Spatial heterogeneity of calcium transient alternans during the early phase of myocardial ischemia in the blood-perfused rabbit heart.

BACKGROUND: Optical mapping of cytosolic calcium transients in intact mammalian hearts is now possible using long-wavelength [Ca(2+)](i) indicators. We propose that beat-to-beat [Ca(2+)](i) transient alternans during ischemia may lead to spatial and temporal heterogeneity of calcium-activated membrane currents. METHODS AND RESULTS: To test this hypothesis, isolated rabbit hearts were loaded with the fluorescent [Ca(2+)](i) indicator, rhod-2 AM, and imaged at 300 frames/sec during blood-perfused ischemic trials. High-quality [Ca(2+)](i) transients were recorded in each of 8 hearts.[Ca(2+)](i) transient alternans was never present in control records but occurred in each of the hearts during ischemia, with onset after 2 to 4 minutes. Alternans was confined to circumscribed regions of the heart surface 5 to 15 mm across. Multiple regions of alternans were found in most hearts, and regions that were out of phase with one another were found in 6 hearts. Quantitative maps of alternans were constructed by calculating an alternans ratio. This ratio behaved as a continuous variable that reached a maximum value in the center of the regions with alternans. CONCLUSIONS: These results demonstrate marked spatial heterogeneity of the [Ca(2+)](i) transient during the early phase of ischemia, which could produce electrical instability and arrhythmias in large mammalian hearts.

Calcium transient alternans in blood-perfused ischemic hearts: observations with fluorescent indicator fura red.

Ischemia produces striking electrophysiological abnormalities in blood-perfused hearts that may be caused, in part, by effects of ischemia on intracellular calcium. To test this hypothesis, intracellular Ca2+ concentration ([Ca2+]i) transients were recorded from the epicardial surface of blood- and saline-perfused rabbit hearts using the long-wavelength indicator Fura Red. Calcium transients were much larger than the movement artifact, representing up to 29% of the total signal. Switching the perfusate from saline to blood did not affect the time course of the transients or the apparent level of [Ca2+]i. Compartmentation of Fura Red fluorescence was estimated by exposure to Mn2+. The results were cytosol 60 +/- 3%, organelles 12 +/- 2%, and autofluorescence plus partly deesterified Fura Red 29 +/- 4%. [Ca2+]i transients were calibrated in situ by perfusion of the extracellular space with high-Ca2+ and Ca(2+)-free EGTA solutions. Peak systolic [Ca2+]i was 663 +/- 74 nM, and end-diastolic [Ca2+]i was 279 +/- 59 nm. Ischemia was produced by interruption of aortic perfusion for 2.5 min during pacing (150 beats/min). Ischemia produced broadening of the [Ca2+]i transient, along with beat-to-beat alternations in the peak systolic and end-diastolic level of [Ca2+]i (calcium transient alternans). [Ca2+]i transient alternans occurred in 82% of blood-perfused hearts vs. 43% of saline-perfused hearts. The discrepancy between large and small transients (mean alternans ratio) was larger in the blood-perfused hearts (0.23 +/- 0.04 vs. 0.07 +/- 0.03, P = 0.005). These observations are important because of the apparent relationship of [Ca2+]i transient alternans to electrical alternans and arrhythmias during ischemia.

Endothelin activates voltage-dependent Ca2+ current by a G protein-dependent mechanism in rabbit cardiac myocytes.

1. Endothelin is a vasoactive peptide released from vascular endothelial cells which has potent cardiac inotropic effects. We examined the effect of endothelin on the verapamil-sensitive Ca2+ current (ICa) in enzymatically dispersed rabbit ventricular myocytes. 2. Using the whole-cell voltage clamp technique with a standard dialysing pipette solution, the application of extracellular endothelin (20 nM) did not increase the peak ICa, but in fact caused a small reversible decline (903 +/- 109 pA without endothelin, 727 +/- 95 pA with endothelin (means +/- S.E.M., n = 14, P less than 0.05)). 3. If GTP (100 microM) was added to the pipette solution, the extracellular application of endothelin (0.2 or 20 nM) caused a large, reproducible increase in peak ICa (871 +/- 85 pA without endothelin, 1230 +/- 110 pA with 20 nM-endothelin (n = 10, P less than 0.05). The endothelin enhancement of ICa occurred after a delay of approximately 3-4 min at room temperature. 4. The GTP requirement for the endothelin effect on ICa suggests that its effect may be mediated through a G protein-dependent pathway. To investigate this further, experiments were performed with pipette solutions containing guanosine-5'-O-(2-thiodiphosphate) (GDP beta S), a GDP analogue which inhibits G protein cycling. With the addition of GDP beta S (0.5-5.0 mM) to the pipette solution (along with 100 microM-GTP), the effect of endothelin on peak ICa was blocked (1062 +/- 86 pA without endothelin, 1170 +/- 134 pA with endothelin (n = 11, P greater than 0.05)). 5. Incubation of myocytes with pertussis toxin (500 ng/ml) prevented the partial ACh-induced reversal of the isoprenolol enhancement of ICa. However, this identical treatment failed to block the endothelin enhancement of the voltage-dependent Ca2+ current (n = 4). 6. Taken together, these results confirm that while the effect of endothelin in rabbit cardiac ventricular myocytes is mediated through a G protein-dependent pathway, the G protein involved is pertussis toxin-insensitive.

Effects of ischemia and hypercarbic acidosis on myocyte calcium transients, contraction, and pHi in perfused rabbit hearts.

The time courses of changes in pHi and cytosolic calcium were compared in isolated perfused rabbit hearts with the use of the calcium-sensitive fluorescent indicator indo-1 and the pH indicator 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF). Cell-permeant forms of these indicators were loaded into myocytes by arterial infusion or by direct infusion into the extravascular space. Indo-1 fluorescence was recorded from the epicardial surface of the left ventricle at an excitation wavelength of 360 nm and emission wavelengths of 400 and 550 nm. BCECF fluorescence was recorded at an excitation wavelength of 490 nm and an emission wavelength of 530 nm. Calibration procedures were developed for each indicator that allowed [Ca2+]i and pHi to be quantified during ischemia. Global ischemia decreased contractility and caused a rapid increase in both the systolic and end-diastolic levels of the calcium transients. Ninety seconds of ischemia increased peak systolic [Ca2+]i from 609 +/- 29 to 1,341 +/- 159 nM, while end-diastolic [Ca2+]i increased from 315 +/- 25 to 553 +/- 52 nM. The observed increase in diastolic [Ca2+]i, was shown not to arise from indo-1-loaded endothelial cells. The initial increase in [Ca2+]i was followed by a gradual decline and then a secondary rise occurring between 5 and 15 minutes of ischemia. In contrast, ischemia caused a monotonic decrease in pHi from a baseline of 7.03 +/- 0.06 to 6.83 +/- 0.02 after 2 minutes, 6.32 +/- 0.1 after 10 minutes, and 6.11 +/- 0.04 after 15 minutes. Perfusion of hearts with acidified (hypercarbic) saline increased the systolic and diastolic levels of the calcium transients, but only when pHi fell below a threshold value, which was more acidic than values achieved during the first 2 minutes of ischemia (6.83 +/- 0.03). Lesser degrees of acidification caused a decrease in contractility but did not affect the calcium transients. Effects of pHi on the calcium transients were not due to altered calcium sensitivity of indo-1. These results suggest that cytosolic acidification may contribute to the increase in [Ca2+]i during the first 15 minutes of global ischemia, but the [Ca2+]i increase during the first 2 minutes is mediated by other factors.

Effect of platelet release products on cytosolic calcium in cardiac myocytes.

The effect of platelet release products on cytosolic calcium [( Ca++]i) was examined by monitoring the fluorescence of chick embryonic heart cells loaded with the fluorescent calcium indicator indo-1 AM. Cell free filtrate of platelet release products was obtained from rabbit platelets activated with thrombin or collagen. This filtrate caused a rapid increase in both systolic and diastolic [Ca++]i in a dose-dependent manner. The effect was not blocked by pretreating the platelets with aspirin or a thromboxane synthetase inhibitor. It was not mimicked by a thromboxane analog, or by several substances known to be released from platelets including ADP, serotonin, or platelet activating factor. Apyrase or ATP-gamma S had no effect on the activity. The responsible product was heat-sensitive, trypsin-sensitive, and partitioned into the aqueous phase of a chloroform suspension. It has a low molecular weight (less than 3kD) and is sensitive to 2-mercaptoethanol. Protease inhibitor appears to prolong the activity. These results suggest that trypsin-sensitive peptide(s) released from activated platelets can increase [Ca++]i in cardiac cells.

Effect of thrombin on calcium homeostasis in chick embryonic heart cells. Receptor-operated calcium entry with inositol trisphosphate and a pertussis toxin-sensitive G protein as second messengers.

UNLABELLED: Thrombin increases intracellular calcium ([Ca++]i) in several cell types and causes a positive inotropic effect in the heart. We examined the mechanism of the thrombin-induced [Ca++]i increase in chick embryonic heart cells loaded with the fluorescent calcium indicator, indo-1. Thrombin (1 U/ml) increased both systolic and diastolic [Ca++]i from 617 +/- 62 and 324 +/- 46 to 1041 +/- 93 and 587 +/- 38 nM, respectively. An initial rapid [Ca++]i increase was followed by a more sustained increase. There were associated increases in contraction strength, beat frequency, and action potential duration. The [Ca++]i increase was not blocked by tetrodotoxin or verapamil, but was blocked by pretreatment with pertussis toxin (100 ng/ml). The thrombin-induced [Ca++]i increase was partly due to intracellular calcium release, since it persisted after removal of external calcium. The [Ca++]i increase in zero calcium was more transitory than in normal calcium and was potentiated by 10 mM Li+. Thrombin also induced influx of calcium across the surface membrane, which could be monitored using Mn++ ions, which quench indo-1 fluorescence when they enter the cell. Thrombin-induced Mn++ entry was insensitive to verapamil, but was blocked by 2 mM Ni++. Thrombin increased inositol trisphosphates by 180% at 90 s and this effect was also blocked by pretreatment with pertussis toxin. CONCLUSION: thrombin promotes calcium entry and release in embryonic heart cells even when action potentials are inhibited. Both modes of [Ca++]i increase may be coupled to the receptor by pertussis toxin-sensitive G proteins.

Cellular mechanism for ischemic ventricular arrhythmias.

Two of the major ionic abnormalities found early in ischemia are (a) loss of potassium with an increase in the extracellular potassium ion concentration and (b) an increase in free cytosolic calcium. Both of these ionic abnormalities can powerfully predispose to the development of arrhythmias.

Use-dependent block of single sodium channels by lidocaine in guinea pig ventricular myocytes.

Single sodium channel openings have been recorded from cell-attached patches of isolated guinea pig ventricular myocytes. A paired pulse protocol was used to test the hypothesis that channel openings are required for lidocaine block. While the averaged ensemble current during the test pulse was much reduced, there was no correlation between the appearance of channel openings during the conditioning pulse and the subsequent test pulse. Analysis of single channel records demonstrated that the unit conductance of open channels was not changed by lidocaine. The block of ensemble INa was explained by roughly equal reductions in number of open channel events, and in the average duration of opening for each event. These results suggest that lidocaine binding to Na+ channels is dependent upon voltage, but may occur before channel opening. A lidocaine-modified channel can still open, but will be less likely to remain open than a drug-free channel. These results are consistent with block of a pre-open state of the channel.

Effect of Bay K8644 on cytosolic calcium transients and contraction in embryonic cardiac ventricular myocytes.

Cytosolic calcium transients were recorded from spontaneously beating chick embryonic myocardial cell aggregates loaded with the fluorescent [Ca2+]i indicator, indo-1. Calcium transients rose rapidly from an end-diastolic [Ca2+]i of 230 +/- 18 nM to a peak systolic [Ca2+]i of 619 +/- 34 nM (n = 21). Relaxation of the transients was slow, and continued throughout diastole. Bay K8644 (0.5 microM) markedly prolonged the action potential and caused similar prolongation of the calcium transients. Calcium transients in the presence of Bay K8644 had an inflection on their rising phase, which was followed by a more gradual increase that continued until the membrane had repolarized to a negative potential of -15 to -30 mV. Bay K8644 caused marked elevation of peak systolic [Ca2+]i to 955 +/- 56 nM (P less than 0.002), with concomitant elevation of end-diastolic [Ca2+]i to 400 +/- 36 nM (P less than 0.002). Optical recordings of contraction showed changes similar to those in the calcium transient: the initial upstroke of the contraction was followed by a more gradual second component, which gave the contraction a "half-dome" appearance. The time to peak [Ca2+]i and the time to peak contraction increased linearly with action potential duration (APD50). The effects of Bay K8644 were simulated, in part, by CsCl (7.5 mM), which produced equivalent prolongation of the action potential and calcium transients. However, CsCl did not elevate diastolic [Ca2+]i. To determine the mechanism of the diastolic [Ca2+]i increase, Bay K8644 was applied to aggregates rendered quiescent by tetrodotoxin. Bay K8644 caused a graded increase in [Ca2+]i, which was followed by resumption of spontaneous beating.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of ischemia on calcium-dependent fluorescence transients in rabbit hearts containing indo 1. Correlation with monophasic action potentials and contraction.

The effects of acute global ischemia on cytosolic calcium transients were studied in perfused rabbit hearts loaded with the fluorescent calcium indicator indo 1. Indo 1-loaded hearts were illuminated at 360 nm, and fluorescence was recorded simultaneously at 400 and 550 nm from the epicardial surface of the left ventricle. The F400/F550 ratio was calculated by an analog circuit, which allowed cancellation of optical motion artifact. Resulting calcium transients demonstrated a rapid upstroke and slow decay similar to those recorded in isolated ventricular myocytes. Global ischemia rapidly suppressed contraction, but it produced a concurrent increase in the systolic and diastolic levels of the calcium transients, together with an increase in the duration of the peak. The effects of ischemia were reversed by reperfusion, inhibited by verapamil, and mimicked by perfusion of nonischemic hearts with acidified (CO2-rich) solution. In addition to elevation of the calcium transients, ischemia caused a pattern of intracellular calcium alternans that was discernible after 2-3 minutes. The pattern of alternans was stable at a given epicardial site, but it could be out of phase at different sites. Similar nonuniformities were observed in contraction strength and in the duration of monophasic action potentials recorded immediately adjacent to the fiber-optic probe. Abnormalities in intracellular calcium may be a causal factor in the loss of electrical and mechanical synchrony in the acutely ischemic heart.

Mechanism of depolarization in the ischaemic dog heart: discrepancy between T-Q potentials and potassium accumulation.

1. To study the origin of ischaemic myocardial depolarization, the diastolic surface potential - T-Q depression-was correlated with subepicardial extracellular K+ accumulation during serial episodes of widespread ischaemia in open-chest dogs, and in isolated, blood-perfused canine hearts. Placement of the reference electrode on a small island of non-ischaemic myocardium simplified the interpretation of the T-Q potentials. 2. In some experiments, changes in resting potential in the ischaemic zone were recorded using a 'contact' monophasic action potential (MAP) electrode. The change in MAP resting potential was linearly related to T-Q depression for a wide range of experimental conditions (R greater than 0.98). T-Q depression is therefore a linear index of depolarization in superficial myocardial cells. 3. The validity of T-Q depression as a 'measure' of local cellular depolarization was further tested by infiltration of isotonic KCl into the superficial myocardium subjacent to the ischaemic zone electrode. Resulting T-Q depression was 2- to 3-fold larger than the maximum values obtained in ischaemia; and the ratio of T-Q depression to the amplitude of the accompanying monophasic potential was consistent with the assumption that KCl had fully depolarized the underlying myocardium (delta Vm = 89 mV). KCl prevented (i.e. occluded) further changes in the T-Q potential during ischaemia. KCl did not have these effects if it was introduced at sites more remote from the electrode (greater than 4 mm). 4. Ischaemic T-Q depression was drastically accelerated by increasing the heart rate from 90 to 180 beats/min and was further accelerated by arterial infusion of CaCl2. These effects were most striking during the first minute of ischaemia. 5. In contrast, the above manoeuvres produced little acceleration of subepicardial K+ accumulation. After CaCl2 infusion, large ischaemic potentials, severe conduction impairment, and arrhythmias could be observed when K+ activity was almost normal (aK = 4.0-4.5 mM). 6. T-Q depression was larger in vivo than in isolated hearts, both absolutely and relative to K+ accumulation. 7. Based on the reproducible amplitude of ischaemic epicardial potential-estimates of cellular depolarization (delta Vm) could be obtained, which were compared with the concurrent change in K+ electrode potential (delta EK) for each experimental condition. 8. Estimated depolarization was nearly identical to delta EK in isolated hearts under basal conditions. However, depolarization significantly exceeded delta EK during rapid pacing, CaCl2 infusion, or during paced occlusions performed in vivo.(ABSTRACT TRUNCATED AT 400 WORDS)

Cytosolic calcium staircase in cultured myocardial cells.

To elucidate the mechanism of the tension staircase, chick embryonic myocardial cell aggregates were loaded with the fluorescent cytosolic calcium indicator, indo 1. Fluctuations in indo 1 fluorescence were compared with recordings of cell edge movement during spontaneous beating and during stimulation by intracellular current pulses. Indo 1-loaded aggregates exhibit fluorescence transients during each transmembrane action potential. The rising phase of the transients is rapid, but the decaying phase is slow (several hundred msec) and is similar in time course to the pandiastolic relaxation seen in the optical recordings of cell edge movement. Acceleration of beat frequency by brief depolarizing current pulses produces an ascending staircase in both edge movement and systolic [Ca2+]i. There is a similar staircase in the diastolic [Ca2+]i, which is also reflected by diastolic cell edge movement. The existence of a diastolic [Ca2+]i staircase may provide new insight into the mechanism of the force-frequency relation in the heart.

Cytosolic calcium transients from the beating mammalian heart.

To elucidate the role of cytosolic calcium, [Ca2+]i, in the physiology of the normal and ischemic heart, we have developed a method for recording [Ca2+]i transients from the epicardial surface of the rabbit ventricle after arterial perfusion with the cell-permeant cytosolic calcium indicator indo-1 AM. Hearts were illuminated at 360 nm, and fluorescence was recorded simultaneously at 400 and 550 nm. The F400/F550 fluorescence ratio was calculated by an analog circuit that allowed cancelation of small movement artifacts that were present at single wavelengths. Clear [Ca2+]i transients were present in the F400/F550 signal and were remarkable for their slow decay. Slow decay of the transients was not due to buffering of [Ca2+]i by indo-1, since there was no associated impairment of contraction or relaxation. The peak amplitude of the [Ca2+]i transients was increased by ouabain, adrenaline, postextrasystolic potentiation, and acetylcholine. The extent to which the transients decayed diminished with shortening of the interbeat interval, but decay of the transients could be further diminished by acetylcholine or caffeine. A major advantage of the intact heart over isolated myocytes is the ability to measure changes in [Ca2+]i during ischemia. Ischemia produced a marked increase in both peak systolic and end-diastolic [Ca2+]i, which was most rapid during the first 30 sec, and approached a plateau value after 90 sec. This increase in [Ca2+]i was associated with a characteristic broadening of the peak of the transient. The increase in [Ca2+]i during ischemia is consistent with a proposed causative role of [Ca2+]i in mediating early electrophysiological abnormalities.

Na+/Ca2+ exchange in cardiac myocytes. Effect of ouabain on voltage dependence.

Sarcolemmal sodium/calcium exchange activity was examined in individual chick embryonic myocardial cell aggregates that were loaded with quin 2. The baseline [Ca2+]i was 68 +/- 4 nM (n = 29). Abrupt superfusion with sodium-free lithium solution produced a fourfold increase in steady-state [Ca2+]i to 290 +/- 19 nM, which was reversible upon sodium restitution. Other methods of increasing [Ca2+]i such as KCl-depolarization or caffeine produced a dose-dependent increase in quin 2 fluorescence, accompanied by sustained contracture. The [Ca2+]i increase in zero sodium was linear, and its half-time (t1/2) of 15.1 +/- 0.1 s was similar to that of the sodium-free contracture (t1/2 = 14.4 +/- 0.5 s) under the same conditions. The sodium-dependent [Ca2+]i increase was not significantly greater when potassium served as the sodium substitute instead of lithium. This suggests that sodium/calcium exchange has little voltage dependence in this situation. However, in aggregates pretreated with ouabain (2.5 microM), the [Ca2+]i increase was almost threefold greater with potassium than with lithium (P less than 0.007). Ouabain therefore potentiated the effect of membrane potential on calcium influx. We propose that elevation of [Na2+]i is a prerequisite for voltage dependence of the sodium/calcium exchange under the conditions studied. Sodium loading will then drastically increase calcium influx during the action potential while inducing an outward membrane current that could accelerate repolarization.

Rate dependence of ischaemic myocardial depolarisation: evidence for a novel membrane current.

Depolarisation of ischaemic myocardial cells is at least partly due to loss of cellular potassium. Whereas most manifestations of ischaemia vary with heart rate potassium loss, however, reportedly does not. Cellular depolarisation was therefore correlated with extracellular potassium activity during serial coronary artery occlusions in Langendorff perfused canine hearts. Occlusions in sinus rhythm (92(11) beats X min-1) were alternated with rapidly paced occlusions (180 beats X min-1). For each occlusion cellular depolarisation was estimated from TQ depression and compared with the simultaneous increase in potassium electrode potential, delta EK. Although potassium accumulation accounted for most of the estimated depolarisation at slow heart rates, a potassium independent mechanism predominated during rapid pacing. The potassium independent mechanism was especially important in the first minute of ischaemia when pacing increased depolarisation by 324%, with little increase in delta EK. It appears that ischaemia induces a rate sensitive depolarising membrane current, which worsens conduction and promotes arrhythmias.

Effect of diltiazem on ischemic myocardial depolarization and extracellular K+ accumulation.

Diltiazem retards ischemic arrhythmias and reduces cellular depolarization, as inferred from recordings of T-Q segment depression (delta T-Q). To explore this further, we correlated delta T-Q with the extracellular K+ electrode potential (delta EK) during serial ischemic trials. delta T-Q and delta EK were uniform in control trials, but decreased markedly in trials that immediately followed diltiazem infusion (0.5 mg/kg). delta EK at 2 min of ischemia was reduced from 11.8 +/- 1.3 to 7.4 +/- 1.2 mV; while delta T-Q was reduced from 7.2 +/- 0.5 to 4.4 +/- 0.7 mV. The effect of diltiazem on ischemic depolarization is largely, but not entirely explained by reduction of delta EK.

Paradoxical electromechanical effect of lanthanum ions in cardiac muscle cells.

Although lanthanum ions (La+++) block calcium influx in cardiac cells, they may paradoxically accentuate the sodium-free contracture. We have therefore studied the effects of La+++ on the zero sodium response in chick embryonic myocardial cell aggregates. Zero sodium alone causes: (a) A maintained contracture; (b) Asynchronous localized contractions that are selectively inhibited by caffeine or ryanodine, and presumably reflect release of calcium from the sarcoplasmic reticulum; (c) A nonspecific conductance increase that is ascribable to calcium-activated ion channels. Addition of La+++ potentiates the sodium-free contracture, and causes similar potentiation of the localized contractions and the conductance increase. All three phenomena occur 5-10-fold faster in 1 mM La+++ than in sodium-free fluid alone. In contrast, when La+++ is combined with caffeine or ryanodine, the zero sodium response is suppressed. We conclude that the paradoxical effect of La+++ on the contracture is not due to calcium influx, but to enhancement, or disinhibition of intracellular calcium release. Relaxation of normal myocardium may involve control of spontaneous calcium release by lanthanum- and sodium-sensitive calcium transport across the surface membrane.