Differential modulation of L-type Ca2+ current by SR Ca2+ release at the T-tubules and surface membrane of rat ventricular myocytes

We have characterized modulation of ICa by Ca2+ at the t-tubules (ie, in control cells) and surface sarcolemma (ie, in detubulated cells) of cardiac ventricular myocytes, using the whole-cell patch clamp technique to record ICa. ICa inactivation was significantly slower in detubulated cells than in control cells (27.1+/-7.8 ms, n=22, versus 16.4+/-7.9 ms, n=22; P<0.05). In atrial myocytes, which lack t-tubules, ICa inactivation was not changed by the treatment used to produce detubulation. In the presence of ryanodine or BAPTA, or when Ba2+ was used as the charge carrier, the rate of inactivation was not significantly different in control and detubulated cells. Frequency-dependent facilitation occurred in control cells but not in detubulated cells, and was abolished by ryanodine. These results suggest that Ca2+ released from the SR has a greater effect on ICa in the t-tubules than at the surface sarcolemma. This does not appear to be due to differences in local Ca2+ release from the SR, because the gain of Ca2+ release was not significantly different in control and detubulated cells. These data suggest that the t-tubules are a key site for the regulation of transsarcolemmal Ca2+ flux by Ca2+ release from the SR; this could play a role in altered Ca2+ homeostasis in pathological conditions. The full text of this article is available online at http://circres.ahajournals.org.     

beta-adrenergic stimulation restores the Ca transient of ventricular myocytes lacking t-tubules

beta-adrenergic stimulation helps to synchronize Ca release in myocytes from failing hearts. Transverse (t-) tubules, which synchronize Ca release in normal cells and contain many of the elements of the beta-adrenergic pathway, may be depleted in such cells. The objective of the present study was to determine whether beta-adrenergic stimulation could reverse the desynchronization of Ca release observed in detubulated ventricular myocytes. The effect of isoprenaline (0.5 microM) on control and detubulated rat ventricular myocytes was investigated. Ca transients were monitored using whole-cell fluorescence and confocal microscopy, and Ca current recorded using the patch-clamp technique. Immunocytochemistry was used to investigate phospholamban (PLB) phosphorylation. Detubulation reduces and slows the Ca transient; these effects were reversed by isoprenaline. This restoration was associated with partial reversal of the desynchronization of Ca release that occurs in detubulated cells. Sarcoplasmic reticulum Ca load increased by the same amount in normal and detubulated cells, but Ca current increased less in detubulated cells (64%) than in control cells (124%) in response to isoprenaline. The pattern and extent of cAMP-dependent protein kinase and CaMKII-induced phosphorylation of PLB in response to isoprenaline was the same in both cell types. Thus, the beta-adrenergic pathway is functional in the absence of t-tubules; such stimulation appears to increase the speed of propagation of Ca via Ca-induced Ca release between adjacent clusters of ryanodine receptors, which may be relevant in pathological conditions, such as heart failure, in which t-tubules are depleted. The data also suggest that the Ca current responds to local signaling pathways, which are better coupled to the channel in the t-tubules than at the surface membrane, whereas PLB responds to whole-cell signaling.     

t-Tubules and sarcoplasmic reticulum function in cardiac ventricular myocytes

Although the existence of t-tubules in mammalian cardiac ventricular myocytes has been recognized for a long time, it now appears that their structure and function are more complex than previously believed. Recent work has provided evidence that many of the key proteins underlying excitation-contraction coupling are located predominantly at the t-tubules. L-type Ca(2+) current (I(Ca)) flowing across the t-tubule membrane provides a rapidly inactivating Ca(2+) influx that triggers Ca(2+) release from the sarcoplasmic reticulum (SR), thereby allowing rapid and synchronous Ca(2+) release throughout the cell; I(Ca) at the t-tubules also appears to be more sensitive than that at the surface membrane to regulation by beta-adrenergic stimulation and intracellular Ca(2+). In contrast, although its density is lower, I(Ca) flowing across the surface membrane inactivates slowly, and thus may help load the SR with Ca(2+). There is also increasing evidence that many of the mechanisms that remove Ca(2+) from the cytoplasm are located predominantly at the t-tubules, which therefore play an important role in determining cellular, and hence SR, Ca(2+) content. Thus, the t-tubules appear to play a central role in the increase and subsequent decrease of Ca(2+) during the systolic Ca(2+) transient. Remodelling of the t-tubules has been reported in cardiac pathologies, and may play a role in the altered cellular, and hence cardiac, function observed in such conditions.     

Functional consequences of detubulation of isolated rat ventricular myocytes

OBJECTIVE: Recent work has suggested that Na(+)/Ca(2+) exchange (NCX) and L-type Ca(2+) current (I(Ca)) are located predominantly in the t-tubules of cardiac ventricular myocytes, which therefore represent a microdomain for the regulation of intracellular Na(+) (Na(i)) and Ca(2+) (Ca(i)). The aim of this study was to investigate the role of the t-tubules in the response of Ca(i) and contraction to interventions that alter the transsarcolemmal Na(+)gradient. METHODS: Enzymatically isolated and detubulated Wistar rat ventricular myocytes were investigated using fluorescence microscopy and optical detection of cell length. RESULTS: In unstimulated cells, spontaneous contractile activity increased when extracellular [Na(+)] was decreased or strophanthidin (100 microM) was added to the bathing solution, but the increase was significantly smaller in detubulated cells than in control cells. In electrically stimulated cells, strophanthidin increased Na(i) to a similar extent in normal and detubulated cells, although the associated increase in Ca(2+) transient amplitude and contraction were significantly smaller in detubulated cells. Similarly, tetrodotoxin (TTX, 10 microM) attenuated the Ca(2+) transient and contraction less in detubulated than in control cells. Increasing stimulation rate (0.05-1 Hz) caused little change or a small increase in contraction amplitude in control cells, but a significant decrease in contraction amplitude in detubulated cells, although the change of Na(i) caused by increasing stimulation rate from 0 to 1 Hz was not significantly different in the two cells types. CONCLUSION: It is concluded that although some Na/K ATPase, NCX and Na(+)channel activity is present on the surface membrane, the t-tubules play a major role in the modulation of contraction via NCX, allowing changes of the transsarcolemmal Na(+)gradient to be translated into changes of Ca(i).     

Ovariectomy enhances SR Ca²⁺ release and increases Ca²⁺ spark amplitudes in isolated ventricular myocytes

This study compared Ca(2+) homeostasis in ventricular myocytes from 8-month-old female C57BL/6J mice that had either a bilateral ovariectomy (OVX) or a sham surgery at 3 weeks of age. Cells were loaded with fura-2 and field-stimulated or voltage-clamped with steps to membrane potentials between -40 and +80 mV (37°C). Peak Ca(2+) transients increased by two-fold in OVX myocytes when compared to sham, and Ca(2+) transient rates of rise and decay were faster in OVX cells. In contrast, Ca(2+) current densities were similar in sham and OVX cells. Sarcoplasmic reticulum (SR) Ca(2+) content, assessed by caffeine, also was higher in OVX compared to sham cells (111.7 ± 11.9 vs. 61.2 ± 10.4 nM; p<0.05). Furthermore, the gain of Ca(2+) release (Ca(2+) release/Ca(2+) current) was significantly greater in OVX than in sham cells (16.3 ± 2.5 vs. 7.7 ± 2.0 nM/pApF(-1) at 0 mV; p<0.05). As changes in unitary Ca(2+) release might account for the increased gain in OVX cells, spontaneous Ca(2+) sparks were compared in fluo-4-loaded myocytes (37°C). Spark frequency was higher in OVX cells than in sham cells. In addition, spark amplitudes were greater in OVX than in sham myocytes (ΔF/F(0)=0.379 ± 0.006 vs. 0.342 ± 0.006; p<0.05). However, spark widths and time courses were similar in the two groups. These data suggest that the size of individual SR Ca(2+) release units is larger and the SR Ca(2+) content is greater in myocytes of OVX mice, producing augmented gain and SR Ca(2+) release. These observations show that OVX disrupts intracellular Ca(2+) homeostasis and suggest that sex steroid hormones modulate unitary Ca(2+) release in individual cardiac myocytes.     

Altered distribution of ICa impairs Ca release at the t-tubules of ventricular myocytes from failing hearts

In mammalian cardiac ventricular myocytes, Ca influx and release occur predominantly at t-tubules, ensuring synchronous Ca release throughout the cell. Heart failure is associated with disrupted t-tubule structure, but its effect on t-tubule function is less clear. We therefore investigated Ca influx and release at the t-tubules of ventricular myocytes isolated from rat hearts ~ 18 weeks after coronary artery ligation (CAL) or corresponding Sham operation. L-type Ca current (I_Ca) was recorded using the whole-cell voltage-clamp technique in intact and detubulated myocytes; Ca release at t-tubules was monitored using confocal microscopy with voltage- and Ca-sensitive fluorophores. CAL was associated with cardiac and cellular hypertrophy, decreased ejection fraction, disruption of t-tubule structure and a smaller, slower Ca transient, but no change in ryanodine receptor distribution, L-type Ca channel expression, or I_Ca density. In Sham myocytes, I_Ca was located predominantly at the t-tubules, while in CAL myocytes, it was uniformly distributed between the t-tubule and surface membranes. Inhibition of protein kinase A with H-89 caused a greater decrease of t-tubular I_Ca in CAL than in Sham myocytes; in the presence of H-89, t-tubular I_Ca density was smaller in CAL than in Sham myocytes. The smaller t-tubular I_Ca in CAL myocytes was accompanied by increased latency and heterogeneity of SR Ca release at t-tubules, which could be mimicked by decreasing I_Ca using nifedipine. These data show that CAL decreases t-tubular I_Ca via a PKA-independent mechanism, thereby impairing Ca release at t-tubules and contributing to the altered excitation–contraction coupling observed in heart failure.     

Na+-Ca2+ exchange activity is localized in the T-tubules of rat ventricular myocytes

Detubulation of rat ventricular myocytes has been used to investigate the role of the t-tubules in Ca2+ cycling during excitation-contraction coupling in rat ventricular myocytes. Ca2+ was monitored using fluo-3 and confocal microscopy. In control myocytes, electrical stimulation caused a spatially uniform increase in intracellular [Ca2+] across the cell width. After detubulation, [Ca2+] rose initially at the cell periphery and then propagated into the center of the cell. Application of caffeine to control myocytes resulted in a rapid and uniform increase of intracellular [Ca2+]; the distribution and amplitude of this increase was the same in detubulated myocytes, although its decline was slower. On application of caffeine to control cells, there was a large, rapid, and transient rise in extracellular [Ca2+] as Ca2+ was extruded from the cell; this rise was significantly smaller in detubulated cells, and the remaining increase was blocked by the sarcolemmal Ca2+ ATPase inhibitor carboxyeosin. The treatment used to produce detubulation had no significant effect on Ca2+ efflux in atrial cells, which lack t-tubules. Detubulation of ventricular myocytes also resulted in loss of Na+-Ca2+ exchange current, although the density of the fast Na+ current was unaltered. It is concluded that Na+-Ca2+ exchange function, and hence Ca2+ efflux by this mechanism, is concentrated in the t-tubules, and that the concentration of Ca2+ flux pathways in the t-tubules is important in producing a uniform increase in intracellular Ca2+ on stimulation.     

Ca efflux via the sarcolemmal Ca ATPase occurs only in the t-tubules of rat ventricular myocytes

The transverse (t-) tubule network is an important site for Ca influx and release during excitation-contraction coupling in cardiac ventricular myocytes; however, its role in Ca extrusion is less clear. The present study was designed to investigate the relative contributions of Ca extrusion pathways across the t-tubule and surface membranes. Ventricular myocytes were isolated from the hearts of adult male Wistar rats and detubulated using formamide. Intracellular Ca was monitored using fluo-3 and confocal microscopy. Caffeine (20 mmol/L) was used to induce SR Ca release; carboxyeosin (20 μmol/L) and nickel (10 mmol/L) were used to inhibit the sarcolemmal Ca ATPase and Na/Ca exchanger (NCX) respectively. Carboxyeosin decreased the rate constant of decay of the caffeine-induced Ca transient in control cells, but had no effect in detubulated cells, suggesting that Ca extrusion via the Ca ATPase occurs only across the t-tubule membrane. However nickel decreased the rate constant of the caffeine-induced Ca transient in control and detubulated cells, although its effect was greater in control cells, suggesting that Ca extrusion via NCX occurs across the surface and t-tubule membranes. The PKA inhibitor H-89 (10 μmol/L) was used to investigate the role of basal PKA activity in Ca extrusion; H-89 appeared to have no effect on Ca extrusion via the Ca ATPase, but reduced Ca extrusion via NCX at the t-tubules but not the surface membrane. Thus it appears that Ca extrusion via the sarcolemmal Ca ATPase occurs only at the t-tubules, and is not regulated by basal PKA activity, while Ca extrusion via NCX occurs across both the surface and t-tubule membranes, but predominantly across the t-tubule membrane due, in part, to localised stimulation of NCX by PKA at the t-tubules. This may be important in heart disease, in which changes in t-tubule structure and protein phosphorylation occur.     

Termination of cardiac Ca2+ sparks: role of intra-SR [Ca2+], release flux, and intra-SR Ca2+ diffusion

Ca(2+) release from cardiac sarcoplasmic reticulum (SR) via ryanodine receptors (RyRs) is regulated by dyadic cleft [Ca(2+)] and intra-SR free [Ca(2+)] ([Ca(2+)](SR)). Robust SR Ca(2+) release termination is important for stable excitation-contraction coupling, and partial [Ca(2+)](SR) depletion may contribute to release termination. Here, we investigated the regulation of SR Ca(2+) release termination of spontaneous local SR Ca(2+) release events (Ca(2+) sparks) by [Ca(2+)](SR), release flux, and intra-SR Ca(2+) diffusion. We simultaneously measured Ca(2+) sparks and Ca(2+) blinks (localized elementary [Ca(2+)](SR) depletions) in permeabilized ventricular cardiomyocytes over a wide range of SR Ca(2+) loads and release fluxes. Sparks terminated via a [Ca(2+)](SR)-dependent mechanism at a fixed [Ca(2+)](SR) depletion threshold independent of the initial [Ca(2+)](SR) and release flux. Ca(2+) blink recovery depended mainly on intra-SR Ca(2+) diffusion rather than SR Ca(2+) uptake. Therefore, the large variation in Ca(2+) blink recovery rates at different release sites occurred because of differences in the degree of release site interconnection within the SR network. When SR release flux was greatly reduced, long-lasting release events occurred from well-connected junctions. These junctions could sustain release because local SR Ca(2+) release and [Ca(2+)](SR) refilling reached a balance, preventing [Ca(2+)](SR) from depleting to the termination threshold. Prolonged release events eventually terminated at a steady [Ca(2+)](SR), indicative of a slower, [Ca(2+)](SR)-independent termination mechanism. These results demonstrate that there is high variability in local SR connectivity but that SR Ca(2+) release terminates at a fixed [Ca(2+)](SR) termination threshold. Thus, reliable SR Ca(2+) release termination depends on tight RyR regulation by [Ca(2+)](SR).     

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.     

beta-Adrenergic stimulation synchronizes intracellular Ca(2+) release during excitation-contraction coupling in cardiac myocytes

To elucidate microscopic mechanisms underlying the modulation of cardiac excitation-contraction (EC) coupling by beta-adrenergic receptor (beta-AR) stimulation, we examined local Ca(2+) release function, ie, Ca(2+) spikes at individual transverse tubule-sarcoplasmic reticulum (T-SR) junctions, using confocal microscopy and our recently developed technique for release flux measurement. beta-AR stimulation by norepinephrine plus an alpha(1)-adrenergic blocker, prazosin, increased the amplitude of SR Ca(2+) release flux (J(SR)), its running integral (integralJ(SR)), and L-type Ca(2+) channel current (I(Ca)), and it shifted their bell-shaped voltage dependence leftward by approximately 10 mV, with the relative effects ranking I(Ca)> J(SR)>integralJ(SR). Confocal imaging revealed that the bell-shaped voltage dependence of SR Ca(2+) release is attributable to a graded recruitment of T-SR junctions as well as to changes in Ca(2+) spike amplitudes. beta-AR stimulation increased the fractional T-SR junctions that fired Ca(2+) spikes and augmented Ca(2+) spike amplitudes, without altering the SR Ca(2+) load, suggesting that more release units were activated synchronously among and within T-SR junctions. Moreover, beta-AR stimulation decreased the latency and temporal dispersion of Ca(2+) spike occurrence at a given voltage, delivering most of the Ca(2+) at the onset of depolarization rather than spreading it out throughout depolarization. Because the synchrony of Ca(2+) spikes affects Ca(2+) delivery per unit of time to contractile myofilaments, and because the myofilaments display a steep Ca(2+) dependence, our data suggest that synchronization of SR Ca(2+) release represents a heretofore unappreciated mechanism of beta-AR modulation of cardiac inotropy.     

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.     

The RyR2 central domain peptide DPc10 lowers the threshold for spontaneous Ca2+ release in permeabilized cardiomyocytes

OBJECTIVE: In vitro experiments have shown that the ryanodine receptor-2 (RyR2) central domain peptide DPc10 (Gly(2460)-Pro(2495)) mimics channel dysfunction associated with catecholaminergic polymorphic ventricular tachycardia (CPVT) by acting competitively to reduce stabilizing interactions between the N-terminal and central domains. In the present study, DPc10 was used as a tool to establish an adult cell model of the disease and to analyse the underlying mechanisms. METHODS: Rat ventricular myocytes were permeabilized with saponin and perfused with solutions approximating the intracellular milieu containing fluo-3. Sarcoplasmic reticulum (SR) Ca(2+) release was detected using confocal microscopy. DPc10 (10 or 50 microM) was compared with 0.2 mM caffeine, which is known to activate RyR2 and to facilitate Ca(2+)-induced Ca(2+) release (CICR). RESULTS: Introduction of DPc10 induced a transient increase in spark frequency and a sustained rise in resting [Ca(2+)]. Under conditions causing initial Ca(2+) overload of the SR, DPc10 reduced the frequency and amplitude of spontaneous, propagated Ca(2+) release (SPCR). Following equilibration with 10microM DPc10, the cytosolic [Ca(2+)] threshold for SPCR was markedly reduced and the proportion of spontaneously active cells increased. Caffeine induced a similar, transient increase in spark frequency and a reduction in the [Ca(2+)] threshold for SPCR. However, unlike DPc10, caffeine increased SPCR frequency and had no sustained effect on resting [Ca(2+)]. These results suggest that the net effect of DPc10 (and CPVT mutations) on RyR2 function in situ is not only to increase the sensitivity to CICR as caffeine does, but also to potentiate Ca(2+) leakage from the SR. As SPCR can trigger delayed after-depolarisations, the decrease in [Ca(2+)] threshold may contribute to arrhythmias in CPVT patients during exercise or stress.     

No apparent requirement for neuronal sodium channels in excitation-contraction coupling in rat ventricular myocytes

The majority of Na channels in the heart are composed of the tetrodotoxin (TTX)-resistant (KD, 2 to 6 micromol/L) "cardiac" NaV1.5 isoform; however, TTX-sensitive (KD, 1 to 25 nmol/L) "neuronal" Na channel isoforms have recently been detected in several cardiac preparations. In the present study, we determined the functional subcellular localization of Na channel isoforms (according to their TTX sensitivity) in rat ventricular myocytes by recording INa in control and detubulated myocytes. We found that TTX-sensitive INa (KD, &8.8 nmol/L) makes up 14+/-3% of total INa in control and < or =4% in detubulated myocytes and calculated that &80% of TTX-sensitive INa is located in the t-tubules, where it generates &1/3 of t-tubular INa. In contrast, TTX-resistant INa is located predominantly (&78%) at the surface membrane. We also investigated the possible contribution of TTX-sensitive INa to excitation-contraction coupling, using 200 nmol/L TTX to selectively block TTX-sensitive INa. TTX decreased the rate of depolarization of the action potential by 10% but did not delay the rise of systolic Ca2+ in the center of the cell (transverse confocal line scan), suggesting that TTX-sensitive INa does not play a role in synchronizing Ca2+ release at the t-tubules; the amplitude of the Ca2+ transient and contraction were also unchanged by 200 nmol/L TTX. The quantity of charge entering via ICa elicited by control or TTX action potential waveforms was similar, suggesting that the trigger for Ca2+ release is not altered by blocking TTX-sensitive INa. We conclude that neuronal INa is concentrated at the t-tubules, but there is no evidence of a requirement for these channels in normal excitation-contraction coupling in ventricular myocytes.     

CaMKII inhibition targeted to the sarcoplasmic reticulum inhibits frequency-dependent acceleration of relaxation and Ca2+ current facilitation

Cardiac Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) in heart has been implicated in Ca(2+) current (I(Ca)) facilitation, enhanced sarcoplasmic reticulum (SR) Ca(2+) release and frequency-dependent acceleration of relaxation (FDAR) via enhanced SR Ca(2+) uptake. However, questions remain about how CaMKII may work in these three processes. Here we tested the role of CaMKII in these processes using transgenic mice (SR-AIP) that express four concatenated repeats of the CaMKII inhibitory peptide AIP selectively in the SR membrane. Wild type mice (WT) and mice expressing AIP exclusively in the nucleus (NLS-AIP) served as controls. Increasing stimulation frequency produced typical FDAR in WT and NLS-AIP, but FDAR was markedly inhibited in SR-AIP. Quantitative analysis of cytosolic Ca(2+) removal during [Ca(2+)](i) decline revealed that FDAR is due to an increased apparent V(max) of SERCA. CaMKII-dependent RyR phosphorylation at Ser2815 and SR Ca(2+) leak was both decreased in SR-AIP vs. WT. This decrease in SR Ca(2+) leak may partly balance the reduced SERCA activity leading to relatively unaltered SR-Ca(2+) load in SR-AIP vs. WT myocytes. Surprisingly, CaMKII regulation of the L-type Ca(2+) channel (I(Ca) facilitation and recovery from inactivation) was abolished by the SR-targeted CaMKII inhibition in SR-AIP mice. Inhibition of CaMKII effects on I(Ca) and RyR function by the SR-localized AIP places physical constraints on the localization of these proteins at the junctional microdomain. Thus SR-targeted CaMKII inhibition can directly inhibit the activation of SR Ca(2+) uptake, SR Ca(2+) release and I(Ca) by CaMKII, effects which have all been implicated in triggered arrhythmias.     

Ca2+ blinks: rapid nanoscopic store calcium signaling

Luminal Ca(2+) in the endoplasmic and sarcoplasmic reticulum (ER/SR) plays an important role in regulating vital biological processes, including store-operated capacitative Ca(2+) entry, Ca(2+)-induced Ca(2+) release, and ER/SR stress-mediated cell death. We report rapid and substantial decreases in luminal [Ca(2+)], called "Ca(2+) blinks," within nanometer-sized stores (the junctional cisternae of the SR) during elementary Ca(2+) release events in heart cells. Blinks mirror small local increases in cytoplasmic Ca(2+),orCa(2+) sparks, but changes of [Ca(2+)] in the connected free SR network were below detection. Store microanatomy suggests that diffusional strictures may account for this paradox. Surprisingly, the nadir of the store depletion trails the peak of the spark by about 10 ms, and the refilling of local store occurs with a rate constant of 35 s(-1), which is approximately 6-fold faster than the recovery of local Ca(2+) release after a spark. These data suggest that both local store depletion and some time-dependent inhibitory mechanism contribute to spark termination and refractoriness. Visualization of local store Ca(2+) signaling thus broadens our understanding of cardiac store Ca(2+) regulation and function and opens the possibility for local regulation of diverse store-dependent functions.     

Loading of calcium and strontium into the sarcoplasmic reticulum in rat ventricular muscle

Previous work suggests that strontium ions (Sr(2+)) are less effective than calcium ions (Ca(2+)) at supporting excitation-contraction (EC) coupling in cardiac muscle. We therefore tested whether this was due to differences in the uptake and release of Ca(2+)and Sr(2+)by the sarcoplasmic reticulum (SR) of rat ventricular trabeculae and myocytes at 22-24 degrees C. In permeabilized trabeculae, isometric contractions activated by exposure to Ca(2+)- and Sr(2+)-containing solutions produced similar maximal force, but were four times more sensitive to Ca(2+)than to Sr(2+). The rate of loading and maximal SR capacity for caffeine-releasable Ca(2+)and Sr(2+)were similar. In isolated, voltage-clamped ventricular myocytes, the SR content was measured as Na(+)-Ca(2+)exchange current during caffeine-induced SR cation releases. The SR Ca(2+)load reached a steady maximum during a train of voltage clamp depolarizations. A similar maximal Sr(2+)load was not observed, suggesting that the SR capacity for Sr(2+)exceeds that for Ca(2+). Therefore, the relative inability of Sr(2+)to support cardiac EC coupling appears not to be due to failure of the SR to sequester Sr(2+). Instead, increases in cytosolic [Sr(2+)] seem to poorly activate Sr(2+)release from the SR.     

Altered cardiac sarcoplasmic reticulum function of intact myocytes of rat ventricle during metabolic inhibition

Changes in the behavior of the sarcoplasmic reticulum (SR) in rat ventricular myocytes were investigated under conditions of metabolic inhibition using laser-scanning confocal microscopy to measure intracellular Ca(2+) and the perforated patch-clamp technique to measure SR Ca(2+) content. Metabolic inhibition had several effects on SR function, including reduced frequency of spontaneous releases of Ca(2+) (sparks and waves of Ca(2+)-induced Ca(2+) release), increased SR Ca(2+) content (79.4+/-5.7 to 115.2+/-6.6 micromol/L cell volume [mean+/-SEM; P:<0.001]), and, after a wave of Ca(2+) release, slower reuptake of Ca(2+) into the SR (rate constant of fall of Ca(2+) reduced from 8.5+/-1.1 s(-)(1) in control to 5.2+/-0.4 s(-)(1) in metabolic inhibition [P:<0.01]). Inhibition of L-type Ca(2+) channels with Cd(2+) (100 micromol/L) did not reproduce the effects of metabolic inhibition on spontaneous Ca(2+) sparks. These results are evidence of inhibition of both Ca(2+) release and reuptake mechanisms. Reduced frequency of release could be attributable to either of these effects, but the increased SR Ca(2+) content at the time of reduced frequency of spontaneous release of Ca(2+) shows that the dominant effect of metabolic inhibition is to inhibit release of Ca(2+) from the SR, allowing the accumulation of greater than normal amounts of Ca(2+). In the context of ischemia, this extra accumulation of Ca(2+) would present a risk of potentially arrhythmogenic, spontaneous release of Ca(2+) on reperfusion of the tissue.     

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.     

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.