Sequence Kernel Association Test for Quantitative Traits in Family Samples |
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Authors: | Han Chen James B. Meigs Josée Dupuis |
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Affiliation: | 1. Department of Biostatistics, Boston University School of Public Health, , Boston, Massachusetts;2. General Medicine Division, Massachusetts General Hospital, , Boston, Massachusetts;3. Department of Medicine, Harvard Medical School, , Boston, Massachusetts;4. National Heart, Lung and Blood Institute's Framingham Heart Study, , Framingham, Massachusetts |
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Abstract: | A large number of rare genetic variants have been discovered with the development in sequencing technology and the lowering of sequencing costs. Rare variant analysis may help identify novel genes associated with diseases and quantitative traits, adding to our knowledge of explaining heritability of these phenotypes. Many statistical methods for rare variant analysis have been developed in recent years, but some of them require the strong assumption that all rare variants in the analysis share the same direction of effect, and others requiring permutation to calculate the P‐values are computer intensive. Among these methods, the sequence kernel association test (SKAT) is a powerful method under many different scenarios. It does not require any assumption on the directionality of effects, and statistical significance is computed analytically. In this paper, we extend SKAT to be applicable to family data. The family‐based SKAT (famSKAT) has a different test statistic and null distribution compared to SKAT, but is equivalent to SKAT when there is no familial correlation. Our simulation studies show that SKAT has inflated type I error if familial correlation is inappropriately ignored, but has appropriate type I error if applied to a single individual per family to obtain an unrelated subset. In contrast, famSKAT has the correct type I error when analyzing correlated observations, and it has higher power than competing methods in many different scenarios. We illustrate our approach to analyze the association of rare genetic variants using glycemic traits from the Framingham Heart Study. |
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Keywords: | rare variant analysis quantitative traits family samples heritability linear mixed effects model |
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