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.     

Specific features of satellite cells and myoblasts at different stages of rat postnatal development

A cell culture consisting mainly of satellite cells and mononuclear myoblasts was derived from femoral muscles of infant (aged 3–7 days) and adult rats. Satellite cells identified by expression of the specific marker Pax7 accounted for approximately 80% of the isolated cell fraction. Mononuclear myoblasts represented by proliferating and postmitotic cell pools were identified immunocytochemically by the expression of markers Ki67 and desmin. Differentiation of satellite cells and myoblasts in the culture depended on the concentration of Ca²⁺ in the culture medium (F12 with different Ca²⁺ concentrations or DMEM). Differentiation of myogenic cells manifested in myoblasts fusion, formation of myotubes, and expression of myosin in myofibrils was observed only in the medium with a high Ca²⁺ concentration (2mM). Satellite cells and myoblasts from the muscles of newborn and adult rats did not differ noticeably in their capacity for differentiation.     

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.     

INHIBITION OF MYOBLAST FUSION AFTER ONE ROUND OF DNA SYNTHESIS IN 5-BROMODEOXYURIDINE

The thymidine analogue 5-bromodeoxyuridine (BUdR) has a differential effect on the synthesis of tissue-specific products and molecules required for growth and division. Proliferating myogenic cells cultured in BUdR fail to fuse and fail to initiate the synthesis of contractile protein filaments. Conversely, BUdR has but a minor effect on cell viability and reproductive integrity. Low concentrations of BUdR result in an enhancement of cell number relative to the controls; higher concentrations are cytotoxic. Suppression of myogenesis is reversible after at least 10 cell generations of growth in the analogue. Cells that do not synthesize DNA, such as postmitotic myoblasts and myotubes, are not affected by BUdR. Incorporation of BUdR for one round of DNA synthesis was accomplished by first incubating myogenic cells, prior to fusion, in 5-fluorodeoxyuridine (FUdR) to block DNA synthesis and collect cells in the presynthetic phase. The cells were then allowed to synthesize either normal DNA or BU-DNA for one S period by circumventing the FUdR block with BUdR or BUdR plus thymidine (TdR). The cultures were continued in FUdR to prevent dilution of the incorporated analogue by further division. After 3 days, the cultures from the FUdR-BUdR series showed the typical BUdR effect; the cells were excessively flattened and few multinucleated myotubes formed. Cells in the control cultures were of normal morphology, and multinucleated myotubes were present. These results were confirmed in another experiment in which BUdR-³H was added to 2-day cultures in which myotubes were forming. Fusion of thymidine-³H-labeled cells begins at 8 hr after the preceding S phase. In contrast, cells which incorporate BUdR-³H for one S period do not fuse with normal myotubes.     

Emergence of TPA-resistant ‘satellite’ cells during muscle histogenesis of human limb

Human satellite cells, obtained by surgical biopsies of traumatized legs of healthy individuals, were grown in culture in the presence of different concentrations of the phorbol ester tetradecanoyl-phorbol 12 acetate (TPA). Satellite cells, after an initial duplicative period, fused into large multinucleated myotubes which readily synthesized myosin and acetylcholine receptor (AChR). The presence of TPA at concentrations up to 10(-7) M did not affect the differentiation pattern, while higher concentrations were toxic. Thus human satellite cells are capable of differentiating in the presence of phorbol esters which block differentiation of embryonic myoblasts [1]. We then examined the appearance of TPA-resistant cells during human muscle histogenesis, since we had observed that differentiation of human myoblasts from a 6-week-old limb was completely and reversibly inhibited by 10(-7) M TPA. Differentiation of myoblasts from 6-, 7- and 8-week-old fetuses was completely inhibited by TPA. Myoblasts from 10-week-old limbs did not form myotubes in the presence of TPA; however, immunohistochemical staining with an antimyosin antibody revealed the presence of a few mononucleated myosin-positive cells which escaped the TPA-induced block of differentiation. At 12 weeks of development, a few oligonucleated, myosin-positive myotubes developed in cultures treated with TPA, and the level of AChR expressed (measured as [125I] alpha-bungarotoxin bound) reached 20% of controls. At 14 weeks of development, about half of the cells in culture were TPA-resistant and by 16 weeks of development no major differences could be detected between control and treated cells. We conclude from these data that a population of TPA-resistant myogenic cells emerges between the 10th and 14th week of human limb development and suggest that this population represents satellite cells.     

On the non-equivalence of skeletal muscle satellite cells and embryonic myoblasts

Postnatal satellite cells, isolated from normal or previously denervated skeletal muscles of juvenile quails, were tested as to their capacity to participate in embryonic muscle ontogeny. They were grafted into 2-day chick embryo hosts, in place of a piece of brachial somitic mesoderm. Satellite cell implants were prepared from pellets either of freshly isolated cells or of cells precultured in vitro under proliferative conditions. Myogenic capacity of the implanted cells was attested by their ability to fuse into myotubes when cultured under differentiation conditions. In no case did the implanted satellite cells invade the adjacent wing bud or participate in wing muscle morphogenesis. They did not either give rise to myotubes at the site of implantation, nor did they even survive longer than 3 days in the embryonic environment. These negative results indicate that postnatal satellite cells, unlike embryonic myoblasts, are unable to take part in muscle embryogenesis. Although they derive from the same somitic myogenic cell line as the embryonic myoblasts, they therefore represent a differentiated non-totipotent type of myogenic cell.     

Proliferation of muscle satellite cells on intact myofibers in culture

Muscle satellite cells are quiescent myogenic stem cells situated between the basal lamina and plasmalemma of mature skeletal muscle fibers. Injury to the fiber triggers the activation and proliferation of satellite cells whose progeny subsequently fuse to form new myotubes during regeneration. In this paper we report the proliferation of satellite cells on single muscle fibers isolated from adult rats and placed in culture. Viable fibers were liberated from muscle with collagenase and purified from non-muscle cells. The fibers were covered with a basal lamina and retained normal morphological characteristics. Each fiber contained two to three satellite cells per 100 myonuclei. Satellite cells showed little proliferative activity in medium with 10% serum but could be induced to enter the cell cycle by chick embryo extract or fibroblast growth factor. Other polypeptide mitogens such as epidermal growth factor, multiplication stimulating activity, and platelet-derived growth factor were ineffective. Mitogen-stimulated satellite cells fused to form new myotubes after 4-5 days in culture. These results imply that satellite cells are under positive growth control since they proliferate in contact with viable mature fibers when stimulated with mitogen. The mature fibers remained viable in culture but did not give rise to mononucleated cells. After several days, however, the fibers began to extend sarcoplasmic sprouts and underwent dedifferentiative changes that led to the formation of multinucleated cells resembling myotubes. These cells reexpressed embryonic isozymes of creatine kinase not made by the mature fibers.     

Diversity of myosin heavy chain expression in satellite cells from mouse soleus and EDL muscles.

Postnatal myoblasts, the satellite cells, originating from slow and fast skeletal muscle fibres differentiate and fuse into myotubes expressing different phenotype of myosin heavy chain (MyHC) isoforms. Little is known, however, of factors which establish and maintain this phenotypic diversity. We used immunofluorescent labelling and Western blotting to examine the expression of slow and fast MyHC isoforms in myotubes formed in vitro from satellite cells isolated from mouse fast twitch extensor digitorum longus (EDL) and slow twitch soleus muscles. Satellite cells were cultured in serum-rich growth medium promoting myoblast proliferation until cross-striated and self-contracting myotubes were formed. We report that in both cultures myotubes expressed slow as well as fast MyHC isoforms, but the level of slow MyHC was higher in soleus culture than in EDL culture. Hence, the pattern of expression of slow and fast MyHC was characteristic of the muscle fibre type from which these cells derive. These results support the concept of phenotypic diversity among satellite cells in mature skeletal muscles and suggest that this diversity is generated in vitro irrespectively of serum mitogens.     

Developmental changes in glycopeptides synthesized by normal and dystrophic satellite cells in culture

Satellite cells were isolated from adult posterior leg muscles of normal and dystrophic (C57 BL/6J/dydy) mice and were grown in culture conditions which allow their terminal differentiation into multinucleated myotubes. Biosynthesis of total cell glycoproteins was studied in normal and dystrophic satellite cells at different stages of cytodifferentiation in vitro by labelling with radioactive fucose and glucosamine. Total radiolabelled glycoproteins were digested with pronase and the resulting glycopeptides were analyzed by gel filtration on Sephadex G-50 and by ion exchange chromatography on DEAE-cellulose. With these techniques, total glycopeptides could be separated into several classes according to their average molecular size and anionic charge. The results obtained show that qualitative and quantitative changes in several classes of glycopeptides occur during cytodifferentiation in vitro of satellite cells from both normal and dystrophic mice. In terms of qualitative changes, a class of fucosyl-glycopeptides, which is eluted at 22 mM sodium phosphate from DEAE-cellulose columns, appears to be exclusively synthesized by normal multinucleated myotubes but not by duplicating mononucleated satellite cells or by other non-myogenic cells. On the other hand, a similar but not identical class of fucosyl-glycopeptides, eluted at 20 mM sodium phosphate from DEAE-cellulose columns, was found to be exclusively synthesized by multinucleated myotubes derived from dystrophic mice. No other differences were found when comparing myotubes from normal vs dystrophic mice.     

Reduced DNA repair during differentiation of a myogenic cell line

Repair synthesis induced by 4-nitroquinoline-1-oxide (4NQO) in L6 myoblasts before and after cellular fusion was measured by [3H] thymidine incorporation into unreplicated DNA. The level of repair synthesis was reuced after the cells had fused into myotubes. The terminal addition of radioactive nucleotides into DNA strands occurred only to a minor extent, and the dilution of [3H] thymidine by intracellular nucleotide pools was shown not to be responsible for the observed difference in repair synthesis, Both the initial rate and the overall incorporation of [3H] thymidine were found to be 50% lower in the myotubes. 4NQO treatment of myoblasts and myotubes induced modifications in the DNA which were observed as single-strand breaks during alkaline sucrose sedimentation. After the myoblasts were allowed a post-treatment incubation, most of the single-strand breaks were not longer apparent. In contrast, a post-treatment incubation of myotubes did not change the extent of single-strand breakage seen. Both myoblasts and myotubes were equally effective in repairing single- strand breaks induced by X radiation. It would appear that when myoblasts fuse, a repair enzyme activity is lost, probably an endonuclease that recognizes one of the 4 NQO modifications of DNA. The result observed is a partial loss of repair synthetic ability and a complete loss of ability to remove the modification that appears as a single-strand break in alkali.     

Changes in protein and glycoprotein biosynthesis during differentiation of satellite cells in vitro

Satellite cells were isolated from leg skeletal muscles of adult mice and grown in culture. During the first few days in culture, satellite cells actively proliferated and starting on day 4 began to fuse into multinucleated myotubes. At various time points during the culture period, the biosynthesis of total cellular proteins and glycoproteins was analysed by pulse-labelling with radioactive leucine or sugars followed by electrophoretic analysis on two-dimensional gels. Our findings are: (1) Replicating mononucleated satellite cells on day 1 of culture did not synthesize detectable amounts of α and β tropomyosins, α-actin, and myosin light chains 1 and 2; (2) the synthesis of these polypeptides was readily detectable in multinucleated myotubes that formed by day 5–6 of culture; (3) other qualitative and quantitative differences in as yet unidentified proteins were observed in replicating cells as compared with multinucleated myotubes as well as to muscle fibroblasts; and (4) at least two distinct glucosamine-containing acidic glycoproteins of about 70 000 D and pI 5 were synthesized by myotubes, but not by replicating satellite cells.These data demonstrate that the biosynthetic programs for proteins and glycoproteins of cultured replicating satellite cells can be distinguished from those of multinucleated myotubes and from those of muscle fibroblasts. These data are interpreted to indicate that during muscle histogenesis in vivo, satellite cells become arrested prior to the expression of terminally differentiated traits.     

Isolation and characterization of myogenic satellite cells from the muscular dystrophic hamster

Myogenic satellite cells were isolated from control and dystrophic hamster diaphragms to examine cellular mechanisms involved in the physiology of muscular dystrophy. The Bio 14.6 dystrophic hamster, which possesses a defect in the delta-sarcoglycan gene, develops biochemical and physical symptoms of Duchenne-like and limb girdle muscular dystrophies. Because primary cultures of the control and dystrophic satellite cells became extensively contaminated with non-myogenic cells during proliferation, cell clones were developed to provide pure cultures for study. Cell culture conditions were optimized with the use of Ham's F-12K medium containing 10% fetal bovine serum +5% horse serum + 10 ng/mL basic fibroblast growth factor + 50 microg/mL porcine gelatin. Proliferation rates of the two clonal cultures were similar between the two lines. Satellite cell-derived myotubes from both primary cultures and clones differed between control and dystrophic animals. Dystrophic myotubes tended to be long and narrow, while the control-derived myotubes were broader. Measurement of muscle-specific creatine kinase during differentiation revealed that the dystrophic myotubes possessed higher creatine kinase levels than control myotubes (up to 146-fold at 168 h). The results demonstrate that satellite cells can be isolated from the hamster and may provide a useful tool to study muscular dystrophies associated with defects in the sarcoglycan complex and the involvement of sarcoglycans in normal skeletal muscle growth and development.     

Effect of phorbol esters and liposome-delivered phospholipids on the differentiation program of normal and dystrophic satellite cells

Satellite cells, isolated from hind limb of normal C57BL/6J mice, differentiate in culture in the presence of concentrations of phorbol esters which inhibit differentiation of embryonic myoblasts. However, if phosphatidylserine containing liposomes were added to the culture medium together with TPA, differentiation of satellite cells was reversibly inhibited. Under these conditions, the withdrawal of these cells from the cell cycle still occurred as in untreated cells. Phosphatidylserine liposomes alone or liposomes containing phosphatidylcholine (either alone or in combination with TPA) had no effect on satellite cell differentiation. In the case of satellite cells from dystrophic C57BL/6J/dydy mice, TPA addition (0.1 microM) to the culture medium partially (about 70%) inhibited morphological and biochemical differentiation. This effect could be prevented by preincubating dystrophic satellite cells with liposomes containing phosphatidylcholine but not other phospholipids. These data indicate that it is possible to change the sensitivity to TPA of satellite cells by modifying the phospholipid composition of their plasma membrane. Possible relationships of these phenomena with activation of protein kinase C or phosphatidylinositol breakdown have been investigated. The results obtained are discussed with regard to possible modulation of the intracellular response to agonist binding.     

Differentiation of activated satellite cells in denervated muscle following single fusions in situ and in cell culture

Satellite cells represent a cellular source of regeneration in adult skeletal muscle. It remains unclear why a large pool of stem myoblasts in denervated muscle does not compensate for the loss of muscle mass during post-denervation atrophy. In this study, we present evidence that satellite cells in long-term denervated rat muscle are able to activate synthesis of contractile proteins after single fusions in situ. This process of early differentiation leads to formation of abnormally diminutive myotubes. The localization of such dwarf myotubes beneath the intact basal lamina on the surface of differentiated muscle fibers shows that they form by fusion of neighboring satellites or by the progeny of a single satellite cell following one or two mitotic divisions. We demonstrated single fusions of myoblasts using electron microscopy, immunocytochemical labeling and high resolution confocal digital imaging. Sequestration of nascent myotubes by the rapidly forming basal laminae creates a barrier that limits further fusions. The recruitment of satellite cells in the formation of new muscle fibers results in a progressive decrease in their local densities, spatial separation and ultimate exhaustion of the myogenic cell pool. To determine whether the accumulation of aberrant dwarf myotubes is explained by the intrinsic decline of myogenic properties of satellite cells, or depends on their spatial separation and the environment in the tissue, we studied the fusion of myoblasts isolated from normal and denervated muscle in cell culture. The experiments with a culture system demonstrated that the capacity of myoblasts to synthesize contractile proteins without serial fusions depended on cell density and the availability of partners for fusion. Satellite cells isolated from denervated muscle and plated at fusion-permissive densities progressed through the myogenic program and actively formed myotubes, which shows that their myogenic potential is not considerably impaired. The results of this study suggest that under conditions of denervation, progressive spatial separation and confinement of many satellite cells within the endomysial tubes of atrophic muscle fibers and progressive interstitial fibrosis are the important factors that prevent their normal differentiation. Our findings also provide an explanation of why denervated muscle partially and temporarily is able to restore its functional capacity following injury and regeneration: the release of satellite cells from their sublaminal location provides the necessary space for a more active regenerative process.     

Myonuclear birthdates distinguish the origins of primary and secondary myotubes in embryonic mammalian skeletal muscles

Myotubes were isolated from enzymically disaggregated embryonic muscles and examined with light microscopy. Primary myotubes were seen as classic myotubes with chains of central nuclei within a tube of myofilaments, whereas secondary myotubes had a smaller diameter and more widely spaced nuclei. Primary myotubes could also be distinguished from secondary myotubes by their specific reaction with two monoclonal antibodies (MAbs) against adult slow myosin heavy chain (MHC). Myonuclei were birth dated with [3H]thymidine autoradiography or with 2-bromo-5'-deoxyuridine (BrdU) detected with a commercial monoclonal antibody. After a single pulse of label during the 1-2 day period when primary myotubes were forming, some primary myotubes had many myonuclei labelled, usually in adjacent groups, while in others no nuclei were labelled. If a pulse of label was administered after this time labelled myonuclei appeared in most secondary myotubes, while primary myotubes received few new nuclei. Labelled and unlabelled myonuclei were not grouped in the secondary myotubes, but were randomly interspersed. We conclude that primary myotubes form by a nearly synchronous fusion of myoblasts with similar birthdates. In contrast, secondary myotubes form in a progressive fashion, myoblasts with asynchronous birthdates fusing laterally with secondary myotubes at random positions along their length. These later-differentiating myoblasts do not fuse with primary myotubes, despite being closely apposed to their surface. Furthermore, they do not generally fuse with each other, as secondary myotube formation is initiated only in the region of the primary myotube endplate.     

Interaction between satellite cells and skeletal muscle fibers

Single myofibers with attached satellite cells isolated from adult rats were used to study the influence of the mature myofiber on the proliferation of satellite cells. The satellite cells remain quiescent when cultured in serum containing medium but proliferate when exposed to mitogen from an extract of crushed adult muscle. The response of satellite cells to mitogen was measured under three situations with respect to cell contact: (1) in contact with a viable myofiber and its basal lamina, (2) detached from the myofiber by centrifugal force and deposited on the substratum and (3) beneath the basal lamina of a Marcaine killed myofiber. The results show that satellite cells in contact with the plasmalemma of a viable myofiber have reduced mitogenic response. Since inhibiting growth may induce differentiation, I tested whether satellite cells proliferating on the surface of a myofiber would fuse. Although the satellite cell progeny were fusion competent, they did not fuse with the myofiber. To determine whether fusion competence of the myofiber changes with time in culture, embryonic myoblasts were challenged to fuse with myofibers that had been stripped of satellite cells and cultured for several days. The myoblasts fused with pseudopodial sprouts growing from the ends of the myofiber, but did not fuse with the original myofiber surface. These results indicate that contact with the surface of a mature myofiber suppresses proliferation of myogenic cells but the cells do not fuse with the myofiber.     

Comparison of the proliferation and differentiation of myogenic satellite cells and embryonic myoblasts derived from the turkey

• 1.1. Embryonic and posthatch turkey skeletal muscle development was compared in in vitro studies using clonal-derived embryonic myoblasts and satellite cells.
• 2.2. Although population doubling times were similar between the two lines (25.4 hr for satellite cells and 26.4 hr for embryonic myoblasts), embryonic myoblasts consistently began log phase growth 24 hr earlier than satellite cells.
• 3.3. Differentiation (fusion) of embryonic myoblasts was maximized by 36 hr in Dulbecco's Modified Eagle's Medium containing 1% horse serum compared with 72 hr for satellite cells.
• 4.4. When administered a serum-free medium which supports proliferation of turkey satellite cells, embryonic myoblasts differentiated to form myotubes.

     

Isolation and preliminary characterisation of DNA-protein complexes from the mitochondria of Saccharomyces cerevisiae

Four independent rat L6 myoblast cell lines have been selected in a single step for resistance to the cytotoxic effects of the lectin concanavalin A (conA). In contrast to parental wild-type myoblast lines, all of the variant clones are unable to undergo normal cellular differentiation to form multinucleated myotubes or biochemical differentiation to produce an increase in the specific activity of the muscle-specific enzyme, creatine phosphokinase (CPK). The correlation between lectin resistance and loss of fusion potential is very tight; clonal variation studies show that there is less than a 2.8×10^?8 chance that the two are not directly related. Membrane preparations from the conA-resistant myoblast lines incorporate significantly less GDP-[¹⁴C]mannose into the lipid intermediates of protein glycosylation than preparations from parental wild-type cells. Also, conversion of mannose label to fucose occurs in myoblasts and this pathway is more active in conA-resistant cells than wild-type cells. Reduced binding of labelled conA to the cell surfaces of variant myoblasts was observed which may result from alterations to membrane glycoprotein receptors. These studies suggest that mannosylated glycoproteins of the cell surface play a role in the development of the myotubes from myoblasts. Lectin-resistant myoblasts should be useful model systems for investigating what appears to be a pleiotropic mutation affecting the myogenesis process through membrane modifications.     

In vitro proliferation and differentiation of myogenic cells from adult Xenopus

A technique is described for isolating amphibian myogenic cells from the muscle of adult Xenopus laevis (Dauchin). Muscles were dissociated with 0.2% collagenase and 0.1% trypsin. The resulting cell suspensions were separated from the remaining myofibres by filtration through nylon grids. Most of the cells remaining in the filtrate suspension were satellite cells or fibroblasts. When plated in Petri dishes, satellite cells adhered to the substrate, became spindle-shaped and proliferated activity in a culture medium supplemented with fetal calf serum. Mitotic waves lasted 4 days and consequently cell density markedly increased. Satellite cells came into contact and began to fuse into myotubes on day 8 of culture. Horse serum, which replaced fetal calf serum in the medium on day 12, accelerated cell fusions which were almost complete on day 18. However, under these conditions, some mononucleated cells continued to undergo mitosis. Cell proliferation with a high rate of mitosis was prolonged by repeated trypsinization and replating in medium supplemented with fetal calf serum. When myofibres from dissociated muscles were cultured under the same conditions, they never fragmented or divided.     

An autoradiographic study of the role of satellite cells and myonuclei during myogenesis in vitro

Satellite cells and myonuclei of neonatal rat muscles were differentially labeled with 3H-thymidine according to the procedure of Moss and Leblond (1971). Minced muscles fragments containing either labeled satellite cells or labeled myonuclei were cultured until multinucleated myotubes grew out from the explants. Reutilzation of isotope released from degenerating nuclei was competitively inhibited by using a culture medium containing excess (0.32-0.41 mM) cold thymidine. after an 8-10 day growth period, the explants were fixed and prepared for autoradiographic (ARG) examination to determine whether labeled satellite cells or myonuclei had contributed to the myonuclear population of the developing myotubes. Counts were made of the number of labeled myotubes in the explants and compared with the number of labeled satellite cells and myonuclei in samples of the original muscle tissues fixed at the time of explantation. The original muscles showed a mean satellite cell labeling index of 51.7% and gave rise to myotubes with a mean labeling incidence of 40%. In contrast, myonuclear labeling in the original muscle tissues showed no correlation with subsequent myotube labeling. Only 3.4% myotube labeling was found in explants in which over 30% of the original tissue myonuclei had been labeled. Under conditions controlled for isotope reutilization, these observations confirm results of in vivo ARG studies indicating that satellite cells are the only significant source of regenerating myoblasts in injured muscle tissue.