Regenerating Muscle Fibers Research Articles

Increased muscle satellite cell content and preserved telomere length in response to combined exercise training in patients with FSHD.

Facioscapulohumeral muscular dystrophy (FSHD) is an inherited muscle disease characterized by weakness and muscle wasting. In the absence of available treatments, exercise training has emerged as a potential strategy to attenuate muscle tissue deterioration. However, little is known about the impact of chronic exercise on degenerative events and regenerative capacity in FSHD muscle. Muscle biopsies were obtained from 16 FSHD patients before and after a 24week training program combining aerobic-, strength- and high-intensity exercise (Control; n = 8, Training; n = 8). Histochemical and immunohistochemical approaches were applied to assess histopathological signs, markers of regeneration, inflammatory infiltrates and satellite cell content. Muscle telomere length was measured as an indicator of the remaining regenerative capacity. The proportion of muscle fibres expressing developmental myosins and centralized myonuclei was not exacerbated after the intervention. Similarly, no alterations were observed in the number of inflammatory infiltrates (CD68+ cells). Alongside muscle hypertrophy in slow (P=0.022) and fast fibres (P=0.022 and P=0.008), satellite cell content increased specifically in fast fibres (+75 %, P=0.015), indicating a functional satellite cell pool in FSHD muscle. Importantly, exercise training was not associated with a shortening of muscle telomere length, suggesting that muscle cell turnover was not accelerated despite an expansion of the satellite cell pool. Our findings suggest that combined exercise training elicits beneficial muscular adaptations without impairing important indicators of skeletal muscle regenerative capacity in patients with FSHD. KEY POINTS: A 24week combined exercise training program is a safe and well-tolerated strategy to attenuate skeletal muscle deterioration in facioscapulohumeral muscular dystrophy (FSHD) patients. Markers of histopathology, muscle fibre regeneration and inflammatory infiltrates were not exacerbated following exercise training in FSHD muscle. Here, we show novel data that exercise training in FSHD patients induced muscle fibre hypertrophy and triggered an expansion of the satellite cell pool specifically in fast fibres. Exercise training in these patients is not associated with a shortening of muscle telomere length thereby indicating a preserved capacity for muscle regeneration.

Development of an in vitro model to study muscle maladaptation to overtraining

Introduction Physical training stimulates skeletal muscle mitochondrial biogenesis and protein synthesis, inducing beneficial adaptations and promoting performance. However, in some cases when the training load is higher than required, the outcome may lead to non-functional overreaching – a state in which performance may be transiently reduced. This condition is relatively common especially among endurance athletes, and if protracted would result in the development of the overtraining syndrome (OTS), whose impact on skeletal muscle metabolism and function is still unknown. Muscle soreness, increased inflammation and reduced muscle mass are often reported. It has been reported that regeneration of skeletal muscle fibres is impaired, probably through a change in energy metabolism (Grobler et al., 2004). For instance, altered mitochondrial structure and function have been suggested (Grobler et al., 2004). The aim of the present project is to determine the molecular mechanisms underlying skeletal muscle maladaptation’s in response to simulated exercise in vitro. Methods Using a model developed in our laboratory (Zanou et al., 2021), we electrically stimulated C2C12 myotubes (a mouse skeletal muscle cell line) to simulate endurance exercise (Zanou et al., 2021). For simulated training (s-T) the stimulation was applied once daily, for three consecutive days. For simulated overtraining (s-OT), the stimulation was applied three times per day for three consecutive days. Mitochondrial biogenesis biomarkers have been measured, alongside proteomics analysis and mitochondrial respiration. Results In the in vitro s-T model, we observed the expected beneficial adaptations to training, which include myotube hypertrophy, increased fast and slow-twitch myosin heavy chain protein content, and increased mitochondrial respiration. Our proteomics data highlighted many positive adaptations, including upregulation of the muscle contractile and mitochondrial proteins. Immunofluorescence staining of F-actin and of the mitochondrial outer membrane protein Tom20, clearly showed robust F-actin structure and regular mitochondrial distribution in response to s-T. Interestingly, s-OT model presented myotube atrophy, and a decrease in fast and slow-twitch myosin heavy chain protein content. Mitochondrial respiration was increased in s-T and showed a clear trend versus reduction in s-OT. Our proteomics data revealed many downregulated proteins pathways in s-OT including muscle contractile and mitochondrial pathways. Immunofluorescence staining also revealed disrupted F-actin structure and aberrant mitochondrial aggregation in response to s-OT. Conclusions s-T recapitulates training positive adaptations, whereas s-OT recapitulates many of the muscle maladaptation observed in overtraining. Our next studies in human OTS muscle will validate key findings from our in vitro s-OT model and guide our mechanistic investigations into the molecular mechanisms of OTS.

The effect of human umbilical cord-derived mesenchymal stem cell transplantation on the reparative properties of muscle-aponeurotic defect reconstruction in the anterior abdominal wall of rats

Postoperative ventral hernias represent a significant challenge in modern surgery, arising as complications following abdominal operations due to weakness or defects in the musculoaponeurotic structure of the anterior abdominal wall. Mesenchymal stem cells (MSCs) possess high reparative potential due to their paracrine ability to stimulate the regeneration of damaged recipient tissues. Objective. To investigate the effect of intraperitoneal transplantation of human umbilical cord-derived MSCs on the regeneration of muscle fibers in the area of musculoaponeurotic defect repair in the anterior abdominal wall of rats. Materials and Methods. A surgical model of a musculoaponeurotic defect (2 cm in diameter) in the anterior abdominal wall was created in 72 white rats. Animals were divided into four groups based on the method of defect correction: 1) repair with autologous tissues; 2) repair with autologous tissues combined with MSC injection; 3) repair using a polypropylene mesh; 4) repair using a polypropylene mesh combined with MSC injection. Human umbilical cord-derived MSCs were isolated using enzymatic methods, validated by flow cytometry for surface marker expression, and administered intraperitoneally at a dose of 1 million cells per kilogram of body weight. On the 10th and 30th days, histological analysis of tissue samples from the repair site was conducted, assessing the presence of granulation tissue, collagen fibers, newly formed connective tissue, and cellular infiltration. Morphometric comparisons included the relative areas of granulation and fibrous reticular tissue, microcirculatory vessels, and counts of neutrophilic leukocytes, lymphohistiocytic elements, and fibroblasts per square millimeter of section. Results. In Group 1, the repair area demonstrated loose connective tissue rich in fibroblasts and histiocytes. In Group 2, a significantly reduced cellular reaction was observed, along with the formation of denser connective tissue bundles; transverse striation of muscle fibers was more clearly visualized at the sites of damage. On day 10, the granulation tissue area was 34.6% smaller, and the microcirculatory vessel area was 15.9% smaller compared to Group 1, and 28.1% and 57.2% smaller, respectively, compared to Group 3. In Group 3, granulation tissue formed at sites of necrosis and muscle fiber destruction. The best results were observed with the combination of polypropylene mesh and MSCs, where complete resolution of the inflammatory response and scar tissue formation was recorded. In Group 4, on day 10, the granulation tissue area was 2.5 times smaller than in Group 1 and 1.3 times smaller than in Group 2. The relative area of microcirculatory vessels was 1.8 times smaller than in Group 1 and 1.3 times smaller than in Group 2, whereas the fibrous reticular tissue area was 3.2 and 1.2 times larger, respectively. By day 30, granulation tissue, microcirculatory vessels, and leukocytes were no longer detected. The fibrous reticular tissue area was the largest among all groups at this time point. Conclusion. Intraperitoneal transplantation of human umbilical cord-derived MSCs in conjunction with polypropylene mesh repair of musculoaponeurotic defects in the anterior abdominal wall of rats improves regeneration at the defect site and promotes faster healing.

Extracellular matrix-mimicking cryogels composed of methacrylated fucoidan enhance vascularized skeletal muscle regeneration following volumetric muscle loss

Volumetric muscle loss (VML) significantly impairs the inherent regenerative ability of skeletal muscle and results in chronic functional impairment. Polysaccharides in the muscle extracellular matrix are crucial for regulating cell proliferation and differentiation. Recent studies indicate that fucoidan has beneficial effects on musculoskeletal conditions. However, the impact of fucoidan on skeletal muscle regeneration remains poorly understood. In this study, methacrylated fucoidan (FuMA) was synthesized through chemical grafting of the methacryloyl group onto fucoidan. In vitro experiments demonstrated that treatment with FuMA significantly up-regulated the expression of myogenic markers and promoted the formation of myotubes in C2C12 myoblast cells. Importantly, FuMA treatment led to a significant enhancement in mitochondrial energy metabolism of myoblasts via activation of the NRF2 antioxidant signaling pathway. To further investigate the regenerative properties in repairing skeletal muscle defects, we fabricated a dual crosslinked cryogel consisting of FuMA and methacrylated gelatin (GelMA) with a porous and interconnected structure. In a rat tibialis anterior muscle VML model, implantation of the FuMA/GelMA cryogel effectively promoted the regeneration of muscle fibers, reduced collagen deposition, and facilitated the formation of new blood vessels. Hence, polysaccharide-based cryogels represent a promising implantable biomimetic scaffold for facilitating skeletal muscle regeneration following severe injuries.

Effect of Porphyromonas gingivalis Infection on Healing of Skeletal Muscle Injury: An In Vivo Study.

Background/Objectives:Porphyromonas gingivalis infection has been associated with various systemic diseases and may cause delayed healing of muscle injury. However, the relationship between muscle injury healing and P. gingivalis infection remains unclear. Our hypothesis was that P. gingivalis infection delays the healing of muscle injuries. Methods: Fifty-six 8-week-old male Wistar rats were randomly divided into two groups: sonicated P. gingivalis was intraperitoneally administered in one group (PG group), whereas saline was administered in the other group (CO group). Skeletal muscle injury was induced via cardiotoxin injections in all animals. The cross-sectional area of regenerating muscle cells was evaluated by haematoxylin-eosin staining, and the degree of muscle fibrosis was evaluated by Masson's trichrome staining. The expression of paired box protein (Pax7) and myoblast determination protein (MyoD) and the identified stages of myocyte regeneration were analysed by immunohistochemical staining. Motion analysis was performed during walking. Results: The cross-sectional area of muscle cells was significantly smaller in the PG group on days 7 and 14 post-injury than in the CO group. The Pax7+/MyoD- ratio was significantly lower in the PG group on day 1 post-injury than in the CO group. Motion analysis of treadmill walking showed that the PG group had a lower minimum calcaneal height on days 3 and 7 post-injury than the CO group. Conclusions: This study suggests that administration of sonicated P. gingivalis in rats can delay the healing process of muscle injury. Further research is needed to understand this mechanism of delay of P. gingivalis.

Inhibition of CILP2 Improves Glucose Metabolism and Mitochondrial Dysfunction in Sarcopenia via the Wnt Signalling Pathway.

Skeletal muscle is the primary organ involved in insulin-mediated glucose metabolism. Elevated levels of CILP2 are a significant indicator of impaired glucose tolerance and are predominantly expressed in skeletal muscle. It remains unclear whether CILP2 contributes to age-related muscle atrophy through regulating the glucose homeostasis and insulin sensitivity. Initially, the expression levels of CILP2 were assessed in elderly mice and patients with sarcopenia. Lentiviral vectors were used to induce either silencing or overexpression of CILP2 in C2C12 myoblast cells. The effects of CILP2 on proliferation, myogenic differentiation, insulin sensitivity and glucose uptake were evaluated using immunofluorescence, western blotting, real-time quantitative polymerase chain reaction, RNA sequencing, glucose uptake experiments, dual-luciferase reporter assays and co-immunoprecipitation (CO-IP). An adeno-associated virus-9 containing a muscle-specific promoter was injected into SAMP8 senile mice to observe the efficacy of CILP2 knockout. We found that there was more CLIP2 expressed in the skeletal muscle of ageing mice (+1.1-fold, p < 0.01) and in patients with sarcopenia (+2.5-fold, p < 0.01) compared to the control group. Following the overexpression of CILP2, Ki67 (-65%, p < 0.01), PCNA (-32%, p < 0.05), MyoD1 (-89%, p < 0.001), MyoG (-31%, p < 0.05) and MyHC (-85%, p < 0.001), which indicate proliferation and differentiation potential, were significantly reduced. In contrast, MuRF-1 (+59%, p < 0.05), atrogin-1 (+43%, p < 0.05) and myostatin (+31%, p < 0.05), the markers of muscular atrophy, were significantly increased. Overexpression of CILP2 decreased insulin sensitivity, glucose uptake (-18%, p < 0.001), GLUT4 translocation to the membrane and the maximum respiratory capacity of mitochondria. Canonical Wnt signalling was identified through RNA sequencing as a potential pathway for CILP2 regulation in C2C12, and Wnt3a was confirmed as an interacting protein of CILP2 in the CO-IP assay. The addition of recombinant Wnt3a protein reversed the inhibitory effects on myogenesis and glucose metabolism caused by CILP2 overexpression. Conversely, CILP2 knockdown promoted myogenesis and glucose metabolism. CILP2 knockdown improved muscle atrophy in mice, characterized by significant increases in time to exhaustion (+42%, p < 0.001), grip strength (+19%, p < 0.01), muscle mass (+15%, p < 0.001) and mean muscle cross-sectional area (+37%, p < 0.01). CILP2 knockdown enhanced glycogen synthesis (+83%, p < 0.001) and the regeneration of oxidative and glycolytic muscle fibres in SAMP8 ageing mice via the Wnt/β-catenin signalling pathway. Our results indicate that CILP2 interacts with Wnt3a to suppress the Wnt/β-catenin signalling pathway and its downstream cascade, leading to impaired insulin sensitivity and glucose metabolism in skeletal muscle. Targeting CILP2 inhibition could offer potential therapeutic benefits for sarcopenia.

Distinct muscle regenerative capacity of human induced pluripotent stem cell-derived mesenchymal stromal cells in Ullrich congenital muscular dystrophy model mice

BackgroundUllrich congenital muscular dystrophy (UCMD) is caused by a deficiency in type 6 collagen (COL6) due to mutations in COL6A1, COL6A2, or COL6A3. COL6 deficiency alters the extracellular matrix structure and biomechanical properties, leading to mitochondrial defects and impaired muscle regeneration. Therefore, mesenchymal stromal cells (MSCs) that secrete COL6 have attracted attention as potential therapeutic targets. Various tissue-derived MSCs exert therapeutic effects in various diseases. However, no reports have compared the effects of MSCs of different origins on UCMD pathology.MethodsTo evaluate which MSC population has the highest therapeutic efficacy for UCMD, in vivo (transplantation of MSCs to Col6a1-KO/NSG mice) and in vitro experiments (muscle stem cell [MuSCs] co-culture with MSCs) were conducted using adipose tissue-derived MSCs, bone marrow-derived MSCs, and xeno-free-induced iPSC-derived MSCs (XF-iMSCs).ResultsIn transplantation experiments on Col6a1-KO/NSG mice, the group transplanted with XF-iMSCs showed significantly enhanced muscle fiber regeneration compared to the other groups 1 week after transplantation. At 12 weeks after transplantation, only the XF-iMSCs transplantation group showed a significantly larger muscle fiber diameter than the other groups without inducing fibrosis, which was observed in the other transplantation groups. Similarly, in co-culture experiments, XF-iMSCs were found to more effectively promote the fusion and differentiation of MuSCs derived from Col6a1-KO/NSG mice than the other primary MSCs investigated in this study. Additionally, in vitro knockdown and supplementation experiments suggested that the IGF2 secreted by XF-iMSCs promoted MuSC differentiation.ConclusionXF-iMSCs are promising candidates for promoting muscle regeneration while avoiding fibrosis, offering a safer and more effective therapeutic approach for UCMD than other potential therapies.

Exogenous hydrogen sulfide enhances myogenic differentiation of C2C12 myoblasts under high palmitate stress

Skeletal muscle atrophy was one of main complications of type 2 diabetes mellitus. Hydrogen sulfide (H2S) is involved in various physiological functions, such as anti-hypertension and anti-oxidant. Skeletal muscle atrophy caused by type 2 diabetes could lead to the regeneration of muscle fibers. Wnt signaling pathway plays a crucial important role in this process. H2S maybe regulate the Wnt signaling pathway to alleviate skeletal muscle atrophy, however, this role has not been clarified. The aim of this study is to investigate the potential regulatory role of H2S in the Wnt signaling pathway. C2C12 myoblasts treated with 500 μmol palmitate as an in vitro model. Western blot was used to detect the levels of CSE, PKM1, β-catenin, MuRF1, MYOG, MYF6 and MYOD1. In addition, MuRF1 was mutated at Cys44 and MuRF1 S-sulfhydration was detected by biotin switch assay. The interaction between PKM1 and MuRF1 was assessed via Co-immunoprecipitation. Differentiation of C2C12 myoblasts was evaluated using LAMININ staining. These data showed the levels of CSE, β-catenin, PKM1, MYOG, MYF6 and MYOD1 were decreased in pal group, compared with control and pal + NaHS groups. MuRF1 Cys44 mutants increased the protein levels of β-catenin, MYOG, MYF6 and MYOD1 in pal group. Our results suggest that H2S regulates the S-sulfhydration levels of MuRF1 at Cys44, influencing the ubiquitination levels of PKM1 and ultimately promoting myoblast differentiation.

LRRK2G2019S Gene Mutation Causes Skeletal Muscle Impairment in Animal Model of Parkinson's Disease.

While the gradually aggravated motor and non-motor disorders of Parkinson's disease (PD) lead to progressive disability and frequent falling, skeletal muscle impairment may contribute to this condition. The leucine-rich repeat kinase2 (LRRK2) is a common disease-causing gene in PD. Little is known about its role in skeletal muscle impairment and its underlying mechanisms. To investigate whether the mutation in LRRK2 causes skeletal muscle impairment, we used 3-month-old (3mo) and 14-month-old (14mo) LRRK2G2019S transgenic (TG) mice as a model of PD, compared with the age-matched littermate wild-type (WT) controls. We measured the muscle mass and strength, ultrastructure, inflammatory infiltration, mitochondrial morphology and dynamics dysfunction through behavioural analysis, electromyography (EMG), immunostaining, transmission electron microscopy (TEM) and other molecular biology techniques. The 3mo-TG mice display mild skeletal muscle impairment with spontaneous potentials in EMG (increased by 130%, p < 0.05), myofibre necrosis(p < 0.05) and myosin heavy chain-II changes (reduced by 19%, p < 0.01). The inflammatory cells and macrophage infiltration are significantly increased (CD8a+ and CD68+ cells up 1060% and 579%, respectively, both p < 0.0001) compared with the WT mice. All of the above pathogenic processes are aggravated by aging. The 14mo-TG mice EMG examinations show a reduced duration (by 31%, p < 0.01) and increased polyphasic waves of motor unit action potentials (by 28%, p < 0.05). The 14mo-TG mice present motor behavioural deficits (p < 0.05), muscle strength and mass reduction by 37% and 8% (p < 0.05 and p < 0.01, respectively). A remarkable increase in inflammatory infiltration is accompanied by pro-inflammatory cytokines in the skeletal muscles. TEM analysis shows muscle fibre regeneration with the reduced length of sarcomeres (by 6%;p < 0.05). The muscle regeneration is activated as Pax7+ cells increased by 106% (p < 0.0001), andmyoblast determination protein elevated by 71% (p < 0.01). We also document the morphological changes and dynamics dysfunction of mitochondria with the increase of mitofusin1 by 43% (p < 0.05)and voltage-dependent anion channel 1 by 115% (p < 0.001) in the skeletal muscles of 14mo-TG mice. Taken together, these findings may provide new insights into the clinical and pathogenic involvement of LRRK2G2019 mutation in muscles, suggesting that the diseases may affect not only midbrain dopaminergic neurons, but also other tissues, and it may help overall clinical management of this devastating disease.

Freeze-dried porous collagen scaffolds for the repair of volumetric muscle loss injuries.

Volumetric muscle loss (VML) injuries are characterized by the traumatic loss of skeletal muscle resulting in permanent damage to both tissue architecture and electrical excitability. To address this challenge, we previously developed a 3D aligned collagen-glycosaminoglycan (CG) scaffold platform that supported in vitro myotube alignment and maturation. In this work, we assessed the ability of CG scaffolds to facilitate functional muscle recovery in a rat tibialis anterior (TA) model of VML. Functional muscle recovery was assessed following implantation of either non-conductive CG or electrically conductive CG-polypyrrole (PPy) scaffolds at 4, 8, and 12 weeks post-injury by in vivo electrical stimulation of the peroneal nerve. After 12 weeks, scaffold-treated muscles produced maximum isometric torque that was significantly greater than non-treated tissues. Histological analysis further supported these reparative outcomes with evidence of regenerating muscle fibers at the material-tissue interface in scaffold-treated tissues that was not observed in non-repaired muscles. Scaffold-treated muscles possessed higher numbers of M1 and M2 macrophages at the injury while conductive CG-PPy scaffold-treated muscles showed significantly higher levels of neovascularization as indicated by the presence of pericytes and endothelial cells, suggesting a persistent wound repair response not observed in non-treated tissues. Finally, only tissues treated with non-conductive CG scaffolds displayed neurofilament staining similar to native muscle, further corroborating isometric contraction data. Together, these findings show that CG scaffolds can facilitate improved skeletal muscle function and endogenous cellular repair, highlighting their potential use as therapeutics for VML injuries.

Distinct phenotype and prognosis of immune-mediated necrotizing myopathy based on clinical-serological-pathological classification.

The aim of the study was to investigate the characteristics and prognosis of patients with immune-mediated necrotizing myopathy (IMNM) based on clinical, serological and pathological classification. A total of 138 patients with IMNM who met the 2018 European Neuromuscular Center criteria for IMNM including 62 anti-SRP, 32 anti-HMGCR-positive and 44 myositis specific antibody-negative were involved in the study. All patients were followed up and evaluated remission and relapse. Clustering analysis based on clinical, serological, and pathological parameters was used to define subgroups. Clustering analysis classified IMNM into three clusters. Cluster 1 patients (n = 35) had the highest CK levels, the shortest disease course, severe muscle weakness, and more inflammation infiltration in muscle biopsy. Cluster 2 patients (n = 79) had the lowest CK level and moderate inflammation infiltrate. Cluster 3 patients (n = 24) had the youngest age of onset, the longest disease course and the least frequency of inflammatory infiltration. Patients in cluster 3 had the longest time-to-remission (median survival time: 61[18.3, 103.7] vs 20.5[16.2, 24.9] and 27[19.6, 34.3] months) and shortest relapse-free time than those in cluster 1 and 2 (median remission time 95%CI: 34[19.9, 48.0] vs 73[49.0, 68.7] and 73[48.4, 97.6] months). Patients with age of onset >55 years, more regeneration of muscle fibers, more CD4+T infiltration, and MAC deposition had more favorable outcomes regarding time to achieving remission. Stratification combining clinical, serological, and pathological features could distinguish phenotypes and prognosis of IMNM. The pathological characteristics may impact the long-term prognosis of patients with IMNM.

Mustn1 in Skeletal Muscle: A Novel Regulator?

Skeletal muscle is a complex organ essential for locomotion, posture, and metabolic health. This review explores our current knowledge of Mustn1, particularly in the development and function of skeletal muscle. Mustn1 expression originates from Pax7-positive satellite cells in skeletal muscle, peaks during around the third postnatal month, and is crucial for muscle fiber differentiation, fusion, growth, and regeneration. Clinically, Mustn1 expression is potentially linked to muscle-wasting conditions such as muscular dystrophies. Studies have illustrated that Mustn1 responds dynamically to injury and exercise. Notably, ablation of Mustn1 in skeletal muscle affects a broad spectrum of physiological aspects, including glucose metabolism, grip strength, gait, peak contractile strength, and myofiber composition. This review summarizes our current knowledge of Mustn1's role in skeletal muscle and proposes future research directions, with a goal of elucidating the molecular function of this regulatory gene.

Neuromuscular Junction Remodeling: the Role of Sub-Synaptic Nuclei, Terminal Schwann Cells, and Trophic Signaling Following Neuromusculoskeletal Injuries

Peripheral nerve crush injury is a well-established model of neuromuscular junction (NMJ) denervation and subsequent re-innervation. Functionally, the muscle tissue follows a similar pattern as neural recovery, with immediate loss of force production that steadily improves in parallel with rates of re-innervation. On the other hand, traumatic injury to the muscle tissue itself, specifically volumetric muscle loss (VML), results in an irrecoverable loss of muscle function. Recent work has indicated significant impairments to the NMJ following VML that appear chronic in nature, alongside functional recovery. Thus, the goal of this study was to compare the effects of nerve and muscle injury on NMJ remodeling, with the hypothesis that VML will result in chronic alterations to the NMJ, including a higher degree of cellular localization to the NMJ. Even numbers of adult male and female mice were used with three experimental groups: injury naive, nerve crush, and VML-injury; and three terminal timepoints: 3-, 48-, and 112-days post injury. Data were analyzed by three-way ANOVA with Tukey’s HSD post-hoc. Confirming the assumed recoverability of the two injury models, we found in vivo maximal torque was fully restored following nerve crush injury (Tukey’s HSD post hoc p=0.730), but remained at a significant deficit following VML (~41% lower than injury naïve; Tukey’s HSD post hoc p&lt;0.001). Compared to nerve crush and injury naïve, we found VML results in aberrantly high trophic signaling and numbers of supporting cells. Protein expression of neuregulin-1 and connective tissue growth factor were both highest in the VML group (~1.2-fold and 12-fold increase compared to injury naïve, respectively; Main effect of group, p&lt;0.001). While nerve crush injury elicited a transient increase in terminal Schwann cell numbers (~38% higher than injury naïve at 48dpi; Tukey’s HSD post hoc p&lt;0.001), VML resulted in a chronic increase (~53% and 27% higher than injury naïve at 48 and 112dpi, respectively; Tukey’s HSD post hoc p&lt;0.001). Moreover, nerve crush injury did not alter the number of sub-synaptic nuclei per NMJ, while VML resulted in significant increases at both 48- and 112-days post injury (~27% and 24% higher than injury naïve, respectively; Tukey’s HSD post hoc p=0.002). In some cases, sex differences were detected, including higher rates of innervation in females than males (Main effect of sex p=0.003), particularly following VML-injury (Tukey’s HSD post hoc p=0.004). The findings herein bear a striking resemblance to NMJs found in dystrophic muscle, which are thought to be the result of continuous cycles of muscle fiber degeneration and regeneration. Thus, the NMJ changes observed following VML may be indicative of a larger issue, such as chronic muscle fiber remodeling and pervasive fibrotic accumulation. R01-AR078903 (JAC &amp; SMG); K02-AG081488 (SMG). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Morphometric evaluation of mitochondrial networks in regenerating myofibers using photothermal microscopy

Background: Mitochondria constitute their interconnected network through dynamic mitochondrial processes such as fission and fusion in response to changes in their intracellular environment, such as energy demand. Transmission electron microscopy is the standard method for evaluating mitochondrial morphology. We have developed a simple method to evaluate mitochondrial morphology using tissue sections for bright-field observation. In this study, we attempted to image light-absorbing molecules (cytochrome c) in mitochondria using photothermal (PT) microscopy. Purpose: This method can observe an entire myocyte, so this study attempted to evaluate the entire mitochondrial network of immature (regenerating) myocytes during the skeletal muscle regeneration process. Methods: The gastrocnemius muscle of anesthetized male Wistar rats (13 weeks old) was subjected to 300 controlled eccentric contractions (ECC) using electrical stimulation. 7 days after ECC loading, in situ perfusion fixation was performed, and transverse sections (1 μm) from red (deep regions) and white (superficial regions) were prepared after Epon embedding. The sections were observed by PT microscopy, and quantitative analysis of mitochondrial morphology was performed. Mitochondrial content was expressed as a percentage of the fiber total area in transverse sections. The PT imaging system uses lasers with wavelengths of 515 nm and 638 nm constituting the PT pump and the probe beams, respectively. Results: After 7 days of ECC, many myofibers with small fiber diameters and central nuclei, which are characteristic of the recovery process after muscle damage, were observed. The cross-sectional area of the regenerating muscle (superficial region 389.9 ± 15.2 μm2, deep region 366.2 ± 17.5 μm2) was significantly smaller than that of the normal muscle (superficial region 2211.1 ± 127.3 μm2, deep region 1396.1 ± 72.9 μm2). Mitochondrial content of the regenerating muscle (superficial region 26.1 ± 1.1%, deep region 22.7 ± 0.8%) was significantly lower than that of the normal muscle (superficial region 31.8 ± 1.9%, deep region 34.9 ± 1.8%). In normal muscle, a linear network of mitochondria along myofibrils was observed. On the other hand, no spatially distributed mitochondria were observed in the cytoplasm of the regenerating muscle. Furthermore, a mitochondrial network was formed around the periphery of the central nucleus. Conclusion: In muscle tissue imaging using PT microscopy, myofibers in the regenerative process have less mitochondrial content than mature muscle fibers and lack the mitochondrial network along myofibrils that characterizes mature muscle. On the other hand, the central nucleus of immature muscle was surrounded by highly developed mitochondria. The mitochondrial morphological characteristics of regenerating muscle fibers may offer a unique window through which to better understand mitochondrial design and function and their plasticity during maturation. This study was supported in part by a Grant-in-Aid for Japan Society for the Promotion of Science (JSPS) KAKENHI Grant (No. JP20H04074, 21K19703). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Effect of HY7602 Fermented Deer Antler on Physical Fatigue and Antioxidant Activity in Mice.

Lactobacillus curvatus HY7602 fermented antler (FA) ameliorates sarcopenia and improves exercise performance by increasing muscle mass, muscle fiber regeneration, and mitochondrial biogenesis; however, its anti-fatigue and antioxidant effects have not been studied. Therefore, this study aimed to investigate the anti-fatigue and antioxidant effects and mechanisms of FA. C2C12 and HepG2 cells were stimulated with 1 mM of hydrogen peroxide (H2O2) to induce oxidative stress, followed by treatment with FA. Additionally, 44-week-old C57BL/6J mice were orally administered FA for 4 weeks. FA treatment (5-100 μg/mL) significantly attenuated H2O2-induced cytotoxicity and reactive oxygen species (ROS) production in both cell lines in a dose-dependent manner. In vivo experiments showed that FA treatment significantly increased the mobility time of mice in the forced swimming test and significantly downregulated the serum levels of alanine aminotransferase (ALT), alkaline phosphatase (ALP), lactate dehydrogenase (LDH), creatine kinase (CK), and lactate. Notably, FA treatment significantly upregulated the activities of the antioxidant enzymes superoxide dismutase (SOD), catalase (CAT), and glutathione/oxidized glutathione ratio (GSH/GSSG) and increased the mRNA expression of antioxidant genes (SOD1, SOD2, CAT, GPx1, GPx2, and GSR) in the liver. Conclusively, FA is a potentially useful functional food ingredient for improving fatigue through its antioxidant effects.

Satellite Cell-Derived Exosomes: A Novel Approach to Alleviate Skeletal Muscle Atrophy and Fibrosis.

Skeletal muscle atrophy coincides with extensive fibrous tissue hyperplasia in muscle-atrophied patients, and fibrous tissue plays a vital role in skeletal muscle function and hinders muscle fiber regeneration. However, effective drugs to manage skeletal muscle atrophy and fibrosis remain elusive. This study isolated and characterized exosomes derived from skeletal muscle satellite cells (MuSC-Exo). The study investigated their effects on denervated skeletal muscle atrophy and fibrosis in Sprague Dawley (SD) rats via intramuscular injection. MuSC-Exo demonstrated the potential to alleviate skeletal muscle atrophy and fibrosis. The underlying mechanism using single-cell RNA sequencing data and functional analysis are analyzed. Mechanistic studies reveal close associations between fibroblasts and myoblasts, with the transforming growth factor β1 (TGF-β1)-Smad3-Pax7 axis governing fibroblast activation in atrophic skeletal muscle. MuSC-Exo intervention inhibited the TGF-β1/Smad3 pathway and improved muscle atrophy and fibrosis. In conclusion, MuSC-Exo-based therapy may represent a novel strategy to alleviate skeletal muscle atrophy and reduce excessive fibrotic tissue by targeting Pax7 through the TGF-β1/Smad3 pathway.

Tankyrase-1 regulates RBP-mediated mRNA turnover to promote muscle fiber formation.

Poly(ADP-ribosylation) (PARylation) is a post-translational modification mediated by a subset of ADP-ribosyl transferases (ARTs). Although PARylation-inhibition based therapies are considered as an avenue to combat debilitating diseases such as cancer and myopathies, the role of this modification in physiological processes such as cell differentiation remains unclear. Here, we show that Tankyrase1 (TNKS1), a PARylating ART, plays a major role in myogenesis, a vital process known to drive muscle fiber formation and regeneration. Although all bona fide PARPs are expressed in muscle cells, experiments using siRNA-mediated knockdown or pharmacological inhibition show that TNKS1 is the enzyme responsible of catalyzing PARylation during myogenesis. Via this activity, TNKS1 controls the turnover of mRNAs encoding myogenic regulatory factors such as nucleophosmin (NPM) and myogenin. TNKS1 mediates these effects by targeting RNA-binding proteins such as Human Antigen R (HuR). HuR harbors a conserved TNKS-binding motif (TBM), the mutation of which not only prevents the association of HuR with TNKS1 and its PARylation, but also precludes HuR from regulating the turnover of NPM and myogenin mRNAs as well as from promoting myogenesis. Therefore, our data uncover a new role for TNKS1 as a key modulator of RBP-mediated post-transcriptional events required for vital processes such as myogenesis.

The comparison of adipose-derived stromal cells (ADSCs) delivery method in a murine model of hindlimb ischemia

BackgroundAdipose-derived stromal cells (ADSCs) demonstrate ability to promote tissue healing and down-regulate excessive inflammation. ADSCs have been used to treat critical limb ischemia in preclinical and clinical trials, but still, there is little known about their optimal delivery strategy. To date, no direct analysis of different methods of ADSCs delivery has been performed in the hindlimb ischemia model. Therefore, in this study we focused on the therapeutic efficacy of different ADSCs delivery methods in a murine model of hindlimb ischemia.MethodsFor the hADSCs isolation, we used the subcutaneous adipose tissue collected during the surgery. The murine hindlimb ischemia was used as a model. The unilateral femoral artery ligation was performed on 10–12-week-old male C57BL/6. ADSCs were delivered directly into ischemic muscle, into the contralateral muscle or intravenously. 7 and 14 days after the surgery, the gastrocnemius and quadriceps muscles were collected for the immunohistochemical analysis. The results were analyzed with relevant tests using the Statistica software.ResultsOur research revealed that muscle regeneration, angiogenesis, arteriogenesis and macrophage infiltration in murine model of hindlimb ischemia differ depending on ADSCs delivery method. We have demonstrated that intramuscular method (directly into ischemic limb) of ADSCs delivery is more efficient in functional recovery after critical limb ischemia than intravenous or contralateral route.ConclusionsWe have noticed that injection of ADSCs directly into ischemic limb is the optimal delivery strategy because it increases: (1) muscle fiber regeneration, (2) the number of capillaries and (3) the influx of macrophages F4/80+/CD206+.

Molecular and Structural Alterations of Skeletal Muscle Tissue Nuclei during Aging.

Aging is accompanied by a progressive loss of skeletal muscle mass and strength. The mechanisms underlying this phenomenon are certainly multifactorial and still remain to be fully elucidated. Changes in the cell nucleus structure and function have been considered among the possible contributing causes. This review offers an overview of the current knowledge on skeletal muscle nuclei in aging, focusing on the impairment of nuclear pathways potentially involved in age-related muscle decline. In skeletal muscle two types of cells are present: fiber cells, constituting the contractile muscle mass and containing hundreds of myonuclei, and the satellite cells, i.e., the myogenic mononuclear stem cells occurring at the periphery of the fibers and responsible for muscle growth and repair. Research conducted on different experimental models and with different methodological approaches demonstrated that both the myonuclei and satellite cell nuclei of aged skeletal muscles undergo several structural and molecular alterations, affecting chromatin organization, gene expression, and transcriptional and post-transcriptional activities. These alterations play a key role in the impairment of muscle fiber homeostasis and regeneration, thus contributing to the age-related decrease in skeletal muscle mass and function.

Vibration acceleration enhances proliferation, migration, and maturation of C2C12 cells and promotes regeneration of muscle injury in male rats.

Vibration acceleration (VA) using a whole-body vibration device is beneficial for skeletal muscles. However, its effect at the cellular level remains unclear. We aimed to investigate the effects of VA on muscles invitro and invivo using the C2C12 mouse myoblast cell line and cardiotoxin-induced injury in male rat soleus muscles. Cell proliferation was evaluated using the WST/CCK-8 assay and proportion of Ki-67 positive cells. Cell migration was assessed using wound-healing assay. Cell differentiation was examined by the maturation index in immunostained cultured myotubes and real-time polymerase chain reaction. Regeneration of soleus muscle in rats was assessed by recruitment of satellite cells, cross-sectional area of regenerated muscle fibers, number of centrally nucleated fibers, and conversion of regenerated muscle from fast- to slow-twitch. VA at 30 Hz with low amplitude for 10 min promoted C2C12 cell proliferation, migration, and myotube maturation, without promoting expression of genes related to differentiation. VA significantly increased Pax7-stained satellite cells and centrally nucleated fibers in injured soleus muscles on Day 7 and promoted conversion of fast- to slow-twitch muscle fibers with an increase in the mean cross-sectional area of regenerated muscle fibers on Day 14. VA enhanced the proliferation, migration, and maturation of C2C12 myoblasts and regeneration of injured rat muscles.