Project description:We sought to determine the global transcriptional response to exercise in the heart in a time-of-day dependent manner. To accomplish this, adult male mice (C57Bl/6, ~12 weeks of age) were habituated to treadmill exercise and exposed to a single bout of low-moderate intensity exercise (60 mintue, 10 m/min, 0% grade) at ZT0 (beginning of rest phase) or ZT12 (beginning of active phase). RNA was isolated from whole hearts harvested immediately after exercise (or from sedentary control mice) for RNA-Seq.

Project description:The circadian clock is a cell-autonomous transcription-translation feedback mechanism that anticipates and adapts physiology and behavior to different phases of the day. A variety of factors including hormones, temperature, food-intake, and exercise can act on tissue-specific peripheral clocks to alter the expression of genes that influence metabolism, all in a time-of-day dependent manner. The aim of this study was to elucidate the effects of exercise timing on adipose tissue metabolism. We performed RNA sequencing on inguinal adipose tissue of mice immediately following maximal exercise or sham treatment at the early rest or early active phase. Only during the early active phase did exercise elicit an immediate increase in serum non-esterified fatty acids. Furthermore, early active phase exercise increased expression of markers of thermogenesis and mitochondrial proliferation in inguinal adipose tissue. In vitro, synchronized 3T3-L1 adipocytes showed a timing-dependent difference in Adrb2 expression, as well as a greater lipolytic activity. Thus, the response of adipose tissue to exercise is time- of-day sensitive and may be partly driven by the circadian clock. To determine the influence of feeding state on the time-of-day response to exercise, we replicated the experiment in 10- hour-fasted early rest phase mice to mimic the early active phase metabolic status. A 10-hour fast led to a similar lipolytic response as observed after active phase exercise, but did not replicate the transcriptomic response, suggesting that the observed changes in gene expression are not driven by feeding status. In conclusion, acute exercise elicits timing-specific effects on adipose tissue to maintain metabolic homeostasis.

Project description:We performed the circadian transcriptome analysis using the skeletal muscle from sedentary and exercised mice either in the early rest phase (ZT3) or in the early active phase (ZT15). By the combination with circadian transcriptomic and metabolomic analysis, we revealed time-of-day-dependent remodeling of circadian muscular metabolic pathways involved in glucose and glycerol metabolism after exercise. We found that only exercise in the early active phase elevates the levels of genes encoding glycolytic enzymes followed by the activation of fatty acid oxidation, branched-chain amino acid catabolism and ketogenesis/ketosis. This study demonstrates that time-of-day is a critical factor to modulate the impact of exercise on metabolic pathways within skeletal muscle.

Project description:Circadian transcriptome in mouse skeletal muscle after exercise in the early rest versus active phase

Project description:The regulation of metabolism in peripheral tissues is mediated by pathways that are under circadian control. a bidirectional relationship is evident between the circadian clock and hypoxia-inducible factor-1 α (HIF1α), which is specific to time-of-day exercise. To elucidate the role of HIF1α in driving the divergences in the systemic and skeletal muscle metabolic responses to exercise, a skeletal muscle-specific HIF1α knockout (KO) mouse model was generated. Metabolic phenotyping alongside global transcriptomic profiling was conducted under basal conditions or in response to an acute exercise bout in HIF1α KO and wild-type (WT) mice at the early rest phase (ZT3) or early active phase (ZT15). Our findings demonstrate that HIF1α is dispensable for the metabolic response to exercise at ZT15, but required for an elevation in glycolytic metabolism in response to exercise at ZT3. Specifically, the loss of HIF1α alters the fate of glucose with a shift towards mannose-6-phosphate production observed at ZT3. In addition, the loss of HIF1α alters the transcriptional profile of skeletal muscle specifically at ZT3 with a shift towards oxidative metabolism. HIF1α contributes to regulating the time-of-day exercise response by driving a shift in substrate preference primarily towards glucose oxidation while sparing fatty acid oxidation. This comprehensive metabolic phenotyping of HIF1α KO mice demonstrates that the contribution of HIF1α to the regulation of time-of-day metabolism is dependent on metabolic status and energetic stressors.

Project description:Gene expression data at rest and immediately post 30 min submaximal exercise in 3 month and 16 month old male rats, some of which were sedentary (SED), had access to a physical activity box twice weekly (PA) and some of which had daily access to a running wheel (EX). We used microarrays to detail global gene expression underlying select health-related phenotypes and identified differentially expressed genes among the three groups. Young (3 month) and old (16 month) male rats were separated into three different groups: Sedentary (SED), twice-weekly physical activity (PA), and regular exercise (EX). Animals were sacrificed either at rest or after 30 min of sub maximal exercise. Then, a portion of cardiac tissue was collected for RNA extraction and hybridization on Affymetrix microarrays.

Project description:The participants performed 8 weeks of superised aerobic endurance exercise. Skeletal muscle biopsise were taken at rest before and after intervention and matched analysis was performed.

Project description:Purpose: The aim of this study is to investigate the translational regulation of skeletal muscle during acute endurance exercise. Methods: We used mRNA-Seq and ribosome profiling to examine transcriptional and translational regulation, respectively. Result: There were clear distinctions between the profiles of transcription and translation even at a basal condition. TOP-motif genes were translationally suppressed immediately after the exercise. Other genes, such as Slc25a25 was significantly translationally up-regulated presumably in a mTOR-independent manner. Conclusion: There were diverse regulation between transcription and translation. Although many focused on overall protein synthesis to understand the effect of exercise, translational regulation of individual genes are required. Transcriptional and translational profiles of mouse gastrocnemius with or without acute endurance exercise were generated using Ion PGM sequencer.

Project description:Profile of small RNA contents of plasma Evs in men and women at rest and after a bout of acute resistance exercise both before and after 12 weeks of chronic resistance exercise training. We profile how acute and chronic weight training imapcts EV small RNA contents and how this differs in men and women.

Project description:The purpose of this experiment was to determine what gene expression changes are induced by acute exercise in humans, and how those changes relate to insulin sensitivity 14 subjects had muscle biopsies at rest and 30 minutes after a single exercise bout for measurement of mRNA changes. Glucose clamps were used to assess insulin sensitivity.