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Advantages and pitfalls in the application of mixed-model association methods

Abstract

Mixed linear models are emerging as a method of choice for conducting genetic association studies in humans and other organisms. The advantages of the mixed-linear-model association (MLMA) method include the prevention of false positive associations due to population or relatedness structure and an increase in power obtained through the application of a correction that is specific to this structure. An underappreciated point is that MLMA can also increase power in studies without sample structure by implicitly conditioning on associated loci other than the candidate locus. Numerous variations on the standard MLMA approach have recently been published, with a focus on reducing computational cost. These advances provide researchers applying MLMA methods with many options to choose from, but we caution that MLMA methods are still subject to potential pitfalls. Here we describe and quantify the advantages and pitfalls of MLMA methods as a function of study design and provide recommendations for the application of these methods in practical settings.

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Figure 1: MLMe increases power and MLMi decreases power compared to linear regression.
Figure 2: Effectiveness of mixed linear models using random or top associated markers in correcting for stratification.
Figure 3: Effectiveness of mixed linear models using top associated markers in increasing study power.

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Acknowledgements

We are grateful to N. Patterson, D. Heckerman, J. Listgarten, C. Lippert, E. Eskin, B. Vilhjalmsson, P. Loh, T. Hayeck, T. Frayling, A. McRae, L. Ronnegard, O. Weissbrod, G. Tucker and the GIANT Consortium for helpful discussions and to A. Gusev and S. Pollack for assistance with the multiple sclerosis and ulcerative colitis data sets. We are grateful to two anonymous referees for their helpful comments. This study makes use of data generated by the Wellcome Trust Case Control Consortium and data from the database of Genotypes and Phenotypes (dbGaP) under accessions phs000090.v2.p1 and phs000091.v2.p1 (see the Supplementary Note for the full set of acknowledgments for these data). This research was supported by US National Institutes of Health (NIH) grants R01 HG006399, P01 GM099568 and R01 GM075091, by the Australian Research Council (DP130102666) and by the Australian National Health and Medical Research Council (APP1011506 and APP1052684).

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Contributions

All authors conceived the project and designed the analyses. J.Y., N.A.Z. and A.L.P. performed the analyses. J.Y., M.E.G. and P.M.V. provided the theoretical derivations. J.Y. wrote the GCTA software. J.Y., N.A.Z. and A.L.P. wrote the manuscript with edits from all authors.

Corresponding authors

Correspondence to Peter M Visscher or Alkes L Price.

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The authors declare no competing financial interests.

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Supplementary Figure 1, Supplementary Tables 1–11 and Supplementary Note. (PDF 434 kb)

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Yang, J., Zaitlen, N., Goddard, M. et al. Advantages and pitfalls in the application of mixed-model association methods. Nat Genet 46, 100–106 (2014). https://doi.org/10.1038/ng.2876

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