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Ketone Bodies Rescue Mitochondrial Dysfunction Via Epigenetic Remodeling

Jessica Gambardella, Stanislovas S. Jankauskas, Urna Kansakar, Fahimeh Varzideh, Roberta Avvisato, Nella Prevete, Simone Sidoli, Pasquale Mone, Xujun Wang, Angela Lombardi, Gaetano Santulli

2023JACC Basic to Translational Science50 citationsDOIOpen Access PDF

Abstract

Ischemic cardiac disease is a major cause of mortality worldwide. However, the exact molecular processes underlying this disorder are not fully known. This study includes a comprehensive and coordinated set of in vivo and in vitro experiments using human cardiac specimens from patients with postischemic heart failure (HF) and healthy control subjects, a murine model of HF, and cellular systems. These approaches identified for the first time a specific pattern of maladaptive chromatin remodeling, namely a double methylation of histone 3 at lysine 27 and a single methylation at lysine 36 (H3_K27me2K36me1) consistently induced by ischemic injury in all these settings: human HF; murine HF; and in vitro models. Mechanistically, this work demonstrates that this histone modification mediates the ischemia-induced transcriptional repression of PPARG coactivator 1α (PGC1α), master regulator of mitochondrial function and biogenesis. Intriguingly, both the augmented H3_K27me2K36me1 and the mitochondrial dysfunction ensued by PGC1α down-regulation were significantly attenuated by the treatment with β-hydroxybutyrate, the most abundant ketone body in humans, revealing a novel pathway coupling metabolism to gene expression. Taken together, these findings establish maladaptive chromatin remodeling as a key mechanism in postischemic heart injury, functionally modulated by ketone bodies.

Topics & Concepts

Chromatin remodelingHistoneEpigeneticsMitochondrial biogenesisBiologyChromatinCell biologyRegulatorMitochondrionCoactivatorVentricular remodelingHistone methylationHistone H3AcetylationDNA methylationBioinformaticsHeart failureMedicineGene expressionInternal medicineGeneGeneticsTranscription factorDiet and metabolism studiesMetabolism, Diabetes, and CancerAdipose Tissue and Metabolism