Genetic Coupling of Enhancer Activity and Connectivity in Gene Expression Control

Overview

Journal Nat Commun

Date 2025 Jan 27

PMID 39870618

Authors

Helen Ray-Jones

Chak Kei Sung

Lai Ting Chan

Alexander Haglund

Pavel Artemov

Monica Della Rosa

Luminita Ruje

Frances Burden

Roman Kreuzhuber

Anna Litovskikh

Eline Weyenbergh

Zoi Brusselaers

Vanessa Xue Hui Tan

Mattia Frontini

Chris Wallace

Valeriya Malysheva

Leonardo Bottolo

Elena Vigorito

Mikhail Spivakov

Affiliations

Soon will be listed here.

Abstract

Gene enhancers often form long-range contacts with promoters, but it remains unclear if the activity of enhancers and their chromosomal contacts are mediated by the same DNA sequences and recruited factors. Here, we study the effects of expression quantitative trait loci (eQTLs) on enhancer activity and promoter contacts in primary monocytes isolated from 34 male individuals. Using eQTL-Capture Hi-C and a Bayesian approach considering both intra- and inter-individual variation, we initially detect 19 eQTLs associated with enhancer-eGene promoter contacts, most of which also associate with enhancer accessibility and activity. Capitalising on these shared effects, we devise a multi-modality Bayesian strategy, identifying 629 "trimodal QTLs" jointly associated with enhancer accessibility, eGene promoter contact, and gene expression. Causal mediation analysis and CRISPR interference reveal causal relationships between these three modalities. Many detected QTLs overlap disease susceptibility loci and influence the predicted binding of myeloid transcription factors, including SPI1, GABPB and STAT3. Additionally, a variant associated with PCK2 promoter contact directly disrupts a CTCF binding motif and impacts promoter insulation from downstream enhancers. Jointly, our findings suggest an inherent genetic coupling of enhancer activity and connectivity in gene expression control relevant to human disease and highlight the regulatory role of genetically determined chromatin boundaries.

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