Population Admixture: Detection by Hardy-Weinberg Test and Its Quantitative Effects on Linkage-Disequilibrium Methods for Localizing Genes Underlying Complex Traits

Population Admixture: Detection by Hardy-Weinberg Test and Its Quantitative Effects on Linkage-Disequilibrium Methods for Localizing Genes Underlying Complex Traits

Hong-Wen Deng^a,b,c, Wei-Min Chen^a,b, and Robert R. Recker^a
^a Osteoporosis Research Center, Creighton University, Omaha, Nebraska 68131
^b Department of Biomedical Sciences, Creighton University, Omaha, Nebraska 68131
^c Laboratory of Molecular and Statistical Genetics, Hunan Normal University, ChangSha, Hunan 410081, People's Republic of China

Corresponding author: Hong-Wen Deng, Osteoporosis Research Ctr., Creighton University, 601 N. 30th St., Omaha, NE 68131., deng{at}creighton.edu (E-mail)

Communicating editor: M. A. ASMUSSEN

In association studies searching for genes underlying complextraits, the results are often inconsistent, and population admixturehas been recognized qualitatively as one major potential cause.Hardy-Weinberg equilibrium (HWE) is often employed to test forpopulation admixture; however, its power is generally unknown.Through analytical and simulation approaches, we quantify thepower of the HWE test for population admixture and the effectsof population admixture on increasing the type I error rateof association studies under various scenarios of populationdifferentiation and admixture. We found that (1) the power ofthe HWE test for detecting population admixture is usually small;(2) population admixture seriously elevates type I error ratefor detecting genes underlying complex traits, the extent ofwhich depends on the degrees of population differentiation andadmixture; (3) HWE testing for population admixture should beperformed with random samples or only with controls at the candidategenes, or the test can be performed for combined samples ofcases and controls at marker loci that are not linked to thedisease; (4) testing HWE for population admixture generallyreduces false positive association findings of genes underlyingcomplex traits but the effect is small; and (5) with populationadmixture, a linkage disequilibrium method that employs casesonly is more robust and yields many fewer false positive findingsthan conventional case-control analyses. Therefore, unless randomsamples are carefully selected from one homogeneous population,admixture is always a legitimate concern for positive findingsin association studies except for the analyses that deliberatelycontrol population admixture.

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