Characterization of Nifedipine Block of the Human Heart Delayed Rectifier, hKv1.5

Assistant Professor of Medicine (Clinician-Educator)

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Vol. 281, Issue 3, 1247-1256, 1997

Characterization of Nifedipine Block of the Human Heart Delayed Rectifier, hKv1.5¹

Xue Zhang, James W. Anderson and David Fedida

Department of Physiology, Botterell Hall, Queen's University, Kingston, Ontario, Canada

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

Nifedipine antagonizes L-type Ca⁺⁺ channels found throughout the cardiovascular system, but also blocks Kv channels, which aremembers of the same supergene family. We have examined nifedipineactions on the human heart K⁺ channel (hKv1.5) expressed in human embryonic kidney cells. Peakand steady-state currents on depolarization were reduced by nifedipinewith K_d values of 18.6 ± 2.7 and 6.3 ± 0.5 µM respectively at+40 mV, and with Hill coefficients of 0.75 ± 0.04 and 0.93 ± 0.03.Block increased rapidly between -10 mV and +10 mV, coincidentwith channel opening and suggested an open channel block mechanism,which was confirmed by tail current crossover on repolarization(unblock on channel closing). At more positive potentials than+20 mV, block was relieved. The time constants ( $tau$ ₂) for nifedipineblock of hKv1.5 were concentration and voltage dependent. At +40mV, $tau$ ₂ was 16.7 ± 0.8 (10 µM), and 4.8 ± 0.6 msec (50 µM), (n= 4-8). Using a first order kinetic analysis, apparent bindingconstants were 5.64 × 10⁶ M¹ s¹ (k₊₁, on-rate) and 37.5 s¹ (k₁, off-rate), with a K_d of 6.65 µM, close to that obtainedfrom the dose-response curve. An increase in the off-rate (k₁)could explain relief of block >+20 mV. The rank order of blockunder different patch configurations was whole-cell $approx$ outside-out> inside-out $>>$ cell-attached macropatches. Together, these suggesteda binding site for nifedipine at the extracellular pore of hKv1.5or at a hydrophobic channel domain within the lipid bilayer ata site that is more accessible from the extracellular side.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

Nifedipine is a Ca⁺⁺ channel antagonist widely used for the treatment of a variety of cardiovascular disorders. Normally, nifedipineblocks voltage-gated calcium channels with a high affinity (K_d= 310 nM in rabbit right atrium, Mecca and Love, 1992; and 200nM in myocardium, Charnet et al., 1987). However, voltage-dependentK⁺ channels belong to the same supergene family as Ca⁺⁺ and Na⁺ channels (Catterall, 1988; Jan and Jan, 1989), with areas ofhomology in the pore and around the carboxyl terminal of S6 inCa⁺⁺ and K⁺ channels (Rampe et al., 1993; Nakayama et al., 1991), and itis known that three types of Ca⁺⁺ antagonists, verapamil, nifedipine and diltiazem, all block clonedK⁺ channels (Rampe et al., 1993; Grissmer et al., 1994). Verapamiland nifedipine produced a marked block of the transient outwardcurrent, I_to in rat ventricular myocytes (Jahnel et al., 1994).Because I_to may contain multiple components of rapidly inactivatingand slowly inactivating K⁺ channels, it is unclear which specific Kv channel or channelsmay be blocked.

One component of I_to may be the rapidly activating delayed rectifier K⁺ channel, hKv1.5 (Van Wagoner et al., 1996), cloned from humanheart (Tamkun et al., 1991; Fedida et al., 1993), which is importantin determining the duration of the plateau phase of the cardiacaction potential. Data exist showing that hKv1.5 is blocked byall three types of Ca⁺⁺ antagonists. Verapamil block of hKv1.5 was described in detail(Rampe et al., 1993) and a mechanism of open channel block fromthe inner pore was suggested. Diltiazem and nifedipine (Grissmeret al., 1994) have also been shown to block hKv1.5, but the detailedcharacteristics of nifedipine's effects on hKv1.5 have not beenstudied. Our study was undertaken to examine the effects of nifedipineon hKv1.5 and to explore its mechanisms of action. Our data suggestedthat nifedipine was an open channel blocker, which acted predominantlyat the external pore of hKv1.5 channels. The effects of nifedipinewere concentration and voltage dependent, but the block was somewhatrelieved at more positive potentials. This effect is in contrastto the block of hKv1.5 by verapamil (Rampe et al., 1993), theinhibition of native K⁺ channels by nifedipine (Jacobs and DeCoursey, 1990) or D600 andrelated phenylalkylamines (DeCoursey, 1995), and the block ofCa⁺⁺ channels by organic Ca⁺⁺ channel antagonists (Sanguinetti and Kass, 1984; Hume, 1985;Uehara and Hume, 1985), where block increased with potential.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Cell culture. The methods used to establish stable HEK cell lines expressing the hKv1.5 K⁺ channel and those used for electrophysiological measurement ofhKv1.5 currents have been described in detail previously (Fedidaet al., 1993). Alternatively, hKv1.5 was transiently transfectedinto HEK cells using the mammalian expression vector pRc/CMV.Cells expressing hKv1.5 were detected by cotransfecting cellswith the vector pHook-1 (Invitrogen, San Diego, CA). This plasmidencoded the production of an antibody to the hapten phOX, whichwhen expressed is displayed on the cell surface. Transfected cellswere maintained in modified Eagle's medium at 37°C in an air/5%CO₂ incubator in 25-mm Petri dishes plated on glass coverslipsuntil use. One hour before experiments, cells were treated withbeads coated with phOX. After 5 min, excess beads were washedoff with cell culture medium and cells which had beads stuck tothem were used for electrophysiological tests. The efficiencyof dual transfection was observed to be better than 80%, so thebeads provided a good means of identifying those cells that expressedhKv1.5. No difference was observed from data obtained using stablecell lines or transient expression of hKv1.5, so all results havebeen included in the analysis.

Solutions. For W/C and O/O macropatches, the control pipette filling solution contained (in mM): KCl, 130; EGTA, 5; MgCl₂, 1; HEPES,10; Na₂ATP, 4; GTP, 0.1; and was adjusted to pH 7.2 with KOH.The control bath solution contained (in mM): NaCl, 135; KCl, 5;sodium acetate, 2.8; MgCl₂, 1; HEPES, 10; CaCl₂, 1; and was adjustedto pH 7.4 with NaOH. For C/A and I/O macropatches, the pipettefilling solution was the extracellular control solution used inW/C recording, and the bath solution was a 135 mM K⁺ solution designed to zero the membrane potential (in C/A recording).It contained (in mM): KCl, 135; HEPES, 10; MgCl₂, 1; dextrose,10; and was adjusted to pH 7.4 with KOH. For gating current experiments,cells were superfused with a solution containing (in mM): NMG,140; HEPES, 10; CaCl₂, 1; MgCl₂, 1; dextrose, 10; pH 7.4 withHCl. The pipette solution contained (in mM): NMG, 140; HEPES,10; MgCl₂, 1; EGTA, 10; pH 7.2 using HCl. Nifedipine was dissolvedin alcohol at a stock concentration of 1, 10 or 100 mM, and wasprotected from the light during all experiments. After controldata were collected, the bathing solution was changed to includenifedipine. Nifedipine effects were very rapid on cells, apparentlyreaching a steady-state within three pulses (30 sec). Steady-statemeasurements made in the presence of nifedipine were obtainedafter at least 3 min exposure to the drug. All chemicals werefrom Sigma Chemical Co. (St. Louis, MO).

Electrophysiological procedures. Coverslips containing cells were removed from the incubator before experiments and placed in a superfusion chamber (volume250 µl) containing the control bath solution at 22 to 23°C. W/C,C/A, O/O and I/O macropatch recordings were made via the variationsof the patch-clamp technique (Hamill et al., 1981), using an Axopatch200A amplifier (Axon Instruments, Foster City, CA). Patch electrodeswere pulled from thin-walled borosilicate glass (World PrecisionInstruments, Sarasota, FL) on a horizontal micropipette puller,fire-polished, and filled with appropriate solutions. Electrodeshad resistances of 1.5 to 3.0 m $Omega$ when filled with control fillingsolution. Analog capacity compensation and 75 to 85% series resistancecompensation were used in all W/C measurements. In some experiments,leak subtraction was applied to data. Membrane potentials havebeen corrected, where appropriate, for junctional potentials thatarose between the pipette and bath solution. Data were filteredat 5 to 10 kHz before digitization and stored on a microcomputerfor later analysis using the pClamp6 software (Axon Instruments).In experiments where gating currents were recorded, the samplerate was 330 kHz and currents were usually leak-subtracted usinga P/6 protocol similar to that described previously (Stühmeret al., 1991; McCormack et al., 1994; Bouchard and Fedida, 1995).Currents were low-pass filtered at 10 to 50 kHz during data collectionor later at 10 kHz for data presentation. Pipettes were routinelysylgarded and fire polished to reduce electrode capacitance andimprove seal resistance. The system that we used for expressionof hKv1.5 conferred certain advantages for the measurement ofgating current. Due to the high level of expression of hKv1.5channels in HEK cells, there was no need for signal averaging,and single gating current transients could be observed. The averagecell capacitance was quite small, and the absence of ionic currentat negative membrane potentials allowed faithful leak subtractionof data.

Data analysis. The concentration-response curve (figs. 2C and 7B) for changes in peak and steady-state current produced by nifedipine werecomputer-fitted to the Hill equation:

f<IT>=1/</IT>[<IT>1+</IT>(Kd/[D]n)] (1)

where f is the fractional current block (f = 1-I_drug/I_control) at drug concentration [D]; K_d is the concentration producinghalf-maximal inhibition and n is the Hill coefficient. The rapidcomponent of inactivation induced by nifedipine was much fasterthan that observed in the absence of drug. Therefore, we usedthis drug induced time-constant ( $tau$ ₂) as an approximation of thedrug channel interaction kinetics, as described previously (Snyderset al., 1992; Slawsky and Castle, 1994), according to the equations:

1/&tgr;2=k+1[D] + k−1 (2a)

and

Kd<IT>=</IT>k−1/k+1 (2b)

in which $tau$ ₂ is the current decay time constant caused by the drug; [D] is the concentration of drug; k₊₁ and k₁are the apparent rate constants of binding and unbinding for thedrug, respectively.

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Fig. 2. Concentration-dependent block of hKv1.5 by nifedipine. A and B, W/C current recording during voltage pulses to +40 mV fromthe holding potential of -80 mV. Currents were recorded in thesteady-state at a large range of nifedipine concentrations. Currenttraces in A and B were from two different cells. The cell in Awas exposed to low concentrations of nifedipine from 0.2 to 10µM and the cell in B was exposed to high concentrations of nifedipinefrom 20 to 200 µM. C: Dose-response curve for nifedipine blockof hKv1.5. Peak and steady-state reduction of current (relativeto control) at a test potential of +40 mV was plotted againstthe concentration of nifedipine. Data were averaged from 4 to10 experiments. Solid lines were fit to the data using a Hillequation (see "Materials and Methods," equation 1). For the reductionof peak current, the K_d value was 18.6 ± 2.7 µM, Hill coefficientwas 0.75 ± 0.04; for the reduction of steady-state current, theK_d value was 6.3 ± 0.5 µM, and the Hill coefficient was 0.93 ±0.03.

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Fig. 7. Comparison of nifedipine-induced block of hKv1.5 in different recording configurations. A, For O/O macropatch (left panel),current traces were elicited from the holding potential of -80mV during a 400-msec pulse to the test potential of +40 mV. Forthe C/A macropatch (right panel), traces were obtained from theholding potential of +80 mV to a pipette test potential of -40mV in a 200-msec pulse. Traces shown were from two different cellsin which currents were recorded in the absence and presence of10 and 100 µM nifedipine. Note that nifedipine actions on hKv1.5were stable after only two or three pulses after nifedipine waswashed into the bath. However, all steady-state data shown here,and in B were obtained after more than 3 min exposure to nifedipine.B, The relative steady-state currents (I_nif/I_ctl) in the presenceof different concentrations of nifedipine have been obtained fromfour modes of patch clamp recording. These were C/A ( $bullet$ ), I/O ( $open circle$ )and O/O ( $black-down-triangle$ ) macropatches, and W/C ( $down-triangle$ ) recording. Current wereobtained during the same voltage protocol as illustrated in A.Solid lines were the best fits to the data using Hill equation(see "Materials and Methods," equation 1). For the data from C/A,I/O, O/O macropatches and W/C recording, the resultant K_d were47.3 ± 10.1, 7.5 ± 1.5, 6.9 ± 1.0, 6.7 ± 0.6 µM and Hill coefficientswere 0.88 ± 0.05, 0.70 ± 0.06, 0.90 ± 0.06, 0.95 ± 0.04, respectively.Data were means ± S.E. from three to seven experiments. The asteriskrepresents a statistically significant (P < .05) difference betweenthe C/A or I/O macropatch data and O/O macropatch or W/C data.

The voltage dependence of block for the uncharged drug was determined as follows: leak-corrected current in the presence ofdrug was normalized to matching control at each voltage above-20 mV. Using data points in the range of full channel opening(>+20 mV), the voltage dependence of block was fitted to a linearequation, and the slope of block determined. Alternatively, in"Discussion," we have calculated the fractional block (f = 1-I_nif/I_control)at each potential and fitted data to the Woodhull equation:

f<IT>=</IT>[D]/([D]<IT>+</IT>K<SUP>*</SUP><SUB>d</SUB><IT> · </IT>e<SUP>−&dgr;zFE/RT</SUP>)

(3)

where F, R, z and T have their usual meanings, $delta$ represents the fractional electrical distance, i.e., the fraction of thetransmembrane electrical field sensed by a single charge at thereceptor site. K^*_d represents the binding affinity at the reference voltage (0mV).

Experimental values are given as means ± S.E.. Analysis of variance was used to compare the effects of nifedipine on hKv1.5currents under different macropatch configurations; Paired t testwas used to compare the amplitudes of off-gating charge in thepresence of nifedipine with control. A value of P < .05 was consideredstatistically significant.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Concentration-dependent and reversible block. The data in Figure 1 show the effects of nifedipine on hKv1.5 currents expressed in HEK cells under W/C recording conditions.The cell was held at -80 mV, and membrane currents were elicitedbefore exposure to nifedipine, during exposure to 10 µM and 50µM nifedipine and after wash out. These are currents in responseto a series of step depolarizing pulses from -30 mV to +40 mV.Extracellular application of 10 µM and 50 µM nifedipine resultedin a reduction of both peak and steady-state hKv1.5 currents witha marked increase in the rate of outward current relaxation inthe presence of nifedipine (Fig. 1B, 1C). This meant that steady-statecurrents recorded at the end of 250 ms pulses, were much morereduced by nifedipine than the peak currents, in a concentration-dependentmanner. After 5 min wash out to control bath solution, the effectof nifedipine was largely reversed. Figure 1D showed that thecurrent was restored to 85% of control current level. Current-voltage(I-V) relationships for the peak and steady-state outward currentin the absence, presence of 10 and 50 µM and washout of nifedipineare shown in Figure 1E and F. Here it can be seen that both peakand steady-state current were reduced in a concentration-dependentmanner, but that the reduction of steady-state current was muchmore than that of peak current. Native HEK cells also possessa small outwardly rectifying K⁺ current. The mean amplitude of this current was 204 ± 19.7 pAat +40 mV (n = 10), which is less than 2% of the total currentin transfected cells on depolarization (compare control hKv1.5current amplitudes in figs. 1E and 2). Nifedipine also reducedthis current, with 50% block at >20 µM (n = 3). However, due tothe small current size, we have not considered contamination bythis endogenous current to be significant.

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Fig. 1. Nifedipine block of hKv1.5 current. A to D, Currents were elicited by 250-msec depolarizing pulses from the holding potentialof -80 mV to voltages between -30 mV and +40 mV in incrementsof +10 mV. W/C currents were recorded in the absence of nifedipine(A) and the presence of 10 µM (B), 50 µM (C) and after 5 min washout (D) nifedipine, respectively. E and F, Current-voltage (I-V)relationships for peak and steady-state outward current in theabsence ( $bullet$ ) and presence of 10 ( $down-triangle$ ), 50 ( $black-down-triangle$ )µM and wash out ( $square$ )of nifedipine are shown in E and F, respectively. The dotted linemarks the zero current level. Data were from the same cell aspanels A to D. Note that after exposure to high concentrationsof nifedipine, wash out was often incomplete as in D.

The effects of nifedipine on hKv1.5 over a wide range of concentrations from 0.2 to 200 µM, further confirmed that the blockwas concentration-dependent (fig. 2). Low concentrations of nifedipine(between 0.2 and 10 µM) are shown in figure 2A. The thresholdfor nifedipine action on hKv1.5 was around 100 to 200 nM, whichwas somewhat lower than expected for dihydropyridine block ofhKv1.5 (cf., Grissmer et al., 1994

). At low concentrations, upto $approx$ 1 µM, there was little effect on peak outward current, butnifedipine induced a slow decay of current that reached a steady-stateat the end of 1 sec depolarizing voltage clamp pulses. At higherconcentrations than 1 µM, a reduction of peak current was observedand a more rapid decay of current to the steady-state. At highconcentrations of nifedipine a marked reduction of peak currentwas observed (fig. 2B) with rapid current decay to the steadystate. The concentration response curve for block of peak andsteady-state outward current by nifedipine at a test potentialof +40 mV is shown in figure 2C. As expected from data in figures1 and 2, steady-state currents ( $open circle$ ) showed a greater level of blockat any particular nifedipine concentration than peak currents( $bullet$ ). The solid lines were fit to the data using the Hill equation(see "Materials and Methods," equation 1). The resultant K_d valuesfor the peak and steady state hKv1.5 current block by nifedipinewere 18.6 ± 2.7 and 6.3 ± 0.5 µM, the Hill coefficients were 0.75± 0.04 and 0.93 ± 0.03, respectively.

Voltage-dependent block. To examine the voltage-dependence of block, the relative steady-state current I_nif/I_ctl at the end of 400 msec voltage clamppulses was plotted as a function of potential. The data in figure3 show normalized hKv1.5 current-voltage(I-V) relationships fordifferent concentrations of nifedipine. The dotted line is thenormal activation curve of hKv1.5. This was obtained from thedeactivating tail current amplitude at -20 mV after 15 msec depolarizingsteps to potentials between -80 to +100 mV from a holding potentialof -100 mV. In the presence of 5, 10, 20 and 50 µM nifedipine,block increased rapidly between -10 and +10 mV, coinciding withthe voltage range of channel opening. These data suggest thatnifedipine binds primarily to the open state of hKv1.5 channels.Over the voltage range between +20 and +90 mV, almost all channelsare open, but block was slightly relieved with depolarizing testpotentials and showed a shallow voltage dependence. At differentconcentrations of nifedipine, block at +90 mV compared with +20mV was reduced from 0.50 ± 0.01 to 0.40 ± 0.03 (5 µM), from 0.57± 0.04 to 0.49 ± 0.06 (10 µM), from 0.70 ± 0.05 to 0.60 ± 0.05(20 µM), and from 0.89 ± 0.02 to 0.84 ± 0.02 (50 µM); (n = 4-6).Over the potential range where channels were fully open, the relationshipfor block by nifedipine at depolarizing voltages was well fittedto a linear equation. The slopes of fit were 1.53 × 10³, 1.16 × 10³, 1.38 × 10³ and 7.35 × 10⁴ mV¹ with 5, 10, 20 and 50 µM nifedipine, respectively.

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Fig. 3. Voltage-dependence of current block by nifedipine. The dotted line represents the activation curve of control hKv1.5. Thiswas obtained from deactivating tail current amplitude at -20 mVafter 15-msec depolarizing steps to potentials between -80 to+100 mV, from a holding potential of -100 mV. The symbols denoteratios of steady-state current in nifedipine to the control currentvalue at each potential. Open symbols show the data between -10and +10 mV. Filled symbols show the data at voltages positiveto +20 mV. The solid lines were the best fit to a linear functionin the form of y = ax + b. With 5, 10, 20 and 50 µM nifedipine,the slopes from this linear fit were 1.53 × 10³, 1.16 × 10³, 1.38 × 10³ and 7.35 × 10⁴ mV¹. Data were mean ± S.E. from 4 to 10 experiments.

Nifedipine has a low pKa $<=$ 1.0 (Uehara and Hume, 1985

), so almost all of the drug is uncharged in the physiological pH rangearound 7.4. In this situation a voltage-dependence to the drugaction (once all channels are open) was not expected. The voltagedependence was not consistent with a positively charged drug actingat the intracellular mouth of the channel. One would expect increasedblock with potential as has been shown for the action of quinidine(Snyders et al., 1992

; Fedida, 1997

), quinine or tetrapentylammoniumions (Snyders and Yeola, 1995

) on hKv1.5. However, if drug bindingwas coupled in some way to a charged process, like K⁺ flux, and if the drug had an extracellular site of action, theresults would be consistent with a relief of block with intracellulardepolarization. This point is developed further in "Discussion."

Effects of nifedipine on current decay of hKv1.5. In the absence of nifedipine, current decayed slowly (fig. 2, A and B) and during the relatively short voltage pulses usedhere, was fitted to a single exponential function with a decaytime constant of 230 ± 8 msec (n = 14) at +40 mV. After additionof nifedipine, the rate of current decay increased in a concentration-dependentmanner (fig. 2, A and B) and could be well fitted with a doubleexponential function. The nifedipine-induced fast time constant, $tau$ ₂, was used as an index of the rate of block of hKv1.5. Figure4A shows the effects of different concentrations of nifedipineand different voltages on the mean $tau$ ₂ values. At each voltage, $tau$ ₂ decreased in a concentration-dependent manner, which indicateda more rapid current decay. At each concentration of nifedipine, $tau$ ₂ became faster at voltages between 0 and +30 mV, then $tau$ ₂ showeda shallow decrease at more positive potentials.

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Fig. 4. Time constants of hKv1.5 current decay in the presence of nifedipine. A, Voltage-dependence of hKv1.5 current decay in differentconcentrations of nifedipine. In the presence of nifedipine, $tau$ ₂was the fast component obtained from biexponential fits to thefalling phase of the currents obtained during 250-msec voltagesteps to between 0 and +90 mV from the holding potential -80 mV.Data were mean ± S.E. from 4 to 10 experiments. B, Kinetics ofnifedipine block of hKv1.5. The reciprocal of the nifedipine-inducedfast time constant (1/ $tau$ ₂) at +40 mV has been plotted against thenifedipine concentration. The best fit to the data (solid line)using the equation 1/ $tau$ ₂=k₊₁. [D] + k₁ resulted inan apparent association rate constant (k₊₁) of 5.64 × 10⁶ M¹ sec¹ and an apparent dissociation rate constant (k₁) of 37.5sec¹. The K_d value (k₁/k₊₁) was 6.65 µM. Error bars, S.E.from four to six experiments.

The rapid component of inactivation induced by nifedipine ( $tau$ ₂, fig. 4A, 5-50 µM) was much faster (approximately 10-fold ormore) than the slow component observed in the absence of drug.Therefore, $tau$ ₂ was used as an approximation of the time courseof drug-channel interaction, as described previously (Snyderset al., 1992

). Figure 4B shows the plot of 1/ $tau$ ₂vs. the concentrationof nifedipine at a test potential of +40 mV. From equation 2a (see"Materials and Methods"), the best least squares fit to the dataresulted in an apparent association rate constant, k₊₁ of5.64 × 10⁶ M¹ sec¹ and an apparent dissociation rate constant, k₁ of 37.5sec¹. The resultant K_d value from equation 2b (see "Materials and Methods")was 6.65 µM, which is consistent with the K_d value of 6.3 µM fromthe dose-response curve (fig. 2B).

Open or closed channel block? Two methods are often used to decide whether drugs predominantly interact with open or closed channels. For open channel blockersthat have a slow block rate and that dissociate from closed channels,currents peak in the presence of drug at a constant level, beforea rapid decay occurs with drug-channel interaction. Such an effectis seen when K⁺ channels are exposed to 4-aminopyridine for the first time (Choquetand Korn, 1992; Bouchard and Fedida, 1995). As a result, an accelerationof current inactivation is generally inferred to mean open-channelbinding (Slawsky and Castle, 1994). However, if the peak currentis reduced due to rapid drug-channel interaction, as for tetrapentylammoniumblock of hKv1.5 (Snyders and Yeola, 1995) or in our experimentswith nifedipine, it can be more difficult to exclude a restingchannel block. One method to analyze the onset of block is tofit the fractional block of current back to the start of the depolarizingpulse (Slawsky and Castle, 1994). If the fit intersects zero blockafter the start of the pulse, a purely open channel block mechanismis favored.

The time course for the development of inhibition by nifedipine is shown in figure 5. The drug-sensitive current expressedas a proportion of the outward current observed in the absenceof the drug ((I_ctl-I_nif)/I_ctl) has been plotted as a functionof time after the start of depolarization (at t = 0 msec). Inhibitionincreased in an exponential manner with time and it can be seenthat both the maximum inhibition and the rate of development ofthis inhibition were concentration dependent. The voltage pulsewas applied at 0 msec and the exponential onset of current blockalways occurred after this time. The mean times of onset of currentblock after application of the depolarizing clamp pulse were 3.33± 0.18, 2.80 ± 0.14, 1.56 ± 0.19, 1.09 ± 0.25, 0.65 ± 0.35 and0.42 ± 0.30 msec with 5, 10, 20, 50, 100 and 200 µM nifedipine(n = 3-5). At a concentration of 200 µM nifedipine, inhibitionwas apparent almost immediately on depolarization, as indicatedfrom the time of intersection of the fit line with the abscissa.Clearly, block occurred with time constants not dissimilar fromthe time constants of current activation at the higher concentrations.These data support the idea that nifedipine binds to open channels,but it is difficult at high concentrations to exclude nifedipinebinding to steps in the activation pathway during the early phaseof channel opening.

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Fig. 5. Concentration-dependent rate of onset of hKv1.5 block by nifedipine. Original currents were obtained from a holding potentialof -80 mV during 200-msec pulses to a test potential of +40 mV.Nifedipine sensitive current was calculated from the subtractionof steady-state currents in control and the presence of nifedipine,divided by the control current level (I_ctl-I_nif)/I_ctl. These havebeen plotted against the time from the start of the voltage clamppulse. The times of onset of block were 3.0, 2.4, 1.3, 1.1, 0.75and 0.35 msec with 5, 10, 20, 50, 100 and 200 µM nifedipine. Thesolid lines were the best fits to a biexponential equation ofthe form [y = A₁*exp(-t/ $tau$ ₁) + A₂*exp(-t/ $tau$ ₂) + C]. Data shown werefrom two different cells.

This open channel block was further confirmed by cross-over of tail currents in the absence and presence of nifedipine. Short,100-msec depolarizing pulses were given to fully open hKv1.5 channelsand cells were then repolarized to a potentials of -50 mV to measureoutward tail currents from deactivating channels (fig. 6A, inset).A typical example of currents is illustrated in figure 6A. Inthe presence of increasing concentrations of nifedipine, peakcurrents were reduced and current decay during voltage clamp pulseswas accelerated. The tail currents from figure 6A are enlargedin figure 6B and C. In the presence of nifedipine, the initialtail current amplitude was less (slowly decaying tracings) comparedwith control, and there was an obvious rising phase that can beseen at the beginning of the tail current in the presence of 10and 5 µM nifedipine, but not obvious with 2 µM nifedipine andabsent in control (fig. 6C, lower panel). Then tail currents crossedover each other (fig. 6C, upper panel). Results of this naturesuggest that nifedipine dissociates from deactivating channelsrather slowly compared with control channel deactivation, andthat nifedipine must dissociate from its binding site before channelscan close. All these properties were consistent with an open channelaction of nifedipine.

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Fig. 6. Deactivation tail current crossover caused by nifedipine. A, Under W/C recording conditions, cell was held at -80 mV and steppedto +40 mV for 100 msec, then stepped back to -50 mV as shown bythe protocol inset in A. Tail currents were recorded during thelast voltage step to -50 mV. Superimposed currents are shown incontrol and the presence of 2, 5 and 10 µM nifedipine. B, Deactivationtail currents from panel A (dotted box) were enlarged to illustratecross-over of control and in the presence of 2, 5 and 10 µM nifedipine.C, Tail currents in B were enlarged again to show crossover clearly(upper panel, in the presence of 5 µM nifedipine) and the risingphase at the beginning of tail currents (lower panel) in the presenceof 2, 5 and 10 µM nifedipine, with the control tracing for comparison.

Site of action. Nifedipine is a 1,4-dihydropyridine with a pKa $<=$ 1.0 (Uehara and Hume, 1985). Thus, at a physiological pH of 7.4, almost allof the nifedipine will be in its neutral form. As an unchargedmoiety it should rapidly cross biological membranes, and thusit has a possible site of action at the outer or inner mouth ofopen hKv1.5 channels. It has been reported that nifedipine canblock Ca⁺⁺ channels from the extracellular side or penetrate the membraneto approach its binding site in the hydrophobic domain near tothe extracellular side. To attempt to determine on which sideof the membrane that hKv1.5 channels could be blocked by nifedipine,the efficacy of block under different macropatch recording conditionswas compared. The data in figure 7A illustrate the effects of10 and 100 µM nifedipine on the current recorded from O/O andC/A macropatches. In both cases the currents were recorded inthe steady state in nifedipine, after at least 3 min exposure.In the presence of nifedipine, at similar concentrations, currentwas much reduced in the O/O patch mode of recording compared withthe C/A patch. Summary steady-state data from two to eight cellsin figure 7B shows the effect of different concentrations of nifedipineon hKv1.5 in C/A, I/O, O/O macropatches and during W/C recording.Data points were obtained by comparing the steady-state currentin control and different concentrations of nifedipine under thedifferent recording conditions. Compared with O/O macropatchesand W/C recording, the current in I/O and C/A macropatches wasrelatively less sensitive to nifedipine. At concentrations of1 to 5 µM nifedipine, very little block was observed in C/A macropatches,whereas at 5 µM nifedipine, current was $approx$ 50% blocked in W/C andO/O macropatch recordings. The rank order of block of hKv1.5 bynifedipine was then, whole-cell $approx$ outside-out > inside-out $>>$ cell-attachedmacropatches. Analysis of variance of the results with 10, 20,50 and 100 µM nifedipine showed that the difference of relativecurrent between C/A or I/O macropatches and O/O macropatches orW/C recordings was statistically significant (P < .05), the differencebetween O/O macropatches and W/C recording was not statisticallysignificant (P > .05).

Our rationale for determining the likely site of action of nifedipine is based on our assumption that variations in the efficacyof block by nifedipine are closely related to the local concentrationsof nifedipine under different recording conditions. If the bindingsite of nifedipine is at or near to the extracellular side, duringW/C recording when nifedipine was superfused into the bath, itcan bind to its receptor directly and efficiently. For the C/Amacropatches, when nifedipine is added to the bath, it has toenter the cell, cross the patch and block from the pipette side.As the pipette filling solution contains no nifedipine, it providesa large volume into which nifedipine at the extracellular faceof the patch would be rapidly diluted away by the pipette constituents.This is likely to reduce the effective local concentration ofnifedipine at the extracellular side of the patch in the C/A configurationand thus decrease the efficacy of nifedipine block of hKv1.5.A similar explanation can be applied to the results from I/O (decreasedefficacy of block) and O/O (high efficacy of block) macropatchconfigurations. In confirmation of these results nifedipine addedto the pipette filling solution had little effect on whole cellcurrents.

An important characteristic of open channel blocking drugs that act on voltage-gated Kv channels at the internal face of themembrane is that they usually cause channel gating charge immobilization.This has been shown to be true for tetraethylammonium ions (Stühmeret al., 1991

; Bezanilla et al., 1991

), for 4-aminopyridine (Bouchardand Fedida, 1995

; McCormack et al., 1994

) and quinidine (Fedida,1997

). It seems that the charged drug binding to sites at theinner mouth of the pore somehow prevents some outward movementor rapid return of the voltage sensor on repolarization. Thisleads to the reduction or slowed movements of different componentsof gating charge. This may be because of their charge that directlyinfluences surface charge at the inner mouth of the pore. Alternatively,the channels may be unable to return to their resting conformationuntil the drugs dissociate, due to steric effects of the drugshindering channel closure. This latter mechanism of immobilizationdoes not depend on charged forms of the drugs. We have postulatedearlier that nifedipine exerts its action towards the extracellularsurface, and thus we do not expect large effects on hKv1.5 gatingcurrents. The effect of different concentrations of nifedipineon typical hKv1.5 gating currents is illustrated in figure 8.Ionic currents were eliminated by substitution of all permeantmonovalent ions in the pipette and extracellular solutions withNMG (see "Materials and Methods"). In transfected HEK cells, datacorrected for leak revealed rapid transient currents on depolarizationand repolarization (fig. 8, A and C). The holding potential was-100 mV. The gating currents on depolarization (on-gating current)reached their peak between 2.2 and 0.5 msec, dependent on thepulse potential. Note that this time is theoretically well withinthe time resolution of the recording system that is limited bythe cell size and access characteristics. As noted previously,peak gating current increased with depolarization, although totalcharge moved (Q_on) eventually saturated (Bezanilla et al., 1991

;McCormack et al., 1994

; Bouchard and Fedida, 1995

) (fig. 8, Eand F). The more rapid decay of on-gating current underlies theincreasingly rapid activation of ionic current with larger depolarizations.The peak gating current on repolarization (off-gating current)was reduced and the decay of off-gating current slowed for largerdepolarizations, and this also is known to occur in Shaker K⁺ channels (Stefani et al., 1994

). Upon repolarization, gatingcharge (Q_off) returns, and although slower for large positivedepolarizations, it was well conserved, with the ratio Q_off/Q_onusually close to 1.0. In the presence of nifedipine (fig. 8, Band D), on and off-gating currents were very similar to thoseseen in control at concentrations of nifedipine from 5 to 50 µM.However, mean data (fig. 8, E and F) revealed a small reductionin off-gating charge after depolarizations to more positive potentialsthan 0 mV at both 5 and 50 µM nifedipine. The reductions werestatistically significant at potentials positive to 0 mV (pairedt test, P < .05). This arises from an increased immobilizationof off-gating current at potentials at which channels are openand suggests that nifedipine block of open hKv1.5 channels isassociated with some inhibition of conformational changes thataccompany channel closing. However, these changes are very smallcompared with the actions of drugs at the intracellular mouthof K⁺ channels, and seem unlikely to be related to the ionic currentblock by nifedipine which has a K_d of 6.3 µM at +40 mV (fig. 2C).

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Fig. 8. Effect of nifedipine on gating currents of hKv1.5 channel. A and B, Data in panel A and B are the gating currents of hKv1.5channel in the absence (A) and presence (B) of 5 µM nifedipine.Cell was depolarized from -100 to +70 mV for 12 msec from a holdingpotential of -100 mV to initiate the on-gating current, then repolarizedto -100 mV to record off-gating current. Traces shown are from-70 to +30 mV in increments of +20 mV. C and D, Data from a differentcell in the absence (C) and presence (D) of 50 µM nifedipine.Traces were elicited using the same voltage protocol as in panelsA and B. E and F, Integrated on- ( $open circle$ ) and off- ( $down-triangle$ ) gating chargemovement in the presence of 5 µM (E) and 50 µM (F) nifedipineexpressed relative to the maximum on- ( $bullet$ ) and off- ( $black-down-triangle$ ) gatingcharge movement in controls. Data were means ± S.E. from four(F) or six (E) experiments. The asterisk represents a statisticallysignificant (P < .05) difference between off-gating charge movementin control and in the presence of nifedipine.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

We have investigated the mechanism of action of nifedipine on the hKv1.5 channel expressed in a human cell system. Nifedipineis a tissue-specific Ca⁺⁺ channel antagonist that has a major role in the vascular bedwhere it is an effective vasodilator. In our study nifedipinealso produced a strong block of a human heart Kv channel.

Nifedipine blocks hKv1.5 with a low K_d. Nifedipine is a widely used Ca⁺⁺ antagonist and has been shown to block native Ca⁺⁺ channels with K_d in the range of 200 to 310 nM (Charnet et al.,1987; Mecca and Love, 1992). Cloned Ca⁺⁺ channels are also blocked by dihydropyridines and phenylalkylamineswith K_ds in the 100s of nM to low µM range (Schuster et al., 1996).Nifedipine blockade of native cardiac potassium channels has alsobeen reported. Transient outward potassium currents I_t in rabbitatrium (Gotoh et al., 1991) and I_to in rat ventricular myocytes(Jahnel et al., 1994) were largely blocked by 30 µM nifedipineand the blockade was concentration-dependent. Besides the blockof potassium channels in intact myocytes, nifedipine also causedthe block of cloned potassium channel hKv1.5 with a K_d of 81 µM(Grissmer et al., 1994). Our data in figures 1 and 2 demonstratedthat nifedipine accelerated the time course of decay of hKv1.5currents. Currents reached a peak that was less than correspondingcontrol currents at concentrations greater than the K_d. Subsequentlynifedipine caused a rapid current decay that was concentrationdependent. Such effects of nifedipine allowed us to calculatedose-response curves for both the peak and steady-state outwardcurrents (fig. 2). Fits of the Hill equation to these data gaveK_d values of 18.6 ± 2.7 and 6.3 ± 0.5 µM for peak and steady-statecurrents, respectively, with Hill coefficients of 0.75 ± 0.04and 0.93 ± 0.03. The peak current measurement represented thepartial block of current by nifedipine, and the interaction betweenrates of channel opening and the onset of block at different pulsepotentials and nifedipine concentrations (see below). For thisreason, the K_d value (18.6 µM) was expected to be lower than forsteady-state block of open channels (6.3 µM). The non-steady-statevalue for the Hill coefficient that was measured (0.75) from thepeak current dose-response cannot then be used to indicate cooperativity.The measurement of steady-state current block reflected the equilibratedinteraction of hKv1.5 channels with nifedipine at different concentrationsand potentials and was of more interest in the present study.The Hill coefficient close to 1.0 for steady-state current blocksuggests that binding of one nifedipine molecule per channel issufficient to block the hKv1.5 channel. Although nifedipine alsoshowed some effects on endogenous current of HEK cells, the averageamplitude was about 2 to 3% of the hKv1.5 current. The endogenouscurrent was also less sensitive to nifedipine, so was unlikelyto significantly distort our quantitation of hKv1.5 current blockby nifedipine in HEK cells. The K_d of 6.3 ± 0.5 µM for hKv1.5expressed in HEK cells was an order of magnitude lower than foran isoform of hKv1.5 (HPCN1) (Grissmer et al., 1994) expressedin MEL cells. Possible reasons for this difference are the differentmammalian expression systems (MEL vs. HEK cells) and small structuraldifferences between the two isoforms of hKv1.5 used here (fHKvs. HPCN1), although it should be noted that these isoforms areidentical throughout the S4-S6 gating and pore regions. We foundthat photoinactivation of the drug occurred readily in the clonedcell system and when making measurements with nifedipine it wasnecessary to carry out all experiments in the dark. A K_d in thelow micromolar range, and threshold effects in the 100 nM rangemake nifedipine a potent blocker of hKv1.5. No studies have addressedblock of specific components of cardiac K⁺ current in intact human myocytes by nifedipine, so at the presenttime it is not possible to relate our observations directly tocurrents in human heart.

Time dependence of block and open channel block. Our data indicated that nifedipine block of hKv1.5 showed marked time-dependence. Block increased in an exponential mannerduring the depolarizing pulses (fig. 2), and the onset of blockoccurred sharply after current activation (figs. 3 and 5). Nifedipinealso modified the tail current (fig. 6). Upon repolarization,control channel deactivation was fast and virtually irreversible(fig. 6A). Open-channel models predict that if a large fractionof the channels is blocked at the start of repolarization andthe unbinding rate (k₁) is fast enough, then the tail maydisplay a rising phase reflecting the unblocking from blockedto open state. Subsequently, the tail should deactivate more slowlythan in control, because some unblocked channels become blockedagain, depending on the relative rate constants for the open toblocked state and the open to closed state. Current traces infigure 6C (lower panel) show that a rising phase was prominentwith 10 and 5 µM, but less so with 2 µM nifedipine and absentin control. Subsequently tail currents cross-over as channelsin the presence of nifedipine move more slowly from the blockedstate to open and closed states than in control (fig. 6, B andC, upper panel) (Snyders et al., 1992; Fedida, 1997). From theresults discussed above we conclude that nifedipine binds to theopen state of the channel.

The rate of current decay in the control could be fitted to a single exponential function, and in the presence of nifedipine,the inactivation became biexponential. The nifedipine-inducedextra component of inactivation had a time constant that was muchfaster than that of slow inactivation; therefore, this fast timeconstant ( $tau$ ₂) can be considered to represent the interaction ofnifedipine with the open state, $tau$ ₂ = 1/(k₊₁ [D] + k₁),as described before (Snyders et al., 1992

; Slawsky and Castle,1994

). Based on this interaction, the apparent association andapparent dissociation rate constants for nifedipine obtained fromfigure 4B were k₊₁ = 5.64 × 10⁶ M¹ sec¹ and k₁ = 37.5 sec¹, respectively. The resultant K_d value from equation [2b] (see"Materials and Methods") was 6.65 µM, which is similar to theK_d value from the dose response curve in figure 2C. It shouldbe noted that $tau$ ₂ represents the transition from the open to blockstate and does not hold at small depolarizations (<0 mV), whereactivation is much slower, or at high drug concentrations, inwhich case the time constant of block may be similar to that ofactivation. In these cases the binding and unbinding rates ofnifedipine cannot be extracted from a simple model such as thatgiven above.

Voltage-dependence of block. In some K⁺ channels voltage-dependence of nifedipine block has been described. In rat alveolar-epithelial cells an inactivatingdelayed rectifier K⁺ channel demonstrated a voltage-dependent $tau$ _block (Jacobs and DeCoursey,1990). In frog atrial myocytes, block of I_k by nisoldipine, anifedipine analogue was voltage dependent (Hume, 1985). Our datain figure 3 showed that current was blocked quickly by nifedipinein the voltage range of channel opening. After channels were fullyopen, block was slightly relieved at more positive voltages. Thisrelief of block was independent of the concentration of nifedipinebetween 5 and 50 µM (fig. 3), and was well fitted to a linearfunction (fig. 3). The slopes of the fits were approximately similar,between 0.75 × 10³ and 1.5 × 10³ mV¹, and these quantify the increase in normalized current with depolarizationsin the presence of the drug. At the same time, data in figure4A indicate that once channels were fully open (>+30 mV), therewas a shallow decrease in the time constants of block with potential.From the above and a consideration of equation 2a and 2b, thesedata indicate that the voltage-dependence to the block must begiven by an increase in the off-rate (k₁) rather than adecrease in the on-rate (k₊₁) at more positive potentials.There are a number of possible explanations for this. First, althoughnifedipine is uncharged, its binding site may be coupled to somevoltage-dependent process, such as conformational changes in thepore with potential or movement of the voltage sensor (Jacobsand DeCoursey, 1990), which can sense the transmembrane voltagechange and confer voltage-dependence to block by an unchargeddrug. It has been proposed by De Coursey that neutral phenylalkylaminedrugs may have rapid access to their receptors, where block isthen stabilized by protonation of the drugs (DeCoursey, 1995).Although nifedipine has a much lower pK_a, such a mechanism couldexplain the voltage-dependence observed in the present experiments.

Nifedipine site of action. An alternative explanation for the voltage-dependence of block could be that nifedipine blocks open K⁺ channels from an external site. It is possible that at more positivevoltages, potassium permeation increases and hinders in some mannerthe binding of nifedipine to its site with a resultant reliefof block. Analogous with this, it is known that K⁺ occupancy of sites in the external mouth of the K⁺ channel pore affects the rate at which charged blockers (ions)can interact with the channel (Baukrowitz and Yellen, 1996). Wehave established that nifedipine induced open-channel block ofhKv1.5 and two additional lines of evidence suggest that the siteis in the external mouth of the pore. The rank order of blockdescribed in figure 7 was W/C $approx$ O/O > I/O $>>$ C/A macropatch. Thissuggested a preferential nifedipine block of hKv1.5 channels fromthe extracellular side or at a hydrophobic domain accessible fromthe extracellular surface. A similar conclusion has been drawnfor native K⁺ channels (Jacobs and DeCoursey, 1990; although see DeCoursey,1995) and for the dihydropyridine binding site in Ca⁺⁺ channels (Nakayama et al., 1991; Schuster et al., 1996), whereit is thought that the dihydropyridines block the channel fromthe extracellular side and mutations in repeat IVS6 affect binding(Schuster et al., 1996). The second line of evidence is basedon the gating current measurements (fig. 8). At concentrationsrequired to produce approximate 50% block of ionic current, nifedipinehad only very small effects on hKv1.5 gating currents. This suggestsa binding site distant from the intracellular mouth of the pore,where binding of numerous drugs immobilizes gating charge (Stühmeret al., 1991; Fedida, 1997). At high concentrations, on-gatingcurrents of hKv1.5 did not change in the presence of nifedipinecompared with the control, but off-gating currents in the presenceof nifedipine were reduced at voltages positive to +10 mV (fig.8F), in the voltage range that channels open. This also supportsthe idea that nifedipine can bind only to channels in the openstate, i.e., at some site exposed when the pore opens.

If we speculate that nifedipine acts at the external mouth of open K⁺ channels as suggested above, and that binding is coupled in a1:1 stoichiometry with a univalent entity (i.e., K⁺ ions) that senses the transmembrane electric field, we can applyequation 3 to observed block (data in fig. 3), with z = 1. Thedata were well fitted to this model, between +20 and +90 mV, atnifedipine concentrations of 5, 10, 20 and 50 µM. The fractionaldistance, $delta$ , was calculated to be between 0.12 and 0.16. Thissuggested that nifedipine binding may be coupled to a chargedprocess that sensed $approx$ 15% of the transmembrane electric field,from the outside, at its binding site. If a higher valence forthe coupling entity was assumed (i.e., z = 2 or 3), $delta$ was reducedproportionally, so the value of 0.12 to 0.16 gives an upper limitfor the distance into the field. Further experiments, perhapsutilizing mutated forms of Kv channels, are required to understandthe apparent voltage-dependence of nifedipine block of K⁺ channels, both in native systems (Jacobs and DeCoursey, 1990

)and in our cloned channel system.

	Footnotes

Accepted for publication February 10, 1997.

Received for publication November 21, 1996.

¹ This work was supported by grants from the Medical Research Foundation of Canada, and the Heart and Stroke Foundation of Ontario,to D.F.

Send reprint requests to: Dr. David Fedida, Department of Physiology, Botterell Hall, Queen's University, Kingston, Ontario, Canada, K7L 3N6.

	Abbreviations

W/C, whole cell recording; C/A, cell-attached recording; O/O, outside-out recording; I/O, inside-out recording; Q, gating charge; HEK, human embryonic kidney; NMG, N-methyl-D-glucamine.

	References

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Fedida, D., Wible, B., Wang, Z., Fermini, B., Faust, F., Nattel, S. and Brown, A. M.: Identity of a novel delayed rectifier current from human heart with a cloned K⁺ channel current. Circ. Res. 73: 210-216, 1993[Abstract].
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J. Gen. Physiol., April 2, 2002; 119(4): 373 - 388.
[Abstract] [Full Text] [PDF]

L. Perchenet, L. Hilfiger, J. Mizrahi, and O. Clement-Chomienne
Effects of Anorexinogen Agents on Cloned Voltage-Gated K+ Channel hKv1.5
J. Pharmacol. Exp. Ther., September 1, 2001; 298(3): 1108 - 1119.
[Abstract] [Full Text] [PDF]

R. Caballero, E. Delpón, C. Valenzuela, M. Longobardo, T. González, and J. Tamargo
Direct Effects of Candesartan and Eprosartan on Human Cloned Potassium Channels Involved in Cardiac Repolarization
Mol. Pharmacol., April 1, 2001; 59(4): 825 - 836.
[Abstract] [Full Text]

S. Lin, Z. Wang, and D. Fedida
Influence of permeating ions on Kv1.5 channel block by nifedipine
Am J Physiol Heart Circ Physiol, March 1, 2001; 280(3): H1160 - H1172.
[Abstract] [Full Text] [PDF]

A. N. Holm, A. Rich, M. G. Sarr, and G. Farrugia
Whole cell current and membrane potential regulation by a human smooth muscle mechanosensitive calcium channel
Am J Physiol Gastrointest Liver Physiol, December 1, 2000; 279(6): G1155 - G1161.
[Abstract] [Full Text] [PDF]

L. Perchenet and O. Clément-Chomienne
Characterization of Mibefradil Block of the Human Heart Delayed Rectifier hKv1.5
J. Pharmacol. Exp. Ther., November 1, 2000; 295(2): 771 - 778.
[Abstract] [Full Text]

L. Yue, J. L. Feng, Z. Wang, and S. Nattel
Effects of ambasilide, quinidine, flecainide and verapamil on ultra-rapid delayed rectifier potassium currents in canine atrial myocytes
Cardiovasc Res, April 1, 2000; 46(1): 151 - 161.
[Abstract] [Full Text] [PDF]

W. H. DuBell, W. J. Lederer, and T. B. Rogers
K+ currents responsible for repolarization in mouse ventricle and their modulation by FK-506 and rapamycin
Am J Physiol Heart Circ Physiol, March 1, 2000; 278(3): H886 - H897.
[Abstract] [Full Text] [PDF]

R. G. Tsushima, A. D. Wickenden, R. A. Bouchard, G. Y. Oudit, P. P. Liu, and P. H. Backx
Modulation of Iron Uptake in Heart by L-Type Ca2+ Channel Modifiers : Possible Implications in Iron Overload
Circ. Res., June 11, 1999; 84(11): 1302 - 1309.
[Abstract] [Full Text] [PDF]

E. Delpon, R. Caballero, C. Valenzuela, M. Longobardo, D. Snyders, and J. Tamargo
Benzocaine enhances and inhibits the K+ current through a human cardiac cloned channel (Kv1.5)
Cardiovasc Res, May 1, 1999; 42(2): 510 - 520.
[Abstract] [Full Text] [PDF]

X. Zhang and D. Fedida
Potassium Channel�Blocking Actions of Nifedipine: A Cause for Morbidity at High Doses?
Circulation, May 26, 1998; 97(20): 2098 - 2098.
[Full Text]

A. Zaza, M. Rocchetti, A. Brioschi, A. Cantadori, and A. Ferroni
Dynamic Ca2+-Induced Inward Rectification of K+ Current During the Ventricular Action Potential
Circ. Res., May 19, 1998; 82(9): 947 - 956.
[Abstract] [Full Text] [PDF]

P. Mitra and M. M. Slaughter
Calcium-induced Transitions between the Spontaneous Miniature Outward and the Transient Outward Currents in Retinal Amacrine Cells
J. Gen. Physiol., April 2, 2002; 119(4): 373 - 388.
[Abstract] [Full Text] [PDF]

B. H. Choi, J.-S. Choi, D.-J. Rhie, S. H. Yoon, D. S. Min, Y.-H. Jo, M.-S. Kim, and S. J. Hahn
Direct inhibition of the cloned Kv1.5 channel by AG-1478, a tyrosine kinase inhibitor
Am J Physiol Cell Physiol, June 1, 2002; 282(6): C1461 - C1468.
[Abstract] [Full Text] [PDF]

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				L. Perchenet, L. Hilfiger, J. Mizrahi, and O. Clement-Chomienne Effects of Anorexinogen Agents on Cloned Voltage-Gated K+ Channel hKv1.5 J. Pharmacol. Exp. Ther., September 1, 2001; 298(3): 1108 - 1119. [Abstract] [Full Text] [PDF]

				R. Caballero, E. Delpón, C. Valenzuela, M. Longobardo, T. González, and J. Tamargo Direct Effects of Candesartan and Eprosartan on Human Cloned Potassium Channels Involved in Cardiac Repolarization Mol. Pharmacol., April 1, 2001; 59(4): 825 - 836. [Abstract] [Full Text]

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				L. Perchenet and O. Clément-Chomienne Characterization of Mibefradil Block of the Human Heart Delayed Rectifier hKv1.5 J. Pharmacol. Exp. Ther., November 1, 2000; 295(2): 771 - 778. [Abstract] [Full Text]

				L. Yue, J. L. Feng, Z. Wang, and S. Nattel Effects of ambasilide, quinidine, flecainide and verapamil on ultra-rapid delayed rectifier potassium currents in canine atrial myocytes Cardiovasc Res, April 1, 2000; 46(1): 151 - 161. [Abstract] [Full Text] [PDF]

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				R. G. Tsushima, A. D. Wickenden, R. A. Bouchard, G. Y. Oudit, P. P. Liu, and P. H. Backx Modulation of Iron Uptake in Heart by L-Type Ca2+ Channel Modifiers : Possible Implications in Iron Overload Circ. Res., June 11, 1999; 84(11): 1302 - 1309. [Abstract] [Full Text] [PDF]

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				B. H. Choi, J.-S. Choi, D.-J. Rhie, S. H. Yoon, D. S. Min, Y.-H. Jo, M.-S. Kim, and S. J. Hahn Direct inhibition of the cloned Kv1.5 channel by AG-1478, a tyrosine kinase inhibitor Am J Physiol Cell Physiol, June 1, 2002; 282(6): C1461 - C1468. [Abstract] [Full Text] [PDF]

Characterization of Nifedipine Block of the Human Heart Delayed Rectifier, hKv1.51

Characterization of Nifedipine Block of the Human Heart Delayed Rectifier, hKv1.5¹