Myoblast Differentiation Research Articles

Revitalizing Muscle Regeneration: Cocoa Polyphenols Shield Mitochondrial Integrity and Boost Myogenesis Under Oxidative Stress.

In this study, we describe the effect of cocoa polyphenol extract (CPE, from flavanols-rich cocoa) on myogenic differentiation in murine myoblasts (C2C12 cells) exposed to H2O2. The myogenic program was monitored using morphological, ultrastructural, and molecular approaches. Treatment with 100 μM of H2O2 for 1 h decreased cell viability. C2C12 (D1) exposed to H2O2 shows more apoptotic and necrotic cells, and mitochondria appear emptied, with cristae heavily damaged. To evaluate the effect of CPE on myoblast viability and myotube formation, 10 μg/mL of CPE were added 24 h prior to H2O2 treatment and cells were supplemented with fresh CPE every 24 h during differentiation. Supplementation with CPE protected C2C12 myoblasts from H2O2-induced oxidative damage both at early (D1) and late (D6) phases of differentiation, preventing cell death and mitochondrial damage. The number of mitochondria (per area of cell surface) increased 2-fold in both control and in CPE-supplemented and mitochondria in myotubes D6 showed a greater extension of mitochondrial cristae than mitochondria in D1. At D1 and D6 the monolayers showed surface and inner cell features relatively comparable to the untreated control suggesting that CPE supplementation significantly mitigated the effect of H2O2. Preliminary data obtained by the myogenic index (Giemsa staining) suggested that CPE-supplemented cells were partially protected from H2O2-induced myogenesis inhibition. The CPE supplementation seems to preserve the mitochondrial integrity and the myogenic differentiation ability of oxidatively injured C2C12 ensuing further nutraceutical perspectives.

The Hox protein Antennapedia orchestrates Drosophila adult flight muscle development.

Muscle development and diversity require a large number of spatially and temporally regulated events controlled by transcription factors (TFs). Drosophila has long stood as a model to study myogenesis due to the highly conserved key TFs involved at all stages of muscle development. While many studies focused on the diversification of Drosophila larval musculature, how distinct adult muscle types are generated is much less characterized. Here, we identify an essential regulator of Drosophila thoracic flight muscle development, the Hox TF Antennapedia (Antp). Correcting a long-standing belief that flight muscle development occurs without the input of Hox TFs, we show that Antp intervenes at several stages of flight muscle development, from the establishment of the progenitor pool in the embryo to myoblast differentiation in the early pupa. Furthermore, the precisely regulated clearance of Hox in the developing flight muscle fibers is required to allow for fibrillar muscle fate diversification, setting these muscles apart from all other adult tubular muscle types.

Development of a Myogenin minimal promoter-based system for visualizing the degree of myogenic differentiation

Myogenic differentiation plays a fundamental role in myogenesis during development and in muscle regeneration. Sequential expression of myogenic regulatory factors (MRFs) including myogenin in the progenitor cells triggers the expression of effector proteins such as myosin heavy chain (MHC), leading to the terminal muscle differentiation. Although we have a snapshot-like understanding of molecules at each stage of the differentiation, how these molecules are interrelated in the continuum of myogenic differentiation remains poorly understood. In this study, we analyzed the dynamics of the minimal Myogenin promoter activity in live myoblasts. With the development of a new co-expression analysis method, we were able to reveal in detail the relationship between this Myogenin promoter activity and the expression of endogenous myogenin or MHC, as differentiation markers. Consequently, we found that our visualization system of myogenic differentiation is suitable for monitoring the transition from myoblasts to myotubes, in which the Myogenin promoter activity quantitatively represents the degree of myogenic differentiation. Thus, this system allows simultaneous observation of the degree of myoblast differentiation in relation to other molecules, which would contribute to deepening our understanding of myogenic differentiation as a continuous process.

Exploring Gene Expression and Alternative Splicing in Duck Embryonic Myoblasts via Full-Length Transcriptome Sequencing

The duck industry is vital for supplying high-quality protein, making research into the development of duck skeletal muscle critical for improving meat and egg production. In this study, we leveraged Oxford Nanopore Technologies (ONT) sequencing to perform full-length transcriptome sequencing of myoblasts harvested from the leg muscles of duck embryos at embryonic day 13 (E13), specifically examining both the proliferative (GM) and differentiation (DM) phases. Our analysis identified a total of 5797 novel transcripts along with 2332 long non-coding RNAs (lncRNAs), revealing substantial changes in gene expression linked to muscle development. We detected 3653 differentially expressed genes and 2246 instances of alternative splicing, with key genes involved in essential pathways, such as ECM–receptor interaction and Notch signaling, prominently featured. Additionally, we constructed a protein–protein interaction network that highlighted critical regulators—MYOM3, MYL2, MYL1, TNNI2, and ACTN2—associated with the processes of proliferation and differentiation in myoblasts. This extensive transcriptomic investigation not only sheds light on the intricate molecular mechanisms driving skeletal muscle development in ducks but also provides significant insights for future breeding strategies aimed at enhancing the efficiency of duck production. The results emphasize the efficacy of ONT sequencing in uncovering complex regulatory networks within avian species, ultimately contributing to progress in animal husbandry.

Lnc-MEG8 regulates yak myoblast differentiation via the miR-22-3p/RTL1 axis

BackgroundThe yak (Bos grunniens) is essential to the livelihoods of Tibetan people on the Qinghai-Tibet Plateau; however, its growth and productivity are constrained by the region's harsh climate and high altitude. Yak skeletal muscle myoblasts, which have evolved to thrive under these challenging conditions, offer a valuable model for investigating muscle development. In this study, we performed transcriptome profiling of yak longissimus dorsi muscle at different growth stages, identifying a key long non-coding RNA, LncRNA-XR_314844 (Lnc-MEG8), with a potential role in muscle development.ResultsWe developed a novel technique to isolate high-quality yak myoblasts, enabling detailed analysis of Lnc-MEG8. Our results indicated that Lnc-MEG8's subcellular localization varies during muscle cell growth: it is found in both the nucleus and cytoplasm during proliferation but shifts mainly to the cytoplasm during differentiation. Functional experiments showed that Lnc-MEG8 promotes cell proliferation and inhibits differentiation, while its silencing had the opposite effect. Further analysis revealed that both Lnc-MEG8 and the gene RTL1 share miR-22-3p as a common target. Dual-luciferase assays confirmed miR-22-3p directly targets both Lnc-MEG8 and RTL1 mRNA. Co-transfection of Lnc-MEG8 and a miR-22-3p mimic restored RTL1 expression, highlighting Lnc-MEG8's regulatory role. Lnc-MEG8 also counteracts miR-22-3p's suppression of key muscle genes such as MyF5 and MyoG, facilitating myotube formation.ConclusionThese findings demonstrate that the Lnc-MEG8-miR-22-3p-RTL1 axis plays a crucial role in yak muscle development, providing insights that could advance muscle tissue engineering and enhance yak meat quality.

Phytol and bilimbi phytocompounds induce thermogenic adipocyte differentiation: An in vitro study on potential anti-obesity effects

BackgroundObesity is a major health concern associated to diabetes, cardiovascular disease, and cancer. Brown adipocytes, which specialise in thermogenesis, offer a potential therapeutic target for obesity prevention and related conditions. This study builds on previous findings of the browning activity of Averrhoa bilimbi hexane fractions and aims to elucidate the underlying mechanisms in vitro. Squalene and phytol, key phytocompounds from bilimbi leaf extract and fractions, were assessed for their ability to induce thermogenic adipocyte using 3T3-L1 preadipocytes and C2C12 myoblasts in vitro models. The result shows that bilimbi fractions F7, F8, and F9, along with squalene and phytol, effectively induced thermogenic adipocyte differentiation. This was evidenced by the upregulation of key markers, including Ucp1, Prdm16, and Pgc1α, and increased expression of the brown adipocyte-specific protein CIDEA in treated 3T3-L1 preadipocytes. Notably, all treatments promoted thermogenic adipocytes differentiation in C2C12 myoblasts via the upregulation of Pgc1α, Ucp1 genes, and UCP1 protein. These findings suggest that bilimbi fractions and its phytocompounds may hold potential as nutraceutical interventions for obesity management.

FNDC1 is a myokine that promotes myogenesis and muscle regeneration.

Myogenesis is essential for skeletal muscle formation and regeneration after injury, yet its regulators are largely unknown. Here we identified fibronectin type III domain containing 1 (FNDC1) as a previously uncharacterized myokine. In vitro studies showed that knockdown of Fndc1 in myoblasts reduces myotube formation, while overexpression of Fndc1 promotes myogenic differentiation. We further generated recombinant truncated mouse FNDC1 (mFNDC1), which retains reliable activity in promoting myoblast differentiation in vitro. Gain- and loss-of-function studies collectively showed that FNDC1 promotes cardiotoxin (CTX)-induced muscle regeneration in adult mice. Furthermore, recombinant FNDC1 treatment ameliorated pathological muscle phenotypes in the mdx mouse model of Duchenne muscular dystrophy. Mechanistically, FNDC1 bound to the integrin α5β1 and activated the downstream FAK/PI3K/AKT/mTOR pathway to promote myogenic differentiation. Pharmacological inhibition of integrin α5β1 or of the downstream FAK/PI3K/AKT/mTOR pathway abolished the pro-myogenic effect of FNDC1. Collectively, these results suggested that myokine FNDC1 might be used as a therapeutic agent to regulate myogenic differentiation and muscle regeneration for the treatment of acute and chronic muscle disease.

From antioxidant to muscle enhancer: Resveratrol's role in grass carp (Ctenopharyngodon idella) nutrition

Resveratrol (RES), a type of stilbenoid, is known for its significant role in enhancing meat quality by virtue of activating SIRT1. Against this backdrop, this study explored the impact of resveratrol on various parameters influencing flesh quality in adult grass carp. Over a span of 9 weeks, adult grass carp were fed diets with five different levels of RES (0, 40, 80, 160 and 320 mg/kg). Our findings demonstrated that resveratrol supplementation had no adverse effects on the growth performance of adult grass carp. Notably, adding the right amount of resveratrol to the diets caused the protein and amino acid levels, pH24 h, and shear force of grass carp muscle to rise. Additionally, it led to a reduction in cooking loss and lactic acid content. Moreover, Addition of appropriate levels of resveratrol to the feed promoted myofiber hyperplasia in adult grass carp, which may be achieved by stimulating adult myoblast proliferation and differentiation. Subsequent studies have found that appropriate levels of resveratrol inhibit endoplasmic reticulum stress (ERS), which promotes muscle fiber development. Additionally, resveratrol was found to lead to an increase in unsaturated fatty acid (UFA) content in grass carp muscle. This alteration in fatty acid composition could be attributed to changes in fatty acid transport, synthesis, and catabolism. According to muscle protein carbonyl level, muscle protein content and frequency of muscle fibers smaller than 20 μm, the optimum resveratrol supplementations of grass carp were 178.33, 198.33 and 226.67 mg/kg.

EGR1 mRNA expression levels and polymorphisms are associated with slaughter performance in chickens

With the implementation of the policy of “centralized slaughtering and chilled to market” and the development of the livestock processing industry, numerous researchers have begun to focus on the selection and breeding of broilers bred for slaughter. The selection of breeds with excellent slaughtering performance and high meat production performance has become one of the most important selective breeding goals. In our previous study, we conducted transcriptome sequencing on chicken breast tissues with high and low breast muscle rates and found higher early growth response protein 1 (EGR1) expression in breast tissues with a low breast muscle ratio, thus hypothesizing that the EGR1 gene is involved in the growth and development process of chicken muscle tissues. Therefore, we analyzed the gene functions and polymorphisms of EGR1 to investigate its association with slaughter traits. We used various experimental methods, including RT-qPCR, Cell Counting Kit 8, 5-ethynyl-2′-deoxyuridine, western blot, flow cytometry, and immunofluorescence, to validate EGR1’s role in chicken primary myoblasts. The results of our functional validation experiments indicate that EGR1 is highly expressed in breast tissues with a low breast muscle content and plays a key role in regulating of muscle growth and development by promoting proliferation and inhibiting the differentiation of chicken primary myoblasts. In addition, we explored the relationship between the EGR1 gene polymorphisms and slaughter traits using mixed linear models for the first time. In a population of Jiangfeng M3 lineage partridge chickens, we identified 4 EGR1 single-nucleotide polymorphisms, 2 of which were significantly associated with slaughter traits, including live weight, slaughter weight, semi-eviscerated weight, eviscerated weight, leg weight, wing weight, and breast muscle rate. In summary, ectopic expression of EGR1 promotes the proliferation and differentiation of chicken primary myoblasts. In addition, polymorphisms in EGR1 were associated with slaughter performance, providing a potential basis for further utilization of EGR1 as a breeding marker.

CircRNA profiling of skeletal muscle satellite cells in goats reveals circTGFβ2 promotes myoblast differentiation

BackgroundCircular RNAs (circRNAs) function as essential regulatory elements with pivotal roles in various biological processes. However, their expression profiles and functional regulation during the differentiation of goat myoblasts have not been thoroughly explored. This study conducts an analysis of circRNA expression profiles during the proliferation phase (cultured in growth medium, GM) and differentiation phase (cultured in differentiation medium, DM1/DM5) of skeletal muscle satellite cells (MuSCs) in goats.ResultsA total of 2,094 circRNAs were identified, among which 84 were differentially expressed as determined by pairwise comparisons across three distinct groups. Validation of the expression levels of six randomly selected circRNAs was performed using reverse transcription PCR (RT-PCR) and quantitative RT-PCR (qRT-PCR), with confirmation of their back-splicing junction sites. Enrichment analysis of the host genes associated with differentially expressed circRNAs (DEcircRNAs) indicated significant involvement in biological processes such as muscle contraction, muscle hypertrophy, and muscle tissue development. Additionally, these host genes were implicated in key signaling pathways, including Hippo, TGF-beta, and MAPK pathways. Subsequently, employing Cytoscape, we developed a circRNA-miRNA interaction network to elucidate the complex regulatory mechanisms underlying goat muscle development, encompassing 21 circRNAs and 47 miRNAs. Functional assays demonstrated that circTGFβ2 enhances myogenic differentiation in goats, potentially through a miRNA sponge mechanism.ConclusionIn conclusion, we identified the genome-wide expression profiles of circRNAs in goat MuSCs during both proliferation and differentiation phases, and established that circTGFβ2 plays a role in the regulation of myogenesis. This study offers a significant resource for the advanced exploration of the biological functions and mechanisms of circRNAs in the myogenesis of goats.

Regulatory effects of yam (Dioscorea opposita Thunb.) glycoprotein on energy metabolism in C2C12 and 3T3-L1 cells and on crosstalk between these two cells

Ethnopharmacological relevanceControlling energy and regulating metabolism have been key strategies in the treatment of metabolic disorders such as obesity. Yam glycoprotein (Y-Gly) is a polysaccharide-protein complex extracted from Chinese yam that has beneficial effects on glucose and lipid metabolism. This study aimed to investigate the role of Y-Gly in regulating energy metabolism in C2C12 and 3T3-L1 cells. Materials and methodsY-Gly was subjected to extraction and chemo-profiling. Staining methods, assay kits, Western Blot and transcriptomics were mainly used to determine the role of Y-Gly. Additionally, the study sought to examine the impact of Y-Gly on white adipose browning in 3T3-L1 cells, employing a cell co-culture technique. ResultsY-Gly promoted myotube differentiation in C2C12 myoblasts, increased cellular glucose consumption, promoted ATP synthesis and mitochondrial biogenesis, and played an active role in energy expenditure and glycolipid metabolism related pathways such as AMPK and MAPK. The introduction of Y-Gly inhibited lipid accumulation after lipogenesis in 3T3-L1 cells, facilitated induction of white adipose browning related proteins such as PPARγ and UCP1 expression, and the effect was more significant after cell co-culture. ConclusionsY-Gly regulates glucose and lipid metabolism by activating the key proteins in the aforementioned pathways, and plays a role in energy metabolism regulation through crosstalk between muscle and adipose tissues. This suggests a possible role of Y-Gly in metabolism-related diseases.

Identification of genetic variants associated with exercise-induced atrial fibrillation in high-performing racehorses

Abstract Background Atrial fibrillation (AF) is the most common cardiac arrhythmia in athletes. Despite a lower burden of classical cardiovascular risk factors, the prevalence of AF in athletes is comparable to that in the general population of similar age (~13%, mean age 65.5), suggesting that exercise-induced AF may have different underlying mechanisms. The prevalence of AF in thoroughbred (TB) and standardbred (STB) racehorses is also relatively high (~5%), suggesting exercise as an independent risk factor. Due to selective breeding and complete control of pedigrees, racehorses are well-suited for genetic studies. Common and rare genetic variation explain a substantial part of AF variance, but no study has identified genetic variants associated with exercise-induced AF in any species. Objective In this project, we aimed to use the racehorse as a model to identify genetic variants associated with exercise-induced AF, and in a future study, possibly replicate the results in human athletes. Here we present preliminary results from the genome-wide association study (GWAS) of AF in racehorses. Methods We collected blood or hair samples from 181 STB and TB racehorses in which 71 had paroxysmal or persistent AF verified by ECG. We extracted DNA and performed whole-genome genotyping using a commercial equine genotyping platform (670k markers). We phased and imputed un-genotyped markers and increased the sample size of the control group, using publicly available equine data from similar breeds from the European Nucleotide Archive. We conducted a GWAS of 7.85 million markers in 71 cases and 296 controls using PLINK2 with covariates adjusted for population stratification, batch and sex. Results We identified one significant locus downstream of the protocadherin gene PCDH18 associated with AF in racehorses. The same locus has been associated with the ECG-trait P-wave terminal force in humans. Changes in P-wave terminal force is associated with increased atrial size, delayed interatrial conduction, left ventricular fibrosis and left atrial function, and considered a good predictor of AF occurrence. Several non-significant but interesting signals were also identified including the genes SLC6A15 (amino acid transport), MYBPH (myosin binding), MYF6 and MYOG (myoblast differentiation). Conclusion In these preliminary results, we have identified a new genetic locus associated with AF in racehorses. In addition, we have identified several candidate genes for further studies to elucidate the genetic background of exercise-induced AF. We aim to replicate our findings in a population of human athletes. Our results may aid the development of risk prediction tools for exercise-induced AF and new drugs for tailored treatment of AF in general.

Electrospinning Aligned SF/Magnetic Nanoparticles-Blend Nanofiber Scaffolds for Inducing Skeletal Myoblast Alignment and Differentiation.

In the realm of skeletal muscle tissue engineering, anisotropic materials that emulate natural tissues show substantial promise. Electrospun scaffolds, mimicking the fibrillar structure of the extracellular matrix, are commonly employed but often fall short in achieving optimal alignment and mechanical strength. Silk fibroin has emerged as a versatile material in tissue engineering, valued for its biocompatibility, mechanical robustness, and biodegradability. However, conventional electrospinning methods of SF result in randomly oriented fibers, limiting their efficacy. In this work, we developed a straightforward method to fabricate directional tissue scaffolds using silk fibroin. By integrating a magnetic field collecting device and incorporating Fe3O4 nanoparticles into the spinning solution, we successfully produced well-aligned silk nanofiber scaffolds. These aligned fibers not only improved scaffold orientation and mechanical properties but also exhibited magnetic responsiveness. The aligned SF scaffolds effectively guided the adhesion, proliferation, and differentiation of mesenchymal stem cells along the fiber direction. Cultured on these scaffolds, myoblast C2C12 cells demonstrated oriented growth, highlighting the potential of aligned SF fibers in advancing skeletal muscle engineering for biomedical applications.

Interferon-β-Induced Injury During Pediatric Muscle Differentiation: Insight Into Juvenile Dermatomyositis Pathogenesis.

Juvenile dermatomyositis (JDM) involves up-regulated type I interferons (IFNs), including IFNβ, yet pathologic mechanisms remain poorly understood. We aimed to characterize the functional and structural effects of IFNβ on in vitro human pediatric myoblast growth and differentiation in a three-dimensional skeletal muscle model (myobundles). Myobundles fabricated from myoblasts of a healthy pediatric donor were exposed to IFNβ at 0 to 5,600 IU/mL during growth (days 1-4), differentiation (days 4-11), and/or mature (days 11-18) periods. To assess myobundle structure and function, contractile force, kinetics, and fatigue were measured at day 18 with subsequent immunohistochemistry. Myobundles were not functionally affected by IFNβ exposure during growth period alone. However, when IFNβ exposure continued through differentiation, myobundles became dysfunctional (P < 0.0001). IFNβ during differentiation or mature periods alone resulted in dose-dependent decreases in contractility, with greater decrease in the differentiation alone group (P < 0.0001). Twitch kinetics and fatigue remained largely unchanged when myobundles were exposed to IFNβ only during growth, yet twitch time slowed (P < 0.005) and fatigue decreased (P < 0.002) when myobundles were exposed during differentiation or mature stages alone. Nuclei density and myofiber size and organization also decreased when IFNβ was added during differentiation period alone. IFNβ decreases pediatric myobundle contractile function most significantly during differentiation of myoblasts to myotubes. Function is not affected when IFNβ exposure is limited to myoblast proliferation alone. These findings implicate a pathologic role for IFNβ in JDM by impairing myoblast differentiation, leading to subsequent loss of function and ongoing need for muscle regeneration and repair.

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

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/β-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/β-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/β-catenin signaling pathway.

METTL16 inhibits differentiation and promotes proliferation and slow myofibers formation in chicken myoblasts

N6-methyladenosine (m6A) plays a crucial regulatory role in muscle growth and development. In our previous studies, we identified a m6A methyltransferase, Methyltransferase like 16 (METTL16), which is associated with chicken muscle development and muscle fiber type conversion. To further understand the regulatory role of METTL16 in chicken muscle function, we analyzed its expression in muscle tissues with different myofiber type compositions and in chicken primary myoblasts (CPMs) at various stages. We also manipulated METTL16 expression in CPMs to examine its effects on cell proliferation, differentiation, muscle fiber type formation, and global m6A RNA methylation status. Our results showed that METTL16 expression increased during myoblast proliferation and gradually decreased in the late differentiation stage. Furthermore, METTL16 exhibited specific expression in slow-twitch muscles. Cell Counting Kit-8 assays, 5-Ethynyl-2'-deoxyuridine staining, RT-qPCR, Western blot, and immunofluorescence analyses showed that METTL16 promotes myoblast proliferation while inhibiting myoblast differentiation. We also observed that METTL16 induces the upregulation of slow-twitch myosin heavy chain (MyHC) and slow-twitch-specific genes in myotubes, while downregulating fast-twitch MyHC and fast-twitch-specific genes. Furthermore, both interference and overexpression of METTL16 led to changes in overall cellular m6A modification levels and Methyltransferase like 3 (METTL3) expression levels. These findings confirm that METTL16 plays a key role in myoblast proliferation, differentiation, and muscle fiber type formation in chickens. Considering the role of myoblasts in chicken muscle growth and meat quality regulation, METTL16 may serve as a key target for molecular selection in chicken meat traits.

Skeletal muscle-derived exosomes selectively coated miRNAs and participate in myoblast proliferation and differentiation mediated by miR-4331-3p

The phenotypic characteristics and meat quality of skeletal muscles are collectively determined by muscle cells and their intricate interactions with the extracellular microenvironment. In this study, we evaluated muscle fiber phenotypes in the longissimus dorsi (HC-L) and psoas major (HC-P) of Hechuan black pigs. The results revealed significant differences in muscle fiber diameter, density, and type (P < 0.05). Subsequently, co-culture experiments with myoblasts demonstrated that skeletal muscle-derived exosomes (SKM-Exos) promoted myoblast proliferation and differentiation with P-Exo exhibiting superior efficacy in promoting the augmentation of MyHCIIa fiber. Furthermore, SKM-Exos are inherently heterogeneous, and the microRNAs (miRNAs) present in SKM-Exos are selectively coated. Notably, the expression of miR-4331-3p was significantly higher in SKM-Exos than in the corresponding skeletal muscles. The expression of miR-4331-3p was significantly elevated in the SKM-Exos of HC-L compared to that of HC-P, and it interacted with differentially expressed genes between HC-L and HC-P. Moreover, miR-4331-3p enhanced myoblast proliferation and inhibited differentiation. Our findings offer valuable insights into the molecular processes that contribute to meat formation, including intricate cellular interactions.

Androgen receptor regulates the differentiation of myoblasts under cyclic mechanical stretch and its upstream and downstream signals

Our previous studies have demonstrated the important roles of androgen receptor (AR) in myoblast proliferation regulated by 15 % (mimic appropriate exercise) and 20 % (mimic excessive exercise) mechanical stretches. Except for myoblast proliferation, differentiation is also an important factor affecting muscle mass and strength. But the role of AR in stretch-regulated myoblast differentiation and AR's upstream and downstream signals remain unknown. In the present study, firstly the differences of myogenic differentiation between C2C12 (with AR expression) and L6 (without AR expression) myoblasts induced by 15 % and 20 % mechanical stretches were compared; secondly, AR antagonist flutamide and AR agonist GTx-007 were used in 15 % and 20 % stretched myoblasts respectively to confirm AR's roles in stretch-regulated myoblast differentiation; thirdly, RNA-seq, molecular dynamic simulation (MD) and co-immunoprecipitation were performed to screen the downstream and upstream molecules of AR during stretches. We found that (1) 15 % stretch increased while 20 % stretch decreased myotube number in differentiating C2C12 and L6 myoblasts, with more significant changes in C2C12 cells than L6 cells; (2) in stretched C2C12 myoblasts, AR antagonist flutamide inhibited 15 % stretch-promoted differentiation while AR agonist GTx-007 reversed 20 % stretch-inhibited differentiation (reflected by changes in myotube number, MHC contents of fast-twitch and slow-twitch fiber, and the levels of myogenic regulatory factors (MRFs) such as MyoD and myogenin); (3) KEGG analysis of RNA-seq showed that the differently expressed genes (DEGs) in C2C12 cells induced by 15 % stretch were enriched in FoxO and JAK-STAT signaling pathways, while DEGs by 20 % stretch were enriched in FoxO and MAPK signaling pathways; (4) MD and co-immunoprecipitation showed that β1 integrin could interact with AR and influence AR's activity in C2C12 cells. In conclusion, AR plays important roles in myoblast differentiation promoted by 15 % stretch while inhibited by 20 % stretch, which was fulfilled through FoxO-MRFs. In addition, α7β1 integrin may be a bridge linking mechanical stretch and AR. This study is beneficial to deeply understand the roles and mechanisms of AR in stretch-regulated muscle mass and strength; and reports firstly that myoblasts sense mechanical stimulus and transmit into intracellular AR via α7β1 integrin.

271P Exploring the effects of the epi-drug Remodelin on murine myoblasts differentiation

271P Exploring the effects of the epi-drug Remodelin on murine myoblasts differentiation

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

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