Rescue of excitation-contraction coupling in dysgenic muscle by addition of fibroblasts in vitro

Muscular dysgenesis (mdg) in mice causes the failure of excitation-contraction (E-C) coupling in skeletal muscle. Cultured dysgenic muscle fails to contract upon depolarization, lacks typical muscle ultrastructure, including normal triads, and lacks functional voltage-dependent slow calcium channels. We show that normal rodent fibroblasts and 3T3 fibroblasts "rescue" dysgenic myotubes, reestablishing contractions (i.e., E-C coupling), normal ultrastructure, and functional slow calcium channels. These results support the finding that the expression of the slow calcium channel is affected in the mdg mutation and that this protein is essential for E-C coupling. Additionally, fibroblast rescue provides a system for examining the mechanisms of heterotypic cellular influence on cell function.     

Muscular dysgenesis in mice: a model system for studying excitation-contraction coupling

Muscular dysgenesis (mdg) is a lethal autosomal, recessive mutation of mice. Skeletal muscle from dysgenic mice is paralyzed due to the failure of excitation-contraction (E-C) coupling. Considerable evidence indicates that this failure results from the absence of a specific gene product, the alpha 1 subunit of the skeletal muscle receptor for dihydropyridine calcium channel modifiers. This dihydropyridine receptor is hypothesized to function in E-C coupling of normal skeletal muscle as the voltage sensor that triggers calcium release from the sarcoplasmic reticulum and thereby causes contraction. The skeletal muscle dihydropyridine receptor is also postulated to function as the ion channel responsible for a slowly activating, dihydropyridine-sensitive calcium current (Islow). Dysgenic skeletal muscle lacks Islow but expresses, at low levels, a distinctly different dihydropyridine-sensitive calcium current (Idys). The channel protein underlying Idys is incapable of serving as a voltage sensor for E-C coupling. Studies using dysgenic skeletal muscle have provided significant insight into the role of dihydropyridine receptors in E-C coupling.     

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.     

Excitation-contraction uncoupling in the developing skeletal muscle of the muscular dysgenesis mouse embryo

The muscular dysgenesis recessive autosomal mutation is characterized by a total lack of muscular contraction and a myofibrillar non-organization. Many abnormalities involved in the excitation-contraction coupling are found in mdg/mdg myotubes: 1) the internal structural organization of the membrane coupling between the sarcoplasmic reticulum (SR) and the transverse (T)-tubule forming the triadic association is defective: the triad number is decreased in the muscle and there are a lack of periodic densities between the SR and T-tubule apposed membranes. 2) the voltage-dependent Ca2+ channel contents, identified by binding with the specific blocker PN 200-110, are decreased. The two fast (30 ms) and slow (100 ms) Ca2+ currents present in normal myotubes are absent in mdg/mdg myotubes in vitro. 3) the Ca2+-dependent K+ conductance triggering an action potential followed by a long lasting after hyperpolarization (ahp) is absent in mdg/mdg myotubes. This indicates a lack of the free intracellular Ca2+ increased by the action potential. These results suggest that: 1) the lack of differentiated triadic junctions is directly correlated with very low amounts of voltage-dependent Ca2+ channels; 2) the low amount of Ca2+ channels results directly in decreased Ca2+ currents; 3) the decreased Ca2+ currents are the consequence of the low intracellular Ca2+ concentration which is not sufficient to trigger a contraction. However, the addition of normal motoneurones to mdg/mdg myotubes in culture induces, few days later, an increase in Ca2+ currents.     

Creatine phosphokinase activity in dysgenic (mdg/mdg) mouse muscle

The specific activity of creatine phosphokinase (CPK) was measured in the muscle of mdg/mdg and control embryos of 14-18 days' gestation. CPK specific activity values were similar in mutant and normal embryos at the earliest stages examined (14-15 days). However, after 15 1/2 days, the specific activity of the enzyme in the mdg/mdg embryos was approximately 50% lower than in the controls. The dysgenic and normal muscle extracts exhibited comparable stability after storage at -85 C. CPK activity levels in the muscle of adult heterozygotes (+/mdg) and wild-type (+/+) controls were found to be statistically identical. The findings suggest that the mdg mutation does not have a primary or direct effect on CPK activity.     

Disease expression in +-/+- ----mdg/mdg mouse chimeras: evidence for an extramuscular component in the pathogenesis of both dysgenic abnormal diaphragm innervation and skeletal muscle 16 S acetylcholinesterase deficiency

Homozygous mdg/mdg mice die at birth and express a syndrome of abnormalities, the most striking of which is a gross failure of skeletal muscle development. Recently, additional abnormalities in the development of nerve-muscle relationships have been recognized; in particular, on muscle fibers within the diaphragm, motor end plates are inappropriately dispersed and, in all muscles, there is a paucity of the 16 S form of acetylcholinesterase (AChE). These abnormalities could result entirely as secondary consequences of the primary muscle defect or from expression of the mdg defect in additional cell types, e.g., motor neurons. To determine if the muscle genotype alone is responsible for these defects in dysgenic mice, chimeras composed of both dysgenic and normal cells have been investigated. Different glucosephosphate isomerase variants existed in the mdg/mdg and normal cells comprising these chimeras and the mutant, normal, or mosaic genotypes of chimera diaphragm and skeletal muscle was estimated by measuring the relative proportions of each isozyme. In two chimeras, the diaphragm innervation pattern was revealed by AChE cytochemistry and in both, discrete regions of abnormally dispersed and normally restricted motor end-plate zones were observed. No correlation between these patterns of innervation and the assessed genotype of the muscle fibers existing in each area was observed. The relative 16 S AChE content in the limbs of four chimeras was found to range from 2.5 to 42.0%. Here also, no correlation between 16 S AChE content and the muscle genotype was observed. The results of these investigations are not consistent with a model of mdg/mdg pathogenesis in which only the skeletal muscle is primarily affected; an extramuscular deficiency responsible for at least part of the full mdg/mdg syndrome is therefore suggested.     

Formation of triads without the dihydropyridine receptor alpha subunits in cell lines from dysgenic skeletal muscle

Muscular dysgenesis (mdg/mdg), a mutation of the skeletal muscle dihydropyridine receptor (DHPR) alpha 1 subunit, has served as a model to study the functions of the DHPR in excitation-contraction coupling and its role in triad formation. We have investigated the question of whether the lack of the DHPR in dysgenic skeletal muscle results in a failure of triad formation, using cell lines (GLT and NLT) derived from dysgenic (mdg/mdg) and normal (+/+) muscle, respectively. The lines were generated by transfection of myoblasts with a plasmid encoding a Large T antigen. Both cell lines express muscle-specific proteins and begin organization of sarcomeres as demonstrated by immunocytochemistry. Similar to primary cultures, dysgenic (GLT) myoblasts show a higher incidence of cell fusion than their normal counterparts (NLT). NLT myotubes develop spontaneous contractile activity, and fluorescent Ca2+ recordings show Ca2+ release in response to depolarization. In contrast, GLTs show neither spontaneous nor depolarization-induced Ca2+ transients, but do release Ca2+ from the sarcoplasmic reticulum (SR) in response to caffeine. Despite normal transverse tubule (T-tubule) formation, GLT myotubes lack the alpha 1 subunit of the skeletal muscle DHPR, and the alpha 2 subunit is mistargeted. Nevertheless, the ryanodine receptor (RyR) frequently develops its normal, clustered organization in the absence of both DHPR alpha subunits in the T-tubules. In EM, these RyR clusters correspond to T-tubule/SR junctions with regularly spaced feet. These findings provide conclusive evidence that interactions between the DHPR and RyR are not involved in the formation of triad junctions or in the normal organization of the RyR in the junctional SR.     

Unusual organization of desmin intermediate filaments in muscular dysgenesis and TTX-treated myotubes

Cytoskeletal intermediate filaments were studied in muscular dysgenesis (mdg) and tetrodotoxin-treated inactive mouse embryo muscle cultures during myofibrillogenesis. Both muscular dysgenesis and tetrodotoxin-treated muscles are characterized in vitro by a total lack of contractile activity and an abnormal development of myofibrils. We studied the organization of the microtubule and intermediate filament networks with immunofluorescence, using anti-tubulin, anti-vimentin, and anti-desmin antibodies during normal and mdg/mdg myogenesis in vitro. Mdg/mdg myotubes present a heterogeneous microtubule network with scattered areas of decreased microtubule density. At the myoblast stage, cells expressed both vimentin and desmin. After fusion only desmin expression is revealed. In mutant myotubes the desmin network remains in a diffuse position and does not reorganize itself transversely, as it does during normal myogenesis. The absence of a mature organization of the desmin network in mdg/mdg myotubes is accompanied by a lack of organization of myofibrils. The role of muscle activity in the organization of myofibrils and desmin filaments was tested in two ways: (i) mdg/mdg myotubes were rendered active by coculturing with normal spinal cord cells, and (ii) normal myotubes were treated with tetrodotoxin (TTX) to suppress contractions. Mdg/mdg innervated myotubes showed cross-striated myofibrils, whereas desmin filaments remained diffuse. TTX-treated myotubes possessed disorganized myofibrils and a very unusual pattern of distribution of desmin: intensively stained desmin aggregates were superimposed upon the diffuse network. We conclude, on the basis of these results, that myofibrillar organization does not directly involve intermediate filaments but does need contractile activity.     

Abnormal enwrapment of intramuscular axons by distal Schwann cells with defective basal lamina in the muscular dysgenic mouse embryo

In the muscular dysgenic (mdg/mdg) mouse embryo, both muscle and nerve are affected early during embryogenesis, from Embryonic Day 13 (E13). We now find that the mutation affects not only the degree of differentiation of the muscle and the pattern of motor innervation but also the relationship between Schwann cell and axon. We studied the sciatic nerve of normal and mdg/mdg embryos between E13 and E18 at the ultrastructural level. We found that in mdg/mdg nerve, (1) Schwann cells do not totally enwrap the growing axons in their most distal part, close to the growth cone, and (2) the terminal Schwann cells do not correctly surround the nerve endings and seal the corresponding synaptic contacts. Moreover, both types of mutant Schwann cell lack a normal electron-dense basal lamina. We found that there is an excess of axons relative to the Schwann cell population in the intramuscular portions of the mdg/mdg sciatic nerve. Our observations point toward a possible defect of the mechanism of migration and maturation of Schwann cells. Such a defect may in turn affect primarily or secondarily the mutual influences between Schwann cell and axon and lead to some or all of the major abnormalities observed in the mdg/mdg neuromuscular system, namely, multifocal polyinnervation, immature axon-myotube contacts, and abnormal T-tubule-sarcoplasmic reticulum junctions.     

Ca2+ signaling in microdomains: Homer1 mediates the interaction between RyR2 and Cav1.2 to regulate excitation-contraction coupling

Excitation-contraction (E-C) coupling and Ca(2+)-induced Ca(2+) release in smooth and cardiac muscles is mediated by the L-type Ca(2+) channel isoform Ca(v)1.2 and the ryanodine receptor isoform RyR2. Although physical coupling between Ca(v)1.1 and RyR1 in skeletal muscle is well established, it is generally assumed that Ca(v)1.2 and RyR2 do not directly communicate either passively or dynamically during E-C coupling. In the present work, we re-examined this assumption by studying E-C coupling in the detrusor muscle of wild type and Homer1(-/-) mice and by demonstrating a Homer1-mediated dynamic interaction between Ca(v)1.2 and RyR2 using the split green fluorescent protein technique. Deletion of Homer1 in mice (but not of Homer2 or Homer3) resulted in impaired urinary bladder function, which was associated with higher sensitivity of the detrusor muscle to muscarinic stimulation and membrane depolarization. This was not due to an altered expression or function of RyR2 and Ca(v)1.2. Most notably, expression of Ca(v)1.2 and RyR2 tagged with the complementary C- and N-terminal halves of green fluorescent protein and in the presence and absence of Homer1 isoforms revealed that H1a and H1b/c reciprocally modulates a dynamic interaction between Ca(v)1.2 and RyR2 to regulate the intensity of Ca(2+)-induced Ca(2+) release and its dependence on membrane depolarization. These findings define the molecular basis of a "two-state" model of E-C coupling by Ca(v)1.2 and RyR2. In one state, Ca(v)1.2 couples to RyR2 by H1b/c, which results in reduced responsiveness to membrane depolarization and in the other state H1a uncouples Ca(v)1.2 and RyR2 to enhance responsiveness to membrane depolarization. These findings reveal an unexpected and novel mode of interaction and communication between Ca(v)1.2 and RyR2 with important implications for the regulation of smooth and possibly cardiac muscle E-C coupling.     

Voltage clamp methods for the study of membrane currents and SR Ca(2+) release in adult skeletal muscle fibres

Skeletal muscle excitation-contraction (E-C)(1) coupling is a process composed of multiple sequential stages, by which an action potential triggers sarcoplasmic reticulum (SR)(2) Ca(2+) release and subsequent contractile activation. The various steps in the E-C coupling process in skeletal muscle can be studied using different techniques. The simultaneous recordings of sarcolemmal electrical signals and the accompanying elevation in myoplasmic Ca(2+), due to depolarization-initiated SR Ca(2+) release in skeletal muscle fibres, have been useful to obtain a better understanding of muscle function. In studying the origin and mechanism of voltage dependency of E-C coupling a variety of different techniques have been used to control the voltage in adult skeletal fibres. Pioneering work in muscles isolated from amphibians or crustaceans used microelectrodes or 'high resistance gap' techniques to manipulate the voltage in the muscle fibres. The development of the patch clamp technique and its variant, the whole-cell clamp configuration that facilitates the manipulation of the intracellular environment, allowed the use of the voltage clamp techniques in different cell types, including skeletal muscle fibres. The aim of this article is to present an historical perspective of the voltage clamp methods used to study skeletal muscle E-C coupling as well as to describe the current status of using the whole-cell patch clamp technique in studies in which the electrical and Ca(2+) signalling properties of mouse skeletal muscle membranes are being investigated.     

Elimination by necrosis,not apoptosis,of embryonic extraocular muscles in the<Emphasis Type="Italic"> muscular dysgenesis</Emphasis> mutant of the mouse

Muscular dysgenesis (mdg) in the mouse is a loss-of-function mutation of the skeletal muscle isoform of the voltage-sensor Ca²⁺ channel of skeletal muscle (DHP receptor alpha1 subunit, Cchl1a3, Chr1), which is essential for excitation-contraction coupling. Affected individuals (genotype mdg/mdg, phenotype MDG) are unable to breathe and die perinatally. We introduce here extraocular muscles in the study of MDG myopathy and show that, despite their developmental origin from head placodes, they are affected like trunk and limb muscles. MDG myotubes in situ are eliminated by necrosis, not apoptosis.The study was supported by the Deutsche Forschungsgemeinschaft, SFB 223 C03, E02     

Discoupling of excitation-contraction processes by urea treatment of frog skeletal muscle

On exposure (E) of frog semitendinosus muscle to 400 mmol/l urea (U) in sodium chloride Ringer's solution, the tension development to isoK+ solutions decreased, while in choline chloride Ringer it increased. On quick removal (R) of urea, always a block of excitation-contraction (E-C) coupling occurred accompanied by transient or persistent swelling of fibres and a similar but definite decrease of their resting membrane potential (Fig. 2). Muscle contraction could be elicited by caffeine even after UER-treatment but then only the slow tension increase (second phase of normal caffeine contraction) occurred (Fig. 3a). The fast tension increase to caffeine (first phase) could be restored if after UER-treatment 5 mmol/l mannitol (Fig. 3b), a 20 min treatment with choline chloride (Fig. 4a) or sodium isethionate (Fig. 4b) Ringer's solution of double osmolarity were applied. Caffeine contraction could not be elicited when sodium chloride Ringer's solution of double osmolarity was used under similar conditions (Fig. 5). E-C block to isoK+ solution persisted in all these experiments. E-C coupling could partially be restored by short treatment of muscle with caffeine (Figs 6a, b).     

Functional studies of Ca2+ channels from plasmalemma and sarcoplasmic reticulum membranes in muscle cells

Physiological and biochemical studies (channel characteristics, intracellular Ca2+ determinations and, channel purification, cloning and expression) of the different components involved in the regulation of intercellular Ca2+ have provided new information about their specific role. Recent information favors a major role for plasmalemma Ca2+ channels in E-C coupling of cardiac muscle, while a major role for sarcoplasmic reticulum Ca2+ release channels (ryanodine receptors) is proposed for E-C coupling of skeletal muscle. In smooth muscle, both plasmalemma and sarcoplasmic reticulum (IP3 receptors) Ca2+ channels are involved in E-C coupling. These studies will be comparatively discussed for skeletal, cardiac and smooth muscle cells.     

Muscle fibers from dysgenic mouse in vivo lack a surface component of peripheral couplings.

We have studied the structure of developing normal and dysgenic (mdg/mdg) mouse muscle fibers in vivo, with special attention to the components of the junctions between the sarcoplasmic reticulum and either the surface membrane or the transverse tubules. Triads and dyads are rare in dysgenic muscle fibers, but have apparently normal disposition of feet and calsequestrin. Peripheral couplings in normal developing muscle fibers have junctional tetrads in their surface membrane in association with the junctional feet. Muscle fibers in dysgenic mice lack junctional tetrads. This provides indirect evidence for the identification of the components of junctional tetrads with dihydropyridine receptors, which are known to be absent in dysgenic muscle fibers.     

Immuno-proteomic approach to excitation--contraction coupling in skeletal and cardiac muscle: molecular insights revealed by the mitsugumins

A comprehensive understanding of excitation-contraction (E-C) coupling in skeletal and cardiac muscle requires that all the major components of the Ca(2+) release machinery be resolved. We utilized a unique immuno-proteomic approach to generate a monoclonal antibody library that targets proteins localized to the skeletal muscle triad junction, which provides a structural context to allow efficient E-C coupling. Screening of this library has identified several mitsugumins (MG); proteins that can be localized to the triad junction in mammalian skeletal muscle. Many of these proteins, including MG29 and junctophilin, are important components in maintaining the structural integrity of the triad junction. Other triad proteins, such as calumin, play a more direct role in regulation of muscle Ca(2+) homeostasis. We have recently identified a family of trimeric intracellular cation-selective (TRIC) channels that allow for K(+) movement into the endoplasmic or sarcoplasmic reticulum to counter a portion of the transient negative charge produced by Ca(2+) release into the cytosol. Further study of TRIC channel function and other novel mitsugumins will increase our understanding of E-C coupling and Ca(2+) homoeostasis in muscle physiology and pathophysiology.     

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.     

Contractions of dysgenic skeletal muscle triggered by a potentiated, endogenous calcium current

The dihydropyridine (DHP) receptor of normal skeletal muscle is hypothesized to function as the voltage sensor for excitation-contraction (E-C) coupling, and also as the calcium channel underlying a slowly activating, DHP-sensitive current (termed ICa-s). Skeletal muscle from mice with muscular dysgenesis lacks both E-C coupling and ICa-s. However, dysgenic skeletal muscle does express a small DHP-sensitive calcium current (termed ICa-dvs) which is kinetically and pharmacologically distinct from ICa-s. We have examined the ability of ICa-dys, or the DHP receptor underlying it, to couple depolarization and contraction. Under most conditions ICa-dys is small (approximately 1 pA/pF) and dysgenic myotubes do not contract in response to sarcolemmal depolarization. However, in the combined presence of the DHP agonist Bay K 8644 (1 microM) and elevated external calcium (10 mM), ICa-dys is strongly potentiated and some dysgenic myotubes contract in response to direct electrical stimulation. These contractions are blocked by removing external calcium, by adding 0.5 mM cadmium to the bath, or by replacing Bay K 8644 with the DHP antagonist (+)-PN 200-110. Only myotubes having a density of ICa-dys greater than approximately 4 pA/pF produce detectible contractions, and the strength of contraction is positively correlated with the density of ICa-dys. Thus, unlike the contractions of normal myotubes, the contractions of dysgenic myotubes require calcium entry. These results demonstrate that the DHP receptor underlying ICa-dys is unable to function as a "voltage sensor" that directly couples membrane depolarization to calcium release from the sarcoplasmic reticulum.     

Long-lasting muscle fatigue: partial disruption of excitation-contraction coupling by elevated cytosolic Ca2+ concentration during contractions

The repeated elevation of cytosolic Ca²⁺ concentration ([Ca²⁺]_i) above resting levels during contractile activity has been associated with long-lasting muscle fatigue. The mechanism underlying this fatigue appears to involve elevated [Ca²⁺]_i levels that induce disruption of the excitation-contraction (E-C) coupling process at the triad junction. Unclear, however, are which aspects of the activity-related [Ca²⁺]_i changes are responsible for the deleterious effects, in particular whether they depend primarily on the peak [Ca²⁺]_i reached locally at particular sites or on the temporal summation of the increased [Ca²⁺] in the cytoplasm as a whole. In this study, we used mechanically skinned fibers from rat extensor digitorum longus muscle, in which the normal E-C coupling process remains intact. The [Ca²⁺]_i was raised either by applying a set elevated [Ca²⁺] throughout the fiber or by using action potential stimulation to induce the release of sarcoplasmic reticulum Ca²⁺ by the normal E-C coupling system with or without augmentation by caffeine or buffering with BAPTA. Herein we show that elevating [Ca²⁺]_i in the physiological range of 2–20 µM irreversibly disrupts E-C coupling in a concentration-dependent manner but requires exposure for a relatively long time (1–3 min) to cause substantial uncoupling. The effectiveness of Ca²⁺ released via the endogenous system in disrupting E-C coupling indicates that the relatively high [Ca²⁺]_i attained close to the release site at the triad junction is a more important factor than the increase in bulk [Ca²⁺]_i. Our results suggest that during prolonged vigorous activity, the many repeated episodes of relatively high triadic [Ca²⁺] can disrupt E-C coupling and lead to long-lasting fatigue. skeletal muscle; low-frequency fatigue; ryanodine receptor; skinned fiber