Recovery of trait heritability from whole genome sequence data

Pierrick Wainschtein; Deepti Jain; Zhili Zheng; TOPMed Anthropometry Working Group; L. Adrienne Cupples; Aladdin H. Shadyab; Barbara McKnight; Benjamin M. Shoemaker; Braxton D. Mitchell; Bruce M. Psaty; Charles Kooperberg; Ching‐Ti Liu; Christine M. Albert; Dan M. Roden; Daniel I. Chasman; Dawood Darbar; Donald M. Lloyd‐Jones; Donna K. Arnett; Elizabeth A. Regan; Eric Boerwinkle; Jerome I. Rotter; Jeffrey R. O’Connell; Lisa R. Yanek; Mariza de Andrade; Matthew Allison; Merry‐Lynn McDonald; Mina K. Chung; Myriam Fornage; Nathalie Chami; Nicholas L. Smith; Patrick T. Ellinor; Ramachandran S. Vasan; Rasika A. Mathias; Ruth J. F. Loos; Stephen S. Rich; Steven A. Lubitz; Susan R. Heckbert; Susan Redline; Xiuqing Guo; Yii-DerIda Chen; Cecelia Laurie; Ryan D. Hernandez; Stephen T. McGarvey; Michael E. Goddard; Cathy C. Laurie; Kari E. North; Leslie A. Lange; Bruce S. Weir; Loïc Yengo; Jian Yang; Peter M. Visscher

doi:10.1101/588020

Recovery of trait heritability from whole genome sequence data

Pierrick Wainschtein(The University of Queensland), Deepti Jain(University of Washington), Zhili Zheng(The University of Queensland), TOPMed Anthropometry Working Group(Boston University), L. Adrienne Cupples(Boston University), Aladdin H. Shadyab(University of Washington), Barbara McKnight(University of Washington), Benjamin M. Shoemaker(University of Maryland, Baltimore), Braxton D. Mitchell(University of Maryland, Baltimore), Bruce M. Psaty(University of Washington), Charles Kooperberg(Boston University), Ching‐Ti Liu(Boston University), Christine M. Albert(Brigham and Women's Hospital), Dan M. Roden(Brigham and Women's Hospital), Daniel I. Chasman(Brigham and Women's Hospital), Dawood Darbar(Northwestern University), Donald M. Lloyd‐Jones(Northwestern University), Donna K. Arnett(University of Kentucky), Elizabeth A. Regan(National Jewish Health), Eric Boerwinkle(UCLA Medical Center), Jerome I. Rotter(University of Maryland, Baltimore), Jeffrey R. O’Connell(University of Maryland, Baltimore), Lisa R. Yanek(Johns Hopkins University), Mariza de Andrade(University of California San Diego), Matthew Allison(University of Alabama at Birmingham), Merry‐Lynn McDonald(Cleveland Clinic), Mina K. Chung(Cleveland Clinic), Myriam Fornage(Child Health and Development Institute), Nathalie Chami(Kaiser Permanente Washington Health Research Institute), Nicholas L. Smith(Harvard University), Patrick T. Ellinor(Boston University), Ramachandran S. Vasan(Boston University), Rasika A. Mathias(Johns Hopkins University), Ruth J. F. Loos(Child Health and Development Institute), Stephen S. Rich(Broad Institute), Steven A. Lubitz(Broad Institute), Susan R. Heckbert(Brigham and Women's Hospital), Susan Redline(Beth Israel Deaconess Medical Center), Xiuqing Guo(UCLA Medical Center), Yii-DerIda Chen(University of Washington), Cecelia Laurie(University of California, San Francisco), Ryan D. Hernandez(University of California, San Francisco), Stephen T. McGarvey(The University of Melbourne), Michael E. Goddard(The University of Melbourne), Cathy C. Laurie(University of North Carolina at Chapel Hill), Kari E. North(University of North Carolina at Chapel Hill), Leslie A. Lange(University of Washington), Bruce S. Weir(The University of Queensland), Loïc Yengo(The University of Queensland), Jian Yang(The University of Queensland), Peter M. Visscher(The University of Queensland)

bioRxiv (Cold Spring Harbor Laboratory)

March 25, 2019

10.1101/588020

Cited by 215Open Access

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Abstract

Abstract Heritability, the proportion of phenotypic variance explained by genetic factors, can be estimated from pedigree data 1 , but such estimates are uninformative with respect to the underlying genetic architecture. Analyses of data from genome-wide association studies (GWAS) on unrelated individuals have shown that for human traits and disease, approximately one-third to two-thirds of heritability is captured by common SNPs 2–5 . It is not known whether the remaining heritability is due to the imperfect tagging of causal variants by common SNPs, in particular if the causal variants are rare, or other reasons such as overestimation of heritability from pedigree data. Here we show that pedigree heritability for height and body mass index (BMI) appears to be largely recovered from whole-genome sequence (WGS) data on 25,465 unrelated individuals of European ancestry. We assigned 33.7 million genetic variants to groups based upon their minor allele frequencies (MAF) and linkage disequilibrium (LD) with variants nearby, and estimated and partitioned genetic variance accordingly. The estimated heritability was 0.68 (SE 0.10) for height and 0.30 (SE 0.10) for BMI, with a range of ~0.60 – 0.71 for height and ~0.25 – 0.35 for BMI, depending on quality control and analysis strategies. Low-MAF variants in low LD with neighbouring variants were enriched for heritability, to a greater extent for protein-altering variants, consistent with negative selection thereon. Cumulatively variants with 0.0001 < MAF < 0.1 explained 0.47 (SE 0.07) and 0.30 (SE 0.10) of heritability for height and BMI, respectively. Our results imply that rare variants, in particular those in regions of low LD, is a major source of the still missing heritability of complex traits and disease.

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