Evidence on the participation of protein kinase C alpha in the proliferation of cultured myoblasts.

There is evidence involving protein kinase C (PKC) in the signal transduction pathways that regulate the differentiation of myoblasts into mature multinucleated muscle cells (myotubes). In order to obtain information on the possible role of individual PKC isozymes in myogenesis, in the present work we investigated the differential expression of PKC isoforms alpha, beta, delta, epsilon, and zeta during muscle cell development in vitro. Chick embryo myoblasts cultured from 1 to 6 days were used as experimental model. Morphological characterization and measurement of specific biochemical parameters in cultures, e.g., DNA synthesis, creatine kinase activity, and myosin levels, revealed a typical muscle cell developmental pattern consisting of an initial proliferation of myoblasts followed by their differentiation into myotubes. PKC activity was high at the proliferation stage, decreased as myoblasts elongated and fused, and increased again in differentiated myotubes. In proliferating myoblasts, the PKC inhibitors calphostin C and bisindolylmaleimide I decreased DNA synthesis whereas in myoblasts undergoing differentiation they exerted the opposite effect, suggesting that PKC plays a role at both stages of myogenesis. Western blot analysis of changes in the expression of PKC isoforms during muscle cell development showed high levels of PKC alpha in the proliferating phase which markedly decreased as myoblasts differentiated. Treatment with TPA of proliferative myoblasts inhibited DNA synthesis and selectively down-regulated PKC alpha, suggesting that this isozyme may have an important role in maintaining myoblast proliferation. On the other hand, an increase in the expression of PKC beta, delta, and epsilon was detected during myogenesis, suggesting that one or more of these isoforms may participate in the differentiation process of myoblasts.     

Creatine kinase, myokinase, and acetylcholinesterase activities in muscle-forming primary cultures of mouse teratocarcinoma cells.

Multipotential mouse teratocarcinoma cells in embryoid bodies were explanted on plastic or collagen substrates. Various modes of cell determination, including myogenesis, occurred. The predominant avenue of differentiation soon became myogenesis: many multinucleated myotubes formed and yielded an extensive network of skeletal muscle fibers. The process does not proceed to normal completion, as the fibers have a paucity of striations and are not contractile. Activities of several enzymes ordinarily associated with muscle differentiation were examined. Acetylcholinesterase activity increases, especially during myotube formation, as in normal myogenesis. However, creatine kinase activity rises during myotube formation and then drops abnormally, and myokinase activity fails to increase appreciably. The fetal isozymic form of creatine kinase is expressed in the cultures, although well differentiated solid tumors taken from mice show attainment of the adult muscle isozyme type if skeletal muscle is demonstrably present. The results are consistent with the interpretation that coordinately regulated changes in gene expressions controlling these functions may be required for later stages of myogenesis.     

Expression of creatine kinase isoenzymes in myogenic cell lines.

Investigation of creatine kinase isoenzyme activity in several cloned myogenic cell lines showed differences in B-type subunit expression. In cultures of myoblasts isolated from rat skeletal muscle by selective cell plating and in the cell lines M58 and M41, the activity of the mononucleated cells was of the BB isoenzyme. After cell fusion, MM, MB, and BB isoenzymes were present; the main activity was of the MM isoenzyme. In the myogenic lines L8 and L84, in cultures of mononucleated cells, creatine kinase activity was absent or barely detectable. The high creatine kinase activity after cell fusion was of the MM type. No BB and MB activity was detected in these lines at any stage of differentiation. The difference in expression of creatine kinase isoenzymes seems not to affect the expression of other parameters of differentiation.     

Characterization of proliferating human skeletal muscle-derived cells in vitro: differential modulation of myoblast markers by TGF-beta2

Adult human skeletal muscle-derived cells (HuSkMC) propagated in vitro are under investigation as a cell-based therapy for the treatment of myocardial infarction. We have characterized HuSkMC with respect to cell identity and state of differentiation as a prerequisite to their clinical use. Flow cytometric analysis of propagated HuSkMC revealed a population of cells that expressed the myoblast markers CD56 and desmin. The presence of myoblasts in these cultures was further confirmed by their capacity to form myotubes and increase creatine kinase activity when cultured in low serum conditions. The non-myoblast fraction of these propagated cells expressed TE7, a marker associated with the fibroblast phenotype. Spontaneous differentiation of myoblasts occurred during serial propagation of HuSkMC, as judged by myotube formation, thereby reducing the myoblast representative fraction with continued cell expansion. We examined transforming growth factor beta2 (TGF-beta2) for its utility in controlling this spontaneous differentiation of adult human myoblasts in vitro. Propagation of HuSkMC in the presence of 1 ng/ml TGF-beta2 for 5 days decreased desmin expression within the myoblast population and caused a parallel reduction of creatine kinase activity. CD56 expression was unaffected, indicating a differential regulation of these myoblast markers. The reduction in desmin expression and creatine kinase activity was, however, reversible upon the removal of TGF-beta. These data collectively indicate that TGF-beta2 restrained differentiation of adult human skeletal myoblasts during propagation without causing irreversible loss of the myoblast phenotype, demonstrating the potential utility of using TGF-beta2 during cultivation and expansion of HuSkMC intended for therapeutic implantation.     

Autonomous expression of c-myc in BC3H1 cells partially inhibits but does not prevent myogenic differentiation.

Myogenic differentiation is obligatorily coupled to withdrawal of myoblasts from the cell cycle and is inhibited by specific polypeptide growth factors. To investigate the potential involvement of c-myc in the control of myogenesis, the BC3H1 muscle cell line was stably transfected with a simian virus 40 promoter:c-myc chimeric gene. In quiescent cells in 0.5% serum, the exogenous c-myc gene was expressed at a level more than threefold greater than the level of endogenous c-myc in undifferentiated, proliferating cells of the parental line in 20% serum. The transfected myc gene partially inhibited the expression of both muscle creatine kinase and the nicotinic acetylcholine receptor, but was not sufficient to prevent the induction of these muscle differentiation products upon mitogen withdrawal.     

Transformation is an alternative to normal skeletal muscle development

The differentiation of skeletal muscle is characterized by cessation of proliferation and fusion of single myoblasts to form non-replicating multinucleate fibers (myotubes). If termination of proliferation is an obligate requirement for further differentiation, myoblasts defective in this stage of development should fail to fuse or exhibit any further characteristics of myotubes. Furthermore, myoblasts which have lost the ability to control and cease proliferation may represent a transformed, potentially tumorigenic population. Formation of the neoplastic state may therefore be viewed as an alternate path, antithetical to the normal differentiation of skeletal muscle. To test this hypothesis, we isolated 13 clones of non-fusing cells from the myogenic L₈ line of rat myoblasts. In contrast to the L₈ line, all of the non-fusing clones maintain their proliferative capacity, do not form myotubes, nor elevated creatine kinase activity nor increased myosin, but do develop into tumors when injected into athymic mice. L₈ cells do not produce tumors in these mice. Analysis of cell growth and serum requirements, plasminogen activator, hexose transport, adhesiveness, LETS protein and growth in soft agar, indicates that these non-fusing cells are transformed and clearly distinguished from the parent L₈ cells. Whereas the L₈ line maintains a near diploid complement of chromosomes, all non-fusing clones were polyploid. In addition, 12 of 13 non-fusing clones (but not the L₈ cells) express an endogenous type C virus. Although all clones defective in differentiation formed tumors, no single in vitro characteristic was found to be a constant index of this tumorigenic capacity. We conclude that cessation of proliferation is an obligate requirement for skeletal myogenesis, that transformation is an alternative to normal skeletal muscle development and that the phenotype of these transformed cells may be quite varied.     

Fibroblast growth factor inducible 14 (Fn14) is required for the expression of myogenic regulatory factors and differentiation of myoblasts into myotubes. Evidence for TWEAK-independent functions of Fn14 during myogenesis

Fibroblast growth factor-inducible 14 (Fn14), distantly related to tumor necrosis factor receptor superfamily and a receptor for TWEAK cytokine, has been implicated in several biological responses. In this study, we have investigated the role of Fn14 in skeletal muscle formation in vitro. Flow cytometric and Western blot analysis revealed that Fn14 is highly expressed on myoblastic cell line C2C12 and mouse primary myoblasts. The expression of Fn14 was decreased upon differentiation of myoblasts into myotubes. Suppression of Fn14 expression using RNA interference inhibited the myotube formation in both C2C12 and primary myoblast cultures. Fn14 was required for the transactivation of skeletal alpha-actin promoter and the expression of specific muscle proteins such as myosin heavy chain fast type and creatine kinase. RNA interference-mediated knockdown of Fn14 receptor in C2C12 myoblasts decreased the levels of myogenic regulatory factors MyoD and myogenin upon induction of differentiation. Conversely, overexpression of MyoD increased differentiation in Fn14-knockdown C2C12 cultures. Suppression of Fn14 expression in C2C12 myoblasts also inhibited the differentiation-associated increase in the activity of serum response factor and RhoA GTPase. In addition, our data suggest that the role of Fn14 during myogenic differentiation could be independent of TWEAK cytokine. Collectively, our study suggests that the Fn14 receptor is required for the expression of myogenic regulatory factors and differentiation of myoblasts into myotubes.     

Morphological changes in staphylococcal cytoplasmic membrane due to action of non-ionic detergent Triton X-100

Ribosomal RNA, labelled with uridine and methionine, from dividing and post-mitotic mouse prenatal muscle cell cultures, has been characterised on polyacrylamide gels. Progress of differentiation in cultures was monitored by recording changing proportions of nuclei in myotubes, and increases in creatine kinase activity. Ribosomal RNA synthesis in myotubes is reduced relative to that in dividing cell cultures and considerable wastage of processed ribosomal RNA occurs. This changed pattern of ribosomal RNA production appears to be established in the post-mitotic myoblasts prior to fusion.     

Inhibition of myogenic differentiation by fibroblast growth factor or type beta transforming growth factor does not require persistent c-myc expression

Skeletal muscle differentiation is accompanied by accumulation of the mRNA encoding the muscle isoenzyme of creatine kinase (MCK) and can be suppressed by serum components, fibroblast growth factor (FGF), or type beta transforming growth factor (TGF beta). Using the nonfusing myogenic cell line, BC3H1, the potential involvement of c-myc in growth factor-dependent inhibition of myogenesis was examined. Withdrawal of undifferentiated myoblasts from the cell cycle in medium with 0.5% serum was associated with a precipitous decline in expression of c-myc mRNA followed by induction of MCK mRNA. In 0.5% serum containing TGF beta, c-myc mRNA declined to a level identical to that in differentiated cells; however, MCK mRNA was not expressed. Exposure of quiescent differentiated cells to FGF or TGF beta caused disappearance of muscle-specific gene products and was accompanied by only transient low level induction of c-myc mRNA. These data indicate that persistent c-myc expression is not required for growth factor-mediated inhibition of myogenic differentiation.     

Induction by Butyrate of Differentiated Properties in Cloned Murine Rhabdomyosarcoma Cells

A cell line derived from the murine rhabdomyosarcoma BW10139 (Dexter, Cancer Res. 37: 3136, 1977) was subcloned and examined with respect to growth and myogenic characteristics in the presence and absence of 1 mM butyrate. Without butyrate, these cells behave as typical transformed cells: they grow rapidly and chaotically, do not form multinucleated muscle fibers and have little or no creatine kinase activity. In the presence of 1 mM sodium butyrate or butyric acid, growth slows, cells become arranged in whorl patterns, and creatine kinase activities increase to levels comparable to those found in normal chick myoblasts immediately prior to cell fusion. The increase in creatine kinase activity is detectable within 2 h exposure to butyrate, reaches a maximum by 24 h, and the elevated level can be maintained for at least six weeks. The induction is reversible upon sequential addition, deletion, and readdition of butyrate to the culture medium. Isoenzyme analyses demonstrated that only the BB form of creatine kinease is induced; MM creatine kinase was not detected. Although formation of multinucleated cells increases after exposure to butyrate, no typical myotubes form. The results suggest that this rhabdomyosarcoma cell line can, under appropriate conditions, re-express some properties characteristic of skeletal muscle, but not the complete muscle phenotype.     

Enhanced proliferation of human skeletal muscle precursor cells derived from elderly donors cultured in estimated physiological (5%) oxygen

Human skeletal muscle precursor cells (myoblasts) have significant therapeutic potential and are a valuable research tool to study muscle cell biology. Oxygen is a critical factor in the successful culture of myoblasts with low (1–6%) oxygen culture conditions enhancing the proliferation, differentiation, and/or viability of mouse, rat, and bovine myoblasts. The specific effects of low oxygen depend on the myoblast source and oxygen concentration; however, variable oxygen conditions have not been tested in the culture of human myoblasts. In this study, muscle precursor cells were isolated from vastus lateralis muscle biopsies and myoblast cultures were established in 5% oxygen, before being divided into physiological (5%) or standard (20%) oxygen conditions for experimental analysis. Five percent oxygen increased proliferating myoblast numbers, and since low oxygen had no significant effect on myoblast viability, this increase in cell number was attributed to enhanced proliferation. The proportion of cells in the S (DNA synthesis) phase of the cell cycle was increased by 50%, and p21^Cip1 gene and protein expression was decreased in 5 versus 20% oxygen. Unlike in rodent and bovine myoblasts, the increase in myoD, myogenin, creatine kinase, and myosin heavy chain IIa gene expression during differentiation was similar in 5 and 20% oxygen; as was myotube hypertrophy. These data indicate for the first time that low oxygen culture conditions stimulate proliferation, whilst maintaining (but not enhancing) the viability and the differentiation potential of human primary myoblasts and should be considered as optimum conditions for ex-vivo expansion of these cells.     

KDM4A regulates myogenesis by demethylating H3K9me3 of myogenic regulatory factors

Histone lysine demethylase 4A (KDM4A) plays a crucial role in regulating cell proliferation, cell differentiation, development and tumorigenesis. However, little is known about the function of KDM4A in muscle development and regeneration. Here, we found that the conditional ablation of KDM4A in skeletal muscle caused impairment of embryonic and postnatal muscle formation. The loss of KDM4A in satellite cells led to defective muscle regeneration and blocked the proliferation and differentiation of satellite cells. Myogenic differentiation and myotube formation in KDM4A-deficient myoblasts were inhibited. Chromatin immunoprecipitation assay revealed that KDM4A promoted myogenesis by removing the histone methylation mark H3K9me3 at MyoD, MyoG and Myf5 locus. Furthermore, inactivation of KDM4A in myoblasts suppressed myoblast differentiation and accelerated H3K9me3 level. Knockdown of KDM4A in vitro reduced myoblast proliferation through enhancing the expression of the cyclin-dependent kinase inhibitor P21 and decreasing the expression of cell cycle regulator Cyclin D1. Together, our findings identify KDM4A as an important regulator for skeletal muscle development and regeneration, orchestrating myogenic cell proliferation and differentiation.Subject terms: Differentiation, Muscle stem cells, Epigenetics     

Characterization of in vitro cultured myoblasts isolated from duck (<Emphasis Type="Italic">Anas platyrhynchos</Emphasis>) embryo

Myoblasts isolated from duck embryonic muscle were purified and in vitro cultured. External characteristics were observed by using the immunofluorescence technique, and growth curve of duck embryonic myoblasts was established after measuring with the MTT method. Moreover, mRNA expression of three marker genes, the Desmin, the muscle creatine kinase (Mck) and the troponin C (Tnnc), which could reflect the development status of myofibers, were detected each 24 h for cultured cells by using the qPCR technique. Results showed that the in vitro cultured duck myoblasts went through a series of developmental stages, including the proliferation of myoblasts, the differentiation of multi-nuclei myotubes, and the formation of myofiber. The cultured duck embryonic myoblasts entered into a logarithmic stage approximately on the fourth day after seeding. Accompanying with its progressive growth before entering into the logarithmic phase, the myoblasts also showed some differentiation phenomena, reflected by a low expression level of Desmin and high expression level of the Mck and Tnnc genes. During the rapid growth of the logarithmic phase, there was a high expression of the Desmin gene, and a low expression level of the Mck gene and the Tnnc gene in the cultured myoblasts. The expression profiles of the three marker genes for muscle development could be used for distinguishing the different developmental stages of in vitro cultured myoblasts at the molecular level, which would be more accurate and more feasible than observing the external characteristics of the cultured cells.     

Role for cellular Src kinase in myoblast proliferation

In this study, a role for cellular Src in muscle cell proliferation and differentiation was investigated. Pharmacological inhibition of Src-class kinases repressed proliferation and promoted differentiation of the C2C12 muscle cell line, even when the cells were cultured under growth-inducing conditions of high serum. Pharmacological inhibition of Src-class kinases also affected cellular components that regulate proliferation and differentiation in muscle; cyclin D1 levels were reduced while, myogenin was increased. Suppression of cyclin D1 and enhancement of myogenin levels also occurred upon expression of a dominant negative Src, corroborating a role for Src kinases in regulating proliferation and differentiation. Inhibition of Src-family kinases also blocked fibroblast growth factor (FGF) induced proliferation but, notably, did not reverse the effect of FGF to inhibit differentiation. Evidence for the Src-class kinase Src in myoblast mitogenesis was obtained by determining the pattern of protein expression and activity for this kinase. Under all conditions examined, Src's expression and enzymatic activity were high in cultures of myoblasts and down-regulated during differentiation. Importantly, Src's activity was rapidly stimulated by mitogen-containing serum and attenuated when myoblasts were switched to low serum-containing differentiation medium. These data indicate that Src is important for maintaining muscle cell proliferation.     

Human myotube differentiation in vitro in different culture conditions

Human muscle cells derived from satellite cells, maintained in standard tissue culture conditions, do not differentiate as rapidly or as completely as myoblasts from other species (chicken, rat, mouse). In an attempt to improve myogenesis, we studied the effects of modifying the culture media and of coculturing muscle with nerve cells, using myoblasts grown in standard culture media as the basis for comparison. Myogenesis was measured by fusion index, creatine kinase (CK) activity; acetylcholinesterase (AChE) activity (total and molecular forms); and the number of acetylcholine receptors (AChR). Modification of culture media accelerated fusion of myoblasts, but the cell density decreased and myotubes were unable to survive for long periods. In contrast, coculturing muscle with nerve cells increased both cell density and the number of myotubes. CK, AChE and AChR increased in the presence of defined media. In the nerve-muscle cocultures the increase was less marked. Manipulating culture conditions modified the molecular forms of AChE. Only a (4 + 6.5) S peak was present in control cultures, but a 10S peak appeared in defined media. The 16S form was detected only in nerve-muscle cocultures. This study shows that fusion of human myoblasts and differentiation of myotubes in tissue culture can be accelerated by removal of serum macromolecules. Further differentiation of myotubes was achieved only in the nerve-muscle cocultures.