DNA synthesis and the cell cycle in cultures of normal and mutant (mdg/mdg) embryonic mouse muscle cells.

The relationship between cell fusion, DNA synthesis and the cell cycle in cultured embryonic normal and dysgenic ($\text{mdg}\text{mdg}$) mouse muscle cells has been determined by autoradiography. The experimental evidence shows that the homozygous mutant myotubes form by a process of cell fusion and that nuclei within the myotubes do not synthesize DNA or undergo mitotic or amitotic division. The duration of the total cell cycle and its component phases was statistically the same in 2-day normal and mutant ($\text{mdg}\text{mdg}$) myogenic cultures with the approximate values: T, 21.5 hr; G₁, 10.5 hr; S, 7.5 hr; and G₂, 2.5 hr. In both kinds of cultures, labeled nuclei appeared in myotubes 15–16 hr after mononucleated cells were exposed to [³H]thymidine, and the rate of incorporation of labeled nuclei into multinucleated muscle cells was comparable in control and dysgenic cultures. Thus, homozygous $\text{mdg}\text{mdg}$ muscle cells in culture are similar to control cells with respect to their mechanism of myotube formation and the coordinate regulation of DNA synthesis and the cell cycle during myogenesis.     

Appearance of contractile activity in muscular dysgenesis (mdgmdg) mouse myotubes during coculture with normal spinal cord cells

Muscular dysgenesis (mdg) in the mouse is an autosomal recessive mutation expressed in the homozygous mutant as lack of skeletal muscle contraction. To test the ability of normal neurons to form neuromuscular contacts with, and/or possibly induce contractions in $\text{mdg}\text{mdg}$ muscle, dispersed cell cultures of normal and dysgenic muscle from newborn mice were cocultured with normal embryonic rat, mouse, and chick dissociated spinal cord cells. Contraction was induced in $\text{mdg}\text{mdg}$ muscle 1 to 10 days (depending upon the species of the neuronal source) following establishment of the cocultures. Control experiments indicated that the dispersed spinal cord preparations were free of myoblasts capable of fusing with $\text{mdg}\text{mdg}$ muscle. The establishment of neuromuscular contacts in the rat neuron cocultures was monitored by cytochemical staining of acetylcholinesterase (AChE), autoradiography of ¹²⁵I-α-bungarotoxin-bound acetylcholine receptors (AChR), and electrophysiological study of muscle membrane activity. Patches of high AChE activity were similar in size and distribution to high-density clusters of AChR on both control and $\text{mdg}\text{mdg}$ myotubes cocultured with rat neurons. The resting membrane potentials of normal myotubes and those of $\text{mdg}\text{mdg}$ myotubes in the presence of neurons were similar (? ?52 mV). The mepp frequency and the mepp amplitude distribution were the same for both control and mutant cocultured muscle. Thus, normal rat spinal cord neurons were capable of forming normal, functional neuromuscular junctions with $\text{mdg}\text{mdg}$ myotubes, and contractions were induced under coculture conditions, in otherwise noncontracting mutant muscle.     

Coordinated development of myofibrils, sarcoplasmic reticulum and transverse tubules in normal and dysgenic mouse skeletal muscle, in vivo and in vitro

We studied the development of transverse (T)-tubules and sarcoplasmic reticulum (SR) in relationship to myofibrillogenesis in normal and dysgenic (mdg/mdg) mouse skeletal muscle by immunofluorescent labeling of specific membrane and myofibrillar proteins. At E16 the development of the myofibrils and membranes in dysgenic and normal diaphragm was indistinguishable, including well developed myofibrils, a delicate network of T-tubules, and a prominent SR which was not yet cross-striated. In diaphragms of E18 dysgenic mice, both the number and size of muscle fibers and myofibrillar organization were deficient in comparison to normal diaphragms, as previously reported. T-tubule labeling was abnormal, showing only scattered tubules and fragments. However, many muscle fibers displayed cross striation of sarcomeric proteins and SR comparable to normal muscle. In cultured myotubes, cross-striated organization of sarcomeric proteins proceeded essentially in two stages: first around the Z-line and later in the A-band. Sarcomeric organization of the SR coincided with the first stage, while the appearance of T-tubules in the mature transverse orientation occurred infrequently, only after A-band maturation. In culture, myofibrillar and membrane organization was equivalent in normal and dysgenic muscle at the earlier stage of development, but half as many dysgenic myotubes reached the later stage as compared to normal. We conclude that the mdg mutation has little effect on the initial stage of membrane and myofibril development and that the deficiencies often seen at later stages result indirectly from the previously described absence of dihydropyridine receptor function in the mutant.     

A probable role of dihydropyridine receptors in repression of Ca2+ sparks demonstrated in cultured mammalian muscle

To activate skeletal muscle contraction, action potentials must be sensed by dihydropyridine receptors (DHPRs) in the T tubule, which signal the Ca²⁺ release channels or ryanodine receptors (RyRs) in the sarcoplasmic reticulum (SR) to open. We demonstrate here an inhibitory effect of the T tubule on the production of sparks of Ca²⁺ release. Murine primary cultures were confocally imaged for Ca²⁺ detection and T tubule visualization. After 72 h of differentiation, T tubules extended from the periphery for less than one-third of the myotube radius. Spontaneous Ca²⁺ sparks were found away from the region of cells where tubules were found. Immunostaining showed RyR1 and RyR3 isoforms in all areas, implying inhibition of both isoforms by a T tubule component. To test for a role of DHPRs in this inhibition, we imaged myotubes from dysgenic mice (mdg) that lack DHPRs. These exhibited T tubule development similar to that of normal myotubes, but produced few sparks, even in regions where tubules were absent. To increase spark frequency, a high-Ca²⁺ saline with 1 mM caffeine was used. Wild-type cells in this saline plus 50 µM nifedipine retained the topographic suppression pattern of sparks, but dysgenic cells in high-Ca²⁺ saline did not. Shifted excitation and emission ratios of indo-1 in the cytosol or mag-indo-1 in the SR were used to image [Ca²⁺] in these compartments. Under the conditions of interest, wild-type and mdg cells had similar levels of free [Ca²⁺] in cytosol and SR. These data suggest that DHPRs play a critical role in reducing the rate of spontaneous opening of Ca²⁺ release channels and/or their susceptibility to Ca²⁺-induced activation, thereby suppressing the production of Ca²⁺ sparks. excitation-contraction coupling; sarcoplasmic reticulum; ryanodine receptors; Ca²⁺ imaging     

Muscle and nerve in muscular dysgenesis in the mouse at birth: Sprouting and multiple innervation

Muscular dysgenesis (mdg) in the mouse is a recessive autosomal mutation affecting the striated musculature: during the whole gestation period, the muscles never show any sign of contractile activity. They are cytologically immature at birth, although the diaphragm is more mature than limb muscles, as confirmed by the levels of creatine phosphokinase. In both limb muscles and diaphragm the cytochemical localization of acetylcholinesterase demonstrates focal accumulations on the entire surface of $\text{mdg}\text{mdg}$ muscles, whereas such foci of acetylcholinesterase activity are restricted to a narrow end plate-rich region in $\text{+}\text{mdg}$? diaphragms. Teased single $\text{mdg}\text{mdg}$ myofiber preparations show that one myofiber can possess several foci of acetylcholinesterase, generally presenting aspects of very immature motor end plates. A study of the motor innervation, after silver nitrate impregnation, provides evidence for a spectacular overgrowth and a generalized sprouting of $\text{mdg}\text{mdg}$ nerves and axons. The $\text{mdg}\text{mdg}$ nerve terminals are generally very immature-looking, with an intense ultraterminal sprouting. Aspects suggesting a denser multiple innervation of $\text{mdg}\text{mdg}$ than $\text{+}\text{mdg}$? myofibers have been observed and choline acetyltransferase activity is increased in $\text{mdg}\text{mdg}$ tissues. Acetylcholinesterase specific activity and the number of α-bungarotoxin binding sites per milligram protein increased in $\text{mdg}\text{mdg}$ compared to $\text{+}\text{mdg}$? diaphragms. The very low amount of 16 S (and 12 S) acetylcholinesterase is probably related to $\text{mdg}\text{mdg}$ muscle inactivity. If the cytological and biochemical data are compared, it seems possible to propose that $\text{mdg}\text{mdg}$ myofibers and axons are in contact in several regions of the same myofiber, in variably mature appositions, and with a very dense multi-innervation.     

Functional and structural recovery of myotubes from mice with muscular dysgenesis after co-culture with normal,non-myoblastic cells

Muscular dysgenesis is a mutation which is characterized by paralysis of skeletal muscle cells. Excitation-contraction coupling is deficient and muscle cells display atypical ultrastructure. In vitro, mutant myotubes recover a normal phenotype when cocultured with spinal cord cells from normal animals or with normal fibroblasts. We have shown that other types of cells, eg certain glial cells present in the spinal cord or in other tissues, have this capacity. In contrast, intervention of neurons in the recovery does not appear likely. Very different types of non-myoblastic cells, then, are capable of restoring contractile activity of dysgenic myotubes in vitro, suggesting that a non-specific mechanism is involved in the phenotypic reversion of affected muscle cells. The restoration process seems to imply a close relationship between myotubes and normal glial cells.     

DISEASED MUSCLE CELLS IN CULTURE

(1) Cultures of differentiated muscle cells have been grown from diseased human, mouse and chick skeletal muscle, and from cardiac muscle of the myopathic hamster. (2) Methods of culture established for normal embryonic and adult skeletal muscle cells have proved suitable for cultures of diseased muscle cells. (3) Myoblasts obtained from dy^2J mouse muscle crushed in vivo before explanting fuse in culture and form morphologically normal myotubes. Studies of the effects of innervation by dy^2J spinal cord neurones on the differentiation of normal, dy^2J and dy myotubes have been inconclusive but it is probable that innervation does not play a part in the pathogenesis of this disorder. (4) Myoblasts prepared by trypsinization of embryonic dy muscle behave normally in culture and fuse to form myotubes that appear normal. It is not clear if myoblasts that migrate from explants of adult muscle in vitro fuse. Aggregates of non-fusing cells have been described, but under other culture conditions normal and abnormal forms of myotube have been observed. dy muscle fibres fail to regenerate even when cultured with normal spinal cord explants and dy nerves are without effect on regenerating normal muscle fibres. These tissue-culture studies suggest that the dy mouse mutation is a myopathic disorder. (5) Embryonic mdg myoblasts have a normal cell cycle in vitro and fuse to form well-differentiated myotubes with cross-striations. mdg myotubes have normal electro-physiological properties but do not contract spontaneously or on depolarization. The defect in the muscle of the mdg mutant appears to be a failure of excitation-contraction coupling. (6) Cells migrate earlier from explants of adult dystrophic chick muscle than from normal muscle but dystrophic chick myotubes appear morphologically normal. Myotubes prepared from embryonic dystrophic chick muscle become vacuolated and degenerate, changes that can be prevented by anti-proteases such as antipain. Lactic dehydrogenase isozyme subunit M4 is absent from dystrophic muscle in vivo but reappears in cultured myotubes. Dystrophic myotubes innervated in culture by either normal or dystrophic neurones exhibit bi-directional lcoupling and multiple innervation. These results suggest that there are changes in dystrophic myotubes and that chick muscular dystrophy is a myopathy. (7) Cardiac muscle cells from the cardiomyopathic hamster synthesize less actin and myosin than normal cells, and Z lines in dystrophic cells are irregularly arranged. The beat frequency of myopathic cardiac cells is lower than that of normal cells and declines more rapidly. Tissue-culture studies have not been made of hamster skeletal muscle. (8) Human dystrophic myotubes do not show degenerative changes in culture and have normal histochemical reactions. RNA synthesis appears normal in dystrophic myotubes but there may be changes in adenyl-cyclase activity and protein synthesis in dystrophic cells. Morphological and biochemical changes have been found in muscle cells cultured from a case of acid-maltase deficiency but phosphorylase activity re-appeared in myotubes cultured from biopsies of phosphorylase-deficient muscle. Innervation by normal mouse nerves does not induce degenerative changes in dystrophic myotubes. (9) Studies on the origins of myoblasts in explants of muscle fibres in culture suggest that in these conditions myoblasts are derived only from satellite cells and that this process may be the same in normal and diseased muscle.     

Characterization of permissivity for hobo-mediated gonadal dysgenesis in Drosophila melanogaster

The hobo transposon is responsible for one of the three hybrid dysgenic systems that have been described in Drosophila melanogaster. Most studies on the hobo dysgenic system have been carried out using the PM system as a reference. However, these two systems differ significantly. In particular, several studies have failed to find any correlation between the molecular structures of hobo elements, the instability of the transposon and the incidence of gonadal dysgenic (GD) sterility. On the other hand, no study of the ability of females to permit hobo activity in their progeny when they are crossed with males harboring active hobo elements (permissivity) has yet been reported. In order to investigate the parameters involved in hobo permissivity, four E strains were studied with regard to the molecular nature of their hobo sequences and the GD sterility induced by a controlled source of hobo transposase. We show that hobo permissivity varies both within and between E strains. Moreover, permissivity decreases with age in E females. Our results are discussed with respect to similar phenomena that have been described in relation to the reactivity of the IR dysgenic system.     

Electrical properties of normal and dysgenic mouse skeletal muscle in culture

Electrical properties of normal and dysgenic mouse skeletal muscle were studied by intracellular recording from embryonic cells developing in vitro. Passive membrane constants were determined from records of transmembrane potential responses to hyperpolarizing pulses of current using two types of analyses, assuming the tubes to be finite cylinders: the off transient and steady state analyses. The following properties of normal and dysgenic fibers were also studied. (a) membrane potentials (b) acetylcholine sensitivity (c) α-Bungarotoxin binding and (d) maximum rate of rise, overshoot and one-half fall time of the action potential. Rare electrotonic coupling between fibroblasts and myotubes was noted. An anomalous type of rectification Was observed in some fibers in which the transmembrane potential responses possessed under and overshoots. These responses may have affected the values of membrane constants as derived by the off transient analysis. In all parameters studied, including membrane constants derived by the steady state analysis, the cultured mouse cells resembled adult denervated mammalian muscle rather than innervated muscle. There were no differences between normal and dysgenic fibers with respect to any of the parameters studied. Dysgenic fibers did not contract although they displayed passive and active membrane properties like those in normal, non-dysgenic fibers.     

Evidence for dysfunction in the regulation of cytosolic Ca2+ in excitation-contraction uncoupled dysgenic muscle

In noncontracting, dysgenic murine muscle, excitation is uncoupled from contraction. To test whether the gene lesion is expressed as a defect in the regulation of the intracellular free Ca2+ levels, cultured normal and dysgenic muscle at various stages of development (proliferative myoblasts, early, late, and mature myotubes) were exposed to increasing increments (0.5-mM steps) of extracellular Ca2+ in ionophore A23187-Ca2+-EGTA-buffered media. Normal and dysgenic muscle at all stages (except myoblast) displayed contractures at approximately 500 microM free Ca2+ and higher. Experiments using finer increments of Ca2+ and different ionophore concentrations indicated an external Ca2+ threshold for contracture at 265 microM Ca2+ for early and late myotubes and 47-78 microM for mature normal and dysgenic myotubes. Low extracellular concentrations of calcium (14 microM and 0.76 nM) caused elongation of both normal and dysgenic myotubes. Mature cells were depolarized by exposure to increasing extracellular K+ and monitored by intracellular recording; normal and dysgenic myotubes showed similar reductions in membrane potentials. Depolarization to -35 mV elicited contractures in normal myotubes, but even depolarization to -9 mV in dysgenic cells elicited no response. Thus steady-state depolarization of dysgenic muscle does not cause contractures, which can, however, be elicited by increasing the intracellular free Ca2+. These results offer new evidence for a possible defect in the regulation of Ca2+ levels in dysgenic muscle.     

Changes in myosin heavy chain isoform expression of overloaded rat skeletal muscles

• 1.1. The effect of functional overload produced by tenotomy of synergistic gastrocnemius muscle on the expression of myosin heavy chain (MHC) isoforms in the plantaris and soleus muscles of the rat was studied using gradient sodium dodecyl sulfate-acrylamide gel electrophoresis.
• 2.2. Five weeks tenotomy, the plantaris and soleus muscle weights induced by tenotomy of the gastrocnemius muscle were 44.3% (P < 0.005) and 37.4% (P < 0.005), respectively, heavier than the contralateral control muscles.
• 3.3. Although four types of MHC isoforms were observed in both control and experimental plantaris, the percentage of MHC isoforms in the control and experimental muscles differed; the hypertrophied plantaris muscle contained more HCI (P < 0.05), HCIIa and HCIId (P < 0.05) and less HCIIb (P < 0.05) than the control muscle.
• 4.4. The control soleus muscle contained two MHC isofonns, HCI and HCIIa. However, there was only a single HCI isoform in the hypertrophied soleus muscle.
• 5.5. These results indicate that overloading a skeletal muscle by removing its synergists produces not only the muscle hypertrophy but also the changes in the expression of MHC isofonns.

     

Distinct myogenic programs of embryonic and fetal mouse muscle cells: expression of the perinatal myosin heavy chain isoform in vitro.

Early embryonic and late fetal mouse myogenic cells showed distinct patterns of perinatal myosin heavy chain (MHC) isoform expression upon differentiation in vitro. In cultures of somite or limb muscle cells isolated from Day 9 to Day 12 embryos, differentiated cells that expressed perinatal MHC were rare and perinatal MHC was not detectable by immunoblotting. In cultures of limb muscle cells isolated from Day 13 to Day 18 fetuses, in contrast, the perinatal MHC isoform was easily detected and was expressed in a substantial percentage of myocytes and myotubes. Analyses of clonally derived muscle colonies and cytosine arabinoside-treated fetal muscle cell cultures suggested that different fetal muscle cell nuclei initiated perinatal MHC expression at different times. In both embryonic and fetal cell cultures, the embryonic MHC isoform was expressed by all differentiated cells examined. A small number of myotubes in fetal muscle cell cultures showed a mosaic distribution of MHC isoform accumulation in which the perinatal MHC isoform accumulated in a restricted region of the myotube near particular nuclei, whereas the embryonic MHC isoform accumulated throughout the myotube. Thus, the myogenic program of fetal, but not embryonic, mouse myogenic cells includes expression of the perinatal MHC isoform upon differentiation in culture.     

The Obestatin/GPR39 System Is Up-regulated by Muscle Injury and Functions as an Autocrine Regenerative System

The maintenance and repair of skeletal muscle are attributable to an elaborate interaction between extrinsic and intrinsic regulatory signals that regulate the myogenic process. In the present work, we showed that obestatin, a 23-amino acid peptide encoded by the ghrelin gene, and the GPR39 receptor are expressed in rat skeletal muscle and are up-regulated upon experimental injury. To define their roles in muscle regeneration, L6E9 cells were used to perform in vitro assays. For the in vivo assays, skeletal muscle tissue was obtained from male rats and maintained under continuous subcutaneous infusion of obestatin. In differentiating L6E9 cells, preproghrelin expression and correspondingly obestatin increased during myogenesis being sustained throughout terminal differentiation. Autocrine action was demonstrated by neutralization of the endogenous obestatin secreted by differentiating L6E9 cells using a specific anti-obestatin antibody. Knockdown experiments by preproghrelin siRNA confirmed the contribution of obestatin to the myogenic program. Furthermore, GPR39 siRNA reduced obestatin action and myogenic differentiation. Exogenous obestatin stimulation was also shown to regulate myoblast migration and proliferation. Furthermore, the addition of obestatin to the differentiation medium increased myogenic differentiation of L6E9 cells. The relevance of the actions of obestatin was confirmed in vivo by the up-regulation of Pax-7, MyoD, Myf5, Myf6, myogenin, and myosin heavy chain (MHC) in obestatin-infused rats when compared with saline-infused rats. These data elucidate a novel mechanism whereby the obestatin/GPR39 system is coordinately regulated as part of the myogenic program and operates as an autocrine signal regulating skeletal myogenesis.     

The molecular basis of P-M hybrid dysgenesis: The role of the P element,a P-strain-specific transposon family

We have shown previously that four of five white mutant alleles arising in P-M dysgenic hybrids result from the insertion of strongly homologous DNA sequence elements. We have named these P elements. We report that P elements are present in 30–50 copies per haploid genome in all P strains examined and apparently are missing entirely from all M strains examined, with one exception. Furthermore, members of the P family apparently transpose frequently in P-M dysgenic hybrids; chromosomes descendant from P-M dysgenic hybrids frequently show newly acquired P elements. Finally, the strain-specific breakpoint hotspots for the rearrangement of the π₂ P X chromsome occurring in P-M dysgenic hybrids are apparently sites of residence of P elements. These observations strongly support the P factor hypothesis for the mechanistic basis of P-M hybrid dysgenesis.     

Transient induction of poly(A)-short myosin heavy chain messenger RNA during terminal differentiation of L6E9 myoblasts

The rat myoblast L₆E₉ cell line under appropriate culture conditions is a uniform population of cycling cells which can be induced to differentiate into a pure population of myotubes. The pattern and kinetics of myogenic differentiation of this cell line are similar to those of primary skeletal muscle myoblasts. We have used this cell line to investigate the controls regulating the synthesis and accumulation of myosin heavy chain during myogenic development. From pulse labeling studies of total cellular protein synthesis, we observed that activation of MHC⁴ synthesis is temporally correlated with cell fusion and myotube formation. MHC synthesis is transiently induced from <1% up to 25% of the total protein synthesized. After MHC has accumulated to the steady-state level characteristic of fully differentiated myotubes, MHC synthesis decreases very rapidly to almost basal levels. To determine whether this transient induction of MHC synthesis was due to parallel changes in MHC messenger RNA levels, the accumulation and compartmentalization of MHC mRNA during L₆E₉ cell differentiation was followed by complementary DNA/RNA hybridization using cDNA prepared against MHC mRNA purified from L₆E₉ cells. We demonstrate that the level of MHC synthesis closely parallels the level of cytoplasmic MHC mRNA. The induction of MHC mRNA accumulation is initiated at least 36 hours prior to cell fusion and at a time when all cells in the population are still uncommitted to terminal differentiation as tested by cell cloning. The level of cytoplasmic MHC mRNA is increased from ~200 molecules per cell in the growing state to ~50,000 molecules at the peak of induction (day 6 after plating). Subsequently the levels of MHC mRNA decrease very rapidly and at day 10 after plating there are only ~3000 molecules per myotube nucleus. A striking feature of this regulation is the behavior of MHC mRNA on oligo(dT) columns. Most (~90%) of the MHC mRNA transiently induced during differentiation has a very short poly(A) tail (<20 nucleotides). We conclude that the striking induction followed by deinduction of MHC synthesis is controlled primarily by the induction and deinduction of cytoplasmic MHC mRNA accumulation. The relationship of our observations to muscle physiology is discussed.     

Muscular dysgenesis: a model system for studying skeletal muscle development

Muscular dysgenesis, caused by an autosomal recessive lethal mutation (mdg) in mice, is characterized by an absence of contraction of skeletal muscle. A historical review of the investigation of this disorder is presented. The early studies of the morphological and physiological aspects of the disorder in vivo and in vitro presented evidence for dysfunction in the skeletal muscle excitation-contraction (E-C) system, and thus suggested that skeletal muscle was the primary target of dysfunction in dysgenesis. Subsequent evidence, including the phenomenon of rescue (restoration of contraction) of dysgenic muscle in culture by spinal cord cells, argued for involvement of the nervous system in the disorder. Experiments demonstrating that dysgenic muscle lacks the slow calcium current associated with E-C coupling, and the protein (the dihydropyridine receptor) also associated with such coupling, led to the discovery of the probable site of the mutation: the gene for the alpha 1 subunit of the dihydropyridine receptor. The neuronal involvement hypothesis was further countered by several lines of evidence, including the phenomenon of fusion of nonmyogenic normal cells with dysgenic myotubes in cocultures of normal cells and dysgenic muscle. The use of the mutant as a model for studying the development of normal skeletal muscle is discussed and future avenues of research are explored.     

Molecular cloning and expression of cardiac-specific myosin heavy chain gene sequences in chick embryo

A recombinant DNA plasmid, pMHC8, that contains gene sequences for embryonic chick cardiac myosin heavy chain was constructed, identified and characterized. The identity of the clone was established by hybridization with labeled probes that afford screening of MHC²² with high specificity, by inhibition of MHC synthesis in the in vitro hybrid-arrested translation assay, and by tissue-specific hybridization of labeled pMHC8 DNA to MHC messenger RNA.The pMHC8 DNA probe is highly specific for chick heart muscle tissue, since it hybridized poorly to chick skeletal muscle RNA and did not detectably hybridize to adult rat heart RNA. Upon screening the embryonic chick heart cells in culture, no detectable level of MHC mRNA was observed in dividing myoblasts, but the mRNA appeared in differentiated cardiac myocytes paralleling morphogenetic changes in the embryonic cells.