Transcriptional overlap links DNA hypomethylation with DNA hypermethylation at adjacent promoters in cancer

DNA methylation is an epigenetic mark associated with gene repression. It is now well established that tumor development involves alterations in DNA methylation patterns, which include both gains (hypermethylation) and losses (hypomethylation) of methylation marks in different genomic regions. The mechanisms underlying these two opposite, yet co-existing, alterations in tumors remain unclear. While studying the human MAGEA6/GABRA3 gene locus, we observed that DNA hypomethylation in tumor cells can lead to the activation of a long transcript (CT-GABRA3) that overlaps downstream promoters (GABRQ and GABRA3) and triggers their hypermethylation. Overlapped promoters displayed increases in H3K36me3, a histone mark known to be deposited during progression of the transcription machinery and to stimulate de novo DNA methylation. Consistent with such a processive mechanism, increases in H3K36me3 and DNA methylation were observed over the entire region covered by the CT-GABRA3 overlapping transcript. Importantly, experimental induction of CT-GABRA3 by depletion of DNMT1 DNA methyltransferase, resulted in a similar pattern of increased DNA methylation in the MAGEA6/GABRA3 locus. Bioinformatics analyses in lung cancer datasets identified other genomic loci displaying this process of coupled DNA hypo- and hypermethylation. In several of these loci, DNA hypermethylation affected tumor suppressor genes, e.g. RERG and PTPRO. Together, our work reveals that focal DNA hypomethylation in tumors can indirectly contribute to hypermethylation of nearby promoters through activation of overlapping transcription, and establishes therefore an unsuspected connection between these two opposite epigenetic alterations.