Analysis of case-control association studies with known risk variants

Noah Zaitlen; Bogdan Paşaniuc; Nick Patterson; Samuela Pollack; Benjamin Voight; Leif Groop; David Altshuler; Brian E. Henderson; Laurence N. Kolonel; Loic Le Marchand; Kevin Waters; Christopher A. Haiman; Barbara Elaine Stranger; Emmanouil T. Dermitzakis; Peter Kraft; Alkes L. Price

doi:10.1093/bioinformatics/bts259

Analysis of case-control association studies with known risk variants

Noah Zaitlen^*, Bogdan Paşaniuc, Nick Patterson, Samuela Pollack, Benjamin Voight, Leif Groop, David Altshuler, Brian E. Henderson, Laurence N. Kolonel, Loic Le Marchand, Kevin Waters, Christopher A. Haiman, Barbara Elaine Stranger, Emmanouil T. Dermitzakis, Peter Kraft, Alkes L. Price

^*Corresponding author for this work

Pharmacology

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

24 Scopus citations

Abstract

Motivation: The question of how to best use information from known associated variants when conducting disease association studies has yet to be answered. Some studies compute a marginal P-value for each Several Nucleotide Polymorphisms independently, ignoring previously discovered variants. Other studies include known variants as covariates in logistic regression, but a weakness of this standard conditioning strategy is that it does not account for disease prevalence and non-random ascertainment, which can induce a correlation structure between candidate variants and known associated variants even if the variants lie on different chromosomes. Here, we propose a new conditioning approach, which is based in part on the classical technique of liability threshold modeling. Roughly, this method estimates model parameters for each known variant while accounting for the published disease prevalence from the epidemiological literature. Results: We show via simulation and application to empirical datasets that our approach outperforms both the no conditioning strategy and the standard conditioning strategy, with a properly controlled false-positive rate. Furthermore, in multiple data sets involving diseases of low prevalence, standard conditioning produces a severe drop in test statistics whereas our approach generally performs as well or better than no conditioning. Our approach may substantially improve disease gene discovery for diseases with many known risk variants.

Original language	English (US)
Article number	bts259
Pages (from-to)	1729-1737
Number of pages	9
Journal	Bioinformatics
Volume	28
Issue number	13
DOIs	https://doi.org/10.1093/bioinformatics/bts259
State	Published - Jul 2012

Funding

Funding: NIH fellowship [5T32ES007142-27 N.Z.]; NHGRI [R01 HG006399 and N.Z., B.P., N.P., A.L.P.]; US National Institutes of Health; National Cancer Institute [cooperative agreements U01-CA98233-07 to David J. Hunter, U01-CA98710-06 to Susan Gapstur, U01-CA98216-06 to Elio Riboli and Rudolf Kaaks, and U01-CA98758-07 to Brian E. Henderson, and Intramural Research Program of NIH/National Cancer Institute, Division of Cancer Epidemiology and Genetics]. The T2D study in the MEC was supported by NIH CA63464, CA54281, 1U01HG004802 and Multiethnic Cohort (MEC) [R37-CA54281 to Laurence N. Kolonel].

ASJC Scopus subject areas

Statistics and Probability
Biochemistry
Molecular Biology
Computer Science Applications
Computational Theory and Mathematics
Computational Mathematics

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10.1093/bioinformatics/bts259

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Zaitlen, N., Paşaniuc, B., Patterson, N., Pollack, S., Voight, B., Groop, L., Altshuler, D., Henderson, B. E., Kolonel, L. N., Marchand, L. L., Waters, K., Haiman, C. A., Stranger, B. E., Dermitzakis, E. T., Kraft, P., & Price, A. L. (2012). Analysis of case-control association studies with known risk variants. Bioinformatics, 28(13), 1729-1737. Article bts259. https://doi.org/10.1093/bioinformatics/bts259

@article{d10f1f5b43944e928cc616e80775c8cc,

title = "Analysis of case-control association studies with known risk variants",

abstract = "Motivation: The question of how to best use information from known associated variants when conducting disease association studies has yet to be answered. Some studies compute a marginal P-value for each Several Nucleotide Polymorphisms independently, ignoring previously discovered variants. Other studies include known variants as covariates in logistic regression, but a weakness of this standard conditioning strategy is that it does not account for disease prevalence and non-random ascertainment, which can induce a correlation structure between candidate variants and known associated variants even if the variants lie on different chromosomes. Here, we propose a new conditioning approach, which is based in part on the classical technique of liability threshold modeling. Roughly, this method estimates model parameters for each known variant while accounting for the published disease prevalence from the epidemiological literature. Results: We show via simulation and application to empirical datasets that our approach outperforms both the no conditioning strategy and the standard conditioning strategy, with a properly controlled false-positive rate. Furthermore, in multiple data sets involving diseases of low prevalence, standard conditioning produces a severe drop in test statistics whereas our approach generally performs as well or better than no conditioning. Our approach may substantially improve disease gene discovery for diseases with many known risk variants.",

author = "Noah Zaitlen and Bogdan Pa{\c s}aniuc and Nick Patterson and Samuela Pollack and Benjamin Voight and Leif Groop and David Altshuler and Henderson, \{Brian E.\} and Kolonel, \{Laurence N.\} and Marchand, \{Loic Le\} and Kevin Waters and Haiman, \{Christopher A.\} and Stranger, \{Barbara Elaine\} and Dermitzakis, \{Emmanouil T.\} and Peter Kraft and Price, \{Alkes L.\}",

note = "Funding Information: Funding: NIH fellowship [5T32ES007142-27 N.Z.]; NHGRI [R01 HG006399 and N.Z., B.P., N.P., A.L.P.]; US National Institutes of Health; National Cancer Institute [cooperative agreements U01-CA98233-07 to David J. Hunter, U01-CA98710-06 to Susan Gapstur, U01-CA98216-06 to Elio Riboli and Rudolf Kaaks, and U01-CA98758-07 to Brian E. Henderson, and Intramural Research Program of NIH/National Cancer Institute, Division of Cancer Epidemiology and Genetics]. The T2D study in the MEC was supported by NIH CA63464, CA54281, 1U01HG004802 and Multiethnic Cohort (MEC) [R37-CA54281 to Laurence N. Kolonel].",

year = "2012",

month = jul,

doi = "10.1093/bioinformatics/bts259",

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volume = "28",

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issn = "1367-4803",

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Zaitlen, N, Paşaniuc, B, Patterson, N, Pollack, S, Voight, B, Groop, L, Altshuler, D, Henderson, BE, Kolonel, LN, Marchand, LL, Waters, K, Haiman, CA, Stranger, BE, Dermitzakis, ET, Kraft, P & Price, AL 2012, 'Analysis of case-control association studies with known risk variants', Bioinformatics, vol. 28, no. 13, bts259, pp. 1729-1737. https://doi.org/10.1093/bioinformatics/bts259

TY - JOUR

T1 - Analysis of case-control association studies with known risk variants

AU - Zaitlen, Noah

AU - Paşaniuc, Bogdan

AU - Patterson, Nick

AU - Pollack, Samuela

AU - Voight, Benjamin

AU - Groop, Leif

AU - Altshuler, David

AU - Henderson, Brian E.

AU - Kolonel, Laurence N.

AU - Marchand, Loic Le

AU - Waters, Kevin

AU - Haiman, Christopher A.

AU - Stranger, Barbara Elaine

AU - Dermitzakis, Emmanouil T.

AU - Kraft, Peter

AU - Price, Alkes L.

N1 - Funding Information: Funding: NIH fellowship [5T32ES007142-27 N.Z.]; NHGRI [R01 HG006399 and N.Z., B.P., N.P., A.L.P.]; US National Institutes of Health; National Cancer Institute [cooperative agreements U01-CA98233-07 to David J. Hunter, U01-CA98710-06 to Susan Gapstur, U01-CA98216-06 to Elio Riboli and Rudolf Kaaks, and U01-CA98758-07 to Brian E. Henderson, and Intramural Research Program of NIH/National Cancer Institute, Division of Cancer Epidemiology and Genetics]. The T2D study in the MEC was supported by NIH CA63464, CA54281, 1U01HG004802 and Multiethnic Cohort (MEC) [R37-CA54281 to Laurence N. Kolonel].

PY - 2012/7

Y1 - 2012/7

N2 - Motivation: The question of how to best use information from known associated variants when conducting disease association studies has yet to be answered. Some studies compute a marginal P-value for each Several Nucleotide Polymorphisms independently, ignoring previously discovered variants. Other studies include known variants as covariates in logistic regression, but a weakness of this standard conditioning strategy is that it does not account for disease prevalence and non-random ascertainment, which can induce a correlation structure between candidate variants and known associated variants even if the variants lie on different chromosomes. Here, we propose a new conditioning approach, which is based in part on the classical technique of liability threshold modeling. Roughly, this method estimates model parameters for each known variant while accounting for the published disease prevalence from the epidemiological literature. Results: We show via simulation and application to empirical datasets that our approach outperforms both the no conditioning strategy and the standard conditioning strategy, with a properly controlled false-positive rate. Furthermore, in multiple data sets involving diseases of low prevalence, standard conditioning produces a severe drop in test statistics whereas our approach generally performs as well or better than no conditioning. Our approach may substantially improve disease gene discovery for diseases with many known risk variants.

AB - Motivation: The question of how to best use information from known associated variants when conducting disease association studies has yet to be answered. Some studies compute a marginal P-value for each Several Nucleotide Polymorphisms independently, ignoring previously discovered variants. Other studies include known variants as covariates in logistic regression, but a weakness of this standard conditioning strategy is that it does not account for disease prevalence and non-random ascertainment, which can induce a correlation structure between candidate variants and known associated variants even if the variants lie on different chromosomes. Here, we propose a new conditioning approach, which is based in part on the classical technique of liability threshold modeling. Roughly, this method estimates model parameters for each known variant while accounting for the published disease prevalence from the epidemiological literature. Results: We show via simulation and application to empirical datasets that our approach outperforms both the no conditioning strategy and the standard conditioning strategy, with a properly controlled false-positive rate. Furthermore, in multiple data sets involving diseases of low prevalence, standard conditioning produces a severe drop in test statistics whereas our approach generally performs as well or better than no conditioning. Our approach may substantially improve disease gene discovery for diseases with many known risk variants.

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EP - 1737

JO - Bioinformatics

JF - Bioinformatics

IS - 13

M1 - bts259

ER -

Analysis of case-control association studies with known risk variants

Abstract

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