Effects of quercetin on single Ca(2+) release channel behavior of skeletal muscle

Quercetin, a bioflavonoid, is known to affect Ca(2+) fluxes in sarcoplasmic reticulum, although its direct effect on Ca(2+) release channel (CRC) in sarcoplasmic reticulum has remained to be elucidated. The present study examined the effect of quercetin on the behavior of single skeletal CRC in planar lipid bilayer. The effect of caffeine was also studied for comparison. At very low [Ca(2+)](cis) (80 pM), quercetin activated CRC marginally, whereas at elevated [Ca(2+)](cis) (10 microM), both open probability (P(o)) and sensitivity to the drug increased markedly. Caffeine showed a similar tendency. Analysis of lifetimes for single CRC showed that quercetin and caffeine led to different mean open-time and closed-time constants and their proportions. Addition of 10 microM ryanodine to CRC activated by quercetin or caffeine led to the typical subconductance state (approximately 54%) and a subsequent addition of 5 microM ruthenium red completely blocked CRC activity. When 6 microM quercetin and 3 mM caffeine were added together to the cis side of CRC, a time-dependent increase of P(o) was observed (from mode 1 (0.376 +/- 0.043, n = 5) to mode 2 (0.854 +/- 0.062, n = 5)). On the other hand, no further activation was observed when quercetin was added after caffeine. Quercetin affected only the ascending phase of the bell-shaped Ca(2+) activation/inactivation curve, whereas caffeine affected both ascending and descending phases. [(3)H]ryanodine binding to sarcoplasmic reticulum showed that channel activity increased more by both quercetin and caffeine than by caffeine alone. These characteristic differences in the modes of activation of CRC by quercetin and caffeine suggest that the channel activation mechanisms and presumably the binding sites on CRC are different for the two drugs.     

Interaction of calcium and local anesthetics with skeletal muscle microsomes

The influence of Ca⁺⁺, several drugs, and pH on the binding of Ca⁺⁺ by skeletal muscle microsomes was studied in vitro. A mass-law graphic analysis revealed the presence of three distinct species of Ca⁺⁺-binding sites in the microsomes, and the binding at only one of these sites was antagonized by local anesthetics and quinidine. These drugs also decreased the maximum Ca⁺⁺-binding capacity of the microsomes. Caffeine and ouabain exerted no effect on the binding at any of the sites. Procaine was also bound by microsomes, and this binding was antagonized by Ca⁺⁺, which also decreased the maximum procaine-binding capacity of microsomes. The sites that bind procaine and Ca⁺⁺ are not identical because the maximum-binding capacities of the interacting sites are distinctly different. The influence of pH on the ability of drugs to antagonize Ca⁺⁺ binding indicates that the displacing activity increases as the percentage of the drug in the nonionized form increases. All of the data obtained in the above studies are consistent with the interpretation that quinidine and local anesthetics of the procaine type noncompetitively antagonize the binding of Ca⁺⁺ by microsomes. The pharmacological significance of a noncompetitive interaction may be related to the property of local anesthetics and quinidine to increase contractile tension in skeletal muscle rather than to their ability to stabilize the cell membrane.     

Single calcium channel behavior in native skeletal muscle

The purpose of this study was to use whole-cell and cell-attached patches of cultured skeletal muscle myotubes to study the macroscopic and unitary behavior of voltage-dependent calcium channels under similar conditions. With 110 mM BaCl2 as the charge carrier, two types of calcium channels with markedly different single-channel and macroscopic properties were found. One class was DHP-insensitive, had a single-channel conductance of approximately 9 pS, yielded ensembles that displayed an activation threshold near -40 mV, and activated and inactivated rapidly in a voltage-dependent manner (T current). The second class could only be well resolved in the presence of the DHP agonist Bay K 8644 (5 microM) and had a single-channel conductance of approximately 14 pS (L current). The 14-pS channel produced ensembles exhibiting a threshold of approximately -10 mV that activated slowly (tau act approximately 20 ms) and displayed little inactivation. Moreover, the DHP antagonist, (+)-PN 200-110 (10 microM), greatly increased the percentage of null sweeps seen with the 14-pS channel. The open probability versus voltage relationship of the 14-pS channel was fitted by a Boltzmann distribution with a VP0.5 = 6.2 mV and kp = 5.3 mV. L current recorded from whole-cell experiments in the presence of 110 mM BaCl2 + 5 microM Bay K 8644 displayed similar time- and voltage-dependent properties as ensembles of the 14-pS channel. Thus, these data are the first comparison under similar conditions of the single-channel and macroscopic properties of T current and L current in native skeletal muscle, and identify the 9- and 14-pS channels as the single-channel correlates of T current and L current, respectively.     

Calsequestrin and the calcium release channel of skeletal and cardiac muscle

Calsequestrin is by far the most abundant Ca(2+)-binding protein in the sarcoplasmic reticulum (SR) of skeletal and cardiac muscle. It allows the Ca2+ required for contraction to be stored at total concentrations of up to 20mM, while the free Ca2+ concentration remains at approximately 1mM. This storage capacity confers upon muscle the ability to contract frequently with minimal run-down in tension. Calsequestrin is highly acidic, containing up to 50 Ca(2+)-binding sites, which are formed simply by clustering of two or more acidic residues. The Kd for Ca2+ binding is between 1 and 100 microM, depending on the isoform, species and the presence of other cations. Calsequestrin monomers have a molecular mass of approximately 40 kDa and contain approximately 400 residues. The monomer contains three domains each with a compact alpha-helical/beta-sheet thioredoxin fold which is stable in the presence of Ca2+. The protein polymerises when Ca2+ concentrations approach 1mM. The polymer is anchored at one end to ryanodine receptor (RyR) Ca2+ release channels either via the intrinsic membrane proteins triadin and junctin or by binding directly to the RyR. It is becoming clear that calsequestrin has several functions in the lumen of the SR in addition to its well-recognised role as a Ca2+ buffer. Firstly, it is a luminal regulator of RyR activity. When triadin and junctin are present, calsequestrin maximally inhibits the Ca2+ release channel when the free Ca2+ concentration in the SR lumen is 1mM. The inhibition is relieved when the Ca2+ concentration alters, either because of small changes in the conformation of calsequestrin or its dissociation from the junctional face membrane. These changes in calsequestrin's association with the RyR amplify the direct effects of luminal Ca2+ concentration on RyR activity. In addition, calsequestrin activates purified RyRs lacking triadin and junctin. Further roles for calsequestrin are indicated by the kinase activity of the protein, its thioredoxin-like structure and its influence over store operated Ca2+ entry. Clearly, calsequestrin plays a major role in calcium homeostasis that extends well beyond its ability to buffer Ca2+ ions.     

Activation and inhibition of purified skeletal muscle calcium release channel by NO donors in single channel current recordings.

The actions of the nitric oxide (NO) donors 1-hydroxy-2-oxo-3-(N-methyl-3-aminopropyl)-3 methyl-1-triazine (NOC-7), S-nitrosoacetylcysteine (CySNO) and S-nitrosoglutathione (GSNO) on the purified calcium release channel (ryanodine receptor) of rabbit skeletal muscle were determined by single channel current recordings. In addition, the activation of the NO donor modulated calcium release channel by the sulfhydryl oxidizing organic mercurial compound 4-(chloromercuri)phenylsulfonic acid (4-CMPS) was investigated. NOC-7 (0.1 and 0.3 mM) and CySNO (0.4 and 0.8 mM) increased the open probability (P(o)) of the calcium release channel at activating calcium concentrations (20-100 microM Ca(2+)) by 60-100%, with no effect on the current amplitude; this activation was abolished by the specific sulfhydryl reducing agent DTT. High concentrations of CySNO (1.6-2 mM) decreased P(o). Activation by GSNO (1 mM) was observed in two thirds of the experiments, but 2 mM and 4 mM GSNO markedly reduced P(o) at activating Ca(2+) (20-100 microM). In contrast to 4-CMPS, NOC-7 or GSNO had no effect at subactivating free Ca(2+) (0.6 microM). 4-CMPS further increased the open probability of NOC-7- or CySNO-stimulated channels and reversed transiently the reduced open probability of CySNO or GSNO inhibited channels at activating free Ca(2+). High concentrations of GSNO did not prevent channel activation of 4-CMPS at subactivating free Ca(2+). The NOC-7-, CySNO- or GSNO-modified channels were completely blocked by ruthenium red. It is suggested that nitrosylation/oxidation of sulfhydryls by NO donors and oxidation of sulfhydryls by 4-CMPS affect different cysteine residues essential in the gating of the calcium release channel.     

Effects of membrane polarization on sarcoplasmic calcium release in skeletal muscle

Calcium release from the sarcoplasmic reticulum was investigated in voltage-clamped, tetrodotoxin-treated frog skeletal muscle fibres injected with arsenazo III. Short (5 ms) depolarizing pulses (test pulses) produced a transient change in arsenazo III absorption, signalling an increase in intracellular calcium in concentration (calcium transient). Conditioning subthreshold depolarizations, which preceded the test pulse, potentiated the calcium transient triggered by the test pulse. Conditioning hyperpolarizations, applied either before or after the test pulse, inhibited the calcium transient. These effects of conditioning polarizations on the calcium transient may explain similar effects of subthreshold polarizations on muscle contraction that have previously been reported. The potentiating effect of subthreshold depolarizations was observed only when the test pulse was short (5 ms). The potentiating effect develops at -48 mV with a time constant of about 7 ms at 6.5 degrees C; this seems to be slower than that predicted by the potential spread from the surface along the tubular system. Thus, part of the effect could arise from the coupling process between tubular depolarization and calcium release.     

Block by ruthenium red of the ryanodine-activated calcium release channel of skeletal muscle

The effects of ruthenium red and the related compounds tetraamine palladium (4APd) and tetraamine platinum (4APt) were studied on the ryanodine activated Ca2+ release channel reconstituted in planar bilayers with the immunoaffinity purified ryanodine receptor. Ruthenium red, applied at submicromolar concentrations to the myoplasmic side (cis), induced an all-or-none flickery block of the ryanodine activated channel. The blocking effect was strongly voltage dependent, as large positive potentials that favored the movement of ruthenium red into the channel conduction pore produced stronger block. The half dissociation constants (Kd) for ruthenium red block of the 500 pS channel were 0.22, 0.38, and 0.62 microM, at +100, +80, and +60 mV, respectively. Multiple ruthenium red molecules seemed to be involved in the inhibition, because a Hill coefficient of close to 2 was obtained from the dose response curve. The half dissociation constant of ruthenium red block of the lower conductance state of the ryanodine activated channel (250 pS) was higher (Kd = 0.82 microM at +100 mV), while the Hill coefficient remained approximately the same (nH = 2.7). Ruthenium red block of the channel was highly asymmetric, as trans ruthenium red produced a different blocking effect. The blocking and unblocking events (induced by cis ruthenium red) can be resolved at the single channel level at a cutoff frequency of 2 kHz. The closing rate of the channel in the presence of ruthenium red increased linearly with ruthenium red concentration, and the unblocking rate of the channel was independent of ruthenium red concentrations. This suggests that ruthenium red block of the channel occurred via a simple blocking mechanism. The on-rate of ruthenium red binding to the channel was 1.32 x 10(9) M-1 s-1, and the off-rate of ruthenium red binding was 0.75 x 10(3) s-1 at +60 mV, in the presence of 200 nM ryanodine. The two related compounds, 4APd and 4APt, blocked the channel in a similar way to that of ruthenium red. These compounds inhibited the open channel with lower affinities (Kd = 170 microM, 4APd; Kd = 656 microM, 4APt), and had Hill coefficients of close to 1. The results suggest that ruthenium red block of the ryanodine receptor is due to binding to multiple sites located in the conduction pore of the channel.     

Functional expression of the calcium release channel from skeletal muscle ryanodine receptor cDNA

Combined patch-clamp and fura-2 measurements were performed to study the calcium release properties of Chinese hamster ovary (CHO) cells transfected with the rabbit skeletal muscle ryanodine receptor cDNA carried by an expression vector. Both caffeine (1-50 mM) and ryanodine (100 microM) induced release of calcium from intracellular stores of transformed CHO cells but not from control (non-transfected) CHO cells. The calcium responses to caffeine and ryanodine closely resembled those commonly observed in skeletal muscle. Repetitive applications of caffeine produced characteristic all-or-none rises in intracellular calcium. Inositol 1,4,5-trisphosphate (IP3) neither activated the ryanodine receptor channel nor interfered with the caffeine-elicited calcium release. These results indicate that functional calcium release channels are formed by expression of the ryanodine receptor cDNA.     

Ryanodine stabilizes multiple conformational states of the skeletal muscle calcium release channel.

Nanomolar to micromolar ryanodine alters the gating kinetics of the Ca2+ release channel from skeletal sarcoplasmic reticulum (SR) fused with bilayer lipid membranes (BLM). In the presence of asymmetric CsCl and 100 microM CaCl2 cis, ryanodine (RY) (5-40 nM) activates the channel, increasing the open probability (po; maximum 300% of control) without changing unitary conductance (468 picosiemens (pS)). Statistical analyses of gating kinetics reveal that open and closed dwell times exhibit biexponential distributions and are significantly modified by nanomolar RY. Altered channel gating kinetics with low nanomolar RY is fully reversible and correlates well with binding kinetics of nanomolar [3H]RY with its high affinity site (Kd1 = 0.7 nM) under identical experimental conditions. RY (20-50 nM) induces occasional 1/2 conductance fluctuations which correlate with [3H]RY binding to a second site having lower affinity (Kd2 = 23 nM). RY (5-50 nM) in the presence of 500 mM CsCl significantly enhances Ca(2+)-induced Ca2+ release from actively loaded SR vesicles. Ryanodine > or = 50 nM stabilizes the channel in a 234-pS subconductance which is not readily reversible. RY (> or = 70 microM) produces a unidirectional transition from the 1/2 to a 1/4 conductance fluctuation, whereas RY > or = 200 microM causes complete closure of the channel. The RY required for stabilizing 1/4 conductance transitions and channel closure do not quantitatively correlate with [3H]RY equilibrium binding constants and is attributed to significant reduction in association kinetics with > 200 nM [3H]RY in the presence of 500 mM CsCl. These results demonstrate that RY stabilizes four discrete states of the SR release channel and supports the existence of multiple interacting RY effector sites on the channel protein.     

ADP-ribose stimulates the calcium release channel RyR1 in skeletal muscle of rat

The Ca(2+) mobilizing metabolite cyclic ADP-ribose has been shown to release Ca(2+) from intracellular ryanodine sensitive stores in many cells. However, the activation of the ryanodine receptor of skeletal muscle by cADP-ribose (cADPr) and its precursor and metabolite (beta-NAD(+) and ADPr) remains to be discussed. We studied the effect of ADPr on the Ca(2+) release channel of skeletal muscle RyR1 after incorporation of microsomes isolated from fast muscles of rat in planar lipid bilayers. We observed an increase in the electrophysiological activity of the channel after addition of ADPr (10 microM) at micromolar Ca(2+) concentrations, characterized by a time-lag. The increase in P(o) is mainly due to an increase in the open frequency. The long time course observed for the development of the ADPr effect may indicate that this activation induces a change in the conformation of the RyR1 channel, which increases its sensitivity to calcium.     

Hypochlorous acid modifies calcium release channel function from skeletal muscle sarcoplasmic reticulum.

We have previously demonstrated that H2O2 at millimolar concentrations induces Ca(2+) release from actively loaded sarcoplasmic reticulum (SR) vesicles and induces biphasic [(3)H]ryanodine binding behavior. Considering that hypochlorous acid (HOCl) is a related free radical and has been demonstrated to be a more effective oxidant of proteins, we evaluated the effects of HOCl on sarcoplasmic reticulum Ca(2+)-channel release mechanism. In a concentration-dependent manner, HOCl activates the SR Ca(2+) release channel and induces rapid release of Ca from actively loaded vesicles. HOCl-induced Ca(2+) release is inhibited in the presence of millimolar concentrations of DMSO. High-affinity [(3)H]ryanodine binding is also enhanced at concentrations from 10 to 100 microM. At HOCl concentrations of >100 microM, equilibrium binding is inhibited. HOCl stimulation of binding is inhibited by the addition of dithiothreitol. The direct interaction between HOCl and the Ca(2+) release mechanism was further demonstrated in single-channel reconstitution experiments. HOCl, at 20 microM, activated the Ca(2+) release channel after fusion of a SR vesicle to a bilayer lipid membrane. At 40 microM, Ca(2+)-channel activity was inhibited. Pretreatment of SR vesicles with HOCl inhibited the fluorescence development of a fluorogenic probe specific to thiol groups critical to channel function. These results suggest that HOCl at micromolar concentrations can modify SR Ca(2+) handling.     

Charged local anesthetics block ionic conduction in the sheep cardiac sarcoplasmic reticulum calcium release channel.

We have examined the effect of the charged local anesthetics QX314, QX222, and Procaine on monovalent cation conduction in the Ca2+ release channel of the sheep cardiac sarcoplasmic reticulum. All three blockers only affect cation conductance when present at the cytoplasmic face of the channel. QX222 and Procaine act as voltage-dependent blockers. With 500 Hz filtering, this is manifest as a relatively smooth reduction in single-channel current amplitude most prominent at positive holding potentials. Quantitative analysis gives an effective valence of approximately 0.9 for both ions and Kb(0)s of 9.2 and 15.8 mM for QX222 and Procaine, respectively. Analysis of the concentration dependence of block suggests that QX222 is binding to a single site with a Km of 491 microM at a holding potential of 60 mV. The use of amplitude distribution analysis, with the data filtered at 1 to 2 kHz, reveals that the voltage and concentration dependence of QX222 block occurs largely because of changes in the blocker on rate. The addition of QX314 has a different effect, leading to the production of a substate with an amplitude of approximately one-third that of the control. The substate's occurrence is dependent on holding potential and QX314 concentration. Quantitative analysis reveals that the effect is highly voltage dependent, with a valence of approximately 1.5 caused by approximately equal changes in the on and off rates. Kinetic analysis of the concentration dependence of the substate occurrence reveals positive cooperativity with at least two QX314s binding to the conduction pathway, and this is largely accounted for by changes in the on rate. A paradoxical increase in the off rate at high positive holding potentials and with increasing QX314 concentration at 80 mV suggests the existence of a further QX314-dependent reaction that is both voltage and concentration dependent. The substate block is interpreted physically as a form of partial occlusion in the vestibule of the conduction pathway giving a reduction in single-channel current by electrostatic means.     

Classes of thiols that influence the activity of the skeletal muscle calcium release channel

The skeletal muscle Ca(2+) release channel/ryanodine receptor (RyR1) is a prototypic redox-responsive ion channel. Nearly half of the 101 cysteines per RyR1 subunit are kept in a reduced (free thiol) state under conditions comparable with resting muscle. Here we assessed the effects of physiological determinants of cellular redox state (oxygen tension, reduced (GSH) or oxidized (GSSG) glutathione, and NO/O(2) (released by 3-morpholinosydnonimine)) on RyR1 redox state and activity. Oxidation of approximately 10 RyR1 thiols (from approximately 48 to approximately 38 thiols/RyR1 subunit) had little effect on channel activity. Channel activity increased reversibly as the number of thiols was further reduced to approximately 23/subunit, whereas more extensive oxidation (to approximately 13 thiols/subunit) inactivated the channel irreversibly. Neither S-nitrosylation nor tyrosine nitration contributed to these effects. The results identify at least three functional classes of RyR1 thiols and suggest that 1) the channel may be protected from oxidation by a large reservoir of functionally inert thiols, 2) the channel may be designed to respond to moderate oxidative stress by a change in activation setpoint, and 3) the channel is susceptible to oxidative injury under more extensive conditions.     

Effect of gadolinium on the ryanodine receptor/sarcoplasmic reticulum calcium release channel of skeletal muscle

The effect of gadolinium ions on the sarcoplasmic reticulum (SR) calcium release channel/ryanodine receptor (RyR1) was studied using heavy SR (HSR) vesicles and RyR1 isolated from rabbit fast twitch muscle. In the [(3)H]ryanodine binding assay, 5 microM Gd(3+) increased the K(d) of the [(3)H]ryanodine binding of the vesicles from 33.8 nM to 45.6 nM while B(max), referring to the binding capacity, was not affected significantly. In the presence of 18 nM[(3)H]ryanodine and 100 microM free Ca(2+), Gd(3+) inhibited the binding of the radiolabeled ryanodine with an apparent K(d) value of 14.7 microM and a Hill coefficient of 3.17. In (45)Ca(2+) experiments the time constant of (45)Ca(2+) efflux from HSR vesicles increased from 90.9 (+/- 11.1) ms to 187.7 (+/- 24.9) ms in the presence of 20 microM gadolinium. In single channel experiments gadolinium inhibited the channel activity from both the cytoplasmic (cis) (IC(50) = 5.65 +/- 0.33 microM, n(Hill) = 4.71) and the luminal (trans) side (IC(50) = 5.47 +/- 0.24 microM, n(Hill) = 4.31). The degree of inhibition on the cis side didn't show calcium dependency in the 100 microM to 1 mM Ca(2+) concentration range which indicates no competition with calcium on its regulatory binding sites. When Gd(3+) was applied at the trans side, EGTA was present at the cis side to prevent the binding of Gd(+3) to the cytoplasmic calcium binding regulatory sites of the RyR1 if Gd(3+) accidentally passed through the channel. The inhibition of the channel did not show any voltage dependence, which would be the case if Gd(3+) exerted its effect after getting to the cis side. Our results suggest the presence of inhibitory binding sites for Gd(3+) on both sides of the RyR1 with similar Hill coefficients and IC(50) values.     

Spontaneous calcium release from sarcoplasmic reticulum. Effect of local anesthetics

Spontaneous calcium release from purified light sarcoplasmic reticulum has been previously described (Palade, P., Mitchell, R. D., and Fleischer, S. (1983) J. Biol. Chem. 258, 8098-8107) and found to be distinct from several other forms of Ca2+ release. Ca2+ release occurs after a lag period following active Ca2+ preloading and depletion of extravesicular Ca2+. In the present study, we find that local anesthetics inhibit spontaneous Ca2+ release, in a time-dependent manner, varying considerably in the preincubation time required to exert maximal effect. At pH 7.0, hydrophilic and mostly charged local anesthetics, such as procaine, procainamide, and N-(2,6-dimethylphenyl carbamoyl methyl)triethyl ammonium bromide, inhibit Ca2+ release only after long preincubations (hours), whereas more hydrophobic local anesthetics are effective after only a short incubation (minutes) with sarcoplasmic reticulum. The more hydrophobic anesthetics take somewhat longer to reach equilibrium, as studied by inhibition of unidirectional Ca2+ efflux, and there is a direct relationship between hydrophobic partition coefficient and half-time to reach equilibrium. Agents known to inhibit permeability pathways for monovalent cations i.e. K+ channel blockers (decamethonium and n-dodecane-1, 12-N,N,N,N',N',N'-hexamethyl-bis-ammonium) or the anion blocker (4,4'-diisothiocyanostilbene-2,2'-disulfonic acid), do not inhibit spontaneous Ca2+ release. Carbonyl cyanide m-fluorophenylhydrazone, a protonophore, and gramicidin D, a monovalent cation ionophore, have no effect on Ca2+ release whether local anesthetics are present or not, while the Ca2+ ionophore A23187 relieves inhibition of Ca2+ release by local anesthetics. Ruthenium red does not inhibit spontaneous Ca2+ release. These findings suggest that the binding site(s) for local anesthetics is located on the inner face of the sarcoplasmic reticulum membrane and that local anesthetics interact directly with a Ca2+ channel rather than with other permeability pathways which might indirectly influence Ca2+ channel gating.     

Regulation of the ryanodine receptor calcium release channel of the sarcoplasmic reticulum in skeletal muscle

In striated muscle contraction is under the tight control of myoplasmic calcium concentration ([Ca2+]i): the elevation in [Ca2+]i and the consequent binding of calcium to troponin C enables, while the decrease in [Ca2+]i prevents the actin-myosin interaction. Calcium ions at rest are stored in the sarcoplasmic reticulum (SR) from which they are rapidly released upon the depolarisation of the sarcolemmal and transverse (T-) tubular membranes of the muscle cell. The protein responsible for this controlled and fast release of calcium is the calcium release channel found in the membrane of the terminal cisternae of the SR. This review focuses on the physiological and pharmacological modulators of the calcium release channel and tries to draw an up-to-date picture of the events that occur between T-tubular depolarisation and the release of calcium from the SR.     

Differential effects of voltage-dependent inactivation and local anesthetics on kinetic phases of Ca2+ release in frog skeletal muscle

In voltage-clamped frog skeletal muscle fibers, Ca(2+) release rises rapidly to a peak, then decays to a nearly steady state. The voltage dependence of the ratio of amplitudes of these two phases (p/s) shows a maximum at low voltages and declines with further depolarization. The peak phase has been attributed to a component of Ca(2+) release induced by Ca(2+), which is proportionally greater at low voltages. We compared the effects of two interventions that inhibit Ca(2+) release: inactivation of voltage sensors, and local anesthetics reputed to block Ca(2+) release induced by Ca(2+). Holding the cells partially depolarized strongly reduced the peak and steady levels of Ca(2+) release elicited by a test pulse and suppressed the maximum of the p/s ratio at low voltages. The p/s ratio increased monotonically with test voltage, eventually reaching a value similar to the maximum found in noninactivated fibers. This implies that the marked peak of Ca(2+) release is a property of a cooperating collection of voltage sensors rather than individual ones. Local anesthetics reduced the peak of release flux at every test voltage, and the steady phase to a lesser degree. At variance with sustained depolarization, they made p/s low at all voltages. These observations were well-reproduced by the "couplon" model of dual control, which assumes that depolarization and anesthetics respectively, and selectively, disable its Ca(2+)-dependent or its voltage-operated channels. This duality of effects and their simulation under such hypotheses are consistent with the operation of a dual, two-stage control of Ca(2+) release in muscle, whereby Ca(2+) released through multiple directly voltage-activated channels builds up at junctions to secondarily open Ca(2+)-operated channels.     

The skeletal muscle calcium release channel: coupled O2 sensor and NO signaling functions

Ion channels have been studied extensively in ambient O2 tension (pO2), whereas tissue PO2 is much lower. The skeletal muscle calcium release channel/ryanodine receptor (RyR1) is one prominent example. Here we report that PO2 dynamically controls the redox state of 6-8 out of 50 thiols in each RyR1 subunit and thereby tunes the response to NO. At physiological pO2, nanomolar NO activates the channel by S-nitrosylating a single cysteine residue. Among sarcoplasmic reticulum proteins, S-nitrosylation is specific to RyR1 and its effect on the channel is calmodulin dependent. Neither activation nor S-nitrosylation of the channel occurs at ambient PO2. The demonstration that channel cysteine residues subserve coupled O2 sensor and NO regulatory functions and that these operate through the prototypic allosteric effector calmodulin may have general implications for the regulation of redox-related systems.     

Phosphorylation modulates the function of the calcium release channel of sarcoplasmic reticulum from skeletal muscle.

The modulation of the calcium release channel (CRC) by protein kinases and phosphatases was studied. For this purpose, we have developed a microsyringe applicator to achieve sequential and multiple treatments with highly purified kinases and phosphatases applied directly at the bilayer surface. Terminal cisternae vesicles of sarcoplasmic reticulum from rabbit fast twitch skeletal muscle were fused to planar lipid bilayers, and single-channel currents were measured at zero holding potential, at 0.15 microM free Ca2+, +/- 0.5 mM ATP and +/- 2.6 mM free Mg2+. Sequential dephosphorylation and rephosphorylation rendered the CRC sensitive and insensitive to block by Mg2+, respectively. Channel recovery from Mg2+ block was obtained by exogenous protein kinase A (PKA) or by Ca2+/calmodulin-dependent protein kinase II (CalPK II). Somewhat different characteristics were observed with the two kinases, suggesting two different states of phosphorylation. Channel block by Mg2+ was restored by dephosphorylation using protein phosphatase 1 (PPT1). Before application of protein kinases or phosphatases, channels were found to be "dephosphorylated" (inactive) in 60% and "phosphorylated" (active) in 40% of 51 single-channel experiments based on the criterion of sensitivity to block by Mg2+. Thus, these two states were interconvertable by treatment with exogenously added protein kinases and phosphatases. Endogenous Ca2+/calmodulin-dependent protein kinase (end CalPK) had an opposite action to exogenous CalPK II. Previously, dephosphorylated channels using PPT (Mg2+ absent) were blocked in the closed state by action of endogenous CalPK. This block was removed to normal activity by the action of either PPT or by exogenous CalPK II. Our findings are consistent with a physiological role for phosphorylation/dephosphorylation in the modulation of the calcium release channel of sarcoplasmic reticulum from skeletal muscle. A corollary of our studies is that only the phosphorylated channel is active under physiological conditions (mM Mg2+). Our studies suggest that phosphorylation can be at more than one site and, depending on the site, can have different functional consequences on the CRC.