Project description:Metabolic flexibility in skeletal muscle is essential for maintaining healthy glucose and lipid metabolism, and its dysfunction is closely linked to metabolic diseases. Exercise enhances metabolic flexibility, making it an important tool for discovering mechanisms that promote efficient energy metabolism. We herein discover pantothenate kinase 4 (PanK4) as a conserved exercise target with high abundance in muscle. Germline deletion of Pank4 reduces circulating IGF-1 and stunts growth in mice. Muscle-specific deletion of Pank4 leads to a reduction in carnitzed and in impaired fatty acid oxidation in oxidative muscle which is related to higher acetyl-CoA and malonyl levels. Acetyl-CoA levels were persistently elevated in SkM lacking PanK4, independent of prandial state. In addition to perturbations of fatty acid oxidation, high SkM acetyl-CoA levels were associated with whole-body glucose intolerance, impaired insulin-stimulated glucose uptake into glycolytic SkM and impaired SkM glucose uptake during exercise. Conversely, we show that an increase in PanK4 lowers acetyl-CoA and increases glucose uptake in glycolytic SkM. Our findings identify PanK4 as a conserved exercise target that regulates SkM acetyl-CoA levels and plays a key role in lipid and glucose metabolism.

Project description:Exercise training is a potent treatment of NAFLD and hepatic insulin resistance. Here we provide molecular information about the hepatic mitochondrial metabolism in mice when chronic overnutrition (high-energy diet (HED) for 6 weeks) is combined with exercise training. Training reduced the hepatic triacylglycerol content, fasting insulin, and reversed glucose intolerance. Training modified the hepatic mitochondrial proteome with a decrease in enzymes related to pyruvate metabolism and entry of acetyl-CoA into the TCA cycle. Transcriptome data revealed down-regulation of glucose oxidation and lipogenesis. The mitochondrial respiratory capacity of trained HED-fed mice is increased despite reduced content of complex I. Training decreased diacylglycerol species and JNK phosphorylation, both of which can induce insulin resistance. Increased mitochondrial mass and oxidative capacity of the trained muscle further unburdens the liver from substrate overload. Together, when high fat and carbohydrate intake in mice is accompanied by exercise, the decline of mitochondrial function and insulin resistance can be prevented by modification of mitochondrial acetyl-CoA metabolism.

Project description:Carnitine acetyltransferase (CRAT) is a mitochondrial enzyme and catalyzes the conversion of acetyl-CoA to acetyl-Carnitine, which enables its export from mitochondria. It was reported that CRAT played a central role in regulating metabolic flexibility and promoting substrate switching from fatty acid to glucose in skeletal myocytes5. Interestingly, CRAT is most abundantly expressed in the heart and its activity is dramatically decreased in the mouse model of HF5,9. However, the specific contribution of this enzyme in the pathogenesis of HF remains largely uncharacterized.

Project description:Exercise training is a potent treatment of NAFLD and hepatic insulin resistance. Here we provide molecular information about the hepatic mitochondrial metabolism in mice when chronic overnutrition (high-energy diet (HED) for 6 weeks) is combined with exercise training. Training reduced the hepatic triacylglycerol content, fasting insulin, and reversed glucose intolerance. Training modified the hepatic mitochondrial proteome with a decrease in enzymes related to pyruvate metabolism and entry of acetyl-CoA into the TCA cycle. Transcriptome data revealed down-regulation of glucose oxidation and lipogenesis. The mitochondrial respiratory capacity of trained HED-fed mice is increased despite reduced content of complex I. Training decreased diacylglycerol species and JNK phosphorylation, both of which can induce insulin resistance. Increased mitochondrial mass and oxidative capacity of the trained muscle further unburdens the liver from substrate overload. Together, when high fat and carbohydrate intake in mice is accompanied by exercise, the decline of mitochondrial function and insulin resistance can be prevented by modification of mitochondrial acetyl-CoA metabolism.

Project description:Muscle is known to be a highly glycolytic tissue, yet the impact of glucose metabolism in muscle stem cell function remains unresolved. Here we use Mass Cytometry (CyTOF) to capture changes in histone acetylation profiles at the single cell level in vivo following injury. We demonstrate that MuSCs transiently increase histone acetylation upon activation, followed by global loss upon commitment. The switch to a committed state is driven by glucose metabolism through pyruvate dehydrogenase (PDH), which fuels histone acetylation via production of acetyl-CoA. Pharmacological or genetic activation of PDH results in increased histone acetylation and impedes myogenic differentiation. Moreover, mice lacking PDH inhibitory kinases, PDK2 and PDK4, accumulate uncommitted satellite cells and exhibit impaired muscle regeneration. These studies identify PDH as a previously unrecognized dynamic metabolic mediator of epigenetic state crucial to myogenic commitment and regeneration.

Project description:Skeletal muscle plays a central role in the control of metabolism and exercise tolerance. Analysis of muscle enhancers activated after exercise in mice revealed the orphan nuclear receptor NURR1/NR4A2 as a prominent component of exercise-responsive enhancers. We show that exercise enhances the expression of NURR1 and transgenic overexpression of NURR1 in skeletal muscle confers an endurance phenotype in mice. NURR1 expression in skeletal muscle is also sufficient to prevent hyperglycemia and hepatic steatosis by enhancing muscle glucose uptake and storage as glycogen. Furthermore, treatment of obese mice with putative NURR1 agonists increases energy expenditure, improves glucose tolerance, and confers a lean phenotype, mimicking the effects of exercise. These findings identify a key role for NURR1 in governance of skeletal muscle glucose metabolism and reveal a transcriptional link between exercise and metabolism. Our findings also identify NURR1 agonists as possible exercise mimetics with the potential to ameliorate obesity and other metabolic abnormalities.

Project description:Skeletal muscle plays a central role in the control of metabolism and exercise tolerance. Analysis of muscle enhancers activated after exercise in mice revealed the orphan nuclear receptor NURR1/NR4A2 as a prominent component of exercise-responsive enhancers. We show that exercise enhances the expression of NURR1 and transgenic overexpression of NURR1 in skeletal muscle confers an endurance phenotype in mice. NURR1 expression in skeletal muscle is also sufficient to prevent hyperglycemia and hepatic steatosis by enhancing muscle glucose uptake and storage as glycogen. Furthermore, treatment of obese mice with putative NURR1 agonists increases energy expenditure, improves glucose tolerance, and confers a lean phenotype, mimicking the effects of exercise. These findings identify a key role for NURR1 in governance of skeletal muscle glucose metabolism and reveal a transcriptional link between exercise and metabolism. Our findings also identify NURR1 agonists as possible exercise mimetics with the potential to ameliorate obesity and other metabolic abnormalities.

Project description:Metabolic dysfunction of skeletal muscle is often prevalent at an early stage in the development of several non-communicable diseases. Here, we investigated the effect of a myokine, secreted protein acidic and rich in cysteine (SPARC), on glucose tolerance in human and mouse skeletal muscles. SPARC knockout mice showed marked decreases in parameters for whole-body glucose metabolism, along with reduced phosphorylation of AMPK and Akt in skeletal muscle tissues compared with wild-type mice. Furthermore, mice injected with SPARC showed improved glucose tolerance concomitant with AMPK activation. Exogenous SPARC treatment accelerated glucose uptake in muscle tissues isolated from wild-type mice but not from AMPKγ3 knockout mice. In muscle cells, SPARC increased glucose uptake concomitant with AMPK activation, mediated by a calcium-dependent signal. Chronic treatment of SPARC restored metabolic functions in diet-induced obese mice. These findings suggest that SPARC improves glucose metabolism via AMPK activation in skeletal muscle, providing mechanistic insights on exercise-induced metabolic benefits and physical inactivity-induced glucose intolerance.

Project description:Formation of myelin by Schwann cells is tightly coupled to nervous system development and is important for neuronal function and long-term maintenance. Perturbation of myelin causes a number of specific disorders that are among the most prevalent diseases affecting the nervous system. Schwann cells synthesize myelin lipids de novo rather than relying on uptake of circulating lipids, and the metabolic sources of myelin formation and maintenance in vivo remain unresolved. One of these questions is how a central metabolite in myelin formation, Acetyl CoA, is generated in myelinating cells. Acetyl CoA-generating pathways are induced at the level of gene expression to support high demands for lipid synthesis and acetylation reactions. However, recent studies have shown that glucose-derived Acetyl CoA itself is not required for myelination, and the requirements of mitochondrially-derived Acetyl CoA has never been tested for myelination in vivo. Several older labeling studies have demonstrated the possibility that cytosolic Acetyl CoA-generating pathways from acetate/ketone bodies satisfy the high demands for lipid synthesis and histone acetylation, and we have employed knockout mice to test the required pathways. Intriguingly, metabolic pathways play different role during the postnatal synthesis of myelin lipids in the postnatal period compared to myelin maintenance postweaning.

Project description:Our studies indicate that glucose and acetate can regulate histone acetylation by altering the acetyl-CoA concentrations in the cell. The purpose of this study was to to determine whether specific gene sets correlated with acetyl-CoA availability. We conclude that 10% of glucose-regulated genes are acetyl-CoA regulated genes (genes suppressed or induced by low glucose and reversed by acetate). Acetate usually regulated gene expression in the same direction as glucose, suggesting that acetyl-CoA is a key mediator of glucose-dependent gene expression. The experiments were performed in quadruplicates for each condition with a total of 12 samples