Allele-specific DNA Methylation is Increased in Cancers and Its Dense Mapping in Normal Plus Neoplastic Cells Increases the Yield of Disease-associated Regulatory SNPs

Overview

Journal Genome Biol

Specialties Biology
Genetics

Date 2020 Jun 30

PMID 32594908

Citations 19

Authors

Catherine Do

Emmanuel L P Dumont

Martha Salas

Angelica Castano

Huthayfa Mujahed

Leonel Maldonado

Arunjot Singh

Sonia C DaSilva-Arnold

Govind Bhagat

Soren Lehman

Angela M Christiano

Subha Madhavan

Peter L Nagy

Peter H R Green

Rena Feinman

Cornelia Trimble

Nicholas P Illsley

Karen Marder

Lawrence Honig

Catherine Monk

Andre Goy

Kar Chow

Samuel Goldlust

George Kaptain

David Siegel

Benjamin Tycko

Affiliations

Soon will be listed here.

Abstract

Background: Mapping of allele-specific DNA methylation (ASM) can be a post-GWAS strategy for localizing regulatory sequence polymorphisms (rSNPs). The advantages of this approach, and the mechanisms underlying ASM in normal and neoplastic cells, remain to be clarified.

Results: We perform whole genome methyl-seq on diverse normal cells and tissues and three cancer types. After excluding imprinting, the data pinpoint 15,112 high-confidence ASM differentially methylated regions, of which 1838 contain SNPs in strong linkage disequilibrium or coinciding with GWAS peaks. ASM frequencies are increased in cancers versus matched normal tissues, due to widespread allele-specific hypomethylation and focal allele-specific hypermethylation in poised chromatin. Cancer cells show increased allele switching at ASM loci, but disruptive SNPs in specific classes of CTCF and transcription factor binding motifs are similarly correlated with ASM in cancer and non-cancer. Rare somatic mutations affecting these same motif classes track with de novo ASM. Allele-specific transcription factor binding from ChIP-seq is enriched among ASM loci, but most ASM differentially methylated regions lack such annotations, and some are found in otherwise uninformative "chromatin deserts."

Conclusions: ASM is increased in cancers but occurs by a shared mechanism involving disruptive SNPs in CTCF and transcription factor binding sites in both normal and neoplastic cells. Dense ASM mapping in normal plus cancer samples reveals candidate rSNPs that are difficult to find by other approaches. Together with GWAS data, these rSNPs can nominate specific transcriptional pathways in susceptibility to autoimmune, cardiometabolic, neuropsychiatric, and neoplastic diseases.

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