-059-302-226-989","document_id":{"jurisdiction":"WO","doc_number":"2011099857","kind":"A1","date":"2011-08-18"}},{"lens_id":"125-892-182-738-929","document_id":{"jurisdiction":"EP","doc_number":"2354247","kind":"A1","date":"2011-08-10"}}]},"extended":{"size":2,"id":193614764,"member":[{"lens_id":"050-059-302-226-989","document_id":{"jurisdiction":"WO","doc_number":"2011099857","kind":"A1","date":"2011-08-18"}},{"lens_id":"125-892-182-738-929","document_id":{"jurisdiction":"EP","doc_number":"2354247","kind":"A1","date":"2011-08-10"}}]}},"sequence":{"seq_list_key":"EP_2354247_A1","type":["DNA","N"],"length_bucket":["NT_1_100"],"length":[19,20,21,26,60,61],"organism":[{"name":"Unknown/Artificial","tax_id":-1}],"document_location":[],"count":1310,"data_source":["EP_SEQL","GBPAT_EBI","EMBLPAT_EBI","DDBJPAT"]},"has_sequence":true,"legal_status":{"ipr_type":"patent for invention","granted":false,"earliest_filing_date":"2010-02-11","has_disclaimer":false,"patent_status":"PENDING","publication_count":1,"has_spc":false,"has_grant_event":false,"has_entry_into_national_phase":false},"abstract":{"en":[{"text":"The invention provides a method for typing samples for rheumatoid arthritis and spondyloarthritis. Typing can be performed in order to discriminate between rheumatoid arthritis and spondyloarthritis in early disease. The invention further provides sets of genes to be used in a method of the invention and a nucleotide microarray and use thereof.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"}]},"abstract_lang":["en"],"has_abstract":true,"claim":{"en":[{"text":"A method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising:\n - determining levels of expression products of a set of genes, said expression products being obtained from, and/or present in, a sample of said individual; \n - typing said sample on the basis of the expression product levels determined for said set of genes; \nwherein said set of genes comprises at least 5 genes listed in table 3.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A method according to claim 1 wherein said set of genes comprises at least 5 genes listed in table 4.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A method according to claim 1 or 2 wherein said set of genes comprises at least 10 genes listed in table 3 or 4, more preferably at least 20 genes listed in table 3 or 4, most preferably at least 50 genes listed in table 3 or 4.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A method according to any one of claims 1-3 wherein said expression product is RNA.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A method according to any one of claims 1-4 wherein said sample is, a blood sample, a peripheral blood mononuclear cell sample or a synovial tissue sample.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A method according to any one of claims 1-5 wherein said synovial tissue sample is obtained from a knee joint or an ankle-joint.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A method according to any one of claims 1-6 wherein said set of genes comprises tumour necrosis factor receptor superfamily member 17 (TNFRSF17) and/or immunoglobulin J polypeptide, linker protein for immunoglobulin alpha and mu polypeptides (IGJ) and/or POU class 2 associating factor 1 (POU2AF1), and/or Der1-like domain family, member 3 (DERL3), and/or Fc receptor-like 5 (FCRL5), and/or plasma cell-induced ER protein 1 (PACAP), and/or prepronociceptin (PNOC), and/or secreted phosphoprotein 1 (SPP1), and/or interferon regulatory factor 4 (IRF4), and/or lymphocyte transmembrane adaptor 1 (LAX1), and/or ELL associated factor 2 (EAF2), and/or pim-2 oncogene (PIM2) and/or actin, alpha 1, skeletal muscle (ACTA1) and/or Myosin, heavy chain 3, skeletal muscle, embryonic (MYH2) and/or myosin, heavy chain 1, skeletal muscle, adult (MYH1), and/or cysteine and glycine-rich protein 3 (CSRP3), and/or actinin, alpha 2 (ACTN2), and/or troponin I type 2 (TNNI2), and/or cytochrome P450, family 26, subfamily B, polypeptide 1 (CYP26B1), and/or titin-cap (TCAP).","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A method according to any one of claims 1-7 wherein RNA levels are determined by microarray analysis.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A nucleotide microarray, comprising at least 5 nucleic acid sequences being able to hybridize to at least 5 genes listed in table 3 or 4, and wherein at least 80% of the nucleic acid molecules of said microarray are able to hybridize to any gene listed in table 3 or 4.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"A nucleotide microarray according to claim 9 comprising at least 10 nucleic acid sequences being able to hybridize to at least 10 genes listed in table 3 or 4, more preferably comprising at least 20 nucleic acid sequences being able to hybridize to at least 20 genes listed in table 3 or 4, more preferably comprising at least 50 nucleic acid sequences being able to hybridize to at least 50 genes listed in table 3 or 4.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"},{"text":"Use of a nucleotide microarray according to claim 9 or 10 for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis.","lang":"en","source":"EPO_FULLTEXT","data_format":"ORIGINAL"}]},"claim_lang":["en"],"has_claim":true,"description":{"en":{"text":"The invention relates to the fields of biology and medicine, more specifically the invention relates to arthritis. Rheumatoid arthritis (RA) and spondyloarthritis (SpA) are the two most frequent forms of chronic arthritis in humans. RA has a prevalence of 1% and SpA of 0.5% in Europe and North America. Rheumatoid arthritis is a chronic inflammatory auto-immune disease. It can affect many tissues or organs, but mostly results in destruction of synovial joints. In rheumatoid arthritis immune complexes are formed in affected joints inducing inflammatory responses. In the serum of rheumatoid arthritis patients (auto)antibodies directed against Fc domains of antibodies called rheumatoid factor (RF) are found, however 40-50% of patients are seronegative for this factor. There are also a high number of false positive test results due to other disorders. Treatment of RA aims at relieving symptoms and preventing destruction of joints. Treatment regimes include disease modifying anti-rheumatic drugs (DMARDs), such as sulfasalazine and methotrexate, glucocorticoids and nonsteroidal anti-inflammatory drugs (NSAIDs) such as diclofenac and ibuprofen. In more recent years biologicals such as Tumor Necrosis Factor (TNF)α inhibitors or TNFα blocking antibodies, have become available for treatment of RA. Examples of these biologicals include etanercept (receptor fusion protein) and infliximab and adalimumab (monoclonal antibodies). Spondyloarthritis is the name of a family of rheumatic inflammatory diseases that are characterized by arthritis of the spine but also peripheral joints. SpA comprises ankylosing spondylitis, psoriatic arthritis and psoriatic spondylitis, reactive arthritis and enteropathic arthritis. Patients suffering from ankylosing spondylitis usually experience pain and stiffness in the lower back, which becomes rigid and curved as the vertebrae fuse together. Approximately 40% of patients will also develop eye inflammation during the course of the disease. Reactive arthritis is redness and swelling of the large joints following a bacterial infection of the gastrointestinal tract, often caused by food poisoning, or genito-urinary tract, usually caused by micro-organisms responsible for chlamydia and gonorrhea. Psoriatic arthritis and psoriatic spondylitis occur in about 5% of people with psoriasis and often manifests itself with tendinitis and swelling of the fingers, and tends to develop 10 years after the onset of psoriasis. Enteropathic arthritis is associated with inflammatory bowel diseases, ulcerative colitis and Crohn's disease. Inflammation of the peripheral joints is accompanied by gastrointestinal symptoms such as abdominal pain and diarrhea. SpA is often referred to as seronegative to differentiate the diseases from RA. Symptoms often overlap between RA and SpA but SpA patients are negative for RF. SpA is often treated with NSAIDs or DMARDs. As with RA, anti-TNF treatment has been shown to be effective in treating spinal and peripheral joint symptoms of spondyloarthritis, psoriasis and intestinal inflammation. The consequences of joint inflammation in RA and SpA are entirely different. Chronic inflammation in RA leads to cartilage and bone destruction almost without repair, whereas joint damage in SpA is dominated by excessive cartilage and bone formation leading to ankylosis. Moreover successful treatment of inflammation by TNF blockade inhibits cartilage and bone destruction in RA but does not affect structural remodeling and ankylosis in human SpA. Consequently, RA and SpA diseases require different treatments. Early diagnosis is crucial as very early diagnostic intervention is the best way to diminish or prevent long-term morbidity and irreversible structural damage and functional impairment of joint mobility. In full-blown disease, the two different disorders are relatively easy to recognize clinically. However, RA and SpA are often indistinguishable in the early phases of the disease. Therefore, a major challenge is to develop methods for early diagnosis of RA versus SpA. It is an aim of the present invention to provide methods and means for typing a sample for discrimination between rheumatoid arthritis and spondyloarthritis. The present invention provides the insight that levels of expression products of a here disclosed set of genes in individuals suffering from rheumatoid arthritis differ from expression product levels of said set of genes in individuals suffering from spondyloarthritis. Importantly, a difference in expression levels of said set of genes according to the invention is already measurable at an early stage of disease (less than six months of disease duration). Thus, by measuring expression levels of at least some genes of the herein provided set of genes, it has now become possible to distinguish between rheumatoid arthritis and spondyloarthritis. Accordingly the invention provides a method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising determining levels of expression products of a set of genes, said expression products being obtained from, and/or present in, a sample of said individual, and typing said sample on the basis of the expression product levels determined for said set of genes, wherein said set of genes comprises at least 5 genes listed in table 3. Preferably, typing a sample comprises measuring the expression product levels of a set of genes according to the invention and comparing said expression levels with reference values. Said reference values are preferably representative of the expression product levels of the same genes in RA and/or SpA patients. Subsequently, said sample is typed as being indicative for RA or SpA depending on similarity with the RA or SpA reference values. In principle, the more gene expression product levels according to the invention are determined, the more accurate the typing of a sample of an individual will be. Determining the levels of expression products of at least 10 genes according to the invention often results in a more accurate typing of a sample of an individual suspected of suffering from RA or SpA than determining the levels of expression products of 5 genes. Likewise, determining the levels of expression products of at least 20 genes according to the invention often results in a more accurate typing of a sample than determining the levels of expression products of 10 genes. Therefore, determining the levels of expression products of at least 10 genes according to the present invention is preferred over determining the levels of expression products of 5 genes. Determining the levels of expression products of at least 20 genes according to the invention is even more preferred. Determining the levels of expression products of at least 50 genes according to the invention is most preferred. As used herein spondyloarthritis or SpA encompasses all subgroups of spondyloarthritis including psoriatic and nonpsoriatic spondyloarthritis. The original data shown in the Examples were obtained in exclusively non-psoriatic SpA but the subsequent confirmation study showed exactly the same findings in psoriatic SpA. Table 3 shows the genes which in a synovial tissue sample of an individual suffering from spondyloarthritis have an at least 1.5 fold higher or lower expression level than in a synovial tissue sample of an individual suffering from rheumatoid arthritis. Table 4 shows the genes which in a synovial tissue sample of an individual suffering from spondyloarthritis have an at least 2 fold higher or lower expression level than in a synovial tissue sample of an individual suffering from rheumatoid arthritis. Thus, determining the levels of expression products of genes listed in table 4 is often preferred over determining the levels of expression products of genes listed in table 3, because the difference between said levels is larger. Hence, typing a sample with a method according to the invention is more sensitive when expression product levels of genes listed in table 4 are determined. Further provided is therefore a method according to the invention wherein a set of genes according to the invention comprises at least 5 genes from table 4. In another preferred embodiment, a method according to the invention is provided wherein a set of genes according to the invention comprises at least 10 genes from table 3 or 4. More preferably a set of genes according to the invention comprises at least 10 genes from table 4. As explained above, in an even more preferred embodiment expression levels of at least 20 genes according to the invention are determined. Further provided is therefore a method according to the invention wherein a set of genes according to the invention comprises at least 20 genes from table 3 or 4. More preferably a set of genes according to the invention comprises at least 20 genes from table 4. Even more preferably a set of genes according to the invention comprises at least 50 genes from table 3 or 4, more preferably a set of genes according to the invention comprises at least 50 genes from table 4. Hence, as defined herein, a set of genes according to the invention comprises at least 5 genes, more preferably at least 10 genes, more preferably at least 20 genes, even more preferably at least 50 genes listed in table 3 or 4. More preferably, a set of genes according to the invention comprises at least 5 genes, more preferably at least 10 genes, more preferably at least 20 genes, even more preferably at least 50 genes listed in table 4. Every sample comprising expression products of genes is, in principle, suitable for a method according to the invention. Preferably, however, said sample comprises synovial tissue, blood or peripheral blood mononuclear cells (PBMC's). Synovial tissue from an individual suffering from rheumatoid arthritis or spondyloarthritis is the primary target tissue of the disease. In view of this, the present inventors identified differentially expressed genes in the inflamed tissue, namely synovial tissue. For identifying differentially expressed genes in RA and SpA, a synovial tissue sample is highly preferred over samples normally used in prior art studies. These studies mostly use peripheral blood for the identification of differentially expressed genes in a wide variety of applications and may reveal some signatures of inflammation, but do not completely assess the complex interaction between inflammation and tissue reaction, such as destruction, remodeling and new tissue formation, which is the crucial distinction between rheumatoid arthritis and spondyloarthritis. According to the invention, now that differentially expressed genes in early RA as compared to early SpA in synovial tissue samples of individuals suffering from RA or SpA have been identified, levels of expression product of the identified genes can also be measured in blood and PBMC's. It is generally not self-evident that genes that are differentially expressed in one kind of tissue, such as synovial tissue, are also differentially expressed in another type of sample, such as PBMC's. However, as is shown in the Examples, several genes identified as being differentially expressed in early RA as compared to early SpA in synovial tissue samples are surprisingly also differentially expressed in PBMC's of individuals suffering from RA or SpA. As explained above, one of the advantages of a method according to the invention is that it is useful in early disease (less than six months disease duration) when the two disorders are indistinguishable clinically. As mentioned above, early diagnosis is crucial because the disorders require different treatment and very early intervention is the best way to diminish or prevent long-term morbidity, irreversible structural damage and functional impairment of joint mobility. Therefore in a preferred embodiment the invention provides a method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising determining levels of expression products of a set of genes, said expression products being obtained from, and/or present in, a sample obtained or prepared from synovial tissue, blood or PBMC's of said individual, and typing said sample on the basis of the expression product levels determined for said set of genes, wherein said set of genes comprises at least 5 genes listed in table 3. As outlined above, said set of genes preferably comprises at least 5, more preferably at least 10, more preferably at least 20, most preferably at least 50 genes from table 3 or 4. More preferably said set of genes comprises at least 5, more preferably at least 10, more preferably at least 20, most preferably at least 50 genes from table 4. Preferably a synovial tissue sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis is obtained or prepared from a knee joint or an ankle-joint of said individual. Knee joints and ankle-joints are part of the group of large synovial joints in the body that are usually affected in rheumatoid arthritis and spondyloarthritis. Thus the invention provides a method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising determining levels of expression products of a set of genes, said expression products being obtained from, and/or present in, a sample of a knee joint or an ankle-joint of said individual, and typing said sample on the basis of the expression product levels determined for said set of genes, wherein said set of genes comprises at least 5 genes listed in table 3. As outlined above, said set of genes preferably comprises at least 5, more preferably at least 10, more preferably at least 20, most preferably at least 50 genes from table 3 or 4. More preferably said set of genes comprises at least 5, more preferably at least 10, more preferably at least 20, most preferably at least 50 genes from table 4. A synovial tissue sample according to the invention is for instance obtained via a biopsy. Alternatively, a synovial sample can be obtained by blind needle biopsy or during surgery. Preferably, however, a blood sample or PBMC sample is used, because obtaining such sample is performed easily with little discomfort for the subject. As used herein a PBMC sample is defined as a sample comprising cells derived from the blood of a subject. Such a sample for instance includes lymphocyte, monocytes, macrophages and/or combinations thereof. With the insight of the present invention, from each gene listed in tables 3 and 4 it has been determined whether said gene has a higher or lower expression level in synovial tissue in SpA and RA. When determining levels of expression products of a set of genes according to the invention using synovial tissue samples from individuals suffering from or suspected of suffering from SpA or RA, not all of said genes will always be regulated as indicated in tables 3 and 4. It is possible that certain individuals suffering from SpA or RA will have an expression level of one or several genes according to the invention that does not match with tables 3 and 4. However, the overall expression pattern in a synovial tissue sample of an individual suffering from RA will still resemble the RA expression pattern according to the invention more than the SpA expression pattern according to the invention, and vice versa. Typing of a synovial tissue sample from individuals suffering from or suspected of suffering from SpA or RA is therefore preferably based on the overall results of the expression levels of the genes determined. Thus in order to type a synovial tissue sample with a method according to the invention, it is preferably determined whether up- or downregulation of a set of genes better resembles either up- or downregulation of genes established in synovial tissue samples from individuals suffering from SpA or up- or downregulation of genes established in synovial tissue samples from individuals suffering from RA. If the expression levels of a set of genes according to the invention of a test sample more closely resemble the expression levels of said genes in RA individuals, the tested sample is typed to be an RA sample. If, on the other hand, the expression levels of said set of genes more closely resemble the expression levels of said genes in SpA individuals, the tested sample is established to be a SpA sample. Likewise, in order to type a blood sample or a PBMC sample with a method according to the invention, it is preferably determined whether up- or downregulation of a set of genes according to the invention better resembles the expression levels of said set of genes in blood samples or PBMC samples from individuals suffering from SpA or the expression levels of said set of genes in blood samples or PBMC samples from individuals suffering from RA. If the expression levels of a set of genes according to the invention of a test sample more closely resemble the expression levels of said genes in RA individuals, the tested sample is typed to be an RA sample. If, on the other hand, the expression levels of said set of genes more closely resemble the expression levels of said genes in SpA individuals, the tested sample is established to be a SpA sample. It is possible that certain individuals suffering from SpA or RA will have an expression level of one or several genes according to the invention that does not match with the differential expression of these genes established in blood samples or PBMC samples from individuals suffering from SpA or RA. However, the overall expression pattern in a blood sample or a PBMC sample of an individual suffering from RA will still resemble the RA expression pattern according to the invention more than the SpA expression pattern according to the invention, and vice versa. Whether the expression levels of a set of genes according to the invention of a test sample more closely resemble the expression levels of said genes in RA or SpA individuals is for instance determined by counting the number of genes from which the up- or downregulation corresponds with the up- or downregulation of said genes in RA or SpA. For example, when the differential regulation of more than 30 out of 50 genes according to the invention, more preferably 35 out of 50 genes according to the invention, even more preferably 40 out of 50 genes according to the invention corresponds to the differential regulation in RA, a test sample is typed as being indicative for RA. When the differential regulation of more than 30 out of 50 genes according to the invention, more preferably 35 out of 50 genes according to the invention, even more preferably 40 out of 50 genes according to the invention corresponds to the differential regulation in SpA, a test sample is typed as being indicative for SpA. In one embodiment the invention provides a method wherein expression levels of at least one of 12 genes with an at least 3-fold positive regulation and/or at least one of 8 genes with an at least 3-fold negative regulation are determined. The 12 selected genes with with an at least 3-fold positive regulation in RA compared to SpA all function in the same pathophysiological mechanism, namely plasmablast and plasma cell differentiation, survival, and function. These genes are tumour necrosis factor receptor superfamily member 17 (TNFRSF17), , immunoglobulin J polypeptide, linker protein for immunoglobulin alpha and mu polypeptides (IGJ), POU class 2 associating factor 1 (POU2AF1), Der1-like domain family, member 3 (DERL3), Fc receptor-like 5 (FCRL5), plasma cell-induced ER protein 1 (PACAP), prepronociceptin (PNOC), secreted phosphoprotein 1 (SPP1), interferon regulatory factor 4 (IRF4), lymphocyte transmembrane adaptor 1 (LAX1), ELL associated factor 2 (EAF2), and pim-2 oncogene (PIM2). The 8 selected genes with an at least 3-fold regulation in RA compared to SpA all function in the same pathophysiological mechanism, namely myocyte or myofibroblast differentiation, survival, and function. These genes are actin, alpha 1, skeletal muscle (ACTA1), Myosin, heavy chain 3, skeletal muscle, embryonic (MYH2), myosin, heavy chain 1, skeletal muscle, adult (MYH1), cysteine and glycine-rich protein 3 (CSRP3), actinin, alpha 2 (ACTN2), troponin I type 2 (TNNI2), cytochrome P450, family 26, subfamily B, polypeptide 1 (CYP26B1), and titin-cap (TCAP). Determining the levels of expression products of these genes is preferred because typing a sample from an individual suspected of suffering from SpA or RA by determining said levels is particularly sensitive. Thus the invention provides a method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising determining levels of expression products of a set of genes, said expression products being obtained from, and/or present in, a sample of said individual and typing said sample on the basis of the expression product levels determined for said set of genes, wherein said set of genes comprises tumour necrosis factor receptor superfamily member 17 (TNFRSF17) and/or immunoglobulin J polypeptide, linker protein for immunoglobulin alpha and mu polypeptides (IGJ) and/or POU class 2 associating factor 1 (POU2AF1), and/or Der1-like domain family, member 3 (DERL3), and/or Fc receptor-like 5 (FCRL5), and/or plasma cell-induced ER protein 1 (PACAP), and/or prepronociceptin (PNOC), and/or secreted phosphoprotein 1 (SPP1), and/or interferon regulatory factor 4 (IRF4), and/or lymphocyte transmembrane adaptor 1 (LAX1), and/or ELL associated factor 2 (EAF2), and/or pim-2 oncogene (PIM2) and/or actin, alpha 1, skeletal muscle (ACTA1) and/or Myosin, heavy chain 3, skeletal muscle, embryonic (MYH2) and/or myosin, heavy chain 1, skeletal muscle, adult (MYH1), and/or cysteine and glycine-rich protein 3 (CSRP3), and/or actinin, alpha 2 (ACTN2), and/or troponin I type 2 (TNNI2), and/or cytochrome P450, family 26, subfamily B, polypeptide 1 (CYP26B1), and/or titin-cap (TCAP). In a preferred embodiment of the invention levels of expression products of at least 2, more preferably at least 3, more preferably at least 4, more preferably at least 5, more preferably at least 6, more preferably at least 7 genes selected from the group consisting of TNFRSF17 and IGJ and POU2AF1 and DERL3, and FCRL5, and PACAP, and PNOC, and SPP1, and IRF4, and LAX1, and EAF2, and PIM2 and ACTA1 and MYH2 and MYH1, and CSRP3, and ACTN2, and TNNI2, and CYP26B1, and TCAP are determined. In a most preferred embodiment, the invention provides a method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising determining levels of expression products of a set of genes, said expression products being obtained from, and/or present in, a sample of said individual, and typing said sample on the basis of the expression product levels determined for said set of genes, wherein said set of genes comprises TNFRSF17 and IGJ and POU2AF1 and DERL3, and FCRL5, and PACAP, and PNOC, and SPP1, and IRF4, and LAX1, and EAF2, and PIM2 and ACTA1 and MYH2 and MYH1, and CSRP3, and ACTN2, and TNNI2, and CYP26B1, and TCAP. In another preferred embodiment, the invention provides a method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising determining levels of expression products of a set of genes, said expression products being obtained from, and/or present in, a sample of said individual, and typing said sample on the basis of the expression product levels determined for said set of genes, wherein said set of genes comprises TNFRSF17, and POU2AF1, and FCRL5, and PACAP, and PNOC, and SPP1, and IRF4, and EAF2, and PIM2, and ACTA1, and MYH2, and CSRP3, and CYP26B1, and TCAP. In one embodiment the invention provides a method according to the invention wherein expression levels of key regulatory genes of significantly regulated molecular pathways are determined. Significantly regulated molecular pathways overrepresented in RA include cytotoxic T lymphocyte-mediated apoptosis, communication between innate and adaptive immune cells, hepatic fibrosis / hepatic stellate cell activation, death receptor signaling and type I diabetes mellitus signaling. Significantly regulated molecular pathways overrepresented in SpA include calcium signaling, actin cytoskeleton signaling, ILK signaling, cellular effects of sildenafil (Viagra) and hepatic fibrosis / hepatic stellate cell activation. Expression products of a set of genes obtained from or present in a sample from an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis comprise for instance nucleic acid molecules and proteins. Analysis of expression products according to the invention can be performed with any method known in the art. Protein levels are for instance measured using antibody-based binding assays. Enzyme labeled, radioactively labeled or fluorescently labeled antibodies are for instance used for detection of protein. Assays that are for instance suitable include enzyme-linked immunosorbent assays (ELISA), radio-immuno assays (RIA), Western Blot assays and immunohistochemical staining assays. Alternatively, in order to determine the expression level of multiple proteins simultaneously protein arrays such as antibody-arrays are for instance used. An expression product according to the invention preferably comprises RNA. The lifespan of RNA molecules is shorter than the lifespan of proteins. RNA levels are therefore more representative of the status of an individual at the time of sample preparation. Furthermore, determining RNA expression levels is less laborious than determining protein levels. For instance oligonucleotides arrays are used that are easier to develop and process than protein chips. Therefore, in a preferred embodiment of the invention an expression product according to the invention is RNA. Accordingly, the invention provides a method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising determining levels of RNA of a set of genes, said RNA being obtained from, and/or present in, a sample of said individual and typing said sample on the basis of the RNA levels determined for said set of genes, wherein said set of genes comprises at least 5 genes listed in table 3. As explained above, said sample preferably comprises synovial tissue, more preferably said sample is obtained or prepared from a knee joint or an ankle-joint of said individual. Most preferably, however, a blood sample or a PBMC sample is used. RNA samples can be processed in numerous ways, as is known to a skilled person. For example, they can be freshly prepared from cells or tissues at the moment of harvesting, or they can be prepared from samples that are stored at -70°C until processed for sample preparation. Tissues or cell samples can also be stored under alternative conditions that preserve the quality of the RNA. Examples of these preservative conditions are fixation using e.g. formaline, RNase inhibitors such as RNAsin (Pharmingen) or RNasecure (Ambion), aquous solutions such as RNAlater (Assuragen), Hepes-Glutamic acid buffer mediated Organic solvent Protection Effect (HOPE), and RCL2 (Alphelys), and non-aquous solutions such as Universal Molecular Fixative (Sakura Finetek USA Inc.). Usually, a chaotropic nucleic acid isolation lysis buffer (Boom method, Boom et al. J Clin Microbiol. 1990; 28:495-503 ) is used for RNA isolation. Preferably RNA levels are quantified. The RNA level of a set of genes according to the invention is determined by any method known in the art. RNA levels can for instance be quantified in relation to a household gene and/or can be determined relatively in relation with RNA levels of other genes measured at the same time. Methods to determine RNA levels of genes are known to a skilled person and include, but are not limited to, Northern blotting, (quantitative) PCR, and microarray analysis. Northern blotting comprises the quantification of RNA of a specific gene by hybridizing a labeled probe that specifically interacts with said RNA, after separation of RNA by gel electrophoresis. Probes are for instance labeled with radioactive isotopes or chemiluminescent substrates. Quantification of the labeled probe that has interacted with said nucleic acid expression product serves as a measure for determining the level of expression. The determined level of expression can be normalized for differences in the total amounts of nucleic acid expression products between two separate samples with for instance an internal or external calibrator by comparing the level of expression of a gene that is known not to differ in expression level between samples or by adding a known quantity of RNA before determining the expression levels. Additionally or alternatively, RNA is reverse transcribed into cDNA. Reverse transcriptase polymerase chain reaction (RT-PCR) is for instance performed using specific primers that hybridize to an RNA sequence of interest and a reverse transcriptase enzyme. Furthermore, RT-PCR can be performed with random primers, such as for instance random hexamers or decamers which hybridize randomly along the RNA, or oligo d(T) which hybridizes to the poly(A) tail of mRNA, and reverse transcriptase enzyme. Quantitative Polymerase Chain Reaction (qPCR) provides an alternative method to quantify the level of expression of nucleic acids. qPCR can be performed by real-time PCR (rtPCR), in which the amount of product is monitored during the amplification reaction, or by end-point measurements, in which the amount of a final product is determined. As is known to a skilled person, rtPCR is for instance performed by the use of a nucleic acid intercalator, such as for example ethidium bromide or SYBR® Green I dye, which interacts which all generated double stranded products resulting in an increase in fluorescence during amplification, or for instance by the use of labeled probes that react specifically with the generated double stranded product of the gene of interest. Alternative detection methods that can be used are provided by amongst other things dendrimer signal amplification, hybridization signal amplification, and molecular beacons. Microarray analysis involves the use of selected nucleic acid molecules that are immobilized on a surface. These nucleic acid molecules, termed probes, are able to hybridize to nucleic acid expression products. In a preferred embodiment the probes are exposed to labeled sample nucleic acid, hybridized, washed and the (relative) amount of nucleic acid expression products in the sample that are complementary to a probe is determined. Microarray analysis allows simultaneous determination of nucleic acid expression levels of a large number of genes. In a method according to the invention it is preferred that at least 5 genes according to the invention are measured simultaneously. Therefore, in a preferred embodiment of the invention RNA levels obtained from, and/or present in, a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis are determined by microarray analysis. Thus the invention provides a method for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising determining RNA levels of a set of genes, said RNA being obtained from, and/or present in, a sample of said individual, and typing said sample on the basis of the RNA levels determined for said set of genes, wherein said set of genes comprises at least 5 genes listed in table 3 and wherein RNA levels are determined by microarray analysis. Background correction can be performed for instance according to the \"offset\" method that avoids negative intensity values after background subtraction. Furthermore, normalization can be performed in order to make the two channels on each single array comparable for instance using global loess normalization, and scale normalization which ensures that the log-ratios are scaled to have the same median-absolute-deviation (MAD) across arrays. In a preferred embodiment a method according to the invention is provided wherein RNA levels of at least 10, more preferably at least 20, most preferably at least 50 genes from table 3 or 4 are determined. More preferably RNA levels of at least 5, more preferably at least 10, more preferably at least 20, most preferably at least 50 genes from table 4 are determined in order to enhance specificity. Now that the invention has provided the insight that the genes listed in tables 3 and 4 are differentially expressed in SpA patients compared to RA patients, a nucleotide microarray is provided in order to measure these changes in expression. Also provided is therefore a nucleotide microarray comprising nucleic acid molecules being able to hybridize to at least 5 genes listed in table 3 or 4, and wherein at least 60%, preferably at least 70%, more preferably at least 80% of the nucleic acid molecules of said microarray are able to hybridize to genes listed in table 3 or 4. Probes immobilized on said nucleotide microarray comprise at least 5 nucleic acid molecules able to hybridize to at least 5 genes listed in table 3 or 4. Each of said at least 5 nucleic acid molecules is capable of hybridizing to a different gene of table 3 or 4, so that, overall, at least 5 different genes listed in table 3 or 4 can be bound. More preferably a nucleotide microarray according to the invention comprises nucleic acid molecules being able to hybridize to at least 10 genes listed in table 3 or 4, more preferably a nucleotide microarray according to the invention comprises nucleic acid molecules being able to hybridize to at least 20 genes listed in table 3 or 4, more preferably a nucleotide microarray according to the invention comprises nucleic acid molecules being able to hybridize to at least 50 genes listed in table 3 or 4. Hybridization is known in the art and refers to the combining of complementary, single-stranded nucleic acids, preferably under stringent conditions. Complementary is also known in the art and refers to two nucleic acid strands from which the base pairs can be non-covalently connected. A nucleotide microarray according to the invention comprises nucleic acid molecules, preferably DNA oligonucleotides. The length of said DNA oligonucleotides can vary between 15 bases and several kilo bases, and is preferably between 20 bases and 1 kilobase, more preferably between 40 and 100 bases, and most preferably between 50 and 80 nucleotides. Most (i.e. at least 60% of) nucleic acid molecules of a nucleotide microarray according to the invention are able to hybridize to genes listed in table 3 or 4. Of note, tables 3 and 4 contain non-limiting examples of suitable nucleic acid probes which are used in the Examples. Other nucleic acid probes which are able to hybridize to a different region of the in table 3 or 4 listed genes are of course also suitable for use in a microarray or method according to the invention. Using a nucleotide microarray according to the invention an accurate gene expression profile is obtained in order to type a sample from an individual suspected of suffering from SpA or RA by determining whether the profile of a sample resembles a SpA expression profile or an RA expression profile according to the invention. The remaining at most 40% of the nucleic acid molecules of a nucleotide microarray are for instance able to hybridize to a set of reference genes or a set of normalization genes. Normalization is preferably performed in order to reduce systemic bias. Systemic bias results in variation by inter-array differences in overall performance, which can be due to for example inconsistencies in array fabrication, staining and scanning, and variation between labeled RNA samples, which can be due for example to variations in purity. Systemic bias can be introduced during the handling of the sample in a microarray experiment. To reduce systemic bias, the determined RNA levels are preferably corrected for background non-specific hybridization and normalized. Said normalization genes detect for instance RNA expression levels of housekeeping genes such as glyceraldehyde-3-phosphate dehydrogenase (GAPDH), hypoxanthine phosphoribosyltransferase (HPRT) and 18S RNA levels, of which the RNA level is thought to be constant in a given cell or tissue and independent from the disease affecting said cell or tissue or inflammatory status of said cell or tissue. The use of such reference probes is advantageous but not mandatory. In one embodiment a microarray according to the invention is provided wherein at least 90% of the nucleic acid sequences are able to hybridize to genes listed in table 3 or 4. In a further embodiment at least 95% or even 100% of the nucleic acid sequences are able to hybridize to genes listed in table 3 or 4. As used herein, a nucleic acid molecule or nucleic acid sequence of the invention that serves as a probe in a microarray analysis preferably comprises a chain of nucleotides, more preferably DNA and/or RNA. In other embodiments a nucleic acid molecule or nucleic acid sequence of the invention comprises other kinds of nucleic acid structures such as for instance a DNA/RNA helix, peptide nucleic acid (PNA), locked nucleic acid (LNA) and/or a ribozyme. Hence, as used herein the term \"nucleic acid molecule\" also encompasses a chain comprising non-natural nucleotides, modified nucleotides and/or non-nucleotide building blocks which exhibit the same function as natural nucleotides. Also provided is a use of a nucleotide microarray according to the invention for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis. As said before, said microarray preferably comprises nucleic acid molecules being able to hybridize to at least 10 genes, preferably at least 20 genes, most preferably at least 50 genes listed in table 3 or 4 in order to improve specificity and/or sensitivity. The invention is further explained in the following examples. These examples do not limit the scope of the invention, but merely serve to clarify the invention. Figure legends \n Figure 1 . Normalization of the microarray data. Raw data from one of the microarrays plotted in MA-plot, A is mean log intensity, M is log ratio. (A). Normalized data from the same microarray plotted in MA-plot (B). Density distribution of the intensities across the red and green channels for the raw data (C) and normalized data (D) of all microarrays in the experiment. Box-plots of the log ratios observed in the microarrays, using the raw data (E) and normalized data (F). The boxes span the range of log ratios that fall in the middle 50% of the distribution. The whiskers show extreme upper and lower observations on each microarray. Figure 2 . Quantitative RT-PCR analysis for technical validation of microarray data on the same cohort. (A). RT-PCR of TNFRSF17, IGJ, POU2AF1, DERL3, FCRL5, CXCL13, PACAP, PNOC, SPP1, IRF4, LAX1, EAF2, PIM2 transcripts which have been determined by microarray analysis as upregulated in synovial tissue samples of RA patients. (B). RT-PCR of ACTA1, MYH2, MYH1, CSRP3, ACTN2, TNNI2, CYP26B and TCAP transcripts which have been determined by microarray analysis as upregulated in synovial tissue samples of SpA patients. Data is represented as an individual expression corrected for expression of the control gene (GAPDH) and bars show the median. Relative expression level was considered significant if p<0.05 (Mann-Whitney). (C). Correlation of microarray data and real time PCR data Figure 3 . Quantitative RT-PCR analysis for biological validation of microarray data on the independent cohort. (A). RT-PCR of TNFRSF17, IGJ, POU2AF1, DERL3 transcripts which have been determined by microarray analysis as upregulated in synovial tissue samples of RA patients. (B). RT-PCR of ACTA1, MYH2, MYH1, CSRP3, ACTN2, TNNI2 transcripts which have been determined by microarray analysis as upregulated in synovial tissue samples of SpA patients. Data is represented as an individual expression corrected for expression of the control gene (GAPDH) and bars show the median. Relative expression level was considered significant if p<0.05 (Mann-Whitney Test). (C). Correlation of microarray data and real time PCR data. D. RT-PCR of TNFRSF17, IGJ, DERL3, FCRL5, ACTA1, MYH2, MYH1, CSRP3, ACTN2, TNNI2 transcripts on RA, psoriatic and non-psoriatic SpA synovium. Figure 4 . Semiquantitative scores for α-SM actin (A) and smooth muscle myosin heavy chain (B) expression in synovial membrane biopsy specimens obtained from RA and SpA joints. Scatterplots show the individual scores, and bars show the mean. p values were calculated using unpaired T test. Figure 5 . Quantitative RT-PCR analysis for biological validation of microarray data on PBMC's of patients with axial SpA (no peripheral disease), RA, and healthy donors. RT-PCR of ACTA1 and MYH2 transcripts which have been determined by microarray analysis as upregulated in PBMC samples of SpA patients. Data is represented as an individual expression corrected for expression of the control gene (GAPDH) and bars show the median. Relative expression level was considered significant if p<0.05 (Mann-Whitney Test). Examples Material and methods Patients and samples synovial tissue samples were obtained from three independent patient cohorts: the first cohort was used for microarray analysis and technical confirmation of differentially expressed genes by quantitative RT-PCR, the second cohort was used for an independent confirmation of the biological validity of the gene expression signature, and the third cohort was used for confirmation of candidate pathways at the protein level by immunohistochemistry. All patients fulfilled the classification criteria for either SpA according to the ESSG criteria (1) or RA according to the ACR criteria (2). All patients had active disease with clinical involvement of at least one knee or ankle joint and were not treated with biological therapies. A total of 20-25 synovial tissue biopsies were obtained and processed as described earlier from these inflamed joints (3): 6-8 biopsies were pooled and used for RNA isolation and 6-8 additional biopsies were used for immunohistochemistry. In order to generate robust microarray data, it was aimed to assess homogeneous and representative samples of RA and SpA in cohort 1. At the histological level, samples were selected for a median histological disease activity as assessed by level of synovial infiltration with CD3+ T and CD20+ B lymphocytes in order to match the cohorts for local disease activity. At the clinical level, only patients who were not treated with disease-modifying anti-rheumatic drugs or biologics were selected in order to exclude treatment-induced biases. Additionally, psoriatic SpA (PsA) was excluded in order to obtain a clinically homogeneous SpA cohort. In the independent validation cohort (cohort 2), additionally patients with early disease of less than 1 year and added PsA were selected as an additional SpA group. The demographic and clinical data of the patient cohorts are given in Table 1. Peripheral blood mononuclear cells (PBMC's) were obtained from patients with axial SpA who did not show symptoms of peripheral disease, patients with RA and healthy donors. RNA isolation and microarray hybridisation RNA was obtained from 6-8 snap frozen synovial tissue biopsies per patient. The RNA isolation, cDNA synthesis, and labelling was carried out using Agilent's Two-Colour Microarray-Based Gene Expression Protocol according to the manufacturer's instructions (G4140-90050, Version 5.7, Agilent Technologies, Palo Alto, CA, USA. RNA quantity was checked with the Bioanalyzer system using the RNA 6000 Nano LabChip kit (Agilent Technologies). As to RNA quality, only the samples with RNA integrity numbers (RIN) values of greater than 6.0 were considered to be of adequate quality to be selected for hybridization. The RNA integrity number (RIN) measures RNA quality on a quantitative scale of 1 (poor) to 10 (high) as measured by a software algorithm that works with the 2100 bioanalyzer and Agilent RNA 6000 Nano LabChip ® kit. To correct for gene-specific dye biases, we used a reverse labelling (dye swap) design with common reference. Labeled samples were hybridized to Agilent 4x44K Human Whole Genome microarrays (G4112F). Slides were washed and scanned on an Agilent G2565 Microarray scanner, and data was extracted using Agilent Feature Extraction software (Version.10.1, Agilent Technologies). Microarray data analysis The microarray data were analyzed using the Limma package (4) of the Bioconductor project (software for analysis of genomic data; www.bioconductor.org). Raw intensity data of each spot on the array from all biological and technical replicates were acquired as array-object, including annotation for each spot. Background correction was performed according to the \"offset\" method that avoids negative intensity values after background subtraction. Background correction was followed by \"within array\" normalization for each microarray separately using global loess normalization (5) in order to make the two channels on each single array comparable. After normalization, the mean log intensity A and the log ratio M of the intensity data were calculated for each spot on the microarray. These quantities are defined as A=(1/2)( 2 logR+ 2 logG) and M= 2 1og(R/G), where R and G are the intensities measured in the red and green channels, respectively (6,7). Next, \"between array\" normalization was performed in order to obtain similar distributions of the mean log intensities or log ratios across a series of arrays. In particular, scale normalization which ensures that the log-ratios are scaled to have the same median-absolute-deviation (MAD) across arrays was applied (6) ( Figure 1 ). The normalized data were then fitted with a linear model for each probe on the array for each biological replicate (8). Limma uses an empirical Bayes method to estimate the standard error of the log ratios (9). Subsequently, it was tested whether the log ratio of each spot on the microarray differs significantly from zero using a t test. The p-values were adjusted for multiple hypotheses testing by Bonferroni correction. Quantitative RT-PCR Total RNA was isolated from synovial tissue biopsies or PBMC's using RNA Stat-60 (Tel-Test Inc, Friendswood, Tx, USA), treated with DNase I (Invitrogen, Carlsbad, CA, USA), and reverse transcribed using RevertAid™H Minus First Strand cDNA Synthesis Kit (Fermentas, St. Leon-Rot, Germany). RNA concentration was determined with the Nanodrop (Nanodrop Technologies, Wilmington, DE USA). Quantitative real-time PCR was performed using StepOnePlus™ Real-Time PCR System (Applied Biosystems, Foster City, CA, USA). Each 20µl reaction was performed in 96-well format with 5 ng of cDNA, 10 µl of SYBR green PCR Master Mix (Applied Biosystems), and a concentration of 50 nmol of each primer. All reactions were performed in duplicate. The mRNA expression levels were normalized to those of the human housekeeping gene glyceraldehyde 3-phosphate dehydrogenase (GAPDH). Oligonucleotide primers were designed using online tool for Real-time PCR (TaqMan) Primer Design (Genscript) and obtained from Invitrogen. The primers are shown in Table 2. Pathway analysis The microarray data were analyzed using Ingenuity Pathways Analysis tools (Ingenuity Systems, Mountain View, CA, USA, http://www.ingenuity.com), to perform functional pathway analysis and to examine the gene ontology, including biological processes, cellular components, molecular functions and genetic networks. Significantly regulated gene lists containing Agilent probe ID and expression ratio were uploaded into the Ingenuity Pathways Analysis environment. Each gene identifier was mapped to its corresponding gene object in the Ingenuity Pathways Knowledge Base and used as a starting point for generating biological networks and canonical pathway analysis. The Functional Analysis of a network identified the biological functions and/or diseases that were most significant to the genes in the network. Fischer's exact test was used to calculate a p value determining the probability that each biological function and/or disease assigned to that network is due to chance alone. A p value ≤ 0.05 was considered significant. Canonical pathways analysis of the Ingenuity Pathways Analysis Library identified those pathways that were most significant to the data set. Immunohistochemistry Immunohistochemical staining for alpha smooth muscle actin (α -SM actin) and smooth muscle myosin heavy chain (SMMH) was performed on frozen tissue sections of synovial tissue biopsies obtained from patients with RA (n=17) and SpA (n=32). All patients had active disease with at least one clinically affected knee or ankle joint, which was used to obtain synovial biopsies by needle arthroscopy. None of the patients was treated with biological agents. The SpA group consisted of both non-psoriatic (n=21) and psoriatic (n=11) SpA. Synovial biopsy samples (8 per patient) were snap-frozen and mounted in Jung tissue freezing medium (Leica Instruments, Nussloch, Germany). The following primary antibodies were used: monoclonal mouse anti-human Actin (Smooth Muscle), clone 1A4 (Dako, Glostrup, Denamrk) and monoclonal mouse anti-human Smooth Muscle Myosin Heavy Chain, clone SMMS-1 (Dako). Parallel sections were incubated with irrelevant isotype- and concentration-matched monoclonal antibody as negative control. After incubation with the primary antibodies, sections were sequentially incubated with a biotinylated second antibody, a streptavidin-horseradish peroxidase link, and finally with aminoethylcarbazole substrate as chromogen (all from Dako, Glostrup, Denmark). Biopsy sections were stained in a single run and the investigator was blinded to the diagnosis and clinical data in order to minimize technical bias. Expression in the different synovial compartments (vessels, intimal lining layer, and synovial sublining) was quantified on a semiquantative four-point scale by two independent observers blinded for diagnosis. The staining and scoring procedures have been extensively described and validated previously (10-16). Data were represented as median and range. Statistics Results from qPCR and immunohistochemistry were analyzed using non-parametrical statistics, using the Mann-Whitney U test for comparison between groups and the Spearman's rank correlation for correlation between data. P<0.05 was considered statistically significant. Results Synovial gene expression analysis by microarray In order to identify novel and unsuspected cellular and molecular pathways involved in the pathogenesis of RA or SpA, pan-genomic microarrays on synovial tissue biopsies were performed and the gene expression profile between both diseases were compared. For this analysis, exclusively non-treated patients were selected and psoriatic SpA was excluded in order to obtain clinically homogenous patient cohorts. All samples were obtained from clinically inflamed knee joints and were selected for a median level of local tissue inflammation as assessed by synovial infiltration with T and B lymphocytes on histology. Furthermore, only samples yielding high RNA quantity and quality were hybridized and only those microarrays passing the technical quality thresholds were retained for further analysis. Using these strict clinical, histological, and technical selection criteria in order to avoid biases due to sample variability and to obtain robust gene signatures, gene expression data from 11 SpA and 7 RA synovial samples were obtained. Using very stringent data analysis criteria, a set of 6270 genes that were highly significantly differentially expressed (p<0.001) between patients SpA and RA was identified. Of these genes, 296 transcripts displayed a more then 2 fold differential expression between SpA and RA synovium (Table 4). 84 transcripts showed a more than 3 fold upregulation in RA versus SpA, with TNFRSF17 showing a 7 fold upregulation. On the other hand, 21 transcripts showed a more than 3 fold upregulation in SpA versus RA, with ACTA1 showing a 15 fold upregulation. Technical validation of the gene expression signature by quantitative RT-PCR In order to confirm the obtained results by an independent technique, 13 transcripts with a known function with an at least 3-fold upregulation in RA synovitis and 8 transcripts with a known function with an at least 3-fold upregulation in SpA synovitis were selected. The expression of these genes was assessed by quantitative real-time RT-PCR (qPCR) on the samples of cohort 1 (RA n=8, SpA n=12), which was also used for the original microarray experiments. Of the 13 genes upregulated in RA, 10 were also significantly upregulated in RA versus SpA synovitis (p<0.05) by qPCR ( Figure 2a ). An additional 2 genes, CXCL13 (p=0.054) and PIM2 (p=0.059), tended to be significantly higher in RA versus SpA. LAX1 (p =0.211) was not differentially expressed. 8 genes upregulated in SpA were also confirmed to be significantly differentially expressed by qPCR ( Figure 2b ). Globally, there was a very good correlation between the microarray and qPCR results (r=0.80, p<0.0001)( Figure 2c ). Interestingly, the fold-change between RA and SpA for those 21 genes was on average 22 times higher by qPCR than by microarray reaching a 25.4 fold upregulation in RA for PACAP and a 574 fold upregulation in SpA for ACTN2. Biological validation of the gene expression signature by quantitative RT-PCR in an independent sample set In order to verify the biological validity of the gene signatures, the top 11 genes (5 upregulated in RA and 6 upregulated in SpA) were subsequently reanalysed by qPCR in an independent set of synovial tissue samples obtained from 10 non-psoriatic SpA and 11 RA patients (Table 1). These patients were specifically selected for short disease duration in order to ascertain that the gene signature is specific for primary pathways involved in the disease process rather than for secondary down-stream effector mechanisms. Also in this independent sample set, the 5 RA genes were confirmed to be differentially expressed, reaching significance for POU2AF1 (p=0.015) and FCRL5 (p=0.015) and tending to significance for TNFRSF17 (p=0.052), IGJ (p=0.098), and DERL3 (p=0.090) ( Figure 3a ). As to the 6 SpA genes, ACTA-1 (p=0.045), MYH2 (p=0.005) and CSRP3 (p=0.012) were significantly upregulated in SpA versus RA with a similar trend for TNNI2 (p=0.066). MYH1 and ACTN2 did not reach significance ( Figure 3b ). As for cohort 1, the qPCR gene expression levels in cohort 2 correlated well with the original microarray results (r=0.76 p= 0.009) ( Figure 3c ). As psoriatic SpA were excluded from our original analyses, additionally qPCR for 9 of previously mentioned genes (4 upregulated in RA and 5 upregulated in SpA) was performed in biopsy samples of 13 psoriatic SpA patients (Table 2). As shown in Figure 3d , the psoriatic SpA completely resembled the non-psoriatic SpA, with none of the genes being differentially expressed between both groups whereas 9 genes were significantly different between psoriatic SpA and RA. When the non-psoriatic and psoriatic SpA were pooled in one single SpA set, 9 of the 9 investigated transcripts were differentially expressed between RA and SpA. Taken together, these qPCR data obtained in an independent sample set demonstrated that the identified gene signatures are not only technically but also biologically reproducible without major influence of disease duration and clinical SpA subtype. Pathway analysis Analysis of the highly expressed genes (3 fold up- or down-regulation) indicated that 14 of the 37 known genes upregulated in RA were related to B lymphocyte/plasma cell biology despite the fact that the samples of cohort 1 were histologically matched for infiltration with T and B cells. This was also the case for cohort 2, indicating that the gene expression signature does not merely reflect a different cellular composition of inflamed synovial tissue in RA versus SpA. As to genes upregulated in SpA, 20 out of the 21 known genes were related to myocyte/myofibroblast biology. Taken together, these data indicate the biological consistence of the gene signature. Analysis of the pathways overrepresented in the microarray dataset by Ingenuity revealed cytotoxic T lymphocyte-mediated apoptosis of target cells, communication between innate and adaptive immune cells, hepatic fibrosis/hepatic stellate cell activation, and Type I Diabetes Mellitus signaling as canonical pathways in RA (Table 5). Calcium signaling, actin cytoskeleton signaling, ILK signaling, cellular effects of Sildenafil, and hepatic fibrosis/hepatic stellate cell activation were the canonical pathways overrepresented in SpA (Table 5). More detailed analysis of these and other pathway with different software tools is currently ongoing in order to define pivotal pathways in RA and SpA synovial inflammation. Validation at the protein level by immunohistochemistry As indicated, almost all of the top-ranking differentially expressed genes identified in SpA versus RA were related to muscle genes. Some of these genes showed a more than 100-fold upregulation in SpA versus RA synovitis in the qPCR experiments ( Figure 2b and 3b ). This signature is unexpected as myocytes are not present in the synovial tissue with the exception of a few smooth muscle cells around small arteries. As vascularity is more pronounced in SpA than in RA synovitis (10,14,15), we performed immunohistochemistry on a large set of SpA and RA synovial biopsies in order to confirm the microarray data on the protein level and to exclude biases due to differences in vascularization. Immunostainings revealed the expression of α-smooth muscle actin and smooth muscle myosin heavy chain not only around blood vessels, as in healthy synovium, but also in the intimal lining layer and the synovial sublining. α-smooth muscle actin positive cells were significantly increased in SpA versus RA in the synovial sublining (p=0.035 ) as well as in the intimal lining layer (p=0.003) despite similar staining around vessels ( Figure 4a ). Similarly, smooth muscle myosin heavy chain positive cells were significantly increased in SpA versus RA in the synovial sublining (p=0.018) whereas the expression around vessels was lower in SpA than in RA synovitis (p=0.031) ( Figure 4b ). These data confirm the gene signature at the protein level and strongly suggest the specific presence of myofibroblasts in the intimal lining layer and the sublining of SpA synovium. Biological validation of the gene expression signature by quantitative RT-PCR in peripheral blood mononuclear cells (PBMC) The data summarized above demonstrate the presence of a robust and reproducible gene expression signature in RA versus SpA synovitis, this is in the target tissue of the disease. We next explored whether genes that were differentially expressed in synovial tissue of SpA versus RA were also differentially expressed in the peripheral compartment, this is in PBMC. Two 'myo'-genes (ACTA and MYH2) that were strongly upregulated in SpA synovitis by microarray as well as qPCR were analyzed by qPCR in PBMC of an independent cohort of 11 SpA patients, 10 RA patients and 8 healthy donors. Importantly, we selected specifically SpA patients with exclusive axial disease as in this subset of patients analysis of inflamed peripheral joint tissue is not possible. Both ACTA and MYH2 appeared to be differentially downregulated in axial SpA patient PBMC's compared to both RA patient and healthy donor PBMC's ( Figure 5 ), demonstrating an inverse gene signature in peripheral blood compared to synovial tissue. These data show that analysis of the expression of our target genes in PBMC is able to discriminate between the different disease states. Moreover, these data show that the differential expression is not restricted to SpA with peripheral joint disease but can also be found in pure axial SpA.\n TABLE-tabl0001 Table 1. Demographic and clinical data of the patient cohorts. None of the patients was treated with biological drugs. Data are represented as mean and standard deviation for age (years), disease duration (years), number of swollen joints, and C-reactive protein serum levels (mg/L). Gender is given as male/female. Presence of autoantibodies and use of anti-rheumatic drugs are indicated if positive. RA = rheumatoid arthritis. SpA = spondyloarthritis. PsA = psoriatic spondyloarthritis. SJC = swollen joint count. CRP = C-reactive protein. RF = rheumatoid factor. ACPA = anti-citrullinated protein antibodies. DMARD = disease modifying anti-rheumatic drugs. Cohort 1 Cohort 2 RA SpA RA SpA PsA (n=8) (n=12) (n=11) (n=10) (n=13) Age 56 ± 15 44 ± 17 56 ± 13 35 ± 14 47 ± 12 Gender 4/4 8/4 4/7 7/3 9/4 Disease 3.7 ± 6.8 ± 0.5 ± 0.6 ± 0.4 0.9 ± duration 2.9 5.8 0.3 0.8 SJC 10 ± 5 3 ± 3 12 ± 10 2 ± 1 2 ± 3 CRP 45 ± 22 43 ± 47 34 ± 48 21 ± 39 12 ± 13 RF or ACPA 4 0 9 0 0 DMARD 0 0 0 3 2 \n TABLE-tabl0002 Table 2. Primers used for quantitative RT-PCR. The genes were selected from the microarray data as being upregulated more then 3 fold in RA (13 genes selected from 37 known transcripts) or in SpA (8 genes selected from 21 known transcripts). Gene/primer (GenBank accession number) Forward Reverse TNFRSF17 (NM_001192) CTCTGGACCTGTTTGGGACT TTCCAGGTCAATGTTAGCCA IGJ(NM_144646) CTTCCAGGATCATCCGTTCT GGTGAGGTGGGATCAGAGAT POU2AF1 (NM_006235) AAGGAACTGCTGAGGAGGAA CACAGAACCTTCCATGTCCA DERL3 (NM_198440) CAACATGCTCTTCGTGTTCC AGTCCCAGCAGGGTCATAAG FCRL5 (NM_031281) GGTGCATATCGCTGTACTGGA AATGGCTCTTGGACTTGGATTTTGAC CXCL13 (NM_006419) AATGAGCCTGGACTCAGAGC ACCTCCAGAACACCTTGGAC PACAP (NM_016459) GATGTACTCAGCCCACATGC CCACATCTGGTAAGCCACAG PNOC (NM_006228) GCAGCTGCAGAAGAGATTTG TGCTCAGGACCAAGTATTGC SPP1 (NM_000582) TCACCTGTGCCATACCAGTT CCACAGCATCTGGGTATTTG IRF4 (NM_002460) CAGTGGGCTGTTTCTGCTTA CAAGTGGAGGTCTTTGGGAT LAX1 (NM_017773) AACGGAAGAAGCGACAAGTT TTGGCTCTTTGTCTGGTTTG EAF2 (NM_018456) GCTGAGGTGGCAGATAGTGA CGACGGTCTAGGTGTGAGAA PIM2 (NM_006875) AATGGTCAGAAGAGCCATCC CCCTGATCCTCAATCCCTTA ACTA1 (NM_001100) TGCCCATTTATGAGGGCTAC CTCAGCTGTGGTCACGAAG MYH2 (NM_017534) GGCTGGAGAAGAACAAGGAC TCCCTCTCCTTCAGCAGTTT MYH1 (NM_005963) ACAAACTGCAAGCAAAGGTG GGAGAGGTTGACGTTGGATT CSRP3 (NM_003476) AGCAACCCTTCCAAATTCAC CCATAACCTTCTCAGCAGCA ACTN2 (NM_001103) ACAAGATGGAGGAGATTGCC TTCAGCTGGTTCATCTGGTC TNNI2 (NM_003282) CAACCTGAAGCAGGTCAAGA ATGCCAGACTTCTCCTCGAT CYP26B1 (NM_019885) CCATCAACGTGTACCAGGAG ACAGGCAGGGAGAAGACATT TCAP (NM_003673) AAGGTACTGGTGAGGGCAAG GCTTCTTCTGCCTAGAGCGT \n TABLE-tabl0003 Table 3. Transcripts displaying a more then 1.5 fold differential expression between SpA and RA in synovial tissue (FC: fold change). FC p.value Systematic Name Gene Probe Sequence 7,14 1,0E-21 NM_001192 TNFRSF17 GATCTCTTTAGGATGACTGTATTTTTCAGTTGCCGATACAGCTTTTTGTCCTCTAACTGT 6,97 4,7E-18 AY172962 AY172962 AAGATAGCAGCCCCGTCAAGCGGGAGTGGAGACCACCACACCCTCCAAACAAAGCAACAA 6,96 1,0E-21 NM_144646 IGJ TTGGGTGATGTAAAACCAACTCCCTGCCACCAAAATAATTAAAATAGTCACATTGTTATC 6,28 1,9E-19 NM_006235 POU2AF1 TTTTCTGGGAAATGACTTTTCTGGGAAATGACAGTTTCTTTGACATATTTTCTTTGCCCA 5,80 1,1E-19 Bl521983 Bl521983 GAAGTCACTTATGAGACACACCAGTGTGGCCTTGTTGGCTTGAAGCTCCTCAGAGGAGGG 5,72 5,5E-19 AW136683 AW136683 TCTGTCATAAGTGTAGCAGGTCTCTGTAGCACTGTCTTCATCACAGATATTGCTCTGGGT 5,66 5,6E-18 X57802 X57802 ATTCTCTGGCTCCAACTTTGGGAACACAGCCACTCTGACCATCAGCGGGACCCAGGCTAT 5,47 1,1E-17 NM_020070 IGLL1 TCCAAGCCAACAAGGCTACACTGGTGTGTCTCATGAATGACTTTTATCCGGGAATCTTGA 5,33 1,4E-17 NM_001013618 CTA-246H3.1 AACAAGGCCACACTGGTGTGTCTCATGAATGACTTCTATCTGGGAATCTTGACGGTGACC 5,15 9,4E-18 NM_014792 KIAA0125 CCATTTTAAAGATGGCTACTTAGGACCATATGGATGTTGTACTGATGTCATTTGACCACG 5,15 1,0E-21 NM_198440 DERL3 AGGCCTAAGAGGCTTCTGGCAGCTTCCATCCTACCCATGACCCCTACTTGGGGCAGAAAA 4,92 1,3E-18 NM_031281 FCRL5 TGGCATATGGACTGAAAGAAACTATGCTATTGGATCTCCTGGATCTCCAGCTTGCTGACT 4,80 4,2E-16 ENST00000216649 ENST00000216649 CTCAAGAGTCGAGTCACCATATCAGTGGACACGTCCAAGAACCAGTTCTCCCTGAGGCTG 4,70 1,0E-19 NM_006419 CXCL13 CAAGAGGCAAAGGAATCCATGTAGTAGATATCCTCTGCTTAAAAACTCACTACGGAGGAG 4,67 1,3E-18 ENST00000377233 ENST00000377233 TTGTATTGGTACCTGCAGAAGCCAGGCCAGCCTCCACAGCTCCTGATCTATGAAGTTTCC 4,53 2,8E-14 NM_016459 PACAP GGACATGTTTGCACTACTTGGGGGAGTTTGGAGAAGACCAGATCTATGAAGCCCACCAAC 4,48 9,4E-18 AF076205 AF076205 CCTCCAGTCTGAGGATGAGGCTGACTATTACTGTCAAACCTGGGGCACTGGCATTGGGGT 4,39 3,1E-17 ENST00000327926 ENST00000327926 TATTTGAATTGGTACCTGCAGAAGCCAGGCCAGTCTCCACAGCTCCTGATCTATGAGGTT 4,38 0,0E+00 NM_006228 PNOC GCCACTGCCATAACTTGTTTGTAAAAGAGCTGTTCTTTTTGACTGATTGTTTTAAACAAC 4,35 5,4E-14 BC073764 IGKC TCAGGGTATTAGCAGCTGGTTAGCCTGGTATCAGCAGAAACCAGAGAAAGCCCCTAAGTC 4,29 4,3E-19 ENST00000379877 ENST00000379877 GTGCAGCTGCAGGAGTCGGGCCCAGGACTGGTGAAGCCTCCGGGGACCCTGTCCCTCACC 4,27 3,1E-16 BX110985 BX110985 CTCTGTGGGGTAGAGATGAAAAGGCTCACTCAGTTCCAGCCCCTGCAGATCCCCCAGGAC 4,24 7,2E-17 BC070333 IGHV1-69 CAGGCCCCTGGACAAGGGCTTGAGTGGATGGGAAGGATCATCCCTATCCTTGGTATAGCA 4,19 0,0E+00 THC2347909 THC2347909 GGAAATGATGTTTGTCTAAAATGGCCAGAGACAACTTTTATAAGCTTCCAGGAAGTGGAG 4,16 1,4E-11 ENST00000377226 ENST00000377226 GAAAGCTCCTAAGCTCCTGATCTATGATGCCTCCAGTTTGGAAAGTGGGGTCCCATCAAG 4,15 7,0E-20 NM_000582 SPP1 TTCCACAGCCATGAATTTCACAGCCATGAAGATATGCTGGTTGTAGACCCCAAAAGTAAG 4,10 5,9E-11 ENST00000259219 ENST00000259219 TGATCTATGCTGCATCCAGTTTGCAGTCGGGGGTCCCATCTCGGTTCAGTGGCAGTGGAT 4,08 4,5E-17 ENST00000312946 ENST00000312946 GGGCAGTCTCCACAGCTCCTGATTTATAGGGTTTCCAATCATCTTTCTGGGGTCCCAGAC 4,06 7,3E-15 BC012876 BC012876 TCTGACACCTCAGCCTCCCTGGCCATCACTGGACTCCAGGCTGAAGATGAGGCTGATTAT 3,86 4,3E-18 NM_014479 ADAMDEC1 TGACTTAGTTCTGCCCTTTGGAGAACAAAAGAAAGCAGTCTTCCATCAAATCACCTTAAA 3,80 0,0E+00 NM_002460 IRF4 TTTTGTATTGATTTTCACAGCTTTGAGGAACATGCATAAGAAATGTAGCTGAAGTAGAGG 3,75 2,3E-17 NM_012390 SMR3A CACCCTATGGTCCAGGGAGAATTCAATCACACTCTCTTCCTCCTCCTTATGGCCCAGGTT 3,66 1,3E-14 AF063695 AF063695 CTGTCAGGTGTGGGATAGTACTAGTGATCATTATGTCTTCGGAACTGGGACCAAGGTCGC 3,63 1,2E-20 BC009479 TTLL3 GCTATATCCGCTTTTCCACGCAGCCCTTCTCCCTGAAGAACCTGGACAAGTGAGCCCCTC 3,63 9.1E-18 X57818 X57818 ACCCTCAGTGTCCGTGTCCCCAGGACAGACAGCCAGCATCACGTGCTCTGGACATAAATT 3,63 4,0E-21 AJ252276 AJ252276 AGATGGTGAAACAATATACGCAGAGAAGTTCCAGGGCAGAGTCACCATAACCGCGGACAC 3,62 7,1E-14 AY998685 AY998685 AATAAGAACTACTTAGTTTGGTACCAGCAAAGACCAGGACAGCCTCCTAAAATGCTCATT 3,55 4,8E-20 NM_017773 LAX1 TCGCACATGACTGTTTATAGCAGCTTCATTCATAATTACCAAAAACTAGAAATAACCCAG 3,54 8,5E-13 A_24_P384604 A_24_P384604 GGTTCAATGGCAGTGGGTCAGGCACTGATTTCACACTGAAAATCAGCCGGGTGGCTGAAG 3,53 1,8E-10 ENST00000328419 ENST00000328419 AGCCTGATGCCTGAACAGTGGAGATCCCGCAGCAGCTACAACTGCTGGGCCATGCATAAA 3,51 2,6E-13 ENST00000379884 ENST00000379884 ACACAGTCTACATGGAGCTGAGAAGCCTGAGATCTGAGGACACGGCCGTGTATTACTGTG 3,51 5,1E-14 ENST00000331195 ENST00000331195 ATACTGGTACCAGCAGCTCCCAGGAACGGCCCCCAAACTCCTCATCGAAAGGAATAATCA 3,50 5,9E-13 ENST00000360623 ENST00000360623 TCTCAGTTATTTATAGCTGTGGTAGCACATACTACGCAGACTCCGTGAAGGGCCGATTCA 3,47 5,3E-15 THC2428956 THC2428956 CATAGTTATAACCACCAACGTCACTGCTGGTTCCAGTGCAGGAGATGGTGATCGACTGTC 3,46 6,5E-11 ENST00000295410 ENST00000295410 GACAGAGTCACCATCACTTGTCGGGCGAGTCAGGGAATTAGCAATTATTTAGCCTGGTTT 3,45 6.1E-14 AJ399872 AJ399872 CAGTTTATTACTGTCAGCAGCGTCGCAATTGGCCTTCTTTCGGCGGAGGGACCCAGCTCA 3,42 1,2E-15 D83692 D83692 ACAACAGAATACGCCGCGTCTGTGAAAGGCAGATTCACCATCTCAAGAGATGATTCCAAA 3,41 2,9E-17 ENST00000361266 ENST00000361266 TGCAATCTGGGTCTGAGTTGAAGAAGCCTGGGGCCTCAGTGAAGGTCTCCTGCAAGGCTT 3,35 3.1E-16 ENST00000360329 ENST00000360329 ACATTGGGAAGGGATGGAGGATGGACGGAGGAAGGACGTGCAGTTGCAGCTCTTTCTGCA 3,35 1,0E-21 NM_018456 EAF2 CAGGATTCCTGATATAGATGCCAGTCATAATAGATTTCGAGACAACAGTGGCCTTCTGAT 3,30 2,0E-11 ENST00000379895 ENST00000379895 ATGGTATGATGGAAGTAATAAATACTATGCAGACTCCGTGAAGGGCCGATTCACCATCTC 3,27 2,0E-14 BC023973 IGLV6-57 AACTCTGCCTCCCTCACCATCTCTGGACTGAGGACTGAGGACGAGGCTGACTACTACTGT 3,27 8,0E-15 XM_372630 LOC390712 CTGTGAAGGGCAGATTCACCATCTCCACAGACAACTCAAAGAACACGCTCTACCTGCAAA 3,26 2,5E-16 AF103312 AF103312 AATGAACAGCCTGAAAACCGAGGACACGGCCATGTATTACTGTACTAGCGCGCCAAATAT 3,25 4,9E-18 NM_006875 PlM2 GGTGAGGGGACCCTACTTTGTTATCCCAAGTGCTCTTATTCTGGTGAGAAGAACCTTAAT 3,25 6,4E-16 AB063923 AB063923 CCTCAGTGAAGGTCTCCTGCAAGGCTTCTGGTTACACCTTTACCAGTCATGGTATCACCT 3,24 7,8E-12 NR_001564 XIST AATATTTCAATGCCTATTCTCTGCAAGGTACTATGTTTCGTAAATTAAATAGGTCTGGCC 3,22 1,8E-13 ENST00000328018 ENST00000328018 CAATAGCCTGGAAGCTGAAGATGCTGCAACGTATTACTGTCATCAGAGTAGTAGTTTACC 3,22 2,8E-11 ENST00000359488 ENST00000359488 TAGGAGACAGAGTCACCATCACTTGCCGGGCAAGTCAGACCATTAGCAGCTATTTAAATT 3,21 1,2E-11 BX640624 l.GHA1 TCGGTGATCAGCACTGAACACAGAACTCACCATGGAGTTTGGACTGAGCTGGGTTTTCCT 3,21 1,5E-11 ENST00000283657 ENST00000283657 GGCCACCATCAACTGCAAGTCCAGCCAGAGTGTTTTATACAGCTCCAACAATAAGAACTA 3,20 1,5E-12 AF471475 AF471475 ACATTAGTGATAGTGGTAGTACCATGTATTACGCAGACTCTGTGAAGGGCCGATTCACCA 3,19 9,1E-15 BC095489 IGKC ACATCCAGATGACCCAGTCTCCATCCTCCCTGTCTGCATCTGTAGGAGGCAGAGTCACCA 3,18 3,2E-11 XM_942451 LOC652791 GCACAAGCTACGCAGACTCCATGAAGGGCCAATTCACCATCTCCAGAGACAATGCTAAGA 3,18 9,5E-16 L04336 L04336 GTTTCCTGCAAGGCTTCTGGATACACCTTCACTAGCTATGCTATGCATTGGGTGCGCCAG 3,17 1,1E-17 M_017709 FAM46C CCTATCCACATCTTTCCAAGATAGACACTAACATGTCATGTCCCAAACATTAGCACGTGG 3,17 1,0E-21 NM_000096 CP TCACGGCCATAGCTTCCAATACAAGCACAGGGGAGTTTATAGTTCTGATGTCTTTGACAT 3,17 1,6E-11 BC034142 IGKV1-5 GATTTTACACTGAAAATCAGCAGAGTGGAGGCTGAGGATGTTGGGGTTTATTACTGCATG 3,15 2,8E-19 NM_033014 OGN AACTAATGATCACAGCTATTATACTACTTTCTCGTTATTTTGTGTGCATGCCTCATTTCC 3,12 5,9E-19 NM_012261 C20orf103 AGAAAACGACTAATGTAACTATGCAGAGTTGTTTGGACTTCTTCCTGTGCCAGGTCCAAG 3,11 6,7E-15 AF035035 LOC647460 GTCTGAAGATTTTGCAACTTATTACTGTCAACAGTATTATAGTTTCCCTCCGACGTTCGG 3,11 1,3E-13 A_24_P204574 A_24_P204574 GAGGATGAGGCTGATTATTACTGTGCAGCATGGGATGACAGCCTGAGTGGTCCCACAGTG 3,11 1,4E-19 NM_033280 SEC11L3 TTCAAGTATGCTCTTTTGGCTGTAATGGGTGCATATGTGTTACTAAAACGTGAATCCTAA 3,09 2,0E-21 NM_012081 ELL2 TGTCTTTTCAAAGTGCTGCCAGTTGAAAAGGGAAGCATTATGTTTACAAATCTGTTTTGA 3,09 6,5E-11 ENST00000379879 ENST00000379879 CTTCAAATGAACAGCCTGAGAGCCGAGGACACGGCCGTGTATTACTGTGCGAGAGACACA 3,08 2,7E-18 NR_001442 FER1L4 GAAGTCTTTCTTACCCATGTGAGCTACCCCAGAGTCTAGTGCTTCCTCTGAATAAACCTA 3,06 2,3E-08 M_001040077 IGHG1 TGAATGGCAAGGAGTACAAGTGCAAGGTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGA 3,06 5,6E-15 AF267875 AF267875 TGAGGACGAGGCTGACTACTACTGTCAGTCTTATGATAGCAGCATCGGGAATGTGATATT 3,03 5,1E-14 U21252 U21252 CCAGAGATGATTCCAAGAACACGGCGTATCTGCAAATGAACAGCCTGAAAACCGAGGACA 3,03 1,0E-08 NM_005570 LMAN1 TTGACTACCATTTTCCTGTGTACTTCATCTATTTGTGTACAAAATGATGTCGTTTTGAGG 3,03 2,7E-17 NM_001006946 SDC1 ACCCTGGGCCCTGGGCTGGAATCAGGAATATTTTCCAAAGAGTGATAGTCTTTTGCTTTT 3,02 7,4E-10 Y11328 Y11328 GTGGCACATACTATGCAGACTCCGTGAAGGGCCGATTCACCATCTCCAGAGACAATGCCA 3,02 8,6E-11 ENST00000360102 ENST00000360102 TGGGTCCGCCAGGCTCCAGGGAAGGGACTGGAGTGGGTTTCATACAGTAGTGGTAATAGT 3,01 1,4E-15 A_24_P203886 A_24_P203886 ATCTCCTGCAGGTCTAGTCGCAGCCTCCTGCATAGTAATGGAAACACCTATTTACATTGT 3,00 3,9E-18 NM_006398 UBD ATTTGGGTGGGATGGGTAGGATGAAGTATATTGCCCAACTCTATGTTTCTTTGATTCTAA 3,00 9,3E-10 ENST00000383048 ENST00000383048 AGTTTGGGCTGAGCTGCCTTTTTCTTGTGGCTATTTTAAAAGGTGTCCAGTGTGAGGTGC 2,99 5,7E-18 NM_005079 TPD52 AACTGCTTACTCAACACTACCACCTTTTCCTTATACTGTATATGATTATGGCCTACAATG 2,99 2,0E-16 X01147 X01147 TGGGCATCACCGGACTCCAGACTGGGGACGAGGCCGATTATTACTGCGGAACATGGAATA 2,98 8,9E-14 NM_000450 SELE GATGTGATAAGGATCAGAACAGCAGAGGTTCTTTTAAAGGGGCAGAAAAACTCTGGGAAA 2,97 4,2E-19 AF343666 AF343666 GGAGGAACCTCTTGGAGAAGCCAGCTATGCTTGCCAGAACTCAGCCCTTTCAGACGTCAC 2,97 4,4E-15 AK026408 AK026408 TACTGTGGTACATGGCACAGCAACTCTAAGACTCACACAGTGCTCCAGACCCATGAGGAA 2,96 1,9E-15 THC2321023 THC2321023 GGTGCCTTCCAGCCTGACCCCTCCTCTGAGCACCACCTGCCAGTGTGACAGCTCCATCTG 2,94 2,6E-10 ENST00000307840 ENST00000307840 GCAGCCTGCAGCCTGAAGATATTGCAACATATTACTGTCAACAGTATGATAATCTCCCTC 2,94 3,8E-14 AF067420 IGHA1 TCTATGATAGTAGTGGTCCCTTTGACTACTGGGGCCAGGGAACCCTGGTCACCGTCTCCT 2,94 1,4E-12 AY003763 AY003763 GCTACAAGTTTGACTACTGGGGCCAGGGAACCCTGGTCACCGTCTCCTCAGCATCCCCGA 2,93 6,3E-14 BC008026 MGC16025 GCCTCTGACCCTGATGAAATAGCTTCGGTGGCATTTGCATCAAGATCATGTTAGTGTCAT 2,92 2,4E-13 BC032451 BC032451 AGCAGCTCCTTAGCCTGGTACCAGCAGAAACCTGGCCTGGCGCCCAGGCTCCTCATCTAT 2,92 7,7E-15 ENST00000354689 ENST00000354689 CTGTGAAAGGCAGATTCACCATCTCAAGAGTTGATTCAAAAAACACGCTGTATCTGCAAA 2,92 3,2E-15 ENST00000358917 ENST00000358917 AGGGGAAGGACTGTGTCCCTGTGTGATGCTTTTGATATCTGGGGCCAAGGGACAATGGTC 2,91 4,1E-11 AB063751 AB063751 CTGGATTCATCTTCAGTAATTACACCATGAACTGGGTCCGCCAGGCTCCAGGGAAGGGGC 2,89 7,0E-21 NM_000439 PCSK1 GAGTTTAACATGTGTGGTCTTGGTATTCTTAAGGGAACTTCCACATTATACATTTGATGT 2,88 5,2E-16 BC022362 BC022362 CAGCAGAGGCCAGGCCAATCTCCAAGGCGCCTAATTTATAAGGTTTCTAACTGGGACTCT 2,87 6,8E-16 M_001040075 LOC651928 TGCTAATGCTCTGGGTCCCTGGATCCAGTGGTGATATTGTGATCGCCCAGACTCCACTCT 2,87 8,4E-20 NM_002281 KRT81 TTGAAAGACCCCTCCCACTCCTGGCCTCACATTTCTCTGTGTGATCCCCCACTTCTGGGC 2,86 5,4E-14 NP102468 NP102468 TTACCATCAGTAGCCTGGAAGCTGAAGATGCTGCAACATATTACTGTCAGCAGGGCAATA 2,86 5,0E-21 NM_001775 CD38 TGAAAAATCCTGAGGATTCATCTTGCACATCTGAGATCTGAGCCAGTCGCTGTGGTTGTT 2,85 1,9E-11 AF035034 AF035034 GCAGGGTGGAGGCTGAGGATGTTGGGGTTTATTACTGCATGCAAGGTACACACTGGCCTC 2,85 7,9E-11 BC024289 BC024289 GCCAAGAACACGCTGTATCTGCAAATGAACAGTCTGAGAGCCGAGGACACGGCTGTGTAT 2,84 5,5E-10 AF471454 AF471454 ATGCAGACTCCGTGAAGGGCCGATTCACCATCTCCAGAGACAATTCCAAGAACACGGTGT 2,83 3,9E-13 A_24_P110487 A_24_P110487 CAGGATTTTATGGTGATAGTGGTTACACAAACTACGCAGACTCTGTGAAGGGCCGATTCA 2,82 7,4E-14 Z18824 Z18824 CTCCAGGGAAGGGGCTGGAGTGGGTTTCATACATTAGTAGTAGTAGTAGTACCATATACT 2,82 1,0E-21 M_002610 PDK1 TGGACACGAAGTGATTTTTGTAACCTGAGCAGTTAATGAATGTGCCAACATTTTCTAGGA 2,82 5,1E-14 NM_002922 RGS1 GAAGTCCCATTAACTTAAAGTATATGTTTTCAAATTGCCATTGCTACTATTGCTTGTCGG 2,81 1,0E-13 AJ245002 AJ245002 TTTGACTGGTTATTATAGAAGGGGGTTTGACTACTGGGGCCAGGGAACCCTGGTCACCGT 2,80 1,7E-12 XM-496145 LOC440361 ATTAAAAGGTGTCCAGTGTGAGGTTCAGCTGGTGCAGTCTGGGGGAGGCTTGGTACATCC 2,79 1,4E-12 NM_006274 CCL19 AGTGTGAGTGTGAGCGAGAGGGTGAGTGTGGTCAGAGTAAAGCTGCTCCACCCCCAGATT 2,78 1,8E-08 NM_002416 CXCL9 TGTGACCCACTTACCTTGCATCTCACAGGTAGACAGTATATAACTAACAACCAAAGACTA 2,78 2,2E-09 AK128476 IGHA1 TGCTGAGTTGGGTTTTCCTTGCTGCTATTTTAAAAGGTGTCCAGTGTGAGGTGCAGCTGG 2,76 1,8E-14 NM_021181 SLAMF7 GGAGACCTCCCTACCAAGTGATGAAAGTGTTGAAAAACTTAATAACAAATGCTTGTTGGG 2,75 1,7E-10 AJ519285 AJ519285 CAATTCCAAGAACACGCTGTATCTGCAAGTGAACAGCCTGAGAGTCGAGGACACGGCCCT 2,75 2,3E-16 BX648200 BHLHB8 CCCGTGCCCCCACTGTAATTGTGCTGAAAATGTTTCTCAAATGACCCAAATTGGCTCTTA 2,75 3,4E-16 AK000347 LAX1 ATTTGTAATTTTGTAAACCCTGTCTCTCATATTTTGTAAAAATACCAAAATTAGCGGTGG 2,73 9,7E-17 DB362335 DB362335 CATCTTCCATTCCTTCCCAAATTATGGAAGTAAGGTTCTTCTCACCAGAATAAGAGCACT 2,72 5,3E-17 NM_001770 CD19 TACATGCCAGTGACACTTCCAGTCCCCTTTGTATTCCTTAAATAAACTCAATGAGCTCTT 2,72 4,6E-15 NM_003116 SPAG4 CGATTTCGCGGTCTTTGGCCTCCAGGTTTATGATGAAACTGAAGTTTCCTTGGGGAAATT 2,71 5,5E-16 CR621698 CR621698 ATGTTGCTCCCCTCTAGTCACTAAGATGCCACATATTTCTACTTGAGTGAACAGATTGCA 2,70 5,6E-07 BC067092 IGKC TCACTATCAGCAGCCTGCAGCCTGAAGATTTTGCAACTTACTATTGTCAACAGGCTAACA 2,69 2,3E-07 ENST00000331696 ENST00000331696 CAGCAGCCTGCAGCCTGAAGATTTTGCAGCTTATTACTGTCAACAGAGTGACAGTACCCC 2,68 2,6E-05 BC030813 BC030813 GTGGGTCTGGGACAGAGTTCACTCTCACCATCAGCAGCCTGCAGTCTGAAGATTTTGCAG 2,66 3,8E-15 NM_001783 CD79A TGATTGTAGCAGCCTCGTTAGTGTCACCCCCTCCTCCCTGATCTGTCAGGGCCACTTAGT 2,63 3,3E-18 NM_012328 DNAJB9 ATTTCTTTCTTAGTTGTTGGCACTCTTAGGTCTTAGTATGGATTTATGTGTTTGTGTGTG 2,61 3,4E-15 AF035040 AF035040 CACCCTTAACTGGGGATACGAAAAAGATGATGCTTTTGATATCTGGGGCCAAGGGACAAT 2,59 1,5E-18 NM_005080 XBP1 CCTTTTTGGCATCCTGGCTTGCCTCCAGTTTTAGGTCCTTTAGTTTGCTTCTGTAAGCAA 2,58 7,6E-16 NM_001077 UGT2B17 TTTCCTGCGACAAAACGTCTTTTCACAACTTACCCTGTTAAGTCAAAATTTATTTTCCAG 2,58 4,5E-16 NM_007029 STMN2 TATAATGGATCATGCGATATCAGGATGGGGAATGTATGACATGGTTTAAAAAGAACTCAT 2,54 3,1E-14 ENST00000327436 ENST00000327436 CTGGAGTGGATGGGGAGCATCTATCCTGGGAACTCTGATACCAGATACAGCCCATCCTTC 2,52 8,9E-17 NM_152866 MS4A1 GAGCTCACACACCATATATTAACATATACAACTGTGAACCAGCTAATCCCTCTGAGAAAA 2,48 4,1E-07 ENST00000295339 ENST00000295339 AGCAGCCTGCAGCCTGAAGATTTTGCAGTTTATTACTGTCAGCAGGATTATAACTTACCT 2,48 5,7E-15 BC031698 FLJ40330 AAACCTTCAAGCTGAGTGCAGAAAGCGCCGTCTTTTACTAGAAGACAGTAAAAGGTTGGT 2,48 4,8E-16 NM_005409 CXCL11 TAAGAAAGGCTGGTTACCATCGGAGTTTACAAAGTGCTTTCACGTTCTTACTTGTTGTAT 2,45 1,6E-09 NM_003299 HSP90B1 AAGAGATTTTCCTGAGAGAACTGATTTCAAATGCTTCTGATGCTTTAGATAAGATAAGGC 2,44 1.1E-13 M_001870 CPA3 GCCAAGTATATCCTCAAGCATACTTCCTAAAGAACTGCCCTCTGTTTGGAATAAGCCAAT 2,40 1,5E-14 ENST00000283694 ENST00000283694 GAGCTTGGGTGGATGGGACGGATCAACCCTAACAGTGGTGGCACAAACTATGCACAGAAG 2,39 9,7E-18 NM_015187 KIAA0746 CTGCTAAGGTAGTGAATAAATCAGTAATGCAATATTGTGGGTCCAAACTACTCTTTGCAC 2,39 5,5E-18 NM_021928 SPCS3 GAATGTCACTTTGACCCTGTCTTGGAACGTCGTACCAAATGCTGGAATTCTACCTCTTGT 2,38 4,8E-15 AW977527 AW977527 GATAAGACATCATTTCCTGCACTACTGGACACACTCAATGAGGTAACTGTTGTTGAACAA 2,38 1,4E-06 ENST00000310579 ENST00000310579 GCAGATTACACTCTCACCATCCGCAGCCTGCAGCCTGAAGATTTTGCAAATTATTACTGT 2,36 1,8E-08 THC2275252 THC2275252 GTCACCGACCCGCCCTTACTCACATGCCTTCCAGGTGCAATAAAGTGGCCCCAAGGAAAA 2,36 1,7E-14 NM_005065 SEL1 L CATTATTTCAGTGTGCATAAGTTCTTAATGTCAACCATCTTTAAGGTATTGTGCATCGAC 2,35 6,4E-11 BC018749 IGLV2-14 CATCACTGGTCTCCAGGCTGAGGACGAGGCTGATTATTACTGCAGCTCATATACAAGCAG 2,34 3,6E-08 AY062331 AY062331 AGCCTGAAGATTTTGCAGTTTATTACTGTCAGCAGCGTAGCGCCTGGCCTCTCACTTTCG 2,34 1,6E-16 NM_016594 FKBP11 TTCTCACTTGGCCTATGGAAAACGGGGATTTCCACCATCTGTCCCAGCGGATGCAGTGGT 2,33 1,7E-12 NM_021777 ADAM28 CTTAGAAGCTTCGAACTCAAAATCATGGAAAGGTTTTAAGATTTGAGGTTGGTTTTAGGG 2,32 6,2E-18 NM_002201 ISG20 CAGGGACTAGAGGCTTTCGGCTTTTTGGGACAGCAACTACCTTGCTTTTGGAAAATACAT 2,32 1,9E-17 DQ100868 DQ100868 GAATGATGATAAGCGCTACAGCCCATCTCTGAAGAGCAGGCTCACCATCACCAAGGACAC 2,32 2,4E-10 NM_002078 GOLGA4 GTGAAATGGAGCAAAAAGTAAAATCTTTAACCCAAGTCTATGAGTCCAAACTTGAAGATG 2,29 6,1E-13 NM_144616 JSRP1 GAGAGGCCTCGGAGAGAGGGGAAGCCGCGGAAGGAGAAGCCGCGGAAGGAGGAGAGACCT 2,28 2.1E-09 NM_001884 HAPLN1 GCTTCGTGGGTTTCCCAGATAAAAAGCATAAGCTGTATGGTGTCTACTGCTTCAGAGCAT 2,28 2,6E-12 NM_003123 SPN TCCTCACCCACCTCTTCACTCTGAATCCTCATGAGGCTTCTCAGCCCTGGATTTCCTGCT 2,28 1,7E-15 BC107852 BC107852 GAGGAAAACAACGCCCCAGCTGGGAAGCCTGAGAACACTTAGCCTTCATGAGTGTCCCCA 2,27 1,4E-15 AK074473 C20orf82 TATCATTCTGCTAAACGGCCCCAAAACAGTAGAATTTCTGCTCATGTCCTAGCAGGTTCA 2,27 6,9E-18 NM_014333 IGSF4 GAAAGAGTACTTCATCTAGATCAGCCTTTTTGTTTCAATGAGGTGTCCAACTGGCCCTAT 2,26 8,9E-17 NM_022567 NYX GAAGTCCTTTGTTTTCTACCACAATCCTCCTCCTCCTCTCCAGGGGCCTGGAAACACTAG 2,26 1,1E-14 NM_015208 ANKRD12 TCATCCCTGAAACATCAAATTCTGATATGCAAACCAAAAAGGAATATGTAGTTTCAGGTG 2,25 1,4E-17 ENST00000379969 ENST00000379969 TTTTCAGTTGTTACAGAGCTCAGCAGCTGTGGTTGCCCCTGTTCTACACCAATTTCAGTT 2,25 2,6E-17 NM_198491 FAM92B AGGGATCTACTGGATTTTAGAGCCAAGATGCAAGGAGTTTATGGGCATTATGACACTCGG 2,24 2,2E-15 THC2404289 THC2404289 AAGCTAATGCGAAATCATTTCTCTCTGATTTACCTGAGGAGGTTAACAAGGACCCATCAA 2,24 2,2E-09 NM_002345 LUM TTTTTATTTCTACTGTCAAATGATGTGCAAAACCTTTTACTGGTTGCATGGAAATCAGCC 2,24 5,0E-17 NM_030926 ITM2C ACTCTTAAATGCTTTGTATATTTTCTCAATTAGATCTCTTTTCAGAAGTGTCTATAGAAC 2,23 8,8E-18 CR620293 CR620293 CAACAAAGGAGCGTCACTTGGATTTTTGTTTTCATCCATGAATGTAGCTGCTTCTGTGTA 2,23 1,3E-15 L06610 L06610 TGAGAGGAAAGTTCTTCACCATGGACTGGACCTGGAGGGTCTTCTGCTTGCTGGCTGTAG 2,23 1,5E-15 ENST00000321715 ENST00000321715 TCCGGCTTCTTCGTCTTCAGCCGCCTGGAGGTGACCAGGGCCGAATGGGAGCAGAAAGAT 2,22 5,4E-15 NM_030776 ZBP1 ATGTTTGAGTCCCAACAAAATTCATATCAAAACATAATCCCAACTGGGTGCAGTGGCTCA 2,21 3,2E-15 NM_033285 TP531NP1 GGGAGGTTAGATGTGTGTTTCAGGCTTGGAGTGTATGAGTGGTTTTGCTTGTATTTTCCT 2,21 3,9E-15 NM_006280 SSR4 GCCTCCTCAGGAAGGCTCAGAGGAATAACGAGGACATTTCCATCATCCCGCCTCTGTTTA 2,21 2,2E-14 NM_182568 FLJ36492 CTCATAGGCATCAGAAAGAAAAGGATCTCTTTCATGAAAATTGCATGTTGCAGGAAGAAA 2,20 7,2E-14 NM_013244 MGAT4C TAGATGTTGGGGAAAACGTTATGCCTAGCAAACAAAGGAGACAATGTTCTAGTTACTTAA 2,20 4,6E-17 NM_024641 MANEA AGATTTGTGGTTACCTATACCACGCTAGGTGTTTTGACATGTTTAGTGTTTCTGCTTTAC 2,18 2,8E-15 NM_001012978 NGFRAP1L1 TCTTGAGGTTAATAATCATAAAATCCCTGCTTTCTAAATTCGCATTTTTCCTGGTGTACC 2,18 6,9E-09 ENST00000322032 ENST00000322032 GTAAACCCACCCACATCAATGTGTCTGTTGTCATGGCGGAGGCGGATGGCACCTGCTACT 2,18 3,7E-15 NM_014383 ZBTB32 AGGAGCGAAGGTTAACAGTAGGGGAGATTGTCGATCTCATCACCATAATAAAGAGTTTCC 2,18 5,1E-14 NM_013250 ZNF215 AAGTTGCAGTTCCTAAGAACCTATTGATGATGTTCAGTGCAGACTTACTGTACCTTTGGG 2,17 9,4E-13 NM_013377 PDZRN4 TCGGTAGAGTATGATTGCCTCGTTCAATGTGGCGTTTTTATATATATTTTGTGACTCTTT 2,17 1,1E-15 NM_005084 PLA2G7 AAAGCATTTAGGACTTCATAAAGATTTTGATCAGTGGGACTGCTTGATTGAAGGAGATGA 2,17 6,6E-12 THC2339566 THC2339566 CTGGATCATAGGTTTTGAGTTCATAATCCAGTAATAACAGCTTTCAGCTTTCTATGAGTA 2,17 9,0E-14 NM_032855 HSH2D GAATCCGAGCCCTTTTCCCATATCATCTGTTTGTTCTGTTGTCTAAAAGCACACTGCAAG 2,16 1,3E-13 NM_000867 HTR2B TCTACTAGATACGCTTCTCCTCACTGAAAATGAAGGTGACAAAACTGAAGAGCAAGTTAG 2,16 5,3E-15 NM_000626 CD79B CGCTGAAGGATGGTATCATCATGATCCAGACGCTGCTGATCATCCTCTTCATCATCGTGC 2,16 1,1E-11 NM_000092 COL4A4 TCCTAAAAGTTCAACCTGTTCATCTTGAACTTGGCCTGAGAACATTTTCTGGGAAGAGGT 2,16 1,6E-15 NM_024563 C5orf23 TGTTTGGATATAAATGTGTATGTGTCCTTGTAAATGTTTCTATCAAGCAAGAATGCCACG 2,16 3,2E-12 AK025047 AK025047 CCTCTCACACCCCTCCAACCTCATTTTGAGAGAACAATTCACATTTTAATTTTTGATGGC 2,15 1,7E-17 AK098753 C22orf35 TGGCTGAGATGATACCCGACCCTCTAGGGAAATTCTTAGAGTAACTTCTAGGAAATGTCA 2,13 3,6E-16 NM_022136 SAMSN1 CTCTGGTTGCTATATCTCATCAGGAAATTCAGATAATGGCAAAGAGGATCTGGAGTCTGA 2,12 1,5E-14 NM_152446 Cl4orf145 GGCCAAATATCCTACTGTGATCACTTCAGTCATATCCTGGACCGTCTTTGGTTTACTGTG 2,12 1,8E-15 THC2287925 THC2287925 GTCCCTTCTCCCTAACACTCCAGTTCAAGATAGCAACCTAAATTCTGAGTTGATTATTCT 2,12 1,5E-14 NM_003292 TPR ATGATGTTTCTCTTGCATCAACTCCAAAACGTCCAAGTACATCACAGACTGTTTCCACTC 2,12 1,6E-09 NM_004887 CXCL14 GTGGTACAACGCCTGGAACGAGAAGCGCAGGGTCTACGAAGAATAGGGTGAAAAACCTCA 2,12 7,9E-13 NM_012108 BRDG1 CCATACAATTTCATTATCTTATCAGAATGAAACCAATTCACAGGGAAACTAGAGACTACG 2,11 2,0E-14 NM_001362 DlO3 AAGTTGGGGTGTCTGCTTTGGGACCAGAGGAAGATAGCTTGAGAGGCATTGGCGAGGTTC 2,11 1,7E-06 ENST00000379913 ENST00000379913 CACAAGCCCAGCAACACCAAGGTGGACAAGAGAGTTGAGTCCAAATATGGTCCCCCATGC 2,11 2,9E-16 NM_022154 SLC39A8 GGAAAATGATTGACAAAGCCCAACAATGATCTCAGGAATTACATTTTCCAACAGACCAAA 2,11 3,7E-10 THC2380963 THC2380963 TATTGAGAGGGGCCTCGACCCCTCCTCATCCCCTCAGTGAAAACAATAAAGACAAATTTT 2,11 3,1E-11 NM_002927 RGS13 ATTAACAAACTTCTTTATCACATGTATCTTCTACATGTAAAACATTTCTGATGATTTTTT 2,10 2,2E-12 NM_001890 CSN1S1 CCTATGCTGTTTGGTACTATCCACAAATCATGCAGTATGTTCCTTTCCCACCGTTTTCCG 2,10 1,9E-17 M_018284 GBP3 GAGATGCCAAGGTGAAAGTACCCAACTTCAAAATGAGATACAAAAGCTACAGAAGACCCT 2,10 1,7E-16 NM_014398 LAMP3 ACCATGTTGACTTTCCTCATGTGTTTCCTTATGACTCAGTAAGTTGGCAAGGTCCTGACT 2,09 2,8E-16 NM_002009 FGF7 GGAGGACTTAGTTTTTCATATGTGTTTCCTTAGTGCCTAGCAGACTATCTGTTCATAATC 2,09 1,4E-12 CR594705 CR594705 ATCCACTCTCTAGAGTCCAGTGTACTTTAGACTTCATCTGAGTCCAATACATGTACCACA 2,09 5,6E-14 NM_003810 TNFSF10 GCAACAATCCATCTCTCAAGTAGTGTATCACAGTAGTAGCCTCCAGGTTTCCTTAAGGGA 2,08 4,2E-10 NM_152687 FLJ33641 CCCAAATGCCTAGAACATCACATAAGGCACTAAATGCCTCATGTTTTACTGACGGGAATT 2,07 2,2E-15 XM_926222 LOC441368 AGAGTTCTACATTTATTCCAGCATTACCAGGTGAAACTCTCACTTACCTATGGAAAATCC 2,07 5,3E-13 NM_003558 P!P5K1B TTCCTATGGACTTTTGCATTATTTCATTGTGCATGCATCCAGTGATTATACATAAGCAAC 2,06 7,3E-09 AW979273 AW979273 GGATATTTGGTATGCTGGCAATGGTAATTCAAATTGGCGTTTAAGAATAATCTTGGCCGG 2,06 7,9E-11 NM_005711 EDIL3 ACATGACTGCCTATCAGTAGATTGATCTGTATTTAATATTCGTTAATTAAATCTGCAGTT 2,06 1,2E-12 NM_000139 MS4A2 TCAATGTCATCTTCTCCATGAAGACCACTGAATGAACACCTTTTCATCCAGCCTTAATTT 2,06 4,4E-14 NM_003037 SLAMF1 AGGCGCAGAACAGAGCGTTACTTGATAACAGCGTTCCATCTTTGTGTTGTAGCAGATGAA 2,06 2,1E-16 NM_014674 EDEM1 TCCTTGCACACTTCAGTGTTTCTCTCCTGTTCAATAAAATGCCCTGTTAAGGTATAATTT 2,06 2,9E-13 NM_000587 C7 CAGATACAAACTATTTCTATCCTGAGTAGTAATCTCACACTTCATCCTATAGAGTCAACC 2,04 2,4E-10 THC2314833 THC2314833 AGGCATTGAAGGCCACGAGTTACATTTGTTGGCAAAGATGAGTATGCAAGTCAACAAGTC 2,04 6,1E-07 NM_022137 SMOC1 TATTCTCTCTCTTATTGTAAGTTTTTGGATCTGCTACTGACAACTTTTAGAGGGTTTTGG 2,04 6,8E-16 AF124170 AF124170 AAGCAGAACCAACATCGCAAGTAATACTGTGAACTGGTACCAGCACCTCCCAGGAATCGC 2,03 1,2E-09 M_018084 KIAA1212 TACTGGAACAGGAAAATGAACATCTGAATCAAACAGTGTCTTCCTTAAGGCAGCGGTCCC 2,03 2,6E-14 BC042469 LOC644846 AAATGTGAAGTCTGGCTTTGAAGAGGGTGTATAACACACATAATTTACTGTGCATCAGTC 2,03 2,7E-09 NM_006475 POSTN AGGAAGTTGCAAGCCAACAAAAAAGTTCAAGGATCTAGAAGACGATTAAGGGAAGGTCGT 2,02 6,9E-14 NM_006533 MIA CTGGCAAAGTCGATGTGAAGACAGACAAATGGGATTTCTACTGCCAGTGAGCTCAGCCTA 2,02 5,1E-1 NM_201269 ZNF644 TTGGAAAGACGAAATGGGATGCTCACAAATCTCCAATCTGGGTCTGAATGAGATGATGCA 2,01 9,2E-17 NM_001951 E2F5 GCACTTTAAGTTTATCACATTTTGTTGACTTCTGACATTCCACTTTCCTAGGTTATAGGA 2,01 4,3E-11 NM_020939 CPNE5 TGGTTCTGTGCCCGTCTCTGAGACAGTCTCTGTGTGGAATTTGCCTTAAACTGAAGTAAA 2,01 1,0E-15 NM_016570 ERGIC2 AGAAAGGGAACGTATCATTAACCATGCTGCAGGCAGCCATGGAGTCTCTGGGATATTTAT 2,00 2,9E-13 NM_181453 GCC2 AAGAACCTTCAAGAAAAGAATGGAGTATACTTACTTAGTCTCAGTCAAAGAGATACCATG 2,00 3,1E-12 NM_144590 ANKRD22 AATCCTTGTGACCACACCGATGGAGATACAGAAAAAGTTAACGACTGGATTCTATCTTCA 2,00 2,7E-13 NM_006495 EVI2B CACAAAACGTACATCAATCATTTCACTTACACCCTGGAAACCAAGCAAAAGCACACTTTT 2,00 1,7E-15 NM_005739 RASGRP1 ATTAACAGCAGGGTCACTTCTCATTTTCTTTGCTGACTTACCTTTTTACTGACCGTTGTG 1,99 1,7E-15 NM_130446 KLHL6 TTCTGGTCTCAATGGCTTCGGGAAACACACATATACACATACACCATGCCCTTGAACTCA 1,99 9,4E-12 NM_002838 PTPRC AGATGTCCTCCTTGTTCTACTCATATATATCTATCTTATATAGTTTACTATTTTACTTCT 1,98 2,8E-12 NM_017935 BANK1 GCACATTTTTGCTTTTTAAGTAGCTGGTTCATTTTCTGAATTTCTCACATTCAGAGTTCC 1,98 3,1E-14 NM_174950 KGFLP1 TGTATCAGACCTACAGGCTGCTGGCAGGATTTGTCAGATAATCAAGCCACACTAACTATA 1,98 2,4E-15 NM_000647 CCR2 ATGAAGTCATGCGTTTAATCACATTCGAGTGTTTCAGTGCTTCGCAGATGTCCTTGATGC 1,98 1,8E-13 BC042649 BC042649 CAGACCCCCTCCTTACAGAGCAAATGTCCAGGCTTCGGAGGTCACTGTCACATCCCAAGA 1,97 2,2E-11 ENST00000379900 ENST00000379900 GGGGCTGGAATGGGTGGCAGTTATATCACATGATGGAAGTAATAAATACTACGCAGACTC 1,97 5,0E-17 NM_002372 MAN2A1 ATGAATCATCCAGTCATTCCAATGGCAAATAAGTTCTCCTCACCTACCCTTGAGCTGCAA 1,96 6,3E-11 AX775927 AX775927 TATGTTTGTGGATGAAATATGAACCGAGTTTGTGGATGAAATATGAGCAGCATGAATATG 1,96 4,0E-12 NM_032932 RAB11FIP4 AGATGGCCTCTGACTCTGTGGGATTCAACTTGACTTTTTGCCCCAGGAGGCTCTGTCTG 1,96 1,1E-07 NM_00541 SEPP1 CGTAAACTATGACCTAGGGGTTTTCTGTTGGATAATTAGCAGTTTAGAATGGAGGAAGAA 1,96 2,8E-13 NM_005292 GPR18 TCAAAACAATTTCAGGCTCGAGTCATTAGTGTCATGCTATACCGTAATTACCTTCGAAGC 1,96 3,4E-06 BX161420 IGHM TGACCACCTATGACAGCGTGACCATCTCCTGGACCCGCCAGAATGGCGAAGCTGTGAAAA 1,96 4,0E-09 NM_006948 STCH TGAGTAACTTATTTTGTATCAGGAATGTTTTGGTACTGTGTTTTCACTCAAACCACTGAC 1,96 1,4E-09 AL831839 FLJ20054 ATAGAATCCCAACTTTTAAGAATGCTTTCCTTATATGCATGTACTTCCTACCGTTAATGC 1,95 3,1E-11 NM_152513 RP5-821D11.2 AGAATGAGACCTGGAGACAAAGGGCATAATTGTTGGGGAAATGGATGACAGCTGAAGCTA 1,95 8,3E-12 NM_006260 DNAJC3 AAGGACGAGAAGCCTGTTGAAGCTATTAGGGTTTGTTCTGAAGTTTTACAGATGGAACCT 1,95 1,2E-14 NM_002661 PLCG2 GAGTCAGCAACAGCAAGTTTTACTCATAGAAGCTGGGGTATGTGTGTAAGGGTATTGTGT 1,95 2,4E-10 NM_004000 CH13L2 ATGATGTGAAGAGTATGGAGACCAAGGTTCAGTTCTTAAAGAATTTAAACCTGGGAGGAG 1,95 2,1E-08 NM_003608 GPR65 AACAAGTTTAAATTGTGTTGCTGATCCAATTCTGTACTGTTTTGTAACCGAAACAGGAAG 1,94 3,2E-14 NM_002164 INDO ATCTGCAAATCGTGACTAAGTACATCCTGATTCCTGCAAGCCAGCAGCCAAAGGAGAATA 1,94 5,5E-11 NM_138738 FCRL2 GAGGAATCAGAAGGGAAGATCAACAGCAAGGATGGGGCATCATTAAGACTTGCTATAAAA 1,94 3,0E-14 M_018440 PAG1 TCTCTCACATGATGGGGTTCTTTAGTACATGGTAACAGCCATGTCATCTTACACACCTAG 1,93 1,8E-16 M_018169 Cl2orf35 CCCATCTTGAGGGAGGACCGTTCCTCAGTTAAGGACTTGTTTATTTAAATGGGACTGTAA 1,93 5,9E-13 A_23_P136961 A_23_P136961 ATATATATGTATGTATATATGTATATATTATGATGTTGGCTGACCCCCTTCCTCCCACTC 1,93 6,4E-14 ENST00000379872 ENST00000379872 TCACACTGACCTGCACCTTCTCTGGGTTCTCACTCAGCACTAGTGGAATGTGTGTGAGCT 1,93 2,2E-16 NM_022085 TXNDC5 ATACGCAAGGGGATGTGGATACTTGGCCCAAAGTAACTGGTGGTAGGAATCTTAGAAACA 1,93 4,2E-14 NM_006713 SUB1 AGGAAGAAAAGGTATTTCTTTAAATCCAGAACAATGGAGCCAGCTGACAGAACAGATTTC 1,92 5,6E-10 NM_003430 ZNF91 TGGAGAATGTGGCAAAGCCTTTAAAGAGTCCTCAGCTCTTACTAAACATAAGATAATTCA 1,92 6,7E-13 NM_138426 GLCC11 CATTGCGCTGAACAGTATTTGAGTTACCATATAATATGGCTTTACACAAGGAAATGTGTG 1,91 2,4E-13 NM_001759 CCND2 CAGCAGCGGGAGAAGCTGTCTCTGATCCGCAAGCATGCTCAGACCTTCATTGCTCTGTGT 1,91 6,9E-12 A1915259 A1915259 TAGGTGATTATATCTTTGGTACCGTATTGAGAACCCACTCTCCCTCCTTGGACCAACTCT 1,90 3,1 E-11 NM_001704 BA13 ACAGTGTGACTATCTTATGTCAGGACCTTCATGTGCCAAACGTCAGTGGTGTTTTCATAT 1,90 4,7E-11 THC2376729 THC2376729 CCCTCGGCAGGTACTTTAGAGTCACGTTCATGCTGTAATATGTGGGGAAGAAAGACTATT 1,90 1,6E-10 NM_130396 WISP3 TGCTCCAGAACATGTGGGATGGGAATATCTAACAGGGTGACCAATGAAAACAGCAACTGT 1,90 5,5E-17 NM_001146 ANGPT1 GTTTCAAACTTGGTGACTTGATCCACTATGCCTTAATGGTTTCCTCCATTTGAGAAAATA 1,90 1,4E-10 NM_002427 MMP13 TTTTTCAACGGACCCATACAGTTTGAATACAGCATCTGGAGTAACCGTATTGTTCGCGT 1,89 7,6E-14 NM_001076 UGT2B15 ATCAAAAGCCTGAAGTGGAATGACTGAAAGATGGGACTCCTCCTTTATTTCAGCATGGAG 1,89 2,6E-14 NM_005013 NUCB2 GATGAGCTTCAGAAACAAAAAGAAGAGCTACAACGTCAGCATGATCAACTGGAGGCTCAG 1,89 4,7E-13 L10374 L10374 CTGTCTTTATGTCCTGTCAGCTTCTATTAGAGGAATGATTGCTATGACCTCATGGTATAG 1,89 1,0E-14 AF086301 MGC24039 TGTTCACCCTCTCAAGGACAAGATAAAGATTGACTTCAGAGATATATCACATCAAGCTAG 1,89 6,3E-14 NM_024730 FLJ22655 GAAATGATTGAGTATGAACCACAGCTGTGTTTTCAAATATGTAGTTTGCCTTTTTGGTTG 1,89 8,2E-09 NM_001460 FM02 CCCTGAAGGATTCATCTAATTTCTCAGTTTCTTTTCTGTTGAAAATCCTGGGCCTTCTTG 1,89 1,4E-12 NM_002825 PTN AAAGGACATCAGCAAACAGGATCAGTTAACTATTGCATTTATATGTACCGTAGGCTTTGT 1,88 5,1E-10 NM_005300 GPR34 AGTAGGAGTGAAAGCACTTCAGAATTTAAACCAGGATACTCCCTGCATGATACATCTGTG 1,88 3,5E-12 NM_018460 ARHGAP15 AATGCATTGAAGCTGTTGAGAAAAGAGGTCTAGATGTTGATGGAATATATCGAGTTAGTG 1,88 2,7E-09 NM_000618 IGF1 AATGTAACTAATTGAATCATTATCTTACATTTACTGTTTAATAAGCATATTTTGAAAATG 1,88 4,9E-12 NM_002184 IL6ST ACAAAAATGAACTGAAGTTTCACATGAGCTATTTCCATTCCAGAATATCTGGGATTCTAC 1,88 7,9E-12 THC2377971 THC2377971 AAGTCACGATGTCCATCATGCTGTAGCTCAATGAATGAGTCTCACATTGTTTCATGTTGT 1,87 2,8E-11 NM_173216 ST6GAL1 ATGCAAATTATGATATGGACGTTATCATTGGTCTGGTGAGATGTTTCATATTTGTGACAG 1,87 3,3E-14 NM_004748 CCPG1 TACTTTTTGTCGCTGGAACGAACTTGATCAGTTCATCAATAAGTTTTTCCTAAACGGTGT 1,87 1,5E-10 NM_017948 NOL8 TAAGGACATCATACATTATGATCCAACGAAGCAAGACCATGCCACTTACGAAAGAAAAAG 1,87 2,8E-14 NM_014685 HERPUD1 TGCAGTGCTTTACTTTAAACTAAGGGGAACTTTGCGGAGGTGAAAACCTTTGCTGGGTTT 1,87 6,8E-13 NM_001034852 SMOC1 CTGCCCCAACGTGGAAAGGTGGGAAGGAAGCCTTCTCCCATTAGCCCCAATGAGAGAACT 1,87 2,6E-11 AK094167 AK094167 CGAGACCCACCTTCCTCTTCCTTTAGCAGCTGGGAAATTGGGGGCGTTTATGGCGCCCCG 1,86 2,8E-09 NM_024781 CCDC102B CATTGCAAAGTAGCATCTAGGTAGAAATCAGGCCAAAATTAAGCTGTGGTTTCCCTCTGA 1,86 1,8E-10 NM_148894 FAM44A TTTCTTCTTCAAAGGAGCTGAAGCATGTTCATGCAAAAAGTGAACCAAGTAAACCTGCCC 1,86 1,1E-10 THC2341371 THC2341371 TCTTCTACCTAAGACCTGAAATGTTGGCGAAGTAAATATGTTGTTCCAATTTTGGTCAAA 1,86 3,2E-16 THC2448843 THC2448843 GGGCAGGTAGGATTTCAATGGCATGTTACATAACCATCCTCTAAAGGGACAGAATGTACA 1,86 8,7E-11 NM_181780 BTLA CCTGACCTTTGTTTCAGGATGCAGGAAGGGTCTGAAGTTTATTCTAATCCATGCCTGGAA 1,86 2,5E-14 NM_015230 CENTD1 ACAGGCCCATACTTCAGTCAGTCCAATCATAGTACAGTGATGTGGTGGTAGATGCTATGA 1,86 2,3E-13 AW389914 AW389914 TGATCTCCAAGGTTCTGACCTCTGAGAGTGACGTTAAGTCCAGAGAGCCACACCACTACA 1,86 2,9E-12 NM_000959 PTGFR CCCATTCAAATTGTCCTAGGTCTATCAGAAATTAGGGAAGGTAGTCCTGCTTTATAATAG 1,85 4,8E-13 NM_006763 BTG2 TTTTAGAAGCAGCCTCATGGTCTCATGCTTAATCTTGTCTCTCTTCTCTTCTTTATGATG 1,85 3,8E-12 NM_032483 PPAPDC1B AAATTCTAATTTAGTACACTCTGAACAAAGCTTATTATACTTACTTAAGATGTGTTTTGA 1,85 9,4E-08 THC2331323 THC2331323 AGATTTTTCATTAGACCTCTTAGGTACAGGAGCCGATGCAGCAATTCCACTAACATGGAA 1,85 1,3E-07 NM_203282 ZNF539 AAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAGCCAGTCCTCAACCCTTACTACA 1,84 2,0E-14 NM_002351 SH2D1A AAGGCTAAGCTTCACTGTAAAATAATAACTGGGAATTCTGGATTGTGTATGGGTGTTGGT 1,84 7,1 E-09 NM_032870 C6orf111 GAATTACGGCATCGAATCCGGCAAAAACAGGAAGCTTTTTGGAGAAAAGAAAAAGAACAG 1,84 2,3E-11 NM_005014 OMD TTATGGTGAACAACGAAGCACTAATGGTCAAACAATACAACTAAAGACACAAGTTTTCAG 1,84 5,8E-12 NM_014739 BCLAF1 CAAAAGAGGAAGAGGTCGTGGTACTTTTCAACGTGGCAGAGGGCGCTTTAACTTCAAAAA 1,84 6,1E-12 BU685299 BU685299 GGATAAACCCCTCATGATCATAATGAATAATGATGTGTGGAGAGTGGGGAGGGTTTACAT 1,84 6,5E-07 AK024584 AK024584 GTCATCCTCTTAATGAAGCATTATGCAGCTGTTAAAGATGATAGATGTAAAGGTTATGAG 1,84 7,3E-13 S82024 STMN2 GTAAATCCCCCTGCCTATATTTATAATGGATCATGCGATATCATGCGATATCAGGATGGG 1,83 3,1E-08 NM_003412 ZIC1 AAGTGCAAACATTTCGTCCCAAAGTCTAAGTACTTTAGTGCAGTAAAATGTTGTTTCATG 1,83 1,7E-13 NM_003571 BFSP2 CTGAAAAGCTTCCTGGAAGTGGAGAGATCCTTCTGCTTTAATCTGAGTAGTCTGTAGCTT 1,83 6,7E-11 AK123333 AK123333 AGAGGAATCCACCAACAGGCACCAGCACTCTGGCAGGCCACCGACCAATGGATTGACATA 1,83 1,7E-11 NM_006639 CYSLTR1 GGCCAAACCACAAAAAGATGAGAAAAATAATACCAAGTGCTTTGAGCCCCCACAAGACAA 1,82 2,7E-12 BC020847 LOC644246 TGATAGCATTAAGCCACTGTATCAACCAATCCTGACAATTTGTATGACTTCTGGATTTCC 1,82 9,8E-14 NM_018963 BRWD1 TTCAAAGTTTAGACCTGATACTAGTTCCAAATCATCAGATTTGGGATCTGTAACTGAATC 1,82 1,4E-14 ENST00000265341 ENST00000265341 GATTTATTTCTTCTAATCAAAGATGCATAACAGCTATTATCTAGGGGACCACCAAATGTG 1,82 6,4E-09 NM_018037 RALGPS2 ATGATATTCCCATGTTGCCTCATGTCCAAAAATATCTCAACTCTGTTCAGTATATAGAAG 1,82 1,2E-15 NM_153837 GPR114 GTGGACAAACCACTCAGCCTCTGTGTGCCTCAGTTTTCCTATTTGTAAAATAGAGGCCAT 1,82 1,3E-10 NM_006933 SLC5A3 AAAGAGAGAAAGAAAGAAACGGATGATGGAGGTCGGTACTGGAAGTTCATAGACTGGTTT 1,82 3,2E-07 BE082118 BE082118 ACACTGGAGAGAAACCCTACAAATGTGAAGAATGTGGCAAAAGCTTTACCTGCTCCTCAA 1,82 5,5E-15 NM_138554 TLR4 TTACTGAGTGTTTCAGAGTGTGTTTGGTTTGAGCAGGTCTAGGGTGATTGAACATCCCTG 1,82 1,5E-13 NM_001198 PRDM1 ATGACATCAGTGTGATCTCTGTAGTGGAGAAGGAAATTCTGGCCGTGGTCAGAAAAGAGA 1,82 1,9E-13 NM_016010 C8orf70 GCATTGAAGGACATTCACCTGGAAACTTACCAAAATTCTGCCATGAGTGTGGGACTAAAT 1,82 2,0E-12 NM_004675 DIRAS3 GTAACATCCATGTTGTCAATACGTATACCTTGTAAGTGGATAACTTTTCTTTTTCCCAGG 1,82 1,9E-10 NM_022091 ASCC3 GCTGGATGGAAAAGAGGAGGATGAGAAGATGAGCAGAGCTTCTGACAGATTCAGAGGACT 1,82 1,4E-07 NM_175910 ZNF493 ATGATTCACACTGGAGAAAAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAATCGG 1,82 8,0E-10 NM_153607 LOC153222 AGTTCTCTAAAGGTTTTCTGTGTTCATACATGGTATACAGATAGCTCATAATGAAGTCCA 1,81 1,0E-12 CR593388 CR593388 ATGGAATTAAGGCCATTGCAATGTATCATCTTTGTAGCATTGTCATCACTCCTAAGCTGC 1,81 7,2E-14 NM_033181 CNR1 TGTACTAGGCCTACTGGGGATCAGAGTTCCCAAGAAAGGAAACCTTTTCTTGTATCTGGA 1,81 2,7E-12 BC025721 ELTD1 ATAGGACCAGCATGCCTAATCATTCTTGTTAATCTCTTGGCTTTTGGAGTCATCATATAC 1,81 6,8E-15 M_001003927 EVI2A GCTGAATCAGACACTTGGAAAAGAACAAAACAGCTCACAGGACCCAACCTAGTGATGCAA 1,81 1,4E-09 NM_000829 GRIA4 CATAGTCTTTGCCTACATTGGTGTCAGCGTGGTCTTATTCCTAGTTAGTAGATTTAGTCC 1,80 8,7E-08 NM_178558 ZNF680 GAGAATTCATGCTAGAGAGAAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAACCG 1,80 3,8E-14 NM_004172 SLC1A3 GTGGCTGTCCTCTTAAGACACTAGTAGAGCAAAGACTTAATCATATCAACTTAATTCTGT 1,80 1,5E-13 AK093811 FLJ36492 CAGCAGATTCCTAGGAAGGAAAATGAAGAGCATGACAGGTAAGCCTATAGCAGCGTTTAA 1,80 1,2E-14 NM_013269 CLEC2D AGCTACCTTAATTTGGCGCTTATTTTTCTTAATCATGTTTCTGACAATCATAGTGTGTGG 1,80 2,4E-16 NM_052864 TIFA TACAGAGTTATAGTGTGTTTACTCCTAAGATGACAGTTCTCTTTGTCTATATTCAGCATC 1,79 1,6E-08 NM_006633 IQGAP2 GATTGCCAAGGATATTCGAAATCAAAGAATCTATCGTAAGCTTCGAAAAGCTGAATTGGC 1,79 3,8E-12 AK097118 AK097118 TAAACGGCTTTATCAGCTAAAGTCCTTGTTCATTCACTGAGTCTTTTGTATCTTTTAGGA 1,79 1,4E-13 NM_018177 N4BP2 AAGTCTTTTGTGAGAGGTATTTAAAGTGCTTTGAGACCTGATTCATGCCCCCCAAAGGGT 1,79 1,8E-09 NM_001005473 PLCXD3 GGATCTGGTTATTGATACTTTAATAAATGTGGTGTAAAGAAAATCCATGGCTACAGTCTG 1,79 2,4E-07 NM_019604 CRTAM AAGCAGAATAGATGTTTGTTTTTCTAGTGGTTATACCAAGCTATACTTCCTGTTTTCACG 1,79 5,8E-10 NM_004310 RHOH AAAGCTTGGTGTTTTCTCTGGGTACACCCCAAGCAGCGTCTCCTTTTGGATACAGTTATT 1,79 5,5E-12 NM_032441 ZMAT1 CCAGTACCCTTGAGCCTTAATCAGCAAGAAAATAACTCTGGCTCATACAGTGTAGAATCT 1,78 2,4E-14 NM_002120 HLA-DOB CCAAATCATTTACTTTTCTGTGGTCCAGCCCTACTCCTATAAGTCATGATCTCCAAAGCT 1,78 3,2E-14 NM_178154 FUT8 CGGAACAGCTCCTTACTCTGAGGAAGTTGATTCTTATTTGATGGTGGTATTGTGACCACT 1,78 3,5E-12 NM_000186 CFH AGGTCTTCACAAGAAAGTTATGCACATGGGACTAAATTGAGTTATACTTGTGAGGGTGGT 1,78 4,2E-12 BX538342 GVIN1 TAATACTCAGTGACCACAAAAGAGCCCCAGTGTCTGAAGAAAAGAGGCAGTGTACCTGAA 1,77 6,5E-11 ENST00000285383 ENST00000285383 CGGTGCCCCTCATGGCTGGAGCAGGGGTGCACCTGCTCCTCACCTTCATCCTCTTTTTCT 1,77 1,5E-08 ENST00000371207 ENST00000371207 AAGCCACATCTTATTTTTCCAAGGTTTAATTTAGTGAGAGGGCAGCATTAGTGTGGAGTG 1,77 1,9E-06 NM_021269 ZNF708 AGATAATTCATACTGGAGAGAAACTCTACAAATGTGAAGAATGTGGCAAAGCTTTTAACC 1,77 2,3E-15 NM_024508 ZBED2 AGACCACCAGTATGAATAAAAGCTTGTTCTGTGTGACCCAGCAAGTGGAAGGACAAAGAA 1,77 1,1 E-14 AF035790 AF035790 ACCCTCTCCAGAGACAACTCCGAGAACACGCTGTTCCTTCAAATGGACAACCTGAGAGCT 1,77 2,4E-16 NM_001024457 RGPD2 TGAAGAAAAGGGAAAACTTGCTGCGGTTGCTCAAGGTCTTCAAGAAACCTCCATACCCAA 1,77 7,9E-08 NM_003064 SLPI AGGTCCTTTCCACCCTGAGACTTGGCTCCACCACTGATATCCTCCTTTGGGGAAAGGCTT 1,77 2,8E-06 NM_052941 GBP4 GAGGAAAGGGAAAACCTTCTCAGAGAGCATGAAAGGCTGCTAAAACACAAGCTGAAGGTA 1,77 2,2E-13 NM_018353 C14orf106 ACAGAATTAAACATGTGCCACAGTAATTGCCAAAATAAACCAACATTAAGGTTCCCAGAT 1,77 8,1E-13 AK094201 ZBTB38 ACCTTGAATGAGACCCTCAAAATCCATGAAAGAATCCATACTGGAGAAAAGCGTTACCAC 1,77 1,3E-08 AK000675 MARCH1 GATTATTGTGTTCTTTGCATATTCATGTAAAACTGATGTGTGAATGACATTGCAGTGAGC 1,77 1,3E-14 NM_032966 BLR1 TTTTCTTTTTAATAAAAAGGCACCTATAAAACAGGTCAATACAGTACAGGCAGCACAGAG 1,77 3,0E-15 NM_012234 RYBP AGGTTATCAACCACACATCCAGTCCTGACATGGAGCTTTTCAGTGTTTGGAGACATTTCT 1,76 7,3E-09 NM_020659 TTYH1 GGCTCTGACCCCCTGATCTCAACTCGTGGCACTAACTTGGAAAAGGGTTGATTTAAAATA 1,76 9,1E-15 NM_020739 CCPG1 TATGGTCGCACTAATGGAAGACAAATGGCAAATCTTGAAATAGAATTGGGGCAATTACCT 1,76 2,8E-11 NM_001463 FRZB AACATTTTGCCTGATTGAGAAGCACAACTGAAACCAGTAGCCGCTGGGGTGTTAATGGTA 1,76 2,0E-09 NM_025159 CXorf21 AGCAACACTTTATCCATTTATTCTGAGAATGTGCAGGAGGGGTTAGTGAAGGGGAATTAA 1,76 2,2E-09 NM_004951 EB12 CTGAAACGGCAAGTCAGTGTATCGATTTCTAGTGCTGTGAAGTCAGCCCCTGAAGAAAAT 1,76 1,8E-13 NM_198930 PYHIN1 TGCTTTCGACTGAGAAAGAGGGAAAATATGTCAAAACTGATGTCAGAAATGCATAGTTTC 1,76 1,8E-11 M_018387 STRBP CCAACATATCCTGTTCCCCACTACTCATTCTTTTAGCAAATGACAGAAGCTAATTCCTAT 1,76 2,3E-11 AL036373 AL036373 CAGTCCTTTATATCCAAAAATCTACTCATGTATTTTATCTCTAGTTTGTTTTTTCCTGGT 1,76 6,8E-11 NM_005192 CDKN3 CTTACAACCTGCCTTAAAAATTACCGAAAAACCTTAATACACTGCTATGGAGGACTTGGG 1,76 1,1E-12 NM_024660 TMEM149 ATGCATTGCGGGTGCTGTCCAAGCTTGGCTCATCTGGGGTTTGCTGGGCTTAACACCCAA 1,75 1,3E-12 NM_014923 FNDC3A ATACTTGCCATTTGAGCCTCACTGCAAAATTAGTGCAGAGGAGAAAACAATTTTTAATGT 1,75 2,6E-09 NM_006603 STAG2 AGGGAGGATTGAGGATCTTAATGAGGGAATGGATTTTGACACCATGGATATAGATTTGCC 1,75 4,9E-16 NM_025195 TRIB1 ACTAACGCTCTCGTGGTTGCTCGACTGTTGTATCTGTGATACATTATCCGACTAAGGACT 1,75 4,2E-07 THC2447689 THC2447689 TTTATGCGTTTTCACTACAATAACAAGTAGAACAGTAGAACAGATGATTAGTCACAGCAG 1,75 1,3E-13 M_017577 GRAMD1C GAATTCCAACGAAGCATACCTAGGGGTAACAGTGAACCTACCTGGGTTTGTTTTGTTTTG 1,75 8,8E-12 NM_013308 GPR171 GAACCTGTGCTTTGATCCTATCCTGTACTATCACCTCTCAAAAGCATTCCGCTCAAAGGT 1,75 7,3E-14 THC2375651 THC2375651 GGCATGCTGGGATTAAATCCTGGCTCAATTTCTCTGTAGAAGAGAAAAGAGAGGGCACAA 1,75 7,4E-15 NM_003136 SRP54 ACACAATATACCAAGTTTGCACAGATGGTAAAAAAGATGGGAGGTATCAAAGGACTTTTC 1,75 2,0E-12 NM_003151 STAT4 CCATGTCTCCAAGTGTGTATGCGGTGTTGAGAGAAAACCTGAGTCCCACAACAATTGAAA 1,74 1,8E-13 NM_004226 STK17B TACCCAATCCCCATGAACTTGTTTCAGATTTGCTCTGTTAGCACTTTTTTCTTTGACTCA 1,74 8,9E-14 AB002384 C6orf32 GGTACATTGTACAGTCTGTAGTTAGGAGGTATAGCCTATAGCTTATGTTAAATGGTTGAA 1,74 5,0E-11 NM_032888 COL27A1 ATCATCAGTGTGGACAACCTCCCTCCTGCCTCATCAGGGAAGCAGTACCGCCTGGAAGTT 1,74 1,3E-06 NM_012252 TFEC AGTTGCTTATGGCATACAAGGCTAAAATTAATTCAGCTATTTAATCTTAATAATTATTAT 1,74 2,1E-09 NM_178565 RSP02 ACACAATACCGTGTCCAACCATTGCTGAATCCAGGAGATGCAAGATGACAATGAGGCATT 1,74 1,1 E-09 NM_005630 SLCO2A1 TGTTACAGACAAGCTTATTTCCAAAGCCACCTCATTTCCAAACATCTCACTCAGGAAGGG 1,74 1,2E-12 ENST00000376752 ENST00000376752 TACAAAGTTTGGAGACTCAACAAATGCTCTAACCTTCTAGAGACAAAAGTCCTATTTCTG 1,74 1,1E-11 NM_004131 GZMB AACCATGAAACGCTACTAACTACAGGAAGCAAACTAAGCCCCCGCTGTAATGAAACACCT 1,74 5,0E-12 NM_024943 TMEM156 TGAAGAATACTCAGAAGTTTATTTTGTGAATGAGTAGACTGGAAAATGTTTGTGTCCAGC 1,74 5,8E-11 NM_014265 ADAM28 TCTACACCTAAGGACTCAAATCCAGAAGCATGAAGCAACAGCTAAGCAAGAACTAATGGT 1,73 2,6E-14 NM_004419 DUSP5 TGGGAAAAGAGTTCTTCAGATCATAGACCAAAAAAGTCATACCTTCGAGGTGGTAGCAGT 1,73 1,2E-07 NM_052942 GBP5 AGTGAGCTCCAGCACGCCCAGAGGACTGTTAATAACGATGATCCATGTGTTTTACTCTAA 1,73 2,4E-12 NM_005241 EVI1 ATGAGGAAAATGGAAGATAATCAATATTCTGAAGCTGAGCTGTCTTCTTTTAGTACTTCC 1,73 2,6E-11 AF035020 AF035020 GTTGGACCACAAACTATGCACAGAAGTTTCAGGGGAAGGTCACCATGACCAAGGACACGT 1,73 3,9E-09 NM_005442 EOMES ATTTGTAAATTCTTAAGCAAATAGAAGCCGAGTGTTAAGGTGTTTTGCTTCTGAAAGAGG 1,73 1,5E-11 NM_006760 UPK2 ATTATTCCTCTCACCCCACTCCTGTCAGAGTTGACTTTCCTCCCATTTTACCACTTTAAA 1,73 4,3E-10 NM_024306 FA2H TCGCCAAGTGTAAAGGCTAAAGAGAAGCAGTTTGACGGACCTTGTGATTTGTACTGTTTG 1,73 3,5E-12 NM_178812 MTDH CTTAATTTAAGAATATTATCCTGGTTTAACAACAGTGCCCTGTTTACAACAGATTGTGCC 1,73 1,2E-06 NM_138330 ZNF675 AGAAACCCTACAAATGTGAAGAATGCGGCAAAGCCTCTAACCAGTTCTCAAATCTTACTA 1,73 2,7E-14 THC2437906 THC2437906 CCTCTGCATTGTTTAAAGGACAACTACAAATCATGCTGGATAAGAGTACTCATTCAATCT 1,73 3,7E-11 A_32_P109645 A_32_P109645 AGACAAGATGCAAGAACACAGCCTGCAGTGATTCACAGCTTTGTTTCAACCCACAAACCA 1,73 1,7E-11 NM_002655 PLAG1 TCCATTAGGAAACGGATTGCATCATACCTGAACATAAGCTGGACTGCTGAAATTGTATTT 1,73 5,5E-11 THC2407956 THC2407956 CCCATGTAAACTAAAGCTTCTTGGTGTTCTCAACAATTTTATGAATAAAAAGGGATCCTG 1,72 1,2E-14 M_016021 UBE2J1 CAATTCATCTGGAAAGACTATCTCTGAGTCAGACTTAAACCACTCTTTTTCACTAACTGA 1,72 2,0E-11 ENST00000369577 ENST00000369577 AAACCTACCGTCAGTCTGAAAAAACTTGAAGTACATTCAAATGATCCAGATATGTCTGTT 1,72 3,8E-12 NM_173799 VSIG9 AGTTACAGAAGCCTGGGTAACTGCAGCTTCTTCACAGAGACTGGTTAGCAACCAGAGGCA 1,72 7,7E-16 NM_031915 SETDB2 GAAGCTGGGACTGTGCCTGAGAAGGAAATCTTCTGCCAATGTGGGGTTAATAAATGTAGA 1,72 3,6E-13 NM_153218 FLJ38725 TGGAAAAACAGGTTGGAAACAGATAAGTAAGGGTCTCAAATGCAATGTCAAAGAGCTTGC 1,72 9,9E-11 NM_152322 BTBD11 TGGGGACAGCCAAGTTTTGTTGATAAACCTATTTCCTAGCATGCCTTCAGGAAGTTGTGC 1,72 2,9E-08 NM_001995 ACSL1 ACTCGGTTCTCCAGGCCTGATTCCCCGACTCCATCCTTTTTCAGGGTTATTTAAAAATCT 1,72 2,7E-13 NM_002249 KCNN3 AGTGACCAAGCCAACACTCTGGTGGACCTTTCCAAGATGCAGAATGTCATGTATGACTTA 1,72 4,2E-07 ENST00000331425 ENST00000331425 AGAAACCCTACACATGTGAAGAATGTGGCAAAGCCTTTAGCCGCTCTTCAACACTTACTA 1,72 2,9E-10 NM_002731 PRKACB AAACCTGTCTGAGATGTTCTTTCTACCAATCTATATGTCTTTCGGTTATCAAGTGTTTCT 1,71 3,0E-09 NM_007214 SEC63 GTTAAGTTGACAAGGCAAACAATGGCTGAAGTATTTGAAAAGGAGCAGTCCATCTGTGCT 1,71 5,3E-10 NM_001007544 Clorf186 TGAGAACTATGGAGTCCATCAGCAGAGATAGTAGTGAAGTCTCTCCCCAGGGAAAATTTT 1,71 1,6E-13 NM_178129 P2RY8 AACACAGGTCTATTGACTCACACACATGTTTTAAGATGGAAAACTTTACTTCTGTTCTTG 1,71 1,2E-11 NM_032738 FCRLM1 GACATACCAGTCTTTAGCTGGTGCTATGGTCTGTTCTTTAGTTCTAGTTTGTATCCCCTC 1,71 1,4E-11 BC007354 MGC16075 TTTGAGCAATTGTCATTTGTTGGACTGATCGTTCAATTTCCTCTTCGGTCCTTGGCCTTT 1,71 1,1 E-12 AL832717 AL832717 CAAATGCGTTCCTATGTGTCAAAAGGCCTAAATAGCCCTGTGTACCTAAAAGATGGTAAT 1,71 2,1E-07 NM_000639 FASLG AAGCAAGAGAGATGTTTTGGGGACTCATTTCATTCCTAACACAGCATGTGTATTTCCAGT 1,71 3,6E-07 NM_025189 ZNF430 AAACCCTACAGATGTGAAGAATGTGGCAGAGCTTTTAACCGGTCCTCACACCTTACTACA 1,71 2,0E-09 NM_005143 HP GATAAGATGTGGTTTGAAGCTGATGGGTGCCAGCCCTGCATTGCTGAGTCAATCAATAAA 1,71 6,1E-11 THC2397697 THC2397697 TGGTAAGTTTCTCTCTCTTTAGAGACTCCACAATAAAGTTTTCAACATGGTAAGGTTTTC 1,71 1,2E-12 AK090431 NOD3 TTTCCTTCCAGACACGTGACACTGATATTAAAGTGCTAATGAGAGGGATCTATTTCTTCT 1,71 2,1 E-08 AK096536 LOC134466 AAGCCTTAATAGATAGTGCAACAACCAATGGATTTGATGATTTTGGGGACTACATCTTTG 1,71 4,0E-14 NM_005127 CLEC2B ATTGGAATTCAAGTAAATACAACTGTTCCACTCAACATGCCGACCTAACTATAATTGACA 1,71 5,3E-12 AB063115 NAV2 AGAGAGGATTTTATTTCTGGGAAATGGAATCGGTTTCTGAGTCCAGCCAACAGCAGAAGA 1,70 3,2E-11 CR597260 CR597260 ACACAGAAGTTTTCAGATTCTATGAAAAGGTATTGAATGAATTGAAGGCTCTGTTAAGGG 1,70 6,0E-09 NM_138286 ZNF681 AACCCTACCAATGTGAAAAATGTGGCAAAGCTTTTAACCAGTCCTCAAACCTTACTGGAC 1,70 2,9E-07 THC2310027 THC2310027 ACCAACACCCACAGGATAGTGGACGGCAAAGTGGTGTTTGAGACCAACATCACAGACGTC 1,70 2,9E-12 NM_139176 NALP7 ATCGCTCTACGAATTACACAGGAAGCGGGATTCGGGTCTCTAAGATGTCTTATGAATGCA 1,70 4,4E-11 M_001002294 FM03 TCGGGAGACTTCAGAAGCCTTGCTTCTTTTTCCATTGGCTGAAGCTCTTTGCAATTCCTA 1,70 2,3E-13 NM_170743 IL28RA GGTGAAAGCAACATGTATCCCTTTAGACTACTAACGGTATATGTTGTTCTTATGTATTTG 1,70 2,5E-10 NM_053277 CLIC6 TGCATTAACAGAAACTATCCTGGGATTAGGTGAAAAATGTCTAGCAAAAGAAACAAAGTC 1,70 3,0E-09 NM_013314 BLNK TAAGCGAGTATATAATATTCCTGTGCGATTTATTGAAGCAACAAAACAATATGCCTTGGG 1,70 5,2E-14 THC2440554 THC2440554 AGTTGTGAAATACTGAGAGCCTTTGATATTCACCATCAGGCTGAAAGAAGTTGATGTTTT 1,70 2,9E-10 AL133118 AL133118 TTTGCCTGATTATTCTCTGTTGAGCTCTACTTGTGGTCATTCAAGATTTTATGATGTTGA 1,70 1,1 E-14 THC2442210 THC2442210 GGCTCAGACCTTAAGAACTGATGGTCTTTTCTTTTACTTCTACACAAAAGTCTAAGCAGT 1,69 5,1 E-11 NM_024920 DNAJB14 TGATACTGAAAACTAAACTGAATAGTTGGTTCCTGAAATCTTGGACTGTTTATGACCTAC 1,69 1,3E-12 NM_015130 TBC1D9 TGTCACAGAGAATCTGAAAGTAGCAGCAAAGACAGAGGGCTCATGACAGGTTTTTGCTTT 1,69 8,5E-11 AK127374 AK127374 CCCTGGTTTTTAATTTTCAAAATATTTTCTTTTTGAAGAGCCAGATTCCAGTGATCCTGC 1,69 7,2E-12 NM_014399 TSPAN13 GAGAGGTTTTGAGATTTGTTGGTGGCATTGGCCTGTTCTTCAGTTTTACAGAGATCCTGG 1,69 6,7E-06 NM_017923 MARCH1 GTCACGCAAAAGATTTTCAGAAAATGTTCGGATATAATTAGCTCTGTTAAATACCCACAG 1,69 4,7E-13 NM_001042413 GLIS3 GTCCTGTGGGGTATCTCCCATTACCCATGTCGCCCTCAAATTACATAAGCGATCATAAAA 1,69 7,0E-10 NM_003878 GGH GGAGGTCAATTGCACAGCAGAATGTTCCAGAATTTTCCTACTGAGTTGTTGCTGTCATTA 1,69 1,5E-09 M_001017373 SAMD3 TTACAGCCTTGGCTGCGCTAGTAGCTGCCTTTCATGTATTTAGGATTGAGTGTCCAAGAA 1,69 2,5E-11 NM_002727 PRG1 AGGACTTGGGTCAACATGGATTAGAAGAGGATTTTATGTTATAAAAGAGGATTTTCCCAC 1,69 9,8E-12 NM_138383 LOC92154 GCCCATCGTCCCTGTGAAGACGCCCACGGTGCCTGACTCCCCCGGCTACATGGGGCCCAC 1,69 4,7E-13 NM_015914 TXNDC11 CGATGCCTCAGAAAACCTCCTTACCGAGAACACGTGGCTCAAGATCCTGGTGGCGACCAT 1,69 2,3E-13 NM_144643 FLJ30655 GAAGAAGCTAACCTTCAAAAAAGTCAGGCTCTACTTGAGGAGAAGCAAAAAGAAGAAGAC 1,69 1,4E-10 NM_030950 RFP TACCCCAGCCTGATCCTCTCTGATAATCTGCGGCAAGTGCGGTACAGTTACCTCCAACAG 1,68 8,7E-13 BC071593 KIT AAAGTGGTTGTTAGTTATAGATGTCTAGGTACTTCAGGGGCACTTCATTGAGAGTTTTGT 1,68 2,0E-12 NM_145165 CHURC1 TTATTTGTAAGTTATCATGAAAAGGTTTATATTCACTATTCTTTATTTCAGTGTAGCACT 1,68 3,5E-04 NM_003251 THRSP GATGAGTGATTCACCCTCTTACTTGGCGACCACTGATGAGATCAACAACAGGTGAACTAT 1,68 1,7E-14 NM_007107 SSR3 AATAAATGCATTTGCTTATTTGACAAACCATCAGTGTCCACTATTTGTTACCAGAGTTGG 1,68 1,3E-08 NM_004385 CSPG2 ACTTCCTGTGCCTTTCCTATCACCTCGAGAAGTAATTATCAGTTGGTTTGGATTTTTGGA 1,68 5,5E-09 BC022313 PRG1 GCATCATATTCGGAAATATCTTCCTAGGTTTATCTACCATTTAGTGTTGTTTAGTCAGAC 1,68 1,6E-06 THC2442822 THC2442822 ATGCTATTCCTGCTACACACAAAAACAAAAAGTTTGATATTTACGGAATTCCACACACTG 1,68 6,6E-09 NM_025134 CHD9 TATGTTTACAGCGACAGCCTCCATCTTCCAAGAAGAGCGATGGTTCTGGGACATATACTA 1,68 6,7E-13 NM_032852 ATG4C TTAGAATTTGTGAAGGGTATTTTAAGCCTGGAATATTGTGTGGGTATTATTGGTGGCAAA 1,68 1,6E-10 THC228791 THC2287911 GAGCTGCCATGTCTTCCGAGTCTGCAGAGGGGTCAGAAATCTGGCTGTTTGGAGAAATCT 1,68 6,3E-10 ENST00000371030 ENST00000371030 CACTTGGAGCACTAGAGGATGACGGAATGTCTTGTATATGCGGTCAACTGTTCAGGATTT 1,68 1,6E-12 NM_080546 SLC44A1 CTCCCTGTTCCATATGCTCGCAATCTCAGCTATTTGGAAGCTACCAGGAATGCTTTCTAA 1,68 3,7E-14 NM_006152 LRMP AGGTTCTCAGAATGACCGTAAGATAGCTTACATTTCCTCTTTTTGCCTTTATCTCCCCAA 1,68 1,2E-11 NM_005668 ST8SIA4 CTTTTGGTTTGGATATTGGGATGCTTAGAAATCCTTTCTGAGATGCATATGAGTGAGGAA 1,68 2,7E-11 NM_017904 TTC22 AGAACCAACCTCCCATCCTGAATCGCCTGGCAAAAATCTTCTACTTCCTGGGAAAGCAGG 1,68 5,9E-09 NM_017847 Clorf27 GAAAAACAGATGTTATCCTCAGCACAAATTCAGTAAAGAGACTACAAAAGGATGATCTTC 1,68 7,5E-10 NM_014905 GLS TTCAGTGTTACTGGAGTTTTCTTCATTGTGCACACAGGACAAATCTGATCTCTTTGGGAA 1,68 2,2E-08 AL564305 AL564305 ATGGCCTGCTGAGCCTCGTGTATCATCTCAAGGAAGGGCTGGAACATGGCGTGGAAGTTC 1,67 1,0E-11 NM_030674 SLC38A1 TTGGGGATGATTCTTACCTTGGTAATTAAATGAAGCTACACATTTGGGTAATCTAGCAAA 1,67 1,8E-13 NM_005767 P2RY5 TCTGTATTGCTGTTTCCAACTGTTGTTTTGACCCTATAGTTTACTACTTTACATCGGACA 1,67 1,8E-08 THC2302184 THC2302184 GCATCTTCTTAATTAGAGGAATTTACCAAAGTATGAGTCTATAAGTACATGCAGTAAGGC 1,67 3,8E-12 NM_014708 KNTC1 CACGGGCCAGCTAGCAGGATTTTCACATCAAATTAGAAGTCTGATTTTGAATAATATCAT 1,67 2,1E-06 ENST00000355095 ENST00000355095 TATCGTCACAACTTACTACACATAAGATAATTCATACTGGAGAGAAACCCTACAAATGTG 1,67 2,6E-14 NM_033632 FBXW7 CATGATGGAGGAAAACAACCTTTAAAGGGATTGTGTCTATGGTTTGATTCACTTAGAAAT 1,67 1,3E-10 NM_000885 ITGA4 ATTTCAAGTAGCTTGCTACTTGGACTTATTGTACTTCTGTTGATCTCATATGTTATGTGG 1,67 8,8E-04 AK054921 CDR1 AGACTATCCATGTCTTCCAGAAAATCCTTGTCTTCCCTCAAATCCATAGCTTCCGAAAAA 1,67 5,0E-12 NM_178127 ANGPTL5 TGGTCTAGCAAATCTAAATGGCATTCATCACTTCTCTGGAAAATTGCTTGCAACTGGAAT 1,66 1,1 E-09 NM_003816 ADAM9 ATTTCCGTTTCCATCATTGAATAAGTCTTATTCAGTCATCGGTGAGGTTAATGCACTAAT 1,66 2,0E-09 NM_001565 CXCL10 GTCAAGCCATAATTGTTCTTAGTTTGCAGTTACACTAAAAGGTGACCAATGATGGTCACC 1,66 7,8E-13 NM_006406 PRDX4 ATCTTCCTGTGGGTAGATCAGTGGATGAGACACTACGTTTGGTTCAAGCATTCCAGTACA 1,66 9,0E-14 M_018665 DDX43 AGACAGAAGTATTGGACATGTTGGCAGTATGAAGAGACCGGACTGATTTGACTGATTCTT 1,66 4,9E-06 NM_018318 CCDC91 TAAAGGAAGCTTTGATTCAGCAATCTCAAGAACAGAAGGAAATATTGGAAAAGTGTTTGG 1,66 4,3E-12 NM_000110 DPYD GTAAAATCCCCTTCGCTGAAATTGCTTATTTTTGGTGTTGGATAGAGGATAGGGAGAATA 1,66 4,6E-15 BC024007 CTBS GCCCCTGTAAATTGGAATACATGATGATTGAACCATCTGTTATGAGAATATTACATTTCC 1,66 2,2E-09 NM_003357 SCGB1A1 GAAGAAGCTGGTGGACACCCTCCCCCAAAAGCCCAGAGAAAGCATCATTAAGCTCATGGA 1,66 9,6E-09 NM_017520 HSMPP8 AGAACAGGAAGCTAGAGAACAAGAACGCTTTCTTAGAGAAGAAAACTGTGCCTAAAAAGC 1,66 3,1 E-14 BC027178 PRPF40A AGTGAAGGGGAATTGGAAAAGCGCAGAAGAACCCTTTTGGAGCAACTGGATGATGATCAA 1,65 6,2E-16 NM_017934 PHIP GCTGTTGTTCGAAGACACCTCTTTAACTTTTGGAACTTCTAGTAGAGGACGAGTCCGAAA 1,65 6,9E-14 NM_000600 IL6 ATTGTTGTTGTTAATGGGCATTCCTTCTTCTGGTCAGAAACCTGTCCACTGGGCACAGAA 1,65 3,3E-07 NM_018136 ASPM ATCACAAATCCCCTGCAAGCTATTCAAATGGTGATGGATACGCTTGGCATTCCTTATTAG 1,65 6,1E-10 NM_004962 GDF10 GCATTGACACCATTCCCCACAGAGATAGTCATGCTGAGTGTGGGTTGTTTAAACATGCAT 1,65 2,4E-04 NM_002113 CFHR1 TTGGATTAATTTGTGAAAATGTAATTATAAGCTGAGACCGGTGGCTCTCTTCTTAAAAGC 1,65 2,2E-08 NM_139250 CTAG1A TGATTGTTTGTCGCTGGAGGAGGACGGCTTACATGTTTGTTTCTGTAGAAAATAAAACTG 1,65 1,5E-14 ENST00000371142 ENST00000371142 ATATTATGGTGATATCCGAACCTAGTGAATGGTATGCTTGGGTGTTTTCCATTGAGAGTG 1,65 2,9E-09 M_001012651 NKTR CTTCTAGGAGTAGATCTTATTCCAGATCATATACAAGATCACGTAGTCTAGCTAGTTCAC 1,65 1,8E-13 NM_022168 IFIH1 CTACGTCCTGGTTGCTCACAGTGGTTCAGGAGTTATCGAACGTGAGACAGTTAATGATTT 1,65 3,9E-08 NM_173531 ZNF100 ACAGAATGTGGCAAAGCTTTTAACCGGTCCTCACACCTTACTACACACAGGATAATTCAT 1,65 5,2E-09 NM_004119 FLT3 CGTCTGCGTTTACTCTTGTTTTCAAAGGGACTTTTGTAAAATCAAATCATCCTGTCACAA 1,65 4,3E-14 NM_001812 CENPC1 AAGGAAGGCCATCAGGAGGATTCGTGATTAGTGGAGTACTATCTCCAGACACAATATCGT 1,65 4,4E-16 NM_013338 ALG5 GGAGCTGGCTACAAATGGGTAAAGACCTACTTTTTATACGACTTCGATATTTGACTGGTG 1,65 1,6E-05 NM_024665 TBL1XR1 AGAGATATTTAGAACATATTACCCTGTGACTTACGTAGGAAACCTAATATGCTGAGTATC 1,65 3,7E-07 NM_001085 SERPINA3 ATAGGTGAGCTCTACCTGCCAAAGTTTTCCATCTCGAGGGACTATAACCTGAACGACATA 1,65 3,5E-09 NM_001147 ANGPT2 CAGTTTACAGACGCTGCTGTCACAACCAAGAATGTTATGTGCAAGTTTATCAGTAAATAA 1,65 3,4E-12 ENST00000334564 ENST00000334564 CAAGGACCATTACTATGGAACATGATAAGATTTACACAAGCGATAATTCAGTCTCTAGTT 1,65 4,1E-11 NM_004665 VNN2 AAAGAGCCTGGGTGTTTGGGTCAGATAAATGAAGATCAAACTCCAGCTCCAGCCTCATTT 1,64 3,2E-12 NM_022841 RFXDC2 AAATCTCTGTAGGACTTTCTGGGGCTTCAGTACCATTTACACCCACGATGAAGGGCTTAA 1,64 1,2E-07 XM_934182 LOC647022 GGTAACCTAAAGAAAAACAACCAGACAAGTGCCCAACGACACTTAAAAAGGTTATTTATT 1,64 4,3E-08 M_017641 KIF21A CATCAACTTTTTCTCCTACCATACTATCCTCAGACAAAGAAACCATTGAAATTATAGACC 1,64 8,5E-12 NM_001781 CD69 TGTGCAATATGTGATGTGGCAAATCTCTATTAGGAAATATTCTGTAATCTTCAGACCTAG 1,64 4,6E-12 NM_032373 PCGF5 TGGTATATTCAACTACAGCTTTCTAAGGATAGGACTACTTTCATGTCTAGTAATACACTG 1,64 1,5E-09 THC2407068 THC2407068 TCTGAAGCTCTTTATGATGCACCGGTGCATTTTTATTTAAAAAATAGATTGTGACTCCTC 1,64 9,8E-08 NM_002162 ICAM3 CGTCTTCGTGGCGGTGTTACTGACCCTGGGCGTGGTGACTATCGTACTGGCCTTAATGTA 1,64 5,9E-13 THC2344956 THC2344956 CTTGGGACATAGTGACTTGGGAGAGTCAGTTAAAGGAAAGTTACCCATCGCCTTTTCCAT 1,64 3,1E-11 THC2364621 THC2364621 GTCTTTCCAGCTCCAGGCCAACATTGTTAATATTTGGATTTTATGAATCTTTAGCACTTG 1,64 5,2E-13 NM_024715 C5orf14 GCTAATTCCAGGACAAGAGCAGGAACATGTGGAGTAGTGATGGTCTGAAAGAAGTTGGAA 1,64 2,5E-07 ENST00000288911 ENST00000288911 TCCAGGAAAAGTGTCTTCTCAGAAACAACCAGCTGAGAAGGCTACAAGTGACGACAAAGA 1,64 4,4E-12 NM_000497 CYP11B1 ATAAAGATGGTCTACAGCTTCATATTGAGGCCCAGCATGTTCCCCCTCCTCACCTTCAGA 1,64 8,2E-10 NM 006947 SRP72 GTAAACACTTGCCATCGTCAGATAGTATGTCTCTAAAAGTAGATGTTGAGGCTCTTGAAA 1,64 2,2E-16 NM_004598 SPOCK1 CTTTTTCTCAAAGTCACTGATGTTTGTTCCTGTTAAATGTATAGCATTGTAATGAGAGCC 1,64 3,1 E-10 NM 017957 EPN3 TCCCTCAGCTTCCTCCTTGGTCAACCTTGACTCGTTGGTCAAGGCACCCCAGGTTGCAAA 1,64 1,7E-11 NM_015032 APRIN ATCTAGTGCAATTGAATCCACACAGTCCACACCACAGAAAGGACGAGGAAGACCATCAAA 1,64 2,7E-10 0 no_017554 PARP14 AAATATTAACATTTCCCTGGACCATAAGAGACCTTTGATTAAGGTTTTGGGAATTAGCAG 1,64 1,3E-13 M_018279 TMEM19 TTTGGTGGTTTAGCTGGATTACTAGGATCAATTGTGGACTCATACTTAGGGGCTACAATG 1,63 1,6E-08 M_001012506 CCDC66 TACCACTAAAAAACAGTAGCTATGAGAGAGAGAATTTGATCTCAGGAAGTAATCAAACAG 1,63 4,1E-13 NM_005755 EB13 TCTAGCTGAGAAATGGAGATGTACTACTCTCTCCTTTACCTTTACCTTTACCACAGTGCA 1,63 8,8E-14 NM_001165 BIRC3 TCCTATACATCGAAGGTGTGCATATATGTTGAATGACATTTTAGGGACATGGTGTTTTTA 1,63 7,1E-04 NM 033647 HELB AATCTCCACAAGTGTCTTCCAGACTTCAGAATTTGAGACTGAATAATTTAATTCCCAGGC 1,63 1,6E-05 ENST00000374279 ENST00000374279 AATGGTTTTGTGCAGTGAACAACACATGGCGAGGTACTAACTGAGAAACTTTTTCATGCT 1,63 8,1E-08 M_006910 RBBP6 CATCTTCCTCTCAGAAGGATGAAAAAATCACTGGAACCCCCAGAAAAGCTCACTCTAAAT 1,63 8,6E-08 THC2376215 THC2376215 TGTCAACTACTCTGAGAATGCAAAATTCTTGTTTTAAAATGTGTATCTTACAACTCCTTC 1,63 8,OE-09 NM_032229 SLITRK6 TCCATACCTTGTAAATAAGTGCCTTACGTGAGTGTGTCATCAATCAGAACCTAAGCACAG 1,63 1,6E-14 BF213738 BF213738 AAATCGAACAGGACAATGGGTAGATGGAGCTACATTTACCAAATCGTTTGGCATGACAGG 1,63 7,8E-11 NM_152527 SLC16A14 GAACTTTTTATCCAATGACTCAACTCTAATTACATCTAAGTTAGACTTGCTCACGTTCAG 1,63 4,9E-13 NM_004867 ITM2A CTAGTTGCTGTGGAGGAAATTCGTGATGTTAGTAACCTTGGCATCTTTATTTACCAACTT 1,63 6,5E-11 NM_001197 BIK TTTTCGTTTTTTCTAAAAGATGAATTCCTATGGCTCTGCAATTGTCACCGGTTAACTGTG 1,63 5,3E-12 NM_152349 KA21 GGAAAAAGTCTGTTTCTCTTCGATTTGATCTTCATTTAGCAGCCACTGATGAAGGGTGTT 1,63 1,9E-04 NM 007281 SCRG1 TTCGTGATTCCTTGCAACAATCAATGAGAATCTTCATGTATTCTGGAGAACACCATTCCT 1,63 1,8E-11 AB014594 DOCK10 TACAATAGTGCACACATTTTTCACTTTAAGGATCCAACATTGCTCTGAGGTTTTAGAAAC 1,63 2,7E-08 M_001001415 ZNF429 ATGTGGCAAAGCTTTTAACCGGTCCTCACACCTTACTAGCCATAGGAGAATTCATACTGG 1,63 2,4E-12 NM_052939 FCRL3 CAATCATGACCATTTGATCCAAGTGTGATCGAAAGCTGTTAATGTGCTCTCTGTATAAAC 1,62 1,9E-12 NM_002348 LY9 CACCACCACAACAGAATGATCTTGAGATTCCTGAAAGTCCTACCTATGAAAATTTCACCT 1,62 1,5E-11 M_016388 TRAT1 ATTTGGCTCCTATTGAAGATGGCTTCTAAGAAAACAAGATGCACAGAGGACACAGAAGGA 1,62 1,5E-08 NM 015723 PNPLA8 GTGCTACAGATACAGAAGAAGTCCATATAATGCTTGATGGCCTGTTACCTCCTGACACCT 1,62 2,3E-11 AK075484 AK075484 CTTTAAAAGGAGTGACATTTTCTAGGGAGGTAATTGTTGTGGATCTTGGGAATGAATACC 1,62 4,4E-11 NM_182556 LOC283130 CCCACGAGGCTTTGTTCTCCTGGGGTTGCTTCCTGGACCCTGAACAAGTTGTGCTCTCAT 1,62 2,2E-11 NM_004792 PPIG GTCCCTTCTCAAAAATAAAACAAAGCAGTCAGGACGATGAATTAAAGTCCTCCATGTTGA 1,62 1,5E-11 NM_181354 OXR1 CATTGAGGAAATGAAGACTGGATACTTCTGTATCTGTGAAGTTGGCACAGGTAACATTTG 1,62 5,2E-06 ENST00000377003 ENST00000377003 ATCGCAGTTAAAGCATGAAACACTTGAATTGGAAAAAGAACTCTGTAGTTTGAGATTTGC 1,62 8,0E-14 AK095791 AK095791 TAAAAGAGCAATCGCAGTTCGGTTTCACATGTATTGTTCTATAATCCAGGCAATAAATGC 1,62 6,8E-10 NM_032121 RP11-217H1.1 CATCTTTGTGTGGATGTGTATACTTTACGCATCTTTCCTTTTGAGTAGAGAAATTATGTG 1,62 1,7E-11 THC2280750 THC2280750 GAGTGTTGTGTCAATGAGAAACAAGACAGTTCATACTCCAGAACCTGTTTAAGAATTAGA 1,62 1,7E-10 BC037528 BC037528 TCACATGGACTTCATTCTGATAAAGGGTGTTTCTTCTTGTTTCACTGTCCATACCTTTGT 1,62 2,8E-11 NM_012097 ARL5A GAAGTAACTTGACCCAAAACACCTTTTATGTTTGCTTAGGGTATATTTTTTCAGTGTCTG 1,62 7,4E-10 NM_002913 RFC1 AGATGGCCTGTTGAATCTGATTCGGACTATGCCAGGCAAGAAATCCAAGTATGAAATAGC 1,62 3,7E-12 THC2350023 THC2350023 GATTTGTTCCAGTGTTGGAGCCCTTTTTAATGAAAATTCTCAACACCTACACTGGAAAAA 1,62 8,2E-13 M_017693 BIVM ATTTCATGAGTCTAGTAGTTCTTTGATTTATAGCAGGATCTTGCTTGCCTCATTTGTTTC 1,62 2,0E-13 THC2412604 THC2412604 GTGCTTGTGCATGCGAATATAAAAATTGATATTCATAGACTCGTTAACCACAGTGTTAGG 1,62 1,3E-12 NM_001010919 RP1-93H18.5 CAAATTTCATCACTGTATACTTTCAATCCGAAGGGCCAGTACTACAGCATGTTGCACAAA 1,62 1,0E-10 NM_019839 LTB4R2 CTTGCTCTGGGCCCCCTACCACGCAGTCAACCTTCTGCAGGCGGTCGCAGCGCTGGCTCC 1,61 8,6E-10 NM_003262 TLOC1 ATGGGGATTGTGAAGAGGATGAGGAAGAGGAAAATGATGGAGAAACACCTAAATCTTCAC 1,61 1,7E-07 NM_032872 SYTL1 GCAGCAGCTATGGGCTGCAGGTGCCCTGGATGGATTCCACACCTGAGGAGAAGCAGCTGT 1,61 8,7E-12 NM_001957 EDNRA GGTTGGTTTGATAAAGCAGTATTTGGGGTCATATTGTTTCCTGTGCTGGAGCAAAAGTCA 1,61 2,1E-06 NM 007139 ZNF92 ATGTGGCAAAGCTTTTAACCGGTCCTCAACCCTTACTAAACATAAAAGAATTCATACAGA 1,61 5,9E-11 NM_152332 MTAC2D1 TGATGATATGTATGCATCATTATAATATAGTATAGTTTCGCTGCCCTAAACATCCTCTGC 1,61 7,2E-04 BX119852 BX119852 AACGAGAGAGAGGTAAAGCCAACAAGCAGAACAGACCTACATTTGCAGCATCTCCAAGTT 1,61 1,3E-08 NM_014803 ZNF518 TGGATTTAGCAGACCTAGGCTTTCAAAAGATTCCATCAGAACTTTGCGGCTTTTCCCTTT 1,61 5,4E-09 AK091335 AK091335 TGTAGACTGAAGGAGTCTTTCAAAACACCCCAGCATTAAATCTCACTCTGCGCTGCTTCT 1,61 1,2E-15 NM_014445 SERP1 TCACCAATTAAGTGCAGTTTATATTCAGGTTGGATTATGCATGTTTAGGTAAACGAAAGC 1,61 3,1E-14 NM 006699 MAN1A2 AATGGAAGGGTCTTCTTCACCACTCCTTACCTTCTATGTGATGGAAAGACTAGAGCTTAT 1,61 4,0E-07 NM_005348 HSP90AA1 GAAGACTTTAGTGTCAGTCACCAAAGAAGGCCTGGAACTTCCAGAGGATGAAGAAGAGAA 1,61 1,1E-07 NM 012484 HMMR ACTATTTCTTCAGAGTTTGTCATATACTGCTTGTCATCTGCATGTCTACTCAGCATTTGA 1,61 6,5E-04 BC045756 BC045756 TGGGTGTTTTTTGGTTTTTGGTTTCTGGTTTACAATCTCGTCATTCAACAAAGATGGGAG 1,61 6,0E-11 BE272930 BE272930 AGAGGACTAGATTATGAATATGACTTCATTGATGACAGCCGTCCCCTCCTCTTCCTAAAC 1,61 2,4E-12 M_019891 ER01 LB ATGGACTGTGTTGGATGTGACAAATGCAGATTATGGGGAAAATTACAGACTCAGGGTTTA 1,61 2,5E-12 NM_003956 CH25H TTGTGGATGGTGTTGACTTCTGACTCTAAAAGCAATCAAACATGTTTCTGCTGGACAGTG 1,61 2,9E-11 NM_003469 SCG2 GATGGCATATGAAAACCTGAACGACAAGGATCAAGAATTAGGTGAGTACTTGGCCAGGAT 1,61 2,0E-09 NM_030627 CPEB4 GTATGTCAGTTAATTGTACTACTTGGCTGAATTTCCATATAGTTTTTACTGTGTATGGGG 1,61 2,4E-08 NM 033356 CASP8 AATCCAGCTATGAATATAGAGGGCTTATGATTCAGATTGTTATCTATCAACTATAAGCCC 1,61 1,4E-14 NM_002872 RAC2 CACTTACCTGTGAGAGTCTTCAAACTTTTAAACCTTGCCAGTCAGGACTTTTGCTATTGC 1,61 3,1E-14 NM_005830 MRPS31 ATATATTTCTGGAGAAACACCTGGAGAGCTTTCCAAAACAAGGACCAATTCGCCACTTCA 1,61 2,3E-09 NM_152997 C4orf7 GTCACGATAAACCTGGTCACCTGAAATTGAAATTGAGCCACTTCCTTGAAGAATCAAAAT 1,61 3,9E-09 M_017662 TRPM6 TGCCCAATTGCCAAACTAAAGACATCAGTTCATTGGTCAAATATTTGTTACCTGGAATGG 1,61 9,6E-10 AA541413 AA541413 TGTACAGAATCCTTTCCAGCTGTAAGTCATCAGCAAGTAAAAAATTTAGTATGGCAATAG 1,61 5,1E-12 NM_021237 SELK TCTGCAGGGAACTGGCCTGACTGACATGCAGTTCCATAAATGCAGATGTTTGTCTCATTA 1,61 1,7E-10 NM 016617 UFM1 TCCATACTCTTCCTATGAAGAGGGAATGCGTATGAATTAAGGCTACTACTGTCACAGAAG 1,61 8,7E-13 AF011794 CCPG1 AAGTCAGAAGAGCTCATATATATAATTCTAATGTCCCACCTATGTCCATTCCATGTACCA 1,60 1,1E-11 NM_030782 CRR9 CTGCCGCCAGCCAAGTGCAACTTGAATTGTCAATGAGTATTTTTGGAAGCATTTGGAGGA 1,60 1,6E-09 NM_005054 RGPD5 TTTGAAAAGTAACAACAGTGAAACTAGTTCAGTAGCCCAGAGTGGATCTGAAAGCAAAGT 1,60 7,2E-07 THC2269172 THC2269172 GCAGAGATCCACGAGGTATTGAGAGCAACGCGGAAAATAGTAGTGAACCCTGTAAAAATC 1,60 7,3E-08 NM 021038 MBNL1 ATCCTTTCAAACCCTCATGACTGACAAAAACTCCATGGGGCCAAATCTGCCTGAAGATCA 1,60 7,2E-14 NM_003263 TLR1 ATATTCCTCCTGTTGATATTGCTGCTTTTGGAAGTTCCAACAATGACTTTATTTTGCATC 1,60 5,8E-10 NM_005086 SSPN AATGTTTTGATTTGCTTTAAAAATGGCCTTCCTACACATTAGCTCCAGCTAAAAAGACAC 1,60 2,5E-14 NM_144778 MBNL2 ATCTTTCTGTAACACTTAAAGAATTCCCTCATTCATTACCTTACAGTGTAAACAGGAGTC 1,60 2,6E-12 NM_005863 NET1 TCTTTGAAAGGGGGGAGGAGGAGTAAAAGCCCGATTATAATGGTGATCAATTCAAGTCAG 1,60 2,9E-06 M_001039884 FLJ44894 AGAAATCCTACAAATGTGAAGAGTGTGGCAAAGCCTTTAACTGGCCCTCACAGCTTGCTA 1,60 9,8E-09 M_018293 ZNF654 CCTGATGAAAATGGTTCAGAAAGATCTGTCAATCAAGCAGTAGTGTGAAAAAAGCACTAT 1,60 7,3E-10 NM_000576 IL1B GGAATCAATTCAATTTGGACTGGTGTGCTCTCTTTAAATCAAGTCCTTTAATTAAGACTG 1,60 1,7E-09 NM_144973 MGC24039 TTCCGGCATTCTTACTAATAGTCTTTCTATTATACTATTGGATCTTTATTCATCCACCTA 1,60 5,2E-12 NM_174953 ATP2A3 CTCTGATGGACAGAATTTTTCTCTTAACTCAGCTTTTGCTACTTTGGCAAAAACTAGCGA 1,60 2,4E-06 AK021980 AK021980 CAGGCAGAATATGATCTGTGTCCAAAAGTGAACTTGAGTCAGGATTGAATCAATTTCAGC 1,60 9,4E-12 AL109696 AL109696 ATGAGGGAATTTTGGGAGAGCTACCACATCAGTACTTTGGCACGCATTAACTGTTCCACA 1,60 1,3E-04 NM_080632 UPF3B CGTTCTGATAGCGAACTTAAAGATGAAAAACCAAAGAGACCTGAAGATGAGAGCGGCAGA 1,60 1,2E-11 NM_000619 IFNG ACTTGAATGTCCAACGCAAAGCAATACATGAACTCATCCAAGTGATGGCTGAACTGTCGC 1,60 5,8E-07 NM_003429 ZNF85 TGCACACCTTACCACACATGAGGTAATTCATACTGGAGAGAAACCCTACAAATGTGAAAA 1,60 1,3E-12 NM 003414 ZNF267 TGTGATGAATGTGGTAAAGCCTTCAGCTATAGGTCATACCTCACTACACATCGGAGAAGT 1,60 9,3E-06 NM_182515 ZNF714 GTCTTCAACCCTTACAAAACATAGAAGAATTCATACTGGAGAGAAACCCTACAAATGTGA 1,59 3,7E-14 NM_002738 PRKCB1 CCTCACTTTGATGTTGTTTTGCAAGATGTTTGTGGAAATGTTCATTTGTATCTGGATCTC 1,59 9,8E-09 ENST00000381475 ENST00000381475 GCCAGATTTACCACCATTCATTCACTGAAAATATTTGCAGACAATTTTTCTGTTTGTCTG 1,59 1,8E-14 NM_015355 SUZ12 CTTGATTGGTAAGCTCTCCAAATGATGAGTTCTAGTAAACTCTGATTTTTGCCTCTGGAT 1,59 2,4E-11 NM_001050 SSTR2 AGGATTGCTCAGCATGAGTCCAATTCAGAGAACGGTGTTTGAGTCAGCTTGTCTGATTGA 1,59 4,6E-11 NM_014802 KIAA0528 GTAAGTGGTGACGCAGTGGTTTTTGTTCGTGAATCTGACTTAGAAGTGGTGTCATCTCAG 1,59 2,0E-12 NM_003121 SPIB CCTGTCCAAGGTTCCCTCTTGTCAGATCTGAGATTTCCTAGTTATGTCTGGGGCCCTCTG 1,59 1,6E-08 ENST00000373093 ENST00000373093 ACATTTTGTAACAATTTGGGTTTCATAGTAACTGTGTTACTTGCCAATCATTCTAGGCTG 1,59 2,2E-08 NM_015271 TRIM2 ACTCTTCAGCACATTCCTTTACTAAGCAGTTTAAAGCCGTCCTAGTGGAGCAAGCCCTAA 1,59 3,9E-07 NM_005502 ABCA1 CCAAAGAGCCATGTGTCATGTAATACTGAACCACTTTGATATTGAGACATTAATTTGTAC 1,59 3,6E-12 NM 000629 IFNAR1 TCCTGTTTAGGGAAAGAAAAAACATCTTCAGATCATAGGTCCTAAAAATACGGGCAAGCT 1,59 2,0E-11 NM_014584 ER01L ATTGTGTTGGTTGTTTTAAATGTCGTCTGTGGGGAAAGCTTCAGACTCAGGGTTTGGGCA 1,59 1,8E-11 NM_052954 CYYR1 TTGTATTAAGTGTCATAATAGCATCAATGTGCACATTACCAGTATAGACTGTTGGAGTTC 1,59 3,4E-12 NM_032941 RECQL GTGACAAAGTCCACGCAGAACTCTTTCAGGGCTGAATCGTCTCAAACTTGTCATTCTGAA 1,59 5,2E-07 NM_032413 C15orf48 AGTGTGCGGAAATGCTTCTGCTACATTTTTAGGGTTTGTCTACATTTTTTGGGCTCTGGA 1,59 2,8E-14 NM 006068 TLR6 CAGAGTGAGTGGTGCCATTACGAACTCTATTTTGCCCATCACAATCTCTTTCATGAAGGA 1,59 3,0E-12 NM_012092 ICOS AAGCTGTGCCTCGACACATCCTCATCCCAAGCATGGGACACCTCAAGATGAATAATAATT 1,59 3,5E-12 M_016649 C20orf6 CCAGAAAAGGATCGAAAAGTCAAAATTGACAAGAGATTTCGAGCCATGTTTCATGACAAG 1,59 3,4E-12 NM 004315 ASAH1 ATGAACTCGATGCTAAGCAGGGTAGATGGTATGTGGTACAAACAAATTATGACCGTTGGA 1,59 4,8E-07 THC2432288 THC2432288 GGAAAAAACCAGCCTTGAAGTGTCTTCTCAGAAACAACCAGCATTGAAGGCTATCTGTGA 1,59 1,9E-09 M_001009568 SMPDL3B AGGTGTCCCCATAAGCGCCATGTTCATCACACCTGGAGTCACCCCATGGAAAACCACATT 1,59 8,7E-06 NM_004719 SFRS21P ATCTGAAAGCAAAGTGTACCAACCTGTATCTTGTCCCCTAAGTGACTTATCTGAGAATGT 1,59 1,3E-13 ENST00000367001 ENST00000367001 TTTGATGTAGCTCTACCGATACTATGTGGTAATGCTATTTTGTTTTACTAACAAGCTCTG 1,59 2,9E-09 NM_005263 GF11 CTGTGGACAAGATGTCATTCATTCACTCAGCAAATGTTCATGGATCACCGGCTACCAAGT 1,59 9,2E-09 A_24_P417757 A_24_P417757 GAGCAGAGACATCCAGGAGAGGAATGGGTGAAATACAGTGATGATGAGGAATCTGATTCT 1,58 4,9E-13 M_016040 TMED5 GCTCTGATATGCATTTGGATGATTAATGTTATGCTGTTCTTTCATGTGAATGTCAAGACA 1,58 2,2E-07 NM_001242 TNFRSF7 AGCCACAACTGCAGTCCCATCCTCTTGTCAGGGCCCTTTCCTGTGTACACGTGACAGAGT 1,58 5,2E-10 NM_181783 TMTC3 GCAAAGGAATTAAAGGCTTTGCCAATTTTGGAGGAGTTACTCAGATACTACCCTGATCAT 1,58 1,4E-09 M_019600 KIAA 1370 CTTTTTGTACTGTTGAAACCACTTCATTGGACATGTTGCAATAGCAAAACCCCCAGTTAG 1,58 7,4E-10 NM 006267 RANBP2 CAACTTCAGAAGTTGAAGTGTCTAGCACATCTGAAACAACACCAAAAGCAGTGGTTTCTC 1,58 3,5E-08 NM_139211 HOP GGAACACATTTCCTTCTGAACTTACTTCCCTAAGTCACTTTCCTTATGTATCATCTAATA 1,58 3,0E-07 M_018151 RIF1 GGTTTGCTTAATCAAACAGAATGTGTGTCAGATAATCAGGTTCATCTTTCTGAATCTACA 1,58 1,5E-12 NM_052946 NOSTRIN ATGGTGGTTTGGATCTTTGAATGGGAAAAAAGGCCATTTTCCTGCCGCTTATGTGGAGGA 1,58 6,5E-11 NM_152835 PDIK1 L TGGTGCTAAGGGATACTTTGTCATTATGATGAAGTAAGTGTTAAGTGTCAGATAAATAGC 1,58 1,2E-06 NM 021023 CFHR3 TCAGGAAGTTACTGGGATTACATTCATTGCACACAAAATGGGTGGTCACCAGCAGTACCA 1,58 1,3E-12 NM_003142 SSB TTTGTTTGCGGGGCTTTTAAAAGGAAAACCGAATTAGGTCCACTTCAATGTCCACCTGTG 1,58 2,0E-09 NM_024689 CXorf36 CAGCACTGAGAACTTCCAGAAAGTGTTAGCCTTCTCCCAACTGTGTTATACCAACCACAT 1,58 2,9E-12 AK027214 CNOT6L GAGGTATATGCACTAACAAAACATTTTCCTCCTTTCATATACGCATGTTACTTAGCTATG 1,58 9,9E-11 NM_001323 CST6 TCAGCTCCTAAAGCACAACTGTGTGCAGATGTGATAAGTCCCCGAGGGCGAAGGCCATTG 1,58 2,2E-07 AK098043 AK098043 AGGGTATCTAGTTAGAGTTATATATATAGTTAGATACATTTGTTTCTGTTGATATTCAGT 1,58 8,6E-06 NM_006144 GZMA GAATGAATATGGTTTGTGCTGGAAGCCTCCGAGGTGGAAAAAACTCGTGCAATGGAGATT 1,58 2,6E-10 NM_005771 DHRS9 ACTCATTTAGATCGTGCTTATTTGGATTGCAAAAGGGAGTCCCACCATCGCTGGTGGTAT 1,58 8,5E-12 M_018297 NGLY1 AAGTAGTCTGTTGGTTCAGTGCATGCTTAGTTGGCAGTTACCACCCTGTGCTAGCATATT 1,58 1,5E-07 NM 015687 FILIP1 GGAAAAGGCTGAATTAAGCCTAAAAGATGATCTTACCAAGTTGAAGTCATTTACCGTGAT 1,58 5,3E-11 ENST00000358356 ENST00000358356 ATATTTAGCATGGATCCCGGTACACTTTCAATACTTAATAAATGGTCAATGTTATTCTTT 1,58 5,3E-08 NM_014234 HSD17B8 AGCTTGGACGACATGGGATCCGCTGTAACTCTGTCCTCCCAGGGTTCATTGCAACACCCA 1,58 7,0E-09 NM_007237 SP140 ACGGAAAGTGATCAAGCGTGTGGCACAATGGATACTGTGGATATTGCAAACAACTCCACT 1,58 4,3E-14 AK025669 AK025669 ACAACTACCTGTAGCTGGGGAGAACATCTTCACATGCCCCATAAACTCCATTTTGGCAAA 1,58 4,3E-12 NM_170736 KCNJ15 GCTGTTTCCACATCAGAACTCCCTTCAAACACAAAGATTGCTGTGAAAACGAAAATGTGT 1,57 2,5E-10 THC2314600 THC2314600 AGAAAGTAAGTTTCCAGAGCAAATCTGACCTAGCATTTGGTATGCTAGGCTCTGCTTTTC 1,57 4,0E-06 NM_004460 FAP TTTCTGGTACTCTGTGAAAGAAGAGAAAAGGGAGTCATGCATTTTGCTTTGGACACAGTG 1,57 2,2E-11 AK126324 SMCHD1 ACAAGTACCTGGGCATGAATTTCCATTTCGATTCAGATGGGACTGGAAACAACCATTCAA 1,57 1,7E-08 A_32_P67223 A_32_P67223 TCCAAGTCAGAAAAACTATTCATATAGGGATGGGCTATTAGCAAGAGTATATGAATAACG 1,57 1,2E-07 AK131420 ZNF66 AAACCCTATAAATGTATAGAATGTGGCAAAGCCTTCAACCGGTCCTCACACCTTACTACA 1,57 2,2E-08 BC030100 BC030100 AGCACAAAATTCAACTCCAACCTGCAGTTAGGATCCCAAAGAGATGTTGACATTTATAGC 1,57 5,2E-05 NM_014159 SETD2 TGGAACTGGGGTTGTGTATGATCGAACTCAAGGACAAGTACCAGATTCCCTAACAGATGA 1,57 5,5E-10 NM_005531 IF116 GACCAGGAAAAACAAGAAAGACATACTCAATCCTGATTCAAGTATGGAAACTTCACCAGA 1,57 1,1E-10 NM 001031716 OBFC2A ACATGTCATAAGTGGTACCCACTTCCCCTTTTTACTGTAGGGTGGATAACTCTTAGGATT 1,57 1,7E-11 NM_004180 TANK AGTTTTCCCACCATCCATTACATCCAGGGGGGATTTCCTTCGGCATCTTAATTCACACTT 1,57 5,3E-07 NM_033402 LRRCC1 TGGAGGCTCAAATTGAGAGTTTATCTAGAGAGAATGAATGTCTGCGAAAGACAAATGAAA 1,57 1,1E-11 AK096677 AK096677 ACTGCTCCCTTGTCTGATACCTGTATTTCTCCAAATGATAAAAAACTTCGTCGCTTAACC 1,57 2,2E-08 NM_153350 FBXL16 ATGCGGAAGATATAACCTTATATTTGGTAAGTGTTTCTTGTGCTATTTTATCACGTGACC 1,57 2,6E-09 NM_177457 LYNX1 ACGGAGACAACTGCTTCAACCCCATGCGCTGCCCGGCTATGGTTGCCTACTGCATGACCA 1,57 2,1E-11 NM 024561 NARG1 L CCAATTCGACTTCCATACATACTGCATGAGAAAGATGACCCTTCGTGCCTATGTTGACCT 1,57 7,0E-13 NM_030764 FCRL2 CATGACAGCTGGAGTTCTCTGGGGACTGTTTGGTGTCCTTGGTTTCACTGGTGTTGCTTT 1,57 5,5E-05 NM_006256 PKN2 AAGACCTCTTAAAAATAGCAACCCTTCATTTGCTCTCTGTGCCACCAATAGCTTCTGAGT 1,57 3,7E-12 NM 032383 HPS3 ACATCAGTTCACTGTTGTTGGAGACATGACAATCATTTTCATCCCAAGAACACTTTAAGG 1,57 2,4E-09 NM_014607 UBXD2 AGTGGACATACGGAAAGACTGTGACTTTATTTTGTAATGGGAGGAAGAAATTTTCTCAGA 1,57 2,5E-13 BC033025 PPAPDC1B AGATGACTGTTTCTACCTCATTTGACCATAACTGTACTTGTGAGCTTCTTTCCTTCCATT 1,57 1,2E-09 NM_002064 GLRX CTGATAAAACTTACAGCCCCCTACACCAAGAGTGTATCTGTGAAAGAGCTCCTACACTTT 1,57 1,3E-08 NM_014373 GPR160 AGGCACAGAATGCTTATTCTCGTCACTGTCCTTTCTATGTCAGCATTCAGAGTTACTGGC 1,57 3,2E-06 NM 020841 OSBPL8 TTATGGCTCTTCGAAATCATTTAGTTTCAAGCACACCGGCCACGGATTATTTTCTGCAAC 1,57 1,1E-14 NM_020240 CDC42SE2 GGTGCCAGTAAGCGTAGAGCGGAAATGTTGACTTTAGTTAACATTGGGTTTAGCATTTCC 1,57 3,2E-04 NM_003005 SELP AAATACCTCTTTATTTTTTGATTGAAGGAAGGTTTTCTCCACTTTGTTGGAAAGCAGGTG 1,56 1,6E-09 NM_006425 SLU7 CTATGACAAGGGATCTGAAGTGCATCTACAGGCAGATCCTACAAAGCTAGAGCTGTTGTA 1,56 4,9E-10 NM 002262 KLRD1 ATACAAAGAACTGCATAGCGTATAATCCAAATGGAAATGCTTTAGATGAATCCTGTGAAG 1,56 1,7E-13 NM_012224 NEK1 AAGATGGAGTCTCGAGTACTGTGGACCAACTTAGTGACATTCATATAGAGCCTGGAACCA 1,56 4,1E-08 AK123473 ZNF292 GGTGTGGAAAAACCCGGTACTGTGCACTATTCTTTCCCAGGAACCATTGGATAAGGATAA 1,56 1,3E-10 0 no_000043 FAS ATGTCTATCCACAGGCTAACCCCACTCTATGAATCAATAGAAGAAGCTATGACCTTTTGC 1,56 3,3E-10 ENST00000233161 ENST00000233161 TGTTGTTGTTTTAGATGGGCTCATTACATAACGAGTTAATTGTCACTAGTAGGAGACTGT 1,56 2,0E-11 NM 014350 TNFAIP8 TGGCCAGCTATGTCCTCTAGGAAATGACAGACCCAACCACCAGCAATAAACATTTCCATT 1,56 2,7E-09 CR936613 KIAA1109 GTAACTTCTGAACCTCAGCATGTTACTCTAATAGTGTTTGGGATTGGCATGGTGAACCGC 1,56 2,1E-09 M_001012452 FLJ32679 AGAGAGATGCCATCAGAAAGTTTATCACCCTATAACAAAGCCAGGGGGCAGTGCCAAAGA 1,56 3,8E-15 AK022936 AK022936 GGTTGGAGTGAAGGTCTTATCTGCATTAATTTTGTTAATGCACATTGTAGATGTGGAGAA 1,56 1,8E-10 M13995 BCL2 ATCAGAGTTGTTGCTTCCCGGCGTCCCTACCTCCTCCTCTGGACAAAGCGTTCACTCCCA 1,56 1,2E-04 NM_013347 RPA4 AGAGAGAGACGGTGATGGATAAATTGACAACTCTGTAGGATTTACTAGCAAGCTAATGGA 1,56 4,1E-11 NM 007043 KRR1 GAGTTGGCAAAAGATTCTGAATTACGATCACAAAGTTGGGAGAGATTTTTGCCACAGTTC 1,56 4,1E-13 NM 014028 OSTM1 ACTGAAAATGTGCTGGGGTTTGTTCTGCTGTCACTGTTTATGCTGCTGGAACTTAGCACT 1,56 2,5E-10 NM_181659 NCOA3 GTCAGTCTGTCTCTTTTTCAGCTCAATTGTATCTGACCCTTCTTTAAGTTATGTGTGTGG 1,56 1,4E-07 ENST00000369697 ENST00000369697 ACTAGAGCAAAATTATGAGTGTCTAAGTATCTTAGTTATGCTTCATAAGATCTGACTGGG 1,56 1,8E-12 AK021804 AK021804 GGTATTGGAAGACTAGTGACTGTATTTAGTACCGGCTTTATATTTTACGATGTTCTTTCT 1,56 2,4E-09 NM_178862 STT3B GAATTGCCTTATGTATAAAATGTCATACTACAGATTTGGAGAAATGCAGCTGGATTTTCG 1,56 2,1E-09 NM_001778 CD48 CATCATGAGGGTGTTGAAAAAGACTGGGAATGAGCAAGAATGGAAGATCAAGCTGCAAGT 1,56 3,6E-09 NM_138290 RPIB9 TGAAATTTTATATTGTTCTGGTACATGTCTGAAATTCTATTGCTTGGAGAGAATCCCCTC 1,56 5,8E-10 NM_014716 CENTB1 GTTCACTTCTCCAAAGTCCGGTCTCTGACCCTTGACTCATGGGAGCCAGAACTAGTGAAG 1,56 1,6E-12 NM_024624 SMC6 TCCTTTCAGATGCCTGGATGAATTTGATGTCTACATGGATATGGTTAATAGGAGAATTGC 1,56 3,6E-09 NM_005126 NR1 D2 CTGCTTCTAAAGTTGCCAGATCTTCGATCTTTAAACAACATGCACTCTGAGGAGCTCTTG 1,56 4,1E-12 M_001004419 CLEC2D TTTCATGGTGCTAATATTACCTGTTCTCCCACTGCTAATGACATACCCGAGACTGAGTAA 1,56 1,3E-07 NM_000640 IL13RA2 ATACATGAAGACTTTCCATATCAAGAGACATGGTATTGACTCAACAGTTTCCAGTCATGG 1,56 4,5E-13 NM_012120 CD2AP CCAACCTTAGGTAAAACAAAAATATTGTAATCCTAGAAATTATCCTCCAGCTTTCTCACC 1,56 1,4E-11 NM_001673 ASNS GGACTGTGGGTAGATAGGGGAACAATGAGAGTCAACTCAGGCTAACTTGGGTTTGAAAAA 1,55 4,4E-11 BC067244 BC067244 CTTCCAAATCACTGGTTTGGGAGGGGGTGGATACATCCTCATTTTCTGTACATGATGCAT 1,55 5,6E-11 NM 004972 JAK2 GGATAACATGGCTGGATGAAAGAAATGACCTTCATTCTGAGACCAAAGTAGATTTACAGA 1,55 4,4E-10 NM_006846 SPINK5 ACATTTCCACCAAGTTTGAGCCCTCAAAATGTCCTGATTACAATGCTGTCTGTCCAACTG 1,55 1,8E-12 NM_003144 SSR1 TCCACACACTAAGCAGAAAACCAAGTTATCAGGACAGAGATATTTCCCAGTTACTCCTAA 1,55 4,8E-09 NM_000499 CYP1A1 GGTAAAACAGGGCCACATAGATGCTGATGGAGCCTTCCCAAGTTGTGCTTGAGCCAGGAG 1,55 2,5E-10 NM 003441 ZNF141 TAAAGAAGTGTGCAAAGCCTTCAATAGGTTCTCAACCCTTACTGTGCACAAGATAATTCA 1,55 1,0E-10 NM_175725 IL5RA AAACACTACAGAAGACAATTATTCACGTTTAAGGTCATACCAAGTTTCCCTTCACTGCAC 1,55 1,2E-10 NM_005625 SDCBP ACTGTCGCCTTAACTATGTTAAGCATCTAGACTAAAAGCCAAAATATAATTATTGCTGCC 1,55 3,1E-04 S71486 S71486 AAGTTGTATACAGTCTGCTCTTTCCTGGTTCTAAGAGAAGAGAGAGCTAAAGAAGAGGCC 1,55 9,2E-10 BX393727 BX393727 ATCAACATCCTCACAGACAATGAAAGCACACCGGAAGGACATGACCACAAGACAGATAAA 1,55 1,7E-07 THC2281706 THC2281706 CTGATGGTTCTCTTCCAAACAATGATCTAGAAAGATGCCCCGTGTCAAGTTGCTTGCCTT 1,55 3,0E-06 NM_021629 GNB4 CAATGTGACAGTGTTACATTTGGAGAGAAGTGTGAAATCTAACCAATCGCTAGCACATAT 1,55 1,5E-08 NM_002558 P2RX1 ACAACCCAGTGTACACACCACCTACGTGCACACAGCATCCTTCCACACTGTGTATGTGAA 1,55 7,3E-11 AB040942 KIAA1509 TACTGAGAAAGAAATGGGAGACTTTTGAATGTTAACAAGATCCATTTTAGGAGTGTTTGG 1,55 8,3E-12 AK094893 LOC645431 CGTATTTATTGTCAGCTCTTTAAACAAAAAGCACTCTATGAAGTGCTGTACTTTACAGTC 1,55 7,1E-11 NM_032505 KBTBD8 AAGTAAAAGGCACAATGGGTACTACAGAATTAAAATGTAGGTCTAACATAATGCCAGTTC 1,55 6,9E-07 ENST00000336749 ENST00000336749 TGTAAGTTCTGAATGGTTCCTTGCTGACTTTGGGTGACACATGTACCACATACTGGCTCA 1,55 4,2E-13 NM_032205 PHF20L1 AACCCATCCACTCTGGGCAGGTGACTGGAATAGCTGATTAAAACATAAATGCTGCTTTTA 1,55 3,0E-12 NM_182926 KTN1 ATGTTTTCACCCTTTCTACTTTGTCAGAAACACTGAACAGAGTTTTGTCTTTTCTAATCC 1,55 6,4E-09 M_016648 LARP7 TGGAGTTACTTCCCAAAAATGTTAATCACAGCTGGATTGAAAGAGTATTTGGGAAATGTG 1,55 1,2E-08 NM_005025 SERPIN11 AAGAGAGCCAATATGTGATGAAAATTGCCAATTCCTTGTTTGTGCAAAATGGATTTCATG 1,54 1,3E-05 BX112397 BX112397 TCTTAACCTAACCCTTAGTCATAAACTAGAACTCTGACCCTTTTCTAGTGAAGAGCTTTT 1,54 1,2E-12 NM_014673 KIAA0103 ACCCAGTCTTAAGGTTTCAAAAACTCTTTGACATTAGATTTCACAACTGCACAATTGAAC 1,54 5,2E-09 NM_080423 PTPN2 TGGGTCTTATCTCAGACCCCAGATCAACTGAGATTCTCATACATGGCTATAACAGAAGGA 1,54 7,1E-12 ENST00000381298 ENST00000381298 ATTGACCAAGTACATCAAGCAGGAGAGCTCTTCCTTCATTCTGTTATAGTCCACATCATT 1,54 1,2E-09 NM 006164 NFE2L2 CAGTAGTTTCACTTTAACTGTAAACAATTTCTTAGGACACCATTTGGGCTAGTTTCTGTG 1,54 6,4E-10 BC043564 KCNA2 CTACATTGCACAGGATGTATTGATATTATCATTCTTGCTGACATATTCTGGAAGCTTTCA 1,54 5,9E-10 NM_015633 FGFR10P2 CCACCAGATACAGAAATGTGCTTTAACATCAGTTGAAACCTAAATTTTCTTATGTTGTGG 1,54 8,5E-10 NM_174912 AMDD CCAGCAGACAAGCAGAGAAACAACTGGGGAATTTATTGACTCATTTAGTTATTCTTTCTA 1,54 4,7E-12 NM_145243 OMA1 GTGTAATTGTCCACCACTGTCTAATCCAGACCCTCGATTACTATTCAAACTCAGCACGAA 1,54 5,5E-07 BC002521 ATRX AAATCCAAGTCTTCAGGATCGTCACGATCAAAGAGGAAACCTTCAATTGTAAACAAAAAT 1,54 8,3E-07 M_018221 MOBK1B TTCAGAGCTGTGATTTTTGCAAAGTATTTTACCAACCTCCTCGATGGCTTTGATAAAGGT 1,54 2,5E-10 NM_145258 LRRC44 TCAGGAGTATTTGCTTGGGGTCATAGTTAAAGCCTAGTTCTCTCAGGTAAATACAGGGAT 1,54 1,3E-12 M_016824 ADD3 GGTGAGTTGGCATGCAAAAAATTACATTGATTACAGTGTGTTTTGGAGCTGGCTCTGTTT 1,54 2,0E-10 NM_018976 SLC38A2 ACAAAACCACGAGTCTCGGGTTAAGGGAAGTGACAATTTTATTCCATTCCAGAGAATGGA 1,54 5,0E-04 NM_030641 APOL6 GTCTGTGGTGAGCAAAGTTTGCCTTATTACACTGATAAAGTGTAATTACACTAATAAAGC 1,54 9,6E-12 M_001008388 ZCD2 ATTTGTGTCTTACTAAAGCAGCTTATTGTAGGTGTTGGCGTTCTAAAACGTTTCCTGCCT 1,54 1,5E-04 NM_000958 PTGER4 CCCAAACGTGGTTACATTAGCCATTCATGTATGTCAGAAGTGCAGAATTGGGGCACTTAA 1,54 6,2E-08 NM_014294 TRAM1 GTTCTTTTCAGTGTTCACATCTTGTTCCCCATTTCTCACTTGTGTCACCAGCTGTTTGTG 1,54 1,2E-11 NR_002819 MALAT1 TATTCATATTTACACGAGAACCTAATATAACTGCCTTGTCTTTTTCAGGTAATAGCCTGC 1,54 4,8E-12 NM_001568 EIF3S6 AAAGCTGAGGGAATGTGAATCAGTGCTTGTGAATGACTTCTTCTTGGTGGCTTGTCTTGA 1,54 1,5E-07 NM_001797 CDH11 AACTAATACGTGCCAGATATAACTGTCTTGTTTCAGTGAGAGACGCCCTATTTCTATGTC 1,54 6,6E-12 NM_015446 AHCTF1 TTGCCGGACCTTTCTGAACCAAACAATGAGCCTTTATTTTCTCCAGCGTCAGAAGTTCCA 1,54 9,0E-09 ENST00000361972 ENST00000361972 ATTGTGCTACTTTTGACCCATGTAATTTACCTAAAAGTTGTAATTGCTGACAGAGTACTG 1,53 4,1E-10 NM_001465 FYB CCTGCTCCTCCTAAACAATTGGACATGGGAGATGAAGTTTACGATGATGTGGATACCTCT 1,53 7,2E-12 NM_180989 GPR180 ACATTAGAGCTACAGGTTAAGACTAGAAAGTCTGAGTTATGTTTTAGGTATACATGATCG 1,53 1,6E-06 NM_002185 IL7R CATCCTGCTTCTACCATGTGGATTTGGTCACAAGGTTTAAGGTGACCCAATGATTCAGCT 1,53 1,7E-06 THC2439806 THC2439806 CATTAGGGAAAGTTTCGTGGGTGCATTAGAGTTCAAGTTTGTTGGCTCATTGTAGGACTG 1,53 6,3E-08 M_001003799 TARP ACAGATGTCATCACAATGGATCCCAAAGACAATTGTTCAAAAGATGCAAATGATACACTA 1,53 1,6E-07 NM_024498 ZNF117 AAACCTTACAAATGTAAAGAATGTGGCAAAGCCTTTAACCAGACCTCACACCTTATTAGA 1,53 1,4E-06 NM_133462 TTC14 TTCAGAGTCTTCTCGCAGTTCCAGAAGGCATTCATCTAGGGCATCCTCAAATCAGATAGA 1,53 9,6E-08 NM_207585 IFNAR2 TATGGGGACCATAGTATCATTCAGTGCATTGTTTACATATTCAAAGTGGTGCACTTTGAA 1,53 3,1E-11 NM_021105 PLSCR1 GTTTAGCTCTTACACTCTATCCTTCCTAGAAAATGGTAATTGAGATTACTCAGATATTAA 1,53 3,2E-04 M_001008224 UACA CAGACTCACAGTGTACTTCCCCAGGTATACCAGCCCATATGCAAAGCAGATCTATGTTAA 1,53 8,9E-09 NM_002519 NPAT TGCCATTAGCCGGCATACCACCATAAGAGAAACTCAATCAGAAAAGAAAGTTTCTCCAAC 1,53 2,1E-09 NM_138810 TAGAP TGCTTTTGTCATAGTTCCACTCTCTCAGATACATGTATCTAATGAAACTGAATAAATCCG 1,53 5,2E-09 AL355687 AL355687 ATATATATCTTTAAGAACTCGCTGTGTTAGGGAAACTGTTTACATATTGAGGTGTTCCTC 1,53 8,5E-05 NM_002666 PLIN AAGGGAACAATCAGATGCAAAAGCTCTTGGGTGTTTATTTAAAATACTAGTGTCACTTTC 1,53 3,5E-09 THC2403056 THC2403056 AGTTGAAATAGACATCTTTTCATGAACTCTGTAATATTTGAAATTATTGATAACTCTTAC 1,53 2,2E-08 A_32_P122595 A_32_P122595 TGAGCTAGTATGAATTTAATTTTTTAGAATGCGACGATGTCATCAGTTCTTAAGTAGGCC 1,53 2,5E-12 M_001023571 IQCB1 GTGTGGCTTTTATTGTAGAACTAAACTTAGCATAGTGTTCTGTTGTTTACATGAAGTGTG 1,53 3,7E-10 NM_005732 RAD50 TTGCACATGCTCTGGTTGAGATAATAAAAAGTCGCTCACAGCAGCGTAACTTCCAGCTTC 1,53 3,4E-12 NM_015423 AASDHPPT CGTATTCCTCTTAACGTGAACCGTCTGTTCATTGTTTTTACCTGTTTTCGTTTTAGCAAG 1,53 5,6E-06 BC039414 BC039414 AATGTTCAAAATGAGAAGACAATAACTGACAAGTCTGTGATTTTTGGGTTAGATGAGACC 1,53 5,3E-09 NM_001715 BLK TCGCACGGTCATCCGGAGTACTAAGCCCCAGTAAGGTGTTCAGGACTGGTAAGCGACTGT 1,53 9,0E-10 ENST00000360548 ENST00000360548 TGTCATTCTGTCAATGTTCATGACAAATTATCTGGAACTATACAGATTACATGGCAGTAG 1,53 1,7E-11 NM_177531 PKHD1L1 TATAAGATTGAATTTATACTGGATAATGTTGTTGGGGTAGAATCCAGAACTTTCAGCCTG 1,53 1,2E-06 NM_000237 LPL AACAGTCGATCAAGGGATGTATTGGAACATGTCGGAGTAGAAATTGTTCCTGATGTGCCA 1,53 8,9E-12 THC2270231 THC2270231 GAATTTTGTTACACTGGAGGAAGGGGAGACCTTGAGGAATATGGTCAGGATCTTCTCCAT 1,53 2,6E-11 NM_025228 TRAF31 P3 GGGTACATTACAGCTTGGGTTTTCCAACTGACTTAGGATTTCTGACTTTTTATTAATTTC 1,53 1,9E-07 NM_015384 NIPBL GAGAGCACCATAGTTGAGCCTAAACAAAATGAAAATAGACTGTCTGACACAAAACCAAAT 1,53 1,1E-04 ENST00000320876 ENST00000320876 CTACTTCTCGTAACATTGGGGTTAGAAGAATACAGATCAAATTGCTTTTTGATGAAACAC 1,53 1,2E-11 NM_018659 CYTL1 TAGTTGTATCTGAAACTGTTATGTATCTCTCTACCTTCTGGAAAACAGGGCTGGTATTCC 1,53 8,5E-12 NM_022763 FNDC3B TGGTGACAGTTTAGTGCCTCTGCCCATTGTCCATGATTTACACTAATTGTGAGCAGTCTT 1,53 1,2E-10 NM_004049 BCL2A1 TGTAACCATATTTGCATTTGAAGGTATTCTCATCAAGAAACTTCTACGACAGCAAATTGC 1,53 2,7E-10 NM_015364 LY96 TGAAGCTATTTCTGGGAGCCCAGAAGAAATGCTCTTTTGCTTGGAGTTTGTCATCCTACA 1,53 3,0E-04 NM_015180 SYNE2 AATCTGGGAGGCAGAAGCCAAATCTGTTTTGGATCAAGATGATGTGGACACCTCAATGGA 1,53 2,3E-08 NM_014857 RABGAP1L GCATTCTGTGTTTTGGTGAAAATCATGTACGACTATGGTTTGAGAGACCTCTACAGAAAC 1,52 5,6E-07 NM_175861 TMTC1 ACCAGACTAAGTGCCAGTATATATATGACTGATATTTTCGTGACTCATAGAAGGTGTCCA 1,52 2,4E-10 NM_005018 PDCD1 GCTGGGACAAGGGATCCCCCTTCCCTGTGGTTCTATTATATTATAATTATAATTAAATAT 1,52 1,2E-09 NM_001167 BIRC4 AGAGGAGAAGCTTTGCAAAATCTGTATGGATAGAAATATTGCTATCGTTTTTGTTCCTTG 1,52 2,4E-10 NM_014618 DBC1 GGAAATGAAAACGTTCTAGCAACTGTATAAAAGCGTTGGGCATGTTTGTTATTTCTATAC 1,52 4,7E-10 NM_024756 MMRN2 TGTGCCCCCACCTAAAATATCATCTTGAATTGTAATCCCTATAATCCCCACATCAAGGGA 1,52 4,9E-10 NM_006716 DBF4 AGACTAGTGAAGAGAAATCAGAATTTTTGGGTTTCACAAGCTACACAGAAAAGAGTGGTA 1,52 6,5E-12 NM_002830 PTPN4 CAGTGCTGGAATCGGAAGAACTGGGGTTCTTATTACTATGGAAACAGCCATGTGTCTCAT 1,52 6,6E-11 NM_207578 PRKACB GCACCTTAGAAGAATGACACCAGAAAACCTTATTATATCACAATATTCTGTTTTCCCCTT 1,52 8,5E-07 NM_014298 QPRT CTGTCAGGGCTGACTTCACCTCTGCTCATCTCAGTTTCCTAATCTGTAAAATGGGTCTAA 1,52 8,9E-05 BC062780 BC062780 AGATGGGAGAACAGAGGAGTAGTGACAGGAGTAGAAGCACTGTAGACCTTTTCATATCAT 1,52 3,5E-11 NM_024312 GNPTAB GCAACTGGAACATGGAGACATCACTTTGAAAGGATACAATTTGTCCAAGTCAGCCTTGCT 1,52 1,9E-08 NM_001117 ADCYAP1 GTAAATTTTAGAAACCCCTCTGTAGCCACTAGTAAGTAATTATGCACTAAATATGAACCC 1,52 8,9E-12 NM_004346 CASP3 TGCACCAAGTCTCACTGGCTGTCAGTATGACATTTCACGGGAGATTTCTTGTTGCTCAAA 1,52 5,9E-09 NM_032883 C20orf100 AAGTTACAGCTTATCCTACCGTGTGTGTGGTTTTGGGGTTTCGTTTGGGTTTGGGTTCTT 1,52 3,3E-13 NM_138459 C6orf68 TGAGTTCACCTGCTAGTACAATCTCCACAACTTGAATGGCATTGGTTGTTCTATAATTCC 1,52 7,1E-12 NM_002240 KCNJ6 GTACAATACCAGATCACTCAAAAAGGTGTGTCAAAGATTTTACCTGGGATATGACAAGCA 1,52 8,4E-13 NM_016265 ZNF12 GTGTTGGACTCATAATCTGAAGACTCACAGAATGGAAACCATGATTATAACAAGACCACA 1,52 2,0E-13 NM_005168 RND3 CTGTTTATTGTTGGCGCTTGTTGAAAACGAGCTTTCTTTCCCATGATAGTGCTTCGTTTT 1,52 2,4E-09 AL161993 ASPHD2 AGACCAGTTTGAGGCACTCACTCTAGAAATAGCCTGTGTTAGCTGATGTGTGAAAGCGTA 1,52 1,1E-08 NM_014395 DAPP1 AGAAGAATGAGATACTGATGTCCACAGTTCATTGGCAGAATCTAACCCCTTCTGTTATCT 1,52 6,2E-12 M_017699 SIDT1 TTTAAAGTCCCCAAATGTGTACTTAGCCTTCTGTTATTCCTTATTCTTTAAGCAGTGTTG 1,52 3,9E-07 AK074562 AK074562 TGAAAGTCATAGAAACAACTTAAAAGTAGAAAATGGTTAGGTGTTACGGCTTTCTCGTCG 1,52 2,5E-11 NM_020123 TM9SF3 GAAGACAGAAGTGTACTCTCTACAATGCAATTTACTGTACAGTTAGAAAGCAAAGTGTTA 1,52 6,5E-08 NM_206855 QKI AAGCTGTTGAATGAGTCTTAAAAATTATACTACTGTTAAGTGGACCAAGTTTGGTGAAGC 1,52 2,2E-07 M_018017 C10orf118 CAGCAAGCACGAAGAAAATTAGATCAGGTTGAGAGTGGAAGCTATGACAAAGAAGTCAGC 1,52 2,4E-09 NM_138467 TYW3 TTCATGTGTACACTTTATAGGAGAATAAGCAAGAGCTTAGGTAAGTTATAGTCCTTACCA 1,52 3,4E-10 BX537651 BX537651 GCTACAATTAGCTGCATTACTTGGTGCCAAAGAGCAGTGGGGAATTGTTGAGTTGCTGTA 1,52 1,3E-07 ENST00000264903 ENST00000264903 TGTGGTATGTTTAGGATGCCCACGGAATGAATTTTTCCTTATTCCAATTCAACCTTCTGT 1,52 1,9E-04 NM_004079 CTSS TCTGTTGGTGTAGATGCGCGTCATCCTTCTTTCTTCCTCTACAGAAGTGGTGTCTACTAT 1,52 1,4E-07 ENST00000377047 ENST00000377047 CTTGCTATATCATGGTTTGCTATGGCACAGACTCAGCTTAGCATGGGGACATTTTGAACT 1,51 1,5E-05 NM_015070 ZC3H13 CCAAGAGATGGACATGATGAAAGAAAATCAAAGAAGCGCTATAGAAATGAAGGGAGTCCC 1,51 5,2E-09 NM_152475 ZNF417 AAGATGCTTCATGGATACAAGAGTTAAAACTTCCTGTCCCATTTAGTGAAACAAAAGGTT 1,51 7,6E-09 NM_170672 RASGRP3 CATTAAGGCAAAGTAGTTCCAGTGATTTAAAATACGGTTCCAAATACGCTAAAACCAACT 1,51 5,9E-11 XM_496707 FLJ12993 AACAAGATTCTCCTGTCAAAAAGGCGTCTTACTGTAAATAGTCCAAGGTGACATTTGTTA 1,51 1,5E-07 NM_001289 CLIC2 GAGAGTGAGCATATCAGAGAGGCAAATTCTTAAAGAATGATTTTTAAAATCAGCTCTAGG 1,51 6,2E-12 NM_006777 ZBTB33 ATAAGTTTCCATATCCAAAGTTCAGAATTCATGTGAAATACTTCTTTGGGGCAAAAGTCC 1,51 5,9E-11 NM_152295 TARS CTGCAGGCGTAACTATTTTTGACCTAGTCAGTTTTTAAACAATGTGCATTTGAAGGAGTT 1,51 8,1E-12 NM_100264 WAC CATCAAGATTACGCGAAGAAGCGCATAACATGGGAACTATTCACATGTCCGAAATTTGTA 1,51 1,4E-09 NM_006506 RASA2 AAGAATTTATTCCCTTTTTACCCTCAGTTTACTTAAGCTGCAGAAGATGGAAGAGGCTTG 1,51 6,9E-12 CR749561 ALDH1L2 TCAAGGAAAATCTGGGCTAAGAGTAGGATATGAGGGATGATGGATAAGGCATGAGACATG 1,51 1,5E-10 NM_018429 BDP1 AAAGGTGGCAGAATTGAAACAAACTGGAAAAACAGACATTTCTCCAAGGGAAAACGAGCT 1,51 1,2E-08 XM_208438 LOC286495 TTTTCTCTTGGGATGTCCCCGTTTTGTTGTGATTGACAACTGTATTGCATTGAAGAAAGT 1,51 7,3E-07 BC015929 NR1D2 TTTAATGTATCTCTTTACATGATCTGAGAGAGGATTCAAGTTGATAGAAATAGCTGAGGG 1,51 3,8E-08 AK123297 AK123297 TGCAATATGGAGGAGAAATGATTAGACCTTAGGAAGTGCCAGTGGGTTGGTCCTTTCATG 1,51 2,1E-07 AK021543 AK021543 AGTTTGTACCCTTTTGATTCACGGCATGGCCCTATAGTTAATTAAGAGGTGGATAACTTA 1,51 8,9E-12 AK026687 AK026687 GTGAGGTTCTATCTGAAAATGTTATTTAGCTATCTTCTGGGACTATTTAATGAAAGTGGG 1,51 8,3E-04 NM_178544 ZNF546 ATAGCATCACTCAGTCCCTGTTAGACTTTAGAAGATTGATACTGATGCACTGCATCCCAA 1,51 4,8E-05 AF116677 AF116677 CTTTGGCTCATAGAATACTTATCTGATTAAAGAAAGCACATGAATTTGCATGGAGTACAG 1,51 9,4E-12 AK128714 AK128714 TTAGAGAAGCCCCCATACCTGGTAGAGCATGTACCATCTTACATGCTTAAATAACTCCAC 1,51 4,7E-07 THC2443199 THC2443199 GAATAAGAATTAAACTGAATGTGCATGTCATCATACTTCTGAAACTGACTTTGGTCAGAG 1,51 2,3E-07 NM_016218 POLK TGTGAAAGAAGACAGCTTAATAGTAGTTAGCTTAAGTAGTTTCTCCAAGTACTTTTGTGC 1,51 8,5E-05 NM_020801 ARRDC3 AGCAAAACAAAGTGCAATATTAAATGTTTGCTTTATAGATTATATTCTATGGCTGTTTGT 1,51 5,0E-08 NM_020711 KIAA1189 TGAAAGCCACAGAGTTAAGTGACCTCAGGTAACATAATGGTGATGGTTGGCCATTTGAGT 1,51 1,9E-07 AK093571 SCML4 CCACACAGAAACAGGGGATTTATTCCACAGTTAGCACCACAGATTGCGACTTGGGAAAAA 1,51 1,2E-11 M_018981 DNAJC10 TTGGGTGATTGATTTCTATGCTCCTTGGTGTGGACCTTGCCAGAATTTTGCTCCAGAATT 1,51 3,8E-09 NM_014810 CEP350 CTGTAGTCTTGTAGCCATAATGAGCAAATTGACTAAGAGAAGCAAAGGTTTCTTGGGGTT 1,51 1,2E-09 NM_173354 SNF1LK CCAACACAAAACTCCTTCCCCTTTTTAAAATGATTTCTGTTCTAATGCCATAGATCAAAG 1,51 6,7E-07 NM_003638 ITGA8 CCCATTATGGGTAATAATACTAGCAATACTTCTTGGATTGTTGGTTCTCGCCATTTTAAC 1,51 4,1E-08 THC2432207 THC2432207 CTTTAGGAAGCGGAAGACTAATGACCGAAGCTTCAAGACTTTGACATGTGTGAAAACATG 1,51 1,6E-05 NM_000165 GJA1 AGTACTGTAAACAGGCTTTAGTCATTAATGTGAGAGACTTAGAAAAAATGCTTAGAGTGG 1,51 1,1E-08 NM_177438 DICER1 CGGTCGCTGTTGCACCTGATAGTAAGGGACAGATTTTTAATGAACATTGGCTGGCATGTT 1,51 6,3E-12 NM_152729 NT5DC1 GTGGTGTTCTATGTGCCGTGTATGGTCATATTAGTAGCTATTTGTTGCAAGATACTTGAA 1,51 2,2E-09 NM_172003 CBWD2 GAAGAGAAACCTGATGGCCTTATCAATGAAGCTACTAGACAAGTTGCTTTGGCAGATGCC 1,50 5,6E-04 NM_001001971 FAM13C1 TATATCATTTTGTGTTATTTTATACGAAAACATGTTTATTATTTTCATTTTTGTAAAAGG 1,50 8,0E-10 AB011103 KIF5C TGGTGGTTTATATCAATAACGATGCTGTACTATAGTCCATGTAACAAAAGATCTGGAAGT 1,50 1,1E-09 NM_198329 UBE1DC1 AAAGCAAGAAGATTCTGTCACTGAGTTAACAGTGGAAGATTCTGGTGAAAGCTTGGAAGA 1,50 2,0E-08 NM_006059 LAMC3 CTGTGAACTCGACCCCGTGTGGATAGTCACACTCCCTGCCGATTCTGTCTGTGGCTTCTT 1,50 1,2E-08 NM_015393 DKFZP56400823 CACAGCCATGGTTTCCATTTCTAGATGAAAGGATGGCCTAGGACATAGGTCTCAAAGACT 1,50 2,5E-10 NM_030762 BHLHB3 ACAACAGTCTGACTATGAGTGAGGAAAATATCTGGGTCTTTTCGTCAGTTTGGTGCATTT 1,50 2,4E-08 NM_014648 DZIP3 GGATGTTATCCTGCTATCAACAAGGAATTGCTCTACAGTCAATAACAGGCAGTCAGCGTA 1,50 8,0E-10 THC2407737 THC2407737 AAGAAGGGACAGTTACACAGTAATTGGGAAAACTTCTGCAAGGACAGATGTGCATTTCTC 1,50 1,0E-09 AJ227863 AJ227863 GGTTTCCATGCCATTAACCGCTAGATCATTTGCATTCTCTCACAGAGTAAACGGAAAAAA 1,50 1,5E-08 NM_031292 PUS7L GGGCTTCAGTTTCAACATCTGTAAAATGGGCATGTTAACATTGCCTACCTCATAGGATTA 1,50 2,3E-09 NM_014450 SIT1 GCCAAGTCACAGGATGTGATCTACCCCGGACTTCCTATCTGAGCTTCAAGGGAGACATCT 1,50 2,2E-13 NM_022365 DNAJC1 GCTCGGTCTGCAGAGGAGCCGTGGACTCAAAATCAACAGAAACTTCTGGAACTGGCGTTG 1,50 8,6E-09 AK057962 AK057962 TCAGGAGCCTTGTTTTAAGACAGCCTGGCTGTCTGAGAGCCACCGGAGTCGAGACTGGAT 1,50 6,7E-08 NM_005356 LCK CCCACCCACATGTGACACATATGCACCTTGTGTCTGTACACGTGTCCTGTAGTTGCGTGG 1,50 1,4E-07 A_24_P473972 A_24_P473972 AATGCTGAATTAGGCAAAACCAATATTTAGTAGTAAATCCATTCCTGGTAGTATAAATCA 1,50 3,0E-11 NM_007114 TMF1 TCACTCATTTACAGCTAGAAATTGGCAATCTAGAAAAAACTCGATCAATAATGGCTGAAG 1,50 2,5E-09 THC2405019 THC2405019 TCCAAAATGGAAGTTGTAGACATTATCTGTAGTTTATGCACAACAATAAATTAGAAAGCC 1,50 4,0E-09 NM_016931 NOX4 AGTGCAATTTCTAAGACTTTGAAACTCAGCGGAATCAATCAGCTGTGTTATGCCAAAGAA 1,50 1,1E-11 THC2363646 THC2363646 GGGACTATGGGTAGATAGGGGAACAATGAAAGTCAACTCAGGCTAACTTGAATGTGAAAA 1,50 8,9E-11 NM_007315 STAT1 TAAAGTCAGTGCCCAACTGTTATAGGTTGTTGGATAAATCAGTGGTTATTTAGGGAACTG 1,50 2,6E-12 NM_148170 CTSC CACTCCCTTGGAAAACAGTAAACATCATTTTGGAATGTGAACAACCAGAGACTACACAGG 1,50 8,4E-11 NM_006010 ARMET GGATTCCCTTCCTTCTGTTGCTGGTGTACTCTAGGACTTCAAAGTGTGTCTGGGATTTTT 1,50 2,4E-10 ENST00000264777 ENST00000264777 GTGGGGAACCCTTACCTAAGTATGTGGATTGACAAATCATGATCTGTACCTAAGCTCAGT 1,50 6,9E-09 NM_014819 PJA2 GTTTGTTTCCTTTTAAGTACTGTTGATCAGTTGTGACACTTACTGGTTAAACTTACGTTG 1,50 5,3E-09 THC2283371 THC2283371 TTAGAAGTGAAGCAACTTGAACTCACTCTCCGAATGTACAAAATGTGGAATTGAAGACTG 1,50 4,7E-13 NM_000321 RB1 GTGCCAGAATTTTAGGAACTTCAGAGATCGTGTATTGAGATTTCTTAAATAATGCTTCAG 1,50 1,4E-07 NM_003437 ZNF136 CAAAAGAGAAAAGCTCTTGAATATAAGCAATGTCCACACGTTTTTAGCCAGCCCACATGC 1,50 2,3E-05 NM_001014975 CFH AATGGAACCAAGTTTGAGTCTTGCCAGGTCAATACTTGGGTCCTGAGTATGGTGACTAGT 1,50 1,6E-10 NM_052847 GNG7 CCCTGCCTCGGAGAACCCCTTTAAGGACAAGAAACCTTGTATTATTTTATAACTGTGTTC 1,50 2,3E-12 NM_005791 MPHOSPH10 ATTAAAGTTGTGTCAAATCTGCCAGCCATAACCATGGAGGAAGTAGCCCCAGTGAGTGTT 1,50 3,7E-09 AK026485 AK026485 TAATCAAATGGTAGGATAGGATATTAATCACTGTAGCTTAAAGCTAAGTTTCTCCCAAGG -1,50 6,0E-09 NM_001101 ACTB GCACCCAGCACAATGAAGATCAAGATCATTGCTCCTCCTGAGCGCAAGTACTCCGTGTGG -1,50 6,1E-05 NM_031449 DKFZp76112123 TGGGTGGGCTCTCAGATTCAGCTCTGTGTAAAGATTCTCTAGCGGGCTGCGCTCCCAAGT -1,50 9,6E-10 A_32_P208713 A_32_P208713 GTCAGGTGTGCTGGCCCTCAATGACCAACACAACAAAGATAAATTTATTGTTTTCTGAGA -1,50 3,6E-08 ENST00000371244 ENST00000371244 CTGATAGGATGAGTATCTTGATTTTTAGGTAAGATCACAGTTTCACAAATTGTGGTGTTG -1,50 3,1E-09 NM_020724 RNF150 CAATAGCAACAGAAATATAAATTATATTCCATTCCCAGAGAGAGAATGCGCTTTGGATTG -1,50 5,1E-06 NM_033315 RASL10B TGGGGGAAGGGTCGTGGGTGGGGAATTTATCACCAACATCCATTGTAGGGGGAATCTATG -1,50 5,4E-09 NM_024110 CARD14 GCAGAGGCATAAGCCCACATATGCTGTGACGCTGGCCACCTTTTCTCAGCTTCTGAGGCT -1,50 3,4E-06 NM_152335 C15orf27 TCTCATTCCAGCATGAGCGTTTCTGAGTCTCTTCAAGACGAATCTAGTTTTCACCTTCAC -1,50 3,2E-12 NM_020888 KIAA1522 GGTAAATGAGCTTGACCTAGAGTAAATGGAGAGACCAAAAGCCTCTGATTTTTAATTTCC -1,50 2,0E-09 NM_018059 FLJ10324 TAGGTTCTATTTATATGGCAGATGACGTGAAATTGTGATGTTTGTTACAGAGCTTTTATG -1,50 1,6E-08 NM_003564 TAGLN2 CTGGGAGTCACTGATGCTGCCTCTGCCTTCTGATGCTGGACTGGCCTTGCTTCTACAAGT -1,50 1,5E-12 AK026765 C6orf59 TTTTCTGGCAGTGTAAGGTCTACACCATTTTCCTCTCAGCATCAGAGAAGGCAGAAAGCA -1,50 1,2E-09 NM_005231 CTTN TTTTGAAGGTGGGGAGGGGAATATACACATTGCTTTTATATTTAATACTTTTGCTGATGC -1,50 1,7E-09 NM_003722 TP73L TCTGTTATGGGCTTTTGGGGAGCCAGAAGCCAATCTACAATCTCTTTTTGTTTGCCAGGA -1,50 7,2E-09 NM_004104 FASN ACGGAGGCCATATGCTTCTTCGTGCAGCAGTTCACGGACATGGAGCACAACAGGGTGCTG -1,50 4,4E-10 NM_138711 PPARG CCAAGGCTTCATGACAAGGGAGTTTCTAAAGAGCCTGCGAAAGCCTTTTGGTGACTTTAT -1,50 4,8E-11 NM_033452 TRIM47 CAGATCGGGCCCCTCAAGAAGTCCTGCATATCCGTGCTGAAGAGGAGGTGATGCCGGGCA -1,50 1,2E-08 BX640708 LOC284454 CACATGTGGGGCATGGAACAAGTTCCTTGTGGACCCAGAAGGGACACAAGCAGGTGTGCT -1,50 3,2E-12 NM_014567 BCAR1 CAGGAATCTGTATATATTTATGGCCGGGCAGGGTGTGGGGCCATGCCTCCTCAGGAGCCG -1,50 1,6E-08 NM_017451 BAIAP2 GGACTTTATCATCGGCAGACCTCAGAAGACAACACACAAAGGTTTCTTTTTTCTTAGCTT -1,50 4,2E-08 NM_032808 LRRN6A TTTCTCTGTAACTTGGGTTTCAATAATTATGGATTTTTATGAAAACTTGAAATAATAAAA -1,50 2,2E-10 NM_004265 FADS2 CTGATCGTAATGTTTATCATGTTACTTCCCCACCCCTACATTTTTTGAAATAAAATAAGG -1,51 9,2E-04 NM_014723 SNPH TAGATTTCTCCCAAGGGGATCACTTAGCTTCTCACTGACACACCCTTCCCAATTGCCACA -1,51 5,2E-09 NM_017982 SUSD4 CATCTCATGATGGAGACAGTAACCAAGGTAATGTTTTGTTTCAGCATTTTAAAAAGACTC -1,51 2,7E-12 NM_024927 PLEKHH3 GCAGCCTGGGCCAGGACTGCTCTGAGATTTGAGGGAAACATGGACCCTTTTGGCCCTGCA -1,51 8,0E-10 AB007877 HSPA12A TCTAAAATATCAGCTACTGGGGTCTCATTCACTACAAGATAAATTCAAACTTCACAGAAC -1,51 2,4E-07 NM_002627 PFKP GCCTGCATGTGCCTGCAGCCACCGTGGACTGTCTGTTTTTGTAACACTTAAGTTATTTTA -1,51 1,3E-10 NM_024307 GDPD3 CGGACCTCCTAAGTCCAGAAGCCTCGAGGTCTCCTGTTTCTCTTCCTGAAAAATAAATAT -1,51 1,4E-05 NM_019032 ADAMTSL4 CAAACGTGTATCACTTTTCAAAAAGAGGTTACACAGACTGAGAAGGACAAGACCTGTTTC -1,51 3,0E-10 AK054645 RP11-138L21.1 CTGCGGAGATAAGTCATTTTGGAATTCAGCTTCCTTCAACACTGAGACTTCATACCTTCA -1,51 2,2E-11 AK128234 CEACAM19 AAACAAAAACTCCCGCTTTCCCAGAGGGTCACTTGGCAGGGGAAAGAATCAGGAAATAAA -1,51 2,2E-09 NM_007098 CLTCL1 CATGTCACTCCAGCAGCACAGGGGACGCAATGGGAGGCAGGGACACCTGGACAATATTTA -1,51 1,6E-07 NM_001040272 C9orf94 GTTGGGTCTCCTTCTTCTTCACCACAAAAACAGGCTCTAAGAAATCATGTTACTAAAAAA -1,51 2,8E-08 NM_144669 GLT1D1 CAGGTCCAATGTTGTCTTAGATCTGATGATGCTGCTATTTACAAAACACTGATCGTCCGA -1,52 8,7E-04 NM_015444 TMEM158 AAATTGCTATTGCTGTAGTAAGAGAAGCTCTTTGTATCTGAACATAGTTGTATTTGAAAT -1,52 3,4E-08 NM_002246 KCNK3 GACTTCAGACTCACCATAATTGCTGATAATTACCCACTCTTAAATTTGTCGAGTGATTTT -1,52 3,7E-13 BC033222 BAHCC1 TCGGGGATCAGAACGATGTCAAGTGAAGAAAAATGCACGGGGGCATGCTGAGCCACTGGA -1,52 2,5E-07 AU185665 AU185665 GTTTTTGATTTGTCAGTTGCTTGGCTGAACTGATCAAGTCGATAGTTGCTTGACAAACTC -1,52 1,2E-11 AK024229 FLJ14167 GGAGAGTTTTCATGTTATTTTCAATACATAGCAGTATCTAAAGACGTAGGCGATGAGACT -1,52 3,0E-09 NM_002944 ROS1 GGAGATGGGTCTGATTAATAGCGTTGTTTGGGAAATAGAGAGTTGAGATAAACACTCTCA -1,52 1,0E-05 NM_001703 BA12 ATATATATATCTCTCTATTTTCACACTCCACTTTGGAACTACCCAGGAGCCAGCGCCCTC -1,52 1,5E-06 NM_000961 PTGIS TTGTTATGCCTTGCTATTTTAATAAAGATTCTATTTTCGTATAACATTGTCAAGTGGAAA -1,52 1,5E-09 NM_182645 VGLL2 AGACGCAAAGATACACTTTTTTCCTTTGGACTGTGAACATGGAAGCCTCAGCCTGAATGT -1,52 3,8E-12 NM_152264 SLC39A13 AAGTGGCCATCGAGAGGTCTGGATGGTTTTATAGCAACTTTGCTGTGATTCCGTTTGTAT -1,52 1,1E-11 ENST00000295989 ENST00000295989 GAAGGTTTCAAATGTGTCTAGTGTTCAGTATTGAGGACAAAGAAATACAAGTGGCAGGCC -1,52 1,8E-09 NM_001505 GPR30 AACAGCTGGGGACAACTGCGGTGATGATGTAAAAACCTTCCCATAAAATGTAAGAAAAGC -1,52 3,5E-11 NM_002998 SDC2 TACAGAACAAGATACCTGCTCAGACAAAGTCACCTGAAGAAACTGATAAAGAGAAAGTTC -1,52 4,1E-09 NM_002619 PF4 GACCTGCAAGCCCCGCTGTACAAGAAAATAATTAAGAAACTTTTGGAGAGTTAGCTACTA -1,52 1,0E-06 CR936831 C80RFK32 TTTAACTTCAATATGCTGTCTGGACATAGTGAGAACTAATGGCAATAAACGTCCAGCTGC -1,52 3,0E-10 NM_020299 AKR1B10 ATCACAGTGAACTTAGTCCTGTTATAGACGAGAATCGAGGTGCTGTTTTAGACATTTATT -1,52 3,6E-12 ENST00000339892 ENST00000339892 TGATCGAGGCCTGCCCGAACCCCAAGGCCAACAGAGAGAAGATGACTCAGATCATGTTTG -1,52 1,5E-08 NM_023107 FGFR1 GCATCTCTTACGAAGAGTTGGAAAAACAAATGCCATATATAAATTCTAAGCCATATGAGG -1,53 3,5E-09 NM_020707 GUP1 GACCGTGGCATCAACGACTGGCTTTGCAAATATGTGTATAACCACATTGGTGGGGAGCAT -1,53 8,5E-09 NM_004947 DOCK3 ATGCTGTGTATTTGTACAGGAATTTGAGCAAAAAATGTATAGAGTGTGATGTCCAATTGG -1,53 1,3E-12 BC052611 PXN CTTGCCTTGTTGAGGCTTTTTCCTTTCAGATGAGCTGTCCTTGACATTCTGATGTGGTGA -1,53 2,4E-09 NM_153344 C6orf141 AAATCTTATCCCGTTTACAAATGTCCTGGGAGTGCATCCAAAGTGAAACTTGGGTATCCT -1,53 2,9E-04 NM_173575 STK32C ATCTTCAAGACTGCCTCGATGCCATCCAGCAAGACTTCGTGATTTTTAACAGAGAAAAGC -1,53 2,4E-08 NM_002152 HRC CTATCTCTGCCCGCTGGTCTGCGAAACGGTCTGCGCTCCAGGAAGCTACGTTGACTATTT -1,53 3,5E-12 NM_018664 SNFT ATACCTGGGAGGAAGGCTTTTCCTTCACAATTGTATACAGGGGGCACCTGTGGCCAGGCC -1,53 1,0E-06 NM_201380 PLEC1 CAAGGGCAGAACACTAACCTGACCGTGGGCGGGGCCTTGCGGTATCCGCCCCCAATAAAA -1,53 4,5E-07 NM_053284 WFIKKN1 AAGCAGGCCTGCGAGCTGCTCAACCGCTTCCAGGACTAGCCCCCGCAGGGGCCTGCGCCA -1,53 1,2E-08 BC017937 BC017937 AAAGTCAGCCTCGCATTTGGAACCCATTTCCCTGAGTTCATTGCTGAATTCCAGAAGGAA -1,53 8,8E-09 NM_018125 ARHGEF10L GTGTGCGAGTGTGTGGGCTGGTGTGTGAATATCTATAAATAAGTATATATGGTGTATATT -1,53 7,9E-11 CR596712 CR596712 CATCTCTTGGTCTATGACGACGATGTTGGAGAGTTCCTACTCCGTGATAACTCAGTTCTA -1,53 1,5E-12 AK127004 AK127004 AAAGCAAATTGTTTGGTGTCTTTCTGTCCCACTACAGTATAGGCCCGGTTCAGACAGAGG -1,53 1,5E-09 NM_138440 VASN TATTCTGGGAAGATGTTTTTCAAACTCAGAGACAAGGACTTTGGTTTTTGTAAGACAAAC -1,53 9,0E-06 NM_198570 UNQ739 CTAGATGACTCTGGGAACTATCAGTCAAAGAAGACTTTTGATGAGGAATAATGGAAAATT -1,53 1,1E-08 NM_153370 Pl16 CTCCGGAAGGGAAAGGCTACGGGGCATGTGCCTCATCACACCATCCATCCTGGAGGCACA -1,54 2,6E-09 NM_013440 PILRB AGGTCTGAACTCCACTGAATTAAACCACTGGCATTTGGGGGCTGTTTATTATAGCAGTGC -1,54 5,8E-08 A_24_P247175 A_24_P247175 TGTCCACCTTCCAGCAGATATGGATCAGCAAGCAGGAGGAGTATGACAAGTCTGGCCCCT -1,54 6,0E-07 AK023086 CNIH3 ATACCTCTCAGTAAAGAAAGAAATAACAACTTCTATCTTGGGCGAGGCATTTCTTCTGTT -1,54 1,6E-09 NM_001825 CKMT2 GGTCGCAGATGTGTACGACATTTCCAACATAGATAGAATTGGTCGATCAGAGGTTGAGCT -1,54 1,9E-08 BC041879 LOC390705 TGCGGGGATGAGGACCTGGAGCCACTGTGACGCCACCCATGAGAACGCCGCTGCGGGCCG -1,54 4,3E-11 NM_003812 ADAM23 GCCTTGCACTGTTGGATTCTGGGTATGACATACTCGCAGCAGTGTTACTGGAACTATTAA -1,54 5,8E-09 NM_022359 PDE4DIP AAACAGCATCTGGATAAAACATGGGCTGATGTGGAGAATCTCAACAGTCAGAATGAAGCT -1,54 5,2E-07 BC022888 CMYA3 TTCCTAATGAAGAACCAAATATGTGTAAAAATATTGCAGAAAACACCCTTGTACCTGGAG -1,54 2,0E-12 NM_020836 KIAA1446 GCATGCCCTGCCAGTTAGTACTGTATTTTGCATTCATTAATAAAAGACACCGGTGGAAAG -1,54 5,0E-13 NM_024060 AHNAK GTGCATTTCTTTACTTGCAAGGGGACAGAGTGTGGGCTTAGGTTTGGGACTAGAGGGGGC -1,54 4,4E-12 NM_138809 LOC134147 AGAGAAGATTGCTCACCTGCAGACAAGCCCTACATTGACGAGGCCAGAAGGAATTTAATT -1,54 1,7E-12 NM_003383 VLDLR TCTAAACAAATAATACCCCCGTCGGAATGGTAACCGAGCCAGCAGCTGAAGTCTCTTTTT -1,54 4,6E-10 NM_006898 HOXD3 TGGTCATTTCTCAAAAACCACAGTCCTCACCACAGTTTATTGATTTCAAATTGTCTGGTA -1,54 9,5E-11 NM_023928 AACS CCAGCTTCCCTCCAAGGAATGAGTGGATTTCATACAGGATCTCTTTATTGCACAGACTGA -1,54 1,0E-06 AK094629 AK094629 AGCTATATTGTGCTCAAAGTATGTTACTGACATTTCTCCGTCGTTAAAAGGAACTGCTCC -1,55 3,9E-11 NM_198965 PTHLH AGCAGGAAAAGAAAAAACGGCGAACTCGCTCTGCCTGGTTAGACTCTGGAGTGACTGGGA -1,55 1,3E-11 AK024186 OBSCN CCTCGCTTCAGCCGGGCGATTCTTCCCCTCATTTGTTGCATTGTTTGCATTAATATGAAT -1,55 9,5E-07 THC2309459 THC2309459 GCGAGAGACATTTGACTCTTGTGTTTGTATCTCCTTTTTATGATTGCTGTACCTACCCAT -1,55 1,5E-07 NM_000156 GAMT CACCAGCCCTGGGCTGATCCCAGCTGTGTGTCACCAGAAGCTTTCCCGGCTTCTCTGTGA -1,55 5,4E-12 NM_004469 FIGF ATTCGTATGATCAGTACTGACTTTCTGATTACTGTCCAGCTTATAGTCTTCCAGTTTAAT -1,55 2,8E-06 BC013821 BC013821 GGACTTAGAGGAAACTCTGGGGCACAAGGAGGTGATGCCTGTCACTTGGACATGGGTGCA -1,55 7,4E-12 ENST00000361200 ENST00000361200 CATGAACATAGGACACGCTTCTGTCTGTAGAGGCTTCATATGAGACCCAGAAAGTCTATC -1,55 2,4E-08 AJ489257 TRDN AACAGAAGATTTAGTTAACACAATTGTATTTAATTATTTGCTTAATATGTATTTTTAAAA -1,55 2,8E-08 NM_004393 DAG1 TTGAGCATGACTTTTCTTGATGTCTGAAGCGTTATTTTGGGTACTTTTTAGGGAGGAATG -1,55 5,0E-09 NM_001003938 HBM AAGTTCCTGACTGGTGTGGCCGTGGTGCTGACCGAAAAATACCGCTGAGCCCTGTGCTGC -1,55 7,5E-11 NR_002330 ST70T1 ATTTTGACTGTGAAACGGCCACCTCTAACAGAAAGTCCATTTTAAACATTGTTTTGTTGT -1,55 2,3E-08 NM_002499 NE01 CTCTACCAGCTGTTAATCCATCACTCTGAGGGGGAGGAAATGTTGCATTGCTGTTTGTAA -1,55 6,3E-11 NM_024567 HMBOX1 CACAGACATCCTTTCCTCTCACAAGCTGTGTGACTTAGTAGATAAAATACTGCCTTCTGC -1,55 3,0E-11 NM_001039570 KREMEN1 CATCGTGGGTCTCATGCACGTCAAGACCTTCCCACATCCAAACTCAGCTTCCAGCAGGGA -1,55 7,4E-08 NM_005220 DLX3 AGACGGTGAACCCCTACACCTACCACCACCAATTCAATCTCAATGGGCTTGCAGGCACGG -1,55 3,1E-07 NM_001620 AHNAK GAAAAGTAACATTCCCTAAAATGAAGATCCCCAAATTTACCTTCTCTGGCCGTGAGCTGG -1,55 5,4E-10 NM_199461 NANOS1 TACAGCTCCTTATCGTTCTATGTACCAGGTATTTTATTACTGAACTAGCAACTAGCCTTT -1,55 1,5E-08 THC2294276 THC2294276 TTAGCCCCATTGCTAATTAAAAGCCCCATTAAAAGAGGGAAGTTCTTTTAGGTATCTACA -1,56 1,4E-12 NM_015193 ARC CCCACAGATTTTATTTTTGCACATAAGCCATAACCAATCCTCAAGGCTGGCACAGGCTTT -1,56 1,8E-11 NM_014181 HSPC159 GACACCGAGCCATTATACCCAGAATAAAATAATACATTTATGCTGGATTTTATTCAGACC -1,56 4,1E-07 AL713714 AL713714 TGAGTAAATCAACACTAGCACTTATGTCTATCCAGAAAATAATCAGGAGATTATCACAGC -1,56 4,7E-08 NM_014772 KlAA0427 CTCCAAGAAGCCAAGTCCCAGTCTGTTTTCTGGCATCAGACACCGGCCCGTGTTCCTTGT -1,56 2,6E-09 NM_022361 POPDC3 TATAGGAAAAAGATATCACTATGATATTCGGCTACCCAACTTCTATCAAATGTCAACTCC -1,56 3,4E-04 NM_152716 FLJ36874 TCTCCCATTCAGCAATCAACCAGACTAAGGAGTTTTGATCCCTAGTGATTACAGCCCTGA -1,56 1,5E-08 ENST00000324559 ENST00000324559 CTCTGTTGATTGACTCCAGTTGAAGGTGAGAAATCTGTACCAATCATTCAAAAAGGGAAT -1,56 6,3E-12 NM_015059 TLN2 ATCTTGTATTTTGTGGCCCAGAAAACTGAACGATTATTTTGTTCCTCCGTAGTCCAAAGG -1,56 6,2E-07 NM_033229 TRlM15 AGCCAGCGGGCTTTCGGGGAAAAAAAAGAAAAAGACATCTAAAATAAAATGTTTAAACTG -1,56 1,0E-07 NM_013239 PPP2R3B GCAAGCTGGCCAACGTCTTCTTCGACACCTTCTTCAACATCGAGAAGTACCTCGACCACG -1,56 1,2E-11 NM_078481 CD97 TCCTGGACTTTTCCTCTCATGTCTTTGCTGCAGAACTGAAGAGACTAGGCGCTGGGGCTC -1,56 9,7E-10 NM_172390 NFATC1 CTCTGGTGGTTGAGATCCCGCCATTTCGGAATCAGAGGATAACCAGCCCCGTTCACGTCA -1,57 6,2E-12 BE138567 BE138567 GGTGACTTTAAATCCAAGGTAAAAAACACGGCATGGGTATTAGTTTGAATAGGGAAAATG -1,57 5,3E-11 NM_002829 PTPN3 TCCGAATGTTTGGCCTTCTGAGAAAAGAGCTTCTAGTAATTGAACCATGGGAAACCCAGC -1,57 1,9E-11 NM_153486 LDHD CCCTTCACCTGGTGACAGGAACACTCCTTTCCTGGTATGGAACGTGAGCTCCCGTGACAT -1,57 9,1E-07 NM_002314 LlMK1 AGTTGAGCATCTAGGAAGTATTAAAACTGTGAAGCTTTCTCAGTGCACTTTGAACCTGGA -1,57 3,5E-05 NM_006133 C11orf11 CAAATTAATATAGCTTATTCTATAAATATATCTGTATATAAAGGTTTCTGTATATTGTAT -1,57 3,5E-09 NM_001007279 RRP22 AAAGGACTTGGCTATGAACTTGACTGGAAACACGCAGCCTGCTCCTGGAGCTTCACTGGA -1,57 4,5E-10 NM_007341 SH3BGR CCAGAAAATGGAAGCTATGAAGCAACATTTCAAATGTCTCTCCACAAACCAAACTCAACA -1,57 2,0E-04 NM_020062 SLC2A4RG CATGTTTGTTTTTGAAGCTCAGGTGTCTCACGTCTGGGCTGCACCAGGCGAAGAGAGAAA -1,57 1,3E-10 ENST00000367058 ENST00000367058 GACACTATTTAAGGGCCCGCCTCTCCTGGCTCACAGCTGCTTGCTGCTCCAGCCTTGCCC -1,57 2,0E-10 NM_014914 CENTG2 CCCTATGATGGTGTGTGTCAAATCAGTTGTAGCTAATCTGTCCAGGGAGAATACTGGCTT -1,57 8,2E-13 NM_002960 S100A3 GGTCTTCTGCGATCAGTTAACCCATTTTACCTAGGAGGCCCAGAGATGTGAGGGCTCCTT -1,57 9,0E-07 NM_052843 OBSCN ACGGGCCCTTCTTACCTCACTCAACTTCAGCCAGGAGGACTGGGTGGTGCTTGCAATGTT -1,57 8,6E-15 NM_032902 PPP1R16A GTCTGGCTGCAAAGACTATTTTTATCCTGCAACTCTTGATAAAGGGCTGTTTTGCCATGG -1,57 1,1E-13 NM_001008392 CTDSPL GCCTATTAGTAATGCTGATTTTATTGTTCCGGTTGAAATCGATGGAACTATACATCAGGT -1,58 1,6E-08 NM_002178 IGFBP6 TGCTGCAGCAACTCCAGACTGAGGTCTACCGAGGGGCTCAAACACTCTACGTGCCCAATT -1,58 6,1E-05 NM_002055 GFAP AATCTTCAGGGCACTGCTGCTGCCTTTAGTCGCTGAGGAAAAATAAAGACAAATGCTGCG -1,58 1,6E-10 NM_018948 ERRF11 TCAGTATTTCCTGGGGATTGTTTGCTTTTTAAGTAAAACACTTCTGACCCATAGCTCAGT -1,58 5,8E-10 NM_032895 MGC14376 TCATCCCAGCATTGCAATGGAGAAAAATGGGAAGCAATGGTTTGGTTGGGAATTTATTCC -1,58 6,0E-11 NM_003966 SEMA5A GGGCTGAGGTTCTAAAGGAATTGAAAAGAGACGATAAACATTGAATGAGGGTGAGGGCAT -1,58 2,6E-09 NM_002252 KCNS3 TGACTGAGACGACATGCATGTAAGATCCACAAAATGAGACAATGCATGTAAATCCATGCT -1,58 5,0E-11 NM_015124 DIP TCTGGGCAGATGTTTAATTTCTGTGACTAATCACTGAACTAGACGAATGTTAAATTTTTT -1,58 2,1E-14 NM_020127 TUFT1 TTTCTGTGTCTCAAGACTGGGCTCACATTCTGGCTTTGTCCATAACAATGCTCTGGGATT -1,58 2,1E-04 AK129956 AK129956 CCTTCCGAGAATAAGTATTACCTTTAAACAATATCAGCGCACACACATAGCTGCATGTTC -1,58 1,6E-05 BC054888 BC054888 AAGCCAGTCTTTTCTGCAAGGTCTGTTGACCAAGAGCATATTTCCCCTCTGTTGTACATC -1,58 1,4E-07 NM_001554 CYR61 ACCAAGAAATCCCCCGAACCAGTCAGGTTTACTTACGCTGGATGTTTGAGTGTGAAGAAA -1,58 8,8E-10 NM_020433 JPH2 ATGGCCCACAGCTCTGCATCTGCATCTGAGCTTCTCAAGACTCCTGGAGCATGAGGGGAA -1,59 3,6E-09 CR622844 CR622844 ATACAAAGTGCAAAAAAGCTTGGCTCCTTCTGTATTCTTTAAAAACAAAACAACAACAAA -1,59 7,3E-10 NM_014575 SCHIP1 AGTTCCTTTTTAGATGTGCTATTAACATTCTGTTGGATTCAGAGGGTTCCTTGAAAGTTT -1,59 4,5E-09 M_016835 MAPT AGTTTGCCATGTTGAGCAGGACTATTTCTGGCACTTGCAAGTCCCATGATTTCTTCGGTA -1,59 8,3E-09 NM_007197 FZD10 CTTCACAGTGCCAGGAAAGAGTGGTTTCTGCGTGTGTATATTTGTAATATATGATATTTT -1,59 7,5E-10 NM_012278 ITGB1 BP2 ATTGAGCAGCAGGAGGCTGAAGGAGGGGAGAACAAAATTGTCCAAACCATGCTGTTTTTT -1,59 1,7E-11 NM_199165 ADSSL1 GGGTTGGTGTTGGCAAGTCAAGAGAGTCGATGATCCAGCTGTTTTAGTCGCAGACTGAGC -1,59 3,5E-09 NM_004058 CAPS AAATCTGTAAAACATCAACCCCCAATCAGAAGATGGCAAATGGGGAATAAAAATAGCAGG -1,59 7,2E-13 NM_145659 IL27 GGAGTTGCTGCTGCTGTCCAAGGCTGGGCACTCAGTCTGGCCCTTGGGGTTCCCAACATT -1,59 5,0E-08 NM_173167 UNC45B GCAGAAGTGGTTCAGACAGCCCGAGAATGTCTCATCAAGTGCATGGATTATGGTTTCATT -1,59 2,7E-11 NM_145064 STAC3 CAAGCACAAGCAGCCTGGCTTCCAGCAGTCTCATTACTTTGTGGCTCTCTATCGGTTCAA -1,59 7,5E-10 NM_004468 FHL3 AGGGCAGCAGTTCACCTCCCGGGATGAAGATCCCTACTGTGTGGCCTGTTTTGGAGAACT -1,59 1,0E-11 NM_207477 FLJ27365 CAAGTCCACTTGGGCATGGGGAGCTGAGAGCTAGCATGCCGTTTAACTTGGCAGGAAGCA -1,59 4,1E-09 A_23_P20578 A_23_P20578 GGGGCTACGTGCCAGGGTATAAGTTCCAGTTTGGCCACACATTTGGCCATCTCACCCATG -1,59 1,0E-09 NM_139166 ABRA CACAGACGAGATGGCAAGATCCAGGTTACTTTTGGAGATCTCTTTGACAGATACGTTCGT -1,60 7,8E-12 AL831818 SYNPO TAGCTGTAACAATCTGTGAGGATTGAGAGGATAGGCTGGTGCTTTGAAGAAAGGCCTTGT -1,60 4,5E-11 THC2431711 THC2431711 AGACTTTTTGCCATATCTGACTGAATATAGCCAGTCATTTTTTCCCTTAAATCAAGTCAC -1,60 2,5E-11 THC2238625 THC2238625 CCTGCTGCTGCTCTTCATACACCAGGATATCCAGCATCTGCTTCAGCCGCCAGGGAATGT -1,60 2,7E-10 NM_198501 SMTNL2 TCCCTCTGGTGAATTCGATACATCGGCTTTACAGGGTTACAGTGATTACCAAGTGTTTTT -1,60 7,7E-16 NM_015689 DENND2A CACAAGAAATAACTCTCAGCCTCAAGGGAAAACTTCCTCCTAGTGCAGCCCTATTCTTTA -1,60 8,2E-11 NM_194463 RNF128 CTGAATGGATGAAACCATTGCATTCTTGTACACTGATTTGAAATGCTGTAAATATGTCCC -1,60 5,2E-12 NM_152372 MYOM3 CCGGATGCACTGGGGCTATCTAACAGTACTGGCATCTGATAGGTAGAGGTCAGGTACGCT -1,60 1,9E-07 NM_032608 MY018B AACCTCTAGGCAGTGACCCATTCAGCTGGAAACTCCCAAGCCTCGACTACGAACGCAAGA -1,60 8,5E-11 NM_152336 FLJ32310 TTCTGTGCCTAAGTGCATATGTGCGACTGACCTGTTGACCTGTTACGAACTAGCTTTTGA -1,60 3,8E-08 NM_001945 HBEGF CCCAGTGGAAAATCGCTTATATACCTATGACCACACAACCATCCTGGCCGTGGTGGCTGT -1,61 3,7E-06 NM_002586 PBX2 TGTATCTTCCTCAATTTCCCCATAAATGAGGTATCTTTTTGTCACACCAAAATCAAGGGG -1,61 1,8E-13 BC045676 C17orf72 ACAGCCAACTGGAAAGATATAAAAGTTTGGGTCTGTCTCCTCTCCTTCAGAAATGAAATA -1,61 2,0E-14 NM_152237 GAS2L1 AGCCCGGTGTTCTGAAGACCTGTGGCCCAGCAGAGCCTCTGACAGTAAAGTTTTGCTCCA -1,61 1,8E-11 ENST00000256367 ENST00000256367 CCTAGTCTCCTGATGTCTGTGCTCGTTATGCTATGCCATGTTGCTTCAGTCAAACAAGAA -1,61 6,4E-11 NM_005194 CEBPB CACGTGTAACTGTCAGCCGGGCCCTGAGTAATCGCTTAAAGATGTTCCTACGGGCTTGTT -1,61 5,6E-11 NM_145038 C2orf39 CTGTCTTTATAGCCTGTCGAAATAAGGAGCCAGAGGAGTTACCTGTGTCCTGCATTATGA -1,61 2,8E-09 AF227517 AF227517 TATAATTTGACCCTAGTTAGAATGGTTATCTGAGGAAGTGGCCTGTACGATTTCTGCTTT -1,61 2,8E-11 NM 007148 ZNF179 ACTTCTAGGCTATGAAACTGACTTCTAGGCTATGAAACTTACAGGGTATGGGTGGGCACA -1,61 4,7E-15 NM_032525 TUBB6 AAGCCTGAAATTGTGCCGTGTTGCCTTATATGAATATGCAGTATGGGACTTTGAAATAAT -1,61 1,2E-06 AB209463 CSNK1 D TTGTATCGCCACTGTATTTGTGTACTTTAACAATCGTGTAAATAATAAATTCATAATGAC -1,62 1,6E-10 0 no_000507 FBP1 TAATGCCACTGGTGTTAAGATATATTTTGAGTGGATGGAGGAGAAATAAACTTATTCCTC -1,62 3,3E-13 M_001017402 LAMB3 GCCTTTAGTTCTCCACTGGGGAGGAATCCTGGACCAAGCACAAAAACTTAACAAAAGTGA -1,62 3,1E-08 M_001024858 SPTB ACCTGCTCAACCGTGCTTCCACCAACCAGAGGAAACCCATTTACTAGTTTTTCTAATAAA -1,62 9,8E-12 NM_032726 PLCD4 CAGCAAAGATTAGGGAAAGAGACTTGACCCCAGGACTGTACTACGACTCTTAAGAGAACA -1,62 4,8E-08 NM_080621 SAMD10 AAGCTTCCTTCGGGAAAATGTCCTAGCTGCTGCTGAGGCTTGAACCCAGACCCCAGCACT -1,62 1,2E-08 M_016223 PACSIN3 CCTGGACCTTTCCAGCAGTGAGAAGTTCCATGAACTCCACCGTGACTTGCACCAGGGCAT -1,63 5,0E-08 NM_012339 TSPAN15 ATCTCTGGCAGTGCCTTGGCGGTGGTATTCAAGGCAGTTTTGTAGCACCTGTAATTGGGG -1,63 2,8E-11 NM 001004439 ITGAL1 GACACATGAAAGGCATCAGTCCCCCTGTGCATAGTACGACCTTTACTGTCGTATTTTTGA -1,63 7,0E-11 AK023606 ADAMTSL4 AAACCGTCAACCCATTTAGCTTATCCCTTGGCCAAAAAGTGTATGAGATGTGCCTGGATG -1,63 3,1E-07 NM_001927 DES CCAGCCCAGGGTGGACTTAGAAAGCAGGGGCTACAAGAGGGAATCCCCGAAGGTGCTGGA -1,63 4,4E-11 NM_199162 ADPRHL1 TCCCTGTGATGAGGTTCTCTCTCAGAGAGTCTTGGAAAAGAGACCACTTGCTCTTGTTTA -1,63 3,4E-11 NM_176072 P2RY2 GCTCCCATGGGCTAGGAGCCAGTGTGAGGCTGTAACTTATACTAAAGGTTGTGTTGCCTG -1,63 7,8E-13 NM_020927 KIAA1576 TAATCGCAAATTACTCCAGATGGTTAAAGAAAACCCTTTCAGAATACAGAACGAGAAAAC -1,63 3,1E-09 AB040888 ODZ3 AAATCATCAAGGACAAAGGCCTCGACCTGTTGCGCTGGGCCGTCTGTTCCTTCTAGGCAC -1,63 3,5E-10 NM_003970 MYOM2 ACCCGTCTAAGGGAGAAAGCTAATGTTTTCCACAAGACTGAACAACGTGTATTTACACGA -1,63 2,4E-14 NR_002942 LOC340508 GGATGAGCTTTGCTATTTAATTACTAATATTATTGAATGCCTTAGAGGAGGCCAGAGCAG -1,63 1,8E-10 NM_012266 DNAJB5 GCTGGGGGAAGACTGCTTCAGCCAGATCCTGGGGTGGGGTCTTTAGGTTTTCTCACTTTG -1,63 2,4E-10 NM_001104 ACTN3 CAGCTCAACGAGTTCCGAGCATCCTTCAACCACTTTGACAGGAAGCGGAATGGGATGATG -1,63 1,1E-10 NM_001299 CNN1 AGAGACCCAGCGGACACACGCGGTTTCGTTTGCAGCGACTGGCATACTATGTGGATGTGA -1,64 1,6E-13 NM_002632 PGF AATGTCACCATGCAGCTCCTAAAGATCCGTTCTGGGGACCGGCCCTCCTACGTGGAGCTG -1,64 1,5E-11 NM_014370 STK23 TAGAGCAGGCCACACAGTTCAGCGCCTTTCTGCTGCCCATGATGGAGTACATCCCCGAAA -1,64 5,2E-11 BU160948 BU160948 TTTTTTGCCTGTGTGAATTCTACTTTTTAGCAAAAATAAAGCCCCCCAAAGGATGTGCAA -1,64 6,5E-11 NM_001231 CASQ1 GTGTCTCTTCCATCACTCTCCATACTCTTTCTTGTGATTCTCCTCTAGCCATATATATGG -1,64 1,9E-13 NM_080647 TBX1 TGTAGATACTGTAGATACTGTAGATACCGCCCCGGCGCCGACTTGATAAACGGTTTCGCC -1,65 1,3E-13 NM_021979 HSPA2 TTTTTTGTTTGTTTCTTTGAAATGTCCTTGTGCCAAGTACGAGATCTATTGTTGGAAGTC -1,65 7,5E-15 NM_018205 LRRC20 TCTGTCTTGGAAAGTGTGGGCAGCCACAGATGCCCCCAAATCAGAGCTCACAGTGGGTGA -1,65 2,7E-08 NM_003098 SNTA1 TCCTGCGACAGCCCTTCGAGAAGCTGCAGATGTCTTCAGATGACGGTGCCAGTCTCCTTT -1,65 1,0E-10 NM_001179 ART3 GGAAGCTTGAAGACCATGGTGAGAAAAACCAGAAGCTTGAAGACCATGGTGTGAAAATCC -1,65 7,1E-09 NM_002704 PPBP GACAGTGACTTGTATGCTGAACTCCGCTGCATGTGTATAAAGACAACCTCTGGAATTCAT -1,65 6,9E-15 NM_138409 C6orf117 GTGGCCTGAGTTATGTAAACAAGTGAGCAACACAGCTTTAATTTCATGGAGGAATCAAAG -1,65 8,3E-09 CR622769 LRRC38 ATATAATAGGCCTCAGCAACCTTGGGATGTTATACTGGGAACTAATAAACTCGTGTGCAA -1,65 8,9E-13 NM_001897 CSPG4 TGGGTTTATTTAAGGGAGATTGCAAGGAAGCTATTTAACATGGTGCTGAGCTAGCCAGGA -1,66 2,8E-12 NM_006877 GMPR GAGGAACGGACGGAAGCTCAAGCTCTTCTACGGGATGAGCTCTGACACCGCCATGAACAA -1,66 1,8E-12 NM_015157 PHLDB1 CAACTGGGGCTTTTGTATAAGAAGACTTTAATATTCTGTAAGGAGCTTGGTCCTGTGAGT -1,66 3,7E-11 NM_015270 ADCY6 CACTAGCCTGAATTTTGCTTGAAGATCACTTTGTCTTGGAAATGACTAGAGAGGCAGAGG -1,66 2,5E-12 NM 025249 KIAA1683 GCTCCCTGCAGTGGGGACTTCGTGGGAGGCACTCATGGCTCTCTGGGTCTAATGAATAAA -1,66 8,5E-10 NM 003803 MYOM1 ACTTGGGTGTGAATGGTTTGGGTTAAGGATGAGACGTCTTCATGCTTTCTCCTCCCTATT -1,66 7,5E-07 NM_001005291 SREBF1 GGCTCCTGTGCTACTTTGCCTTTTGCAAACTTTATTTTCATAGATTGAGAAGTTTTGTAC -1,66 2,4E-10 NM_002471 MYH6 ATCAACCAGAAGAAGAAGATGGAGTCGGATCTGACCCAGCTCCAGTCGGAAGTGGAGGAG -1,66 1,8E-10 NM_000476 AK1 CCAGCGGGCGTGTGGACGACAATGAGGAGACCATCAAAAAGCGGCTGGAGACCTATTACA -1,67 7,9E-10 NM_015069 ZNF423 TTTCCGCCGCAGACTACATTTCTAGAGTTAGAGAAACCTGCTTTTTAAGGCTATTGTCCT -1,67 7,5E-11 NM_001042 SLC2A4 TGTATATATATAGATACTTCTATAAAGTCACTGCTGAAGACAAGCATCCTATTGTGGAGG -1,67 3,5E-12 AF131834 AF131834 GCGATCTCCCAGTGAGCCATCACGATGCCCTTTTCAAATAAATGTTAATGTTGTCACCAC -1,67 6,2E-12 AK023797 KlAA0672 GATGTCTTTCAGGACAGTGTCCAAATGTATGTCTGTACACTTAGTATGGTATTCCCCAGT -1,67 2,7E-11 NM_000127 EXT1 ACGACTACTCCATGGTGTTGACAGGAGCTGCTATTTACCACAAATATTATCACTACCTAT -1,67 2,7E-05 NM_002966 S100A10 AGAAAAGTTAAATACCAGATAAGCTTTTGATTTTTGTATTGTTTGCATCCCCTTGCCCTC -1,67 8,7E-15 AK098354 AK098354 ACCCTGGATTAATGTAAATAGCTTTTTGGGGAACGGATTCTAATGTCACGTATGTGACCG -1,67 1,8E-13 NM_022144 TNMD GGAGATTTGTGATAACGTGACCATGTATTGGATCAATCCCACTCTAATATCAGTTTCTGA -1,67 3,9E-08 AB095949 ADAMTS16 GAAATGGGAAAAATGAAATTCCTGCTAAGGTGCTTCTATCTCTTTCAGATTCATGCATTG -1,67 2,0E-11 NM_005159 ACTC AACCGGGAGAAGATGACTCAGATCATGTTTGAGACCTTCAATGTCCCTGCCATGTACGTG -1,67 1,3E-06 NM_012156 EPB41L1 AGACATTGTATGCTTATGGTTTCTCATTATGAAGGTGCAGCTTGTAGGAGGTTTGTACGG -1,68 5,0E-06 NM_032777 GPR124 AAAGCTTTGTATTATTCTTCCACATATGCTGGCTGCTGTTTACACACCCTGCCAATGCCT -1,68 5,8E-08 NM_153020 RBM24 TTTTGCCTGTGTAGATTTCATTTATTGGTAATTCATTAGTTTAACACTATTATGTAGTTT -1,68 1,9E-07 NM_001449 FHL1 CTGTAAAATGGCATTTGAATCTCGTTCTTTGTGTCCTTACTTTCTGCCCTATACCATCAA -1,68 2,9E-09 NM_015432 PLEKHG4 GACTTGATGCCTTTTGAATAACTTTCAATAGAATTGTCTAAAATTATCTTACTGGTTGTT -1,68 7,8E-11 NM_000710 BDKRB1 TTCATCCCATAGGAAAGAAATCTTCCAACTTTTCTGGCGGAATTAAAACAGCATTGAACC -1,68 2,1E-04 NM_021939 FKBP10 CAGACTGGGCTGTAGTTAGCTTTTCATCCCTAAAGAAGGCTTTCCCTAAGGAACCATAGA -1,69 3,2E-12 NM_172311 SALF AAGCCATTGGTGATGCAGAGTGGTAAACCTTGTGAGCTCAGTACATCTATTTTGTGAACA -1,69 1,6E-11 NM_004235 KLF4 CGTTCCAGTGCCAAAAATGCGACCGAGCATTTTCCAGGTCGGACCACCTCGCCTTACACA -1,69 1,5E-11 NM_003196 TCEA3 ACCACCACTGACCTCTTCCAGTGCAGCAAATGCAAGAAGAAGAACTGCACCTATAACCAG -1,69 3,1E-12 AK123912 AK123912 GTAAAATGGAACCAAATCGCCTCTTCAATGGATTTGGTCCCCTTCAACCAGCTGTAGCTA -1,69 3,3E-14 NM_004653 SMCY TCCTACTATCTCCTGGCCTGGACCTCAGAAGGAGCTTTTTGCCTATCTATAATTTTTCAC -1,70 1,7E-07 NM_206862 TACC2 TTGCATTTTCCTAGTATAATTCATAGCAAGTTGACCTCAGAGTTCCTGTATCAGGGAGAT -1,70 7,8E-11 NM_005309 GPT GGATGACCATTCTGCCCCCCTTGGAGAAACTGCGGCTGCTGCTGGAGAAGCTGAGCAGGT -1,70 9,7E-08 NM_017625 lTLN1 TCCTCCCAACCATGAGATCCCAAGGATGGAGAACAACTTACCCAGTAGCTAGAATGTTAA -1,70 6,0E-12 A_24_P919283 A_24_P919283 CTCAGAGAAGCCAGTCAAATCTCCCCTTGTTGAGAACATTTTGACAGCATAAAATTGCTG -1,70 3,2E-13 NM_021046 KRTAP5-8 TGCAAGCCCTGCTGTTCCCAGTCCAGCTGCTGTAAGCCCTGCTGCTGCTCTTCAGGCTGT -1,70 4,5E-11 NM_016300 ARPP-21 TAGGTATGCCTTTATAGCTTAGCTAGTGACATGAATTCATCAAGGTAAGATTTTCTCCTA -1,70 6,1E-10 NM_020386 HRASLS TTGGGAGGAGGAAAAGAAACCTGGGGTGAATACTTATTTTCAGTGCATCATTACTGTTCC -1,70 6,1E-08 NM_052886 MAL2 CTAGAATTTAGGTGTGAGATTTTTTGTTTCCCAGGTATAGCAGGCTTATGTTTGGTGGCA -1,70 5,7E-12 NM_031886 KCNA7 CTCAAAGGGCATTTAGAGGAAGAAGGCTGAAATCACTAACACATATAGGGCTTCCTTTGG -1,70 2,2E-09 NM_198271 LMOD3 TCAAGTGTCTAGCACATACTACATCTAAGAGGCTAAACTCTGATAGGAAAAGCACTTTAA -1,71 5,6E-05 NM_002421 MMP1 ACATGTGCAGTCACTGGTGTCACCCTGGATAGGCAAGGGATAACTCTTCTAACACAAAAT -1,71 3,0E-08 NM_002081 GPC1 AGGTCCCCGGTTGCTGGTCAGGTCCCCATGGCTTGTTCTCTGGAACCTGACTTTAGATGT -1,71 9,7E-12 AK055821 AK055821 GACAAACAGCTCATAAGCCCGTACTTTTACATACTCACTTCCTGAATTGCATATTGAAAA -1,71 2,0E-12 ENST00000216214 ENST00000216214 CAGCTGGATCAAAAGGGCTTCTTTGGAATTAGGTTGTTTTAGTAACTTCTGTTCCAAAGA -1,72 3,4E-08 NM_001020818 MYADM TTTTTTAAATCCTTGGAGCTTCTGGTTCCTATCAGTTCCTGTTGTTAATCGTAGAACCGT -1,72 2,5E-11 NM_001458 FLNC AATGTCACCTACACTGTCAAGGAGAAAGGGGACTACATCCTCATTGTCAAGTGGGGTGAC -1,72 1,3E-12 NM_006366 CAP2 GGGGAGAGTGCCAACAATTTCCATTAATAAGACAGAAGGTTGCCACATATACCTCAGTGA -1,72 1,5E-11 NM_002340 LSS GTTACTGAAAGTCACTTTTATGAGCATCTGCCTTAATAAACAGACATTGATTCCCTTATC -1,72 4,1E-13 A_32_P171043 A_32_P171043 CACAGTGACTAGTCATATACTGGAGTAGCTCTGTTGTTCATTATTTGTAACAGGTCCATG -1,72 1,3E-13 NM_178568 RTN4RL1 AGCATCCACAGTGTTAGTCCAAAGGGTCGGACCGTGTCGTCAGCCTAGCGTTTGGTCAGT -1,72 2,4E-12 NM_017911 FAM118A TGTTTTGACCACTTTCCAGGATATGTGCAAGACCTTGCCACTCAGATCTGCAAACAGCAA -1,73 1,6E-06 NM_000037 ANK1 ATCATAGTCCGTGTTCAAAGTGTAAACTGTACAGTAATCAGCCTTGTGTATATGAAAAAC -1,73 8,8E-13 NM_002135 NR4A1 AATGACAGATTCTGACATTTATATTTGTGTATTTTCCTGGATTTATAGTATGTGACTTTT -1,73 1,1E-12 AK022045 AK022045 TGTAATCAGTTCATCTTACCTTGCCGGGCTCTGAAAGAATGAGTGTGTGGGATCAGATTT -1,74 6,1E-10 NM_018687 LOC55908 CTGAATCTGCCTGGATGGAACTGAGGACCAATCATGCTGCAAGGAACACTTCCACGCCCC -1,74 3,2E-12 NM_002607 PDGFA GTTTACCTAATATTACCTGTTTTGTATACCTGAGAGCCTGCTATGTTCTTCTTTTGTTGA -1,74 2,3E-10 ENST00000330255 ENST00000330255 ACCGTGAGCCCGACTTTCATCCGGTCGTACCACGTGTATCCAGAGCAAGGAAACTGGGAA -1,74 1,5E-14 NM_004997 MYBPH AAGGCGCAGAGATTGGAGTGCCCTGCGGAGTTGCACACTGGGTGGGAAGCACTCAAATAA -1,74 2,0E-10 NM_130808 CPNE4 GAGGCCTGGATCTGTTAAGCCCTTGTATTGTTAACTTTTTACAAAGAAACACAGATAACA -1,75 8,1E-08 ENST00000257704 ENST00000257704 AGCTGCACCTACCACAGCCAAGTGTATGCCAATGGGCAGAACTTCACGGATGCAGACAGC -1,75 6,9E-13 AK022486 FLNB TGTGTTCCAAGTTCTTTCTATAAAGAATCCTTCCAGAGGGAAGCCACTGTGAGTGAAAAT -1,75 2,3E-09 NM_001670 ARVCF GAGAAAAAGCATTAAAAATAAGCCAAAATAAGACTATTGGTAAACACCTAAATTTTTGTA -1,75 3,2E-12 NR_001544 CYorfl4 CCAGAACTGTGGGCAATAAATGTCTGTTGTTTATTACCTGTCCAGTATCTTTGGTATTTT -1,76 2,1E-09 NM_173608 C14orf80 TTCCAAGGCCAGGTGGCCACAGGGACGATGCAGATGCAGAGCCCACGTCACATGCTCGCT -1,76 1,4E-07 NM_025225 PNPLA3 CTTGACTACTAAAAACGTCTCCATGGCGGGGGTAACAAGATGATAATCTACTTAATTTTA -1,76 4,5E-13 NM_004273 CHST3 GTGGAAGCTGCTCTTTACCTCAAAAGCACAAAGCAGAATTGGCAACTTCACATGTCTCGA -1,76 2,9E-12 AK090474 LOC441245 TGCTCCTTCAGCATAAGGATAGTCTGCTGCTGCCACCCCGGGAAGGAGGTGAACGTCAGG -1,77 1,2E-13 NM_025135 FHOD3 TCCAGATGTAAACCCCAAACTTGTACACAAAAGAAAGCACAGATTGTTTACCTGTTGTGG -1,77 5,6E-11 NM_001681 ATP2A2 CTCTTTTTCCGTTACTTGGCTATTGGCTGTTACGTCGGCGCTGCTACCGTGGGTGCTGCT -1,77 6,1E-12 AK024388 FGFR1 CGCTCATTGGTGTTCATTCAGGAATACAGATACCTAGATTCACACACGTGGTGTGTTAAC -1,77 1,1E-13 CR608907 CR608907 AGAAAAAGAAAGATGTGTAAAGTAACAGAGAGAGGTGGCTATGGTGTAGAGACCTCTTTC -1,77 9,6E-13 ENST00000382496 ENST00000382496 TTGATTACCTATGGTTATCTGCAATTACCTACGCTTATCTTATCAGACCCTAGATGCCAT -1,77 5,5E-13 NM_002206 ITGA7 AGGAGGTTGTGTCACTGACTCAGGCTGCTCCTTCTCTAGTTTCCCCTCTCATCTGACCTT -1,77 3,7E-07 NM_005279 GPR1 TTCCCTTTGCTAACAATGAGTATTTGCTACTTGTGTCTCATCTTCAAGGTGAAGAAGCGA -1,78 5,3E-11 NM_002616 PER1 TTCTCAGAACTCAGATGTGGCTAGACCAACCAGTGGGAAACTGCCCCAGCTTCTCCCACC -1,78 4,5E-12 NM_001039906 FLJ30064 AAACATCAGTCAGTGCGTAGAACTGGTAAATGTCAGAGAAATGTATCACTTATCAGAGCG -1,78 6,9E-11 NM_001040167 LFNG AAGCGAATGATAAGGGAAAAGTTCTCAGGGAATTGAAGTGTTGTTGCTATGGTGACGTCC -1,79 2,0E-12 NM_001017421 FKSG30 AACTGGGACGACATGGAGAAGATCTGGCACCACACCTTCTACAATGAGCTGCGCGTGGCT -1,79 5,6E-12 NM_020478 ANK1 CTCTTGGCATGAATGACTGACTGTAGACGCATGACCTCCAGGCTTCAATCCTGCCTCTTG -1,80 3,0E-14 NM_000727 CACNG1 ATGAACATTGCAGGGACAACCTGTGTTTGCCAGCTGGGTGTTCCGTGTAAATAGCCAGCC -1,80 1,4E-16 NM_024786 ZDHHC11 AGAGTCAATACCAGAGAACCAGAGGCATCCTCTGTATTTTAATGAACTCTGCATTTTAAT -1,80 1,1E-14 NM_020689 SLC24A3 TTGATTCTGTTGCACATTTTGCACTGGTTTATGGCGATTGTTTTCTTGGACGGATAGTGT -1,80 2,6E-11 AK097227 SPOCD1 TGGAGGTGGCTGATAAGAGTAGAGTTTCAAAATCTCTTTAAACCTTCCTAAAGCAATGAT -1,81 3,6E-10 NM_033317 DMKN AGTTCTCCAGGAAGGAGGAGCTTCCTACTTTTGAGTTTCTCTGTGGAAATAAAACATGAA -1,81 5,8E-13 AK123855 C1orf170 CTGGGTGGGGGTCCTCAAGACTGTGGGAGACCCTGGCTGCTGAGCAGAGAACACATGGAT -1,81 2,3E-15 NM_133371 MYOZ3 GAAAAGGAGCCTGGTGGGGAGACCACTGCACCCAAAACAAATCCTTTCTTCTTCTGAGAA -1,82 3,4E-15 NM_002514 NOV TAGGCTGCAAAATTAAATCTAGACATTCTTTTAATGCCACCACACGTGTTCCGCTTCTCT -1,84 2,7E-16 NM_005685 GTF2IRD1 TCGGATATGTATCGATGCCTTTTAGTTTTTCCAATGATTTTTACACTATATTCCTGCCAC -1,85 1,2E-11 NM_000540 RYR1 GAGTCTTATGTCTGGAAGATGTACCAAGAGAGATGTTGGGATTTCTTCCCAGCTGGTGAT -1,86 1,5E-10 ENST00000377444 ENST00000377444 CTGGAACCCTCATTTTCCCCACTCTCAATGTCCCAGTGTCCAGCGTGACTAAGGACACGG -1,86 1,7E-12 NM_005061 RPL3L TTGCTGGTACCAAGAAGCGGGTCATTACGCTGAGAAAGTCCCTCCTGGTGCATCACAGTC -1,86 7,0E-10 NM_173201 ATP2A1 GTCCTCAAGATCTCACTGCCAGTCATTGGGCTCGACGAAATCCTCAAGTTCGTTGCTCGG -1,86 3,3E-10 NM_002686 PNMT CACCTTCAGACAGGCGTAGATGATGTCAAGGGCGTCTTCTTCGCCTGGGCTCAGAAGGTT -1,88 2,1E-14 NM_033655 CNTNAP3 ACTACCTTCACTGGCATTTCCATAGTCCTGGAATCCAGAGCCAAGTGGCCTATCTAAAAT -1,88 1,1E-14 NM_033342 TRIM7 CGTAACATACCAGTTAGGGCCTGCGGAAGCATCTTGTAATGGAACACATTACTATTTCTG -1,88 6,0E-12 NM_133379 TTN GATCTGAGTGCTTTCATATTTTCCAAATTATGTGGATCTAATAAACTTCCAAACAGGTCC -1,89 8,3E-13 NM_012309 SHANK2 CGTTCCTGTAACTTGTTCTACATTCCACAGTCTTTACCGTTTTATGTTCAAAATTACAAC -1,89 1,8E-11 NM_024074 TMEM38A TTCACAGAATCCTGGCAGCAGCTCCAGTCAAGAATGTCACTGGTTGGCATGATATTCTTA -1,89 2,5E-10 NM_138569 C6orf142 CACTGTTCTAGCCTTTAATGCCTTCTACTTAATATTAAGCTGACCGCAATACTAACGTGC -1,90 3,4E-14 NM_032578 MYPN AAAGAAATCCTCTGTGGGGTCACTTTAAAAACTACTAGCTTCAACTACCACTTACAAAAT -1,90 3,5E-12 NM_003311 PHLDA2 TTTATTTCGCTGGTTCTTTGTAGTCACATATTTTATAGTCTTAATATCTTGTTTTTGCAT -1,90 2,8E-15 NM_000930 PLAT TGAACAACTAGGCTTCAGCATATTTATAGCAATCCATGTTAGTTTTTACTTTCTGTTGCC -1,90 9,8E-13 AK131277 B4GALNT3 TCACCCATGGTGCATTGGACACTGGATCTTGAACTCCAGAGTCTGTTTAGGGAGGTGAGC -1,91 4,5E-12 NM_001033602 KlAA0774 TTCTAACTTGTGCCTAAGAATTATTGGGAAATGAAAATGCATTTCTATCTAGCTTCCCAG -1,93 1,8E-09 NM_152888 COL22A1 GACCAGACACTTGGCAAATTTACCTCTTTCTTCAAAAGAAAAACTTTAAGAAAATGAGCC -1,93 2,1E-07 BC045778 LOC283824 TGAACTATCTGAAATTGACCAGTAATCAAAGTTCCAATCATCTGAATGCTTTTCCTTGAG -1,93 2,5E-12 NM_000290 PGAM2 ACTACAACTCCATTAGCAAGGAGCGTCGGTACGCAGGCCTGAAGCCCGGGGAACTCCCCA -1,93 4,1E-13 NM_003837 FBP2 CAGAGATGGTAGCTATGAGTATGCAAAAGGTAAATCCACTTAATCACATACAGAAGAGCA -1,94 1,9E-15 AK126298 AK126298 TTTGCCTCATTCCATACTGATCATCCCAGCTGAACAATTTGAAAACTGTTCTGCCTTTTT -1,94 1,1E-11 AB033021 FBXO40 ATGTGTGATGTCAAATCAAACTGAAATGAAGAATGAGATTGAGTATATCTGTGGTGACTG -1,94 1,7E-12 NM_153426 PITX2 AATAGTTTCTCTGGTGGATGCAATGATGTTTCTGAAACTGCTATGTACAACCTACCCTGT -1,95 8,0E-13 NM_006741 PPP1R1A GACCGCTGTCCCTTATTTCAACCCGTTAGCAACAATGGATAGAGAACACAGTGGCTATTA -1,96 1,6E-11 NM_003226 TFF3 TGTCCCTTTGCTCCCGGCAAGCTTTCTGCTGAAAGTTCATATCTGGAGCCTGATGTCTTA -1,97 9,8E-05 NM_000484 APP AGTGAAGATGGATGCAGAATTCCGACATGACTCAGGATATGAAGTTCATCATCAAAAATT -1,97 7,1E-11 AB016898 LOC653483 GCTGCTGCGTGTTTCTTCCAGGGTGATTCCTTTCCGCTGGGTCACTTCAAAGCCGACCTT -1,97 7,8E-13 NM_001958 EEF1A2 CTCTGGCAAGAAGCTGGAGGACAACCCCAAGTCCCTGAAGTCTGGAGACGCGGCCATCGT -1,98 2,8E-15 NM_000231 SGCG ATGTGCCAGTGAAAGTGTTTGGACAAAAACTACATGATCTCAAAATGCACGTGGATGTGA -1,99 5,4E-12 NM_005331 HBQ1 TGGAAAGGACCTTCCTGGCTTTCCCCGCCACGAAGACCTACTTCTCCCACCTGGACCTGA -1,99 1,1E-12 NM_147175 HS6ST2 TCCCATGATTTCAACTGTAAACATCTGTCCATTGGTGTAGCTTTACAAACCATTCACTGA -2,00 1,1E-14 NM_007174 CIT AGGAAGAGAACACAAGGAATGATTCAAGATCCACCTTGAGAGGAATGAACTTTGTTGTTG -2,00 1,1E-11 NM_153610 CMYA5 CATGTGAGCAAAATCGACAAGAAAACCTTGACTTTACAGAGCAGTGTGTGAGTAAACAGA -2,00 4,1E-16 NM_138370 LOC91461 GTGAGTTTACCAGCCTAGCTATGGGACTGCTGGCTCCTAGTCCAGGAATCATGGGGGTAT -2,01 8,7E-14 NM_018723 A2BP1 TGACAAAACCATAAAAACCTTCCAATGTGGGGAGAAAGGAAGCTTTCCGAGGCCTGAGTA -2,07 1,2E-10 NM_005609 PYGM AAGTCAGCGCCTTGTACAAGAACCCAAGAGAGTGGACGCGGATGGTGATCCGGAACATAG -2,08 3,5E-12 NM_007026 DUSP14 GTTTAATAAACTGGTTCTGCTCTCTTCTGAATCTCATGCCTTTGGCACCTTGGTAGGTGC -2,09 2,6E-13 NM_004165 RRAD TTTTTTCACAGCCCGGGTGTGCCTGCCCTGGAGGGAGGCTCTTCAGTGCGGTAGCTATTT -2,12 8,7E-16 NM_032854 COR06 ACTGGCATGAGGAGTTAGGTTCATCACAAATACACACACACTGCCCCCAACCCTCTGCCG -2,12 1,6E-10 NM_014476 PDLlM3 AAACATACACTTAGCTATGTTTTGCAACTCTTTTTGGGGCTAGCAATAATGATATTTAAA -2,15 1,2E-14 NM_006308 HSPB3 TTCCTGTTCAGATGACATGGGGAAGATGATGGTTCAGCCACTGGTACTACGAGAATGTTT -2,15 2,7E-15 ENST00000332074 ENST00000332074 AATGGAAGACAGTTCCCGACCTTCTACCCCACAGAGATCAGCTCATGAGAATCTCATGGA -2,16 1,0E-13 NM_014859 KlAA0672 TTTTGATGTTGCAGCTTTGCTCACTTCCTGGCAAGGGCAGGTCATGCCTCAATTTGTAAT -2,18 2,4E-16 NM_002469 MYF6 TTTTTTGGAACTGCGAGTGGCTTAGGTCTAGCCTCATTTTGTTTTTGTTTGGTTGGTTTT -2,20 6,3E-18 NM_000635 RFX2 AAGCTCACAGTTAACGGATTGTAATGCCCGGCTTTTCCTCACTCCTGGTAACCAATACAA -2,20 3,6E-14 NM_002200 IRF5 GAGCACTTAGGTATCATATCAGATGCTCAAGGCTGGCAGCTACCCCCTTCTTGAGAGTCC -2,22 1,7E-12 NM_013353 TMOD4 AGGCCATGACCCGAAACAATGAACTACGTCGCCAGCAAAAGAAGAGATAACACTGCATTT -2,23 4,3E-16 BC015836 BC015836 GGCTGGATTGTGGGCTGCATCATAATGATTTATGTTGTCTTCTCTTAGAAAGGCAAGAAG -2,23 8,1E-17 NM_001007271 DUSP13 GATTTCCCTGACCCAATTCAGAGATTCTTTATGCAAAAGTGAGTTCAGTCCATCTCTATA -2,24 1,2E-19 NM_006732 FOSB TTTTTACAATCTGTATCTTTGACAATTCTGGGTGCGAGTGTGAGAGTGTGAGCAGGGCTT -2,25 5,6E-14 NM_000517 HBA2 CACAGACTCAGAGAGAACCCACCATGGTGCTGTCTCCTGCCGACAAGACCAACGTCAAGG -2,26 2,7E-14 NM_006783 GJB6 AGAAGACCGTGTTTACCATTTTTATGATTTCTGCGTCTGTGATTTGCATGCTGCTTAACG -2,27 1,3E-16 NM_021116 ADCY1 AGAGTGATGTGGGCAAGGGTGTCAATTTTCTCGCACAATACAAACTCACTGAGGATGCTT -2,28 1,5E-13 NM_080874 ASB5 CAGATATTAAAGCTGCTTTTGGGTAAAACAGGTTTCCACCAGTATTTTCCCTGAGCTAGA -2,30 1,7E-14 ENST00000284767 ENST00000284767 TTAACTTAAACATAGGGATAATGGCAAGCCACTCATAATGTTGTCATTTGAAGATCACAC -2,31 5,8E-15 NM_024875 SYNP02L ACAGCATCTTGTGAAAGTTATGGAGCATGAAAAGACTGAAGGGCCAGGACAGTTTGCATG -2,32 3,0E-19 NM_004816 C9orf61 GAGGATTATTGTTGATTCCATTTACTCATGCTTGCAAAACTAGAGACCCCTAAGGCAGAA -2,32 1,3E-12 NM_004004 GJB2 GTCATAGCACCTAACAACATTGTAGCCTCAATCGAGTGAGACAGACTAGAAGTTCCTAGT -2,33 3,7E-16 NM_004660 DDX3Y CACTGATAGGAAGGTCCACATCCACAAAGTTTCTCTTGAGTTTTGTTATGTGTTTTGCTG -2,34 5,7E-14 NM_001007176 C8orf22 AAAGACTATCGCTGGAAGTGGCACTTGCTACCTGGTGCATCTTTGAAAAGTGTGCCTTTA -2,35 2,8E-15 NM_006790 MYOT TAACCCAGAAGGAGAATTTCAGCGTTTGGCAGCTCAATCTGGACTCTATGAAAGTGAAGA -2,38 1,8E-15 NM_032588 TRlM63 ACGATGTGCTGTATTTCAGTGTCTATCCCAGACATACGGGGTGGTAACTGAGTTTGTGTT -2,40 4,5E-15 NM_004533 MYBPC2 CCAAGACAATTGGTGGTGGAGTCCTGACCCCAATCCCCAACCTCCCAGGACTGTGTTCTT -2,40 2,4E-13 NM_021245 MYOZ1 GCAATGCCCTATGGTGGATATGAGAAGGCCTCCAAACGCATGACCTTCCAGATGCCCAAG -2,41 3,4E-10 NM_003063 SLN CAATATCTGCTATGCTGTAGTGCTAGGATTGATTATGTGTTCTCCAAAGATGCTGCTCCC -2,44 7,9E-16 NM_001976 EN03 CTCGGAGCGTCTGGCCAAATACAACCAACTCATGAGGATCGAGGAGGCTCTTGGGGACAA -2,52 4,9E-09 NM_001008 RPS4Y1 CAACTTTATCAAATTTGATACAGGCAATTTGTGTATGGTGATTGGTGGAGCCAACCTCGG -2,52 3,8E-10 NM_001039567 RPS4Y2 TGTTGGTGTGATCACAAACAGGGAAAGACATCCTGGTTCTTGCGATGTGGTACATGTGAA -2,56 1,4E-17 NM_033118 MYLK2 CAGGAGAATTAGGAAGGCCATGGGGCAGCCTCCAGTCTGCTCTCAGCTTGTGCCTTGTAA -2,56 3,6E-20 NM_006789 APOBEC2 ACAGCCTCAGACCCGAGGTTTAGATTTCTGAAATATGCATTTTATGTTAAGTTGGGTATT -2,57 2,7E-09 NM_004543 NEB TCTGCAGGACTTACAGATCCTGCAGTCAATGTTTCGGTTTAGACTCTCCACTGTTACCTA -2,67 1,4E-10 BC107798 TNNT1 TCCGAGCGTAAGAAGCCTCTGGACATTGACTACATGGGGGAGGAACAGCTCCGGGAGAAA -2,69 7,0E-21 NM_144994 ANKRD23 ACACACCTTTTTATACCAATCAGTATCCTCTGTTCATTAAAACTGGCTATCCATTAAAAA -2,71 2,8E-13 NM_000366 TPM1 GTGCTTTCTATTGTACAGAAGCTCTTCGTTTCAGTGTCAAATAAACACTGTGTAAGCTAA -2,75 3,7E-12 NM_006757 TNNT3 GACAAGGCCAAGGAGCTCTGGGAGACCCTGCACCAGCTGGAGATTGACAAGTTCGAGTTT -2,77 7,1E-13 NM_003280 TNNC1 CAGCGGCACGGTGGACTTTGATGAGTTCCTGGTCATGATGGTTCGGTGCATGAAGGACGA -2,98 3,1E-11 NM_003279 TNNC2 GACTTCGACGAGTTCCTGAAGATGATGGAGGACGTGCAGTAAGGAGTGGACAGTCGCCTC -3,14 2,9E-16 NM_005181 CA3 AGACAGCAAGAATTGAGCTAATAATATGTTTTAACTCTTAACACCAGCAAGAAGTCAGTC -3,20 4,1E-14 NM_003673 TCAP AGGCAAGGATGGTGGGGCCCCCAGCACCCTCTGTTAGTGCCGCAATAAATGCTCAATCAT -3,24 1,4E-20 NM_014332 SMPX GTGTGGTTTTGAGGAGGGATATGATTTTATGGAGAATGATATGGCAATGTGCCTAACGAT -3,27 2,3E-13 NM_133378 TTN CTGACAACCCTGATCATCATGGACGTACAGAAACAAGATGGTGGACTTTATACCCTGAGT -3,29 5,8E-15 NM_019885 CYP26B1 TTTGTTTTGATATGAAACTGGTACCGTGTGAGTGTTTTTGCTGTCGTGGTTTTAATCTGT -3,31 1,8E-14 NM_000432 MYL2 AAGGAGGCTCCGGGTCCAATTAACTTTACTGTGTTCCTCACAATGTTTGGGGAGAAACTT -3,52 5,2E-18 NM_006063 KBTBD10 GCTGGGATGTTGAAGGAAATACGTTATGCTTCAGGAGCTAGTTGCCTAGCAACACGTTTA -3,52 6,5E-17 NM_206819 MYBPC1 AGGATGCCACCATGACTAAAGAGAGTGCAGTGATCGCCAGGGATGGTAAAATCTACAAAA -3,64 6,1E-20 BX647448 CMYA3 TTTGAGGAACTTGATGTAAACATGGTGTTCAGAAATCTCGTGTCTATCTCAATGGGATAT -3,69 7,6E-16 NM_013292 MYLPF GAGGAGTTGGATGCCATGATGAAGGAAGCCAGCGGTCCCATCAACTTCACCGTCTTCCTG -3,81 2,8E-14 NM_198060 NRAP GGCCAGAGAGGAAGTTTGTTCACCAGAGACAGGCTTCAGATGGCTTTGATTTCGGCAAGC -3,96 8,9E-17 NM_003282 TNNI2 GGAGCGGGACCTGCGAGACGTGGGTGACTGGAGGAAGAACATCGAGGAGAAGTCTGGCAT -4,25 1,4E-20 NM_001103 ACTN2 TCCCATCAGAATGCAATAAAAGCGGAAGTCACAGTTTGTTTCCTGGAAACTTTGACAAGC -4,33 5,5E-18 NM_003476 CSRP3 TATGTGTTTCTCCTCAGAAGTGATCAGGTCTTTACTGAATGTTAGAAGAGGCCTTTGGAA -4,69 4,6E-14 NM_005963 MYH1 TTATCTAACTGCTGAAAGGTGACCAAAGAAATGCACAAAATGTGAAAATCTTTGTCACTC -5,01 1,6E-16 NM_079422 MYL1 AGAAAATTGAGTTTGAACAATTTCTGCCTATGATGCAAGCCATTTCCAACAACAAGGACC -5,43 1,7E-17 NM_203377 MB GGAGTTCATCTCGGAATGCATCATCCAGGTTCTGCAGAGCAAGCATCCCGGGGACTTTGG -8,36 8,1E-16 NM_000257 MYH7 CCGTGACATTGGCACGAAGGGCTTGAATGAGGAGTAGCTTTGCCACATCTTGATCTGCTC -12,08 2,6E-18 NM_001824 CKM ACACTCGGAGCTTGTGCTTTGTCTCCACGCAAAGCGATAAATAAAAGCATTGGTGGCCTT -12,49 1,1E-17 NM_017534 MYH2 CGGGAGGTTCACACAAAAGTCATAAGTGAAGAGTGATCATGTCCTGATGCCATGGAATGA -15,31 2,5E-18 NM_001100 ACTA1 CCGCAGTCACTTTCTTTGTAACAACTTCCGTTGCTGCCATCGTAAACTGACACAGTGTTT \n TABLE-tabl0004 Table 4. Transcripts displaying a more then 2 fold differential expression between SpA and RA in synovial tissue (FC: fold change). FC p.value Systematic Name Gene Probe Sequence 7,14 1,0E-21 NM_001192 TNFRSF17 GATCTCTTTAGGATGACTGTATTTTTCAGTTGCCGATACAGCTTTTTGTCCTCTAACTGT 6,97 4,7E-18 AY172962 AY172962 AAGATAGCAGCCCCGTCAAGCGGGAGTGGAGACCACCACACCCTCCAAACAAAGCAACAA 6,96 1,0E-21 NM_144646 IGJ TTGGGTGATGTAAAACCAACTCCCTGCCACCAAAATAATTAAAATAGTCACATTGTTATC 6,28 1,9E-19 NM_006235 POU2AF1 TTTTCTGGGAAATGACTTTTCTGGGAAATGACAGTTTCTTTGACATATTTTCTTTGCCCA 5,80 1,1E-19 B1521983 B1521983 GAAGTCACTTATGAGACACACCAGTGTGGCCTTGTTGGCTTGAAGCTCCTCAGAGGAGGG 5,72 5,5E-19 AW136683 AW136683 TCTGTCATAAGTGTAGCAGGTCTCTGTAGCACTGTCTTCATCACAGATATTGCTCTGGGT 5,66 5,6E-18 X57802 X57802 ATTCTCTGGCTCCAACTTTGGGAACACAGCCACTCTGACCATCAGCGGGACCCAGGCTAT 5,47 1,1E-17 NM_020070 lGLL1 TCCAAGCCAACAAGGCTACACTGGTGTGTCTCATGAATGACTTTTATCCGGGAATCTTGA 5,33 1,4E-17 NM_001013618 CTA-246H3.1 AACAAGGCCACACTGGTGTGTCTCATGAATGACTTCTATCTGGGAATCTTGACGGTGACC 5,15 9,4E-18 NM_014792 KlAA0125 CCATTTTAAAGATGGCTACTTAGGACCATATGGATGTTGTACTGATGTCATTTGACCACG 5,15 1,0E-21 NM_198440 DERL3 AGGCCTAAGAGGCTTCTGGCAGCTTCCATCCTACCCATGACCCCTACTTGGGGCAGAAAA 4,92 1,3E-18 NM_031281 FCRL5 TGGCATATGGACTGAAAGAAACTATGCTATTGGATCTCCTGGATCTCCAGCTTGCTGACT 4,80 4,2E-16 ENST00000216649 ENST00000216649 CTCAAGAGTCGAGTCACCATATCAGTGGACACGTCCAAGAACCAGTTCTCCCTGAGGCTG 4,70 1,0E-19 NM_006419 CXCL13 CAAGAGGCAAAGGAATCCATGTAGTAGATATCCTCTGCTTAAAAACTCACTACGGAGGAG 4,67 1,3E-18 ENST00000377233 ENST00000377233 TTGTATTGGTACCTGCAGAAGCCAGGCCAGCCTCCACAGCTCCTGATCTATGAAGTTTCC 4,53 2,8E-14 NM_016459 PACAP GGACATGTTTGCACTACTTGGGGGAGTTTGGAGAAGACCAGATCTATGAAGCCCACCAAC 4,48 9,4E-18 AF076205 AF076205 CCTCCAGTCTGAGGATGAGGCTGACTATTACTGTCAAACCTGGGGCACTGGCATTGGGGT 4,39 3,1E-17 ENST00000327926 ENST00000327926 TATTTGAATTGGTACCTGCAGAAGCCAGGCCAGTCTCCACAGCTCCTGATCTATGAGGTT 4,38 0,0E+00 NM_006228 PNOC GCCACTGCCATAACTTGTTTGTAAAAGAGCTGTTCTTTTTGACTGATTGTTTTAAACAAC 4,35 5,4E-14 BC073764 IGKC TCAGGGTATTAGCAGCTGGTTAGCCTGGTATCAGCAGAAACCAGAGAAAGCCCCTAAGTC 4,29 4,3E-19 ENST00000379877 ENST00000379877 GTGCAGCTGCAGGAGTCGGGCCCAGGACTGGTGAAGCCTCCGGGGACCCTGTCCCTCACC 4,27 3,1E-16 BX110985 BX110985 CTCTGTGGGGTAGAGATGAAAAGGCTCACTCAGTTCCAGCCCCTGCAGATCCCCCAGGAC 4,24 7,2E-17 BC070333 IGHV1-69 CAGGCCCCTGGACAAGGGCTTGAGTGGATGGGAAGGATCATCCCTATCCTTGGTATAGCA 4,19 0,0E+00 THC2347909 THC2347909 GGAAATGATGTTTGTCTAAAATGGCCAGAGACAACTTTTATAAGCTTCCAGGAAGTGGAG 4,16 1,4E-11 ENST00000377226 ENST00000377226 GAAAGCTCCTAAGCTCCTGATCTATGATGCCTCCAGTTTGGAAAGTGGGGTCCCATCAAG 4,15 7,0E-20 NM_000582 SPP1 TTCCACAGCCATGAATTTCACAGCCATGAAGATATGCTGGTTGTAGACCCCAAAAGTAAG 4,10 5,9E-11 ENST00000259219 ENST00000259219 TGATCTATGCTGCATCCAGTTTGCAGTCGGGGGTCCCATCTCGGTTCAGTGGCAGTGGAT 4,08 4,5E-17 ENST00000312946 ENST00000312946 GGGCAGTCTCCACAGCTCCTGATTTATAGGGTTTCCAATCATCTTTCTGGGGTCCCAGAC 4,06 7,3E-15 BC012876 BC012876 TCTGACACCTCAGCCTCCCTGGCCATCACTGGACTCCAGGCTGAAGATGAGGCTGATTAT 3,86 4,3E-18 NM_014479 ADAMDEC1 TGACTTAGTTCTGCCCTTTGGAGAACAAAAGAAAGCAGTCTTCCATCAAATCACCTTAAA 3,80 0,0E+00 NM_002460 lRF4 TTTTGTATTGATTTTCACAGCTTTGAGGAACATGCATAAGAAATGTAGCTGAAGTAGAGG 3,75 2,3E-17 NM_012390 SMR3A CACCCTATGGTCCAGGGAGAATTCAATCACACTCTCTTCCTCCTCCTTATGGCCCAGGTT 3,66 1,3E-14 AF063695 AF063695 CTGTCAGGTGTGGGATAGTACTAGTGATCATTATGTCTTCGGAACTGGGACCAAGGTCGC 3,63 1,2E-20 BC009479 TTLL3 GCTATATCCGCTTTTCCACGCAGCCCTTCTCCCTGAAGAACCTGGACAAGTGAGCCCCTC 3,63 9,1E-18 X57818 X57818 ACCCTCAGTGTCCGTGTCCCCAGGACAGACAGCCAGCATCACGTGCTCTGGACATAAATT 3,63 4,0E-21 AJ252276 AJ252276 AGATGGTGAAACAATATACGCAGAGAAGTTCCAGGGCAGAGTCACCATAACCGCGGACAC 3,62 7,1E-14 AY998685 AY998685 AATAAGAACTACTTAGTTTGGTACCAGCAAAGACCAGGACAGCCTCCTAAAATGCTCATT 3,55 4,8E-20 NM_017773 LAX1 TCGCACATGACTGTTTATAGCAGCTTCATTCATAATTACCAAAAACTAGAAATAACCCAG 3,54 8,5E-13 A_24_P384604 A_24_P384604 GGTTCAATGGCAGTGGGTCAGGCACTGATTTCACACTGAAAATCAGCCGGGTGGCTGAAG 3,53 1,8E-10 ENST00000328419 ENST00000328419 AGCCTGATGCCTGAACAGTGGAGATCCCGCAGCAGCTACAACTGCTGGGCCATGCATAAA 3,51 2,6E-13 ENST00000379884 ENST00000379884 ACACAGTCTACATGGAGCTGAGAAGCCTGAGATCTGAGGACACGGCCGTGTATTACTGTG 3,51 5,1E-14 ENST00000331195 ENST00000331195 ATACTGGTACCAGCAGCTCCCAGGAACGGCCCCCAAACTCCTCATCGAAAGGAATAATCA 3,50 5,9E-13 ENST00000360623 ENST00000360623 TCTCAGTTATTTATAGCTGTGGTAGCACATACTACGCAGACTCCGTGAAGGGCCGATTCA 3,47 5,3E-15 THC2428956 THC2428956 CATAGTTATAACCACCAACGTCACTGCTGGTTCCAGTGCAGGAGATGGTGATCGACTGTC 3,46 6,5E-11 ENST00000295410 ENST00000295410 GACAGAGTCACCATCACTTGTCGGGCGAGTCAGGGAATTAGCAATTATTTAGCCTGGTTT 3,45 6,1E-14 AJ399872 AJ399872 CAGTTTATTACTGTCAGCAGCGTCGCAATTGGCCTTCTTTCGGCGGAGGGACCCAGCTCA 3,42 1,2E-15 D83692 D83692 ACAACAGAATACGCCGCGTCTGTGAAAGGCAGATTCACCATCTCAAGAGATGATTCCAAA 3,41 2,9E-17 ENST00000361266 ENST00000361266 TGCAATCTGGGTCTGAGTTGAAGAAGCCTGGGGCCTCAGTGAAGGTCTCCTGCAAGGCTT 3,35 3,1E-16 ENST00000360329 ENST00000360329 ACATTGGGAAGGGATGGAGGATGGACGGAGGAAGGACGTGCAGTTGCAGCTCTTTCTGCA 3,35 1,0E-21 NM_018456 EAF2 CAGGATTCCTGATATAGATGCCAGTCATAATAGATTTCGAGACAACAGTGGCCTTCTGAT 3,30 2,0E-11 ENST00000379895 ENST00000379895 ATGGTATGATGGAAGTAATAAATACTATGCAGACTCCGTGAAGGGCCGATTCACCATCTC 3,27 2,0E-14 BC023973 IGLV6-57 AACTCTGCCTCCCTCACCATCTCTGGACTGAGGACTGAGGACGAGGCTGACTACTACTGT 3,27 8,0E-15 XM_372630 LOC390712 CTGTGAAGGGCAGATTCACCATCTCCACAGACAACTCAAAGAACACGCTCTACCTGCAAA 3,26 2,5E-16 AF103312 AF103312 AATGAACAGCCTGAAAACCGAGGACACGGCCATGTATTACTGTACTAGCGCGCCAAATAT 3,25 4,9E-18 NM_006875 PlM2 GGTGAGGGGACCCTACTTTGTTATCCCAAGTGCTCTTATTCTGGTGAGAAGAACCTTAAT 3,25 6,4E-16 AB063923 AB063923 CCTCAGTGAAGGTCTCCTGCAAGGCTTCTGGTTACACCTTTACCAGTCATGGTATCACCT 3,24 7,8E-12 NR_001564 XIST AATATTTCAATGCCTATTCTCTGCAAGGTACTATGTTTCGTAAATTAAATAGGTCTGGCC 3,22 1,8E-13 ENST00000328018 ENST00000328018 CAATAGCCTGGAAGCTGAAGATGCTGCAACGTATTACTGTCATCAGAGTAGTAGTTTACC 3,22 2,8E-11 ENST00000359488 ENST00000359488 TAGGAGACAGAGTCACCATCACTTGCCGGGCAAGTCAGACCATTAGCAGCTATTTAAATT 3,21 1,2E-11 BX640624 IGHA1 TCGGTGATCAGCACTGAACACAGAACTCACCATGGAGTTTGGACTGAGCTGGGTTTTCCT 3,21 1,5E-11 ENST00000283657 ENST00000283657 GGCCACCATCAACTGCAAGTCCAGCCAGAGTGTTTTATACAGCTCCAACAATAAGAACTA 3,20 1,5E-12 AF471475 AF471475 ACATTAGTGATAGTGGTAGTACCATGTATTACGCAGACTCTGTGAAGGGCCGATTCACCA 3,19 9,1E-15 BC095489 IGKC ACATCCAGATGACCCAGTCTCCATCCTCCCTGTCTGCATCTGTAGGAGGCAGAGTCACCA 3,18 3,2E-11 XM_942451 LOC652791 GCACAAGCTACGCAGACTCCATGAAGGGCCAATTCACCATCTCCAGAGACAATGCTAAGA 3,18 9,5E-16 L04336 L04336 GTTTCCTGCAAGGCTTCTGGATACACCTTCACTAGCTATGCTATGCATTGGGTGCGCCAG 3,17 1,1E-17 NM_017709 FAM46C CCTATCCACATCTTTCCAAGATAGACACTAACATGTCATGTCCCAAACATTAGCACGTGG 3,17 1,0E-21 NM_000096 CP TCACGGCCATAGCTTCCAATACAAGCACAGGGGAGTTTATAGTTCTGATGTCTTTGACAT 3,17 1,6E-11 BC034142 IGKV1-5 GATTTTACACTGAAAATCAGCAGAGTGGAGGCTGAGGATGTTGGGGTTTATTACTGCATG 3,15 2,8E-19 NM_033014 OGN AACTAATGATCACAGCTATTATACTACTTTCTCGTTATTTTGTGTGCATGCCTCATTTCC 3,12 5,9E-19 NM_012261 C20orf103 AGAAAACGACTAATGTAACTATGCAGAGTTGTTTGGACTTCTTCCTGTGCCAGGTCCAAG 3,11 6,7E-15 AF035035 LOC647460 GTCTGAAGATTTTGCAACTTATTACTGTCAACAGTATTATAGTTTCCCTCCGACGTTCGG 3,11 1,3E-13 A_24_P204574 A_24_P204574 GAGGATGAGGCTGATTATTACTGTGCAGCATGGGATGACAGCCTGAGTGGTCCCACAGTG 3,11 1,4E-19 NM_033280 SEC11 L3 TTCAAGTATGCTCTTTTGGCTGTAATGGGTGCATATGTGTTACTAAAACGTGAATCCTAA 3,09 2,0E-21 NM_012081 ELL2 TGTCTTTTCAAAGTGCTGCCAGTTGAAAAGGGAAGCATTATGTTTACAAATCTGTTTTGA 3,09 6,5E-11 ENST00000379879 ENST00000379879 CTTCAAATGAACAGCCTGAGAGCCGAGGACACGGCCGTGTATTACTGTGCGAGAGACACA 3,08 2,7E-18 NR_001442 FER1L4 GAAGTCTTTCTTACCCATGTGAGCTACCCCAGAGTCTAGTGCTTCCTCTGAATAAACCTA 3,06 2,3E-08 NM_001040077 IGHG1 TGAATGGCAAGGAGTACAAGTGCAAGGTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGA 3,06 5,6E-15 AF267875 AF267875 TGAGGACGAGGCTGACTACTACTGTCAGTCTTATGATAGCAGCATCGGGAATGTGATATT 3,03 5,1E-14 U21252 U21252 CCAGAGATGATTCCAAGAACACGGCGTATCTGCAAATGAACAGCCTGAAAACCGAGGACA 3,03 1,0E-08 NM_005570 LMAN1 TTGACTACCATTTTCCTGTGTACTTCATCTATTTGTGTACAAAATGATGTCGTTTTGAGG 3,03 2,7E-17 NM_001006946 SDC1 ACCCTGGGCCCTGGGCTGGAATCAGGAATATTTTCCAAAGAGTGATAGTCTTTTGCTTTT 3,02 7,4E-10 Y11328 Y11328 GTGGCACATACTATGCAGACTCCGTGAAGGGCCGATTCACCATCTCCAGAGACAATGCCA 3,02 8,6E-11 ENST00000360102 ENST00000360102 TGGGTCCGCCAGGCTCCAGGGAAGGGACTGGAGTGGGTTTCATACAGTAGTGGTAATAGT 3,01 1,4E-15 A_24_P203886 A_24_P203886 ATCTCCTGCAGGTCTAGTCGCAGCCTCCTGCATAGTAATGGAAACACCTATTTACATTGT 3,00 3,9E-18 NM_006398 UBD ATTTGGGTGGGATGGGTAGGATGAAGTATATTGCCCAACTCTATGTTTCTTTGATTCTAA 3,00 9,3E-10 ENST00000383048 ENST00000383048 AGTTTGGGCTGAGCTGCCTTTTTCTTGTGGCTATTTTAAAAGGTGTCCAGTGTGAGGTGC 2,99 5,7E-18 NM_005079 TPD52 AACTGCTTACTCAACACTACCACCTTTTCCTTATACTGTATATGATTATGGCCTACAATG 2,99 2,0E-16 X01147 X01147 TGGGCATCACCGGACTCCAGACTGGGGACGAGGCCGATTATTACTGCGGAACATGGAATA 2,98 8,9E-14 NM_000450 SELE GATGTGATAAGGATCAGAACAGCAGAGGTTCTTTTAAAGGGGCAGAAAAACTCTGGGAAA 2,97 4,2E-19 AF343666 AF343666 GGAGGAACCTCTTGGAGAAGCCAGCTATGCTTGCCAGAACTCAGCCCTTTCAGACGTCAC 2,97 4,4E-15 AK026408 AK026408 TACTGTGGTACATGGCACAGCAACTCTAAGACTCACACAGTGCTCCAGACCCATGAGGAA 2,96 1,9E-15 THC2321023 THC2321023 GGTGCCTTCCAGCCTGACCCCTCCTCTGAGCACCACCTGCCAGTGTGACAGCTCCATCTG 2,94 2,6E-10 ENST00000307840 ENST00000307840 GCAGCCTGCAGCCTGAAGATATTGCAACATATTACTGTCAACAGTATGATAATCTCCCTC 2,94 3,8E-14 AF067420 IGHA1 TCTATGATAGTAGTGGTCCCTTTGACTACTGGGGCCAGGGAACCCTGGTCACCGTCTCCT 2,94 1,4E-12 AY003763 AY003763 GCTACAAGTTTGACTACTGGGGCCAGGGAACCCTGGTCACCGTCTCCTCAGCATCCCCGA 2,93 6,3E-14 BC008026 MGC16025 GCCTCTGACCCTGATGAAATAGCTTCGGTGGCATTTGCATCAAGATCATGTTAGTGTCAT 2,92 2,4E-13 BC032451 BC032451 AGCAGCTCCTTAGCCTGGTACCAGCAGAAACCTGGCCTGGCGCCCAGGCTCCTCATCTAT 2,92 7,7E-15 ENST00000354689 ENST00000354689 CTGTGAAAGGCAGATTCACCATCTCAAGAGTTGATTCAAAAAACACGCTGTATCTGCAAA 2,92 3,2E-15 ENST00000358917 ENST00000358917 AGGGGAAGGACTGTGTCCCTGTGTGATGCTTTTGATATCTGGGGCCAAGGGACAATGGTC 2,91 4,1E-11 AB063751 AB063751 CTGGATTCATCTTCAGTAATTACACCATGAACTGGGTCCGCCAGGCTCCAGGGAAGGGGC 2,89 7,0E-21 NM_000439 PCSK1 GAGTTTAACATGTGTGGTCTTGGTATTCTTAAGGGAACTTCCACATTATACATTTGATGT 2,88 5,2E-16 BC022362 CAGCAGAGGCCAGGCCAATCTCCAAGGCGCCTAATTTATAAGGTTTCTAACTGGGACTCT 2,87 6,8E-16 NM_001040075 LOC651928 TGCTAATGCTCTGGGTCCCTGGATCCAGTGGTGATATTGTGATCGCCCAGACTCCACTCT 2,87 8,4E-20 NM_002281 KRT81 TTGAAAGACCCCTCCCACTCCTGGCCTCACATTTCTCTGTGTGATCCCCCACTTCTGGGC 2,86 5,4E-14 NP102468 NP102468 TTACCATCAGTAGCCTGGAAGCTGAAGATGCTGCAACATATTACTGTCAGCAGGGCAATA 2,86 5,0E-21 NM_001775 CD38 TGAAAAATCCTGAGGATTCATCTTGCACATCTGAGATCTGAGCCAGTCGCTGTGGTTGTT 2,85 1,9E-11 AF035034 AF035034 GCAGGGTGGAGGCTGAGGATGTTGGGGTTTATTACTGCATGCAAGGTACACACTGGCCTC 2,85 7,9E-11 BC024289 BC024289 GCCAAGAACACGCTGTATCTGCAAATGAACAGTCTGAGAGCCGAGGACACGGCTGTGTAT 2,84 5,5E-10 AF471454 AF471454 ATGCAGACTCCGTGAAGGGCCGATTCACCATCTCCAGAGACAATTCCAAGAACACGGTGT 2,83 3,9E-13 A_24_P110487 A_24_P110487 CAGGATTTTATGGTGATAGTGGTTACACAAACTACGCAGACTCTGTGAAGGGCCGATTCA 2,82 7,4E-14 Z18824 Z18824 CTCCAGGGAAGGGGCTGGAGTGGGTTTCATACATTAGTAGTAGTAGTAGTACCATATACT 2,82 1,0E-21 NM_002610 PDK1 TGGACACGAAGTGATTTTTGTAACCTGAGCAGTTAATGAATGTGCCAACATTTTCTAGGA 2,82 5,1E-14 NM_002922 RGS1 GAAGTCCCATTAACTTAAAGTATATGTTTTCAAATTGCCATTGCTACTATTGCTTGTCGG 2,81 1,0E-13 AJ245002 AJ245002 TTTGACTGGTTATTATAGAAGGGGGTTTGACTACTGGGGCCAGGGAACCCTGGTCACCGT 2,80 1,7E-12 XM_496145 LOC440361 ATTAAAAGGTGTCCAGTGTGAGGTTCAGCTGGTGCAGTCTGGGGGAGGCTTGGTACATCC 2,79 1,4E-12 NM_006274 CCL19 AGTGTGAGTGTGAGCGAGAGGGTGAGTGTGGTCAGAGTAAAGCTGCTCCACCCCCAGATT 2,78 1,8E-08 NM_002416 CXCL9 TGTGACCCACTTACCTTGCATCTCACAGGTAGACAGTATATAACTAACAACCAAAGACTA 2,78 2,2E-09 AK128476 IGHA1 TGCTGAGTTGGGTTTTCCTTGCTGCTATTTTAAAAGGTGTCCAGTGTGAGGTGCAGCTGG 2,76 1,8E-14 NM_021181 SLAMF7 GGAGACCTCCCTACCAAGTGATGAAAGTGTTGAAAAACTTAATAACAAATGCTTGTTGGG 2,75 1,7E-10 AJ519285 AJ519285 CAATTCCAAGAACACGCTGTATCTGCAAGTGAACAGCCTGAGAGTCGAGGACACGGCCCT 2,75 2,3E-16 BX648200 BHLHB8 CCCGTGCCCCCACTGTAATTGTGCTGAAAATGTTTCTCAAATGACCCAAATTGGCTCTTA 2,75 3,4E-16 AK000347 LAX1 ATTTGTAATTTTGTAAACCCTGTCTCTCATATTTTGTAAAAATACCAAAATTAGCGGTGG 2,73 9,7E-17 DB362335 DB362335 CATCTTCCATTCCTTCCCAAATTATGGAAGTAAGGTTCTTCTCACCAGAATAAGAGCACT 2,72 5,3E-17 NM_001770 CD19 TACATGCCAGTGACACTTCCAGTCCCCTTTGTATTCCTTAAATAAACTCAATGAGCTCTT 2,72 4,6E-15 NM_003116 SPAG4 CGATTTCGCGGTCTTTGGCCTCCAGGTTTATGATGAAACTGAAGTTTCCTTGGGGAAATT 2,71 5,5E-16 CR621698 CR621698 ATGTTGCTCCCCTCTAGTCACTAAGATGCCACATATTTCTACTTGAGTGAACAGATTGCA 2,70 5,6E-07 BC067092 IGKC TCACTATCAGCAGCCTGCAGCCTGAAGATTTTGCAACTTACTATTGTCAACAGGCTAACA 2,69 2,3E-07 ENST00000331696 ENST00000331696 CAGCAGCCTGCAGCCTGAAGATTTTGCAGCTTATTACTGTCAACAGAGTGACAGTACCCC 2,68 2,6E-05 BC030813 BC030813 GTGGGTCTGGGACAGAGTTCACTCTCACCATCAGCAGCCTGCAGTCTGAAGATTTTGCAG 2,66 3,8E-15 NM_001783 CD79A TGATTGTAGCAGCCTCGTTAGTGTCACCCCCTCCTCCCTGATCTGTCAGGGCCACTTAGT 2,63 3,3E-18 NM_012328 DNAJB9 ATTTCTTTCTTAGTTGTTGGCACTCTTAGGTCTTAGTATGGATTTATGTGTTTGTGTGTG 2,61 3,4E-15 AF035040 AF035040 CACCCTTAACTGGGGATACGAAAAAGATGATGCTTTTGATATCTGGGGCCAAGGGACAAT 2,59 1,5E-18 NM_005080 XBP1 CCTTTTTGGCATCCTGGCTTGCCTCCAGTTTTAGGTCCTTTAGTTTGCTTCTGTAAGCAA 2,58 7,6E-16 NM_001077 UGT2B17 TTTCCTGCGACAAAACGTCTTTTCACAACTTACCCTGTTAAGTCAAAATTTATTTTCCAG 2,58 4,5E-16 NM_007029 STMN2 TATAATGGATCATGCGATATCAGGATGGGGAATGTATGACATGGTTTAAAAAGAACTCAT 2,54 3,1E-14 ENST00000327436 ENST00000327436 CTGGAGTGGATGGGGAGCATCTATCCTGGGAACTCTGATACCAGATACAGCCCATCCTTC 2,52 8,9E-17 NM_152866 MS4A1 GAGCTCACACACCATATATTAACATATACAACTGTGAACCAGCTAATCCCTCTGAGAAAA 2,48 4,1E-07 ENST00000295339 ENST00000295339 AGCAGCCTGCAGCCTGAAGATTTTGCAGTTTATTACTGTCAGCAGGATTATAACTTACCT 2,48 5,7E-15 BC031698 FLJ40330 AAACCTTCAAGCTGAGTGCAGAAAGCGCCGTCTTTTACTAGAAGACAGTAAAAGGTTGGT 2,48 4,8E-16 NM_005409 CXCL11 TAAGAAAGGCTGGTTACCATCGGAGTTTACAAAGTGCTTTCACGTTCTTACTTGTTGTAT 2,45 1,6E-09 NM_003299 HSP90B1 AAGAGATTTTCCTGAGAGAACTGATTTCAAATGCTTCTGATGCTTTAGATAAGATAAGGC 2,44 1,1E-13 NM_001870 CPA3 GCCAAGTATATCCTCAAGCATACTTCCTAAAGAACTGCCCTCTGTTTGGAATAAGCCAAT 2,40 1,5E-14 ENST00000283694 ENST00000283694 GAGCTTGGGTGGATGGGACGGATCAACCCTAACAGTGGTGGCACAAACTATGCACAGAAG 2,39 9,7E-18 NM_015187 KlAA0746 CTGCTAAGGTAGTGAATAAATCAGTAATGCAATATTGTGGGTCCAAACTACTCTTTGCAC 2,39 5,5E-18 NM_021928 SPCS3 GAATGTCACTTTGACCCTGTCTTGGAACGTCGTACCAAATGCTGGAATTCTACCTCTTGT 2,38 4,8E-15 AW977527 AW977527 GATAAGACATCATTTCCTGCACTACTGGACACACTCAATGAGGTAACTGTTGTTGAACAA 2,38 1,4E-06 ENST00000310579 ENST00000310579 GCAGATTACACTCTCACCATCCGCAGCCTGCAGCCTGAAGATTTTGCAAATTATTACTGT 2,36 1,8E-08 THC2275252 THC2275252 GTCACCGACCCGCCCTTACTCACATGCCTTCCAGGTGCAATAAAGTGGCCCCAAGGAAAA 2,36 1,7E-14 NM_005065 SEL1L CATTATTTCAGTGTGCATAAGTTCTTAATGTCAACCATCTTTAAGGTATTGTGCATCGAC 2,35 6,4E-11 BC018749 IGLV2-14 CATCACTGGTCTCCAGGCTGAGGACGAGGCTGATTATTACTGCAGCTCATATACAAGCAG 2,34 3,6E-08 AY062331 AY062331 AGCCTGAAGATTTTGCAGTTTATTACTGTCAGCAGCGTAGCGCCTGGCCTCTCACTTTCG 2,34 1,6E-16 NM_016594 FKBP11 TTCTCACTTGGCCTATGGAAAACGGGGATTTCCACCATCTGTCCCAGCGGATGCAGTGGT 2,33 1,7E-12 NM_021777 ADAM28 CTTAGAAGCTTCGAACTCAAAATCATGGAAAGGTTTTAAGATTTGAGGTTGGTTTTAGGG 2,32 6,2E-18 NM_002201 lSG20 CAGGGACTAGAGGCTTTCGGCTTTTTGGGACAGCAACTACCTTGCTTTTGGAAAATACAT 2,32 1,9E-17 DQ100868 DQ100868 GAATGATGATAAGCGCTACAGCCCATCTCTGAAGAGCAGGCTCACCATCACCAAGGACAC 2,32 2,4E-10 NM_002078 GOLGA4 GTGAAATGGAGCAAAAAGTAAAATCTTTAACCCAAGTCTATGAGTCCAAACTTGAAGATG 2,29 6,1E-13 NM_144616 JSRP1 GAGAGGCCTCGGAGAGAGGGGAAGCCGCGGAAGGAGAAGCCGCGGAAGGAGGAGAGACCT 2,28 2,1E-09 NM_001884 HAPLN1 GCTTCGTGGGTTTCCCAGATAAAAAGCATAAGCTGTATGGTGTCTACTGCTTCAGAGCAT 2,28 2,6E-12 NM_003123 SPN TCCTCACCCACCTCTTCACTCTGAATCCTCATGAGGCTTCTCAGCCCTGGATTTCCTGCT 2,28 1,7E-15 BC107852 BC107852 GAGGAAAACAACGCCCCAGCTGGGAAGCCTGAGAACACTTAGCCTTCATGAGTGTCCCCA 2,27 1,4E-15 AK074473 C20orf82 TATCATTCTGCTAAACGGCCCCAAAACAGTAGAATTTCTGCTCATGTCCTAGCAGGTTCA 2,27 6,9E-18 NM_014333 IGSF4 GAAAGAGTACTTCATCTAGATCAGCCTTTTTGTTTCAATGAGGTGTCCAACTGGCCCTAT 2,26 8,9E-17 NM_022567 NYX GAAGTCCTTTGTTTTCTACCACAATCCTCCTCCTCCTCTCCAGGGGCCTGGAAACACTAG 2,26 1,1E-14 NM_015208 ANKRD12 TCATCCCTGAAACATCAAATTCTGATATGCAAACCAAAAAGGAATATGTAGTTTCAGGTG 2,25 1,4E-17 ENST00000379969 ENST00000379969 TTTTCAGTTGTTACAGAGCTCAGCAGCTGTGGTTGCCCCTGTTCTACACCAATTTCAGTT 2,25 2,6E-17 NM_198491 FAM92B AGGGATCTACTGGATTTTAGAGCCAAGATGCAAGGAGTTTATGGGCATTATGACACTCGG 2,24 2,2E-15 THC2404289 THC2404289 AAGCTAATGCGAAATCATTTCTCTCTGATTTACCTGAGGAGGTTAACAAGGACCCATCAA 2,24 2,2E-09 NM_002345 LUM TTTTTATTTCTACTGTCAAATGATGTGCAAAACCTTTTACTGGTTGCATGGAAATCAGCC 2,24 5,0E-17 NM_030926 ITM2C ACTCTTAAATGCTTTGTATATTTTCTCAATTAGATCTCTTTTCAGAAGTGTCTATAGAAC 2,23 8,8E-18 CR620293 CR620293 CAACAAAGGAGCGTCACTTGGATTTTTGTTTTCATCCATGAATGTAGCTGCTTCTGTGTA 2,23 1,3E-15 L06610 L06610 TGAGAGGAAAGTTCTTCACCATGGACTGGACCTGGAGGGTCTTCTGCTTGCTGGCTGTAG 2,23 1,5E-15 ENST00000321715 ENST00000321715 TCCGGCTTCTTCGTCTTCAGCCGCCTGGAGGTGACCAGGGCCGAATGGGAGCAGAAAGAT 2,22 5,4E-15 NM_030776 ZBP1 ATGTTTGAGTCCCAACAAAATTCATATCAAAACATAATCCCAACTGGGTGCAGTGGCTCA 2,21 3,2E-15 NM_033285 TP53INP1 GGGAGGTTAGATGTGTGTTTCAGGCTTGGAGTGTATGAGTGGTTTTGCTTGTATTTTCCT 2,21 3,9E-15 NM_006280 SSR4 GCCTCCTCAGGAAGGCTCAGAGGAATAACGAGGACATTTCCATCATCCCGCCTCTGTTTA 2,21 2,2E-14 NM_182568 FLJ36492 CTCATAGGCATCAGAAAGAAAAGGATCTCTTTCATGAAAATTGCATGTTGCAGGAAGAAA 2,20 7,2E-14 NM_013244 MGAT4C TAGATGTTGGGGAAAACGTTATGCCTAGCAAACAAAGGAGACAATGTTCTAGTTACTTAA 2,20 4,6E-17 NM_024641 MANEA AGATTTGTGGTTACCTATACCACGCTAGGTGTTTTGACATGTTTAGTGTTTCTGCTTTAC 2,18 2,8E-15 NM_001012978 NGFRAP1L1 TCTTGAGGTTAATAATCATAAAATCCCTGCTTTCTAAATTCGCATTTTTCCTGGTGTACC 2,18 6,9E-09 ENST00000322032 ENST00000322032 GTAAACCCACCCACATCAATGTGTCTGTTGTCATGGCGGAGGCGGATGGCACCTGCTACT 2,18 3,7E-15 NM_014383 ZBTB32 AGGAGCGAAGGTTAACAGTAGGGGAGATTGTCGATCTCATCACCATAATAAAGAGTTTCC 2,18 5,1E-14 NM_013250 ZNF215 AAGTTGCAGTTCCTAAGAACCTATTGATGATGTTCAGTGCAGACTTACTGTACCTTTGGG 2,17 9,4E-13 NM_013377 PDZRN4 TCGGTAGAGTATGATTGCCTCGTTCAATGTGGCGTTTTTATATATATTTTGTGACTCTTT 2,17 1,1E-15 NM_005084 PLA2G7 AAAGCATTTAGGACTTCATAAAGATTTTGATCAGTGGGACTGCTTGATTGAAGGAGATGA 2,17 6,6E-12 THC2339566 THC2339566 CTGGATCATAGGTTTTGAGTTCATAATCCAGTAATAACAGCTTTCAGCTTTCTATGAGTA 2,17 9,0E-14 NM_032855 HSH2D GAATCCGAGCCCTTTTCCCATATCATCTGTTTGTTCTGTTGTCTAAAAGCACACTGCAAG 2,16 1,3E-13 NM_000867 HTR2B TCTACTAGATACGCTTCTCCTCACTGAAAATGAAGGTGACAAAACTGAAGAGCAAGTTAG 2,16 5,3E-15 NM_000626 CD79B CGCTGAAGGATGGTATCATCATGATCCAGACGCTGCTGATCATCCTCTTCATCATCGTGC 2,16 1,1E-11 NM_000092 COL4A4 TCCTAAAAGTTCAACCTGTTCATCTTGAACTTGGCCTGAGAACATTTTCTGGGAAGAGGT 2,16 1,6E-15 NM_024563 C5orf23 TGTTTGGATATAAATGTGTATGTGTCCTTGTAAATGTTTCTATCAAGCAAGAATGCCACG 2,16 3,2E-12 AK025047 AK025047 CCTCTCACACCCCTCCAACCTCATTTTGAGAGAACAATTCACATTTTAATTTTTGATGGC 2,15 1,7E-17 AK098753 C22orf35 TGGCTGAGATGATACCCGACCCTCTAGGGAAATTCTTAGAGTAACTTCTAGGAAATGTCA 2,13 3,6E-16 NM_022136 SAMSN1 CTCTGGTTGCTATATCTCATCAGGAAATTCAGATAATGGCAAAGAGGATCTGGAGTCTGA 2,12 1,5E-14 NM_152446 C14orf145 GGCCAAATATCCTACTGTGATCACTTCAGTCATATCCTGGACCGTCTTTGGTTTACTGTG 2,12 1,8E-15 THC2287925 THC2287925 GTCCCTTCTCCCTAACACTCCAGTTCAAGATAGCAACCTAAATTCTGAGTTGATTATTCT 2,12 1,5E-14 NM_003292 TPR ATGATGTTTCTCTTGCATCAACTCCAAAACGTCCAAGTACATCACAGACTGTTTCCACTC 2,12 1,6E-09 NM_004887 CXCL14 GTGGTACAACGCCTGGAACGAGAAGCGCAGGGTCTACGAAGAATAGGGTGAAAAACCTCA 2,12 7,9E-13 NM_012108 BRDG1 CCATACAATTTCATTATCTTATCAGAATGAAACCAATTCACAGGGAAACTAGAGACTACG 2,11 2,0E-14 NM_001362 DIO3 AAGTTGGGGTGTCTGCTTTGGGACCAGAGGAAGATAGCTTGAGAGGCATTGGCGAGGTTC 2,11 1,7E-06 ENST00000379913 ENST00000379913 CACAAGCCCAGCAACACCAAGGTGGACAAGAGAGTTGAGTCCAAATATGGTCCCCCATGC 2,11 2,9E-16 NM_022154 SLC39A8 GGAAAATGATTGACAAAGCCCAACAATGATCTCAGGAATTACATTTTCCAACAGACCAAA 2,11 3,7E-10 THC2380963 THC2380963 TATTGAGAGGGGCCTCGACCCCTCCTCATCCCCTCAGTGAAAACAATAAAGACAAATTTT 2,11 3,1E-11 NM_002927 RGS13 ATTAACAAACTTCTTTATCACATGTATCTTCTACATGTAAAACATTTCTGATGATTTTTT 2,10 2,2E-12 NM_001890 CSN1S1 CCTATGCTGTTTGGTACTATCCACAAATCATGCAGTATGTTCCTTTCCCACCGTTTTCCG 2,10 1,9E-17 NM_018284 GBP3 GAGATGCCAAGGTGAAAGTACCCAACTTCAAAATGAGATACAAAAGCTACAGAAGACCCT 2,10 1,7E-16 NM_014398 LAMP3 ACCATGTTGACTTTCCTCATGTGTTTCCTTATGACTCAGTAAGTTGGCAAGGTCCTGACT 2,09 2,8E-16 NM_002009 FGF7 GGAGGACTTAGTTTTTCATATGTGTTTCCTTAGTGCCTAGCAGACTATCTGTTCATAATC 2,09 1,4E-12 CR594705 CR594705 ATCCACTCTCTAGAGTCCAGTGTACTTTAGACTTCATCTGAGTCCAATACATGTACCACA 2,09 5,6E-14 NM_003810 TNFSF10 GCAACAATCCATCTCTCAAGTAGTGTATCACAGTAGTAGCCTCCAGGTTTCCTTAAGGGA 2,08 4,2E-10 NM_152687 FLJ33641 CCCAAATGCCTAGAACATCACATAAGGCACTAAATGCCTCATGTTTTACTGACGGGAATT 2,07 2,2E-15 XM_926222 LOC441368 AGAGTTCTACATTTATTCCAGCATTACCAGGTGAAACTCTCACTTACCTATGGAAAATCC 2,07 5,3E-13 NM_003558 PlP5K1B TTCCTATGGACTTTTGCATTATTTCATTGTGCATGCATCCAGTGATTATACATAAGCAAC 2,06 7,3E-09 AW979273 AW979273 GGATATTTGGTATGCTGGCAATGGTAATTCAAATTGGCGTTTAAGAATAATCTTGGCCGG 2,06 7,9E-11 NM_005711 EDIL3 ACATGACTGCCTATCAGTAGATTGATCTGTATTTAATATTCGTTAATTAAATCTGCAGTT 2,06 1,2E-12 NM_000139 MS4A2 TCAATGTCATCTTCTCCATGAAGACCACTGAATGAACACCTTTTCATCCAGCCTTAATTT 2,06 4,4E-14 NM_003037 SLAMF1 AGGCGCAGAACAGAGCGTTACTTGATAACAGCGTTCCATCTTTGTGTTGTAGCAGATGAA 2,06 2,1E-16 NM_014674 EDEM1 TCCTTGCACACTTCAGTGTTTCTCTCCTGTTCAATAAAATGCCCTGTTAAGGTATAATTT 2,06 2,9E-13 NM_000587 C7 CAGATACAAACTATTTCTATCCTGAGTAGTAATCTCACACTTCATCCTATAGAGTCAACC 2,04 2,4E-10 THC2314833 THC2314833 AGGCATTGAAGGCCACGAGTTACATTTGTTGGCAAAGATGAGTATGCAAGTCAACAAGTC 2,04 6,1E-07 NM_022137 SMOC1 TATTCTCTCTCTTATTGTAAGTTTTTGGATCTGCTACTGACAACTTTTAGAGGGTTTTGG 2,04 6,8E-16 AF124170 AF124170 AAGCAGAACCAACATCGCAAGTAATACTGTGAACTGGTACCAGCACCTCCCAGGAATCGC 2,03 1,2E-09 NM_018084 KlAA1212 TACTGGAACAGGAAAATGAACATCTGAATCAAACAGTGTCTTCCTTAAGGCAGCGGTCCC 2,03 2,6E-14 BC042469 LOC644846 AAATGTGAAGTCTGGCTTTGAAGAGGGTGTATAACACACATAATTTACTGTGCATCAGTC 2,03 2,7E-09 NM_006475 POSTN AGGAAGTTGCAAGCCAACAAAAAAGTTCAAGGATCTAGAAGACGATTAAGGGAAGGTCGT 2,02 6,9E-14 NM_006533 MIA CTGGCAAAGTCGATGTGAAGACAGACAAATGGGATTTCTACTGCCAGTGAGCTCAGCCTA 2,02 5,1E-10 NM_201269 ZNF644 TTGGAAAGACGAAATGGGATGCTCACAAATCTCCAATCTGGGTCTGAATGAGATGATGCA 2,01 9,2E-17 NM_001951 E2F5 GCACTTTAAGTTTATCACATTTTGTTGACTTCTGACATTCCACTTTCCTAGGTTATAGGA 2,01 4,3E-11 NM_020939 CPNE5 TGGTTCTGTGCCCGTCTCTGAGACAGTCTCTGTGTGGAATTTGCCTTAAACTGAAGTAAA 2,01 1,0E-15 NM_016570 ERGIC2 AGAAAGGGAACGTATCATTAACCATGCTGCAGGCAGCCATGGAGTCTCTGGGATATTTAT 2,00 2,9E-13 NM_181453 GCC2 AAGAACCTTCAAGAAAAGAATGGAGTATACTTACTTAGTCTCAGTCAAAGAGATACCATG 2,00 3,1E-12 NM_144590 ANKRD22 AATCCTTGTGACCACACCGATGGAGATACAGAAAAAGTTAACGACTGGATTCTATCTTCA 2,00 2,7E-13 NM_006495 EVl2B CACAAAACGTACATCAATCATTTCACTTACACCCTGGAAACCAAGCAAAAGCACACTTTT -2,01 8,7E-14 NM_018723 A2BP1 TGACAAAACCATAAAAACCTTCCAATGTGGGGAGAAAGGAAGCTTTCCGAGGCCTGAGTA -2,07 1,2E-10 NM_005609 PYGM AAGTCAGCGCCTTGTACAAGAACCCAAGAGAGTGGACGCGGATGGTGATCCGGAACATAG -2,08 3,5E-12 NM_007026 DUSP14 GTTTAATAAACTGGTTCTGCTCTCTTCTGAATCTCATGCCTTTGGCACCTTGGTAGGTGC -2,09 2,6E-13 NM_004165 RRAD TTTTTTCACAGCCCGGGTGTGCCTGCCCTGGAGGGAGGCTCTTCAGTGCGGTAGCTATTT -2,12 8,7E-16 NM_032854 COR06 ACTGGCATGAGGAGTTAGGTTCATCACAAATACACACACACTGCCCCCAACCCTCTGCCG -2,12 1,6E-10 NM_014476 PDLlM3 AAACATACACTTAGCTATGTTTTGCAACTCTTTTTGGGGCTAGCAATAATGATATTTAAA -2,15 1,2E-14 NM_006308 HSPB3 TTCCTGTTCAGATGACATGGGGAAGATGATGGTTCAGCCACTGGTACTACGAGAATGTTT -2,15 2,7E-15 ENST00000332074 ENST00000332074 AATGGAAGACAGTTCCCGACCTTCTACCCCACAGAGATCAGCTCATGAGAATCTCATGGA -2,16 1,0E-13 NM_014859 KlAA0672 TTTTGATGTTGCAGCTTTGCTCACTTCCTGGCAAGGGCAGGTCATGCCTCAATTTGTAAT -2,18 2,4E-16 NM_002469 MYF6 TTTTTT GGAACTGCGAGTGGCTTAGGTCTAGCCTCATTTTGTTTTTGTTTGGTTGGTTTT -2,20 6,3E-18 NM_000635 RFX2 AAGCTCACAGTTAACGGATTGTAATGCCCGGCTTTTCCTCACTCCTGGTAACCAATACAA -2,20 3,6E-14 NM_002200 lRF5 GAGCACTTAGGTATCATATCAGATGCTCAAGGCTGGCAGCTACCCCCTTCTTGAGAGTCC -2,22 1,7E-12 NM_013353 TMOD4 AGGCCATGACCCGAAACAATGAACTACGTCGCCAGCAAAAGAAGAGATAACACTGCATTT -2,23 4,3E-16 BC015836 BC015836 GGCTGGATTGTGGGCTGCATCATAATGATTTATGTTGTCTTCTCTTAGAAAGGCAAGAAG -2,23 8,1E-17 NM_001007271 DUSP13 GATTTCCCTGACCCAATTCAGAGATTCTTTATGCAAAAGTGAGTTCAGTCCATCTCTATA -2,24 1,2E-19 NM_006732 FOSB TTTTTACAATCTGTATCTTTGACAATTCTGGGTGCGAGTGTGAGAGTGTGAGCAGGGCTT -2,25 5,6E-14 NM_000517 HBA2 CACAGACTCAGAGAGAACCCACCATGGTGCTGTCTCCTGCCGACAAGACCAACGTCAAGG -2,26 2,7E-14 NM_006783 GJB6 AGAAGACCGTGTTTACCATTTTTATGATTTCTGCGTCTGTGATTTGCATGCTGCTTAACG -2,27 1,3E-16 NM_021116 ADCY1 AGAGTGATGTGGGCAAGGGTGTCAATTTTCTCGCACAATACAAACTCACTGAGGATGCTT -2,28 1,5E-13 NM_080874 ASB5 CAGATATTAAAGCTGCTTTTGGGTAAAACAGGTTTCCACCAGTATTTTCCCTGAGCTAGA -2,30 1,7E-14 ENST00000284767 ENST00000284767 TTAACTTAAACATAGGGATAATGGCAAGCCACTCATAATGTTGTCATTTGAAGATCACAC -2,31 5,8E-15 NM_024875 SYNP02L ACAGCATCTTGTGAAAGTTATGGAGCATGAAAAGACTGAAGGGCCAGGACAGTTTGCATG -2,32 3,0E-19 NM_004816 C9orf61 GAGGATTATTGTTGATTCCATTTACTCATGCTTGCAAAACTAGAGACCCCTAAGGCAGAA -2,32 1,3E-12 NM_004004 GJB2 GTCATAGCACCTAACAACATTGTAGCCTCAATCGAGTGAGACAGACTAGAAGTTCCTAGT -2,33 3,7E-16 NM_004660 DDX3Y CACTGATAGGAAGGTCCACATCCACAAAGTTTCTCTTGAGTTTTGTTATGTGTTTTGCTG -2,34 5,7E-14 NM_001007176 C8orf22 AAAGACTATCGCTGGAAGTGGCACTTGCTACCTGGTGCATCTTTGAAAAGTGTGCCTTTA -2,35 2,8E-15 NM_006790 MYOT TAACCCAGAAGGAGAATTTCAGCGTTTGGCAGCTCAATCTGGACTCTATGAAAGTGAAGA -2,38 1,8E-15 NM_032588 TRlM63 ACGATGTGCTGTATTTCAGTGTCTATCCCAGACATACGGGGTGGTAACTGAGTTTGTGTT -2,40 4,5E-15 NM_004533 MYBPC2 CCAAGACAATTGGTGGTGGAGTCCTGACCCCAATCCCCAACCTCCCAGGACTGTGTTCTT -2,40 2,4E-13 NM_021245 MYOZ1 GCAATGCCCTATGGTGGATATGAGAAGGCCTCCAAACGCATGACCTTCCAGATGCCCAAG -2,41 3,4E-10 NM_003063 SLN CAATATCTGCTATGCTGTAGTGCTAGGATTGATTATGTGTTCTCCAAAGATGCTGCTCCC -2,44 7,9E-16 NM_001976 EN03 CTCGGAGCGTCTGGCCAAATACAACCAACTCATGAGGATCGAGGAGGCTCTTGGGGACAA -2,52 4,9E-09 NM_001008 RPS4Y1 CAACTTTATCAAATTTGATACAGGCAATTTGTGTATGGTGATTGGTGGAGCCAACCTCGG -2,52 3,8E-10 NM_001039567 RPS4Y2 TGTTGGTGTGATCACAAACAGGGAAAGACATCCTGGTTCTTGCGATGTGGTACATGTGAA -2,56 1,4E-17 NM_033118 MYLK2 CAGGAGAATTAGGAAGGCCATGGGGCAGCCTCCAGTCTGCTCTCAGCTTGTGCCTTGTAA -2,56 3,6E-20 NM_006789 APOBEC2 ACAGCCTCAGACCCGAGGTTTAGATTTCTGAAATATGCATTTTATGTTAAGTTGGGTATT -2,57 2,7E-09 NM_004543 NEB TCTGCAGGACTTACAGATCCTGCAGTCAATGTTTCGGTTTAGACTCTCCACTGTTACCTA -2,67 1,4E-10 BC107798 TNNT1 TCCGAGCGTAAGAAGCCTCTGGACATTGACTACATGGGGGAGGAACAGCTCCGGGAGAAA -2,69 7,0E-21 NM_144994 ANKRD23 ACACACCTTTTTATACCAATCAGTATCCTCTGTTCATTAAAACTGGCTATCCATTAAAAA -2,71 2,8E-13 NM_000366 TPM1 GTGCTTTCTATTGTACAGAAGCTCTTCGTTTCAGTGTCAAATAAACACTGTGTAAGCTAA -2,75 3,7E-12 NM_006757 TNNT3 GACAAGGCCAAGGAGCTCTGGGAGACCCTGCACCAGCTGGAGATTGACAAGTTCGAGTTT -2,77 7,1E-13 NM_003280 TNNC1 CAGCGGCACGGTGGACTTTGATGAGTTCCTGGTCATGATGGTTCGGTGCATGAAGGACGA -2,98 3,1E-11 NM_003279 TNNC2 GACTTCGACGAGTTCCTGAAGATGATGGAGGACGTGCAGTAAGGAGTGGACAGTCGCCTC -3,14 2,9E-16 NM_005181 CA3 AGACAGCAAGAATTGAGCTAATAATATGTTTTAACTCTTAACACCAGCAAGAAGTCAGTC -3,20 4,1E-14 NM_003673 TCAP AGGCAAGGATGGTGGGGCCCCCAGCACCCTCTGTTAGTGCCGCAATAAATGCTCAATCAT -3,24 1,4E-20 NM_014332 SMPX GTGTGGTTTTGAGGAGGGATATGATTTTATGGAGAATGATATGGCAATGTGCCTAACGAT -3,27 2,3E-13 NM_133378 TTN CTGACAACCCTGATCATCATGGACGTACAGAAACAAGATGGTGGACTTTATACCCTGAGT -3,29 5,8E-15 NM_019885 CYP26B1 TTTGTTTTGATATGAAACTGGTACCGTGTGAGTGTTTTTGCTGTCGTGGTTTTAATCTGT -3,31 1,8E-14 NM_000432 MYL2 AAGGAGGCTCCGGGTCCAATTAACTTTACTGTGTTCCTCACAATGTTTGGGGAGAAACTT -3,52 5,2E-18 NM_006063 KBTBD10 GCTGGGATGTTGAAGGAAATACGTTATGCTTCAGGAGCTAGTTGCCTAGCAACACGTTTA -3,52 6,5E-17 NM_206819 MYBPC1 AGGATGCCACCATGACTAAAGAGAGTGCAGTGATCGCCAGGGATGGTAAAATCTACAAAA -3,64 6,1E-20 BX647448 CMYA3 TTTGAGGAACTTGATGTAAACATGGTGTTCAGAAATCTCGTGTCTATCTCAATGGGATAT -3,69 7,6E-16 NM_013292 MYLPF GAGGAGTTGGATGCCATGATGAAGGAAGCCAGCGGTCCCATCAACTTCACCGTCTTCCTG -3,81 2,8E-14 NM_198060 NRAP GGCCAGAGAGGAAGTTTGTTCACCAGAGACAGGCTTCAGATGGCTTTGATTTCGGCAAGC -3,96 8,9E-17 NM_003282 TNNI2 GGAGCGGGACCTGCGAGACGTGGGTGACTGGAGGAAGAACATCGAGGAGAAGTCTGGCAT -4,25 1,4E-20 NM_001103 ACTN2 TCCCATCAGAATGCAATAAAAGCGGAAGTCACAGTTTGTTTCCTGGAAACTTTGACAAGC -4,33 5,5E-18 NM_003476 CSRP3 TATGTGTTTCTCCTCAGAAGTGATCAGGTCTTTACTGAATGTTAGAAGAGGCCTTTGGAA -4,69 4,6E-14 NM_005963 MYH1 TTATCTAACTGCTGAAAGGTGACCAAAGAAATGCACAAAATGTGAAAATCTTTGTCACTC -5,01 1,6E-16 NM_079422 MYL1 AGAAAATTGAGTTTGAACAATTTCTGCCTATGATGCAAGCCATTTCCAACAACAAGGACC -5,43 1,7E-17 NM_203377 MB GGAGTTCATCTCGGAATGCATCATCCAGGTTCTGCAGAGCAAGCATCCCGGGGACTTTGG -8,36 8,1E-16 NM_000257 MYH7 CCGTGACATTGGCACGAAGGGCTTGAATGAGGAGTAGCTTTGCCACATCTTGATCTGCTC -12,08 2,6E-18 NM_001824 CKM ACACTCGGAGCTTGTGCTTTGTCTCCACGCAAAGCGATAAATAAAAGCATTGGTGGCCTT -12,49 1,1E-17 NM_017534 MYH2 CGGGAGGTTCACACAAAAGTCATAAGTGAAGAGTGATCATGTCCTGATGCCATGGAATGA -15,31 2,5E-18 NM_001100 ACTA1 CCGCAGTCACTTTCTTTGTAACAACTTCCGTTGCTGCCATCGTAAACTGACACAGTGTTT \n TABLE-tabl0005 Table 5: Ingenuity Pathways Analysis of significantly differential expressed genes Top Canonical Pathways overrepresented in RA Pathway p-value Ratio Cytotoxic T Lymphocyte-mediated Apoptosis of Target Cells 7.19E-06 7/31 (0.226) Communication between Innate and Adaptive Immune Cells 8.85E-05 10/90 (0.111) Hepatic Fibrosis / Hepatic Stellate Cell Activation 1.26E-04 14/135 (0.104) Death Receptor Signaling 1.85E-04 9/64 (0.141) Type I Diabetes Mellitus Signaling 1.93E-04 12/114 (0.105) Top Canonical Pathways overrepresented in SpA Pathway p-value Ratio Calcium Signaling 5.72E-12 21/206 (0.102) Actin Cytoskeleton Signaling 1.77E-09 20/237 (0.084) ILK Signaling 1.92E-08 17/186 (0.091) Cellular Effects of Sildenafil (Viagra) 1.25E-07 14/151 (0.093) Hepatic Fibrosis / Hepatic Stellate Cell Activation 3.4E-06 12/135 (0.089) References \n 1. 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or suspected of suffering from rheumatoid arthritis or spondyloarthritis, the method comprising:
- determining levels of expression products of a set of genes, said expression products being obtained from, and/or present in, a sample of said individual;
- typing said sample on the basis of the expression product levels determined for said set of genes;wherein said set of genes comprises at least 5 genes listed in table 3."],"number":1,"annotation":false,"title":false,"claim":true},{"lines":["A method according to claim 1 wherein said set of genes comprises at least 5 genes listed in table 4."],"number":2,"annotation":false,"title":false,"claim":true},{"lines":["A method according to claim 1 or 2 wherein said set of genes comprises at least 10 genes listed in table 3 or 4, more preferably at least 20 genes listed in table 3 or 4, most preferably at least 50 genes listed in table 3 or 4."],"number":3,"annotation":false,"title":false,"claim":true},{"lines":["A method according to any one of claims 1-3 wherein said expression product is RNA."],"number":4,"annotation":false,"title":false,"claim":true},{"lines":["A method according to any one of claims 1-4 wherein said sample is, a blood sample, a peripheral blood mononuclear cell sample or a synovial tissue sample."],"number":5,"annotation":false,"title":false,"claim":true},{"lines":["A method according to any one of claims 1-5 wherein said synovial tissue sample is obtained from a knee joint or an ankle-joint."],"number":6,"annotation":false,"title":false,"claim":true},{"lines":["A method according to any one of claims 1-6 wherein said set of genes comprises tumour necrosis factor receptor superfamily member 17 (TNFRSF17) and/or immunoglobulin J polypeptide, linker protein for immunoglobulin alpha and mu polypeptides (IGJ) and/or POU class 2 associating factor 1 (POU2AF1), and/or Der1-like domain family, member 3 (DERL3), and/or Fc receptor-like 5 (FCRL5), and/or plasma cell-induced ER protein 1 (PACAP), and/or prepronociceptin (PNOC), and/or secreted phosphoprotein 1 (SPP1), and/or interferon regulatory factor 4 (IRF4), and/or lymphocyte transmembrane adaptor 1 (LAX1), and/or ELL associated factor 2 (EAF2), and/or pim-2 oncogene (PIM2) and/or actin, alpha 1, skeletal muscle (ACTA1) and/or Myosin, heavy chain 3, skeletal muscle, embryonic (MYH2) and/or myosin, heavy chain 1, skeletal muscle, adult (MYH1), and/or cysteine and glycine-rich protein 3 (CSRP3), and/or actinin, alpha 2 (ACTN2), and/or troponin I type 2 (TNNI2), and/or cytochrome P450, family 26, subfamily B, polypeptide 1 (CYP26B1), and/or titin-cap (TCAP)."],"number":7,"annotation":false,"title":false,"claim":true},{"lines":["A method according to any one of claims 1-7 wherein RNA levels are determined by microarray analysis."],"number":8,"annotation":false,"title":false,"claim":true},{"lines":["A nucleotide microarray, comprising at least 5 nucleic acid sequences being able to hybridize to at least 5 genes listed in table 3 or 4, and wherein at least 80% of the nucleic acid molecules of said microarray are able to hybridize to any gene listed in table 3 or 4."],"number":9,"annotation":false,"title":false,"claim":true},{"lines":["A nucleotide microarray according to claim 9 comprising at least 10 nucleic acid sequences being able to hybridize to at least 10 genes listed in table 3 or 4, more preferably comprising at least 20 nucleic acid sequences being able to hybridize to at least 20 genes listed in table 3 or 4, more preferably comprising at least 50 nucleic acid sequences being able to hybridize to at least 50 genes listed in table 3 or 4."],"number":10,"annotation":false,"title":false,"claim":true},{"lines":["Use of a nucleotide microarray according to claim 9 or 10 for typing a sample of an individual suffering from or suspected of suffering from rheumatoid arthritis or spondyloarthritis."],"number":11,"annotation":false,"title":false,"claim":true}]}},"filters":{"npl":[],"notNpl":[],"applicant":[],"notApplicant":[],"inventor":[],"notInventor":[],"owner":[],"notOwner":[],"tags":[],"dates":[],"types":[],"notTypes":[],"j":[],"notJ":[],"fj":[],"notFj":[],"classIpcr":[],"notClassIpcr":[],"classNat":[],"notClassNat":[],"classCpc":[],"notClassCpc":[],"so":[],"notSo":[],"sat":[]},"sequenceFilters":{"s":"SEQIDNO","d":"ASCENDING","p":0,"n":10,"sp":[],"si":[],"len":[],"t":[],"loc":[]}}