Integration of GWAS SNPs and tissue specific expression profiling reveal discrete eQTLs for human traits in blood and brain

Dena G. Hernandez; Mike A. Nalls; Matthew Moore; Sean Chong; Allissa Dillman; Daniah Trabzuni; J. Raphael Gibbs; Mina Ryten; Sampath Arepalli; Michael E. Weale; Alan B. Zonderman; Juan Troncoso; Richard O'Brien; Robert Walker; Colin Smith; Stefania Bandinelli; Bryan J. Traynor; John Hardy; Andrew B. Singleton; Mark R. Cookson

doi:10.1016/j.nbd.2012.03.020

Integration of GWAS SNPs and tissue specific expression profiling reveal discrete eQTLs for human traits in blood and brain

Dena G. Hernandez, Mike A. Nalls, Matthew Moore, Sean Chong, Allissa Dillman, Daniah Trabzuni, J. Raphael Gibbs, Mina Ryten, Sampath Arepalli, Michael E. Weale, Alan B. Zonderman, Juan Troncoso, Richard O'Brien, Robert Walker, Colin Smith, Stefania Bandinelli, Bryan J. Traynor, John Hardy, Andrew B. Singleton, Mark R. Cookson

School of Medicine

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

83 Scopus citations

Abstract

Genome-wide association studies have nominated many genetic variants for common human traits, including diseases, but in many cases the underlying biological reason for a trait association is unknown. Subsets of genetic polymorphisms show a statistical association with transcript expression levels, and have therefore been nominated as expression quantitative trait loci (eQTL). However, many tissue and cell types have specific gene expression patterns and so it is not clear how frequently eQTLs found in one tissue type will be replicated in others. In the present study we used two appropriately powered sample series to examine the genetic control of gene expression in blood and brain. We find that while many eQTLs associated with human traits are shared between these two tissues, there are also examples where blood and brain differ, either by restricted gene expression patterns in one tissue or because of differences in how genetic variants are associated with transcript levels. These observations suggest that design of eQTL mapping experiments should consider tissue of interest for the disease or other traits studied.

Original language	English (US)
Pages (from-to)	20-28
Number of pages	9
Journal	Neurobiology of Disease
Volume	47
Issue number	1
DOIs	https://doi.org/10.1016/j.nbd.2012.03.020
State	Published - Jul 2012

Keywords

Blood
Brain
EQTL
GWAS

ASJC Scopus subject areas

Neurology

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Hernandez, D. G., Nalls, M. A., Moore, M., Chong, S., Dillman, A., Trabzuni, D., Gibbs, J. R., Ryten, M., Arepalli, S., Weale, M. E., Zonderman, A. B., Troncoso, J., O'Brien, R., Walker, R., Smith, C., Bandinelli, S., Traynor, B. J., Hardy, J., Singleton, A. B., & Cookson, M. R. (2012). Integration of GWAS SNPs and tissue specific expression profiling reveal discrete eQTLs for human traits in blood and brain. Neurobiology of Disease, 47(1), 20-28. https://doi.org/10.1016/j.nbd.2012.03.020

Hernandez, DG, Nalls, MA, Moore, M, Chong, S, Dillman, A, Trabzuni, D, Gibbs, JR, Ryten, M, Arepalli, S, Weale, ME, Zonderman, AB, Troncoso, J, O'Brien, R, Walker, R, Smith, C, Bandinelli, S, Traynor, BJ, Hardy, J, Singleton, AB & Cookson, MR 2012, 'Integration of GWAS SNPs and tissue specific expression profiling reveal discrete eQTLs for human traits in blood and brain', Neurobiology of Disease, vol. 47, no. 1, pp. 20-28. https://doi.org/10.1016/j.nbd.2012.03.020

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title = "Integration of GWAS SNPs and tissue specific expression profiling reveal discrete eQTLs for human traits in blood and brain",

abstract = "Genome-wide association studies have nominated many genetic variants for common human traits, including diseases, but in many cases the underlying biological reason for a trait association is unknown. Subsets of genetic polymorphisms show a statistical association with transcript expression levels, and have therefore been nominated as expression quantitative trait loci (eQTL). However, many tissue and cell types have specific gene expression patterns and so it is not clear how frequently eQTLs found in one tissue type will be replicated in others. In the present study we used two appropriately powered sample series to examine the genetic control of gene expression in blood and brain. We find that while many eQTLs associated with human traits are shared between these two tissues, there are also examples where blood and brain differ, either by restricted gene expression patterns in one tissue or because of differences in how genetic variants are associated with transcript levels. These observations suggest that design of eQTL mapping experiments should consider tissue of interest for the disease or other traits studied.",

keywords = "Blood, Brain, EQTL, GWAS",

author = "Hernandez, {Dena G.} and Nalls, {Mike A.} and Matthew Moore and Sean Chong and Allissa Dillman and Daniah Trabzuni and Gibbs, {J. Raphael} and Mina Ryten and Sampath Arepalli and Weale, {Michael E.} and Zonderman, {Alan B.} and Juan Troncoso and Richard O'Brien and Robert Walker and Colin Smith and Stefania Bandinelli and Traynor, {Bryan J.} and John Hardy and Singleton, {Andrew B.} and Cookson, {Mark R.}",

note = "Funding Information: This research was supported in part by the Intramural Research Program of the NIH, National Institute on Aging ( ZO1-AG000947 and Z01-AG000185 ) and in part by the UK Medical Research Council . The InCHIANTI study baseline (1998–2000) was supported as a {"}targeted project{"} (ICS110.1/RF97.71) by the Italian Ministry of Health and in part by the U.S. National Institute on Aging (Contracts: 263 MD 9164 and 263 MD 821336 ). ",

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doi = "10.1016/j.nbd.2012.03.020",

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AU - Hernandez, Dena G.

AU - Nalls, Mike A.

AU - Moore, Matthew

AU - Chong, Sean

AU - Dillman, Allissa

AU - Trabzuni, Daniah

AU - Gibbs, J. Raphael

AU - Ryten, Mina

AU - Arepalli, Sampath

AU - Weale, Michael E.

AU - Zonderman, Alan B.

AU - Troncoso, Juan

AU - O'Brien, Richard

AU - Walker, Robert

AU - Smith, Colin

AU - Bandinelli, Stefania

AU - Traynor, Bryan J.

AU - Hardy, John

AU - Singleton, Andrew B.

AU - Cookson, Mark R.

N1 - Funding Information: This research was supported in part by the Intramural Research Program of the NIH, National Institute on Aging ( ZO1-AG000947 and Z01-AG000185 ) and in part by the UK Medical Research Council . The InCHIANTI study baseline (1998–2000) was supported as a "targeted project" (ICS110.1/RF97.71) by the Italian Ministry of Health and in part by the U.S. National Institute on Aging (Contracts: 263 MD 9164 and 263 MD 821336 ).

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N2 - Genome-wide association studies have nominated many genetic variants for common human traits, including diseases, but in many cases the underlying biological reason for a trait association is unknown. Subsets of genetic polymorphisms show a statistical association with transcript expression levels, and have therefore been nominated as expression quantitative trait loci (eQTL). However, many tissue and cell types have specific gene expression patterns and so it is not clear how frequently eQTLs found in one tissue type will be replicated in others. In the present study we used two appropriately powered sample series to examine the genetic control of gene expression in blood and brain. We find that while many eQTLs associated with human traits are shared between these two tissues, there are also examples where blood and brain differ, either by restricted gene expression patterns in one tissue or because of differences in how genetic variants are associated with transcript levels. These observations suggest that design of eQTL mapping experiments should consider tissue of interest for the disease or other traits studied.

AB - Genome-wide association studies have nominated many genetic variants for common human traits, including diseases, but in many cases the underlying biological reason for a trait association is unknown. Subsets of genetic polymorphisms show a statistical association with transcript expression levels, and have therefore been nominated as expression quantitative trait loci (eQTL). However, many tissue and cell types have specific gene expression patterns and so it is not clear how frequently eQTLs found in one tissue type will be replicated in others. In the present study we used two appropriately powered sample series to examine the genetic control of gene expression in blood and brain. We find that while many eQTLs associated with human traits are shared between these two tissues, there are also examples where blood and brain differ, either by restricted gene expression patterns in one tissue or because of differences in how genetic variants are associated with transcript levels. These observations suggest that design of eQTL mapping experiments should consider tissue of interest for the disease or other traits studied.

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Integration of GWAS SNPs and tissue specific expression profiling reveal discrete eQTLs for human traits in blood and brain

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