Studies on intercellular LETS glycoprotein matrices

Intercellular matrices secreted by chick embryo fibroblasts in culture were studied by scanning electron microscopy. Cell-cell contact is a prerequisite for the expression of such matrices. The smallest fiber detected by transmission electron microscopy is 5--10 nm in diameter. These matrix fibers tend to cluster to form bundles. Immunofluorescence and immunoferritin procedures reveal that LETS protein is one of the components of the matrices. The matrices are isolated from other cellular organelles by detergent treatment. More than 90% of the proteins in cell-free matrices are LETS protein, suggesting that the matrices are probably made of only one component--LETS protein. Since the solubilization of matrices requires beta-mercaptoethanol, LETS protein matrices may be the first known polymer system in nature to use disulfide linkage as an intermolecular polymerization vehicle. Collagen does not appear to be involved in such matrices. The LETS protein matrix supports the morphological conversion of rounded cells into spindle-shaped, and also promotes myoblast fusion. It does not, however, exert an effect upon cell growth, the rate of glucose uptake or protease production.     

Role of disulfide bonds in the attachment and function of large, external, transformation-sensitive glycoprotein at the cell surface

Reduction of disulfide linkages by dithiothreitol removes LETS (large, external, transformation-sensitive) protein from the cell surface. This process is dependent upon the concentration of dithiothreitol and the time and temperature of reaction. At 0 degrees C the release of LETS protein by dithiothreitol is completely blocked, but this is apparently not due to a requirement for metabolic energy. At this temperature, reduction of LETS protein is incomplete. These results suggest that intact disulfide bonds are involved in the retention of this protein on the cell surface. Furthermore, reduction of purified LETS protein interferes with its ability to confer flattened morphology and increased adhesivity when added to transformed cells. It appears, therefore, that disulfide bonds are functionally important at the cell surface.     

Surface distribution of LETS protein in relation to the cytoskeleton of normal and transformed cells

The organization of LETS protein on the surface of NIL8 hamster cells has been examined by immunofluorescence staining. The distribution of LETS protein was found to depend on the culture conditions; in subconfluent, low-serum arrested cultures the LETS protein is predominantly located at the cell-substrate interface and also in regions of cell-cell contact, whereas in dense cultures the cells are surrounded by a network of LETS protein fibrils. Transformed derivatives of these cells exhibit only sporadic staining for LETS protein, in the form of short intercellular bridges. Agents that cause alterations in cell shape and cytoplasmic filaments have been used to explore the relationship of LETS protein to the internal cytoskeletal elements. Reciprocally, perturbations of the cell surface were examined for their effects on internal filaments. The arrangement of microtubules seems to be unrelated to the presence of LETS protein in the cells studied. Actin microfilament bundles and LETS protein respond in a coordinate fashion to some perturbants but independently with respect to others. The patterns of staining for LETS protein are consistent with an involvement in cell-to-cell and cell-to-substrate adhesion.     

Restoration of normal morphology, adhesion and cytoskeleton in transformed cells by addition of a transformation-sensitive surface protein.

Transformed cells lack a large, external, transformation-sensitive (LETS) glycoprotein which is a major surface component of their normal counterparts. Addition of LETS glycoprotein isolated from normal cells to transfomed cells restores certain morphological features and adhesive properties characteristic of normal cells. LETS protein is detected on the cell surface both by iodination using lactoperoxidase and by immunofluorescent staining. The surface distribution pattern detected by immunofluorescence is strikingly similar to that of normal cells. After addition of LETS protein, transformed cells also exhibit well defined actin cables which are not seen in untreated, transformed cells. All these alterations can be blocked by treating LETS protein with specific antisera or by subjecting it to mild trypsinization prior to addition to transformed cells. The effects are rapidly reversible by mild trypsinization, which removes the added LETS protein. The high rate of uptake of 2-deoxyglucose, characteristic of transformed cells, is not affected by LETS protein. These results suggest that LETS protein may have a role in cell attachment and spreading, and affect the organization of cytoskeleton.     

Lack of correlation between the decreased expression of cell surface LETS protein and tumorigenicity in human cell hybrids

An analysis of the correlation between tumorigenicity and the loss of expression of the large external transformation-sensitive glycoprotein (LETS) was performed on human cell hybrids and their respective normal and tumorigenic parental cell lines. The distribution of cell surface LETS protein in a series of cell lines was examined by both specific immunofluorescent staining and by gel electrophoresis of lactoperoxidase-catalyzed, iodinated cell surface proteins. The tumorigenicity of these cell lines was assayed in nude mice. Although the series of cell lines studied provided a broad spectrum of LETS protein expression, both quantitatively and qualitatively, there does not appear to be a correlation between tumorigenicity and decreased expression of the LETS protein.In a series of transformed, nontumorigenic hybrids, the LETS protein expression was found to be altered with respect to both decreased organizational complexity and decreased content. These hybrids continue to express a number of other transformed phenotypes. Conversely, a number of tumorigenic hybrids continue to express relatively high levels of LETS protein when compared with nontumorigenic hybrids. Thus an alteration in LETS protein expression by itself, or in concert with a spectrum of other transformation properties, does not appear to be a sufficient requirement for tumorigenicity and lends further support to an apparent separate control of the transformed versus tumorigenic phenotype.     

Effects of cocultivation with transformed cells on surface proteins of normal cells.

Virally transformed fibroblasts do not have on their surface a major protein (large external transformation-sensitive, LETS) which is present in normal cells. Cocultivation of the transformed cells with normal cells whose surface proteins have been prelabelled induces an accelerated release of the LETS protein from the normal cells. We have investigated various conditions which affect this phenomenon. Our results show that alteration of cell surface proteins by cocultivation with the transformed cells is time and dose-dependent and requires cell contact. Serum was depleted at least 99% of plasminogen by affinity chromatography and used in the cocultivation experiments. It was found that activation of plasminogen was not required for the accelerated turnover of the LETS protein. Other diffusible proteases are also unlikely to be involved. The possibility that transformed cells have a membrane bound activity is discussed. The role of plasminogen activation was also tested for its relevance in transformation related proteolysis, growth and morphology of cells.     

Effects of cocultivation with transformed cells on surface proteins of normal cells

Virally transformed fibroblasts do not have on their surface a major protein (large external transformation-sensitive, LETS) which is present in normal cells. Cocultivation of the transformation cells with normal cells whose surface proteins have been prelabelled induces an accelerated release of the LETS protein from the normal cells. We have investigated various conditions which affect this phenomenon. Our results show that alteration of cell surface proteins by cocultivation with the transformed cells is time and dose-dependent and requires cell contact. Serum was depleted at least 99% of plasminogen by affinity chromatography and used in the cocultivation experiments. It was found that activation of plasminogen was not required for the accelerated turnover of the LETS protein. Other diffusible proteases are also unlikely to be involved. The possibility that transformed cells have a membrane bound activity is discussed. The role of plasminogen activation was also tested for its relevance in transformation related proteolysis, growth and morphology of cells.     

Cell surface proteins of Drosophila. II. A comparison of embryonic and ecdysone-induced proteins

The cell-surface proteins of Drosophila embryos at gastrula and myoblast fusion stages were characterized by radioiodination and two-dimensional gel electrophoresis. Over 13% of the cell surface proteins detected in gastrula embryos were not found in myoblast fusion stage embryos or in Drosophila embryonic cell line EH34A3 cells. Nearly 18% of the cell-surface proteins detected in myoblast fusion stage embryos were evident only at that stage. Embryonic cell-surface proteins were compared with cell-surface proteins from untreated EH34A3 cells and EH34A3 cells treated with 20-hydroxyecdysone, which induces cell aggregation and the expression of "new" proteins at the cell surface (D. F. Woods and C. A. Poodry, 1983, Dev. Biol. 96, 23-31). Only one of the proteins induced by ecdysone in EH34A3 cells was detected in the NP-40 soluble fraction of radioiodinated cell lysates, even after fractionation by lectin affinity chromatography and immunoprecipitation to enrich for putative ecdysone induced proteins. However, extraction of the NP-40 insoluble pellet of embryo cells revealed one additional protein that was present both in myoblast fusion stage embryos and hormone-treated culture cells. It was concluded that except for these two proteins, the cell-surface proteins induced in cultured cell lines by treatment with 20-hydroxyecdysone are not present in significant amounts in gastrula or myoblast fusion stage embryos.     

Quantitation of a transformation-sensitive, adhesive cell surface glycoprotein. Decrease of several untransformed permanent cell lines

We have quantitated the transformation-sensitive, cell surface LETS glycoprotein on many untransformed cell types. By SDS-polyacrylamide gel electrophoresis, this trypsin-sensitive iodinatable glycoprotein comprises 1-3% of total cellular protein of the seven early passage cell types tested. In contrast, it constitutes less than 0.15% of the protein in four of six continuous cell lines. This decrease is reflected in alterations both in [14C]glucosamine labeling and in the immunofluorescent staining of early passage vs. these four permanent cell lines. These results help to clarify previous experiments in which CSP, a purified LETS protein, partially restored a fibroblastic phenotype to cells transformed by tumor viruses. These findings also indicate that a major decrease in this cell surface glycoprotein can occur in the establishment of a continuous cell line without resulting in cellular transformation.     

Spontaneous myoblast fusion is mediated by cell surface Ca-dependent protein kinase(s)

Mononucleated myoblasts divide in vitro until they attain confluency and fuse, forming multinucleated myotubes. Fusion is an extracellular Ca2+-dependent process. We used for our studies an established line of skeletal myoblasts (L6) as well as a non-fusing Myo- alpha-amanitin-resistant mutant of this line (Ama102). Our results show that extracellular calcium at concentrations which elicit myoblast fusion activates the phosphorylation of a protein species of 48 kD, present at the surface of mononucleated myoblasts of the fusing wild type (L6). At fusion, as the cells become independent of the extracellular calcium concentration for their further differentiation, this activation can no longer be observed. In fusion inhibition experiments, where we used lowered calcium levels, the phosphorylation of the 48 kD protein band is clearly decreased. When the myoblasts are fed with standard medium, they fuse rapidly and the phosphorylation of the 48 kD species is markedly increased. The above-described phenomenon takes place at the cell surface and is completed in a short time. The use of Myo- mutant showed that it is developmentally regulated. In view of our results, it is reasonable to postulate that Ca2+-activated phosphorylation of the cell surface could be on the basis of spontaneous myoblast fusion.     

Cell surface and metabolic labelling of the proteins of normal and transformed chicken cells.

We have studied the surface proteins of normal and transformed chick cells using four-labelling techniques with different specificities, (a) lactoperoxidase catalysed iodination (b) galactose oxidase/B3H4 (c) pyridoxal phosphate/B3H4 and (d) periodate/B3H4. All methods labelled a large external transformation-sensitive (LETS) protein, in agreement with previous studies. In addition, using galactose oxidase and periodate labelling techniques, we present evidence which suggests that the transformed cell surface glycoproteins are more sialylated. The LETS protein was also labelled with (14C) glucosamine and after trypsinization a small band of identical molecular weight to LETS remained, possibly representing an internal pool of the protein. In contrast LETS protein labelled with (3H) fucose was completely removed by trypsin, suggesting that the internal pool of the protein is incompletely glycosylated. Evidence is also presented to show that although the level of the protein is drastically reduced at the transformed cell surface, it is still synthesised and shed into the medium.     

Changes in the surface membrane during myoblast fusion.

1. During fusion of chick-embryo myoblasts in culture, the surface membrane is affected as follows. Uptake of 2-aminoisobutyrate and 2-deoxyglucose, each of which is concentrated 20-fold relative to its concentration in the medium, is unaltered; uptake of alpha-methyl glucoside and choline (15 mM), each of which equilibrates relative to its concentration in the medium, approximately doubles. An approximate doubling also occurs in iodinatable surface protein (and in total protein) and in cell surface area as judged by light-microscopy. Adenylate cyclase (in the absence or the presence of fluoride) increases by more than 2-fold. 2. It is concluded that, during myoblast fusion cells increase in size, and this is reflected in an increased rate of simple diffusion; the rate of facilitated processes such as the uptake of amino acids and sugars, on the other hand, remains unaltered, though the activity of certain enzymes is increased. These results indicate that specific changes in the function of surface membrane occur during myoblast fusion in vitro.     

Caspase-1-induced calpastatin degradation in myoblast differentiation and fusion: cross-talk between the caspase and calpain systems

Previously, we found that calpastatin diminished transiently prior to myoblast fusion (rat L8 myoblasts), allowing calpain-induced protein degradation, required for fusion. Here we show that the transient diminution in calpastatin is due to its degradation by caspase-1. Inhibition of caspase-1 prevents calpastatin diminution and prevents myoblast fusion. Caspase-1 activity is transiently increased during myoblast differentiation. Both calpain and caspase appear to be responsible for the fusion-associated membrane protein degradation. Caspase-1 has been implicated in the activation of proinflammatory cytokines, and in cell apoptosis. The involvement of caspase-1 in L8 myoblast fusion represents a novel function for this caspase in a non-apoptotic differentiation process, and points to cross-talk between the calpain and caspase systems in some differentiation processes.     

Inhibition of fusion of embryonic muscle cells in culture by tunicamycin is prevented by leupeptin

The carbohydrate requirement for alignment and fusion of embryonic quail muscle cells has been examined in tissue culture by use of tunicamycin (TM). The mononucleated, spindle-shaped proliferating myoblasts were treated with TM at various times before fusion and differentiation into multinucleated muscle fibers capable of spontaneous contraction. Tm blocked protein glycosylation and expression of glycoproteins on the cell surface, and strongly inhibited fusion when added to cultures of differentiating muscle cells before the fusion "burst," but had no apparent effect on cell alignment. The inhibition of fusion was partially prevented when TM was administered in the presence of protease inhibitors such as leupeptin and pepstatin, but the inhibition of glycosylation was not prevented. Both glycosylation and fusion were completely restored to normal by the removal of the antibiotic from the medium. These studies provide strong support for the idea that myoblast fusion is partially mediated by glycoproteins with asparagine-linked oligosaccharides. However, the requirement for the carbohydrate portion of the glycoprotein appears to be indirect in that it acts to stabilize the protein moiety against proteolytic degradation. Our findings do not rule out the possibility that oligosaccharide units of surface glycolipids have some role in myoblast fusion.     

Cell-type specific adhesive interactions of skeletal myoblasts with thrombospondin-1.

Thrombospondin-1 (TSP-1) is an extracellular matrix glycoprotein that may play important roles in the morphogenesis and repair of skeletal muscle. To begin to explore the role of thrombospondin-1 in this tissue, we have examined the interactions of three rodent skeletal muscle cell lines, C2C12, G8, and H9c2, with platelet TSP-1. The cells secrete thrombospondin and incorporate it into the cell layer in a distribution distinct from that of fibronectin. Myoblasts attach and spread on fibronectin- or thrombospondin-coated substrates with similar time and concentration dependencies. Whereas cells adherent on fibronectin organize actin stress fibers, cells adherent on TSP-1 display prominent membrane ruffles and lamellae that contain radial actin microspikes. Attachment to thrombospondin-1 or the 140-kDa tryptic fragment is mediated by interactions with the type 1 repeats and the carboxy-terminal globular domain. Attachment is not inhibited by heparin, GRGDSP peptide, or VTCG peptide but is inhibited by chondroitin sulphate A. Integrins of the beta 1 or alpha V subgroups do not appear to be involved in myoblast attachment to TSP-1; instead, this process depends in part on cell surface chondroitin sulphate proteoglycans. Whereas the central 70-kDa chymotryptic fragment of TSP-1 does not support myoblast attachment, the carboxy-terminal domain of TSP-1 expressed as a fusion protein in the bacterial expression vector, pGEX, supported myoblast attachment to 30% the level of intact TSP-1. Thrombospondin-4 (TSP-4) is also present in skeletal muscle and a fusion protein containing the carboxy-terminal domain of TSP-4 also supported myoblast adhesion, although this protein was less active on a molar basis than the TSP-1 fusion protein. Thus, the carboxyterminal domain of TSP-1 appears to contain a primary attachment site for myoblasts, and this activity is present in a second member of the thrombospondin family.     

Sphingosine Blocks Both Membrane Fusion and Calmodulin-Dependent Phosphorylation of the 100-kDa Protein of Chick Embryonic Myoblasts

Sphingosine, a potent inhibitor of protein kinase C, was found to block membrane fusion of chick embryonic myoblasts in culture. This effect was dose-dependent and could be reversed upon removal of the drug. Treatment with 12-O-tetradecanoylphorbol 13-acetate, which is a powerful activator of protein kinase C and capable of preventing myoblast fusion, further potentiated the inhibitory effect of sphingosine. Thus, the sphingosine-mediated inhibition of myoblast fusion appears to be independent of protein kinase C. Sphingosine also decreased the phosphorylation state of the 100-kDa protein when given to the cell extracts, and this inhibition was competitive with calmodulin. Thus, sphingosine seems to act as a calmodulin antagonist. These results suggest that the sphingosine-mediated inhibition of myoblast fusion may be associated with the inhibitory effect of the drug against the calmodulin-dependent phosphorylation of the 100-kDa protein.     

Antibodies to 100- and 60-kDa surface proteins inhibit substratum attachment and differentiation of rodent skeletal myoblasts

A rabbit polyclonal antiserum was raised against membrane vesicles shed from the surface of fusing L6 rat myoblasts. In immunoblots the antiserum recognized fibronectin, a protein of approximately 100,000 Da (100-kDa), and a protein of approximately 60,000 Da (60 kDa). If added prior to cellular alignment, immunoglobulins from this serum inhibited fusion of both rat (L6) and mouse (C2) myoblasts in a dose-dependent fashion. To determine which component of this serum was responsible for fusion inhibition, antibodies against fibronectin, the 100- and 60-kDa proteins were microaffinity purified and tested, individually, for their effects on myoblast fusion. Antibodies against fibronectin had no effect on fusion. Antibodies against the 100-kDa protein released most cells from the substratum. Antibodies against the 60-kDa protein completely inhibited fusion. Fusion inhibition was accompanied by a corresponding inhibition of expression of two differentiation markers, creatine phosphokinase and the acetylcholine receptor. The 60-kDa protein was found, by immunoblot analysis, in smooth muscle-like cells (BC3H1 cells) and in variant L6 cells that do not differentiate and do not fuse. However, in the differentiation incompetent cells, the 60-kDa antigen appeared to be present in reduced amount. Indirect immunofluorescence of unpermeabilized L6 cells revealed alterations in the distribution of all three antigens during development. Fibronectin first appeared in long fibrillar arrays above the surface of cells that were beginning to align and fuse; fibronectin was not present on myotubes. The 100-kDa protein was seen initially in prominent fibrillar projections at the tips of prefusion myoblasts. During fusion the antigen was observed at sites of cell-cell contact and on extracellular vesicles. The 100-kDa protein appeared to be less abundant on myotubes. The 60-kDa protein first appeared in regions of cell-cell contact on cells that were beginning to align and fuse. As. fusion progressed, the 60-kDa protein was also found in extracellular vesicles. The 60-kDa protein was not observed on myotubes. As a result of this study we have identified two previously undescribed cell surface proteins involved in rodent skeletal myogenesis. The first is an approximately 100-kDa protein involved in early interactions of skeletal myoblasts with their substratum. The second is an approximately 60-kDa protein involved in myoblast differentiation. Both proteins are shed from the myoblast surface during myotube formation.     

Cell surface and metabolic labelling of the proteins of normal and transformed chicken cells

We have studied the surface proteins of normal and transformed chick cells using four-labelling techniques with different specificities, (a) lactoperoxidase catalysed iodination (b) galactose oxidase/B³H₄ (c) pyridoxal phosphate/B³H₄ and (d) periodate/B³H₄. All methods labelled a large external transformation-sensitive (LETS) protein, in agreement with previous studies. In addition, using galactose oxidase and periodate labelling techniques, we present evidence which suggests that the transformed cell surface glycoproteins are more sialylated.The LETS protein was also labelled with [¹⁴C]glucosamine and after trypsinization a small band of identical molecular weight to LETS remained, possibly representing an internal pool of the protein. In contrast LETS protein labelled with [³H]fucose was completely removed by trypsin, suggesting that the internal pool of the protein is incompletely glycosylated. Evidence is also presented to show that although the level of the protein is drastically reduced at the transformed cell surface, it is still synthesised and shed into the medium.     

Effects of cytochalasin B and colchicine on attachment of a major surface protein of fibroblasts

We have investigated the effects of the drugs cytochalasin B and colchicine on the surface levels of the large, external, transformation-sensitive (LETS) glycoprotein. Colchicine neither removed LETS protein from the surface, nor inhibited its regeneration after removal by mild trypsinization. Cells treated with cytochalasin B, however, showed both a 2–3-fold increase in the turnover rate of their surface LETS protein and a marked inhibition in its regeneration. Inhibition of regeneration was not due to inhibition of synthesis or transport to the surface. In fact, in the presence of cytochalasin B, increased quantities of LETS protein were released into the medium. The results are consistent with the idea of an association of LETS protein with the actin-containing microfilaments. However, other possible explanations, such as effects on cellular morphology or on transport of sugar precursors cannot yet be excluded.     

The Wiskott-Aldrich syndrome protein (WASP) is essential for myoblast fusion in Drosophila

In higher organisms, mononucleated myoblasts fuse to form multinucleated myotubes. During this process, myoblasts undergo specific changes in cell morphology and cytoarchitecture. Previously, we have shown that the actin regulator Kette (Hem-2/Nap-1) is essential for myoblast fusion. In this study, we describe the role of the evolutionary conserved Wiskott-Aldrich syndrome protein that serves as a regulator for the Arp2/3 complex for myoblast fusion. By screening an EMS mutagenesis collection, we discovered a new wasp allele that does not complete fusion during myogenesis. Interestingly, this new wasp3D3-035 allele is characterized by a disruption of fusion after precursor formation. The molecular lesion in this wasp allele leads to a stop codon preventing translation of the CA domain. Usually, the WASP protein exerts its function through the Arp2/3-interacting CA domain. Accordingly, a waspDeltaCA that is expressed in a wild-type background acts as dominant-negative during the fusion process. Furthermore, we show that the myoblast fusion phenotype of kette mutant embryos can be suppressed by reducing the gene dose of wasp3D3-035. Thus, Kette antagonizes WASP function during myoblast fusion.