Project description:Exercise stimulates systemic and tissue-specific adaptations that protect against lifestyle related diseases including obesity and type 2 diabetes. Exercise places high mechanical and energetic demands on contracting skeletal muscle, which require finely-tuned protein post-translational modifications involving signal transduction (e.g. phosphorylation) to elicit appropriate short- and long-term adaptive responses. To uncover the breadth of protein phosphorylation events underlying the adaptive responses to endurance exercise and skeletal muscle contraction, we performed global, unbiased mass spectrometry-based phosphoproteomic analyses of skeletal muscle from two rodent models, in situ muscle contraction in rats and treadmill-based endurance exercise in mice.

Project description:Muscle satellite cells (MuSCs), skeletal muscle-resident stem cells, are crucial for regeneration of myofibers. Mechanical cues are thought to be important for activation and proliferation of muscle satellite cells, but the molecular entity that senses biophysical forces in MuSCs remains to be elucidated. In this study, we identified PIEZO1, a mechanosensitive ion channel that is activated by membrane tension, as a critical determinant for myofiber regeneration. We investigated gene profiles of Piezo1-deficient MuSCs to understand the role of PIEZO1 during myogenesis. Our results suggest that PIEZO1 governs the cytoskeletal reorganization to regulate cellular events in MuSCs (i.e., activation, cell-division, and proliferation) during skeletal muscle regeneration.

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:Immune cells sense the microenvironment to fine-tune their inflammatory responses. Patients with cryopyrin associated periodic syndrome (CAPS), caused by mutations in the NLRP3 gene, present auto-inflammation and its manifestation is largely dependent on environmental cues. However, the underlying mechanisms are poorly understood. Here, we uncover that KCNN4, a calcium-activated potassium channel, links PIEZO-mediated mechanotransduction to NLRP3 inflammasome activation. Yoda1, a PIEZO1 agonist, lowers the threshold for NLRP3 inflammasome activation. PIEZO-mediated sensing of stiffness and shear stress increases NLRP3-dependent inflammation. Myeloid-specific deletion of PIEZO1/2 protects mice from gouty arthritis. Activation of PIEZO1 triggers calcium influx, which activates KCNN4 to evoke potassium efflux promoting NLRP3 inflammasome activation. Activation of PIEZO signaling is sufficient to activate the inflammasome in cells expressing CAPS-causing NLRP3 mutants via KCNN4. Finally, pharmacologic inhibition of KCNN4 alleviates auto-inflammation in CAPS patient cells and in CAPS-mimicking mice. Thus, PIEZO-dependent mechanical inputs augment inflammation in NLRP3-dependent diseases including CAPS.

Project description:Tendon tissue growth is promoted by mechanical stimulation, but the mechanism is not well understood. Piezo1, a mechanical stress-responsive channel receptor, is expressed in tendon cells, and the fact that tendon tissue growth was accelerated in Piezo1 gain of function mice suggests that Piezo1 plays an important role in tendon tissue growth. RNA-seq of tendon tissues from these mice showed increased expression of tendon-related genes and decreased expression of muscle-related genes, suggesting that Piezo1 may play a role in maintaining and enhancing the properties of tendon cells.

Project description:Some forms of mitochondrial dysfunction induce sterile inflammation through mitochondrial DNA (mtDNA) recognition by intracellular DNA sensors. However, the involvement of mitochondrial dynamics mitigating such processes and their impact on muscle fitness remain unaddressed. Here we report that opposite mitochondrial morphologies induce distinct inflammatory signatures, caused by differential activation of DNA sensors TLR9 or cGAS. In the context of mitochondrial fragmentation, we demonstrate that mitochondria-endosome contacts mediated by the endosomal protein Rab5C are required in TLR9 activation in cells. Skeletal muscle mitochondrial fragmentation promotes TLR9-dependent inflammation, muscle atrophy, reduced physical performance and enhanced IL6 response to exercise, which improved upon chronic anti-inflammatory treatment. Taken together, our data demonstrate that mitochondrial dynamics is key in preventing sterile inflammatory responses, which precede the development of muscle atrophy and impaired physical performance. Thus, we propose the targeting of mitochondrial dynamics as an approach to treating disorders characterized by chronic inflammation and mitochondrial dysfunction.

Project description:Wolff’s law and the Utah Paradigm of skeletal physiology state that bone architecture adapts to mechanical loads. These models predict the existence of a mechanostat that links strain induced by mechanical forces to skeletal remodeling. However, how the mechanostat influences bone remodeling remains elusive. Here, we find that Piezo1 deficiency in osteoblastic cells leads to loss of bone mass and spontaneous fractures with increased bone resorption. Furthermore, Piezo1-deficient mice are resistant to further bone loss and bone resorption induced by hind limb unloading, demonstrating that PIEZO1 can affect osteoblast-osteoclast crosstalk in response to mechanical forces. At the mechanistic level, in response to mechanical loads, PIEZO1 in osteoblastic cells controls the YAP-dependent expression of type II and IX collagens. In turn, these collagen isoforms regulate osteoclast differentiation. Taken together, our data identify PIEZO1 as the major skeletal mechanosensor that tunes bone homeostasis.

Project description:Analysis of the changes in the transcriptome of circulating neutrophils and skeletal muscle from standardized resting conditions (baseline; pre-EXTRI) to 3, 48 and 96 hours after an experimental exercise trial (EXTRI; 1 hour of cycling followed by 1 hours of running) in 8 healthy, endurance-trained, male subjects. It was hypothesized that the time-course dependent transcriptomic changes would reflect the molecular and signalling mechanisms by which neutrophils regulate and counter-regulate inflammation, and by which skeletal muscle responds, regenerates, and phenotypically adapts to intense, prolonged exercise involving muscle damage. Results provide an important insight in the signalling pathways underlying the transcriptional activation and priming of circulatory neutrophils in response to physiological stress, in particular muscle-derived damage-associated molecular patterns. Furthermore, the study provides novel data on the skeletal muscle transcriptome beyond 48 hours after strenuous endurance exercise, and indicates important muscular remodelling processes at 96 hours post-EXTRI. Blood and muscle samples were taken under standardized conditions at baseline (pre-EXTRI), and 3, 48 and 96 hours post-EXTRI. Total mRNA was extracted from isolated neutrophils, and from skeletal muscle tissue.

Project description:Different modes of acute exercise (a single bout) and chronic exercise (12 weeks of training) result in different post-translational (acetyl and phospho) responses in skeletal muscle. We also include global proteomics as well as metabolomics and transcriptomics data indicating that the distinct metabolic responses to each type of exercise corresponds to the PTM responses.

Project description:The ANKRD1 gene is responsive to different forms of mechanical stress, including injury, stretching, resistance exercise, and eccentric contractions. We showed that ankrd1a, zebrafish homologue of mammalian ANKRD1, gets activated in the heart, after cryoinjury of the ventricle and in skeletal muscle after stab wound, suggesting its role in muscle healing processes. To identify targets of ankrd1a involved in skeletal muscle repair we performed RNA-seq of injured adult ankrd1a mutant and wt zebrafish muscle at 5 days post injury. Non-injured skeletal muscle of both genotypes were used as controls. The loss of ankrd1a function affected the expression of genes involved in muscle contraction, muscle cell differentiation, MAPK and integrin-mediated signaling pathways, and cell-substrate adhesion. Our findings offer novel insights into the ankrd1a function and skeletal muscle repair in adult zebrafish.