Bempedoic acid suppresses diet-induced hepatic steatosis independently of ATP-citrate lyase.

ATP citrate lyase (ACLY) synthesizes acetyl-CoA for de novo lipogenesis (DNL), which is elevated in metabolic dysfunction-associated steatotic liver disease. Hepatic ACLY is inhibited by the LDL-cholesterol-lowering drug bempedoic acid (BPA), which also improves steatosis in mice. While BPA potently suppresses hepatic DNL and increases fat catabolism, it is unclear if ACLY is its primary molecular target in reducing liver triglyceride.

Propionyl-CoA metabolism links chromatin acylation to cardiac transcription.

The molecular mechanisms that link propionyl-CoA metabolism and epigenetic regulation of gene expression are unclear, as are the implications for heart function. Now, new insights into the modulation of chromatin acylation and transcription by aberrant oxidation of propionyl-CoA are revealed in the dysfunctional hearts of mice with propionic acidemia.

Dietary branched-chain amino acids get to the heart of H3K23Pr.

Cardiac metabolism provides effects that extend beyond the transformation of energy for the heart to operate effectively. Some metabolites also function as signaling molecules and exert transcriptional changes. Heart failure is a progressive pathology in which these metabolite functions falter.

A subpopulation of lipogenic brown adipocytes drives thermogenic memory.

Sustained responses to transient environmental stimuli are important for survival. The mechanisms underlying long-term adaptations to temporary shifts in abiotic factors remain incompletely understood. Here, we find that transient cold exposure leads to sustained transcriptional and metabolic adaptations in brown adipose tissue, which improve thermogenic responses to secondary cold encounter.

Acetylcarnitine shuttling links mitochondrial metabolism to histone acetylation and lipogenesis.

The metabolite acetyl-CoA is necessary for both lipid synthesis in the cytosol and histone acetylation in the nucleus. The two canonical precursors to acetyl-CoA in the nuclear-cytoplasmic compartment are citrate and acetate, which are processed to acetyl-CoA by ATP-citrate lyase (ACLY) and acyl-CoA synthetase short-chain 2 (ACSS2), respectively. It is unclear whether other substantial routes to nuclear-cytosolic acetyl-CoA exist.

Histone N-terminal acetyltransferase NAA40 links one-carbon metabolism to chemoresistance.

Aberrant function of epigenetic modifiers plays an important role not only in the progression of cancer but also the development of drug resistance. N-alpha-acetyltransferase 40 (NAA40) is a highly specific epigenetic enzyme catalyzing the transfer of an acetyl moiety at the N-terminal end of histones H4 and H2A. Recent studies have illustrated the essential oncogenic role of NAA40 in various cancer types but its role in chemoresistance remains unclear.

Histone N-alpha terminal modifications: genome regulation at the tip of the tail.

Histone proteins are decorated with numerous post-(PTMs) or co-(CTMs) translational modifications mainly on their unstructured tails, but also on their globular domain. For many decades research on histone modifications has been focused almost solely on the biological role of modifications occurring at the side-chain of internal amino acid residues. In contrast, modifications on the terminal N-alpha amino group of histones-despite being highly abundant and evolutionarily conserved-have been largely overlooked.

NAA40 contributes to colorectal cancer growth by controlling PRMT5 expression.

N-alpha-acetyltransferase 40 (NAA40) catalyzes the transfer of an acetyl moiety to the alpha-amino group of serine 1 (S1) on histones H4 and H2A. Our previous studies linked NAA40 and its corresponding N-terminal acetylation of histone H4 (N-acH4) to colorectal cancer (CRC). However, the role of NAA40 in CRC development was not investigated.

Histone Acetyltransferases in Cancer: Guardians or Hazards?

Histone acetyltransferases (HATs) catalyzing N-epsilon-lysine or N-alpha-terminal acetylation on histone and non-histone substrates are important epigenetic regulators controlling gene expression and chromatin structure. Deregulation of these enzymes by genetic or epigenetic alterations accompanied by defects in gene transcription have been implicated in oncogenesis. Therefore, these enzymes are considered promising therapeutic targets, offering new horizons for epigenetic cancer therapy.