Invited Commentary: Efficient Testing of Gene-Environment Interaction

doi:10.1093/aje/kwn352

American Journal of Epidemiology Advance Access originally published online on November 20, 2008
American Journal of Epidemiology 2009 169(2):231-233; doi:10.1093/aje/kwn352

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American Journal of Epidemiology Published by the Johns Hopkins Bloomberg School of Public Health 2008.

Invited Commentary

Invited Commentary: Efficient Testing of Gene-Environment Interaction

Nilanjan Chatterjee and Sholom Wacholder

Correspondence to Dr. Nilanjan Chatterjee, 6120 Executive Boulevard, EPS 8020, Rockville, MD 20852 (e-mail: chattern{at}mail.nih.gov).

Received for publication May 30, 2008. Accepted for publication August 26, 2008.

Gene-environment-wide interaction studies of disease occurrencein human populations may be able to exploit the same agnosticapproach to interrogating the human genome used by genome-wideassociation studies. The authors discuss 2 methods for takingadvantage of possible independence between a single nucleotidepolymorphism they call G (a genetic factor) and an environmentalfactor they call E while maintaining nominal type I error instudying G-E interaction when information on many genes is available.The first method is a simple 2-step procedure for testing thenull hypothesis of no multiplicative interaction against thealternative hypothesis of a multiplicative interaction betweenan E and at least one of the markers genotyped in a genome-wideassociation study. The added power for the method derives froma clever work-around of a multiple testing procedure. The secondis an empirical-Bayes–style shrinkage estimation frameworkfor G-E interaction and the associated tests that can gain efficiencyand power when the G-E independence assumption is met for mostG's in the underlying population and yet, unlike the case-onlymethod, is resistant to increased type I error when the underlyingassumption of independence is violated. The development of newapproaches to testing for interaction is an example of methodologicalprogress leading to practical advantages.

association; environment; genes; genetic markers; genetics; genome

Abbreviations: E, environmental factor; G, genetic factor

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