Alternans of cardiac calcium cycling in a cluster of ryanodine receptors: a simulation study

Mechanical alternans in cardiac muscle is associated with intracellular Ca(2+) alternans. Mechanisms underlying intracellular Ca(2+) alternans are unclear. In previous experimental studies, we produced alternans of systolic Ca(2+) under voltage clamp, either by partially inhibiting the Ca(2+) release mechanism, or by applying small depolarizing pulses. In each case, alternans relied on propagating waves of Ca(2+) release. The aim of this study is to investigate by computer modeling how alternans of systolic Ca(2+) is produced. A mathematical model of a cardiac cell with 75 coupled elements is developed, with each element contains L-type Ca(2+) current, a subspace into which Ca release takes place, a cytoplasmic space, sarcoplasmic reticulum (SR) release channels [ryanodine receptor (RyR)], and uptake sites (SERCA). Interelement coupling is via Ca(2+) diffusion between neighboring subspaces via cytoplasmic spaces and network SR spaces. Small depolarizing pulses were simulated by step changes of cell membrane potential (20 mV) with random block of L-type channels. Partial inhibition of the release mechanism is mimicked by applying a reduction of RyR open probability in response to full stimulation by L-type channels. In both cases, systolic alternans follow, consistent with our experimental observations, being generated by propagating waves of Ca(2+) release and sustained through alternation of SR Ca(2+) content. This study provides novel and fundamental insights to understand mechanisms that may underlie intracellular Ca(2+) alternans without the need for refractoriness of L-type Ca or RyR channels under rapid pacing.     

Invited review: mechanisms of calcium handling in smooth muscles.

The concentration of cytoplasmic Ca(2+) regulates the contractile state of smooth muscle cells and tissues. Elevations in global cytoplasmic Ca(2+) resulting in contraction are accomplished by Ca(2+) entry and release from intracellular stores. Pathways for Ca(2+) entry include dihydropyridine-sensitive and -insensitive Ca(2+) channels and receptor and store-operated nonselective channels permeable to Ca(2+). Intracellular release from the sarcoplasmic reticulum (SR) is accomplished by ryanodine and inositol trisphosphate receptors. The impact of Ca(2+) entry and release on cytoplasmic concentration is modulated by Ca(2+) reuptake into the SR, uptake into mitochondria, and extrusion into the extracellular solution. Highly localized Ca(2+) transients (i.e., sparks and puffs) regulate ionic conductances in the plasma membrane, which can provide feedback to cell excitability and affect Ca(2+) entry. This short review describes the major transport mechanisms and compartments that are utilized for Ca(2+) handling in smooth muscles.     

Impaired calcium release during fatigue.

Impaired calcium release from the sarcoplasmic reticulum (SR) has been identified as a contributor to fatigue in isolated skeletal muscle fibers. The functional importance of this phenomenon can be quantified by the use of agents, such as caffeine, which can increase SR Ca(2+) release during fatigue. A number of possible mechanisms for impaired calcium release have been proposed. These include reduction in the amplitude of the action potential, potentially caused by extracellular K(+) accumulation, which may reduce voltage sensor activation but is counteracted by a number of mechanisms in intact animals. Reduced effectiveness of SR Ca(2+) channel opening is caused by the fall in intracellular ATP and the rise in Mg(2+) concentrations that occur during fatigue. Reduced Ca(2+) available for release within the SR can occur if inorganic phosphate enters the SR and precipitates with Ca(2+). Further progress requires the development of methods that can identify impaired SR Ca(2+) release in intact, blood-perfused muscles and that can distinguish between the various mechanisms proposed.     

Mice null for calsequestrin 1 exhibit deficits in functional performance and sarcoplasmic reticulum calcium handling

In skeletal muscle, the release of calcium (Ca(2+)) by ryanodine sensitive sarcoplasmic reticulum (SR) Ca(2+) release channels (i.e., ryanodine receptors; RyR1s) is the primary determinant of contractile filament activation. Much attention has been focused on calsequestrin (CASQ1) and its role in SR Ca(2+) buffering as well as its potential for modulating RyR1, the L-type Ca(2+) channel (dihydropyridine receptor, DHPR) and other sarcolemmal channels through sensing luminal [Ca(2+)]. The genetic ablation of CASQ1 expression results in significant alterations in SR Ca(2+) content and SR Ca(2+) release especially during prolonged activation. While these findings predict a significant loss-of-function phenotype in vivo, little information on functional status of CASQ1 null mice is available. We examined fast muscle in vivo and in vitro and identified significant deficits in functional performance that indicate an inability to sustain contractile activation. In single CASQ1 null skeletal myofibers we demonstrate a decrease in voltage dependent RyR Ca(2+) release with single action potentials and a collapse of the Ca(2+) release with repetitive trains. Under voltage clamp, SR Ca(2+) release flux and total SR Ca(2+) release are significantly reduced in CASQ1 null myofibers. The decrease in peak Ca(2+) release flux appears to be solely due to elimination of the slowly decaying component of SR Ca(2+) release, whereas the rapidly decaying component of SR Ca(2+) release is not altered in either amplitude or time course in CASQ1 null fibers. Finally, intra-SR [Ca(2+)] during ligand and voltage activation of RyR1 revealed a significant decrease in the SR[Ca(2+)](free) in intact CASQ1 null fibers and a increase in the release and uptake kinetics consistent with a depletion of intra-SR Ca(2+) buffering capacity. Taken together we have revealed that the genetic ablation of CASQ1 expression results in significant functional deficits consistent with a decrease in the slowly decaying component of SR Ca(2+) release.     

Capsaicin stimulates uncoupled ATP hydrolysis by the sarcoplasmic reticulum calcium pump

In muscle cells the sarcoplasmic reticulum (SR) Ca(2+)-ATPase (SERCA) couples the free energy of ATP hydrolysis to pump Ca(2+) ions from the cytoplasm to the SR lumen. In addition, SERCA plays a key role in non-shivering thermogenesis through uncoupled reactions, where ATP hydrolysis takes place without active Ca(2+) translocation. Capsaicin (CPS) is a naturally occurring vanilloid, the consumption of which is linked with increased metabolic rate and core body temperature. Here we document the stimulation by CPS of the Ca(2+)-dependent ATP hydrolysis by SERCA without effects on Ca(2+) accumulation. The stimulation by CPS was significantly dependent on the presence of a Ca(2+) gradient across the SR membrane. ATP activation assays showed that the drug reduced the nucleotide affinity at the catalytic site, whereas the affinity at the regulatory site increased. Several biochemical analyses indicated that CPS stabilizes an ADP-insensitive E(2)P-related conformation that dephosphorylates at a higher rate than the control enzyme. Under conditions where uncoupled SERCA was specifically inhibited by the treatment with fluoride, low temperatures, or dimethyl sulfoxide, CPS had no stimulatory effect on ATP hydrolysis by SERCA. It is concluded that CPS stabilizes a SERCA sub-conformation where Ca(2+) is released from the phosphorylated intermediate to the cytoplasm instead of the SR lumen, increasing ATP hydrolysis not coupled with Ca(2+) transport. To the best of our knowledge CPS is the first natural drug that augments uncoupled SERCA, presumably resulting in thermogenesis. The role of CPS as a SERCA modulator is discussed.     

Inactivation of L-type calcium channels in cardiomyocytes. Experimental and theoretical approaches

The L-type calcium current (ICa) plays an important role in excitation-contraction coupling of heart cells. It is critical for forming the major trigger for Ca(2+)-induced Ca(2+) release from the sarcoplasmic reticulum and hence its feedback regulation is of fundamental biological significance. The channel inactivation sharpens the kinetics and temporal precision of the Ca(2+) signals so that it prevents longer-term increases in free intracellular Ca(2+) concentration. Cardiac L-type Ca(2+) channels are known to inactivate through voltage- and Ca(2+)-dependent mechanisms. Pure voltage-dependent inactivation has a much slower time course of development than Ca(2+)-dependent inactivation and plays minor role in inhibition of Ca(2+) influx into the cell. The major determinant of the inactivation kinetics of Ca(2+) current during depolarization is Ca(2+)-dependent mechanisms. Furthermore, it is possible to distinguish two phases in Ca(2+)-dependent inactivation of calcium current: a slow phase that depends on Ca(2+) flow through the channels (Ca(2+) current-dependent inactivation) and a fast one that depends on Ca(2+) released from the sarcoplasmic reticulum (Ca(2+) release-dependent inactivation). Although both Ca(2+) released from the SR and Ca(2+) permeating channels play a role, SR-released Ca(2+) is the most effective inactivation mechanism in inhibition of Ca(2+) entry through the channel.     

Mitochondrial calcium signalling and cell death: approaches for assessing the role of mitochondrial Ca2+ uptake in apoptosis

Local Ca(2+) transfer between adjoining domains of the sarcoendoplasmic reticulum (ER/SR) and mitochondria allows ER/SR Ca(2+) release to activate mitochondrial Ca(2+) uptake and to evoke a matrix [Ca(2+)] ([Ca(2+)](m)) rise. [Ca(2+)](m) exerts control on several steps of energy metabolism to synchronize ATP generation with cell function. However, calcium signal propagation to the mitochondria may also ignite a cell death program through opening of the permeability transition pore (PTP). This occurs when the Ca(2+) release from the ER/SR is enhanced or is coincident with sensitization of the PTP. Recent studies have shown that several pro-apoptotic factors, including members of the Bcl-2 family proteins and reactive oxygen species (ROS) regulate the Ca(2+) sensitivity of both the Ca(2+) release channels in the ER and the PTP in the mitochondria. To test the relevance of the mitochondrial Ca(2+) accumulation in various apoptotic paradigms, methods are available for buffering of [Ca(2+)], for dissipation of the driving force of the mitochondrial Ca(2+) uptake and for inhibition of the mitochondrial Ca(2+) transport mechanisms. However, in intact cells, the efficacy and the specificity of these approaches have to be established. Here we discuss mechanisms that recruit the mitochondrial calcium signal to a pro-apoptotic cascade and the approaches available for assessment of the relevance of the mitochondrial Ca(2+) handling in apoptosis. We also present a systematic evaluation of the effect of ruthenium red and Ru360, two inhibitors of mitochondrial Ca(2+) uptake on cytosolic [Ca(2+)] and [Ca(2+)](m) in intact cultured cells.     

Metabotropic Ca2+ channel-induced calcium release in vascular smooth muscle

Contraction of vascular smooth muscle cells (VSMCs) depends on the rise of cytosolic [Ca(2+)] owing to either Ca(2+) influx through voltage-gated Ca(2+) channels of the plasmalemma or to receptor-mediated Ca(2+) release from the sarcoplasmic reticulum (SR). Although the ionotropic role of L-type Ca(2+) channels is well known, we review here data suggesting a new role of these channels in arterial myocytes. After sensing membrane depolarization Ca(2+) channels activate G proteins and the phospholipase C/inositol 1,4,5-trisphosphate (InsP(3)) pathway. Ca(2+) released through InsP(3)-dependent channels of the SR activates ryanodine receptors to amplify the cytosolic Ca(2+) signal, thus triggering arterial cerebral vasoconstriction in the absence of extracellular calcium influx. This metabotropic action of L-type Ca(2+) channels, denoted as calcium channel-induced Ca(2+) release, could have implications in cerebral vascular pharmacology and pathophysiology, because it can be suppressed by Ca(2+) channel antagonists and potentiated with small concentrations of extracellular vasoactive agents as ATP.     

Myocardial calcium cycling defect in furazolidone cardiomyopathy.

We have previously demonstrated that in furazolidone-induced congestive heart failure in turkeys the specific Ca(2+)-ATPase activity of myocardial sarcoplasmic reticulum (SR) is 60% increased in compensation for a 50% depression in net Ca(2+)-sequestration activity. This study tested the hypothesis that SR Ca(2+)-uptake and Ca(2+)-ATPase activities were uncoupled in this cardiomyopathy because of increased Ca(2+)-release channel activity. A novel microassay was used to monitor Ca2+ transport by myocardial homogenates using the fluorescent Ca2+ dye indo 1 to indicate extravesicular ionized Ca2+. The method is applied to cyropreserved biopsy specimens of myocardium and requires only 50 mg tissue. Both SR Ca(2+)-pump and SR Ca(2+)-channel activity were estimated using the channel-inhibitor ruthenium red (RR) and the mitochondrial inhibitor sodium azide. The specificity of the RR inhibition was confirmed using ryanodine. Cardiomyopathy was induced in 2-week-old turkey poults by the addition of 0.07% furazolidone to their feed for 4 weeks. Compared with controls, myocardial maximal Ca(2+)-channel activity relative to maximal Ca(2+)-pump activity was 22% greater and duration of Ca(2+)-channel activity was 100% increased. However, the heart failure birds had 43 and 53% decreases in absolute maximal Ca(2+)-pumping and Ca(2+)-channel activities, respectively. The abnormal Ca(2+)-channel activity resulted in 200% greater time before initiation of net Ca2+ sequestration and 700% greater final myocardial Ca2+ concentrations. For all birds, the Ca(2+)-accumulating activity was highly correlated with Ca(2+)-release activity (all p less than 0.05). These data indicate that in this animal model of congestive heart failure there is defective SR Ca(2+)-channel function resulting in abnormal Ca2+ homeostasis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reversible inhibition of the calcium-pumping ATPase in native cardiac sarcoplasmic reticulum by a calmodulin-binding peptide. Evidence for calmodulin-dependent regulation of the V(max) of calcium transport

Calmodulin (CaM) and Ca(2+)/CaM-dependent protein kinase II (CaM kinase) are tightly associated with cardiac sarcoplasmic reticulum (SR) and are implicated in the regulation of transmembrane Ca(2+) cycling. In order to assess the importance of membrane-associated CaM in modulating the Ca(2+) pump (Ca(2+)-ATPase) function of SR, the present study investigated the effects of a synthetic, high affinity CaM-binding peptide (CaM BP; amino acid sequence, LKWKKLLKLLKKLLKLG) on the ATP-energized Ca(2+) uptake, Ca(2+)-stimulated ATP hydrolysis, and CaM kinase-mediated protein phosphorylation in rabbit cardiac SR vesicles. The results revealed a strong concentration-dependent inhibitory action of CaM BP on Ca(2+) uptake and Ca(2+)-ATPase activities of SR (50% inhibition at approximately 2-3 microM CaM BP). The inhibition, which followed the association of CaM BP with its SR target(s), was of rapid onset (manifested within 30 s) and was accompanied by a decrease in V(max) of Ca(2+) uptake, unaltered K(0.5) for Ca(2+) activation of Ca(2+) transport, and a 10-fold decrease in the apparent affinity of the Ca(2+)-ATPase for its substrate, ATP. Thus, the mechanism of inhibition involved alterations at the catalytic site but not the Ca(2+)-binding sites of the Ca(2+)-ATPase. Endogenous CaM kinase-mediated phosphorylation of Ca(2+)-ATPase, phospholamban, and ryanodine receptor-Ca(2+) release channel was also strongly inhibited by CaM BP. The inhibitory action of CaM BP on SR Ca(2+) pump function and protein phosphorylation was fully reversed by exogenous CaM (1-3 microM). A peptide inhibitor of CaM kinase markedly attenuated the ability of CaM to reverse CaM BP-mediated inhibition of Ca(2+) transport. These findings suggest a critical role for membrane-bound CaM in controlling the velocity of Ca(2+) pumping in native cardiac SR. Consistent with its ability to inhibit SR Ca(2+) pump function, CaM BP (1-2.5 microM) caused marked depression of contractility and diastolic dysfunction in isolated perfused, spontaneously beating rabbit heart preparations. Full or partial recovery of contractile function occurred gradually following withdrawal of CaM BP from the perfusate, presumably due to slow dissociation of CaM BP from its target sites promoted by endogenous cytosolic CaM.     

Analysis of cellular calcium fluxes in cardiac muscle to understand calcium homeostasis in the heart

Central to controlling intracellular calcium concentration ([Ca(2+)](i)) are a number of Ca(2+) transporters and channels with the L-type Ca(2+) channel, Na(+)-Ca(2+) exchanger and sarcoplasmic reticulum Ca(2+)-ATPase (SERCA) being of particular note in the heart. This review concentrates on the regulation of [Ca(2+)](i) in cardiac muscle and the homeostatic mechanisms employed to ensure that the heart can operate under steady-state conditions on a beat by beat basis. To this end we discuss the relative importance of various sources and sinks of Ca(2+) responsible for initiating contraction and relaxation in cardiac myocytes and how these can be manipulated to regulate the Ca(2+) content of the major Ca(2+) store, the sarcoplasmic reticulum (SR). We will present a simple feedback system detailing how such control can be achieved and highlight how small perturbations to the steady-state operation of the feedback loop can be both beneficial physiologically and underlie changes in systolic Ca(2+) in ageing and heart disease. In addition to manipulating the amplitude of the normal systolic Ca(2+) transient, the tight regulation of SR Ca(2+) content is also required to prevent the abnormal, spontaneous or diastolic release of Ca(2+) from the SR. Such diastolic events are a major factor contributing to the genesis of cardiac arrhythmias in disease situations and in recently identified familial mutations in the SR Ca(2+) release channel (ryanodine receptor, RyR). How such diastolic release arises and potential mechanisms for controlling this will be discussed.     

Cannabinoid receptor agonists inhibit depolarization-induced calcium influx in cerebellar granule neurons.

Neuronal cannabinoid receptors (CB(1)) are coupled to inhibition of voltage-sensitive Ca(2+) channels (VSCCs) in several cell types. The purpose of these studies was to characterize the interaction between endogenous CB(1) receptors and VSCCs in cerebellar granule neurons (CGN). Ca(2+) transients were evoked by KCl-induced depolarization and imaged using fura-2. The CB(1) receptor agonists CP55940, Win 55212-2 and N-arachidonylethanolamine (anandamide) produced concentration-related decreases in peak amplitude of the Ca(2+) response and total Ca(2+) influx. Pre-treatment of CGN with pertussis toxin abolished agonist-mediated inhibition. The inhibitory effect of Win 55212-2 on Ca(2+) influx was additive with inhibition produced by omega-agatoxin IVA and nifedipine but not with omega-conotoxin GVIA, indicating that N-type VSCCs are the primary effector. Paradoxically, the CB(1) receptor antagonist, SR141716, also inhibited KCl-induced Ca(2+) influx into CGN in a concentration-related manner. SR141716 inhibition was pertussis toxin-insensitive and was not additive with the inhibition produced by Win 55212-2. Confocal imaging of CGN in primary culture demonstrate a high density of CB(1) receptor expression on CGN plasma membranes, including the neuritic processes. These data demonstrate that the CB(1) receptor is highly expressed by CGN and agonists serve as potent and efficacious inhibitory modulators of Ca(2+) influx through N-type VSCC.     

Termination of cardiac Ca(2+) sparks: an investigative mathematical model of calcium-induced calcium release

A Ca(2+) spark arises when a cluster of sarcoplasmic reticulum (SR) channels (ryanodine receptors or RyRs) opens to release calcium in a locally regenerative manner. Normally triggered by Ca(2+) influx across the sarcolemmal or transverse tubule membrane neighboring the cluster, the Ca(2+) spark has been shown to be the elementary Ca(2+) signaling event of excitation-contraction coupling in heart muscle. However, the question of how the Ca(2+) spark terminates remains a central, unresolved issue. Here we present a new model, "sticky cluster," of SR Ca(2+) release that simulates Ca(2+) spark behavior and enables robust Ca(2+) spark termination. Two newly documented features of RyR behavior have been incorporated in this otherwise simple model: "coupled gating" and an opening rate that depends on SR lumenal [Ca(2+)]. Using a Monte Carlo method, local Ca(2+)-induced Ca(2+) release from clusters containing between 10 and 100 RyRs is modeled. After release is triggered, Ca(2+) flux from RyRs diffuses into the cytosol and binds to intracellular buffers and the fluorescent Ca(2+) indicator fluo-3 to produce the model Ca(2+) spark. Ca(2+) sparks generated by the sticky cluster model resemble those observed experimentally, and Ca(2+) spark duration and amplitude are largely insensitive to the number of RyRs in a cluster. As expected from heart cell investigation, the spontaneous Ca(2+) spark rate in the model increases with elevated cytosolic or SR lumenal [Ca(2+)]. Furthermore, reduction of RyR coupling leads to prolonged model Ca(2+) sparks just as treatment with FK506 lengthens Ca(2+) sparks in heart cells. This new model of Ca(2+) spark behavior provides a "proof of principle" test of a new hypothesis for Ca(2+) spark termination and reproduces critical features of Ca(2+) sparks observed experimentally.     

Modulation of palmitate-induced cardiomyocyte cell death by interventions that alter intracellular calcium

The objective of this study was to investigate whether palmitate-induced cell death in cardiomyocytes was dependent on alterations of intracellular calcium ([Ca2+)I). Specifically, we sought to determine whether palmitate might produce a cellular calcium overload by increasing calcium influx into the cell or by altering sarcoplasmic reticulum (SR) calcium transport. We also determined whether palmitate's effects might be modulated by agents that alter [Ca2+]l. Treatment of chick embryonic cardiomyocytes in culture with palmitate (100 uM) produced a significant (P < 0.05) and 42.9 +/- 5.3% reduction in cell survival or increase in cell death. As determined by FURA-2 measurement of [Ca2+]I, the cytotoxicity of palmitate on cardiomyocytes did not appear to be mediated through acute increases in [Ca2+]l. In contrast, the unsaturated fatty acid, arachidonic acid increased [Ca2+]l. The calcium ionophore ionomycin significantly (P < 0.05) increased palmitate-induced cardiomyocyte cell death. The effects of ionomycin and palmitate, however, were additive, suggesting palmitate and ionomycin acted in an independent manner to induce cell death. Furthermore, in contrast to palmitate, an ionomycin-induced increase in [Ca2+]l was demonstrated in these cells. Inhibition of SR calcium reuptake by thapsigargin, which acutely increases [Ca2+]I, also significantly (P < 0.05) increased palmitate-induced cardiomyocyte death. Again, these two agents most likely acted in an independent manner because of the additive nature of the effect of palmitate and thapsigargin on cell viability. Palmitate-induced cardiotoxicity was not mediated through release of [Ca2+]I from SR or through voltage-operated channels on plasma membranes, as neither SR calcium depletion by low concentrations of ryanodine nor blockade of the voltage-operated calcium channel with nifedipine significantly altered palmitate-induced cardiomyocyte death. These data suggest that palmitate-induced cardiac cell death is enhanced by increases in [Ca2+]I and highlights the potential adverse effect of a combination of palmitate with conditions that increase [Ca2+]I in cardiomyocytes.     

Effects of hypoxia and mitochondrial inhibition on the capacitative calcium entry in rabbit pulmonary arterial smooth muscle cells

We have investigated the effects of hypoxia and mitochondria inhibitors on the capacitative Ca(2+) entry (CCE) in cultured smooth muscle cells from rabbit small pulmonary arteries. Cyclopiazonic acid (CPA) depleted Ca(2+) from sarcoplasmic reticulum (SR) in Ca(2+)-free medium and subsequent addition of Ca(2+) led to the nifedipine-insensitive, La(3+)-sensitive Ca(2+) influx. The presence of CCE was further verified by the measurement of unidirectional Mn(2+) influx. During the decay phase of the CCE-induced [Ca(2+)]c transients, hypoxia (P(O2) < 50 mmHg) and the mitochondria inhibitor FCCP reversibly increased [Ca(2+)]c, that is La(3+)-sensitive. Once SR is depleted by CPA, subsequent treatment of FCCP slowed the decay of CCE-induced [Ca(2+)]c transients but it did not attenuate Mn(2+) influx. Mitochondrial uptake of incoming Ca(2+) through CCE was demonstrated by additional increase in [Ca(2+)]c with Ca(2+) ionophore after terminating CCE. Together, it is suggested that the augmentation of CCE-induced [Ca(2+)]c transients by hypoxia and FCCP reflects a net gain of [Ca(2+)]c by the inhibition of mitochondrial Ca(2+) uptake.     

Highly cooperative dependence of sarco/endoplasmic reticulum calcium ATPase SERCA2a pump activity on cytosolic calcium in living cells

Sarco/endoplasmic reticulum (SR/ER) Ca(2+)-ATPase (SERCA) is an intracellular Ca(2+) pump localized on the SR/ER membrane. The role of SERCA in refilling intracellular Ca(2+) stores is pivotal for maintaining intracellular Ca(2+) homeostasis, and disturbed SERCA activity causes many disease phenotypes, including heart failure, diabetes, cancer, and Alzheimer disease. Although SERCA activity has been described using a simple enzyme activity equation, the dynamics of SERCA activity in living cells is still unknown. To monitor SERCA activity in living cells, we constructed an enhanced CFP (ECFP)- and FlAsH-tagged SERCA2a, designated F-L577, which retains the ATP-dependent Ca(2+) pump activity. The FRET efficiency between ECFP and FlAsH of F-L577 is dependent on the conformational state of the molecule. ER luminal Ca(2+) imaging confirmed that the FRET signal changes directly reflect the Ca(2+) pump activity. Dual imaging of cytosolic Ca(2+) and the FRET signals of F-L577 in intact COS7 cells revealed that SERCA2a activity is coincident with the oscillatory cytosolic Ca(2+) concentration changes evoked by ATP stimulation. The Ca(2+) pump activity of SERCA2a in intact cells can be expressed by the Hill equation with an apparent affinity for Ca(2+) of 0.41 ± 0.0095 μm and a Hill coefficient of 5.7 ± 0.73. These results indicate that in the cellular environment the Ca(2+) dependence of ATPase activation is highly cooperative and that SERCA2a acts as a rapid switch to refill Ca(2+) stores in living cells for shaping the intracellular Ca(2+) dynamics. F-L577 will be useful for future studies on Ca(2+) signaling involving SERCA2a activity.     

Enhanced calcium mobilization in rat ventricular myocytes during the onset of pressure overload-induced hypertrophy

Early cardiovascular changes evoked by pressure overload (PO) may reveal adaptive strategies that allow immediate survival to the increased hemodynamic load. In this study, systolic and diastolic Ca(2+) cycling was analyzed in left ventricular rat myocytes before (day 2, PO-2d group) and after (day 7, PO-7d group) development of hypertrophy subsequent to aortic constriction, as well as in myocytes from time-matched sham-operated rats (sham group). Ca(2+) transient amplitude was significantly augmented in the PO-2d group. In the PO-7d group, intracellular Ca(2+) concentration ([Ca(2+)](i)) was reduced during diastole, and mechanical twitch relaxation (but not [Ca(2+)](i) decline) was slowed. In PO groups, fractional sarcoplasmic reticulum (SR) Ca(2+) release at a twitch, SR Ca(2+) content, SR Ca(2+) loss during diastole, and SR-dependent integrated Ca(2+) flux during twitch relaxation were significantly greater than in sham-operated groups, whereas the relaxation-associated Ca(2+) flux carried by the Na(+)/Ca(2+) exchanger was not significantly changed. In the PO-7d group, mRNA levels of cardiac isoforms of SR Ca(2+)-ATPase (SERCA2a), phospholamban, calsequestrin, ryanodine receptor, and NCX were not significantly altered, but the SERCA2a-to-phospholamban ratio was increased 2.5-fold. Moreover, greater sensitivity to the inotropic effects of the beta-adrenoceptor agonist isoproterenol was observed in the PO-7d group. The results indicate enhanced Ca(2+) cycling between SR and cytosol early after PO imposition, even before hypertrophy development. Increase in SR Ca(2+) uptake may contribute to enhancement of excitation-contraction coupling (augmented SR Ca(2+) content and release) and protection against arrhythmogenesis due to buildup of [Ca(2+)](i) during diastole.     

Role of Junctin protein interactions in cellular dynamics of calsequestrin polymer upon calcium perturbation

Calsequestrin (CSQ), the major intrasarcoplasmic reticulum calcium storage protein, undergoes dynamic polymerization and depolymerization in a Ca(2+)-dependent manner. However, no direct evidence of CSQ depolymerization in vivo with physiological relevance has been obtained. In the present study, live cell imaging analysis facilitated characterization of the in vivo dynamics of the macromolecular CSQ structure. CSQ2 appeared as speckles in the presence of normal sarcoplasmic reticulum (SR) Ca(2+) that were decondensed upon Ca(2+) depletion. Moreover, CSQ2 decondensation occurred only in the stoichiometric presence of junctin (JNT). When expressed alone, CSQ2 speckles remained unchanged, even after Ca(2+) depletion. FRET analysis revealed constant interactions between CSQ2 and JNT, regardless of the SR Ca(2+) concentration, implying that JNT is an essential component of the CSQ scaffold. In vitro solubility assay, electron microscopy, and atomic force microscopy studies using purified recombinant proteins confirmed Ca(2+) and JNT-dependent disassembly of the CSQ2 polymer. Accordingly, we conclude that reversible polymerization and depolymerization of CSQ are critical in SR Ca(2+) homeostasis.