Project description:We performed RNA-Seq on skeletal muscle tissue in Active individuals, indivduals with obesity (Obese) and individuals with obesity and T2D (T2D) (n =6 per group). PCA of top ranked contributing genes show clear separation of the Active group from Obese and T2D with considerable overlap between Obese and T2D. Over-representation analysis highlighted that Active had an upregulation of genes related to respiration/mitochondrial capacity in comparison to Obese and T2D. RRBS was performed on skeletal muscle tissue from a subset of participants from each group (n = 3). Data was analyzed to reveal (DMS) differentially methylated sites located at differentially expressed genes related to mitochondrial respiration/function. Out of a combined 488 DMS related to mitochondrial related differentially expressed genes, 11% were significantly positively correlated with gene expression and 12% were significantly negatively associated with gene expression. Significantly correlated DMS were mainly located in the promoter and 1st intron region

Project description:The homeodomain transcription factor Prep1 was previously shown to regulate insulin sensitivity. Our aim was to study the specific role of Prep1 for the regulation of energy metabolism in skeletal muscle. Muscle specific ablation of Prep1 resulted in increased expression of respiratory chain subunits. This finding was consistent with an increase in mitochondrial enzyme activity without affecting mitochondrial volume fraction as assessed by electron microscopy. Metabolic phenotyping revealed no differences in daily energy expenditure or body composition. However, during treadmill exercise challenge, Prep1 ablation resulted in a higher maximal oxidative capacity and better endurance. Elevated PGC-1α expression was identified as a cause for increased mitochondrial capacity in Prep1-ablated mice. Prep1 stabilizes p160 Mybbp1a, a known inhibitor of PGC-1α activity. Thereby, P160 protein levels were significantly lower in muscle of Prep1-ablated mice. By a ChIPseq approach, PREP1-binding sites in genes encoding mitochondrial components (e.g. Ndufs2) were identified that might be responsible for elevated OXPHOS proteins in the muscle of Prep1 nullmutants. These results suggest that Prep1 exhibits additional direct effects on regulation of mitochondrial proteins. We therefore conclude that Prep1 is a regulator of oxidative phosphorylation components via direct and indirect mechanisms. Consequence of Prep1 ablation in skeletal muscle was investigated in Prep1deltaSM mice and compared to Prep1 flox mice, both on C57BL/6 background. 4 mice of each genotype were used to extract RNA from the tibialis anterior muscle.

Project description:Lipotoxicity, the accumulation of lipids in non-adipose tissues, alters the metabolic transcriptome and mitochondrial metabolism in skeletal muscle. The mechanisms involved remain poorly understood. Here we show that lipotoxicity increased histone deacetylase 4 (HDAC4) and histone deacetylase 5 (HDAC5), which reduced the expression of metabolic genes and oxidative metabolism in skeletal muscle. This metabolic reprogramming was linked with reduced expression of p53-dependent genes that mediate apoptosis and ferroptosis, which preserved cell viability in response to lipotoxicity. Mechanistically, impaired mitochondrial metabolism reduced acetylation of p53 at K120, a modification required for transcriptional activation of apoptosis, while redox drivers of ferroptosis were also reduced. Overexpression of loss-of-function HDAC4 and HDAC5 mutants in skeletal muscle of obese db/db mice enhanced oxidative capacity, increased apoptosis and ferroptosis and reduced muscle mass. This study identifies HDAC4 and HDAC5 as repressors of the oxidative state of skeletal muscle, and that this metabolic reprogramming, considered deleterious for normal metabolism, is critical to preserve muscle integrity in response to lipotoxicity.

Project description:Oxidative posttranslational modifications (Ox-PTMs) regulate cellular homeostasis in several tissues, including skeletal and cardiac muscles. The putative relationship between Ox-PTMs and intrinsic components of oxidative energy metabolism has not been previously described. We determined the metabolic phenotype and the Ox-PTM profile in the skeletal and cardiac muscles of rats selected for low (LCR) or high (HCR) intrinsic aerobic capacity. The HCR rats have a pronounced increase in mitochondrial content and antioxidant capacity when compared to LCR rats in the skeletal muscle, but only modest changes in the cardiac muscle. Redox proteomics analysis reveals that HCR and LCR rats have different Ox-PTM of cysteine (Cys) residue profile in the skeletal and cardiac muscles. HCR rats have higher number of oxidized Cys residues in the skeletal muscle and conversely display higher number of reduced Cys residues in the cardiac muscle than LCR rats. Most of the proteins with differentially oxidized Cys residues in the skeletal muscle are important regulators of the oxidative metabolism. The most significantly oxidized protein in the skeletal muscle of HCR rats is malate dehydrogenase (MDH1). Interestingly, HCR rats show higher MDH1 activity in the skeletal muscle, but not in the cardiac muscle. Thus, this study uncovers an association between Ox-PTMs and intrinsic aerobic capacity, providing new insights into the role of Ox-PTMs as essential signaling to maintain metabolic homeostasis in different muscle types.

Project description:Skeletal muscle function is vital to movement, thermogenesis and metabolism. Muscle fibers differ in contractile ability, mitochondrial content and metabolic properties and muscle fiber transition influences muscle function. However, the molecular mechanisms regulating muscle fiber transition in muscle function are unclear. Here, in over 150 human muscle samples, we observed that markers of oxidative muscle fiber and mitochondria correlate positively with PPARGC1 and CDK4, and, negatively with CDKN2A, a locus significantly associated with type 2 diabetes. Mice expressing an overactive Cdk4 that cannot bind its inhibitor p16INK4a, a product of the CDKN2A locus, are longer, leaner, exhibit increased oxidative myofibers with superior mitochondrial energetics, display enhanced muscle glucose uptake, and are protected from obesity and diabetes. In contrast, Cdk4-deficiency, or skeletal muscle-specific deletion of Cdk4’s transcriptional target, E2F3, reduces oxidative myofiber numbers, deteriorates mitochondrial function and exercise capacity, while increasing diabetes susceptibility. E2F3 activates the PPARGC1 promoter and CDK4/E2F3/PPARGC1 levels correlate positively with exercise and fitness, and negatively with adiposity, insulin resistance and lipid accumulation in muscle. These findings provide insight into oxidative muscle fiber transition and function that is of relevance to metabolic and muscular diseases.

Project description:Skeletal muscle insulin resistance and β-cell dysfunction are signature features of type 2 diabetes (T2D) pathogenesis. We previously demonstrated a pivotal role for the cell cycle kinase, Cdk4, in regulation of β-cell mass. Here, we demonstrate that Cdk4R/R mice, which harbor constitutively active Cdk4 kinase, are resistant to obesity and diabetes. The metabolic protection is associated with Cdk4 promoting the numbers and regeneration potential of slow/oxidative muscle fibers, improved muscle mitochondrial bioenergetics and elevated E2F3 and PGC-1α expression in muscle. In contrast, muscle-specific E2F3 knockout mice exhibit poor exercise capacity and susceptibility to obesity and diabetes. Exercise induces levels of Cdk4/E2F3/PGC-1α, while those levels are suppressed in obesity. Also, levels of E2F3/PGC-1α negatively correlate with adiposity, insulin resistance and lipid accumulation in human muscle biopsies. These findings are supportive of an important role for Cdk4/E2F3 in muscle fiber type development and metabolism with therapeutic potential for metabolic and muscular diseases.

Project description:Skeletal muscle insulin resistance, decreased phosphatidylinositol 3-kinase (PI3K) activation and altered mitochondrial function are hallmarks of type 2 diabetes. We created mice with a muscle-specific knockout of p110α or p110β, the two major catalytic subunits of PI3K. We find that mice with muscle-specific knockout of p110α, but not p110β, display impaired muscle insulin signaling and reduced muscle size due to enhanced proteasomal and autophagic activity. Despite insulin resistance and muscle atrophy, M-p110αKO mice show decreased serum myostatin, increased mitochondrial mass, increased mitochondrial fusion visualized by intravital microscopy, and increased PGC1α expression, especially PCG1α2 and PCG1α3. This leads to enhanced mitochondrial oxidative capacity, striking increases in muscle NADH content, and higher muscle free radical release measured in vivo using pMitoTimer reporter. Thus, p110α is the dominant catalytic isoform of PI3K in muscle in control of insulin sensitivity and muscle mass, and has a unique role in mitochondrial homeostasis in skeletal muscle.

Project description:Title: Total Skeletal Muscle PGC-1 Deficiency Uncouples Mitochondrial Derangements from Fiber Type Determination and Insulin Sensitivity Abstract: Evidence is emerging that the PGC-1 coactivators serve a critical role in skeletal muscle metabolism, function, and disease. Mice with total PGC-1 deficiency in skeletal muscle (PGC-1α-/- βf/f/MLC-Cre mice) were generated and characterized. PGC-1α-/-βf/f/MLC-Cre mice exhibit a dramatic reduction in exercise performance compared to single PGC-1α- or PGC-1β-deficient mice and wild-type controls. The exercise phenotype of the PGC-1α-/-βf/f/MLC-Cre mice was associated with a marked diminution in muscle oxidative capacity and mitochondrial structural derangements consistent with fusion/fission and biogenic defects together with rapid depletion of muscle glycogen stores during exercise. Surprisingly, the skeletal muscle fiber type profile of the PGC-1α-/-βf/f/MLCCre mice was not significantly different than the wild-type mice. Moreover, insulin sensitivity and glucose tolerance were also not altered in the PGC-1α-/-βf/f/MLC-Cre mice. Taken together, we conclude that PGC-1 coactivators are necessary for the oxidative and mitochondrial programs of skeletal muscle but are dispensable for fundamental fiber type determination and insulin sensitivity.

Project description:Skeletal muscle wasting and reduced oxidative capacity coexist in patients with COPD/pulmonary emphysema and are independently associated with higher mortality. Whether reduced respiration contributes to muscle atrophy in that setting remains unknown. We have previously shown that a mouse with genetically induced COPD/pulmonary emphysema recapitulates muscle dysfunction features present in patients’ muscles, including reduced expression and activity of succinate dehydrogenase (SDH), which are partially reversed by genetic gain of SDH function. Previous research suggests that succinate accumulation, a by-product of SDH inhibition, can increase respiratory capacity of skeletal muscle. Here, we generated an inducible, muscle-specific SDH-C knockout mouse which demonstrates lower mitochondrial oxygen consumption and oxidative fibers’ contractility, associated with overall reduced exercise endurance. These changes are partially offset by mitochondrial complex I-dependent respiration, a respiratory pattern replicated in the muscles from the COPD/pulmonary emphysema genetic model. Moreover, while mice skeletal muscle SDH-C knockout causes an early succinate accumulation associated with a downregulated transcriptome, these changes do not correlate with the proteomic landscape; and animals muscle mass, fiber-type composition, and dry body mass constituents remain unaltered. We preset the first conditional, skeletal muscle-specific SDH-C knockout animal and demonstrate that while SDH-C regulates fibers respiration in genetically induced pulmonary emphysema, it does not control muscle mass.

Project description:Skeletal muscle wasting and reduced oxidative capacity coexist in patients with COPD/pulmonary emphysema and are independently associated with higher mortality. Whether reduced respiration contributes to muscle atrophy in that setting remains unknown. We have previously shown that a mouse with genetically induced COPD/pulmonary emphysema recapitulates muscle dysfunction features present in patients’ muscles, including reduced expression and activity of succinate dehydrogenase (SDH), which are partially reversed by genetic gain of SDH function. Previous research suggests that succinate accumulation, a by-product of SDH inhibition, can increase respiratory capacity of skeletal muscle. Here, we generated an inducible, muscle-specific SDH-C knockout mouse which demonstrates lower mitochondrial oxygen consumption and oxidative fibers’ contractility, associated with overall reduced exercise endurance. These changes are partially offset by mitochondrial complex I-dependent respiration, a respiratory pattern replicated in the muscles from the COPD/pulmonary emphysema genetic model. Moreover, while mice skeletal muscle SDH-C knockout causes an early succinate accumulation associated with a downregulated transcriptome, these changes do not correlate with the proteomic landscape; and animals muscle mass, fiber-type composition, and dry body mass constituents remain unaltered. We preset the first conditional, skeletal muscle-specific SDH-C knockout animal and demonstrate that while SDH-C regulates fibers respiration in genetically induced pulmonary emphysema, it does not control muscle mass.