Rare genetic variation at transcription factor binding sites modulates local DNA methylation profiles.

Alejandro Martin-Trujillo,Jonathan G Seidman,George A Porter,Elizabeth Goldmuntz,Richard Kim,Andrew J Sharp,Felix Richter,Sarah U Morton,Daniel Bernstein,Alessandro Giardini,Steven R Depalma,Christine E Seidman,Jane W Newburger,Wendy K Chung,Paras Garg,Nihir Patel,Dorota Gruber,Bharati Jadhav,Bruce D Gelb,Martin Tristani‐Firouzi ,David Mckean

doi:10.1371/journal.pgen.1009189

Abstract

Although DNA methylation is the best characterized epigenetic mark, the mechanism by which it is targeted to specific regions in the genome remains unclear. Recent studies have revealed that local DNA methylation profiles might be dictated by cis-regulatory DNA sequences that mainly operate via DNA-binding factors. Consistent with this finding, we have recently shown that disruption of CTCF-binding sites by rare single nucleotide variants (SNVs) can underlie cis-linked DNA methylation changes in patients with congenital anomalies. These data raise the hypothesis that rare genetic variation at transcription factor binding sites (TFBSs) might contribute to local DNA methylation patterning.In this work, by combining blood genome-wide DNA methylation profiles, whole genome sequencing-derived SNVs from 247 unrelated individuals along with 133 predicted TFBS motifs derived from ENCODE ChIP-Seq data, we observed an association between the disruption of binding sites for multiple TFs by rare SNVs and extreme DNA methylation values at both local and, to a lesser extent, distant CpGs. While the majority of these changes affected only single CpGs, 24% were associated with multiple outlier CpGs within ±1kb of the disrupted TFBS. Interestingly, disruption of functionally constrained sites within TF motifs lead to larger DNA methylation changes at nearby CpG sites. Altogether, these findings suggest that rare SNVs at TFBS negatively influence TF-DNA binding, which can lead to an altered local DNA methylation profile. Furthermore, subsequent integration of DNA methylation and RNA-Seq profiles from cardiac tissues enabled us to observe an association between rare SNV-directed DNA methylation and outlier expression of nearby genes.In conclusion, our findings not only provide insights into the effect of rare genetic variation at TFBS on shaping local DNA methylation and its consequences on genome regulation, but also provide a rationale to incorporate DNA methylation data to interpret the functional role of rare variants.

Highlights

Over the last decade, genomic DNA sequence variation has been associated with quantitative changes in multiple molecular phenotypes, including variation in gene expression and epigenetic marks such as chromatin accessibility and DNA methylation [1,2,3,4,5]
Rare variants at canonical transcription factors (TFs) motifs affect local DNA methylation profiles The flow diagram presented in Fig 1A represents our approach to integrate, filter and analyze data to determine the influence of rare regulatory genetic variation on local DNA methylation profiles
After identification of rare single nucleotide variants (SNVs) that lie within transcription factor binding sites (TFBSs), we extracted β-values corresponding to the Illumina Infinium MethylationEPIC BeadChip (EPIC) microarray probes located within the proximity of the SNV-disrupted TFBSs and ranked them from lowest (1) to highest (247)

Summary

Introduction

Genomic DNA sequence variation has been associated with quantitative changes in multiple molecular phenotypes, including variation in gene expression and epigenetic marks such as chromatin accessibility and DNA methylation [1,2,3,4,5]. These variants are commonly referred to as quantitative trait loci (QTLs), the mapping of which has allowed us to unravel the primary mechanisms by which cis-regulatory variants can influence phenotypic variation. An important regulatory mechanism for controlling transcriptional activity is DNA methylation [12]

Methods

Results

Conclusion