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

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

Lectin activity from embryonic chick brain,heart, and liver: Changes with development

Extracts of embryonic chick brain, heart, and liver agglutinate glutaraldehyde-fixed trypsinized or pronase-treated rabbit erythrocytes. Agglutination activity of extracts from each organ was inhibited by a number of saccharides. Lactose was the most potent saccharide inhibitor of those tested. The specific agglutination activity of the extracts from each of the organs studied changed with development of the embryo. In general, specific agglutination activity declined later in embryogenesis, and after hatching. However, the pattern of developmental change differed for each of the organs tested. Liver was unusual in that, after hatching, agglutination activity rose again; and the agglutinin found at this time was apparently different from that found in the embryo.     

Metalloendoprotease inhibitors which block the differentiation of L6 myoblasts inhibit insulin degradation by the endogenous insulin-degrading enzyme

The cultured myoblasts of the rat skeletal muscle cell line L6 proliferate till confluency and then fuse to form myotubes and express a number of muscle-specific proteins. We had shown that this differentiation process is blocked by specific metalloendoprotease inhibitors. We now demonstrate that metabolizing L6 myoblasts and their cell extracts degrade insulin to acid-soluble fragments by a non-lysosomal pathway. About 90% of the insulin-degrading activity residues in the cytoplasm and is due to a 110-kDa enzyme known as the insulin-degrading enzyme. The same metalloendoprotease inhibitors that block the differentiation of L6 myoblasts also inhibit insulin degradation by the metabolizing L6 cells, their cell extracts, and the insulin-degrading enzyme immunoprecipitated from the cytosolic extracts by a monoclonal antibody. These results suggest that the insulin-degrading enzyme is the metalloendoprotease whose activity is required for the initiation of the morphological and biochemical differentiation of L6 myoblasts.     

Developmentally regulated lectin from embryonic chick pectoral muscle. Purification by affinity chromatography.

A lectin, whose specific activity in soluble extracts of embryonic chick pectoral muscle increases strikingly between 8 and 16 days of development, has been purified by affinity chromatography on derivatized Sepharose 4B coupled to p-aminophenyl-beta-D-lactoside. After affinity chromatography the lectin is pure except for minor contamination with another protein possibly representing a second muscle lectin. The latter can be completely removed by preparative isoelectric focusing. The purified lectin has an apparent molecular weight of 30,000 and an apparent subunit molecular weight of 15,000. Its isoelectric point is 4.0. The most potent saccharide inhibitors tested were thiodigalactoside and lactose. An antibody has been raised to the pure lectin. Studies with this antibody indicate that the lectin is present both on the surface of and within myoblasts.     

Stretch-induced growth in chicken wing muscles: role of soluble growth-promoting factors

The involvement of soluble growth-promoting factors in stretch-induced hypertrophy of the Patagialis muscle (PAT) in the chicken wing was investigated. Soluble extracts were prepared from young chicken PAT muscles made hypertrophic by passive stretch and from unstretched contralateral controls. Extracts were tested for their ability to stimulate cell proliferation and creatine phosphokinase (CPK) activity in primary monolayer cultures of chick embryo muscle cells. Factors were present in muscle extracts which showed a dose-dependent stimulation of cell proliferation and CPK activity in vitro. Passive stretch for 5 days produced a rapid hypertrophy of the PAT which was accompanied by a dramatic increase in the activity of the growth factor(s). Release of stretch resulted in an arrest of growth and an immediate fall in growth factor activity. The difference in growth-stimulating activity between control and stretched PAT extracts could be demonstrated in chicken transferrin-sensitive chick myoblast cultures. Stretch thus induces an increase in a class-specific growth factor, possibly Transferrin, in the PAT. Stretched PAT extracts stimulated: (a) chick myoblast proliferation to a greater extent than an optimum concentration of chick embryo extract, and (b) CPK activity in vitro to a greater extent than excess Transferrin. Both control and stretched PAT extracts supported the growth of rat myoblasts. We conclude that PAT muscle extracts also contain unknown growth factor(s) which are different from Transferrin.     

Control of differentiation in heterokaryons and hybrids involving differentiation-defective myoblast variants

Clones of differentiation-defective myoblasts were isolated by selecting clones of L6 rat myoblasts that did not form myotubes under differentiation-stimulating conditions. Rat skeletal myosin light chain synthesis was induced in heterokaryons formed by fusing these defective myoblasts to differentiated chick skeletal myocytes. This indicates that the structural gene for this muscle protein was still responsive to chick inducing factors and that the defective myoblasts were not producing large quantities of molecules that dominantly suppressed the expression of differentiated functions. The regulation of the decision to differentiate was then examined in hybrids between differentiation- defective myoblasts and differentiation-competent myoblasts. Staining with antimyosin antibodies showed that the defective myoblasts and homotypic hybrids formed by fusing defective myoblasts to themselves could in fact differentiate, but did so more than a thousand times less frequently than the 64% differentiation achieved by competent L6 myoblasts or homotypic competent X competent L6 hybrids. Heterotypic hybrids between differentiation-defective myoblasts and competent L6 cells exhibited an intermediate behavior of approximately 1% differentiation. A theoretical model for the regulation of the commitment to terminal differentiation is proposed that could explain these results by invoking the need to achieve threshold levels of secondary inducing molecules in response to differentiation-stimulating conditions. This model helps explain many of the stochastic aspects of cell differentiation.     

A role for the Ca2(+)-dependent adhesion molecule, N-cadherin, in myoblast interaction during myogenesis

The formation of multinucleate skeletal muscle cells (myotubes) is a Ca2(+)-dependent process involving the interaction and fusion of mononucleate muscle cells (myoblasts). Specific cell-cell adhesion precedes lipid bilayer union during myoblast fusion and has been shown to involve both Ca2(+)-independent (CI)2 and Ca2(+)-dependent (CD) mechanisms. In this paper we present evidence that CD myoblast adhesion involves a molecule similar or identical to two known CD adhesion glycoproteins, N-cadherin and A-CAM. These molecules were previously identified by other laboratories in brain and cardiac muscle, respectively, and are postulated to be the same molecule. Antibodies to N-cadherin and A-CAM immunoblotted a similar band with a molecular weight of approximately 125,000 in extracts of brain, heart, and pectoral muscle isolated from chick embryos and in extracts of muscle cells grown in vitro at Ca2+ concentrations that either promoted or inhibited myotube formation. In assays designed to measure the interaction of fusion-competent myoblasts in suspension, both polyclonal and monoclonal anti-N-cadherin antibodies inhibited CD myoblast aggregation, suggesting that N-cadherin mediates the CD aspect of myoblast adhesion. Anti-N-cadherin also had a partial inhibitory effect on myotube formation likely due to the effect on myoblast-myoblast adhesion. The results indicate that N-cadherin/A-CAM plays a role in myoblast recognition and adhesion during skeletal myogenesis.     

Sensitivity of cultured and skinned chick myotube to calcium, strontium, and barium ions examined by recording isometric contractions.

Sensitivity of cultured chick myotubes to alkaline earth metal ions was investigated by recording contractile isometric tension through a semiconductor transducer. The myotubes were obtained by culturing myoblasts of chick embryo breast muscles, and skinned chemically before physiological experiments. Contractions developed in response to Ca2+ in a bathing medium higher than 3 x 10(-7) M and reached maximum at 1 x 10(-5) M. Sr2+ was less effective than Ca2+; the threshold concentration was 1 x 10(-5) M and the tension reached maximum at 1 x 10(-3) M. Ba2+ was the least effective among the three alkaline earth metal ions; only one fifth of the Ca(2+)-induced maximum tension was attained at 1 x 10(-3) M. The sensitivity was similar to that of the mature pectoral muscle fiber, a fast twitch muscle fiber, rather than that of the anterior latissimus dorsi, a slow tonic muscle fiber. The sensitivity was shown to be dependent on its troponin C by replacing it with troponin C from the mature pectoral or cardiac muscle. This indicates that TnC of a fast-muscle type is expressed in the cultured chick myotube as in the mature pectoral muscle. The contractile apparatus was thus shown to be well developed in the cultured myotube with characteristics similar to the mature fast twitch muscle fiber.     

Slow and fast myosin heavy chain content defines three types of myotubes in early muscle cell cultures

We prepared monoclonal antibodies specific for fast or slow classes of myosin heavy chain isoforms in the chicken and used them to probe myosin expression in cultures of myotubes derived from embryonic chicken myoblasts. Myosin heavy chain expression was assayed by gel electrophoresis and immunoblotting of extracted myosin and by immunostaining of cultures of myotubes. Myotubes that formed from embryonic day 5-6 pectoral myoblasts synthesized both a fast and a slow class of myosin heavy chain, which were electrophoretically and immunologically distinct, but only the fast class of myosin heavy chain was synthesized by myotubes that formed in cultures of embryonic day 8 or older myoblasts. Furthermore, three types of myotubes formed in cultures of embryonic day 5-6 myoblasts: one that contained only a fast myosin heavy chain, a second that contained only a slow myosin heavy chain, and a third that contained both a fast and a slow heavy chain. Myotubes that formed in cultures of embryonic day 8 or older myoblasts, however, were of a single type that synthesized only a fast class of myosin heavy chain. Regardless of whether myoblasts from embryonic day 6 pectoral muscle were cultured alone or mixed with an equal number of myoblasts from embryonic day 12 muscle, the number of myotubes that formed and contained a slow class of myosin was the same. These results demonstrate that the slow class of myosin heavy chain can be synthesized by myotubes formed in cell culture, and that three types of myotubes form in culture from pectoral muscle myoblasts that are isolated early in development, but only one type of myotube forms from older myoblasts; and they suggest that muscle fiber formation probably depends upon different populations of myoblasts that co-exist and remain distinct during myogenesis.     

Isolation and partial characterization of high-buoyant-density proteoglycans synthesized in ovo by embryonic chick skeletal muscle and heart

Proteoglycans, a major component of the extracellular matrix, are produced in many tissues. A report from this laboratory describes the proteoglycans synthesized in culture by chick embryonic skeletal muscle myotubes. To extend this study to in vivo conditions, chick embryos were radiolabeled in ovo and the newly synthesized high-buoyant-density proteoglycans from skeletal muscle analyzed. In both leg muscle and pectoral muscle, three major high-density proteoglycans are synthesized. One is small and is similar to the proteoglycans synthesized in culture by muscle fibroblasts. The other two proteoglycans are large. The larger of these shares structural features with the proteoglycan synthesized by skeletal muscle cells in culture. It has large chondroitin sulfate chains (estimated molecular weight of 70,000) with a high proportion of chondroitin 6-sulfate (approximately 90%). The smaller of the two large proteoglycans is distinct (chondroitin sulfate of estimated molecular weight 24,000 and approximately 60% 6-sulfated disaccharides) and is not detected in muscle cultures; evidence suggests it is not made by myoblasts. Whole hearts synthesize proteoglycans with some structural similarities, and also differences, to those made in skeletal muscle. These data indicate that the proteoglycans synthesized in muscle cultures are likewise made in developing muscle in ovo but that another distinct strictly in ovo proteoglycan is also produced.     

Thiol protease and cathepsin D activities in selected tissues and cultured cells from normal and dystrophic mice

Thiol protease and cathepsin D activities were studied in extracts from hindlimb muscle of 60-day-old normal and dystrophic mice, strain 129 ReJ, and from cultured normal and dystrophic cells. Total thiol protease activity in dystrophic muscle extracts was 3.5 times higher than in normal muscle extracts, while cathepsin D, activity was 2.2 times greater in dystrophic muscle compared with normal muscle. Activation (pH 4.5, 30 degrees C) of latent thiol protease activity in extracts of muscle occurred concomitant with the inactivation or dissociation of endogenous protease inhibitors. Thiol protease assays revealed a higher ratio of active to inactive protease activity in extracts from dystrophic muscle than from normal muscle. Cultured myoblasts (L69/1) were found to contain 30-fold more thiol protease(s) and 6-fold more cathepsin D activity than whole muscle. Cells established from dystrophic muscle and grown in culture for periods up to 6 months were more responsive to thiol protease activation conditions than similar cultures derived from normal muscle. From data on the rate and extent of thiol protease activation in extracts from dystrophic cells and hindlimb muscle compared with normal tissue, it appears that cells and tissues from dystrophic mice contain a lower level of protease inhibitors than cells and tissues from normal mice.     

Alanine or pyruvate is required for the development of myotubes from myoblasts and cortisol satisfies this requirement

Development of myotubes from chick embryo breast muscle myoblasts has been shown to occur in the combined presence of insulin, and both the low and high molecular weight components (LMW, HMW) of chick embryo extract. We report here that alanine, or pyruvate, will replace the LMW component with serine enhancing this effect. In addition, extracts of embryonic kidneys were the most active of five embryonic tissues tested in replacing the LMW component, which led to the finding that cortisol is active in promoting both the development of myotubes and the expression of creatine phosphokinase activity, a muscle-specific indicator of myogenesis. Since it was observed that myoblasts are highly glycolytic, it may be that pyruvate is limiting, suggesting that some aspect of oxidative metabolism is also limiting in these cells.     

The calcium-dependent myoblast adhesion that precedes cell fusion is mediated by glycoproteins

Presumptive myoblasts from explants of chick embryo pectoral muscle proliferate, differentiate, and fuse to form multinucleate myotubes. One event critical to multinucleate cell formation is the specific adhesion of myoblasts before union of their membranes. In the studies reported here five known inhibitors of myotube formation--trifluoperazine, sodium butyrate, chloroquine, 1,10 phenanthroline, and tunicamycin--were tested for their effect on the Ca++-dependent myoblast adhesion step. The first four inhibitors of myotube formation do not perturb myoblast adhesion but rather block fusion of aggregated cells, which suggests that these agents perturb molecular events required for the union of the lipid bilayers. By contrast, tunicamycin exerts its effect by inhibiting the myoblast adhesion step, thereby blocking myotube formation. The effect of tunicamycin can be blocked by a protease inhibitor, however, which implies that the carbohydrate residues protect the glycoproteins from proteolytic degradation rather than participate directly in cell-cell adhesion. Whereas trypsin treatment of myoblasts in the absence of Ca++ destroys the cells' ability to exhibit Ca++-dependent adhesion, the presence of Ca++ during trypsin treatment inhibits the enzyme's effect, which suggests that myoblast adhesion is mediated by a glycoprotein(s) that has a conformation affected by Ca++. Finally, myoblast adhesion is inhibited by an antiserum raised against fusion-competent myoblasts. The effect of the antiserum is blocked by a fraction from the detergent extract of pectoral muscle that binds to immobilized wheat germ agglutinin, which again suggests that glycoproteins mediate Ca++-dependent myoblast adhesion.     

Effect of inhibitors of glycoprotein processing on integrin and the adhesion of myoblasts to extracellular matrix proteins

The effect of the glucosidase inhibitors N-methyl-1-deoxynojirimycin (MDJN) and bromoconduritol on the adhesion of chick myoblasts and rat L6 myoblasts to fibronectin and laminin was compared with that of the mannosidase I inhibitor, 1-deoxymannojirimycin (ManDJN). Chick and rat L6 myoblasts treated with glucosidase inhibitors showed impaired binding to fibronectin. Glucosidase inhibitor-treated chick, but not rat L6, myoblasts also showed impaired binding to laminin. In contrast ManDJN had no significant effect on the adhesion of rat or chick cells to either substrate, suggesting that complex oligosaccharides are not required for normal biosynthesis of myoblast fibronectin or laminin receptors. Binding of monoclonal antibody JG22 to glucosidase-inhibitor-treated myoblasts revealed a marked decrease in the number of integrin molecules available at the cell surface. We suggest that the previously reported inhibitory effects of glucosidase inhibitors on the terminal differentiation of myoblasts may be mediated, at least in part, through their effect on integrin accumulation.     

Effects of ATP on the stability of enzymes against heat treatment in 6-aminonicotinamide treated quail

The stabilities of liver and pectoral muscle enzymes in 6-aminonicotinamide (6-AN) treated quail against heat treatment in the presence and absence of added ATP were investigated. Only ATP level in the brain and pectoral muscle of 6-AN treated group was significantly reduced compared to the control group whereas ADP and AMP levels were not affected. In the thermal stability (55 degrees C) of liver enzymes, the activity of acetylcholinesterase (AChE) was not affected whereas the activities of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and lactate dehydrogenase (LDH) were significantly lowered (P<0.01). The addition of 1mM ATP to liver enzyme extracts of 6-AN group afforded 4- and 1.7-fold more protection for GAPDH and LDH, respectively (P<0.01). In liver, LDH appeared to be more protected by ATP than GAPDH. In muscle, however, GAPDH and AChE activity were significantly affected but not LDH. The addition of 1mM ATP to muscle enzyme extracts of 6-AN group afforded 1.7-fold more protection for GAPDH (P<0.01) but rather inactivated AChE. A marked reduction in ATP levels in muscle did not affect specifically muscle enzyme activities only since liver enzyme activities were also affected to the same degree as muscle.     

Expression of fast and slow isoforms of the Ca2+-ATPase in developing chick skeletal muscle

The expression of fast and slow isoforms of the sarcoplasmic reticulum Ca2+-ATPase was studied in the developing chick embryo and in tissue-cultured myotubes. Monoclonal antibodies specific for each isoform were used as probes of protein expression. Analysis of expression of Ca2+-ATPase isoforms in chick thigh muscles by immunofluorescence microscopy revealed that all muscle fibers expressed both isoforms during their development. Primary generation muscle fibers expressed predominantly the slow isoform. Secondary generation fibers expressed both isoforms at comparable levels. Loss of the "inappropriate" isoforms occurred late in embryonic development. Immunoblot analysis of embryonic thigh muscle proteins indicated that the expression of the slow isoform varied little from embryonic Day 6 (ED6) to ED19, while expression of the fast isoform increased dramatically just prior to ED19. Tissue-cultured myotubes derived from ED12 chick thigh muscle myoblasts, plated at high density, expressed both isoforms of the Ca2+-ATPase at very similar levels. Clonal analysis of myoblasts taken from early (ED6) and late (ED12) chick thigh muscles showed that all muscle colonies expressed both forms, consistent with in vivo results. Fiber-type specific isoforms of the Ca2+-ATPase and myosin heavy chain are not coordinately expressed in developing chick skeletal muscle.     

Recovery of the acetylcholinesterase activity in a monolayer culture of chick myoblasts after irreversible inhibition by an organophosphorus inhibitor

The recovery of the acetylcholine esterase (AChE) activity after the irreversible inhibition with an organophosphorus inhibitor B-156 was studied in a developing monolayer culture of chick myoblasts. The culture was obtained from muscles of posterior limbs of the 11 day old chick embryos. The AChE activity was estimated by the modified Ellman method from the moment of inoculation to the stage of spontaneous contractions of muscle fibres. After the B-156 treatment the AChE activity of muscle cells decreased, then started to increase and the maximum recovery of activity, below the initial level, was attained within roughly 2 days after the treatment. The AChE activity in the treated culture somewhat decreased thereafter. The lower the inhibitor concentration, i.e. the lower the value of the initial AChE inhibition, the higher the starting rate and degree of recovery of the AChE activity. The results obtained suggest that, unlike the multilayer culture of muscle tissue at later stages of differentiation no compensatory enhancement of AChE biosynthesis after irreversible inhibition of this enzyme by an organophosphorus inhibitor is observed in the monolayer culture of chick myoblasts at the early stages of myogenesis.     

Distribution of an endogenous lectin in the developing chick optic tectum

We determined the cellular localization of an endogenous lectin at various times during the development of a well-characterized region of chick brain, the optic tectum. This lectin is a carbohydrate-binding protein that interacts with lactose and other saccharides, undergoes striking changes in specific activity with development, and has previously been purified by affinity chromatography from extracts of embryonic chick brain and muscle. Cellular localization in the tectum was done by indirect immunofluoresecent staining, using immunoglobulin G derived from an antiserum raised against pure lectin. No lectin was detectable in the optic tectum examined at 5 days of embryonic development. From approximately 7 days of development, neuronal cell bodies and fibers were labeled by the antibody; and extracts of tectum contained hemagglutination activity that could be inhibited by lactose or by the antiserum. Lectin remained present in many tectal neuronal layers after hatching; but in 2-month-old chicks it was sparse or absent in most of the tectum except for prominent labeling of fibers in the stratum album centrale. The initial appearance of lectin in the optic tectum was not dependent on innervation by optic nerve fibers since bilateral enucleation during embryogenesis did not affect it. Lectin was detectable on the surface of embryonic optic tectal neurons dissociated with a buffer containing EDTA.     

Comparative studies of the endogenous phospholipids and their in vitro hydrolysis by endogenous phospholipases of various tissues from 7-day-old chicks: a thin layer chromatographic and densitometric analysis

The phospholipid profiles of heart, kidney, and pectoral muscle of 7-day-old chicks and their in vitro response to the endogenous lipolytic enzymes (mainly in the phospholipase group) at pH 7.4 and 38 degrees C for 60 min were analysed by TLC technology and densitometry. The noticeable preferential deacylation of cardiolipin (CL) as detected by the formation of monolysocardiolipin (MLCL) and concurrent reduction of CL level were the most prevalent lipolytic events of chick cardiac muscle, but the least prevalent in chick pectoral muscle. Deacylation of ethanolamine plasmalogen (PE) as revealed by the formation of the corresponding lyso alkenyl derivative was also prominent in cardiac muscle, but much less so in kidney and none at all was detected in pectoral muscle. The level of sphingomyelin (SM) was much higher in kidney than heart and pectoral muscle. Following in vitro incubation, the reduction in the level of SM and the high level of ceramide (Cer) production were most conspicuous in kidney, less in cardiac muscle and least in pectoral muscle. The hydrolysis of PE and SM confirm the action of endogenous PLA(2) and endogenous sphingomyelinase on PE and SM respectively. These data clearly illustrate the differential response of the endogenous substrates (phospholipids) to the endogenous phospholipases of the tissues studied and are probably related to their physiological activities in vivo.