Control of myoblast fusion by a guanine nucleotide exchange factor, loner, and its effector ARF6

Myoblast fusion is essential for the formation and regeneration of skeletal muscle. In a genetic screen for regulators of muscle development in Drosophila, we discovered a gene encoding a guanine nucleotide exchange factor, called loner, which is required for myoblast fusion. Loner localizes to subcellular sites of fusion and acts downstream of cell surface fusion receptors by recruiting the small GTPase ARF6 and stimulating guanine nucleotide exchange. Accordingly, a dominant-negative ARF6 disrupts myoblast fusion in Drosophila embryos and in mammalian myoblasts in culture, mimicking the fusion defects caused by loss of Loner. Loner and ARF6, which also control the proper membrane localization of another small GTPase, Rac, are key components of a cellular apparatus required for myoblast fusion and muscle development. In muscle cells, this fusigenic mechanism is coupled to fusion receptors; in other fusion-competent cell types it may be triggered by different upstream signals.     

Sythesis of tropomyosin in cultures of differentiating muscle cells

The accumulation of tropomyosin in cultures of differentiating muscle cells was quantitatively measured. Tropomyosin was isolated from cultured cells during and after myoblast fusion; both alpha- and beta- subunits were present in myotube cultures. During fusion small amounts of tropomyosin were detectable, but, as fusion approached a maximum, tropomyosin accumulation began to increase. The increased synthesis of tropomyosin after the initiation of muscle cell fusion is consistent with the increased synthesis of other proteins characteristic of muscle, including myosin.     

Myoblast fusion: lessons from flies and mice

The fusion of myoblasts into multinucleate syncytia plays a fundamental role in muscle function, as it supports the formation of extended sarcomeric arrays, or myofibrils, within a large volume of cytoplasm. Principles learned from the study of myoblast fusion not only enhance our understanding of myogenesis, but also contribute to our perspectives on membrane fusion and cell-cell fusion in a wide array of model organisms and experimental systems. Recent studies have advanced our views of the cell biological processes and crucial proteins that drive myoblast fusion. Here, we provide an overview of myoblast fusion in three model systems that have contributed much to our understanding of these events: the Drosophila embryo; developing and regenerating mouse muscle; and cultured rodent muscle cells.     

Development of the sarcotubular system in fusion-arrested myoblasts.

We have compared the effect of two different procedures, equally effective in preventing muscle cell fusion in culture, on the development of the sarcotubular system in rat muscle cells. Whereas in myoblasts grown in low Ca++ medium the T system was poorly developed and diadic or triadic couplings between T tubules and sarcoplasmic reticulum were rare, in cytochalasin B-treated myoblasts the development of the sarcotubular system was comparable to that seen in myotubes of the same age. We conclude that (a) muscle cell fusion is not essential for the development of the sarcotubular system, and (b) procedures used to prevent cell fusion in vitro may affect directly muscle cell differentiation by a process independent of the fusion block.     

Normal myoblast fusion requires myoferlin

Muscle growth occurs during embryonic development and continues in adult life as regeneration. During embryonic muscle growth and regeneration in mature muscle, singly nucleated myoblasts fuse to each other to form myotubes. In muscle growth, singly nucleated myoblasts can also fuse to existing large, syncytial myofibers as a mechanism of increasing muscle mass without increasing myofiber number. Myoblast fusion requires the alignment and fusion of two apposed lipid bilayers. The repair of muscle plasma membrane disruptions also relies on the fusion of two apposed lipid bilayers. The protein dysferlin, the product of the Limb Girdle Muscular Dystrophy type 2 locus, has been shown to be necessary for efficient, calcium-sensitive, membrane resealing. We now show that the related protein myoferlin is highly expressed in myoblasts undergoing fusion, and is expressed at the site of myoblasts fusing to myotubes. Like dysferlin, we found that myoferlin binds phospholipids in a calcium-sensitive manner that requires the first C2A domain. We generated mice with a null allele of myoferlin. Myoferlin null myoblasts undergo initial fusion events, but they form large myotubes less efficiently in vitro, consistent with a defect in a later stage of myogenesis. In vivo, myoferlin null mice have smaller muscles than controls do, and myoferlin null muscle lacks large diameter myofibers. Additionally, myoferlin null muscle does not regenerate as well as wild-type muscle does, and instead displays a dystrophic phenotype. These data support a role for myoferlin in the maturation of myotubes and the formation of large myotubes that arise from the fusion of myoblasts to multinucleate myotubes.     

Jamb and jamc are essential for vertebrate myocyte fusion

Cellular fusion is required in the development of several tissues, including skeletal muscle. In vertebrates, this process is poorly understood and lacks an in vivo-validated cell surface heterophilic receptor pair that is necessary for fusion. Identification of essential cell surface interactions between fusing cells is an important step in elucidating the molecular mechanism of cellular fusion. We show here that the zebrafish orthologues of JAM-B and JAM-C receptors are essential for fusion of myocyte precursors to form syncytial muscle fibres. Both jamb and jamc are dynamically co-expressed in developing muscles and encode receptors that physically interact. Heritable mutations in either gene prevent myocyte fusion in vivo, resulting in an overabundance of mononuclear, but otherwise overtly normal, functional fast-twitch muscle fibres. Transplantation experiments show that the Jamb and Jamc receptors must interact between neighbouring cells (in trans) for fusion to occur. We also show that jamc is ectopically expressed in prdm1a mutant slow muscle precursors, which inappropriately fuse with other myocytes, suggesting that control of myocyte fusion through regulation of jamc expression has important implications for the growth and patterning of muscles. Our discovery of a receptor-ligand pair critical for fusion in vivo has important implications for understanding the molecular mechanisms responsible for myocyte fusion and its regulation in vertebrate myogenesis.     

5-Azacytidine permits gene activation in a previously noninducible cell type

We previously reported that silent muscle genes in fibroblasts could be activated following fusion with muscle cells to form heterokaryons. This activation did not require changes in chromatin structure involving significant DNA synthesis. We report here that muscle gene activation was never observed when HeLa cells were used as the nonmuscle fusion partner. However, if HeLa cells were treated with 5-azacytidine (5-aza-CR) prior to fusion, muscle gene expression was induced in the heterokaryons. The genes for both an early (5.1H11 cell surface antigen) and a late (MM-creatine kinase) muscle function were activated, but were frequently not coordinately expressed. These results suggest that the expression of two muscle genes, which is usually sequential, is not interdependent. Furthermore, changes induced by 5-aza-CR, presumably in the level of DNA methylation, are required for muscle genes in HeLa cells to be expressed in response to putative trans-acting regulatory factor(s) present in muscle cells.     

Dependence of myoblast fusion on a cortical actin wall and nonmuscle myosin IIA

Cell-cell fusion is a fundamental cellular process that is essential for development as well as fertilization. Myoblast fusion to form multinucleated skeletal muscle myotubes is a well studied, yet incompletely understood example of cell-cell fusion that is essential for formation of contractile skeletal muscle tissue. Studies in this report identify several novel cytoskeletal events essential to an early phase of myoblast fusion among cultured murine myoblasts. During myoblast pairing and alignment, cortical actin filaments organize into a dense actin wall structure that parallels and extends the length of the plasma membrane of the bipolar, aligned cells. As fusion progresses, gaps appear within the actin wall at sites of vesicle accumulation, the vesicles pair across the aligned myoblasts, cell-cell contacts and fusion pores form. Inhibition of nonmuscle myosin IIA (NM-MHC-IIA) motor activity prevents formation of this cortical actin wall, as well as the appearance of vesicles at a membrane proximal location, and myoblast fusion. These results suggest that early formation of a subplasmalemmal actin wall during myoblast alignment is a critical event for myoblast fusion that supports bipolar membrane alignment and temporally regulates trafficking of vesicles to the nascent fusion sites during skeletal muscle myoblast differentiation.     

Characterisation of the role of Vrp1 in cell fusion during the development of visceral muscle of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

Background  

In Drosophila muscle cell fusion takes place both during the formation of the somatic mesoderm and the visceral mesoderm, giving rise to the skeletal muscles and the gut musculature respectively. The core process of myoblast fusion is believed to be similar for both organs. The actin cytoskeleton regulator Verprolin acts by binding to WASP, which in turn binds to the Arp2/3 complex and thus activates actin polymerization. While Verprolin has been shown to be important for somatic muscle cell fusion, the function of this protein in visceral muscle fusion has not been determined.     

Spatial and functional restriction of regulatory molecules during mammalian myoblast fusion

Myoblast fusion is a highly regulated process that is key for forming skeletal muscle during development and regeneration in mammals. Much remains to be understood about the molecular regulation of myoblast fusion. Some molecules that influence mammalian muscle fusion display specific cellular localization during myogenesis. Such molecules can be localized to the contact region between two fusing cells either in both cells or only in one of the cells. How distinct localization of molecules contributes to fusion is not clear. Further complexity exists as other molecules are functionally restricted to myoblasts at later stages of myogenesis to regulate their fusion with multinucleated myotubes. This review examines these three categories of molecules and discusses how spatial and functional restriction may contribute to the formation of a multinucleated cell. Understanding how and why molecules become restricted in location or function is likely to provide further insights into the mechanisms regulating mammalian muscle fusion.     

The zebrafish fast myosin light chain mylpfa:H2B-GFP transgene is a useful tool for in vivo imaging of myocyte fusion in the vertebrate embryo

BackgroundSkeletal muscle fibers are multinucleated syncytia that arise from the fusion of mononucleated precursors, the myocytes, during embryonic development, muscle hypertrophy in post-embryonic growth and muscle regeneration after injury. Even though myocyte fusion is central to skeletal muscle differentiation, our current knowledge of the molecular mechanism of myocyte fusion in the vertebrates is rather limited. Previous work, from our group and others, has shown that the zebrafish embryo is a very useful model for investigating the cell biology and genetics of vertebrate myocyte fusion in vivo.ResultsHere, we report the generation of a stable transgenic zebrafish strain that expresses the Histone 2B-GFP (H2B-GFP) fusion protein in the nuclei of all fast-twitch muscle fibers under the control of the fast-twitch muscle-specific myosin light chain, phosphorylatable, fast skeletal muscle a (mylpfa) gene promoter. By introducing this transgene into a mutant for junctional adhesion molecule 3b (jam3b), which encodes a cell adhesion protein previously implicated in myocyte fusion, we demonstrate the feasibility of using this transgene for the analysis of myocyte fusion during the differentiation of the trunk musculature of the zebrafish embryo.ConclusionsSince we know so little about the molecules regulating vertebrate myocyte fusion, we propose that the mylpfa:H2B-GFP transgene will be a very useful reporter for conducting forward and reverse genetic screens to identify new components regulating vertebrate myocyte fusion.     

Towards a molecular pathway for myoblast fusion in Drosophila

Intercellular fusion among myoblasts is required for the generation of multinucleated muscle fibers during skeletal muscle development. Recent studies in Drosophila have shed light on the molecular mechanisms that underlie this process, and a signaling pathway that relays fusion signals from the cell membrane to the cytoskeleton has emerged. In this article, we review these recent advances and discuss how Drosophila offers a powerful model system to study myoblast fusion in vivo.     

c-MET Regulates Myoblast Motility and Myocyte Fusion during Adult Skeletal Muscle Regeneration

Adult muscle stem cells, satellite cells (SCs), endow skeletal muscle with tremendous regenerative capacity. Upon injury, SCs activate, proliferate, and migrate as myoblasts to the injury site where they become myocytes that fuse to form new muscle. How migration is regulated, though, remains largely unknown. Additionally, how migration and fusion, which both require dynamic rearrangement of the cytoskeleton, might be related is not well understood. c-MET, a receptor tyrosine kinase, is required for myogenic precursor cell migration into the limb for muscle development during embryogenesis. Using a genetic system to eliminate c-MET function specifically in adult mouse SCs, we found that c-MET was required for muscle regeneration in response to acute muscle injury. c-MET mutant myoblasts were defective in lamellipodia formation, had shorter ranges of migration, and migrated slower compared to control myoblasts. Surprisingly, c-MET was also required for efficient myocyte fusion, implicating c-MET in dual functions of regulating myoblast migration and myocyte 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.     

Antisocial, an intracellular adaptor protein, is required for myoblast fusion in Drosophila.

Somatic muscle formation in Drosophila requires fusion of muscle founder cells with fusion-competent myoblasts. In a genetic screen for genes that control muscle development, we identified antisocial (ants), a gene that encodes an ankyrin repeat-, TPR repeat-, and RING finger-containing protein, required for myoblast fusion. In ants mutant embryos, founder cells and fusion-competent myoblasts are properly specified and patterned, but they are unable to form myotubes. ANTS, which is expressed specifically in founder cells, interacts with the cytoplasmic domain of Dumbfounded, a founder cell transmembrane receptor, and with Myoblast city, a cytoskeletal protein, both of which are also required for myoblast fusion. These findings suggest that ANTS functions as an intracellular adaptor protein that relays signals from Dumbfounded to the cytoskeleton during myoblast 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.