Creatine kinase and aldolase isoenzyme transitions in cultures of chick skeletal muscle cells

Transition between isozymic forms of enolase during in vitro differentiation of neuroblastoma cells-II

An analysis of enolase expression during differentiation of neuroblastoma clones in homogeneous culture is presented. The enolases expressed in these neuroblast-like cells are identical to those of mouse brain with respect to the examined properties. Our biochemical investigation has premitted us to demonstrate formally that neuroblastoma cells undergo a transition from the embryonic ?? form to the neuronal ?? form and contain both enolases as well as the ?? hybrid form during maturation. These results suggest that the same phenomenon must exist in vivo for neuroblasts. In neuroblastoma cells, an increase in both ?? and ?? neuron specific enolases is related to cell maturation and expression of the ?? form precedes that of the ?? form during differentiation. Modulation of neuronal enolase activities is similar in the various conditions of differentiation studied and appears not to be necessarily related with morphological differentiation, although concomitant with an arrest of cell division. The evolution of specific neuronal enolases in neuroblastoma cells parallels that observed in vivo, in brain from embryonic day 15 to post-natal day 7. Moreover, at least one treatment (dimethylsulfoxide) causes an important decrease in the high specific ?? activity of these cells as occurs in vivo. This enolase can therefore also be considered as a biochemical marker for neuroblastoma maturation. As observed with other markers and other cell types, neuroblastoma cells in culture express an immature biochemical differentiation of the enolase isozymes.

The role of sperm creatine kinase in the assessment of male fertility

The lack of reliable methods to assess sperm fertilizing potential has been a long-standing problem for infertile couples and for their physicians. The most widely used tests, the measurements of sperm concentrations, motility, velocity and morphology in the ejaculate, are of limited utility. Indeed, following intrauterine insemination, a treatment that compensates for low motile sperm concentrations, there were no significant differences found in semen parameters among those who did or did not achieve pregnancies. Other available assays probing for selected sperm functions, such as membrane integrity, acrosome enzyme activity, bovine cervical mucus penetration test, zona-free hamster oocyte penetration test and sperm binding to various carbohydrates,10–13 have all failed thus far to consistently predict male fertility. It became increasingly obvious that there was a need to identify cellular markers of sperm quality and fertilizing potential.

Transferrin as a muscle trophic factor

Muscle cells grow by proliferation and protein accumulation. During the initial stages of development the participation of nerves is not always required. Myoblasts and satellite cells proliferate, fusing to form myotubes which further differentiate to muscle fibers. Myotubes and muscle fibers grow by protein accumulation and fusion with other myogenic cells. Muscle fibers finally reach a quasi-steady state which is then maintained for a long period. The mechanism of maintenance is not well understood. However, it is clear that protein metabolism plays a paramount role. The role played by satellite cells in the maintenance of muscle fibers is not known. Growth and maintenance of muscle cells are under the influence of various tissues and substances. Among them are Tf and the motor nerve, the former being the main object of this review and essential for both DNA and protein synthesis. Two sources of Tf have been proposed, i.e., the motor nerve and the tissue fluid. The first proposal is that the nervous trophic influence on muscle cells is mediated by Tf which is released from the nerve terminals. In this model, the sole source of Tf which is donated to muscle cells should be the nerve, and Tf should not be provided for muscle fiber at sites other than the synaptic region; otherwise, denervation atrophy would not occur, since Tf provided from TfR located at another site would cancel the effect of denervation. The second proposal is that Tf is provided from tissue fluid. This implies that an adequate amount of Tf is transferred from serum to tissue fluid; in this case TfR may be distributed over the entire surface of the cells. The trophic effects of the motor neuron have been studied in vivo, but its effects of myoblast proliferation have not been determined. There are few experiments on its effects on myotubes. Most work has been made on muscle fibers, where innervation is absolutely required for their maintenance. Without it, muscle fibers atrophy, although they do not degenerate. In contrast, almost all the work on Tf has been performed in vitro. Its effects on myoblast proliferation and myotube growth and maintenance have been established; myotubes degenerate following Tf removal. But its effects on mature muscle fibers in vivo are not well understood. Muscle fibers possess TfR all over on their cell surface and contain a variety of Fe-binding proteins, such as myoglobin. It is entirely plausible that muscle fibers require an amount of Tf, and that this is provided by TfR scattered on the cell surface.(ABSTRACT TRUNCATED AT 400 WORDS)

M-band: a safeguard for sarcomere stability?

The sarcomere of striated muscle is a very efficient machine transforming chemical energy into movement. However, a wrong distribution of the generated forces may lead to self-destruction of the engine itself. A well-known example for this is eccentric contraction (elongation of the sarcomere in the activated state), which damages sarcomeric structure and leads to a reduced muscle performance. The goal of this review is to discuss the involvement of different cytoskeletal systems, in particular the M-band filaments, in the mechanisms that provide stability during sarcomeric contraction. The M-band is the transverse structure in the center of the sarcomeric A-band, which is responsible both for the regular packing of thick filaments and for the uniform distribution of the tension over the myosin filament lattice in the activated sarcomere. Although some proteins from the Ig-superfamily, like myomesin and M-protein, are the major candidates for the role of M-band bridges, the exact molecular organisation of the M-band is not clear. However, the protein composition of the M-band seems to modulate the mechanical characteristics of the thick filament lattice, in particular its stiffness, adjusting it to the specific demands in different muscle types. The special M-band design in slow fibers might be part of structural adaptations, favouring sarcomere stability for a continuous contractile activity over a broad working range. In conclusion, we discuss why the interference with M-band structure might have fatal consequences for the integrity of the working sarcomere.

Sexual dimorphism in rat cerebrum and cerebellum: different patterns of catalytically active creatine kinase isoenzymes during postnatal development and aging

During postnatal development, maturation and aging the Wistar rat cerebrum and cerebellum synthesize, in a different sex-dependent manner, catalytically active dimeric cytosolic (c) muscle-type (MM) and heart-type (MB) creatine kinase (CK), besides the supposedly sole type brain-specific (BB) CK. In both sexes, typical and atypical neuromuscular cCK isoenzymes were present during the study for 26 months. As in rat heart, females showed more cerebral cCK variants (41%) in comparison to males. Female rats exhibited about 93% more cerebellar variants of cCK isoenzymes as compared to males. The male cerebellum showed predominantly BB- and MB-CK during the whole study in comparison to the female one that contained all neuromuscular cCK variants. Only female rats showed decreases and increases of cerebral CK specific activity. In contrast to males, coinciding with the weaning period, cerebral female CK activity decreased 45% from 14 to 21 days and increased about 3-fold in female rats and only 1.3-fold in males from 21 to 45 days of age. Contrary to the remarkable 4-fold increase of chicken brain CK specific activity exhibited at old age, the rat did not show another cerebral CK activity increase during senescence in either sex. However, sex differences of CK specific activity appeared in the cerebellum at all ages. From the sex-specific plateau phase at 45-60 days until 2.2 years of age, about a 41% independent increase of cerebellar CK specific activity was observed in both sexes. After puberty, the differential cerebellum-cerebrum values of CK specific activity were higher for female rats than males during youth, adulthood and senescence. The present work shows that in rat cerebrum and cerebellum, production of ATP through anaerobic transphosphorylation by the CK/PC system is sex-and age-specific, especially in the cerebellum, when glycolysis and the Krebs cycle lose capacity. As in rat heart, under physiological conditions at all ages the several cCK isoenzymes do participate in a gender-specific manner, in favor of females, in diverse functions of the different cell compartments of glial and neuronal cells with regard to their high and fluctuating energy demands not completely covered by anaerobic and aerobic glycolysis.

Opposite transitions of chick brain catalytically active cytosolic creatine kinase isoenzymes during development

Postnatally the rat brain synthesizes catalytic forms of muscle type (MM) and heart type (MB) creatine kinase (CK), besides the supposedly sole type vertebrate brain-specific (BB) CK. We intended to demonstrate that in Rhode Island chicken brain, cytosolic (c) CK isoenzymatic transitions. (for example BB-CK is followed by the appearance of MB-CK and MM-CK during muscle differentiation), can also occur during development and aging. Cytosolic post 125000 x g, mitochondrial CK-free, brain samples were obtained for zone electrophoresis separation and identification of catalytically active cCK isoforms. BB-CK was never found during chicken brain ontogeny. Against the accepted view, an opposite isoenzyme transition pattern from MM through BB-CK was found in the chicken embryonic brain from the very early stages of development up to day 2 post-hatching. At very early stages of chicken brain ontogeny constitutive MM- and MB-CK isoenzymes were present before the advent of creatine. It seems to be that typical and atypical brain MM- and MB-CK could be working as ATPases in the absence of creatine before embryonic stage 28 (day 5.5) and/or such CK isoforms may begin to form part of the slow component b in developing early neurons and later in the nuclei of glial cells to be used by the CK/phosphocreatine (PC) system as the neural tissues mature. The post-hatching transition pattern showed simultaneous expression of more than one CK isoenzyme within the same neural sample as in post-natal rat brain, presumably due to regional differential transphosphorylation requirements. Strain-dependent enzymatic specific activities have been reported in several species. Since equivalent values of brain CK specific activity were obtained previously from the embryonic plateau phase of CK activity during White Leghorn development, and those from Rhode Island brain neurons cultured 11 days, we compared if, in vivo, a similar brain CK specific activity pattern was physiologically equivalent during Rhode Island and White Leghorn chicken ontogeny. We found quantitatively different strain-specific CK specific activity patterns during this period. Rhode Island brain CK activity values were approximately 4.5-fold those of White Leghorn ones. This indicates that production of energy from anaerobic metabolism and transphosphorylation by the CK/PC system to synthesize ATP more efficiently is strain-specific. In Rhode Islands, there was an age-dependent increase of CK specific activity, mostly in older animals (440% above the value found during the embryonic plateau), when the Krebs cycle and glycolysis lose capacity. During adult life and aging, under physiological conditions, the three CK isoenzymes may participate in diverse functions of the different cell compartments of brain glia and neurons with regard to their high and fluctuating energy demands that are not completely covered by anaerobic and aerobic glycolisis.

Conditions for the culture of bovine embryonic myogenic cells

The objective of this experiment was to determine the growth characteristics of bovine embryonic muscle cells and to optimize the growth conditions for these cells using commercially-prepared media and sera. In the first study, the growth of muscle cells isolated from the hindlimb was determined by measuring DNA content. The DNA concentration was lowest (P < 0.001) at 24 h post-plating and increased to a maximum at approximately 60 h. The slopes of creatine kinase activity and fusion index curves were similar to the DNA; however, the creatine kinase activity achieved a maximum at 140 h post-plating, while the fusion index reached maximum at 120 h. In the second study, cells were cultured on different substrata, either plastic, gelatin, or collagen. There were no differences (P > 0.05) in the cell growth rates for any of the three substrata. In the third study, cells were grown in 10% fetal bovine serum (FBS) and either a balanced salt solution (BSS; 30 mM Hepes, 10 mM glucose, 120 mM NaCl, 2.5 mM Na2HPO4, and 3 mM KCl), McCoy's 5A, Dulbecco's Minimal Essential Medium/Ham's F12 (DMEM/F12), or 70% DMEM/20% M-199. Cell numbers adhering to the plate at 26 h post-plating were different (P > 0.001) between each medium (DMEM/M-199 > McCoy's 5A > DMEM/F12 > BSS). Cell proliferation rates for each treatment medium were greatest for DMEM/M-199, followed by McCoy's 5A, DMEM/F12, and BSS. Cell differentiation was highest (P < 0.05) in the DMEM/F12, followed by McCoy's 5A, DMEM/M-199, and BSS. In the final study, the cells were treated with different sources of serum added at 10% to DMEM/M-199. The sera consisted of FBS, newborn calf serum (NCS), horse serum (HS) and iron-supplemented calf serum (Fe(2+)-CS). The cells were added to each well at 10(4) cells. At 24 h post-plating, the serum-free, NCS, and FBS-treated cell numbers were greater (P < 0.05) than the cells treated with HS or Fe(2+)-CS, which may reflect the efficient adherence to the surface or faster adaptation to the serum by the cells. The proliferation rate was greatest (P < 0.001) for the cells treated with Fe(2+)-CS, followed by FBS = NCS, HS, and no serum. Therefore, the muscle cells obtained from bovine embryos grow and differentiate similar to muscle cells from other species. The optimal growth medium for growing these cells in vitro is DMEM/M-199 plus 10% Fe(2+)-CS, while the optimal differentiation medium is McCoy's 5A.

Overexpression of myotonic dystrophy kinase in BC3H1 cells induces the skeletal muscle phenotype

Myotonic muscular dystrophy is an autosomal dominant defect that produces muscle wasting, myotonia, and cardiac conduction abnormalities. The myotonic dystrophy locus codes for a putative serine-threonine protein kinase of unknown function. We report that overexpression of human myotonic dystrophy protein kinase induces the expression of skeletal muscle-specific genes in undifferentiated BC3H1 muscle cells. BC3H1 clones expressing myotonic dystrophy kinase appear equivalent to differentiated cells with respect to expression of myogenin, retinoblastoma tumor supressor gene, M creatine kinase, beta-tropomyosin, and vimentin. In addition, differential display analysis demonstrates that the pattern of gene expression exhibited by myotonic dystrophy kinase-expressing cells is essentially identical to that of differentiated BC3H1 muscle cells. These observations suggest that myotonic dystrophy kinase may function in the myogenic pathway.

Noncoordinate changes in the steady-state mRNA expressed from aldolase A and aldolase C genes during differentiation of chicken myoblasts

In chickens, as in all vertebrates, tissue-specific expression of aldolase isozymes A, B, and C is developmentally coordinated. These developmental transitions in aldolase expression have been studied most extensively by charting enzyme activity during normal and abnormal development of specific vertebrate tissues. Indeed, aldolase expression has been a key marker for normal differentiation and for retrodifferentiation during carcinogenesis. Aldolase expression during chicken myoblast differentiation offers a model for investigating the regulatory mechanisms of these developmental transitions at the level of gene expression. For these studies, cDNAs encoding the most isozyme-specific regions of both chicken aldolase A and C were cloned. The chicken aldolase A cDNA represents the first report of this sequence. Aldolase steady-state mRNA expression was measured during chicken myoblast differentiation in primary cultures using RNase protection assays with cRNA probes generated from these aldolase cDNA clones. Steady-state mRNA for aldolase C, the predominant embryonic aldolase isozyme in chickens, did not significantly change throughout myoblast differentiation. In contrast, expression of steady-state mRNA for aldolase A, the only aldolase isozyme found in adult-skeletal muscle, was not detected until after myoblast fusion was approximately 50% completed. Aldolase A expression gradually increased throughout myoblast differentiation until approximately 48 h after fusion was completed when there was a dramatic increase. These results are contrasted with those of Turner et al. (1974) [Dev Biol 37:63-89] that showed a coordinated switch in isozyme activities between the embryonic aldolase C and the muscle-specific aldolase A. This discordant expression indicates that the aldolase A and C genes may employ different regulatory mechanisms during myoblast differentiation.

Glycosphingolipids during skeletal muscle cell differentiation: comparison of normal and fusion-defective myoblasts

The regulation of glycosphingolipid (GSL) synthesis in culture by fusion-competent (E63) myoblasts and fusion-defective (fu-1) cells was examined. Upon reaching confluency E63 cells fused to form multinucleated myotubes and demonstrated many characteristics of developing skeletal muscle including induction of creatine kinase activity and a shift in creatine kinase isozymes to the MM isoform. The fu-1 cells displayed none of these characteristics, despite the fact that both cells were cloned from the same parental myoblast line (rat L8). There was a transient increase in the synthesis of total neutral GSLs by E63 cells at the time of membrane fusion. In contrast, neutral GSL synthesis by fu-1 cells gradually decreased with time in culture. The major GSLs synthesized by both cell types were lactosylceramide and ganglioside GM3, with more complex structures being observed with prolonged time in culture. Several glycosyltransferase activities were assayed at varying times in culture. Generally, the changes in activities fell into three groups. One group was maximally activated at the end of the culture period (GalT-3, GalNAcT-1 and GalT-6). Another group was maximally activated during the time of active membrane fusion (GlcT and SAT-1). A third group was maximally activated at the time of cell contact and the beginning of membrane fusion (GlcNAcT-1 and GalT-2). In terms of the times of maximal activation there were few differences between E63 and fu-1 cells, with one notable exception. The activity of GalT-2 (lactosylceramide synthase) in E63 cells increased dramatically upon contact and the beginning of membrane fusion, whereas there were no changes in GalT-2 activity in fu-1 cells during time in culture. These results support our hypothesis that membrane glycosphingolipids play an important role in the differentiation of skeletal muscle cells.

Incomplete development of human spermatozoa is associated with increased creatine phosphokinase concentration and abnormal head morphology

Our previous creatine phosphokinase (CK) activity studies in human sperm revealed differences among men and among sperm populations within the same specimen. Samples with low sperm concentrations, high incidence of abnormal sperm morphology, and diminished fertility had higher per sperm CK activity. In the present work, we demonstrated, with 14C-FDNB covalent CK active site modification and with direct CK immunocytochemistry, that the higher CK activity is related to an increased content of CK and of other proteins in sperm. Also, sperm heads with higher CK content were significantly larger and rounder and showed a higher incidence of amorph configuration. We suggest that these biochemical and morphological irregularities are related and are due to a failure of spermatogenesis, more specifically, to a higher retention of cytoplasm, which in normal sperm development is lost to the Sertoli cells as residual bodies. Thus higher CK activity and larger or irregular head size in human sperm signify cellular immaturity and a failure to complete spermatogenesis.

Inhibition by transforming growth factor beta of choline acetyltransferase stimulation in a co-culture of spinal cord and muscle cells from mice

Choline acetyltransferase (CAT) activity increased 11-fold in co-cultures of spinal cord and muscle cells from fetal mice relative to cultures of spinal cord cells alone. The addition of transforming growth factor-beta (TGF-beta) to the medium at 30 pM throughout the culture period inhibited the increase of CAT activity in the co-cultures, but did not affect the activity in cultures of spinal cord cells alone. TGF-beta did not inhibit glutamic acid decarboxylase activity in the co-cultures. Other growth factors such as epidermal growth factor, fibroblast growth factor and beta-NGF had little or no effect on CAT activity. TGF-beta markedly inhibited the fusion of myoblasts to myotubes and the expression of marker enzymes for muscle differentiation. When TGF-beta was included during muscle culture and removed before inoculation with spinal cord cells, myoblasts did not subsequently form myotubes. CAT activity in the spinal cord cells, however, markedly increased in co-cultures with the undifferentiated myoblasts. When TGF-beta was added to the co-cultures after myotube formation was complete, the increase in CAT activity was inhibited according to the length of TGF-beta treatment. These results suggest that TGF-beta inhibits the muscle-induced stimulation of CAT activity by inhibiting the production, secretion and/or action of trophic factors from muscle.

Regulation of glycolipid synthesis during differentiation of clonal murine muscle cells

The two clonal murine muscle cell lines G7 and G8, originally derived from the M114 line, represent unique models for comparative studies of myogenesis. Glycolipid synthesis was examined during differentiation using [3H]-galactose and [3H]-glucosamine as precursors. Upon G7 contact glucosylceramide labeling increased and nLcOse5Cer labeling stopped. During membrane fusion, glucosylceramide labeling stopped and lactosylceramide became the major synthetic product. G8 cells presented a different pattern, with increased labeling of GbOse3Cer during myogenesis. The major ganglioside synthesized by both myoblasts was GM3, and more complex structures were observed following completion of myotube formation. Total glycopeptide labeling increased when G8 myoblasts fused and remained elevated in myotubes, whereas no differences during fusion of G7 cells were noted. Upon comparison of the two clonal lines, the only consistent observation was a significant increase in the synthesis of total gangliosides and neutral glycolipid during cell contact and membrane fusion (p less than 0.02). The results suggest that changes in the synthesis of specific glycolipid structures during myogenesis are unique to each muscle cell line examined. However, transient increases in synthesis of total myoblast gangliosides and neutral glycolipids may be a more general phenomenon, possibly by curbing proliferation or by altering myoblast membrane fluidity characteristics during differentiation.

Changes in phosphofructokinase isozymes during development of myoblasts to myotubes

The regulation of phosphofructokinase during development of C2C12 myoblasts to myotubes was investigated. Enzyme activity was markedly increased during myogenic development. The increase was observed when enzyme activity was measured under optimal conditions and was not due to changes in the allosteric kinetic properties of the enzyme. Immunoprecipitation of phosphofructokinase from [35S]methionine-labeled myogenic cells revealed that equal amounts of liver and muscle isozymes are present in myoblasts, while in myotubes there was a much higher level of the muscle isozyme. These results were confirmed using an immunoblotting technique. The increase in the level of muscle isozyme in myotubes is due to an increase in the rate of synthesis of the muscle isozyme and occurs in spite of a measurably small increase in its degradation rate. Northern blot analysis using a synthetic oligonucleotide probe showed a 25-fold increase in the level of muscle phosphofructokinase mRNA in myotubes. The conclusion is drawn that the increase in muscle isozyme in myotubes during myogenesis is due to an increase in its mRNA level.

Spermatogenesis-related change in the synthesis of the creatine kinase B-type and M-type isoforms in human spermatozoa

We have demonstrated earlier that the per sperm creatine-N-phosphotransferase (CK) activity was increased in oligospermic vs. normospermic men. The increased sperm CK activity is related to higher concentrations of cellular CK, which may indicate a defect of cytoplasmic extrusion during spermatogenesis. In the present work, we examined whether in spermatozoa, similar to muscle, there is a change in the synthesis of B-CK and M-CK isoforms during cellular differentiation. In 109 normospermic and 50 oligospermic specimens (sperm concentrations 60.6 +/- 3.7 vs. 8.8 +/- 1.3 million sperm/ml; all values expressed as mean +/- SEM), the relative concentrations of the M-CK isoform (M-CK/M-CK + B-CK) were 27.2% +/- 2.1% vs. 6.7% +/- 0.9% (P less than 0.001). The per sperm CK activities showed comparable differences (0.21 +/- 0.02 vs. 0.89 +/- 0.1 CK IU/100 million sperm; P less than 0.001) in the two groups, and there was a close correlation between per sperm CK activities and M-CK concentrations (R = 0.69, P less than 0.001, N = 159). This indicates that the loss of cytoplasm and the commencement of M-CK isoform synthesis are related events during the last phase of spermatogenesis, also that the incidence of spermatozoa with incomplete cellular maturation is higher in oligospermic specimens. In characterizing the M-CK, we found that sperm (unlike muscle tissue) lack the MB hybrid of CK dimers. However, in the presence of muscle M-CK, the muscle-sperm MB-CK hybrid has formed. Thus in sperm and muscle the M-CK isoforms are structurally different, whereas the B-CKs are apparently homologous.(ABSTRACT TRUNCATED AT 250 WORDS)

Phosphagen kinase evolution. Expression in echinoderms

Arginine kinase and creatine kinase that catalyze the transfer of a phosphate group between ATP and arginine and creatine, respectively, play an important role in cellular energetics. In contrast to most animals which exhibit a single phosphagen kinase activity (creatine kinase in chordates and arginine kinase in protostomians), echinoderms exhibit both arginine kinase and creatine kinase activities, sometimes in the same tissue. In contrast to chordates in which creatine kinases are dimers (consisting of two subunits of 40 kDa) and protostomians in which arginine kinases are usually monomers (40 kDa), echinoids contain specific phosphagen kinases: a dimeric arginine kinase (consisting of two subunits of 42 kDa) in eggs and a monomeric creatine kinase (145 kDa) in sperm. We have examined echinoderms from the five existing classes (echinoids, asteroids, ophiuroids, holothurians and crinoids) for the expression of these specific phosphagen kinases in different tissues. Gel filtration was used to determine the molecular masses of the native enzymes. Antibodies specific for arginine kinase or for creatine kinase were used to characterize the subunit composition of arginine kinase and creatine kinase after SDS/PAGE and transfer. In all echinoderms analyzed, arginine kinase always occurred as an enzyme of about 81 kDa consisting of two subunits of 42 kDa and creatine kinase as a monomeric enzyme of 140-155 kDa. The occurrence in echinoderms of both phosphagen kinases with distinct specificities and specific molecular structures is discussed from both a developmental and evolutionary point of view.

Alpha-actinin expression during avian myogenesis in vivo. Evidence for the existence of an embryo-specific isoform of alpha-actinin

The isoforms of skeletal muscle alpha-actinin present during chick embryogenesis were analyzed by two-dimensional electrophoresis in combination with the immunoblot technique. Chicken embryonic muscles at 8-15 days contain an embryo-specific isoform of alpha-actinin. The embryonic alpha-actinin isoform has a molecular mass of 112 kDa and an isoelectric point of 5.8, whereas the values for the adult isoform of alpha-actinin were 100 kDa and 5.85, respectively. To characterize the two classes of alpha-actinin polypeptides we have compared the two proteins by 125I-labeled two-dimensional peptide mapping. The embryonic isoform is highly similar to, but exhibited extensive peptide differences to, the adult isoform of alpha-actinin. The developmental sequence of the expression of the alpha-actinins was also studied. In extracts of skeletal muscle from 8-10-day-old embryos, only the embryonic isoform was detected. In extracts from 15-day-old embryos, both the embryonic and the adult isoforms coexisted. However by 21 days, the embryonic isoform had disappeared and only the adult isoform was detected. These data suggested that the embryonic and the adult isoform of alpha-actinins are distinct proteins and that during skeletal myogenesis in ovo one class of alpha-actinin is replaced by a new class of alpha-actinin polypeptides, and that the latter is maintained into adulthood.

Skeletal muscle CK-B activity in neurogenic muscular atrophies

Creatine kinase isoenzymes were determined in skeletal muscle biopsy specimens of 34 patients suffering from neurogenic muscular atrophies. The findings were compared: (1) with those of 38 control muscle samples and (2) with those in 41 muscular dystrophies and other myopathic conditions. The measurements were made by electrophoretic separation and elution of the isoenzymes and by immunoinhibition assay. The results showed that the total and specific CK activity were significantly decreased (P less than 0.005) in neurogenic atrophies in contrast to myopathic conditions where no differences from control levels were observed. This decrease was due to a decrease of the CK-M subunit activity, while the CK-B subunit was elevated. The muscle CK-MB activity was considerably elevated in muscular dystrophies (P less than 0.02) and myositis (P less than 0.001), but it was also slightly elevated in neurogenic conditions. The similarity of the muscle CK isoenzyme pattern in neurogenic atrophies and myotonic dystrophy was noted. These findings could possibly reflect considerable difference in the regeneration process of neurogenic atrophies and muscular dystrophies.

Alternative promoter usage by aldolase A during in vitro myogenesis

Aldolase A in the mouse, as in human and rat, shows tissue-specific variability of message size. In addition, in muscle tissue the mRNA size is also developmentally regulated. In order to determine whether this muscle-specific regulatory mechanism can be reproduced in vitro, we have examined the mRNA species of aldolase A isolated from mouse C2C12 myoblasts and myotubes on Northern blots and by primer extension. We show that aldolase A mRNA increases during in vitro myogenesis; that this induction is accompanied by a change in the message population; and that this change is due to activation of a muscle-specific alternative promoter.

Transcriptional repression of an embryo-specific muscle gene

Skeletal muscle involves both the induction and repression of gene expression. Although activation and up-regulation of several contractile protein genes has been shown to occur via transcriptional mechanisms, the mechanisms by which contractile protein genes are repressed during muscle development remain unknown. However, a post-transcriptional mechanism has been implicated in the repression of thymidine kinase expression during muscle development. The chicken cardiac troponin T (cTNT) gene is expressed in early embryonic skeletal muscle but is abruptly repressed in late embryonic/fetal development. Using run-on transcription assays we demonstrate here that cTNT gene repression occurs at the level of transcription. Thus, transcriptional as well as post-transcriptional mechanisms operate both to activate and repress gene expression during skeletal muscle development.

Differential expression of creatine kinase and phosphoglycerate mutase isozymes during development in aneural and innervated human muscle culture

Several enzymes that occur in multimolecular forms undergo transitions during myogenesis. Studies of such developmentally regulated isozymes (e.g. creatine kinase) indicate that muscle cells, cultured in the absence of neural tissue never develop fully mature isozyme patterns, but continue to express large amounts of 'housekeeping' isozymes that are characteristically present in fetal muscle. We studied two developmentally controlled isozymes, creatine kinase (CK) and phosphoglycerate mutase (PGAM) in normal human muscle, both aneurally cultured and co-cultured with fetal mouse spinal cord complex. Innervated cultures attain a greater degree of maturity than non-innervated cultures, as revealed by light and electron microscopy, showing well-developed sarcomeres and motor endplates after several weeks in vitro. During early stages of muscle regeneration in co-culture, characteristic fetal isozyme patterns of CK-BB and PGAM-BB activity predominate, as in aneural cultures. The muscle-specific isozymes (CK-MM; PGAM-MM) begin to appear as the muscle differentiates, and after 2-3 months in co-culture only, virtually all enzyme activity is due to the muscle-specific forms of CK and PGAM, as is normally observed in mature skeletal muscle in vivo.

Skeletal muscle neural cell adhesion molecule (N-CAM): changes in protein and mRNA species during myogenesis of muscle cell lines

Qualitative and quantitative changes in neural cell adhesion molecule (N-CAM) protein and mRNA forms were measured during myogenesis in G8-1 and C2 cell lines. Indirect immunofluorescence assay showed that N-CAM was constitutively expressed by myoblasts in culture and that myotubes appeared to be stained more strongly. These changes were quantified using a dot blot assay. N-CAM levels increased almost 4-fold in G8-1 cells and 15-fold in C2 cells during myogenesis. The kinetics of accumulation of N-CAM were not coordinate with other muscle markers such as creatine kinase or acetylcholine receptor levels, since N-CAM accumulated significantly ahead of these markers. Immunoblotting showed that myogenesis was not associated with changes in the extent of sialylation of N-CAM. However, distinct changes in desialo forms were observed after neuraminidase treatment. Myogenesis was accompanied by increases in 125- and 155-kD desialo forms with minor changes in 120- and 145-kD forms. Biosynthetic labeling studies showed that myoblasts specifically expressed a transmembrane isoform of 145 kD that was phosphorylated and was down-regulated in myotubes. Pulse-chase analysis of myotubes showed that the 120-kD isoform and an isoform of 145 kD that co-migrated with, but was distinct from, the 145 kD transmembrane isoform of myoblasts were precursors of the 125- and 155-kD isoforms, respectively, that accumulated in myotubes. The 125- and 155-kD isoforms in myotubes are linked to the cell membrane via phosphatidylinositol linkage and can be released by phospholipase C. Indirect immunofluorescence analysis showed that phosphatidylinositol specific phospholipase C specifically released N-CAM from the myotube membrane generating N-CAM-free myotubes, while myoblasts were unaffected by this treatment. Three N-CAM mRNA species were observed in mouse muscle cell lines. Myoblasts were characterized by their expression of 6.7- and 5.2-kb transcripts while myotubes express 5.2- and 2.9-kb transcripts. Thus, myogenesis is qualitatively associated with a down regulation of the 6.7-kb transcript and an up regulation of the 5.2- and 2.9-kb transcript.

Iron supports myogenic cell differentiation to the same degree as does iron-bound transferrin

T. Hasegawa, K. Saito, I. Kimura, and E. Ozawa (1981, Proc. Jopan Acad. B 57, 206-210) have shown that Fe ion can promote myogenic cell growth as Fe-bound transferrin. In the present work, the effects of these substances in supporting myogenic cell differentiation were examined. The hallmarks of differentiation adopted were appearance of structural and regulatory proteins, myofibrils, sarcoplasmic reticulum, and Ca-activated activities of myosin B and phosphorylase kinase; isoform transition of creatine kinase; and acquisition of cell membrane excitability and contractility following electrical stimulation of myotubes. The degree of differentiation of myotubes cultured in the presence of Fe ion was almost the same as that of myotubes cultured in the presence of Fe-bound transferrin. These facts suggest that transferrin protein molecules do not play a primary role in differentiation. Further, it has also been shown that myotubes acquire excitation-contraction and metabolism coupling qualitatively similar to that of adult muscle fiber.

Innervation is required to stabilize and amplify creatine kinase activity in regenerated extensor digitorum longus muscles of rats

Neural control of creatine kinase (CK, adenosine 5'-triphosphate creatine phosphotransferase: EC 2.7.3.2) was investigated by measuring enzymatic activity and isoenzymatic representation of CK in extensor digitorum longus (EDL) muscles of adult rats during and after regeneration. Experimental models were ischemized EDLs, reversibly or permanently denervated. Results showed that, during regeneration, CK in muscle fibers was likewise modified in both reversibly and permanently denervated EDLs. After regeneration a clear dichotomy was observed between the regenerated EDLs which were innervated and recovering CK activity, and those in which innervation was prevented and were rapidly losing activity. Further to investigate the neural influence on CK turnover, merely denervated age-matched EDLs were analysed and found to lose CK activity rapidly. The major conclusions are that during regeneration muscle CK is autonomously expressed, but following regeneration neural influence becomes an absolute requirement for stabilization and amplification of CK.

Characterization of myogenic cell lines derived by 5-azacytidine treatment

Three myogenic clonal cell lines were isolated from C3H 10T1/2 C18 cells (10T1/2) treated with 5-azacytidine (5-aza-CR). These lines reproducibly underwent fusion at confluence into functional myotubes capable of contracting in response to acetylcholine. The degree of fusion could be increased two- to threefold if the cells were grown on gelatin-coated dishes. All of the cell lines lost some of their myogenic potential after repeated passaging and the percentage of colonies capable of forming muscle was not increased by permissive media containing 2% horse serum. The 10T1/2 cells expressed only the BB form of creatine phosphokinase but all of the myogenic clones expressed additionally the MM and MB forms of the isozyme after fusion. The overall genomic level of 5-methylcytosine was decreased in some but not all of the cell clones tested. Comparisons between the 10T1/2 cells which never form muscle without 5-aza-CR treatment and clonal derivatives of committed cell types might be of value in understanding the molecular basis of the commitment process.

Muscle cell cultures from chicken breast muscle have increased specific activities of creatine kinase when incubated at 41 degrees C compared with 37 degrees C

Chicken muscle cell cultures were incubated at 41 degrees C, the physiological chicken body temperature, and compared with cultures incubated at 37 degrees C, the typical cell culture incubation temperature. The cultures incubated at 41 degrees C show not only an increase in creatine kinase (CK)-specific activity but also a marked increase in the percentage of adult muscle CK isozyme (MM-CK) in 7-day muscle cultures. Muscle cell cultures incubated in the presence of cytosine arabinoside (ara-C), a cell proliferation inhibitor, do not have the mononucleated cell overgrowth seen at 41 degrees C and thus exhibit a further increase in creatine kinase-specific activity compared with cultures incubated at 41 degrees C in the absence of ara-C. These results suggest that muscle cell cultures incubated at 41 degrees C are more highly differentiated than those incubated at 37 degrees C.

The primary structure of chicken B-creatine kinase and evidence for heterogeneity of its mRNA

cDNA clones for chicken B-CK were isolated by immunoscreening from a gizzard cDNA library constructed in the expression vector lambda gtll. The entire coding portion in addition to the complete 3' untranslated region and 42 bp of the 5' noncoding part are represented in the clone H4. On RNA blots H4 insert DNA hybridized to a 1600 bp poly(A)+ RNA from gizzard, brain and heart but not to breast or skeletal muscle RNA. In vitro generated sense strand transcripts of H4 insert DNA were translated in vitro into a protein indistinguishable from isolated, authentic B-CK. The distinct nucleotide sequences of H4 insert DNA and M-CK cDNA were translated into 82% homologous amino acid sequences. Sequence heterogeneity among the B-CK cDNA clones within both the 3' noncoding and even in the coding region indicates the existence of multiple B-CK mRNA species.

Creatine kinase isoenzymes in spermatozoa

Two isoforms of creatine kinase (CK, E.C. 2.7.3.2), the brain type BB-CK and the mitochondrial-bound MiMi-CK, as well as adenylate kinase (myokinase, E.C. 2.7.4.3) were identified in washed spermatozoa from chicken and man by cellulose polyacetate electrophoresis and immunoblots. BB-CK was localized by indirect immunofluorescence staining within the sperm tail but not in the head portion. MiMi-CK is confined to the midpiece region rich in mitochondria and has been localized directly by immunogold staining within the mitochondria. In contrast to chicken, seminal plasma from man was also found to contain considerable amounts of BB-CK. Total creatine content of spermatozoa (8-15 mM) and seminal plasma (3.8 +/- 0.4 mM) as well as preliminary experiments with metabolic blockers indicate a dependence of sperm motility on CK and phosphoryl creatine (CP). The presence of two CK isoforms located in different 'compartments' of spermatozoa suggests a CP-shuttle in sperm similar to that described for cross-striated muscle.

Isoenzyme changes during rat facial development

A method is presented by which rat facial processes from different stages were obtained in pure fraction. The morphology, and protein and DNA contents in free dissected facial processes were determined. Facial processes of embryonic rats aged 9-15 days were analyzed by isoelectric focusing for their isoenzymic distribution of four enzymes: lactate dehydrogenase, creatine phosphokinase, fructose diphosphate aldolase and phosphoglycerate mutase. A dominance of LDH-5, LDH-4 and LDH-3 isoenzymes was observed. As a comparison, LDH isoenzymes from mandibular and maxillary processes of rat embryos aged 9-11 days only revealed LDH-5 and to a smaller extent LDH-4. The results support the presence of a prominent anaerobic metabolism in these tissues during early facial development. The change to LDH-3 development correlates well with the formation of new blood vessels. From the ninth embryonic day, isoenzyme BB of creatine phosphokinase was present and during days 10-15 MB and MM developed. Isoenzyme A4 of fructose diphosphate aldolase was present from the ninth embryonic day and isoenzymes A3C and A2C2 developed during days 10-15. From the tenth embryonic day, isoenzyme BB of phosphoglycerate mutase was present and during days 10-15 isoenzyme MB and MM developed. Isoenzyme development was first seen in mandibular processes, followed by maxillary, lateral nasal and medial nasal processes, and it preceded morphologic evidence of skeletal muscle formation.

Specific proteolytic modification of creatine kinase isoenzymes. Implication of C-terminal involvement in enzymic activity but not in subunit-subunit recognition

We are using the isoenzymes of creatine kinase (CK) to investigate the effect of specific proteolytic modification on the abilities of enzyme subunits to establish precise subunit-subunit recognition in vitro. Previous work by others has shown that treatment of the MM isoenzyme of rabbit CK with Proteinase K results in a specific proteolytic modification and inactivation of the enzyme. In the present work, we show that both the MM and BB isoenzymes of chicken CK are also specifically modified by Proteinase K, resulting in over 98% loss of catalytic activity and approx. 10% decreases in subunit molecular masses of the enzymes. Similar reactions appear to occur when the isoenzymes are treated with Pronase E. Limited amino acid sequence analysis of intact and Proteinase K-modified MM-CK suggests that the proteolytic modification results from a single peptide-bond cleavage occurring between alanine residues 328 and 329, about 50 amino acid residues from the C-terminal end; the active-site cysteine residue was recovered in the large protein fragment of modified M-CK subunits. Proteolytically modified M-CK and B-CK subunits were able to refold and reassociate into dimeric structures after treatment with high concentrations of LiCl and at low pH. Thus the proteolytically modified CK subunits retain their ability to refold and to establish precise subunit-subunit recognition in vitro.

Nuclear substructure antigens. Monoclonal antibodies against components of nuclear matrix preparations

We describe two monoclonal antibodies, I-2 and I-14, which recognize, respectively, proteins of 36 and 40 kD. By immunofluorescence microscopy on chick embryo fibroblasts, both antigens were found to be located within a nuclear substructure which excludes nucleoli and part of the nucleoplasm; hence we refer to these antigens as nuclear substructure antigens. By immuno-electron microscopy on chick liver sections, the I-14 antigen was identified predominantly in clusters of interchromatin granules and in perichromatin fibrils. The two substructure antigens share a remarkable resistance to sequential extraction of nuclei with DNase I, RNase A, non-ionic detergent and high salt, indicating that they constitute part of an operationally defined residual nuclear matrix. Finally, both substructure antigens are virtually absent from the nuclei of adult erythrocytes. These properties suggest that substructure antigens may be involved in RNA transcription, processing or transport, possibly by contributing nucleoskeletal support.

Dual adhesion systems of chick myoblasts

Cultured chick myoblasts (Mb) were resuspended by incubation with 100 micrograms/ml trypsin/2.5 mM CaCl2 (to yield TC-Mb), or with 5 micrograms/ml trypsin/2.5 mM EDTA (to yield LTE-Mb). As measured in a particle counter, TC-Mb aggregation was Ca2+ dependent, whereas LTE-Mb aggregated equally well in the presence of CaCl2 or EDTA. Cells subjected to the same treatments in sequence, like cells dissociated directly with 100 micrograms/ml trypsin/2.5 mM EDTA, did not aggregate significantly in the presence or absence of Ca2+. Adhesive specificity was assessed by mixing unlabeled cells with cells labeled with a fluorescent dye and then analyzing the distribution of fluorescent and nonfluorescent cells in aggregates. No adhesive specificity was seen in controls (i.e., TC-Mb aggregated randomly with TC-Mb, or LTE-Mb with LTE-Mb), but TC-Mb and LTE-Mb did not cross-adhere. These results indicate the existence of two independent, noncomplementing, adhesion systems, and suggest that the differential treatments preserve or activate one system while destroying the other. Myoblasts dissociated with 2.5 mM EDTA in the absence of exogenous trypsin (E-Mb) have both adhesion systems active on their surfaces, as do Mb grown in Ca2+-free medium and then dissociated with 0.7 mM EDTA (Knudsen, K. A., and Horwitz, A. F., Dev. Biol. 58, 328-338, 1977). Although aggregation of E-Mb is largely Ca2+ independent and that of Knudsen/Horwitz-Mb is largely Ca2+ dependent, they adhere well to each other and to LTE-Mb while segregating from TC-Mb. Fibroblasts also have dual adhesion systems, one Ca2+ dependent and the other Ca2+ independent, but TC-Fb do not cross-adhere to TC-Mb (nor E-Fb to E-Mb). Cell type-specific adhesive selectivity may thus contribute to the selectivity of myocyte fusion.

Heart C-protein is transiently expressed during skeletal muscle development in the embryo, but persists in cultured myogenic cells

The expression of cardiac and white skeletal C-protein isoforms was analyzed in developing chicken embryos and in primary skeletal muscle cell cultures by immunoblot and immunofluorescence staining using polyclonal antibodies specific for both of the two different proteins. In the embryo, cardiac C-protein was detected in the developing heart from very early stages through adulthood. In skeletal muscle, cardiac C-protein is shown to be transiently expressed between Days 3 and 15 during development. In contrast, the expression of white skeletal C-protein is gradual and progressive starting approximately from Day 15 on in development. In primary cell cultures of skeletal muscle, however, cardiac C-protein remained expressed throughout prolonged culture time, this in conjunction with white skeletal C-protein. Thus the down regulation of cardiac C-protein and the transition from cardiac C-protein to adult skeletal (white) C-protein which was observed during skeletal muscle development in vivo, does not seem to go to completion in the in vitro system.

Novel thick filament protein of chicken pectoralis muscle: the 86 kd protein. II. Distribution and localization

Antibodies specific for the novel 86 kd protein purified from chicken pectoralis myofibrils stained by indirect immunofluorescence the middle third of each half A-band of isolated myofibrils and myotubes. Pectoralis muscle 86 kd protein, like pectoralis C-protein, displayed a fibre-type specific distribution by being restricted to fast twitch fibres and absent in slow tonic and heart muscle fibres. This was demonstrated by immunoblotting experiments with tissue extracts and by immunofluorescence labelling of cryosections. In primary cell cultures prepared from embryonic chicken breast muscle, 86 kd protein, C-protein and myomesin were all detected in post-mitotic myoblasts where fluorescence was found in a cross-striated pattern along strands of nascent myofibrils. Fluorescence due to the 86 kd protein was restricted to myofibrils within myotubes and no significant labelling of the sarcoplasm was evident. Glycerinated fast twitch muscle fibres, after incubation with antibodies to 86 kd protein, revealed in each half of the A-band nine distinctly labelled stripes, spaced about 43 nm apart. Simultaneous incubation of fibres with antibodies against 86 kd protein and C-protein showed a co-localization of the seven C-protein stripes (stripes 5 to 11), with seven stripes of 86 kd protein. The two additional stripes (stripes 3 and 4) labelled by anti-86 kd antibody continued towards the M-band at the same periodicity from the last C-protein stripe (stripe 5). Thus, partial co-localization of two different thick filament proteins is demonstrated and the identity of transverse stripes at positions 3 and 4 attributed in part to the presence of the new 86 kd protein.

Accumulation of creatine kinase mRNA during myogenesis: molecular cloning of a B-creatine kinase cDNA

Cytosolic creatine kinase isoenzymes MM, MB, and BB are assembled from M or B subunits which occur in different relative amounts in specific tissues. The accumulation of mRNAs encoding the M and B subunits was measured during myogenesis in culture. The relative concentration of the two mRNAs was determined by hybridization with a M-CK cDNA probe isolated previously and a B-CK cDNA probe, the cloning and characterization of which is reported here. The B-CK cDNA hybridizes specifically to a 1.6-kb mRNA found in brain and gizzard but not in adult skeletal muscle tissue. The M-CK cDNA hybridizes to a smaller mRNA 1.4-kb long which is specific to skeletal muscle. In culture, the B-CK mRNA is transiently induced and then declines to a low but detectable level.

Myomesin and M-protein: expression of two M-band proteins in pectoral muscle and heart during development

The expression of the myofibrillar M-band proteins myomesin and M-protein was studied in chicken pectoral muscle and heart during differentiation using monoclonal antibodies in a double-antibody sandwich enzyme-linked immunosorbent assay, immunoblotting, and immunocytochemistry. In presumptive pectoral muscle, myomesin accumulated first, increasing from 2% of the adult concentration at day 7 to 70% by day 16 in ovo. M-protein accumulation lagged 6-7 d behind that of myomesin attaining only 40% of the adult concentration in ovo. The molecular masses of myomesin (185 kD) and M-protein (165 kD) remained constant during embryogenesis. In cultured myogenic cells the accumulation and M-band localization of myomesin preceded that of M-protein by 1.5 d. Chicken heart was shown, in addition to M-protein, to contain unique isoforms of myomesin. In hearts of 6 d embryos, a 195-kD myomesin isoform was the major species; throughout development, however, a transition to a mixture of 195 and 190 kD was observed, the latter being the major species in the adult tissue. During heart differentiation the initial accumulation of myomesin again preceded that of M-protein, albeit on an earlier time scale than in pectoral muscle with M-protein reaching adult proportions first.

Regulation of creatine kinase induction in differentiating mouse myoblasts

The regulation of creatine kinase (CK) induction during muscle differentiation was analyzed with MM14 mouse myoblasts. These cells withdraw from the cell cycle and commit to terminal differentiation when fed with mitogen-depleted medium. Myoblasts contained trace amounts of an isozyme of brain CK (designated BB-CK), but differentiation was accompanied by the induction of two other isozymes of muscle and brain CKs (designated MM-CK and MB-CK). Increased CK activity was detectable within 6 h of mitogen removal, 3 h after the first cells committed to differentiation and 6 h before fusion began. By 48 h, MM-CK activity increased more than 400-fold, MB-CK activity increased more than 150-fold, and BB-CK activity increased more than 10-fold. Antibodies prepared against purified mouse MM-CK cross-reacted with muscle and brain CKs (designated M-CK and B-CK, respectively) from a variety of species and were used to demonstrate that the increase in enzymatic activity was paralleled by an increase in the protein itself. CK antibodies were also used to aid in identifying cDNA clones to M-CK. cDNA sequences which corresponded to protein-coding regions cross-hybridized with B-CK mRNA; however, a subclone containing the 3'-nontranslated region was unique and was used to quantitate M-CK mRNA levels during myoblast differentiation. M-CK mRNA was not detectable in myoblasts, but within 5 to 6 h of mitogen withdrawal (6 to 7 h before fusion begins) it accumulated to about 30 molecules per cell. By 24 h, myotubes contained approximately 1,100 molecules per nucleus of M-CK mRNA.

Two tissue-specific isozymes of creatine kinase have closely matched amino acid sequences

Creatine kinase activity is associated with different isozyme species. We have examined two of these: the cytoplasmic brain (B) isozyme that is expressed in many tissues and is reported to be induced by estrogen and the developmentally regulated cytoplasmic muscle (M) isozyme that is found predominantly in differentiated muscle tissue. Recently, we cloned and sequenced the cDNA for the M isoenzyme of rabbit creatine kinase. We now report the isolation of B-isozyme cDNAs and the deduced primary structure of the polypeptide. The translated cDNA nucleotide sequence was cross-checked by fast-atom bombardment/mass spectrometry of tryptic fragments from the protein. The sequence is exactly colinear with the rabbit M isozyme and the two isozymes have 80% nucleotide and amino acid sequence identity. There are blocks of 36 and 41 amino acids where the amino acid sequence is conserved exactly. The colinearity of the two sequences and the extent of their identity makes it unlikely that either isozyme has unique polypeptide domains that account for specialized functions. The rationale for the existence of these creatine kinase isozymes, with distinct biological features, evidently is at the level of regulation of individual isozyme expression.

Subcellular localization of creatine kinase in Torpedo electrocytes: association with acetylcholine receptor-rich membranes

Creatine kinase (CK, EC 2.7.3.2) has recently been identified as the intermediate isoelectric point species (pl 6.5-6.8) of the Mr 40,000-43,000 nonreceptor, peripheral v-proteins in Torpedo marmorata acetylcholine receptor-rich membranes (Barrantes, F. J., G. Mieskes, and T. Wallimann, 1983, Proc. Natl. Acad. Sci. USA, 80: 5440-5444). In the present study, this finding is substantiated at the cellular and subcellular level of the T. marmorata electric organ by immunofluorescence and by protein A-gold labeling of either ultrathin cryosections of electrocytes or purified receptor-membrane vesicles that use subunit-specific anti-chicken creatine kinase antibodies. The muscle form of the kinase, on the one hand, is present throughout the entire T. marmorata electrocyte except in the nuclei. The brain form of the kinase, on the other hand, is predominantly located on the ventral, innervated face of the electrocyte, where it is closely associated with both surfaces of the postsynaptic membrane, and secondarily in the synaptic vesicles at the presynaptic terminal. Labeling of the noninnervated dorsal membrane is observed at the invaginated sac system. In the case of purified acetylcholine receptor-rich membranes, antibodies specific for chicken B-CK label only one face of the isolated vesicles. No immunoreaction is observed with anti-chicken M-CK antibodies. A discussion follows on the possible implications of these localizations of creatine kinase in connection with the function of the acetylcholine receptor at the postsynaptic membrane, the Na/K ATPase at the dorsal electrocyte membrane, and the ATP-dependent transmitter release at the nerve ending.

Regulation of creatine kinase induction in differentiating mouse myoblasts

The regulation of creatine kinase (CK) induction during muscle differentiation was analyzed with MM14 mouse myoblasts. These cells withdraw from the cell cycle and commit to terminal differentiation when fed with mitogen-depleted medium. Myoblasts contained trace amounts of an isozyme of brain CK (designated BB-CK), but differentiation was accompanied by the induction of two other isozymes of muscle and brain CKs (designated MM-CK and MB-CK). Increased CK activity was detectable within 6 h of mitogen removal, 3 h after the first cells committed to differentiation and 6 h before fusion began. By 48 h, MM-CK activity increased more than 400-fold, MB-CK activity increased more than 150-fold, and BB-CK activity increased more than 10-fold. Antibodies prepared against purified mouse MM-CK cross-reacted with muscle and brain CKs (designated M-CK and B-CK, respectively) from a variety of species and were used to demonstrate that the increase in enzymatic activity was paralleled by an increase in the protein itself. CK antibodies were also used to aid in identifying cDNA clones to M-CK. cDNA sequences which corresponded to protein-coding regions cross-hybridized with B-CK mRNA; however, a subclone containing the 3'-nontranslated region was unique and was used to quantitate M-CK mRNA levels during myoblast differentiation. M-CK mRNA was not detectable in myoblasts, but within 5 to 6 h of mitogen withdrawal (6 to 7 h before fusion begins) it accumulated to about 30 molecules per cell. By 24 h, myotubes contained approximately 1,100 molecules per nucleus of M-CK mRNA.

Content and synthesis of glycolytic enzymes and creatine kinase in skeletal muscles and normal and dystrophic chickens

A number of workers have reported that avian muscular dystrophy causes alterations in the levels of certain enzyme activities in "fast-twitch" muscle fibers but has little effect on enzyme activities in "slow-twitch" muscle fibers. In the present work, the effects of this disease on the content and relative rates of synthesis of a number of glycolytic enzymes and the skeletal muscle-specific MM isoenzyme of creatine kinase in chicken muscles was investigated. It was shown that (i) the approximate 50% reductions in steady-state concentrations of three glycolytic enzymes (aldolase, enolase, and glyceraldehyde-3-P dehydrogenase) in dystrophic breast (fast-twitch) muscle result predominantly from decreases in relative rates of synthesis, rather than accelerations in relative rates of degradation, of these proteins in the diseased tissue; (ii) in contrast to the situation with the glycolytic enzymes, muscular dystrophy has only minor effects (25% or less) on the content and relative rate of synthesis of MM creatine kinase in breast muscle fibers; (iii) the muscular dystrophy-associated alterations in content and synthesis of the glycolytic enzymes in breast muscle fibers become apparent only during postembryonic maturation of this tissue; and (iv) as expected, muscular dystrophy has no significant effect on the content or relative rates of synthesis of glycolytic enzymes in slow-twitch lateral adductor muscles of the chicken. These results are discussed in terms of the apparent similarities between the effects of muscular dystrophy and surgical denervation on the protein synthetic programs expressed by mature fast-twitch muscle fibers.

Differential sensitivity of chicken MM-creatine kinase to trypsin and proteinase-K

Under several conditions of SDS-PAGE, the chicken MM-creatine kinase (MM-CK) monomer migrated as a approximately 50,000 dalton polypeptide, approx 25% larger than usually reported. Characterization by sedimentation equilibrium indicated that the anomalous molecular weight was an artifact of electrophoresis. Digestion with trypsin caused only moderate reductions in CK activity, despite extensive degradation of the denatured enzyme revealed by SDS-PAGE. Characterization of trypsinized MM-CK under non-denaturing conditions of electrophoresis and HPLC revealed no fragmentation of the native enzyme, suggesting that MM-CK quaternary structure was maintained despite extensive tryptic nicking. In contrast, much lower concentrations of proteinase-K generated only a single fragment in SDS-PAGE while causing a nearly total loss of enzyme activity.

Bovine glycogenosis type II. Biochemical and morphological characteristics of skeletal muscle in culture

The biochemical and morphological properties of cultured skeletal muscle from calves born into a herd of cattle, which are heterozygous for glycogenosis type II, were studied over 17 days. Muscle was cultured by a modification of the explant technique in which the mononucleated cells that grew from the explants were subcultured. Skeletal muscle from animals up to 15 months of age grew in culture to produce mature, cross-striated and spontaneously contractile myotubes. The creatine kinase activity was 310 (+/- 45.4) mU/mg protein on day 7 when fusion was complete, and 210 (+/- 15.1) mU/mg protein on day 17 of culture. Mature muscle cultures from animals affected by glycogenosis type II showed the characteristic biochemical and morphological abnormalities previously observed in vivo. Acid alpha-glucosidase activity was absent whereas the activities of neutral alpha-glucosidase, lysosomal alpha-mannosidase and creatine kinase were the same as in cultures of unaffected muscle. The concentration of glycogen was higher in cultured affected muscle than in cultured unaffected muscle. On days 7, 9 and 17 of culture the glycogen concentrations were 66.7 (+/- 2.7), 89.0 (+/- 5.5) and 120.3 (+/- 34.2) micrograms/mg protein respectively in affected muscle and 51.8 (+/- 3.6), 59.9 (+/- 5.4) and 55.4 (+/- 1.0) micrograms/mg protein respectively in non-affected muscle. Electron microscopic studies showed that the glycogen accumulated within the lysosomes. These results indicate that bovine glycogenosis type II is expressed in tissue culture since the cultured skeletal muscle from affected animals shows the same abnormalities as skeletal muscle in vivo.

Modulation of differentiation in vitro. II. Influence of cell spreading and surface events on myogenesis

We examined the influence of attachment and spreading on myogenesis by adding polylysine-covered beads at different times after plating the cells on a plastic substratum. We show that polylysine per se acting on the cell surface can modulate myogenesis independently of cell spreading. Thus cell shape would not be the limiting factor for the division and differentiation of L6 myoblasts. Multinucleation of the cells was found to be first enhanced by the addition of polylysine-covered beads to replicating myoblasts, although the final percentage of fusion attained by these cultures was lower than in the controls. A similar phenomenon was observed concerning myosin synthesis. No such effect could be observed when the beads were added to a nonfusing mutant or to fibroblasts. Our results show that this phenomenon is specific. We postulate that some of the surface molecules necessary for this process appear on myoblasts shortly before they fuse.