Project description:MicroRNAs (miRNAs) are small, non-coding RNAs that play a critical role in regulating gene expression post-transcriptionally. Skeletal muscle-specific miRNAs, including miR-1, are important for skeletal muscle development and maintenance. In response to mechanical loading, skeletal muscle levels of miR-1 decrease by approximately 50%, suggesting a potential involvement in muscle hypertrophy. In the current investigation, we hypothesized that a reduction of miR-1 levels in response to mechanical loading would be necessary for skeletal muscle growth to occur. By significantly elevating miR-1 levels during the hypertrophic process via lentiviral delivery, we observed a blunted growth response in the plantaris muscle subjected to synergist ablation. A deeper RNA-based integrative analysis (transcriptomics and RNA eCLIP) indicates that miR-1 inhibits the expression of Itm2a and Melusin, two membrane-related proteins. While their exact mechanism in muscle hypertrophy is yet to be identified, our results suggest that miR-1-regulated membrane proteins are important for skeletal muscle hypertrophy.

Project description:Transcriptome analysis of skeletal muscle during hypertrophic growth in aged mice Global gene expression patterns were determined from microarray results on day 1, 3, 5, 7, 10 and 14 during plantaris muscle hypertrophy induced by synergist ablation in old adult mice (25 months).

Project description:The platelet-derived growth-factor receptors alpha and beta (PDGFRα and PDGFRβ) mark fibroblasts and pericytes in skeletal muscle, respectively. While the role that these cells play in muscle growth has been evaluated, it was not known whether the receptors that mark these cells play a role in controlling transcriptional and functional changes during skeletal muscle hypertrophy. To evaluate this, we inhibited PDGFR signaling in mice subjected to a synergist ablation muscle growth procedure, and measured changes 3 and 10 days later. The results indicated that PDGF signaling was required for fiber hypertrophy and ECM production that occur during muscle growth.

Project description:Skeletal muscle specific overexpression of miRNA-1 impairs mechanical overload-induced skeletal muscle hypertrophy

Project description:Divergent skeletal muscle phenotypes result from chronic resistance-type- versus endurance-type contraction, reflecting the principle of training specificity. However, it is unclear whether there is a common set of genetic factors that influence skeletal muscle adaptation to different modes of training. Female rats were obtained from out-bred lines selectively bred from high responders to endurance training (HRT) or low responders to endurance training (LRT; n=6/group; generation 19). Both groups underwent 14 d of synergist ablation to induce functional overload of the plantaris muscle prior to comparison to non-overload controls of the same genotype. RNA sequencing was performed to identify Gene Ontology Biological Processes with differential (LRT vs HRT) gene set enrichment. Running distance, determined well in advance of synergist ablation, increased in response to aerobic training in HRT but not LRT (65 ±26% versus -6 ±18%, respectively, mean ±SD, p<0.0001). The hypertrophy response to functional overload was attenuated in LRT versus HRT (20.1 ±5.6% versus 41.6 ±16.1%, respectively, P = 0.015). There were between-group differences in the magnitude of response of 96 upregulated- and 101 downregulated pathways. A further 27 pathways showed contrasting upregulation or downregulation in LRT versus HRT in response to functional overload. In conclusion, low responders to aerobic endurance training were also low responders for compensatory hypertrophy, and attenuated hypertrophy was associated with differential gene expression. Thus, our findings suggest that genetic factors that underpin aerobic training maladaptation may also dysregulate the transcriptional activity of biological processes that contribute to adaptation to mechanical overload.

Project description:Skeletal muscle specific overexpression of miRNA-1 impairs mechanical overload-induced skeletal muscle hypertrophy [RNA-Seq]

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:Mechanosensing is required for the senses of touch and hearing, and impacts on cellular processes such as cell differentiation, migration, invasion and tissue homeostasis. Mechanical inputs give rise to p38- and JNK-signaling, which mediates adaptive physiological responses in various tissues. In muscle, fiber contraction-induced p38 and JNK signaling ensures adaptation to exercise, muscle repair and hypertrophy. However, the mechanism by which muscle fibers sense mechanical load to activate this signaling, as well as the physiological roles of mechanical stress sensing more broadly, have remained elusive. Here, we show that the upstream MAP3K ZAK is a sensor of cellular compression induced by osmotic shock and cyclic compression in vitro, and muscle contraction in vivo. This function relies on ZAK’s ability to recognize stress fibers in cells and the corresponding Z-discs in muscle fibers, when under tension. Consequently, ZAK-deficient mice present with skeletal muscle defects characterized by fibers with centralized nuclei and progressive adaptation towards a slower myosin profile. Our results highlight how cells in general sense mechanical compressive load, and how mechanical forces generated during muscle contraction are translated into MAP kinase signaling.

Project description:Cachexia is a systemic metabolic syndrome characterized by loss of fat and skeletal muscle mass in chronic wasting diseases such as cancer. The regulation of cellular protein synthesis in response to workload in skeletal muscle is generally blunted in cancer cachexia; however, the precise molecular regulation is largely unknown. In this study, to examine the molecular mechanism of skeletal muscle protein metabolism in cancer cachexia, we analyzed comprehensive gene expression in skeletal muscle using microarrays. CD2F1 mice (male, 7 weeks old) were subcutaneously transplanted (1*10^6 cells per mouse) with a mouse colon cancer-derived cell line (C26) as a model of cancer cachexia. Functional overload of the plantaris muscle by synergist ablation was performed at the 2nd week, and the plantaris muscle was sampled at the 4th week of cancer transplantation. The hypertrophy of skeletal muscle (increased skeletal muscle weight/protein synthesis efficiency and activation of mTOR signaling) associated with compensatory overload was significantly suppressed with the cancer cachexia. Gene expression profiling and pathway analysis by microarray showed that resistance to muscle protein synthesis associated with cancer cachexia was induced by downregulation of insulin-like growth factor-1. These observations show that cancer cachexia induces resistance to muscle protein synthesis, which could be a potential factor inhibiting the adaptation of skeletal muscle growth to physical exercise.