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A scalable unified framework of total and allele-specific counts for cis-QTL, fine-mapping, and prediction

Yanyu Liang, François Aguet, Alvaro Barbeira, Kristin Ardlie, Hae Kyung Im

2021Nature Communications35 citationsDOIOpen Access PDF

Abstract

Genetic studies of the transcriptome help bridge the gap between genetic variation and phenotypes. To maximize the potential of such studies, efficient methods to identify expression quantitative trait loci (eQTLs) and perform fine-mapping and genetic prediction of gene expression traits are needed. Current methods that leverage both total read counts and allele-specific expression to identify eQTLs are generally computationally intractable for large transcriptomic studies. Here, we describe a unified framework that addresses these needs and is scalable to thousands of samples. Using simulations and data from GTEx, we demonstrate its calibration and performance. For example, mixQTL shows a power gain equivalent to a 29% increase in sample size for genes with sufficient allele-specific read coverage. To showcase the potential of mixQTL, we apply it to 49 GTEx tissues and find 20% additional eQTLs (FDR < 0.05, per tissue) that are significantly more enriched among trait associated variants and candidate cis-regulatory elements comparing to the standard approach.

Topics & Concepts

Quantitative trait locusExpression quantitative trait lociComputational biologyLeverage (statistics)BiologyComputer scienceAlleleScalabilityGeneticsGeneSingle-nucleotide polymorphismArtificial intelligenceGenotypeDatabaseGenetic Mapping and Diversity in Plants and AnimalsGenetic and phenotypic traits in livestockGenetic Associations and Epidemiology
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