The Characterization of Twenty Sequenced Human Genomes

Kimberly Pelak; Kevin V. Shianna; Dongliang Ge; Jessica M. Maia; Mingfu Zhu; Jason P. Smith; Elizabeth T. Cirulli; Jacques Fellay; Samuel P. Dickson; Curtis Gumbs; Erin L. Heinzen; Anna C. Need; Elizabeth K. Ruzzo; Abanish Singh; C. Ryan Campbell; Linda K. Hong; Katharina A. Lornsen; Alexander McKenzie; Nara L. M. Sobreira; Julie Hoover‐Fong; Joshua D. Milner; Ruth Ottman; Barton F. Haynes; James J. Goedert; David B. Goldstein

doi:10.1371/journal.pgen.1001111

The Characterization of Twenty Sequenced Human Genomes

Kimberly Pelak(Duke University), Kevin V. Shianna(Duke University), Dongliang Ge(Duke University), Jessica M. Maia(Duke University), Mingfu Zhu(Duke University), Jason P. Smith(Duke University), Elizabeth T. Cirulli(Duke University), Jacques Fellay(Duke University), Samuel P. Dickson(Duke University), Curtis Gumbs(Duke University), Erin L. Heinzen(Duke University), Anna C. Need(Duke University), Elizabeth K. Ruzzo(Duke University), Abanish Singh(Duke University), C. Ryan Campbell(Duke University), Linda K. Hong(Duke University), Katharina A. Lornsen(Duke University), Alexander McKenzie(Duke University), Nara L. M. Sobreira(Johns Hopkins Medicine), Julie Hoover‐Fong(Johns Hopkins Medicine), Joshua D. Milner(National Institute of Allergy and Infectious Diseases), Ruth Ottman(Columbia University), Barton F. Haynes(Duke University), James J. Goedert(National Cancer Institute), David B. Goldstein(Duke University)

PLoS Genetics

September 9, 2010

10.1371/journal.pgen.1001111

Cited by 160Open Access

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Abstract

We present the analysis of twenty human genomes to evaluate the prospects for identifying rare functional variants that contribute to a phenotype of interest. We sequenced at high coverage ten "case" genomes from individuals with severe hemophilia A and ten "control" genomes. We summarize the number of genetic variants emerging from a study of this magnitude, and provide a proof of concept for the identification of rare and highly-penetrant functional variants by confirming that the cause of hemophilia A is easily recognizable in this data set. We also show that the number of novel single nucleotide variants (SNVs) discovered per genome seems to stabilize at about 144,000 new variants per genome, after the first 15 individuals have been sequenced. Finally, we find that, on average, each genome carries 165 homozygous protein-truncating or stop loss variants in genes representing a diverse set of pathways.

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