Project description:Hypoxic conditions and maximal exercise provide related but distinct energetic stresses for muscle tissue and induce different adaptations in skeletal muscle in mammals. High swim performance fish, including Danio Rerio (Zebrafish), are well-able to tolerate both hypoxia and fast swimming. Expression profiling was performed using microarrays to compare and contrast the adaptations to sustained hypoxia and repeated near maximal exercise in skeletal muscle of adult wild-type Zebrafish.
Project description:Unconditioned thoroughbred geldings were exercised to maximal heart rate or fatigue on an equine high-speed treadmill. Skeletal muscle biopsies were taken from the middle gluteal muscle before, immediately after and four hours after exercise. Three-condition experiment, Pre exercise (T0), Immediately post exercise (T1), 4 hours post exercise (T2). Hybridisations: T0 vs T1, T0 vs T2 Biological replicates: 8 Technical replication Dye swap
Project description:Unconditioned thoroughbred geldings were exercised to maximal heart rate or fatigue on an equine high-speed treadmill. Skeletal muscle biopsies were taken from the middle gluteal muscle before, immediately after and four hours after exercise.
Project description:Physical inactivity and over-nutrition are key risk factors for metabolic diseases, with impaired skeletal muscle gene transcription and metabolic function proposed as key etiological factors. Here, we have used RNA-seq to assessed the skeletal muscle transcriptome from mice fed a control or high fat diet (HFD), both pre- and 3h post-exercise. HFD up-regulated genes involved in lipid catabolism in skeletal muscle (quadriceps), while decreasing 241 exercise-responsive genes related to skeletal muscle plasticity. Collectively, this experimental approach provides a suitable resource to study transcriptional and metabolic networks in skeletal muscle in the context of health and disease.
Project description:We examined global mRNA expression using cDNA microarrays in skeletal muscle of humans before, and 3h and 48h after 300 maximal eccentric contractions. Keywords: Time course Healthy, non-trained university-aged subjects performed 300 single leg maximal eccentric contractions. Skeletal muscle biopsies were taken from the vastus lateralis before, 3h and 48h after the exercise bout. Total RNA was extracted, amplified, reverse transcribed, and cDNA was analyzed on a custom made cDNA microarray. Four subjects were analyzed, and samples were not pooled between subjects (i.e. individual microarrays were used for baseline vs. 3H and baseline vs. 48h for EACH subject; repeated measures design).
Project description:Mechanistic insights into the molecular events by which exercise enhances the skeletal muscle phenotype are lacking, particularly in the context of type 2 diabetes. Here we unravel a fundamental role for exercise-responsive cytokines (exerkines) on skeletal muscle development and growth in individuals with normal glucose tolerance or type 2 diabetes. Acute exercise triggered an inflammatory response in skeletal muscle, concomitant with an infiltration of immune cells. These exercise effects were potentiated in type 2 diabetes. In response to contraction or hypoxia, cytokines were mainly produced by endothelial cells and macrophages. The chemokine CXCL12 was induced by hypoxia in endothelial cells, as well as by conditioned medium from contracted myotubes in macrophages. We found that CXCL12 was associated with skeletal muscle remodeling after exercise and differentiation of cultured muscle. Collectively, acute aerobic exercise mounts a non-canonical inflammatory response, with an atypical production of exerkines, which is potentiated in type 2 diabetes.
Project description:Mechanisms underlying exercise induced insulin sensitization are of interest as exercise is a clinically critical option as a lifestyle intervention for diabetic patients. Some of microRNAs (miRNAs), which can be secreted from skeletal muscle after exercise, regulate insulin sensitivity and are used for diagnostic marker for diabetic patients. MiR-204 is well-known for its involvement in development, cancer, and metabolism. However, it is still unknown whether miR-204 associates with exerciseinduced glycemic control. In preliminary data, we found that endurance exercise of mice increases miR-204 expression levels in skeletal muscle. In chronic exercise mice model, miR-204 expression levels were increased with glycolytic enzymes in skeletal muscle. When hypoxia induced hypoxia inducible factor 1 alpha (HIF1α), miR-204 expression levels were increased. HIF1α overexpression also increased miR-204 expression levels. To corroborate the causality between miR-204 and glycolysis, miR-204 mimic was introduced to myoblast cell line, C2C12 myoblast cell line. After exposure to miR-204 mimic, C2C12 cells could increase the glycolysis rate measured by extracellular acidification rate. miR-204 mimics also increased mRNA expression levels of glycolytic enzymes. In vivo intravenous miR-204 administration to mice also increased the glucose clearance rate after refeeding of mice. MiR-204 increased blood glucose surge on earlier point of refeeding but promoted the blood glucose lowering on later point of refeeding. Skeletal muscle glycolytic enzymes were increased in mRNA expression levels by miR-204 injection. This finding suggests the novel physiological role of miR-204 in skeletal muscle glycolysis where insulin action is limited.
Project description:The few investigations on exercise-induced global gene expression responses in human skeletal muscle haves typically focused at one specific mode of exercise and few such studies have implemented control measures. However, interpretation on distinct phenotype regulation necessitate comparison between essentially different modes of exercise and the ability to identify true exercise effects, necessitate implementation of independent non-exercise control subjects. Furthermore, muscle transkriptometranscriptome data made available through previous exercise studies can be difficult to extract and interpret by individuals that are inexperienced with bioinformatic procedures. In a comparative study, we; (1) investigated the human skeletal muscle transcriptome response to differentiated exercise and non-exercise control intervention, and; (2) aimed to develop a straightforward search tool to allow for easy extraction and interpretation of our data. We provide a simple spreadsheet containing transcriptome data allowing other investigators to see how mRNA of their interest behave in skeletal muscle following exercise, both endurance, strength and non-exercise. Our approach, allow investigators easy access to information on genuine transcriptome effects of differentiated exercise, to better aid hyporthesis-driven question in this particular field of research.
Project description:The few investigations on exercise-induced global gene expression responses in human skeletal muscle haves typically focused at one specific mode of exercise and few such studies have implemented control measures. However, interpretation on distinct phenotype regulation necessitate comparison between essentially different modes of exercise and the ability to identify true exercise effects, necessitate implementation of independent non-exercise control subjects. Furthermore, muscle transkriptometranscriptome data made available through previous exercise studies can be difficult to extract and interpret by individuals that are inexperienced with bioinformatic procedures. In a comparative study, we; (1) investigated the human skeletal muscle transcriptome response to differentiated exercise and non-exercise control intervention, and; (2) aimed to develop a straightforward search tool to allow for easy extraction and interpretation of our data. We provide a simple spreadsheet containing transcriptome data allowing other investigators to see how mRNA of their interest behave in skeletal muscle following exercise, both endurance, strength and non-exercise. Our approach, allow investigators easy access to information on genuine transcriptome effects of differentiated exercise, to better aid hyporthesis-driven question in this particular field of research. 18 subjects were divided into 3 groups, performing 12 weeks of Endurance or Strength training or no training. Biopsies for microarray were take before (Pre) and 2½ and 5 hours after the last training session. Isolated RNA from these biopsies were then measured with the Affymetrix Human Gene 1.0 ST arrays.