Project description:Examination of effect of mechanical loading induced by hindlimb suspension, and subsequent reloading, in soleus muscle in 14 day old female pathogen–free Wistar rats. Keywords = skeletal muscle Keywords = atrophy

Project description:Examination of effect of mechanical loading induced by hindlimb suspension, and subsequent reloading, in soleus muscle in 14 day old female pathogen–free Wistar rats. Keywords = skeletal muscle Keywords = atrophy Keywords: other

Project description:To investigate the molecular mechanisms governing the transition of skeletal muscle from atrophy to compensatory regeneration and hypertrophy, we employed a mouse model involving hindlimb unloading and subsequent reloading, conducting a comprehensive analysis of global gene expression using RNA-sequencing (RNA-seq). Gastrocnemius muscle samples were obtained from three groups: control mice, mice subjected to 10 days of hindlimb unloading-induced muscle atrophy, and mice reintroduced to normal cage activity for 1 day following the unloading period (reloading).

Project description:Muscle unloading and reloading

Project description:Analysis of effect of hindlimb suspension and reloading on C57Bl/6 mouse soleus muscle. Experimental groups examined: -Control mice, 14 days -Hindlimb suspension for 7 days -Hindlimb suspension for 7 days, and subsequent reloading for 1 day -Hindlimb suspension for 7 days, and subsequent reloading for 7 days

Project description:Analysis of effect of hindlimb suspension and reloading on C57Bl/6 mouse soleus muscle. Experimental groups examined: -Control mice, 14 days -Hindlimb suspension for 7 days -Hindlimb suspension for 7 days, and subsequent reloading for 1 day -Hindlimb suspension for 7 days, and subsequent reloading for 7 days Keywords: other

Project description:Skeletal muscle possesses the ability to adapt its size in response to milieus, which is called plasticity. Overload like resistance training induces the increment of muscle mass called muscle hypertrophy. Muscle stem cells (also known as muscle stem cells) function to supply new nuclei for myofiber during the overload in muscle. Using compensatory hypertrophy in plantaris muscles, we isolated MuSCs from plantaris muscles 4 days after surgery. Control MuSCs were also prepared from sham plantaris muscles.

Project description:The purpose of this study was to evaluate the effect of fish oil-derived n-3 PUFA therapy, which had statistically and clinically significant beneficial effects on muscle mass and strength, on skeletal muscle gene expression profile. We selected 10 subjects with the largest hypertrophy response (change in thigh muscle volume) from the treatment group.

Project description:Transforming growth factor-β (TGF-β) signaling is associated with progressive skeletal muscle wasting and fibrosis, while double knockout of TGF-β type I receptors Acvr1b and Tgfbr1 results in hypertrophy. Gaining insights in how myofibre-specific knockout of these receptors affects muscle transcriptome, strength and mitochondrial activity could aid in the development of therapeutic interventions to improve muscle function. Here, we show that 3 months of myofibre-specific knockout of both receptors (dKO) in mice induced a 1.6-fold increase in gastrocnemius medialis mass and a 1.3-fold increase in maximal force. Soleus muscle mass and maximal force both increased 1.2-fold in dKO mice. Muscle hypertrophy in dKO mice was accompanied by a proportional increase in succinate dehydrogenase enzyme activity. Single receptor knockout caused minor phenotypical alterations. Transcriptome analyses revealed that gastrocnemius medialis had 1811 and soleus had 295 differentially expressed genes, mainly related to muscle contraction, hypertrophy, filament organization and oxidative metabolism. Hgf and Sln genes were strongly upregulated in both muscles of dKO mice, while Sntb1 was downregulated. This in combination of transcriptional changes are associated with muscle hypertrophy and increased mitochondrial biosynthesis. Our study highlights that myofibre-specific interference with both TGF-β type I receptors concurrently stimulates myofibre hypertrophy and mitochondrial activity.

Project description:Skeletal muscle mass is an important determinant of whole-body glucose disposal. We here show that mice (M-PDK1KO mice) with skeletal muscle–specific deficiency of 3'-phosphoinositide–dependent kinase 1 (PDK1), a key component of the phosphatidylinositol 3-kinase (PI3K) signaling pathway, manifest a reduced skeletal muscle mass under the static condition as well as impairment of exercise load–induced muscle hypertrophy. Whereas exercise load-induced changes in gene expression were not affected, the phosphorylation of ribosomal protein S6 kinase (S6K) and S6 induced by exercise load was attenuated in skeletal muscle of M-PDK1KO mice, suggesting that PDK1 regulates muscle hypertrophy not through changes in gene expression but through stimulation of protein synthesis via the S6K-S6 axis.