Common DNA sequence variation influences 3-dimensional conformation of the human genome

David U Gorkin,Jonathan Sebat,Joshua Chiou,Tristin Liu,Yunjiang Qiu,Kipper Fletez-Brant,Anthony D Schmitt,Kasper D Hansen,Amina Noor,Ming Hu,Yun Li,Kyle J Gaulton,Bing Ren

doi:10.1186/s13059-019-1855-4

Abstract

BackgroundThe 3-dimensional (3D) conformation of chromatin inside the nucleus is integral to a variety of nuclear processes including transcriptional regulation, DNA replication, and DNA damage repair. Aberrations in 3D chromatin conformation have been implicated in developmental abnormalities and cancer. Despite the importance of 3D chromatin conformation to cellular function and human health, little is known about how 3D chromatin conformation varies in the human population, or whether DNA sequence variation between individuals influences 3D chromatin conformation.ResultsTo address these questions, we perform Hi-C on lymphoblastoid cell lines from 20 individuals. We identify thousands of regions across the genome where 3D chromatin conformation varies between individuals and find that this variation is often accompanied by variation in gene expression, histone modifications, and transcription factor binding. Moreover, we find that DNA sequence variation influences several features of 3D chromatin conformation including loop strength, contact insulation, contact directionality, and density of local cis contacts. We map hundreds of quantitative trait loci associated with 3D chromatin features and find evidence that some of these same variants are associated at modest levels with other molecular phenotypes as well as complex disease risk.ConclusionOur results demonstrate that common DNA sequence variants can influence 3D chromatin conformation, pointing to a more pervasive role for 3D chromatin conformation in human phenotypic variation than previously recognized.

Highlights

Three-dimensional (3D) organization of chromatin is essential for proper regulation of gene expression [1,2,3] and plays an important role in other nuclear processes including DNA replication [4, 5], X chromosome inactivation [6,7,8,9], and DNA repair [10, 11]
Our results demonstrate that variation in 3D chromatin conformation is readily detectable from Hi-C data, often overlaps with regions of transcriptomic and epigenomic variability, and is influenced in part by genetic variation that may contribute to disease risk
Mapping 3D chromatin conformation across individuals To generate maps of 3D chromatin conformation suitable for comparison across individuals, we performed “dilution” Hi-C on lymphoblastoid cell lines (LCLs) derived from 13 Yoruban individuals, one Puerto Rican trio, and one Han Chinese trio (19 individuals total; Additional file 2: Table S1)

Summary

Introduction

Three-dimensional (3D) organization of chromatin is essential for proper regulation of gene expression [1,2,3] and plays an important role in other nuclear processes including DNA replication [4, 5], X chromosome inactivation [6,7,8,9], and DNA repair [10, 11]. Many genetic variants associated with human traits by Genome-Wide Association Studies (GWAS) occur in distal regulatory elements that loop to putative target gene promoters in 3D, and in some cases, the strength of these looping interactions has been shown to vary between alleles of the associated SNP [33, 34]. These studies demonstrate that both large effects as well as more subtle aberrations of 3D chromatin conformation are potential mechanisms of disease, population-level variation in 3D chromatin conformation more broadly has remained unexplored. Despite the importance of 3D chromatin conformation to cellular function and human health, little is known about how 3D chromatin conformation varies in the human population, or whether DNA sequence variation between individuals influences 3D chromatin conformation

Methods

Results

Conclusion