Inositol trisphosphate and excitation-contraction coupling in skeletal muscle

The role of inositol trisphosphate as a chemical messenger in excitation-contraction coupling is discussed, both in terms of positive and negative results. The evidence presented includes experiments on the effect of inositol trisphosphate in intact and skinned fibers, in calcium release from isolated sarcoplasmic reticulum vesicles, in activation of single calcium release channels incorporated in planar bilayers, and biochemical experiments that have established the presence of all the intermediate steps involved in the metabolism of phosphoinositides, both in intact muscle and in isolated membranes. From these results, it is clear that a role for inositol triphosphate in skeletal muscle function is highly likely; whether this molecule is the physiological messenger in excitation-contraction coupling remains to be established.     

Support for a trimeric collar of myosin binding protein C in cardiac and fast skeletal muscle, but not in slow skeletal muscle

Myosin-binding protein C (MyBPC) is proposed to take on a trimeric collar arrangement around the thick filament backbone in cardiac muscle, based on interactions between cardiac MyBPC domains C5 and C8. We have now determined, using yeast two-hybrid and in vitro binding assays, that the C5:C8 interaction is not dependent on the 28-residue cardiac-specific insert in C5. Furthermore, an interaction of similar affinity occurs between domains C5 and C8 of fast skeletal muscle MyBPC, but not between these domains of the slow skeletal muscle protein. These data have implications for the role and quaternary structure of MyBPC in skeletal muscle.     

The role of stem cells in skeletal and cardiac muscle repair.

In postnatal muscle, skeletal muscle precursors (myoblasts) can be derived from satellite cells (reserve cells located on the surface of mature myofibers) or from cells lying beyond the myofiber, e.g., interstitial connective tissue or bone marrow. Both of these classes of cells may have stem cell properties. In addition, the heretical idea that post-mitotic myonuclei lying within mature myofibers might be able to re-form myoblasts or stem cells is examined and related to recent observations for similar post-mitotic cardiomyocytes. In adult hearts (which previously were not considered capable of repair), the role of replicating endogenous cardiomyocytes and the recruitment of other (stem) cells into cardiomyocytes for new cardiac muscle formation has recently attracted much attention. The relative contribution of these various sources of precursor cells in postnatal muscles and the factors that may enhance stem cell participation in the formation of new skeletal and cardiac muscle in vivo are the focus of this review. We concluded that, although many endogenous cell types can be converted to skeletal muscle, the contribution of non-myogenic cells to the formation of new postnatal skeletal muscle in vivo appears to be negligible. Whether the recruitment of such cells to the myogenic lineage can be significantly enhanced by specific inducers and the appropriate microenvironment is a current topic of intense interest. However, dermal fibroblasts appear promising as a realistic alternative source of exogenous myoblasts for transplantation purposes. For heart muscle, experiments showing the participation of bone marrow-derived stem cells and endothelial cells in the repair of damaged cardiac muscle are encouraging.     

Regulation of cardiac gap junction channel permeability and conductance by several phosphorylating conditions

Short term (15 min) effects of activators of protein kinase A (PKA), PKC and PKG on cardiac macroscopic (g_j) and single channel (_j) gap junctional conductances were studied in pairs of neonatal rat cardiomyocytes. Under dual whole-cell voltage-clamp, PKC activation by 100 nM TPA increased g_j by 16 ± 2% (mean ± S.E.M, n=9), 1.5 mM of the PKG activator 8-bromo-cGMP (8Br-cGMP) decreased g_j by 26 ± 2% (n=4), whereas 1.5 mM of the PKA activator 8Br-cAMP did not affect g_j (1 ± 5%, n=11). Single cardiac gap junction channel events, resolved in the presence of heptanol, indicated two _j sizes of 20 pS and 40–45 pS. Under control conditions, the larger events were most frequently observed. Whereas 8Br-cAMP did not change this distribution, TPA or 8Br-cGMP shifted the _j distribution to the lower sizes. Diffusion of 6-carboxyfluorescein (6-CF), a gap junction permeant tracer, from the injected cell to neighboring cells was studied on small clusters of neonatal rat cardiomyocytes. Under control conditions, 6-CF labeled 8.4 ± 0.4 cells (mean ± S.E.M, n=31). Whereas 8Br-cAMP did not change the extent of dye transfer (8.1 ± 0.5 cells, n=10), TPA restricted the diffusion of 6-CF to 2.2 ± 0.2 cells (n=30) and 8Br-cGMP to 3.5 ± 0.3 cells (n=10). This suggests that permeability and single channel conductance of Cx43 gap junction channels are parallel related. Altogether, these results point to the differential modulation of electrical and metabolic coupling of cardiac cells by various phosphorylating conditions.     

心肌细胞／胶原复合体移植心梗大鼠梗死周边区的电偶联网络变化

目的应用免疫组化技术和电生理技术记录心肌细胞／胶原复合体对心梗大鼠梗死周边区的有效不应期（ERP）及缝隙连接蛋白43（Cx43）改变,探讨梗死周边区的电偶联网络变化。方法将成年SD大鼠随机分组：假手术组、模型组、移植组。后2组制作心肌梗死动物模型,假手术组仅开胸,不结扎冠状动脉,移植组移植心肌细胞与胶原材料复合组织。结果①左室ERP变化：与假手术组相比,心梗组梗死周边区ERP显著延长（P〈0．01）;移植组梗死周边区ERP延长,但较心梗阻ERP缩短,差异无显著性（P〉0．01）。②Cx43免疫组化结果：移植组Cx43阳性蛋白表达高于心梗组。结论移植的心肌细胞／胶原复合体移植可改善大鼠心肌梗死周边区缝隙连接电偶联网络,进而调控心肌细胞／胶原复合体与宿主心肌同步收缩。     

Feet,bridges, and pillars in triad junctions of mammalian skeletal muscle: Their possible relationship to calcium buffers in terminal cisternae and T-tubules and to excitation-contraction coupling

Summary The structure of the triad junction was examined in thin sections of mammalian fast-twitch skeletal muscle. The aims of the experiments were twofold: first, to examine relationships between the contents of the junctional gap and the terminal cisternae that could be significant in excitation-contraction coupling and, second, to look for structures in the transverse tubules that could support a calcium buffer system. Procedures known to stabilize cytoskeletal elements were used in an attempt to retain the original structure. Feet, pillars and bridges were often seen side by side in the same junction. In one such junction, the average center-to-center spacing between four bridges was 30.9±1.7 nm and between five foot-like structures was 29.2±1.4 nm. The subunit structure of the feet could be seen in many sections. The lumen of the terminal cisternae was filled with a tetragonal network of calsequestrin which formed parallel strands near the junctional membrane, in register with the feet. The strands overlay the area occupied by rods seen in freeze-fracture replicas of terminal cisterna membrane. The contents of the transverse tubules were aggregated into bands, or tethers, which extended across the short axis of the tubule at regular intervals of about 30 nm. The tethers consisted of flattened discs, stacked across the long axis of the tubule, aligned with the junctional feet. Lanthanum staining of the tethers indicated cationic binding sites that could buffer luminal calcium ion concentration in the vicinity of the voltage sensor for contraction. It is suggested (i) that the control of calcium concentration near the voltage sensor is necessary for normal activation, (ii) that feet, pillars and bridges are different images of a spanning structure, and (iii) that the regular alignment of tethers, feet and calsequestrin is functionally significant in excitation-contraction coupling.     

Cryopreservation of mitochondria and mitochondrial function in cardiac and skeletal muscle fibers

Long-term preservation of muscle mitochondria for consequent functional analysis is an important and still unresolved challenge in the clinical study of metabolic diseases and in the basic research of mitochondrial physiology. We here present a method for cryopreservation of mitochondria in various muscle types including human biopsies. Mitochondrial function was analyzed after freeze-thawing permeabilized muscle fibers using glycerol and dimethyl sulfoxide as cryoprotectant. Using optimal freeze-thawing conditions, high rates of adenosine 5(')-diphosphate-stimulated respiration and high respiratory control were observed, showing intactness of mitochondrial respiratory function after cryopreservation. Measurement of adenosine 5(')-triphosphate (ATP) formation showed normal rates of ATP synthesis and ATP/O ratios. Intactness of the outer mitochondrial membrane and functional coupling between mitochondrial creatine kinase and oxidative phosphorylation were verified by respiratory cytochrome c and creatine tests. Simultaneous confocal imaging of mitochondrial flavoproteins and nicotinamide adenine dinucleotide revealed normal intracellular arrangement and metabolic responses of mitochondria after freeze-thawing. The method therefore permits, after freezing and long-term storage of muscle samples, mitochondrial function to be estimated and energy metabolism to be monitored in situ. This will significantly expand the scope for screening and exchange of human biopsy samples between research centers, thus providing a new basis for functional analysis of mitochondrial defects in various diseases.     

Effects of internal Na and external K concentrations on Na/K coupling of Na,K-pump in frog skeletal muscle

Summary To clarify the dependency of the Na/K coupling of the Na,K-pump on internal Na and external K concentrations in skeletal muscle, the ouabain-induced change in membrane potential, the ouabain-induced change in Na efflux and the membrane resistance were measured at various internal Na and external K concentrations in bullfrog sartorius muscle.Upon raising the internal Na concentration from 6 mmol/kg muscle water to 20 mmol/kg muscle water, the magnitude of the ouabain-induced change in membrane potential increased about eightfold and the magnitude of the ouabain-induced change in Na efflux increased about fivefold while the membrane resistance was not significantly changed. As the external K concentration increased from 1 to 10mm, the magnitude of the ouabain-induced change in membrane potential decreased (1/5.5 fold), while the magnitude of the ouabain-induced change in Na efflux increased (about 1.5-fold). The membrane resistance decreased upon raising the external K concentration from 1 to 10mm (1/2-fold). These observations imply that the values of the Na/K coupling of the Na,K-pump increases upon raising the internal Na concentration and decreases upon raising the external K concentration.     

Protein secretion from mouse skeletal muscle: coupling of increased exocytotic and endocytotic activities in denervated muscle

The secretion of proteins labelled by incorporation of radioactive amino acids was studied in innervated and 10 to 13-day-denervated mouse skeletal muscle. The secretion of ³H-leucine-labelled proteins, expressed per mg muscle wet weight, increased after denervation, and the kinetics of the secretory process was also altered in denervated muscle. Separation of secreted ³⁵S-methionine-labelled proteins by sodium dodecyl sulphate polyacrylamide gel electrophoresis followed by autoradiography revealed some denervation-induced alterations in the pattern of secreted proteins. The secretion from both innervated and denervated muscle was highly temperature sensitive and was reversibly inhibited by brefeldin A, a drug that blocks forward membrane transport from the endoplasmic reticulum/Golgi apparatus. This drug was also found to inhibit the uptake of fluorescein isothiocyanate-labelled dextran in denervated muscle but had no effect on the endocytotic activity of innervated muscle. This lends support to the hypothesis that the increased endocytotic activity in denervated muscle is coupled to a high secretory activity.Abbreviations BF A Brefeldin A - dpm Disintegrations per minute - EDL extensor digitorum longus - FITC fluorescein isothiocyanate - LDH lactate dehydrogenase - SDS-P AGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis - TCA trichloroacetic acid     

Molecular interactions of STAC proteins with skeletal muscle dihydropyridine receptor and excitation‐contraction coupling

Excitation‐contraction coupling (ECC) is the physiological process in which an electrical signal originating from the central nervous system is converted into muscle contraction. In skeletal muscle tissue, the key step in the molecular mechanism of ECC initiated by the muscle action potential is the cooperation between two Ca²⁺ channels, dihydropyridine receptor (DHPR; voltage‐dependent L‐type calcium channel) and ryanodine receptor 1 (RyR1). These two channels were originally postulated to communicate with each other via direct mechanical interactions; however, the molecular details of this cooperation have remained ambiguous. Recently, it has been proposed that one or more supporting proteins are in fact required for communication of DHPR with RyR1 during the ECC process. One such protein that is increasingly believed to play a role in this interaction is the SH3 and cysteine‐rich domain‐containing protein 3 (STAC3), which has been proposed to bind a cytosolic portion of the DHPR α_1S subunit known as the II–III loop. In this work, we present direct evidence for an interaction between a small peptide sequence of the II–III loop and several residues within the SH3 domains of STAC3 as well as the neuronal isoform STAC2. Differences in this interaction between STAC3 and STAC2 suggest that STAC3 possesses distinct biophysical features that are potentially important for its physiological interactions with the II–III loop. Therefore, this work demonstrates an isoform‐specific interaction between STAC3 and the II–III loop of DHPR and provides novel insights into a putative molecular mechanism behind this association in the skeletal muscle ECC process.     

The relative position of RyR feet and DHPR tetrads in skeletal muscle

In skeletal muscle, L-type calcium channels (or dihydropyridine receptors, DHPRs) are coupled functionally to the calcium release channels of the sarcoplasmic reticulum (or ryanodine receptors, RyRs) within specialized structures called calcium release units (CRUs). The functional linkage requires a specific positioning of four DHPRs in correspondence of the four identical subunits of a single RyR type 1. Four DHPRs linked to the four binding sites of the RyR1 cytoplasmic domain (or foot), define the corners of a square, constituting a tetrad. RyRs self-assemble into ordered arrays and by associating with them, DHPRs also assemble into ordered arrays. The approximate location of the four DHPRs relative to the four identical subunits of a RyR-foot can be predicted on the basis of the relative position of tetrads and feet within the arrays. However, until recently one vital piece of information has been lacking: the orientation of the two arrays relative to one another. In this work we have defined the relative orientation of the RyR and DHPR arrays by directly superimposing replicas of rotary shadowed images of rows of feet, obtained from isolated SR vesicles, and replicas of tetrad arrays obtained by freeze-fracture. If the orientation for the two sets of images is carefully maintained, the superimposition provides specific constraints on the DHPR-RyR relative position.     

Cooperative interactions between the contractile proteins of cardiac and skeletal muscle.

The calcium activation of the ATPase (ATP phosphohydrolase, EC 3.6.1.3) activity of cardiac actomyosin reconstituted from bovine cardiac myosin and a complex of actin-tropomyosin-troponin extracted from bovine cardiac muscle at 37 degrees C was studied and compared with similar proteins from rabbit fast skeletal muscle. The proteins of the actin complex were identified by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. Half-maximal activation of the cardiac actomyosin was seen at a calcium concentration of 1.2 +/- 0.002 (S.E. of mean) muM. A hybridized reconstituted actomyosin made with cardiac myosin and the actin-tropomyosin-troponin complex extracted from rabbit skeletal muscle was also activated by calcium but the half-maximal value was shifted to 0.65 +/- 0.02 (S.E. of mean) muM Ca2+. Homologous rabbit skeletal actomyosin showed half-maximal activation at 0.90 +/- 0.01 (S.E. of mean) muM Ca2+ and the value for a hybridized actomyosin made with rabbit skeletal myosin and the actin-complex from cardiac muscle was found at 1.4 +/- 0.03 (S.E. of mean) muM Ca2+ concentration. Kinetic analysis of the Ca2+ activated ATPase activity of reconstituted bovine cardiac actomyosin indicated some degree of cooperativity with respect to calcium. Double reciprocal plots of reconstituted actomyosins made with bovine cardiac actin complex were curvilinear and significantly different than those of reconstituted actomyosins made with the rabbit fast skeletal actin complex. The Ca2+-dependent cooperativity was of a mixed type as determined from Hill plots for homologous reconstituted bovine cardiac and rabbit fast skeletal actomyosin. The results show that cooperative interactions in reconstituted actomyosins were greater when the actin-tropomyosin-troponin complex was derived from cardiac than skeletal muscle.     

The pore region of the skeletal muscle ryanodine receptor is a primary locus for excitation-contraction uncoupling in central core disease

Human central core disease (CCD) is caused by mutations/deletions in the gene that encodes the skeletal muscle ryanodine receptor (RyR1). Previous studies have shown that CCD mutations in the NH2-terminal region of RyR1 lead to the formation of leaky SR Ca2+ release channels when expressed in myotubes derived from RyR1-knockout (dyspedic) mice, whereas a COOH-terminal mutant (I4897T) results in channels that are not leaky to Ca2+ but lack depolarization-induced Ca2+ release (termed excitation-contraction [EC] uncoupling). We show here that store depletion resulting from NH2-terminal (Y523S) and COOH-terminal (Y4795C) leaky CCD mutant release channels is eliminated after incorporation of the I4897T mutation into the channel (Y523S/I4897T and Y4795C/I4897T). In spite of normal SR Ca2+ content, myotubes expressing the double mutants lacked voltage-gated Ca2+ release and thus exhibited an EC uncoupling phenotype similar to that of I4897T-expressing myotubes. We also show that dyspedic myotubes expressing each of seven recently identified CCD mutations located in exon 102 of the RyR1 gene (G4890R, R4892W, I4897T, G4898E, G4898R, A4905V, R4913G) behave as EC-uncoupled release channels. Interestingly, voltage-gated Ca2+ release was nearly abolished (reduced approximately 90%) while caffeine-induced Ca2+ release was only marginally reduced in R4892W-expressing myotubes, indicating that this mutation preferentially disrupts voltage-sensor activation of release. These data demonstrate that CCD mutations in exon 102 disrupt release channel permeation to Ca2+ during EC coupling and that this region represents a primary molecular locus for EC uncoupling in CCD.     

Influence of ryanodine receptor agonist and antagonist on development of potassium contracture in phasic (twitch) and tonic fibers of frog skeletal muscle

We compared the influence of external calcium and the inhibitor (dantrolene) and activator (4-chloro-m-cresol) of ryanodine-sensitive Ca channels of the sarcoplasmic reticulum on the characteristics of potassium contracture in phasic and tonic frog skeletal muscle fibers. The duration of contracture in tonic fibers, as contrasted to the phasic ones, is not limited by the presence of Ca²⁺. The tonic contractile response is virtually indifferent to dantrolene and is much less sensitive to chlorocresol than the phasic one (1 mM vs. 0.25 mM). In phasic fibers, the K⁺ contracture on the chlorocresol background is quite similar in amplitude and dynamics to that in control, whereas tonic fibers exhibit response summation without relaxation upon removal of excessive K⁺. One can suggest that in phasic fibers the Ca²⁺ influx can directly create a level sufficient to sustain contraction, while in tonic fibers its effect is mediated by Ca-dependent activation of the beta isoform of the ryanodine-sensitive channel.     

Transgenic and tissue culture analyses of the muscle creatine kinase enhancer Trex control element in skeletal and cardiac muscle indicate differences in gene expression between muscle types

The muscle creatine kinase (MCK) gene is expressed at high levels only in differentiated skeletal and cardiac muscle. The activity of the cloned enhancer–promoter has previously been shown to be dependent on the Trex element which is specifically bound by a yet unidentified nuclear factor, TrexBF. We have further characterized the function of the Trex site by comparing wild-type and Trex-mutated MCK transgenes in five mouse skeletal muscles: quadriceps, extensor digitorum longus (EDL), soleus, diaphragm, and distal tongue, as well as in heart ventricular muscle. Several types of statistical analysis including analysis of variance (ANOVA) and rank sum tests were used to compare expression between muscle types and between constructs. Upon mutation of the Trex site, median transgene expression levels decreased 3- to 120-fold in the muscles examined, with statistically significant differences in all muscles except the EDL. Expression in the largely slow soleus muscle was more affected than in the EDL, and expression in the distal tongue and diaphragm muscles was affected more than in soleus. Median expression of the transgene in ventricle decreased about 18-fold upon Trex mutation. Transfections into neonatal rat myocardiocytes confirmed the importance of the Trex site for MCK enhancer activity in heart muscle, but the effect is larger in transgenic mice than in cultured cells.     

Implication of connexins 40 and 43 in functional coupling between mouse cardiac fibroblasts in primary culture

Cardiac fibroblasts contribute to the structure and function of the myocardium. However their involvement in electrophysiological processes remains unclear; particularly in pathological situations when they proliferate and develop fibrosis. We have identified the connexins involved in gap junction channels between fibroblasts from adult mouse heart and characterized their functional coupling. RT-PCR and Western blotting results show that mRNA and proteins of connexin40 and connexin43 are expressed in cultured cardiac fibroblasts, while Cx45 is not detected. Analysis of gap junctional communications established by these connexins with the gap-FRAP technique demonstrates that fibroblasts are functionally coupled. The time constant of permeability, k, calculated from the fluorescence recovery curves between cell pairs is 0.066 ± 0.005 min^− 1 (n = 65). Diffusion analysis of Lucifer Yellow through gap junction channels with the scrape-loading method demonstrates that when they are completely confluent, a majority of fibroblasts are coupled forming an interconnecting network over a distance of several hundred micrometers. These data show that cardiac fibroblasts express connexin40 and connexin43 which are able to establish functional communications through homo and/or heterotypic junctions to form an extensive coupled cell network. It should then be interesting to study the conditions to improve efficiency of this coupling in pathological conditions.     

Calcium indicators and calcium signalling in skeletal muscle fibres during excitation–contraction coupling

During excitation–contraction coupling in skeletal muscle, calcium ions are released into the myoplasm by the sarcoplasmic reticulum (SR) in response to depolarization of the fibre’s exterior membranes. Ca²⁺ then diffuses to the thin filaments, where Ca²⁺ binds to the Ca²⁺ regulatory sites on troponin to activate muscle contraction. Quantitative studies of these events in intact muscle preparations have relied heavily on Ca²⁺-indicator dyes to measure the change in the spatially-averaged myoplasmic free Ca²⁺ concentration (Δ[Ca²⁺]) that results from the release of SR Ca²⁺. In normal fibres stimulated by an action potential, Δ[Ca²⁺] is large and brief, requiring that an accurate measurement of Δ[Ca²⁺] be made with a low-affinity rapidly-responding indicator. Some low-affinity Ca²⁺ indicators monitor Δ[Ca²⁺] much more accurately than others, however, as reviewed here in measurements in frog twitch fibres with sixteen low-affinity indicators. This article also examines measurements and simulations of Δ[Ca²⁺] in mouse fast-twitch fibres. The simulations use a multi-compartment model of the sarcomere that takes into account Ca²⁺’s release from the SR, its diffusion and binding within the myoplasm, and its re-sequestration by the SR Ca²⁺ pump. The simulations are quantitatively consistent with the measurements and appear to provide a satisfactory picture of the underlying Ca²⁺ movements.