Comparison of N- and P/Q-Type Voltage-Gated Calcium Channel Current Inhibition

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Volume 17, Number 12, Issue of June 15, 1997 pp. 4570-4579
Copyright ©1997 Society for Neuroscience

Comparison of N- and P/Q-Type Voltage-Gated Calcium Channel Current Inhibition

Kevin P. M. Currie and Aaron P. Fox
The Department of Pharmacological and Physiological Sciences, The University of Chicago, Chicago, Illinois 60637

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Activation of N- and P/Q-type voltage-gated calcium channels triggers neurotransmitter release at central and peripheral synapses.These channels are targets for regulatory mechanisms, includinginhibition by G-protein-linked receptors. Inhibition of P/Q-typechannels has been less well studied than the extensively characterizedinhibition of N-type channels, but it is thought that they areinhibited by similar mechanisms although possibly to a lesserextent than N-type channels. The aim of this study was to comparethe inhibition of the two channel types.
Calcium currents were recorded from adrenal chromaffin cells and isolated by the selective blockers $omega$ -conotoxin GVIA (1 µM)and $omega$ -agatoxin IVA (400 nM). The inhibition was elicited by ATP(100 µM) or intracellular application of GTP- $gamma$ -S. It was classifiedas voltage-sensitive (relieved by a conditioning prepulse) orvoltage-insensitive (present after a conditioning prepulse). Thevoltage-insensitive inhibition accounted for a 20% reduction ofboth currents, whereas the voltage-sensitive inhibition reducedthe N-type current by 45% but the P/Q-type current by 18%. However,the voltage dependence of the inhibition, the time course of relieffrom inhibition during a conditioning prepulse, and the time courseof reinhibition after such a prepulse showed few differences betweenthe N- and P/Q-type channels. Assuming a simple bimolecular reaction,our data suggest that changes in the kinetics of the G-protein/channelinteraction alone cannot explain the differences in the inhibitionof the N- and P/Q-type calcium channels. The subtle differencesin inhibition may facilitate the selective regulation of neurotransmitterrelease.
Key words: calcium channel; G-protein; ATP; inhibition; patch clamp; GTP- $gamma$ -S; N-type calcium channel; P/Q-type calcium channel

INTRODUCTION

Of the multiple subtypes of voltage-gated calcium channel current (I_Ca), it has been shown that calcium influx via the N-,P, and Q-subtypes triggers neurotransmission at central and peripheralsynapses (Luebke et al., 1993; Takahashi and Momiyama, 1993; Regehrand Mintz, 1994; Wheeler et al., 1994; Waterman, 1996; Wrightand Angus, 1996). N-type channels are identified pharmacologicallyas being blocked irreversibly by $omega$ -conotoxin GVIA ( $omega$ -Cgtx GVIA)(McCleskey et al., 1987; Plummer et al., 1989) and are encodedfor by the class B $alpha$ ₁ subunit gene (Dubel et al., 1992; Williamset al., 1992). P-type channels are blocked potently by $omega$ -agatoxinIVA ( $omega$ -Aga IVA) (Mintz et al., 1992); Q-type channels also areblocked by $omega$ -Aga IVA but with a somewhat lower affinity (Zhanget al., 1993; Randall and Tsien, 1995). Biophysically, the P-typechannels exhibit little or no inactivation during prolonged depolarizations,whereas Q-type channels show substantial inactivation even after100 msec (Llinás et al., 1989; Mintz et al., 1992; Randall andTsien, 1995). It remains unclear which $alpha$ subunit gene encodesfor the P- and Q-type channels. The class A $alpha$ ₁ subunit producedinactivating currents that more closely resembled the Q-type current(Zhang et al., 1993), but it also may encode for channels withproperties similar to the P-type (Stea et al., 1994; Liu et al.,1996). Until these issues are resolved, many researchers in thefield have adopted the terminology "P/Q-type" current when referringto either component.

Synaptic transmission can be regulated by neurotransmitter modulation of voltage-gated calcium channels, such as the welldocumented inhibition of N-type channels by activation of G-protein-linkedreceptors (Hille, 1992, 1994; Dolphin, 1995). Several pathways,most of which are membrane-delimited, converge on the N-type channels.There is general consensus that this involves a direct effectof the activated G-protein subunit or subunits on the calciumchannel itself, and recent evidence indicates a key role for theG-protein $beta$ $gamma$ subunits (Herlitze et al., 1996; Ikeda, 1996). Theinhibition exhibits characteristic gating shifts manifested asslowed activation kinetics, a diminution of the inhibition atpositive membrane potentials, and partial relief from inhibitionby conditioning prepulses (Bean, 1989; Elmslie et al., 1990; Peningtonet al., 1991). These effects have been incorporated into modelsin which the channels exhibit two functional gating states, onein the presence ("reluctant") and another in the absence ("willing")of inhibition (Bean, 1989; Elmslie et al., 1990; Boland and Bean,1993; Golard and Siegelbaum, 1993).

Recently, it has become apparent that P/Q-type channels are inhibited by similar mechanisms (Mintz and Bean, 1993), but therehas been little detailed comparison with N-type current inhibition.However, a few reports suggest that the N-type current is inhibitedto a greater extent than the P/Q-type current (Mintz and Bean,1993; Bayliss et al., 1995; Bourinet et al., 1996; Currie andFox, 1996). Such differential targeting may have a role in theselective regulation of neurotransmission. Therefore, we havecompared the similarities and differences in the inhibitory modulationof N- and P/Q-type I_Ca in bovine adrenal chromaffin cells.

MATERIALS AND METHODS
Culture of cells. Chromaffin cells were prepared by digestion of bovine adrenal glands with collagenase and purified by densitygradient centrifugation, as previously described (Artalejo etal., 1992a). The cells were plated on collagen-coated glass coverslips(22 × 22 mm) at a density of ~0.15 × 10⁶ cells/cm² and maintained in an incubator at 37°C in an atmosphere of 92.5%air/7.5% CO₂ with a relative humidity of 90%. Fibroblasts weresuppressed effectively with cytosine arabinoside (10 µM), leavingrelatively pure chromaffin cell cultures. Although mixed, thecultures were enriched somewhat for epinephrine-containing overnorepinephrine-containing cells. One-half of the incubation mediumwas exchanged every day. This medium consisted of DMEM/F12 (1:1)supplemented with fetal bovine serum (10%), glutamine (2 mM),penicillin/streptomycin (100 U · ml¹/100 µg · ml¹), cytosine arabinoside (10 µM), and 5-fluorodeoxyuridine (10µM).

Electrophysiology. Chromaffin cells were voltage-clamped in the whole-cell configuration of the patch-clamp technique (Hamillet al., 1981) with an Axopatch 1C amplifier (Axon Instruments,Foster City, CA) at a holding potential of $-$ 80 mV, and I_Ca wasactivated by step depolarizations. Current-voltage curves weregenerated by voltage ramps of 100 msec duration from the holdingpotential ( $-$ 80 mV) to +100 mV. Leak currents were generated byaveraging 16 hyperpolarizing sweeps (steps or ramps). All of thedata reported in this paper were capacitance- and leak-subtracted.The data were filtered at 2 kHz and then digitized at 100 µsecper point. Series resistance was compensated partially ( $approx$ 80%)by using the series resistance compensation circuit of the Axopatch-1Camplifier. Electrodes were pulled from microhematocrit capillarytubes (Drummond, Broomall, PA) and coated with SYLGARD (Dow Corning,Midland, MI). After fire polishing, final electrode resistanceswhen filled with the CsCl-based patch pipette solution (see below)were ~1.5-2.0 M $Omega$ . Voltage protocols and data analysis were performedin AxoBasic. Data are reported as mean ± SEM, and statisticalsignificance was determined with paired or independent Student'st test.

Solutions. Electrodes were filled with (in mM): CsCl 110, MgCl₂ 4, HEPES 20, EGTA 10, GTP 0.35, ATP 4, and creatine phosphate14, pH 7.3 (adjusted by CsOH); osmolality, $approx$ 310 mOsm. In someexperiments 0.07 GTP- $gamma$ -S replaced an equal amount of GTP. TheNaCl-based extracellular recording medium contained (in mM): NaCl140, KCl 2, glucose 10, HEPES 10, CaCl₂ 10, and tetrodotoxin (TTX)2 µM, pH 7.3 (adjusted with NaOH); osmolality, $approx$ 315 mOsm. Insome experiments the NaCl was replaced by choline Cl. Nisoldipine(1 µM) was present in all extracellular solutions to block anyfacilitation (L-type) I_Ca. ATP for extracellular application wasprepared as a stock solution in distilled water and kept on icebefore dilution to final concentrations in extracellular recordingmedium. $omega$ -Conotoxin GVIA (Alomone Labs, Jerusalem, Israel) and $omega$ -agatoxin IVA (gift from Dr. N. Saccomano, Pfizer, Groton, CT)were stored at $-$ 20°C either lyophilized or as concentrated stocksin distilled water. Final concentrations were prepared daily bydilution in extracellular recording medium. Bovine serum albumin(BSA; (1 mg/ml) was included in the recording medium to preventnonspecific binding of the peptides. BSA itself was found to haveno effect on I_Ca .

After the formation of a seal, the cell was perfused continually by an Adams & List (Westbury, NY) DAD-12 superfusion system.In brief, this consisted of a "sewer pipe" arrangement in whicha quartz capillary of 100 µm diameter is placed close to the cell.The sewer pipe was connected to six reservoirs, and flow fromthese was controlled by valves operated by the AxoBasic software.This enabled the cell to be perfused continually with fresh solutionand the rapid exchange of solutions for application of toxinsor ATP. The exchange time for switching between two solutionswas <1 sec. The bath volume was kept relatively constant by usingan outlet connected to a vacuum. All solutions perfused in thisway contained 1 mg/ml BSA. All experiments were performed at roomtemperature (~23°C).

RESULTS
We have shown previously that ATP inhibits both N-type and P/Q-type calcium currents in adrenal chromaffin cells. The aimsof this study were to investigate the similarities and differencesin the inhibitory response of the N- and P/Q-type calcium currents.These experiments included prepulse depolarizations to very positivepotentials. Chromaffin cells possess L-type calcium channels,which are normally quiescent but can be recruited by similar depolarizingprepulses, neurotransmitters such as dopamine that elevate cAMP,or rapid repetitive depolarizations in the physiological range(Fenwick et al., 1982; Artalejo et al., 1990, 1992b). To avoidthe complication of recruitment of these channels, we included1 µM nisoldipine, which selectively blocks these L-type channels(Artalejo et al., 1991) in all extracellular solutions.

In the presence of nisoldipine (1 µM) the I_Ca was composed almost totally of N-type and P/Q-type I_Ca. Perfusion of 1 µM $omega$ -CgtxGVIA to block the N-type current reduced the peak inward I_Ca amplitudeby 48 ± 2% (n = 20). Subsequent perfusion of 400 nM $omega$ -Aga IVAto identify the P/Q-type I_Ca blocked most of the remaining current,equivalent to 45 ± 2% (n = 17) of the total current amplitude(Fig. 1A). A small component of the total current (7 ± 1%; n =17) remained after application of both toxins. There was no differencein the percentage block by the two toxins if the order of applicationwas reversed (i.e., $omega$ -Aga IVA applied before $omega$ -Cgtx GVIA), indicatingthat there was no overlap in the pool of channels blocked by eachtoxin. In this case $omega$ -Aga IVA blocked 43 ± 3% and $omega$ -Cgtx GVIAblocked 47 ± 3% of the peak I_Ca (n = 9). Some cells bathed inthe NaCl-based recording solution exhibited a small TTX-resistantinward sodium current. This current decayed rapidly (3-4 msec)during the depolarizing steps used to activate I_Ca and was fullyinactivated either by depolarizing prepulses or by changing theholding potential to $-$ 50 mV. The current also disappeared whenthe cells were perfused with choline Cl-based recording solution.It did not interfere with the measurement of peak I_Ca, becausechanging the recording solution from NaCl to choline Cl-basedsolution had no effect on the measured peak inward I_Ca amplitude.
Fig. 1. ATP inhibits N-type I_Ca to a greater extent than P/Q-type I_Ca. A, Plotted is peak current amplitude against time. Cells weredepolarized to +20 mV from a holding potential of $-$ 80 mV. ATP(100 µM) and toxins were applied to the cell, as indicated bythe horizontal bars. The combination of $omega$ -Cgtx GVIA (1 µM) and $omega$ -Aga IVA (400 nM) blocked almost all of the current in this cell.ATP inhibited both the $omega$ -Cgtx GVIA and $omega$ -Aga IVA-sensitive currentcomponents. B, N-type and P/Q-type I_Ca in the presence and absence(control) of ATP. The N-type I_Ca currents are generated by subtractingthe currents obtained after $omega$ -Cgtx GVIA from those obtained before $omega$ -Cgtx GVIA. The P/Q-type currents are that component of I_Ca thatremained after block with $omega$ -Cgtx GVIA. Note the slowed activationkinetics and the larger inhibition of the N-type current. C, Thebar chart on the left plots the percentage of inhibition producedby 100 µM ATP in 35 cells like the one shown above (A, B). Thepercentage of inhibition of peak inward current amplitude is plottedfor both the N- and P/Q-type currents. The currents were isolatedby obtaining data before and after application of $omega$ -Cgtx GVIA.There was a significantly larger inhibition of N-type, as comparedwith P/Q-type, current. The bar chart on the right plots datacollected from nine cells in which ATP was applied before andafter $omega$ -Aga IVA. In this case the current after block with $omega$ -AgaIVA was termed the N-type I_Ca, and the difference currents wereP/Q-type I_Ca.
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ATP inhibits N-type I_Ca to a greater extent than P/Q-type I_Ca
To compare the inhibition of the N- and P/Q-type currents, we applied a supramaximal dose of ATP (100 µM) to cells beforeand after application of $omega$ -Cgtx GVIA (Fig. 1A). The I_Ca that remainedafter application of $omega$ -Cgtx GVIA was termed the P/Q-type I_Ca.Subtraction of the currents obtained after $omega$ -Cgtx GVIA applicationfrom those obtained before $omega$ -Cgtx GVIA application yielded a differencecurrent that was pure N-type I_Ca. Figure 1B shows that the N-typeI_Ca was inhibited to a greater extent than the P/Q-type I_Ca andthat the activation kinetics of both currents were slowed. Aftervery long steps there was often little or no inhibition, becauseit was slowly relieved during the depolarization. Thus all currentamplitudes from the same cell were measured at a fixed time afteractivation of the current (typically ~10 msec) corresponding tothe peak of the control I_Ca. Although arbitrary, it is commonpractice to measure the inhibition in this manner. Activationof N-type channels in chromaffin cells is slightly slower thanthat of P/Q-type channels (Artalejo et al., 1992a), but we werecareful to measure the amplitudes at a point at which both currentshad peaked.

The mean percentage of inhibition by ATP was 65 ± 1.6% for the N-type current and 39 ± 1.2% (n = 35; p < 0.001) for the P/Q-typecurrent. The same pattern of differential inhibition was seenif the order of toxin application was reversed so that ATP wasapplied before and after application of $omega$ -Aga IVA (Fig. 1C). Inthis case the current remaining after block with $omega$ -Aga IVA wasthe N-type I_Ca, and the P/Q-type I_Ca was the subtracted differencecurrent. In nine cells recorded in this way the N-type currentwas inhibited by 60 ± 4.3%, and the P/Q-type current inhibitionwas 36 ± 3.0% (p < 0.001).

Differences in the voltage sensitivity of the inhibition of N- and P/Q-type currents
The ATP-mediated inhibition of I_Ca exhibited voltage sensitivity; it was diminished at very positive test potentials and wasrelieved in part by depolarizing prepulses to very positive potentials(Currie and Fox, 1996). The two current components were isolatedin the same manner as shown in Figure 1 to determine whether theinhibition of the N- and P/Q-type I_Ca was equally voltage-sensitive.Depolarizing voltage step commands to +20 mV for 20 msec wereused to activate the currents in control conditions and with ATPpresent to elicit the inhibition. Then, still in the presenceof ATP, I_Ca was activated again, but the test pulse was precededby a depolarizing prepulse to +100 mV for 50 msec (Fig. 2A). Suchprepulses relieved a significantly greater proportion of the N-typecurrent inhibition (69 ± 3%) than the P/Q-type current inhibition(47 ± 3%; n = 17; p < 0.001). Note that, in control conditionsin the absence of inhibition, identical prepulses had no effecton I_Ca, because in chromaffin cells these channels show no voltage-dependentinactivation (Artalejo et al., 1992a). Thus under control conditionsthe peak amplitude of those currents preceded by a prepulse was98.4 ± 0.4% (n = 23) of those not preceded by a prepulse.
Fig. 2. The magnitude of the voltage-sensitive block is different for the N- and P/Q-type currents. A, Shown are current records ofN-type and P/Q-type I_Ca isolated as in Figure 1. The traces labeledcontrol were obtained in the absence of ATP, the traces labeledATP were obtained in the presence of 100 µM ATP, and the traceslabeled ATP + prepulse were obtained in the continued presenceof ATP but preceded by a depolarizing prepulse to + 100 mV lasting50 msec. The voltage protocol is illustrated above the currentrecords. The prepulse relieved ~70% of the N-type current inhibitionbut only ~50% of the P/Q-type current inhibition. B, The bar charton the left plots the percentage of inhibition produced by 100µM ATP for 17 cells like that in A. The inhibition is dividedinto the voltage-sensitive component (relieved by depolarizingprepulses) and the voltage-insensitive component (the inhibitionthat persists after a prepulse). The voltage-insensitive componentwas similar for the two currents, but the voltage-sensitive componentwas more than twice as large in the N-type current as in the P/Q-typecurrent. The bar chart on the right illustrates that the samepattern of inhibition was seen if $omega$ -Aga IVA (rather than $omega$ -CgtxGVIA) was used to isolate the currents. This single prepulse didnot produce significant reversal of $omega$ -Aga IVA block.
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Figure 2B shows the pooled data for these experiments in which the total percentage of inhibition of the peak current is subdividedinto the voltage-sensitive component (the component that was relievedby a depolarizing prepulse) and the voltage-insensitive component(the component of the inhibition that was not relieved by a depolarizingprepulse). The voltage-insensitive component accounted for approximatelythe same amount of inhibition for both currents. In contrast,approximately twice as much N-type current inhibition was voltage-sensitiveas compared with the P/Q-type current. The same pattern of inhibitionwas seen if the data were obtained before and after $omega$ -Aga IVArather than $omega$ -Cgtx GVIA to isolate the currents (Fig. 2B). Itshould be noted that in using this protocol there will be somereblock of the voltage-sensitive inhibition during the 10 msecinterval between the prepulse and test pulse (see below). However,this is likely to be <10% and to be similar for the two currenttypes.

Intracellular GTP- $gamma$ -S mimics the differential inhibition produced by ATP
GTP- $gamma$ -S is an analog of GTP that is resistant to hydrolysis, and therefore irreversibly activates G-proteins. By includingGTP- $gamma$ -S in the patch pipette solution, the inhibition of I_Ca couldbe elicited without the need for receptor activation by ATP. Inall experiments reported here, after inhibition of I_Ca by theGTP- $gamma$ -S, ATP was applied to the cells to ensure that the G-proteinswere fully activated and that the inhibition was maximal. In mostcases the response to ATP was occluded, although in some cellsit did produce a small increase in the inhibition.

The GTP- $gamma$ -S-containing patch pipette solution was identical to the normal solution except that 70 µM (one-fifth) of the GTPwas replaced by GTP- $gamma$ -S. Once the whole-cell configuration wasobtained, the GTP- $gamma$ -S slowly dialyzed into the cell and activatedthe G-proteins, causing an inhibition of the calcium current overa period of 5-7 min (Fig. 3A). In many cells the GTP- $gamma$ -S appearedto activate transiently an inward current over the same time course(data not shown). This inward current decayed back to baselinewithin a few minutes in almost all cells, and those cells in whichthis was not the case were discarded. The ionic nature of thiscurrent was not investigated in this study. Figure 3A shows thatthe inhibition of I_Ca produced by GTP- $gamma$ -S was similar to thatproduced by ATP. The currents on the left were recorded shortlyafter breaking into the cell before the GTP- $gamma$ -S had time to diffuseinto the cell and activate the G-proteins. A prepulse given atthis time had no effect on the amplitude or kinetics of I_Ca. Thecurrents on the right were recorded 7-8 min later after the GTP- $gamma$ -Shad inhibited the current. A prepulse given at this time spedthe activation kinetics and increased the amplitude of I_Ca dueto relief of the voltage-sensitive component of the inhibition.
Fig. 3. Intracellular GTP- $gamma$ -S mimics the inhibition elicited by ATP. A, Currents recorded from a cell with patch pipette solutioncontaining GTP- $gamma$ -S. For these experiments one-fifth of the GTPin the patch pipette solution (total GTP = 350 µM) was replacedwith an equal amount (70 µM) of GTP- $gamma$ -S. The currents on the leftwere recorded within 1 min of entering the whole-cell configurationbefore significant activation of G-proteins by the GTP- $gamma$ -S. Thoseon the right were recorded 7-8 min after entering the whole-cellconfiguration. Each trace shows two superimposed currents. Thecontrol current was elicited by a 20 msec test pulse to +20 mVwith no prepulse (labeled no prepulse). The second current waspreceded by a depolarizing prepulse to +100 mV for 50 msec, 10msec before the test pulse (labeled with prepulse). GTP- $gamma$ -S inhibitsI_Ca and slows the activation kinetics of I_Ca in a manner indistinguishablefrom ATP. The dashed line is for illustrative purposes and representsthe peak amplitude of the uninhibited current. B, Plotted is thepercentage block of I_Ca produced by 1 µM $omega$ -Cgtx GVIA for cellsloaded with control or GTP- $gamma$ -S containing patch pipette solution.There was a significant reduction in toxin block when GTP- $gamma$ -Swas present in the patch pipette solution. C, Shown is the potentiationof N- and P/Q-type I_Ca amplitude produced by prepulses on GTP- $gamma$ -S(as shown in A) or ATP (100 µM) inhibited currents. The increasein current amplitude produced by the prepulses was attributableto relief of the voltage-sensitive component of the inhibition.It is presented as the ratio of the current amplitude with a prepulserelative to that without a prepulse. The N-type current was potentiatedsignificantly more than the P/Q-type current, reflecting the differentialvoltage sensitivity of the inhibition for the two channel types.
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When GTP- $gamma$ -S was used to produce the inhibition, the differential targeting of the N- and P/Q-type I_Ca was still apparent.This was manifested in the percentage of current blocked by $omega$ -CgtxGVIA (Fig. 3B). In cells loaded with GTP- $gamma$ -S-containing patchpipette solution, $omega$ -Cgtx GVIA blocked 25 ± 1.8% (n = 27) of thecurrent, and in cells loaded with control patch pipette solutioncontaining no GTP- $gamma$ -S, it blocked 48 ± 2.4% (n = 20; p < 10⁹). This is consistent with a higher proportion of the N-type currentbeing inhibited by the GTP- $gamma$ -S, as compared with the P/Q-typecurrent.

The voltage-sensitive component of the inhibition produced by GTP- $gamma$ -S was investigated by using a prepulse protocol like thatshown in Figure 2A. The N- and P/Q-type I_Ca were isolated by using $omega$ -Cgtx GVIA as before. Because dialysis of GTP- $gamma$ -S into the cellstarts immediately on entering the whole-cell configuration, therewas no way to obtain reliable control (uninhibited) data. Thus,the amount of voltage-sensitive inhibition was quantified by determiningthe increase in current amplitude produced by a prepulse relativeto the amplitude of the current remaining after full inhibition(Fig. 3A). This potentiation of current amplitude was 2.51 ± 0.11for the N-type I_Ca and 1.46 ± 0.04 (n = 21; p < 10⁹) for the P/Q-type I_Ca, illustrating the greater degree of voltage-sensitiveinhibition of the N-type current relative to the P/Q-type current.The same analysis performed on currents inhibited by ATP applicationproduced similar results (Fig. 3C). The potentiation was 2.20± 0.12 for the N-type current and 1.33 ± 0.03 (n = 15; p < 10⁴) for the P/Q-type current.

Comparison of the voltage-sensitive inhibition
Because the voltage-sensitive component of the inhibition accounted for the differential targeting of the two current types,it was investigated more closely by varying the parameters ofthe prepulse protocol. The voltage protocols were repeated beforeand after application of $omega$ -Cgtx GVIA to isolate the N- and P/Q-typeI_Ca. GTP- $gamma$ -S patch pipette solution was used to stimulate theinhibition to minimize any complications with desensitizationof the agonist response, but experiments also were done usingATP to stimulate the inhibition. Any cells that showed excessivedesensitization or rundown over the course of the protocol werediscarded.

Figure 4 shows the data in which the time course of relief from inhibition was investigated. Prepulses were to either +100or +140 mV and were separated from the test pulse by an intervalof 10 msec. The duration of the prepulse was varied from 2 to50 msec. The current increase caused by each prepulse (over currentsactivated with no prepulse preceding them) was normalized, andthe data were fit with a single exponential to determine the timeconstant for the relief from inhibition. At +100 mV (Fig. 4A)the time constant for the N-type current was 9.8 ± 0.7 msec (n= 12), and for the P/Q-type current there was a small but significantincrease in the time constant to 13.1 ± 1.0 msec (n = 12; p =0.01). When this was repeated using ATP to produce the inhibition,there was a small difference in the time constants, but it wasnot statistically significant (N-type = 9.9 ± 1.0 msec and P/Q-type= 10.8 ± 1.8 msec; n = 4). At +140 mV (Fig. 4B) there was no differencein the time course for relief from inhibition with time constantsof 11.5 ± 1.0 and 11.7 ± 0.8 msec (n = 5) for the N- and P/Q-typecurrents, respectively.
Fig. 4. Time course of relief from inhibition is similar for N- and P/Q-type currents. The voltage protocol used is shown at the top.The holding potential was $-$ 80 mV, and the test pulse was of 20msec duration to +20 mV. The test pulse was preceded by a prepulse(to either +100 or +140 mV), and the two were separated by aninterpulse of 10 msec during which the cell was returned to theholding potential. The patch pipette solution contained GTP- $gamma$ -S(70 µM) to elicit inhibition. The voltage protocols were repeatedbefore and after application of $omega$ -Cgtx GVIA (1 µM) to isolatethe N- and P/Q type currents. A, Plotted is relief from inhibitionas a function of prepulse duration by prepulses to +100 mV. Theincrease in current amplitude produced by each of the prepulses(i.e., the amplitude of the current with a prepulse minus theamplitude of a current without a prepulse) was normalized to thatproduced by the longest duration prepulse (50 msec), which isknown to produce a maximal relief from inhibition. The data werefit with a single exponential, giving time constants of 9.8 ±0.7 msec for the N-type current and 13.1 ± 1.0 msec for the P/Q-typecurrent. B, Plotted is relief from inhibition by prepulses to+140 mV. Time constants were 11.5 ± 1.0 msec for N-type currentand 11.7 ± 0.8 msec for P/Q-type current.
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Figure 5 explores the time course for channel reinhibition after a prepulse to +100 mV. When the cell is repolarized afterthe prepulse, the channels become reinhibited, so by varying theduration of the interpulse between the prepulse and test pulse,the time course of this reinhibition was determined. This wasrepeated at potentials of $-$ 60, $-$ 80, and $-$ 100 mV. The prepulsewas to +100 mV for 50 msec, and the interpulse duration was variedfrom 5 to 300 msec. The increase in current produced by the prepulseswas normalized, and the data were fit with a single exponentialdecay. Figure 5A shows that at $-$ 60 mV the time constants for reinhibitionof the N- and P/Q-type currents were virtually identical at 108± 11 and 105 ± 11 msec, respectively (n = 5). At $-$ 80 mV the timeconstants again were not significantly different when the inhibitionwas elicited either by GTP- $gamma$ -S-containing patch pipette solution(Fig. 5B) (N-type = 112 ± 17 msec; P/Q-type = 91 ± 8 msec; n =7) or by ATP application (N-type = 110 ± 7 msec; P/Q-type = 87± 10 msec; n = 5). Similarly, at $-$ 100 mV (data not shown) therewas no statistically significant difference between the time constantsof reinhibition for the N-type (143 ± 17 msec) and the P/Q-typecurrents (125 ± 11 msec; n = 5).
Fig. 5. Time course of reinhibition is similar for N- and P/Q-type currents. The voltage protocol used is shown at the top. The holdingpotential was $-$ 80 mV, and the test pulse was of 20 msec durationto +20 mV. The test pulse was preceded by a prepulse of 50 msecduration to +100 mV, and the two were separated by an interpulseduring which the cell was repolarized to either $-$ 60 mV or $-$ 80mV. The duration of the interpulse was varied from 5 to 300 msec.The patch pipette solution contained GTP- $gamma$ -S (70 µM) to elicitinhibition. The voltage protocols were repeated before and afterapplication of $omega$ -Cgtx GVIA (1 µM) to isolate the N- and P/Q typecurrents. A, Plotted is reinhibition as a function of interpulseduration at $-$ 60 mV. The increase in current amplitude caused byeach of the prepulses was normalized to that produced by a prepulsefollowed by the shortest duration of interpulse (5 msec). Thedata were fit with a single exponential, giving time constantsof reinhibition of 108 ± 11 msec for the N-type and 105 ± 11 msecfor the P/Q-type currents. B, Plotted is reinhibition at $-$ 80 mV.The time constants of the reinhibition were 112 ± 17 msec forthe N-type current and 91 ± 8 msec for the P/Q-type current.
[View Larger Version of this Image (16K GIF file)]

The voltage dependence of the relief from inhibition was studied by varying the potential to which the prepulse was stepped(Fig. 6). Prepulses to increasingly positive potentials relievemore of the inhibition, so for a prepulse of a fixed durationthe voltage dependence of the relief can be compared for the twocurrent types. The prepulse duration was 10 msec, as was the interpulseduration. Prepulse potential was changed in the range between $-$ 10 mV and +120 mV. The increase in current amplitude for eachprepulse was normalized, and the data were fit with a sigmoidalcurve (Fig. 6). The midpoint of the curve (representing 50% ofmaximal relief from inhibition) was found to be shifted significantlyin the hyperpolarized direction for the P/Q-type current (+40± 1.9 mV) relative to the N-type current (+51 ± 1.8 mV; n = 6;p < 0.001). The slight change in the slope of the curve was notsignificant. Similar data were obtained using ATP to inhibit I_Ca.The midpoint of inhibition was +40 ± 2 mV for the P/Q-type currentand +56 ± 2 mV (n = 6; p < 0.001) for the N-type current. Theexperiments were repeated with a prepulse duration of 100 msecrather than 10 msec. The data were shifted slightly to the leftfor both current types, but there remained a significant differencebetween the two, with a midpoint for the P/Q-type current of +31± 2 mV and for the N-type current of +47 ± 2 mV (n = 4; p = 0.03).
Fig. 6. Comparison of the voltage dependence of the relief from inhibition for N- and P/Q-type channels. The voltage protocol usedis shown at the top. The holding potential was $-$ 80 mV, and thetest pulse was to +20 mV for 20 msec. The duration of the prepulseand interpulse was not varied, and both were 10 msec. The potentialof the prepulse was varied from $-$ 10 to +120 mV. The patch pipettecontained GTP- $gamma$ -S (70 µM) to elicit the inhibition. Voltage protocolswere repeated before and after application of $omega$ -Cgtx GVIA (1 µM)to isolate the N-type and P/Q type currents. The graph plots datafrom six cells in which the increase in amplitude produced byeach of the prepulses was normalized to the increase producedby the most positive prepulse (+120 mV). The data were plottedagainst prepulse potential and fit with a sigmoidal curve.
[View Larger Version of this Image (22K GIF file)]

Comparison of the current-voltage relationship of N- and P/Q-type I_Ca
The hyperpolarized shift in the voltage dependence of relief from inhibition could be attributable to shifts in the gatingof the P/Q-type current relative to the N-type current. This wasinvestigated by comparing the current-voltage relationship forthe two current types, using ramp depolarizations from $-$ 80 to+100 mV. These experiments were performed in choline Cl-basedrecording solution to minimize the contribution of TTX-resistantsodium channels if present. Ramps were performed before and afterapplication of either $omega$ -Cgtx GVIA (to isolate the N-type current)or $omega$ -Aga IVA (to isolate the P/Q-type current). Application of $omega$ -Cgtx GVIA reduced the amplitude of I_Ca and produced a smallbut statistically significant leftward shift in the I/V relationshiprelative to control (Fig. 7A). Application of $omega$ -Aga IVA also reducedthe amplitude and shifted the I/V curve by a similar amount butin the opposite direction (Fig. 7B), indicating that the shiftwas due to genuine differences in the properties of the N- andP/Q-type currents. The mean data revealed a statistically significanthyperpolarized shift (7-10 mV) in the peak of the I/V curve forthe P/Q-type current relative to the N-type current (Table 1).
Fig. 7. Voltage dependence of N- and P/Q-type calcium current I/V curves. A, Three I/V curves are superimposed. The first (control)was obtained before toxin application and so is composed of bothN- and P/Q-type I_Ca. The second was obtained after block by $omega$ -CgtxGVIA (1 µM) and thus represents mainly the P/Q-type current (alongwith the small toxin-insensitive component). Note that in additionto a reduction in amplitude the $omega$ -Cgtx GVIA shifted the I/V curveto the left. The third curve was obtained by subtracting the curveobtained after $omega$ -Cgtx GVIA from that obtained before $omega$ -Cgtx GVIA.This difference I/V represents the pure N-type current and isshifted to the right relative to control. Note that the shiftin reversal potential was apparent only in some cells and wasattributable, at least in part, to a small residual current presentin some cells after leak subtraction. B, In this set of experiments $omega$ -Agatoxin IVA (400 nM) was used to block and isolate P/Q-typeI_Ca. After block with $omega$ -Aga IVA, the I/V curve shifted to theright, and the difference I/V shifted to the left relative tocontrol. Both manipulations reveal that the P/Q-type I/V curveshifted by ~7 mV to the left relative to the N-type I/V curve.
[View Larger Version of this Image (16K GIF file)]

Table 1. Shifts in the peak of the I/V relationships after toxin application

Voltage at which I/V relationship peaked (mV)

Control I/V I/V after toxin Difference I/V

$omega$ -Cgtx GVIA application (n = 9) 26.9 ± 0.6 23.0 ± 0.4 30.6 ± 0.6

$omega$ -Aga IVA application (n = 6) 25.2 ± 1.3 28.1 ± 0.7 21.2 ± 1.2

The voltage at which the I/V relationship peaked was measured before toxin application (control I/V) and after applicationof either 1 µM $omega$ -Cgtx GVIA to block N-type I_Ca or 400 nM $omega$ -AgaIVA to block P/Q-type I_Ca (I/V after toxin). Subtraction of I/Vcurves obtained after toxin application from those obtained beforetoxin application yielded difference I/V curves representing thepure N-type or P/Q-type currents. The shifts after applicationof either toxin relative to control were statistically significant(p < 0.01), as were the shifts between the I/V after toxin andthe difference I/V (p < 0.0003).

The percentage inhibition produced by ATP was examined by using ramp I/V = curves (n = 5), and it was found that there wasno significant difference in the extent of the inhibition overa 30 mV voltage range spanning the peak for both current types(+10 to +30 mV for the P/Q-type I_Ca; +20 to +40 mV for the N-typeI_Ca). The inhibition was proportionally less for both currenttypes at potentials both negative and positive to those statedabove. Hence, the differential inhibition reported in this paperusing step depolarizations (to +20 or +30 mV) were not artifactsgenerated by the shift in gating properties for the two currenttypes.

DISCUSSION

N-type channels are preferentially targeted by ATP
Cultured bovine adrenal chromaffin cells provide a good model in which to compare the inhibition of N- and P/Q-type I_Ca becausethey are voltage-clamped readily, express the currents in an approximately1:1 ratio, and we previously have characterized the inhibitionproduced by ATP (Currie and Fox, 1996). This paper clearly demonstratesthat the N-type I_Ca was inhibited to a greater extent than theP/Q-type I_Ca. A supramaximal dose of ATP (100 µM; EC₅₀ = 0.5 µM)was used to ensure full activation of the receptors before andafter application of either $omega$ -Cgtx GVIA or $omega$ -AGA IVA to isolatethe two currents. This ruled out the possibility that the differencewas due to cell variability or the level of G-protein activationand was confirmed by using GTP- $gamma$ -S to maximally stimulate theinhibition in an irreversible manner.

A small component of current in the chromaffin cells was insensitive to either $omega$ -Cgtx GVIA or $omega$ -Aga IVA. Although not thoroughlyinvestigated, ATP inhibited this current in some cells (Currieand Fox, unpublished data). To ensure that the toxin-insensitivecurrent did not account for the differential inhibition of theN- and P/Q-type I_Ca, we used both $omega$ -Cgtx GVIA and $omega$ -Aga IVA toisolate the currents. Thus, in some cases the residual toxin-insensitivecurrent was included in the N-type I_Ca, and in others it was includedin the P/Q-type I_Ca, but this had little effect on the data becausein all cases the residual current was extremely small.

Using conditioning prepulses, we classified the inhibition as either voltage-sensitive (that component relieved by a prepulse)or voltage-insensitive (that component present after a prepulse).This classification is purely functional, because it is by nomeans clear whether the two components represent different signalingpathways or whether there is only partial reversal of a singleinhibitory mechanism. Nevertheless, it was striking that the voltage-insensitivecomponent of the inhibition accounted for the same percentagereduction of the N- and P/Q-type currents ( $approx$ 20%) and that thedifference in the inhibition was accounted for by the voltage-sensitivecomponent ( $approx$ 45% Vs $approx$ 18%).

Properties of the voltage-sensitive inhibition
Both the N- and P/Q-type currents exhibited the typical characteristics of this type of inhibitory modulation, including slowedactivation kinetics and partial reversal by prepulses to verydepolarized potentials. These characteristics have been incorporatedinto models (Bean, 1989; Elmslie et al., 1990; Boland and Bean,1993; Golard and Siegelbaum, 1993) in which the channels exhibittwo functional gating states, one from which they readily openon depolarization (willing) and one from which they open slowly(reluctant). Activation of the inhibitory pathway (perhaps bindingof the G-protein $beta$ $gamma$ subunit to the channel) shifts a proportionof the channels into the reluctant state, but strong depolarizationscan still open these channels and overcome the inhibition, possiblyby promoting the dissociation of the G-protein subunit or subunitsfrom the channel (but see Kasai, 1992).

Despite the 2.5-fold difference in the magnitude of the voltage-sensitive inhibition, there were only small differences inthe time course for relief from inhibition or for reinhibitionof the two channel types. There was a significant shift in thevoltage dependence of the relief from inhibition (Fig. 6), butthis may be accounted for by the similar shift in the current-voltagerelationships of the two channels ( $-$ 10 mV for the P/Q- relativeto the N-type). In this study the activation in the presence ofinhibitor could not be well fit even with multiple exponentialsand was complicated further by somewhat different Ca²⁺-dependent inactivation kinetics of the N- and P/Q-type currents.This prevented a quantitative comparison, but qualitatively theslowing was similar for the N- and P/Q-type I_Ca. Thus, all ofour data point to there being little difference in the voltage-sensitiveinhibition of the two channel types in terms of the kinetics orvoltage dependence.

What accounts for the differential inhibition of the two channel types?
For the purposes of this discussion we will assume that the voltage-sensitive inhibition is produced by direct interactionof the activated G-protein subunit or subunits with the calciumchannel, as represented by the simple binding scheme below:

(1)

In Equation 1 above, CaCh represents either the N-type or P/Q-type calcium channel, G* the activated G-protein, and k₁ andk_-1 are the forward and back rate constants, respectively. Theinteraction site or sites seem to be on the $alpha$ ₁ subunit of thecalcium channel, because channels expressed in Xenopus oocytesby either $alpha$ _1A or $alpha$ _1B subunits alone are susceptible to G-protein-mediatedinhibition (Roche et al., 1995; Bourinet et al., 1996). Bindingsites for G-protein $beta$ $gamma$ subunits recently have been identifiedin the I-II linker of the $alpha$ _1A and $alpha$ _1B subunits (De Waard et al.,1997; Zamponi et al., 1997), but see Zhang et al. (1996) for areport in which sites in both domain I and the C terminus of the $alpha$ ₁ subunit are involved in G-protein modulation. The calcium channel $beta$ -subunit also plays a role, because it clearly "antagonizes"the inhibition in both native (Campbell et al., 1995) and recombinantchannels (Bourinet et al., 1996).

Assuming a binding model such as (Eq. 1), the fractional occupancy of the channels by G-proteins can be written as:

(2)

The time constant for binding of the G-protein to the channel, for instance during reblock of the channels after a prepulse,is:

(3)

Recently Tsien and colleagues compared the inhibition of cloned $alpha$ _1A and $alpha$ _1B channels expressed in Xenopus oocytes (Zhanget al., 1996). They suggested that variations in the off-rate(k_-1) of the G-protein from the channel explain the differencesin the extent of inhibition (fractional occupancy, Eq. 2) andreinhibition rate (Eq. 3) that they observed for the two channeltypes. Our data obtained in native channels from chromaffin cellsshow that the kinetics of relief from inhibition and reinhibitionbetween the two channel types are very similar, suggesting thatthe off-rate remains unchanged. If there is an increase in theG-protein off-rate (k_-1) for the P/Q-type channels relative toN-type channels, it suggests that the local concentration of activatedG-proteins near P/Q-type channels is lower, such that the kineticsfor the two channel types (Eq. 3) remain similar. Alternatively,the difference in reinhibition rate observed between our studyand that of Zhang et al. (1996) may be attributable to the factthat the channels expressed in the Xenopus oocyte system are notidentical to those in chromaffin cells. These differences mayreside in the $alpha$ ₁ subunit or in accessory subunits. A preliminaryreport showed that the extent of inhibition of currents producedby expression of $alpha$ _1A or $alpha$ _1B alone was similar but that coexpressionof a $beta$ ₃-subunit led to a greater reduction in the inhibition of $alpha$ _1A, as compared with $alpha$ _1B (Roche and Treistman, 1996). This suggeststhat the influence of the calcium channel $beta$ -subunit is criticalin leading to the differential inhibition of the two channel types.

Another explanation of our data is that, rather than the affinity of the G-protein/calcium channel interaction, it is theefficacy with which the bound G-protein exerts its actions thatis different for the two channel types (off-rates and G-proteinconcentrations are similar for the two channel types). However,this explanation is not consistent with the data of Zhang et al.(1996).

N- and P/Q-type calcium channels as targets for regulation of neurotransmission
N-type calcium channels are targets of at least five inhibitory pathways (Hille, 1994), and it now seems that P/Q-type channelsare inhibited in a similar manner. It remains unclear whetherthe voltage-dependent relief from inhibition identifies two distinctpathways or whether there is partial relief of a single pathway.Phosphorylation may mediate the voltage-insensitive inhibitionin at least some cell types (Diversé-Pierluissi et al., 1995).Functionally, the voltage-sensitive inhibition is greater forthe N-type channels and also may provide a more "dynamic" aspectto the inhibition. This would be achieved if there were relieffrom inhibition during trains of action potentials. However, useof short depolarizing steps to mimic action potentials suggeststhat for N-type channels this may be confined to cells capableof firing at very high rates (Penington et al., 1991; Williamset al., 1997). Relief of P/Q-type channel inhibition by actionpotentials may depend on the duration of the action potentialwaveform (Brody et al., 1997).

The nonlinear relationship between intracellular calcium levels and secretion (Heinemann et al., 1994) means that even smallchanges in calcium influx could have profound effects on transmitterrelease. Ultimately, the regulation of neurotransmitter releasewill be due to the summation of many subtle inputs, includingthe inhibition of I_Ca investigated in this paper. There is alsoevidence to suggest that P/Q-type channels may be potentiatedselectively in some systems (Mogul et al., 1993; Huang et al.,1996). Hence, one might envisage a situation whereby the relativeproportion of N- and P/Q-type channels at synapses would be regulatedprecisely. Synapses in which P/Q-type channels dominate wouldbe inhibited less and so would operate over a smaller range (betweenuninhibited and maximally inhibited states) than synapses in whichN-type channels dominate, thus providing a fine tuning of theregulation of release.

FOOTNOTES

Received Dec. 2, 1996; revised March 26, 1997; accepted March 31, 1997.

This work was supported by National Institutes of Health grants to A.P.F. We thank Dr. Zhong Zhou for kindly preparing thechromaffin cells and Dr. Nicholas Saccomano of Pfizer, Incorporated,Groton, CT, for the gift of $omega$ -Aga IVA.

Correspondence should be addressed to Dr. Kevin Currie, The Department of Pharmacological and Physiological Sciences, TheUniversity of Chicago, 947 East 58th Street, Chicago, IL 60637.

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