Role of muscle fibroblasts in the deposition of type-IV collagen in the basal lamina of myotubes

In cell cultures of quail, chick, or mouse skeletal muscle, both myogenic and fibrogenic cells synthesize and secrete type-IV collagen, a major structural component of the basal lamina. Type-IV collagen, together with laminin, forms characteristic patches and strands on the surface of developing myotubes, marking the onset of basement-membrane formation. The pattern for type-IV collagen and laminin is unique to these proteins and is not paralleled by other matrix proteins, such as fibronectin or type-I or -III collagen. In the present study, we used species-specific antibodies to either mouse or chick type-IV collagen to demonstrate the ability of fibroblast--derived type-IV collagen to incorporate in the basal lamina of myotubes. In combination cultures of embryonic quail skeletal myoblasts and mouse muscle fibroblasts, antibodies specific for mouse type-IV collagen revealed the deposition of type-IV collagen on the surface of quail myotubes in the pattern typical of the beginning of basement-membrane formation. Control cultures consisting of only quail muscle cells containing myoblasts and fibroblasts demonstrated no such reaction with these antibodies. Deposits of mouse type-IV collagen were also observed on the surface of quail myotubes when conditioned medium from mouse muscle fibroblasts was added to quail myoblast cultures. Similarly, in combination cultures of mouse myoblasts and chick muscle fibroblasts, chick type-IV-collagen deposits were identified on the surface of mouse myotubes. These results indicate that type-IV collagen synthesized by muscle fibroblasts may be incorporated into the basal lamina forming on the plasmalemma of myotubes, and may explain ultrastructural studies by Lipton on the contribution of fibroblasts to the formation of basement membranes in skeletal muscle.     

Synthesis of type IV collagen and laminin in cultures of skeletal muscle cells and their assembly on the surface of myotubes

The synthesis of two components of the basal lamina, laminin and type IV collagen, and their extracellular deposition on the surface of myotubes was studied in cultures of embryonic mouse and quail skeletal muscle cells and in the rat myoblast cell line L6. Production of type IV collagen and laminin by myoblasts and muscle fibroblasts was demonstrated by incorporation of radioactive amino acids into proteins and by immunoprecipitation with specific antibodies and electrophoretic analysis of labeled proteins. Immunofluorescence staining experiments revealed strong intracellular reactions with antibodies to laminin and type IV collagen in mononucleated myogenic and fibrogenic cells. Cells of fibroblast-like morphology showed a more intense staining than bipolar, spindle-shaped cells which perhaps represented postmitotic myoblasts. Myotubes did not show detectable intracellular staining. The formation of a basal lamina on myotubes was indicated by the deposition of laminin and type IV collagen on the surface of myotubes as viewed by immunofluorescence examination of unfixed cells. Staining for extracellular laminin was stronger in mass cultures than in myogenic clones, suggesting that secretion and deposition of components of the basal lamina on the myotube surface are complex processes which may involve cooperation between myogenic and fibrogenic cells.     

Role of laminin and fibronectin in selecting myogenic versus fibrogenic cells from skeletal muscle cells in vitro

Growth of embryonic skeletal muscle occurs by fusion of multinucleated myotubes with differentiated, fusion-capable myoblasts. Selective recognition seems to prevent fusion of myotubes with nonmyogenic cells such as muscle fibroblasts, endothelial cells, or nerve cells, but the nature of the signal is as yet unknown. Here we provide evidence that one of the selection mechanisms may be the enhanced affinity for laminin of myogenic cells as compared to fibrogenic cells. Growing myotubes in myoblast cultures accumulate laminin and type IV collagen on their surface in patches and strands as the first step in assembling a continuous basal lamina on mature myofibers (U. Kühl, R. Timpl, and K. von der Mark (1982), Dev. Biol. 93, 344-359). Fibronectin, on the other hand, assembles into an intercellular fibrous meshwork not associated with the free myotube surface. Over a brief time period (10-20 min) myoblasts from embryonic mouse thigh muscle adhere faster to laminin than do fibroblasts from the same tissue; these adhere faster to fibronectin. When a mixture of the cells is plated for 20 min on laminin/type IV collagen substrates, only myogenic cells adhere, giving rise to cultures with more than 90% fusion after 2 weeks; on fibronectin/type I collagen in the same time primarily fibroblastic cells adhere, giving rise to cultures with less than 10% nuclei in myotubes. The differential affinities of myoblasts for basement membrane constituents and of fibroblasts for interstitial connective tissue components may play a role in sorting out myoblasts from fibroblasts in skeletal muscle development.     

Analysis of fibronectin expression during human muscle differentiation

Fibronectin expression during human muscle differentiation was investigated by determining its distribution in foetal, normal adult and dystrophic muscle and in foetal, normal adult and dystrophic muscle cultures during myogenesis. Muscle sections and muscle cultures were studied by indirect immunofluorescence staining using polyclonal and monoclonal anti-human antibodies. Mass and clonal muscle cultures were prepared from foetal, adult and dystrophic muscle tissue. Immunofluorescence staining detected fibronectin on the epimysium, perimysium and endomysium of transverse sections of normal adult muscle, while sarcoplasm was devoid of this glycoprotein. In foetal muscle, some fibers showed a prominent ring of fibronectin. In mass and clonal cultures, myoblasts were found to synthesize and accumulate fibronectin while myotubes did not. No difference in fibronectin distribution was observed between Duchenne Muscular Dystrophy (DMD) and control myotubes. An enzyme-linked immunoassay (ELISA), performed on homogenated muscle, sonicated fibroblasts and muscle cells, showed a high fibronectin level in fibroblasts when compared with the other samples tested.     

Entactin promotes adhesion and long-term maintenance of cultured regenerated skeletal myotubes.

The basal lamina protein, laminin, has been shown to promote migration and proliferation of cultured skeletal myoblasts, resulting in increased myotube formation. However, skeletal myotubes adhere poorly to a laminin substrate, and long-term cultures of skeletal myotubes on laminin have not been achieved. We have found that cultured satellite cells from bupivacaine-damaged rat skeletal muscle actively proliferate and differentiate on a diluted Matrigel substrate composed of laminin, type IV collagen, heparan sulfate proteoglycan, and entactin. Myotubes cultured on diluted Matrigel are contractile and have never been observed to detach from the culture dish; rather, myotubes generally atrophy after 2-3 weeks in culture. Antibodies directed against the various protein components of Matrigel were used to determine the role of each component in enhancing muscle differentiation. Anti-laminin impaired satellite cell adhesion, whereas antibodies against either type IV collagen or heparan sulfate proteoglycan had no effect. Anti-entactin did not inhibit attachment, proliferation, or fusion of cultured satellite cells; however, myotubes exposed to anti-entactin failed to adhere to the culture dish after spontaneous myotube contractions began. We conclude that entactin is responsible for long-term maintenance and maturation of contractile skeletal myotubes on a diluted Matrigel substrate. This is the first study to assign a biological function for entactin in myogenesis.     

Basal lamina components are concentrated in premuscle masses and at early acetylcholine receptor clusters in chick embryo hindlimb muscles

As an initial step in characterizing the function of basal lamina components during muscle cell differentiation and innervation in vivo, we have determined immunohistochemically the pattern of expression of three components--laminin, proteins related to agrin (an acetylcholine receptor (AChR)-aggregating protein), and a heparan sulfate proteoglycan--during the development of chick embryo hindlimb muscles. Monoclonal antibodies against agrin were used to purify the protein from the Torpedo ray and to characterize agrin-like proteins from embryonic and adult chicken. In early hindlimb buds (stage 19), antibodies against laminin and agrin stained the ectodermal basement membrane and bound to limb mesenchyme with a generalized, punctate distribution. However, as dorsal and ventral premuscle masses condensed (stage 22-23), mesenchymal immunoreactivity for laminin and agrin-like proteins, but not the proteoglycan, became concentrated in these myogenic regions. Significantly, the preferential accumulation of these molecules in myogenic regions of the limb preceded by 1-2 days the appearance of muscle-specific proteins, myoblast fusion, and muscle innervation. All three basal lamina components were preferentially associated with all AChR clusters from the time we first observed them on newly formed myotubes at stage 26. Localization of these antigens in three-dimensional collagen gel cultures of limb mesenchyme, explanted prior to innervation of the limb, paralleled the staining patterns seen during limb development in the embryo. These results indicate that basal lamina molecules intrinsic to limb mesenchyme are early markers for myogenic and synaptic differentiation, and suggest that these components play important roles during the initial phases of myogenesis and synaptogenesis.     

Ultroser G and brain extract induce a continuous basement membrane with specific synaptic elements in aneurally cultured human skeletal muscle cells

Basement membrane (BM) components were studied on human muscle and skeletal muscle cells cultured on different media by immunofluorescence and electron microscopy. Their topographical relation with acetylcholine receptors was investigated. Myotubes cultured on a combination of the serum substitute Ultroser G and brain extract show a continuous layer of heparan sulfate proteoglycans (HSPGs), laminin, and type IV collagen. In contrast, myotubes cultured on serum-containing media are associated with granular depositions of HSPG and laminin and only with wisps of type IV collagen. Omission of brain extract or substitution by chicken embryo extract results in an intermediate staining pattern. For all types of cultures, fibronectin is localized in and around mononuclear cells, but hardly associated with myotubes. A codistribution between clusters of acetylcholine receptors and HSPG and laminin and Vicia villosa B4 lectin-positive material exists only in Ultroser G/brain extract-based myotubes like in muscle in vivo. No clustering is observed in serum-based myotubes. Electron microscopy reveals that the former myotubes are surrounded by a continuous BM consisting of a lamina lucida, lamina densa, and lamina fibroreticularis. Proteoglycans are present on the external site of the lamina densa and associated in a regular fashion with collagen fibrils. In conclusion, BMs associated with myotubes cultured on Ultroser G/brain extract resemble in many ways the in vivo situation, including synaptic specializations. Cultured myotubes may serve as a model system for studies on the structure and function of human muscular (synaptic) BM under normal and pathological conditions.     

In vitro attachment of skeletal muscle fibers to a collagen gel duplicates the structure of the myotendinous junction

The myotendinous junction (MTJ) and its associated cells and connective tissue are important structures involved in transmission of contractile force from skeletal muscle to tendon. A model culture system was developed to investigate the formation of the MTJ and its attachment to collagen fibers. Skeletal muscle cells were cultured in a well modeled from two layers of a native gel of type I collagen. Muscle cells cultured in this manner formed attachments to the collagen gel and developed into highly contractile multinucleated muscle fibers with the development of extensive terminal invaginations of the sarcolemma. In addition, the subsarcolemma at the ends of muscle fibers showed areas of increased electron density which corresponded well with the termini of myofibrils. The results indicate that the development of sarcolemmal invaginations at the end of a muscle fiber probably occurs intrinsically during muscle development in vivo. The direct association of collagen fibers with the basal lamina at the end of muscle fibers was only occasionally observed in culture, suggesting that other fibrils or proteins may also be involved in the attachment of collagen fibers to the basal lamina of muscle fibers at the MTJ.     

Creatine kinase, myokinase, and acetylcholinesterase activities in muscle-forming primary cultures of mouse teratocarcinoma cells.

Multipotential mouse teratocarcinoma cells in embryoid bodies were explanted on plastic or collagen substrates. Various modes of cell determination, including myogenesis, occurred. The predominant avenue of differentiation soon became myogenesis: many multinucleated myotubes formed and yielded an extensive network of skeletal muscle fibers. The process does not proceed to normal completion, as the fibers have a paucity of striations and are not contractile. Activities of several enzymes ordinarily associated with muscle differentiation were examined. Acetylcholinesterase activity increases, especially during myotube formation, as in normal myogenesis. However, creatine kinase activity rises during myotube formation and then drops abnormally, and myokinase activity fails to increase appreciably. The fetal isozymic form of creatine kinase is expressed in the cultures, although well differentiated solid tumors taken from mice show attainment of the adult muscle isozyme type if skeletal muscle is demonstrably present. The results are consistent with the interpretation that coordinately regulated changes in gene expressions controlling these functions may be required for later stages of myogenesis.     

Embedding in a collagen gel stabilizes the polarity of epithelial cells in thyroid follicles in suspension culture

Separated thyroid follicles are stable in suspension culture in Coon's modified Ham's F12 medium containing 0.5% calf serum. They resemble follicles in vivo except for the absence of a basal lamina. However, the epithelial cells reverse polarity and the follicles invert when the serum concentration is raised to 5%. A number of substances, especially components of extracellular matrix, were added to the medium to ascertain if they could stabilize the follicles against inversion in 5% serum. Cellular and plasma fibronectin, gelatin, heat-denatured collagen, methylcellulose and laminin did not stabilize. The addition to the medium of as little as 50 micrograms/ml of acid-soluble collagen prepared from calf skin or rat tail tendons resulted in the formation of small clouds of gel. Follicles embedded within the gel were stabilized. Follicles in the same dish but not embedded in the gel inverted. Stabilization was not specific for collagen, since follicles embedded in a plasma clot were also stabilized. A gel was not sufficient for stabilization, since embedding in an agarose gel did not stabilize. Ultrastructural studies indicate that adherence to a limited number of gelled fibers of collagen covering only a small fraction of the basal plasma membrane may be sufficient to stabilize and that a basal lamina formed in the presence of laminin but without added collagen does not stabilize.     

Type I collagen reduces the degradation of basal lamina proteoglycan by mammary epithelial cells

When mouse mammary epithelial cells are cultured on a plastic substratum, no basal lamina forms. When cultured on a type I collagen gel, the rate of glycosaminoglycan (GAG) synthesis is unchanged, but the rate of GAG degradation is markedly reduced and a GAG-rich, basal lamina-like structure accumulates. This effect of collagen was investigated by comparing the culture distribution, nature, and metabolic stability of the 35S-GAG-containing molecules produced by cells on plastic and collagen. During 48 h of labeling with 35SO4, cultures on collagen accumulate 1.4-fold more 35S-GAG per microgram of DNA. In these cultures, most of the extracellular 35S-GAG is immobilized with the lamina and collagen gel, whereas in cultures on plastic all extracellular 35S-GAG is soluble. On both substrata, the cells produce several heparan sulfate-rich 35S-proteoglycan fractions that are distinct by Sepharose CL-4B chromatography. The culture types contain similar amounts of each fraction, except that collagen cultures contain nearly four times more of a fraction that is found largely bound to the lamina and collagen gel. During a chase this proteoglycan fraction is stable in cultures on collagen, but is extensively degraded in cultures on plastic. Thus, collagen-induced formation of a basal lamina correlates with reduced degradation and enhanced accumulation of a specific heparan sulfate-rich proteoglycan fraction. Immobilization and stabilization of basal laminar proteoglycan(s) by interstitial collagen may be a physiological mechanism of basal lamina maintenance and assembly.     

The organogenesis of murine striated muscle: a cytoarchitectural study

The ultrastructure and the three-dimensional cytoarchitecture of the developing murine extensor digitorum longus muscle has been studied in spaced, serial, transverse and longitudinal ultrathin sections of the muscles of 12-, 14-, 16-, and 18-day in utero, newborn, and 5-day-old 129 ReJ mice. Despite the fact that in vivo myogenesis is asynchronous (i.e., during most of the fetal period, multiple stages of myogenesis can be seen in a single developing muscle mass), a distinct temporal pattern of development can be seen across the entire width and length of the developing muscle. At 12 days in utero, the developing extensor digitorum longus muscle consists of primary myotubes surrounded by a pleomorphic population of mononucleated cells devoid of myofilaments. At this stage, blood vessels and nerves are found peripheral to but not within the developing muscle mass. A delay of 2 days occurs between the time of formation of the primary and secondary myotubes. Clusters (consisting of one primary myotube and secondary myotubes), axon bundles, capillaries, and primitive motor endplates are found in the muscle by 16 days in utero. Evidence is presented consistent with the hypothesis that cluster formation and cluster dispersal occur simultaneously in the developing muscle, beginning as early as 16-days in utero. By 18 days in utero, many of the primary myotubes of the cluster and the independent myotubes (i.e., single myotubes enclosed in their own basal lamina) have begun to acquire the polygonal shape, fascicular arrangement, and ultrastructure characteristic of more mature myofibers. At birth, clusters are infrequently encountered, and intramuscular axons have begun to undergo myelination. At this time, the only undifferentiated, mononucleated cells present in the muscle are myosatellite cells. The first week postnatal was characterized by further maturation of the myofibers.     

The role of myonuclei in muscle regeneration: An in vitro study

It is well established that during muscle regeneration, the satellite cells which are in a state of mitotic arrest, can initiate cell division to produce myoblasts which subsequently fuse to form myotubes. However, whether myonuclei, contained within damaged myotubes, or “freed” as a result of the trauma, play any role in muscle regeneration remains unresolved. In myogenic cultures, it is possible to obtain renewed myogenesis when initial cultures are sub-cultured. The aim of this study, was to obtain evidence of the participation by myonuclei of primary cultures in myogenesis which occurs subsequently in secondary cultures. In culture, myonuclei can be labelled with H³-thymidine and their ultimate fate, either as “free” myonuclei or myonuclei associated with disrupted myotubes can be followed unequivocally. Three types of experiments are performed: (i) Primary myogenic cultures containing only myotubes are subcultured. (ii) Primary myogenic cultures containing myotubes with labelled myonuclei are disrupted and subcultured. (iii) Primary myogenic cultures containing myotubes with unlabelled myonuclei are mixed with labelled mononucleated myogenic cells and sub-cultured. In all instances no evidence of myogenesis from myonuclei is obtained. It is concluded that myonuclei, which were rendered postmitotic during myogenesis, remain so when muscle is disrupted and cannot re-enter the mitotic cycle.     

Basal lamina formation on thyroid epithelia in separated follicles in suspension culture

When thyroid follicles are isolated by collagenase treatment of minced thyroid lobes, the basal lamina around each follicle is removed. The basal lamina does not reform when follicles are cultured in suspension in Coon's modified Ham's F-12 medium containing, in addition, 0.5% calf serum, insulin, transferrin, and thyrotropin. We have added acid soluble collagen and/or laminin to see if they would result in the formation of a basal lamina. An extended basal lamina did not form when follicles were embedded in a gel formed from acid-soluble rat tendon collagen or from calf skin collagen when added at a concentration of 100 micrograms collagen/ml. However, laminin at a concentration of 5.1 micrograms/ml gave rise to short segments of a basal lamina within 30 min. At longer time intervals, the segments lengthened and covered the base of many cells, and were continuous across the gap between cells and across the mouth of a coated pit. Not all basal surfaces were covered, and no exposed apical surfaces with microvilli had a basal lamina. There was no obvious difference in the appearance of the basal lamina if collagen was added in addition to laminin, but collagen, in contact with the plasma membrane when added alone, was lifted off the membrane in the presence of the basal lamina. The basal lamina appeared denser if formed in the presence of 5% serum instead of 0.5%.     

Expression of Masticatory-specific Isoforms of Myosin Heavy-chain,Myosin-binding Protein-C and Tropomyosin in Muscle Fibers and Satellite Cell Cultures of Cat Masticatory Muscle

We test the hypothesis that cat jaw satellite cells belong to a distinct lineage preprogrammed to express masticatory-specific isoforms of myosin heavy-chain (m-MyHC), myosin-binding protein-C (m-MBP-C), and tropomyosin (m-Tm) during myogenesis in vitro. A monoclonal antibody (MAb) against m-MyHC and MAbs raised here against cat m-MBP-C and m-Tm were used to stain cryostat sections of cat masseter muscle and cultured myotubes derived from satellite cells of cat temporalis and limb muscles, using peroxidase immunohistochemistry. MAbs against m-MBP-C bound purified m-MBP-C in Western blots. MAbs against m-Tm failed to react with m-Tm in Western blots, but reacted with native m-Tm in gel electrophoresis–derived ELISA. In cat masseter sections, MAbs against m-MyHC, m-MBP-C, and m-Tm stained all masticatory fibers, but not the jaw-slow fibers. Cat jaw and limb muscle cultures mature significantly more slowly relative to rodent cultures. However, at 3 weeks, all three MAbs extensively stained temporalis myotubes, whereas they apparently stained isolated myotubes weakly in cat limb and rat jaw cultures. We conclude that satellite cells of masticatory fibers are preprogrammed to express these isoforms during myogenesis in vitro. These results consolidate the notion that masticatory and limb muscle allotypes are distinct. (J Histochem Cytochem 58:623–634, 2010)     

Satellite cells from dystrophic (mdx) mouse muscle are stimulated by fibroblast growth factor in vitro

Satellite cells cultured from dystrophic (mdx) and from control mouse hindlimb muscles grow and fuse to form muscle fibers within 4-5 days. Total cell number and muscle-fiber formation are stimulated by bovine fibroblast growth factor (FGF). At low FGF levels (0.02-0.20 ng/ml) control satellite cells as well as fibroblasts are unresponsive, while mdx satellite cells show three- to four-fold increases in growth. Control cells do not begin to respond until FGF levels reach 1-5 ng/ml. Heparin, a major constituent of muscle fiber basal lamina, inhibits myogenesis in these mouse muscle cultures. The heightened sensitivity of mdx satellite cells to FGF may permit high rates of new fiber formation in vivo without a parallel hyperplasia in the muscle fibroblast population. This finding may be important in explaining successful regeneration in mdx muscle in vivo and the fact that mdx animals escape the catastrophic symptoms seen in the related human Duchenne muscular dystrophy.     

Immunohistochemical analysis of the distribution of type VI collagen in the lingual mucosa of rats during the morphogenesis of filiform papillae

Iwasaki, S., Yoshizawa, H. and Aoyagi, H. 2012. Immunohistochemical analysis of the distribution of type VI collagen in the lingual mucosa of rats during the morphogenesis of filiform papillae. —Acta Zoologica (Stockholm) 93 : 80–87. We examined the distribution after immunostaining of immunofluorescence of type VI collagen, differential interference contrast (DIC) images, and images obtained using confocal laser‐scanning microscopy in transmission mode, after toluidine blue staining, during morphogenesis of the filiform papillae, keratinization of the lingual epithelium and myogenesis in the rat tongue on semi‐ultrathin sections of epoxy resin‐embedded samples. Immunoreactivity specific for type VI collagen was dispersed over a relatively wide range of connective tissue in the mesenchyme of fetuses on day 15 after conception (E15), at which time the lingual epithelium was composed of one or two layers of cuboidal cells and the lingual muscle was barely recognizable. Slight immunoreactivity specific for type VI collagen was scattered within the lamina propria in fetuses on E17 and on E19, and immunoreactivity was relatively distinct on the connective tissue around the lingual muscle during myogenesis. In fetuses on E19, the epithelium was already stratified squamous. At postnatal stages from P0 to P14, keratinization of the lingual epithelium advanced gradually as morphogenesis of the filiform papillae proceeded during postnatal development. In newborns on P0, myogenesis of the tongue was almost completed. The intensity of immunoreactivity specific for type VI collagen at postnatal stages was mainly restricted on the endomysium and perimysium around the lingual muscle, while scant immunoreactivity was evident in the connective tissue in the lamina propria. Immunoreactivity around the fully mature lingual muscle on P7 and P14 was weaker than that on E19 and P0. Thus, type VI collagen appeared in the connective tissue that surrounded the lingual muscles such as the endomysium and perimysium, in parallel with changes in extracellular components during myogenesis of the tongue.     

Basal lamina formation by cultured microvascular endothelial cells

The production of a basal lamina by microvascular endothelial cells (MEC) cultured on various substrata was examined. MEC were isolated from human dermis and plated on plastic dishes coated with fibronectin, or cell-free extracellular matrices elaborated by fibroblasts, smooth muscle cells, corneal endothelial cells, or PF HR9 endodermal cells. Examination of cultures by electron microscopy at selected intervals after plating revealed that on most substrates the MEC produced an extracellular matrix at the basal surface that was discontinuous, multilayered, and polymorphous. Immunocytochemical studies demonstrated that the MEC synthesize and deposit both type IV collagen and laminin into the subendothelial matrix. When cultured on matrices produced by the PF HR9 endodermal cells MEC deposit a subendothelial matrix that was present as a uniform sheet which usually exhibited lamina rara- and lamina densa-like regions. The results indicate that under the appropriate conditions, human MEC elaborate a basal lamina-like matrix that is ultrastructurally similar to basal lamina formed in vivo, which suggests that this experimental system may be a useful model for studies of basal lamina formation and metabolism.     

Differentiation of creatine phosphokinase during myogenesis: quantitative fractionation of isozymes

A technique is described for the quantitative measurement of creatine phosphokinase (CPK) isozymes in extracts of chick muscle. The isozymes are fractionated by stepwise elution with increasing salt concentrations from DEAE-Sephadex minicolumns. Isozyme separation was confirmed by polyacrylamide gel electrophoresis followed by enzyme staining. We used this method to determine changes in CPK isozymes during the course of myogenesis in culture. The total specific activity of CPK increases about 20-fold during myogenesis. Quantative analysis of isozyme changes shows that the muscle-specific form (MM) accounts for virtually all of this increase. Activity of MM-CPK is undetectable in 1-day cultures, increases rapidly after myoblast fusion, and comprises more than 70% of total CPK in mature cultures. In contrast, the specific activity of the brain-specific isozyme (BB) remains constant throughout myogenesis. This was interpreted as indicating that the B subunit is expressed in both mononucleated cells and myotubes. We confirmed this by analyzing CPK isozymes in fibroblast cultures and in myotube-enriched cultures. Elimination of most of the mononucleated cells in the cultures produced an increase in the specific activity of CPK, but had no effect on the isozyme pattern and did not decrease the relative amount of the BB isozyme. Pure fibroblast cultures contained very low CPK activity, predominantly the BB isozyme.