Erythropoietin induces a shift of muscle phenotype from fast glycolytic to slow oxidative.

Sedentary and trained rat groups were studied. Each of these groups was either erythropoietin or placebo treated. Erythropoietin treatment increased significantly all haematological parameters studied. Training per se failed to modify haematological parameters. In a second time, we studied the specific activity of several oxidative enzymes in three different muscles. In sedentary rats, erythropoietin treatment increased significantly the specific activities of cytochrome c oxidase and L-3-hydroxyacyl CoA dehydrogenase in the soleus and those of L-3-hydroxyacyl CoA dehydrogenase and phosphofructokinase in both locomotor muscles. Training increased the oxidative enzymes activities in all muscles studied. In trained rats, effects of erythropoietin and training on oxidative enzymes activities were additive. In all erythropoietin treated muscles, the expression of slow twitch myosin light chains and oxidative myosin heavy chains increased. A similar phenomenon took place in all trained groups for light chains and in placebo treated trained rats for heavy chains. In trained groups, the effects of the hormone and of training were additive. Our results suggest strongly that two different mechanisms are involved in the response of skeletal muscles to erythropoietin treatment and to endurance training and probably whole body endurance is affected by erythropoietin treatment by an increase of oxygenation of all tissues.

Altered myosin isoform expression in rat skeletal muscles induced by a changed thyroid state.

The aim of our study was to find out, which are the thyroid linked mechanisms responsible for the changes in myosin isoform composition which accompany endurance training (ET) in rodents. We studied the interaction between ET and altered sedentary group with no thyroid treatment or Se group. Six groups of rats were compared: (1) a trained group with no thyroid treatment or T group; (2) a thyroid state in rats; (3) a sedentary group rendered hypothyroid with 6-n-propyl thio uracil (H); (4) a sedentary group rendered hyperthyroid with T3 (150 microg kg(-1) every other day for 4 weeks) (St); (5) trained rats rendered hyperthyroid with T3 (150 microg kg(-1) every other day for 4 weeks) (Tt) and (6) a trained group kept euthyroid with T3 (150 ng kg(-1) every other day for 4 weeks) (Te). In each group myosin isoform composition was determined in five muscles, three locomotor muscles: (1) extensor digitorum longus, (2) superficial lateral gastrocnemius, (3) deep medial gastrocnemius, (4) an antigravity muscle, the soleus and (5) a rhytmic respiratory muscle, the crural diaphragm. Different muscles responded in a specific way to variations of the thyroid state and training.

Plasticity of skeletal myosin in endurance-trained rats (I). A quantitative study.

The aim of this study was to quantify modifications in the expression of skeletal myosin light chain (MLC) and myosin heavy chain (MHC) isoforms of five muscles, according to their fiber composition and function, following endurance training in rats. Rodents were assigned randomly to one of two groups: caged sedentary controls (C) or endurance-trained rats (T). In T rats, three out of the four fast and mixed muscles studied exhibited a significant increase in the expression of MLC1s, 1f and 2s and a significant decrease in MLC2f and 3f, the exception being the plantaris muscle. In two out of the four muscles we observed a significant increase in MHCI and IIa, the exception being both gastrocnemii, where the expression of MHCI did not change. In the soleus of T rats, the expression of MLC1s, 2f and 3f decreased significantly, while that of MLC2s increased significantly, compared with those of C rats. The expression of MHCIIa in T rats decreased significantly compared with that of C rats, while the expression of MHCI increased significantly. In all muscles studied, a significant slowing of myosin isoforms was observed after endurance training.

Long-term histological follow-up of genetically modified myoblasts grafted into the brain.

Although primary muscle cells have been used as intracerebral vehicles for transgene expression in the past, data concerning their long-term survival after grafting into the brain, and the reaction of the host tissue to their implantation are lacking. In order to study these aspects, we have implanted, into the brain, primary muscle cells infected ex vivo with recombinant retroviruses carrying the E. coli LacZ gene. The muscle cells were delivered stereotaxically into different areas of the brain of adult rats and the grafts were analyzed up to 105 days after implantation. Intraventricular implantations did not lead to surviving grafts. In contrast, myoblasts developed when they were grafted into gray or white matter regions. They appeared numerous during the first weeks, but decreased dramatically in number over time. Over months, the grafts appeared to fill up with collagen. Astrocytes elaborated a continuous glia limitans surrounding the implant. Blood vessels coming from the host tissue were found within the grafts. The blood-brain barrier was permanently disrupted within the transplants. beta-Galactosidase activity was abundant during the first weeks, but decreased to a very low level subsequently. This decrease paralleled that of the number of muscle cells. In conclusion, myoblasts transplanted into the adult brain survived only temporarily, which implies a transient transgene expression. In addition, before being eliminated, muscle cells were surrounded by a glia limitans, which may limit exchanges with the host tissue. Altogether, these results suggest that intracerebral transplantation of myoblasts may possibly provide a relevant vehicle only for short-term delivery of a gene product.

Effect of increased physical activity on growth and differentiation of regenerating rat soleus muscle.

Our purpose was to determine the effect of physical exercise on growth and differentiation during regeneration of a slow-twitch muscle. Degeneration/regeneration of the left soleus muscles of Wistar female rats was induced by injection of a snake venom. Muscular differentiation was studied by monitoring the sequential expression of the various myosin heavy chain isoforms (MHCs). Rats were assigned to one of two groups: cage sedentary (n = 14) or exercised (n = 16). The exercise programme began 1-day post-injection and the rats ran 1 h/day on a motorized treadmill. Then, 9 and 25 days after venom treatment, the soleus MHC phenotype as determined by immunohistology, electrophoresis and immunoblotting, was studied. At 25 days the expression of MHCs by regenerating soleus was not changed by the increased level of physical activity (P > 0.05). Exercised and sedentary regenerating muscles contained similar numbers of type-I fibres (100% of total fibres), levels of MHC-1 (85.4 and 89.5% of total MHCs), MHC-2a and M/HC-2x/d and their fibres expressed MHC-1 (100% of total fibres) and MHC-2 (45-50%) in the same way. Moreover, the masses of regenerating and nonregenerating soleus were significantly increased by physical exercise (P < 0.02). At 9 days no effect of muscular exercise was found. In conclusion, endurance exercise did not alter differentiation of regenerating soleus. Moreover regenerating soleus can respond to increased physical activity by enhancing its mass in the same way as mature muscle.

[Dystrophin expression in skeletal muscles in endurance-trained hypo-hyperthyroid and growth-hormone treated rats]. / Expression de la dystrophine dans le muscle squelettique du rat entraîné en endurance, hypo-hyperthyroïdien, et traité par l'hormone de croissance.

The aim of this study was to determine the effect of chronic muscular exercise, thyroid status and growth hormone administration on skeletal muscle dystrophin expression. Relative abundance of dystrophin (quantity in arbitrary units/50 micrograms of protein) was measured by immunoblotting and densimometry. Our results indicate that relative abundance of dystrophin in slow-or fast-twicht muscle was not modified by chronic muscular exercise (5 weeks), thyroxine administration (4 weeks), antithyroid drug treatment (6 weeks) or growth hormone administration (6 weeks).

Human skeletal muscle myosin light chains analyzed by immobilized pH gradients during ontogenesis: identification of new phosphorylatable isoforms of light chain 2.

Previous studies using two-dimensional gel electrophoresis have described adult and fetal isoforms of skeletal muscle myosin light chains (MLC). They have also revealed an embryo-specific light chain (LC1emb), apparently absent in most adult skeletal muscles. In order to characterize more thoroughly the MLC family, we have analyzed the MLCs from human skeletal muscle at different developmental stages using a two-dimensional electrophoresis technique with an immobilized pH gradient in the first dimension. The high resolution of this novel technique, resolving components which in isoelectric points are less than or equal to 0.01 pH, combined with sensitive silver staining, has allowed us to identify four phosphorylatable isoforms of MLC2: two slow-myosin light chains (MLC2Sa and b), two fast myosin light chains (MLC2Fa and b), and their phosphorylated counterparts: MLC2SaP and bP, MLC2FaP and bP. The following major modifications during development were observed: (i) The embryonic LC (LC1emb) persists up to at least 26 weeks of fetal life. (ii) The polymorphism of LC2 is already evident at 10 weeks of development but only the nonphosphorylated forms of LC2S and LC2F seem to be present. The LC2Fa form is predominant. As early as 26 weeks of fetal life, the 4 phosphorylated forms are detected. In the adult, LC2Fb is a minor component. (iii) LC3F (fast) is already expressed at an early embryonic stage (10 weeks).

Affinity labeling of myoblast surface proteins with 5'-P-fluorosulfonylbenzoyl adenosine: concomitant inhibition of ectoprotein kinase activity and myoblast fusion.

During in vitro myogenesis, mononucleated myoblasts fuse among themselves to form multinucleated myotubes. We have recently reported for the first time in the literature that a Ca2(+)-dependent ectoprotein kinase is responsible for this process, but we had no direct evidence for the role of extracellular ATP. To investigate whether the cells can fuse or not in the absence of this nucleotide, we used a nucleotide affinity label, fluorosulfonylbenzoyl adenosine (FSBA). We report here its use in detecting the nucleotide-binding sites at the cell surface of intact myoblasts in culture. We demonstrate that FSBA blocks fusion by inhibiting the ectoprotein kinase activity of the cells at sublethal concentrations. Radioactive [14C]SBA is incorporated into seven cell surface proteins and into the 48-kDa protein, among others. This species is specific for fusion-competent myoblasts and is implicated in this process. This is the first time that nucleotide-binding molecular species have been identified at the surface of myoblasts.

Enantiomer resolution in immobilized pH gradient gels via inclusion of a chiral discriminator.

The separation of enantiomeric forms of dansylated amino acids by isoelectric focusing in immobilized pH gradients (IPG) is demonstrated for the first time. Separations occur in a pH 3.0-4.0 IPG interval, in presence of 7Murea, 10% methanol and 60 mM beta-cyclodextrin (CD) as chiral discriminator. It is found that the inclusion complex formed between the D-form and CD has a lower pI than the uncomplexed form (delta pI = 0.05 for DL-Phe and delta pI = 0.025 for DL-Trp); from this, it is calculated that the pK of the tertiary amino group in the dansyl moiety is lowered by 0.1 pH unit in the former case (D-Phe) and by 0.05 in the case of D-Trp (both values referring to 60 mM CD gels). For some racemates (e.g., DL-Phe) the separation mechanism is still operative with CD concentrations as low as 20 mM. In our system 60 mM CD appears to be the solubility limit of CD. As the complex is stable in the electric field for at least 15 h, this separation mechanism could be exploited for purifying large quantities of pure D and L forms from racemates in multicompartment electrolyzers with isoelectric Immobiline membranes.

2-D analysis of human skeletal muscle myosin light chains with immobilized pH gradients.

Myosin light chains (LC) are a low molecular mass fraction non-covalently bound to the heavy chains. They are present in the myosin molecules and exhibit various degrees of polymorphism among the different species. By utilizing a highly-resolving 2-D technique, in narrow immobilized pH gradients, we have compared the LC forms of skeletal muscle in human and rabbit. Our findings: (1) both forms, LC1 and LC3, migrate in the two species with rather similar electrophoretic constants (both in terms of pI and Mr); (2) the LC2 forms of rabbit and humans exhibit the same Mr but quite different pI values, the rabbit forms being more acidic; (3) the chain LC2Sb is resolved into two spots in both rabbit and humans. In the former, the two bands have equal intensity, while in the latter the high pI component is clearly the most abundant.

Nebulin seen in DMD males including one patient with a large DNA deletion encompassing the DMD gene.

The presence of nebulin in a muscle specimen from a patient with Duchenne muscular dystrophy (DMD) due to a large deletion precludes the possibility that this protein is the DMD gene product.

A cell surface phosphoprotein of 48 kDa specific for myoblast fusion.

The data we present here permit us to affirm that a 48 kDa phosphoprotein is the target of extracellular Ca2+ during fusion. It is detected only in fusion-competent L6 myoblasts and not in the fusion-defective spontaneous stable variants we isolated. The phosphorylation of this protein species can be totally inhibited by culturing myoblasts in a medium containing low Ca2+ concentrations (0.250 mM). However, under such conditions myoblasts do not fuse, but withdraw from the cell cycle and accumulate the muscle isoform of creatine kinase (M-CK). The results we have obtained support the following conclusions: (1) in fusion-competent cells, overall Ca2+-dependent phosphorylation of cell surface proteins appears to be necessary, but is not sufficient by itself for myoblast fusion; (2) the phosphorylation of a 48 kDa protein species is required for cell fusion; and (3) the phosphorylation of this 48 kDa protein is independent of other main events of cellular differentiation.

Differential immunoreactivity for Z-DNA in rat myoblast nuclei during their terminal differentiation.

L6 myoblasts in vitro accomplish the process of terminal differentiation from dividing mononucleated cells to quiescent plurinucleated myotubes, synthesizing muscle-specific proteins. They have been tested, using paraformaldehyde and acetic acid fixations and immunocytochemical techniques, for the presence of Z-DNA at different stages: namely after 3, 5 and 8-9 days of culture. The nuclei of the actively dividing 3-day myoblasts were strongly Z-DNA and B-DNA-positive. The inhibition of replication by araC did not diminish the reaction. In the myotubes, the nuclei became Z-DNA-negative but were still B-DNA-positive. In contrast, the nuclei of a non-fusing alpha-amanitin-resistant mutant (Ama102) stayed Z-DNA-positive. These results tend to show that during the process of terminal differentiation Z-DNA either becomes less accessible or is present in undetectable amounts. In circular DNAs, it has been shown that the presence of Z-DNA depends on their negative supercoiling. In addition, the presence of closed superhelical loops of nuclear DNA has been demonstrated in several mammalian cell types; moreover, the density of DNA topological turns in these loops varies during cellular differentiation and malignant transformation. The relationship between these results and ours is discussed.

Spontaneous myoblast fusion is mediated by cell surface Ca2+-dependent protein kinase(s).

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

Metabolic changes in the extracellular matrix during differentiation of myoblasts of the L6 line and of a Myo- non-fusing mutant.

In the present study we have characterized by biochemical and immunochemical methods the changes which take place in collagen, laminin and fibronectin biosynthesis during the differentiation of clonal skeletal myoblasts of the L6 line. Time-course experiments showed that the relative rate of synthesis of collagen increased significantly during the cell-cell contact step of myogenesis and decreased later on. The major collagens synthesized were types I and III, found mainly as soluble precursors in the culture medium. Types IV and V collagens were detected exclusively in the cell layer. The relative amounts of types I and III collagens remained unchanged during myogenesis, while types IV and V collagens increased as the cells of the L6 line fused. In a non-fusing alpha-amanitin-resistant mutant of the L6 line (Ama 102), the rate of collagen synthesis was largely depressed and its rate of degradation was increased as compared with the fusing wild type. The synthesis of laminin was very low in cells of the fusing wild type, but abundant and associated with the cell layer of the Myo- mutant. The appearance of a muscle-specific extracellular matrix is a complex process involving changes in the organization, the biosynthesis and remodelling of its macromolecules of the extracellular matrix.

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.

Solubilization of plasma membranes in anionic, non-ionic and zwitterionic surfactants for iso-dalt analysis: a critical evaluation.

A critical study has been made of the solubilizing properties of anionic, nonionic and zwitterionic surfactants to be used in the first dimension of two-dimensional isoelectric focusing-sodium dodecyl sulphate (IF-SDS) maps. Excess of SDS is a powerful solubilizing agent, but prevents proteins from entering the IF gel. Nonidet P-40 (NP-40)-urea mixtures are mediocre solubilizing agents, but are compatible with the IF dimension. Zwitterionic detergents (zwittergents) appear to exhibit a well balanced solubilizing power and are able to generate sharp two-dimensional maps, with round spots and minimal vertical and horizontal streaking. SB3-12 and SB3-14 appear to have the best solubilizing properties; shorter surfactants (SB3-8) exhibit a poor solubilization efficiency, while longer detergents (SB3-16) bind too strongly to hydrophobic regions in proteins. The random performance of non-ionic detergents has been attributed to their ability to form mixed micelles with the carrier ampholytes used in the IF step: depending on the relative ratio of NP-40 to Ampholines, different types of micelles would be formed, which, when reaching appropriate stoichiometries and charge densities, would mimic the behaviour of natural zwittergents. Acceptable two-dimensional maps can be obtained when the sample is lysed in limiting amounts of SDS (SDS:protein = 1:3), suggesting that excess of free SDS in solution is deleterious to the IF process.

Alterations in glycosylation of plasma membrane proteins during myogenesis.

Highly purified plasma membranes were obtained from cells of the L6 line at three characteristic stages of myogenesis: Actively proliferating cells; post-mitotic, confluent myoblasts which have already aligned; and fused myotubes. Differential glycosylation of the plasma membrane proteins of these cells was detected by staining polyacrylamide gels of the separated components with three lectins of different specificity: Concanavalin A (conA), wheat germ agglutinin (WGA) and phytohemagglutinin (PHA) Els. Four kinds of developmentally regulated changes could be identified. 1. Those which took place only at confluency (160, 150, 90, 85, 60, 43 and 40 kD for conA binding, 190 kD for WGA binding, 190 and 110 kD for PHA Els binding. 2. Those which took place only at fusion (135, 51.5 and 38 kD for conA, 160 and 150 kD for WGA and 150 kD for PHA Els binding). 3. Those where the phenomena initiated at confluency continue during fusion (66.5 and 32 kD for conA and 120 kD for PHA binding). 4. Those where opposite changes take place at confluency and at fusion (48 kD for conA, 180, 98 and 85 kD for PHA binding). These results suggest that most developmentally regulated changes in glycosylation take place during the first cell-cell contact step of myogenesis. Metabolic labelling experiments showed that, on the contrary, only few alterations in the accumulation of plasma membrane proteins take place prior to the main burst of fusion.