Increasing ryanodine receptor open probability alone does not produce arrhythmogenic calcium waves: threshold sarcoplasmic reticulum calcium content is required

Diastolic waves of Ca(2+) release have been shown to activate delayed afterdepolarizations as well as some cardiac arrhythmias. The aim of this study was to investigate whether increasing ryanodine receptor open probability alone or in the presence of beta-adrenergic stimulation produces diastolic Ca release from the sarcoplasmic reticulum (SR). When voltage-clamped rat ventricular myocytes were exposed to caffeine (0.5 to 1.0 mmol), diastolic Ca(2+) release was seen to accompany the first few stimuli but was never observed in the steady state. We attribute the initial phase of diastolic Ca(2+) release to a decrease in the threshold SR Ca(2+) content required to activate Ca(2+) waves and its subsequent disappearance to a decrease of SR content below this threshold. Application of isoproterenol (1 micromol/L) increased the amplitude of the systolic Ca(2+) transient and also the SR Ca(2+) content but did not usually produce diastolic Ca(2+) release. Subsequent addition of caffeine, however, resulted in diastolic Ca(2+) release. We estimated the time course of recovery of SR Ca(2+) content following recovery from emptying with a high (10 mmol/L) concentration of caffeine. Diastolic Ca(2+) release recommenced only when SR content had increased back to its final level. We conclude that increasing ryanodine receptor open probability alone does not produce arrhythmogenic diastolic Ca(2+) release because of the accompanying decrease of SR Ca(2+) content. beta-Adrenergic stimulation increases SR content and thereby allows the increased ryanodine receptor open probability to produce diastolic Ca(2+) release. The implications of these results for arrhythmias associated with abnormal ryanodine receptors are discussed.     

Effects of ryanodine and caffeine on contractility, membrane voltage, and calcium exchange in cultured heart cells

To investigate the mechanisms of action of ryanodine and caffeine, changes in mechanical and electrical activity caused by these agents were correlated with alterations in 45Ca fluxes and cell Ca contents in chick embryo ventricular cell monolayer cultures. Ryanodine (10(-10)-10(-5) M) irreversibly decreased contraction amplitude by 10-70% relative to control in a concentration-dependent manner with minimal effects on electrical activity. Ryanodine caused a slight decrease in rapid 45Ca uptake, but no change in total exchangeable calcium content or rapid 45Ca efflux. Caffeine (1-20 mM) caused a transient (less than 10 seconds) 5-12% increase in contraction amplitude followed by a sustained 9-76% decrease in contraction amplitude and a 10 mV decrease in diastolic membrane voltage. Caffeine caused a decrease in rapid 45Ca uptake, a decrease in total exchangeable calcium content, and an increase in rapid 45Ca efflux. These results suggest that caffeine produces a decrease in sarcoplasmic reticulum (SR) Ca2+ uptake, and/or an increase in SR Ca2+ release that eventually depletes the SR of Ca2+, presumably accounting for the negative inotropic effect. The ryanodine effects on contraction are more difficult to account for solely in terms of alterations of transsarcolemmal Ca2+ fluxes and Ca2+ contents. Our data indicate an important role for the SR in excitation-contraction coupling in cultured chick embryo ventricular cells and suggest that SR Ca2+ is part of the rapidly exchanging Ca2+ compartment noted in 45Ca flux studies.     

Sarcoplasmic reticulum calcium content fluctuation is the key to cardiac alternans

The aim of this work was to investigate whether beat-to-beat alternation in the amplitude of the systolic Ca(2+) transient (Ca(2+) alternans) is due to changes of sarcoplasmic reticulum (SR) Ca(2+) content, and if so, whether the alternans arises due to a change in the gain of the feedback controlling SR Ca(2+) content. We found that, in rat ventricular myocytes, stimulating with small (20 mV) depolarizing pulses produced alternans of the amplitude of the Ca(2+) transient. Confocal measurements showed that the larger transients resulted from propagation of Ca(2+) waves. SR Ca(2+) content (measured from caffeine-evoked membrane currents) alternated in phase with the alternans of Ca(2+) transient amplitude. After a large transient, if SR Ca(2+) content was elevated by brief exposure of the cell to a Na(+)-free solution, then the alternans was interrupted and the next transient was also large. This shows that changes of SR Ca(2+) content are sufficient to produce alternans. The dependence of Ca(2+) transient amplitude on SR content was steeper under alternating than under control conditions. During alternation, the Ca(2+) efflux from the cell was also a steeper function of SR Ca(2+) content than under control. We attribute these steeper relationships to the fact that the larger responses in alternans depend on wave propagation and that wave propagation is a steep function of SR Ca(2+) content. In conclusion, alternans of systolic Ca(2+) appears to depend on alternation of SR Ca(2+) content. This, in turn results from the steep dependence on SR Ca(2+) content of Ca(2+) release and therefore Ca(2+) efflux from the cell as a consequence of wave propagation.     

S100A1 increases the gain of excitation-contraction coupling in isolated rabbit ventricular cardiomyocytes

The effect of S100A1 protein on cardiac excitation-contraction (E-C) coupling was studied using recombinant human S100A1 protein (0.01-10 microM) introduced into single rabbit ventricular cardiomyocytes via a patch pipette. Voltage clamp experiments (20 degrees C) indicated that 0.1 microM S100A1 increased Ca(2+) transient amplitude by approximately 41% but higher or lower S100A1 concentrations had no significant effect. L-type Ca(2+) current amplitude or Ca(2+) efflux rates via the Na(+)/Ca(2+) exchanger (NCX) were unaffected. The rate of Ca(2+) uptake associated with the SR Ca(2+)-ATPase (SERCA2a) was increased by approximately 22% with 0.1 microM S100A1, but not at other S100A1 concentrations. Based on the intracellular Ca(2+) and I(NCX) signals in response to 10 mM caffeine, no significant change in SR Ca(2+) content was observed with S100A1 (0.01-10 microM). Therefore, 0.1 microM S100A1 appeared to increase the fractional Ca(2+) release from the SR. This result was confirmed by measurements of Ca(2+) transient amplitude at a range of SR Ca(2+) contents. The hyperbolic relationship between these two parameters was shifted to the left by 0.1 microM S100A1. [(3)H]-ryanodine binding studies indicated that S100A1 increased ryanodine receptor (RyR) activity at 0.1 and 0.3 microM Ca(2). As with the effects on E-C coupling, 0.1 microM S100A1 produced the largest effect. Co-immunoprecipitation studies on a range of Ca(2+)-handling proteins support the selective interaction of S100A1 on SERCA2a and RyR. In summary, S100A1 had a stimulatory action on RyR2 and SERCA2a in rabbit cardiomyocytes. Under the conditions of this study, the net effect of this dual action is to enhance the Ca(2+) transient amplitude without significantly affecting the SR Ca(2+) content.     

Coordinated control of cell Ca(2+) loading and triggered release from the sarcoplasmic reticulum underlies the rapid inotropic response to increased L-type Ca(2+) current

The aim of this study was to investigate how sarcoplasmic reticulum (SR) Ca(2+) content and systolic Ca(2+) are controlled when Ca(2+) entry into the cell is varied. Experiments were performed on voltage-clamped rat and ferret ventricular myocytes loaded with fluo-3 to measure intracellular Ca(2+) concentration ([Ca(2+)](i)). Increasing external Ca(2+) concentration ([Ca(2+)](o)) from 1 to 2 mmol/L increased the amplitude of the systolic Ca(2+) transient with no effect on SR Ca(2+) content. This constancy of SR content is shown to result because the larger Ca(2+) transient activates a larger Ca(2+) efflux from the cell that balances the increased influx. Decreasing [Ca(2+)](o) to 0.2 mmol/L decreased systolic Ca(2+) but produced a small increase of SR Ca(2+) content. This increase of SR Ca(2+) content is due to a decreased release of Ca(2+) from the SR resulting in decreased loss of Ca(2+) from the cell. An increase of [Ca(2+)](o) has two effects: (1) increasing the fraction of SR Ca(2+) content, which is released on depolarization and (2) increasing Ca(2+) entry into the cell. The results of this study show that the combination of these effects results in rapid changes in the amplitude of the systolic Ca(2+) transient. In support of this, the changes of amplitude of the transient occur more quickly following changes of [Ca(2+)](o) than following refilling of the SR after depletion with caffeine. We conclude that the coordinated control of increased Ca(2+) entry and greater fractional release of Ca(2+) is an important factor in regulating excitation-contraction coupling.     

Extreme sarcoplasmic reticulum volume loss and compensatory T-tubule remodeling after Serca2 knockout

Cardiomyocyte contraction and relaxation are controlled by Ca(2+) handling, which can be regulated to meet demand. Indeed, major reduction in sarcoplasmic reticulum (SR) function in mice with Serca2 knockout (KO) is compensated by enhanced plasmalemmal Ca(2+) fluxes. Here we investigate whether altered Ca(2+) fluxes are facilitated by reorganization of cardiomyocyte ultrastructure. Hearts were fixed for electron microscopy and enzymatically dissociated for confocal microscopy and electrophysiology. SR relative surface area and volume densities were reduced by 63% and 76%, indicating marked loss and collapse of the free SR in KO. Although overall cardiomyocyte dimensions were unaltered, total surface area was increased. This resulted from increased T-tubule density, as revealed by confocal images. Fourier analysis indicated a maintained organization of transverse T-tubules but an increased presence of longitudinal T-tubules. This demonstrates a remarkable plasticity of the tubular system in the adult myocardium. Immunocytochemical data showed that the newly grown longitudinal T-tubules contained Na(+)/Ca(2+)-exchanger proximal to ryanodine receptors in the SR but did not contain Ca(2+)-channels. Ca(2+) measurements demonstrated a switch from SR-driven to Ca(2+) influx-driven Ca(2+) transients in KO. Still, SR Ca(2+) release constituted 20% of the Ca(2+) transient in KO. Mathematical modeling suggested that Ca(2+) influx via Na(+)/Ca(2+)-exchange in longitudinal T-tubules triggers release from apposing ryanodine receptors in KO, partially compensating for reduced SERCA by allowing for local Ca(2+) release near the myofilaments. T-tubule proliferation occurs without loss of the original ordered transverse orientation and thus constitutes the basis for compensation of the declining SR function without structural disarrangement.     

ATP-dependent effects of halothane on SR Ca2+ regulation in permeabilized atrial myocytes

OBJECTIVE: Previous work suggests that modification of sarcoplasmic reticulum (SR) function may contribute to the cardioprotective effect of halothane during ischaemia and reperfusion. The aim of this study was to investigate the effects of halothane on spontaneous Ca(2+) release from the sarcoplasmic reticulum (Ca(2+) sparks and waves). METHODS: Rat atrial myocytes were permeabilized with saponin and perfused with solutions approximating to the intracellular milieu and containing fluo-3. SR Ca(2+) release was detected using confocal microscopy. RESULTS: In the presence of 5 mM ATP, halothane (0.25-2 mM) had no significant effect on the amplitude or frequency of spontaneous Ca(2+) waves. However, in the presence of 0.05 mM ATP, halothane (0.25-2 mM) induced a concentration-dependent decrease in the amplitude and an increase in the frequency of spontaneous Ca(2+) waves, e.g., 1 mM halothane decreased the amplitude by 34.7+/-3.5% (n=9) and increased the frequency by 67+/-19.9% (n=7). In the presence of 5 mM ATP, 1 mM halothane had no significant effect on the amplitude or frequency of Ca(2+) sparks. When [ATP] was reduced to 0.05 mM, Ca(2+) spark frequency decreased by 67.9+/-14% and the amplitude increased by 27.5+/-4.9% (n=13). Subsequent introduction of halothane (0.5-1 mM) induced a transient burst of Ca(2+) sparks, consistent with ryanodine receptor (RyR) activation. Further experiments showed that the decrease in Ca(2+) spark frequency following ATP depletion was associated with a progressive increase in the SR Ca(2+) content over 1-2 min. This rise in SR Ca(2+) content did not occur when 1 mM halothane was present during ATP depletion. CONCLUSIONS: These data suggest that the sensitivity of the RyR to activation by halothane increases at low [ATP]. In metabolically impaired cells, halothane would be expected to lessen any rise in SR Ca(2+) content and to reduce the amplitude of spontaneous Ca(2+) release. These effects of halothane are considered in relation to the events that occur during ischaemia and reperfusion.     

Spatiotemporal characteristics of SR Ca(2+) uptake and release in detubulated rat ventricular myocytes

In cardiac ventricular myocytes, sarcoplasmic reticulum (SR) Ca(2+) load is a key determinant of SR Ca(2+) release. This release normally occurs predominantly from SR junctions at sarcolemmal invaginations (t-tubules), ensuring synchronous SR Ca(2+) release throughout the cell. However under conditions of Ca(2+) overload, spontaneous SR Ca(2+) release and propagating Ca(2+) waves can occur, which are pro-arrhythmic. We used detubulated rat ventricular myocytes to determine the dependence of Ca(2+) wave propagation on SR Ca(2+) load, and the role of t-tubules in SR Ca(2+) uptake and spontaneous release. After SR Ca(2+) depletion, recovery of Ca(2+) transient amplitude (and SR Ca(2+) load) was slower in detubulated than control myocytes (half-maximal recovery: 9.9+/-1.4 vs. 5.5+/-0.7 beats). In detubulated myocytes the extent and velocity of Ca(2+) propagation from the cell periphery increased with each beat and depended steeply on SR Ca(2+) load. Isoproterenol (ISO) accelerated recovery, increased maximal propagation velocity and reduced the threshold SR Ca(2+) load for propagation. Ca(2+) spark frequency was uniform across control cell width and was similar at the periphery of detubulated cells. However, internal Ca(2+) spark frequency in detubulated cells was 75% lower (despite comparable local SR Ca(2+) load); this transverse spark frequency profile was similar to that in atrial myocytes. We conclude that: (1) t-tubule Ca(2+) fluxes normally control SR Ca(2+) refilling; (2) Ca(2+) wave propagation depends steeply on SR Ca(2+) content (3) SR-t-tubule junctions are important in initiating SR Ca(2+) release and (4) ISO enhances propagation of SR Ca release, but not the initiation of SR Ca release events (for given SR Ca(2+) loads).     

Beta-adrenergic enhancement of sarcoplasmic reticulum calcium leak in cardiac myocytes is mediated by calcium/calmodulin-dependent protein kinase

Enhanced cardiac diastolic Ca leak from the sarcoplasmic reticulum (SR) ryanodine receptor may reduce SR Ca content and contribute to arrhythmogenesis. We tested whether beta-adrenergic receptor (beta-AR) agonists increased SR Ca leak in intact rabbit ventricular myocytes and whether this depends on protein kinase A or Ca/calmodulin-dependent protein kinase II (CaMKII) activity. SR Ca leak was assessed by acute block of the ryanodine receptor by tetracaine and assessment of the consequent shift of Ca from cytosol to SR (measured at various SR Ca loads induced by varying frequency). Cytosolic [Ca] ([Ca](i)) and SR Ca load ([Ca](SRT)) were assessed using fluo-4. beta-AR activation by isoproterenol dramatically increased SR Ca leak. However, this effect was not inhibited by blocking protein kinase A by H-89, despite the expected reversal of the isoproterenol-induced enhancement of Ca transient amplitude and [Ca](i) decline rate. In contrast, inhibitors of CaMKII, KN-93, or autocamtide-2-related inhibitory peptide II or beta-AR blockade reversed the isoproterenol-induced enhancement of SR Ca leak, and CaMKII inhibition could even reduce leak below control levels. Forskolin, which bypasses the beta-AR in activating adenylate cyclase and protein kinase A, did not increase SR Ca leak, despite robust enhancement of Ca transient amplitude and [Ca](i) decline rate. The results suggest that beta-AR stimulation enhances diastolic SR Ca leak in a manner that is (1) CaMKII dependent, (2) not protein kinase A dependent, and 3) not dependent on bulk [Ca](i).     

What role does modulation of the ryanodine receptor play in cardiac inotropy and arrhythmogenesis?

In this article we review the role of the Ryanodine Receptor (RyR) in cardiac inotropy and arrhythmogenesis. Most of the calcium that activates cardiac contraction comes from the sarcoplasmic reticulum (SR) from where it is released through the RyR. The amplitude of the systolic Ca transient depends steeply on the SR Ca content and it is therefore important that SR content be regulated. This regulation occurs via changes of SR Ca content affecting systolic Ca and thence sarcolemmal Ca fluxes. In the steady state, the cardiac myocyte must be in Ca flux balance on each beat and this has implications for understanding even simple inotropic manoeuvres. The main part of the review considers the effects of modulating the RyR on systolic Ca. Potentiation of RyR opening produces an increase of the amplitude of the Ca transient but this effect disappears within a few beats because the increased sarcolemmal efflux of Ca decreases SR Ca content. We conclude that it is therefore unlikely that potentiation of the RyR by phosphorylation plays a dominant role in the actions of positive inotropic agents such as β-adrenergic stimulation. Some cardiac arrhythmias result from release of Ca from the SR in the form of waves. This is best known to occur when the SR is overloaded with calcium. Mutations in the RyR also produce cardiac arrhythmias attributed to Ca waves due to leaky RyRs and a similar leak has been suggested to contribute to arrhythmias in heart failure. We show that, due to compensatory changes of SR Ca content, simply making the RyR leaky does not produce Ca waves in the steady state and that SR Ca content is critical in determining whether Ca waves occur.     

Local Ca(2+) signaling and EC coupling in heart: Ca(2+) sparks and the regulation of the [Ca(2+)](i) transient

The elementary event of Ca(2+) release in heart is the Ca(2+) spark. It occurs at a low rate during diastole, activated only by the low cytosolic [Ca(2+)](i). Synchronized activation of many sparks is due to the high local [Ca(2+)](i) in the region surrounding the sarcoplasmic reticulum (SR) Ca(2+) release channels and is responsible for the systolic [Ca(2+)](i) transient. The biophysical basis of this calcium signaling is discussed. Attention is placed on the local organization of the ryanodine receptors (SR Ca(2+) release channels, RyRs) and the other proteins that underlie and modulate excitation-contraction (EC) coupling. A brief review of specific elements that regulate SR Ca(2+) release (including SR lumenal Ca(2+) and coupled gating of RyRs) is presented. Finally integrative calcium signaling in heart is presented in the context of normal heart function and heart failure.     

K201 modulates excitation-contraction coupling and spontaneous Ca2+ release in normal adult rabbit ventricular cardiomyocytes

OBJECTIVES: The drug K201 (JTV-519) increases inotropy and suppresses arrhythmias in failing hearts, but the effects of K201 on normal hearts is unknown. METHODS: The effect of K201 on excitation-contraction (E-C) coupling in normal myocardium was studied by using voltage-clamp and intracellular Ca(2+) measurements in intact cells. Sarcoplasmic reticulum (SR) function was assessed using permeabilised cardiomyocytes. RESULTS: Acute application of <1 micromol/L K201 had no significant effect on E-C coupling. K201 at 1 micromol/L decreased Ca(2+) transient amplitude (to 83+/-7%) without affecting I(Ca,L) or the SR Ca(2+) content. At 3 micromol/L K201 caused a larger reduction of Ca(2+) transient amplitude (to 60+/-7%) with accompanying reductions in I(Ca,L) amplitude (to 66+/-8%) and SR Ca(2+) content (74+/-9%). Spontaneous SR Ca(2+) release during diastole was induced by increasing intracellular [Ca(2+)]. At 1 micromol/L K201 reduced the frequency of spontaneous Ca(2+) release. The effect of K201 on SR-mediated Ca(2+) waves and Ca(2+) sparks was examined in beta-escin-permeabilised cardiomyocytes by confocal microscopy. K201 (1 micromol/L) reduced the frequency and velocity of SR Ca(2+) waves despite no change in SR Ca(2+) content. At 3 micromol/L K201 completely abolished Ca(2+) waves and reduced the SR Ca(2+) content (to approximately 73%). K201 at 1 micromol/L reduced Ca(2+) spark amplitude and frequency. Assays specific to SR Ca(2+)-ATPase and RyR2 activity indicated that K201 inhibited both SR Ca(2+) uptake and release. CONCLUSIONS: K201 modifies E-C coupling in normal cardiomyocytes. A dual inhibitory action on SERCA and RyR2 explains the ability of K201 to suppress spontaneous diastolic Ca(2+) release during Ca(2+) overload without significantly affecting Ca(2+) transient amplitude.     

Effects of eicosapentaenoic acid on cardiac SR Ca(2+)-release and ryanodine receptor function

n-3 polyunsaturated fatty acids (PUFAs) can prevent life-threatening arrhythmias but the mechanisms responsible have not been established. There is strong evidence that part of the antiarrhythmic action of PUFAs is mediated through inhibition of the Ca(2+)-release mechanism of the sarcoplasmic reticulum (SR). It has also been shown that PUFAs activate protein kinase A (PKA) and produce effects in the cardiac cell similar to beta-adrenergic stimulation. We have investigated whether the inhibitory effect of PUFAs on the Ca(2+)-release mechanism is caused by direct inhibition of the SR Ca(2+)-release channel/ryanodine receptor (RyR) or requires activation of PKA. Experiments in intact cells under voltage-clamp show that the n-3 PUFA eicosapentaenoic acid (EPA) is able to reduce the frequency of spontaneous waves of Ca(2+)-release while increasing SR Ca(2+) content even when PKA activity is inhibited with H-89. This suggests that the EPA-induced inhibition of SR Ca(2+)-release is not dependent on activation of PKA. Consistent with this, single-channel studies demonstrate that EPA (10-100 microM), but not saturated fatty acids, reduce the open probability (Po) of the cardiac RyR incorporated into phospholipid bilayers. EPA also inhibited the binding of [3H]ryanodine to isolated heavy SR. Our results indicate that direct inhibition of RyR channel gating by PUFAs play an important role in the overall antiarrhythmic properties of these compounds.     

Ca(2+) signaling in cardiac myocytes overexpressing the alpha(1) subunit of L-type Ca(2+) channel

Voltage-gated L-type Ca(2+) channels (LCCs) provide Ca(2+) ingress into cardiac myocytes and play a key role in intracellular Ca(2+) homeostasis and excitation-contraction coupling. We investigated the effects of a constitutive increase of LCC density on Ca(2+) signaling in ventricular myocytes from 4-month-old transgenic (Tg) mice overexpressing the alpha(1) subunit of LCC in the heart. At this age, cells were somewhat hypertrophic as reflected by a 20% increase in cell capacitance relative to those from nontransgenic (Ntg) littermates. Whole cell I(Ca) density in Tg myocytes was elevated by 48% at 0 mV compared with the Ntg group. Single-channel analysis detected an increase in LCC density with similar conductance and gating properties. Although the overexpressed LCCs triggered an augmented SR Ca(2+) release, the "gain" function of EC coupling was uncompromised, and SR Ca(2+) content, diastolic cytosolic Ca(2+), and unitary properties of Ca(2+) sparks were unchanged. Importantly, the enhanced I(Ca) entry and SR Ca(2+) release were associated with an upregulation of the Na(+)-Ca(2+) exchange activity (indexed by the half decay time of caffeine-elicited Ca(2+) transient) by 27% and SR Ca(2+) recycling by approximately 35%. Western analysis detected a 53% increase in the Na(+)-Ca(2+) exchanger expression but no change in the abundance of ryanodine receptor (RyR), SERCA2, and phospholamban. Analysis of I(Ca) kinetics suggested that SR Ca(2+) release-dependent inactivation of LCCs remains intact in Tg cells. Thus, in spite of the modest cardiac hypertrophy, the overexpressed LCCs form functional coupling with RyRs, preserving both orthograde and retrograde Ca(2+) signaling between LCCs and RyRs. These results also suggest that a modest but sustained increase in Ca(2+) influx triggers a coordinated remodeling of Ca(2+) handling to maintain Ca(2+) homeostasis.     

Type 3 ryanodine receptors of skeletal muscle are segregated in a parajunctional position

A key event in skeletal muscle activation is the rapid release of Ca(2+) from the sarcoplasmic reticulum (SR), the Ca(2+) storage organelle in the muscle cell. The surface membrane/transverse tubules and the SR form functional units (calcium release units containing one or two couplons or junctions), where the voltage-sensing dihydropyridine receptor of the surface membrane interacts with the SR Ca(2+) release channel [ryanodine receptor (RyR)] and depolarization of the cell membrane is converted into Ca(2+) release from the SR. Although RyR1 is the most important isoform in skeletal muscle, some muscles also express high levels of RyR3, an isoform with a wide tissue distribution. The cytoplasmic domains of RyRs are visible in the electron microscope as periodically disposed feet. We find that, in muscles containing only RyR1, feet are exclusively located over the junctional SR surface facing the surface membrane/transverse tubule. In muscles containing RyR1 as well as RyR3, additional feet are located in lateral parajunctional regions immediately adjacent to junctional SR. Biochemical content of RyR3 and content of parajunctional feet are highly correlated in different muscles and the disposition of parajunctional versus junctional feet are notably different. On the basis of these two observations, we postulate that RyR3s are restricted to the parajunctional region, and thus their activation must be indirect and derivative during excitation-contraction coupling.     

Ignition of calcium sparks in arterial and cardiac muscle through caveolae

Ca(2+) sparks are localized intracellular Ca(2+) events released through ryanodine receptors (RyRs) that control excitation-contraction coupling in heart and smooth muscle. Ca(2+) spark triggering depends on precise delivery of Ca(2+) ions through dihydropyridine (DHP)-sensitive Ca(2+) channels to RyRs of the sarcoplasmic reticulum (SR), a process requiring a very precise alignment of surface and SR membranes containing Ca(2+) influx channels and RyRs. Because caveolae contain DHP-sensitive Ca(2+) channels and may colocalize with SR, we tested the hypothesis that caveolae are the structural element necessary for the generation of Ca(2+) sparks. Using methyl-ss-cyclodextrin (dextrin) to deplete caveolae, we found that dextrin dose-dependently decreased the frequency, amplitude, and spatial size of Ca(2+) sparks in arterial smooth muscle cells and neonatal cardiomyocytes. However, temporal characteristics of Ca(2+) sparks were not significantly affected. We ruled out the possibility that the decreases in Ca(2+) spark frequency and size are caused by changes in DHP-sensitive L-type channels, SR Ca(2+) load, or changes in membrane potential. Our results suggest a novel signaling model that explains the formation of Ca(2+) sparks in a caveolae microdomain. The transient elevation in [Ca(2+)](i) at the inner mouth of a single caveolemmal Ca(2+) channel induces simultaneous activation and thus opens several RyRs to generate a local Ca(2+) release event, a Ca(2+) spark. Alterations in the molecular assembly and ultrastructure of caveolae may lead to pathophysiological changes in Ca(2+) signaling. Thus, caveolae may be intimately involved in cardiovascular cell dysfunction and disease.     

Sorcin interacts with sarcoplasmic reticulum Ca2+–ATPase and modulates excitation–contraction coupling in the heart

Sorcin is a 21.6-kDa Ca(2+) binding protein of the penta-EF hand family. Several studies have shown that sorcin modulates multiple proteins involved in excitation-contraction (E-C) coupling in the heart, such as the cardiac ryanodine receptor (RyR2), L-type Ca(2+) channel, and Na(+)-Ca(2+) exchanger, while it has also been shown to be phosphorylated by cAMP-dependent protein kinase (PKA). To elucidate the effects of sorcin and its PKA-dependent regulation on E-C coupling in the heart, we identified the PKA-phosphorylation site of sorcin, and found that serine178 was preferentially phosphorylated by PKA and dephosphorylated by protein phosphatase-1. Isoproterenol allowed sorcin to translocate to the sarcoplasmic reticulum (SR). In addition, adenovirus-mediated overexpression of sorcin in adult rat cardiomyocytes significantly increased both the rate of decay of the Ca(2+) transient and the SR Ca(2+) load. An assay of oxalate-facilitated Ca(2+) uptake showed that recombinant sorcin increased Ca(2+) uptake in a dose-dependent manner. These data suggest that sorcin activates the Ca(2+)-uptake function in the SR. In UM-X7. 1 cardiomyopathic hamster hearts, the relative amount of sorcin was significantly increased in the SR fraction, whereas it was significantly decreased in whole-heart homogenates. In failing hearts, PKA-phosphorylated sorcin was markedly increased, as assessed using a back-phosphorylation assay with immunoprecipitated sorcin. Our results suggest that sorcin activates Ca(2+)-ATPase-mediated Ca(2+) uptake and restores SR Ca(2+) content, and may play critical roles in compensatory mechanisms in both Ca(2+) homeostasis and cardiac dysfunction in failing hearts.     

Abnormal intracellular calcium homeostasis in sympathetic neurons from young prehypertensive rats

Hypertension is associated with cardiac noradrenergic hyperactivity, although it is not clear whether this precedes or follows the development of hypertension itself. We hypothesized that Ca(2+) homeostasis in postganglionic sympathetic neurons is impaired in spontaneously hypertensive rats (SHRs) and may occur before the development of hypertension. The depolarization-induced rise in intracellular free calcium concentration ([Ca(2+)](i); measured using fura-2-acetoxymethyl ester) was significantly larger in cultured sympathetic neurons from prehypertensive SHRs than in age matched normotensive Wistar-Kyoto rats. The decay of the [Ca(2+)](i) transient was also faster in SHRs. The endoplasmic reticulum Ca(2+) content and caffeine-induced [Ca(2+)](i) amplitude were significantly greater in the young SHRs. Lower protein levels of phospholamban and more copies of ryanodine receptor mRNA were also observed in the young SHRs. Depleting the endoplasmic reticulum Ca(2+) store did not alter the difference of the evoked [Ca(2+)](i) transient and decay time between young SHRs and Wistar-Kyoto rats. However, removing mitochondrial Ca(2+) buffering abolished these differences. A lower mitochondrial membrane potential was also observed in young SHR sympathetic neurons. This resulted in impaired mitochondrial Ca(2+) uptake and release, which might partly be responsible for the increased [Ca(2+)](i) transient and faster decay in SHR sympathetic neurons. This Ca(2+) phenotype seen in early development in cardiac stellate and superior cervical ganglion neurons may contribute to the sympathetic hyperresponsiveness that precedes the onset of hypertension.     

Potentiation of Ca(2+) release by cADP-ribose in the heart is mediated by enhanced SR Ca(2+) uptake into the sarcoplasmic reticulum

cADP-Ribose (cADPR) is a novel endogenous messenger that is believed to mobilize Ca(2+) from ryanodine-sensitive Ca(2+) stores. Despite intense research, the precise mechanism of action of cADPR remains uncertain, and experimental findings are contradictory. To elucidate the mechanism of cADPR action, we performed confocal Ca(2+) imaging in saponin-permeabilized rat ventricular myocytes. Exposure of the cells to cADPR resulted in a slow (>2 minutes) and steady increase in the frequency of Ca(2+) sparks. These effects on local release events were accompanied by a significant increase in sarcoplasmic reticulum (SR) Ca(2+) content. In comparison, sensitization of ryanodine receptors (RyRs) by caffeine, a true RyR agonist, caused a rapid (<1 second) and transient potentiation of Ca(2+) sparks followed by a decrease in SR Ca(2+) content. When the increase in the SR load was prevented by partial inhibition of the SR Ca(2+) with thapsigargin, cADPR failed to produce any increase in sparking activity. cADPR had no significant impact on activity of single cardiac RyRs incorporated into lipid bilayers. However, it caused a significant increase in the rate of Ca(2+) uptake by cardiac SR microsomes. Our results suggest that the primary target of cADPR is the SR Ca(2+) uptake mechanism. Potentiation of Ca(2+) release by cADPR is mediated by increased accumulation of Ca(2+) in the SR and subsequent luminal Ca(2+)-dependent activation of RyRs.