Effects of Cadmium and Nisoldipine on the Delayed Rectifier Potassium Current in Guinea Pig Ventricular Myocytes

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Vol. 281, Issue 2, 826-833, 1997

Effects of Cadmium and Nisoldipine on the Delayed Rectifier Potassium Current in Guinea Pig Ventricular Myocytes¹

Pascal Daleau² , Majed Khalifa³ and Jacques Turgeon⁴

Quebec Heart Institute, Laval Hospital, Faculty of Medicine, Department of Pharmacology, Laval University (P.D.) and School of Pharmacy, Laval University (M.K., J.T.), Ste-Foy, P.Q., Canada, G1V 4G5

	Abstract

Top Abstract Introduction Methods Results Discussion References

Block of the slow inward calcium current (I_si) during assessment of the delayed rectifier potassium current (I_K) of cardiacventricular myocytes is commonly achieved by use of either inorganiccompounds such as cadmium or dihydropyridine derivatives suchas nisoldipine. Effects of these two I_si blockers on I_K characteristicsof guinea pig ventricular myocytes were compared in this study.Currents were measured in the whole cell configuration of thepatch-clamp technique and I_K tail amplitudes were measured at $-$ 40 mV after depolarizations to various test potentials (voltagesteps, $-$ 20 to +50 mV) for either 250 (I_K250), 450 (I_K450) or 5000(I_K5000) msec. Activating and tail currents measured in the presenceof cadmium were of greater amplitudes when voltage steps weremore positive than 0 mV but were of smaller amplitudes at V_test $<=$ 0 mV compared to currents measured in the presence of nisoldipineor Tyrode solution. In the presence of the rapid component ofthe delayed rectifier E-4031, a blocker of cadmium increased I_Ksamplitude during high voltage tests and caused a positive shiftin the voltage dependence of I_Ks activation at low depolarizingpotentials. In contrast, no effect on I_K was observed when nisoldipinewas added to Tyrode solution. In conclusion, results obtainedin this study suggest that cadmium depresses and/or shifts theactivation curve of the rapid component and increases and positivelyshifts the slow component of I_K in guinea pig ventricular myocytes.These observations lead us to propose that nisoldipine may bea better tool to inhibit long lasting inward calcium current duringassessment of I_K.

	Introduction

Top Abstract Introduction Methods Results Discussion References

Elimination of L-type calcium current (I_Ca-L) is commonly required during pharmacological or physiological studies assessingmodulation of I_K in ventricular myocytes. Successful block ofI_Ca-L has been achieved by use of either organic or inorganiccalcium channel antagonists (Reuter et al., 1985; Kamp and Miller,1987; Kamp et al., 1988). However, specificity of block of calciumchannel antagonists relative to cardiac potassium currents isof great concern in order not to bias interpretation of recordsobtained.

Previous studies have suggested that calcium channel antagonists may not be as specific as generally thought (Hume, 1985;Nerbonne and Gurney, 1987; Richard et al., 1988; Fan and Hiraoka,1991; Follmer et al., 1992). For example, cobalt modifies amplitudeand kinetics of deactivating I_K tail current in guinea pig ventricularmyocytes (Fan and Hiraoka, 1991). Moreover, in this species, cobaltpositively shifts the voltage-dependent activation curve of I_K(Fan and Hiraoka, 1991). In cat ventricular myocytes, cadmiumshifts to more positive potentials the voltage-dependent activationcurve of I_K (Follmer et al., 1992). Contrasting results have beenobtained in studies looking at the effects of organic I_Ca-L blockerson I_K. Among dihydropyridine derivatives, nisoldipine does notreduce I_K tail current after 1-sec depolarizing pulses in calfPurkinje fibers although nicardipine reduces I_K in frog atrialfibers at concentrations greater than 0.01 µM (Kass, 1982; Richardet al., 1988).

In guinea pig ventricular myocytes, I_K is composed of a rapidly activating, inwardly rectifying component (I_Kr) and a slowlyactivating, outwardly rectifying component (I_Ks) (Sanguinettiand Jurkiewicz, 1990a). I_Kr is the major repolarizing currentduring normal action potential duration and the target of mostmethanesulfonamide class III antiarrhythmic agents (Sanguinettiand Jurkiewicz, 1990a; Follmer and Colatsky, 1990; Wettwer etal., 1992). In contrast, I_Ks is selectively blocked by diureticsand has a more predominant role in repolarization during prolongedaction potential duration or rapid heart rates during which I_Ksactivation may accumulate (Courtney et al., 1992; Jurkiewicz andSanguinetti, 1993; Turgeon et al., 1994; Daleau and Turgeon, 1994).Numerous studies assessing I_K properties in guinea pig ventricularmyocytes have used either cadmium or nisoldipine to block I_Ca-L.Although these drugs became the gold standard blockers of I_Ca-L,no study carefully looked at their effects on I_K components inguinea pig ventricular myocytes.

Therefore, the objective of our study was to compare effects of cadmium and nisoldipine on the amplitude, kinetics and activationand deactivation current-voltage curves of I_Kr and I_Ks in guineapig ventricular myocytes.

	Methods

Top Abstract Introduction Methods Results Discussion References

Patch-Clamp Experiments

Cell preparation and solutions. Experiments were performed on single ventricular myocytes obtained from adult guinea pig hearts by use of an enzymatic dissociationtechnique. All solutions used during the cell isolation procedurewere oxygenated and maintained at 37°C. The hearts were mountedon a Langendorff apparatus and rinsed for 2 min with a calcium-freesolution (solution A) containing (in mM): NaCl 132, KCl 4.8, MgCl₂1.2, HEPES 10, glucose 5, pH was adjusted to 7.35 with NaOH. Then,hearts were perfused with a low sodium-high potassium HEPES-bufferedsolution (solution B, in mM): NaCl 17, HEPES 10, KCl 5.4, K-glutamate128, MgCl₂ 1) for a period of 2 min. At the end of this period,perfusion of solution B containing collagenase (final concentration300 U/ml; Worthington Biochemical Corp., Freehold, NJ) and protease(0.7 U/ml; Sigma Chemical Co., St. Louis, MO) was started andcontinued until the system pressure dropped to 15 mm Hg (approximately15 min). Hearts were finally reperfused with a solution made of60% solution B and 40% solution A containing 0.5 mM CaCl₂. Atthis point, the ventricles were cut down and minced slightly toincrease cell yield. After filtration through 200-µm nylon mesh,the dispersed cells were washed by centrifugation (200 rpm, 2min), resuspended in solution A containing 1.8 mM CaCl₂ and maintainedat 30°C before use.

The normal Tyrode solution used to superfuse cells during recording of currents contained (in mM): NaCl 145, KCl 4, MgCl₂1, CaCl₂ 0.1, HEPES 10, glucose 5; pH was adjusted to 7.35 withNaOH. Either nisoldipine (Bayer Leverkusen) 0.2 µM or cadmium(Sigma) 0.1 mM were added to eliminate the slow inward calciumcurrent (I_Ca-L). Calcium was lowered to 0.1 mM in the extracellularsolution to reproduce experimental conditions generally used duringstudy of I_K, to avoid any I_Ca contamination and to prevent leakcurrent (Balser et al., 1990

). Effects of cadmium or nisoldipineon I_K were also assessed independently using a Tyrode solutioncontaining 1.8 mM CaCl₂ in the control and washout periods ofthese experiments. The pipette solution contained (in mM): MgCl₂2, CaCl₂ 1, EGTA 11, MgATP 5, K₂ATP 5, HEPES 10; pH was adjustedto 7.2 with KOH and final potassium concentration was fixed at130 mM with KCl.

Electrophysiological Measurements

A small aliquot of dissociated cells was placed in a 0.5-ml chamber mounted on the stage of an inverted microscope (modelCK2, Olympus, Lake Success, NY). Cells were allowed to adhereto the coverslip at the bottom of the chamber and then superfusedcontinuously with the external solution pre-warmed (30°C) by aPeltier device (Medical System Corp., Greenvale, NY). In our experiments,complete replacement of external solution contained in the chamberwas achieved within 2 to 3 min when the superfusion rate was 2ml/min.

All currents were recorded in the whole cell, voltage-clamp configuration of the patch-clamp technique using an Axopatch-1Damplifier (Axon Instruments Inc., Burlingame, CA). Voltage-clampcommand pulses were generated by a 12-bit digital-to-analog converter(model TL/1, Axon Instruments Inc.) controlled by the pClamp softwarepackage (version 4.05b; Axon Instruments Inc.). Heat-polishedpatch-clamp pipette electrodes used (capillary glass from Radnoti,Starbore glass capillary tubing 1.2 mm O.D.) had a tip resistanceof 3 to 5 M $Omega$ when filled with the pipette solution. Series resistancewas compensated 50 to 80% to improve fidelity of whole cell voltage-clampmeasurements.

Protocols

Rod-shape cells with clear cross striations, resting potential of at least $-$ 78 mV and stable I_K and I_K1 currents (as assessedduring a baseline period of at least 4 min) were used. Effectsof nisoldipine and cadmium on the I_Kr and I_Ks activating componentsof I_K were studied in cells held at $-$ 40 mV (to inactivate I_Na)and depolarized by pulses lasting either 250 msec (I_K250), 450msec (I_K450) or 5000 msec (I_K5000). Test potentials of depolarizingpulses varied between $-$ 20 and +50 mV. I_K was measured from thepeak magnitude of tail current obtained upon repolarization to $-$ 40 mV.

Data Storage and Analysis

Currents were filtered at either 2 KHz (I_K250 and I_K450 protocols) or 100 Hz (I_K5000 protocol) by a four-pole Bessel filter( $-$ 3 dB/octave). Currents were sampled at 4 KHz (I_K250 and I_K450)and 400 Hz (I_K5000) by use of a 12-bit analog-to-digital converter(TL-1 DMA, Axon Instruments) and stored on hard disk for subsequentanalysis. Data are presented as mean ± S.D. Statistically significantdifferences in I_K activating curves for I_K250 and I_K5000 in thepresence of cadmium and nisoldipine were compared by a Student'spaired t test. Best fit of data was established by comparisonof $chi$ ² analysis. Level of statistical significance was set at P < .05.

	Results

Top Abstract Introduction Methods Results Discussion References

Comparative effects of cadmium and nisoldipine on the delayed rectifier potassium current. Figure 1A illustrates outward currents elicited by a 5-sec pulse to various depolarizing potentials from a holding potentialof $-$ 40 mV. Deactivating currents (tails) were recorded on repolarizationto $-$ 40 mV. In these recordings, the same guinea pig ventricularmyocyte was perfused with a low-calcium (0.1 mM) Tyrode solutioncontaining either 0.1 mM cadmium (left panels) or nisoldipine0.2 µM (right panels). When nisoldipine replaced cadmium in theperfusate, I_K5000 activating and tail currents elicited by depolarizingsteps to voltages of more than 0 mV decreased although those elicitedby lower depolarizing voltages increased. Figure 1B illustratescurrent-voltage relationships observed during the experiment shownin figure 1A for the deactivating currents. At a test potentialof +50 mV, superfusion of the myocyte with the nisoldipine containingbuffer reduced I_K5000 tail current by 90 pA (27%). In contrast,at a test potential of $-$ 20 mV, I_K5000 tail current was increased25 pA (50%) by nisoldipine. A reversal of the effect was observedupon reperfusion of the myocyte with the cadmium containing buffersolution (fig. 1C).

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Fig. 1. A shows I_K activating currents elicited by 5-sec voltage tests between $-$ 10 and +50 mV and tail currents recorded followingrepolarization to $-$ 40 mV, during application of either 0.1 mMcadmium or 0.2 µM nisoldipine. B compares the current-voltagerelationship of I_K tail current amplitude obtained in the presenceof either 0.1 mM cadmium or 0.2 µM nisoldipine. Changes in I_Ktail amplitude caused by nisoldipine were fully reversible (C).

To appreciate intercell reproducibility in these effects, the I-V relationship between I_K tail current amplitudes and depolarizingvoltage steps was constructed from 9 cells exposed first to cadmiumand then to nisoldipine (fig. 2). In figure 2, tail currents amplitudeswere normalized for cell capacitance. After short depolarizingpulses (250 msec; fig. 2A) I_K tail current amplitude measuredin the presence of cadmium tended to be reduced for depolarizingpotential <0 mV but increased for depolarizing potentials >20mV compared to current amplitudes measured during superfusionof nisoldipine. Differences in I_K tail current amplitudes werestatistically significant at test voltages of $-$ 10, +40 and +50mV (P < .05). When stimulation lasted 5 sec (fig. 2B), a situationwhere outward current is largely I_Ks, a crossing over in the I-Vcurves was still observed although the crossing point was shiftfrom +20 to 0 mV compared to I_K250. A significant difference inI_K tail current amplitude was noticed at +20, +30, +40 and +50mV (P < .05).

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Fig. 2. Current-voltage relationship of I_K tail current obtained upon repolarization to $-$ 40 mV after test pulses of a duration ofeither 250 (A) or 5000 (B) msec. This relationship illustratesmean data of normalized current from 9 cells (* P < .05).

Kinetics of I_K5000 deactivating current were assessed in six cells using a biexponential curve fitting function. Table 1summarizes changes in the faster time constant ( $tau$ ₁) caused bythe exchange of cadmium by nisoldipine in the external bathingsolution. Superfusion with nisoldipine increased $tau$ ₁ by about 180%(P < .05) in a voltage-independent manner. On reperfusion withcadmium in the absence of nisoldipine (washout), $tau$ ₁ almost returnedto initial base-line values.

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TABLE 1
Changes in the fast time constant ( $tau$ ₁) of I_K5000 deactivating current induced by exposure of cells to cadmium or nisoldipine

Effects of cadmium on the delayed rectifier potassium current. In this series of experiments, control recordings were obtained during superfusion of cells with normal Tyrode solution (containing1.8 mM calcium). Test pulse duration was either 250 msec (I_K250),450 msec (I_K450) or 5000 msec (I_K5000). Under control conditions,a large inward L-type calcium current was elicited (fig. 3). Whenthe external solution was replaced by a solution containing cadmium0.1 mM (calcium concentration lowered to 0.1 mM to reproduce experimentalconditions used during study of I_K), the L-type calcium currentwas eliminated. However, the amplitude of I_K tail currents wasincreased for all pulse durations tested at +10 mV and for I_Ktail current elicited by 5 sec pulses to $-$ 10 mV (fig. 4). In contrast,the amplitudes of I_K tail current was reduced for the shorterpulses (i.e., 450 and 250 msec) after voltage steps to $-$ 10 mV.This effect was reproducibly observed in five cells tested (fig.4, A and B). Amplitudes of I_K250 and I_K5000 tail current normalizedby cell capacitance recorded after test pulses to voltages <0mV during cadmium tended to be decreased compared to control conditionsbut were increased for voltage pulses $>=$ +20 mV (P < .05).

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Fig. 3. Effects of cadmium on I_K were assessed after a control period during which cells were bathed in a normal Tyrode solution.I_K current was elicited by voltage pulses of three different durations(5000 msec $-$ I_K5000; 450 msec $-$ I_K450 and 250 msec $-$ I_K250) attwo voltage levels ( $-$ 10 and +10 mV). In control conditions, testpulses elicited large inward calcium currents that activated andinactivated during I_K activation. However, this current was totallyeliminated by 0.1 mM cadmium.

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Fig. 4. Current-voltage relationship of I_K tail current observed in five cells tested in the presence or absence of 0.1 mM cadmium(* P < .05). Current was normalized for cell capacitance and obtainedon repolarization to $-$ 40 mV after 250- (A) or 5000- (B) msec depolarizingpulse durations.

Table 2 summarizes changes in the fast time constant ( $tau$ ₁) of I_K5000 tail current induced by cadmium 0.1 mM. Superfusion withcadmium decreased $tau$ ₁ by $approx$ 30% (P < .05) compared to values determinedin the presence of calcium 1.8 mM. This decrease was voltage-independent.Values of $tau$ ₁ returned toward base-line values on removal of cadmiumand reperfusion of cells with the normal Tyrode solution (containing1.8 mM calcium).

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TABLE 2
Changes in the fast time constant ( $tau$ ₁) of I_K5000 deactivating current indced by cadmium

Specific effects of cadmium on I_Kr and I_Ks were assessed using the specific I_Kr blocker E-4031. When 5 µM E-4031 was introducedin the extracellular solution, only I_Ks was present in the delayedrectifier. As in the previous experiments presented in figures1, 2, 3, 4, addition of cadmium to the control solution inducedan increase in I_K amplitude at high voltages. These results werereproducible in three cells tested. Moreover, cadmium 0.1 mM modifiedthe I-V curve at low voltages tested (fig. 5) inducing a positiveshift of about +5 mV in I_K activation. Fast time constant of deactivationof I_K estimated in the presence of E-4031 was 310 ± 35 msec and302 ± 38 msec after test pulses to +40 and +20 mV, respectively.Cadmium had no significant effects on $tau$ ₁ measured under the sameconditions (i.e., 333 ± 37 msec at +40 mV and 326 ± 45 msec at+20 mV, respectively).

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Fig. 5. Recordings of membrane currents obtained in cells previously exposed to E-4031 (5 µM) to eliminate I_Kr. Currents were elicitedby 5000-millisecond depolarizing steps from $-$ 10 to +50 mV followedby repolarization to $-$ 30 mV. Recordings were obtained in the presenceof a low calcium concentration (0.1 mM) at baseline (A) and duringsuperfusion with 0.1 mM cadmium (B). Dashed arrows indicate zerocurrent. To better discriminate between I_Ca inactivating and I_Ksactivating currents, time-independent background current was subtractedfrom all recordings except for the activating current elicitedby a test pulse to $-$ 10 mV. Plot of current-voltage relation ofI_K tail current measured after long pulses (5000 msec) to varioustest potentials at baseline ( $open circle$ ) and in the presence of 0.1 mMcadmium ( $bullet$ ) is illustrated in C.

Another series of experiments were designed to determine the concentration-dependence of cadmium effects on I_K. Figure 6 showsa typical example of I_K I-V curves obtained when cadmium concentrationwas increased sequentially from 20 to 100 µM and from 100 to 500µM in the same cell. The increase in current amplitude elicitedby +50 mV voltage tests was dependent on cadmium concentrationin the range of the concentrations tested. Similar results wereobserved in four cells tested. In contrast, decrease in I_K observedat lower depolarizing potentials was almost unaffected by increasingconcentration of cadmium of more than 20 µM.

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Fig. 6. Concentration-dependent effect of cadmium on the current-voltage relationship of I_K tail current recorded after 5-sec testpulses to stepwise increased potentials. Effects of three concentrationsof cadmium, i.e., 20 µM (filled circles), 100 µM (open circles)and 500 µM (squares) on the same cell are presented.

Effects of nisoldipine on the delayed rectifier potassium current. Effects of nisoldipine 0.2 µM on I_K were determined and compared to recordings obtained using a normal Tyrode solution (containing1.8 mM calcium) as the external solution. Traces in figure 7Ashow that this concentration of nisoldipine entirely blocks I_Ca-Lbut does not alter amplitude of I_K250 tail current. As well nochanges were observed on I_K activating and tail currents duringlong pulses (5000 msec; fig. 7B). These effects were reproducedin five cells tested (fig. 8, A and B). Finally, no significantchanges in I_K5000 deactivating constant ( $tau$ ₁) were observed bythe superfusion of cells with nisoldipine 0.2 µM (table 3).

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Fig. 7. I_K activating and tail currents elicited by pulse protocols that allow discrimination between effects on the rapid and slowcomponents of I_K are shown in control conditions (superfusionof a normal Tyrode solution containing 1.8 mM calcium) and inthe presence of 0.2 µM nisoldipine. In A, cell potential was clampedat 0 mV during 250 msec and then at $-$ 40 mV to deactivate I_K, conditionsthat favor the presence of the rapid component of I_K. I_si wassuppressed during superfusion of nisoldipine but I_K tail was keptunchanged by the drug. Also, nisoldipine did not modified I_K inconditions that favor the presence of the slow component of I_K(5-sec test pulse to +50 mV) (B). In this case, no inward currentwas observed because the voltage of +50 mV is near or more thanthe reversal potential of I_si.

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Fig. 8. Current-voltage relationship of I_K tail current observed in five cells tested in the presence or absence of 0.2 µM nisoldipine.Current was normalized for cell capacitance and obtained uponrepolarization to $-$ 40 mV following 250- (A) or 5000- (B) msecdepolarizing pulse durations.

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TABLE 3
Changes in the fast time constant ( $tau$ ₁) of I_K5000 deactivating current induced by nisoldipine

	Discussion

Top Abstract Introduction Methods Results Discussion References

Our experiments examined the effects of cadmium and nisoldipine on the two components of I_K, namely I_Kr and I_Ks. Studies wereconducted at concentrations of cadmium and nisoldipine usuallyused to block I_Ca-L in experiments designed to characterize modulationof I_K (Arena and Kass, 1988; Balser et al., 1990; Sanguinettiand Jurkiewicz, 1990a; Daleau and Turgeon, 1994). Our findingshave shown a decrease in I_K amplitude at low voltage steps whichis consistent with an induction of a shift in I_Kr activation previouslyreported (Follmer et al., 1992). In addition, our results alsoprovide evidence that the inorganic calcium channel blocker cadmiumalso shifts to positive voltages the activation curve of I_Ks andincreases its amplitude. However, the organic dihydropyridinederivative calcium channel antagonist nisoldipine, had no effectson I_K activation curve and had minimal effects on deactivationkinetics. These results suggest that nisoldipine is a better toolthan cadmium for use in study of I_K.

I_K recorded from guinea pig ventricular myocytes in the presence of 0.1 mM cadmium was decreased when elicited by voltagesteps $<=$ 0 mV but increased when elicited by voltage steps $>=$ 20mV compared to I_K obtained in the presence of nisoldipine or a1.8 mM CaCl₂-containing Tyrode solution. Also, with E-4031 inthe extracellular solution, cadmium increased I_K amplitude elicitedat high voltage tested and positively shifts the I-V curve atlow voltages. From these experiments, we cannot discriminate betweena positive shift in I_Kr activation or a reduction in I_Kr amplitude.However, it has been described in cat ventricular myocytes, whereI_K is mainly due to I_Kr, that cadmium added directly to the bathsolution containing 3 µM nitrendipine, decreased I_K at low depolarizingpotentials but increased peak I_K tail current and shifted thevoltage dependence of activation to more positive potentials byabout 15 mV (Follmer et al., 1992). On the basis of our resultsand the results of Follmer et al. (1992), we propose that cadmiumshifts toward positive potentials I_Kr and I_Ks I-V curves and increasesI_Ks amplitude elicited at voltages $>=$ +20 mV.

In contrast, experiments conducted with nisoldipine were not associated with alteration in I_K characteristics which confirmsprevious results (Kass, 1982) obtained in Purkinje fibers with10 µM nisoldipine (i.e., 50 times the concentration usually usedto block I_Ca). From these experiments, we concluded that cadmiumis almost exclusively responsible for the difference observedin I_K characteristics recorded in the presence of either cadmiumor nisoldipine. In guinea pig ventricular myocytes, lanthanum,an inorganic calcium current blocker, blocks I_Kr and shifts positivelythe voltage dependency of I_Ks activation curve (Sanguinetti andJurkiewicz, 1990b). Cobalt, another inorganic salt, alters I_Kproperties similar to lanthanum, with a more pronounced reductionof I_K at negative potentials and a positive shift of I_K I-V curvein the whole voltage range of I_Ks activation (Fan and Hiraoka,1991).

Deactivation kinetics of I_K were faster in the presence of cadmium compared to nisoldipine. Recordings obtained showed thatthe fast time constant ( $tau$ ₁) of I_K deactivation was increased byabout 180% when 0.1 mM cadmium was replaced by 0.2 µM nisoldipine.This effect was voltage independent. However, when cadmium wasadded to a normal Tyrode solution, $tau$ ₁ was decreased to 65 to 70%of control value, consistent with the increase of $tau$ ₁ observedwhen cadmium was replaced by nisoldipine in the bath solution.In contrast, no changes in $tau$ ₁ were observed when nisoldipine wasadded to a normal Tyrode solution. Modification in the kineticsof I_K produced by cadmium suggests a direct interaction of thecompound with negatively charged gating particles. Follmer etal. (1992) also observed a faster decay of I_K tail currents inthe presence of cadmium in cat ventricular myocytes. In contrast,such an effect was absent in frog heart cells (Duchatelle-Gourdonet al., 1989). In our experiments, cadmium had minimum effectson the fast time constant of deactivation in the presence of E-4031which is consistent with a predominant effect on I_Kr deactivationkinetics.

Finally we have assessed effects of different concentrations of cadmium on I_K, i.e., 20, 100 and 500 µM (fig. 6). Changesin I_K amplitude observed at lower depolarizing potentials werealmost unaffected by cadmium concentration of more than 20 µMalthough increase in I_K observed at positive depolarizing potentialsremains concentration dependent.

In conclusion, we have shown that cadmium shifts the activation curve and increases the amplitude of the slow component ofthe delayed rectifier potassium current in guinea pig ventricularmyocytes. These effects are complementary to the previously demonstratedshift in I_Kr I-V curve caused by cadmium. These effects were observedat a concentration that overlaps with its effects on the L-typecalcium current. Therefore, these effects must be considered inthe interpretation of I_K-modulation studies where this cationis present. However, nisoldipine seems to be a more powerful andspecific tool, at a concentration aimed to fully inhibit I_Ca inI_K studies.

	Acknowledgments

The authors thank Michel Blouin and Carolle Bergeron for technical assistance.

	Footnotes

Accepted for publication January 22, 1997.

Received for publication September 18, 1996.

¹ This work was supported by grants from the Medical Research Council of Canada (MT12883 and MT11876) and by an operating grantfrom the Heart and Stroke Foundation of Canada.

² Recipient of a scholarship from the Fonds de la Recherche en Santé du Québec (950122-103).

³ Recipient of a studentship from the Corporation de l'Institut de Cardiologie de Québec.

⁴ Recipient of a scholarship from the Joseph C. Edwards Foundation.

Send reprint requests to: Dr. Pascal Daleau, Quebec Heart Institute, Research Center, Laval Hospital, 2725 chemin Ste-Foy, Ste-Foy, Quebec, CANADA, G1V 4G5.

	Abbreviations

I_K, delayed rectifier potassium current; I_K250, delayed rectifier elicited by 250 msec depolarizing voltage steps; I_K450, delayed rectifier elicited by 450 msec depolarizing voltage steps; I_K5000, delayed rectifier elicited by 5000 msec depolarizing voltage steps; V_test, voltage steps; I_Ca or I_si, slow inward calcium current; I_Ca-L, long lasting inward calcium current; I_Kr, rapid component of the delayed rectifier; I_Ks, slow component of the delayed rectifier; I_K1, inward rectifier potassium current; I_Na, outward sodium current; I-V, current-voltage relationship.

	References

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