Unraveling a novel dual-function regulatory element showing epistatic interaction with a variant that escapes genome-wide association studies

Abstract

Regulation of gene expression has recently been complexified by the identification of Epromoters, a subset of promoters with enhancer function. Here, we uncovered the first dual cis-regulatory element, "ESpromoter," exhibiting both enhancer and silencer function, as a regulator of the nearby genesATP2B4andLAX1in single human T cells. Through integrative approach, we pinpointed functional rs11240391, a severe malaria risk variant that escapes detection in genome-wide association studies, challenging conventional strategies for identifying causal variants. CRISPR-modified cells demonstrated the regulatory effect of ESpromoter and rs11240391 onLAX1expression and T cell activation. Furthermore, our findings revealed an epistatic interaction between ESpromoter SNPs and rs11240391, impacting severe malaria susceptibility by further reducingLAX1expression. This groundbreaking discovery challenges the conventional enhancer-silencer dichotomy. It highlights the sophistication of transcriptional regulation and argues for an integrated approach combining genetics, epigenetics, and genomics to identify new therapeutic targets for complex diseases.HIGHLIGHTSNovel dual enhancer-silencer element (ESpromoter) in a single human cell typeFunctional SNP for severe malaria risk that escapes genome-wide association studiesGenome editing at the SNP demonstrates a regulatory effect onLAX1and T cell activationEpistatic interaction between SNPs increases the risk of severe malariaIn briefEpistatic interaction between common variants within a novel dual enhancer-silencer regulatory element and theLAX1promoter variant is responsible for severe malaria susceptibility through T-cell activation.