Detecting Rare and Common Haplotype-environment Interaction Under Uncertainty of Gene-environment Independence Assumption

Overview

Journal Biometrics

Publisher Oxford University Press

Specialty Public Health

Date 2016 Aug 2

PMID 27478935

Citations 7

Authors

Yuan Zhang

Shili Lin

Swati Biswas

Affiliations

Soon will be listed here.

Abstract

Finding rare variants and gene-environment interactions (GXE) is critical in dissecting complex diseases. We consider the problem of detecting GXE where G is a rare haplotype and E is a nongenetic factor. Such methods typically assume G-E independence, which may not hold in many applications. A pertinent example is lung cancer-there is evidence that variants on Chromosome 15q25.1 interact with smoking to affect the risk. However, these variants are associated with smoking behavior rendering the assumption of G-E independence inappropriate. With the motivation of detecting GXE under G-E dependence, we extend an existing approach, logistic Bayesian LASSO, which assumes G-E independence (LBL-GXE-I) by modeling G-E dependence through a multinomial logistic regression (referred to as LBL-GXE-D). Unlike LBL-GXE-I, LBL-GXE-D controls type I error rates in all situations; however, it has reduced power when G-E independence holds. To control type I error without sacrificing power, we further propose a unified approach, LBL-GXE, to incorporate uncertainty in the G-E independence assumption by employing a reversible jump Markov chain Monte Carlo method. Our simulations show that LBL-GXE has power similar to that of LBL-GXE-I when G-E independence holds, yet has well-controlled type I errors in all situations. To illustrate the utility of LBL-GXE, we analyzed a lung cancer dataset and found several significant interactions in the 15q25.1 region, including one between a specific rare haplotype and smoking.

Citing Articles

Bayesian Approaches in Exploring Gene-environment and Gene-gene Interactions: A Comprehensive Review.

Sun N, Wang Y, Chu J, Han Q, Shen Y Cancer Genomics Proteomics. 2023; 20(6suppl):669-678.

PMID: 38035701 PMC: 10687732. DOI: 10.21873/cgp.20414.

Bivariate quantitative Bayesian LASSO for detecting association of rare haplotypes with two correlated continuous phenotypes.

Sajal I, Biswas S Front Genet. 2023; 14:1104727.

PMID: 36968609 PMC: 10033866. DOI: 10.3389/fgene.2023.1104727.

A unified method for rare variant analysis of gene-environment interactions.

Lim E, Chen H, Dupuis J, Liu C Stat Med. 2019; 39(6):801-813.

PMID: 31799744 PMC: 7261513. DOI: 10.1002/sim.8446.

Bivariate logistic Bayesian LASSO for detecting rare haplotype association with two correlated phenotypes.

Yuan X, Biswas S Genet Epidemiol. 2019; 43(8):996-1017.

PMID: 31544985 PMC: 6836722. DOI: 10.1002/gepi.22258.

Comparison of haplotype-based tests for detecting gene-environment interactions with rare variants.

Papachristou C, Biswas S Brief Bioinform. 2019; 21(3):851-862.

PMID: 31329820 PMC: 7299304. DOI: 10.1093/bib/bbz031.

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