Your search keyword '"SATELLITE cells"' showing total 859 results

1. Autophagy in Muscle Regeneration: Mechanisms, Targets, and Therapeutic Perspective.

Author

Chu, Yun, Yuan, Xinrun, Tao, Yiming, Yang, Bin, and Luo, Jinlong

Abstract

Autophagy maintains the stability of eukaryotic cells by degrading unwanted components and recycling nutrients and plays a pivotal role in muscle regeneration by regulating the quiescence, activation, and differentiation of satellite cells. Effective muscle regeneration is vital for maintaining muscle health and homeostasis. However, under certain disease conditions, such as aging, muscle regeneration can fail due to dysfunctional satellite cells. Dysregulated autophagy may limit satellite cell self-renewal, hinder differentiation, and increase susceptibility to apoptosis, thereby impeding muscle regeneration. This review explores the critical role of autophagy in muscle regeneration, emphasizing its interplay with apoptosis and recent advances in autophagy research related to diseases characterized by impaired muscle regeneration. Additionally, we discuss new approaches involving autophagy regulation to promote macrophage polarization, enhancing muscle regeneration. We suggest that utilizing cell therapy and biomaterials to modulate autophagy could be a promising strategy for supporting muscle regeneration. We hope that this review will provide new insights into the treatment of muscle diseases and promote muscle regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

2. CLIC5 promotes myoblast differentiation and skeletal muscle regeneration via the BGN-mediated canonical Wnt/β-catenin signaling pathway.

Author

Xin Zhang, Linjuan He, Liqi Wang, Yubo Wang, Enfa Yan, Boyang Wan, Qiuyu Zeng, Pengguang Zhang, Xingbo Zhao, and Jingdong Yin

Subjects

*MUSCLE regeneration, *CHLORIDE channels, *SATELLITE cells, *GENE expression, *CELLULAR signal transduction, *WNT signal transduction

Abstract

Myoblast differentiation plays a vital role in skeletal muscle regeneration. However, the protein-coding genes controlling this process remain incompletely understood. Here, we showed that chloride intracellular channel 5 (CLIC5) exerts a critical role in mediating myogenesis and skeletal muscle regeneration. Deletion of CLIC5 in skeletal muscle leads to reduced muscle weight and decreases the number and differentiation potential of satellite cells. In vitro, CLIC5 consistently inhibits myoblast proliferation while promoting myotube formation. CLIC5 promotes myogenic differentiation by activating the canonical Wnt/ß-catenin signaling pathway in a biglycan (BGN)-dependent manner. CLIC5 deletion impairs muscle regeneration. Paired box gene 7 (Pax7) expression and the activity of BGN-mediated canonical Wnt/ß-catenin signaling are reduced in CLIC5-deficient mice. Conversely, increasing CLIC5 levels in skeletal muscles enhances muscle regeneration capacity. In conclusion, our findings underscore CLIC5 as a pivotal regulator of myogenesis and skeletal muscle regeneration, functioning through interaction with BGN to activate the canonical Wnt/ß-catenin signaling pathway. [ABSTRACT FROM AUTHOR]

Published

2024

3. TMEM16A regulates satellite cell-mediated skeletal muscle regeneration by ensuring a moderate level of caspase 3 activity.

Author

Sun, Zhiyuan, Shan, Xinqi, Fan, Chun'e, Liu, Lutao, Li, Shuai, Wang, Jiahui, Zhou, Na, Zhu, Minsheng, and Chen, Huaqun

Subjects

SATELLITE cells, SKELETAL muscle, CASPASES, MUSCLE growth, SMALL molecules, CHLORIDE channels, MUSCLE regeneration, SUPERIOR colliculus

Abstract

It has been documented that caspase 3 activity is necessary for skeletal muscle regeneration, but how its activity is regulated is largely unknown. Our previous report shows that intracellular TMEM16A, a calcium activated chloride channel, significantly regulates caspase 3 activity in myoblasts during skeletal muscle development. By using a mouse line with satellite cell (SC)-specific deletion of TMEM16A, we examined the role of TMEM16A in regulating caspase 3 activity in SC (or SC-derived myoblast) as well as skeletal muscle regeneration. The mutant animals displayed apparently impaired regeneration capacity in adult muscle along with enhanced ER stress and elevated caspase 3 activity in Tmem16a−/− SC derived myoblasts. Blockade of either excessive ER stress or caspase 3 activity by small molecules significantly restored the inhibited myogenic differentiation of Tmem16a−/− SCs, indicating that excessive caspase 3 activity resulted from TMEM16A deletion contributes to the impaired muscle regeneration and the upstream regulator of caspase 3 was ER stress. Our results revealed an essential role of TMEM16A in satellite cell-mediated skeletal muscle regeneration by ensuring a moderate level of caspase 3 activity. [ABSTRACT FROM AUTHOR]

Published

2024

4. The MyoGravity project to study real microgravity effects on human muscle precursor cells and tissue.

Author

Di Filippo, Ester Sara, Chiappalupi, Sara, Falone, Stefano, Dolo, Vincenza, Amicarelli, Fernanda, Marchianò, Silvia, Carino, Adriana, Mascetti, Gabriele, Valentini, Giovanni, Piccirillo, Sara, Balsamo, Michele, Vukich, Marco, Fiorucci, Stefano, Sorci, Guglielmo, and Fulle, Stefania

Subjects

POSTURAL muscles, MYONEURAL junction, SATELLITE cells, SPACE flight, ION transport (Biology), MUSCLE regeneration, SKELETAL muscle

Abstract

Microgravity (µG) experienced during space flights promotes adaptation in several astronauts' organs and tissues, with skeletal muscles being the most affected. In response to reduced gravitational loading, muscles (especially, lower limb and antigravity muscles) undergo progressive mass loss and alteration in metabolism, myofiber size, and composition. Skeletal muscle precursor cells (MPCs), also known as satellite cells, are responsible for the growth and maintenance of muscle mass in adult life as well as for muscle regeneration following damage and may have a major role in µG-induced muscle wasting. Despite the great relevance for astronaut health, very few data are available about the effects of real µG on human muscles. Based on the MyoGravity project, this study aimed to analyze: (i) the cellular and transcriptional alterations induced by real µG in human MPCs (huMPCs) and (ii) the response of human skeletal muscle to normal gravitational loading after prolonged exposure to µG. We evaluated the transcriptomic changes induced by µG on board the International Space Station (ISS) in differentiating huMPCs isolated from Vastus lateralis muscle biopsies of a pre-flight astronaut and an age- and sex-matched volunteer, in comparison with the same cells cultured on the ground in standard gravity (1×g) conditions. We found that huMPCs differentiated under real µG conditions showed: (i) upregulation of genes related to cell adhesion, plasma membrane components, and ion transport; (ii) strong downregulation of genes related to the muscle contraction machinery and sarcomere organization; and (iii) downregulation of muscle-specific microRNAs (myomiRs). Moreover, we had the unique opportunity to analyze huMPCs and skeletal muscle tissue of the same astronaut before and 30 h after a long-duration space flight on board the ISS. Prolonged exposure to real µG strongly affected the biology and functionality of the astronaut's satellite cells, which showed a dramatic reduction of responsiveness to activating stimuli and proliferation rate, morphological changes, and almost inability to fuse into myotubes. RNA-Seq analysis of post- vs. pre-flight muscle tissue showed that genes involved in muscle structure and remodeling are promptly activated after landing following a long-duration space mission. Conversely, genes involved in the myelination process or synapse and neuromuscular junction organization appeared downregulated. Although we have investigated only one astronaut, these results point to a prompt readaptation of the skeletal muscle mechanical components to the normal gravitational loading, but the inability to rapidly recover the physiological muscle myelination/innervation pattern after landing from a long-duration space flight. Together with the persistent functional deficit observed in the astronaut's satellite cells after prolonged exposure to real µG, these results lead us to hypothesize that a condition of inefficient regeneration is likely to occur in the muscles of post-flight astronauts following damage. [ABSTRACT FROM AUTHOR]

Published

2024

5. Single‐cell RNA‐seq reveals novel interaction between muscle satellite cells and fibro‐adipogenic progenitors mediated with FGF7 signalling

Author

Lu Ma, Yingying Meng, Yalong An, Peiyuan Han, Chen Zhang, Yongqi Yue, Chenglong Wen, Xin'e Shi, Jianjun Jin, Gongshe Yang, and Xiao Li

Subjects

FGF7–FGFR2, muscle regeneration, satellite cells, senescence, single‐cell RNA‐seq, Diseases of the musculoskeletal system, RC925-935, Human anatomy, QM1-695

Abstract

Abstract Background Muscle satellite cells (MuSCs) exert essential roles in skeletal muscle adaptation to growth, injury and ageing, and their functions are extensively modulated by microenvironmental factors. However, the current knowledge about the interaction of MuSCs with niche cells is quite limited. Methods A 10× single‐cell RNA sequencing (scRNA‐seq) was performed on porcine longissimus dorsi and soleus (SOL) muscles to generate a single‐cell transcriptomic dataset of myogenic cells and other cell types. Sophisticated bioinformatic analyses, including unsupervised clustering analysis, marker gene, gene set variation analysis (GSVA), AUCell, pseudotime analysis and RNA velocity analysis, were performed to explore the heterogeneity of myogenic cells. CellChat analysis was used to demonstrate cell–cell communications across myogenic cell subpopulations and niche cells, especially fibro‐adipogenic progenitors (FAPs). Integrated analysis with human and mice datasets was performed to verify the expression of FGF7 across diverse species. The role of FGF7 on MuSC proliferation was evaluated through administering recombinant FGF7 to porcine MuSCs, C2C12, cardiotoxin (CTX)‐injured muscle and d‐galactose (d‐gal)‐induced ageing model. Results ScRNA‐seq totally figured out five cell types including myo‐lineage cells and FAPs, and myo‐lineage cells were further classified into six subpopulations, termed as RCN3+, S100A4+, ID3+, cycling (MKI67+), MYF6+ and MYMK+ satellite cells, respectively. There was a higher proportion of cycling and MYF6+ cells in the SOL population. CellChat analysis uncovered a particular impact of FAPs on myogenic cells mediated by FGF7, which was relatively highly expressed in SOL samples. Administration of FGF7 (10 ng/mL) significantly increased the proportion of EdU+ porcine MuSCs and C2C12 by 4.03 ± 0.81% (P

Published

2024

6. Loss of Tob1 promotes muscle regeneration through muscle stem cell expansion.

Author

Yasuo Kitajima, Kiyoshi Yoshioka, Yoko Mikumo, Shun Ohki, Kazumitsu Maehara, Yasuyuki Ohkawa, and Yusuke Ono

Subjects

*MUSCLE regeneration, *STEM cells, *MUSCLE cells, *MUSCULAR dystrophy, *MUSCLE growth, *SARCOPENIA

Abstract

Muscle stem cells (MuSCs) play an indispensable role in postnatal muscle growth and hypertrophy in adults. MuSCs also retain a highly regenerative capacity and are therefore considered a promising stem cell source for regenerative therapy for muscle diseases. In this study, we identify tumor-suppressor protein Tob1 as a Pax7 target protein that negatively controls the population expansion of MuSCs. Tob1 protein is undetectable in the quiescent state but is upregulated during activation in MuSCs. Tob1 ablation in mice accelerates MuSC population expansion and boosts muscle regeneration. Moreover, inactivation of Tob1 in MuSCs ameliorates the efficiency of MuSC transplantation in a murine muscular dystrophy model. Collectively, selective targeting of Tob1 might be a therapeutic option for the treatment of muscular diseases, including muscular dystrophy and age-related sarcopenia. [ABSTRACT FROM AUTHOR]

Published

2024

7. Frequent Icing Stimulates Skeletal Muscle Regeneration Following Injury With Necrosis in a Small Fraction of Myofibers in Rats.

Author

Kawashima, Masato, Nagata, Itsuki, Terada, Erika, Tamari, Asano, Kurauchi, Mami, Sakuraya, Tohma, Sonomura, Takahiro, Oyanagi, Eri, Yano, Hiromi, Peake, Jonathan M., and Arakawa, Takamitsu

Subjects

MUSCLE regeneration, SATELLITE cells, SKELETAL muscle, MYOSITIS, MUSCLE injuries

Abstract

Icing interventions on the injured skeletal muscle affect the macrophage-related regenerative events and muscle repair. However, despite its importance for the practice in sport medicine, the influence of different icing protocols on muscle regeneration remains unclear. Here, using a rodent model of mild muscle injury with necrosis in a small fraction of myofibers, the injured animals were allocated to four groups: non-icing control (Con) and a single treatment (Ice-1), three treatments (Ice-3), or nine treatments (Ice-9) with a 30-min icing each time within two days following injury. Muscle regeneration was compared between the groups on post-injury days 1, 3, 5, and 7. The results showed that compared with the Con group, muscle regeneration was faster in the Ice-9 group (but not in the Ice-1 and Ice-3 groups), as indicated by more rapid accumulation of satellite cells within the regenerating area and enlarged size of regenerating myofibers (p <0.05, respectively). There was also less macrophage accumulation (p <0.05) and a trend toward early removal of necrotic myofibers in the damaged/regenerating area in the Ice-9 group (p =0.0535). These results demonstrate that in the case of mild muscle damage, more frequent icing treatment is more effective to stimulate muscle regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

8. The Multiple Roles of Lactate in the Skeletal Muscle.

Author

Bartoloni, Bianca, Mannelli, Michele, Gamberi, Tania, and Fiaschi, Tania

Subjects

*CELL metabolism, *SATELLITE cells, *SKELETAL muscle, *GENETIC transcription, *LACTATES, *MUSCLE regeneration, *G protein coupled receptors

Abstract

Believed for a long time to be merely a waste product of cell metabolism, lactate is now considered a molecule with several roles, having metabolic and signalling functions together with a new, recently discovered role as an epigenetic modulator. Lactate produced by the skeletal muscle during physical exercise is conducted to the liver, which uses the metabolite as a gluconeogenic precursor, thus generating the well-known "Cori cycle". Moreover, the presence of lactate in the mitochondria associated with the lactate oxidation complex has become increasingly clear over the years. The signalling role of lactate occurs through binding with the GPR81 receptor, which triggers the typical signalling cascade of the G-protein-coupled receptors. Recently, it has been demonstrated that lactate regulates chromatin state and gene transcription by binding to histones. This review aims to describe the different roles of lactate in skeletal muscle, in both healthy and pathological conditions, and to highlight how lactate can influence muscle regeneration by acting directly on satellite cells. [ABSTRACT FROM AUTHOR]

Published

2024

9. Myosin heavy chain‐perinatal regulates skeletal muscle differentiation, oxidative phenotype and regeneration.

Author

Sharma, Akashi, Zehra, Aatifa, and Mathew, Sam J.

Subjects

*SKELETAL muscle, *MUSCLE regeneration, *PHENOTYPES, *PERINATAL death, *SATELLITE cells, *MYOSIN, *MUSCLE growth

Abstract

Myosin heavy chain‐perinatal (MyHC‐perinatal) is one of two development‐specific myosin heavy chains expressed exclusively during skeletal muscle development and regeneration. The specific functions of MyHC‐perinatal are unclear, although mutations are known to lead to contracture syndromes such as Trismus‐pseudocamptodactyly syndrome. Here, we characterize the functions of MyHC‐perinatal during skeletal muscle differentiation and regeneration. Loss of MyHC‐perinatal function leads to enhanced differentiation characterized by increased expression of myogenic regulatory factors and differentiation index as well as reduced reserve cell numbers in vitro. Proteomic analysis revealed that loss of MyHC‐perinatal function results in a switch from oxidative to glycolytic metabolism in myofibers, suggesting a shift from slow type I to fast type IIb fiber type, also supported by reduced mitochondrial numbers. Paracrine signals mediate the effect of loss of MyHC‐perinatal function on myogenic differentiation, possibly mediated by non‐apoptotic caspase‐3 signaling along with enhanced levels of the pro‐survival apoptosis regulator Bcl2 and nuclear factor kappa‐B (NF‐κB). Knockdown of MyHC‐perinatal during muscle regeneration in vivo results in increased expression of the differentiation marker myogenin (MyoG) and impaired differentiation, evidenced by smaller myofibers, elevated fibrosis and reduction in the number of satellite cells. Thus, we find that MyHC‐perinatal is a crucial regulator of myogenic differentiation, myofiber oxidative phenotype and regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

10. Agent-based model demonstrates the impact of nonlinear, complex interactions between cytokines on muscle regeneration.

Author

Haase, Megan, Comlekoglu, Tien, Petrucciani, Alexa, Peirce, Shayn M., and Blemker, Silvia S.

Subjects

*MUSCLE regeneration, *SATELLITE cells, *MUSCLE physiology, *LATIN hypercube sampling, *EXTRACELLULAR matrix, *CAPILLARIES

Abstract

Muscle regeneration is a complex process due to dynamic and multiscale biochemical and cellular interactions, making it difficult to identify microenvironmental conditions that are beneficial to muscle recovery from injury using experimental approaches alone. To understand the degree to which individual cellular behaviors impact endogenous mechanisms of muscle recovery, we developed an agent-based model (ABM) using the Cellular-Potts framework to simulate the dynamic microenvironment of a cross-section of murine skeletal muscle tissue. We referenced more than 100 published studies to define over 100 parameters and rules that dictate the behavior of muscle fibers, satellite stem cells (SSCs), fibroblasts, neutrophils, macrophages, microvessels, and lymphatic vessels, as well as their interactions with each other and the microenvironment. We utilized parameter density estimation to calibrate the model to temporal biological datasets describing cross-sectional area (CSA) recovery, SSC, and fibroblast cell counts at multiple timepoints following injury. The calibrated model was validated by comparison of other model outputs (macrophage, neutrophil, and capillaries counts) to experimental observations. Predictions for eight model perturbations that varied cell or cytokine input conditions were compared to published experimental studies to validate model predictive capabilities. We used Latin hypercube sampling and partial rank correlation coefficient to identify in silico perturbations of cytokine diffusion coefficients and decay rates to enhance CSA recovery. This analysis suggests that combined alterations of specific cytokine decay and diffusion parameters result in greater fibroblast and SSC proliferation compared to individual perturbations with a 13% increase in CSA recovery compared to unaltered regeneration at 28 days. These results enable guided development of therapeutic strategies that similarly alter muscle physiology (i.e. converting extracellular matrix [ECM]-bound cytokines into freely diffusible forms as studied in cancer therapeutics or delivery of exogenous cytokines) during regeneration to enhance muscle recovery after injury. [ABSTRACT FROM AUTHOR]

Published

2024

11. Styxl2 regulates de novo sarcomere assembly by binding to non-muscle myosin IIs and promoting their degradation.

Author

Xianwei Chen, Yanfeng Li, Jin Xu, Yong Cui, Qian Wu, Haidi Yin, Yuying Li, Chuan Gao, Liwen Jiang, Huating Wang, Zilong Wen, Zhongping Yao, and Zhenguo Wu

Subjects

*MYOSIN, *KNOCKOUT mice, *STRIATED muscle, *MUSCLE regeneration, *SATELLITE cells

Abstract

Styxl2, a poorly characterized pseudophosphatase, was identified as a transcriptional target of the Jak1-Stat1 pathway during myoblast differentiation in culture. Styxl2 is specifically expressed in vertebrate striated muscles. By gene knockdown in zebrafish or genetic knockout in mice, we found that Styxl2 plays an essential role in maintaining sarcomere integrity in developing muscles. To further reveal the functions of Styxl2 in adult muscles, we generated two inducible knockout mouse models: one with Styxl2 being deleted in mature myofibers to assess its role in sarcomere maintenance, and the other in adult muscle satellite cells (MuSCs) to assess its role in de novo sarcomere assembly. We find that Styxl2 is not required for sarcomere maintenance but functions in de novo sarcomere assembly during injury-induced muscle regeneration. Mechanistically, Styxl2 interacts with non-muscle myosin IIs, enhances their ubiquitination, and targets them for autophagy-dependent degradation. Without Styxl2, the degradation of non-muscle myosin IIs is delayed, which leads to defective sarcomere assembly and force generation. Thus, Styxl2 promotes de novo sarcomere assembly by interacting with non-muscle myosin IIs and facilitating their autophagic degradation. [ABSTRACT FROM AUTHOR]

Published

2024

12. Exploring the Role of Extracellular Vesicles in Skeletal Muscle Regeneration.

Author

Porcu, Cristiana, Dobrowolny, Gabriella, and Scicchitano, Bianca Maria

Subjects

*EXTRACELLULAR vesicles, *MUSCLE regeneration, *SKELETAL muscle, *MESENCHYMAL stem cells, *CELL communication, *EXTRACELLULAR matrix, *SATELLITE cells

Abstract

Skeletal muscle regeneration entails a multifaceted process marked by distinct phases, encompassing inflammation, regeneration, and remodeling. The coordination of these phases hinges upon precise intercellular communication orchestrated by diverse cell types and signaling molecules. Recent focus has turned towards extracellular vesicles (EVs), particularly small EVs, as pivotal mediators facilitating intercellular communication throughout muscle regeneration. Notably, injured muscle provokes the release of EVs originating from myofibers and various cell types, including mesenchymal stem cells, satellite cells, and immune cells such as M2 macrophages, which exhibit anti-inflammatory and promyogenic properties. EVs harbor a specific cargo comprising functional proteins, lipids, and nucleic acids, including microRNAs (miRNAs), which intricately regulate gene expression in target cells and activate downstream pathways crucial for skeletal muscle homeostasis and repair. Furthermore, EVs foster angiogenesis, muscle reinnervation, and extracellular matrix remodeling, thereby modulating the tissue microenvironment and promoting effective tissue regeneration. This review consolidates the current understanding on EVs released by cells and damaged tissues throughout various phases of muscle regeneration with a focus on EV cargo, providing new insights on potential therapeutic interventions to mitigate muscle-related pathologies. [ABSTRACT FROM AUTHOR]

Published

2024

13. Deletion of TECRL promotes skeletal muscle repair by up-regulating EGR2.

Author

Sha Geng, Song-Bai Liu, Wei He, Xiangbin Pan, Yi Sun, Ting Xue, Shiyuan Han, Jing Lou, Ying Chang, Jiqing Zheng, Xinghong Shi, Yangxin Li, and Yao-Hua Song

Subjects

*SKELETAL muscle, *MUSCLE regeneration, *HISTONE acetyltransferase, *SATELLITE cells, *MYOCARDIUM

Abstract

Myogenic regeneration relies on the proliferation and differentiation of satellite cells. TECRL (trans-2,3-enoyl-CoA reductase like) is an endoplasmic reticulum protein only expressed in cardiac and skeletal muscle. However, its role in myogenesis remains unknown. We show that TECRL expression is increased in response to injury. Satellite cell-specific deletion of TECRL enhances muscle repair by increasing the expression of EGR2 through the activation of the ERK1/2 signaling pathway, which in turn promotes the expression of PAX7. We further show that TECRL deletion led to the upregulation of the histone acetyltransferase general control nonderepressible 5, which enhances the transcription of EGR2 through acetylation. Importantly, we showed that AAV9-mediated TECRL silencing improved muscle repair in mice. These findings shed light on myogenic regeneration and muscle repair. [ABSTRACT FROM AUTHOR]

Published

2024

14. Dynamics of pax7 expression during development, muscle regeneration, and in vitro differentiation of satellite cells in rainbow trout (Oncorhynchus mykiss).

Author

Rallière, Cécile, Jagot, Sabrina, Sabin, Nathalie, and Gabillard, Jean-Charles

Subjects

*SATELLITE cells, *RAINBOW trout, *CELL differentiation, *MUSCLE regeneration, *BASAL lamina, *STEM cells

Abstract

Essential for muscle fiber formation and hypertrophy, muscle stem cells, also called satellite cells, reside beneath the basal lamina of the muscle fiber. Satellite cells have been commonly identified by the expression of the Paired box 7 (Pax7) due to its specificity and the availability of antibodies in tetrapods. In fish, the identification of satellite cells remains difficult due to the lack of specific antibodies in most species. Based on the development of a highly sensitive in situ hybridization (RNAScope®) for pax7, we showed that pax7+ cells were detected in the undifferentiated myogenic epithelium corresponding to the dermomyotome at day 14 post-fertilization in rainbow trout. Then, from day 24, pax7+ cells gradually migrated into the deep myotome and were localized along the muscle fibers and reach their niche in satellite position of the fibres after hatching. Our results showed that 18 days after muscle injury, a large number of pax7+ cells accumulated at the wound site compared to the uninjured area. During the in vitro differentiation of satellite cells, the percentage of pax7+ cells decreased from 44% to 18% on day 7, and some differentiated cells still expressed pax7. Taken together, these results show the dynamic expression of pax7 genes and the follow-up of these muscle stem cells during the different situations of muscle fiber formation in trout. [ABSTRACT FROM AUTHOR]

Published

2024

15. Circadian Clock in Muscle Disease Etiology and Therapeutic Potential for Duchenne Muscular Dystrophy.

Author

Kiperman, Tali and Ma, Ke

Subjects

*DUCHENNE muscular dystrophy, *ETIOLOGY of diseases, *MUSCLE diseases, *SKELETAL muscle physiology, *SUPRACHIASMATIC nucleus, *MUSCLE physiology

Abstract

Circadian clock and clock-controlled output pathways exert temporal control in diverse aspects of skeletal muscle physiology, including the maintenance of muscle mass, structure, function, and metabolism. They have emerged as significant players in understanding muscle disease etiology and potential therapeutic avenues, particularly in Duchenne muscular dystrophy (DMD). This review examines the intricate interplay between circadian rhythms and muscle physiology, highlighting how disruptions of circadian regulation may contribute to muscle pathophysiology and the specific mechanisms linking circadian clock dysregulation with DMD. Moreover, we discuss recent advancements in chronobiological research that have shed light on the circadian control of muscle function and its relevance to DMD. Understanding clock output pathways involved in muscle mass and function offers novel insights into the pathogenesis of DMD and unveils promising avenues for therapeutic interventions. We further explore potential chronotherapeutic strategies targeting the circadian clock to ameliorate muscle degeneration which may inform drug development efforts for muscular dystrophy. [ABSTRACT FROM AUTHOR]

Published

2024

16. Comparison of Three Antagonists of Hedgehog Pathway to Promote Skeletal Muscle Regeneration after High Dose Irradiation.

Author

Rota Graziosi, Emmanuelle, François, Sabine, Nasser, Farah, Gauthier, Michel, Oger, Myriam, Favier, Anne-Laure, Drouet, Michel, Jullien, Nicolas, and Riccobono, Diane

Subjects

HEDGEHOG signaling proteins, SKELETAL muscle, BASAL cell carcinoma, SATELLITE cells, RADIATION exposure, MUSCLE regeneration, IRRADIATION, PLATELET-rich plasma, BONE regeneration

Abstract

The current geopolitical context has brought the radiological nuclear risk to the forefront of concerns. High-dose localized radiation exposure leads to the development of a musculocutaneous radiation syndrome affecting the skin and subcutaneous muscles. Despite the implementation of a gold standard treatment based on an invasive surgical procedure coupled with autologous cell therapy, a muscular defect frequently persists. Targeting the modulation of the Hedgehog (Hh) signaling pathway appears to be a promising therapeutic approach. Activation of this pathway enhances cell survival and promotes proliferation after irradiation, while inhibition by Cyclopamine facilitates differentiation. In this study, we compared the effects of three antagonists of Hh, Cyclopamine (CA), Vismodegib (VDG) and Sonidegib (SDG) on differentiation. A stable cell line of murine myoblasts, C2C12, was exposed to X-ray radiation (5 Gy) and treated with CA, VDG or SDG. Analysis of proliferation, survival (apoptosis), morphology, myogenesis genes expression and proteins production were performed. According to the results, VDG does not have a significant impact on C2C12 cells. SDG increases the expression/production of differentiation markers to a similar extent as CA, while morphologically, SDG proves to be more effective than CA. To conclude, SDG can be used in the same way as CA but already has a marketing authorization with an indication against basal cell cancers, facilitating their use in vivo. This proof of concept demonstrates that SDG represents a promising alternative to CA to promotes differentiation of murine myoblasts. Future studies on isolated and cultured satellite cells and in vivo will test this proof of concept. [ABSTRACT FROM AUTHOR]

Published

2024

17. Lineage tracing reveals a novel PDGFRβ+ satellite cell subset that contributes to myo-regeneration of chronically injured rotator cuff muscle.

Author

Dar, Ayelet, Li, Angela, and Petrigliano, Frank A.

Subjects

*SATELLITE cells, *ROTATOR cuff, *PLATELET-derived growth factor, *SUPRASPINATUS muscles, *SKELETAL muscle injuries, *MUSCLE regeneration, *MUSCULAR atrophy

Abstract

Massive rotator cuff (RC) tendon tears are associated with progressive fibro-adipogenesis and muscle atrophy that altogether cause shoulder muscle wasting. Platelet derived growth factor β (PDGFRβ) lineage cells, that co-express PDGFRα have previously been shown to directly contribute to scar formation and fat accumulation in a mouse model of irreversible tendon and nerve transection (TTDN). Conversely, PDGFRβ+ lineage cells have also been shown to be myogenic in cultures and in other models of skeletal muscle injury. We therefore hypothesized that PDGFRβ demarcates two distinct RC residing subpopulations, fibro-adipogenic and myogenic, and aimed to elucidate the identity of the PDGFRβ myogenic precursors and evaluate their contribution, if any, to RC myo-regeneration. Lineage tracing revealed increasing contribution of PDGFRβ+ myo-progenitors to the formation of GFP+ myofibers, which were the most abundant myofiber type in regenerated muscle at 2 weeks post-TTDN. Muscle regeneration preceded muscle atrophy and both advanced from the lateral site of tendon transection to the farthest medial region. GFP+/PDGFRβ+Sca-1−lin−CXCR4+Integrin-β1+ marked a novel subset of satellite cells with confirmed myogenic properties. Further studies are warranted to identify the existence of PDGFRβ+ satellite cells in human and other mouse muscles and to define their myo-regenerative potential following acute and chronic muscle injury. [ABSTRACT FROM AUTHOR]

Published

2024

18. Establishment and Characterization of SV40 T-Antigen Immortalized Porcine Muscle Satellite Cell.

Author

Ni, Mengru, He, Jingqing, Li, Tao, Zhao, Gan, Ji, Zhengyu, Ren, Fada, Leng, Jianxin, Wu, Mengyan, Huang, Ruihua, Li, Pinghua, and Hou, Liming

Subjects

*SATELLITE cells, *MUSCLE cells, *MUSCLE growth, *MUSCLE regeneration, *SKELETAL muscle

Abstract

Muscle satellite cells (MuSCs) are crucial for muscle development and regeneration. The primary pig MuSCs (pMuSCs) is an ideal in vitro cell model for studying the pig's muscle development and differentiation. However, the long-term in vitro culture of pMuSCs results in the gradual loss of their stemness, thereby limiting their application. To address this conundrum and maintain the normal function of pMuSCs during in vitro passaging, we generated an immortalized pMuSCs (SV40 T-pMuSCs) by stably expressing SV40 T-antigen (SV40 T) using a lentiviral-based vector system. The SV40 T-pMuSCs can be stably sub-cultured for over 40 generations in vitro. An evaluation of SV40 T-pMuSCs was conducted through immunofluorescence staining, quantitative real-time PCR, EdU assay, and SA-β-gal activity. Their proliferation capacity was similar to that of primary pMuSCs at passage 1, and while their differentiation potential was slightly decreased. SiRNA-mediated interference of SV40 T-antigen expression restored the differentiation capability of SV40 T-pMuSCs. Taken together, our results provide a valuable tool for studying pig skeletal muscle development and differentiation. [ABSTRACT FROM AUTHOR]

Published

2024

19. Restoring Mitochondrial Function and Muscle Satellite Cell Signaling: Remedies against Age-Related Sarcopenia.

Author

Marzetti, Emanuele, Lozanoska-Ochser, Biliana, Calvani, Riccardo, Landi, Francesco, Coelho-Júnior, Hélio José, and Picca, Anna

Subjects

*SATELLITE cells, *SARCOPENIA, *MUSCLE cells, *CELL communication, *MUSCLE mass, *MUSCLE regeneration, *LUNGS

Abstract

Sarcopenia has a complex pathophysiology that encompasses metabolic dysregulation and muscle ultrastructural changes. Among the drivers of intracellular and ultrastructural changes of muscle fibers in sarcopenia, mitochondria and their quality control pathways play relevant roles. Mononucleated muscle stem cells/satellite cells (MSCs) have been attributed a critical role in muscle repair after an injury. The involvement of mitochondria in supporting MSC-directed muscle repair is unclear. There is evidence that a reduction in mitochondrial biogenesis blunts muscle repair, thus indicating that the delivery of functional mitochondria to injured muscles can be harnessed to limit muscle fibrosis and enhance restoration of muscle function. Injection of autologous respiration-competent mitochondria from uninjured sites to damaged tissue has been shown to reduce infarct size and enhance cell survival in preclinical models of ischemia–reperfusion. Furthermore, the incorporation of donor mitochondria into MSCs enhances lung and cardiac tissue repair. This strategy has also been tested for regeneration purposes in traumatic muscle injuries. Indeed, the systemic delivery of mitochondria promotes muscle regeneration and restores muscle mass and function while reducing fibrosis during recovery after an injury. In this review, we discuss the contribution of altered MSC function to sarcopenia and illustrate the prospect of harnessing mitochondrial delivery and restoration of MSCs as a therapeutic strategy against age-related sarcopenia. [ABSTRACT FROM AUTHOR]

Published

2024

20. Lysine Distinctively Manipulates Myogenic Regulatory Factors and Wnt/Ca 2+ Pathway in Slow and Fast Muscles, and Their Satellite Cells of Postnatal Piglets.

Author

Wang, Xiaofan, Zong, Xiaoyin, Ye, Mao, Jin, Chenglong, Xu, Tao, Yang, Jinzeng, Gao, Chunqi, Wang, Xiuqi, and Yan, Huichao

Subjects

*SATELLITE cells, *CALCIUM ions, *PIGLETS, *LYSINE, *MYOSIN, *MUSCLE regeneration, *PROTEIN kinase C

Abstract

Muscle regeneration, representing an essential homeostatic process, relies mainly on the myogenic progress of resident satellite cells, and it is modulated by multiple physical and nutritional factors. Here, we investigated how myogenic differentiation-related factors and pathways respond to the first limiting amino acid lysine (Lys) in the fast and slow muscles, and their satellite cells (SCs), of swine. Thirty 28-day-old weaned piglets with similar body weights were subjected to three diet regimens: control group (d 0–28: 1.31% Lys, n = 12), Lys-deficient group (d 0–28: 0.83% Lys, n = 12), and Lys rescue group (d 0–14: 0.83% Lys; d 15–28: 1.31% Lys, n = 6). Pigs on d 15 and 29 were selectively slaughtered for muscular parameters evaluation. Satellite cells isolated from fast (semimembranosus) and slow (semitendinosus) muscles were also selected to investigate differentiation ability variations. We found Lys deficiency significantly hindered muscle development in both fast and slow muscles via the distinct manipulation of myogenic regulatory factors and the Wnt/Ca2+ pathway. In the SC model, Lys deficiency suppressed the Wnt/Ca2+ pathways and myosin heavy chain, myogenin, and myogenic regulatory factor 4 in slow muscle SCs but stimulated them in fast muscle SCs. When sufficient Lys was attained, the fast muscle-derived SCs Wnt/Ca2+ pathway (protein kinase C, calcineurin, calcium/calmodulin-dependent protein kinase II, and nuclear factor of activated T cells 1) was repressed, while the Wnt/Ca2+ pathway of its counterpart was stimulated to further the myogenic differentiation. Lys potentially manipulates the differentiation of porcine slow and fast muscle myofibers via the Wnt/Ca2+ pathway in opposite trends. [ABSTRACT FROM AUTHOR]

Published

2024

21. Hotspots and trends in satellite cell research in muscle regeneration: A bibliometric visualization and analysis from 2010 to 2023

Author

Nan Huang, Kang Zou, Yanbiao Zhong, Yun Luo, Maoyuan Wang, and Li Xiao

Subjects

Muscle regeneration, Satellite cells, Bibliometrics, Muscle atrophy, Muscle injury, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Background: The incidence of muscle atrophy or sports injuries is increasing with time and population aging, thereby attracting considerable attention to muscle generation research. Muscle satellite cells, which play an important role in this process, lack comprehensive literature regarding their use for muscle regeneration. Hence, this study aimed to analyze the hotspots and trends in satellite cell research from 2010 to 2023, providing a reference for muscle regeneration research. Methods: Studies on satellite cells’ role in muscle regeneration from 2010 to 2023 were retrieved from the Web of Science Core Collection. Using CiteSpace and VOSviewer, we analyzed annual publications, authors and co-citing authors, countries and institutions, journals and co-citing journals, co-citing references, and keywords. Results: From 2010 to 2023, 1468 papers were retrieved, indicating an overall increasing trend in the number of annual publications related to satellite cells in muscle regeneration. The United States had the highest number of publications, while the Institut National de la Santé et de la Recherche Médicale was the institution with the most publications. Among journals, '' PloS One'' had the highest number of published papers, and ''Cell'' emerged as the most co-cited journal. A total of 7425 authors were involved, with Michael A. Rudnicki being the author with the highest number of publications and the most co-cited author. The most cited reference was ''Satellite cells and the muscle stem cell niche.'' Among keywords, “satellite cells” was the most common, with ''heterogeneity'' having the highest centrality. Frontier themes included ''Duchenne muscular dystrophy,” ''skeletal muscle,” ''in-vivo,” ''muscle regeneration,” ''mice,'' ''muscle atrophy,” ''muscle fibers,” ''inflammation,” '' mesenchymal stem cells,” and ''satellite cell.'' Conclusion: This study presents the current status and trends in satellite cell research on muscle regeneration from 2010 to 2023 using bibliometric analyses, providing valuable insights into numerous future research directions.

Published

2024

22. 骨骼肌再生过程中卫星细胞调控机制及其生态位信号的作用.

Author

孔健达, 穆玉晶, 朱 磊, 李志林, and 陈世娟

Subjects

*SATELLITE cells, *SKELETAL muscle, *SKELETAL muscle injuries, *PROGENITOR cells, *EXTRACELLULAR matrix, *MUSCLE regeneration, *ENDOTHELIAL cells

Abstract

BACKGROUND: Satellite cells are a specific population of adult stem cells contained in skeletal muscle that promote the regenerative reconstruction of injured skeletal muscle, but their specific mechanisms are not well established. OBJECTIVE: To review the regulatory role of satellite cells during skeletal muscle regeneration and the mechanism of interaction between satellite cells and their ecological niche signals, aiming to provide new research ideas and perspectives based on the summary of existing knowledge. METHODS: Web of Science, PubMed, CNKI, WanFang, and VIP databases were searched for literature published between January 2002 and June 2022. English search terms were “muscle, skeletal muscle, muscle injury, stem cells, satellite cells, muscle repair”. Chinese search terms were “skeletal muscle, skeletal muscle regeneration, skeletal muscle reconstruction, satellite cells, ecological niche”. The 66 included papers were organized and analyzed. RESULTS AND CONCLUSION: (1) Satellite cells exist in skeletal muscle and contribute to both the formation of new muscle fibers after injury and the effective growth of existing adult muscle fibers. (2) After the activation of quiescent satellite cells in satellite cells, the steps of satellite cell proliferation, differentiation and fusion to form muscle fibers during skeletal muscle regeneration are influenced by their intrinsic regulatory effects of different mechanisms. (3) Satellite cells can interact with myofibers, extracellular matrix, skeletal muscle junctions, fibroblast progenitor cells, immune cells and endothelial cells in the ecological niche signal to promote satellite cell activation, proliferation and differentiation to achieve effective skeletal muscle regeneration. (4) Possible breakthroughs in future research include: the division pattern of satellite cells in the body; the mechanisms regulating satellite cell transfer; the specific timing of satellite cell differentiation or self-renewal in vivo; and the interaction mechanisms between satellite cells and skeletal muscle junctions. (5) This review may provide some theoretical reference values for the field of injury reconstruction of skeletal muscle and its innovation. [ABSTRACT FROM AUTHOR]

Published

2024

23. Studying the Effect of MBNL1 and MBNL2 Loss in Skeletal Muscle Regeneration.

Author

Yadava, Ramesh S., Mandal, Mahua, and Mahadevan, Mani S.

Subjects

*MUSCLE regeneration, *RNA-binding proteins, *SKELETAL muscle, *FACIOSCAPULOHUMERAL muscular dystrophy, *MUSCULAR dystrophy, *SATELLITE cells, *KNOCKOUT mice

Abstract

Loss of function of members of the muscleblind-like (MBNL) family of RNA binding proteins has been shown to play a key role in the spliceopathy of RNA toxicity in myotonic dystrophy type 1 (DM1), the most common muscular dystrophy affecting adults and children. MBNL1 and MBNL2 are the most abundantly expressed members in skeletal muscle. A key aspect of DM1 is poor muscle regeneration and repair, leading to dystrophy. We used a BaCl2-induced damage model of muscle injury to study regeneration and effects on skeletal muscle satellite cells (MuSCs) in Mbnl1∆E3/∆E3 and Mbnl2∆E2/∆E2 knockout mice. Similar experiments have previously shown deleterious effects on these parameters in mouse models of RNA toxicity. Muscle regeneration in Mbnl1 and Mbnl2 knockout mice progressed normally with no obvious deleterious effects on MuSC numbers or increased expression of markers of fibrosis. Skeletal muscles in Mbnl1∆E3/∆E3/ Mbnl2∆E2/+ mice showed increased histopathology but no deleterious reductions in MuSC numbers and only a slight increase in collagen deposition. These results suggest that factors beyond the loss of MBNL1/MBNL2 and the associated spliceopathy are likely to play a key role in the defects in skeletal muscle regeneration and deleterious effects on MuSCs that are seen in mouse models of RNA toxicity due to expanded CUG repeats. [ABSTRACT FROM AUTHOR]

Published

2024

24. Enhanced Diaphragm Muscle Function upon Satellite Cell Transplantation in Dystrophic Mice.

Author

Azzag, Karim, Gransee, Heather M., Magli, Alessandro, Yamashita, Aline M. S., Tungtur, Sudheer, Ahlquist, Aaron, Zhan, Wen-Zhi, Onyebu, Chiemelie, Greising, Sarah M., Mantilla, Carlos B., and Perlingeiro, Rita C. R.

Subjects

*RESPIRATORY muscles, *SATELLITE cells, *CELL transplantation, *MUSCULAR dystrophy, *MUSCLE regeneration

Abstract

The diaphragm muscle is essential for breathing, and its dysfunctions can be fatal. Many disorders affect the diaphragm, including muscular dystrophies. Despite the clinical relevance of targeting the diaphragm, there have been few studies evaluating diaphragm function following a given experimental treatment, with most of these involving anti-inflammatory drugs or gene therapy. Cell-based therapeutic approaches have shown success promoting muscle regeneration in several mouse models of muscular dystrophy, but these have focused mainly on limb muscles. Here we show that transplantation of as few as 5000 satellite cells directly into the diaphragm results in consistent and robust myofiber engraftment in dystrophin- and fukutin-related protein-mutant dystrophic mice. Transplanted cells also seed the stem cell reservoir, as shown by the presence of donor-derived satellite cells. Force measurements showed enhanced diaphragm strength in engrafted muscles. These findings demonstrate the feasibility of cell transplantation to target the diseased diaphragm and improve its contractility. [ABSTRACT FROM AUTHOR]

Published

2024

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

Author

Sato, Seira, Hanai, Tatsuhiro, Kanamoto, Takashi, Kawano, Fuminori, Hikida, Minami, Yokoi, Hiroyuki, Take, Yasuhiro, Magome, Takuya, Ebina, Kosuke, Mae, Tatsuo, Tanaka, Hiroyuki, and Nakata, Ken

Subjects

*SOLEUS muscle, *MYOBLASTS, *MUSCLE regeneration, *MUSCLE injuries, *WHOLE-body vibration, *SATELLITE cells, *RATS

Abstract

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 in vitro and in vivo 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. [ABSTRACT FROM AUTHOR]

Published

2024

26. Regulation of Satellite Cells Functions during Skeletal Muscle Regeneration: A Critical Step in Physiological and Pathological Conditions.

Author

Careccia, Giorgia, Mangiavini, Laura, and Cirillo, Federica

Subjects

*MUSCLE regeneration, *SATELLITE cells, *CELL physiology, *SKELETAL muscle, *CELLULAR control mechanisms, *MUSCULAR dystrophy

Abstract

Skeletal muscle regeneration is a complex process involving the generation of new myofibers after trauma, competitive physical activity, or disease. In this context, adult skeletal muscle stem cells, also known as satellite cells (SCs), play a crucial role in regulating muscle tissue homeostasis and activating regeneration. Alterations in their number or function have been associated with various pathological conditions. The main factors involved in the dysregulation of SCs' activity are inflammation, oxidative stress, and fibrosis. This review critically summarizes the current knowledge on the role of SCs in skeletal muscle regeneration. It examines the changes in the activity of SCs in three of the most common and severe muscle disorders: sarcopenia, muscular dystrophy, and cancer cachexia. Understanding the molecular mechanisms involved in their dysregulations is essential for improving current treatments, such as exercise, and developing personalized approaches to reactivate SCs. [ABSTRACT FROM AUTHOR]

Published

2024

27. Severely Damaged Freeze-Injured Skeletal Muscle Reveals Functional Impairment, Inadequate Repair, and Opportunity for Human Stem Cell Application.

Author

Fioretti, Daniela, Ledda, Mario, Iurescia, Sandra, Carletti, Raffaella, Di Gioia, Cira, Lolli, Maria Grazia, Marchese, Rodolfo, Lisi, Antonella, and Rinaldi, Monica

Subjects

HUMAN stem cells, SKELETAL muscle, SATELLITE cells, MESENCHYMAL stem cells, MILITARY medicine, SKELETAL muscle injuries, MUSCLE injuries

Abstract

Background: The regeneration of severe traumatic muscle injuries is an unsolved medical need that is relevant for civilian and military medicine. In this work, we produced a critically sized nonhealing muscle defect in a mouse model to investigate muscle degeneration/healing phases. Materials and methods: We caused a freeze injury (FI) in the biceps femoris of C57BL/6N mice. From day 1 to day 25 post-injury, we conducted histological/morphometric examinations, an analysis of the expression of genes involved in inflammation/regeneration, and an in vivo functional evaluation. Results: We found that FI activates cytosolic DNA sensing and inflammatory responses. Persistent macrophage infiltration, the prolonged expression of eMHC, the presence of centrally nucleated myofibers, and the presence of PAX7+ satellite cells at late time points and with chronic physical impairment indicated inadequate repair. By looking at stem-cell-based therapeutic protocols of muscle repair, we investigated the crosstalk between M1-biased macrophages and human amniotic mesenchymal stem cells (hAMSCs) in vitro. We demonstrated their reciprocal paracrine effects where hAMSCs induced a shift of M1 macrophages into an anti-inflammatory phenotype, and M1 macrophages promoted an increase in the expression of hAMSC immunomodulatory factors. Conclusions: Our findings support the rationale for the future use of our injury model to exploit the full potential of in vivo hAMSC transplantation following severe traumatic injuries. [ABSTRACT FROM AUTHOR]

Published

2024

28. Injury-experienced satellite cells retain long-term enhanced regenerative capacity

Author

Jacopo Morroni, Anna Benedetti, Lorenza Esposito, Marco De Bardi, Giovanna Borsellino, Carles Sanchez Riera, Lorenzo Giordani, Marina Bouche, and Biliana Lozanoska-Ochser

Subjects

Satellite cells, Inflammatory memory, Repeated injury, Muscle regeneration, Medicine (General), R5-920, Biochemistry, QD415-436

Abstract

Abstract Background Inflammatory memory or trained immunity is a recently described process in immune and non-immune tissue resident cells, whereby previous exposure to inflammation mediators leads to a faster and stronger responses upon secondary challenge. Whether previous muscle injury is associated with altered responses to subsequent injury by satellite cells (SCs), the muscle stem cells, is not known. Methods We used a mouse model of repeated muscle injury, in which intramuscular cardiotoxin (CTX) injections were administered 50 days apart in order to allow for full recovery of the injured muscle before the second injury. The effect of prior injury on the phenotype, proliferation and regenerative potential of satellite cells following a second injury was examined in vitro and in vivo by immunohistochemistry, RT-qPCR and histological analysis. Results We show that SCs isolated from muscle at 50 days post-injury (injury-experienced SCs (ieSCs)) enter the cell cycle faster and form bigger myotubes when cultured in vitro, compared to control SCs isolated from uninjured contralateral muscle. Injury-experienced SCs were characterized by the activation of the mTORC 1 signaling pathway, suggesting they are poised to activate sooner following a second injury. Consequently, upon second injury, SCs accumulate in greater numbers in muscle at 3 and 10 days after injury. These changes in SC phenotype and behavior were associated with accelerated muscle regeneration, as evidenced by an earlier appearance of bigger fibers and increased number of myonuclei per fiber at day 10 after the second injury. Conclusions Overall, we show that skeletal muscle injury has a lasting effect on SC function priming them to respond faster to a subsequent injury. The ieSCs have long-term enhanced regenerative properties that contribute to accelerated regeneration following a secondary challenge.

Published

2023

29. Therapeutic Consequences of Targeting the IGF-1/PI3K/AKT/FOXO3 Axis in Sarcopenia: A Narrative Review.

Author

Gellhaus, Benjamin, Böker, Kai O., Schilling, Arndt F., and Saul, Dominik

Subjects

*SARCOPENIA, *FORKHEAD transcription factors, *SATELLITE cells, *UBIQUITIN ligases, *MUSCLE regeneration, *PI3K/AKT pathway, *MUSCLE cells, *OLDER people

Abstract

The high prevalence of sarcopenia in an aging population has an underestimated impact on quality of life by increasing the risk of falls and subsequent hospitalization. Unfortunately, the application of the major established key therapeutic—physical activity—is challenging in the immobile and injured sarcopenic patient. Consequently, novel therapeutic directions are needed. The transcription factor Forkhead-Box-Protein O3 (FOXO3) may be an option, as it and its targets have been observed to be more highly expressed in sarcopenic muscle. In such catabolic situations, Foxo3 induces the expression of two muscle specific ubiquitin ligases (Atrogin-1 and Murf-1) via the PI3K/AKT pathway. In this review, we particularly evaluate the potential of Foxo3-targeted gene therapy. Foxo3 knockdown has been shown to lead to increased muscle cross sectional area, through both the AKT-dependent and -independent pathways and the reduced impact on the two major downstream targets Atrogin-1 and Murf-1. Moreover, a Foxo3 reduction suppresses apoptosis, activates satellite cells, and initiates their differentiation into muscle cells. While this indicates a critical role in muscle regeneration, this mechanism might exhaust the stem cell pool, limiting its clinical applicability. As systemic Foxo3 knockdown has also been associated with risks of inflammation and cancer progression, a muscle-specific approach would be necessary. In this review, we summarize the current knowledge on Foxo3 and conceptualize a specific and targeted therapy that may circumvent the drawbacks of systemic Foxo3 knockdown. This approach presumably would limit the side effects and enable an activity-independent positive impact on skeletal muscle. [ABSTRACT FROM AUTHOR]

Published

2023

30. ApoE isoform does not influence skeletal muscle regeneration in adult mice.

Author

Burke, Benjamin I., Goh, Jensen, Albathi, Fatmah A., Valentino, Taylor R., Nolt, Georgia L., Joshi, Jai K., Dungan, Cory M., Johnson, Lance A., Yuan Wen, Ismaeel, Ahmed, and McCarthy, John J.

Subjects

MUSCLE regeneration, SKELETAL muscle, APOLIPOPROTEIN E, APOLIPOPROTEIN E4, MICE

Abstract

Introduction: Apolipoprotein E (ApoE) has been shown to be necessary for proper skeletal muscle regeneration. Consistent with this finding, single-cell RNAsequencing analyses of skeletal muscle stem cells (MuSCs) revealed that Apoe is a top marker of quiescent MuSCs that is downregulated upon activation. The purpose of this study was to determine if muscle regeneration is altered in mice which harbor one of the three common human ApoE isoforms, referred to as ApoE2, E3 and E4. Methods: Histomorphometric analyses were employed to assess muscle regeneration in ApoE2, E3, and E4 mice after 14 days of recovery from barium chloride-induced muscle damage in vivo, and primary MuSCs were isolated to assess proliferation and differentiation of ApoE2, E3, and E4 MuSCs in vitro. Results: There was no difference in the basal skeletal muscle phenotype of ApoE isoforms as evaluated by section area, myofiber cross-sectional area (CSA), and myonuclear and MuSC abundance per fiber. Although there were no differences in fiber-type frequency in the soleus, Type IIa relative frequency was significantly lower in plantaris muscles of ApoE4 mice compared to ApoE3. Moreover, ApoE isoform did not influence muscle regeneration as assessed by fiber frequency, fiber CSA, and myonuclear and MuSC abundance. Finally, there were no differences in the proliferative capacity or myogenic differentiation potential of MuSCs between any ApoE isoform. Discussion: Collectively, these data indicate nominal effects of ApoE isoform on the ability of skeletal muscle to regenerate following injury or the in vitro MuSC phenotype. [ABSTRACT FROM AUTHOR]

Published

2023

31. Signaling roles of platelets in skeletal muscle regeneration.

Author

Graca, Flavia A., Minden‐Birkenmaier, Benjamin A., Stephan, Anna, Demontis, Fabio, and Labelle, Myriam

Subjects

*BLOOD platelets, *MUSCLE regeneration, *SATELLITE cells, *SKELETAL muscle, *MUSCLE cells, *REGENERATION (Biology), *GUIDED tissue regeneration, *BLOOD platelet activation

Abstract

Platelets have important hemostatic functions in repairing blood vessels upon tissue injury. Cytokines, growth factors, and metabolites stored in platelet α‐granules and dense granules are released upon platelet activation and clotting. Emerging evidence indicates that such platelet‐derived signaling factors are instrumental in guiding tissue regeneration. Here, we discuss the important roles of platelet‐secreted signaling factors in skeletal muscle regeneration. Chemokines secreted by platelets in the early phase after injury are needed to recruit neutrophils to injured muscles, and impeding this early step of muscle regeneration exacerbates inflammation at later stages, compromises neo‐angiogenesis and the growth of newly formed myofibers, and reduces post‐injury muscle force production. Platelets also contribute to the recruitment of pro‐regenerative stromal cells from the adipose tissue, and the platelet releasate may also regulate the metabolism and proliferation of muscle satellite cells, which sustain myogenesis. Therefore, harnessing the signaling functions of platelets and the platelet secretome may provide new avenues for promoting skeletal muscle regeneration in health and disease. [ABSTRACT FROM AUTHOR]

Published

2023

32. Tenascin-C-enriched regeneration-specific extracellular matrix guarantees superior muscle regeneration in Ambystoma mexicanum.

Author

Ohashi, Ayaka, Terai, Suzuno, Furukawa, Saya, Yamamoto, Sakiya, Kashimoto, Rena, and Satoh, Akira

Subjects

*MUSCLE regeneration, *EXTRACELLULAR matrix, *SATELLITE cells, *MUSCLE injuries, *CELL migration

Abstract

Severe muscle injury causes distress and difficulty in humans. Studying the high regenerative ability of the axolotls may provide hints for the development of an effective treatment for severe injuries to muscle tissue. Here, we examined the regenerative process in response to a muscle injury in axolotls. We found that axolotls are capable of complete regeneration in response to a partial muscle resection called volumetric muscle loss (VML), which mammals cannot perfectly regenerate. We investigated the mechanisms underlying this high regenerative capacity in response to VML, focusing on the migration of muscle satellite cells and the extracellular matrix (ECM) formed during VML injury. Axolotls form tenascin-C (TN-C)-enriched ECM after VML injury. This TN-C-enriched ECM promotes the satellite cell migration. We confirmed the importance of TN-C in successful axolotl muscle regeneration by creating TN-C mutant animals. Our results suggest that the maintenance of a TN-C-enriched ECM environment after muscle injury promotes the release of muscle satellite cells and supports eventually high muscle regenerative capacity. In the future, better muscle regeneration may be achieved in mammals through the maintenance of TN-C expression. [Display omitted] • Axolotl muscle regeneration ability is superior to that of mammals. • The presence of regeneration-promoting ECM contributes to higher muscle regeneration. • Tenascin-C is the component consisting of the regeneration-promoting ECM. • Loss of Tenascin-C impairs the axolotl muscle regeneration ability. [ABSTRACT FROM AUTHOR]

Published

2023

33. Tenascin-C-EGFR activation induces functional human satellite cell proliferation and promotes wound-healing of skeletal muscles via oleanic acid.

Author

Zhang, Hao, Zhou, Lin, Wang, Huihao, Gu, Wei, Li, Zhiqiang, Sun, Jun, Wei, Xiaoen, and Zheng, Yuxin

Subjects

*WOUND healing, *SATELLITE cells, *CELL proliferation, *DUCHENNE muscular dystrophy, *MUSCULAR atrophy, *SKELETAL muscle, *MUSCLE regeneration

Abstract

Human satellite cells (HuSCs) have been deemed to be the potential cure to treat muscular atrophy diseases such as Duchenne muscular dystrophy. However, the clinical trials of HuSCs were restricted to the inadequacy of donors because of that freshly isolated HuSCs quickly lost the Pax7 expression and myogenesis capacity in vivo after a few days of culture. Here we found that oleanic acid, a kind of triterpenoid endowed with diverse biological functions with treatment potential, could efficiently promote HuSCs proliferation. The HuSCs cultured in the medium supplement with oleanic acid could maintain a high expression level of Pax7 and retain the ability to differentiate into myotubes as well as facilitate muscle regeneration in injured muscles of recipient mice. We further revealed that Tenascin-C acts as the core mechanism to activate the EGFR signaling pathway followed by HuSCs proliferation. Taken together, our data provide an efficient method to expand functional HuSCs and a novel mechanism that controls HuSCs proliferation, which sheds light on the HuSCs-based therapy to treat muscle diseases. [Display omitted] • Oleanic acid could efficiently promote HuSCs proliferation. • Oleanic acid-cultured HuSCs retain the ability to differentiate into functional myotubes. • Oleanic acid induces Tenascin-C and EGFR signaling pathway followed by HuSCs proliferation. [ABSTRACT FROM AUTHOR]

Published

2023

34. RhoA Is a Crucial Regulator of Myoblast Fusion.

Author

Noviello, Chiara, Kobon, Kassandra, Randrianarison-Huetz, Voahangy, Maire, Pascal, Pietri-Rouxel, France, Falcone, Sestina, and Sotiropoulos, Athanassia

Subjects

*SATELLITE cells, *STEM cells, *MUSCLE cells, *MUSCULAR hypertrophy, *GENE fusion, *SKELETAL muscle, *MUSCLE regeneration

Abstract

Satellite cells (SCs) are adult muscle stem cells that are mobilized when muscle homeostasis is perturbed. Here we show that RhoA in SCs is indispensable to have correct muscle regeneration and hypertrophy. In particular, the absence of RhoA in SCs prevents a correct SC fusion both to other RhoA-deleted SCs (regeneration context) and to growing control myofibers (hypertrophy context). We demonstrated that RhoA is dispensable for SCs proliferation and differentiation; however, RhoA-deleted SCs have an inefficient movement even if their cytoskeleton assembly is not altered. Proliferative myoblast and differentiated myotubes without RhoA display a decreased expression of Chordin, suggesting a crosstalk between these genes for myoblast fusion regulation. These findings demonstrate the importance of RhoA in SC fusion regulation and its requirement to achieve an efficient skeletal muscle homeostasis restoration. [ABSTRACT FROM AUTHOR]

Published

2023

35. The roles of miRNAs in adult skeletal muscle satellite cells.

Author

Koopmans, Pieter Jan, Ismaeel, Ahmed, Goljanek-Whysall, Katarzyna, and Murach, Kevin A.

Subjects

*SATELLITE cells, *MUSCLE cells, *SKELETAL muscle, *MICRORNA, *MYOBLASTS, *MUSCLE regeneration

Abstract

Satellite cells are bona fide muscle stem cells that are indispensable for successful post-natal muscle growth and regeneration after severe injury. These cells also participate in adult muscle adaptation in several capacities. MicroRNAs (miRNAs) are post-transcriptional regulators of mRNA that are implicated in several aspects of stem cell function. There is evidence to suggest that miRNAs affect satellite cell behavior in vivo during development and myogenic progenitor behavior in vitro, but the role of miRNAs in adult skeletal muscle satellite cells is less studied. In this review, we provide evidence for how miRNAs control satellite cell function with emphasis on satellite cells of adult skeletal muscle in vivo. We first outline how miRNAs are indispensable for satellite cell viability and control the phases of myogenesis. Next, we discuss the interplay between miRNAs and myogenic cell redox status, senescence, and communication to other muscle-resident cells during muscle adaptation. Results from recent satellite cell miRNA profiling studies are also summarized. In vitro experiments in primary myogenic cells and cell lines have been invaluable for exploring the influence of miRNAs, but we identify a need for novel genetic tools to further interrogate how miRNAs control satellite cell behavior in adult skeletal muscle in vivo. [Display omitted] • MicroRNAs are essential for the viability and function of myogenic cells. • Strong in vitro evidence for how specific microRNAs control myogenic cell behavior. • Satellite cells communicate in vivo with other cells via exosome-bound microRNAs. • Need for novel tools to study microRNA control of adult muscle satellite cells. [ABSTRACT FROM AUTHOR]

Published

2023

36. miRNA-126a plays important role in myoblast and endothelial cell interaction.

Author

Mierzejewski, Bartosz, Ciemerych, Maria Anna, Streminska, Wladyslawa, Janczyk-Ilach, Katarzyna, and Brzoska, Edyta

Subjects

*ENDOTHELIAL cells, *SATELLITE cells, *CELL migration, *STEM cells, *MUSCLE cells, *MUSCLE regeneration

Abstract

Muscle satellite cells (SCs) are stem cells and the main players in skeletal muscle reconstruction. Since satellite cells are located near or in direct contact with blood vessels their niche is formed, inter alia, by endothelial cells. The cross-talk between satellite cells and endothelial cells determines quiescence or proliferation of these cells. However, little is known about the role of miRNA in these interactions. In the present study we identified miRNA that were up-regulated in SC-derived myoblasts treated with stromal derived factor-1 (SDF-1) and/or down-regulated in cells in which the expression of CXCR4 or CXCR7, that is, SDF-1 receptors, was silenced. SDF-1 is one of the important regulators of cell migration, mobilization, skeletal muscle regeneration, and angiogenesis. We hypothesized that selected miRNAs affect SC-derived myoblast fate and interactions with endothelial cells. We showed that miR-126a-3p inhibited both, myoblast migration and fusion. Moreover, the levels of Cxcl12, encoding SDF-1 and Ackr3, encoding CXCR7, were reduced by miR-126a-3p mimic. Interestingly, the miR-126a-3p mimic significantly decreased the level of numerous factors involved in myogenesis and the miR-126a-5p mimic increased the level of Vefga. Importantly, the treatment of endothelial cells with medium conditioned by miR-126-5p mimic transfected SC-derived myoblasts promoted tubulogenesis. [ABSTRACT FROM AUTHOR]

Published

2023

37. Sox11 is enriched in myogenic progenitors but dispensable for development and regeneration of the skeletal muscle.

Author

Oprescu, Stephanie N., Baumann, Nick, Chen, Xiyue, Sun, Qiang, Zhao, Yu, Yue, Feng, Wang, Huating, and Kuang, Shihuan

Subjects

*SOX transcription factors, *MUSCLE regeneration, *SKELETAL muscle, *SATELLITE cells, *TRANSCRIPTION factors

Abstract

Transcription factors (TFs) play key roles in regulating differentiation and function of stem cells, including muscle satellite cells (MuSCs), a resident stem cell population responsible for postnatal regeneration of the skeletal muscle. Sox11 belongs to the Sry-related HMG-box (SOX) family of TFs that play diverse roles in stem cell behavior and tissue specification. Analysis of single-cell RNA-sequencing (scRNA-seq) datasets identify a specific enrichment of Sox11 mRNA in differentiating but not quiescent MuSCs. Consistent with the scRNA-seq data, Sox11 levels increase during differentiation of murine primary myoblasts in vitro. scRNA-seq data comparing muscle regeneration in young and old mice further demonstrate that Sox11 expression is reduced in aged MuSCs. Age-related decline of Sox11 expression is associated with reduced chromatin contacts within the topologically associating domains. Unexpectedly, Myod1Cre-driven deletion of Sox11 in embryonic myoblasts has no effects on muscle development and growth, resulting in apparently healthy muscles that regenerate normally. Pax7CreER- or Rosa26CreER- driven (MuSC-specific or global) deletion of Sox11 in adult mice similarly has no effects on MuSC differentiation or muscle regeneration. These results identify Sox11 as a novel myogenic differentiation marker with reduced expression in quiescent and aged MuSCs, but the specific function of Sox11 in myogenesis remains to be elucidated. [ABSTRACT FROM AUTHOR]

Published

2023

38. Postnatal skeletal muscle myogenesis governed by signal transduction networks: MAPKs and PI3K–Akt control multiple steps.

Author

Endo, Takeshi

Subjects

*SATELLITE cells, *MYOBLASTS, *CELL cycle proteins, *SKELETAL muscle, *MYOGENESIS, *CELLULAR signal transduction, *WNT signal transduction, *MUSCLE regeneration

Abstract

Skeletal muscle myogenesis represents one of the most intensively and extensively examined systems of cell differentiation, tissue formation, and regeneration. Muscle regeneration provides an in vivo model system of postnatal myogenesis. It comprises multiple steps including muscle stem cell (or satellite cell) quiescence, activation, migration, myogenic determination, myoblast proliferation, myocyte differentiation, myofiber maturation, and hypertrophy. A variety of extracellular signaling and subsequent intracellular signal transduction pathways or networks govern the individual steps of postnatal myogenesis. Among them, MAPK pathways (the ERK, JNK, p38 MAPK, and ERK5 pathways) and PI3K–Akt signaling regulate multiple steps of myogenesis. Ca2+, cytokine, and Wnt signaling also participate in several myogenesis steps. These signaling pathways often control cell cycle regulatory proteins or the muscle-specific MyoD family and the MEF2 family of transcription factors. This article comprehensively reviews molecular mechanisms of the individual steps of postnatal skeletal muscle myogenesis by focusing on signal transduction pathways or networks. Nevertheless, no or only a partial signaling molecules or pathways have been identified in some responses during myogenesis. The elucidation of these unidentified signaling molecules and pathways leads to an extensive understanding of the molecular mechanisms of myogenesis. • Skeletal muscle myogenesis is a representative of cell differentiation, tissue formation, and regeneration systems. • Postnatal myogenesis comprises multiple steps: MuSC activation, determination, proliferation, differentiation, maturation, etc. • A variety of signal transduction networks, including MAPK pathways and PI3K–Akt signaling, govern individual steps of myogenesis. • Elucidation of unidentified signaling pathways leads to a comprehensive understanding of myogenesis. [ABSTRACT FROM AUTHOR]

Published

2023

39. Skeletal muscle regeneration failure in ischemic-damaged limbs is associated with pro-inflammatory macrophages and premature differentiation of satellite cells.

Author

Southerland, Kevin W., Xu, Yueyuan, Peters, Derek T., Lin, Xin, Wei, Xiaolin, Xiang, Yu, Fei, Kaileen, Olivere, Lindsey A., Morowitz, Jeremy M., Otto, James, Dai, Qunsheng, Kontos, Christopher D., and Diao, Yarui

Subjects

*SATELLITE cells, *MUSCLE regeneration, *CELL differentiation, *SKELETAL muscle, *PERIPHERAL vascular diseases, *CELL communication, *MACROPHAGES

Abstract

Background: Chronic limb-threatening ischemia (CLTI), a severe manifestation of peripheral arterial disease (PAD), is associated with a 1-year limb amputation rate of approximately 15–20% and substantial mortality. A key feature of CLTI is the compromised regenerative ability of skeletal muscle; however, the mechanisms responsible for this impairment are not yet fully understood. In this study, we aim to delineate pathological changes at both the cellular and transcriptomic levels, as well as in cell–cell signaling pathways, associated with compromised muscle regeneration in limb ischemia in both human tissue samples and murine models of CLTI. Methods: We performed single-cell transcriptome analysis of ischemic and non-ischemic muscle from the same CLTI patients and from a murine model of CLTI. In both datasets, we analyzed gene expression changes in macrophage and muscle satellite cell (MuSC) populations as well as differential cell–cell signaling interactions and differentiation trajectories. Results: Single-cell transcriptomic profiling and immunofluorescence analysis of CLTI patient skeletal muscle demonstrated that ischemic-damaged tissue displays a pro-inflammatory macrophage signature. Comparable results were observed in a murine CLTI model. Moreover, integrated analyses of both human and murine datasets revealed premature differentiation of MuSCs to be a key feature of failed muscle regeneration in the ischemic limb. Furthermore, in silico inferences of intercellular communication and in vitro assays highlight the importance of macrophage-MuSC signaling in ischemia induced muscle injuries. Conclusions: Collectively, our research provides the first single-cell transcriptome atlases of skeletal muscle from CLTI patients and a murine CLTI model, emphasizing the crucial role of macrophages and inflammation in regulating muscle regeneration in CLTI through interactions with MuSCs. [ABSTRACT FROM AUTHOR]

Published

2023

40. Intravital microscopy of satellite cell dynamics and their interaction with myeloid cells during skeletal muscle regeneration.

Author

Yingzhu He, Youshan Heng, Zhongya Qin, Xiuqing Wei, Zhenguo Wu, and Jianan Qu

Subjects

*SATELLITE cells, *MYELOID cells, *MUSCLE regeneration, *SKELETAL muscle, *CELL size, *CELL anatomy

Abstract

The article focuses on studying the interaction between muscle satellite cells (MuSC) and myeloid cells during skeletal muscle regeneration, utilizing a dual-laser multimodal nonlinear optical microscope. Topics discussed include the transient nature of cell-cell contact between these cell types, reduced infiltration of neutrophils and macrophages during MuSC activation, and the role of macrophages in MuSC proliferation.

Published

2023

41. Pax7 haploinsufficiency impairs muscle stem cell function in Cre-recombinase mice and underscores the importance of appropriate controls.

Author

Mademtzoglou, Despoina, Geara, Perla, Mourikis, Philippos, and Relaix, Frederic

Subjects

*STEM cells, *CELL physiology, *MUSCLE cells, *STEM cell research, *MUSCLE regeneration, *MUSCLE growth

Abstract

Ever since its introduction as a genetic tool, the Cre-lox system has been widely used for molecular genetic studies in vivo in the context of health and disease, as it allows time- and cell-specific gene modifications. However, insertion of the Cre-recombinase cassette in the gene of interest can alter transcription, protein expression, or function, either directly, by modifying the landscape of the locus, or indirectly, due to the lack of genetic compensation or by indirect impairment of the non-targeted allele. This is sometimes the case when Cre-lox is used for muscle stem cell studies. Muscle stem cells are required for skeletal muscle growth, regeneration and to delay muscle disease progression, hence providing an attractive model for stem cell research. Since the transcription factor Pax7 is specifically expressed in all muscle stem cells, tamoxifen-inducible Cre cassettes (CreERT2) have been inserted into this locus by different groups to allow targeted gene recombination. Here we compare the two Pax7-CreERT2 mouse lines that are mainly used to evaluate muscle regeneration and development of pathological features upon deletion of specific factors or pathways. We applied diverse commonly used tamoxifen schemes of CreERT2 activation, and we analyzed muscle repair after cardiotoxin-induced injury. We show that consistently the Pax7-CreERT2 allele targeted into the Pax7 coding sequence (knock-in/knock-out allele) produces an inherent defect in regeneration, manifested as delayed post-injury repair and reduction in muscle stem cell numbers. In genetic ablation studies lacking proper controls, this inherent defect could be misinterpreted as being provoked by the deletion of the factor of interest. Instead, using an alternative Pax7-CreERT2 allele that maintains bi-allelic Pax7 expression or including appropriate controls can prevent misinterpretation of experimental data. The findings presented here can guide researchers establish appropriate experimental design for muscle stem cell genetic studies. [ABSTRACT FROM AUTHOR]

Published

2023

42. Rab44 deficiency accelerates recovery from muscle damage by regulating mTORC1 signaling and transport of fusogenic regulators.

Author

Oyakawa, Shun, Yamaguchi, Yu, Kadowaki, Tomoko, Sakai, Eiko, Noguromi, Mayuko, Tanimoto, Ayuko, Ono, Yusuke, Murata, Hiroshi, and Tsukuba, Takayuki

Subjects

*SATELLITE cells, *MEMBRANE proteins, *SKELETAL muscle, *CHIMERIC proteins, *GUANOSINE triphosphatase, *CELLULAR signal transduction, *MUSCLE regeneration

Abstract

The skeletal muscle is a tissue that shows remarkable plasticity to adapt to various stimuli. The development and regeneration of skeletal muscles are regulated by numerous molecules. Among these, we focused on Rab44, a large Rab GTPase, that has been recently identified in immune cells and osteoclasts. Recently, bioinformatics data has revealed that Rab44 is upregulated during the myogenic differentiation of myoblasts into myotubes in C2C12 cells. Thus, Rab44 may be involved in myogenesis. Here, we have investigated the effects of Rab44 deficiency on the development and regeneration of skeletal muscle in Rab44 knockout (KO) mice. Although KO mice exhibited body and muscle weights similar to those of wild‐type (WT) mice, the histochemical analysis showed that the myofiber cross‐sectional area (CSA) of KO mice was significantly smaller than that of WT mice. Importantly, the results of muscle regeneration experiments using cardiotoxin revealed that the CSA of KO mice was significantly larger than that of WT mice, suggesting that Rab44 deficiency promotes muscle regeneration. Consistent with the in vivo results, in vitro experiments indicated that satellite cells derived from KO mice displayed enhanced proliferation and differentiation. Mechanistically, KO satellite cells exhibited an increased mechanistic target of rapamycin complex 1 (mTORC1) signaling compared to WT cells. Additionally, enhanced cell surface transport of myomaker and myomixer, which are essential membrane proteins for myoblast fusion, was observed in KO satellite cells compared to WT cells. Therefore, Rab44 deficiency enhances muscle regeneration by modulating the mTORC1 signaling pathway and transport of fusogenic regulators. [ABSTRACT FROM AUTHOR]

Published

2023

43. FKBP25 regulates myoblast viability and migration and is differentially expressed in in vivo models of muscle adaptation.

Author

Cree, Tabitha, Gomez, Tania Ruz, Timpani, Cara A., Rybalka, Emma, Price, John T., and Goodman, Craig A.

Subjects

*SKELETAL muscle, *DUCHENNE muscular dystrophy, *CELL cycle, *PEPTIDYLPROLYL isomerase, *CELL migration, *SATELLITE cells, *MUSCLE regeneration

Abstract

FKBP25 (FKBP3 gene) is a dual‐domain PPIase protein that consists of a C‐terminal PPIase domain and an N‐terminal basic tilted helix bundle (BTHB). The PPIase domain of FKBP25 has been shown to bind to microtubules, which has impacts upon microtubule polymerisation and cell cycle progression. Using quantitative proteomics, it was recently found that FKBP25 was expressed in the top 10% of the mouse skeletal muscle proteome. However, to date there have been few studies investigating the role of FKBP25 in non‐transformed systems. As such, this study aimed to investigate potential roles for FKBP25 in myoblast viability, migration and differentiation and in adaptation of mature skeletal muscle. Doxycycline‐inducible FKBP25 knockdown in C2C12 myoblasts revealed an increase in cell accumulation/viability and migration in vitro that was independent of alterations in tubulin dynamics; however, FKBP25 knockdown had no discernible impact on myoblast differentiation into myotubes. Finally, a series of in vivo models of muscle adaptation were assessed, where it was observed that FKBP25 protein expression was increased in hypertrophy and regeneration conditions (chronic mechanical overload and the mdx model of Duchenne muscular dystrophy) but decreased in an atrophy model (denervation). Overall, the findings of this study establish FKBP25 as a regulator of myoblast viability and migration, with possible implications for satellite cell proliferation and migration and muscle regeneration, and as a potential regulator of in vivo skeletal muscle adaptation. [ABSTRACT FROM AUTHOR]

Published

2023

44. Influence of sexual dimorphism on satellite cell regulation and inflammatory response during skeletal muscle regeneration.

Author

Jomard, Charline and Gondin, Julien

Subjects

*MUSCLE regeneration, *SKELETAL muscle, *SATELLITE cells, *SEXUAL dimorphism, *CELLULAR control mechanisms, *OVARIAN cancer, *MENSTRUATION disorders

Abstract

After injury, skeletal muscle regenerates thanks to the key role of satellite cells (SC). The regeneration process is supported and coordinated by other cell types among which immune cells. Among the mechanisms involved in skeletal muscle regeneration, a sexual dimorphism, involving sex hormones and more particularly estrogens, has been suggested. However, the role of sexual dimorphism on skeletal muscle regeneration is not fully understood, likely to the use of various experimental settings in both animals and human. This review aims at addressing how sex and estrogens regulate both the SC and the inflammatory response during skeletal muscle regeneration by considering the different experimental designs used in both animal models (i.e., ovarian hormone deficiency, estrogen replacement or supplementation, treatments with estrogen receptors agonists/antagonists and models knockout for estrogen receptors) and human (hormone therapy replacement, pre vs. postmenopausal, menstrual cycle variation...). [ABSTRACT FROM AUTHOR]

Published

2023

45. Angiotensin-(1-7) improves skeletal muscle regeneration.

Author

Valero-Breton, Mayalen, Tacchi, Franco, Abrigo, Johanna, Simon, Felipe, Cabrera, Daniel, and Cabello-Verrugio, Claudio

Subjects

*MUSCLE regeneration, *SKELETAL muscle, *MUSCULAR dystrophy, *ANGIOTENSIN II, *SATELLITE cells

Abstract

Skeletal muscle possesses regenerative potential via satellite cells, compromised in muscular dystrophies leading to fibrosis and fat infiltration. Angiotensin II (Ang-II) is commonly associated with pathological states. In contrast, Angiotensin (1-7) [Ang-(1-7)] counters Ang-II, acting via the Mas receptor. While Ang-II affects skeletal muscle regeneration, the influence of Ang-(1-7) remains to be elucidated. Therefore, this study aims to investigate the role of Ang-(1- 7) in skeletal muscle regeneration. C2C12 cells were differentiated in the absence or presence of 10 nM of Ang-(1-7). The diameter of myotubes and protein levels of myogenin and myosin heavy chain (MHC) were determined. C57BL/6 WT male mice 16-18 weeks old) were randomly assigned to injury-vehicle, injury-Ang-(1-7), and control groups. Ang-(1-7) was administered via osmotic pumps, and muscle injury was induced by injecting barium chloride to assess muscle regeneration through histological analyses. Moreover, embryonic myosin (eMHC) and myogenin protein levels were evaluated. C2C12 myotubes incubated with Ang-(1-7) showed larger diameters than the untreated group and increased myogenin and MHC protein levels during differentiation. Ang-(1-7) administration enhances regeneration by promoting a larger diameter of new muscle fibers. Furthermore, higher numbers of eMHC (+) fibers were observed in the injured-Ang-(1-7), which also had a larger diameter. Moreover, eMHC and myogenin protein levels were elevated, supporting enhanced regeneration due to Ang-(1-7) administration. Ang-(1-7) effectively promotes differentiation in vitro and improves muscle regeneration in the context of injuries, with potential implications for treating muscle-related disorders. [ABSTRACT FROM AUTHOR]

Published

2023

46. Muscle stem cells contribute to long‐term tissue repletion following surgical sepsis

Author

Rebecca E. Schmitt, Aneesha Dasgupta, Paige C. Arneson‐Wissink, Srijani Datta, Alexandra M. Ducharme, and Jason D. Doles

Subjects

sepsis, muscle stem cells, satellite cells, muscle wasting, skeletal muscle, muscle regeneration, Diseases of the musculoskeletal system, RC925-935, Human anatomy, QM1-695

Abstract

Abstract Background Over the past decade, advances in sepsis identification and management have resulted in decreased sepsis mortality. This increase in survivorship has highlighted a new clinical obstacle: chronic critical illness (CCI), for which there are no effective treatment options. Up to half of sepsis survivors suffer from CCI, which can include multi‐organ dysfunction, chronic inflammation, muscle wasting, physical and mental disabilities, and enhanced frailty. These symptoms prevent survivors from returning to regular day‐to‐day activities and are directly associated with poor quality of life. Methods Mice were subjected to cecal ligation and puncture (CLP) with daily chronic stress (DCS) as an in vivo model to study sepsis late‐effects/sequelae on skeletal muscle components. Longitudinal monitoring was performed via magnetic resonance imaging, skeletal muscle and/or muscle stem cell (MuSCs) assays (e.g., post‐necropsy wet muscle weights, minimum Feret diameter measurements, in vitro MuSC proliferation and differentiation, number of regenerating myofibres and numbers of Pax7‐positive nuclei per myofibre), post‐sepsis whole muscle metabolomics and MuSC isolation and high‐content transcriptional profiling. Results We report several findings supporting the hypothesis that MuSCs/muscle regeneration are critically involved in post‐sepsis muscle recovery. First, we show that genetic ablation of muscle stem cells (MuSCs) impairs post‐sepsis muscle recovery (maintenance of 5–8% average lean mass loss compared with controls). Second, we observe impaired MuSCs expansion capacity and morphological defects at 26 days post‐sepsis compared with control MuSCs (P

Published

2023

47. Aging of the immune system and impaired muscle regeneration: A failure of immunomodulation of adult myogenesis

Author

Tidball, James G, Flores, Ivan, Welc, Steven S, Wehling-Henricks, Michelle, and Ochi, Eisuke

Subjects

Medical Physiology, Biomedical and Clinical Sciences, Aging, Regenerative Medicine, Stem Cell Research - Nonembryonic - Non-Human, Stem Cell Research - Embryonic - Non-Human, Stem Cell Research, 2.1 Biological and endogenous factors, Underpinning research, 1.1 Normal biological development and functioning, Aetiology, Musculoskeletal, Inflammatory and immune system, Immunomodulation, Muscle Development, Muscle, Skeletal, Regeneration, Satellite Cells, Skeletal Muscle, Skeletal muscle, Muscle injury, Muscle inflammation, Muscle regeneration, Medical and Health Sciences, Gerontology, Biomedical and clinical sciences, Health sciences

Abstract

Skeletal muscle regeneration that follows acute injury is strongly influenced by interactions with immune cells that invade and proliferate in the damaged tissue. Discoveries over the past 20 years have identified many of the key mechanisms through which myeloid cells, especially macrophages, regulate muscle regeneration. In addition, lymphoid cells that include CD8+ T-cells and regulatory T-cells also significantly affect the course of muscle regeneration. During aging, the regenerative capacity of skeletal muscle declines, which can contribute to progressive loss of muscle mass and function. Those age-related reductions in muscle regeneration are accompanied by systemic, age-related changes in the immune system, that affect many of the myeloid and lymphoid cell populations that can influence muscle regeneration. In this review, we present recent discoveries that indicate that aging of the immune system contributes to the diminished regenerative capacity of aging muscle. Intrinsic, age-related changes in immune cells modify their expression of factors that affect the function of a population of muscle stem cells, called satellite cells, that are necessary for normal muscle regeneration. For example, age-related reductions in the expression of growth differentiation factor-3 (GDF3) or CXCL10 by macrophages negatively affect adult myogenesis, by disrupting regulatory interactions between macrophages and satellite cells. Those changes contribute to a reduction in the numbers and myogenic capacity of satellite cells in old muscle, which reduces their ability to restore damaged muscle. In addition, aging produces changes in the expression of molecules that regulate the inflammatory response to injured muscle, which also contributes to age-related defects in muscle regeneration. For example, age-related increases in the production of osteopontin by macrophages disrupts the normal inflammatory response to muscle injury, resulting in regenerative defects. These nascent findings represent the beginning of a newly-developing field of investigation into mechanisms through which aging of the immune system affects muscle regeneration.

Published

2021

48. ATF3 induction prevents precocious activation of skeletal muscle stem cell by regulating H2B expression.

Author

Zhang, Suyang, Yang, Feng, Huang, Yile, He, Liangqiang, Li, Yuying, Wan, Yi Ching Esther, Ding, Yingzhe, Chan, Kui Ming, Xie, Ting, Sun, Hao, and Wang, Huating

Subjects

STEM cells, SKELETAL muscle, MUSCLE cells, MUSCLE regeneration, SATELLITE cells, CELL cycle, SUPERIOR colliculus

Abstract

Skeletal muscle stem cells (also called satellite cells, SCs) are important for maintaining muscle tissue homeostasis and damage-induced regeneration. However, it remains poorly understood how SCs enter cell cycle to become activated upon injury. Here we report that AP-1 family member ATF3 (Activating Transcription Factor 3) prevents SC premature activation. Atf3 is rapidly and transiently induced in SCs upon activation. Short-term deletion of Atf3 in SCs accelerates acute injury-induced regeneration, however, its long-term deletion exhausts the SC pool and thus impairs muscle regeneration. The Atf3 loss also provokes SC activation during voluntary exercise and enhances the activation during endurance exercise. Mechanistically, ATF3 directly activates the transcription of Histone 2B genes, whose reduction accelerates nucleosome displacement and gene transcription required for SC activation. Finally, the ATF3-dependent H2B expression also prevents genome instability and replicative senescence in SCs. Therefore, this study has revealed a previously unknown mechanism for preserving the SC population by actively suppressing precocious activation, in which ATF3 is a key regulator. Muscle regeneration relies on activation and expansion of skeletal muscle stem cells. Here, authors show that ATF3 induction prevents precocious activation of skeletal muscle stem cells by binding and promoting the transcription of Histone2B. [ABSTRACT FROM AUTHOR]

Published

2023

49. Injury-experienced satellite cells retain long-term enhanced regenerative capacity.

Author

Morroni, Jacopo, Benedetti, Anna, Esposito, Lorenza, De Bardi, Marco, Borsellino, Giovanna, Riera, Carles Sanchez, Giordani, Lorenzo, Bouche, Marina, and Lozanoska-Ochser, Biliana

Subjects

*SATELLITE cells, *MUSCLE regeneration, *SKELETAL muscle injuries, *INFLAMMATORY mediators, *MUSCLE injuries, *CELL cycle, *MUSCLE cells

Abstract

Background: Inflammatory memory or trained immunity is a recently described process in immune and non-immune tissue resident cells, whereby previous exposure to inflammation mediators leads to a faster and stronger responses upon secondary challenge. Whether previous muscle injury is associated with altered responses to subsequent injury by satellite cells (SCs), the muscle stem cells, is not known. Methods: We used a mouse model of repeated muscle injury, in which intramuscular cardiotoxin (CTX) injections were administered 50 days apart in order to allow for full recovery of the injured muscle before the second injury. The effect of prior injury on the phenotype, proliferation and regenerative potential of satellite cells following a second injury was examined in vitro and in vivo by immunohistochemistry, RT-qPCR and histological analysis. Results: We show that SCs isolated from muscle at 50 days post-injury (injury-experienced SCs (ieSCs)) enter the cell cycle faster and form bigger myotubes when cultured in vitro, compared to control SCs isolated from uninjured contralateral muscle. Injury-experienced SCs were characterized by the activation of the mTORC 1 signaling pathway, suggesting they are poised to activate sooner following a second injury. Consequently, upon second injury, SCs accumulate in greater numbers in muscle at 3 and 10 days after injury. These changes in SC phenotype and behavior were associated with accelerated muscle regeneration, as evidenced by an earlier appearance of bigger fibers and increased number of myonuclei per fiber at day 10 after the second injury. Conclusions: Overall, we show that skeletal muscle injury has a lasting effect on SC function priming them to respond faster to a subsequent injury. The ieSCs have long-term enhanced regenerative properties that contribute to accelerated regeneration following a secondary challenge. [ABSTRACT FROM AUTHOR]

Published

2023

50. The aminopeptidase LAP3 suppression accelerates myogenic differentiation via the AKT‐TFE3 pathway in C2C12 myoblasts.

Author

Osana, Shion, Kitajima, Yasuo, Naoki, Suzuki, Murayama, Kazutaka, Takada, Hiroaki, Tabuchi, Ayaka, Kano, Yutaka, and Nagatomi, Ryoichi

Subjects

*MYOBLASTS, *SATELLITE cells, *MUSCLE cells, *STEM cells, *MUSCLE growth, *MUSCLE regeneration

Abstract

Skeletal muscle maintenance depends largely on muscle stem cells (satellite cells) that supply myoblasts required for muscle regeneration and growth. The ubiquitin–proteasome system is the major intracellular protein degradation pathway. We previously reported that proteasome dysfunction in skeletal muscle significantly impairs muscle growth and development. Furthermore, the inhibition of aminopeptidase, a proteolytic enzyme that removes amino acids from the termini of peptides derived from proteasomal proteolysis, impairs the proliferation and differentiation ability of C2C12 myoblasts. However, no evidence has been reported on the role of aminopeptidases with different substrate specificities on myogenesis. In this study, therefore, we investigated whether the knockdown of aminopeptidases in differentiating C2C12 myoblasts affects myogenesis. The knockdown of the X‐prolyl aminopeptidase 1, aspartyl aminopeptidase, leucyl‐cystinyl aminopeptidase, methionyl aminopeptidase 1, methionyl aminopeptidase 2, puromycine‐sensitive aminopeptidase, and arginyl aminopeptidase like 1 gene in C2C12 myoblasts resulted in defective myogenic differentiation. Surprisingly, the knockdown of leucine aminopeptidase 3 (LAP3) in C2C12 myoblasts promoted myogenic differentiation. We also found that suppression of LAP3 expression in C2C12 myoblasts resulted in the inhibition of proteasomal proteolysis, decreased intracellular branched‐chain amino acid levels, and enhanced mTORC2‐mediated AKT phosphorylation (S473). Furthermore, phosphorylated AKT induced the translocation of TFE3 from the nucleus to the cytoplasm, promoting myogenic differentiation through increased expression of myogenin. Overall, our study highlights the association of aminopeptidases with myogenic differentiation. [ABSTRACT FROM AUTHOR]

Published

2023