Project description:Radiotherapy (RT) reduces the risk of cancer recurrence and death, while accompanied by multiple side effects including muscle fibrosis and weakness, seriously affects the life quality of patients. However, the underlying mechanism is poorly defined. Here, we identify cancer cells secrete more spermidine synthase (SRM) enzyme through small extracellular vesicles (sEVs) to trigger skeletal muscle weakness upon RT. Mechanistically, RT-triggered arachidonic acid (ArA) accumulation elevates the ISGylation of SRM protein, facilitating SRM packaging into EVs from primary tumor. Circulating SRM results in spermidine accumulation in skeletal muscle and type I collagen fiber biosynthesis in an eIF5A-dependent manner. However, losartan treatment blocks the ISGylation of SRM and its subsequent secretion. Collectively, our findings determine that ArA functions in concert for circulating SRM secretion upon RT, which aggravates skeletal muscle fibrosis through rewiring polyamine metabolism, shedding light on the alleviation of RT-mediated muscle weakness when combined with losartan treatment.

Project description:Radiotherapy (RT) reduces the risk of cancer recurrence and death, while accompanied by multiple side effects including muscle fibrosis and weakness, seriously affects the life quality of patients. However, the underlying mechanism is poorly defined. Here, we identify cancer cells secrete more spermidine synthase (SRM) enzyme through small extracellular vesicles (sEVs) to trigger skeletal muscle weakness upon RT. Mechanistically, RT-triggered arachidonic acid (ArA) accumulation elevates the ISGylation of SRM protein, facilitating SRM packaging into EVs from primary tumor. Circulating SRM results in spermidine accumulation in skeletal muscle and type I collagen fiber biosynthesis in an eIF5A-dependent manner. However, losartan treatment blocks the ISGylation of SRM and its subsequent secretion. Collectively, our findings determine that ArA functions in concert for circulating SRM secretion upon RT, which aggravates skeletal muscle fibrosis through rewiring polyamine metabolism, shedding light on the alleviation of RT-mediated muscle weakness when combined with losartan treatment.

Project description:Radiotherapy (RT) reduces the risk of cancer recurrence and death, while accompanied by multiple side effects including muscle fibrosis and weakness, seriously affects the life quality of patients. However, the underlying mechanism is poorly defined. Here, we identify cancer cells secrete more spermidine synthase (SRM) enzyme through small extracellular vesicles (sEVs) to trigger skeletal muscle weakness upon RT. Mechanistically, RT-triggered arachidonic acid (ArA) accumulation elevates the ISGylation of SRM protein, facilitating SRM packaging into EVs from primary tumor. Circulating SRM results in spermidine accumulation in skeletal muscle and type I collagen fiber biosynthesis in an eIF5A-dependent manner. However, losartan treatment blocks the ISGylation of SRM and its subsequent secretion. Collectively, our findings determine that ArA functions in concert for circulating SRM secretion upon RT, which aggravates skeletal muscle fibrosis through rewiring polyamine metabolism, shedding light on the alleviation of RT-mediated muscle weakness when combined with losartan treatment.

Project description:Radiotherapy (RT) reduces the risk of cancer recurrence and death, while accompanied by multiple side effects including muscle weakness, seriously affects the life quality of patients. However, the underlying mechanism is not well defined. Here, we identify cancer cells secrete more spermidine synthase (SRM) protein through small extracellular vesicles (sEVs) to trigger skeletal muscle weakness upon RT. Mechanistically, RT-triggered arachidonic acid (ArA) accumulation elevates the ISGylation of SRM protein, facilitating SRM package into EVs from primary tumor. Circulating SRM proteins enhance spermidine accumulation in skeletal muscle and type I collagen fibers biosynthesis in an eIF5A-dependent manner. Deposition of randomly aligned collogen fibers induced by SRM+ EVs results in skeletal muscle fibrosis and weakness, as well as bone matrix loss. However, losartan treatment blocks the ISGylation of SRM and its subsequent secretion. Collectively, our findings determine that ArA functions in concert for circulating SRM secretion upon RT, which aggravates skeletal muscle fibrosis through rewiring polyamine metabolism, shedding light on the alleviation of RT-mediated muscle weakness when combined with losartan treatment.

Project description:Cancer is considered as a disease of a specific organ, but its effects are felt throughout the body. The systemic effects of cancer can lead to weakness in muscles and heart, which hastens cancer-associated death. The majority of preclinical studies, including our own, on cancer-induced skeletal muscle defects utilized mouse models and C2C12 myoblast cell line of mouse origin (>7,700 publications). However, a recent study reported distinct metabolic pathways in mouse compared to human. For example, while higher fasting circulating levels of glucose in human is associated with shortened lifespan, it is associated with longer lifespan in mouse. Since the metabolic activity of the skeletal muscle primarily determines circulating glucose levels, skeletal muscle in mouse and human may function differently and not all skeletal muscle defects noted in tumor-bearing mice may not translate into human. Therefore, we developed a robust human model system using human muscle stem cells to understand cancer-induced skeletal muscle defects in human. We found conditioned media from breast cancer cell lines affected cell molecular biomarkers (e.g. PAX7 annd MyOD) and cell surface markers (e.g. CD82, CD54 and CD90) which were associated with dynamic changes of mRNAs, proteins and peptides in human muscle stem cells or human myotubes differentiated from human muscle stem cells. This study will help in cost-effective discovery of drugs that are effective irrespective genetic ancestry and reveal utility of two class of drugs to overcome cancer-induced skeletal muscle defects

Project description:Morphological studies of skeletal muscle tissue have provided detailed insights into the architecture of muscle fibers, the surrounding cells, and the extracellular matrix. However, a spatial proteomics analysis of the skeletal muscle, including the muscle-tendon transition zone, is lacking. Here, we prepared thin cryotome muscle sections along the longitudinal axis of the mouse soleus muscle and measured each muscle slice using short LC-MS gradients. We generated more than 3000 high-resolution longitudinal protein profiles of central to distal skeletal muscle regions and created a molecular network of different skeletal muscle regions that reveals the complex architecture of the muscle-tendon transition zone. Among the proteins that show an increasing profile from muscle to tendon, we find proteins related to neuronal activity, fatty acid biosynthesis, and the renin-angiotensin system (RAS). Blocking the RAS in cultured mouse tenocytes using losartan reduces the synthesis of extracellular matrix proteins, including collagen and fibronectin. Overall, our analysis of thin cryotome sections provides a spatial proteome of skeletal muscle and reveals that the RAS acts as an additional regulator of the matrix within muscle-tendon junctions.

Project description:Cancer is considered as a disease of a specific organ, but its effects are felt throughout the body. The systemic effects of cancer can lead to weakness in muscles and heart, which hastens cancer-associated death. miR-486 is a myogenic microRNA and its reduced expression in skeletal muscle is observed in muscular dystrophy. Muscle-specific transgenic expression of miR-486 using muscle creatine kinase promoter (MCK-miR-486) partially rescues skeletal muscle defects in muscular dystrophy animal models. We had previously demonstrated reduced circulating and skeletal muscle levels of miR-486 in several cancer types and lower miR-486 levels correlated with skeletal muscle defects and functional limitations in mammary tumor models. Therefore, skeletal muscle defects induced by cancer could resemble defects observed in various dystrophies, which could be reversed through skeletal muscle expression of miR-486. We performed functional limitations studies and biochemical analysis of skeletal muscles of MMTV-Neu transgenic mice that mimic HER2+ breast cancer and MMTV-PyMT transgenic mice that mimic luminal subtype B breast cancer and these mice crossed to MCK-miR-486 transgenic mice. miR-486 significantly prevented tumor-induced reduction in muscle contraction force, grip strength, and rotarod performance in MMTV-Neu, but not in MMTV-PyMT mice. In MMTV-Neu model, miR-486 reversed several of the cancer-induced changes in skeletal muscle including loss of p53, phospho-AKT, and phospho-laminin alpha 2 (LAMA2) and gain of phosphorylation of the pre-mRNA processing factor hnRNPA0 and the splicing factor SRSF10. LAMA2 is a part of the dystrophin-associated glycoprotein complex, and its loss-of-function mutation is associated with congenital muscular dystrophy. Thus, similar to muscular dystrophy, miR-486 has the potential to reverse skeletal muscle defects and cancer burden in select cancer types.

Project description:ICU acquired weakness (ICUAW) is a complication of critical illness characterized by structural and functional impairment of skeletal muscle that may persist for years after ICU discharge with many survivors developing protracted courses with few regaining functional independence. Elucidating molecular mechanisms underscoring sustained ICUAW is crucial to understanding outcomes linked to different morbidity trajectories as well as for the development of novel therapies. Quadriceps muscle biopsies and functional measures of muscle strength and mass were obtained at 7 days and 6 months post-ICU discharge from a cohort of ICUAW patients. Unsupervised co-expression network analysis of transcriptomic profiles identified discrete modules of co-expressed genes associated with the degree of muscle weakness and atrophy in early and sustained ICUAW. Modules were enriched for genes involved in skeletal muscle regeneration and extracellular matrix deposition. Collagen deposition in persistent ICUAW was confirmed by histochemical stain. Modules were further validated in an independent cohort of critically ill patients with sepsis-induced multi-organ failure and a porcine model of ICUAW, demonstrating disease-associated conservation across species and peripheral muscle type. Our findings provide a pathomolecular basis for sustained ICUAW, implicating aberrant expression of distinct skeletal muscle structural and regenerative genes in early and persistent ICUAW. Total RNA was extracted from approximately 200mg of quadriceps muscle (vastus lateralis) tissue in patients with Intensive care unit (ICU) acquired weakness (ICUAW) at day 7 post-ICU discharge (D7) and month 6 post-ICU discharge (M6), and from healthy controls (C)

Project description:Persons with Down syndrome (DS) exhibit low muscle strength that significantly impairs their physical functioning. The Ts65Dn mouse model of DS also exhibits muscle weakness in vivo and may serve as a useful model to examine potential factors responsible for DS-associated muscle dysfunction. Therefore, the purpose of this experiment was to directly assess skeletal muscle function in the Ts65Dn mouse and to reveal potential mechanisms of DS-associated muscle weakness. Soleus muscles were harvested from anesthetized male Ts65Dn and wild-type (WT) colony controls. In vitro muscle contractile experiments revealed normal force generation of unfatigued Ts65Dn soleus, but a 12% reduction in force was observed in Ts65Dn muscle during recovery following fatiguing contractions compared to WT muscle (p<0.05). Oxidative stress may contribute to DS-related pathologies, including muscle weakness, which may be the result of overexpression of chromosome 21 genes (e.g., copper-zinc superoxide dismutase (SOD1)). SOD1 expression was 25% higher (p<0.05) in Ts65Dn soleus compared to WT muscle but levels of other antioxidant proteins were unchanged. Lipid peroxidation (4-hydroxynoneal) was unaltered in Ts65Dn muscle although protein carbonyls were 20% greater compared to muscle of WT animals (p<0.05). Cytochrome c oxidase expression was reduced 22% in Ts65Dn muscle, suggesting a limitation in mitochondrial function may contribute to post-fatigue muscle weakness. Microarray analysis of Ts65Dn soleus revealed alteration of numerous cellular pathways including: proteolysis, glucose and fat metabolism, neuromuscular transmission, and ATP biosynthesis. In summary, the Ts65Dn mouse displays evidence of muscle dysfunction, and the potential role of mitochondria and oxidative stress warrants further investigation. We used microarrays to gain insight into potential mechanisms of DS-associated skeletal muscle weakness. Soleus muscles were obtained from four male Ts65Dn (DS) mice and four male colony control mice. Animals were apparently healthy and approximately five months old. The muscles were harvested in the basal state under anesthesia induced by sodium pentobarbital at approximately the same time of the day.

Project description:Dysferlin is expressed in skeletal and cardiac muscle. However, dysferlin deficiency, namely limb girdle muscular dystrophy 2B (LGMD2B) and Myoshi myopathy, results in skeletal muscle weakness and spares the heart. This dichotomy could be caused by differential regulation of protective mechanisms. Therefore, we compared intraindividual mRNA expression profiles between cardiac and skeletal muscle in dysferlin-deficient SJL/J mice and normal C57BL/6 mice. Keywords: parallel sample