Ca2+ influx through alpha1S DHPR may play a role in regulating Ca2+ release from RyR1 in skeletal muscle

Skeletal muscle fiber types differ in their contents of total phosphate, which includes inorganic phosphate (P_i) and high-energy organic pools of ATP and phosphocreatine (PCr). At steady state, uptake of P_i into the cell must equal the rate of efflux, which is expected to be a function of intracellular P_i concentration. We measured ³²P-labeled P_i uptake rates in different muscle fiber types to determine whether they are proportional to cellular P_i content. P_i uptake rates in isolated, perfused rat hindlimb muscles were linear over time and highest in soleus (2.42 ± 0.17 µmol·g^–1·h^–1), lower in red gastrocnemius (1.31 ± 0.11 µmol·g^–1·h^–1), and lowest in white gastrocnemius (0.49 ± 0.06 µmol·g^–1·h^–1). Reasonably similar rates were obtained in vivo. P_i uptake rates at plasma P_i concentrations of 0.3–1.7 mM confirm that the P_i uptake process is nearly saturated at normal plasma P_i levels. P_i uptake rate correlated with cellular P_i content (r = 0.99) but varied inversely with total phosphate content. Sodium-phosphate cotransporter (PiT-1) protein expression in soleus and red gastrocnemius were similar to each other and seven- to eightfold greater than PiT-1 expression in white gastrocnemius. That the PiT-1 expression pattern did not match the pattern of P_i uptake across fiber types implies that other factors are involved in regulating P_i uptake in skeletal muscle. Furthermore, fractional turnover of the cellular P_i pool (0.67, 0.57, and 0.33 h^–1 in soleus, red gastrocnemius, and white gastrocnemius, respectively) varies among fiber types, indicating differential management of intracellular P_i, likely due to differences in resistance to P_i efflux from the fiber. inorganic phosphate; sodium-inorganic phosphate transporters; PiT-2; inorganic phosphate efflux     

RyR3 amplifies RyR1-mediated Ca(2+)-induced Ca(2+) release in neonatal mammalian skeletal muscle

The neonatal mammalian skeletal muscle contains both type 1 and type 3 ryanodine receptors (RyR1 and RyR3) located in the sarcoplasmic reticulum membrane. An allosteric interaction between RyR1 and dihydropyridine receptors located in the plasma membrane mediates voltage-induced Ca(2+) release (VICR) from the sarcoplasmic reticulum. RyR3, which disappears in adult muscle, is not involved in VICR, and the role of the transiently expressed RyR3 remains elusive. Here we demonstrate that RyR1 participates in both VICR and Ca(2+)-induced Ca(2+) release (CICR) and that RyR3 amplifies RyR1-mediated CICR in neonatal skeletal muscle. Confocal measurements of intracellular Ca(2+) in primary cultured mouse skeletal myotubes reveal active sites of Ca(2+) release caused by peripheral coupling between dihydropyridine receptors and RyR1. In myotubes lacking RyR3, the peripheral VICR component is unaffected, and RyR1s alone are able to support inward CICR propagation in most cells at an average speed of approximately 190 microm/s. With the co-presence of RyR1 and RyR3 in wild-type cells, unmitigated radial CICR propagates at 2,440 microm/s. Because neonatal skeletal muscle lacks a well developed transverse tubule system, the RyR3 reinforcement of CICR seems to ensure a robust, uniform, and synchronous activation of Ca(2+) release throughout the cell body. Such functional interplay between RyR1 and RyR3 can serve important roles in Ca(2+) signaling of cell differentiation and muscle contraction.     

Expression levels of RyR1 and RyR3 control resting free Ca2+ in skeletal muscle

To better understand the role of the transient expression of ryanodine receptor (RyR) type 3 (RyR3) on Ca²⁺ homeostasis during the development of skeletal muscle, we have analyzed the effect of expression levels of RyR3 and RyR1 on the overall physiology of cultured myotubes and muscle fibers. Dyspedic myotubes were infected with RyR1 or RyR3 containing virions at 0.2, 0.4, 1.0, and 4.0 moieties of infection (MOI), and analysis of their pattern of expression, caffeine sensitivity, and resting free Ca²⁺ concentration ([Ca²⁺]_r) was performed. Although increased MOI resulted in increased expression of each receptor isoform, it did not significantly affect the immunopattern of RyRs or the expression levels of calsequestrin, triadin, or FKBP-12. Interestingly, myotubes expressing RyR3 always had significantly higher [Ca²⁺]_r and lower caffeine EC₅₀ than did cells expressing RyR1. Although some of the increased sensitivity of RyR3 to caffeine could be attributed to the higher [Ca²⁺]_r in RyR3-expressing cells, studies of [³H]ryanodine binding demonstrated intrinsic differences in caffeine sensitivity between RyR1 and RyR3. Tibialis anterior (TA) muscle fibers at different stages of postnatal development exhibited a transient increase in [Ca²⁺]_r coordinately with their level of RyR3 expression. Similarly, adult soleus fibers, which also express RyR3, had higher [Ca²⁺]_r than did adult TA fibers, which exclusively express RyR1. These data show that in skeletal muscle, RyR3 increases [Ca²⁺]_r more than RyR1 does at any expression level. These data suggest that the coexpression of RyR1 and RyR3 at different levels may constitute a novel mechanism by which to regulate [Ca²⁺]_r in skeletal muscle. ryanodine receptor; calcium release; ryanodine binding; muscle fibers     

Ca2+ release through ryanodine receptors regulates skeletal muscle L-type Ca2+ channel expression

Skeletal muscle obtained from mice that lack the type 1 ryanodine receptor (RyR-1), termed dyspedic mice, exhibit a 2-fold reduction in the number of dihydropyridine binding sites (DHPRs) compared with skeletal muscle obtained from wild-type mice (Buck, E. D., Nguyen, H. T., Pessah, I. N., and Allen, P. D. (1997) J. Biol. Chem. 272, 7360-7367 and Fleig, A., Takeshima, H., and Penner, R. (1996) J. Physiol. (Lond.) 496, 339-345). To probe the role of RyR-1 in influencing L-type Ca(2+) channel (L-channel) expression, we have monitored functional L-channel expression in the sarcolemma using the whole-cell patch clamp technique in normal, dyspedic, and RyR-1-expressing dyspedic myotubes. Our results indicate that dyspedic myotubes exhibit a 45% reduction in maximum immobilization-resistant charge movement (Q(max)) and a 90% reduction in peak Ca(2+) current density. Calcium current density was significantly increased in dyspedic myotubes 3 days after injection of cDNA encoding either wild-type RyR-1 or E4032A, a mutant RyR-1 that is unable to restore robust voltage-activated release of Ca(2+) from the sarcoplasmic reticulum (SR) following expression in dyspedic myotubes (O'Brien, J. J., Allen, P. D., Beam, K., and Chen, S. R. W. (1999) Biophys. J. 76, A302 (abstr.)). The increase in L-current density 3 days after expression of either RyR-1 or E4032A occurred in the absence of a change in Q(max). However, Q(max) was increased 85% 6 days after injection of dyspedic myotubes with cDNA encoding the wild-type RyR-1 but not E4032A. Because normal and dyspedic myotubes exhibited a similar density of T-type Ca(2+) current (T-current), the presence of RyR-1 does not appear to cause a general overall increase in protein synthesis. Thus, long-term expression of L-channels in skeletal myotubes is promoted by Ca(2+) released through RyRs occurring either spontaneously or during excitation-contraction coupling.     

DHPR activation underlies SR Ca2+ release induced by osmotic stress in isolated rat skeletal muscle fibers

Changes in skeletal muscle volume induce localized sarcoplasmic reticulum (SR) Ca²⁺ release (LCR) events, which are sustained for many minutes, suggesting a possible signaling role in plasticity or pathology. However, the mechanism by which cell volume influences SR Ca²⁺ release is uncertain. In the present study, rat flexor digitorum brevis fibers were superfused with isoosmotic Tyrode''s solution before exposure to either hyperosmotic (404 mOsm) or hypoosmotic (254 mOsm) solutions, and the effects on cell volume, membrane potential (E_m), and intracellular Ca²⁺ ([Ca²⁺]_i) were determined. To allow comparison with previous studies, solutions were made hyperosmotic by the addition of sugars or divalent cations, or they were made hypoosmotic by reducing [NaCl]_o. All hyperosmotic solutions induced a sustained decrease in cell volume, which was accompanied by membrane depolarization (by 14–18 mV; n = 40) and SR Ca²⁺ release. However, sugar solutions caused a global increase in [Ca²⁺]_i, whereas solutions made hyperosmotic by the addition of divalent cations only induced LCR. Decreasing osmolarity induced an increase in cell volume and a negative shift in E_m (by 15.04 ± 1.85 mV; n = 8), whereas [Ca²⁺]_i was unaffected. However, on return to the isoosmotic solution, restoration of cell volume and E_m was associated with LCR. Both global and localized SR Ca²⁺ release were abolished by the dihydropyridine receptor inhibitor nifedipine by sustained depolarization of the sarcolemmal or by the addition of the ryanodine receptor 1 inhibitor tetracaine. Inhibitors of the Na-K-2Cl (NKCC) cotransporter markedly inhibited the depolarization associated with hyperosmotic shrinkage and the associated SR Ca²⁺ release. These findings suggest (1) that the depolarization that accompanies a decrease in cell volume is the primary event leading to SR Ca²⁺ release, and (2) that volume-dependent regulation of the NKCC cotransporter contributes to the observed changes in E_m. The differing effects of the osmotic agents can be explained by the screening of fixed charges by divalent ions.     

Measurement of RyR permeability reveals a role of calsequestrin in termination of SR Ca(2+) release in skeletal muscle

The mechanisms that terminate Ca(2+) release from the sarcoplasmic reticulum are not fully understood. D4cpv-Casq1 (Sztretye et al. 2011. J. Gen. Physiol. doi:10.1085/jgp.201010591) was used in mouse skeletal muscle cells under voltage clamp to measure free Ca(2+) concentration inside the sarcoplasmic reticulum (SR), [Ca(2+)](SR), simultaneously with that in the cytosol, [Ca(2+)](c), during the response to long-lasting depolarization of the plasma membrane. The ratio of Ca(2+) release flux (derived from [Ca(2+)](c)(t)) over the gradient that drives it (essentially equal to [Ca(2+)](SR)) provided directly, for the first time, a dynamic measure of the permeability to Ca(2+) of the releasing SR membrane. During maximal depolarization, flux rapidly rises to a peak and then decays. Before 0.5 s, [Ca(2+)](SR) stabilized at ～35% of its resting level; depletion was therefore incomplete. By 0.4 s of depolarization, the measured permeability decayed to ～10% of maximum, indicating ryanodine receptor channel closure. Inactivation of the t tubule voltage sensor was immeasurably small by this time and thus not a significant factor in channel closure. In cells of mice null for Casq1, permeability did not decrease in the same way, indicating that calsequestrin (Casq) is essential in the mechanism of channel closure and termination of Ca(2+) release. The absence of this mechanism explains why the total amount of calcium releasable by depolarization is not greatly reduced in Casq-null muscle (Royer et al. 2010. J. Gen. Physiol. doi:10.1085/jgp.201010454). When the fast buffer BAPTA was introduced in the cytosol, release flux became more intense, and the SR emptied earlier. The consequent reduction in permeability accelerated as well, reaching comparable decay at earlier times but comparable levels of depletion. This observation indicates that [Ca(2+)](SR), sensed by Casq and transmitted to the channels presumably via connecting proteins, is determinant to cause the closure that terminates Ca(2+) release.     

Protein kinase C alpha modulates the Ca2+ influx phase of the Ca2+ response to 1alpha,25-dihydroxy-vitamin-D3 in skeletal muscle cells.

Treatment of chick skeletal muscle cells with 1alpha,25-dihydroxy-vitamin D3 [1alpha,25(OH)2D3] triggers a rapid and sustained increase in cytosolic Ca2+ ([Ca2+]i), which depends on Ca2+ mobilization from inner stores and extracellular Ca2+ entry. Fluorimetric analysis of changes in [Ca2+]i in Fura-2-loaded cells revealed that the hormone significantly stimulates the Ca2+ influx phase within the concentration range of 10(-12)-10(-6) M, with maximal effects (3.5-fold increase) at 10(-9) M 1alpha,25(OH)2D3. The effects of the sterol on the Ca2+ entry pathway were abolished by the PKC inhibitors bisindolylmaleimide and calphostin. We have recently shown that, in these cells, 1alpha,25(OH)2D3 activates and translocates PKC alpha to the membrane, suggesting that this isozyme accounts for PKC-dependent 1alpha,25(OH)2D3 modulation of Ca2+ entry. The role of PKC alpha was specifically addressed here using antisense technology. When the expression of PKC alpha was selectively knocked out by intranuclear microinjection of an antisense oligonucleotide against PKC alpha mRNA, the Ca2+ influx component of the response to 1alpha,25(OH)2D3 was markedly reduced (-60%). These results demonstrate that 1alpha,25(OH)2D3-induced activation of PKC alpha enhances extracellular Ca2+ entry partially contributing to maintainance of the sustained phase of the Ca2+ response to the sterol.     

Inactivation of a Ca2+-induced Ca2+ release channel from skeletal muscle sarcoplasmic reticulum during active Ca2+ transport

ATP-dependent Ca2+ uptake by subfractions of skeletal muscle sarcoplasmic reticulum (SR) was studied with the Ca2+ indicator dye, antipyrylazo III. Ca2+ uptake by heavy SR showed two phases, a slow uptake phase and a fast uptake phase. By contrast, Ca2+ uptake by light SR exhibited a monophasic time course. In both fractions a steady state of Ca2+ uptake was observed when the concentration of free Ca2+ outside the vesicles was reduced to less than 0.1 microM. In the steady state, the addition of 5 microM Ca2+ to the external medium triggered rapid Ca2+ release from heavy SR but not from light SR, indicating that the heavy fraction contains a Ca2+-induced Ca2+ release channel. During Ca2+ uptake, heavy SR showed a constant Ca2+-dependent ATPase activity (1 mumol/mg protein X min) which was about 150 times higher than the rate of Ca2+ uptake in the slow uptake phase. Ruthenium red, an inhibitor of Ca2+-induced Ca2+ release, enhanced the rate of Ca2+ uptake during the slow phase without affecting Ca2+-dependent ATPase activity. Adenine nucleotides, activators of Ca2+ release, reduced the Ca2+ uptake rate. These results suggest that the rate of Ca2+ accumulation by heavy SR is not proportional to ATPase activity during the slow uptake phase due to the activation of the channel for Ca2+-induced Ca2+ release. In addition, they suggest that the release channel is inactivated during the fast Ca2+ uptake phase.     

Ca2+ -induced Ca2+ release through localized Ca2+ uncaging in smooth muscle

Ca(2+)-induced Ca(2+) release (CICR) from the sarcoplasmic reticulum (SR) occurs in smooth muscle as spontaneous SR Ca(2+) release or Ca(2+) sparks and, in some spiking tissues, as Ca(2+) release that is triggered by the activation of sarcolemmal Ca(2+) channels. Both processes display spatial localization in that release occurs at a higher frequency at specific subcellular regions. We have used two-photon flash photolysis (TPFP) of caged Ca(2+) (DMNP-EDTA) in Fluo-4-loaded urinary bladder smooth muscle cells to determine the extent to which spatially localized increases in Ca(2+) activate SR release and to further understand the molecular and biophysical processes underlying CICR. TPFP resulted in localized Ca(2+) release in the form of Ca(2+) sparks and Ca(2+) waves that were distinguishable from increases in Ca(2+) associated with Ca(2+) uncaging, unequivocally demonstrating that Ca(2+) release occurs subsequent to a localized rise in [Ca(2+)](i). TPFP-triggered Ca(2+) release was not constrained to a few discharge regions but could be activated at all areas of the cell, with release usually occurring at or within several microns of the site of photolysis. As expected, the process of CICR was dominated by ryanodine receptor (RYR) activity, as ryanodine abolished individual Ca(2+) sparks and evoked release with different threshold and kinetics in FKBP12.6-null cells. However, TPFP CICR was not completely inhibited by ryanodine; Ca(2+) release with distinct kinetic features occurred with a higher TPFP threshold in the presence of ryanodine. This high threshold release was blocked by xestospongin C, and the pharmacological sensitivity and kinetics were consistent with CICR release at high local [Ca(2+)](i) through inositol trisphosphate (InsP(3)) receptors (InsP(3)Rs). We conclude that CICR activated by localized Ca(2+) release bears essential similarities to those observed by the activation of I(Ca) (i.e., major dependence on the type 2 RYR), that the release is not spatially constrained to a few specific subcellular regions, and that Ca(2+) release through InsP(3)R can occur at high local [Ca(2+)](i).     

Exercise attenuates {alpha}-adrenergic-receptor responsiveness in skeletal muscle vasculature

Attenuation of sympathetic vasoconstriction(sympatholysis) in working muscles during dynamic exercise iscontroversial. A potential mechanism is a reduction in-adrenergic-receptor responsiveness. The purpose of this study wasto examine ₁- and ₂-adrenergic-receptor-mediated vasoconstriction inresting and exercising skeletal muscle using intra-arterial infusionsof selective agonists. Thirteen mongrel dogs were instrumentedchronically with flow probes on the external iliac arteries of bothhindlimbs and a catheter in one femoral artery. The selective₁-adrenergic agonist (phenylephrine) or the selective₂-adrenergic agonist (clonidine) was infused as a bolusinto the femoral artery catheter at rest and during mild and heavyexercise. Intra-arterial infusions of phenylephrine elicited reductionsin vascular conductance of 76 ± 4, 71 ± 5, and 31 ± 2% at rest, 3 miles/h, and 6 miles/h and 10% grade, respectively.Intra-arterial clonidine reduced vascular conductance by 81 ± 5, 49 ± 4, and 14 ± 2%, respectively. The response tointra-arterial infusion of clonidine was unaffected by surgicalsympathetic denervation. Agonist infusion did not affect eithersystemic blood pressure, heart rate, or blood flow in the contralateraliliac artery. ₁-Adrenergic-receptor responsiveness wasattenuated during heavy exercise. In contrast,₂-adrenergic-receptor responsiveness was attenuated evenat a mild exercise intensity. These results suggest that the mechanismof exercise sympatholysis may involve reductions in postsynaptic-adrenergic-receptor responsiveness.

     

The role of Ca2+-ATpase and its hydrophobic component in the release of Ca2+ from skeletal muscle sarcoplasmic reticulum

The Ca2+ permeability of proteoliposomes containing Ca2+-ATPase of sarcoplasmic reticulum and its hydrophobic fragment was investigated, using the method of synthetic penetrant ions and the radioisotopic method. The former method was used to determine the diffusional membrane potential formed by Ca2+ concentration gradient. It was demonstrated that Ca2+-ATPase, whose active center is oriented outside, has and asymmetric conductivity, i. e., it facilitates the rapid efflux of Ca2+ from proteoliposomes. This efflux is stimulated by the membrane potential positive inside. The hydrophobic fragment of Ca2+-ATPase forms a Ca2+-channel with a high conductivity for Ca2+. This channel is responsible for the Ca2+ efflux from sarcoplasmic reticulum.     

A possible role of protein phosphorylation in the inactivation of a Ca2+-induced Ca2+ release channel from skeletal muscle sarcoplasmic reticulum

The Ca2+-induced Ca2+ release channel in the heavy fraction of the sarcoplasmic reticulum (SR) from rabbit skeletal muscle is inactivated during ATP-dependent Ca2+ uptake (Morii, H., Takisawa, H., & Yamamoto, T. (1985) J. Biol. Chem. 260, 11536-11541). AMP, one of the adenine nucleotides which activate the Ca2+ release, delayed the onset of the channel inactivation when added early during the course of the Ca2+ uptake. However, AMP could no longer activate the channel but accelerated the inactivation when added during the later phase of the Ca2+ uptake. In SR passively loaded with Ca2+, the Ca2+ channel which had been activated by AMP and Ca2+ was not spontaneously inactivated. Similarly, during GTP-dependent Ca2+ uptake, the channel activated by AMP was not inactivated. In addition acid phosphatase markedly delayed the onset of the inactivation during ATP-dependent Ca2+ uptake, without affecting Ca2+ ATPase activity or GTP-dependent Ca2+ uptake by heavy SR. The effect of the phosphatase was completely blocked by ruthenium red, a potent inhibitor of the channel. These results suggest that the channel is inactivated through an ATP-dependent process, presumably phosphorylation of proteins in the SR membrane. This was supported by the findings that the reactivation of the inactivated channel by added Ca2+ was markedly accelerated by the addition of acid phosphatase and that several proteins of heavy SR were phosphorylated during ATP-dependent Ca2+ uptake.     

Mechanical stress induces tumor necrosis factor-{alpha} production through Ca2+ release-dependent TLR2 signaling

We studied centrifugation-mediated mechanical stress-induced tumor necrosis factor-alpha (TNF-alpha) production in the monocyte-like cell line THP-1. The induction of TNF-alpha by mechanical stress was dependent on the centrifugation speed and produced the highest level of TNF-alpha after 1 h of stimulation. TNF-alpha production returned to normal levels after 24 h of stimulation. Mechanical stress also induced Toll-like receptor-2 (TLR2) mRNA in proportion to the expression of TNF-alpha. The inhibition of TLR2 signaling by dominant negative myeloid differentiation factor 88 (MyD88) blocked TNF-alpha expression response to mechanical stress. After transient overexpression of TLR2 in HEK-293 cells, mechanical stress induced TNF-alpha mRNA production. Interestingly, mechanical stress activated the c-Src-dependent TLR2 phosphorylation, which is necessary to induce Ca(2+) fluxes. When THP-1 cells were pretreated with BAPTA-AM, thapsigargin, and NiCl(2).6H(2)O, followed by mechanical stimulation, both TLR2 and TNF-alpha production were inhibited, indicating that centrifugation-mediated mechanical stress induces both TLR2 and TNF-alpha production through Ca(2+) releases from intracellular Ca(2+) stores following TLR2 phosphorylation. In addition, TNF-alpha treatment in THP-1 cells induced TLR2 production in response to mechanical stress, whereas the preincubation of anti-TNF-alpha antibody scarcely induced the mechanical stress-mediated production of TLR2, indicating that TNF-alpha produced by mechanically stimulated THP-1 cells affected TLR2 production. We concluded that TNF-alpha production induced by centrifugation-mediated mechanical stress is dependent on MyD88-dependent TLR2 signaling that is associated with Ca(2+) release and that TNF-alpha production induced by mechanical stress affects TLR2 production.     

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.     

Ca2+ Modulation of sarcoplasmic reticulum Ca2+ release in rat skeletal muscle fibers

Ca²⁺ transients and the rate of Ca²⁺ release (dCa_REL/dt) from the sarcoplasmic reticulum (SR) in voltage-clamped, fast-twitch skeletal muscle fibers from the rat were studied with the double Vaseline gap technique and using mag-fura-2 and fura-2 as Ca²⁺ indicators. Single pulse experiments with different returning potentials showed that Ca²⁺ removal from the myoplasm is voltage independent. Thus, the myoplasmic Ca²⁺ removal (dCa_REM/dt) was studied by fitting the decaying phase of the Ca²⁺ transient (Melzer, Ríos & Schneider, 1986) and dCa_REL/dt was calculated as the difference between dCa/dt and dCa_REM/dt. The fast Ca²⁺ release decayed as a consequence of Ca²⁺ inactivation of Ca²⁺ release. Double pulse experiments showed inactivation of the fast Ca²⁺ release depending on the prepulse duration. At constant interpulse interval, long prepulses (200 msec) induced greater inactivation of the fast Ca²⁺ release than shorter depolarizations (20 msec). The correlation (r) between the myoplasmic [Ca²⁺]_i and the inhibited amount of Ca²⁺ release was 0.98. The [Ca²⁺]_i for 50% inactivation of dCa_REL/dt was 0.25 m, and the minimum number of sites occupied by Ca²⁺ to inactivate the Ca²⁺ release channel was 3.0. These data support Ca²⁺ binding and inactivation of SR Ca²⁺ release.This work was supported by Grant-in-Aid from the American Heart Association (National) and Muscular Dystrophy Association (USA). Part of this work was developed in Dr. Stefani's laboratory at Baylor College of Medicine.     

Involvement of calmodulin in 1alpha,25-dihydroxyvitamin D3 stimulation of store-operated Ca2+ influx in skeletal muscle cells

The steroid hormone 1alpha,25-dihydroxyvitamin D(3) (1, 25-(OH)(2)D(3)) rapidly modulates Ca(2+) homeostasis in avian skeletal muscle cells by driving a complex signal transduction mechanism, which promotes Ca(2+) release from inner stores and cation influx from the outside through both L-type and store-operated Ca(2+) (SOC) channels. In the present work, we evaluated the involvement of calmodulin (CAM) in 1,25-(OH)(2)D(3) regulation of SOC influx in chick skeletal muscle cells. Treatment with 10(-9) m 1,25-(OH)(2)D(3) in Ca(2+)-free medium resulted in a rapid but transient Ca(2+) rise correlated with the sterol-induced inositol 1,4,5-trisphosphate (IP(3)) production. The SOC influx stimulated by the hormone was insensitive to both CAM antagonists (fluphenazine, trifluoperazine, chlorpromazine, compound 48/80) and the CAM-dependent protein kinase II (CAMKII) inhibitor KN-62 when added after the sterol-dependent Ca(2+) transient, but it was completely abolished when added prior to the IP(3)-induced mobilization of Ca(2+) from endogenous stores. Moreover, in cells microinjected with antisense oligonucleotides directed against the CAM mRNA the sterol-stimulated SOC influx was reduced up to 60% respect to uninjected cells. The present results suggest that the 1, 25-(OH)(2)D(3)-induced (IP(3)-mediated) cytosolic Ca(2+) transient is required for CAM, activation which in turn activates SOC influx in a mechanism that seems to include CAMKII.     

Modulation of ryanodine-induced Ca2+ release in amphibian skeletal muscle

We examined effects of ryanodine on tension in intact and skinned amphibian skeletal muscle. 100 microM ryanodine (RY) alone in the frog Ringer's solution (FR) produced tension in the intact muscle reaching its peak by 1 h; 10 min treatment with RY augmented depolarization-induced tension and prevented a subsequent caffeine-induced contraction. In contrast, RY in Ca2+-free FR was unable to produce tension, after which caffeine produced irreversible tension. In skinned fibers, RY at pCa 6.5 produced tension and abolished a subsequent caffeine-induced contraction; while Ry in 2 mM EGTA did not produce tension. These data indicate that RY, in the presence of CA2+, releases CA2+ from the SR resulting in subsequent depletion of CA in the SR.     

t-Butylhydroperoxide and gliotoxin stimulate Ca2+ release from rat skeletal muscle mitochondria

Summary

Rat liver mitochondria have a specific Ca²⁺ release pathway which operates when NAD⁺ is hydrolysed to nicotinamide and ADPribose. NAD⁺ hydrolysis is Ca²⁺-dependent and inhibited by cyclosporine A (CSA). Mitochondrial Ca²⁺ release can be activated by the prooxidant t-butylhydroperoxide (tbh) or by gliotoxin (GT), a fungal metabolite of the epipolythiodioxopiperazine group. Tbh oxidizes NADH to NAD⁺ through an enzyme cascade consisting of glutathione peroxidase, glutathione reductase, and the energy linked transhydrogenase, whereas GT oxidizes some vicinal thiols to the disulfide form, a prerequisite for NAD⁺ hydrolysis. We report now that rat skeletal muscle mitochondria also contain a specific Ca²⁺ release pathway activated by both tbh and GT. Ca²⁺ release increases with the mitochondrial Ca²⁺ load, is completely inhibited in the presence of CSA, and is paralleled by pyridine nucleotide oxidation. In the presence of tbh and GT, mitochondria do not lose their membrane potential and do not swell, provided continuous release and re-uptake of Ca²⁺ (‘Ca²⁺ cycling’) is prevented. These data support the notion that both tbh- and GT-induced Ca²⁺ release are not the consequence of an unspecific increase of the inner membrane permeability (‘pore’ formation). Tbh induces Ca²⁺ release from rat skeletal muscle less efficiently than from liver mitochondria indicating that the coupling between tbh and NADH oxidation is much weaker in skeletal muscle mitochondria. This conclusion is corroborated by a much lower glutathione peroxidase activity in skeletal muscle than in liver mitochondria. The prooxidant-dependent pathway promotes, under drastic conditions (high mitochondrial Ca²⁺ loads and high tbh concentrations), Ca²⁺ release to about the same extent and rate as the Na⁺/Ca²⁺ exchanger. This renders the prooxidant-dependent pathway relevant in the pathophysiology of mitochondrial myopathies where its activation by an increased generation of reactive oxygen species probably results in excessive Ca²⁺ cycling and damage to mitochondria.     

Ca2+ sparks in embryonic mouse skeletal muscle selectively deficient in dihydropyridine receptor alpha1S or beta1a subunits.

Ca2+ sparks are miniature Ca2+ release events from the sarcoplasmic reticulum of muscle cells. We examined the kinetics of Ca2+ sparks in excitation-contraction uncoupled myotubes from mouse embryos lacking the beta1 subunit and mdg embryos lacking the alpha1S subunit of the dihydropyridine receptor. Ca2+ sparks occurred spontaneously without a preferential location in the myotube. Ca2+ sparks had a broad distribution of spatial and temporal dimensions with means much larger than those reported in adult muscle. In normal myotubes (n = 248 sparks), the peak fluorescence ratio, DeltaF/Fo, was 1.6 +/- 0.6 (mean +/- SD), the full spatial width at half-maximal fluorescence (FWHM) was 3.6 +/- 1.1 micrometer and the full duration of individual sparks, Deltat, was 145 +/- 64 ms. In beta-null myotubes (n = 284 sparks), DeltaF/Fo = 1.9 +/- 0.4, FWHM = 5.1 +/- 1.5 micrometer, and Deltat = 168 +/- 43 ms. In mdg myotubes (n = 426 sparks), DeltaF/Fo = 1 +/- 0.5, the FWHM = 2.5 +/- 1.1 micrometer, and Deltat = 97 +/- 50 ms. Thus, Ca2+ sparks in mdg myotubes were significantly dimmer, smaller, and briefer than Ca2+ sparks in normal or beta-deficient myotubes. In all cell types, the frequency of sparks, DeltaF/Fo, and FWHM were gradually decreased by tetracaine and increased by caffeine. Both results confirmed that Ca2+ sparks of resting embryonic muscle originated from spontaneous openings of ryanodine receptor channels. We conclude that dihydropyridine receptor alpha1S and beta1 subunits participate in the control of Ca2+ sparks in embryonic skeletal muscle. However, excitation-contraction coupling is not essential for Ca2+ spark formation in these cells.