Project description:Hepatic acetyl-CoA metabolism modulates neuroinflammation and depression susceptibility via acetate

Project description:In the adult brain, epigenetic control of gene expression has important roles in the processing of neural activity. Emerging evidence suggests that epigenetic regulation is dependent on metabolic state, implicating specific metabolic factors in neural functions that drive behavior. In neurons, histone acetylation is dependent on the metabolite acetyl-CoA that is produced from acetate by chromatin-bound ACSS21. Here, using in vivo stable isotope labeling in mouse, we show that alcohol metabolism rapidly fuels histone acetylation in the brain by direct deposition of alcohol-derived acetyl groups onto histones in an ACSS2-dependent manner. A similar induction was observed with heavy labeled acetate injection in vivo. Injection of labeled alcohol into a pregnant mouse results in incorporation of labeled acetyl groups into gestating fetal brains, indicating that the acetate passes through the placenta. In isolated primary hippocampal neurons ex vivo, extracellular acetate induced learning and memory-related transcriptional programs that were sensitive to ACSS2 inhibition. Strikingly, alcohol-related associative learning requires ACSS2 in vivo. These findings establish a novel and direct link between alcohol metabolism and neuronal ACSS2-dependent histone acetylation in the brain, providing evidence that dynamic acetate release from liver metabolism may travel to the brain for direct epigenetic regulation in neurons.

Project description:In the adult brain, epigenetic control of gene expression has important roles in the processing of neural activity. Emerging evidence suggests that epigenetic regulation is dependent on metabolic state, implicating specific metabolic factors in neural functions that drive behavior. In neurons, histone acetylation is dependent on the metabolite acetyl-CoA that is produced from acetate by chromatin-bound ACSS21. Here, using in vivo stable isotope labeling in mouse, we show that alcohol metabolism rapidly fuels histone acetylation in the brain by direct deposition of alcohol-derived acetyl groups onto histones in an ACSS2-dependent manner. A similar induction was observed with heavy labeled acetate injection in vivo. Injection of labeled alcohol into a pregnant mouse results in incorporation of labeled acetyl groups into gestating fetal brains, indicating that the acetate passes through the placenta. In isolated primary hippocampal neurons ex vivo, extracellular acetate induced learning and memory-related transcriptional programs that were sensitive to ACSS2 inhibition. Strikingly, alcohol-related associative learning requires ACSS2 in vivo. These findings establish a novel and direct link between alcohol metabolism and neuronal ACSS2-dependent histone acetylation in the brain, providing evidence that dynamic acetate release from liver metabolism may travel to the brain for direct epigenetic regulation in neurons.

Project description:In the adult brain, epigenetic control of gene expression has important roles in the processing of neural activity. Emerging evidence suggests that epigenetic regulation is dependent on metabolic state, implicating specific metabolic factors in neural functions that drive behavior. In neurons, histone acetylation is dependent on the metabolite acetyl-CoA that is produced from acetate by chromatin-bound ACSS21. Here, using in vivo stable isotope labeling in mouse, we show that alcohol metabolism rapidly fuels histone acetylation in the brain by direct deposition of alcohol-derived acetyl groups onto histones in an ACSS2-dependent manner. A similar induction was observed with heavy labeled acetate injection in vivo. Injection of labeled alcohol into a pregnant mouse results in incorporation of labeled acetyl groups into gestating fetal brains, indicating that the acetate passes through the placenta. In isolated primary hippocampal neurons ex vivo, extracellular acetate induced learning and memory-related transcriptional programs that were sensitive to ACSS2 inhibition. Strikingly, alcohol-related associative learning requires ACSS2 in vivo. These findings establish a novel and direct link between alcohol metabolism and neuronal ACSS2-dependent histone acetylation in the brain, providing evidence that dynamic acetate release from liver metabolism may travel to the brain for direct epigenetic regulation in neurons.

Project description:While prior work in muscle cells indicates that metabolic reprogramming is associated with quiescence, whether metabolic changes occur in cancer to drive quiescence is unclear. Using a multi-omics approach, we found that the metabolic enzyme ACSS2 is both highly upregulated in quiescent cells and required for their survival. ACSS2 converts acetate into acetyl-CoA, and we confirmed increased acetate-derived acetyl-CoA in quiescent cells, demonstrating increased ACSS2 activity. Interestingly, supplementing cells with acetate alone was sufficient to induce a reversible quiescent cell cycle exit.

Project description:Coordination of cellular metabolism is essential for optimal T cell responses. Here, we identify cytosolic acetyl-CoA production as an essential metabolic node for CD8 T cell function in vivo. We show that CD8 T cell responses to infection depend on acetyl-CoA derived from citrate via the enzyme ATP citrate lyase (ACLY). However, ablation of ACLY triggers an alternative, acetate-dependent pathway for acetyl-CoA production mediated by acyl-CoA synthetase short chain family member 2 (ACSS2). Mechanistically, acetate fuels both the TCA cycle and cytosolic acetyl-CoA production, impacting T cell effector responses, acetate-dependent histone acetylation, and chromatin accessibility at effector gene loci. When ACLY is functional, ACSS2 is not required, suggesting acetate is not an obligate metabolic substrate for CD8 T cell function. However, loss of ACLY renders CD8 T cells dependent on acetate (via ACSS2) to maintain acetyl-CoA production and effector function. Together, ACLY and ACSS2 coordinate cytosolic acetyl-CoA production in CD8 T cells to maintain chromatin accessibility and T cell effector function.

Project description:Coordination of cellular metabolism is essential for optimal T cell responses. Here, we identify cytosolic acetyl-CoA production as an essential metabolic node for CD8 T cell function in vivo. We show that acetyl-CoA derived from mitochondrial citrate via the enzyme ATP citrate lyase (Acly) is required for CD8 T cell responses to infection. However, ablation of Acly triggers an alternative, acetate-dependent pathway for acetyl-CoA production in T cells mediated by acyl-CoA synthetase short chain family member 2 (Acss2). Mechanistically, acetate fuels both the TCA cycle and cytosolic acetyl-CoA production, impacting T cell effector responses, acetate-dependent histone acetylation, and effector gene expression by altering chromatin accessibility. When Acly is functional, Acss2 is not required, suggesting acetate is not an obligate metabolic substrate for CD8 T cell function. However, deletion of Acly renders CD8 T cells dependent on acetate (via Acss2) to maintain acetyl-CoA production and effector function. Thus, together Acly and Acss2 coordinate cytosolic acetyl-CoA production in CD8 T cells to maintain chromatin accessibility and T cell effector function.

Project description:Coordination of cellular metabolism is essential for optimal T cell responses. Here, we identify cytosolic acetyl-CoA production as an essential metabolic node for CD8 T cell function in vivo. We show that CD8 T cell responses to infection depend on acetyl-CoA derived from citrate via the enzyme Acly (ATP citrate lyase). However, ablation of Acly triggers an alternative, acetate-dependent pathway for acetyl-CoA production mediated by Acss2 (acyl-CoA synthetase short chain family member 2). Mechanistically, acetate fuels both the TCA cycle and cytosolic acetyl-CoA production, impacting T cell effector responses, acetate-dependent histone acetylation, and chromatin accessibility at effector gene loci. When Acly is functional, Acss2 is not required, suggesting acetate is not an obligate metabolic substrate for CD8 T cell function. However, deletion of Acly renders CD8 T cells dependent on acetate (via Acss2) to maintain acetyl-CoA production and effector function. Thus, together Acly and Acss2 coordinate cytosolic acetyl-CoA production in CD8 T cells to maintain chromatin accessibility and T cell effector function.

Project description:The severe harm of depression to human life has attracted great attention to neurologists, but its pathogenesis is extremely complicated and has not yet been fully elaborated. Here, we provided a new strategy for revealing the specific pathways of abnormal brain glucose catabolism in depression, which from the supply of energy substrates and the evaluation of mitochondrial structure and function. By using stable isotope-resolved metabolomics technique, we discovered the tricarboxylic acid cycle (TCA cycle) is blocked and the gluconeogenesis is abnormally activated in chronic unpredictable mild stress (CUMS) rats. In addition, our results showed an interesting phenomenon that the brain attempted to activate all possible metabolic enzymes in energy-producing pathways, but CUMS rats still exhibited a low TCA cycle activity due to impaired mitochondria. Depression caused mitochondrial structure and function impaired, and then led to abnormal brain glucose catabolism. The combination of the stable isotope-resolved metabolomics and mitochondrial structure and function analysis can accurately clarify the mechanism of depression. The mitochondrial pyruvate carrier and acetyl-CoA maybe the key targets for depression treatment. The strategy provides a unique insight for exploring the mechanism of depression, the discovery of new targets, and the development of ideal novel antidepressants.

Project description:Histone acetylation, a post-translational modification associated with transcriptional activation, is governed by nuclear acetyl-CoA pools that can vary depending on the metabolic state of the cell. The metabolic enzyme acetyl-CoA synthetase 2 (ACSS2) is proposed to regulate nuclear acetyl-CoA levels, using local acetate to produce acetyl-CoA that is utilized for histone acetylation. We hypothesize that during gene activation, a local transfer of intact acetate occurs between histones to upregulate transcription via sequential action of epigenetic and metabolic enzymes. Here we present converging lines of evidence in support of this acetate transfer to serve rapid gene induction. Using stable isotope labeling, we detect local transfer of intact acetate between histone acetylation sites both in vitro using purified mammalian enzymes and in vivo using quiescence exit in Saccharomyces cerevisiae as a change-of-state model. We delineate the enzymatic components required for this transfer mechanism, finding that ACSS2, histone deacetylase and histone acetyltransferase enzymes are necessary for efficient acetyl-group transfer in vitro. We show that Acs2, the yeast orthologue of ACSS2, is recruited to the genome during quiescence exit, and observe dynamic changes of histone acetylation in the vicinity of Acs2 peaks in vivo. Strikingly, we find that Acs2 is preferentially associated with the most upregulated growth genes, suggesting that acetyl-group transfer might play an important role in increased gene expression. Overall, our data reveal direct transfer of acetate between histone lysine residues to facilitate rapid transcriptional induction, an exchange that may be critical during metabolic alterations and changes in nutrient availability.