Analysis of Rare, Exonic Variation amongst Subjects with Autism Spectrum Disorders and Population Controls

Li Liu; Aniko Sabo; Benjamin M. Neale; Uma Nagaswamy; Christine Stevens; Elaine Lim; Corneliu A. Bodea; Donna Muzny; Jeffrey G. Reid; Eric Banks; Hillary Coon; Mark DePristo; Huyen Dinh; Tim Fennel; Jason Flannick; Stacey Gabriel; Kiran Garimella; Shannon Gross; Alicia Hawes; Lora Lewis; Vladimir Makarov; Jared Maguire; Irene Newsham; Ryan Poplin; Stephan Ripke; Khalid Shakir; Kaitlin E. Samocha; Yuanqing Wu; Eric Boerwinkle; Joseph D. Buxbaum; Edwin H. Cook; Bernie Devlin; Gerard D. Schellenberg; James S. Sutcliffe; Mark J. Daly; Richard A. Gibbs; Kathryn Roeder

doi:10.1371/journal.pgen.1003443

Analysis of Rare, Exonic Variation amongst Subjects with Autism Spectrum Disorders and Population Controls

Li Liu, Aniko Sabo, Benjamin M. Neale, Uma Nagaswamy, Christine Stevens, Elaine Lim, Corneliu A. Bodea, Donna Muzny, Jeffrey G. Reid, Eric Banks, Hillary Coon, Mark DePristo, Huyen Dinh, Tim Fennel, Jason Flannick, Stacey Gabriel, Kiran Garimella, Shannon Gross, Alicia Hawes, Lora LewisVladimir Makarov, Jared Maguire, Irene Newsham, Ryan Poplin, Stephan Ripke, Khalid Shakir, Kaitlin E. Samocha, Yuanqing Wu, Eric Boerwinkle, Joseph D. Buxbaum, Edwin H. Cook, Bernie Devlin, Gerard D. Schellenberg, James S. Sutcliffe, Mark J. Daly, Richard A. Gibbs, Kathryn Roeder

School of Health Professions

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

71 Scopus citations

Abstract

We report on results from whole-exome sequencing (WES) of 1,039 subjects diagnosed with autism spectrum disorders (ASD) and 870 controls selected from the NIMH repository to be of similar ancestry to cases. The WES data came from two centers using different methods to produce sequence and to call variants from it. Therefore, an initial goal was to ensure the distribution of rare variation was similar for data from different centers. This proved straightforward by filtering called variants by fraction of missing data, read depth, and balance of alternative to reference reads. Results were evaluated using seven samples sequenced at both centers and by results from the association study. Next we addressed how the data and/or results from the centers should be combined. Gene-based analyses of association was an obvious choice, but should statistics for association be combined across centers (meta-analysis) or should data be combined and then analyzed (mega-analysis)? Because of the nature of many gene-based tests, we showed by theory and simulations that mega-analysis has better power than meta-analysis. Finally, before analyzing the data for association, we explored the impact of population structure on rare variant analysis in these data. Like other recent studies, we found evidence that population structure can confound case-control studies by the clustering of rare variants in ancestry space; yet, unlike some recent studies, for these data we found that principal component-based analyses were sufficient to control for ancestry and produce test statistics with appropriate distributions. After using a variety of gene-based tests and both meta- and mega-analysis, we found no new risk genes for ASD in this sample. Our results suggest that standard gene-based tests will require much larger samples of cases and controls before being effective for gene discovery, even for a disorder like ASD.

Original language	English (US)
Article number	e1003443
Journal	PLoS genetics
Volume	9
Issue number	4
DOIs	https://doi.org/10.1371/journal.pgen.1003443
State	Published - Apr 2013

ASJC Scopus subject areas

Ecology, Evolution, Behavior and Systematics
Molecular Biology
Genetics
Genetics(clinical)
Cancer Research

Access to Document

10.1371/journal.pgen.1003443

Cite this

Liu, L., Sabo, A., Neale, B. M., Nagaswamy, U., Stevens, C., Lim, E., Bodea, C. A., Muzny, D., Reid, J. G., Banks, E., Coon, H., DePristo, M., Dinh, H., Fennel, T., Flannick, J., Gabriel, S., Garimella, K., Gross, S., Hawes, A., ... Roeder, K. (2013). Analysis of Rare, Exonic Variation amongst Subjects with Autism Spectrum Disorders and Population Controls. PLoS genetics, 9(4), Article e1003443. https://doi.org/10.1371/journal.pgen.1003443

Liu, L, Sabo, A, Neale, BM, Nagaswamy, U, Stevens, C, Lim, E, Bodea, CA, Muzny, D, Reid, JG, Banks, E, Coon, H, DePristo, M, Dinh, H, Fennel, T, Flannick, J, Gabriel, S, Garimella, K, Gross, S, Hawes, A, Lewis, L, Makarov, V, Maguire, J, Newsham, I, Poplin, R, Ripke, S, Shakir, K, Samocha, KE, Wu, Y, Boerwinkle, E, Buxbaum, JD, Cook, EH, Devlin, B, Schellenberg, GD, Sutcliffe, JS, Daly, MJ, Gibbs, RA & Roeder, K 2013, 'Analysis of Rare, Exonic Variation amongst Subjects with Autism Spectrum Disorders and Population Controls', PLoS genetics, vol. 9, no. 4, e1003443. https://doi.org/10.1371/journal.pgen.1003443

@article{002186abcf9745edb2f88c6165f419a7,

title = "Analysis of Rare, Exonic Variation amongst Subjects with Autism Spectrum Disorders and Population Controls",

abstract = "We report on results from whole-exome sequencing (WES) of 1,039 subjects diagnosed with autism spectrum disorders (ASD) and 870 controls selected from the NIMH repository to be of similar ancestry to cases. The WES data came from two centers using different methods to produce sequence and to call variants from it. Therefore, an initial goal was to ensure the distribution of rare variation was similar for data from different centers. This proved straightforward by filtering called variants by fraction of missing data, read depth, and balance of alternative to reference reads. Results were evaluated using seven samples sequenced at both centers and by results from the association study. Next we addressed how the data and/or results from the centers should be combined. Gene-based analyses of association was an obvious choice, but should statistics for association be combined across centers (meta-analysis) or should data be combined and then analyzed (mega-analysis)? Because of the nature of many gene-based tests, we showed by theory and simulations that mega-analysis has better power than meta-analysis. Finally, before analyzing the data for association, we explored the impact of population structure on rare variant analysis in these data. Like other recent studies, we found evidence that population structure can confound case-control studies by the clustering of rare variants in ancestry space; yet, unlike some recent studies, for these data we found that principal component-based analyses were sufficient to control for ancestry and produce test statistics with appropriate distributions. After using a variety of gene-based tests and both meta- and mega-analysis, we found no new risk genes for ASD in this sample. Our results suggest that standard gene-based tests will require much larger samples of cases and controls before being effective for gene discovery, even for a disorder like ASD.",

author = "Li Liu and Aniko Sabo and Neale, {Benjamin M.} and Uma Nagaswamy and Christine Stevens and Elaine Lim and Bodea, {Corneliu A.} and Donna Muzny and Reid, {Jeffrey G.} and Eric Banks and Hillary Coon and Mark DePristo and Huyen Dinh and Tim Fennel and Jason Flannick and Stacey Gabriel and Kiran Garimella and Shannon Gross and Alicia Hawes and Lora Lewis and Vladimir Makarov and Jared Maguire and Irene Newsham and Ryan Poplin and Stephan Ripke and Khalid Shakir and Samocha, {Kaitlin E.} and Yuanqing Wu and Eric Boerwinkle and Buxbaum, {Joseph D.} and Cook, {Edwin H.} and Bernie Devlin and Schellenberg, {Gerard D.} and Sutcliffe, {James S.} and Daly, {Mark J.} and Gibbs, {Richard A.} and Kathryn Roeder",

note = "Funding Information: We thank T. Lehner and A. Felsenfeld for their support and contribution to the project. We acknowledge the clinicians and organizations that contributed to samples used in this study, including the Autism Genetics Resource Exchange, the institutions of the Boston Autism Consortium, and The Autism Sequencing Collection (TASC) centers. Recruitment of TASC subjects was supported by Autism Speaks. JD Buxbaum, B Devlin, MJ Daly, RA Gibbs, A Sabo, GD Schellenberg, and JS Sutcliffe are lead investigators in the Autism Sequencing Consortium (ASC). The ASC is comprised of groups sharing massively parallel sequencing data in autism. We would like to thank the editor and anonymous reviewers for their valuable comments and suggestions. Finally, we are grateful to the many families, without whose participation this project would not have been possible. For full citation of resources, please see .",

year = "2013",

month = apr,

doi = "10.1371/journal.pgen.1003443",

language = "English (US)",

volume = "9",

journal = "PLoS genetics",

issn = "1553-7390",

publisher = "Public Library of Science",

number = "4",

}

TY - JOUR

T1 - Analysis of Rare, Exonic Variation amongst Subjects with Autism Spectrum Disorders and Population Controls

AU - Liu, Li

AU - Sabo, Aniko

AU - Neale, Benjamin M.

AU - Nagaswamy, Uma

AU - Stevens, Christine

AU - Lim, Elaine

AU - Bodea, Corneliu A.

AU - Muzny, Donna

AU - Reid, Jeffrey G.

AU - Banks, Eric

AU - Coon, Hillary

AU - DePristo, Mark

AU - Dinh, Huyen

AU - Fennel, Tim

AU - Flannick, Jason

AU - Gabriel, Stacey

AU - Garimella, Kiran

AU - Gross, Shannon

AU - Hawes, Alicia

AU - Lewis, Lora

AU - Makarov, Vladimir

AU - Maguire, Jared

AU - Newsham, Irene

AU - Poplin, Ryan

AU - Ripke, Stephan

AU - Shakir, Khalid

AU - Samocha, Kaitlin E.

AU - Wu, Yuanqing

AU - Boerwinkle, Eric

AU - Buxbaum, Joseph D.

AU - Cook, Edwin H.

AU - Devlin, Bernie

AU - Schellenberg, Gerard D.

AU - Sutcliffe, James S.

AU - Daly, Mark J.

AU - Gibbs, Richard A.

AU - Roeder, Kathryn

N1 - Funding Information: We thank T. Lehner and A. Felsenfeld for their support and contribution to the project. We acknowledge the clinicians and organizations that contributed to samples used in this study, including the Autism Genetics Resource Exchange, the institutions of the Boston Autism Consortium, and The Autism Sequencing Collection (TASC) centers. Recruitment of TASC subjects was supported by Autism Speaks. JD Buxbaum, B Devlin, MJ Daly, RA Gibbs, A Sabo, GD Schellenberg, and JS Sutcliffe are lead investigators in the Autism Sequencing Consortium (ASC). The ASC is comprised of groups sharing massively parallel sequencing data in autism. We would like to thank the editor and anonymous reviewers for their valuable comments and suggestions. Finally, we are grateful to the many families, without whose participation this project would not have been possible. For full citation of resources, please see .

PY - 2013/4

Y1 - 2013/4

N2 - We report on results from whole-exome sequencing (WES) of 1,039 subjects diagnosed with autism spectrum disorders (ASD) and 870 controls selected from the NIMH repository to be of similar ancestry to cases. The WES data came from two centers using different methods to produce sequence and to call variants from it. Therefore, an initial goal was to ensure the distribution of rare variation was similar for data from different centers. This proved straightforward by filtering called variants by fraction of missing data, read depth, and balance of alternative to reference reads. Results were evaluated using seven samples sequenced at both centers and by results from the association study. Next we addressed how the data and/or results from the centers should be combined. Gene-based analyses of association was an obvious choice, but should statistics for association be combined across centers (meta-analysis) or should data be combined and then analyzed (mega-analysis)? Because of the nature of many gene-based tests, we showed by theory and simulations that mega-analysis has better power than meta-analysis. Finally, before analyzing the data for association, we explored the impact of population structure on rare variant analysis in these data. Like other recent studies, we found evidence that population structure can confound case-control studies by the clustering of rare variants in ancestry space; yet, unlike some recent studies, for these data we found that principal component-based analyses were sufficient to control for ancestry and produce test statistics with appropriate distributions. After using a variety of gene-based tests and both meta- and mega-analysis, we found no new risk genes for ASD in this sample. Our results suggest that standard gene-based tests will require much larger samples of cases and controls before being effective for gene discovery, even for a disorder like ASD.

AB - We report on results from whole-exome sequencing (WES) of 1,039 subjects diagnosed with autism spectrum disorders (ASD) and 870 controls selected from the NIMH repository to be of similar ancestry to cases. The WES data came from two centers using different methods to produce sequence and to call variants from it. Therefore, an initial goal was to ensure the distribution of rare variation was similar for data from different centers. This proved straightforward by filtering called variants by fraction of missing data, read depth, and balance of alternative to reference reads. Results were evaluated using seven samples sequenced at both centers and by results from the association study. Next we addressed how the data and/or results from the centers should be combined. Gene-based analyses of association was an obvious choice, but should statistics for association be combined across centers (meta-analysis) or should data be combined and then analyzed (mega-analysis)? Because of the nature of many gene-based tests, we showed by theory and simulations that mega-analysis has better power than meta-analysis. Finally, before analyzing the data for association, we explored the impact of population structure on rare variant analysis in these data. Like other recent studies, we found evidence that population structure can confound case-control studies by the clustering of rare variants in ancestry space; yet, unlike some recent studies, for these data we found that principal component-based analyses were sufficient to control for ancestry and produce test statistics with appropriate distributions. After using a variety of gene-based tests and both meta- and mega-analysis, we found no new risk genes for ASD in this sample. Our results suggest that standard gene-based tests will require much larger samples of cases and controls before being effective for gene discovery, even for a disorder like ASD.

UR - http://www.scopus.com/inward/record.url?scp=84876852800&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84876852800&partnerID=8YFLogxK

U2 - 10.1371/journal.pgen.1003443

DO - 10.1371/journal.pgen.1003443

M3 - Article

C2 - 23593035

AN - SCOPUS:84876852800

SN - 1553-7390

VL - 9

JO - PLoS genetics

JF - PLoS genetics

IS - 4

M1 - e1003443

ER -

Analysis of Rare, Exonic Variation amongst Subjects with Autism Spectrum Disorders and Population Controls

Abstract

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this