Systemic ablation of RyR3 alters Ca2+ spark signaling in adult skeletal muscle

Ca2+ sparks are localized intracellular Ca2+ release events from the sarcoplasmic reticulum in muscle cells that result from synchronized opening of ryanodine receptors (RyR). In mammalian skeletal muscle, RyR1 is the predominant isoform present in adult skeletal fibers, while some RyR3 is expressed during development. Functional studies have revealed a differential role for RyR1 and RyR3 in the overall Ca2+ signaling in skeletal muscle, but the contribution of these two isoforms to Ca2+ sparks in adult mammalian skeletal muscle has not been fully examined. When enzyme-disassociated, individual adult skeletal muscle fibers are exposed to an osmotic shock, the resting fiber converts from a quiescent to a highly active Ca2+ release state where Ca2+ sparks appear proximal to the sarcolemmal membrane. These osmotic shock-induced Ca2+ sparks occur in ryr3(-/-) muscle with a spatial distribution similar to that seen in wild type muscle. Kinetic analysis reveals that systemic ablation of RyR3 results in significant changes to the initiation, duration and amplitude of individual Ca2+ sparks in muscle fibers. These changes may reflect the adaptation of the muscle Ca2+ signaling or contractile machinery due to the loss of RyR3 expression in distal tissues, as biochemical assays identify significant changes in expression of myosin heavy chain protein in ryr3(-/-) muscle.     

Caffeine-induced Release of Intracellular Ca2+ from Chinese Hamster Ovary Cells Expressing Skeletal Muscle Ryanodine Receptor : Effects on Full-Length and Carboxyl-Terminal Portion of Ca2+Release Channels

The ryanodine receptor (RyR)/Ca²⁺ release channel is an essential component of excitation–contraction coupling in striated muscle cells. To study the function and regulation of the Ca²⁺ release channel, we tested the effect of caffeine on the full-length and carboxyl-terminal portion of skeletal muscle RyR expressed in a Chinese hamster ovary (CHO) cell line. Caffeine induced openings of the full length RyR channels in a concentration-dependent manner, but it had no effect on the carboxyl-terminal RyR channels. CHO cells expressing the carboxyl-terminal RyR proteins displayed spontaneous changes of intracellular [Ca²⁺]. Unlike the native RyR channels in muscle cells, which display localized Ca²⁺ release events (i.e., “Ca²⁺ sparks” in cardiac muscle and “local release events” in skeletal muscle), CHO cells expressing the full length RyR proteins did not exhibit detectable spontaneous or caffeine-induced local Ca²⁺ release events. Our data suggest that the binding site for caffeine is likely to reside within the amino-terminal portion of RyR, and the localized Ca²⁺ release events observed in muscle cells may involve gating of a group of Ca²⁺ release channels and/or interaction of RyR with muscle-specific proteins.     

Structural and functional properties of ryanodine receptor type 3 in zebrafish tail muscle

The ryanodine receptor (RyR)1 isoform of the sarcoplasmic reticulum (SR) Ca²⁺ release channel is an essential component of all skeletal muscle fibers. RyR1s are detectable as “junctional feet” (JF) in the gap between the SR and the plasmalemma or T-tubules, and they are required for excitation–contraction (EC) coupling and differentiation. A second isoform, RyR3, does not sustain EC coupling and differentiation in the absence of RyR1 and is expressed at highly variable levels. Anatomically, RyR3 expression correlates with the presence of parajunctional feet (PJF), which are located on the sides of the SR junctional cisternae in an arrangement found only in fibers expressing RyR3. In frog muscle fibers, the presence of RyR3 and PJF correlates with the occurrence of Ca²⁺ sparks, which are elementary SR Ca²⁺ release events of the EC coupling machinery. Here, we explored the structural and functional roles of RyR3 by injecting zebrafish (Danio rerio) one-cell stage embryos with a morpholino designed to specifically silence RyR3 expression. In zebrafish larvae at 72 h postfertilization, fast-twitch fibers from wild-type (WT) tail muscles had abundant PJF. Silencing resulted in a drop of the PJF/JF ratio, from 0.79 in WT fibers to 0.03 in the morphants. The frequency with which Ca²⁺ sparks were detected dropped correspondingly, from 0.083 to 0.001 sarcomere⁻¹ s⁻¹. The few Ca²⁺ sparks detected in morphant fibers were smaller in amplitude, duration, and spatial extent compared with those in WT fibers. Despite the almost complete disappearance of PJF and Ca²⁺ sparks in morphant fibers, these fibers looked structurally normal and the swimming behavior of the larvae was not affected. This paper provides important evidence that RyR3 is the main constituent of the PJF and is the main contributor to the SR Ca²⁺ flux underlying Ca²⁺ sparks detected in fully differentiated frog and fish fibers.     

Facilitated Hyperpolarization Signaling in Vascular Smooth Muscle-overexpressing TRIC-A Channels

The TRIC channel subtypes, namely TRIC-A and TRIC-B, are intracellular monovalent cation-specific channels and likely mediate counterion movements to support efficient Ca²⁺ release from the sarco/endoplasmic reticulum. Vascular smooth muscle cells (VSMCs) contain both TRIC subtypes and two Ca²⁺ release mechanisms; incidental opening of ryanodine receptors (RyRs) generates local Ca²⁺ sparks to induce hyperpolarization and relaxation, whereas agonist-induced activation of inositol trisphosphate receptors produces global Ca²⁺ transients causing contraction. Tric-a knock-out mice develop hypertension due to insufficient RyR-mediated Ca²⁺ sparks in VSMCs. Here we describe transgenic mice overexpressing TRIC-A channels under the control of a smooth muscle cell-specific promoter. The transgenic mice developed congenital hypotension. In Tric-a-overexpressing VSMCs from the transgenic mice, the resting membrane potential decreased because RyR-mediated Ca²⁺ sparks were facilitated and cell surface Ca²⁺-dependent K⁺ channels were hyperactivated. Under such hyperpolarized conditions, L-type Ca²⁺ channels were inactivated, and thus, the resting intracellular Ca²⁺ levels were reduced in Tric-a-overexpressing VSMCs. Moreover, Tric-a overexpression impaired inositol trisphosphate-sensitive stores to diminish agonist-induced Ca²⁺ signaling in VSMCs. These altered features likely reduced vascular tonus leading to the hypotensive phenotype. Our Tric-a-transgenic mice together with Tric-a knock-out mice indicate that TRIC-A channel density in VSMCs is responsible for controlling basal blood pressure at the whole-animal level.     

Personal recollections on the discovery of the ryanodine receptors of muscle

The intracellular Ca²⁺ release channels are indispensable molecular machinery in practically all eukaryotic cells of multicellular animals. They serve a key role in cell signaling by way of Ca²⁺ as a second messenger. In response to a signaling event, the channels release Ca²⁺ from intracellular stores. The resulting rise in cytoplasmic Ca²⁺ concentration triggers the cell to carry out its specialized role, after which the intracellular Ca²⁺ concentration must be reduced so that the signaling event can again be repeated. There are two types of intracellular Ca²⁺ release channels, i.e., the ryanodine receptors and the inositol triphosphate receptors. My focus in this minireview is to present a personal account, from the vantage point our laboratory, of the discovery, isolation, and characterization of the ryanodine receptors from mammalian muscle. There are three isoforms: ryanodine receptor 1 (RyR1), first isolated from rabbit fast twitch skeletal muscle; ryanodine receptor 2 (RyR2), first isolated from dog heart; and ryanodine receptor 3 (RyR3), first isolated from bovine diaphragm muscle. The ryanodine receptors are the largest channel structures known. The RyR isoforms are very similar albeit with important differences. Natural mutations in humans in these receptors have already been associated with a number of muscle diseases.     

Ca2+ sparks are initiated by Ca2+ entry in embryonic mouse skeletal muscle and decrease in frequency postnatally

"Spontaneous" Ca²⁺ sparks and ryanodine receptor type 3 (RyR3) expression are readily detected in embryonic mammalian skeletal muscle but not in adult mammalian muscle, which rarely exhibits Ca²⁺ sparks and expresses predominantly RyR1. We have used confocal fluorescence imaging and systematic sampling of enzymatically dissociated single striated muscle fibers containing the Ca²⁺ indicator dye fluo 4 to show that the frequency of spontaneous Ca²⁺ sparks decreases dramatically from embryonic day 18 (E18) to postnatal day 14 (P14) in mouse diaphragm and from P1 to P14 in mouse extensor digitorum longus fibers. In contrast, the relative levels of RyR3 to RyR1 protein remained constant in diaphragm muscles from E18 to P14, indicating that changes in relative levels of RyR isoform expression did not cause the decline in Ca²⁺ spark frequency. E18 diaphragm fibers were used to investigate possible mechanisms underlying spark initiation in embryonic fibers. Spark frequency increased or decreased, respectively, when E18 diaphragm fibers were exposed to 8 or 0 mM Ca²⁺ in the extracellular Ringer solution, with no change in either the average resting fiber fluo 4 fluorescence or the average properties of the sparks. Either CoCl₂ (5 mM) or nifedipine (30 µM) markedly decreased spark frequency in E18 diaphragm fibers. These results indicate that Ca²⁺ sparks may be triggered by locally elevated [Ca²⁺] due to Ca²⁺ influx via dihydropyridine receptor L-type Ca²⁺ channels in embryonic mammalian skeletal muscle. calcium; ryanodine receptor; dihydropyridine receptor; muscle development     

Characterization of Functional TRPV1 Channels in the Sarcoplasmic Reticulum of Mouse Skeletal Muscle

TRPV1 represents a non-selective cation channel activated by capsaicin, acidosis and high temperature. In the central nervous system where TRPV1 is highly expressed, its physiological role in nociception is clearly identified. In skeletal muscle, TRPV1 appears implicated in energy metabolism and exercise endurance. However, how as a Ca²⁺ channel, it contributes to intracellular calcium concentration ([Ca²⁺]_i) maintenance and muscle contraction remains unknown. Here, as in rats, we report that TRPV1 is functionally expressed in mouse skeletal muscle. In contrast to earlier reports, our analysis show TRPV1 presence only at the sarcoplasmic reticulum (SR) membrane (preferably at the longitudinal part) in the proximity of SERCA1 pumps. Using intracellular Ca²⁺ imaging, we directly accessed to the channel functionality in intact FDB mouse fibers. Capsaicin and resiniferatoxin, both agonists as well as high temperature (45°C) elicited an increase in [Ca²⁺]_i. TRPV1-inhibition by capsazepine resulted in a strong inhibition of TRPV1-mediated functional responses and abolished channel activation. Blocking the SR release (with ryanodine or dantrolene) led to a reduced capsaicin-induced Ca²⁺ elevation suggesting that TRPV1 may participate to a secondary SR Ca²⁺ liberation of greater amplitude. In conclusion, our experiments point out that TRPV1 is a functional SR Ca²⁺ leak channel and may crosstalk with RyR1 in adult mouse muscle fibers.     

Calcium signaling in insulin action on striated muscle

Striated muscles (skeletal and cardiac) are major physiological targets of insulin and this hormone triggers complex signaling pathways regulating cell growth and energy metabolism. Insulin increases glucose uptake into muscle cells by stimulating glucose transporter (GLUT4) translocation from intracellular compartments to the cell surface. The canonical insulin-triggered signaling cascade controlling this process is constituted by well-mapped tyrosine, lipid and serine/threonine phosphorylation reactions. In parallel to these signals, recent findings reveal insulin-dependent Ca²⁺ mobilization in skeletal muscle cells and cardiomyocytes. Specifically, insulin activates the sarco-endoplasmic reticulum (SER) channels that release Ca²⁺ into the cytosol i.e., the Ryanodine Receptor (RyR) and the inositol 1,4,5-triphosphate receptor (IP₃R). In skeletal muscle cells, a rapid, insulin-triggered Ca²⁺ release occurs through RyR, that is brought about upon S-glutathionylation of cysteine residues in the channel by reactive oxygen species (ROS) produced by the early activation of the NADPH oxidase (NOX2). In cardiomyocytes insulin induces a fast and transient increase in cytoplasmic [Ca²⁺]_i trough L-type Ca²⁺ channels activation. In both cell types, a relatively slower Ca²⁺ release also occurs through IP₃R activation, and is required for GLUT4 translocation and glucose uptake. The insulin-dependent Ca²⁺ released from IP₃R of skeletal muscle also promotes mitochondrial Ca²⁺ uptake. We review here these actions of insulin on intracellular Ca²⁺ channel activation and their impact on GLUT4 traffic in muscle cells, as well as other implications of insulin-dependent Ca²⁺ release from the SER.     

Two ryanodine receptor isoforms in nonmammalian vertebrate skeletal muscle: possible roles in excitation-contraction coupling and other processes

The ryanodine receptor (RyR) is a Ca²⁺ release channel in the sarcoplasmic reticulum in vertebrate skeletal muscle and plays an important role in excitation–contraction (E–C) coupling. Whereas mammalian skeletal muscle predominantly expresses a single RyR isoform, RyR1, skeletal muscle of many nonmammalian vertebrates expresses equal amounts of two distinct isoforms, α-RyR and β-RyR, which are homologues of mammalian RyR1 and RyR3, respectively. In this review we describe our current understanding of the functions of these two RyR isoforms in nonmammalian vertebrate skeletal muscle. The Ca²⁺ release via the RyR channel can be gated by two distinct modes: depolarization-induced Ca²⁺ release (DICR) and Ca²⁺-induced Ca²⁺ release (CICR). In frog muscle, α-RyR acts as the DICR channel, whereas β-RyR as the CICR channel. However, several lines of evidence suggest that CICR by β-RyR may make only a minor contribution to Ca²⁺ release during E–C coupling. Comparison of frog and mammalian RyR isoforms highlights the marked differences in the patterns of Ca²⁺ release mediated by RyR1 and RyR3 homologues. Interestingly, common features in the Ca²⁺ release patterns are noticed between β-RyR and RyR1. We will discuss possible roles and significance of the two RyR isoforms in E–C coupling and other processes in nonmammalian vertebrate skeletal muscle.     

Characterization of the Calcium-release Channel/Ryanodine Receptor from Zebrafish Skeletal Muscle

Calcium (Ca²⁺)-mediated signaling is fueled by two sources for Ca²⁺: Ca²⁺ can enter through Ca²⁺ channels located in the plasma membrane and can also be released from intracellular stores. In the present study the intracellular Ca²⁺ release channel/ryanodine receptor (RyR) from zebrafish skeletal muscle was characterized. Two RyR isoforms could be identified using immunoblotting and single-channel recordings. Biophysical properties as well as the regulation by modulators of RyR, ryanodine, ruthenium red and caffeine, were measured. Comparison with other RyRs showed that the zebrafish RyRs have features observed with all RyRs described to date and thus, can serve as a model system in future genetic and physiological studies. However, some differences in the biophysical properties were observed. The slope conductance for both isoforms was higher than that of the mammalian RyR type 1 (RyR1) measured with divalent ions. Also, inhibition by millimolar Ca²⁺ concentrations of the RyR isoform that is inhibited by high Ca²⁺ concentrations (teleost α RyR isoform) was attenuated when compared to mammalian RyRs. Due to the widespread expression of RyR these findings have important implications for the interpretation of the role of the RyR in Ca²⁺ signaling when comparing zebrafish with mammalian physiology, especially when analyzing mutations underlying physiological changes in zebrafish. Received: 15 February 2001/Revised: 1 June 2001     

Ca2+-induced Ca2+ Release in Chinese Hamster Ovary (CHO) Cells Co-expressing Dihydropyridine and Ryanodine Receptors

Combined patch-clamp and Fura-2 measurements were performed on chinese hamster ovary (CHO) cells co-expressing two channel proteins involved in skeletal muscle excitation-contraction (E-C) coupling, the ryanodine receptor (RyR)-Ca²⁺ release channel (in the membrane of internal Ca²⁺ stores) and the dihydropyridine receptor (DHPR)-Ca²⁺ channel (in the plasma membrane). To ensure expression of functional L-type Ca²⁺ channels, we expressed α₂, β, and γ DHPR subunits and a chimeric DHPR α₁ subunit in which the putative cytoplasmic loop between repeats II and III is of skeletal origin and the remainder is cardiac. There was no clear indication of skeletal-type coupling between the DHPR and the RyR; depolarization failed to induce a Ca²⁺ transient (CaT) in the absence of extracellular Ca²⁺ ([Ca²⁺]_o). However, in the presence of [Ca²⁺]_o, depolarization evoked CaTs with a bell-shaped voltage dependence. About 30% of the cells tested exhibited two kinetic components: a fast transient increase in intracellular Ca²⁺ concentration ([Ca²⁺]_i) (the first component; reaching 95% of its peak <0.6 s after depolarization) followed by a second increase in [Ca²⁺]_i which lasted for 5–10 s (the second component). Our results suggest that the first component primarily reflected Ca²⁺ influx through Ca²⁺ channels, whereas the second component resulted from Ca²⁺ release through the RyR expressed in the membrane of internal Ca²⁺ stores. However, the onset and the rate of Ca²⁺ release appeared to be much slower than in native cardiac myocytes, despite a similar activation rate of Ca²⁺ current. These results suggest that the skeletal muscle RyR isoform supports Ca²⁺-induced Ca²⁺ release but that the distance between the DHPRs and the RyRs is, on average, much larger in the cotransfected CHO cells than in cardiac myocytes. We conclude that morphological properties of T-tubules and/or proteins other than the DHPR and the RyR are required for functional “close coupling” like that observed in skeletal or cardiac muscle. Nevertheless, some of our results imply that these two channels are potentially able to directly interact with each other.     

New factors contributing to dynamic calcium regulation in the skeletal muscle triad—a crowded place

Skeletal muscle is a highly organized tissue that has to be optimized for fast signalling events conveying electrical excitation to contractile response. The site of electro-chemico-mechanical coupling is the skeletal muscle triad where two membrane systems, the extracellular t-tubules and the intracellular sarcoplasmic reticulum, come into very close contact. Structure fits function here and the signalling proteins DHPR and RyR1 were the first to be discovered to bridge this gap in a conformational coupling arrangement. Since then, however, new proteins and more signalling cascades have been identified just in the last decade, adding more diversity and fine tuning to the regulation of excitation-contraction coupling (ECC) and control over Ca²⁺ store content. The concept of Ca²⁺ entry into working skeletal muscle has become attractive again with the experimental evidence summarized in this review. Store-operated Ca²⁺ entry (SOCE), excitation-coupled Ca²⁺ entry (ECCE), action-potential-activated Ca²⁺ current (APACC), and retrograde EC-coupling (ECC) are new concepts additional to the conventional orthograde ECC; they have provided fascinating new insights into muscle physiology. In this review, we discuss the discovery of these pathways, their potential roles, and the signalling proteins involved that show that the triad may become a crowded place in time.     

Atrial local Ca signaling and inositol 1,4,5-trisphosphate receptors

In atrial myocytes lacking t-tubules, action potential triggers junctional Ca²⁺ releases in the cell periphery, which propagates into the cell interior. The present article describes growing evidence on atrial local Ca²⁺ signaling and on the functions of inositol 1,4,5-trisphosphate receptors (IP₃Rs) in atrial myocytes, and show our new findings on the role of IP₃R subtype in the regulation of spontaneous focal Ca²⁺ releases in the compartmentalized areas of atrial myocytes. The Ca²⁺ sparks, representing focal Ca²⁺ releases from the sarcoplasmic reticulum (SR) through the ryanodine receptor (RyR) clusters, occur most frequently at the peripheral junctions in isolated resting atrial cells. The Ca²⁺ sparks that were darker and longer lasting than peripheral and non-junctional (central) sparks, were found at peri-nuclear sites in rat atrial myocytes. Peri-nuclear sparks occurred more frequently than central sparks. Atrial cells express larger amounts of IP₃Rs compared with ventricular cells and possess significant levels of type 1 IP₃R (IP₃R1) and type 2 IP₃R (IP₃R2). Over the last decade the roles of atrial IP₃R on the enhancement of Ca²⁺-induced Ca²⁺ release and arrhythmic Ca²⁺ releases under hormonal stimulations have been well documented. Using protein knock-down method and confocal Ca²⁺ imaging in conjunction with immunocytochemistry in the adult atrial cell line HL-1, we could demonstrate a role of IP₃R1 in the maintenance of peri-nuclear and non-junctional Ca²⁺ sparks via stimulating a posttranslational organization of RyR clusters.     

Ca2+ sparks and T tubule reorganization in dedifferentiating adult mouse skeletal muscle fibers

Ca⁺ sparks are rare in healthy adult mammalian skeletal muscle but may appear when adult fiber integrity is compromised, and occur in embryonic muscle but decline as the animal develops. Here we used cultured adult mouse flexor digitorum brevis muscle fibers to monitor occurrence of Ca²⁺ sparks during maintenance of adult fiber morphology and during eventual fiber morphological dedifferentiation after various times in culture. Fibers cultured for up to 3 days retain normal morphology and striated appearance. Ca²⁺ sparks were rare in these fibers. At 5–7 days in culture, many of the original muscle fibers exhibit sprouting and loss of striations, as well as the occurrence of spontaneous Ca²⁺ sparks. The average rate of occurrence of Ca²⁺ sparks is >10-fold higher after 5–7 days in culture than in days 1–3. With the use of fibers cultured for 7 days, application of the Ca²⁺ channel blockers Co²⁺ or nifedipine almost completely suppressed the occurrence of Ca²⁺ sparks, as previously shown in embryonic fibers, suggesting that Ca²⁺ sparks may be generated by similar mechanisms in dedifferentiating cultured adult fibers and in embryonic fibers before final differentiation. The sarcomeric disruption observed under transmitted light microscopy in dedifferentiating fibers was accompanied by morphological changes in the transverse (T) tubular system, as observed by fluorescence confocal imaging of both an extracellular marker dye and membrane staining dyes. Changes in T tubule morphology coincided with the appearance of Ca²⁺ sparks, suggesting that Ca²⁺ sparks may either be a signal for, or the result of, disruption of DHPR-ryanodine receptor 1 coupling. calcium ion signaling; muscle remodeling; fluo 4; calcium ion imaging     

Dihydropyridine receptor-ryanodine receptor interactions in skeletal muscle excitation-contraction coupling

Much recent progress has been made in our understanding of the mechanism of sarcoplasmic reticulum Ca²⁺ release in skeletal muscle. Vertebrate skeletal muscle excitation-contraction (E-C) coupling is thought to occur by a mechanical coupling mechanism involving protein-protein interactions that lead to activation of the sarcoplasmic reticulum (SR) ryanodine receptor (RyR)/Ca²⁺ release channel by the voltage-sensing transverse (T–) tubule dihydropyridine receptor (DHPR)/Ca²⁺ channel. In a subsequent step, the released Ca²⁺ amplify SR Ca²⁺ release by activating release channels that are not linked to the DHPR. Experiments with mutant muscle cells have indicated that skeletal muscle specific DHPR and RyR isoforms are required for skeletal muscle E-C coupling. A direct functional and structural interaction between a DHPR-derived peptide and the RyR has been described. The interaction between the DHPR and RyR may be stabilized by other proteins such as triadin (a SR junctional protein) and modulated by phosphorylation of the DHPR.     

Ryanodine Receptor Luminal Ca Regulation: Swapping Calsequestrin and Channel Isoforms

Sarcoplasmic reticulum (SR) Ca²⁺ release in striated muscle is mediated by a multiprotein complex that includes the ryanodine receptor (RyR) Ca²⁺ channel and the intra-SR Ca²⁺ buffering protein calsequestrin (CSQ). Besides its buffering role, CSQ is thought to regulate RyR channel function. Here, CSQ-dependent luminal Ca²⁺ regulation of skeletal (RyR1) and cardiac (RyR2) channels is explored. Skeletal (CSQ1) or cardiac (CSQ2) calsequestrin were systematically added to the luminal side of single RyR1 or RyR2 channels. The luminal Ca²⁺ dependence of open probability (Po) over the physiologically relevant range (0.05-1 mM Ca²⁺) was defined for each of the four RyR/CSQ isoform pairings. We found that the luminal Ca²⁺ sensitivity of single RyR2 channels was substantial when either CSQ isoform was present. In contrast, no significant luminal Ca²⁺ sensitivity of single RyR1 channels was detected in the presence of either CSQ isoform. We conclude that CSQ-dependent luminal Ca²⁺ regulation of single RyR2 channels lacks CSQ isoform specificity, and that CSQ-dependent luminal Ca²⁺ regulation in skeletal muscle likely plays a relatively minor (if any) role in regulating the RyR1 channel activity, indicating that the chief role of CSQ1 in this tissue is as an intra-SR Ca²⁺ buffer.     

Calcium-dependent facilitation and graded deactivation of store-operated calcium entry in fetal skeletal muscle

Activation of store-operated Ca²⁺ entry (SOCE) into the cytoplasm requires retrograde signaling from the intracellular Ca²⁺ release machinery, a process that involves an intimate interaction between protein components on the intracellular and cell surface membranes. The cellular machinery that governs the Ca²⁺ movement in muscle cells is developmentally regulated, reflecting maturation of the junctional membrane structure as well as coordinated expression of related Ca²⁺ signaling molecules. Here we demonstrate the existence of SOCE in freshly isolated skeletal muscle cells obtained from embryonic days 15 and 16 of the mouse embryo, a critical stage of muscle development. SOCE in the fetal muscle deactivates incrementally with the uptake of Ca²⁺ into the sarcoplasmic reticulum (SR). A novel Ca²⁺-dependent facilitation of SOCE is observed in cells transiently exposed to high cytosolic Ca²⁺. Our data suggest that cytosolic Ca²⁺ can facilitate SOCE whereas SR luminal Ca²⁺ can deactivate SOCE in the fetal skeletal muscle. This cooperative mechanism of SOCE regulation by Ca²⁺ ions not only enables tight control of SOCE by the SR membrane, but also provides an efficient mechanism of extracellular Ca²⁺ entry in response to physiological demand. Such Ca²⁺ signaling mechanism would likely contribute to contraction and development of the fetal skeletal muscle.     

Hyperactive Intracellular Calcium Signaling Associated with Localized Mitochondrial Defects in Skeletal Muscle of an Animal Model of Amyotrophic Lateral Sclerosis

Amyotrophic lateral sclerosis (ALS) is a fatal neuromuscular disorder characterized by degeneration of motor neurons and atrophy of skeletal muscle. Mutations in the superoxide dismutase (SOD1) gene are linked to 20% cases of inherited ALS. Mitochondrial dysfunction has been implicated in the pathogenic process, but how it contributes to muscle degeneration of ALS is not known. Here we identify a specific deficit in the cellular physiology of skeletal muscle derived from an ALS mouse model (G93A) with transgenic overexpression of the human SOD1^G93A mutant. The G93A skeletal muscle fibers display localized loss of mitochondrial inner membrane potential in fiber segments near the neuromuscular junction. These defects occur in young G93A mice prior to disease onset. Fiber segments with depolarized mitochondria show greater osmotic stress-induced Ca²⁺ release activity, which can include propagating Ca²⁺ waves. These Ca²⁺ waves are confined to regions of depolarized mitochondria and stop propagating shortly upon entering the regions of normal, polarized mitochondria. Uncoupling of mitochondrial membrane potential with FCCP or inhibition of mitochondrial Ca²⁺ uptake by Ru360 lead to cell-wide propagation of such Ca²⁺ release events. Our data reveal that mitochondria regulate Ca²⁺ signaling in skeletal muscle, and loss of this capacity may contribute to the progression of muscle atrophy in ALS.     

Functional Coupling of Ryanodine Receptors to KCa Channels in Smooth Muscle Cells from Rat Cerebral Arteries

The relationship between Ca²⁺ release (“Ca²⁺ sparks”) through ryanodine-sensitive Ca²⁺ release channels in the sarcoplasmic reticulum and K_Ca channels was examined in smooth muscle cells from rat cerebral arteries. Whole cell potassium currents at physiological membrane potentials (−40 mV) and intracellular Ca²⁺ were measured simultaneously, using the perforated patch clamp technique and a laser two-dimensional (x–y) scanning confocal microscope and the fluorescent Ca²⁺ indicator, fluo-3. Virtually all (96%) detectable Ca²⁺ sparks were associated with the activation of a spontaneous transient outward current (STOC) through K_Ca channels. A small number of sparks (5 of 128) were associated with currents smaller than 6 pA (mean amplitude, 4.7 pA, at −40 mV). Approximately 41% of STOCs occurred without a detectable Ca²⁺ spark. The amplitudes of the Ca²⁺ sparks correlated with the amplitudes of the STOCs (regression coefficient 0.8; P < 0.05). The half time of decay of Ca²⁺ sparks (56 ms) was longer than the associated STOCs (9 ms). The mean amplitude of the STOCs, which were associated with Ca²⁺ sparks, was 33 pA at −40 mV. The mean amplitude of the “sparkless” STOCs was smaller, 16 pA. The very significant increase in K_Ca channel open probability (>10⁴-fold) during a Ca²⁺ spark is consistent with local Ca²⁺ during a spark being in the order of 1–100 μM. Therefore, the increase in fractional fluorescence (F/F_o) measured during a Ca²⁺ spark (mean 2.04 F/F_o or ∼310 nM Ca²⁺) appears to significantly underestimate the local Ca²⁺ that activates K_Ca channels. These results indicate that the majority of ryanodine receptors that cause Ca²⁺ sparks are functionally coupled to K_Ca channels in the surface membrane, providing direct support for the idea that Ca²⁺ sparks cause STOCs.