Calcium entry via Na/Ca exchange during the action potential directly contributes to contraction of failing human ventricular myocytes

Prolongation of the Ca2+ transient and action potential (AP) durations are two characteristic changes in myocyte physiology in the failing human heart. The hypothesis of this study is that Ca2+ influx via reverse mode Na+/Ca2+ exchanger (NCX) or via L-type Ca2+ channels directly activates contraction in failing human myocytes while in normal myocytes this Ca2+ is transported into the sarcoplasmic reticulum (SR) to regulate SR Ca2+ stores. METHODS: Myocytes were isolated from failing human (n=6), nonfailing human (n=3) and normal feline hearts (n=9) and whole cell current and voltage clamp techniques were used to evoke and increase the duration of APs (0.5 Hz, 37 degrees C). Cyclopiazonic acid (CPA 10(-6) M), nifedipine (NIF;10(-6) M) and KB-R 7943 (KB-R; 3x10(-6) M) were used to reduce SR Ca2+ uptake, Ca2+ influx via the L-type Ca2+ current and reverse mode NCX, respectively. [Na+)i was changed by dialyzing myocytes with 0, 10 and 20 mM Na(+) pipette solutions. RESULTS: Prolongation of the AP duration caused an immediate prolongation of contraction and Ca2+ transient durations in failing myocytes. The first beat after the prolonged AP was potentiated by 21+/-5 and 27+/-5% in nonfailing human and normal feline myocytes, respectively (P<0.05), but there was no significant effect in failing human myocytes (+5+/-4% vs. steady state). CPA blunted the potentiation of the first beat after AP prolongation in normal feline and nonfailing human myocytes, mimicking the failing phenotype. NIF reduced steady state contraction in feline myocytes but the potentiation of the first beat after AP prolongation was unaltered (21+/-3% vs. base, P<0.05). KB-R reduced basal contractility and abolished the potentiation of the first beat after AP prolongation (2+/-1% vs. steady state). Increasing [Na+]i shortened AP, Ca2+ transient and contraction durations and increased steady state and post AP prolongation contractions. Dialysis with 0 Na+ eliminated these effects. CONCLUSIONS: Ca2+ enters both normal and failing cardiac myocytes during the late portion of the AP plateau via reverse mode NCX. In (normal) myocytes with good SR function, this Ca(2+) influx helps maintain and regulate SR Ca2+ load. In (failing) human myocytes with poor SR function this Ca2+ influx directly contributes to contraction. These studies suggest that the Ca2+ transient of the failing human ventricular myocytes has a higher than normal reliance on Ca2+ influx via the reverse mode of the NCX during the terminal phases of the AP.     

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.     

Omega 3 polyunsaturated fatty acid modulates dihydropyridine effects on L-type Ca2+ channels, cytosolic Ca2+, and contraction in adult rat cardiac myocytes.

The effect of docosahexaenoic acid (DHA; C22:6) on dihydropyridine (DHP) interaction with L-type Ca2+ channel current (ICa), cytosolic Ca2+ (Cai), and cell contraction in isolated adult rat cardiac myocytes was studied. The DHP L-type Ca(2+)-channel blocker nitrendipine (10 nM) reduced peak ICa (measured by whole-cell voltage clamp from -45 to 0 mV) and reduced the amplitude of the Ca2+ transient (measured as the transient in indo-1 fluorescence, 410/490 nm) and the twitch amplitude (measured via photodiode array) during steady-state electrical stimulation (0.5 Hz). The DHP L-type Ca2+ channel agonist BAY K 8644 (10 nM) significantly increased ICa, the amplitude of the Cai transient, and contraction. When cells were exposed to DHA (5 microM) simultaneously with either BAY K 8644 or nitrendipine, the drug effects were abolished. Arachidonic acid (C20:4) at 5 microM did not block the inhibitory effects of nitrendipine nor did it prevent the potentiating effects of BAY K 8644. DHA modulation of DHP action could be reversed by cell perfusion with fatty acid-free bovine serum albumin at 1 mg/ml. Neither DHA nor arachidonic acid alone (5 microM) had any apparent effect on the parameters measured. DHA (5 microM) had no influence over beta-adrenergic receptor stimulation (isoproterenol, 0.01-1 microM)-induced increases in ICa, Cai, or contraction. The findings that DHA inhibits the effect of DHP agonists and antagonists on Ca(2+)-channel current but has no effect alone or on beta-adrenergic-induced increases in ICa suggests that DHA specifically binds to Ca2+ channels at or near DHP binding sites and interferes with ICa modulation.     

Cardiac sarcoplasmic reticulum calcium release and load are enhanced by subcellular cAMP elevations in PI3Kgamma-deficient mice

We recently showed that phosphoinositide-3-kinase-gamma-deficient (PI3Kgamma-/-) mice have increased cardiac contractility without changes in heart size compared with control mice (ie, PI3Kgamma+/+ or PI3Kgamma+/-). In this study, we show that PI3Kgamma-/- cardiomyocytes have elevated Ca2+ transient amplitudes with abbreviated decay kinetics compared with control under field-stimulation and voltage-clamp conditions. When Ca2+ transients were eliminated with high Ca2+ buffering, L-type Ca2+ currents (I(Ca,L)), K+ currents, and action potential duration (APD) were not different between the groups, whereas, in the presence of Ca2+ transients, Ca2+-dependent phase of I(Ca,L) inactivation was abbreviated and APD at 90% repolarization was prolonged in PI3Kgamma-/- mice. Excitation-contraction coupling (ECC) gain, sarcoplasmic reticulum (SR) Ca2+ load, and SR Ca(2+) release fluxes measured as Ca2+ spikes, were also increased in PI3Kgamma-/- cardiomyocytes without detectable changes in Ca2+ spikes kinetics. The cAMP inhibitor Rp-cAMP eliminated enhanced ECC and SR Ca2+ load in PI3Kgamma-/- without effects in control myocytes. On the other hand, the beta-adrenergic receptor agonist isoproterenol increased I(Ca,L) and Ca2+ transient equally by approximately 2-fold in both PI3Kgamma-/- and PI3Kgamma+/- cardiomyocytes. Our results establish that PI3Kgamma reduces cardiac contractility in a highly compartmentalized manner by inhibiting cAMP-mediated SR Ca2+ loading without directly affecting other major modulators of ECC, such as AP and I(Ca,L).     

Calcium cycling in the aged heart

One of the most important hallmarks of the aged heart is altered calcium homeostasis, possibly due to age-associated alterations in several major calcium cycling processes involved in cardiac excitation-contraction coupling. During ageing, the magnitude of the L-type Ca²⁺ channel current (I_Ca,L) becomes significantly increased in parallel with the enlargement of cardiac myocytes, resulting in an unaltered I_Ca,L density. Since the inactivation of I_Ca,L is slowed, and the action potential duration is prolonged, the net Ca²⁺ influx during each action potential is increased in cells of senescent myocardium relative to cells of adult control. While neither mRNA nor protein levels of the sarcoplasmic reticulum (SR) Ca²⁺ release channel (ryanodine receptor) significantly change with advancing adult age, the mRNA abundance and the density of SR Cat+ pump decrease with ageing and are associated with a diminished SR Ca²⁺ sequestration rate in the aged heart. In addition, cardiac chronotropic and inotropic responses to β-adrenergic receptor stimulation are also reduced with advancing age. The multiple changes in Ca cycling that occur during ageing result in an augmented Cat+ influx, slowed SR Ca²⁺ sequestration and prolonged durations of the Ca_i transient and contraction. These alterations which prolong electromechanical systole may be construed as an adaptation in that they prolong the force-bearing capacity of the senescent cells following excitation. This is helpful with respect to maintaining the cardiac function in the aged heart. However, they also increase the risk of Ca²⁺ overload and Cat²⁺-dependent arrhythmias during stress in the senescent heart. Although reduced (3-adrenergic responses with ageing contribute to diminished contraction reserve, these may be viewed in part, as adaptive, in that they protect against Ca²⁺ overload during stress.     

Hypoxia inhibits contraction but not calcium channel currents or changes in intracellular calcium in arteriolar muscle cells

OBJECTIVE: We tested the hypothesis that hypoxia inhibits currents through L-type Ca(2+) channels and inhibits norepinephrine-induced rises in intracellular Ca(2+) in cremasteric arteriolar muscle cells, thus accounting for the inhibitory effect of hypoxia on norepinephrine-induced contraction of these cells. METHODS: Single smooth muscle cells were enzymatically isolated from second-order and third-order arterioles from hamster cremaster muscles. The effects of hypoxia (partial pressure of oxygen: 10-15 mm Hg) were examined on Ba(2+) (10 mM) currents through L-type Ca(2+) channels by use of the perforated patch clamp technique. Also, the effect of hypoxia on norepinephrine-induced calcium changes was studied using Fura 2 microfluorimetry. RESULTS: Hypoxia inhibited the norepinephrine-induced (10 microM) contraction of single arteriolar muscle cells by 32.9 +/- 5.6% (mean +/- SE, n = 4). However, hypoxia had no significant effect on whole-cell currents through L-type Ca(2+) channels: the peak current densities measured at +20 mV were -3.83 +/- 0.40 pA/pF before hypoxia and -3.97 +/- 0.36 pA/pF during hypoxia (n = 15; p > 0.05). In addition, hypoxia did not inhibit Ca(2+) transients in arteriolar muscle cells elicited by 10 microM norepinephrine. Instead, hypoxia increased basal Ca(2+) (13.8 +/- 3.2%) and augmented peak Ca(2+) levels (29.4 +/- 7.3%) and steady-state Ca(2+) levels (15.2 +/- 5.4%) elicited by 10 microM norepinephrine (n = 21; p < 0.05). CONCLUSIONS: These data indicate that hypoxia inhibits norepinephrine-induced contraction of single cremasteric arteriolar muscle cells by a mechanism that involves neither L-type Ca(2+) channels nor norepinephrine-induced Ca(2+) mobilization. Instead, our findings suggest that hypoxia must inhibit norepinephrine-induced contraction by affecting a component of the signaling pathway that lies downstream from the increases in Ca(2+) produced by this neurotransmitter.     

Effects of calsequestrin over-expression on excitation-contraction coupling in isolated rabbit cardiomyocytes

OBJECTIVE: This study investigated the role of calsequestrin (CSQ) in the control of excitation-contraction (E-C) coupling in the heart. METHODS: CSQ over-expression was induced in isolated rabbit ventricular cardiomyocytes using an adenovirus coding for rabbit CSQ (Ad-CSQ). After 24 h of culture, CSQ protein expression was increased by 58+/-18% (n=10). An adenovirus coding for beta-galactosidase (Ad-LacZ) was used as a control. RESULTS: In voltage-clamped, Fura-2-loaded cardiomyocytes, L-type Ca2+ current (I(Ca,L)) and Ca2+ transient amplitude were both increased in the Ad-CSQ group by approximately 78%. Doubling the external Ca2+ concentration in the control group (Ad-LacZ) increased the LTCC amplitude to a similar degree (85+/-6%), but increased the Ca2+ transient amplitude by 149+/-13%. This suggests that SR Ca2+ release may be inhibited upon CSQ over-expression. Alternatively, nifedipine (0.5 microM) was used to reduce I(Ca,L) in Ad-CSQ-transfected cells to values comparable to control (Ad-LacZ). Under these conditions, Ca2+ transient amplitude was not different from Ad-LacZ, but the SR Ca2+ content was approximately 60% higher as assessed by both the caffeine-induced Ca2+ release and the accompanying Na+/Ca2+ exchanger current (I(NCX)). The cause of the increased I(Ca,L) is unknown. No change in the expression level of the alpha1-subunit of the L-type Ca channel was observed. beta-Escin-permeabilized cardiomyocytes were used to study Ca2+ sparks imaged with Fluo-3 at 145-155 nmol/L [Ca2+]. Spontaneous Ca2+ spark frequency, duration, width, and amplitude were unchanged in the Ad-CSQ group, but SR Ca2+ content was 48% higher than Ad-LacZ. CONCLUSIONS: CSQ over-expression increased SR Ca2+ content but reduced the gain of E-C coupling in rabbit cardiomyocytes.     

Remodeling of T-tubules and reduced synchrony of Ca2+ release in myocytes from chronically ischemic myocardium

In ventricular cardiac myocytes, T-tubule density is an important determinant of the synchrony of sarcoplasmic reticulum (SR) Ca2+ release and could be involved in the reduced SR Ca2+ release in ischemic cardiomyopathy. We therefore investigated T-tubule density and properties of SR Ca2+ release in pigs, 6 weeks after inducing severe stenosis of the circumflex coronary artery (91+/-3%, N=13) with myocardial infarction (8.8+/-2.0% of total left ventricular mass). Severe dysfunction in the infarct and adjacent myocardium was documented by magnetic resonance and Doppler myocardial velocity imaging. Myocytes isolated from the adjacent myocardium were compared with myocytes from the same region in weight-matched control pigs. T-tubule density quantified from the di-8-ANEPPS (di-8-butyl-amino-naphthyl-ethylene-pyridinium-propyl-sulfonate) sarcolemmal staining was decreased by 27+/-7% (P<0.05). Synchrony of SR Ca2+ release (confocal line scan images during whole-cell voltage clamp) was reduced in myocardium myocytes. Delayed release (ie, half-maximal [Ca2+]i occurring later than 20 ms) occurred at 35.5+/-6.4% of the scan line in myocardial infarction versus 22.7+/-2.5% in control pigs (P<0.05), prolonging the time to peak of the line-averaged [Ca2+]i transient (121+/-9 versus 102+/-5 ms in control pigs, P<0.05). Delayed release colocalized with regions of T-tubule rarefaction and could not be suppressed by activation of protein kinase A. The whole-cell averaged [Ca2+]i transient amplitude was reduced, whereas L-type Ca2+ current density was unchanged and SR content was increased, indicating a reduction in the gain of Ca2+-induced Ca2+ release. In conclusion, reduced T-tubule density during ischemic remodeling is associated with reduced synchrony of Ca2+ release and reduced efficiency of coupling Ca2+ influx to Ca2+ release.     

Expression of T-type Ca(2+) channels in ventricular cells from hypertrophied rat hearts.

In this study we examined the existence of T-type Ca(2+) current in ventricular myocytes isolated from rats with pressure-overload hypertrophy. The whole-cell clamp technique was used to record Ca(2+) currents in enzymatically dissociated ventricular cells. T- and L-type Ca(2+) currents were separated by applying voltage steps to different test potentials from a holding potential of -80 mV and -50 mV. T-type Ca(2+) current was defined as the difference between the currents from the two holding potentials. Ventricular myocytes from sham-operated rats showed only L-type Ca(2+) current (maximal density -13.9+/-1.3 pA/pF n=17), whereas ventricular myocytes isolated from rats with aortic stenosis showed both L- and T-type Ca(2+) currents. The average values of T- and L-type Ca(2+) current density were -4.8+/-0.4 pA/pF and -12.4+/-0.9 pA/pF (n=32), respectively. T-type Ca(2+) current was distinguished from L-type Ca(2+) current by its voltage dependence, its kinetics and by its strong blockade by nickel 50 microM. In conclusion, we have demonstrated that hypertrophied ventricular rat cells express T-type Ca(2+) channels and this finding strongly supports a role for this channel in regulating growth processes in cardiac tissue.     

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).     

No role for a voltage sensitive release mechanism in cardiac muscle

We have investigated the possibility that some component of calcium release from the cardiac sarcoplasmic reticulum (SR) may occur directly in response to the surface membrane action potential rather than by calcium induced calcium release (CICR). Experiments were performed on rat ventricular myocytes and intracellular calcium concentration ([Ca(2+)](i)) measured with fluo-3. In order to mimic physiological conditions, experiments were performed at 37 degrees C, using the perforated patch technique (to avoid intracellular dialysis) with pulses from -80 to 0 mV. The addition of 500 microM Cd(2+) to inhibit the L-type Ca current reduced the rate of increase of the Ca transient to 2.8 +/- 1% of control. When experiments were performed with Na-free solutions in the pipette, Cd(2+) abolished the transient completely suggesting that the residual Ca entry was on Na-Ca exchange. The addition of Ni(2+) produced a concentration dependent inhibition of the Ca transient with 5 mM being sufficient to completely inhibit the transient. The inhibitory effects of Ni(2+) were unaffected by prior exposure to isoprenaline. These results provide no evidence for a voltage activated calcium release mechanism in cardiac muscle and are consistent with SR Ca(2+) release being triggered by a process of Ca(2+) induced Ca(2+) release.     

Clinical L-type Ca(2+) channel blockade prevents ischemic preconditioning of human myocardium

Although Ca(2+) channel blockers are commonly used to control both blood pressure and angina in patients with coronary artery disease, clinical trials have associated the use of L-type Ca(2+) channel blockers with increased cardiovascular mortality. Recent evidence has implicated Ca(2+) entry through the L-type Ca(2+) channel during transient ischemia as a proximal stimulus for ischemic preconditioning (IPC) in experimental animals. We therefore hypothesized that clinical L-type Ca(2+) channel blockade prevents IPC in human myocardium. Human atrial trabeculae were suspended in organ baths, field simulated at 1 Hz, and force development was recorded. Following 90 min equilibration, trabeculae from control patients and patients taking L-type Ca(2+) channel blockers were subjected to simulated ischemia/reperfusion (I/R: 45/120 min) with or without 5 min of simulated ischemia (IPC stimulus) prior to I/R. IPC increased post-ischemic developed force in control patients from 14.6+/-2.6 to 43.1+/-3.5% baseline developed force (%BDF P<0.05 I/R vs IPC). Whereas IPC failed to increase post-ischemic developed force in myocardium from patients taking L-type Ca(2+) channel blockers (15. 1+/-1.9 vs 16.6+/-1.7 %BDF, P>0.05 L-type I/R v L-type IPC). We conclude that: (1) atrial muscle can be preconditioned by transient ischemia; (2) atrial muscle from patients taking L-type Ca(2+) channel blockers cannot be preconditioned by transient ischemia; and (3) the increased cardiovascular mortality historically associated with the use of Ca(2) channel blockers in patients with coronary artery disease may be, in part, due to the pharmacological inhibition of ischemic preconditioning.     

Increased sarcoplasmic reticulum calcium leak but unaltered contractility by acute CaMKII overexpression in isolated rabbit cardiac myocytes

The predominant cardiac Ca2+/calmodulin-dependent protein kinase (CaMK) is CaMKIIdelta. Here we acutely overexpress CaMKIIdeltaC using adenovirus-mediated gene transfer in adult rabbit ventricular myocytes. This circumvents confounding adaptive effects in CaMKIIdeltaC transgenic mice. CaMKIIdeltaC protein expression and activation state (autophosphorylation) were increased 5- to 6-fold. Basal twitch contraction amplitude and kinetics (1 Hz) were not changed in CaMKIIdeltaC versus LacZ expressing myocytes. However, the contraction-frequency relationship was more negative, frequency-dependent acceleration of relaxation was enhanced (tau(0.5Hz)/tau(3Hz)=2.14+/-0.10 versus 1.87+/-0.10), and peak Ca2+ current (ICa) was increased by 31% (-7.1+/-0.5 versus -5.4+/-0.5 pA/pF, P<0.05). Ca2+ transient amplitude was not significantly reduced (-27%, P=0.22), despite dramatically reduced sarcoplasmic reticulum (SR) Ca2+ content (41%; P<0.05). Thus fractional SR Ca2+ release was increased by 60% (P<0.05). Diastolic SR Ca2+ leak assessed by Ca2+ spark frequency (normalized to SR Ca2+ load) was increased by 88% in CaMKIIdeltaC versus LacZ myocytes (P<0.05; in an multiplicity-of-infection-dependent manner), an effect blocked by CaMKII inhibitors KN-93 and autocamtide-2-related inhibitory peptide. This enhanced SR Ca2+ leak may explain reduced SR Ca2+ content, despite measured levels of SR Ca2+-ATPase and Na+/Ca2+ exchange expression and function being unaltered. Ryanodine receptor (RyR) phosphorylation in CaMKIIdeltaC myocytes was increased at both Ser2809 and Ser2815, but FKBP12.6 coimmunoprecipitation with RyR was unaltered. This shows for the first time that acute CaMKIIdeltaC overexpression alters RyR function, leading to enhanced SR Ca2+ leak and reduced SR Ca2+ content but without reducing twitch contraction and Ca2+ transients. We conclude that this is attributable to concomitant enhancement of fractional SR Ca2+ release in CaMKIIdeltaC myocytes (ie, CaMKII-dependent enhancement of RyR Ca2+ sensitivity during diastole and systole) and increased ICa.     

Action potential prolongation in cardiac myocytes of old rats is an adaptation to sustain youthful intracellular Ca2+ regulation

Advanced age in rats is accompanied by reduced expression of the sarcoplasmic reticulum (SR) Ca2+ pump (SERCA-2). The amplitudes of intracellular Ca2+ (Ca2+(i)) transients and contractions in ventricular myocytes isolated from old (23-24-months) rats (OR), however, are similar to those of young (4-6-months) rat myocytes (YR). OR myocytes also manifest slowed inactivation of L-type Ca2+ current (I(CaL)) and marked prolongation of action potential (AP) duration. To determine whether and how age-associated AP prolongation preserves the Ca2+(i) transient amplitude in OR myocytes, we employed an AP-clamp technique with simultaneous measurements of I(CaL) (with Na+ current, K+ currents and Ca2+ influx via sarcolemmal Na+-Ca2+ exchanger blocked) and Ca2+(i) transients in OR rat ventricular myocytes dialyzed with the fluorescent Ca2+ probe, indo-1. Myocytes were stimulated with AP-shaped voltage clamp waveforms approximating the configuration of prolonged, i.e. the native, AP of OR cells (AP-L), or with short AP waveforms (AP-S), typical of YR myocytes. Changes in SR Ca2+ load were assessed by rapid, complete SR Ca2+ depletions with caffeine. As expected, during stimulation with AP-S vs AP-L, peak I(CaL) increased, by 21+/-4%, while the I(CaL) integral decreased, by 19+/-3% (P<0.01 for each). Compared to AP-L, stimulation of OR myocytes with AP-S reduced the amplitudes of the Ca2+(i) transient by 31+/-6%, its maximal rate of rise (+dCa2+(i)/dt(max); a sensitive index of SR Ca2+ release flux) by 37+/-4%, and decreased the SR Ca2+ load by 29+/-4% (P<0.01 for each). Intriguingly, AP-S also reduced the maximal rate of the Ca2+(i) transient relaxation and prolonged its time to 50% decline, by 35+/-5% and 33+/-7%, respectively (P<0.01 for each). During stimulation with AP-S, the gain of Ca2+-induced Ca2+ release (CICR), indexed by +dCa2+(i)/dt(max)/I(CaL), was reduced by 46+/-4% vs AP-L (P<0.01). We conclude that the effects of an application of a shorter AP to OR myocytes to reduce +dCa2+(i)/dt(max) and the Ca2+ transient amplitude are attributable to a reduction in SR Ca2+ load, presumably due to a reduced I(CaL) integral and likely also to an increased Ca2+ extrusion via sarcolemmal Na+-Ca2+ exchanger. The decrease in the Ca2+(i) transient relaxation rate in OR cells stimulated with shorter APs may reflect a reduction of Ca2+/calmodulin-kinase II-regulated modulation of Ca2+ uptake via SERCA-2, consequent to a reduced local Ca2+ release in the vicinity of SERCA-2, also attributable to reduced SR Ca2+ load. Thus, the reduction of CICR gain during stimulation with AP-S is the net result of both a diminished SR Ca2+ release and an increased peak I(CaL). These results suggest that ventricular myocytes of old rats utilize AP prolongation to preserve an optimal SR Ca2+ loading, CICR gain and relaxation of Ca2+(i) transients.     

Cellular mechanisms of altered contractility in the hypertrophied heart: big hearts, big sparks

To investigate the cellular mechanisms for altered Ca2+ homeostasis and contractility in cardiac hypertrophy, we measured whole-cell L-type Ca2+ currents (ICa,L), whole-cell Ca2+ transients ([Ca2+]i), and Ca2+ sparks in ventricular cells from 6-month-old spontaneously hypertensive rats (SHRs) and from age- and sex-matched Wistar-Kyoto and Sprague-Dawley control rats. By echocardiography, SHR hearts had cardiac hypertrophy and enhanced contractility (increased fractional shortening) and no signs of heart failure. SHR cells had a voltage-dependent increase in peak [Ca2+]i amplitude (at 0 mV, 1330+/-62 nmol/L [SHRs] versus 836+/-48 nmol/L [controls], P<0.05) that was not associated with changes in ICa,L density or kinetics, resting [Ca2+]i, or Ca2+ content of the sarcoplasmic reticulum (SR). SHR cells had increased time of relaxation. Ca2+ sparks from SHR cells had larger average amplitudes (173+/-192 nmol/L [SHRs] versus 109+/-64 nmol/L [control]; P<0.05), which was due to redistribution of Ca2+ sparks to a larger amplitude population. This change in Ca2+ spark amplitude distribution was not associated with any change in the density of ryanodine receptors, calsequestrin, junctin, triadin 1, Ca2+-ATPase, or phospholamban. Therefore, SHRs with cardiac hypertrophy have increased contractility, [Ca2+]i amplitude, time to relaxation, and average Ca2+ spark amplitude ("big sparks"). Importantly, big sparks occurred without alteration in the trigger for SR Ca2+ release (ICa,L), SR Ca2+ content, or the expression of several SR Ca2+-cycling proteins. Thus, cardiac hypertrophy in SHRs is linked with an alteration in the coupling of Ca2+ entry through L-type Ca2+ channels and the release of Ca2+ from the SR, leading to big sparks and enhanced contractility. Alterations in the microdomain between L-type Ca2+ channels and SR Ca2+ release channels may underlie the changes in Ca2+ homeostasis observed in cardiac hypertrophy. Modulation of SR Ca2+ release may provide a new therapeutic strategy for cardiac hypertrophy and for its progression to heart failure and sudden death.     

Increased phospholamban phosphorylation limits the force-frequency response in the MLP-/- mouse with heart failure

Reduced Ca(2+) release from the sarcoplasmic reticulum (SR) and a negative force-frequency relation characterize end-stage human heart failure. The MLP(-/-) mouse with dilated cardiomyopathy is used as a model to explore novel therapeutic interventions but the alterations in Ca(2+) handling in MLP(-/-) remain incompletely understood. We studied [Ca(2+)](i) in left ventricular myocytes from MLP(-/-) and WT mice (3-4 months old; whole-cell voltage clamp, 30 degrees C). At 1 Hz stimulation, the amplitude of [Ca(2+)](i) transients was similar. However, in contrast to WT, at higher frequencies the [Ca(2+)](i) transient amplitude declined in MLP(-/-) and there was no increase in SR Ca(2+) content. Unexpectedly, the decline of [Ca(2+)](i) was faster in MLP(-/-) than in WT (at 1 Hz, tau of 80 +/- 9 vs. 174 +/- 29 ms, P < 0.001) and the frequency-dependent acceleration of the decline was abolished suggesting an enhanced basal SERCA activity. Indeed, the Ca(2+) affinity of SR Ca(2+) uptake in homogenates was higher in MLP(-/-), with the maximal uptake rate similar to WT. Phosphorylation of phospholamban in MLP(-/-) was increased (2.3-fold at Ser(16) and 2.9-fold at the Thr(17) site, P < 0.001) with similar SERCA and total phospholamban protein levels. On increasing stimulation frequency to 4 Hz, WT, but not MLP(-/-), myocytes had a net gain of Ca(2+), suggesting inadequate Ca(2+) sequestration in MLP(-/-). In conclusion, increased baseline phosphorylation of phospholamban in MLP(-/-) leads to a reduced reserve for frequency-dependent increase of Ca(2+) release. This represents a novel paradigm for altered Ca(2+) handling in heart failure, underscoring the importance of phosphorylation pathways.     

Immunogold-labeled L-type calcium channels are clustered in the surface plasma membrane overlying junctional sarcoplasmic reticulum in guinea-pig myocytes-implications for excitation-contraction coupling in cardiac muscle

Ca(2+) release through ryanodine receptors, located in the membrane of the junctional sarcoplasmic reticulum (SR), initiates contraction of cardiac muscle. Ca(2+)influx through plasma membrane L-type Ca(2+)channels is thought to be an important trigger for opening ryanodine receptors ("Ca(2+)-induced Ca(2+)-release"). Optimal transmission of the transmembrane Ca(2+)influx signal to SR release is predicted to involve spatial juxtaposition of L-type Ca(2+)channels to the ryanodine receptors of the junctional SR. Although such spatial coupling has often been implicitly assumed, and data from immunofluorescence microscopy are consistent with its existence, the definitive demonstration of such a structural organization in mammalian tissue is lacking at the electron-microscopic level. To determine the spatial distribution of plasma membrane L-type Ca(2+)channels and their location in relation to underlying junctional SR, we applied two high-resolution immunogold-labeling techniques, label-fracture and cryothin-sectioning, combined with quantitative analysis, to guinea-pig ventricular myocytes. Label-fracture enabled visualization of colloidal gold-labeled L-type Ca(2+)channels in planar freeze-fracture electron-microscopic views of the plasma membrane. Mathematical analysis of the gold label distribution (by nearest-neighbor distance distribution and the radial distribution function) demonstrated genuine clustering of the labeled channels. Gold-labeled cryosections showed that labeled L-type Ca(2+)channels quantitatively predominated in domains of the plasma membrane overlying junctional SR. These findings provide an ultrastructural basis for functional coupling between L-type Ca(2+)channels and junctional SR and for excitation-contraction coupling in guinea-pig cardiac muscle.     

Altered action potential dynamics in electrically remodeled canine atria: evidence for altered intracellular Ca2+ handling.

BACKGROUND: Electrical instability following sustained rapid excitation has been attributed to altered ion channels. Alterations of Ca(2+) handling could also contribute to abnormal dynamics of action potential, favoring the initiation and perpetuation of arrhythmia. METHODS AND RESULTS: Transmembrane action potentials and twitch force (TF) were recorded from normal (n=6) and remodeled (6-week atrial pacing at 400 beats/min, n=6) canine atria. When the cycle length (CL) was suddenly prolonged in normal atria, both TF and action potential duration (APD) increased on the first beat, and decreased subsequently. Opposite changes were observed with sudden CL shortening. These dynamics in both APD and TF were abolished by ryanodine, but augmented by cyclopiazonic acid, an inhibitor of the sarcoplasmic reticulum (SR) Ca(2+) pump. In remodeled atria (RA), dynamic changes in APD were also concordant with dynamic changes in TF. The transient increases in APD and TF were enhanced, and the transient decreases were reduced compared to normal atria. The maximal slopes of APD and TF restitution curves were flatter and the magnitude of alternans was reduced in RA. The protein expression of SR Ca(2+) ATPase and SR Ca(2+)-release channel in RA was significantly reduced. CONCLUSION: Altered Ca(2+) handling may underlie abnormal APD dynamics in RA.     

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.