Projecting genetic associations through gene expression patterns highlights disease etiology and drug mechanisms

Author:

Pividori MiltonORCID,Lu Sumei,Li BinglanORCID,Su Chun,Johnson Matthew E.,Wei Wei-QiORCID,Feng QipingORCID,Namjou BahramORCID,Kiryluk Krzysztof,Kullo Iftikhar J.ORCID,Luo YuanORCID,Sullivan Blair D.ORCID,Voight Benjamin F.ORCID,Skarke CarstenORCID,Ritchie Marylyn D.ORCID,Grant Struan F. A.ORCID,Greene Casey S.ORCID,

Abstract

AbstractGenes act in concert with each other in specific contexts to perform their functions. Determining how these genes influence complex traits requires a mechanistic understanding of expression regulation across different conditions. It has been shown that this insight is critical for developing new therapies. Transcriptome-wide association studies have helped uncover the role of individual genes in disease-relevant mechanisms. However, modern models of the architecture of complex traits predict that gene-gene interactions play a crucial role in disease origin and progression. Here we introduce PhenoPLIER, a computational approach that maps gene-trait associations and pharmacological perturbation data into a common latent representation for a joint analysis. This representation is based on modules of genes with similar expression patterns across the same conditions. We observe that diseases are significantly associated with gene modules expressed in relevant cell types, and our approach is accurate in predicting known drug-disease pairs and inferring mechanisms of action. Furthermore, using a CRISPR screen to analyze lipid regulation, we find that functionally important players lack associations but are prioritized in trait-associated modules by PhenoPLIER. By incorporating groups of co-expressed genes, PhenoPLIER can contextualize genetic associations and reveal potential targets missed by single-gene strategies.

Funder

Gordon and Betty Moore Foundation

U.S. Department of Health & Human Services | NIH | National Cancer Institute

U.S. Department of Health & Human Services | NIH | National Human Genome Research Institute

Publisher

Springer Science and Business Media LLC

Subject

General Physics and Astronomy,General Biochemistry, Genetics and Molecular Biology,General Chemistry,Multidisciplinary

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