Use of aequorin for the appraisal of the hypothesis of the release of calcium from the sarcoplasmic reticulum induced by a change of pH in skinned cardiac cells

A change of pH did not modify the sensitivity of aequorin to Ca2+, but an increase of pH enhanced the Ca2+ sensitivity of the myofilaments of a skinned canine cardiac Purkinje cell. The tension-pCa curve did not present any hysteresis when a given [free Ca2+] was reached from a higher versus from a lower [free Ca2+] in the presence of pH 6.60, 7.10 or 7.40. A rapid variation of pH in either direction failed to induce Ca2+ release from the sarcoplasmic reticulum (SR). The proton ionophores CCCP and gramicidin also failed to induce Ca2+ release from the SR. Increase of pH from 7.10 to 7.40 enhanced Ca2+ accumulation into the SR and, thereby, augmented the Ca2+ content of the SR. Consequently, the amplitude of a subsequent Ca2+ release triggered by a rapid increase of [free Ca2+] at the outer surface of the SR was increased. Conversely, a decrease of pH from 7.10 to 6.60 diminished the Ca2+ accumulation into the SR, the Ca2+ content of the SR and the amplitude of a subsequent Ca2+-induced release of Ca2+ from the SR. In addition, the optimum [free Ca2+] for triggering Ca2+-induced release of Ca2+ was shifted to higher [free Ca2+] values by a decrease of pH from 7.40 to 7.10 or 7.10 to 6.60. This may help to explain the enhancement of the aequorin light transient during acidosis in the intact cardiac muscle inasmuch as acidosis may increase the [free Ca2+] trigger at the outer surface of the SR by inhibiting Na+-Ca2+ exchange across the sarcolemma.     

Time and calcium dependence of activation and inactivation of calcium- induced release of calcium from the sarcoplasmic reticulum of a skinned canine cardiac Purkinje cell

Microprocessor-controlled changes of [free Ca2+] at the outer surface of the sarcoplasmic reticulum (SR) wrapped around individual myofibrils of a skinned canine cardiac Purkinje cell and aequorin bioluminescence recording were used to study the mechanism of Ca2+-induced release of Ca2+ from the SR. This Ca2+ release is triggered by a rapid increase of [free Ca2+] at the outer surface of the SR of a previously quiescent skinned cell. Ca2+-induced release of Ca2+ occurred under conditions that prevented any synthesis of ATP from ADP, was affected differentially by interventions that depressed the SR Ca2+ pump about equally, and required ionic conditions incompatible with all known Ca2+-releasing, uncoupled, partial reactions of the Ca2+ pump. Increasing the [free Ca2+]trigger up to an optimum increased the amount of Ca2+ released. A supraoptimum increase of [free Ca2+] trigger inactivated Ca2+-induced release of Ca2+, but partial inactivation was also observed at [free Ca2+] below that necessary for its activation. The amplitude of the Ca2+ release induced by a given increase of [free Ca2+] decreased when the rate of this increase was diminished. These results suggest that Ca2+-induced release of Ca2+ is through a channel across the SR membrane with time- and Ca2+-dependent activation and inactivation. The inactivating binding site would have a higher affinity for Ca2+ but a lower rate constant than the activating site. Inactivation appeared to be a first-order kinetic reaction of Ca2+ binding to a single site at the outer face of the SR with a Q10 of 1.68. The removal of inactivation was the slowest step of the cycle, responsible for a highly temperature-dependent (Q10 approximately 4.00) refractory period.     

Rapid ionic modifications during the aequorin-detected calcium transient in a skinned canine cardiac Purkinje cell

A microprocessor-controlled system of microinjections and microaspirations has been developed to change, within approximately 1 ms, the [free Ca2+] at the outer surface of the sarcoplasmic reticulum (SR) wrapped around individual myofibrils (0.3-0.4 micron radius) of a skinned canine cardiac Purkinje cell (2.5-4.5 micron overall radius) at different phases of a Ca2+ transient. Simultaneously monitoring tension and aequorin bioluminescence provided two methods for estimating the peak myoplasmic [free Ca2+] reached during the spontaneous cyclic Ca2+ release from the SR obtained in the continuous presence of a bulk solution [free Ca2+] sufficiently high to overload the SR. These methods gave results in excellent agreement for the spontaneous Ca2+ release under a variety of conditions of pH and [free Mg2+], and of enhancement of Ca2+ release by calmodulin. Disagreement was observed, however, when the Ca2+ transient was modified during its ascending phase. The experiments also permitted quantification of the aequorin binding within the myofibrils and determination of its operational apparent affinity constant for Ca2+ at various [free Mg2+] levels. An increase of [free Ca2+] at the outer surface of the SR during the ascending phase of the Ca2+ transient induced further release of Ca2+. In contrast, an increase of [free Ca2+] during the descending phase of the Ca2+ transient did not cause further Ca2+ release. Varying [free H+], [free Mg2+], or the [Na+]/[K+] ratio had no significant effect on the Ca2+ transient during which the modification was applied, but it altered the subsequent Ca2+ transient. Therefore, Ca2+ appears to be the major, if not the only, ion controlling Ca2+ release from the SR rapidly enough to alter a Ca2+ transient during its course.     

Fluorescence and differential light absorption recordings with calcium probes and potential-sensitive dyes in skinned cardiac cells

This report describes an optical system for microspectrophotometry in a single cardiac cell from which the sarcolemma has been removed by microdissection (skinned cardiac cell). This system is attached to the high power inverted microscope used for the microdissection and includes (a) a single variable wavelength microspectrophotometer used to define the spectrum of a given dye or Ca2+ probe; and (b) a dual wavelength, differential microspectrophotometer used to record differentially between the optimum wavelength and a wavelength separated by 25--30 nm. Results are presented using the following optical methods: (a) fluorescence measurements with chlorotetracycline to monitor the amount of Ca2+ bound to the inner face of the sarcoplasmic reticulum (SR) membrane; (b) differential absorption measurements with arsenazo III to measure changes of myoplasmic [Ca2+]free resulting from Ca2+ release from the SR; (c)fluorescence and (or) differential absorption measurements with the potential-sensitive dyes merocyanine 540, NK 2367, and di-S-C3(5) to monitor changes of charge distribution on the SR membrane during Ca2+ accumulation in the SR, as well as before and during Ca2+-induced release of Ca2+ from the SR. A small and rapid signal is observed which precedes the Ca2+-induced release of Ca2+ from the SR. It is detected as an increase of CA2+ binding inside the SR with chlorotetracycline and as a "hyperpolarization" with potential-sensitive dyes, while no transient change of myoplasmic [Ca2+]free is detected with arsenazo III. This small and rapid signal preceding the Ca2+ release may be a first hint to an understanding of the mechanism whereby a small increase of [Ca2+]free outside the SR triggers Ca2+ release from the SR.     

The regulation of tension in a chemically skinned molluscan smooth muscle: effect of Mg2+ on the Ca2+-activated tension generation

Chemically skinned anterior byssus retractor muscle (ABRM) preparations were prepared by treatment with the nonionic detergents saponin and Triton X-100. Both maximum peak tension and rate of contraction were found to be greater in saponin-treated ABRM than in ABRM treated with Triton X-100. Active tension was initiated at a concentration of free Ca2+ above 0.1 microM, and maximum tension development was found at a [Ca2+] = approximately 32 microM. During exposure of the muscle preparation to optimal Ca2+ concentration, a high and almost constant tension level was sustained. The force recovery was high after a quick release during this period indicating the presence of an "active" state rather than a "catch" state. Actually, a state equivalent to the catch state in the living ABRM could not be induced, if the Ca2+ concentration was above 0.1 microM. Variations in the ionic strength in the range of 0.07--0.28 M had no influence on active state and only slightly affected the maximum tension developed. The influence of Mg2+ on the Ca2+-activated tension was examined by studying the tension-pCa relation at two concentrations of free Mg2+ (0.43 and 4.0 mM). The tension-pCa relation was found to be S-shaped with tension increasing steeply over approximately 1 pCa unit, indicating the existence of cooperativity between Ca2+ sites. Increasing the free concentration of Mg2+ shifted the tension-pCa relation to lower pCa as in striated muscles, demonstrating a decreasing Ca2+ sensitivity with increasing Mg2+. At [Mg2+] = 4.0 mM the half-maximum tension was found at [Ca2+] = 0.43 microM, decreasing to 0.20 microM at [Mg2+] = 0.43 mM. At both Mg2+ concentrations studied, plots of log Prel/(1--Prel) vs. log [Ca2+] were nonlinear with a shape indicating a rather complicated model for cooperativity, probably involving four sites for Ca2+. These Ca2+--Mg2+ interactions are most probably taking place at the myosin head itself because troponin is absent in this myosin-regulated muscle.     

Effects of ryanodine in skinned cardiac cells

Ryanodine (1 X 10(-5) M) did not affect the Ca2+ sensitivity of the myofilaments of skinned (sarcolemma removed by microdissection) cardiac cells from the rat ventricle. Ryanodine (1 X 10(-5) M) inhibited three types of Ca2+ release from the sarcoplasmic reticulum (SR), which have different mechanisms: 1) Ca2+-induced release of Ca2+ triggered by a rapid and transient increase of [free Ca2+] at the outer surface of the SR; 2) caffeine-induced release of Ca2+; 3) spontaneous cyclic release of Ca2+ occurring in the continuous presence of a [free Ca2+] sufficient to overload the SR. These results suggest that the three types of Ca2+ release are through the same channel across the SR membrane, although the gating mechanisms are different for the three types. Ryanodine also diminished the rate of Ca2+ accumulation into the SR. Even in the presence of 1 X 10(-5) M ryanodine the SR accumulated Ca2+ that could be released when the SR was sufficiently overloaded with Ca2+. Thus, ryanodine pretreatment did not permit the direct activation of the myofilaments by externally applied Ca2+. The approximately 1000-fold difference in the effective concentrations of ryanodine in intact vs. skinned cardiac cells suggests that low concentrations of ryanodine act in the intact cardiac tissues through processes or on structures that are destroyed by the skinning procedure. No significant differences were observed in the effects of ryanodine in skinned cardiac cells from different adult mammalian species.     

Calcium accumulation and release by the sarcoplasmic reticulum of digitonin-lysed adult mammalian ventricular cardiomyocytes.

We have developed a model for characterizing calcium handling by the intact cardiac sarcoplasmic reticulum (SR) that yields data consistent with both mathematical simulations of in situ SR Ca2+ uptake and deduced behavior of the Ca2(+)-induced Ca2+ efflux channels in mechanically skinned single cardiac cells. In Na(+)-based media (37 degrees C, pH 7.2, 50 mM Pi, 10 mM MgATP, pMg 3.3, 10 mM phosphocreatine), SR 45Ca2+ uptake by digitonin-lysed rat myocytes as a function of free [Ca2+] peaked at pCa 6.2, declined until pCa 5.6 and increased again at lower pCa. When Ca2(+)-induced Ca2+ efflux was inhibited with 30 microM ruthenium red and 10 mM procaine, uptake was saturable with a Vmax of 160 +/- 5 nmol.min-1.mg-1, K0.5 of 500 nM free [Ca2+] and slope factor of 1.6. In K(+)-based media, maximum Pi- and oxalate-supported uptake increased to 220 and 260 nmol.min-1.mg-1, respectively. Without phosphocreatine, 45Ca2+ uptake declined under all conditions; this was correlated with a decrease in ATP/ADP. Vmax for 45Ca2+ uptake was increased 20% in hyperthyroid myocytes but depressed 30% in myocytes from heart failure-prone rats. In canine myocytes, Vmax was the same as in normal rat cells, but K0.5 was 830 nM. Without efflux inhibitors, ryanodine caused a concentration-dependent decline in net Pi-supported 45Ca2+ uptake at pCa 6.3 (K0.5 = 1 microM), while 10 microM ryanodine depressed uptake at all pCa between 7.2 and 5.6. Ruthenium red/procaine fully reversed this effect.     

Calcium-induced calcium release from purified cardiac sarcoplasmic reticulum vesicles. General characteristics

Isolated canine cardiac sarcoplasmic reticulum exhibits Ca2+-induced Ca2+ release from both actively and passively loaded vesicles. The rate and extent of Ca2+ release depend on the extravesicular ionized Ca2+ concentration ( [Ca2+]o) at the onset of release. Maximal release following ATP-dependent, phosphate-facilitated Ca2+ loading (up to 360 nmol of Ca2+/mg of protein/min at 37 degrees C) occurs at 1.5-2 microM [Ca2+]o, with reduced release at both lower and higher Ca2+ concentrations (half-maximal Ca2+ release at approximately 0.8 and 5.5 microM [Ca2+]o). Only a portion of the accumulated Ca2+ is released and the release is followed by reuptake of Ca2+. A similar Ca2+ dependence is obtained in the absence of ATP and Pi by measuring unidirectional Ca2+ efflux from passively loaded vesicles (maximal Ca2+ efflux at 1 microM [Ca2+]o; half-maximal Ca2+-dependent efflux at approximately 0.15 and 13 microM [Ca2+]o). Although the Ca2+ release rates observed in this study are several orders of magnitude lower than the rate of Ca2+ release which occurs in muscle cells in vivo, this Ca2+ release phenomenon may be related to the Ca2+-induced Ca2+ release which has been described for skinned cardiac cells ( Fabiato , A. (1983) Am. J. Physiol. 245, C1-C14). Ca2+ release occurs in the presence of an ATP-regenerating system and is not accompanied by a reduction in ATP hydrolysis. Also, since unidirectional Ca2+ efflux (as high as 860 nmol of Ca2+/mg of protein/min at 37 degrees C) exceeds net Ca2+ release under similar conditions, Ca2+ influx proceeds during the period of net Ca2+ release. Therefore, Ca2+ release does not involve reversal or cessation of inward Ca2+ pumping. Other data indicate that Ca2+ release is not mediated through the Ca2+ pump protein, but occurs through a separate Ca2+-dependent efflux pathway, possibly a channel.     

Contribution of sarcolemmal sodium-calcium exchange and intracellular calcium release to force development in isolated canine ventricular muscle

The aim of this work was to determine the relationship between peak twitch amplitude and sarcoplasmic reticulum (SR) Ca2+ content during changes of stimulation frequency in isolated canine ventricle, and to estimate the extent to which these changes were dependent upon sarcolemmal Na(+)-Ca2+ exchange. In physiological [Na+]o, increased stimulation frequency in the 0.2-2-Hz range resulted in a positive inotropic effect characterized by an increase in peak twitch amplitude and a decrease in the duration of contraction, measured as changes in isometric force development or unloaded cell shortening in intact muscle and isolated single cells, respectively. Action potentials recorded from single cells indicated that the inotropic effect was associated with a progressive decrease of action potential duration and a marked reduction in average time spent by the cell near the resting potential during the stimulus train. The frequency-dependent increase of peak twitch force was correlated with an increase of Ca2+ uptake into and release from the SR. This was estimated indirectly using the phasic contractile response to rapid (less than 1 s) lowering of perfusate temperature from 37 degrees C to 0-2 degrees C and changes of twitch amplitude resulting from perturbations in the pattern of electrical stimulation. Lowering [Na+]o from 140 to 70 mM resulted in an increase of contractile strength, which was accompanied by a similar increase of apparent SR Ca2+ content, both of which could be abolished by exposure to ryanodine (1 x 10(-8) M), caffeine (3 x 10(-3) M), or nifedipine (2 x 10(-6) M). Increased stimulation frequency in 70 mM [Na+]o resulted in a negative contractile staircase, characterized by a graded decrease of peak isometric force development or unloaded cell shortening. SR Ca2+ content estimated under identical conditions remained unaltered. Rate constants derived from mechanical restitution studies implied that the depressant effect of increased stimulation frequency in 70 mM [Na+]o was not a consequence of a decreased rate of refilling of a releasable pool of Ca2+ within the cell. These results demonstrate that frequency-dependent changes of contractile strength and intracellular Ca2+ loading in 140 mM [Na+]o require the presence of a functional sarcolemmal Na(+)-Ca2+ exchange process. The possibility that the negative staircase in 70 mM [Na+]o is related to inhibition of Ca(2+)-induced release of Ca2+ from the SR by various cellular mechanisms is discussed.     

Spontaneous Ca2+ release from the sarcoplasmic reticulum limits Ca2+- dependent twitch potentiation in individual cardiac myocytes. A mechanism for maximum inotropy in the myocardium

We hypothesized that the occurrence of spontaneous Ca2+ release from the sarcoplasmic reticulum (SR), in diastole, might be a mechanism for the saturation of twitch potentiation common to a variety of inotropic perturbations that increase the total cell Ca. We used a videomicroscopic technique in single cardiac myocytes to quantify the amplitude of electrically stimulated twitches and to monitor the occurrence of the mechanical manifestation of spontaneous SR Ca2+ release, i.e., the spontaneous contractile wave. In rat myocytes exposed to increasing bathing [Ca2+] (Cao) from 0.25 to 10 mM, the Cao at which the peak twitch amplitude occurred in a given cell was not unique but varied with the rate of stimulation or the presence of drugs: in cells stimulated at 0.2 Hz in the absence of drugs, the maximum twitch amplitude occurred in 2 mM Cao; a brief exposure to 50 nM ryanodine before stimulation at 0.2 Hz shifted the Cao of the maximum twitch amplitude to 7 mM. In cells stimulated at 1 Hz in the absence of drugs, the maximum twitch amplitude occurred in 4 mM Cao; 1 microM isoproterenol shifted the Cao of the maximum twitch amplitude to 3 mM. Regardless of the drug or the stimulation frequency, the Cao at which the twitch amplitude saturated varied linearly with the Cao at which spontaneous Ca2+ release first occurred, and this relationship conformed to a line of identity (r = 0.90, p = less than 0.001, n = 25). The average peak twitch amplitude did not differ among these groups of cells. In other experiments, (a) the extent of rest potentiation of the twitch amplitude in rat myocytes was also limited by the occurrence of spontaneous Ca2+ release, and (b) in both rat and rabbit myocytes continuously stimulated in a given Cao, the twitch amplitude after the addition of ouabain saturated when spontaneous contractile waves first appeared between stimulated twitches. A mathematical model that incorporates this interaction between action potential-mediated SR Ca2+ release and the occurrence of spontaneous Ca2+ release in individual cells predicted the shape of the Cao-twitch relationship observed in other studies in intact muscle. Thus, the occurrence of spontaneous SR Ca2+ release is a plausible mechanism for the saturation of the inotropic response to Ca2+ in the intact myocardium.     

Myofilament-generated tension oscillations during partial calcium activation and activation dependence of the sarcomere length-tension relation of skinned cardiac cells

During partial Ca2+ activation, skinned cardiac cells with sarcoplasmic reticulum destroyed by detergent developed spontaneous tension oscillations consisting of cycles (0.1-1 Hz) of rapid decrease of tension corresponding to the yield of some sarcomeres and slow redevelopment of tension corresponding to the reshortening of these sarcomeres. Such myofilament-generated tension oscillations were never observed during the full activation induced by a saturating [free Ca2+] or during the rigor tension induced by decreasing [MgATP] in the absence of free Ca2+ or when the mean sarcomere length (SL) of the preparation was greater than 3.10 microm during partial Ca2+ activation. A stiff parallel elastic element borne by a structure that could be digested by elastase hindered the study of the SL--active tension diagram in 8-13-microm-wide skinned cells from the rat ventricle, but this study was possible in 2-7-microm-wide myofibril bundles from the frog or dog ventricle. During rigor the tension decreased linearly when SL was increased from 2.35 to 3.80 microm. During full Ca2+ activation the tension decreased by less than 20% when SL was increased from 2.35 to approximately 3.10 microm. During partial Ca2+ activation the tension increased when SL was increased from 2.35 to 3.00 microm. From this observation of an apparent increase in the sensitivity of the myofilaments to Ca2+ induced by increasing SL during partial Ca2+ activation, a model was proposed that describes the tension oscillations and permits the derivation of the maximal velocity of shortening (Vmax). Vmax was increased by increasing [free Ca2+] or decreasing [free Mg2+] but not by increasing SL.     

Spread of Ca2+ in the sarcomere during fast and slow activation of mammalian cardiac myocytes

A multi-compartment model was used to estimate Ca2+ gradients in a sarcomere of a cardiac myocyte. The mathematical model assumed Ca2+ release from the sarcoplasmic reticulum as a driving function, and calculated Ca2+ binding to myoplasmic buffers, Ca2+ uptake by the sarcoplasmic reticulum, and diffusion of Ca2+ (and the buffers). During the fast Ca2+ transient similar to those observed during a twitch, the model predicted a large Ca2+ gradient in the sarcomere. A trajectory of the instantaneous relation between spatially averaged concentrations of Ca2+ and the Ca2+-troponin complex showed a counterclockwise loop, indicating non-equilibrium Ca2+ binding to troponin. During slow changes in [Ca2+] with time to peaks of approximately 500 ms or longer, the gradient of [Ca2+] was largely dissipated and the apparent equilibrium of the Ca2+-troponin binding reaction was suggested with little hysteresis of the trajectory. We conclude that a steady-state relation between [Ca2+] and mechanical activity can be achieved uniformly in the sarcomere by slowing the rate of Ca2+ release from the sarcoplasmic reticulum.     

Activation of single cardiac and skeletal ryanodine receptor channels by flash photolysis of caged Ca2+.

Single ryanodine-sensitive sarcoplasmic reticulum (SR) Ca2+ release channels isolated from rabbit skeletal and canine cardiac muscle were reconstituted in planar lipid bilayers. Single channel activity was measured in simple solutions (no ATP or Mg2+) with 250 mM symmetrical Cs+ as charge carrier. A laser flash was used to photolyze caged-Ca2+ (DM-nitrophen) in a small volume directly in front of the bilayer. The free [Ca2+] in this small volume and in the bulk solution was monitored with Ca2+ electrodes. This setup allowed fast, calibrated free [Ca2+] stimuli to be applied repetitively to single SR Ca2+ release channels. A standard photolytically induced free [Ca2+] step (pCa 7-->6) was applied to both the cardiac and skeletal release channels. The rate of channel activation was determined by fitting a single exponential to ensemble currents generated from at least 50 single channel sweeps. The time constants of activation were 1.43 +/- 0.65 ms (mean +/- SD; n = 5) and 1.28 +/- 0.61 ms (n = 5) for cardiac and skeletal channels, respectively. This study presents a method for defining the fast Ca2+ regulation kinetics of single SR Ca2+ release channels and shows that the activation rate of skeletal SR Ca2+ release channels is consistent with a role for CICR in skeletal muscle excitation-contraction coupling.     

Calcium-gated calcium channels in sarcoplasmic reticulum of rabbit skinned skeletal muscle fibers

The action of ruthenium red (RR) on Ca2+ loading by and Ca2+ release from the sarcoplasmic reticulum (SR) of chemically skinned skeletal muscle fibers of the rabbit was investigated. Ca2+ loading, in the presence of the precipitating anion pyrophosphate, was monitored by a light-scattering method. Ca2+ release was indirectly measured by following tension development evoked by caffeine. Stimulation of the Ca2+ loading rate by 5 microM RR was dependent on free Ca2+, being maximal at pCa 5.56. Isometric force development induced by 5 mM caffeine was reversibly antagonized by RR. IC50 for the rate of tension rise was 0.5 microM; that for the extent of tension was 4 microM. RR slightly shifted the steady state isometric force/pCa curve toward lower pCa values. At 5 microM RR, the pCa required for half-maximal force was 0.2 log units lower than that of the control, and maximal force was depressed by approximately 16%. These results suggest that RR inhibited Ca2+ release from the SR and stimulated Ca2+ loading into the SR by closing Ca2+-gated Ca2+ channels. Previous studies on isolated SR have indicated the selective presence of such channels in junctional terminal cisternae.     

Effects of ryanodine on intracellular Ca2+ transients in mammalian cardiac muscle

We observed the effects of ryanodine on the aequorin luminescence, membrane potential, and contraction of canine cardiac Purkinje fibers and ferret ventricular muscle. In canine Purkinje fibers, ryanodine (10 nM to 1 microM) abolished the spontaneous spatiotemporal fluctuations in [Ca2+] that occur as a result of Ca2+-induced Ca2+ release from the sarcoplasmic reticulum (SR) during exposure to low-Na+ solutions. Ryanodine strongly reduced the twitch and both components of the intracellular aequorin luminescence signal (L1 and L2), which normally accompanies contraction. The small luminescence signals that remained in ryanodine could be abolished by a Ca2+ channel blocker (nitrendipine, 10 microM). The plateau phase of the action potential was reduced by nitrendipine in the presence of ryanodine, which suggests that Ca2+ current was not blocked by ryanodine. In ferret ventricular tissue, ryanodine (1 microM) prolonged the action potential and reduced the peak amplitudes of both the aequorin transient and the twitch, while greatly prolonging the time-to-peak of both signals. Increases in extracellular [Ca2+] restored the peak amplitudes of the twitch and the aequorin luminescence, but did not restore the normal time-to-peak. The results show that in both tissues, the negative inotropic effect of ryanodine is due to the reduction of the intracellular [Ca2+] transient. Inasmuch as neither Ca2+ entry via surface membrane Ca2+ channels nor Na+-Ca2+ exchange appears to be blocked by ryanodine, the most probable cause of reduction of the [Ca2+] transient is an inhibition of Ca2+ release by the SR.     

Excitation-contraction coupling in intact frog skeletal muscle fibers injected with mmolar concentrations of fura-2.

Experiments were carried out to test the hypothesis that mM concentrations of fura-2, a high-affinity Ca2+ buffer, inhibit the release of Ca2+ from the sarcoplasmic reticulum (SR) of skeletal muscle fibers. Intact twitch fibers from frog muscle, stretched to a long sarcomere length and pressure-injected with fura-2, were activated by an action potential. Fura-2's absorbance and fluorescence signals were measured at different distances from the site of fura-2 injection; thus, the myoplasmic free Ca2+ transient (delta [Ca2+]) and the amount and rate of SR Ca2+ release could be estimated at different myoplasmic concentrations of fura-2 ([fura-2T]). At [fura-2T] = 2-3 mM, the amplitude and half-width of delta [Ca2+] were reduced to approximately 25% of the values measured at [fura-2T] less than 0.15 mM, whereas the amount and rate of SR Ca2+ release were enhanced by approximately 50% (n = 5; 16 degrees C). Similar results were observed in experiments carried out at low temperature (n = 2; 8.5-10.5 degrees C). The finding of an enhanced rate of Ca2+ release at 2-3 mM [fura-2T] is opposite to that reported by Jacquemond et al. (Jacquemond, V., L. Csernoch, M. G. Klein, and M. F. Schneider. 1991. Biophys. J. 60:867-873) from analogous experiments carried out on cut fibers. In two experiments involving the injection of larger amounts of fura-2, reductions in SR Ca2+ release were observed; however, we were unable to decide whether these reductions were due to [fura-2T] or to some nonspecific effect of the injection itself. These experiments do, however, suggest that if large [fura-2T] inhibits SR Ca2+ release in intact fibers, [fura-2T] must exceed 6 mM to produce an effect comparable to that reported by Jacquemond et al. in cut fibers. Our clear experimental result that 2-3 mM [fura-2T] enhances SR Ca2+ release supports the proposal that delta [Ca2+] triggered by an action potential normally feeds back to inhibit further release of Ca2+ from the SR (Baylor, S.M., and S. Hollingworth. 1988. J. Physiol. [Lond.]. 403:151-192). Our results provide no support for the hypothesis that Ca(2+)-induced Ca2+ release plays a significant role in excitation-contraction coupling in amphibian skeletal muscle.     

Sarcomere mechanics in uniform and non-uniform cardiac muscle: a link between pump function and arrhythmias

Starling's Law and the well-known end-systolic pressure-volume relationship (ESPVR) of the left ventricle reflect the effect of sarcomere length (SL) on stress (sigma) development and shortening by myocytes in the uniform ventricle. We show here that tetanic contractions of rat cardiac trabeculae exhibit a sigma-SL relationship at saturating [Ca2+] that depends on sarcomere geometry in a manner similar to skeletal sarcomeres and the existence of opposing forces in cardiac muscle shortened below slack length. The sigma-SL-[Ca2+]free relationships (sigma-SL-CaR) at submaximal [Ca2+] in intact and skinned trabeculae were similar, albeit that the sensitivity for Ca2+ of intact muscle was higher. We analyzed the mechanisms underlying the sigma-SL-CaR using a kinetic model where we assumed that the rates of Ca2+ binding by Troponin-C (Tn-C) and/or cross-bridge (XB) cycling are determined by SL, [Ca2+] or stress. We analyzed the correlation between the model results and steady state stress measurements at varied SL and [Ca2+] from skinned rat cardiac trabeculae to test the hypotheses that: (i) the dominant feedback mechanism is SL, stress or [Ca2+]-dependent; and (ii) the feedback mechanism regulates: Tn-C-Ca2+ affinity, XB kinetics or, unitary XB-force. The analysis strongly suggests that feedback of the number of strong XBs to cardiac Tn-C-Ca2+ affinity is the dominant mechanism that regulates XB recruitment. Application of this concept in a mathematical model of twitch-stress accurately reproduced the sigma-SL-CaR and the time course of twitch-stress as well as the time course of intracellular [Ca2+]i. Modeling of the response of the cardiac twitch to rapid stress changes using the above feedback model uniquely predicted the occurrence of [Ca2+]i transients as a result of accelerated Ca2+ dissociation from Tn-C. The above concept has important repercussions for the non-uniformly contracting heart in which arrhythmogenic Ca2+ waves arise from weakened areas in cardiac muscle. These Ca2+ waves can reversibly be induced in muscle with non-uniform excitation contraction coupling (ECC) by the cycle of stretch and release in the border zone between the damaged and intact regions. Stimulus trains induced propagating Ca2+ waves and reversibly induced arrhythmias. We hypothesize that rapid force loss by sarcomeres in the border zone during relaxation causes Ca2+ release from Tn-C and initiates Ca2+ waves propagated by the sarcoplasmic reticulum (SR). These observations suggest the unifying hypothesis that force feedback to Ca2+ binding by Tn-C is responsible for Starling's Law and the ESPVR in uniform myocardium and leads in non-uniform myocardium to a surge of Ca2+ released by the myofilaments during relaxation, which initiates arrhythmogenic propagating Ca2+ release by the SR.     

Effect of luminal calcium on Ca2+ release channel activity of sarcoplasmic reticulum in situ.

Ca2+ influx into empty SR in the absence of Ca2+ pump activity was determined in skinned frog skeletal muscle fibers and compared with Ca2+ efflux from loaded SR (i.e., Ca2+ release) to deepen our understanding of the properties of the Ca2+ release channel (CRC). Calcium content in SR increased approximately in a first-order kinetics and finally reached the equilibrium level determined by cytoplasmic Ca2+ ([Ca2+]c). Because AMP caused an increase in the rate of Ca2+ influx, and procaine, Mg2+, and high concentrations of Ca2+ caused a characteristic decrease, the major Ca2+ influx pathway was concluded to be the CRC, as is true of Ca2+ release. The apparent rate constant (k(app)) of Ca2+ efflux did not significantly change when the loading level was decreased to one-third. At a given [Ca2+]c, the same equilibrium level of calcium in SR was attained with a similar k(app) by both Ca2+ influx and Ca2+ efflux. The relationship between [Ca2+]c and calcium in SR indicated the Ca2+ binding sites in SR. These results, together with the anticipated effects of these Ca2+ buffer sites on kinetics, are consistent with the idea that luminal Ca2+ inhibits the CRC.     

Phosphatidylinositol 4,5-bisphosphate enhances calcium release from sarcoplasmic reticulum of skeletal muscle

In the course of our study on the function of sarcoplasmic reticulum (SR) in skeletal muscle, the stimulatory action of phosphatidylinositol 4,5-bisphosphate (PIP2) on the Ca2+ release from SR was demonstrated by using chemically skinned fibers and fragmented SR vesicles. PIP2 induced a tension spike followed by sustained contraction in skinned fibers. PIP2 enhanced the caffeine-induced Ca2+ release from SR vesicles at low concentrations and triggered Ca2+ release by itself at high concentrations. PIP2 also enhanced 45Ca2+ efflux from SR vesicles. However, inositol 1,4,5-triphosphate never produced these effects. The Ca2+-releasing action of PIP2 was only weakly affected by ruthenium red or procaine. These observations suggest that PIP2 activates an SR Ca2+ release channel whose properties are different from those of the Ca2+-induced Ca2+ release channel.     

The heavy metal ions Ag+ and Hg2+ trigger calcium release from cardiac sarcoplasmic reticulum

Heavy metal ions have been shown to induce Ca2+ release from skeletal sarcoplasmic reticulum (SR) by binding to free sulfhydryl groups on a Ca2+ channel protein and are now examined in cardiac SR. Ag+ and Hg2+ (at 10-25 microM) induced Ca2+ release from isolated canine cardiac SR vesicles whereas Ni2+, Cd2+, and Cu2+ had no effect at up to 200 microM. Ag(+)-induced Ca2+ release was measured in the presence of modulators of SR Ca2+ release was compared to Ca2(+)-induced Ca2+ release and was found to have the following characteristics. (i) Ag(+)-induced Ca2+ release was dependent on free [Mg2+], such that rates of efflux from actively loaded SR vesicles increased by 40% in 0.2 to 1.0 mM Mg2+ and decreased by 50% from 1.0 to 10.0 mM Mg2+. (ii) Ruthenium red (2-20 microM) and tetracaine (0.2-1.0 mM), known inhibitors of SR Ca2+ release, inhibited Ag(+)-induced Ca2+ release. (iii) Adenine nucleotides such as cAMP (0.25-2.0 mM) enhanced Ca2(+)-induced Ca2+ release, and stimulated Ag(+)-induced Ca2+ release. (iv) Low Ag+ to SR protein ratios (5-50 nmol Ag+/mg protein) stimulated Ca2(+)-dependent ATPase activity in Triton X-100-uncoupled SR vesicles. (v) At higher ratios of Ag+ to SR proteins (50-250 nmol Ag+/mg protein), the rate of Ca2+ efflux declined and Ca2(+)-dependent ATPase activity decreased gradually, up to a maximum of 50% inhibition. (vi) Ag+ stimulated Ca2+ efflux from passively loaded SR vesicles (i.e., in the absence of ATP and functional Ca2+ pumps), indicating a site of action distinct from the SR Ca2+ pump. Thus, at low Ag+ to SR protein ratios, Ag+ is very selective for the Ca2+ release channel. At higher ratios, this selectivity declines as Ag+ also inhibits the activity of Ca2+,Mg2(+)-ATPase pumps. Ag+ most likely binds to one or more sulfhydryl sites "on" or "adjacent" to the physiological Ca2+ release channel in cardiac SR to induce Ca2+ release.