Electrical activity and contraction in cells isolated from rat and guinea-pig ventricular muscle: a comparative study

Non-ionotropic voltage-gated calcium channel signaling

Voltage-gated calcium channels (VGCCs) are the major conduits for calcium ions (Ca2+) within excitable cells. Recent studies have highlighted the non-ionotropic functionality of VGCCs, revealing their capacity to activate intracellular pathways independently of ion flow. This non-ionotropic signaling mode plays a pivotal role in excitation-coupling processes, including gene transcription through excitation-transcription (ET), synaptic transmission via excitation-secretion (ES), and cardiac contraction through excitation-contraction (EC). However, it is noteworthy that these excitation-coupling processes require extracellular calcium (Ca2+) and Ca2+ occupancy of the channel ion pore. Analogous to the "non-canonical" characterization of the non-ionotropic signaling exhibited by the N-methyl-D-aspartate receptor (NMDA), which requires extracellular Ca2+ without the influx of ions, VGCC activation requires depolarization-triggered conformational change(s) concomitant with Ca2+ binding to the open channel. Here, we discuss the contributions of VGCCs to ES, ET, and EC coupling as Ca2+ binding macromolecules that transduces external stimuli to intracellular input prior to elevating intracellular Ca2+. We emphasize the recognition of calcium ion occupancy within the open ion-pore and its contribution to the excitation coupling processes that precede the influx of calcium. The non-ionotropic activation of VGCCs, triggered by the upstroke of an action potential, provides a conceptual framework to elucidate the mechanistic aspects underlying the microseconds nature of synaptic transmission, cardiac contractility, and the rapid induction of first-wave genes.

Comparison of guinea-pig ventricular myocytes and dog Purkinje fibres for in vitro assessment of drug-induced delayed repolarization

INTRODUCTION

QT interval prolongation and Torsade de Pointes (TdP) arrhythmias are recognised as a potential risk with many drugs, most of which delay cardiac repolarization by inhibiting the rapidly activating K(+) current (I(Kr)). The objective of this study was to compare the effects of compounds on cardiac action potentials recorded from guinea-pig ventricular myocytes and dog Purkinje fibres.

METHODS AND RESULTS

Effects of dofetilide, sotalol, cisapride, terfenadine, haloperidol and sparfloxacin, compounds known to cause QT prolongation (positive controls), and nifedipine and verapamil, not associated with QT prolongation (negative controls) were studied on intracellular action potentials recorded from guinea-pig isolated ventricular myocytes (VM) and dog isolated Purkinje fibres (PF). Prolongation of action potential duration (APD) by sotalol, dofetilide and sparfloxacin was concentration-dependent and of greater magnitude in dog PF compared to guinea-pig VM. The maximum prolongation of APD in guinea-pig VM at 0.5 and 1 Hz was approximately 25% and this was associated with complete inhibition of I(Kr) by dofetilide. Effects on APD of cisapride and haloperidol in both preparations, and terfenadine in guinea-pig VM, were biphasic, consistent with inhibition of multiple ion channels. There was no effect of terfenadine on APD in dog PF. Haloperidol increased APD by more than 25% in guinea-pig VM, consistent with effects on additional repolarizing currents. The negative controls shortened APD to a greater extent in guinea-pig VM compared to dog PF. In general, the positive control drugs increased action potential triangulation (APD(40-90)) to a greater extent than APD(90).

CONCLUSION

Guinea-pig isolated VM may be more sensitive for detecting APD prolongation with compounds inhibiting multiple ion channels and action potential triangulation (APD(40-90)). Effects on repolarizing currents other than I(Kr) were also distinguished in guinea-pig VM.

Differential Ca2+ and Sr2+ regulation of intracellular divalent cations release in ventricular myocytes

The regulation of the Ca2+ -induced Ca2+ release (CICR) from intracellular stores is a critical step in the cardiac cycle. The inherent positive feedback of CICR should make it a self-regenerating process. It is accepted that CICR must be governed by some negative control, but its nature is still debated. We explore here the importance of the Ca2+ released from sarcoplasmic reticulum (SR) on the mechanisms that may control CICR. Specifically, we compared the effect of replacing Ca2+ with Sr2+ on intracellular Ca2+ signaling in intact cardiac myocytes as well as on the function of single ryanodine receptor (RyR) Ca2+ release channels in panar bilayers. In cells, both CICR and Sr2+ -induced Sr2+ release (SISR) were observed. Action potential induced Ca2+ -transients and spontaneous Ca2+ waves were considerably faster than their Sr2+ -mediated counterparts. However, the kinetics of Ca2+ and Sr2+ sparks was similar. At the single RyR channel level, the affinities of Ca2+ and Sr2+ activation were different but the affinities of Ca2+ and Sr2+ inactivation were similar. Fast Ca2+ and Sr2+ stimuli activated RyR channels equally fast but adaptation (a spontaneous slow transition back to steady-state activity levels) was not observed in the Sr2+ case. Together, these results suggest that regulation of the RyR channel by cytosolic Ca2+ is not involved in turning off the Ca2+ spark. In contrast, cytosolic Ca2+ is important in the propagation global Ca2+ release events and in this regard single RyR channel sensitivity to cytosolic Ca2+ activation, not low-affinity cytosolic Ca2+ inactivation, is a key factor. This suggests that the kinetics of local and global RyR-mediated Ca2+ release signals are affected in a distinct way by different divalent cations in cardiac muscle cells.

Role of the Na+–H+exchanger (NHE1) in heart muscle function during transient acidosis. A study in papillary muscles from rat and guinea pig hearts

The sodium–hydrogen exchanger (NHE) helps the cell to recover from intracellular acidosis. In this study, we have investigated the effect of HOE 642 (a specific NHE1 blocker) on papillary muscles from rats and guinea pigs during transient acidosis and PKC activation by recording developed force (DF), action potential characteristics, and electrical conductance (stimulus–response interval). Two protocols were used, with or without HOE 642 (10–5mol/L): papillary muscle was exposed (i) for 15 min to a glucose-free, nonoxygenated HEPES buffer containing lactate (20 mmol/L) (pH 6.8) followed by 15 min recovery or (ii) to a PKC activator (phorbolmyristate acetate (PMA) (10–9mol/L)) for 30 min. The DF after acidification remained significantly decreased in the NHE-blocked papillary muscles. During recovery from acidosis, papillary muscles exposed to HOE 642 remained at a higher electrical resistance. The present study shows that post-acidotic continued depression of DF and change in tissue electrophysiological properties might occur as a result of blocking the NHE. During infarct development, the tissue-protecting effect of NHE blockade has been well documented. When acidosis or reduced contractile function is present, however, blocking NHE by HOE 642 might not improve the situation.Key words: sodium–hydrogen exchange (NHE), HOE 642 (cariporide), gap junction, PKC, acidosis.

Species-independent metabolic response to an increase of [Ca(2+)](i) in quiescent cardiac muscle

1. The aim of the present investigation was to contrast the Ca2+ dependence of cardiac energy metabolism in two species with differential reliance on extracellular Ca2+ for excitation-contraction coupling. 2. We measured energy expenditure as the rate of oxygen consumption (Vo2) of isolated, Langendorff-perfused hearts of rats and guinea-pigs during KCl arrest. In parallel experiments, we indexed intracellular Ca2+ concentration ([Ca2+]i) of isolated right-ventricular trabeculae, using the Ca2+ fluorophore fura-2 and ratiometric spectrofluorometry. By varying extracellular Na+ concentration ([Na+]o), Vo2-[Na+]o and [Ca2+]i-[Na+]o relationships were constructed for each species. 3. Reduction of [Na+]o during K+ arrest caused pronounced species-dependent elevations of both Vo2 and [Ca2+]i. Despite the species dependence of both Vo2 and [Ca2+]i on [Na+]o, a single species-independent Vo2-[Ca2+]i relationship obtained. 4. We infer that elevation of the metabolic rate of the arrested heart above its basal value is determined primarily by [Ca2+]i and is not species dependent.

The voltage-sensitive release mechanism of excitation contraction coupling in rabbit cardiac muscle is explained by calcium-induced calcium release

The putative voltage-sensitive release mechanism (VSRM) was investigated in rabbit cardiac myocytes at 37 degrees C with high resistance microelectrodes to minimize intracellular dialysis. When the holding potential was adjusted from -40 to -60 mV, the putative VSRM was expected to operate alongside CICR. Under these conditions however, we did not observe a plateau at positive potentials of the cell shortening versus voltage relationship. The threshold for cell shortening changed by -10 mV, but this resulted from a similar change of the threshold for activation of inward current. Cell shortening under conditions where the putative VSRM was expected to operate was blocked in a dose dependent way by nifedipine and CdCl2 and blocked completely by NiCl2. "Tail contractions" persisted in the presence of nifedipine and CdCl2 but were blocked completely by NiCl2. Block of early outward current by 4-aminopyridine and 4-acetoamido-4'-isothiocyanato-stilbene-2,2'-disulfonic acid (SITS) demonstrated persisting inward current during test depolarizations despite the presence of nifedipine and CdCl2. Inward current did not persist in the presence of NiCl2. A tonic component of cell shortening that was prominent during depolarizations to positive potentials under conditions selective for the putative VSRM was sensitive to rapidly applied changes in superfusate [Na+] and to the outward Na+/Ca2+ exchange current blocking drug KB-R7943. This component of cell shortening was thought to be the result of Na+/Ca2+ exchange-mediated excitation contraction coupling. Cell shortening recorded under conditions selective for the putative VSRM was increased by the enhanced state of phosphorylation induced by isoprenaline (1 microM) and by enhancing sarcoplasmic reticulum Ca2+ content by manipulation of the conditioning steps. Under these conditions, cell shortening at positive test depolarizations was converted from tonic to phasic. We conclude that the putative VSRM is explained by CICR with the Ca2+ "trigger" supplied by unblocked L-type Ca2+ channels and Na+/Ca2+ exchange.

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

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

Cytokine-induced nitric oxide production inhibits mitochondrial energy production and impairs contractile function in rat cardiac myocytes

OBJECTIVES

The present study examined whether nitric oxide (NO) produced by inducible nitric oxide synthase (iNOS) can directly inhibit aerobic energy metabolism and impair cell function in interleukin (IL)-1beta,-stimulated cardiac myocytes.

BACKGROUND

Recent reports have indicated that excessive production of NO induced by cytokines can disrupt cellular energy balance through the inhibition of mitochondrial respiration in a variety of cells. However, it is still largely uncertain whether the NO-induced energy depletion affects myocardial contractility.

METHODS

Primary cultures of rat neonatal cardiac myocytes were prepared, and NO2-/NO3- (NOx) in the culture media was measured using Griess reagent.

RESULTS

Treatment with IL-1beta (10 ng/ml) increased myocyte production of NOx in a time-dependent manner. The myocytes showed a concomitant significant increase in glucose consumption, a marked increase in lactate production, and a significant decrease in cellular ATP (adenosine 5'-triphosphate). These metabolic changes were blocked by co-incubation with N(G)-monomethyl-L-arginine (L-NMMA), an inhibitor of NO synthesis. Sodium nitroprusside (SNP), a NO donor, induced similar metabolic changes in a dose-dependent manner, but 8-bromo-cyclic guanosine 3',5'-monophosphate (8-bromo-cGMP), a cGMP donor, had no effect on these parameters. The activities of the mitochondrial iron-sulfur enzymes, NADH-CoQreductase and succinate-CoQreductase, but not oligomycin-sensitive ATPase, were significantly inhibited in the IL-1beta, or SNP-treated myocytes. Both IL-1beta and SNP significantly elevated maximum diastolic potential, reduced peak calcium current (I(Ca)), and lowered contractility in the myocytes. KT5823, an inhibitor of cGMP-dependent protein kinase, did not block the electrophysiological and contractility effects.

CONCLUSIONS

These data suggest that IL-1beta-induced NO production in cardiac myocytes lowers energy production and myocardial contractility through a direct attack on the mitochondria, rather than through cGMP-mediated pathways.

Tetracaine can inhibit contractions initiated by a voltage-sensitive release mechanism in guinea-pig ventricular myocytes

1. Effects of tetracaine on membrane currents and cell shortening were measured with high resistance electrodes, single-electrode voltage clamp (switch clamp) and a video edge detector at 37 C in cardiac ventricular myocytes. 2. Sequential voltage steps from -65 mV to -40 and 0 mV were used to activate two mechanisms of excitation-contraction (EC) coupling separately. The step to -40 mV activated the voltage-sensitive release mechanism (VSRM); the step to 0 mV1 activated Ca2+-induced Ca2+ release (CICR) coupled to inward Ca2+ current (IL). 3. Exposure to 100-300 microM tetracaine inhibited VSRM contractions but not CICR contractions. Inhibition of VSRM contractions was independent of INa blockade. In contrast, 100 microM Cd2+ blocked IL and CICR contractions, but not VSRM contractions. Simultaneous application of both agents blocked both mechanisms of EC coupling. 4. Contraction-voltage relationships were sigmoidal when the VSRM was available. However, when the VSRM was inhibited with 100-300 microM tetracaine, contraction-voltage relationships became bell-shaped. The tetracaine-insensitive contractions were abolished by 0.1 microM ryanodine, indicating that they were dependent on release of SR Ca2+. 5. At a higher concentration (1 mM) tetracaine also inhibited IL and contractions triggered by IL; however, the time course of effects on IL and associated contractions were different than for VSRM contractions. 6. With continuous application of tetracaine, the VSRM remained inhibited although SR Ca2+ stores increased 4-fold as assessed with caffeine. CICR contractions were not inhibited and maximum amplitude of contraction was not reduced. 7. Rapid application of tetracaine just before and during test steps also inhibited VSRM contractions, but without significantly affecting sarcoplasmic reticulum (SR) Ca2+ stores or CICR contractions. Maximum amplitude of contraction was reduced. 8. Rapid application of tetracaine (100-300 microM) allows preferential inhibition of the VSRM and provides a pharmacological method to assess the contribution of the VSRM to EC coupling.

Actions of cADP-ribose and its antagonists on contraction in guinea pig isolated ventricular myocytes. Influence of temperature

Although it is becoming widely accepted that cADP-ribose (cADPR) can regulate calcium release from the endoplasmic reticulum in sea urchin eggs and in a variety of mammalian cell types, it remains controversial whether this substance might influence calcium release during excitation-contraction coupling in cardiac muscle. We have investigated possible actions of cADPR in intact cells isolated from guinea pig ventricle, paying particular attention to the possible influence of temperature. At 36 degrees C, myocyte contraction was influenced by cytosolic application of cADPR in a concentration-dependent manner (showing an approximately 30% increase in contraction with 5 mumol/L cADPR applied via a patch pipette in myocytes stimulated to fire action potentials at 1 Hz). Calcium transients measured with fura 2 were also increased by 5 mumol/L cADPR. Antagonists of cADPR reduced contraction at 36 degrees C (by approximately 35% with either 50 mumol/L 8-Br-cADPR or 5 mumol/L 8-amino-cADPR applied via the patch pipette). At room temperature (approximately 20 degrees C to 24 degrees C), no significant effects on contraction were detected with either cADPR or its antagonists. At 36 degrees C, treatment of the cells with a mixture of 2 mumol/L ryanodine and 1 mumol/L thapsigargin to suppress function of the sarcoplasmic reticulum stores of calcium prevented the action of 5 mumol/L cADPR applied via a patch pipette. These observations are consistent with an action of cytosolic cADPR to enhance calcium-induced calcium release from the sarcoplasmic reticulum in guinea pig ventricular myocytes at 36 degrees C. The observed influence of temperature under the conditions of our experiments is one factor that might help to account for failure to detect actions of cADPR and its analogues in some previous studies.

Low concentrations of UD-CG 212 enhance myocyte contractility by an increase in calcium responsiveness in the presence of inorganic phosphate

Recent data show that UD-CG 212 in nanomolar concentrations increases myofibrillar Ca++ responsiveness of chemically skinned cardiac preparations in the presence of elevated inorganic phosphate. We studied the effects of UD-CG 212 on cell shortening of intact myocytes and in addition measured the intracellular calcium transients with the aid of INDO-1 fluorescence in the presence of 5 mM inorganic phosphate. The validity of our experimental system was first tested with the calcium channel opener Bay k 8644. Bay k 8644 at 10(-8) M did not significantly influence myocyte shortening (+ 13.9 +/- 4.6%, n = 9) but at 10(-7) M and 10(-6) M significantly increased contraction by 40.1 +/- 13.6% and 52.5 +/- 17.0% respectively. Bay k 8644 at 10(-8) M increased the INDO-1 fluorescence ratio by 17.3 +/- 4.7% (P < 0.01; n = 9), and at 10(-7) M by 21.5 +/- 4.3% (P < 0.01; n = 9), whereas 10(-6) M Bay k 8644 had no significant effect on peak INDO-1 ratio. However, 10(-7) and 10(-6) M Bay k 8644 accelerated and broadened the calcium transients.(ABSTRACT TRUNCATED AT 250 WORDS)

Contractions in guinea-pig ventricular myocytes triggered by a calcium-release mechanism separate from Na+ and L-currents

1. Unloaded cell shortening and membrane currents were examined in isolated guinea-pig ventricular myocytes at 37 degrees C using video edge detection and single-electrode voltage clamp. 2. Inward Na+ currents were eliminated by lidocaine, tetrodotoxin, replacement of extracellular Na+ with choline chloride or sucrose, or by voltage inactivation of Na+ channels. In the absence of Na+ current, the threshold for contraction was approximately -50 or -55 mV. 3. Verapamil (5 microM) and nifedipine (2 microM) failed to inhibit contractions at negative membrane potentials when positive conditioning pulses were used to maintain intracellular Ca2+ stores via Na(+)-Ca2+ exchange. In contrast, 200 microM Ni2+ inhibited these contractions. 4. Contractions were abolished when the extracellular solution was nominally Ca2+ free. However, contractions were restored by as little as 50 microM extracellular Ca2+. 5. Ryanodine (30 nM) completely abolished contractions initiated by depolarizing steps from -65 to -40 mV, but had minimal effects on contractions initiated by depolarizing steps from -40 to +5 mV. Subtraction of contraction-voltage relations determined in the presence of ryanodine from control relations revealed a ryanodine-sensitive component of contraction. This component activated at -55 mV and reached a plateau near -25 mV. 6. The amplitudes of contractions initiated by depolarizing steps from -40 mV were directly proportional to the magnitude of Ca2+ current (ICa). In contrast, contractions initiated by steps from either -55 or -65 mV were not proportional to ICa. These contractions appeared at potentials negative to the threshold for L-type Ca2+ current, increased to a plateau at more positive potentials and did not decrease at potentials at which ICa decreased. 7. Subtraction of the contraction-voltage relationship determined from a membrane potential of -40 mV from that at -55 mV revealed a component of contraction with a negative activation threshold whose amplitude was not proportional to inward current. The shape of this relationship was virtually identical to that of the ryanodine-sensitive component of contraction. 8. This study identifies a component of contraction associated with Ca2+ release from sarcoplasmic reticulum (SR) which can be separated from other mechanisms of contraction on the basis of membrane potential. Our observations suggest that this voltage-dependent release mechanism is a true trigger mechanism which activates a portion of cardiac contraction which is attributable to SR Ca2+ release.

Effects of the Anemonia sulcata toxin (ATX II) on intracellular sodium and contractility in rat and guinea-pig myocardium

The effects of the Anemonia sulcata toxin ATX II on action potentials and contractility of isolated papillary muscles and single myocytes from rat and guinea-pig hearts have been studied. ATX II prolonged the action potential in both rat and guinea-pig papillary muscle. Although it produced a positive inotropic effect in guinea-pig papillary muscle, it failed to do so in rat papillary muscle. However, in single rat and guinea-pig ventricular cells, it both prolonged the action potential and had a positive inotropic effect. We suggest that ATX II does not cause a positive inotropic effect in rat papillary muscle, because it induces Ca2+ overload. In single cells the positive inotropic effect was reduced by approximately 50% when the contractions were triggered by voltage clamp pulses of constant duration rather than by action potentials. This suggests that the inotropic effect of ATX II is in part the result of the prolongation of the action potential. The intracellular Na+ activity (a(i)Na) in single ventricular cells was measured with the Na(+)-sensitive fluorescent dye SBFI. After exposure of the cells to ATX II, a(i)Na was increased by a maximum of 1.9 +/- 0.3 and 2.2 +/- 0.3 mM in rat and guinea-pig cells, respectively. It is suggested that the positive inotropic effect of ATX II is also in part the result of the rise in a(i)Na.

Intracellular calcium and mechanical function in isolated perfused hearts from rats and guinea pigs

We tested the hypothesis that the variable functional properties of rat versus guinea pig hearts are due to differences in intracellular Ca2+ handling. Hearts isolated from rats and guinea pigs were perfused with physiological saline, and isovolumic left ventricular (LV) pressure as well as coronary perfusion pressure were recorded simultaneously with Ca2+ transients from aequorin-loaded cells. Guinea pig hearts developed 47% less LV pressure than rat hearts, and the time to peak pressure was prolonged by 71% at similar heart rates. Diastolic and systolic levels of myoplasmic Ca2+ were approximately the same in both species at normal external Ca2+ concentration (1 mM); however, at low Ca2+ concentration (0.5 mM), guinea pig hearts maintained a higher level of myoplasmic Ca2+ than rat hearts, and the relative depression of LV systolic pressure was less. Guinea pig hearts also exhibited higher resistance to the negative inotropic effect of caffeine and did not respond to increments in perfusion pressure with increases in LV-developed pressure and systolic Ca2+ levels as did rat hearts. These contrasting findings with regard to intracellular Ca2+ handling may be attributed to a different organization of the ionic transport system with higher dependence of rat cardiomyocytes on normal function of the sarcoplasmic reticulum.

Tension-voltage relations of single myocytes reflect Ca release triggered by Na/Ca exchange at 35 degrees C but not 23 degrees C

Contractile tension in response to 200-ms voltage-clamp pulses was measured in isolated guinea pig ventricular cells conditioned to constant Ca load. At 23 degrees C, the tension-voltage relation was bell shaped, decaying from a maximum at +20 mV to zero at +100 mV, but at 35 degrees C it was sigmoidal, with similar twitch tensions at +20 and +100 mV. Tension at 35 degrees C and +100 mV was reduced by ryanodine or caffeine and abolished by removal of Ca just before the test pulse. At 35 degrees C and +100 mV, twitch tension increased markedly as the Na concentration in the patch pipette ([Na]p) was varied between 0 and 20 mM. Cd (300 microM) blocked tension at all potentials at 23 degrees C, but tension remained in the presence of Cd at 35 degrees C (29% of control at +2 mV and 100% of control at +100 mV). Cd-resistant tension began to relax during the clamp pulse at all potentials (80 +/- 10 ms at +2 mV and 140 +/- 12 ms at +100 mV). Ni (3.6 mM) both reduced and slowed tension transients at all potentials. The results suggest that fast contractions due to sarcoplasmic reticulum Ca release can be triggered by Ca influx through either Ca current (ICa) or Na/Ca exchange and that those triggered through exchange are much more temperature sensitive than those triggered by ICa.

Relaxation in rabbit and rat cardiac cells: species-dependent differences in cellular mechanisms

The roles of the sarcoplasmic reticulum (SR) Ca(2+)-ATPase and Na(+)-Ca2+ exchange in Ca2+ removal from cytosol were compared in isolated rabbit and rat ventricular myocytes during caffeine contractures and electrically stimulated twitches. Cell shortening and intracellular calcium concentration ([Ca2+]i) were measured in indo-1-loaded cells. Na(+)-Ca2+ exchange was inhibited by replacement of external Na+ by Li+. To avoid net changes in cell or SR Ca2+ load during a twitch in 0 Na+ solution, intracellular Na+ (Na+i) was depleted using a long pre-perfusion with 0 Na+, 0 Ca2+ solution. SR Ca2+ accumulation was inhibited by caffeine or thapsigargin (TG). Relaxation of steady-state twitches was 2-fold faster in rat than in rabbit (before and after Na+i depletion). In contrast, caffeine contractures (where SR Ca2+ accumulation is inhibited), relaxed faster in rabbit cells. Removal of external Na+ increased the half-time for relaxation of caffeine contractures 15- and 5-fold in rabbit and rat myocytes respectively (and increased contracture amplitude in rabbit cells only). The time course of relaxation in 0 Na+, 0 Ca2+ solution was similar in the two species. Inhibition of the Na(+)-Ca2+ exchange during a twitch increased the [Ca2+]i transient amplitude (delta[Ca2+]i) by 50% and the time constant of [Ca2+]i decline (tau) by 45% in rabbit myocytes. A smaller increase in tau (20%) and no change in delta[Ca2+]i were observed in rat cells in 0 Na+ solution. [Ca2+]i transients remained more rapid in rat cells. Inhibition of the SR Ca(2+)-ATPase during a twitch enhanced delta[Ca2+]i by 25% in both species. The increase in tau after TG exposure was greater in rat (9-fold) than in rabbit myocytes (2-fold), which caused [Ca2+]i decline to be 70% slower in rat compared with rabbit cells. The time course of [Ca2+]i decline during twitch in TG-treated cells was similar to that during caffeine application in control cells. Combined inhibition of these Ca2+ transport systems markedly slowed the time course of [Ca2+]i decline, so that tau was virtually the same in both species and comparable to that during caffeine application in 0 Na+, 0 Ca2+ solution. Thus, the combined participation of slow Ca2+ transport mechanisms (mitochondrial Ca2+ uptake and sarcolemmal Ca(2+)-ATPase) is similar in these species. We conclude that during the decline of the [Ca2+]i transient, the Na(+)-Ca2+ exchange is about 2- to 3-fold faster in rabbit than in rat, whereas the SR Ca(2+)-ATPase is 2- to 3-fold faster in the rat.(ABSTRACT TRUNCATED AT 400 WORDS)

Buffering of calcium influx by sarcoplasmic reticulum during the action potential in guinea-pig ventricular myocytes

1. Intracellular [Ca2+] ([Ca2+]i) transients, monitored by the fluorescent Ca2+ indicator, indo-1, and twitch contractions elicited by action potentials, by voltage clamp pulses or by rapid, brief pulses of caffeine, were measured in guinea-pig single ventricular myocytes. Experiments were designed to determine whether and to what extent the trans-sarcolemmal Ca2+ influx is immediately sequestered by the sarcoplasmic reticulum (SR). 2. Rapid, brief (100-200 ms) pulses of caffeine onto a rested myocyte elicited a [Ca2+]i transient and a contraction. Following exposure to specific SR inhibitors, ryanodine (100 nM) or thapsigargin (200 nM), the rapid application of caffeine onto a rested myocyte failed to elicit changes in [Ca2+]i or in cell length, indicating that caffeine increases [Ca2+]i by specifically discharging Ca2+ from the SR. In the absence of these inhibitors, a second pulse of caffeine, within 3 min following a prior pulse, failed to elicit a [Ca2+]i transient or contraction, indicating that a caffeine pulse depletes the SR releasable Ca2+ pool. 3. Following Ca2+ depletion of the SR by double caffeine pulses at rest, an electrical stimulation elicited a slow increase in [Ca2+]i, and, after a delay, a small, slow twitch contraction. The simultaneous application of caffeine and electrical stimulation of cells in which the SR was Ca2+ depleted elicited [Ca2+]i transients with an increased rate of rise and a larger amplitude (53 +/- 8 and 63 +/- 9% respectively; mean +/- S.E.M., n = 21) than those elicited by electrical stimulation alone. 4. Whether caffeine affected the L-type calcium current (ICa) elicited by electrical stimulation was determined under whole-cell voltage clamp. A caffeine pulse delivered at the onset of a depolarizing voltage clamp step also increased the rates of rise and the amplitudes of the [Ca2+]i transients and twitch contractions in cells in which the SR was depleted of Ca2+. However, Ca2+ influx via ICa decreased when caffeine was pulsed in conjunction with the voltage clamp, as the peak ICa was either unchanged or decreased while its inactivation was consistently accelerated. 5. Because the stimulation-dependent trans-sarcolemmal Ca2+ influx via ICa is not increased by a caffeine pulse, the augmentation of the rates of rise and the amplitudes of the electrically stimulated [Ca2+]i transients by caffeine pulsed in conjunction with the electrical stimulation in cells in which the SR had been depleted of Ca2+ indicates that a portion of Ca2+ influx during depolarization in the absence of caffeine is rapidly buffered by the SR.(ABSTRACT TRUNCATED AT 400 WORDS)

Changes in cell length consequent on depolarization in single left ventricular myocytes from guinea-pigs with pressure-overload left ventricular hypertrophy

Cell length was measured in single guinea-pig left ventricular myocytes by using a high-resolution photodiode array. Step depolarizations from a holding potential of -45 mV were applied using a switch-clamp technique with 2 M KCl microelectrodes, which were devoid of Ca2+ buffering. Comparison was made between myocytes from sham-operated guinea-pigs and guinea-pigs with mild pressure-overload left ventricular hypertrophy induced by infra-renal aortic constriction. The relation between cell shortening and membrane voltage was bell shaped, and a phasic component of shortening was evident at the range of potentials over which the L-type calcium current was activated. Mean cell shortening was increased in the hypertrophy group, and was maximal at +15 mV in both groups (control, 7.6 +/- 0.9 microns, n = 11, hypertrophy 11.0 +/- 1.2 microns, n = 20, p < 0.05). The latency to the onset of contraction was significantly shorter in the hypertrophy myocytes at -25 mV and at potentials positive to +50 mV. The relation between time-to-peak shortening and voltage showed a trend to shorter times in the hypertrophy group. At very positive potentials a slow component of contraction was identified which was relatively larger in the hypertrophy myocytes. This finding is consistent with increased calcium entry via sarcolemmal sodium-calcium exchange in the myocytes from the hypertrophy group.

Effects of propofol and enflurane on action potentials, membrane currents and contraction of guinea-pig isolated ventricular myocytes

1. The effects of two general anaesthetics, propofol and enflurane, on electrical activity and contractions were investigated in single myocytes isolated from guinea-pig ventricles. 2. Propofol and enflurane depressed the plateau and shortened the duration of action potentials. 3. Under voltage-clamp conditions, propofol and enflurane reduced the amplitude of inward calcium current and of additional inward current activated by cytosolic calcium. 4. Contractions (measured with an optical technique) accompanying either action potentials or second inward currents (in response to depolarizations to 0 mV) were reduced by both anaesthetics. The mechanisms for calcium entry during contractions accompanying pulses to positive potentials such as +60 mV are thought to differ from those accompanying second inward currents which are evoked by pulses from -40 to 0 mV. Enflurane enhanced the amplitudes of contractions accompanying pulses to positive potentials; in contrast these contractions were depressed by propofol. 5. In experiments where recovery processes were investigated by use of pairs of voltage-clamp pulses with a variable interval between them, enflurane but not propofol slowed the recovery of contractions and calcium-activated 'tail' currents. These observations are consistent with the hypothesis that enflurane may impair calcium handling by the sarcoplasmic reticulum whereas propofol has little, if any, effect at this site. 6. In conclusion, the actions of propofol and enflurane on second inward currents contribute to their effects on action potentials and contraction. The negative inotropic effect of both anaesthetics may result partly from reduced calcium influx to trigger contraction, and for enflurane, partly from an impairment of calcium handling by the sarcoplasmic reticulum.

Class III antiarrhythmic action and inotropy: effects of almokalant in acute ischaemic heart failure in dogs

We studied the haemodynamic and metabolic effects of the novel class III antiarrhythmic agent almokalant (H 234/09) in acute ischaemic heart failure at a dose prolonging ventricular repolarization. In pentobarbital anaesthetized dogs, heart failure was induced by microembolization of the area supplied by the main left coronary artery until a stable left ventricular end-diastolic pressure (LVEDP) of 32 +/- 2 mmHg was achieved. Embolization depressed LV dP/dt(max), LV dP/dt(min), left ventricular systolic pressure (LVSP) and cardiac output. After intravenous infusion of almokalant (0.35 micrograms/kg) LV dP/dt(max) and LV dP/dt(min) were not significantly changed at paced cycle length of 300 msec., whereas LVSP and aortic pressure decreased both at spontaneous and paced cycle length of 300 msec. LVEDP remained unchanged. Heart rate decreased from 185 +/- 7 to 167 +/- 5 beats/min., and corrected QT-time (QTc) increased from 9.5 +/- 0.3 to 10.4 +/- 0.5 msec. Arterial concentration and net myocardial uptake of glucose, lactate and free fatty acids were not significantly influenced by almokalant. In conclusion, almokalant at a dose prolonging ventricular repolarization had no negative inotropic effect in acute ischaemic heart failure.

Effects of neuropeptide Y on cell length and membrane currents in isolated guinea pig ventricular myocytes

Direct effects of neuropeptide Y were studied in left ventricular myocytes isolated from guinea pigs. Contraction was measured as the change in unloaded cell length using a photodiode array. Action potentials were elicited at 1 Hz in current-clamp mode, and membrane currents were measured using a switch-clamp amplifier with 2 M-KCl microelectrodes. At concentrations of 10(-6) M and above, neuropeptide Y reduced contraction in a concentration-dependent fashion. The reduction in contraction by the peptide was proportionately greater in the presence of isoproterenol, and the increase in contraction caused by isoproterenol was completely inhibited by 10(-6) M neuropeptide Y. In response to neuropeptide Y, action potential duration was shortened, and the time course of the shortening was similar to that of the reduction in contraction. Under voltage clamp, 1 x 10(-5) M neuropeptide Y reduced peak L-type calcium current by 32% and shifted the myocyte current-voltage relation during a slow ramp in a manner that suggested a reduction in the background rectifier K+ current. The effects of the peptide on membrane currents were greatly attenuated by preincubation of the cells with pertussis toxin (100 ng/ml). We conclude that neuropeptide Y reduces developed shortening, action potential duration, L-type calcium current, and background rectifier current in single guinea pig ventricular myocytes and that these effects are mediated, at least in part, via membrane G proteins.

The cytosolic calcium transient modulates the action potential of rat ventricular myocytes

1. The modulation of the action potential by the cytosolic Ca2+ (Cai2+) transient was studied in single isolated rat ventricular myocytes loaded with the acetoxymethyl ester form of the Ca(2+)-sensitive fluorescent dye Indo-1. Stimulation following rest and exposure to ryanodine were used to change the amount of Ca2+ released from the sarcoplasmic reticulum and thus the size of the Cai2+ transient. The Cai2+ transient was measured as the change, upon stimulation, in the ratio of Indo-1 fluorescence at 410 nm to that at 490 nm (410/490) and action potentials or membrane currents were recorded using patch-type microelectrodes. 2. When stimulation was initiated following rest, the magnitude of the Cai2+ transient decreased in a beat-dependent manner until a steady state was reached. The negative staircase in the Cai2+ transient was accompanied by a similar beat-dependent decrease in the duration of the action potential, manifested primarily as a gradual loss of the action potential plateau (approximately -45 mV). A slow terminal phase of repolarization of a few millivolts in amplitude was found to parallel the terminal decay of the Cai2+ transient. 3. The terminal portion of phase-plane loops of membrane potential (Vm) vs. Indo-1 ratio from all of the beats of a stimulus train followed a common linear trajectory even though the individual beats differed markedly in the duration and amplitude of the action potential and Cai2+ transient. 4. When the stimulation dependence of the Cai2+ transient was titrated away with submaximal exposure to ryanodine, the stimulation-dependent changes in the action potential plateau and terminal phase of repolarization were also eliminated. The same effect was noted in cells which, fortuitously, did not show a staircase in the Cai2+ transient following a period of rest. 5. When action potentials were triggered immediately following spontaneous release of Ca2+ from the sarcoplasmic reticulum, which results in a small depolarization at the resting potential, phase-plane loops (Vm vs. Indo-1 ratio) of the spontaneous events followed the same linear trajectory as the terminal phase of repolarization in the loops of the stimulated beats. 6. Following repolarization from brief voltage clamp pulses (to minimize time and voltage-dependent currents associated with depolarization), an inward current was observed that rose and fell in phase with the Cai2+ transient. This current was present at -70 mV, near the resting potential, and at -40 mV, a potential relevant to the plateau of the action potential.(ABSTRACT TRUNCATED AT 400 WORDS)

Interval dependence of force and twitch duration in rat heart explained by Ca2+ pump inactivation in sarcoplasmic reticulum

1. The influence of the interstimulus interval on twitch duration was analysed in isolated heart muscle of the rat. When the muscle was in the steady state at interstimulus intervals at 5 s a test interval was interposed and varied. Duration of twitch and action potential, sarcomere length and peak force of the test beats were measured. 2. Twitch force and duration increased when the test interval was increased from 0.4 to 10 s. This effect was abolished by inhibitors of sarcoplasmic reticulum function (ryanodine, caffeine, Sr2+). Hence, the interval dependence is controlled by the sarcoplasmic reticulum. 3. Post-extrasystolic potentiation, variation of [Ca2+]o and [Na+]o and blocking of iCa with nifedipine and Mn2+ led to large variations in force, reflecting variations in the amount of Ca2+ released from the sarcoplasmic reticulum. The effect on twitch duration was small, indicating that twitch duration was rather insensitive to the amount of released Ca2+, and not controlled by iCa and Na(+)-Ca2+ exchange. 4. Action potential duration was much shorter than twitch duration and, depending on the intervention, changes were in the same or in opposite direction. Hence, the action potential did not determine twitch duration. 5. Small variations in sarcomere length amongst test contractions were observed, but these variations could not account for the effects of the test interval. 6. It is proposed that the Ca2+ pump in the sarcoplasmic reticulum is activated during each contraction and inactivates slowly. Thus, after a short interval the pump is still activated and rapidly sequesters much of the released Ca2+ leading to a small twitch and rapid relaxation. This mechanism ensures proper relaxation and diastolic filling of the ventricle. The biochemical basis and implications of the hypothesis are discussed.

Sustained subthreshold-for-twitch depolarization in rat single ventricular myocytes causes sustained calcium channel activation and sarcoplasmic reticulum calcium release

Single rat ventricular myocytes, voltage-clamped at -50 to -40 mV, were depolarized in small steps in order to define the mechanisms that govern the increase in cytosolic [Ca2+] (Cai) and contraction, measured as a reduction in myocyte length. Small (3-5 mV), sustained (seconds) depolarizations that caused a small inward or no detectable change in current were followed after a delay by small (less than 2% of the resting length), steady reductions in cell length measured via a photodiode array, and small, steady increases in Cai measured by changes in Indo-1 fluorescence. Larger (greater than -30 and less than -20 mV), sustained depolarizations produced phasic Ca2+ currents, Cai transients, and twitch contractions, followed by a steady current and a steady increase in Cai and contraction. Nitrendipine (or Cd, verapamil, or Ni) abolished the steady contraction and always produced an outward shift in steady current. The steady, nitrendipine-sensitive current and sustained increase in Cai and contraction exhibited a similar voltage dependence over the voltage range between -40 and -20 mV. 2 microM ryanodine in the presence of intact Ca2+ channel activity also abolished the steady increase in Cai and contraction over this voltage range. We conclude that when a sustained depolarization does not exceed about -20 mV, the resultant steady, graded contraction is due to SR Ca2+ release graded by a steady ("window") Ca2+ current. The existence of appreciable, sustained, graded Ca2+ release in response to Ca2+ current generated by arbitrarily small depolarizations is not compatible with any model of Ca2(+)-induced Ca2+ release in which the releasing effect of the Ca2+ channel current is mediated solely by Ca2+ entry into a common cytosolic pool. Our results therefore imply a distinction between the triggering and released Ca2+ pools.

Sarcolemma, sarcoplasmic reticulum, and sarcomeres as limiting factors in force production in rat heart

Inotropic interventions were compared with respect to their maximum effect on force of contraction in rat myocardium to identify limiting steps in calcium handling. Peak force, sarcomere length, and action potentials were measured in thin ventricular trabeculae. Relevant control conditions were stimulation frequency, 0.2 Hz; [Ca2+]o, 1 mM; [K+]o, 5 mM; [Na+]o, 150 mM. The inotropic interventions and results were as follows. 1) The interventions of high [Ca2+]o, low [Na+]o, high [K+]o, addition of tetraethylammonium chloride, or postextrasystolic potentiation resulted in approximately the same (within 5%) maximum force (Fmax). Above the respective optimum doses, force declined and aftercontractions were often observed. Combinations of the different interventions never enhanced force to above Fmax. This suggests that Fmax is determined by a maximum level of Ca2+ in the sarcoplasmic reticulum, above which spontaneous release occurs. 2) Sr2+ (10 mM) caused an increase of force to 1.3 X Fmax and lengthening of contraction and action potentials. The force-sarcomere length relation was, then, similar to that in skinned fibers at maximum activation. Hence, 1.3 X Fmax reflects saturation of the sarcomeres. We postulate that a large influx of Sr2+ during the long action potential can circumvent the reticulum and activate the sarcomeres directly. When the reticulum was blocked with ryanodine, maximum force of tetanic contractions was about 1.1 X Fmax. This result supports the above conclusions. 3) Isoproterenol increased force to a maximum that was 20% below Fmax and shortened the contraction. This may be due to a decreased sensitivity of the sarcomeres to Ca2+ or to stimulation of the Ca2+ pump in the reticulum, that is, an increasing fraction of the released Ca2+ is sequestered before it can activate the sarcomeres. Thus, three factors that limit force production were identified, depending on the inotropic stimulus.

Comparison of intracellular pH transients in single ventricular myocytes and isolated ventricular muscle of guinea-pig

1. Intracellular pH was recorded (double-barrelled pH-selective microelectrodes) in single ventricular myocytes and whole papillary muscles isolated from guinea-pig heart. Both preparations were acid-loaded by various manoeuvres (addition and removal of external NH4Cl or CO2) in order that a comparison could be made of the size and speed of intracellular pH changes and hence of the apparent intracellular buffering power (beta). 2. For the same acid-loading procedure, the size of intracellular pH (pHi) changes was about threefold larger in the isolated myocyte than in whole papillary muscle. The rate of initial acid loading as well as the subsequent rate of pHi recovery (caused by acid extrusion from the cell) were also threefold faster in the myocyte. Estimates of apparent intrinsic (non-CO2) buffering power, based upon the size of pHi changes during acid loading, were 15-20 mmol l-1 for the myocyte and about 70 mmol l-1 for whole muscle. This latter value is similar to previous estimates of beta in heart. 3. When acid extrusion was reduced by applying a high dose of amiloride (1 mmol l-1), then the size of the pHi change during acid loading increased greatly in papillary muscle but changed much less in the myocyte; beta now appeared to be about 30 mmol l-1 in whole muscle but remained essentially unchanged in the myocyte. 4. We conclude that previous values for beta in cardiac muscle have been greatly overestimated because of the presence of sarcolemmal acid extrusion. Paradoxically, this error in estimating beta is far less evident in the isolated myocyte. We suggest that this is because a much more rapid acid loading is achievable in the myocyte so that acid loading will be blunted less by acid extrusion than in whole muscle. We present a simple mathematical model that demonstrates this phenomenon. We conclude that beta in ventricular muscle is likely to resemble that measured in the isolated myocyte, i.e. 15-20 mmol l-1. 5. Slow acid loading in whole ventricular muscle will also affect the kinetics of pHi changes. The model indicates that the rate of pHi recovery from an acid load in papillary muscle does not reflect the pHi dependence of acid extrusion. Instead, it is heavily influenced by the slow rate of acid loading. This emphasises that great care should be taken when interpreting the kinetics of pHi changes in multicellular ventricular preparations.

Taurine modulates ion influx through cardiac Ca2+ channels

The effects of taurine on the inward Ca2+ current (ICa) were investigated by means of the whole-cell voltage-clamp technique in isolated single guinea pig ventricular myocytes. ICa were elicited by 200-ms test pulses from a conditioning holding potential of -45 mV to various test potentials at a rate of 0.5 Hz. Taurine (10-20 mM) had different effects on ICa, depending on the extracellular Ca2+ concentration [( Ca]o). A small stimulatory effect of taurine was found in low [Ca]o (0.8 mM), and a small inhibitory effect was found in high [Ca]o (3.6 mM). Taurine had no significant effect on ICa in normal [Ca]o (1.8 mM). Such dual effects on ICa may explain the various effects reported for taurine especially its dual inotropic actions on cardiac muscle depending upon [Ca]o. Thus, taurine acts in a manner to keep ICa relatively constant. Taurine increased the resting potential irrespective of [Ca]o, suggesting that, in addition, taurine increased K+ conductance and/or ion exchange systems such as the Na/Ca and Na/K exchange.

Changes in cytosolic calcium monitored by inward currents during action potentials in guinea-pig ventricular cells

Action potentials were recorded from single cells isolated from guinea-pig ventricular muscle. Contraction was measured with an optical technique. Tail currents thought to be activated by cytosolic calcium were recorded when action potentials were interrupted by application of a voltage-clamp. A family of tail currents was recorded by interrupting the action potential at various times after the upstroke. The envelope of tail current amplitudes was taken as an index of changes in cytosolic calcium. Consistent with this interpretation, tail currents were negligible following intracellular loading with the calcium chelator BAPTA to suppress calcium transients. The cytosolic calcium transient estimated from the envelope of tails reached a peak approximately 50 ms after the upstroke of the action potential, and fell close to diastolic levels before repolarization was complete; 10 mM caffeine delayed the time to peak contraction, and caused a prolongation of the cytosolic calcium transient estimated from the envelope of tail currents. Caffeine also induced the appearance of a distinct late plateau phase of the action potential. Intracellular BAPTA suppressed the late plateau, contraction and tail currents in cells exposed to caffeine. Exposure to caffeine increased the time constant for decay of tail currents (from approximately 25 to 70 ms). When action potentials were greatly abbreviated by interruption with a voltage-clamp, a progressive decline occurred in the subsequent three contractions and tail currents. There was a progressive reversal of these effects over four responses when the full action potential duration was restored. None of these effects was observed in cells exposed to caffeine. Calcium-activated tail currents appear to be a useful qualitative index of changes in cytosolic calcium. The observations are consistent with the suggestion that cytosolic calcium is reduced during the plateau by a combination of calcium extrusion through Na-Ca exchange and calcium uptake into caffeine-sensitive stores. It also appears that reduction of stores loading during abbreviated action potentials reduces subsequent contraction in cells not exposed to caffeine.

Fate of gap junctions in isolated adult mammalian cardiomyocytes

The fate of gap junctions in dissociated adult myocytes, maintained for up to 22 hours in culture medium, was investigated by semiquantitative analysis of thin sections and by freeze-fracture electron microscopy. Gap junctions in the dissociated myocyte are intact bimembranous structures seen either as invaginated surface-located structures or as annular profiles in the cytoplasm. Surface-located junctions are sealed from the exterior by a sheet of nonjunctional membrane originating (together with the "outer" junctional membrane) from the formerly neighboring cell. Serial sectioning was used to establish that at least part of the annular gap junction population in the freshly isolated myocyte represents truly discrete cytoplasmic vesicles; thus, some gap junctions are rapidly endocytosed after myocyte separation. Analysis of the surface-located-to-annular gap junction ratio suggested that no further endocytosis occurred in rabbit and cat myocytes maintained for 22 and 15 hours, respectively. Guinea pig myocytes, by contrast, did appear to continue endocytosis in culture. Analysis of the distance of gap junctional structures from the cell surface suggested that little if any inward migration of gap junction vesicles occurred. Hypoxia had no detectable effect on the internalization or inward movement of gap junctions. The quantity of ultrastructurally detectable gap junction membrane appeared to remain constant over time, as did the incidence of "complex structures" (i.e., annular gap junction profiles with features previously suggested to represent degradation). New gap junction formation was negligible, and a reappraisal of the nature of "complex structures" led to the conclusion that the origin of these structures need not be related to degradation. Taken together, the findings suggest that degradation and disappearance of gap junctional membrane after isolation of the mature myocyte constitute a much slower process than previously believed, and the possibility that the cardiac gap junction protein has a longer half-life than its counterpart in liver remains open.

Sodium current kinetics in intact rat papillary muscle: measurements with the loose-patch-clamp technique

1. Rapid inward sodium current (INa) was studied on intact rat papillary muscles and trabeculae excised from right or left ventricle using the loose-patch-clamp technique. All experiments were carried out at 25 degrees C. 2. Currents were recorded from patches with a large current density of mean 5.9 +/- 0.5 mA/cm2. 3. The current was reduced by tetrodotoxin (TTX) in a dose-dependent manner. The concentration of TTX producing half-maximal blockade of INa was 6.3 +/- 0.8 mumol/l. 4. Na+ current appeared upon depolarization at a threshold potential of about -55 mV and reached its maximum at about -20 mV. 5. Kinetic data were evaluated using the Hodgkin-Huxley model. 6. Time constants of activation (tau m) were estimated using single-pulse and tail-current measurements. They had a maximum of about 0.4 ms near the threshold potential and declined at more positive and at more negative potentials to values near 0.1 ms. 7. Two time constants were necessary to describe inactivation. Both time constants had their maximal values of 135 +/- 8.1 and 29.1 +/- 5.9 ms at about -80 mV and decreased towards 4 and 0.5 ms at potentials positive to -20 mV.

Use-dependent reduction and facilitation of Ca2+ current in guinea-pig myocytes

1. Action potentials, calcium currents (iCa) and cell contraction have been recorded from single guinea-pig myocytes during periods of stimulation from rest. Voltage clamp was carried out using a single microelectrode. Cell contraction was measured optically. All experiments were performed at 18-22 degrees C. 2. An inverse relationship was observed between cell contraction and action potential duration or iCa. Mixed trains of action potentials and voltage clamp pulses preserved this relationship. Long voltage clamp pulses induced negative 'staircases' of iCa and positive 'staircases' of cell contraction. A facilitation of iCa was observed during repetitive stimulation with clamp pulses of 100 ms duration or less and was accompanied by a decrease in cell contraction. 3. The voltage dependence of inward current staircases was found to depend on Ca2+ entry rather than membrane voltage for long voltage clamp pulses and was not affected by 30 mM-TEA or 50 microM-TTX. Current reduction was greatest at 0 mV (P less than 0.05) when iCa was largest. Changes in cell contraction during pulse trains showed a similar voltage dependence. The time constant of current staircases was only mildly voltage dependent. 4. Interference with normal cellular mechanisms for Ca2+ uptake and release by strontium, 1-5 mM-caffeine and 1 microM-ryanodine increased current staircases and could abolish iCa facilitation with short clamp pulses. 5. Variations in the level of Ca2+-dependent inactivation of iCa can explain many features of the changes in iCa during stimulation after rest. Long clamp pulses (or action potentials) may increase cell Ca2+ loading and inhibit iCa. Short clamp pulses reduce available Ca2+ for cell contraction and this may reflect a lowered myoplasmic Ca2+ level which allows facilitation of iCa.

Ryanodine as a trigger of tension oscillations in rat ventricular muscle

In rat ventricular muscles, ryanodine (10-30 nM) evoked tension oscillation in the relaxation phase of an isometric twitch (relaxation oscillations) and an increase of tonic tension (ryanodine contracture). Both events were more pronounced in Ca2+-loaded rat muscles due to the addition of 0.5 microM adrenaline, an increase in the Ca2+ concentration in the solution and high muscle activity. The ryanodine-induced tension oscillations were comparable to those triggered by caffeine in this species. In both cases, blockers of the release of Ca2+ from the sarcoplasmic reticulum, namely tetracaine and dantrolene, abolished the relaxation oscillations and the ryanodine contracture. The results suggest that the ability of low concentrations of ryanodine to facilitate the release of Ca2+ from the sarcoplasmic reticulum, as shown recently in biochemical experiments, makes a direct contribution to triggering the relaxation oscillations and the ryanodine contracture in intact ventricular muscles. The Ca2+ load of the sarcoplasmic reticulum appears to be essential for the manifestation of the ryanodine Ca2+-releasing activity in rat ventricular muscles.

On the mechanism of isoprenaline- and forskolin-induced depolarization of single guinea-pig ventricular myocytes

1. Isoprenaline (10 nM to 1 microM) and forskolin (0.6-100 microM) depolarized single guinea-pig myocytes studied in vitro. Under voltage clamp both agents caused an inward current to flow. 2. These effects were abolished by propranolol (100 nM) and the beta1-antagonist metoprolol (100-200 nM), but not by the beta2-agonist [corrected] salbutamol (1 microM). 3. The interaction of isoprenaline with forskolin, caffeine or isobutylmethylxanthine (IBMX) on current amplitude was as expected if all of these drugs were causing inward current by increasing intracellular levels of cyclic adenosine monophosphate (cyclic AMP). Low concentrations of forskolin (less than 600 nM) or IBMX (less than 20 microM) potentiated the effect of isoprenaline, whereas isoprenaline caused no further inward current in cells in which high concentrations of forskolin (600 nM-100 microM) or IBMX (20 microM-1 mM) were already evoking maximum inward current. 4. Isoprenaline-induced inward current was reduced 30-50% by acetylcholine (10-30 microM). This action of acetylcholine was blocked by atropine (100 nM). 5. The effect of isoprenaline on holding current was critically dependent on temperature. The onset of the current was delayed and its amplitude reduced as the myocyte was cooled from 37 degrees C to ambient temperature (22-24 degrees C). 6. Isoprenaline-induced inward current was not affected by the potassium channel blockers barium (2 mM) or tetraethylammonium (TEA; 10-20 mM). The amplitude of the inward current did not vary as a function of [K+]o. 7. The inward current was not affected by the calcium channel blockers cadmium 1 mM, or nifedipine (10 microM), or when internal calcium was reduced by including EGTA in the recording electrode filling solution. 8. The amplitude of the current was also unaffected by caesium (5 mM), which blocks the hyperpolarization-activated, non-specific channel if, or by strophanthidin (10 microM) which blocks the Na+-K+ pump. It was unchanged by substitution of external chloride by isethionate. 9. The inward current was absent when external sodium was replaced by the impermeant ion tetramethylammonium (TMA). 10. Isoprenaline- and forskolin-induced inward currents were associated with an increase in both membrane chord conductance and noise. The increase in conductance was most readily measured at potentials where the inwardly rectifying potassium channel, iK1, was small, or when iK1 was blocked by the addition of barium (2 mM).(ABSTRACT TRUNCATED AT 400 WORDS)

Calcium-activated inward current and contraction in rat and guinea-pig ventricular myocytes

1. Single ventricular cells from rat and guinea-pig hearts were voltage clamped, and contraction was monitored with an optical method. 2. In rat cells, short (2-10 ms) depolarizing pulses to 0 mV from a holding potential of -40 mV evoked current carried by calcium, and on repolarization to -40 mV there was a slow 'tail' current which decayed much more slowly than the expected deactivation of calcium current at this potential. 3. When rat cells were loaded with EGTA diffusing into the cytosol from an intracellular electrode, contraction and the tail current were both abolished, whereas the peak calcium current was not reduced. 4. Exposure of rat cells to ryanodine (1-2 microM) suppressed both contraction and the tail current, but not peak calcium current. 5. The tail current was unaffected by tetrodotoxin (10 microM), but was reduced by lowering extracellular sodium to 10% by replacement with lithium or choline. 6. In rat cells, exposure to nifedipine (1-5 microM) initially caused a marked reduction of calcium current while substantial contraction and tail current remained; longer exposure to nifedipine suppressed both contraction and the tail current. Isoprenaline (50-100 nM) caused a marked increase in peak calcium current, while under these conditions there was little or no increase in either contraction or tail current. 7. The amplitude of the tail current in rat cells varied with the duration of the depolarization at 0 mV; the tail current evoked by repolarization to -40 mV reached a peak just as contraction was beginning to develop and was back to undetectable levels just as relaxation became significant, as might be expected if the tail current were determined by the cytosolic calcium transient which triggered contraction. 8. In guinea-pig cells, a tail current was also recorded on repolarization to a holding potential of -40 mV, and, as in rat cells, the tail was suppressed by cytosolic EGTA and reduced by exposure of the cells to low-sodium solution. 9. It is concluded that the tail currents recorded in both rat and guinea-pig cells represent current activated by a rise in cytosolic calcium; in rat cells this is markedly dependent on ryanodine-sensitive release of calcium from internal stores. The origin of this current, and its possible role during the plateaux of action potentials are discussed.