Project description:Metabolic Dysfunction-Associated Steatohepatitis (MASH) is characterized by liver steatosis and inflammation which lead to fibrosis following hepatic stellate cell (HSC) activation. Acetyl-CoA is fundamental for de novo lipogenesis (DNL) and cholesterol synthesis and can be derived from citrate via ATP citrate lyase (ACLY), or from acetate via acetyl-CoA synthetase (ACSS2). Here, we find that EVT0185, an ACLY and ACSS2 inhibitor, leads to resolution of MASH and fibrosis while lowering insulin and glucose in four distinct mouse models. EVT0185 also reduces fibrosis alone and in combination with semaglutide and more effectively than bempedoic acid in a model not characterized by steatosis or insulin resistance. Spatial transcriptomic and scRNAseq reveal marked downregulation of cholesterol synthesis in HSCs with EVT0185 treatment in vivo and in vitro. These data indicate a critical role for ACLY and ACSS2 in HSCs and suggest further clinical evaluation of EVT0185 for reducing MASH and fibrosis may be warranted.

Project description:ATP citrate lyase (ACLY) synthesizes acetyl-CoA for de novo lipogenesis (DNL), which is elevated in non-alcoholic fatty liver disease. Hepatic ACLY is inhibited by the LDL-cholesterol lowering drug bempedoic acid (BPA), which has been shown to improve steatosis in mice. However, the acetyl-CoA synthetase ACSS2 can compensate for ACLY deficiency to support DNL, potentially complicating the targeting of ACLY. We show that hepatic loss of both ACLY and ACSS2 reduces DNL. Nevertheless, even when ACSS2 is suppressed by dietary or genetic means, we find that steatosis is counterintuitively exacerbated with hepatic ACLY deficiency in mice fed a Western diet (WD), linked to reduced expression of PPARa target genes controlling fatty acid oxidation. Conversely, BPA treatment increased fat catabolism and ameliorated WD-mediated lipid accumulation in both WT and liver ACLY knockout mice. Thus, hepatic ACLY plays an unexpected role in restraining diet-dependent lipid accumulation, and BPA improves steatosis independent of ACLY.

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 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 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:Increased fatty acid synthesis benefits glioblastoma malignancy. However, the coordinated regulation of cytosolic acetyl-CoA production, the exclusive substrate for fatty acid synthesis, remains unclear. Here, we show that proto-oncogene tyrosine kinase c-SRC is activated in glioblastoma and remodels cytosolic acetyl-CoA production for fatty acid synthesis. Firstly, acetate is an important substrate for fatty acid synthesis in glioblastoma. c-SRC phosphorylates acetyl-CoA synthetase ACSS2 at Tyr530 and Tyr562 to stimulate the conversion of acetate to acetyl-CoA in cytosol. Secondly, c-SRC inhibits citrate-derived acetyl-CoA synthesis by phosphorylating ATP-citrate lyase ACLY at Tyr682. ACLY phosphorylation shunts citrate to IDH1-catalyzed NADPH production to provide reducing equivalent for fatty acid synthesis. The c-SRC-unresponsive double-mutation of ACSS2 and ACLY significantly reduces fatty acid synthesis and hampers glioblastoma progression. In conclusion, this remodeling fulfills the dual needs of glioblastoma cells for both acetyl-CoA and NADPH in fatty acid synthesis and provides evidence for glioma treatment by c-SRC inhibition.

Project description:Immunosuppressive tumor microenvironments are common in cancers such as metabolic dysfunction-associated steatohepatitis (MASH)-driven hepatocellular carcinoma (HCC). While immune cell metabolism influences effector function, the impact of tumor metabolism on immunogenicity is less understood. ATP citrate lyase (ACLY), a key enzyme linking catabolic and anabolic processes, supports lipid metabolism and gene regulation. Although ACLY inhibition shows anti-proliferative effects in various tumors, clinical translation has been limited by challenges in inhibitor development and compensatory metabolic pathways. Using a mouse model of MASH-driven HCC that mirrors human disease, genetic inhibition of ACLY in hepatocytes and tumors reduced neoplastic lesions by over 70%. To evaluate the therapeutic potential of this pathway, a novel small-molecule ACLY inhibitor, EVT0185 (6-[4-(5-carboxy-5-methyl-hexyl)-phenyl]-2,2-dimethylhexanoic acid), was identified via phenotypic screening. EVT0185 is converted to a CoA thioester in the liver by SLC27A2 with cryo-EM structural analysis revealing EVT0185-CoA directly interacts with ACLY’s CoA binding site. Oral delivery of EVT0185 in four mouse models of MASH-HCC dramatically reduces tumor burden as monotherapy and enhances efficacy of current standards of care including tyrosine kinase inhibitors and immunotherapies. Transcriptomic and spatial profiling in mice and humans linked reduced tumor ACLY with increases in CXCL13, tumor infiltrating B-cells and tertiary lymphoid structures. Remarkably, the depletion of B cells blocked the anti-tumor effects of ACLY depletion. Together, these findings illustrate how targeting tumor metabolism can rewire immune function and suppress cancer progression in MASH-HCC.

Project description:Immunosuppressive tumor microenvironments are common in cancers such as metabolic dysfunction-associated steatohepatitis (MASH)-driven hepatocellular carcinoma (HCC). While immune cell metabolism influences effector function, the impact of tumor metabolism on immunogenicity is less understood. ATP citrate lyase (ACLY), a key enzyme linking catabolic and anabolic processes, supports lipid metabolism and gene regulation. Although ACLY inhibition shows anti-proliferative effects in various tumors, clinical translation has been limited by challenges in inhibitor development and compensatory metabolic pathways. Using a mouse model of MASH-driven HCC that mirrors human disease, genetic inhibition of ACLY in hepatocytes and tumors reduced neoplastic lesions by over 70%. To evaluate the therapeutic potential of this pathway, a novel small-molecule ACLY inhibitor, EVT0185 (6-[4-(5-carboxy-5-methyl-hexyl)-phenyl]-2,2-dimethylhexanoic acid), was identified via phenotypic screening. EVT0185 is converted to a CoA thioester in the liver by SLC27A2 with cryo-EM structural analysis revealing EVT0185-CoA directly interacts with ACLY’s CoA binding site. Oral delivery of EVT0185 in four mouse models of MASH-HCC dramatically reduces tumor burden as monotherapy and enhances efficacy of current standards of care including tyrosine kinase inhibitors and immunotherapies. Transcriptomic and spatial profiling in mice and humans linked reduced tumor ACLY with increases in CXCL13, tumor infiltrating B-cells and tertiary lymphoid structures. Remarkably, the depletion of B cells blocked the anti-tumor effects of ACLY depletion. Together, these findings illustrate how targeting tumor metabolism can rewire immune function and suppress cancer progression in MASH-HCC.

Project description:Exhausted T cells (TEX) in cancer and chronic viral infections undergo metabolic and epigenetic remodeling, impairing protective capabilities. However, the impact of nutrient metabolism on epigenetic modifications that control TEX differentiation remains unclear. Our study reveals that TEX cells shift from acetate to citrate metabolism by downregulating acetyl-CoA synthetase 2 (ACSS2) while maintaining ATP-citrate lyase (ACLY) activity. This metabolic switch increases citrate-dependent histone acetylation, mediated by histone acetyltransferase KAT2A-ACLY interactions, at TEX signature-genes while reducing acetate-dependent histone acetylation, dependent on p300-ACSS2 complexes, at effector and memory T cell genes. Nuclear ACSS2 overexpression or ACLY inhibition prevents TEX differentiation and enhances tumor-specific T cell responses. These findings unveil a nutrient-driven histone code governing CD8+ T cell differentiation, with implications for metabolic- and epigenetic-based T cell therapies

Project description:To investigate the role of ACSS2 and ACLY in the regulation of epigenetic states of CD8+ T cells in cancer and chronic viral infections Exhausted T cells (TEX) in cancer and chronic viral infections undergo metabolic and epigenetic remodeling, impairing protective capabilities. However, the impact of nutrient metabolism on epigenetic modifications that control TEX differentiation remains unclear. Our study reveals that TEX cells shift from acetate to citrate metabolism by downregulating acetyl-CoA synthetase 2 (ACSS2) while maintaining ATP-citrate lyase (ACLY) activity. This metabolic switch increases citrate-dependent histone acetylation, mediated by histone acetyltransferase KAT2A-ACLY interactions, at TEX signature-genes while reducing acetate-dependent histone acetylation, dependent on p300-ACSS2 complexes, at effector and memory T cell genes. Nuclear ACSS2 overexpression or ACLY inhibition prevents TEX differentiation and enhances tumor-specific T cell responses. These findings unveil a nutrient-driven histone code governing CD8+ T cell differentiation, with implications for metabolic- and epigenetic-based T cell therapies