Complex and rate-dependent beat-to-beat variations in Ca2+ transients of canine Purkinje cells

Purkinje fibers play an essential role in transmitting electrical impulses through the heart, but they may also serve as triggers for arrhythmias linked to defective intracellular calcium (Ca(2+)) regulation. Although prior studies have extensively characterized spontaneous Ca(2+) release in nondriven Purkinje cells, little attention has been paid to rate-dependent changes in Ca(2+) transients. Therefore we explored the behaviors of Ca(2+) transients at pacing rates ranging from 0.125 to 3 Hz in single canine Purkinje cells loaded with fluo3 and imaged with a confocal microscope. The experiments uncovered the following novel aspects of Ca(2+) regulation in Purkinje cells: 1) the cells exhibit a negative Ca(2+)-frequency relationship (at 2.5 Hz, Ca(2+) transient amplitude was 66 ± 6% smaller than that at 0.125 Hz); 2) sarcoplasmic reticulum (SR) Ca(2+) release occurs as a propagating wave at very low rates but is localized near the cell membrane at higher rates; 3) SR Ca(2+) load declines modestly (10 ± 5%) with an increase in pacing rate from 0.125 Hz to 2.5 Hz; 4) Ca(2+) transients show considerable beat-to-beat variability, with greater variability occurring at higher pacing rates. Analysis of beat-to-beat variability suggests that it can be accounted for by stochastic triggering of local Ca(2+) release events. Consistent with this hypothesis, an increase in triggering probability caused a decrease in the relative variability. These results offer new insight into how Ca(2+) release is normally regulated in Purkinje cells and provide clues regarding how disruptions in this regulation may lead to deleterious consequences such as arrhythmias.     

Burst emergence of intracellular Ca2+ waves evokes arrhythmogenic oscillatory depolarization via the Na+-Ca2+ exchanger: simultaneous confocal recording of membrane potential and intracellular Ca2+ in the heart

Intracellular Ca(2+) waves (CaWs) of cardiomyocytes are spontaneous events of Ca(2+) release from the sarcoplasmic reticulum that are regarded as an important substrate for triggered arrhythmias and delayed afterdepolarizations. However, little is known regarding whether or how CaWs within the heart actually produce arrhythmogenic membrane oscillation because of the lack of data confirming direct correlation between CaWs and membrane potentials (V(m)) in the heart. On the hypothesis that CaWs evoke arrhythmogenic oscillatory depolarization when they emerge synchronously and intensively in the heart, we conducted simultaneous fluorescence recording of intracellular Ca(2+) ([Ca(2+)](i)) dynamics and V(m) of ventricular myocytes on subepicardial surfaces of Langendorff-perfused rat hearts using in situ dual-view, rapid-scanning confocal microscopy. In intact hearts loaded with fluo4/acetoxymethyl ester and RH237 under perfusion with cytochalasin D at room temperature, individual myocytes exhibited Ca(2+) transients and action potentials uniformly on ventricular excitation, whereas low-K(+)-perfused (2.4 mmol/L) hearts exhibited CaWs sporadically between Ca(2+) transients without discernible membrane depolarization. Further [Ca(2+)](i) loading of the heart, produced by rapid pacing and addition of isoproterenol, evoked triggered activity and subsequent oscillatory V(m), which are caused by burst emergence of CaWs in individual myocytes. Such arrhythmogenic membrane oscillation was abolished by ryanodine or the Na(+)-Ca(2+) exchanger inhibitor SEA0400, indicating an essential role of CaWs and resultant Na(+)-Ca(2+) exchanger-mediated depolarization in triggered activity. In summary, we demonstrate a mechanistic link between intracellular CaWs and arrhythmogenic oscillatory depolarizations in the heart. Our findings provide a cellular perspective on abnormal [Ca(2+)](i) handling in the genesis of triggered arrhythmias in the heart.     

Nonuniform Ca2+ transients in arrhythmogenic Purkinje cells that survive in the infarcted canine heart

OBJECTIVE AND METHODS: In this study, we investigated whether Ca(2+) transients are altered in Purkinje cell aggregates dispersed from the subendocardium overlying the infarcted zone of the left ventricle (IZPCs) 48 h after coronary artery occlusion. To do so, we combined epifluorescent imaging with microelectrode recordings of IZPCs and normal canine Purkinje cell aggregates (NZPCs). RESULTS: NZPCs respond to an action potential (AP) by a small Ca(2+) transient at the cell surface immediately after the AP upstroke followed by a large [Ca(2+)] transient, which propagates to the cell core. In addition, focal Ca(2+) waves can originate spontaneously later during the AP or during the diastolic interval (Circ Res 2000;86:448-55) and then propagate throughout the aggregate as 'cell-wide Ca(2+) waves'. Electrically-evoked Ca(2+) transients in IZPCs arose significantly faster than those in NZPCs, and showed substantial spatiotemporal nonuniformity within an IZPC aggregate as well as between IZPC aggregates. IZPCs showed, hitherto undetected, low amplitude, micro Ca(2+) transients (extent 相似文献   

Excitation-dependent intracellular Ca2+ waves at the border zone of the cryo-injured rat heart revealed by real-time confocal microscopy

Intracellular Ca2+ waves, which develop under Ca2+-overloaded conditions of the injured myocardium, are regarded as an important substrate for triggered arrhythmias. However, little is known about whether Ca2+ waves arise or become proarrhythmic in the injured heart in situ. On the hypothesis that injured myocardium manifests frequent Ca2+ waves and produce an oscillatory [Ca2+]i rise leading to triggered activity, we applied cryo-injury to the epicardial surface of fluo 3-AM-loaded perfused rat hearts and analyzed spatiotemporal [Ca2+]i changes at border zones of the injured myocardium using real-time confocal microscopy. In intact regions Ca2+ waves barely emerged, whereas the border zone myocardium exhibited frequent Ca2+ waves, propagating randomly within the individual cells. Two different types of Ca2+ waves were identified: highly frequent waves (159.6+/-86.5 waves/min/cell, n=266) adjacent to the cryo-ablated regions, and less frequent waves (79.0+/-50.1 waves/min/cell, n=160) slightly farther (>2 cells) away from the ablated regions (vicinities). The former Ca2+ waves emerged asynchronously to Ca2+ transients. Contrariwise, the latter depended on ventricular excitation: they vanished instantaneously on Ca2+ transients, but emerged more frequently and propagated more swiftly after cessation of higher-frequency pacing. Immediately after 3-Hz pacing, some cryo-injured hearts exhibited oscillatory [Ca2+]i rises; an instantaneous and synchronous elevation of [Ca2+]i followed by burst occurrence of Ca2+ waves with a gradual decrease in incidence and propagation velocity in a considerable number of cells. These observations indicate that myocardial injury induces Ca2+ waves in the heart, and that their synchronous occurrence could become a substrate for triggered arrhythmias.     

Bergmann glia modulate cerebellar Purkinje cell bistability via Ca2+-dependent K+ uptake

Recent studies have shown that cerebellar Bergmann glia display coordinated Ca(2+) transients in live mice. However, the functional significance of Bergmann glial Ca(2+) signaling remains poorly understood. Using transgenic mice that allow selective stimulation of glial cells, we report here that cytosolic Ca(2+) regulates uptake of K(+) by Bergmann glia, thus providing a powerful mechanism for control of Purkinje cell-membrane potential. The decline in extracellular K(+) evoked by agonist-induced Ca(2+) in Bergmann glia transiently increased spike activity of Purkinje cells in cerebellar slices as well as in live anesthetized mice. Thus, Bergmann glia play a previously unappreciated role in controlling the membrane potential and thereby the activity of adjacent Purkinje cells.     

2APB- and JTV519(K201)-sensitive micro Ca waves in arrhythmogenic Purkinje cells that survive in infarcted canine heart

OBJECTIVES/BACKGROUND: Studies from several laboratories have implicated intracellular Ca(2+) dynamics in the modulation of electrical activity. We have reported that abnormal Ca(2+) wave activity is the underlying cause of afterdepolarization-induced electrical activity in subendocardial Purkinje cells that survive in the 48-hour infarcted canine heart. These cells form the focus of arrhythmias at this time postcoronary artery occlusion. METHODS: We studied the effects of agonists and antagonists on the abnormal Ca(2+) release activity of Purkinje cell aggregates dispersed from the subendocardium 48 hours postcoronary artery occlusion (IZPCs). Studies were completed using epifluorescent microscopy of Fluo-3 loaded Purkinje cells. RESULTS: Similar to our previous report, highly frequent traveling micro Ca(2+) transients (muCaiTs) and cell-wide Ca(2+) waves were seen in IZPCs in the absence of any drug. Isoproterenol (ISO) increased muCaiTs and cell-wide Ca(2+) waves in Purkinje cells dispersed from the normal heart (NZPCs). In IZPCs, ISO increased cell-wide wave frequency but had no effect on the already highly frequent micro Ca(2+) wave transient activity, suggesting that ISO lowers the threshold of cell-wide generators responding to micro Ca(2+) transients. Drugs that block inward sodium or calcium currents (verapamil, tetrodotoxin) had no effect on Ca(2+) activity in Purkinje cells. Antagonists of intracellular Ca(2+) release channels [ryanodine, JTV519(K201)] greatly suppressed spontaneous Ca(2+) release events in IZPCs. 2APB, an agent that blocks IP(3) receptors, greatly reduced the frequency of Ca(2+) events in IZPCs. CONCLUSIONS: In arrhythmogenic Purkinje cells that survive in the infarcted heart, agents that block or inhibit intracellular Ca(2+) release channel activity reduced Ca(2+) waves and could be antiarrhythmic.     

A model of canine purkinje cell electrophysiology and Ca(2+) cycling: rate dependence, triggered activity, and comparison to ventricular myocytes

Purkinje cells (Pcell) are characterized by different electrophysiological properties and Ca(2+) cycling processes than ventricular myocytes (Vcell) and are frequently involved in ventricular arrhythmias. Yet, the mechanistic basis for their arrhythmic vulnerability is not completely understood. The objectives were to: (1) characterize Pcell electrophysiology, Ca(2+) cycling, and their rate dependence; (2) investigate mechanisms underlying Pcell arrhythmogenicity; and compare Pcell and Vcell electrophysiology, Ca(2+) cycling, and arrhythmic properties. We developed a new mathematical model of Pcell. The Ca(2+) subsystem includes spatial organization and receptors distribution unique to Pcell. Results were: (1) in Pcell and Vcell, Na(+) accumulation via its augmentation of repolarizing I(NaK) dominates action potential duration adaptation and, in Pcell, I(NaL) contributes additional action potential duration shortening at short cycle length; (2) steep Pcell restitution is attributable to slow recovery of I(NaL); (3) biphasic Ca(2+) transients of Pcell reflect the delay between Ca(2+) release from junctional sarcoplasmic reticulum and corbular sarcoplasmic reticulum; (4) Pcell Ca(2+) alternans, unlike Vcell, can develop without inducing action potential alternans; (5) Pcell action potential alternans develops at a shorter cycle length than Vcell, with increased subcellular heterogeneity of Ca(2+) cycling attributable to refractoriness of Ca(2+) release from corbular sarcoplasmic reticulum and junctional sarcoplasmic reticulum; (6) greater Pcell vulnerability to delayed afterdepolarizations is attributable to higher sarcoplasmic reticulum Ca(2+) content and ionic currents that reduce excitation threshold and promote triggered activity; and (7) early after depolarizations generation in Pcell is mostly attributable to reactivation of I(NaL2), whereas I(CaL) plays this role in Vcell. Steeper rate dependence of action potential and Ca(2+) transients, central peripheral heterogeneity of Ca(2+) cycling, and distinct ion channel profile underlie greater arrhythmic vulnerability of Pcell compared to Vcell.     

Ion channels and arrhythmias

Changes in ionic currents through ion channels of the myocardial cell membrane have to be regarded as main cause of cardiac arrhythmias. Three basic arrhythmogenic mechanisms are responsible for the initiation of tachyarrhythmias: 1. The disturbance of normal automaticity in cardiac pacemaker cells dependent on the currents If, ICa-L, ICa-T or IK-ACh,Ado and the occurrence of abnormal automaticity in atrial and ventricular working myocardium based on the currents ICa-L, INa, IK, IK1 or IK-ACh,Ado. 2. Triggered activity which may be recognized by the appearance of early (EAD) or late afterdepolarizations (LAD). EAD are mainly due to inhibition of the outward currents IKr and IKs and are favoured by an increase in the inward currents INa and ICa-L, respectively. Typical arrhythmias are torsade de pointes occurring during treatment with K(+)-channel inhibitors (e.g. sotalol) or in patients with QT-syndrome. LAD may be observed during Ca(2+)-overload of the myocardial cell (digitalis intoxication, catecholamines) and are based on the transient inward current Iti, which is build up by the participation of the currents INa/Ca, INS and ICa-L. 3. Reentry mechanisms are the most frequent cause of tachyarrhythmias. They originate in an anatomically defined excitation circle with unidirectional block. Na(+)- and Ca(2+)-channel dependent disturbances of conduction with long excitable gap may be distinguished from Na(+)-channel dependent disturbances of conduction and refractory period with short excitable gap. Interruption of reentry is possible in the first case by depression of conduction and excitability (Na(+)- or Ca(2+)-channel blockers), in the second case by increase in refractory period (K(+)- or Na(+)-channel blockers).     

Role of the conduction system in the endocardial excitation spread in the right ventricle

The role of the Purkinje network in the excitation sequence in the endocardial surface of the right ventricle was studied using an isolated perfused canine preparation. The preparation was electrically stimulated at the proximal right bundle branch, and the activation time was mapped using contiguous bipolar electrodes or a microelectrode, or both. The earliest activation of muscle was observed at the junction between the ventricular septum and the free wall in front of the anterior papillary muscle. After the initial activation, the spread of ventricular muscle excitation in the free wall was essentially radial at a mean (± standard deviation) conduction velocity of 1.67 ± 0.20 m/s. The activation of muscle in this area was almost always preceded by the activation of Purkinje fibers by 2 to 6 ms. Thus the Purkinje system was considered indispensable for the excitation spread in this area. In the lower third of the septum, the excitation sequence was essentially similar to that of the free wall, indicating a possible contribution of the fast conducting Purkinje system. In contrast, in the upper two thirds of the septum the activation of ventricular muscle spread from apex to base with a significantly delayed conduction velocity of 0.41 ± 0.88 m/s, and it was not preceded by activation of Purkinje fibers, thus indicating the lack of involvement of the Purkinje system.Functional distribution of the anterior, posterior and lateral branches of the right bundle to the excitation spread of the right ventricular endocardial muscle was confirmed by the selective transection of one of these special conducting fibers, which suggested the etiologic significance of injury to each branch of the right bundle as a cause of various electrocardiographic patterns of incomplete right bundle branch block.     

Mechanisms by which discharge modulates diastolic depolarization in sheep and dog Purkinje fibers

For reasons unknown, a fast drive is prone to induce overdrive excitation in sheep Purkinje fibers under conditions that still induce overdrive suppression in dog Purkinje fibers. Our aim was to study by means of a microelectrode technique diastolic depolarization (DD) and its changes with overdrive in sheep and dog Purkinje fibers perfused in vitro under identical conditions. The major results are: (a) At a slow rate, diastolic depolarization is much faster and larger in sheep than in dog Purkinje fibers. (b) Faster rates increase DD slope and amplitude in sheep and decrease them in dog Purkinje fibers. (c) DD slope and amplitude increase in sheep and decrease in dog if the same number of action potentials are separated by a shorter diastole. (d) The change in DD slope and amplitude induced by a fast drive persists after a subsequent slow drive of approximately 20 s. (e) The fastest drives can induce an oscillatory potential superimposed on early DD in sheep. (f) In both species, high [Ca(2+)](o) increases and low [Ca(2+)](o) decreases DD slope and amplitude. (g) Neither high nor low [Ca(2+)](o) change the DD rate-dependence patterns peculiar to either species. (h) DD amplitude in dog in high [Ca(2+)](o) is still smaller than that in sheep in Tyrode solution. (i) Caffeine prevents the steepening of early DD by drive, but not the subsequent increase which can lead to overdrive excitation in both species. (j) TTX decreases DD slope and amplitude in both species. (k) Cs(+) markedly reduces DD slope and amplitude and more so at faster rates, especially in the sheep. We conclude that the differences in diastolic depolarization and the different behavior of DD with overdrive in the two species account for the propensity of sheep Purkinje fibers to develop overdrive excitation and for that of dog Purkinje fibers to develop overdrive suppression.     

Influence of interleukin-2 on Ca2+ handling in rat ventricular myocytes

In the present study, we examined the effect of interleukin-2 (IL-2) on cardiomyocyte Ca(2+) handling. The effects of steady-state and transient changes in stimulation frequency on the intracellular Ca(2+) transient were investigated in isolated ventricular myocytes by spectrofluorometry. In the steady state (0.2 Hz) IL-2 (200 U/ml) decreased the amplitude of Ca(2+) transients induced by electrical stimulation and caffeine. At 1.25 mM extracellular Ca(2+) concentration ([Ca(2+)](o)), when the stimulation frequency increased from 0.2 to 1.0 Hz, diastolic Ca(2+) level and peak intracellular Ca(2+) concentration ([Ca(2+)](i)), as well as the amplitude of the transient, increased. The positive frequency relationships of the peak and amplitude of [Ca(2+)](i) transients were blunted in the IL-2-treated myocytes. The effect of IL-2 on the electrically induced [Ca(2+)](i) transient was not normalized by increasing [Ca(2+)](o) to 2.5 mM. IL-2 inhibited the frequency relationship of caffeine-induced Ca(2+) release. Blockade of sarcoplasmic reticulum (SR) Ca(2+)-ATPase with thapsigargin resulted in a significant reduction of the amplitude-frequency relationship of the transient similar to that induced by IL-2. The restitutions were not different between control and IL-2 groups at 1.25 mM [Ca(2+)](o), which was slowed in IL-2-treated myocytes when [Ca(2+)](o) was increased to 2.5 mM. There was no difference in the recirculation fraction (RF) between control and IL-2-treated myocytes at both 1.25 and 2.5 mM [Ca(2+)](o). The effects of IL-2 on frequency relationship, restitution, and RF may be due to depressed SR functions and an increased Na(+)-Ca(2+) exchange activity, but not to any change in L-type Ca(2+) channels.     

In Situ Confocal Imaging in Intact Heart Reveals Stress-Induced Ca2+ Release Variability in a Murine Catecholaminergic Polymorphic Ventricular Tachycardia Model of Type 2 Ryanodine ReceptorR4496C+/- Mutation

Background- Catecholaminergic polymorphic ventricular tachycardia is directly linked to mutations in proteins (eg, type 2 ryanodine receptor [RyR2](R4496C)) responsible for intracellular Ca(2+) homeostasis in the heart. However, the mechanism of Ca(2+) release dysfunction underlying catecholaminergic polymorphic ventricular tachycardia has only been investigated in isolated cells but not in the in situ undisrupted myocardium. Methods and Results- We investigated in situ myocyte Ca(2+) dynamics in intact Langendorff-perfused hearts (ex vivo) from wild-type and RyR2(R4496C+/-) mice using laser scanning confocal microscopy. We found that myocytes from both wild-type and RyR2(R4496C+/-) hearts displayed uniform, synchronized Ca(2+) transients. Ca(2+) transients from beat to beat were comparable in amplitude with identical activation and decay kinetics in wild-type and RyR2(R4496C+/-) hearts, suggesting that excitation-contraction coupling between the sarcolemmal Ca(2+) channels and mutated RyR2(R4496C+/-) channels remains intact under baseline resting conditions. On adrenergic stimulation, RyR2(R4496C+/-) hearts exhibited a high degree of Ca(2+) release variability. The varied pattern of Ca(2+) release was absent in single isolated myocytes, independent of cell cycle length, synchronized among neighboring myocytes, and correlated with catecholaminergic polymorphic ventricular tachycardia. A similar pattern of action potential variability, which was synchronized among neighboring myocytes, was also revealed under adrenergic stress in intact hearts but not in isolated myocytes. Conclusions- Our studies using an in situ confocal imaging approach suggest that mutated RyR2s are functionally normal at rest but display a high degree of Ca(2+) release variability on intense adrenergic stimulation. Ca(2+) release variability is a Ca(2+) release abnormality, resulting from electric defects rather than the failure of the Ca(2+) release response to action potentials in mutated ventricular myocytes. Our data provide important insights into Ca(2+) release and electric dysfunction in an established model of catecholaminergic polymorphic ventricular tachycardia.     

Calcium handling and role of endothelin-1 in monocrotaline right ventricular hypertrophy of the rat

We investigated the role of endothelin-1 (ET-1) in right ventricular function and intracellular Ca(2+)(Ca(2+)(i)) handling of isolated perfused rat hearts with right ventricular hypertrophy induced by monocrotaline (50 mg/kg). Nine weeks after monocrotaline (n=9) or saline (control n=9) treatment, hearts were perfused isovolumically at 37 degrees C and right ventricular function (fluid-filled balloon), right ventricular intracellular Ca(2+) transients (aequorin bioluminescence method) and the effects of ET-1 were determined. Monocrotaline-treated rats developed considerable right ventricular hypertrophy (right ventricular weight:body weight ratio: 1.07+/-0.13 v. 0.60+/-0.03 in controls P<0.05) and these hearts generated higher right ventricular systolic and diastolic pressure, but similar systolic and diastolic wall stress, indicating a compensated functional state. Hypertrophied hearts demonstrated a prolonged duration of isovolumic contraction (time to 90% decline from peak: 105+/-1 v 89+/-4 ms at 3 m M extracellular Ca(2+) P<0.05), but neither the time to peak pressure (71+/-3 ms) nor time to peak light (25+/-3 ms) were different from controls. The increased duration of contraction correlated with a similar prolongation of the Ca(2+)transient (time to 90% decline from peak: 72+/-4 v 50+/-3 ms P<0.05), indicating a reduced rate of Ca(2+)sequestration in hypertrophic right ventricles. Peak systolic intracellular Ca(2+)was similar in control and hypertrophied hearts (1.04+/-0.02 and 0.99+/-0.02 microM, P>0.05, n=6). ET-1 (1-300 p M) affected neither the time course of right ventricular contraction nor that of the Ca(2+)transient or peak systolic Ca(2+)concentrations. These data are the first measurements of right ventricular Ca(2+)transients in beating normal and hypertrophic hearts. We conclude that ET-1 plays no role in compensated hypertrophy because it affected neither right ventricular function nor intracellular Ca(2+)handling in this model.     

Intranuclear Ca2+ transients during neurite regeneration of an adult mammalian neuron.

Depolarization-induced increases in cytoplasmic and intranuclear Ca2+ were visualized in adult mammalian dorsal root ganglion (DRG) neurons during different stages of neurite extension by using confocal laser scanning microscopy and the long-wavelength Ca2+ indicator dye fluo 3-AM (acetoxymethyl ester of fluo 3). In neurons beginning to extend neurites, depolarization led to pronounced increases in nuclear and nucleolar Ca2+ levels severalfold greater than corresponding increases in the cytoplasm. The nucleolar Ca2+ signal often exceeded that of the nucleus, indicating regional heterogeneity of the nucleus. The subcellular calcium transients were dependent on extracellular Ca2+ and the level of depolarization, indicating the importance of transmembrane Ca2+ fluxes in triggering the nuclear events. After neurite extension, the nuclear Ca2+ signals were attenuated and never exceeded cytoplasmic levels. These results indicate that activity-dependent modulation of intranuclear Ca2+ levels is greater in DRG neurons during early neurite extension. Given the importance of Ca2+ in gene expression, the results may be relevant to Ca(2+)-dependent nuclear events responsible for axonal regeneration.     

Alpha(1)-adrenoceptor subtypes mediate negative inotropy in myocardium from alpha(1A/C)-knockout and wild type mice

Cardiac alpha(1)-adrenoceptors (AR) have two predominant subtypes (alpha(1A)-AR and alpha(1B)-AR) however, their roles in regulating contraction are unclear. We determined the effects of stimulating alpha(1A)-AR (using the subtype-selective agonist A61603) and alpha(1B)-AR (using a gene knockout mouse lacking alpha(1A)-AR) separately, and together (using phenylephrine) on Ca(2+) transients, intracellular pH, and contraction of mouse cardiac trabeculae. Stimulation of alpha(1)-AR subtypes separately or together caused a triphasic contractile response. After a transient ( approximately 3%) force rise (phase 1), force declined markedly (phase 2), then partially recovered (phase 3). In phase 2, the force decline (% of initial) with combined alpha(1A)-AR plus alpha(1B)-AR stimulation (50+/-3%) was more than with separate subtype stimulation (P<0.01), suggesting alpha(1A)-AR and alpha(1B)-AR mediate additive effects during phase 2. Force decline in phase 2 paralleled decreases of Ca(2+) transients that were reduced more with combined vs. separate subtype stimulation. During phase 3 the final force reduction was similar with stimulation of alpha(1A)-AR (20+/-5%), or alpha(1B)-AR (20+/-3%), or both (26+/-4%) suggesting alpha(1A)-AR and alpha(1B)-AR mediate non-additive effects during phase 3. In contrast, Ca(2+) transients recovered fully in phase 3 suggesting reduced force in phase 3 involved decreased myofilament Ca(2+)-sensitivity. Decreased Ca(2+)-sensitivity was not mediated by changes of intracellular pH since this was not affected by alpha(1)-AR stimulation. In contrast to mouse trabeculae, rat trabeculae demonstrated a positive inotropic response to alpha(1)-AR stimulation. In conclusion, for mouse myocardium in vitro both alpha(1)-adrenoceptor subtypes mediate negative inotropy involving decreased Ca(2+) transients and a decreased Ca(2+) sensitivity that does not involve altered intracellular pH.     

Three distinct types of Ca(2+) waves in Langendorff-perfused rat heart revealed by real-time confocal microscopy

Although Ca(2+) waves in cardiac myocytes are regarded as arrhythmogenic substrates, their properties in the heart in situ are poorly understood. On the hypothesis that Ca(2+) waves in the heart behave diversely and some of them influence the cardiac function, we analyzed their incidence, propagation velocity, and intercellular propagation at the subepicardial myocardium of fluo 3-loaded rat whole hearts using real-time laser scanning confocal microscopy. We classified Ca(2+) waves into 3 types. In intact regions showing homogeneous Ca(2+) transients under sinus rhythm (2 mmol/L [Ca(2+)](o)), Ca(2+) waves did not occur. Under quiescence, the waves occurred sporadically (3.8 waves. min(-1) x cell(-1)), with a velocity of 84 microm/s, a decline half-time (t(1/2)) of 0.16 seconds, and rare intercellular propagation (propagation ratio <0.06) (sporadic wave). In contrast, in presumably Ca(2+)-overloaded regions showing higher fluorescent intensity (113% versus the intact regions), Ca(2+) waves occurred at 28 waves x min(-1) x cell(-1) under quiescence with a higher velocity (116 microm/s), longer decline time (t(1/2) = 0.41 second), and occasional intercellular propagation (propagation ratio = 0.23) (Ca(2+)-overloaded wave). In regions with much higher fluorescent intensity (124% versus the intact region), Ca(2+) waves occurred with a high incidence (133 waves x min(-1) x cell(-1)) and little intercellular propagation (agonal wave). We conclude that the spatiotemporal properties of Ca(2+) waves in the heart are diverse and modulated by the Ca(2+)-loading state. The sporadic waves would not affect cardiac function, but prevalent Ca(2+)-overloaded and agonal waves may induce contractile failure and arrhythmias.     

Calcium-activated Cl(-) current contributes to delayed afterdepolarizations in single Purkinje and ventricular myocytes

BACKGROUND: The ionic mechanism underlying the transient inward current (I(ti)), the current responsible for delayed afterdepolarizations (DADs), appears to be different in ventricular myocytes and Purkinje fibers. In ventricular myocytes, I(ti) was ascribed to a Na(+)-Ca(2+) exchange current, whereas in Purkinje fibers, it was additionally ascribed to a Cl(-) current and a nonselective cation current. If Cl(-) current contributes to I(ti) and thus to DADs, Cl(-) current blockade may be potentially antiarrhythmogenic. In this study, we investigated the ionic nature of I(ti) in single sheep Purkinje and ventricular myocytes and the effects of Cl(-) current blockade on DADs. METHODS AND RESULTS: In whole-cell patch-clamp experiments, I(ti) was induced by repetitive depolarizations from -93 to +37 mV in the presence of 1 micromol/L norepinephrine. In both Purkinje and ventricular myocytes, I(ti) was inward at negative potentials and outward at positive potentials. The anion blocker 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS) blocked outward I(ti) completely but inward I(ti) only slightly. The DIDS-sensitive component of I(ti) was outwardly rectifying, with a reversal close to the reversal potential of Cl(-) currents. Blockade of Na(+)-Ca(2+) exchange by substitution of extracellular Na(+) by equimolar Li(+) abolished the DIDS-insensitive component of I(ti). DIDS reduced both DAD amplitude and triggered activity based on DADs. Conclusions-In both Purkinje and ventricular myocytes, I(ti) consists of 2 ionic mechanisms: a Cl(-) current and a Na(+)-Ca(2+) exchange current. Blockade of the Cl(-) current may be potentially antiarrhythmogenic by lowering DAD amplitude and triggered activity based on DADs.     

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).     

Mechanisms underlying enhanced cardiac excitation contraction coupling observed in the senescent sheep myocardium

Ageing related stiffening of the vascular system is believed to be in part responsible for a number of clinical outcomes including hypertension and heart failure. In the present study, we sought to determine whether there are alterations in cardiac excitation contraction coupling that may help compensate for the increased vessel stiffness. Experiments were performed on single cardiac myocytes isolated from young (18 months) and aged (>8 years) sheep. Intracellular Ca(2+) concentration, action potentials, L-type Ca(2+) currents and SR Ca(2+) content were measured at 23 degrees C. With ageing, cell capacitance increased by 26% indicating cellular hypertrophy. Action potential duration (APD90) (590 +/- 21 vs. 726 +/- 36 ms), Ca(2+) transient amplitude (112 +/- 15 vs. 202 +/- 25 nmol l(-1)) and fractional cell shortening (by 37%) also increased in the aged hearts (all values P < 0.05). The larger Ca(2+) transient amplitude observed under current clamp conditions was maintained under voltage clamp control; however, SR Ca(2+) content was identical. Both the peak L-type Ca(2+) current (2.8 +/- 0.3 vs. 4.9 +/- 0.5 pA pF(-1)) and integrated Ca(2+) entry (5.1 +/- 0.7 vs. 7.9 +/- 0.8 micromol l(-1), all P < 0.01) were greater in aged cells. In this study we show that in the ageing ovine myocardium, the amplitude of the systolic Ca(2+) transient is increased. The larger Ca(2+) transients cannot simply be explained by changes in APD and we suggest that the greater inward L-type Ca(2+) current provides a more effective trigger for calcium-induced-calcium release from the SR whilst maintaining a stable SR Ca(2+) content. These changes in cardiac excitation contraction coupling may help maintain cardiac output in the face of increased great vessel stiffness.