Several mechanisms of action have been proposed for DNA methyltransferase and histone deacetylase inhibitors (DNMTi and HDACi); mainly based on candidate gene approaches. However, less is known about their genome-wide transcriptional and epigenomic consequences. By mapping global transcription start site (TSS) and chromatin dynamics, we observed the cryptic transcription of thousands of treatment-induced non-annotated TSSs (TINATs) following DNMTi and/or HDACi treatment. The resulting transcripts frequently splice into protein-coding exons and encode truncated or chimeric open reading frames translated into products with predicted abnormal or immunogenic functions. TINAT transcription after DNMTi coincided with DNA hypomethylation and gain in classical promoter histone marks, while HDACi specifically induced a subset of TINATs in association with H2AK9ac, H3K14ac, and H3K23ac. Despite this mechanistic difference, both inhibitors convergently induced transcription from identical sites since we found TINATs to be encoded in solitary long-terminal repeats of the LTR12 family, epigenetically repressed in virtually all normal cells. In contrast to genetic mutations, epigenetic changes are potentially reversible, which is deeming them an attractive target for cancer treatment. Inhibitors directed against DNA methyltransferases (DNMTi) and histone deacetylases (HDACi) are used for the treatment of several haematopoietic malignancies1,2. However, despite their clinical use for several years, there is still a lack of knowledge regarding the mode of action3. Two previous studies on DNMTi in cancer cell lines reported the up-regulation of double stranded RNA (dsRNA) molecules originating from codogenic endogenous retroviruses (ERV) followed by an interferon response and the induction of viral defense genes4,5. However, it remains unclear how other classes of epigenetic drugs integrate into these findings and whether there are additional effects, potentially missed by candidate gene approaches. Here, we globally mapped DNMTi and HDACi-induced transcriptomic and epigenomic changes by using whole-genome profiling technologies (Supplementary Fig. 1 and Supplementary Table 1) and show that the vast majority of TSSs that transcriptionally responded towards epigenetic modulation were cryptic, currently non-annotated TSSs encoded in solitary long-terminal repeats (LTRs).
HPV-related methylation signature predicts survival in oropharyngeal squamous cell carcinomas
High-risk types of human papilloma virus (HPV) are increasingly associated with oropharyngeal squamous cell carcinoma (OPSCC). Strikingly, patients with HPV-positive OPSCC are highly curable with ionizing radiation and have better survival compared with HPV-negative patients, but the underlying molecular mechanisms remain poorly understood. We applied an array-based approach to monitor global changes in CpG island hypermethylation between HPV-negative and HPV-positive OPSCCs and identified a specific pattern of differentially methylated regions that critically depends on the presence of viral transcripts. HPV-related alterations were confirmed for the majority of candidate gene promoters by mass spectrometric, quantitative methylation analysis. There was a significant inverse correlation between promoter hypermethylation of ALDH1A2, OSR2, GATA4, GRIA4, and IRX4 and transcript levels. Interestingly, Kaplan-Meier analysis revealed that a combined promoter methylation pattern of low methylation levels in ALDH1A2 and OSR2 promoters and high methylation levels in GATA4, GRIA4, and IRX4 promoters was significantly correlated with improved survival in 3 independent patient cohorts. ALDH1A2 protein levels, determined by immunohistochemistry on tissue microarrays, confirmed the association with clinical outcome. In summary, our study highlights specific alterations in global gene promoter methylation in HPV-driven OPSCCs and identifies a signature that predicts the clinical outcome in OPSCCs.
Although clonal selection by genetic driver aberrations in cancer is well documented, the ability of epigenetic alterations to promote tumor evolution is undefined. We used 450k arrays and next-generation sequencing to evaluate intratumor heterogeneity and evolution of DNA methylation and genetic aberrations in chronic lymphocytic leukemia (CLL). CLL cases exhibit vast interpatient differences in intratumor methylation heterogeneity, with genetically clonal cases maintaining low methylation heterogeneity and up to 10% of total CpGs in a monoallelically methylated state. Increasing methylation heterogeneity correlates with advanced genetic subclonal complexity. Selection of novel DNA methylation patterns is observed only in cases that undergo genetic evolution, and independent genetic evolution is uncommon and is restricted to low-risk alterations. These results reveal that although evolution of DNA methylation occurs in high-risk, clinically progressive cases, positive selection of novel methylation patterns entails coevolution of genetic alteration(s) in CLL.
The molecular mechanisms underlying the genesis of cholangiocarcinomas (CCs) are poorly understood. Epigenetic changes such as aberrant hypermethylation and subsequent atypical gene expression are characteristic features of most human cancers. In CC, data regarding global methylation changes are lacking so far. We performed a genome-wide analysis for aberrant promoter methylation in human CCs. We profiled 10 intrahepatic and 8 extrahepatic CCs in comparison to non-neoplastic biliary tissue specimens, using methyl-CpG immunoprecipitation (MCIp) combined with whole-genome CpG island arrays. DNA methylation was confirmed by quantitative mass spectrometric analysis and functional relevance of promoter hypermethylation was shown in demethylation experiments of two CC cell lines using 5-aza-2 0 deoxycytidine (DAC) treatment. Immunohistochemical staining of tissue microarrays (TMAs) from 223 biliary tract cancers (BTCs) was used to analyze candidate gene expression at the protein level. Differentially methylated, promoter-associated regions were nonrandomly distributed and enriched for genes involved in cancer-related pathways including Wnt, transforming growth factor beta (TGF-b), and PI3K signaling pathways. In CC cell lines, silencing of genes involved in Wnt signaling, such as SOX17, WNT3A, DKK2, SFRP1, SFRP2, and SFRP4 was reversed after DAC administration. Candidate protein SFRP2 was substantially down-regulated in neoplastic tissues of all BTC subtypes as compared to normal tissues. A significant inverse correlation of SFRP2 protein expression and pT status was found in BTC patients. Conclusion: We provide a comprehensive analysis to define the genome-wide methylation landscape of human CC. Several candidate genes of cancer-relevant signaling pathways were identified, and closer analysis of selected Wnt pathway genes confirmed the relevance of this pathway in CC. The presented global methylation data are the basis for future studies on epigenetic changes in cholangiocarcinogenesis. (HEPATOLOGY 2014;59:544-554)
While transcription as regulated by histones and their post-translational modifications has been well described, the function of histone variants in this process remains poorly characterized. Potentially important insight into this process pertain to the frequently occurring mutations of H3.3, leading to G34 substitutions in childhood glioblastoma and giant cell tumor of the bone (GCTB). In this study, we have established primary cell lines from GCTB patients and used them to uncover the influence of H3.3 G34W substitutions on cellular growth behavior, gene expression, and chromatin compaction. Primary cell lines with H3.3 G34W showed increased colony formation, infiltration and proliferation, known hallmarks of tumor development. Isogenic cell lines with H3.3 G34W recapitulated the increased proliferation observed in primary cells. Transcriptomic analysis of primary cells and tumor biopsies revealed slightly more downregulated gene expression, perhaps by increased chromatin compaction. We identified components related to splicing, most prominently hnRNPs, by immunoprecipitation and mass spectrometry that specifically interact with H3.3 G34W in the isogenic cell lines. RNA-sequencing analysis and hybridization-based validations further enforced splicing aberrations. Our data uncover a role for H3.3 in RNA processing and chromatin modulation that is blocked by the G34W substitution, potentially driving the tumorigenic process in GCTB.
Colorectal cancer (CRC) presents as a very heterogeneous disease which cannot sufficiently be characterized with the currently known genetic and epigenetic markers. To identify new markers for CRC we scrutinized the methylation status of 231 DNA repair-related genes by methyl-CpG immunoprecipitation followed by global methylation profiling on a CpG island microarray, as altered expression of these genes could drive genomic and chromosomal instability observed in these tumors. We show for the first time hypermethylation of MMP9, DNMT3A and LIG4 in CRC which was confirmed in two CRC patient groups with different ethnicity. DNA ligase IV (LIG4) showed strong differential promoter methylation (up to 60%) which coincided with downregulation of mRNA in 51% of cases. This functional association of LIG4 methylation and gene expression was supported by LIG4 re-expression in 5-aza-2'-deoxycytidine-treated colon cancer cell lines, and reduced ligase IV amounts and end-joining activity in extracts of tumors with hypermethylation. Methylation of LIG4 was not associated with other genetic and epigenetic markers of CRC in our study. As LIG4 is located on chromosome 13 which is frequently amplified in CRC, two loci were tested for gene amplification in a subset of 47 cases. Comparison of amplification, methylation and expression data revealed that, in 30% of samples, the LIG4 gene was amplified and methylated, but expression was not changed. In conclusion, hypermethylation of the LIG4 promoter is a new mechanism to control ligase IV expression. It may represent a new epigenetic marker for CRC independent of known markers.
Differential Expression of the Tumor Suppressor A-Kinase Anchor Protein 12 in Human Diffuse and Pilocytic Astrocytomas Is Regulated by Promoter Methylation
The scaffold protein A-kinase anchor protein 12 (AKAP12) exerts tumor suppressor activity and is downregulated in several tumor entities. We characterized AKAP12 expression and regulation in astrocytomas, including pilocytic and diffusely infiltrating astrocytomas. We examined 194 human gliomas and 23 normal brain white matter samples by immunohistochemistry or immunoblotting for AKAP12 expression. We further performed quantitative methylation analysis of the AKAP12 promoter by MassARRAY® of normal brain, World Health Organization (WHO) grade I to IV astrocytomas, and glioma cell lines. Our results show that AKAP12 is expressed in a perivascular distribution in normal CNS, strongly upregulated in tumor cells in pilocytic astrocytomas, and weakly expressed in diffuse astrocytomas of WHO grade II to IV. Methylation analyses revealed specific hypermethylation of AKAP12α promoter in WHO grade II to IV astrocytomas. Restoration experiments using 5-aza-2'-deoxycytidine in primary glioblastoma cells decreased AKAP12α promoter methylation and markedly increased AKAP12α mRNA levels. In summary, we demonstrate that AKAP12 is differentially expressed in human astrocytomas showing high expression in pilocytic but low expression in diffuse astrocytomas of all WHO-grades. Our results further indicate that epigenetic mechanisms are involved in silencing AKAP12 in diffuse astrocytomas; however, a tumor suppressive role of AKAP12 in distinct astrocytoma subtypes remains to be determined.
Evolution and resulting tumor heterogeneity is currently under investigation for many malignancies since it may explain resistance of tumors to therapies. Pronounced intra-tumor genetic variation has been recently appreciated for solid tumors and leukemias, including chronic lymphocytic leukemia (CLL). Heterogeneous epigenetic alterations, such as DNA methylation, have the potential to add complexity to the leukemic cell population. Studies of the CLL methylome have revealed an abundance of genomic loci that display altered DNA methylation states, including methylation marks showing high prognostic significance. Despite the ubiquity of these epigenetic alterations, the mechanisms and impact of changes to the tumor epigenome in CLL are currently undefined. Here, we have used Illumina 450k arrays and next-generation sequencing to evaluate intra-tumor heterogeneity and evolution of DNA methylation and genetic aberrations in 80 cases of CLL, with 30 cases evaluated at two or more time points. CLL cases exhibit vast inter-patient differences in intra-tumor methylation heterogeneity. Genetically clonal cases maintain low methylation heterogeneity, resulting in up to 10% of total CpGs existing in a monoallelically-methylated state throughout the tumor cell population. Cases with high levels of methylation heterogeneity display a significantly shorter treatment-free time window preceding first therapy (median difference 11 vs. 49 months, P<0.01), coincident with unfavorable prognostic markers (IGHV unmutated, P<0.01; ZAP70 demethylated, P<0.05). Increasing methylation heterogeneity correlates with advanced genetic subclonal complexity (P<0.001). Intriguingly, a longitudinal evaluation reveals that selection of novel global DNA methylation patterns is observed only in cases that undergo genetic evolution. The level of methylation heterogeneity and presence of a genetic subclonal driver mutation in early time points are significantly associated with methylation evolution, signifying that heterogeneity indicates the presence of active evolution occurring within the tumor population. Independent genetic evolution without broad alterations to DNA methylation is uncommon and is associated with low-risk genetic alterations (e.g. deletion of 13q14). Cases showing high levels of methylation evolution display a significantly shorter event-free time window following first therapy (median survival 9 vs. 110 months, P<0.0001). This study articulates the novel finding of epigenetic and genetic coevolution in leukemia and highlights the dominant role of genetic aberrations in the selection of developing methylation patterns. As epigenetics plays a key role in determining cellular phenotypes, we propose that parallel alterations to the genome and epigenome endow expanding subclonal leukemic populations with novel attributes which contribute to acquired therapy resistance. This work also advocates a benefit of monitoring DNA methylation heterogeneity and evolution during CLL disease course. Disclosures: Kipps: Celgene: Membership on an entity's Board of Directors or advisory committees, Research Funding. Stilgenbauer:Roche: Consultancy, Research Funding, Travel grants Other; Mundipharma: Consultancy, Research Funding.
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