DNA-dependent RNA polymerases in skeletal muscle cells differentiating in vitro.

The main classes of RNA polymerase in cultured chick embryo skeletal muscle cells were identified and their levels determined during differentiation in vitro. Cell cultures contained a high proportion of muscle cells (>80%) and exhibited a high degree of fusion (>80%). The levels of RNA polymerases I and II increased by 1.8 and 1.5 times, respectively, from prefusion myoblasts (24 hr) to postfusion myotubes (120 hr). RNA polymerase III, a single peak on DEAE-Sephadex chromatography, was less than 7% of the total activity. The results suggest that the rates of synthesis of the main RNA types, which reportedly decline during myogenesis, are not determined by the relative levels of the main RNA polymerases and are more likely a reflection of chromatin template availability.     

Engineered genetic selection links in vivo protein folding and stability with asparagine-linked glycosylation

Predicting the structural consequences of site-specific glycosylation remains a major challenge due in part to the lack of convenient experimental tools for rapidly determining how glycosylation influences protein folding. To address this shortcoming, we developed a genetic selection that directly links the in vivo folding of asparagine-linked (N-linked) glycoproteins with antibiotic resistance. Using this assay, we identified three known or putative glycoproteins from Campylobacter jejuni (Peb3, CjaA, and Cj0610c) whose folding was significantly affected by N-glycosylation. We also used the genetic selection to isolate a glycoengineered variant of the Escherichia coli colicin E7 immunity protein (Im7) whose intracellular folding and stability were enhanced as a result of N-glycosylation. In addition to monitoring the effect of glycan attachment on protein folding in living cells, this strategy could easily be extended for optimizing protein folding in vivo and engineering glycosylation enzymes, pathways, and hosts for optimal performance. See accompanying commentary by Danielle Tullman-Ercek DOI: 10.1002/biot.201300319     

Organization of connectin/titin filaments in sarcomeres of differentiating chicken skeletal muscle cells

Very long, elastic connectin/titin molecules position the myosin filaments at the center of a sarcomere by linking them to the Z line. The behavior of the connectin filaments during sarcomere formation in differentiating chicken skeletal muscle cells was observed under a fluorescent microscope using the antibodies to the N terminal (located in the Z line), C terminal (M line), and C zone (myosin filament) regions of connectin and was compared to the incorporation of -actinin and myosin into forming sarcomeres. In early stages of differentiating muscle cells, the N terminal region of connectin was incorporated into a stress fiber-like structure (SFLS) together with -actinin to form dots, whereas the C terminal region was diffusely distributed in the cytoplasm. When both the C and N terminal regions formed striations in young myofibrils, the epitope to the C zone of A-band region, that is the center between the A-I junction and the M-line, initially was diffuse in appearance and later formed definite striations. It appears that it took some time for the N and C terminal regions of connectin to form a regular organization in a sarcomere. Thus the two ends of the connectin filaments were first fixed followed by the specific binding of the middle portion onto the myosin filament during sarcomere formation.     

Primary longitudinal adhesion structures: plectin-containing precursors of costameres in differentiating human skeletal muscle cells

Plectin is a high molecular mass protein (ca 530 kDa) that binds actin, intermediate filaments, and microtubules. Mutations of the human plectin gene cause epidermolysis bullosa simplex with muscular dystrophy. In mature human skeletal muscle, plectin is localized between neighboring myofibrils and between myofibrils and the sarcolemma, both at the level of Z-discs. In the present study we have analyzed plectin expression patterns with emphasis on its sarcolemmal localization during human skeletal muscle differentiation in vitro. In myoblasts plectin showed a cytoplasmic intermediate filament-like distribution, whereas in myotubes plectin is also found at the level of the sarcolemma. In particular, in early myotubes a specific plectin isoform colocalizes with the costameric proteins vinculin and beta1D integrin in longitudinally orientated structures which increased in number and longitudinal extension upon further maturation. In mature myotubes processes perpendicular to the parallel system of longitudinal structures became apparent. Subsequent to the occurrence of spontaneous myofibrillar contractions, the number of longitudinal streaks decreased, and plectin and other costameric proteins were found in an orderly cross-striated sarcolemmal lattice overlying myofibrillar Z-discs. Our study demonstrates that plectin is preassembled together with vinculin and beta1D integrin into primary longitudinal adhesion structures. After the occurrence of spontaneous contractions, these structures reorient and mature costameres are assembled.     

Membrane dynamics of differentiating cultured embryonic chick skeletal muscle cells by fluorescence microscopy techniques

Changes in membrane fluidity during myogenesis have been studied by fluorescence microscopy of individual cells growing in monolayer cultures of embryonic chick skeletal muscle cells. Membrane fluidity was determined by the techniques of fluorescence photobleaching recovery (FDR), with the use of a lipidsoluble carbocyanine dye, and by fluorescence depolarization (FD), with perylene used as the lipid probe. The fluidity of myoblast plasma membranes, as determined from FPR measurements in membrane areas above nuclei, increased during the period of myoblast fusion and then returned to its initial level. The membrane fluidity of fibroblasts, also found in these primary cultures, remained constant. The fluidity in specific regions along the length of the myoblast membrane was studied by FD, and it was observed that the extended arms of the myoblast have the highest fluidity on the cell and that the tips at the ends of the arms had the lowest fluidity. However, since the perylene probe used in the FD experiments appeared to label cytoplasmic components, changes in fluidity measured with this probe reflect changes in membrane fluidity as well as in cytoplasmic fluidity. The relative change in each of these compartments cannot yet be ascertained. Tips have specialized surface structures, filopodia and lamellipodia, which may be accompanied by a more immobile membrane as well as a more rigid cytoplasm. Rounded cells, which may also have a more convoluted surface structure, show a lower apparent membrane fluidity than extended cells.     

蛋白激酶C对胰岛素抵抗骨骼肌细胞的影响

目的探讨蛋白激酶C(Protein Kinase C,PKC)在棕榈酸(Palmitic Acid,PA)诱导的骨骼肌细胞胰岛素抵抗(Isulin Resistance,IR)中的作用。方法免疫荧光鉴定原代大鼠骨骼肌细胞,氧化酶-过氧化物酶偶联法(GOD-POD法)检测培养液中葡萄糖浓度。设立对照组、棕榈酸组(PA组)、罗格列酮组(Rosiglitazone,Ros组),每组一分为二,分别加PKC抑制剂白屈莱红碱(Chelerythrine Chloride,CC)与正常培养液作用1h,Western Blot检测PKB及P-Ser473 PKB表达水平。结果 90%以上的细胞-αsarcometric actin免疫荧光染色呈阳性反应,表明培养的细胞为骨骼肌细胞;0.6mmol/L的PA作用24h可诱导骨骼肌细胞产生胰岛素抵抗;PA组与对照组相比P-Ser473 PKB水平显著降低,与本组未加CC相比显著升高。同时,罗格列酮组及本组加CC中P-Ser473PKB水平均高于PA组。结论在PA诱导的骨骼肌细胞IR方面PKC起重要作用,罗格列酮与PKC抑制剂CC均能改善PA引起的IR。     

Geranylgeranylaceton induces heat shock protein 72 in skeletal muscle cells

Effects of an antiulcer drug, geranylgeranylaceton (GGA), and/or heat-stress on 72 kDa heat shock protein (HSP72) expression and protein content in cultured skeletal muscle cells were studied. Mouse skeletal muscle cells (C(2)C(12)) were subjected to either 1) control (cultured at 37 degrees C without GGA), 2) GGA administration (10(-11) - 10(-8) M), 3) heat-stress at 41 degrees C for 60 min, or 4) GGA administration combined with heat-stress. Expression of HSP72 was up-regulated by GGA administration. Heat-stress further enhanced the GGA-related up-regulation of HSP72. Administration of GGA caused an increase of muscular protein content as a dose-dependent manner. Protein synthesis was also stimulated by heat-stress alone in myotubes. It was suggested that GGA stimulates the differentiation of myoblasts and protein synthesis. These observations may also suggest that the administration of GGA could be one of the useful tools to gain muscular mass not only in athletes, but also in patients during rehabilitation.     

A Mucor pusillus mutant defective in asparagine-linked glycosylation.

A Mucor pusillus mutant defective in asparagine-linked glycosylation was found in our stock cultures. This mutant, designated 1116, secreted aspartic proteinase (MPP) in a less-glycosylated form than that secreted by the wild-type strain. Analysis of enzyme susceptibility, lectin binding, and carbohydrate composition indicated that this mutant secreted three glycoforms of MPPs, one of which contained no carbohydrate; the other two had truncated asparagine-linked oligosaccharide chains such as Man0-1GlcNAc2. Further analysis using oligosaccharide processing inhibitors, such as castanospermine, 1-deoxynojirimycin and N-methyldeoxynojirimycin, suggested that MPPs in the mutant were glycosylated through a transfer of the truncated lipid-linked oligosaccharides, Man0-1GlcNAc2, to the MPP protein but not through an aberrant processing. In addition, genetic studies with forced primary heterokaryons indicated that the mutation in strain 1116 was recessive.     

Dystroglycan glycosylation and its role in matrix binding in skeletal muscle

Dystroglycan is an essential component of the dystrophin-glycoprotein complex. Three glycan sequencing studies have identified O-linked mannose chains, including NeuAcalpha 2,3Galbeta 1,4GlcNAcbeta 1,2Manalpha-O, on alpha dystroglycan. Chemical deglycosylation of alpha dystroglycan, antibody blocking studies, and glycan blocking studies all suggest that the O-linked glycans on alpha dystroglycan mediate the binding of extracellular matrix proteins in skeletal muscle. Structural data on laminin G domains and agrin-binding studies also suggest this is the case. Dystroglycan, however, is able to bind proteins via mechanisms that do not involve O-linked glycans. Moreover, laminin and other matrix proteins can bind cell adhesion molecules via their glycan chains. Thus although complex and sometimes not overly convincing, these data suggest that glycosylation plays an important role in dystroglycan binding and function in skeletal muscle.     

Insulin-like growth factor-I induces androgen receptor activation in differentiating C2C12 skeletal muscle cells

The modulating effect of IGF-I on the regulation of AR gene expression and activation in skeletal muscle cells remains poorly understood. In this study, the effects of IGF-I treatment on AR induction and activation in the absence of AR ligands were examined. Differentiating C2C12 cells were treated with different concentrations (0–250 ng/ml) of IGF-I or for various periods of time (0–60 min) of 250 ng/ml IGF-I. Treatment of C2C12 cells with IGF-I resulted in a dose- and time-dependent increase in total AR and phosphorylated AR (Ser 213). IGF-I treatment also led to significantly increased AR mRNA expression when compared with the control. The levels of skeletal α-actin and myogenin mRNA, known target genes of AR, were also significantly upregulated after 5 or 10 min of treatment with IGF-I. Confocal images revealed that IGF-I stimulated nuclear localization of AR in the absence of ligands. In addition, an electrophoretic mobility shift assay indicated that IGF-I stimulated the AR DNA binding activity in a time-dependent manner. The present results suggest that IGF-I stimulates the expression and activation of AR by ligand-independent mechanism in differentiating C2C12 mouse skeletal muscle cells.     

Membrane function in differentiating skeletal muscle cells: I. Kinetic analysis of amino acid transport

Primary cultures of mononucleated myoblasts from 12-day-old chick embryos have a twofold higher rate of α-aminoisobutyric acid (AIB) transport before fusion occurs to form multinucleated myotubes. Several lines of evidence indicate that the uptake of AIB observed in both myoblasts and myotubes is primarily carrier-mediated by a membrane transport system. Increasing the temperature from 24 to 37°C results in a threefold increase in the rate of AIB uptake; both methionine and glycine inhibit AIB uptake by more than 85%; and 2,4-dinitrophenol inhibits AIB uptake by approximately 50%. In addition, the energies of activation (14.5 and 14.0 kcal/mole for myoblasts and myotubes, respectively) are characteristic of carrier-mediated transport. Resolution of AIB uptake into a saturable, carrier-mediated component and a nonsaturable, diffusion component shows that at concentrations of AIB≤1.5 mM over 97% of total AIB uptake is carriermediated in both myoblasts and myotubes. Kinetic analysis of carrier-mediated AIB uptake indicates that myoblasts and myotube membrane carriers have the same affinity for AIB (K_m values = 1.73 and 1.31 mM, respectively). However, the V_max for myoblasts is 23.7 nmole/mg/min while myotubes have a V_max of 12.6 nmole/mg/min. The twofold difference in V_max is shown to be due to a twofold difference in the quantity of membrane transport sites per milligram of protein.     

Primary cultures of cardiac muscle cells as models for investigation of protein glycosylation

Primary cardiac cell cultures of newborn rats containing approximately 50% (by cell number) spontaneously contracting cardiomyocytes were used to study the role of protein N-glycosylation for the binding of dihydropyridine (DHP) to the voltage-dependent L-type calcium channel. This binding is not influenced by the accompanying non-muscle cells.Exposure of the cells up to 6 g/ml of the N-glycosylation inhibitor tunicamycin for a 44 h period resulted in a decrease of the specific DHP binding sites (B_max) to 46.0 ± 17.2% of the untreated control. Similar effects were observed after enzymatic deglycosylation using N-glycosidase F (PNGase F). The results suggest that a posttranslational modification of parts of the cardiac L-type Ca⁺⁺ channel by N-glycosylation is an important determinant for the binding of Ca⁺⁺ antagonists of the DHP-type to the ₁ subunit which itself is not glycosylated. The results suggest a participation of N glycosylation in the assembling of the subunits to the functional channel and/or its turnover. However, a possible effect of tunicamycin on the expression of the Ca channel as an alternative mechanism cannot be excluded.