Effects of pCai and pHi on cell-to-cell coupling

Reduction of ST elevation in repeated coronary occlusion model depends on both altered metabolic response and conduction property

The aim of this study was to elucidate the mechanisms of altered electrical response to ischemia in repeated coronary occlusion model. To test its dependence on metabolic response, extracellular K+ concentration (eKC), myocardial pH and PCO2 were simultaneously measured with epicardial ECG during three consecutive 4 min of left anterior descending coronary artery (LAD) occlusion separated by 15 min of reperfusion in canine hearts. ECG changes induced by infusion of high K+-buffer (10 mM) into the coronary arterial bed via carotid artery-LAD bypass (referred to as high K+-challenges: HKC) were also tested prior to (the first HKC), and during each reperfusion period (the second to the fourth HKC). ST elevation was significantly reduced in subsequent occlusions (3.14 +/- 0.48 and 2.98 +/- 0.47 mV in the second and third occlusion, both P<0.05, compared to 4.91 +/- 0.78 mV in the first). This was accompanied by significant attenuation of the changes in eKC, tissue pH and PCO2. ST elevation induced by HKC also significantly reduced after repeated occlusion (4.09 +/- 0.79 mV in the fourth HKC vs. 5.64 +/- 0.68 mV in the first, P<0.05) in spite of the identical changes in eKC during HKC. This progressive decrease in ST changes by HKC was rather consistent with augmented conduction delay (86.4 +/- 7.1% increase in activation time in the fourth vs. 54.3 +/- 3.4% in the first, P<0.01). These findings indicate that repeated ischemia induces altered electrical response to subsequent ischemia based on both attenuated metabolic response and altered conduction property.

Onset dynamics of reentrant tachycardia and rate-dependent conduction changes in canine ventricular muscle: effects of Na+ and Ca2+ channel blockade

To show that cycle-length (CL) prolongation occurring at the onset of reentrant tachycardias may be associated with an increase in conduction time (CT), and to investigate the involvement of Na+ and Ca2+ channel activity, reentrant activity was induced by programmed stimulation in thin ventricular muscle slices with a central cryothermal lesion, as documented with 7 to 12 bipolar recordings. We studied the course of the CL measured in successive tachycardia beats, as well as the course of conduction times after abrupt transition from a pacing CL of 1,000 to 400 ms (pacing paradigm). The majority of the tachycardias displayed a dynamic behavior in which CL increased progressively, with an exponential rate constant of 37 +/- 35 beats (mean +/- SD), stabilizing at 325 +/- 67 ms after a total increase of 17 +/- 17 ms. In the pacing paradigm, CT was prolonged from 68 +/- 21 ms to 79 +/- 24 ms according to a biphasic course consisting of an abrupt increase in the first response to 400 ms, followed up by an exponential increase, stabilizing with a rate constant of 18 +/- 23 beats. Lidocaine 5 x 10(-5) mol/L induced an increase in steady-state CT, which was not further modified by adding verapamil 10(-5) mol/L. However, verapamil prolonged the rate constant of the exponential course by 60 +/- 40 beats. Thus, the onset dynamics of reentrant tachycardias share common features with the dynamic behavior of CT in the pacing paradigm, in which both Na+ channel activity and Ca2+-modulated cellular coupling appear to be involved.

Protective effects of trimetazidine on hypoxic cardiac myocytes from the rat

The electrophysiological effects of the antianginal drug trimetazidine (TMZ) were investigated in cultured rat ventricular myocytes using a substrate-free hypoxia model of ischemia. The transmembrane potentials were recorded with glass microelectrodes and the contractions were simultaneously monitored with a video motion detector. The cardiomyocytes were treated with TMZ (1-5.10(-4) M final concentration) in the bath. The untreated and the drug-treated cells were submitted either to 150 min normoxia or to 150 min hypoxia followed by 90 min reoxygenation in the absence of oxidizable substrate. In normoxic conditions, TMZ did not affect the maximal diastolic potential (MDP) but significantly lowered the plateau potential level (OS) and decreased the upstroke velocity (Vmax) and the spontaneous action potential rate (APR). Conversely, TMZ significantly increased action potential duration at 80% repolarization (APD80). Under substrate-free hypoxia, the untreated cells displayed a progressive contractile failure and an important decrease in OS and APD. In parallel, early postdepolarizations triggering high rate spikes were observed. Prolonging oxygen depletion led to the cessation of the spontaneous electrical activity and thereafter to a gradual decrease in MDP. Near normal rhythmic action potentials and contractions resumed after reoxygenation. Comparatively, the treatment by 5.10(-4) M TMZ almost completely prevented the decrease in plateau amplitude, resting membrane potential, Vmax, APD80, and rate caused by substrate-free hypoxia. Moreover, the hypoxia-induced arrhythmias and the cessation of spontaneous electromechanical activities did not occur in the presence of TMZ (5.10(-4) M). After reoxygenation, the TMZ-treated cells exhibited a higher action potential amplitude than that of the untreated cells, although the TMZ-induced depressive effects on the spontaneous frequency and the Vmax persisted. In conclusion, this study shows that TMZ (5.10(-4) M) is efficient in protecting the isolated cardiac myocytes against the functional alterations induced by substrate-free hypoxia and led thus to a better recovery upon reoxygenation. The cytoprotective action may be linked, at least in part, to apparent ion channel blocking effects of the drug, which appeared in basal conditions at concentrations used in this study.

Intracellular Ca2+, intercellular electrical coupling, and mechanical activity in ischemic rabbit papillary muscle. Effects of preconditioning and metabolic blockade

During myocardial ischemia, electrical uncoupling and contracture herald irreversible damage. In the present study, we tested the hypothesis that an increase of intracellular Ca2+ is an important factor initiating these events. Therefore, we simultaneously determined tissue resistance, mechanical activity, pH(0), and intracellular Ca2+ (with the fluorescent indicator indo 1, Molecular Probes, Inc) in arterially perfused rabbit papillary muscles. Sustained ischemia was induced in three experimental groups: (1) control, (2) preparations preconditioned with two 5-minute periods of ischemia followed by reperfusion, and (3) preparations pretreated with 1 mmol/L iodoacetate to block anaerobic metabolism and minimize acidification during ischemia. In a fourth experimental group, intracellular Ca2+ was increased under nonischemic conditions by perfusing with 0.1 mmol/L ionomycin and 0.1 mumol/L gramicidin. Ca2+ transients and contractions rapidly disappeared after the induction of ischemia. In the control group, diastolic Ca2+ began to rise after 12.6 +/- 1.3 minutes of ischemia; uncoupling, after 14.5 +/- 1.2 minutes of ischemia; and contracture, after 12.6 +/- 1.5 minutes of ischemia (mean +/- SEM). Preconditioning significantly postponed Ca2+ rise, uncoupling, and contracture (21.5 +/- 4.0, 24.0 +/- 4.1, and 23.0 +/- 5.3 minutes of ischemia, respectively). Pretreatment with iodoacetate significantly advanced these events (1.9 +/- 0.7, 3.6 +/- 0.9, and 1.9 +/- 0.2 minutes of ischemia, respectively). In all groups, the onset of uncoupling always followed the start of Ca2+ rise, whereas the start of contracture was not different from the rise in Ca2+. Perfusion with ionomycin and gramicidin permitted estimation of a threshold [Ca2+] for electrical uncoupling of 685 +/- 85 nmol/L. In conclusion, the rise in intracellular Ca2+ is the main trigger for cellular uncoupling during ischemia. Contracture is closely associated with the increase of intracellular Ca2+ during ischemia.

Correlation of ischemia-induced extracellular and intracellular ion changes to cell-to-cell electrical uncoupling in isolated blood-perfused rabbit hearts. Experimental Working Group

BACKGROUND

The relationships between the metabolic, ionic, and electrical changes of acute ischemia have not been determined precisely because they have been studied under different experimental conditions. We used ion-selective electrodes, nuclear magnetic resonance spectroscopy, and the four-electrode method to perform four series of experiments in the isolated blood-perfused rabbit heart loaded with 5F-BAPTA during 30 to 35 minutes of no-flow ischemia. We sought to determine the relationship between changes in phosphocreatine (PCr), adenosine triphosphate (ATP), intracellular calcium ([CA2+]i), intracellular pH (pHi) extracellular potassium ([K+]e), extracellular pH (pHe), and whole-tissue resistance (rt).

METHODS AND RESULTS

In the first 8 minutes of ischemia, [K+]e rose from 4.9 to 10.8 mmol/L, PCr fell by 90%, ATP decreased by 25%, and pHi and pHe decreased by 0.5 U, while [Ca2+]i and rt changed only slightly. Between 8 and 23 minutes, [K+]e changed only slightly; pHi, pHe, and ATP continued to fall, and [Ca2+]i rose. rt did not increase until >20 minutes of ischemia, when pHi was <6.0 and [Ca2+]i had increased more than three-fold. The increase in rt, indicating electrical uncoupling, coincided with the third phase of the [K+]e change.

CONCLUSIONS

Our study suggests that cellular uncoupling occurs only after a significant rise in [Ca2+]i and fall in pHi and that these ionic and electrical changes can be identified by the change in [K+]e. Our study underscores the importance of using a common model while attempting to formulate an integrated picture of the ionic, metabolic, and electrical events that occur during acute ischemia.

The protective effect of D-sotalol against hypoxia-induced myocardial uncoupling

The effects of D-sotalol on intercellular electrical coupling and ultrastructure under hypoxic conditions were investigated in myocardial samples from eight young (1-2 months) and four older (10-12 months) guinea pigs. A right ventricular muscle strip was kept simultaneously in two divided chambers and superfused with normoxic and/or hypoxic (97% N2+ 3% Co2) Krebs solution. Hypoxia caused shortening of action potential duration (APD) and electrical cell-to-cell uncoupling. If the uncoupling appeared after short-term hypoxia (less than 30 min), administration of 3.10(-7)M of D-sotalol to the hypoxic perfusate led to a recovery of electrical coupling. Transmission electron microscopy revealed moderate reversible ultrastructural alterations of the cardiomyocytes. No apparent changes in intercellular junctions were observed. The recoupling effect of sotalol decreased with the time of hypoxia as the ultrastructural damage progressed. After prolonged hypoxia (more than 30 min), cardiomyocytes were markedly injured, intercellular junctions were severely affected, and gap junctions occurred less frequently. In these cases, administration of D-sotalol caused only transient recoupling. After 1 h of hypoxia, no recoupling was observed. Pretreatment with D-sotalol prevented hypoxia-induced electrical uncoupling and markedly attenuated ultrastructural damage, although shortening of APD still persisted. Our results indicate that the cardioprotective effect of D-sotalol on electrical intercellular coupling is closely associated with sotalol-induced prevention of the ultrastructural damage. Considering previous results, we suggest that this protective effect of D-sotalol may be related to its ability to increase intracellular cyclic adenosine monophosphate and, thereby, to decrease cytosolic free Ca. These effects can explain the antiarrhythmic and defibrillating properties of D-sotalol.

A structural basis for the unequal sensitivity of the major cardiac and liver gap junctions to intracellular acidification: the carboxyl tail length

The regulation of junctional conductance (Gi) of the major cardiac (connexin43; Cx43) and liver (connexin32; Cx32) gap junction proteins by intracellular hydrogen ion concentration (pH; pHi), as well as well as that of a truncation mutant of Cx43 (M257) with 125 amino acids deleted from the COOH terminus, was characterized in pairs of Xenopus laevis oocytes expressing homologous channels. Oocytes were injected with 40 nl mRNAs (2 micrograms/microliters) encoding the respective proteins; subsequently, cells were stripped, paired, and incubated for 20-24 h. Gj was measured in oocyte pairs using the dual electrode voltage-clamp technique, while pHi was recorded simultaneously in the unstimulated cell by means of a proton-selective microelectrode. Because initial experiments showed that the pH-sensitive microelectrode responded more appropriately to acetate than to CO2 acidification, oocytes expressing Cx32 and wild type and mutant Cx43 were exposed to a sodium acetate saline, which was balanced to various levels of pH using NaOH and HCl. pH was changed in a stepwise manner, and quasi-steady-state Gj -pHi relationships were constructed from data collected at each step after both Gj and pHi had reached their respective asymptotic values. A moderate but significant increase of Gj was observed in Cx43 pairs as pHi decreased from 7.2 to 6.8. In both Cx32 and M257 pairs, Gj increased significantly over a wider pH range (i.e., between 7.2 and 6.3). Further acidification reversibly reduced Gj to zero in all oocyte pairs. Pooled data for the individual connexins obtained during uncoupling were fitted by the Hill equation; apparent 50%-maximum (pK;pKa) values were 6.6 and 6.1 for Cx43 and Cx32, respectively, and Hill coefficients were 4.2 for Cx43 and 6.2 for Cx32. Like Cx32, M257 had a more acidic pKa (6.1) and steeper Hill coefficient (6.0) than wild type Cx43. The pKa and Hill coefficient of M257 were very similar to those of Cx32. These experiments provide the first direct comparison of the effects of acidification on Gj in oocyte pairs expressing Cx43 or Cx32. The results indicate that structural differences in the connexins are the basis for their unequal sensitivity to intracellular acidification in vivo. The data further suggest that a common pH gating mechanism may exist between amino acid residues 1 and 256 in both Cx32 and Cx43. However, the longer carboxyl tail of Cx43 relative to Cx32 or M257 provides additional means to facilitate acidification-induced gating; its presence shifts the pKa from 6.1 (Cx32 and M257) to 6.6 (Cx43) in the conductance of these channels.

The effect of K+/H+ antiporter nigericin on gap junction permeability

The K+/H+ antiporter nigericin inhibits the intercellular exchange of the fluorescent dye Lucifer Yellow between DM15-transformed fibroblasts derived from the Djungarian hamster. The efficacy of nigericin action was related to its concentration and time of incubation. The nigericin-induced uncoupling effect on gap junctions was reversible and was shown to be based on its ability to cause cystolic acidification. The effect of nigericin on dye-coupling in intact and 12-O-tetradecanoyl-phorbol-13-acetate (TPA)-pretreated cells did not differ, indicating that the uncoupling effect of H+ on gap junctions in DM15 cells was not mediated by the TPA-dependent isoform of protein kinase C.

Influence of rate-dependent cellular uncoupling on conduction change during simulated ischemia in guinea pig papillary muscles: effect of verapamil

This study was performed to determine if the changes in cellular coupling induced by simulated ischemia were rate-dependent and if they contributed to the rate-dependent conduction slowing that occurs in this setting. We also sought to determine if the known ability of verapamil to prevent ischemia-induced conduction changes might be related to the preservation of cellular coupling. We studied the effects of increasing stimulation frequency from 0.5 to 2.0 Hz on the simultaneous changes in the maximum rate of rise (Vmax) of the action potential upstroke, conduction velocity, and internal longitudinal resistance (ri) determined by the voltage ratio method in superfused guinea pig papillary muscles under conditions of simulated ischemia (SI). When stimulation frequency was 0.5 Hz, 30 minutes of SI caused a 16.5% decrease in Vmax, a 16% increase in ri, and a 12.9% decrease in conduction velocity. When stimulation frequency was increased to 2.0 Hz, 30 minutes of SI caused a 30% decrease in Vmax, a 72.9% increase in ri, and a 21.4% decrease in conduction velocity. Thus, the changes were rate-dependent. Verapamil (1 X 10(-6) M) did not influence the changes in these parameters during SI at 0.5 Hz nor the decrease in Vmax during SI at 2.0 Hz, but it did prevent the rate-dependent increase in ri. Verapamil also prevented the rate-dependent decrease in conduction velocity induced by SI. Our results suggest that during simulated ischemia the rate-dependent component of the increase in Ri contributes to the rate-dependence of the conduction slowing.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of calmidazolium and dibutyryl cyclic AMP on the longitudinal internal resistance in sinus node strips

The effects of calmidazolium (10(-7) mol/l) and db cAMP (10(-3) mol/l) on the longitudinal internal resistance (ri) in the rabbit sinus node strips were studied by means of microelectrode and extracellular recording techniques. Calmidazolium (CDZ) decreased ri by 27%. An addition of db cAMP to the CDZ-containing Tyrode potentiated this effect by further 14%. db cAMP initially decreased ri by 17%, then it enhanced this resistance by 7% above the pretreatment control value. An addition of CDZ to the db cAMP-containing Tyrode reduced ri by 41% below the pretreatment control. Possible mechanisms underlying these effects were discussed in terms of cAMP, Cai, and calmodulin action on the cell coupling.

Effect of oxygen withdrawal on active and passive electrical properties of arterially perfused rabbit ventricular muscle

Oxygen withdrawal from myocardial cells leads to changes of the transmembrane action potential (mainly action potential shortening), to cellular uncoupling, and to changes of vascular permeability. This study was aimed at the simultaneous measurement of electrical activity and passive electrical properties (extracellular and intracellular longitudinal resistance) in arterially perfused rabbit papillary muscles under different conditions of changed oxygen supply. These included 1) complete anoxia (erythrocyte-free perfusate), 2) hypoxia (PO2 between 23-28 mm Hg, erythrocytes present) in the presence and absence of glucose, and 3) normoxia with erythrocyte-free perfusate. Similarly to myocardial ischemia, rapid cellular uncoupling occurred only after an initial stable period of approximately 17 minutes, and it required complete anoxia. The marked shortening of the action potential developed before cellular uncoupling. In six out of eight experiments, the fibers were inexcitable when uncoupling started. In severe hypoxia, no significant change of internal longitudinal resistance was observed over 35-40 minutes. The time course of the extracellular longitudinal resistance was different from the change in intracellular resistance: A marked decrease occurred almost immediately after the onset of oxygen withdrawal. This decrease was followed by a small increase in conduction velocity, which was most likely due to a change in the interstitial compartment (edema). It was observed during anoxic as well as during hypoxic perfusion. We conclude that 1) cellular uncoupling in arterially perfused tissue requires almost complete oxygen lack and occurs with a delay of more than 10 minutes, 2) marked action potential shortening precedes uncoupling, and therefore can not simply be attributed to an increase in free, intracellular calcium, and 3) vascular endothelial function is more sensitive to oxygen withdrawal than the myocyte.