Abstract Our goal is to investigate the impact of diet and pressure overload on the histone code, and how this influences changes in gene expression in the healthy and hypertrophied/failing hearts and, in turn, how it impacts progression of the disease. Deciphering the histone code and how diet can modify it, provides us an educated means to exploit it to our advantage, especially during pathological conditions. Acetylation and methylation of histone lysine (K) residues were the first histone modifications discovered and are, therefore, the most widely studied and understood. However, to-date, there are 11 confirmed modifiers of histone lysine residues, including the acyl groups butyryl (Bu), crotonyl (Cr), and b-hydroxybutyrate (bHB) 1, whose source, genomic distribution, and functional relevance, remain largely unknown in the heart, and are the focus of our study. Our recent findings uniquely show that dietary fat is a major regulator of histone butyrylation, including H3K9-butyryl (H3K9Bu). Using genome-wide chromatin immunoprecipitation-sequencing (ChIP-Seq), we show that H3K9Bu is abundant at all transcriptionally active promoters. Both a high-fat diet and stress accelerated the conversion of butyryl-CoA to crotonyl-CoA via acyl-CoA dehydrogenase short chain (ACADS), resulting in a substantial reduction in global promoter-H3K9Bu. A deletion of ACADS both in the mouse heart and in human cells reversed this effect and increased promoter and gene-body H3K9Bu. Paradoxically, though, a fat-free diet had the highest levels of H3K9Bu. Deletion of fatty acid synthetase (FASN), abolished H3K9Bu in cells maintained in a glucose-rich, fatty acid-free, but not in a fatty acid-rich, medium, proving that fatty acid synthesis from carbohydrates substitutes for dietary fat as a source butyryl-CoA. In contrast to H3K9Bu, there were minimal dietary-induced changes in H3K9-acetyl (H3K9ac) levels. Importantly, RNA-sequencing (RNA-Seq) revealed that diet-induced changes in H3K9Bu abundance in the mouse heart was associated with differential changes in gene expression, but only when stressed by pressure overload. Moreover, promoter-H3K9Bu levels inversely correlated with the extent of changes in gene expression levels, as evidenced by the more robust changes seen in the hearts of mice on a, short-term, high-fat vs a fat-free diet, as well as, after deletion of the ACADS. Interestingly, H3K9Bu abundance inversely correlated with H3K9-crotonyl (H3K9Cr) and Cdk9. In sum, our data uniquely show that H3K9Bu is enriched at active promoters, is negatively regulated by high-fat and stress in an ACADS-dependent fashion, and its abundance inversely correlates with stress-induced changes in gene expression. We are proposing that histone H3K9Bu, H3K9Cr, and H3K9-b-hydroxybutyryl (H3K9bHB), are products of the b-oxidation intermediates, butyryl-CoA, crotonyl-CoA, and b-hydroxybutyryl-CoA, or the ketone body, b-hydroxybutyrate, which serve as substrates for histones modificati...