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Mitochondrial fatty acid oxidation regulates monocytic type I interferon signaling via histone acetylation

Jing Wu, Komudi Singh, Vivian Shing, Anand Kumar Gupta, Brett C. Arenberg, Rebecca D. Huffstutler, Duck‐Yeon Lee, Michael N. Sack

2025Science Advances15 citationsDOIOpen Access PDF

Abstract

Although lipid-derived acetyl–coenzyme A (CoA) is a major carbon source for histone acetylation, the contribution of fatty acid β-oxidation (FAO) to this process remains poorly characterized. To investigate this, we generated mitochondrial acetyl-CoA acetyltransferase 1 (ACAT1, distal FAO enzyme) knockout macrophages. 13 C-carbon tracing confirmed reduced FA-derived carbon incorporation into histone H3, and RNA sequencing identified diminished interferon-stimulated gene expression in the absence of ACAT1. Chromatin accessibility at the Stat1 locus was diminished in ACAT1 −/− cells. Chromatin immunoprecipitation analysis demonstrated reduced acetyl-H3 binding to Stat1 promoter/enhancer regions, and increasing histone acetylation rescued Stat1 expression. Interferon-β release was blunted in ACAT1 −/− and recovered by ACAT1 reconstitution. Furthermore, ACAT1-dependent histone acetylation required an intact acetylcarnitine shuttle. Last, obese subjects’ monocytes exhibited increased ACAT1 and histone acetylation levels. Thus, our study identifies an intriguing link between FAO-mediated epigenetic control of type I interferon signaling and uncovers a potential mechanistic nexus between obesity and type I interferon signaling.

Topics & Concepts

AcetylationHistoneBiologyChromatin immunoprecipitationChromatinHistone deacetylase 2BiochemistryMolecular biologyHistone deacetylaseGene expressionPromoterGeneImmune cells in cancerImmune Cell Function and Interactioninterferon and immune responses
Mitochondrial fatty acid oxidation regulates monocytic type I interferon signaling via histone acetylation | Litcius