Project description:Adult male and female C56BL6J mice were subjected to 8 weeks of small mouse cage (SMC) intervention to model physical inactivity. Widely-used physical inactivity models such as hindlimb unloading and immobilization do not phenocopy metabolic adaptations that occur with human sedentary behavior, whereas many aspects of metabolic adaptations with SMC appear to reproduce this effect. The RNAseq analyses were performed in muscles from these mice to capture changes in skeletal muscle gene expression landscape.

Project description:Global gene expression of the rat soleus muscle was assessed with microarrays after 12 hrs of physical inactivity and also after 12 hours of physical inactivity immediately followed by 2 hrs treadmill walking and compared to normally caged rats with voluntary standing and intermittent cage movements. Keywords: between group design

Project description:Global gene expression of the rat soleus muscle was assessed with microarrays after 12 hrs of physical inactivity and also after 12 hours of physical inactivity immediately followed by 2 hrs treadmill walking and compared to normally caged rats with voluntary standing and intermittent cage movements. Experiment Overall Design: Rats were either prevented from standing on the their hindlimbs for 12 hrs or were prevented from standing on the their hindlimbs for 12 hrs and then immediately engaged in 2 hours treadmill walking and compared to caged rats with normal standing/ambulatory activity. RNA was extracted from soleus muscles and each array represents the pooling of the RNA from the soleus of 8-10 different rats.

Project description:Colon cancer is the second most cancer type in Europe. Its development is highly influenced by life style factors such as nutrition and physical inactivity. Detailed biological mechanisms are so far unclear. The purpose of this study was to investigate the effects of chronic wheel running on gene expression in rat colon mucosa. Therefore six-week-old male Wistar rats (exercise (EX) group, n=20) completed a stress free voluntary running exercise period of 12 weeks. Sedentary rats served as a control (CO, n=9) group. In the colon mucosa, steady-state mRNA expression levels of approximately 10,000 genes were compared between both groups by micro-array analysis (MWG rat 10k array). 8,846 mRNAs were detected above background level. Chronic exercise led to a decreased expression of 47 genes at a threshold-factor of 2.0. 3 genes were found to be up-regulated in the EX group. The identified genes encode proteins involved in signal transduction (n=11), transport (n=8), immune system (n=7), cytoskeleton (n=6), protein targeting (n=6) and metabolism (n=5). Among the genes regulated by chronic exercise, the betaine-homocysteine methyltransferase 2 (BHMT2) seems to be of particular interest. Physical activity may protect against aberrant methylation by repressing the BHMT2 gene and thus contribute to a decreased risk of developing colon cancer. In summary, our experiment presents the first gene expression pattern in rat colon mucosa following chronic wheel running and therefore represents an important step in understanding the molecular mechanisms responsible for the preventive effect of physical activity on the development of colon cancer. Keywords: voluntary running exercise, animal model

Project description:This study aimed to examine if early life exercise could normalize the reduced heart mass we have previously observed in the adult hearts from growth restricted rats. We investigated the molecular pathways using microarray analysis to explain how endurance exercise in early life might be regulating the sustained increase in heart mass we have observed in these rats in adulthood. At 5 weeks of age, male WKY rats were allocated to one of the following exercise treatments: remained sedentary with post mortem (PM) at 9 or 24 weeks, early exercise training (from 5-9 weeks of age) with PM at 9 or 24 weeks, or later exercise training (from 20-24 weeks of age) with PM at 24 weeks (n=8 males/group). Exercise training involved treadmill running 5 days/ week for 4 weeks. Running duration progressively increased from 20 up to 60 minutes per day, with the treadmill speed set at 15 m/min for the first week and 20 m/min thereafter. At 9 or 24 weeks of age rats were killed with an intraperitoneal injection of Ilium Xylazil-20 (30 mg/kg) and Ketamine (225 mg/kg). The rats in the 9 week old early exercise and 24 week old later exercise groups were killed 72 hours following the last bout of treadmill running. Total RNA was obtained from the whole-hearts for analysis Total RNA obtained from the hearts of WKY rats. Male offspring remained sedentary or underwent treadmill running from 5-9 weeks (early exercise) or 20-24 weeks of age (later exercise).

Project description:This study aimed to examine if early life exercise could normalize the reduced heart mass we have previously observed in the adult hearts from growth restricted rats. We investigated the molecular pathways using microarray analysis to explain how endurance exercise in early life might be regulating the sustained increase in heart mass we have observed in these rats in adulthood. At 5 weeks of age, male WKY rats were allocated to one of the following exercise treatments: remained sedentary with post mortem (PM) at 9 or 24 weeks, early exercise training (from 5-9 weeks of age) with PM at 9 or 24 weeks, or later exercise training (from 20-24 weeks of age) with PM at 24 weeks (n=8 males/group). Exercise training involved treadmill running 5 days/ week for 4 weeks. Running duration progressively increased from 20 up to 60 minutes per day, with the treadmill speed set at 15 m/min for the first week and 20 m/min thereafter. At 9 or 24 weeks of age rats were killed with an intraperitoneal injection of Ilium Xylazil-20 (30 mg/kg) and Ketamine (225 mg/kg). The rats in the 9 week old early exercise and 24 week old later exercise groups were killed 72 hours following the last bout of treadmill running. Total RNA was obtained from the whole-hearts for analysis

Project description:The purpose of this study was to determine whether postdevelopmental myostatin depletion influenced the changes in skeletal muscle gene expression profiles induced by a long-term increase in physical activity. Myostatin levels in muscles of adult male mice with floxed myostatin genes were reduced ~85% by activating Cre recombinase. Control mice with normal myostatin genes had the same Cre-activating treatment. Some of the mice were housed in ordinary cages throughout the study, limiting their physical activity. Other mice were given free access to running wheels for the final 12 weeks of the study. At the end of the study, comprehensive gene expression profiles of triceps brachii muscles were determined by RNA sequencing (RNA-Seq), with muscles from mice selected for similarity of running behavior throughout the period of wheel access. Wheel running increased expression of hundreds of mRNAs encoding proteins involved in oxidative energy metabolism, and this response was not affected by myostatin deficiency. The running-induced increase in the ratio of Myh1 mRNA (which encodes myosin heavy chain type 2x) to Myh4 mRNA (which encodes myosin heavy chain type 2b) also was not affected by myostatin depletion. At every threshold of P (computed by analysis of variance), the number of transcripts with interactions between activity level and myostatin level was fewer than the number expected by chance. These data suggest that myostatin is not required for transcriptional adaptations to moderate-intensity exercise. 12 samples, 6 from sedentary mice and 6 from active (wheel running) mice. 3 control and 3 myostatin-deficient mice within each activity level.

Project description:Atherosclerosis development is largely driven by old age and lifestyle factors, such as diet, physical activity and smoking. Microarray analysis of skeletal muscle gene expression was performed on young (14 weeks) and aged (49-52 weeks) C57BL/6 wild-type (WT) and atherosclerosis-prone ApoE-/- mice, which were subjected to physical endurance exercise on a treadmill for 5 weeks, with or without a high fat diet.

Project description:Physical exercise training is a known protective factor against cardiovascular morbidity and mortality. Nevertheless, the underlying specific molecular mechanisms still remain uncompletely explored. To identify molecular mechanisms by which exercise training induces this favorable phenotype a genomic approach was used in an animal model of mild exercise previously demonstrated by our group to induce cardioprotection. Our data indicate that mild exercise by inducing no or few permanent changes in gene expression profile is able to determine cardioprotection without induction of cardiac hypertrophy. Experiment Overall Design: We investigated the gene expression profile by Affymetrix technology (230 2.0 GeneChip rat genome array) induced by mild exercise training (treadmill running: 25 m/min, 10% incline, 1 h/day, 3 days/week, 10 weeks) on left ventricle (LV) of exercise-trained (n=10) and sedentary control (n=10) rats.

Project description:Inorganic phosphate (Pi) is used extensively as a preservative and a flavor enhancer in the Western diet. Physical inactivity, a common feature of Western societies, increases cardiovascular morbidity and mortality. We explore the relationship between dietary Pi excess and impaired exercise tolerance and physical inactivity. Analysis of the Dallas Heart Study shows association of higher serum Pi with reduced time spent in moderate to vigorous physical activity and increased sedentary time in humans. To test for causality, we investigated the impact of chronic exposure of high dietary Pi on exercise capacity in mice. Consumption of a high Pi diet for 3 months does not change the body weight but reduces maximal oxygen uptake, treadmill duration, and spontaneous locomotor activity, which is accompanied by substantial reduction in fat oxidation and fatty acid (FA) levels and downregulation of genes involved in FA synthesis, release, and oxidation, including Fabp4, Hsl, Fasn, and Ppar in muscle. Similar results are recapitulated in in vitro by incubating C2C12 myotubes with high Pi media. In conclusion, our findings indicate that dietary phosphotoxicity reduces skeletal muscle FA metabolism and impairs exercise capacity independent of obesity, and may represent a novel and modifiable risk factor for cardiovascular disease.