Large-scale DNA methylation expression analysis across 12 solid cancers reveals hypermethylation in the calcium-signaling pathway

INTRODUCTION

Cancer is a complex disease [1, 2], with the dysregulation of genes linked to many tumor features [3, 4]. Of these cancer-associated genes, oncogenes are usually activated, whereas tumor suppressor genes are inactivated [5]. A diverse number of regulators control gene expression in cancer, including genetic and epigenetic changes [6–8]. In recent years, epigenetics in cancer research has attracted considerable attention due to its emerging role in cancer development, prognosis, and treatment [5, 9, 10]. As the most common epigenetic modification, and as a bridge between gene expression regulation and chromatin architecture [11, 12], DNA methylation is crucial for gene and transposon silencing and imprinting and X chromosome inactivation [13]. DNA hypermethylation in gene promoter regions leads to gene downregulation, whereas hypomethylation causes gene upregulation [11, 14]. Alteration of the site-specific targeted regions of gene promoters can upregulate gene expression in cancer cells [15]. Abnormal DNA methylation often occurs in cancers, which regulates the expression of genes, especially those responsible for cell growth, proliferation, differentiation, and apoptosis processes [10, 11, 16].

Indeed, aberrant DNA methylation is a common feature of cancer cells and is correlated with gene expression [17–21]. A recent study reclassified cancers into different methylation-driven subgroups, providing new insights into cancer and strategies for cancer diagnosis, prognosis, and therapy [14, 22–24]. Given its heterogeneous nature, however, much is still unknown about cancer, including whether a common pattern of DNA methylation exists across various cancer types.

In this study, we analyzed the associations of pan-cancer DNA methylation and gene expression in 4,138 cancer tissue samples and 338 matched normal tissue samples across 12 solid cancer types. We found that the number of lowly expressed genes with hypermethylation (epigenetically silenced genes) ranged from 33 to 992, and the number of highly expressed genes with hypomethylation (epigenetically activated genes) ranged from 0 to 34. Interestingly, the epigenetically silenced genes were found to be enriched in the calcium-signaling pathway across nine cancer types. These results suggest that various cancers share similarities in DNA methylation, with more epigenetically silenced than epigenetically activated genes identified across cancers, and reversing aberrant DNA methylation of genes involved in the calcium-signaling pathway could be a potential strategy for cancer treatment.

RESULTS

Global hypermethylation across 12 cancer types

We analyzed a total of 485,577 CpG sites in each tissue sample across 12 solid cancer types. As shown in Figure 1, the number of hypermethylated and hypomethylated CpG sites ranged from 4,972 to 17,724 and 1,705 to 6,870, respectively, among the cancer types. Thus, the number of hypermethylated CpG sites was around 2.5 times greater than that of the hypomethylated CpG sites (Figure 1A). Approximately half of the CpG sites could be annotated and were distributed in different regions in each of the 12 cancers, including the 1st Exon, 3’UTR, 5’UTR, gene body, TSS200, and TSS1500 regions, with the highest distribution in the gene body and TSS1500 regions, followed by the TSS200 region, and lastly the 3’UTR region (Figure 1B, 1C). Furthermore, for most CpG sites, there were twice as many hypermethylated CpG sites annotated in the genome regions than there were hypomethylated sites (Supplementary Table 2).

Figure 1: Methylation status across 12 cancer types. A. Global hypermethylation across 12 cancer types. B. Distribution of hypermethylated CpG sites in the genome across 12 cancer types. C. Distribution of hypomethylated CpG sites in the genome across 12 cancer types.

Epigenetically silenced and activated genes across the 12 cancer types

Many of the CpG sites were negatively correlated with gene expression (r < -0.2, p < 0.05; Supplementary Table 3). For example, USP44 gene expression was significantly negatively correlated with DNA methylation across all cancer types (all r < -0.2, p < 0.05; Figure 2). According to the correlation coefficients, we counted the number of hyper- or hypomethylated genes in each cancer type. As shown in Table 1, the number of downregulated genes ranged from 33 to 992 among the cancer types. Of these genes, 6 were epigenetically silenced in nine cancer types, 37 were epigenetically silenced in at least eight cancer types, 96 were epigenetically silenced in at least seven cancer types, 190 were epigenetically silenced in at least six cancer types, and 340 were epigenetically silenced in at least five cancer types (Supplementary Table 4). For instance, NOVA1, NRXN1, TMEM132C, USP44, VIPR2, and ZSCAN23 were consistently downregulated in nine cancers (Supplementary Table 5). It is possible, therefore, that some of these silenced genes could be good biomarkers for cancer prognosis. For example, the highly expressed ZSCAN23 gene was associated with good prognosis in BRCA (p = 0.004, Supplementary Figure 1). The number of activated genes with hypomethylation (epigenetically activated genes) ranged from 0 to 34 across cancers (Table 1). There were only four upregulated genes with low DNA hypomethylation across two cancer types. GRHL2 was activated in BRCA and UCEC; and NAA25, NOD2, and TNFRSF9 were activated in KIRC and KIRP (Supplementary Table 6).

Figure 2: Negative correlation of USP44 gene expression and DNA methylation across 12 cancer types. X-axis from 0 to 1 represents the beta value of the USP44 CpG sites in each cancer type. Y-axis from 0 to 8 represents the USP44 gene expression value (log₂(RSEM+1)) across 12 cancer types.

Hypermethylation in the calcium-signaling pathway across different cancer types

We analyzed enrichment of epigenetically silenced genes in each cancer type. The calcium-signaling pathway was shared in nine cancer types, followed by the cell adhesion pathway shared in eight cancer types, and the cancer and Wnt signaling pathways shared in five cancer types (Table 2). To validate these results, based on the 340 epigenetically silenced genes in at least five cancer types (Supplementary Table 4), we drew a protein-protein interaction network and found some genes with higher degrees of interaction, such as ADCY4, ADCY8, and PRKCB. (Supplementary Figure 2). In addition, enrichment analysis of biological pathways showed that the 340 epigenetically silenced genes were enriched in the neuroactive ligand-receptor interaction, calcium-signaling, cell adhesion molecules (CAMs), vascular smooth muscle contraction, and melanogenesis pathways (Supplementary Table 7). Of note, many genes involved in the calcium-signaling pathway were epigenetically silenced. For example, AGTR1, GRIN2A, ITPKB, and SLC8A3 were repressed by hypermethylation in six cancer types, and ADCY4, ADCY8, BST1, and PRKCB were inhibited by hypermethylation in five cancer types (Supplementary Table 8). Furthermore, GPCR, membrane Na⁺/Ca²⁺ exchanger, MLCK, and CAMK were decreased by hypermethylation in at least three cancer types, and most other genes (voltage-gated channel, PTK, Gq, PLC_β, Gs, PMCA, IP3R, PKA, SERCA, FAK2, PKC, IP3K and NOS) were downregulated in at least one cancer type (Figure 3). The genes downregulated by hypermethylation were located in nodes of the calcium-signaling pathway, such as Na⁺/Ca²⁺ exchanger and GPCR (Figure 3). Moreover, the DNA methylation of genes in the calcium-signaling pathway clearly distinguished the cancer samples from the normal tissue samples across nine cancer types (Figure 4), providing further support for DNA methylation in gene expression regulation in the calcium-signaling pathway in cancer cells. We also analyzed gene expression fold change of eight genes in the calcium-signaling pathway across twelve cancer types (Supplementary Table 9), and found that these genes were almost all downregulated across cancers.

Figure 3: Epigenetically silenced genes of the calcium-signaling pathway in nine solid cancer types (BLCA, BRCA, COAD, HNSC, KIRP, LIHC, LUAD, LUSC and UCEC). Epigenetically silenced genes of the calcium-signaling pathway were based on the KEGG pathway database. Green proteins were downregulated by hypermethylation in more than two solid cancer types. Light blue proteins were downregulated by hypermethylation in one cancer type. Black proteins were not downregulated by hypermethylation in any cancer type.

Figure 4: DNA methylation of epigenetically silenced genes involved in the calcium-signaling pathway across nine cancer types. Green lines of each small figure represent normal tissue and red lines represent tumor tissue of each cancer type. Upper column represents the DNA methylation level from low to high.

DISCUSSION

Abnormal gene expression and aberrant DNA methylation are common characteristics in cancer cells [1, 2]. In this study, we investigated DNA methylation patterns and their potential role in regulating gene expression across 12 solid cancer types. Results showed that more epigenetically silenced than epigenetically activated genes were detected across cancers. This might be caused by the different number of hypermethylated and hypomethylated CpG sites (Figure 1A). In addition, more hypermethylated CpG sites locate closely to the gene promoter regions (Figure 1B, 1C). This distribution of CpG sites is consistent with previous findings that cancer exhibits hypomethylation in many repeat sequences in the genome, but displays hypermethylation in local regions, especially in gene promoter regions [25, 26]. Hypermethylated CpG sites near the gene promoter regions can lead to gene silencing in cancer [26–28], so differences in the number of hypermethylated or hypomethylated genes would be expected. Generally, the level of global hypomethylation in the whole cancer genome is mainly due to low methylated CpG sites located in the intergenic regions, including the repeated DNA sequences [25]. In addition, hypomethylation in the gene body region might regulate gene splicing [20]. Furthermore, methylation disorders have been linked to low-level gene expression in cancer cells [29]. In fact, highly expressed genes in cancers are preferentially regulated by other epigenetic factors, such as microRNA, in diverse cancer types [9, 19, 30].

Compared with previous research [22, 31], we found that the commonly dysregulated genes controlled by aberrant DNA methylation across multiple cancer types were primarily involved in the calcium-signaling and CAMs pathways, which are associated with oncogenesis [4, 7, 32]. Of note, genes in the calcium-signaling pathway were decreased by hypermethylation (Figure 3, Supplementary Figure 2), and were shared by multiple solid cancer types (Table 2 and Supplementary Table 7). More importantly, some epigenetically silenced genes were located in key nodes of the calcium-signaling pathway, including Na⁺/Ca²⁺ exchanger and GPCR. The calcium-signaling pathway acts in various biological processes, such as cell cycle, survival, apoptosis, migration, and gene expression [33]. Previous studies have found that the calcium-signaling pathway is deregulated in cancers, and that upregulating or downregulating the genes in the pathway can promote cancer cell proliferation, migration, and tumor metastasis [32, 34]. A recent study identified alterations in the expression of proteins involved in the movement of Ca²⁺ across the plasma membrane and subcellular organelles in cancers [35]. Changing calcium channels and pumps in cancer can trigger calcium fluxes, which are an essential component of the epigenetic mechanism of action [34]. Ca²⁺ channels or pumps are potential therapeutic targets for specific cancer subtypes and are correlated with prognosis [34–36]. In the present study, we did find that the CAMs pathway was downregulated by DNA methylation across different cancer types. This pathway is correlated with cancer angiogenesis, invasion, and metastasis, and thus cell adhesion molecules might be applied in cancer therapy [37–41]. The calcium-signaling pathway is critical in cancer biology, and as far as we know, this study is the first report to reveal the similarities in the calcium-signaling pathway and CAMs pathway in various cancer types via large-scale data mining.

DNA methylation can alter gene expression without changing gene sequences, and can be reversed by many effectors, such as the environment or drugs [5, 10, 42]. Previous studies have proposed that hypermethylation can serve as a cancer therapeutic target [5, 43]. We found more downregulated than upregulated genes across the studied cancers. Some of the epigenetically silenced genes detected in this study are involved in tumorigenesis, and could possibly be used as prognostic biomarkers [7]. DNA methylation-mediated gene silencing is essential for cancer cell survival, and demethylation of these genes by drugs can stimulate gene expression and improve patient condition [16, 44]. Since the calcium-signaling and CAMs pathways play critical roles in tumorigenesis, reversing the aberrant DNA methylation of these pathways could be an effective strategy to suppress cancers and develop anti-cancer drugs. A recent study indicated that targeting the calcium-signaling pathway can reverse epigenetic silencing of tumor suppressor genes (TSGs) in cancer by drugs [35], lending support to our notion that the calcium-signaling pathway could be an effective target in cancer therapy.

In summary, we found a common pattern of DNA methylation in gene expression regulation across multiple solid cancer types. DNA methylation generally decreased gene expression across the studied cancers, but increased expression in a few genes. This large-scale analysis revealed, for the first time, hypermethylation in the calcium-signaling pathway, which could be a promising therapeutic target in cancer treatment.

MATERIALS AND METHODS

Data acquisition and filtration

We collected DNA methylation data of 4,138 tumor samples and 338 matched normal tissue samples across 12 cancer types, as well as the corresponding gene expression data, from The Cancer Genome Atlas (TCGA) database (http://cancergenome.nih.gov/) (Supplementary Table 1). DNA methylation data were produced by the Illumina Infinium Human DNA Methylation 450 platform and quantified using beta values ranging from 0 to 1, with values close to 0 or close to 1 indicating low or high levels of DNA methylation, respectively. Gene expression data were produced by the Illumina HiSeq 2000 RNA Sequencing Version 2 analysis platform and quantified using RNA-Seq by Expectation-Maximization (RSEM). In each cancer type, CpG sites and genes with missing values over 5% in all samples were disregarded. The remaining CpG sites and genes with missing values in a few subjects were filled using R package “impute”. The DNA methylation β-values and gene expression RSEM values were normalized by R package “preprocessCore”. All CpG sites were annotated by R package “IlluminaHumanMethylation450k.db”.

Genome-wide methylation analysis across 12 cancer types

We compared the genome-wide methylation levels in normal tissues to tumor tissues based on the mean DNA methylation beta value for each CpG site in each cancer type. The hypermethylated CpG sites were determined by the following criteria: CpG sites were unmethylated in normal adjacent tissue (mean DNA methylation beta value ≤ 0.2) and methylated in tumor tissue (mean DNA methylation beta value > 0.2). The hypomethylated CpG sites were determined by similar criteria: CpG sites were unmethylated in normal adjacent tissue (mean DNA methylation beta value > 0.2) and methylated in tumor tissue (mean DNA methylation beta value ≤ 0.2) [45]. To explore the distribution of these hypermethylated and hypomethylated CpG sites in the genome, we annotated the CpG sites using the “IlluminaHumanMethylation450k.db” package.

Association of DNA methylation with gene expression across 12 cancer types

We examined the relationship between DNA methylation and gene expression across cancers using Pearson correlation. A Pearson correlation coefficient value of less than -0.2 and p-value less than 0.05 were considered statistically significant [45]. To identify the candidate epigenetically silenced genes, we adopted the following criteria: 1) 95^th percentile for DNA methylation beta value in normal tissue < 0.2; 2) 95^th percentile for DNA methylation beta value in tumor tissue > 0.2 and maximum DNA methylation beta value in tumor tissue > 0.5; and 3) mean DNA methylation beta value in tumor tissue > 0.2. To identify the candidate epigenetically activated genes, we adopted the following criteria: 1) 95^th percentile for DNA methylation beta value in tumor tissue < 0.2; 2) 95^th percentile for DNA methylation beta value in normal tissue > 0.2 and maximum DNA methylation beta value in normal tissue > 0.5; and 3) mean DNA methylation beta value in normal tissue > 0.2.

Protein interaction and pathway enrichment analysis

Protein-protein interactions were analyzed using the STRING database (http://string-db.org/). To understand the pathways involved in the dysregulated genes across cancers, we explored the biological pathways using the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway database (http://www.kegg.jp/kegg/pathway.html), which is widely used for systematic analysis of gene function [46]. All pathways were downloaded from the KEGG pathway database [47], and cluster analysis using the Database for Annotation, Visualization and Integrated Discovery (DAVID) (https://david.ncifcrf.gov/) was conducted [48]. A p-value of less than 0.05 was considered statistically significant.

ACKNOWLEDGMENTS

This work was supported by grants from the Chinese Academy of Sciences (KJZD-EW-L14 and QYZDB-SSW-SMC020), National Basic Research Program of China (2012CB518205), National Natural Science Foundation of China (81272309, 31322029, 81602346), and Youth Innovation Promotion Association of the Chinese Academy of Sciences.

CONFLICTS OF INTEREST

The authors declare no conflicting financial interests.

REFERENCES

1. Grossmann ME, Ray A, Dogan S, Mizuno NK, Cleary MP. Balance of adiponectin and leptin modulates breast cancer cell growth. Cell Res. 2008; 18:1154-1156.

2. Kidane D, Sweasy JB. Tipping the balance in the powerhouse of the cell to “protect” colorectal cancer. PLoS Genet. 2012; 8:e1002758.

3. Hanahan D, Weinberg RA. Hallmarks of cancer: the next generation. Cell. 2011; 144:646-674.

4. Zardawi SJ, O’Toole SA, Sutherland RL, Musgrove EA. Dysregulation of Hedgehog, Wnt and Notch signalling pathways in breast cancer. Histol Histopathol. 2009; 24:385-398.

5. Jones PA, Issa JP, Baylin S. Targeting the cancer epigenome for therapy. Nature reviews Genetics. 2016; 17:630-641.

6. Kondo Y, Shen L, Cheng AS, Ahmed S, Boumber Y, Charo C, Yamochi T, Urano T, Furukawa K, Kwabi-Addo B, Gold DL, Sekido Y, Huang TH, Issa JP. Gene silencing in cancer by histone H3 lysine 27 trimethylation independent of promoter DNA methylation. Nat Genet. 2008; 40:741-750.

7. Suzuki H, Watkins DN, Jair KW, Schuebel KE, Markowitz SD, Chen WD, Pretlow TP, Yang B, Akiyama Y, Van Engeland M, Toyota M, Tokino T, Hinoda Y, Imai K, Herman JG, Baylin SB. Epigenetic inactivation of SFRP genes allows constitutive WNT signaling in colorectal cancer. Nat Genet. 2004; 36:417-422.

8. Weinhold N, Jacobsen A, Schultz N, Sander C, Lee W. Genome-wide analysis of noncoding regulatory mutations in cancer. Nat Genet. 2014; 46:1160-1165.

9. Kasinski AL, Slack FJ. Epigenetics and genetics. MicroRNAs en route to the clinic: progress in validating and targeting microRNAs for cancer therapy. Nat Rev Cancer. 2011; 11:849-864.

10. Esteller M. Epigenetics in cancer. N Engl J Med. 2008; 358:1148-1159.

11. Sharma S, Kelly TK, Jones PA. Epigenetics in cancer. Carcinogenesis. 2010; 31:27-36.

12. Portela A, Esteller M. Epigenetic modifications and human disease. Nature biotechnology. 2010; 28:1057-1068.

13. Law JA, Jacobsen SE. Establishing, maintaining and modifying DNA methylation patterns in plants and animals. Nat Rev Genet. 2010; 11:204-220.

14. Witte T, Plass C, Gerhauser C. Pan-cancer patterns of DNA methylation. Genome Med. 2014; 6:66.

15. Choudhury SR, Cui Y, Lubecka K, Stefanska B, Irudayaraj J. CRISPR-dCas9 mediated TET1 targeting for selective DNA demethylation at BRCA1 promoter. Oncotarget. 2016; 7: 46545-46556. doi: 10.18632/oncotarget.10234.

16. De Carvalho DD, Sharma S, You JS, Su SF, Taberlay PC, Kelly TK, Yang X, Liang G, Jones PA. DNA methylation screening identifies driver epigenetic events of cancer cell survival. Cancer Cell. 2012; 21:655-667.

17. Jones PA, Baylin SB. The fundamental role of epigenetic events in cancer. Nat Rev Genet. 2002; 3:415-428.

18. Jones PA, Baylin SB. The epigenomics of cancer. Cell. 2007; 128:683-692.

19. You JS, Jones PA. Cancer genetics and epigenetics: two sides of the same coin? Cancer Cell. 2012; 22:9-20.

20. Huang WY, Hsu SD, Huang HY, Sun YM, Chou CH, Weng SL, Huang HD. MethHC: a database of DNA methylation and gene expression in human cancer. Nucleic acids research. 2015; 43:D856-861.

21. Warden CD, Lee H, Tompkins JD, Li X, Wang C, Riggs AD, Yu H, Jove R, Yuan YC. COHCAP: an integrative genomic pipeline for single-nucleotide resolution DNA methylation analysis. Nucleic acids research. 2013; 41:e117.

22. Gevaert O, Tibshirani R, Plevritis SK. Pancancer analysis of DNA methylation-driven genes using MethylMix. Genome Biol. 2015; 16:17.

23. Zhang C, Zhao H, Li J, Liu H, Wang F, Wei Y, Su J, Zhang D, Liu T, Zhang Y. The identification of specific methylation patterns across different cancers. PLoS One. 2015; 10:e0120361.

24. Baek SJ, Yang S, Kang TW, Park SM, Kim YS, Kim SY. MENT: methylation and expression database of normal and tumor tissues. Gene. 2013; 518:194-200.

25. Ehrlich M. DNA hypomethylation in cancer cells. Epigenomics. 2009; 1:239-259.

26. Herman JG, Baylin SB. Gene silencing in cancer in association with promoter hypermethylation. N Engl J Med. 2003; 349:2042-2054.

27. Baylin SB, Ohm JE. Epigenetic gene silencing in cancer - a mechanism for early oncogenic pathway addiction? Nat Rev Cancer. 2006; 6:107-116.

28. Ehrlich M. DNA methylation in cancer: too much, but also too little. Oncogene. 2002; 21:5400-5413.

29. Landau DA, Clement K, Ziller MJ, Boyle P, Fan J, Gu H, Stevenson K, Sougnez C, Wang L, Li S, Kotliar D, Zhang W, Ghandi M, Garraway L, Fernandes SM, Livak KJ, et al. Locally disordered methylation forms the basis of intratumor methylome variation in chronic lymphocytic leukemia. Cancer Cell. 2014; 26:813-825.

30. Slack FJ. MicroRNAs regulate expression of oncogenes. Clin Chem. 2013; 59:325-326.

31. Kim JH, Karnovsky A, Mahavisno V, Weymouth T, Pande M, Dolinoy DC, Rozek LS, Sartor MA. LRpath analysis reveals common pathways dysregulated via DNA methylation across cancer types. BMC genomics. 2012; 13:526.

32. Monteith GR, McAndrew D, Faddy HM, Roberts-Thomson SJ. Calcium and cancer: targeting Ca2+ transport. Nat Rev Cancer. 2007; 7:519-530.

33. Clapham DE. Calcium signaling. Cell. 2007; 131:1047-1058.

34. Monteith GR, Davis FM, Roberts-Thomson SJ. Calcium channels and pumps in cancer: changes and consequences. J Biol Chem. 2012; 287:31666-31673.

35. Raynal NJ, Lee JT, Wang Y, Beaudry A, Madireddi P, Garriga J, Malouf GG, Dumont S, Dettman EJ, Gharibyan V, Ahmed S, Chung W, Childers WE, Abou-Gharbia M, Henry RA, Andrews AJ, et al. Targeting Calcium Signaling Induces Epigenetic Reactivation of Tumor Suppressor Genes in Cancer. Cancer Res. 2016; 76:1494-1505.

36. Chen YF, Chen YT, Chiu WT, Shen MR. Remodeling of calcium signaling in tumor progression. J Biomed Sci. 2013; 20:23.

37. Craig SE, Brady-Kalnay SM. Cancer cells cut homophilic cell adhesion molecules and run. Cancer research. 2011; 71:303-309.

38. Farahani E, Patra HK, Jangamreddy JR, Rashedi I, Kawalec M, Rao Pariti RK, Batakis P, Wiechec E. Cell adhesion molecules and their relation to (cancer) cell stemness. Carcinogenesis. 2014; 35:747-759.

39. Calaf GM, Roy D, Narayan G, Balajee AS. Differential expression of cell adhesion molecules in an ionizing radiation-induced breast cancer model system. Oncology reports. 2013; 30:285-291.

40. Saadatmand S, de Kruijf EM, Sajet A, Dekker-Ensink NG, van Nes JG, Putter H, Smit VT, van de Velde CJ, Liefers GJ, Kuppen PJ. Expression of cell adhesion molecules and prognosis in breast cancer. The British journal of surgery. 2013; 100:252-260.

41. Cavallaro U, Christofori G. Cell adhesion and signalling by cadherins and Ig-CAMs in cancer. Nature reviews Cancer. 2004; 4:118-132.

42. Wu SC, Zhang Y. Active DNA demethylation: many roads lead to Rome. Nat Rev Mol Cell Biol. 2010; 11:607-620.

43. Ren J, Singh BN, Huang Q, Li Z, Gao Y, Mishra P, Hwa YL, Li J, Dowdy SC, Jiang SW. DNA hypermethylation as a chemotherapy target. Cell Signal. 2011; 23:1082-1093.

44. Chiappinelli KB, Strissel PL, Desrichard A, Li H, Henke C, Akman B, Hein A, Rote NS, Cope LM, Snyder A, Makarov V, Buhu S, Slamon DJ, Wolchok JD, Pardoll DM, Beckmann MW, et al. Inhibiting DNA Methylation Causes an Interferon Response in Cancer via dsRNA Including Endogenous Retroviruses. Cell. 2015; 162:974-986.

45. The Cancer Genome Atlas Research Network. Comprehensive molecular characterization of clear cell renal cell carcinoma. Nature. 2013; 499:43-49.

46. Kanehisa M, Goto S. KEGG: kyoto encyclopedia of genes and genomes. Nucleic Acids Res. 2000; 28:27-30.

47. Irizarry RA, Hobbs B, Collin F, Beazer-Barclay YD, Antonellis KJ, Scherf U, Speed TP. Exploration, normalization, and summaries of high density oligonucleotide array probe level data. Biostatistics. 2003; 4:249-264.

48. Huang da W, Sherman BT, Lempicki RA. Systematic and integrative analysis of large gene lists using DAVID bioinformatics resources. Nat Protoc. 2009; 4:44-57.