Project description:Acute aerobic exercise has been shown to improve skeletal muscle mitochondrial function and completeness of fatty acid β-oxidation which contribute to improved insulin sensitivity. The effectiveness of acute exercise on improving mitochondrial adaptations, leading to improved insulin sensitivity, in overweight/obese (Ov/Ob) individuals is controversial. This study aimed to determine the effects of acute exercise on epigenetic regulation of genes involved in skeletal muscle mitochondrial adaptations in lean vs Ov/Ob men.

Project description:Acute aerobic exercise has been shown to improve skeletal muscle mitochondrial function and completeness of fatty acid β-oxidation which contribute to improved insulin sensitivity. The effectiveness of acute exercise on improving mitochondrial adaptations, leading to improved insulin sensitivity, in overweight/obese (Ov/Ob) individuals is controversial. This study aimed to determine the effects of acute exercise on epigenetic regulation, specifically nucleosome positioning, of genes involved in skeletal muscle mitochondrial adaptations in lean vs Ov/Ob men.

Project description:Obesity-related insulin resistance (OIR) is one of the main contributors to type 2 diabetes and other metabolic diseases. Protein kinases are implicated in key signaling steps including insulin signaling and glucose metabolism. Molecular mechanisms underlying OIR involving global active kinases remain less understood. Herein, we report findings from an in vivo active kinase profiling study in skeletal muscle from lean control (Lean) and OIR human participants, which identified the 1st active kinome comprised of 54 active protein kinases in human skeletal muscle. The activities of 23 kinases were different in OIR compared to Lean muscle (11 hyper- and 12 hypo-active), while their protein abundance was the same between the two groups. The activities of multiple kinases involved in AMPK and p38 signaling were lower in OIR compared to Lean. On the contrary, multiple kinases in JNK signaling pathway exhibited higher activity in OIR vs. Lean muscle. The kinase-substrate-prediction based on experimental data further confirmed a potential down-regulation of insulin signaling (e.g., inhibited phosphorylation of insulin receptor substrate-1 and AKT1/2). These findings provide a global view of the active kinome in OIR and Lean muscle, pinpoint novel specific impairment in kinase activities in multiple signaling pathways important for skeletal muscle insulin resistance, and provide potential drug targets (i.e., abnormal active kinase) to prevent and/or reverse skeletal muscle insulin resistance in humans.

Project description:It is well established that obese animals and humans show deficiencies in skeletal muscle content and metabolism. However, the mechanisms under how skeletal muscle metabolism affects systemic energy homeostasis is not well-defined. Here, we compared the skeletal muscle transcriptome from obese and lean controls in different species. We found an immune-responsive transcription factor interferon regulatory factor 4 (IRF4) was conserved to be increased in obese subjects from the three species (humans, non-human primates and mice). Thus, we demonstrated that loss of IRF4 specifically in skeletal muscle of mice showed protection against the metabolic effects of high-fat diet, with unexpected increased plasma and muscle branched-chain amino acid (BCAA) levels. Conversely, overexpression of skeletal muscle IRF4 caused obesity and insulin resistance, with decreased BCAA contents. Mechanistically, IRF4 can transcriptionally regulate branched-chain aminotransferase isozyme (BCATm) expression, and that overexpression of BCATm can reverse the effects of IRF4 depletion regarding to metabolic phenotypes. Further, we demonstrated ablation of IRF4 in skeletal muscle increased mitochondrial activity and glycogen synthesis in a BCATm- dependent manner. These studies establish IRF4 as a novel driver of BCAA metabolism via BCATm in skeletal muscle and may interpret the BCAAs paradox in obesity.

Project description:It is well established that obese animals and humans show deficiencies in skeletal muscle content and metabolism. However, the mechanisms under how skeletal muscle metabolism affects systemic energy homeostasis is not well-defined. Here, we compared the skeletal muscle transcriptome from obese and lean controls in different species. We found an immune-responsive transcription factor interferon regulatory factor 4 (IRF4) was conserved to be increased in obese subjects from the three species (humans, non-human primates and mice). Thus, we demonstrated that loss of IRF4 specifically in skeletal muscle of mice showed protection against the metabolic effects of high-fat diet, with unexpected increased plasma and muscle branched-chain amino acid (BCAA) levels. Conversely, overexpression of skeletal muscle IRF4 caused obesity and insulin resistance, with decreased BCAA contents. Mechanistically, IRF4 can transcriptionally regulate branched-chain aminotransferase isozyme (BCATm) expression, and that overexpression of BCATm can reverse the effects of IRF4 depletion regarding to metabolic phenotypes. Further, we demonstrated ablation of IRF4 in skeletal muscle increased mitochondrial activity and glycogen synthesis in a BCATm- dependent manner. These studies establish IRF4 as a novel driver of BCAA metabolism via BCATm in skeletal muscle and may interpret the BCAAs paradox in obesity.

Project description:Skeletal muscle fiber composition and muscle energetics are not static and change in muscle disease. This study was performed to determine if a mitochondrial myopathy is associated with adjustments in skelatal fiber type composition. These effects of drug induced mitochondrial dysfunction on skeletal muscle fiber type composition were analyzed in an animal model.

Project description:Exercise is a behavior modification indispensable for long-term weight loss. Exercise activates the Creb-Regulated Transcriptional Coactivator (Crtc) family of transcriptional coregulators to drive Creb1-mediated anabolic transcriptional programs in skeletal muscle. Here, we show that induced overexpression of a skeletal muscle specific Crtc2 transgene in aged mice leads to greater weight loss during alternate day fasting, and selective loss of fat rather than lean mass. Transcriptional profiling revealed that fasting and weight loss downregulated most of the mitochondrial electron transport genes and other regulators of mitochondrial function that were substantially reversed in the Crtc2 mice, which maintained higher energy expenditure during fasting. The Crtc2 mice displayed greater mitochondrial activity, metabolic flux capacity for both carbohydrates and fats, improved glucose tolerance and insulin sensitivity, and increased oxidative capacity before the fast, suggesting muscle-intrinsic mechanisms in support of improved weight loss. This work reveals that Crtc2/Creb1-mediated signaling coordinates metabolic adaptations in skeletal muscle that explain how Crtc2/Creb contribute to the effects of exercise on metabolism and weight loss.

Project description:We investigated the short and long term effects of electrically induced exercise on mRNA expression of human paralyzed muscle. We developed an exercise dose that activated the muscle for 0.6% of the day. The short term effects were assessed 3 hours after a single dose of exercise, while the long term effects were assessed after training 5 days per week for at least one year (adherence 81%). A single dose of electrical stimulation increased the mRNA expression of transcriptional, translational, and enzyme regulators of metabolism important to shift muscle toward an oxidative phenotype (PGC-1a, NR4A3, IFRD1, ABRA, PDK4). However, chronic training increased the mRNA expression of specific metabolic pathway genes (BRP44, BRP44L, SDHB, ACADVL), mitochondrial fission and fusion genes (MFF, MFN1, MFN2), and slow muscle fiber genes (MYH6, MYH7, MYL3, MYL2).Furthermore, regulating these same pathways may be critical to developing efficient activity protocols to reduce the prevalence of diabetes in people with longstanding paralysis from SCI. We analyzed skeletal muscle using the Affymetrix Human Exon 1.0 ST platform. Array data was processed by Partek Genomic Suites.

Project description:The apolipoprotein E (APOE) gene is the strongest genetic risk modifier for Alzheimer's disease (AD), with the APOE4 allele increasing risk and APOE2 decreasing it compared to the common APOE3 allele. Using single-nuclei RNA sequencing of the temporal cortex from APOE2 carriers, APOE3 homozygotes, and APOE4 carriers, we found that AD-associated transcriptomic changes were highly APOE genotype-dependent. Comparing AD with controls, APOE2 carriers showed upregulated synaptic and myelination-related pathways, preserving synapses and myelination at the protein level. Conversely, these pathways were downregulated in APOE3 homozygotes, resulting in reduced synaptic and myelination proteins. In APOE4 carriers, excitatory neurons displayed reduced synaptic pathways similar to APOE3, but oligodendrocytes showed upregulated myelination pathways like APOE2. However, their synaptic and myelination protein levels remained unchanged or increased. APOE4 carriers also showed increased pro-inflammatory signatures in microglia but reduced responses to amyloid-β pathology. These findings reveal APOE genotype-specific molecular alterations in AD across cell types.

Project description:Skeletal muscle, as a large and insulin sensitive tissue, is an important contributor to metabolic homeostasis and energy expenditure. Obese dogs exhibit skeletal muscle insulin resistance, but the causes of these changes are unclear. Thus, we used canine microarrays to analyze gene expression profiles of skeletal muscle tissue collected from obese dogs, after 24 wk of ad libitum feeding. Skeletal muscle tissue samples were collected from 9 intact female beagles (4 yr-old; 4 control; 5 ad libitum) after 24 wk of ad libitum feeding.