Abstract
Simple SummaryLoss of DNA methylation is often observed in human tumors, but how this epigenetic alteration impacts the transcriptome of cancer cells remains largely undefined. So far, DNA hypomethylation in tumors has been associated with aberrant activation of a germline-specific gene expression program. Here, we exploited transcriptomic and methylomic datasets of lung adenocarcinoma to investigate the possibility that other gene expression programs also become ectopically activated in hypomethylated tumors. Remarkably, we found that DNA hypomethylation in lung adenocarcinoma is associated with ectopic activation of not only germline-specific genes, but also gene clusters displaying specific expression in the gastrointestinal tract, or in stratified epithelia. Interestingly, expression of genes in this latter group was of prognostic value. Together, our study brings novel insight into the transcriptomic changes associated with DNA hypomethylation in tumors, and is an incentive to explore the value of hypomethylated DNA sequences as cancer biomarkers.Genome-wide loss of DNA methylation is commonly observed in human cancers, but its impact on the tumor transcriptome remains ill-defined. Previous studies demonstrated that this epigenetic alteration causes aberrant activation of a germline-specific gene expression program. Here, we examined if DNA hypomethylation in tumors also leads to de-repression of gene clusters with other tissue specificities. To this end, we explored transcriptomic and methylomic datasets from human lung adenocarcinoma (LUAD) cell lines, normal lung, and lung alveolar type II cells, considered as the origin of LUAD. Interestingly, DNA demethylation in LUAD cell lines was associated with activation of not only germline-specific (CG) genes, but also gene clusters displaying specific expression in the gastrointestinal tract (GI), or in stratified epithelia (SE). Consistently, genes from all three clusters showed highly specific patterns of promoter methylation among normal tissues and cell types, and were generally sensitive to induction by a DNA demethylating agent. Analysis of TCGA datasets confirmed that demethylation and activation of CG, GI and SE genes also occurs in vivo in LUAD tumor tissues, in association with global genome hypomethylation. For genes of the GI cluster, we demonstrated that HNF4A is a necessary factor for transcriptional activation following promoter demethylation. Interestingly, expression of several SE genes, in particular FAM83A, correlated with both tumor grade and reduced patient survival. Together, our study uncovers novel cell-type specific gene clusters that become aberrantly activated in LUAD tumors in association with genome-wide hypomethylation.
Highlights
Cell type-specific patterns of gene expression are in part determined by epigenetic mechanisms, involving chemical modifications of DNA and associated histones, which modulate the accessibility of transcription factors to the chromatin [1,2]
A selection procedure was applied, using the following criteria (Figure 1A): (i) transcripts are not expressed and their promoter region is methylated in normal lung and AT2 cells; (ii) their expression is observed in a fraction of the lung adenocarcinoma (LUAD) cell lines and is inversely correlated with their promoter DNA methylation level; (iii) accuracy of expression specificity, transcriptional start site (TSS) position, and the structure of the transcripts was validated after visualization of RNA-seq data with the Integrative Genome Viewer (IGV)
Consistent with previous data, the results showed that CG-DDIC gene promoters only become substantially demethylated in the LUAD samples that show a marked decrease in global DNA methylation
Summary
Cell type-specific patterns of gene expression are in part determined by epigenetic mechanisms, involving chemical modifications of DNA and associated histones, which modulate the accessibility of transcription factors to the chromatin [1,2]. Methylation of CpG dinucleotides in the DNA, for instance, has been associated with a closed chromatin structure, and long-term repression of gene transcription [1]. It was proposed that DNA methylation contributes to the establishment of specific gene expression programs during differentiation of the various cell lineages [3]. Loosening of gene regulatory processes is thought to confer increased plasticity to cancer cells, thereby accelerating their progression towards a state of enhanced malignancy [5]
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