Abstract
BackgroundGenomic rearrangements exert a heavy influence on the molecular landscape of cancer. New analytical approaches integrating somatic structural variants (SSVs) with altered gene features represent a framework by which we can assign global significance to a core set of genes, analogous to established methods that identify genes non-randomly targeted by somatic mutation or copy number alteration. While recent studies have defined broad patterns of association involving gene transcription and nearby SSV breakpoints, global alterations in DNA methylation in the context of SSVs remain largely unexplored.ResultsBy data integration of whole genome sequencing, RNA sequencing, and DNA methylation arrays from more than 1400 human cancers, we identify hundreds of genes and associated CpG islands (CGIs) for which the nearby presence of a somatic structural variant (SSV) breakpoint is recurrently associated with altered expression or DNA methylation, respectively, independently of copy number alterations. CGIs with SSV-associated increased methylation are predominantly promoter-associated, while CGIs with SSV-associated decreased methylation are enriched for gene body CGIs. Rearrangement of genomic regions normally having higher or lower methylation is often involved in SSV-associated CGI methylation alterations. Across cancers, the overall structural variation burden is associated with a global decrease in methylation, increased expression in methyltransferase genes and DNA damage response genes, and decreased immune cell infiltration.ConclusionGenomic rearrangement appears to have a major role in shaping the cancer DNA methylome, to be considered alongside commonly accepted mechanisms including histone modifications and disruption of DNA methyltransferases.
Highlights
The cancer genome is characterized by widespread genomic rearrangement in addition to point mutations
In two separate studies of The Cancer Genome Atlas (TCGA) and Pan-Cancer Analysis of Whole Genomes (PCAWG) data, respectively [3, 5], we developed a systematic analytical approach to integrate somatic structural variant (SSV) breakpoints with the expression of nearby genes, whereby we cataloged hundreds of genes appearing deregulated by rearrangement-mediated cis-regulatory alterations
Previous studies have examined the relationship between copy number alterations (CNAs) and DNA methylation in cancer [12], to date, there has been no global survey to identify CpG islands (CGIs) with altered methylation associated with nearby SSV breakpoints, independently of any associated CNA
Summary
The cancer genome is characterized by widespread genomic rearrangement in addition to point mutations. In two separate studies of TCGA and PCAWG data, respectively [3, 5], we developed a systematic analytical approach to integrate SSV breakpoints with the expression of nearby genes, whereby we cataloged hundreds of genes appearing deregulated by rearrangement-mediated cis-regulatory alterations. In addition to genetic mutations and genomic rearrangements, epigenetic alterations, including DNA methylation, play a major role in the development and progression of cancer. New analytical approaches integrating somatic structural variants (SSVs) with altered gene features represent a framework by which we can assign global significance to a core set of genes, analogous to established methods that identify genes non-randomly targeted by somatic mutation or copy number alteration. While recent studies have defined broad patterns of association involving gene transcription and nearby SSV breakpoints, global alterations in DNA methylation in the context of SSVs remain largely unexplored
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