Role of Ca and Ca-activated protease in myoblast fusion

In this report, we have examined the effects of a calcium chelator, EGTA, and a calcium ionophore, A23187, on fusion of a cloned muscle cell line, L₆. Our results confirm that EGTA essentially blocks all myoblast fusion because the lateral alignment of presumptive myoblasts cannot occur in the absence of extracellular calcium. A23187, however, promotes the precocious fusion of myoblasts, apparently by facilitating Ca²⁺ transport into myoblasts. We have also demonstrated that a Ca²⁺-activated protease, CAP (mM), appears to relocate in response to the Ca²⁺ flux, changing from a random, dispersed distribution in proliferative myoblasts to a predominantly peripheral distribution in prefusion myoblasts. Coincident with the mM CAF relocation is an altered distribution of a surface glycoprotein, fibronectin. Extracellular fibronectin is seen in abundance in proliferating myoblasts, but is essentially absent from the surface of fusing myoblasts. We suggest that mM CAF when activated by Ca²⁺ influx may act to promote the release of fibronectin from the myoblast cell surface, thus providing a mechanism by which the membrane of the fusing myoblast may be rearranged to accommodate fusion.     

Detection of myosin in prefusion G0 lizard myoblasts in vitro.

The relationships between withdrawal of myoblasts from the cell cycle, myosin synthesis, and myoblast fusion have been examined in cultures of skeletal muscle derived from the regenerating tail of the lizard Anolis carolinensis. Utilizing both immunocytochemistry and transmission electron microscopy, we have demonstrated the presence of myosin in mononucleated lizard myoblasts which have entered a prefusion G₀ period. A model is presented summarizing our current view of lizard myogenesis in vitro.     

Reentry into the cell cycle of differentiated skeletal myocytes

The activation of muscle-specific myosin synthesis and its relationship to withdrawal from the cell cycle have been examined in cycle-synchronized myoblasts under growth-restrictive, fusion-impermissive (low Ca²⁺) culture conditions. Under these conditions, embryonic quail skeletal myoblasts, collected in mitosis by mechanical shake-off, complete one normal cycle and arrest in G₁. The presence of skeletal muscle myosin is first detected, by indirect immunofluorescence, 8 hr into this protracted G₁. Within the next 10–11 hr the percentage myosin positive (Myo+) cells increases with good synchrony, reaching approximately 95%. Refeeding with a proliferation-stimulating, low Ca²⁺ medium when approximately 50% of the cells are Myo+ induces reentry into S. Applying a 15-min pulse with [³H]TdR immediately preceding fixation at regular intervals following refeeding, cells can be detected which are Myo+ and whose nuclei have incorporated [³H]TdR. The numbers of such doubly labeled cells are small but consistent with the fraction of cells in S (by time-lapse analysis) at the postfeeding times sampled. These cinematographic studies also indicate that progression to mitosis following stimulation occurs slowly and asynchronously. The kinetics of progression of the stimulated cells suggest that they reenter S from a different compartment in G₁ than do log-phase myoblasts. We conclude that in fusion-blocked quail myocytes irreversible withdrawal from the cell cycle is neither an obligate precondition for, nor an immediate consequence of the activation of the muscle-specific contractile gene set.     

Mechanism of soybean trypsin inhibitor induced polyspermy as determined by an analysis of refertilized sea urchin (Arbacia punctulata) eggs

The decreased growth rate observed in older muscle cultures has been attributed to the withdrawal of cells from the proliferative pool by fusion. The possibility was examined that this decrease reflects changes in the cell cycle as well. Before fusion, the cycle is relatively short and uniform (10.0 ± 2.7 hr) becoming greatly extended and more variable (19.2 ± 8.5 hr) in cultures undergoing fusion. Most of the increase in generation time is introduced by a long, variable G₁ phase, that phase to which fusion is restricted. These stage-specific cycle characterstics are a function of changes occurring in the medium, rather than of time in culture. Older cultures, refed fresh medium acquire the cell cycle characteristics of younger cultures, and conversely, early cultures fed medium collected from older cultures exhibit cycle measurements typical of older cultures.Although the mean G₁ time almost doubles at the time of fusion, there is no evidence that cells actually withdraw from the cycle prior to fusion. Continuous labeling before and after the initiation of fusion indicate that at all stages virtually 100% of the mononucleated cells incorporate ³H-TdR. Since fusion occurs in G₁, it seems reasonable to assume that some preparation for fusion occurs during this phase and the probability of fusion increases with protraction of G₁.     

Role of Ca2+ and Ca2+-activated protease in myoblast fusion

In this report, we have examined the effects of a calcium chelator, EGTA, and a calcium ionophore, A23187, on fusion of a cloned muscle cell line, L6. Our results confirm that EGTA essentially blocks all myoblast fusion because the lateral alignment of presumptive myoblasts cannot occur in the absence of extracellular calcium. A23187, however, promotes the precocious fusion of myoblasts, apparently by facilitating Ca2+ transport into myoblasts. We have also demonstrated that a Ca2+-activated protease, CAF (mM), appears to relocate in response to the Ca2+ flux, changing from a random, dispersed distribution in proliferative myoblasts to a predominantly peripheral distribution in prefusion myoblasts. Coincident with the mM CAF relocation is an altered distribution of a surface glycoprotein, fibronectin. Extracellular fibronectin is seen in abundance in proliferating myoblasts, but is essentially absent from the surface of fusing myoblasts. We suggest that mM CAF when activated by Ca2+ influx may act to promote the release of fibronectin from the myoblast cell surface, thus providing a mechanism by which the membrane of the fusing myoblast may be rearranged to accommodate fusion.     

Development of normal and genetically dystrophic mouse muscle in tissue culture : I. Prefusion and fusion activities of muscle cells: Phase contrast and time lapse study

Dispersed cell cultures, derived from the forelimbs and hindlimbs of genetically dystrophic (dy/dy) and normal (+/+) day mouse embryos were studied with phase contrast microscopy and time lapse cinematography. The composition of the cell populations, and the prefusion and fusion activities of the cells were analysed. Forelimbs of both normal and dystrophic embryos consistently yielded fewer mononucleated cells, more fat cells and fewer myoblasts than hindlimbs, but there was no difference in the population of cells from normal and dystrophic limbs. During prefusion, myoblasts (both normal and dystrophic) exhibited (1) an apparent lack of contact inhibition of locomotion, which was in actuality an extensive movement of one myoblast under another; (2) formation of prefusion aggregates that broke up and realigned into new aggregates before fusion; (3) a special type of post-mitotic association and reassociation, not found among fibroblasts. Onset of rapid cell fusion of myoblasts occurred in a 4 to 8 h period, and was directly dependent upon initial cell concentration. No differences were found between cultures of normal and dystrophic cells in their prefusion activities or in time of onset of rapid cell fusion, when initial concentrations of cells were kept constant. The results of the present study are compared with those of other in vitro studies of dystrophic muscle.     

Ultrastructural studies of lizard (Anolis carolinensis) myogenesis in vitro

In vitro differentiation of lizard (Anolis carolinensis) skeletal muscle cells was studied by electron microscopy. Myogenesis was studied under conditions in which large numbers of postmitotic prefusion myoblasts accumulate (Growth Medium) and under conditions which are permissive for myotube formation (Fusion Medium). In Growth Medium, myogenic cells proliferate, then assume a characteristic spherical morphology which permits definitive identification of prefusion myoblasts. During the early stages of culture, these round myoblasts resemble myoblasts described in other systems; ultrastructural similarities and differences are discussed. After longer periods of culture in Growth Medium, a continuum of differentiation from isolated myofilaments to assembled myofibrils was seen in these mononucleated cells. These observations confirm the dissociability of contractile protein assembly and myoblast fusion Cultures maintained in Fusion Medium or transferred from Growth Medium to Fusion Medium form multinucleated myotubes on a predictable time scale. Myogenesis was followed in these cultures with particular reference to the early events in myofilament assembly and myofibril formation.     

In differentiating prefusion myoblasts connexin43 gap junction coupling is upregulated before myoblast alignment then reduced in post-mitotic cells

Previously we have shown that during in vivo muscle regeneration differentiating rat primary myoblasts transiently upregulate connexin43 (Cx43) gap junctions and leave cell cycle synchronously. Here, we studied the temporal regulation of Cx expression in relation to functional dye coupling in allogenic primary myoblast cultures using western blotting, immuno-confocal microscopy and dye transfer assays. As in vivo, Cx43 was the only Cx isotype out of Cx26, 32, 37, 40, 43 and 45 found in cultured rat myoblasts by immunostaining. Cultured myoblasts showed similar temporal regulation of Cx43 expression and phenotypic maturation to those regenerating in vivo. Cx43 protein was progressively upregulated in prefusion myoblasts, first by the cytoplasmic assembly in sparse myoblast meshworks and then in cell membrane particles in aligned cells. Dye injection using either Lucifer Yellow alone, Cascade Blue with a non-junction permeant FITC-dextran revealed an extensive gap junction coupling between the sparse interacting myoblasts and a reduced communication between the aligned, but still prefused cells. The aligned myoblasts, uniformly upregulate p21^waf1/cip1 and p27^kip1 cell cycle control proteins. Taken together, in prefusion myoblasts less membrane-bound Cx43 was found to mediate substantially more efficient dye coupling in the growing cell fraction than those in the aligned post-mitotic myoblasts. These and our in vivo results in early muscle differentiation are consistent with the role of Cx43 gap junctions in synchronizing cell cycle control of myoblasts to make them competent for a coordinated syncytial fusion.     

Quantal Division and a Postmitotic State in Myoblast Differentiation

The reversible arrest of myoblast differentiation by ethidium bromide (EB) has been used to examine the nature of the transition from the proliferative state to terminal differentiation resulting in fusion into muscle fibers. If EB is introduced at the time that myoblasts are shifted to medium that induces fusion, all apparent cytodifferentiation is suspended. When such EB arrested myoblasts are released from EB inhibition they fuse without reentering the cell cycle. If EB arrested myoblasts are released into proliferation promoting medium rather than medium that induces fusion they neither fuse nor proliferate. In this case they remain quiescent in the proliferating medium for an extended period, however, if these myoblasts are subsequently shifted to medium that induces fusion, they fuse without reentering the cell cycle. Apparently the myoblasts have become postmitotic and competent to fuse into muscle fibers during their initial exposure to fusion inducing medium, even though cytodifferentiation has been blocked. Exposure of these postmitotic fusion competent myoblasts to proliferation promoting medium does not stimulate them to reenter the cell cycle but does prevent fusion into muscle fibers. These results are most consistent with a quantal division model of myoblast differentiation rather than a gradual transition from the proliferative state to a state in which fusion occurs.     

kette and blown fuse interact genetically during the second fusion step of myogenesis in Drosophila

Drosophila myoblast fusion proceeds in two steps. The first one gives rise to small syncytia, the muscle precursor cells, which then recruit further fusion competent myoblasts to reach the final muscle size. We have identified Kette as an essential component for myoblast fusion. In kette mutants, founder cells and fusion-competent myoblasts are determined correctly and overcome the very first fusion. But then, at the precursor cell stage, fusion is interrupted. At the ultrastructural level, fusion is characterised by cell-cell recognition, alignment, formation of prefusion complexes, electron dense plaques and membrane breakdown. In kette mutants, electron dense plaques of aberrant length accumulate and fusion is interrupted owing to a complete failure of membrane breakdown. Furthermore, we show that kette interacts genetically with blown fuse (blow) which is known to be required to proceed from prefusion complexes to the formation of the electron dense plaques. Interestingly, a surplus of Kette can replace Blow function during myogenesis. We propose a model in which Dumbfounded/Sticks and stones-dependent cell adhesion is mediated over Rolling Pebbles, Myoblast city, Crk, Blown fuse and Kette, and thus induces membrane fusion.     

Quantal division and a postmitotic state in myoblast differentiation.

The reversible arrest of myoblast differentiation by ethidium bromide (EB) has been used to examine the nature of the transition from the proliferative state to terminal differentiation resulting in fusion into muscle fibers. If EB is introduced at the time that myoblasts are shifted to medium that induces fusion, all apparent cytodifferentiation is suspended. When such EB arrested myoblasts are released from EB inhibition they fuse without reentering the cell cycle. If EB arrested myoblasts are released into proliferation promoting medium rather than medium that induces fusion they neither fuse nor proliferate. In this case they remain quiescent in the proliferating medium for an extended period, however, if these myoblasts are subsequently shifted to medium that induces fusion, they fuse without reentering the cell cycle. Apparently the myoblasts have become postmitotic and competent to fuse into muscle fibers during their initial exposure to fusion inducing medium, even though cytodifferentiation has been blocked. Exposure of these postmitotic fusion competent myoblasts to proliferation promoting medium does not stimulate them to reenter the cell cycle but does prevent fusion into muscle fibers. These results are most consistent with a quantal division model of myoblast differentiation rather than a gradual transition from the proliferative state to a state in which fusion occurs.     

Differential Effects of 3,5,3′-Triiodothyronine on Control andmdxMyoblasts and Fibroblasts: Analysis by Flow Cytometry

The possibility of differential effects of triiodothyronine (T3) treatmentin vivoon myoblast and fibroblast cell proliferation was examined in control andmdxmuscle cultures. Cell isolates were purified in a Percoll gradient, sorted by flow cytometry (light scatter), and characterized as myoblasts and fibroblasts using anti-skeletal muscle myosin fluorescence. The two cell types were grown separately or remixed (1:1). Cultures were incubated with or without T3 (10⁻⁹M) for 19 h. Cells were either exposed to [³H]thymidine for 1 h and DNA prepared for scintillation counts or stained with propidium iodide for cell cycle analysis by flow cytometry. Overall [³H]thymidine uptake per cell was greater inmdxthan control cells (mainly fibroblasts and mixed cells) and was decreased by T3 only in myoblast and mixed cultures. Cell cycle data showed that the effects of T3 originated primarily at the G₀/G₁phase. There were moremdxthan control myoblasts at G₀/G₁without T3. After T3 treatment, more control fibroblasts than myoblasts were at G₀/G₁, but moremdxmyoblasts than fibroblasts were at G₀/G₁. In the absence of T3, there were also fewermdxthan control myoblasts in S. After T3, only the proportion ofmdxmyoblasts in S phase was reduced. Results are consistent with distinct T3 effects on muscle regenerationin vivoand support the hypothesis that cycling and proliferation ofmdxand control myoblasts are differentially modulated by T3. As control andmdxfibroblasts also showed distinct responses to T3, muscle regeneration likely occurs by a complex regulation of gene expression endogenous to specific cell types as well as interactions between cells of different lineage.     

Changes in adenylate cyclase,cyclic AMP,and protein kinase levels in chick myoblasts,and their relationship to differentiation

Examination of components of the cAMP system in primary cultures of differentiating chick myoblasts revealed a basal intracellular cAMP level of 50–100 pmole/mg of DNA, which increased ten to fifteen-fold for approximately 1 hr between 37.5 and 39.5 hr of culture, only 5–6 hr before the initiation of myoblast fusion. Activities of the enzymes adenylate cyclase and protein kinase were examined during the initial stages of myoblast differentiation. Both the basal activity and the degree of NaF stimulation of adenylate cyclase increased during the time examined, the appearance of these changes coinciding in time of culture with the observed peak of cAMP. The protein kinase present was sensitive to cAMP, and its basal and cAMP stimulated activities increased throughout the prefusion period of culture. The results suggest a causal relationship between the increase in adenylate cyclase activities, the increase in intracellular cAMP, and the onset of fusion; and the possibility that intracellular cAMP levels control the expression of myoblast differentiation is discussed.     

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.     

Myotomal myogenesis inBombina variegata L.

Summary InBombina variegata, striated myofibrils first appear in G₂ uninucleated primary myoblasts. Multinucleated muscle fibres form later as a result of the fusion of primary myobasts with secondary myoblasts of mesenchymal origin. The nuclei of the polykaryocytes vary in size and DNA content (nuclear dimorphism). The larger nuclei of the primary myoblasts retain tetraploid quantities of DNA, whereas the smaller nuclei of the secondary myoblasts are diploid. From this we conclude that fusion can take place between cells that are in different phases of the cell cycle (G₁–G₂). Our findings are compared with those on myogenesis in other chordate species and are confronted with the current commonly accepted model of vertebrate muscle differentiation.This work is dedicated to Professor Kazimierz Sembrat on his 55-th anniversary of research workThis research was supported in part by Nencki Institute of Experimental Biology, Polish Academy of Sciences, Warsaw, Poland     

MITOSIS AND THE PROCESSES OF DIFFERENTIATION OF MYOGENIC CELLS IN VITRO

The relation between the mitotic cycle and myoblast fusion has been studied in chick skeletal muscle in vitro. The duration of the cell cycle phases was the same in both early and late cultures. By tracing a cohort of pulse-labeled cells, it was found that myoblast fusion does not occur in S, G₂, or M. Cell surface alterations required for fusion are dependent upon the position of the cell in the division cycle. In early cultures, fusion takes place only after a minimum delay of 5 hr from the time the cell has entered G₁. The mitosis preceding fusion may condition the cell for the abrupt shift in synthetic activity that occurs in the subsequent G₁. In older cultures fusion of labeled cells is diminished. Two factors account for the cessation of fusion in older cultures. First, the number of myogenic stem cells declines, but these cells do not disappear as the cultures mature. Their persistence was demonstrated by labeling dividing mononucleated cells in older cultures and challenging them with nascent myotubes. Some of these labeled cells were incorporated into the forming myotubes. Second, a block to fusion develops during myotube maturation. Well developed myotubes challenged with labeled competent myogenic cells failed to incorporate the labeled nuclei.     

Viral transformation of rat myoblasts: effects on fusion and surface properties.

Lines of rat myoblasts infected by avian sarcoma viruses have been isolated, cloned, and used to study the effects of viral transformation on myogenic differentiation and the surface changes associated with differentiation. The lines transformed by sarcoma viruses failed to fuse into myotubes and did not show the increase in myosin synthesis normally associated with fusion. The parental nontransformed line showed, subsequent to fusion, a surface alteration detectable by external labeling methods. This alteration, an increase in the level of an external protein of MW > 200 × 10³, is similar to that observed in fibroblasts arrested in the G₁ phase of the cell cycle. This protein was absent or greatly reduced on the surfaces of the myoblast lines that had been transformed by sarcoma viruses. Therefore, viral transformation causes loss of several properties normally associated with arrest of myoblasts in G₁.     

Differentiation of quail myoblasts transformed with a temperature sensitive mutant of Rous sarcoma virus. II. Relationship of myoblast fusion with calcium and temperature.

The effects of calcium and temperature on fusion of quail embryonic myoblasts were examined using cells transformed with a temperature-sensitive mutant of Rous sarcoma virus (ts-RSV). The transformed quail myoblasts (QM-RSV) fused to form myotubes at 41 degrees C, the non-permissive temperature, but not at 35.5 degrees C, the permissive temperature. On incubation at 41 degrees C, a period of more than 10 hr was needed for the myoblasts to become fusion-competent, but calcium was not needed for development of fusion-competence. Once the cells had become competent, fusion proceeded even at 35.5 degrees C. These results suggest that the src gene product expressed at 35.5 degrees C may control the fusion of cells in the competent stage by inactivating a component(s) that is associated with fusion-competence. However, fusion of even myoblasts in the competent stage was blocked in calcium-deficient medium, suggesting that calcium is essential for the fusion, probably at a step immediately before membrane union. Unlike fusion, other biochemical processes of differentiation proceeded even in calcium-deficient medium, indicating a distinction of fusion from these other processes during myoblast differentiation.     

Transient involvement of gap junctional communication before fusion of newborn rat myoblasts

Heptanol-sensitive gap junction communication was characterized by the gap-FRAP method (fluorescence recovery after photobleaching) in confluent rat myoblasts developing in primary culture. Cell to cell dye diffusion was mainly restricted to a short period of the prefusion lag period and disappeared duringfusion promotion except between some myoblasts and myotubes. This short period of occurrence of gap junction communication might be transiently and partially involved during the first steps preparing the subsequent fusion, since treatment with an uncoupler (heptanol) reduced the formation of multinucleated myotubes. During subsequent steps, functional gap junctions are not involved between myoblasts in the process of fusing, but a possible secondary involvement for fusion of remaining myoblasts to newly-formed myotubes is discussed. These data, together with results from other authors, suggest a regulatory role of gap junction communication in development and fusion of skeletal muscle cells, by providing a pathway for exchanging small molecules from one myoblast to another.