Genetic effects on liver chromatin accessibility identify disease regulatory variants

NISC Comparative Sequencing Program

doi:10.1016/j.ajhg.2021.05.001

Genetic effects on liver chromatin accessibility identify disease regulatory variants

NISC Comparative Sequencing Program

Research output: Contribution to journal › Article › peer-review

24 Scopus citations

Abstract

Identifying the molecular mechanisms by which genome-wide association study (GWAS) loci influence traits remains challenging. Chromatin accessibility quantitative trait loci (caQTLs) help identify GWAS loci that may alter GWAS traits by modulating chromatin structure, but caQTLs have been identified in a limited set of human tissues. Here we mapped caQTLs in human liver tissue in 20 liver samples and identified 3,123 caQTLs. The caQTL variants are enriched in liver tissue promoter and enhancer states and frequently disrupt binding motifs of transcription factors expressed in liver. We predicted target genes for 861 caQTL peaks using proximity, chromatin interactions, correlation with promoter accessibility or gene expression, and colocalization with expression QTLs. Using GWAS signals for 19 liver function and/or cardiometabolic traits, we identified 110 colocalized caQTLs and GWAS signals, 56 of which contained a predicted caPeak target gene. At the LITAF LDL-cholesterol GWAS locus, we validated that a caQTL variant showed allelic differences in protein binding and transcriptional activity. These caQTLs contribute to the epigenomic characterization of human liver and help identify molecular mechanisms and genes at GWAS loci.

Original language	English
Pages (from-to)	1169-1189
Number of pages	21
Journal	American journal of human genetics
Volume	108
Issue number	7
DOIs	https://doi.org/10.1016/j.ajhg.2021.05.001
State	Published - Jul 1 2021

Keywords

ATAC-seq
caQTL
cardiometabolic traits
chromatin accessibility
eQTL
GWAS
transcription factor motif

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10.1016/j.ajhg.2021.05.001

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@article{5256946616584dcf930f20d2b9e6c121,

title = "Genetic effects on liver chromatin accessibility identify disease regulatory variants",

abstract = "Identifying the molecular mechanisms by which genome-wide association study (GWAS) loci influence traits remains challenging. Chromatin accessibility quantitative trait loci (caQTLs) help identify GWAS loci that may alter GWAS traits by modulating chromatin structure, but caQTLs have been identified in a limited set of human tissues. Here we mapped caQTLs in human liver tissue in 20 liver samples and identified 3,123 caQTLs. The caQTL variants are enriched in liver tissue promoter and enhancer states and frequently disrupt binding motifs of transcription factors expressed in liver. We predicted target genes for 861 caQTL peaks using proximity, chromatin interactions, correlation with promoter accessibility or gene expression, and colocalization with expression QTLs. Using GWAS signals for 19 liver function and/or cardiometabolic traits, we identified 110 colocalized caQTLs and GWAS signals, 56 of which contained a predicted caPeak target gene. At the LITAF LDL-cholesterol GWAS locus, we validated that a caQTL variant showed allelic differences in protein binding and transcriptional activity. These caQTLs contribute to the epigenomic characterization of human liver and help identify molecular mechanisms and genes at GWAS loci.",

keywords = "ATAC-seq, caQTL, cardiometabolic traits, chromatin accessibility, eQTL, GWAS, transcription factor motif",

author = "{NISC Comparative Sequencing Program} and Currin, {Kevin W.} and Erdos, {Michael R.} and Narisu Narisu and Vivek Rai and Swarooparani Vadlamudi and Perrin, {Hannah J.} and Idol, {Jacqueline R.} and Tingfen Yan and Albanus, {Ricardo D.Oliveira} and Broadaway, {K. Alaine} and Etheridge, {Amy S.} and Bonnycastle, {Lori L.} and Peter Orchard and Didion, {John P.} and Chaudhry, {Amarjit S.} and Barnabas, {Beatrice B.} and Sean Black and Bouffard, {Gerard G.} and Brooks, {Shelise Y.} and Holly Coleman and Lyudmila Dekhtyar and Joel Han and Ho, {Shi ling} and Juyun Kim and Richelle Legaspi and Maduro, {Quino L.} and Masiello, {Catherine A.} and McDowell, {Jennifer C.} and Casandra Montemayor and Mullikin, {James C.} and Morgan Park and Riebow, {Nancy L.} and Karen Schandler and Brian Schmidt and Christina Sison and Sirintorn Stantripop and Thomas, {James W.} and Thomas, {Pamela J.} and Meghana Vemulapalli and Young, {Alice C.} and Federico Innocenti and Schuetz, {Erin G.} and Scott, {Laura J.} and Parker, {Stephen C.J.} and Collins, {Francis S.} and Mohlke, {Karen L.}",

note = "Publisher Copyright: {\textcopyright} 2021 American Society of Human Genetics",

year = "2021",

month = jul,

day = "1",

doi = "10.1016/j.ajhg.2021.05.001",

language = "English",

volume = "108",

pages = "1169--1189",

journal = "American journal of human genetics",

issn = "0002-9297",

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T1 - Genetic effects on liver chromatin accessibility identify disease regulatory variants

AU - NISC Comparative Sequencing Program

AU - Currin, Kevin W.

AU - Erdos, Michael R.

AU - Narisu, Narisu

AU - Rai, Vivek

AU - Vadlamudi, Swarooparani

AU - Perrin, Hannah J.

AU - Idol, Jacqueline R.

AU - Yan, Tingfen

AU - Albanus, Ricardo D.Oliveira

AU - Broadaway, K. Alaine

AU - Etheridge, Amy S.

AU - Bonnycastle, Lori L.

AU - Orchard, Peter

AU - Didion, John P.

AU - Chaudhry, Amarjit S.

AU - Barnabas, Beatrice B.

AU - Black, Sean

AU - Bouffard, Gerard G.

AU - Brooks, Shelise Y.

AU - Coleman, Holly

AU - Dekhtyar, Lyudmila

AU - Han, Joel

AU - Ho, Shi ling

AU - Kim, Juyun

AU - Legaspi, Richelle

AU - Maduro, Quino L.

AU - Masiello, Catherine A.

AU - McDowell, Jennifer C.

AU - Montemayor, Casandra

AU - Mullikin, James C.

AU - Park, Morgan

AU - Riebow, Nancy L.

AU - Schandler, Karen

AU - Schmidt, Brian

AU - Sison, Christina

AU - Stantripop, Sirintorn

AU - Thomas, James W.

AU - Thomas, Pamela J.

AU - Vemulapalli, Meghana

AU - Young, Alice C.

AU - Innocenti, Federico

AU - Schuetz, Erin G.

AU - Scott, Laura J.

AU - Parker, Stephen C.J.

AU - Collins, Francis S.

AU - Mohlke, Karen L.

PY - 2021/7/1

Y1 - 2021/7/1

N2 - Identifying the molecular mechanisms by which genome-wide association study (GWAS) loci influence traits remains challenging. Chromatin accessibility quantitative trait loci (caQTLs) help identify GWAS loci that may alter GWAS traits by modulating chromatin structure, but caQTLs have been identified in a limited set of human tissues. Here we mapped caQTLs in human liver tissue in 20 liver samples and identified 3,123 caQTLs. The caQTL variants are enriched in liver tissue promoter and enhancer states and frequently disrupt binding motifs of transcription factors expressed in liver. We predicted target genes for 861 caQTL peaks using proximity, chromatin interactions, correlation with promoter accessibility or gene expression, and colocalization with expression QTLs. Using GWAS signals for 19 liver function and/or cardiometabolic traits, we identified 110 colocalized caQTLs and GWAS signals, 56 of which contained a predicted caPeak target gene. At the LITAF LDL-cholesterol GWAS locus, we validated that a caQTL variant showed allelic differences in protein binding and transcriptional activity. These caQTLs contribute to the epigenomic characterization of human liver and help identify molecular mechanisms and genes at GWAS loci.

AB - Identifying the molecular mechanisms by which genome-wide association study (GWAS) loci influence traits remains challenging. Chromatin accessibility quantitative trait loci (caQTLs) help identify GWAS loci that may alter GWAS traits by modulating chromatin structure, but caQTLs have been identified in a limited set of human tissues. Here we mapped caQTLs in human liver tissue in 20 liver samples and identified 3,123 caQTLs. The caQTL variants are enriched in liver tissue promoter and enhancer states and frequently disrupt binding motifs of transcription factors expressed in liver. We predicted target genes for 861 caQTL peaks using proximity, chromatin interactions, correlation with promoter accessibility or gene expression, and colocalization with expression QTLs. Using GWAS signals for 19 liver function and/or cardiometabolic traits, we identified 110 colocalized caQTLs and GWAS signals, 56 of which contained a predicted caPeak target gene. At the LITAF LDL-cholesterol GWAS locus, we validated that a caQTL variant showed allelic differences in protein binding and transcriptional activity. These caQTLs contribute to the epigenomic characterization of human liver and help identify molecular mechanisms and genes at GWAS loci.

KW - ATAC-seq

KW - caQTL

KW - cardiometabolic traits

KW - chromatin accessibility

KW - eQTL

KW - GWAS

KW - transcription factor motif

UR - http://www.scopus.com/inward/record.url?scp=85107580896&partnerID=8YFLogxK

U2 - 10.1016/j.ajhg.2021.05.001

DO - 10.1016/j.ajhg.2021.05.001

M3 - Article

AN - SCOPUS:85107580896

SN - 0002-9297

VL - 108

SP - 1169

EP - 1189

JO - American journal of human genetics

JF - American journal of human genetics

IS - 7

ER -

Genetic effects on liver chromatin accessibility identify disease regulatory variants

Abstract

Keywords

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