Transcripts with High Distal Heritability Mediate Genetic Effects on Complex Metabolic Traits

Overview

Journal bioRxiv

Date 2024 Oct 10

PMID 39386475

Authors

Anna L Tyler

J Matthew Mahoney

Mark P Keller

Candice N Baker

Margaret Gaca

Anuj Srivastava

Isabela Gerdes Gyuricza

Madeleine J Braun

Nadia A Rosenthal

Alan D Attie

Gary A Churchill

Gregory W Carter

Affiliations

Soon will be listed here.

Abstract

Although many genes are subject to local regulation, recent evidence suggests that complex distal regulation may be more important in mediating phenotypic variability. To assess the role of distal gene regulation in complex traits, we combined multi-tissue transcriptomes with physiological outcomes to model diet-induced obesity and metabolic disease in a population of Diversity Outbred mice. Using a novel high-dimensional mediation analysis, we identified a composite transcriptome signature that summarized genetic effects on gene expression and explained 30% of the variation across all metabolic traits. The signature was heritable, interpretable in biological terms, and predicted obesity status from gene expression in an independently derived mouse cohort and multiple human studies. Transcripts contributing most strongly to this composite mediator frequently had complex, distal regulation distributed throughout the genome. These results suggest that trait-relevant variation in transcription is largely distally regulated, but is nonetheless identifiable, interpretable, and translatable across species.

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