A unified test of linkage analysis and rare-variant association for analysis of pedigree sequence data

Hao Hu; Jared C. Roach; Hilary Coon; Stephen L. Guthery; Karl V. Voelkerding; Rebecca L. Margraf; Jacob D. Durtschi; Sean V. Tavtigian; Shankaracharya; Wilfred Wu; Paul Scheet; Shuoguo Wang; Jinchuan Xing; Gustavo Glusman; Robert Hubley; Hong Li; Vidu Garg; Barry Moore; Leroy Hood; David J. Galas; Deepak Srivastava; Martin G. Reese; Lynn B. Jorde; Mark Yandell; Chad D. Huff

doi:10.1038/nbt.2895

A unified test of linkage analysis and rare-variant association for analysis of pedigree sequence data

Hao Hu, Jared C. Roach, Hilary Coon, Stephen L. Guthery, Karl V. Voelkerding, Rebecca L. Margraf, Jacob D. Durtschi, Sean V. Tavtigian, Shankaracharya, Wilfred Wu, Paul Scheet, Shuoguo Wang, Jinchuan Xing, Gustavo Glusman, Robert Hubley, Hong Li, Vidu Garg, Barry Moore, Leroy Hood, David J. GalasDeepak Srivastava, Martin G. Reese, Lynn B. Jorde, Mark Yandell, Chad D. Huff

Epidemiology

Research output: Contribution to journal › Article › peer-review

76 Scopus citations

Abstract

High-throughput sequencing of related individuals has become an important tool for studying human disease. However, owing to technical complexity and lack of available tools, most pedigree-based sequencing studies rely on an ad hoc combination of suboptimal analyses. Here we present pedigree-VAAST (pVAAST), a disease-gene identification tool designed for high-throughput sequence data in pedigrees. pVAAST uses a sequence-based model to perform variant and gene-based linkage analysis. Linkage information is then combined with functional prediction and rare variant case-control association information in a unified statistical framework. pVAAST outperformed linkage and rare-variant association tests in simulations and identified disease-causing genes from whole-genome sequence data in three human pedigrees with dominant, recessive and de novo inheritance patterns. The approach is robust to incomplete penetrance and locus heterogeneity and is applicable to a wide variety of genetic traits. pVAAST maintains high power across studies of monogenic, high-penetrance phenotypes in a single pedigree to highly polygenic, common phenotypes involving hundreds of pedigrees.

Original language	English (US)
Pages (from-to)	663-669
Number of pages	7
Journal	Nature biotechnology
Volume	32
Issue number	7
DOIs	https://doi.org/10.1038/nbt.2895
State	Published - Jul 2014

ASJC Scopus subject areas

Biotechnology
Bioengineering
Applied Microbiology and Biotechnology
Molecular Medicine
Biomedical Engineering

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10.1038/nbt.2895

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Hu, H., Roach, J. C., Coon, H., Guthery, S. L., Voelkerding, K. V., Margraf, R. L., Durtschi, J. D., Tavtigian, S. V., Shankaracharya, Wu, W., Scheet, P., Wang, S., Xing, J., Glusman, G., Hubley, R., Li, H., Garg, V., Moore, B., Hood, L., ... Huff, C. D. (2014). A unified test of linkage analysis and rare-variant association for analysis of pedigree sequence data. Nature biotechnology, 32(7), 663-669. https://doi.org/10.1038/nbt.2895

Hu, H, Roach, JC, Coon, H, Guthery, SL, Voelkerding, KV, Margraf, RL, Durtschi, JD, Tavtigian, SV, Shankaracharya, Wu, W, Scheet, P, Wang, S, Xing, J, Glusman, G, Hubley, R, Li, H, Garg, V, Moore, B, Hood, L, Galas, DJ, Srivastava, D, Reese, MG, Jorde, LB, Yandell, M & Huff, CD 2014, 'A unified test of linkage analysis and rare-variant association for analysis of pedigree sequence data', Nature biotechnology, vol. 32, no. 7, pp. 663-669. https://doi.org/10.1038/nbt.2895

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abstract = "High-throughput sequencing of related individuals has become an important tool for studying human disease. However, owing to technical complexity and lack of available tools, most pedigree-based sequencing studies rely on an ad hoc combination of suboptimal analyses. Here we present pedigree-VAAST (pVAAST), a disease-gene identification tool designed for high-throughput sequence data in pedigrees. pVAAST uses a sequence-based model to perform variant and gene-based linkage analysis. Linkage information is then combined with functional prediction and rare variant case-control association information in a unified statistical framework. pVAAST outperformed linkage and rare-variant association tests in simulations and identified disease-causing genes from whole-genome sequence data in three human pedigrees with dominant, recessive and de novo inheritance patterns. The approach is robust to incomplete penetrance and locus heterogeneity and is applicable to a wide variety of genetic traits. pVAAST maintains high power across studies of monogenic, high-penetrance phenotypes in a single pedigree to highly polygenic, common phenotypes involving hundreds of pedigrees.",

author = "Hao Hu and Roach, {Jared C.} and Hilary Coon and Guthery, {Stephen L.} and Voelkerding, {Karl V.} and Margraf, {Rebecca L.} and Durtschi, {Jacob D.} and Tavtigian, {Sean V.} and Shankaracharya and Wilfred Wu and Paul Scheet and Shuoguo Wang and Jinchuan Xing and Gustavo Glusman and Robert Hubley and Hong Li and Vidu Garg and Barry Moore and Leroy Hood and Galas, {David J.} and Deepak Srivastava and Reese, {Martin G.} and Jorde, {Lynn B.} and Mark Yandell and Huff, {Chad D.}",

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AU - Moore, Barry

AU - Hood, Leroy

AU - Galas, David J.

AU - Srivastava, Deepak

AU - Reese, Martin G.

AU - Jorde, Lynn B.

AU - Yandell, Mark

AU - Huff, Chad D.

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A unified test of linkage analysis and rare-variant association for analysis of pedigree sequence data

Abstract

ASJC Scopus subject areas

MD Anderson CCSG core facilities

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