Myosin accumulation in mononucleated cells of chick muscle cultures.

The biosynthesis and accumulation of the myosin heavy chain (MHC) peptide has been examined in embryonic chick skeletal muscle cultures under conditions of normal or arrested cell fusion. When compared with primary chick fibroblasts, the myogenic cells accumulated significantly more MHC, even while mononucleated. Electron microscopy of the fusion-blocked cultures revealed the presence of myosinlike thick filaments in the myoblasts. It is concluded that cell fusion is not a prerequisite for myosin accumulation or myofilament assembly during embryonic chick muscle differentiation.     

Role of muscle fibroblasts in the deposition of type-IV collagen in the basal lamina of myotubes

In cell cultures of quail, chick, or mouse skeletal muscle, both myogenic and fibrogenic cells synthesize and secrete type-IV collagen, a major structural component of the basal lamina. Type-IV collagen, together with laminin, forms characteristic patches and strands on the surface of developing myotubes, marking the onset of basement-membrane formation. The pattern for type-IV collagen and laminin is unique to these proteins and is not paralleled by other matrix proteins, such as fibronectin or type-I or -III collagen. In the present study, we used species-specific antibodies to either mouse or chick type-IV collagen to demonstrate the ability of fibroblast--derived type-IV collagen to incorporate in the basal lamina of myotubes. In combination cultures of embryonic quail skeletal myoblasts and mouse muscle fibroblasts, antibodies specific for mouse type-IV collagen revealed the deposition of type-IV collagen on the surface of quail myotubes in the pattern typical of the beginning of basement-membrane formation. Control cultures consisting of only quail muscle cells containing myoblasts and fibroblasts demonstrated no such reaction with these antibodies. Deposits of mouse type-IV collagen were also observed on the surface of quail myotubes when conditioned medium from mouse muscle fibroblasts was added to quail myoblast cultures. Similarly, in combination cultures of mouse myoblasts and chick muscle fibroblasts, chick type-IV-collagen deposits were identified on the surface of mouse myotubes. These results indicate that type-IV collagen synthesized by muscle fibroblasts may be incorporated into the basal lamina forming on the plasmalemma of myotubes, and may explain ultrastructural studies by Lipton on the contribution of fibroblasts to the formation of basement membranes in skeletal muscle.     

Differences in the Expression and Distribution of Flotillin-2 in Chick,Mice and Human Muscle Cells

Myoblasts undergo a series of changes in the composition and dynamics of their plasma membranes during the initial steps of skeletal muscle differentiation. These changes are crucial requirements for myoblast fusion and allow the formation of striated muscle fibers. Membrane microdomains, or lipid rafts, have been implicated in myoblast fusion. Flotillins are scaffold proteins that are essential for the formation and dynamics of lipid rafts. Flotillins have been widely studied over the last few years, but still little is known about their role during skeletal muscle differentiation. In the present study, we analyzed the expression and distribution of flotillin-2 in chick, mice and human muscle cells grown in vitro. Primary cultures of chick myogenic cells showed a decrease in the expression of flotillin-2 during the first 72 hours of muscle differentiation. Interestingly, flotillin-2 was found to be highly expressed in chick myogenic fibroblasts and weakly expressed in chick myoblasts and multinucleated myotubes. Flotillin-2 was distributed in vesicle-like structures within the cytoplasm of chick myogenic fibroblasts, in the mouse C2C12 myogenic cell line, and in neonatal human muscle cells. Cryo-immunogold labeling revealed the presence of flotillin-2 in vesicles and in Golgi stacks in chick myogenic fibroblasts. Further, brefeldin A induced a major reduction in the number of flotillin-2 containing vesicles which correlates to a decrease in myoblast fusion. These results suggest the involvement of flotillin-2 during the initial steps of skeletal myogenesis.     

Acetylcholinesterase activity in developing skeletal muscle cells

Acetylcholinesterase activity has been demonstrated biochemically and cytochemically in developing chick embryo skeletal muscle cells growing in culture. The enzyme shows the same pattern of drug sensitivity as that of adult skeletal muscle acetylcholinesterase and in present in cultured myogenic cells before the time of cell fusion, the formation of myotubes, and the subsequent increase in rate of myosin synthesis. Myogenic cell fusion is accompanied, however, by a large increase in activity of acetylcholinesterase. The enzyme activity is restricted in these cultures to myogenic cells. Neighboring fibroblasts show no cytochemical responses when challenged with techniques showing intense activity in myoblasts and myotubes. In addition, evidence is presented which strongly suggests that acetylcholinesterase activity in dividing myogenic cells is not constant over the cell cycle.     

Synthesis of rat myosin light chains in heterokaryons formed between undifferentiated rat myoblasts and chick skeletal myocytes

The control of gene expression during terminal myogenesis was explored in heterokaryons between differentiated and undifferentiated myogenic cells by analyzing the formation of species specific myosin light chains of chick and rat skeletal muscle. Dividing L6 rat myoblasts served as the biochemically undifferentiated parent. The differentiated parental cells were mononucleated muscle cells (myocytes) that were obtained from primary cultures of embryonic chick thigh muscle by blocking myotube formation with EGTA and later incubating the postimitotic cells in cytochalasin B. Heterokaryons were isolated by the selective rescue of fusion products between cells previously treated with lethal doses of different cell poisons. 95-99% pure populations of heterokaryons formed between undifferentiated rat myoblasts and differentiated chick myocytes were obtained. The cells were labeled with [35S]methionine, and whole cell extracts were analyzed on two-dimensional polyacrylamide gels. These heterokaryons synthesize the light chain of chick myosin and both embryonic and adult light chains of rat skeletal myosin. Control homokaryons formed by fusing undifferentiated cells to themselves did not synthesize skeletal myosin light chains. Control heterokaryons formed between undifferentiated rat myoblasts and chick fibroblasts also failed to synthesize myosin light chains. These results indicate that differentiated chick muscle cells provide some factor that induces L6 myoblasts to synthesize rat myosin light chains. This system provides a model for investigating the processes by which differentiated cell functions are induced.     

Induction of muscle genes in neural cells

The regulation of skeletal muscle genes was examined in heterokaryons formed by fusing differentiated chick skeletal myocytes to four different rat neural cell lines. Highly enriched populations of heterokaryons isolated using irreversible biochemical inhibitors were labeled with [35S]methionine and analyzed on two-dimensional gels. Rat skeletal myosin light chains were induced in three of the four cell combinations. The one exception, the S-20 cholinergic cell line, not only failed to synthesize rat muscle proteins but also suppressed chick myogenic functions. Experiments with heterokaryons between chick myocytes and cells from whole embryonic rat brain cultures demonstrated that rat skeletal myosin light chains are inducible in normal diploid neural cells as well as in established neural cell lines. In contrast, dividing cell hybrids between rat myoblasts and rat glial cells were nonmyogenic. These results demonstrate that although neural cells may contain factors that prevent the decision to differentiate along myogenic lines in cell hybrids, most neural cell lines do not dominantly suppress the expression of muscle structural genes in heterokaryons. Furthermore, the skeletal myosin light chain genes in most neural cell lines are regulated by a mechanism that permits them to respond to putative chick skeletal myocyte-inducing factors. The "open" state of these myogenic genes may explain many of the reports of apparent "transdifferentiation" to muscle in neural cultures and neural tumors.     

SV40 immortalizes myogenic cells: DNA synthesis and mitosis in differentiating myotubes

Primary skeletal muscle myoblasts have a limited proliferative capacity in cell culture and cease to proliferate after several passages. We examined the effects of several oncogenes on the immortalization and differentiation of primary cultures of rat skeletal muscle myoblasts. Retroviruses containing a SV40 large T antigen (LT) gene very efficiently immortalize myogenic cells. The immortalized cell lines retain a very high differentiation capacity and form, in the appropriate culture conditions, a very dense network of muscle fibers. As in primary culture, cell fusion is associated with the synthesis of large amounts of muscle-specific proteins. However, unlike normal myoblasts (and previously established myogenic cell lines), nuclei in the multinucleated fibers of SV40-immortalized cells synthesize DNA and enter mitosis. Thus, withdrawal from DNA synthesis is not obligatory for cell fusion and biochemical differentiation. Using a retrovirus coding for a temperature-sensitive SV40 LT, myogenic cell lines were produced in which the SV40 LT could be inactivated by a shift from 33 degrees C to 39 degrees C. The inactivation of LT induced massive cell fusion and synthesis of muscle proteins. The nuclei in those fibers did not synthesize DNA, nor did they undergo mitosis. This approach enabled the reproducible establishment of myogenic cell lines from very small populations of myoblasts or single primary myogenic clones. Activated p53 also readily immortalized cells in primary muscle cultures, however the cells of eight out of the nine cell lines isolated had a fibroblastic morphology and could not be induced to form multinucleated fibers.     

Laminin alters cell shape and stimulates motility and proliferation of murine skeletal myoblasts

Proliferating skeletal myoblasts show multiple specific responses to laminin, one of the major glycoprotein components of basement membranes. Using MM14Dy myoblasts, a myogenic cell strain derived from a normal adult mouse skeletal muscle, we show in this study that substrate-bound laminin but not other matrix proteins such as collagens or fibronectin specifically and rapidly induces the outgrowth of cell processes, resulting in bipolar, spindle-shaped cells. This effect is independent from the presence of collagens or serum, and was also observed in primary cultures of fetal mouse skeletal myoblasts. The outgrowth of cell processes on laminin is associated with a dramatic stimulation of cell motility: MM14 myoblasts migrate about five times faster on laminin than on fibronectin. In another series of experiments the effect of laminin and fibronectin on thymidine uptake and proliferation of myoblasts was tested. On top of a type I collagen substrate which was provided to ensure complete adhesion even at low doses of laminin or fibronectin, laminin stimulated myoblast proliferation and incorporation of [3H]thymidine in a dose-dependent manner. The stimulation is two- to threefold higher than on dishes coated with equivalent amounts of fibronectin and is observed both in the presence and in the absence of serum. These results suggest that laminin, a major component of the muscle basal lamina, may be actively involved in the development and regeneration of skeletal muscle.     

Role of laminin and fibronectin in selecting myogenic versus fibrogenic cells from skeletal muscle cells in vitro

Growth of embryonic skeletal muscle occurs by fusion of multinucleated myotubes with differentiated, fusion-capable myoblasts. Selective recognition seems to prevent fusion of myotubes with nonmyogenic cells such as muscle fibroblasts, endothelial cells, or nerve cells, but the nature of the signal is as yet unknown. Here we provide evidence that one of the selection mechanisms may be the enhanced affinity for laminin of myogenic cells as compared to fibrogenic cells. Growing myotubes in myoblast cultures accumulate laminin and type IV collagen on their surface in patches and strands as the first step in assembling a continuous basal lamina on mature myofibers (U. Kühl, R. Timpl, and K. von der Mark (1982), Dev. Biol. 93, 344-359). Fibronectin, on the other hand, assembles into an intercellular fibrous meshwork not associated with the free myotube surface. Over a brief time period (10-20 min) myoblasts from embryonic mouse thigh muscle adhere faster to laminin than do fibroblasts from the same tissue; these adhere faster to fibronectin. When a mixture of the cells is plated for 20 min on laminin/type IV collagen substrates, only myogenic cells adhere, giving rise to cultures with more than 90% fusion after 2 weeks; on fibronectin/type I collagen in the same time primarily fibroblastic cells adhere, giving rise to cultures with less than 10% nuclei in myotubes. The differential affinities of myoblasts for basement membrane constituents and of fibroblasts for interstitial connective tissue components may play a role in sorting out myoblasts from fibroblasts in skeletal muscle development.     

DISEASED MUSCLE CELLS IN CULTURE

(1) Cultures of differentiated muscle cells have been grown from diseased human, mouse and chick skeletal muscle, and from cardiac muscle of the myopathic hamster. (2) Methods of culture established for normal embryonic and adult skeletal muscle cells have proved suitable for cultures of diseased muscle cells. (3) Myoblasts obtained from dy^2J mouse muscle crushed in vivo before explanting fuse in culture and form morphologically normal myotubes. Studies of the effects of innervation by dy^2J spinal cord neurones on the differentiation of normal, dy^2J and dy myotubes have been inconclusive but it is probable that innervation does not play a part in the pathogenesis of this disorder. (4) Myoblasts prepared by trypsinization of embryonic dy muscle behave normally in culture and fuse to form myotubes that appear normal. It is not clear if myoblasts that migrate from explants of adult muscle in vitro fuse. Aggregates of non-fusing cells have been described, but under other culture conditions normal and abnormal forms of myotube have been observed. dy muscle fibres fail to regenerate even when cultured with normal spinal cord explants and dy nerves are without effect on regenerating normal muscle fibres. These tissue-culture studies suggest that the dy mouse mutation is a myopathic disorder. (5) Embryonic mdg myoblasts have a normal cell cycle in vitro and fuse to form well-differentiated myotubes with cross-striations. mdg myotubes have normal electro-physiological properties but do not contract spontaneously or on depolarization. The defect in the muscle of the mdg mutant appears to be a failure of excitation-contraction coupling. (6) Cells migrate earlier from explants of adult dystrophic chick muscle than from normal muscle but dystrophic chick myotubes appear morphologically normal. Myotubes prepared from embryonic dystrophic chick muscle become vacuolated and degenerate, changes that can be prevented by anti-proteases such as antipain. Lactic dehydrogenase isozyme subunit M4 is absent from dystrophic muscle in vivo but reappears in cultured myotubes. Dystrophic myotubes innervated in culture by either normal or dystrophic neurones exhibit bi-directional lcoupling and multiple innervation. These results suggest that there are changes in dystrophic myotubes and that chick muscular dystrophy is a myopathy. (7) Cardiac muscle cells from the cardiomyopathic hamster synthesize less actin and myosin than normal cells, and Z lines in dystrophic cells are irregularly arranged. The beat frequency of myopathic cardiac cells is lower than that of normal cells and declines more rapidly. Tissue-culture studies have not been made of hamster skeletal muscle. (8) Human dystrophic myotubes do not show degenerative changes in culture and have normal histochemical reactions. RNA synthesis appears normal in dystrophic myotubes but there may be changes in adenyl-cyclase activity and protein synthesis in dystrophic cells. Morphological and biochemical changes have been found in muscle cells cultured from a case of acid-maltase deficiency but phosphorylase activity re-appeared in myotubes cultured from biopsies of phosphorylase-deficient muscle. Innervation by normal mouse nerves does not induce degenerative changes in dystrophic myotubes. (9) Studies on the origins of myoblasts in explants of muscle fibres in culture suggest that in these conditions myoblasts are derived only from satellite cells and that this process may be the same in normal and diseased muscle.     

Antagonistic effects of laminin and fibronectin on the expression of the myogenic phenotype

Skeletal myoblasts from fetal muscle respond adversely to fibronectin and laminin substrata: when primary mouse skeletal myoblasts are plated onto laminin, more myosin and desmin-positive myoblasts (myo+ cells) develop than on plates coated with fibronectin or collagen. In clonal cultures virtually all cells differentiate into postmitotic, fusion-capable myo + myoblasts on laminin after 3 days. In contrast, on fibronectin, the majority of the cells becomes myosin- and desmin-negative, partially due to proliferation of undifferentiated myoblast precursor cells, partially due to dedifferentiation or modulation of myoblasts into fibroblast-like myo- cells. Loss of the myogenic phenotype on fibronectin was also observed in cloned mouse myoblasts and in cultures of a differentiating mouse satellite cell line, MM14Dy, confirming that the appearance of desmin-negative cells is a result of myoblast modulation and not due simply to overgrowth by muscle fibroblasts. In the light of other effects of laminin on myoblasts, such as the stimulation of migration, differentiation and proliferation, our findings are consistent with the notion that laminin and fibronectin may be counteracting factors in the control of muscle differentiation.     

Dissection of protease-activated receptor-1-dependent and -independent responses to thrombin in skeletal myoblasts

Thrombin exerts a number of effects on skeletal myoblasts in vitro. It stimulates proliferation and intracellular calcium mobilization and inhibits differentiation and apoptosis induced by serum deprivation in these cells. Many cellular responses to thrombin are mediated by protease-activated receptor-1 (PAR-1). Expression of PAR-1 is present in mononuclear myoblasts in vitro, but repressed when fusion occurs to form myotubes. In the current study, we used PAR-1-null mice to determine which of thrombin's effects on myoblasts are mediated by PAR-1. Thrombin inhibited fusion almost as effectively in cultures prepared from the muscle of PAR-1-null myoblasts as in cultures prepared from wild-type mice. Apoptosis was inhibited as effectively in PAR-1-null myoblasts as in wild-type myoblasts. These effects in PAR-1-null myoblasts were mediated by a secreted inhibitor of apoptosis and fusion, as demonstrated previously for normal rat myoblasts. Thrombin failed to induce an intracellular calcium response in PAR-1-null myoblast cultures, although these cells were able to mobilize intracellular calcium in response to activation of other receptors. PAR-1-null myoblasts also failed to proliferate in response to thrombin. These results demonstrate that thrombin's effects on myoblast apoptosis and fusion are not mediated by PAR-1 and that PAR-1 is the only thrombin receptor capable of inducing proliferation and calcium mobilization in neonatal mouse myoblasts.     

DNA synthesis, mitosis and fusion of myocardial cells

Myocardial cells obtained from embryonic chick ventricles have been used to investigate (1) whether differentiated cells can undergo DNA synthesis and mitosis and, (2) whether heart cells when grown in culture can fuse with each other and with chick skeletal myoblasts to form heterokaryon myotubes. Electron microscopic observations have shown that myocardial cells of day 3 and day 20 chick embryos did contain myofibrils with defined sarcomeres; these cells have been observed in mitosis. Cells obtained by tryptic digestion of day 12 chick ventricles when grown in culture continued to replicate their DNA as shown by thymidine-³H radioautography with DNase controls and were observed in all stages of mitosis. Electron microscopy showed that myofibrils were present in some of the cultured cells. Bi-, tri- and tetranucleate cells were observed in the cultures. Thymidine-³H radioautography showed that these cells were formed by karyokinesis without cytokinesis and by the fusion of uninucleate cells. Since the heart cells could fuse with each other, we tested the possibility that they could fuse with skeletal myoblasts to form heterokaryon myotubes. This was accomplished by co-culturing thymidine-³H labeled ventricular cells and unlabeled skeletal myoblasts. Radioautography with DNase controls showed that some of the myotubes consisted of unlabeled skeletal muscle nuclei and labeled heart nuclei in varied proportions. The factors initiating the formation of these heterokaryons have not been elucidated.     

Effect of fibroblast growth factor on the division and fusion of bovine myoblasts

The effect of fibroblast growth factor (FGF) on the rate of proliferation and fusion of bovine myoblast has been examined. Addition to the cultures of 0.1 mug-1 mug/ml of FGF stimulates the rate of proliferation and delays the fusion of primary cultures of bovine myoblasts cultured in 10% serum. Final cell densities reached in the presence of 0.1 mug/ml of FGF were fivefold higher than in controls; with 1 mug/ml, they were 10-fold higher. Increases in cell density were paralleled by increases in acetylcholine receptor sites as measured by the binding of 125I-alpha-bungarotoxin. Both fusion and the appearance of acetylcholine receptor sites were delayed in the presence of FGF. Growth hormone, insulin and testosterone, which have been reported to be mitogenic for rat and chick embryo myoblasts, did not have significant effects on DNA synthesis in bovine myoblasts when compared to the FGF. Conversely, FGF did not stimulate the proliferation of chick embryo myoblasts, indicating that it is not active in all vertebrate species.     

Change of hyaluronic acid synthesis during differentiation of myogenic cells and its relation to transformation of myoblasts by Rous sarcoma virus

Hyaluronic acid synthesis was examined in cultures of differentiating chick embryo muscle cells before, during and after fusion. Prior to fusion, hyaluronic acid was synthesized and secreted into the medium, but once fusion began this synthesis was reduced significantly. Synthesis then increased again after completion of fusion. Thus, production of hyaluronic acid was lowest at the time of or right before cell fusion. When myoblasts were transformed by Rous sarcoma virus (RSV), a higher amount of hyaluronic acid was synthesized, and cells were not able to fuse. The turnover rate of hyaluronic acid might be different between myotubes and RSV-transformed myoblasts. The addition of exogenous hyaluronic acid to myoblast cultures resulted in the partial inhibition of fusion. The effect was reversible because fusion took place after removal of the exogenous hyaluronic acid. These observations suggest that hyaluronic acid plays an important role in the differentiation of myogenic cells, and that elevated hyaluronic acid synthesis may partly be the reason for inhibition of myotube formation upon transformation by Rous sarcoma virus.     

Isolation and characterization of terminally differentiated chicken and rat skeletal muscle myoblasts

The ability of skeletal muscle myoblasts to differentiate in the absence of spontaneous fusion was studied in cultures derived from chicken embryo leg muscle, rat myoblast lines L6 and L8, and the mouse myoblast line G8. Following 48–96 hr of culture in a low-Ca²⁺ (25 μm), Mg²⁺-depleted medium, chicken myoblasts exhibited only 3–5% fusion whereas up to 64% of the cells fused in control cultures. Depletion of Mg²⁺ led to preferential elimination of fibroblasts, with the result that 97% of the mononucleated cells remaining at 120 hr exhibited a bipolar morphology and stained with antibodies directed against M-creatine kinase, skeletal muscle myosin, and desmin. Mononucleated myoblasts rarely showed visible cross-striations or M-line staining with anti-myomesin unless the medium was supplemented with 0.81 mM Mg²⁺, suggesting that Mg²⁺ plays a role in sarcomere assembly. Conditions of Ca²⁺ and Mg²⁺ depletion inhibited myoblast fusion in the rodent cell lines as well, but mononucleated myoblasts failed to differentiate under these conditions. Differentiated individual myoblasts from rat cell lines and from chicken cell cultures were obtained when fusion was inhibited by growth in cytochalasin B (CB). CB-treated rat myoblast cultures accumulated MM-CK to nearly twice the specific activity found in extensively fused control cultures of comparable age. Spherical cells which accumulated during CB treatment were isolated and shown to contain nearly eight times the CK specific activity present in nonspherical cells from the same cultures. Approximately 90% of these cells exhibited immunofluorescent staining with antibodies to skeletal muscle myosin, failed to incorporate [³H]thymidine or to form colonies in clonal subculture, and thus represent terminally differentiated rat myoblasts. Quantitative microfluorometric DNA measurements on individual nuclei demonstrated that the terminally differentiated myoblasts obtained in these experiments from both chicken and rat contain 2cDNA levels, suggesting arrest in the G₀ stage of the cell cycle.     

Lack of evidence for the involvement of a β-D-galactosyl-specific lectin in the fusion of chick myoblasts

The role of a β-D-galactosyl-specific lectin, first reported by Teichberg et al., in the fusion of myoblasts in vitro was investigated. The concentration of this lectin in embryonic chick skeletal muscle was found to reach maximal levels at the time of myoblast fusion in vivo. β-D-Galactosyl-β-thiogalactopyranoside and lactose are potent inhibitors of agglutination of trypsinized rabbit erythrocytes caused by the lectin. However, at concentrations of 50 mM these compounds had no effect on either nonsynchronous fusion of myoblasts or on the release of synchronized myoblast cultures from EGTA fusion block. The presence of the agglutinin in the external membranes of chick myoblasts and myotubes could not be demonstrated. It is, therefore, concluded that the involvement of the lectin in the fusion of chick myoblasts remains questionable.     

Isoproterenol induces an increase in muscle fiber size by the proliferation of Pax7‐positive cells and in a mTOR‐independent mechanism

β‐Adrenergic signaling regulates many physiological processes in skeletal muscles. A wealth of evidence has shown that β‐agonists can increase skeletal muscle mass in vertebrates. Nevertheless, to date, the specific role of β‐adrenergic receptors in different cell phenotypes (myoblasts, fibroblasts, and myotubes) and during the different steps of embryonic skeletal muscle differentiation has not been studied. Therefore, here we address this question through the analysis of embryonic chick primary cultures of skeletal muscle cells during the formation of multinucleated myotubes. We used isoproterenol (ISO), a β‐adrenergic receptor agonist, to activate the β‐adrenergic signaling and quantified several aspects of muscle differentiation. ISO induced an increase in myoblast proliferation, in the percentage of Pax7‐positive myoblasts and in the size of skeletal muscle fibers, suggesting that ISO activates a hyperplasic and hypertrophic muscle response. Interestingly, treatment with ISO did not alter the number of fibroblast cells, suggesting that ISO effects are specific to muscle cells in the case of chick myogenic cell culture. We also show that rapamycin, an inhibitor of the mammalian target of rapamycin signaling pathway, did not prevent the effects of ISO on chick muscle fiber size. The collection of these results provides new insights into the role of β‐adrenergic signaling during skeletal muscle proliferation and differentiation and specifically in the regulation of skeletal muscle hyperplasia and hypertrophy.     

Induction of Creatine Phosphokinase in Cultures of Chick Skeletal Myoblasts without Concomitant Cell Fusion

The induction of the enzyme creatine phosphokinase (CPK) in cultures of chick breast muscle myoblasts has been distinguished from the process of fusion of myoblasts resulting in the formation of multinucleated myotubes. Primary cultures of myoblasts grown in the presence of phospholipase C, BUdR or EGTA, all of which prevent cell fusion, contain amounts of CPK similar to the level in untreated cultures. Both the brain and muscle isozymes are present in all cultures. We conclude that the induction of CPK is not dependent upon the formation of multinucleated myotubes.     

Studies on asparagine-linked protein glycosylation in differentiating skeletal muscle cells

The embryonic development of skeletal muscle proceeds by the adherence and fusion of myoblast cells to form multinucleated myotubes. In the present study, enzymes in the dolichol pathway for asparagine-linked glycoprotein synthesis and oligosaccharide chain composition were characterized in myoblasts and myotubes derived from the C2 (mouse) muscle cell line. The N-acetylglucosaminyltransferase responsible for chain initiation and the mannosyl- and glucosyltransferases for Dol-P-Man and Dol-P-Glc synthesis were characterized with respect to substrate, cation, and detergent dependence. Time course studies in the absence and presence of exogenous Dol-P revealed that myoblasts had a two- to threefold higher capacity than myotubes for Dol-sugar synthesis. Pulse-chase experiments following the elongation of the Dol-oligosaccharide by intact cells showed myoblasts to label oligosaccharide intermediates approximately fourfold greater than myotubes; myotubes, however, were more efficient than myoblasts for converting the intermediates to the glucosylated Dol-tetradecasaccharide. Oligosaccharide chains isolated from sarcolemma glycopeptides were analyzed by Con A, WGA, and QAE chromatography. There were no differences between myoblast and myotube oligosaccharides with respect to the proportion of tri-tetraantennary complex, biantennary complex, and high mannose chains. Hybrid chains were not detected. The major high mannose chain contained nine mannose residues. Sialyltransferase activity was identical. The results suggest that higher levels of Dol-P and protein acceptor contribute to the greater degree of protein glycosylation in myoblast vs myotube muscle cells.