Evolution and Functional Impact of Rare Coding Variation from Deep Sequencing of Human Exomes

Jacob A. Tennessen; Abigail W. Bigham; Timothy D. O’Connor; Wenqing Fu; Eimear E. Kenny; Simon Gravel; Sean McGee; Ron Do; Xiaoming Liu; Goo Jun; Hyun Min Kang; Daniel M. Jordan; Suzanne M. Leal; Stacey Gabriel; Mark J. Rieder; Gonçalo R. Abecasis; David Altshuler; Deborah A. Nickerson; Eric Boerwinkle; Shamil Sunyaev; Carlos D. Bustamante; Michael J. Bamshad; Joshua M. Akey; Broad GO; Seattle GO; on behalf of the NHLBI Exome Sequencing Project

doi:10.1126/science.1219240

Evolution and Functional Impact of Rare Coding Variation from Deep Sequencing of Human Exomes

Jacob A. Tennessen(University of Washington), Abigail W. Bigham(University of Washington), Timothy D. O’Connor(University of Washington), Wenqing Fu(University of Washington), Eimear E. Kenny(Stanford University), Simon Gravel(Stanford University), Sean McGee(University of Washington), Ron Do(Broad Institute), Xiaoming Liu(The University of Texas Health Science Center at Houston), Goo Jun(University of Michigan), Hyun Min Kang(University of Michigan), Daniel M. Jordan(Brigham and Women's Hospital), Suzanne M. Leal(Baylor College of Medicine), Stacey Gabriel(Broad Institute), Mark J. Rieder(University of Washington), Gonçalo R. Abecasis(University of Michigan), David Altshuler(Broad Institute), Deborah A. Nickerson(University of Washington), Eric Boerwinkle(Baylor College of Medicine), Shamil Sunyaev(Broad Institute), Carlos D. Bustamante(Stanford University), Michael J. Bamshad(University of Washington), Joshua M. Akey(University of Washington), Broad GO, Seattle GO, on behalf of the NHLBI Exome Sequencing Project

Science

May 18, 2012

10.1126/science.1219240

Cited by 1,719

Abstract

As a first step toward understanding how rare variants contribute to risk for complex diseases, we sequenced 15,585 human protein-coding genes to an average median depth of 111× in 2440 individuals of European (n = 1351) and African (n = 1088) ancestry. We identified over 500,000 single-nucleotide variants (SNVs), the majority of which were rare (86% with a minor allele frequency less than 0.5%), previously unknown (82%), and population-specific (82%). On average, 2.3% of the 13,595 SNVs each person carried were predicted to affect protein function of ~313 genes per genome, and ~95.7% of SNVs predicted to be functionally important were rare. This excess of rare functional variants is due to the combined effects of explosive, recent accelerated population growth and weak purifying selection. Furthermore, we show that large sample sizes will be required to associate rare variants with complex traits.

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