Powerful Identification of Cis-regulatory SNPs in Human Primary Monocytes Using Allele-Specific Gene Expression

Jonas Carlsson Almlöf,Heather Lloyd-Jones,Christian Hengstenberg,Alison H Goodall,Willem H Ouwehand,Bing Ge,Jessy Brocheton,Per Lundmark,Tiphaine Godefroy,Camilla Enström,Panos Deloukas,Tomi Pastinen,Jonathan Stephens,Carole Proust,François Cambien,Nilesh J Samani,Ulrika Liljedahl,Nicola Foad,Jeanette Erdmann,Anders Lundmark,Abigail Crisp-Hihn,Jennifer Jolley,Catherine M Rice,Heribert Schunkert,Seraya Maouche,Rhian Gwilliam,Harald H.h Göring ,Jennifer Sambrook ,Ann Christine Syvänen

doi:10.1371/journal.pone.0052260

Abstract

A large number of genome-wide association studies have been performed during the past five years to identify associations between SNPs and human complex diseases and traits. The assignment of a functional role for the identified disease-associated SNP is not straight-forward. Genome-wide expression quantitative trait locus (eQTL) analysis is frequently used as the initial step to define a function while allele-specific gene expression (ASE) analysis has not yet gained a wide-spread use in disease mapping studies. We compared the power to identify cis-acting regulatory SNPs (cis-rSNPs) by genome-wide allele-specific gene expression (ASE) analysis with that of traditional expression quantitative trait locus (eQTL) mapping. Our study included 395 healthy blood donors for whom global gene expression profiles in circulating monocytes were determined by Illumina BeadArrays. ASE was assessed in a subset of these monocytes from 188 donors by quantitative genotyping of mRNA using a genome-wide panel of SNP markers. The performance of the two methods for detecting cis-rSNPs was evaluated by comparing associations between SNP genotypes and gene expression levels in sample sets of varying size. We found that up to 8-fold more samples are required for eQTL mapping to reach the same statistical power as that obtained by ASE analysis for the same rSNPs. The performance of ASE is insensitive to SNPs with low minor allele frequencies and detects a larger number of significantly associated rSNPs using the same sample size as eQTL mapping. An unequivocal conclusion from our comparison is that ASE analysis is more sensitive for detecting cis-rSNPs than standard eQTL mapping. Our study shows the potential of ASE mapping in tissue samples and primary cells which are difficult to obtain in large numbers.

Highlights

Owing to the rapid advances in genotyping technology a large number of genome-wide association studies have been performed during the past five years to identify associations between SNPs and human complex diseases and traits [1]
Using genotypic expression (GTE) mapping, the SNP genotypes are tested for an association with the total gene expression levels, and using allele-specific gene expression (ASE) analysis, the relative expression levels between the two alleles of a transcript are used as the quantitative phenotype against which the SNP genotypes are analyzed
The results presented here are based on GTE mapping of RNA extracted from 395 monocyte samples and ASE analysis of a subset of 188 monocyte samples from the same donors

Summary

Introduction

Owing to the rapid advances in genotyping technology a large number of genome-wide association studies have been performed during the past five years to identify associations between SNPs and human complex diseases and traits [1]. These studies have detected genome-wide significant association signals for about 2200 loci with at least 240 diseases or traits [2,3]. Genome-wide expression quantitative trait locus (eQTL) analysis of tissues or cell types that are relevant for a disease or trait of interest is frequently used as the initial step to define a function for disease-associated SNP alleles [4,5,6]. Cis-regulatory SNPs identified in a relevant tissue are functional candidates for further investigation of diseasecausing genetic variants

Methods

Results

Conclusion