Effects of the Neuroprotective Agent Riluzole on the High Voltage-Activated Calcium Channels of Rat Dorsal Root Ganglion Neurons

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Vol. 282, Issue 3, 1280-1290, 1997

Effects of the Neuroprotective Agent Riluzole on the High Voltage-Activated Calcium Channels of Rat Dorsal Root Ganglion Neurons¹

Chao-Sheng Huang, Jin-Ho Song, Keiichi Nagata, Jay Z Yeh and Toshio Narahashi

Department of Molecular Pharmacology and Biological Chemistry, Northwestern University Medical School, Chicago, Illinois

	Abstract

Top Abstract Introduction Methods Results Discussion References

The effects of riluzole, a neuroprotective drug, on high voltage-activated (HVA) calcium channels of rat dorsal root ganglionneurons were studied using the whole-cell patch-clamp technique.Riluzole inhibited HVA calcium channel currents in a dose-dependent,time-dependent and reversible manner. The apparent dissociationconstants for riluzole inhibition of the transient and sustainedcomponents of the current were 42.6 and 39.5 µM, respectively.Riluzole accelerated the activation kinetics of calcium channelswithout affecting the voltage dependence of activation. It acceleratedthe fast component of deactivation kinetics without affectingthe slow component. It also accelerated fast and slow inactivationkinetics of the HVA channels. However, only one of the two componentsin the steady-state inactivation curve for the HVA channels wasshifted in the hyperpolarizing direction by riluzole, which indicatesdifferential block of the multiple-type HVA channels. By use ofthe specific blockers nimodipine, $omega$ -conotoxin GVIA and $omega$ -agatoxinIVA, the HVA calcium channels were found to comprise L-type (10%),N-type (63%), P/Q-type (23%) and R-type (9%). Riluzole blockedN- and P/Q-type channels, but not L-type channel, with the orderof efficacy of P/Q- > N- $>>$ L-type channels. Riluzole inhibitionof N- and P/Q-type calcium channels may result in reduced calciuminflux at presynaptic terminals, which thereby decreases excessiveexcitatory neurotransmitter release, especially glutamate, a mechanismknown to cause neuronal death in ischemic conditions.

	Introduction

Top Abstract Introduction Methods Results Discussion References

Riluzole, a novel neuroprotective drug with anticonvulsant, sedative and anti-ischemic properties (Malgouris et al., 1989;Stutzmann et al., 1991; Romettino et al., 1991; Pratt et al.,1992; Bryson et al., 1996), has been used to prolong the survivalof patients with amyotrophic lateral sclerosis (Bensimon et al.,1994; Bryson et al., 1996; Lacomblez et al., 1996).

Ischemic damage is known to be caused by the neurotoxic effects of excitatory amino acids released as a result of hyperexcitationof presynaptic nerves (Choi and Rothman, 1990; Rothman, 1984;Meldrum, 1985; Rothman and Olney, 1986). The excess activationof the glutamatergic receptors, especially the NMDA receptors,causes a massive influx of Ca⁺⁺ through the open channels leading to cell death. Riluzole blockedkainate and NMDA receptors (Debono et al., 1993); this would lessenthe cell damage caused by ischemia. Several lines of evidencesuggested that riluzole inhibited synaptic transmission by reducingthe release of glutamate from the presynaptic nerve terminals(Martin et al., 1993; Boireau et al., 1995; Rothstein and Kuncl,1995).

The neuroprotective effect of riluzole is also known to rely in part on inhibition of sodium channels (Hebert et al., 1994;Benoit and Escande, 1991), because the inhibition of sodium channelswas correlated with postischemic neuronal protection (Prenen etal., 1988; Boening et al., 1989; Yamasaki et al., 1991). Riluzolehad a higher affinity for the inactivated state than the restingstate of sodium channels, which resulted in a selective blockof damaged or depolarized nerve thereby preventing excess stimulationof the glutamatergic receptors (Song et al., 1996).

Because transmitter release from the nerve terminals is mediated by voltage-gated calcium channels, neuroprotective drugssuch as riluzole could also block these channels, thereby preventingexcess release of transmitter. The present study was undertakento test this hypothesis. It was indeed demonstrated that riluzoleblocked the HVA calcium channels, with much higher affinitiesfor N-type and P/Q-type calcium channels than L-type channels.

	Methods

Top Abstract Introduction Methods Results Discussion References

Cell culture

DRG were dissected from the lumbosacral area of newborn Sprague-Dawley rats (1-5 days old) under methoxyflurane anesthesia,and were transferred into Ca⁺⁺-/Mg⁺⁺-free phosphate-buffered saline solution supplemented with 6 g/lD-glucose. The ganglia were digested in this solution added with2.5 mg/ml trypsin (type XI, Sigma Chemical Co., St. Louis, MO)for 25 min at 37°C and then washed with DMEM containing 10% neonatalcalf serum and 0.08 mg/ml gentamicin. The ganglia were dissociatedacutely by repeated triturations with use of a fire-polished Pasteurpipette in 2.0 ml DMEM. The dissociated neurons were plated ontocoverslips coated with poly-L-lysine (0.1 mg/ml, Sigma). Cellswere maintained in DMEM containing neonatal calf serum and gentamicinin a 90% air/10% CO₂ atmosphere controlled at 36°C. Neurons culturedfor less than 2 days were used for experiments. In most experiments,recording began 4 hr after the plating. Cells cultured more than1 day usually develop processes and may result in poor space clampcondition. Any recording with inadequate space clamp, such asthat with slow tail current and slow settling of capacity transient,was discarded.

Electrophysiology. Ionic currents were recorded under voltage-clamp conditions by the whole-cell patch clamp technique (Hamill et al., 1981).Pipette electrodes were made from 1.5-mm (outside diameter) borosilicateglass capillary tubes and had a resistance of 2 megohm when filledwith standard internal solution. The transmembrane voltage wasclamped at $-$ 80 mV. Unless otherwise indicated, a period of 10min was allowed after rupture of the membrane to ensure adequateequilibration between the internal pipette solution and the cellinterior. Cells showing a rundown rate of calcium currents morethan 1%/min were excluded. Membrane currents passing through theelectrode were recorded with an Axopatch amplifier (Axopatch-1B,Axon Instruments, Foster City, CA), and currents were stored inan SX 386 computer (DELL Computer Company, Austin, TX) using pCLAMP6 software (Axon Instruments).

The external and internal solutions for whole-cell current recording were designed to eliminate sodium and potassium channelcurrents. The standard external solution contained (in mM): BaCl₂,10; tetraethylammonium chloride, 130; d-glucose, 25; HEPES, 5;and tetrodotoxin, 200 nM. The standard internal solution contained(in mM): CsCl, 105; HEPES, 40; d-glucose, 5; MgCl₂, 2.5; EGTA10; Mg-ATP, 5; and Li₃-GTP, 0.5. Unless otherwise indicated, thepH of all solutions was adjusted to 7.3 with 1 M CsOH, and theosmolarity was raised to 300 mOsm with sucrose.

Drug application. The recording chamber was perfused continuously with the normal external solution by gravity at a rate of 1 ml/min. Unlessotherwise described, all the drugs were applied to the bath bygravity. The total volume of the chamber was only 1 ml facilitatingthe rate of application and washout of the drug. All experimentswere carried out at a room temperature of 20-23°C.

Calcium channel toxins were dissolved in distilled water to make a stock solution which was divided into 100-µl aliquots andstored at $-$ 20°C. The test solution was pipetted directly to thebath solution to achieve the desired concentration, while thebath perfusion was stopped. Stopping the bath perfusion for lessthan 15 min did not accelerate the rundown of the currents. Thefinal solution also contained 1% cytochrome C to saturate thenonspecific peptide binding to the chamber. Because of the diffusiontime of the toxin in the bath, sometime the onset of the toxinaction was slow. However, we found that a few more pipettingsof the bath solution after addition of the toxin facilitated itsdiffusion and shortened its onset of the effect.

Nimodipine and Bay K 8644 were dissolved in 100% ethanol as 10 mM stock solution, and kept in light-proof containers. Experimentswere performed under restricted light conditions in the presenceof dihydropyridines. Riluzole was dissolved in DMSO at a concentrationof 100 mM and diluted to external solution at the desired concentrationson the day of experiment. The final concentration of ethanol orDMSO was less than 0.3% (v/v), which did not affect calcium channelcurrents.

$omega$ -CTx was purchased from Bachem California (Torrence, CA), nimodipine from Tocris Cookson (St. Louis, MO), and Bay K 8644from Calbiochem (La Jolla, CA). $omega$ -Aga was a gift from Pfizer Inc.(Groton, CT) and riluzole from Mitsui Pharmaceuticals (Tokyo,Japan). All other chemicals were purchased from Sigma ChemicalCo. (St. Louis, MO).

Data analysis. The dose-response relationship of riluzole inhibition of the transient and sustained calcium channel currents was fitted toa sigmoid curve as calculated by the four-parametric logisticfunction equation (Tandel Scientific, Corte Madera, CA):

Ip<IT>=I</IT>max[<IT>Cn/</IT>(<IT>Cn+K</IT><IT>d</IT><IT>n</IT>)] (1)

where I_p represents the inhibition of calcium channel currents recorded at riluzole concentration C, and I_max is the maximalinhibition (%) of calcium channel currents. K_d and n denote thehalf-maximal effective concentration of riluzole and the Hillcoefficient, respectively.

Statistical analysis was done by use of the Student's t test at a significant level of P = .05. Data are given as mean ± S.E.M.with the number of experiments (n).

	Results

Top Abstract Introduction Methods Results Discussion References

Time- and Dose-Dependent Inhibition of HVA Ca⁺⁺ Channel Currents by Riluzole

With 10 mM barium as charge carrier, the T-type calcium channel current was activated by a test pulse to $-$ 40 mV from a holdingpotential of $-$ 80 mV. The current had fast inactivation kineticsand was found in only 15% of the cells tested. A test pulse to $-$ 20 mV from the same holding potential activated the HVA calciumchannel currents which reached the maximal amplitude at a testpulse to 0 mV or 10 mV. Cells generating T-type calcium channelcurrents were discarded to avoid the contamination of HVA calciumchannel currents.

Riluzole was applied to the bath while HVA calcium channel currents were evoked by 200-msec test pulses from $-$ 80 mV to +20mV at 20-sec intervals. Riluzole at 300 µM inhibited the calciumchannel currents, and the effect reached the maximum taking morethan 3 min after bath perfusion (fig. 1). Both peak and steady-stateamplitudes were suppressed. After washout, the riluzole inhibitoryeffect persisted for a while, and a complete recovery usuallytook more than 3 min. In 20% of the cells studied, a rebound to118% of the control current amplitude was observed after washout(fig. 1). The slow onset and offset of the riluzole inhibitoryeffect and the rebound phenomenon suggest that intracellular componentsmay be involved in the riluzole action.

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Fig. 1. Riluzole inhibition of the HVA calcium channel current. Currents are evoked by a step pulse to +20 mV from a holding potentialof $-$ 80 mV at an interval of 20 sec. (A) Current traces a to ecorrespond to currents at times a to e in panel B. (B) Riluzole300 µM inhibits the HVA channel current with a slow onset andoffset. A rebound of the current amplitude occurs after washoutof riluzole.

To study the dose-response relationship for the riluzole block of the HVA calcium channels, different concentrations of riluzolewere perfused cumulatively. Riluzole inhibited both the peak currentand sustained currents measured at the end of 200 msec pulse ina dose-dependent manner, and a complete block occurred at 300µM riluzole. Using equation 1, the dose-response relationshipsfor riluzole inhibition of peak and sustained calcium channelcurrents were fitted to sigmoid curves, which yielded apparentK_d values of 42.6 ± 7.4 µM (n = 10-16) and 39.5 ± 17.26 µM (n= 7-16), and the Hill coefficients of 1.1 ± 0.160 and 0.83 ± 0.212,respectively (fig. 2).

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Fig. 2. The dose-response relationship for riluzole inhibition of the peak transient ( $bullet$ ) and sustained ( $open circle$ ) components of HVA calciumcurrents with apparent K_dvalues of 42.6 ± 7.4 µM (n= 10-16) and 39.5 ± 17.26 µM (n = 7-16), respectively.

Effects of Riluzole on the Kinetics of HVA Calcium Channels

Activation. To study the effect of riluzole on the activation of calcium channel currents, current-voltage (I-V) relationships for thetransient calcium channel currents were plotted by 5-mV incrementalstep pulses from $-$ 80 mV to +75 mV in the absence and presenceof riluzole (fig. 3A). Because the I-V relationship was nonlinearin the positive potential range, the constant field theory (Goldman,1943; Hodgkin and Katz, 1949) was used to calculate the maximalcurrent amplitude at its full activation (Ohmori and Yoshii, 1977,Yoshii et al., 1988). The constant field equation for divalentcations is:

IBa<IT>=</IT>(<IT>4F2 Em/RT</IT>)<IT>×P</IT>Ba[Ba++]o<IT>/</IT>[<IT>1−</IT>exp(<IT>2FEm/RT</IT>)]<IT>,</IT> (2)

where I_Ba denotes the calcium channel current with barium as the charge carrier, F is the Faraday constant, E_m is the membranepotential, R is the gas constant, T is the absolute temperature,P_Ba is the permeability of barium and [Ba⁺⁺]_o is the external barium concentration. By normalizing the observedcurrent amplitudes to the calculated maximal amplitude and byfitting to equation 2, a steady-state activation curve is plottedas a function of membrane potential (fig. 3B). The midpoint potentialsfor the activation curves were $-$ 1.6 ± 0.34 mV, $-$ 2.7 ± 0.23 mVand $-$ 1.2 ± 0.21 mV in the absence of riluzole ( $bullet$ , n = 7), andin the presence of 30 µM ( $black-square$ , n = 7) and 100 µM ( $black-triangle$ , n = 3) riluzole,respectively.

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Fig. 3. Effect of riluzole on the activation of HVA channels. (A) Current-voltage relationships for HVA channels in the absence ( $bullet$ )and presence of 30 µM ( $black-square$ ) and 100 µM ( $black-triangle$ ) riluzole. (B) The voltagedependence of activation curve for HVA channels is fitted by theconstant field equation (see text). Riluzole at 30 and 100 µMreduces the mid-point potential from the control value of $-$ 1.6± 0.34 mV to $-$ 2.7 ± 0.23 mV (n = 7) and $-$ 1.2 ± 0.21 mV, respectively(P > .05). (C) The time to peak of HVA channel currents in thepresence and absence of riluzole is measured as shown in the inset,and the data are plotted as a function of riluzole concentration.(D) The time to peak for HVA channel currents in the absence ( $open circle$ )or presence ( $bullet$ ) of 30 µM riluzole is plotted against the steppulse potential. Riluzole reduction of the time to peak for HVAchannel currents is not voltage dependent (n = 5).

The time to peak of the calcium channel current was measured in a time-expanded record as shown in the inset of figure 3C,and was normalized to that of the control current. Riluzole shortenedthe time to peak in a dose-dependent manner (fig. 3C) with a maximalreduction to 70 ± 3.12% of control (n = 7-18) at a concentrationof 300 µM. Figure 3D shows the time to peak of calcium channelcurrents at different test pulse potentials in the presence andabsence of 30 µM riluzole. There was no voltage dependence inriluzole reduction of the time to peak (n = 5). Thus, riluzoleshortens the time to peak in a dose-dependent and voltage-independentmanner.

Inactivation. To study the kinetics of channel inactivation, calcium channel currents were generated at a test pulse to +20 mV precededby a 5-sec conditioning prepulse to various potentials and werenormalized to the current associated with $-$ 100 mV prepulse. Plotof the normalized current amplitude against the prepulse potentialyielded a steady-state inactivation curve for the calcium channel,which could be fitted by two exponential functions, which indicatesthe existence of at least two groups of HVA calcium channels withdistinct inactivation kinetics (fig. 4A). Riluzole at 30 µM shiftedthe half-inactivation potentials for one group of calcium channelsfrom 48.2 ± 1.31 mV to 55.4 ± 1.70 mV (P < .05), and for the othergroup from $-$ 8.1 ± 1.98 mV to $-$ 9.0 ± 2.53 mV (P > .05) (n = 7).The slope factor was changed by riluzole from 9.6 ± 0.81 mV to11.6 ± 1.29 mV for the former (P < .05), and from 7.6 ± 1.09 mVto 7.91 ± 1.49 mV for the latter (P > .05) (n = 7). Thus, riluzoleselectively shifted the steady-state inactivation curve for onegroup of HVA calcium channels in the hyperpolarizing direction.

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Fig. 4. (A) The steady-state inactivation curve for HVA channels in the absence ( $open circle$ ) and presence ( $bullet$ ) of 30 µM riluzole showing twocomponents. Riluzole shifts the half-inactivation potential from $-$ 48.2 ± 1.31 mV to $-$ 55.4 ± 1.7 mV for one component (P < .05),and from $-$ 8.1 ± 1.98 mV to $-$ 9.0 ± 2.53 mV for the other component(P > .05) (n = 7). (B) Riluzole accelerates the inactivation kinetics.The time course of inactivation of HVA channel currents generatedby step pulses from $-$ 80 mV to +20 mV for a duration of 300 mseccan be fitted to a double-exponential curve. The time constantsof the HVA channel inactivation are reduced by rulizole to 47.5± 5.49% and 41.4 ± 5.71% of control for the fast and slow inactivation,respectively.

The time course of inactivation of calcium channel currents was fitted to two exponential functions. Riluzole reduced boththe fast and slow time constants of calcium channel inactivationto 69.7 ± 8.99% (n = 11) and 79.8 ± 8.43% (n = 8) of controls,respectively, at 3 µM, and to 16.3 ± 8.09% (n = 16) and 24.7 ±7.64% (n = 13) of controls, respectively, at 300 µM (fig. 4B).

Deactivation. The tail current evoked upon step hyperpolarization of the membrane after a depolarizing test pulse reflects the fractionof calcium channels remaining open at the end of the test pulse.The decay component of this tail current represents the deactivationor closure of the activation gate of the channel. With an increasein the duration of depolarizing pulse, the tail current amplitudereached a maximum and gradually decreased (fig. 5, A and B). Toensure the full activation of the channel and to minimize theeffect of inactivation, the subsequent tail current experimentswere performed with a 10-msec test pulse. The rate of decay ofthe tail current varied with the level of repolarization aftera depolarizing pulse to a fixed potential level (fig. 5Ca), andcould be fitted by a double-exponential curve (fig. 5Cb). Figure5D plots the fast time constant against various repolarizing potentialsafter the same depolarizing pulse in the presence and absenceof 30 µM riluzole. Riluzole decreased the fast time constant (fig.5D), but not the slow time constant (data not shown) for the decayof tail current. At repolarizing potentials more positive then $-$ 40 mV, riluzole clearly reduced the fast time constant (n = 7,P < .05), whereas at the more negative repolarizing potentials,this effect was less pronounced because of the fast deactivationkinetics. As shown in figure 5E, the deactivation kinetics didnot change significantly by varying the depolarizing potentialpreceding the same repolarizing potential ( $open circle$ , n = 5). However,riluzole reduction of the fast time constant for the decay oftail current was absent if preceded by large positive depolarizingtest pulses ( $bullet$ , n = 5). Thus, riluzole accelerates the deactivationkinetics of HVA calcium channels by reducing the fast time constantfor the decay phase in a voltage-dependent manner.

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Fig. 5. Effects of riluzole on the deactivation of HVA channels. (A) The tail current amplitude is time dependent. The currents areevoked by step pulses from $-$ 80 mV to +20 mV with 1- to 14-ms durations.(B) Normalized tail current amplitude as a function of pulse duration.(C) HVA channel currents are generated by the same test pulsewhich is followed by repolarization to various potentials. Decayof the calcium tail current is slowed with repolarization to lessnegative potentials (Ca) and can be fitted to a double-exponentialcurve (Cb). (D) Riluzole at 30 µM reduces the fast time constantfor the decay of HVA channel tail current, and the effect is morepronounced at more positive repolarizing potentials. (E) HVA channelcurrents are evoked by the protocol shown in the inset. Plot ofthe fast time constant for the decay of HVA tail current againstthe test pulse potential. Riluzole reduces the fast time constantin a voltage-dependent manner.

Pharmacological Dissection of HVA Calcium Channels

Effects of dihydropyridines. Nimodipine was used as a dihydropyridine antagonist to block the L-type calcium channel current because of its less voltage-dependentaction. Nimodipine at 10 µM suppressed HVA channel currents reversibly(fig. 6A). Bay K 8644 (5 µM), a dihydropyridine agonist knownto prolong the opening of dihydropyridine-sensitive calcium channels(Fox et al., 1987; Nowycky et al., 1985), potentiated HVA calciumchannel currents (fig. 6, A and C). Current traces a to d in figure6B correspond to the currents at times a to d in figure 6A. Subtractingthe current in nimodipine (trace b) from the control current (tracea) yields the L-type current blocked by 10 µM nimodipine, whereassubtracting current trace c from current trace d yields the L-typecurrent in the present of 5 µM Bay K 8644 (fig. 6B2). Thus, 5µM Bay K 8644 potentiated the L-type current 3.1 ± 0.53 times(n = 5). Note that the decay of tail current was prolonged byBay K 8644 (fig. 6B2). To test if 10 µM nimodipine can completelyblock the L-type current, 5 µM Bay K 8644 was applied in the absenceand presence of 10 µM nimodipine (fig. 6C). Bay K 8644 potentiationof the L-type current was observed in the control and was completelyabolished in the presence of 10 µM nimodipine. Thus, nimodipine,at a concentration of 10 µM, was sufficient to block all the L-typecurrent.

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Fig. 6. Effects of dihydropyridines on HVA channel currents. (A) Nimodipine at 10 µM inhibits the HVA channel current and Bay K 8644at 5 µM potentiates it. (B) Current traces a to d were recordedat times a to d of panel A. (C) Nimodipine at 10 µM inhibits 5µM Bay K 8644 potentiation of HVA channel currents. Thus, 10 µMnimodipine inhibits the dihydropyridine-sensitive L-type currentcompletely.

Various types of calcium channels. $omega$ -Aga is known to block the P-type calcium channel (Mintz et al., 1992a, b; Mintz and Bean, 1993). It also blocks the Q-typechannel in certain preparations (Randall et al., 1993; Satheret al., 1993; Wheeler et al., 1994; Randall and Tsien, 1995; Rusinand Moises, 1995). $omega$ -CTx blocks the N-type calcium channel selectively(McCleskey et al., 1987). The residual current insensitive todihydropyridine antagonists, $omega$ -Aga and $omega$ -CTx, is designated asthe R-type current, which can be blocked by the nonspecific calciumchannel blocker CdCl₂ (Ellinor et al., 1993; Zhang et al., 1993;Randall and Tsien, 1995). To separate various types of calciumchannels present in the same cell, 10 µM nimodipine, 1 µM $omega$ -CTx,300 nM $omega$ -Aga and 150 µM CdCl₂ were applied to the bath in sequence(fig. 7A). Current traces a to e in figure 7B represent the currentsindicated at times a to e in figure 7A. Similar to figure 6, L-,N-, P- and R-type calcium channel currents were isolated by subtractingthe current after application of respective blocker from thatbefore application (fig. 7B). Thus, the precentages of L-, N-,P/Q- and R-type calcium channel currents out of the total currentare 10.5 ± 1.10, 62.8 ± 2.35, 22.8 ± 1.81 and 9.1 ± 1.62%, respectively(n = 4-20). To test whether $omega$ -CTx and $omega$ -Aga block part of theL-type current, 10 µM nimodipine was applied in the presence of1 µM $omega$ -CTx and 300 nM $omega$ -Aga (fig. 7C). Nimodipine was able toblock a small portion of the HVA calcium channel current stillremaining in the presence of $omega$ -CTx and $omega$ -Aga. Thus $omega$ -CTx and $omega$ -Agado not seem to block the L-type current.

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Fig. 7. (A) Sequential applications of various calcium channel blockers including 10 µM nimodipine, 1 µM $omega$ -CTx, 300 nM $omega$ -Aga and 150µM CdCl₂. (B) Currents subtracted before and after the administrationof respective HVA channel blockers yield L-, N-, P/Q- and R-typecurrents. (C) Nimodipine 10 µM, applied after 1 µM $omega$ -GTx and 300nM $omega$ -Aga, still blocks the HVA channel current. L-, N-, P/Q- andR-type currents represent 10.5 ± 1.10%, 62.8 ± 2.35%, 22.8 ± 1.81%,and 9.1 ± 1.62% of the total current, respectively (n = 4-20).

Riluzole Inhibition of Various Types of HVA Calcium Channel Currents

Because riluzole affects only one of the two groups contained in the steady-state inactivation curve (fig. 4A), riluzole mayhave selective actions on some of the HVA calcium channels. Toprove this hypothesis, riluzole inhibition of HVA calcium channelcurrents was studied in the presence of various calcium channelblockers. As shown in figure 8, 30 µM riluzole blocked HVA calciumchannel currents by 17.1 ± 0.83%, 17.1 ± 1.49%, 3.9 ± 0.58% and9.3 ± 1.45% in the control (n = 30), in the presence of 10 µMnimodipine (n = 11), 1 µM $omega$ -CTx (n = 11) and 300 nM $omega$ -Aga (n =10), respectively. Thus, $omega$ -CTx-GIVA and $omega$ -Aga-IVA, but not nimodipine,partially block riluzole inhibition of HVA calcium channel currents.

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Fig. 8. Riluzole inhibition of various HVA channel currents. Riluzole at 30 µM inhibits 17.1 ± 0.83, 17.1 ± 1.49, 3.9 ± 0.58 and 9.3± 1.45% in the control (n = 30), in the presence of 10 µM nimodipine(n = 11), 1 µM $omega$ -CTx (n = 11), and 300 nM $omega$ -Aga (n = 10), respectively.

To determine the efficacy of riluzole on various HVA calcium channels, riluzole inhibitory effect was studied further in theabsence and presence of different calcium channel blockers inthe same cell. Nimodipine did not affect riluzole inhibition ofHVA calcium channel currents (fig. 9A), which indicates that theL-type channel is not the target of riluzole. However, riluzolereduced the fast time constant for the decay of tail current inBay K 8644-modified calcium channel from 0.33 ± 0.039 ms to 0.25± 0.034 ms (n = 4, fig. 9, B and C). Thus, riluzole does not affectthe native L-type current, but accelerates the deactivation ofthe Bay K 8644-modified L-type calcium channel.

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Fig. 9. Riluzole inhibitory effect on the HVA channel current is tested in the presence and absence of dihydropyridines in the samecell. (A) Riluzole 30 µM inhibition of HVA channel currents isnot affected by 10 µM nimodipine. (B) Riluzole inhibitory effecton HVA channel currents in the presence of 5 µM Bay K 8644. (C)Riluzole still accelerates the decay of the Bay K 8644-modifiedHVA channel tail current. Thus, 30 µM riluzole does not affectunmodified L-type current, but accelerates the decay of Bay K8644-modified L-type tail current.

Figure 10A shows the riluzole inhibitory effect on the HVA calcium channel current in the presence and absence of 1 µM $omega$ -CTxin a representative cell. Current traces a to d in figure 10B representthe currents at times a to d in figure 10A. Current trace a minuscurrent trace b (a $-$ b), 13.42% of the total HVA current, representsthe portion of the total HVA calcium channel current blocked by30 µM riluzole. Because $omega$ -CTx blocks the N-type current, currenttrace c minus current d (c $-$ d), 4.6% of the total HVA calciumchannel current, equals the portion of the current other thanthe N-type current blocked by 30 µM riluzole. Thus, (a $-$ b) minus(c $-$ d), 8.8%, equals the N-type current that was blocked by riluzole.The total N-type current equals (a $-$ c) 62.8%. Therefore, thepercentage of the total N-type current blocked by 30 µM riluzoleis 14.2% (8.8 $div$ 62.8) in this cell. Through similar calculation,30 µM riluzole blocks 1.7 ± 2.88%, 20 ± 1.84%, 32.5 ± 2.35% ofthe total L- (n = 10), N- (n = 12) and P/Q (n = 10)-type currents,respectively (fig. 10C). Thus, 30 µM riluzole blocks P/Q- and N-typecalcium currents selectively.

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Fig. 10. (A) Riluzole at 30 µM inhibits the current to a lesser extent in the presence of 1 µM $omega$ -CTx than in the absence. (B) Currenttraces a to d were recorded to at times a to d in A. (C) Riluzoleat 30 µM inhibits L-, N- and P/Q-type currents 1.7 ± 2.88%, 20± 1.84% and 32.5 ± 2.35%, respectively.

	Discussion

Top Abstract Introduction Methods Results Discussion References

The HVA channels in neonatal rat DRG neurons contained various types with relative fractions of N- $>>$ P/Q- > L- ~R-type. Riluzoleinhibited these channel types with relative efficacies of P/Q-> N- $>>$ L-type.

HVA calcium channels in rat DRG neurons. There are at least four pharmacologically distinguishable HVA calcium channels in rat DRG neurons, i.e., L-, N-, P/Q- andR-type. Without separating the Q-type current from the P-typecurrent, our results show that 62.8% of the HVA channel currentsare a $omega$ -CTx-sensitive N-type current, 22.8% are a $omega$ -Aga-sensitiveP/Q-type current, and 10.5% are a dihydropyridine-sensitive L-typecurrent. The remaining 9.1% of the HVA channel currents are insensitiveto the these blockers but sensitive to Cd⁺⁺; they are termed as R-type currents.

The HVA calcium channel current of rat DRG neurons contains a strikingly higher percentage of the $omega$ -CTx-sensitive N-type current.This may have several causes. First, calcium channel blockersmay have overlapping effects. In chick sensory neurons, $omega$ -CTxreversibly blocks part of the L-type current in addition to theirreversible inhibition of N-type currents (Aosaki and Kasai,1989

). In contrast, dihydropyridines can partially block the N-typecurrent in DRG neurons (Regan et al., 1991

). Therefore, it ispossible that 1 µM $omega$ -CTx in our study may have blocked the N-typecurrent completely and the L-type current partially, resultingin a larger inhibition of HVA channel currents. However, the administrationof $omega$ -CTx was preceded by nimodipine (fig. 7A) at a concentrationhigh enough to block the L-type current completely, and 10 µMnimodipine, preceded by the application of 1 µM $omega$ -CTx, still blockedthe HVA channel current (fig. 7C). Thus, this is not likely thecase.

Second, rundown of the calcium channel current may have contributed to the calculated percentage of inhibition of HVA channelcurrents by various inhibitors. However, only cells with a rundownrate less than 1%/min within 10 min after rupture of the membranewere used in our experiments. Furthermore, experiments with calciumchannel blockers were completed within 15 min. Thus, rundown ofthe calcium channel current may have played only a minor rolein the calculation of the fraction of various components of HVAchannel currents.

Third, developmental changes are known to occur in the HVA calcium channel density in DRG neurons (Bickmeyer et al., 1993

;Kostyuk et al., 1993

). The HVA channel current responds to calciumchannel blockers in an age-dependent manner (Disterhoft et al.,1993

), which indicates that the proportion of different HVA channelsmay also change with age. Therefore, a higher proportion of theN-type current found in pups with an age of 1 to 5 days in ourstudy may be because of the early age of development. Becausethe N-type calcium channels are located mostly at the nerve terminalscontrolling neurotransmitter release (Dutar et al., 1989

; Levequeet al., 1994), their high expression in DRG neurons at the earlyage of development may play a major role in the synaptic plasticityand transmission.

HVA calcium channel currents other than the N-type current may also play an important role in neurotransmission (Lundy etal., 1991

; Hillyard et al., 1992

; Mintz et al., 1992b

). P-typecurrents are inhibited by $gamma$ -aminobutyric acid in rat Purkinjeneurons (Mintz and Bean, 1993

) and potentiated by adenosine inguinea pig hippocampal neurons (Mogul et al., 1993

). Furthermore,several ligands including carbachol and ( $-$ )-baclofen inhibit theQ-type currents in rat hippocampal neurons. A single type of receptorcan be coupled to several types of calcium channels. Activationof the mu opioid receptor in rat DRG neurons modulates multiplecomponents of HVA calcium channel currents, including P-, Q- andN-type calcium currents (Rusin and Moises, 1995

Differential block of HVA channel currents by riluzole. Riluzole differentially inhibits HVA channel currents. First, riluzole affects only one of the two components of steady-stateinactivation curve for the HVA channel current (fig. 4). Second, $omega$ -CTx and $omega$ -Aga, but not nimodipine, partially abolish riluzolesuppression of HVA channel currents, which indicates the involvementof N- and P/Q-type currents and the exclusion of L-type currentin riluzole's inhibitory effect (fig. 8). Third, the inhibitoryaction of riluzole on the various types of HVA channel currentsis in the order of P/Q- > N- $>>$ L-type currents (fig. 10C). BecauseP- and Q-type currents are different in the inactivation kineticsand the sensitivity to $omega$ -Aga (Randall et al., 1993; Randall andTsien, 1995; Rusin and Moises, 1995), riluzole may not block P-and Q-type currents equally.

Although nimodipine does not block riluzole inhibition of HVA channel currents, thereby excluding its effect on the L-typecurrent, riluzole accelerates the decay of the BAY K 8644-modifiedHVA channel tail current (fig. 9C). This indicates that the BayK 8644-modified L-type current and unmodified L-type current mayhave different affinities for riluzole. This is in line with theevidence that the BAY K 8644-modified L-type channel was differentfrom the unmodified L-type channel in their activation and deactivationkinetics (Grabner et al., 1996

Mechanism of riluzole block of HVA calcium channel currents. The kinetic values of deactivation and inactivation of HVA channel currents are altered by riluzole, but the activation kineticsremains unchanged. Riluzole selectively blocks the sodium channelin the inactivated state without affecting the activation kinetics(Hebert et al., 1994; Benoit and Escande, 1991; Song et al., 1996).However, there are differences between sodium and calcium blockby riluzole. Riluzole blocks sodium channels rapidly and the effectis reversed rapidly after washout, which suggests a direct actionon the channel (Benoit and Escande, 1991; Song et al., 1996).In contrast, the slow time course of the onset and offset of riluzoleinhibitory effect on HVA channel currents suggests an indirectmechanism involving riluzole interactions with some intracellularcomponents. This idea is further supported by the rebound phenomenonafter washout of riluzole, reminiscent of the rebound of baclofeneffect on the calcium channel (Matsushima et al., 1993).

Several lines of evidence indicate that G proteins may be involved in riluzole neuroprotective effects. Riluzole inhibitionof glutamate-induced aspartate release from cerebellar granulecells is abolished by pretreatment of the cells with pertussistoxin (Doble et al., 1992

). Furthermore, riluzole inhibition ofNMDA-, but not veratridine-induced neurotoxicity, is abolishedby pertussis toxin pretreatment (Malgouris et al., 1994

; Hubertet al., 1994

). Riluzole inhibition of HVA channel currents waseliminated by GDP- $beta$ -S or N-ethylmaleimide in the internal solution,whereas pretreatment of DRG neurons with pertussis toxin failedto attenuate riluzole's inhibitory effect, which suggests theinvolvement of the pertussis toxin-insensitive G proteins in riluzolemodulation of HVA channels (Huang et al., in press, 1997).

Because calcium channels control the presynaptic neurotransmitter release, riluzole inhibition of P/Q- and N-type calciumchannels may reduce glutamate release in presynaptic terminalsand thus avoid excess activation of NMDA receptors, which wouldcause massive calcium influx leading to cell death in ischemicbrain insult.

	Acknowledgments

We thank Julia Irizarry for secretarial assistance.

	Footnotes

Accepted for publication May 9, 1997.

Received for publication November 14, 1996.

¹ This work was supported by National Institutes of Health Grant NS14144.

Send reprint requests to: Dr. Toshio Narahashi, Department of Molecular Pharmacology and Biological Chemistry, Northwestern University Medical School, 303 E. Chicago Avenue, Chicago, IL 60611-3008.

	Abbreviations

HVA, high voltage-activated; DRG, dorsal root ganglion; DMEM, Delbecco's Modified Eagle Medium; HEPES, 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid; DMSO, dimethylsulfoxide; $omega$ -CTx, $omega$ -conotoxin GVIA; $omega$ -Aga, $omega$ -agatoxin IVA; I-V, current-voltage; NMDA, N-methyl-D-aspartate, EGTA, [ethylenebis(oxyethylenenitrilo)]tetraacetic acid,.

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				W. van Drongelen, H. Koch, F. P. Elsen, H. C. Lee, A. Mrejeru, E. Doren, C. J. Marcuccilli, M. Hereld, R. L. Stevens, and J.-M. Ramirez Role of Persistent Sodium Current in Bursting Activity of Mouse Neocortical Networks In Vitro J Neurophysiol, November 1, 2006; 96(5): 2564 - 2577. [Abstract] [Full Text] [PDF]

				H. S. Ahn, S. E. Kim, H.-J. Jang, M.-J. Kim, D.-J. Rhie, S.-H. Yoon, Y.-H. Jo, M.-S. Kim, K.-W. Sung, and S. J. Hahn Interaction of Riluzole with the Closed Inactivated State of Kv4.3 Channels J. Pharmacol. Exp. Ther., October 1, 2006; 319(1): 323 - 331. [Abstract] [Full Text] [PDF]

				W-C Chen, H-H Cheng, C-J Huang, C-T Chou, S-I Liu, I-S Chen, S-S Hsu, H-T Chang, J-K Huang, and C-R Jan Effect of Riluzole on Ca2+ Movement and Cytotoxicity in Madin-Darby Canine Kidney Cells Human and Experimental Toxicology, August 1, 2006; 25(8): 461 - 469. [Abstract] [PDF]

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				J. Dunlop, H. Beal McIlvain, Y. She, and D. S. Howland Impaired Spinal Cord Glutamate Transport Capacity and Reduced Sensitivity to Riluzole in a Transgenic Superoxide Dismutase Mutant Rat Model of Amyotrophic Lateral Sclerosis J. Neurosci., March 1, 2003; 23(5): 1688 - 1696. [Abstract] [Full Text] [PDF]

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				T. Narahashi Neuroreceptors and Ion Channels as the Basis for Drug Action: Past, Present, and Future J. Pharmacol. Exp. Ther., July 1, 2000; 294(1): 1 - 26. [Abstract] [Full Text]

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Effects of the Neuroprotective Agent Riluzole on the High Voltage-Activated Calcium Channels of Rat Dorsal Root Ganglion Neurons1

Effects of the Neuroprotective Agent Riluzole on the High Voltage-Activated Calcium Channels of Rat Dorsal Root Ganglion Neurons¹