Gene-lifestyle Interactions in the Genomics of Human Complex Traits

Overview

Journal Eur J Hum Genet

Specialty Genetics

Date 2022 Mar 22

PMID 35314805

Authors

Vincent Laville

Timothy Majarian

Yun J Sung

Karen Schwander

Mary F Feitosa

Daniel I Chasman

Amy R Bentley

Charles N Rotimi

L Adrienne Cupples

Paul S de Vries

Michael R Brown

Alanna C Morrison

Aldi T Kraja

Mike Province

C Charles Gu

W James Gauderman

D C Rao

Alisa K Manning

Hugues Aschard

Affiliations

Soon will be listed here.

Abstract

The role and biological significance of gene-environment interactions in human traits and diseases remain poorly understood. To address these questions, the CHARGE Gene-Lifestyle Interactions Working Group conducted series of genome-wide interaction studies (GWIS) involving up to 610,475 individuals across four ancestries for three lipids and four blood pressure traits, while accounting for interaction effects with drinking and smoking exposures. Here we used GWIS summary statistics from these studies to decipher potential differences in genetic associations and G×E interactions across phenotype-exposure-ancestry combinations, and to derive insights on the potential mechanistic underlying G×E through in-silico functional analyses. Our analyses show first that interaction effects likely contribute to the commonly reported ancestry-specific genetic effect in complex traits, and second, that some phenotype-exposures pairs are more likely to benefit from a greater detection power when accounting for interactions. It also highlighted modest correlation between marginal and interaction effects, providing material for future methodological development and biological discussions. We also estimated contributions to phenotypic variance, including in particular the genetic heritability conditional on the exposure, and heritability partitioned across a range of functional annotations and cell types. In these analyses, we found multiple instances of potential heterogeneity of functional partitions between exposed and unexposed individuals, providing new evidence for likely exposure-specific genetic pathways. Finally, along this work, we identified potential biases in methods used to jointly meta-analyze genetic and interaction effects. We performed simulations to characterize these limitations and to provide the community with guidelines for future G×E studies.

Citing Articles

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Dron J, Natarajan P, Peloso G Curr Opin Lipidol. 2024; .

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Accounting for heterogeneity due to environmental sources in meta-analysis of genome-wide association studies.

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Large-scale genome-wide interaction analyses on multiple cardiometabolic risk factors to identify age-specific genetic risk factors.

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Gene-vegetarianism interactions in calcium, estimated glomerular filtration rate, and testosterone identified in genome-wide analysis across 30 biomarkers.

Francis M, Westerman K, Manning A, Ye K PLoS Genet. 2024; 20(7):e1011288.

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Gene-environment interactions within a precision environmental health framework.

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