Long-Lasting Facilitation of 4-Amino-n-[2,3-3H]butyric Acid ([3H]GABA) Release from Rat Hippocampal Slices by Nicotinic Receptor Activation

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Vol. 295, Issue 2, 453-462, November 2000

Long-Lasting Facilitation of 4-Amino-n-[2,3-³H]butyric Acid ([³H]GABA) Release from Rat Hippocampal Slices by Nicotinic Receptor Activation¹

Attila Köfalvi, Beáta Sperlágh, Tibor Zelles and E. Sylvester Vizi

Department of Pharmacology, Institute of Experimental Medicine, Hungarian Academy of Sciences, Budapest, Hungary

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

In this study we explored the effect of the stimulation of nicotinic acetylcholine receptors located on interneurons by measuring4-amino-n-[2,3-³H]butyric acid ([³H]GABA) release and monitoring [Ca ²⁺]_i in superfused hippocampal slices. In the presence of 6-cyano-7-nitroquinoxaline-2,3-dione,(±)-2-amino-5-phosphonopentanoic acid, and atropine, i.e., underthe blockade of N-methyl-D-aspartate and non-N-methyl-D-aspartateglutamate and muscarinic receptors, nicotine did not alter thespontaneous outflow of [³H]GABA, but significantly increased the stimulation-evoked [³H]GABA efflux. This effect of nicotine depended on the time intervalbetween nicotine treatment and electrical stimulus, the concentrationof nicotine (1-100 µM), and the parameters of electrical depolarization.Acetylcholine (0.03-3 mM), and the $alpha$ 7 subtype-selective agonistcholine (0.1-10 mM), also potentiated stimulus-evoked releaseof [³H]GABA, whereas 1,1-dimethyl-4-phenilpiperazinium iodide failedto increase the tritium outflow significantly. The effect of nicotinetreatment was prevented by tetrodotoxin (1 µM) and by the nicotinicacetylcholine receptor antagonist mecamylamine (10 µM), and the $alpha$ 7 subtype-selective antagonists $alpha$ -bungarotoxin (100 nM) and methyllycaconitine(10 nM), whereas dihidro- $beta$ -erythroidine (20 nM) was without effect.Perfusion of 100 µM nicotine caused a [Ca²⁺]_i transient in about one-third of the tested interneurons; however,the response to subsequent electrical stimulation remained unchanged.Inhibition of the GABA transporter system by nipecotic acid (1mM) or by decreasing the bath temperature to 12°C abolished completelythe effect of nicotine to potentiate the stimulation-evoked releaseof GABA. These findings indicate that the activation of $alpha$ 7-typenicotinic receptors of hippocampal interneurons results in a long-lastingability of these cells to respond to depolarization with an increasedrelease of GABA mediated by the transportersystem.

	Introduction

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Hippocampal nicotinic acetylcholine receptors (nAChRs) are important target sites of the well known behavioral and cognitiveeffects of the tobacco alkaloid nicotine (Dani and Heinemann,1996; Lloyd and Williams, 2000). In addition they also serve asthe potential molecular target of endogenous acetylcholine (ACh)released from varicose axon terminals of septal cholinergic afferents(Frotscher and Leranth, 1985) acting on different subtypes ofmuscarinic and nAChRs (Lukas et al., 1999) via synaptic and nonsynapticinteractions (Vizi and Kiss, 1998; Vizi and Lendvai, 1999; Vizi,2000).

The presence of nAChRs in the mammalian hippocampus has been revealed by molecular biological and immunocytochemical studies(Deneris et al., 1988; Freedman et al., 1993; Seguela et al.,1993). Hippocampal nAChRs play an important role in the regulationof noradrenergic neurotransmission (Sacaan et al., 1995, 1996;Clarke and Reuben, 1996; Sershen et al., 1997; Vizi and Lendvai,1999), can stimulate [³H]serotonin release from the dissected slices (Lendvai et al.,1996), and may participate in the modulation of glutamate release(Gray et al., 1996). In addition, a series of electrophysiologicalstudies indicate that the release of $gamma$ -aminobutyric acid (GABA)is also regulated by nAChRs in the hippocampus. Application ofnAChR agonists directly excites hippocampal interneurons, appearingas a depolarization detected by whole-cell patch-clamp or as ahyperpolarization in recordings of hippocampal neurons (Reeceand Schwartzkroin, 1991; Alkondon et al., 1997, 1999; Albuquerqueet al., 1998; Frazier et al., 1998a; McQuiston and Madison, 1999).Recently, it was found that hippocampal GABAergic interneuronsare responsive to the activation of at least two subtypes of nAChR,assembled from $alpha$ 4 and $beta$ 2; and homopentameric $alpha$ 7 subunits, respectively(Alkondon et al., 1997, Jones and Yakel, 1997; McQuiston and Madison,1999). $alpha$ 4 $beta$ 2 subtype is predominantly localized on the terminalor preterminal region, whereas $alpha$ 7-type homopentameric nAChRs arelocated on the somatodendritic region of interneurons, and mediatefast synaptic transmission (Alkondon et al., 1998; Frazier etal., 1998b); moreover, nicotine-responsive interneurons exhibituneven cell-type-specific regional distribution (McQuiston andMadison, 1999). The many types of hippocampal interneurons showa great variety of morphological and functional diversity (Freundand Buzsáki, 1996; Vizi and Kiss, 1998), and they play differentroles in the ensemble of hippocampal neuronal network, e.g., theycan control behavior-dependent electrical activity patterns (Ylinenet al., 1995), synaptic plasticity (Maccaferri and McBain, 1995),and synchronization of large populations of principal cells atslow and fast frequencies (Cobb et al., 1995; Whittington et al.,1995) underlying different aspects of memory formation. Therefore,to understand the precise site of effect of memory enhancementby nicotine it is of crucial interest how nicotinic receptor activationinfluences the release of GABA from the interneurons of thehippocampus.

Early neurochemical studies indicated that nicotine enhanced 4-amino-n-[2,3-³H]butyric acid ([³H]GABA) release from rat hippocampal synaptosomes (Wonnacott etal., 1989) and the regulation of GABA release by nicotinic receptorshas been described in other regions such as globus pallidus andsubstantia nigra (Kayadjanian et al., 1994) and guinea pig corticalslices (Bianchi et al., 1995), although these latter effects provedto be indirect. More recently, Lu et al. (1998) pharmacologicallycharacterized hippocampal nicotinic receptors present on the nerveterminals derived from different brain regions, including thehippocampus. This study identified the $alpha$ 4 $beta$ 2 assembly as the majorsubunit composition responsible for stimulation of GABA releasefrom mouse brain synaptosomes. However, there are no neurochemicaldata on the impact of nicotine receptor stimulation on GABA releasein a more integrated system, i.e., in brain slices, and this enablesthe study of the effect of not only presynaptic but also preterminaland somatodendritic receptors on the release. These receptorsmay be activated by ACh released from both synaptic and nonsynapticvaricosities and by nicotine inhaled duringsmoking.

Therefore, in this report, we have directly measured the spontaneous and the electrically evoked outflow of [³H]GABA from rat hippocampal slices in in vitro release experiments,and explored the effect of nicotinic receptor stimulation. Weshow that the activation of $alpha$ 7-type nicotinic receptors of hippocampalinterneurons results in a long-lasting ability of these cellsto respond to depolarization with an increased release of GABAmediated by the transporter system. In addition the excitatoryeffect of nicotine on intracellular Ca²⁺ level measured from identified CA1 interneurons is alsodemonstrated.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

[³H]GABA Release from Hippocampal Slices. [³H]GABA release experiments were carried out with slight modifications of the technique described in our previous studies(Katona et al., 1999; Vizi and Sperlágh, 1999). Male Wistar rats(140-160 g, breeder; Gedeon Richter Ltd., Budapest, Hungary) weredecapitated and the brain was quickly put into ice-cold Krebs'solution of the following composition: 115 mM NaCl, 3 mM KCl,1.2 mM KH₂PO₄, 1.2 mM MgSO₄, 2.5 mM CaCl₂, 25 mM NaHCO₃, and 10mM glucose. The solution was oxygenated with 95% O₂ and 5% CO₂,and the pH was 7.4. Both hippocampi were rapidly dissected and400-µm-thick slices were cut transversely with a McIlwain tissuechopper and incubated in 1 ml of oxygenated Krebs' solution containing4 µCi of [³H]GABA, specific activity 86.0 Ci/mmol (Amersham Pharmacia BiotechUK Ltd., Buckinghamshire, England) for 60 min at 37°C. The incubatingsolution was supplemented with $beta$ -alanine (1 mM; Tocris CooksonLtd., Bristol, England) to prevent tritium uptake into glial cells(Iversen and Kelly, 1975). After incubation, the slices were rinsedthree times with 6 ml of Krebs' solution, and four slices weretransferred to each of four polypropylene tissue chambers, andperfused continuously with 95% O₂- and 5% CO₂-saturated Krebs'solution (37°C, flow rate of 0.6 ml/min). To minimize the formationof GABA metabolites, the perfusion solution contained aminooxyaceticacid (100 µM; Sigma Chemical Co., St. Louis, MO). Upon terminationof the 50-min preperfusion period, (±)-2-amino-5-phosphonopentanoicacid (AP-5) (10 µM; Research Biochemicals International, Natick,MA), 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) disodium (10µM; Research Biochemicals International), and atropine sulfate(10 µM; EGIS, Budapest, Hungary) were added to the perfusion solutionto block excitatory N-methyl-D-aspartate (NMDA)-, non-NMDA-, andmuscarinic receptor-mediated synaptic transmission, and after10 min, 3-min samples of the effluent were collected and assayedfor [³H]GABA. In the beginning of the ninth sample collection, electricalfield stimulation (except where noted, at 50 V, 10 Hz, 3 ms, 360bipolar square-wave pulses) was applied using a Grass S88 stimulator(Grass Medical Instruments, Quincy, MA) and a pair of platinumringelectrodes.

The nicotinic receptor agonist ( $-$ )-nicotine di-(+)-tartrate (Sigma), 1,1-dimethyl-4-phenilpiperazinium iodide (DMPP; Sigma),acetylcholine iodide (Sigma), and choline chloride (Sigma) wereused in different concentrations ranging from 1 µM to 10 mM, perfusedfor 30 s, 15 min before the electrical field stimulation. In someexperiments nicotine was perfused 1 s, 30, 45, or 60 min beforethe stimulation. The nicotinic receptor antagonists mecamylaminehydrochloride (MEC, 10 µM; Research Biochemicals International),dihydro- $beta$ -erythroidine hydrobromide (DH $beta$ E, from 20 nM to 10 µM;Research Biochemicals International), $alpha$ -bungarotoxin ( $alpha$ -BTX, 100nM; Sigma), methyllycaconitine citrate (MLA, 10 nM; Research BiochemicalsInternational), and the GABA uptake inhibitor (±)-nipecotic acid(1 mM; Sigma) were added to the perfusion solution 30 min beforethe electrical stimulation, and perfused thereafter. Tetrodotoxin(TTX, 1 µM; Sigma) was applied in the Krebs' solution 15 min beforethe perfusion of nicotine and perfused until the end of the experiment.The protein kinase C (PKC) inhibitor staurosporine (100 nM; Sigma)and the chloride channel blockers niflumic acid (100 µM; AldrichChemical Co., Milwaukee, WI) and flufenamic acid (100 µM; AldrichChemical Co.) were added to the Krebs' solution 10 min beforethe sample collection period and their perfusion continued untilthe end of the experiment. Staurosporine was dissolved in dimethylsulfoxide (Sigma), the final concentration of which (0.001% v/v)was found to have no effect on [³H]GABA efflux from rat hippocampal slices. Niflumic acid and flufenamicacid were dissolved in NaOH, producing a final concentration ofNaOH 1.1 × 10⁴ N, which alone did not significantly affect the resting and thestimulation-evoked release of [³H]GABA. When the effect of low bath temperature was tested, thetemperature of the tissue chambers and the perfusion solutionwas fast cooled to 12°C by the Frigomix R thermoelectric device(Braun Instruments, Darmstadt, Germany), before the beginningof the collection period, as described previously (Vizi, 1998

;Vizi and Sperlágh, 1999

). The temperature of the bath was monitoredby a small thermoresistor probe placed in the chamber close tothe slices. In some cases, depolarization by potassium chlorideat the concentration of 50 mM was used instead of electrical stimulation,and the duration of high K⁺ perfusion was 30 s. The composition of KCl solution was as follows:68 mM NaCl, 50 mM KCl, 1.2 mM KH₂PO₄, 1.2 mM MgSO₄, 2.5 mM CaCl₂,25 mM NaHCO₃, and 10 mM glucose. The solution was oxygenated with95% O₂ and 5% CO₂, and the pH was 7.4. In another experiment Ca²⁺-free medium of the following composition was used: 115 mM NaCl,3 mM KCl, 1.2 mM KH₂PO₄, 1.2 mM MgSO₄, 25 mM NaHCO₃, 10 mM glucose,and 1 mM EGTA. The solution was oxygenated with 95% O₂ and 5%CO₂, and the pH was 7.4.

Radioactivity Assay. Previous studies showed that in the presence of aminooxyacetic acid the majority of tritium release under comparable conditionrepresents [³H]GABA (Bernath and Zigmond, 1988). The radioactivity releasedfrom the preparations was measured with a Packard 1900 Tricarbliquid scintillation spectrometer (Canberra, Australia). A 0.5-mlaliquot of the perfusate samples was added to 2 ml of scintillationfluid (Packard Ultima Gold) and counts were determined. To determinethe residual radioactivity, the tissue was weighed and homogenized,and the radioactivity was extracted with 10% trichloroacetic acid.The release of [³H]GABA was calculated in percentage of the amount of radioactivityin the tissue at the sample collection time (fractional release,%). The tissue tritium uptake was determined as the sum release+ the tissue content after the experiment. The release of [³H]GABA evoked by field stimulation (stimulation-evoked release,S) was calculated by the area-under-the-curve (AUC) method, i.e.,subtracting the resting release expected to be released, calculatedfrom the pre- and poststimulation period, from the release evokedby simulation, which lasts until a sample tritium content is equalto the prestimulation period sample contents. All data representthe mean ± S.E. of n observations, except EC₅₀ values, which arepresented as mean (95% confidence interval) from n experiments.EC₅₀ values were estimated by fitting the data to a sigmoidallogistic equation using the program Prism (GraphPad, San Diego,CA). Statistical significance was calculated by the two-tailedStudent's t test, Welch's test, one- or two-way ANOVA followedby Dunnett test, as appropriate, and P < .05 was accepted as significantchange.

[Ca²⁺]_i Measurement in Interneurons of Hippocampal Slices. Wistar rats (16-20 days old) were anesthetized (xylazine; Spofa, Prague, Czech Republic plus ketamine; SelBruHa, Budapest,Hungary) and decapitated. The brain was removed and placed inice-cold cutting solution (composition: 126 mM NaCl, 2.5 mM KCl,26 mM NaHCO₃, 0.5 mM CaCl₂, 5 mM MgCl₂, 1.25 mM NaH₂PO₄, and 10mM glucose, pH 7.4 when continuously bubbled with 95% O₂ + 5%CO₂) for 1 to 5 min. Coronal slices (250 µm in thickness) werecut with a vibratome (Vibratome 1000; TPI, St. Louis, MO), separatedinto left and right halves, and transferred to a mash-bottom holdingchamber containing artificial cerebrospinal fluid (ACSF; 126 mMNaCl, 2.5 mM KCl, 26 mM NaHCO₃, 2 mM CaCl₂, 2 mM MgCl₂, 1.25 mMNaH₂PO₄, and 10 mM glucose) bubbled with a mixture of 95% O₂ +5% CO₂, making the final pH 7.4. After 20- to 25-min incubationat 35.5°C the slices were kept at room temperature until dye loading.For bulk loading of the calcium indicator the slices were incubatedin ACSF supplemented with 5 µM fura-2 acetoxymethyl ester (fura-2/AM)(Molecular Probes, Eugene, OR) and 0.025% (w/v) Pluronic F-127detergent (Molecular Probes) for 45 to 55 min at room temperature.Subsequently the slices were left in ACSF for at least 60 minto ensure fura-2/AM de-esterification. Slices were submerged andsuperfused (2 ml/min) in an experimental chamber mounted on aGibraltar BX1 platform (Burleigh, Fishers, NY) and viewed witha 40× water immersion objective in an Olympus BX50WI (Olympus,Hamburg, Germany) microscope. Field stimulation of the slices(10 Hz, 3 ms, 50 pulses) was performed through platinum electrodesplaced in two opposite sides of the experimental chamber. Interneuronsof the CA1 stratum radiatum and lacunosum moleculare were alternatelyilluminated at wavelengths 340 ± 5 and 380 ± 5 nm with a TILLPolychrome II monochromator (Planegg, Germany). The UV illuminationwas attenuated by means of an adjustable diaphragm installed inthe light path. The emitted light (510 ± 20 nm) was detected bya cooled charged-coupled device camera (Photometrics Quantix;Photometrics, Tucson, AZ) and the system was controlled by theAxon Imaging Workbench 2.2 software. The [Ca²⁺]_i values of cell somata were calculated off-line using the equationof Grynkiewicz et al. (1985): [Ca²⁺]_i = K_d × F_max³⁸⁰/F_min³⁸⁰ × (R $-$ R_min)/(R_max $-$ R) where R is the ratio of emission intensity,exciting at 340 nm, to emission intensity, exciting at 380 nm;R_min is the ratio at zero free Ca²⁺; R_max is the ratio at saturating Ca²⁺; F_max³⁸⁰ is the fluorescence intensity, exciting at 380 nm, for zero Ca²⁺; and F_min³⁸⁰ is the fluorescence intensity at saturating free Ca²⁺. Intensities of cell images were corrected for the actual backgroundfluorescence obtained from locations close to the fura-2-loadedinterneuron. The K_d, F_max³⁸⁰/F_min³⁸⁰, R_min, and R_max values were determined empirically by means ofthe calcium calibration buffer kit with magnesium No. 2 (MolecularProbes). The parameters K_d, F_max³⁸⁰/F_min³⁸⁰, R_min, and R_max characterizing the system were 182, 8.415, 0.314,and 5.735 nM,respectively.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Effect of Nicotinic Receptor Activation on Release of [³H]GABA. Spontaneous [³H]GABA efflux at the beginning of the 15-sample collection period was 0.094 ± 0.008% (n = 16) of the total actualtissue content in the presence of CNQX (10 µM), AP-5 (10 µM),and atropine (10 µM), and remained fairly constant until the endof the experiment. Electrical field stimulation (50 V, 3 ms, 10Hz, 360 pulses) elicited a rapidly increasing tritium overflow(stimulation-evoked release S = 0.76 ± 0.11%, n = 16), which reachedits maximum within 3 min, and declined to the baseline level inthe next 6 min upon termination of the stimulus (Fig. 1).

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Fig. 1. Effect of nicotine ( $open circle$ ; n = 16) (100 µM) on the release of [³H]GABA from hippocampal slices. The slices were superfused for 50 min at a rate of 0.6 ml/min with Krebs' solution. After the preperfusion period, glutamate receptor antagonist CNQX (10 µM) and AP-5 (10 µM) and muscarinic receptor antagonist atropine (10 µM) were added to the perfusion solution for 10 min. Subsequently, 3-min samples were collected and assayed for radioactivity. The release of [³H]GABA was expressed as a fractional release (%; see calculation under Materials and Methods). In the 6th min, nicotine perfusion was applied for 30 s, and then the superfusion of the slices continued with nicotine-free medium. Fifteen minutes later, electrical field stimulation was applied (S: 50 V, 10 Hz, 3 ms, 360 pulses). The values show the mean ± S.E. Asterisks represent significant differences from the control (

; n = 19) value (***P < .001).

Being a nonselective and potent agonist of all known nAChRs, we used nicotine to activate the interneuronal nAChR. Nicotine(1-200 µM) was perfused for 30 s in every experiment, and, exceptwhere noted, 15 min before the electrical field stimulation, andthen the perfusion of the slices was continued with nicotine-freemedium. After the treatment with nicotine, there was no significantchange in the spontaneous [³H]GABA release (0.155 ± 0.017 and 0.151 ± 0.015% before and duringthe perfusion of nicotine, respectively, n = 10, P > .05). Incontrast, [³H]GABA outflow evoked by the subsequent electrical depolarizationwas increased concentration-dependently in preparations that hadbeen exposed to nicotine for 30 s (Figs. 1 and 2): the electricallyevoked outflow of [³H]GABA was found to be 255 ± 55% (n = 6, P < .05), 342 ± 82% (n= 6, P < .05), and 440 ± 62% (n = 19, P < .001) of the controlvalue at 3, 10, and 100 µM nicotine, respectively. The EC₅₀ valueof the potentiation of evoked [³H]GABA release by nicotine was calculated to 4.1 µM (95% confidenceinterval is 2.6-6.4 µM). Nicotine generated a "bell-shaped" concentration-responsecurve, and at 200 µM the electrically evoked release of [³H]GABA was not significantly different from the control, indicatingthe desensitization of the response at this concentration (S =1.78 ± 0.64, n = 7, P > .05) (Fig. 2). Under the same conditions,ACh and DMPP, other agonists of nAChR, and choline, the selectiveagonist of $alpha$ 7 subunit-bearing nAChR (Alkondon et al., 1999

) werealso tested at different concentrations ranging from 3 µM to 10mM. None of these drugs affected significantly the resting releaseof [³H]GABA. Between 30 µM and 3 mM, ACh potentiated the evoked [³H]GABA release concentration-dependently with an EC₅₀ of 147 µM(95% confidence interval is 50.5-426 µM); the maximal responseof ACh obtained at 3 mM concentration (S = 325 ± 87% of control)was not significantly different from the maximal response of nicotine.ACh also generated a "bell-shaped" concentration-response curve,i.e., above 3 mM, less potentiation of [³H]GABA release by ACh was observed; however, this change did notreach the level of significance. In the presence of the selective $alpha$ 7-type nicotine receptor agonist choline (100 µM-10 mM) the evoked[³H]GABA release were also augmented, resulting in a concentration-responsecurve similar to that of ACh (EC₅₀ = 352 µM, 95% confidence intervalis 69 µM-1.79 mM). DMPP, administered in concentrations rangingfrom 0.03 to 1 mM, did not potentiate significantly the evoked[³H]GABA release (Fig. 2).

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Fig. 2. Concentration dependence of the effect of nicotinic receptor agonists on stimulation-induced [³H]GABA release from rat hippocampal slices in the presence of CNQX, AP-5, and atropine. Slices were perfused for 30 s with nicotine in different concentrations ranging from 1 to 200 µM, DMPP (from 30 µM to 1 mM), ACh (from 3 µM to 10 mM), and choline (from 10 µM to 10 mM), respectively, 15 min before the electrical stimulation (50 V, 10 Hz, 360 pulses). The release of [³H]GABA is expressed as fractional release (%) and the evoked release of [³H]GABA was calculated by the AUC method (details under Materials and Methods). The values show the mean ± S.E. of 4 to 19 identical experiments. Asterisks represent significant differences from the control value (*P < .05, **P < .01, ***P < .001). $down-triangle$ , nicotine (EC₅₀ = 4.1 µM);

, choline (EC₅₀ = 352 µM); $black-triangle$ , ACh (EC₅₀ = 147 µM); $open circle$ , DMPP.

The effect of nicotine was found to be dependent upon the time interval between the nicotine perfusion and the electricalfield stimulation. When administered for a similar period (30s) but 1 s and 30 min before the respective field stimulation,nicotine elicited a similar potentiation of evoked [³H]GABA release, suggesting rapid and long-lasting sensitizationof GABA release machinery in response to short challenge of nicotinicreceptor activation (Fig. 3). When the time interval between thenicotine application and the electrical stimulation was increasedto 45 and 60 min, the stimulatory effect of nicotine declinedand no significant potentiation was detectable in the evoked releaseof [³H]GABA(Fig. 3).

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Fig. 3. Time dependence of the potentiating effect of nicotine on the evoked release of [³H]GABA in the hippocampal slice. In the presence of CNQX, AP-5, and atropine, the electrical field depolarization (50 V, 10 Hz, 3 ms, 360 pulses) of the slices occurred 15, 30, 45, 60 min, and immediately (0 min) after the 30-s-long perfusion of nicotine (100 µM). The time interval between the perfusion of nicotine and the electrical depolarization of the slices is shown on the x-axis. The release of [³H]GABA is expressed as fractional release (%) and the evoked release of [³H]GABA was calculated by the AUC method (details under Materials and Methods). All values show the mean ± S.E. of 5 to 7 identical experiments. Asterisks display significant differences from the mean of control measured without previous nicotine perfusion (dashed line, ***P < .001).

Because a number of publications showed that under different stimulation conditions release of GABA may occur either via exocytosisor via reversed transporter system, and could be derived fromdifferent neuronal populations (Bernath and Zigmond, 1988

), itseemed to be important to explore the effect of nicotine at differentstimulation conditions. The influence of stimulation parameterson nicotine-enhanced evoked [³H]GABA release is shown in Fig. 4. The action of nicotine to potentiatethe evoked [³H]GABA release strongly depended on the voltage of stimulation:at higher stimulation voltage (50 V) the potentiation was morepronounced than at lower voltage (35 V), and at 25 V the potentiationdid not reach the level of significance (Fig. 4). The effect ofnicotine also exhibited frequency dependence, i.e., its effectwas abolished when the stimulation frequency was decreased to2 Hz, notwithstanding the same number of pulses was applied (360shocks) (Fig. 4).

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Fig. 4. Voltage and frequency dependence of the effect of nicotine (100 µM) on stimulation-evoked [³H]GABA release from rat hippocampal slices. Slices were exposed to 30-s perfusion of nicotine (100 µM) and 15 min later electrical field stimulation was applied with varying stimulation voltage (25-50 V) or frequency (2-10 Hz) but constant impulse duration (3 ms) and number of shocks (360 pulses). In control experiments slices were stimulated identically, but without previous application of nicotine. CNQX, AP-5, and atropine were present in the perfusion solution in every experiment. The release of [³H]GABA is expressed as fractional release (%) and the evoked release of [³H]GABA was calculated by the AUC method (details under Materials and Methods). Data represent the mean ± S.E. of 6 to 19 identical experiments. Asterisks display significant differences from the mean of control measured without previous nicotine perfusion (*P < .05, ***P < .001).

The effect of nicotine (100 µM) was also tested on [³H]GABA release evoked by high potassium depolarization. Perfusion of KCl(50 mM) for 30 s elicited a rapidly increasing [³H]GABA outflow that returned to the resting release in the next3 min upon termination the KCl perfusion (S = 0.39 ± 0.11%, n= 2). When nicotine was perfused at 100 µM 15 min before the stimulationby high K⁺, no change in evoked [³H]GABA release was observed (S = 0.44 ± 0.05%, n = 2, P > .05).

In our experiments, $alpha$ -BTX (100 nM) and MLA (10 nM), selective antagonists of $alpha$ 7 subunit-containing nAChR (Alkondon et al.,1992

; Freedman et al., 1993

; Clarke and Reuben, 1996

; Jones andYakel, 1997

), had no effect alone on the resting and the evoked[³H]GABA efflux. On the other hand, both $alpha$ -BTX and MLA completelyabolished the effect of nicotine (100 µM) on the evoked releaseof [³H]GABA (Fig. 5). Other nicotinic antagonists such as DH $beta$ E, at20 nM, a concentration blocking selectively the $alpha$ -BTX-insensitivenAChR, had no influence on the effect of nicotine to potentiatethe evoked release of [³H]GABA, whereas at higher concentrations (100 nM-10 µM) a partialor complete blockade was observed. The nonselective nAChR receptorantagonist MEC (10 µM) was also effective in preventing the actionof nicotine to potentiate evoked [³H]GABA release (Fig. 5).

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Fig. 5. Inhibition of the effect of nicotine (100 µM) on stimulation-induced [³H]GABA release by nAChR antagonists. Perfusion of each antagonists started 10 min before the sample collection period and continued until the end of the experiment. The experimental protocol was otherwise identical with that shown in Fig. 1. $black-square$ show the results obtained in experiments without nicotine perfusion;

show the results obtained in experiments when slices were challenged to 30-s perfusion of nicotine. The release of [³H]GABA is expressed as fractional release (%) and the evoked release of [³H]GABA was calculated by the AUC method (details under Materials and Methods). The columns represent the mean ± S.E. of 5 to 19 identical experiments. Asterisks show significant differences from respective controls (*P < .05, **P < .01, ***P < .001).

Effect of Nicotine Perfusion on Evoked Release of [³H]GABA under Ca²⁺-Free Conditions. Because nAChRs are known to be ligand-gated Ca²⁺ channels, it was important to test the Ca²⁺ dependence of the effect of nicotine on the evoked release of[³H]GABA. Perfusion of Ca²⁺-free medium was started 20 min before the sample collection period,and changed to normal Krebs' solution 5 min after the 30-s perfusionof nicotine (100 µM). In Ca²⁺-free medium, the amount of the resting outflow of [³H]GABA was significantly increased (0.39 ± 0.02 and 0.19 ± 0.03%,n = 4, P < .001), but returned to the basal level in the next12 min after changing to normal Krebs' solution (Fig. 6). Whennicotine was perfused in the absence of external Ca²⁺, release of [³H]GABA evoked by subsequent electrical field stimulation, nowin the presence of Ca²⁺, was not significantly different from that measured in the absenceof nicotine (S = 0.59 ± 0.07 and 0.56 ± 0.02%, n = 4, P > .05;Fig. 6).

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Fig. 6. External Ca²⁺ dependence of the effect of nicotine ( $open circle$ ; n = 4) (100 µM) on the release of [³H]GABA from hippocampal slices. Perfusion of Ca²⁺-free medium supplemented with 1 mM EGTA was started 20 min before the sample collection period, and changed to normal Krebs' solution after 5 min of 30-s nicotine (100 µM) perfusion as indicated by horizontal bars. Subsequently, electrical field stimulation was applied (S: 50 V, 10 Hz, 3 ms, 360 pulses). Both solutions were supplemented with CNQX (10 µM) and AP-5 (10 µM), and atropine (10 µM). The values show the mean ± S.E.

, Ca²⁺ free without nicotine, n = 4.

Effect of Nicotine Perfusion on [Ca²⁺]_i in Interneurons in CA1 Hippocampal Region. To examine the effect of nicotine on the level of intracellular Ca²⁺ that can regulate several intracellular signaling pathways, influencingcell function on a longer-lasting time scale (Berridge, 1993)we simulated the conditions in [³H]GABA release experiments and measured [Ca²⁺]_i in the soma of individual interneurons of the CA1 stratum radiatumand lacunosum moleculare layer of hippocampal slices. Perfusionof 100 µM nicotine caused a 108 ± 26 nM increase in the [Ca²⁺]_i (3.1 ± 0.7 times increase compared with the basal [Ca²⁺]_i) in 7 of 20 interneurons (35%). Figure 7A shows a representativeexperiment. The rest of the interneurons (13) were not respondingat all for this type of administration of nicotine. Electricalfield stimulation (10 Hz, 3 ms, 50 pulses) after nicotine administrationelicited an 85 ± 13 nM [Ca²⁺]_i transient (2.6 ± 0.2 times increase, n = 20), which did notdiffer significantly from the effect of field stimulation appliedin the absence of previous nicotine administration (65 ± 9 nMor 2.9 ± 0.2 times elevation, n = 13, P > .05). When the effectof nicotine was tested in the presence of 10 nM MLA only 2 interneurons(15%) responded by a 37 ± 20 nM increase in [Ca²⁺]_i (1.6 ± 0.03 times enhancement) and 11 remained silent (Fig.7B). In the presence of 10 µM MEC none of other 10 examined interneuronsresponded for nicotine.

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Fig. 7. Representative recordings showing the effect of nicotine perfusion on [Ca²⁺]_i of rat hippocampal CA1 interneurons. A, perfusion of 100 µM nicotine induced a [Ca²⁺]_i transient in an interneuron located at the stratum lacunosum moleculare. B, in the presence of the nicotinic receptor antagonist MLA (10 nM), nicotine failed to enhance [Ca²⁺]_i in 11 of 13 tested interneurons; a CA1 stratum radiatum interneuron. Perfusion of AP-5 (10 µM), CNQX (10 µM), and atropine (0.1-1 µM) started 13 min before and continued until the end of the measurements. Field stimulation (10 Hz, 3 ms, 50 pulses) was delivered through platinum electrodes. Cells were loaded with fura-2/AM and [Ca²⁺]_i of the soma of the interneurons was measured. Light-transmitted DIC images show the respective interneurons the traces were recorded from. Pseudocolor ratio images indicate the [Ca²⁺]_i in the somata of the perfused interneurons at time point before and after nicotine administration.

Effect of PKC and Chloride Channel Inhibition on Nicotine Potentiation of Evoked Release of [³H]GABA. To test the involvement of PKC enzyme in the long-lasting potentiation of [³H]GABA release after short challenge of nicotinic receptor activation,the effect of the nonselective PKC inhibitor staurosporine wasalso examined. Staurosporine at 100 nM concentration was ineffectiveto change nicotine-induced potentiation of [³H]GABA release (data not shown). Similarly, flufenamic acid (100µM) and niflumic acid (100 µM), inhibitors of Cl conductance associated with the activation of $alpha$ 7-type nAChR (Seguelaet al., 1993) did not affect increased evoked release in responseto nicotine application (data notshown).

Effect of Sodium Channel Inhibition on Nicotine-Induced Potentiation of Evoked Release of [³H]GABA. To examine the sensitivity of the effect of nicotine and the subsequent sensitization of the release apparatus to the Na⁺ channel blocker TTX (1 µM) separately, two different applicationprocedures were used. When TTX was administered 10 min beforethe sample collection period, and it was redrawn after nicotineapplication, nicotine (100 µM) was ineffective to potentiate theevoked release of [³H]GABA (S = 0.85 ± 0.14%, n = 4, and S = 0.61 ± 0.18%, n = 4,in the presence and absence of nicotine, respectively; P > .05;Fig. 8). Similar findings were obtained when TTX was introducedafter nicotine stimulation and perfused throughout the experiments:no significant potentiation of evoked release of [³H]GABA was observed in response to previous nicotine application(100 µM) under these conditions (S = 0.91 ± 0.46%, n = 6, andS = 0.54 ± 0.21%, n = 6, in the presence and absence of nicotine,respectively; P > .05; Fig. 8).

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Fig. 8. Inhibition of sodium channels by TTX (1 µM) prevented the effect of nicotine (100 µM for 30 s) to potentiate the release of [³H]GABA induced by electrical field stimulation (50 V, 10 Hz, 360 pulses). A, TTX perfusion was started 10 min before the sample collection period and finished 12 min before the electrical stimulation. The experimental protocol was otherwise identical with that shown in Fig. 1, i.e., nicotine was administered 15 min before the electrical stimulation, in the presence of TTX. B, TTX was perfusion was started 12 min before the electrical stimulation and continued until the end of the experiment. $black-square$ show the results obtained in experiments without nicotine perfusion;

show the results obtained in experiments when slices were challenged to 30-s perfusion of nicotine. The release of [³H]GABA is expressed as fractional release (%) and the evoked release of [³H]GABA was calculated by the AUC method (details under Materials and Methods). The columns represent the mean ± S.E. of 4 to 19 identical experiments. Asterisks show significant differences from respective controls (***P < .001).

Role of Membrane Transporters in the Effect of Nicotine. Because it has been shown previously (Nicholls, 1989; Bernath et al., 1993) that intraterminal sodium accumulation, due tostrong depolarizing stimuli, may reverse the GABA transporterand elicit GABA release into the extracellular space, the involvementof the GABA transporter in the effect of nicotine was also examined.To separate carrier-mediated and vesicular release of GABA, lowtemperature and the selective GAT1 GABA transporter inhibitornipecotic acid (do Nascimento et al., 1998) were tested in ourexperiments. Cooling the bath temperature to 12-17°C results inthe inactivation of integral transporter proteins of cell membrane,a method useful to distinguish between carrier-mediated and exocytoticrelease of GABA (Vizi, 1998; Vizi and Sperlágh, 1999). Figure9 demonstrates the results obtained in those experiments thatwere performed at 12°C. Although the resting outflow of [³H]GABA remained unchanged (0.085 ± 0.0087%, n = 16, and 0.066± 0.0023%, n = 4, at 37 and 12°C, respectively; P > .05), thestimulation-evoked [³H]GABA outflow was approximately 1.7 times higher at 12°C thanat 37°C (Fig. 9), which might be due to the blockade of the inwardtransport of the released GABA. At low temperature, nicotine (100µM) was completely ineffective to increase stimulation-evoked[³H]GABA outflow (Fig. 9).

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Fig. 9. Low temperature (12°C) or nipecotic acid (1 mM), both inhibits the GABA transport system, fully abolished the effect of nicotine (100 µM) on electrical stimulation-induced [³H]GABA release. Nipecotic acid perfusion was started 10 min before the sample collection period and continued until the end of experiment. The experimental protocol was otherwise identical with that shown in Fig. 1. $black-square$ show the results obtained in experiments without nicotine perfusion;

show the results obtained in experiments when slices were challenged to 30-s perfusion of nicotine. The release of [³H]GABA is expressed as fractional release (%) and the evoked release of [³H]GABA was calculated by the AUC method (details under Materials and Methods). The values represent the mean ± S.E. of 4 to 19 identical experiments. Asterisks show significant differences from respective control (***P < .001) or from 37°C control (*P < .05), as indicated.

In subsequent experiments, nipecotic acid was applied in a concentration of 1 mM, which inhibits GABA uptake into brain slicesby 99% (Krogsgaard-Larsen and Johnston, 1975

). Nipecotic acidis taken up preferentially by carriers, and this may result inheteroexchange or enhanced countertransport of intracellularlystored GABA, and preservation of released GABA in the extracellularspace, which lead to an increased net GABA efflux (Szerb, 1982

;Bernath and Zigmond, 1988

). According to these, in our experiments,nipecotic acid greatly enhanced the basal GABA outflow (2.34 ±0.11%, n = 4, P < .01). The evoked release of [³H]GABA also tended to increase in the presence of nipecotic acid,but it did not reach the level of significance (Fig. 9). However,in the presence of nipecotic acid, nicotine (100 µM) failed toincrease stimulation-evoked release of [³H]GABA (Fig. 9).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

In this study we explored the effect of the activation of nAChRs located on hippocampal GABAergic interneurons by 1) measuringGABA release from superfused hippocampal slices at rest and inresponse to depolarizing stimuli, and 2) monitoring [Ca²⁺]_i in individual hippocampalinterneurons.

Modulation of GABA Release by Nicotinic Agonists. Recent electrophysiological findings indicated that functional $alpha$ 4 $beta$ 2-like and $alpha$ 7-type nicotinic ACh receptors are present onsubsets of hippocampal interneurons (Alkondon et al., 1997, 1998;Frazier et al., 1998a,b; McQuiston and Madison, 1999). Nevertheless,application of nicotinic agonists, i.e., nicotine, ACh, and cholinefailed to affect basal [³H]GABA outflow in our experiments, which could be explained by1) only a subpopulation of interneurons express nAChR, and inour model, where the outflow of GABA from the whole slice is measured,no change in the overall [³H]GABA outflow is detectable; 2) because a number of studies showedthat subthreshold doses of nicotine readily desensitize nicotinicreceptors (Frazier et al., 1998; Lu et al., 1999) it might occurunder our experimental conditions that desensitization of nAChRis gradually developed by subactivating concentrations of nicotinereaching the perfusion chamber earlier than the bulk of nicotine-containingsolution; or 3) by the simple activation of somatodendritic orpreterminal nAChR by nicotinic agonists is ineffective to elicitrepetitive action potentials spreading to axon terminals and giverise to detectable GABA release; instead, subsequent depolarizationis necessary to amplify the signal of nicotinic receptor activationto result in a measurable amount of GABA release. Indeed, whenthe interneurons were depolarized synchronously by electricalfield stimulation at 10 Hz, a strongly increased [³H]GABA outflow was observed after perfusion of slices by nicotinicreceptor agonists nicotine, choline, and ACh. Because the excitatorytransmission was blocked by CNQX, AP-5, and atropine, it is unlikelythat nicotine acted indirectly upon GABAergic cells by facilitatingexcitatory neurotransmission during the electrical field stimulation.In addition, it can also be exluded that disinhibiton of GABAergiccells was the reason for the increased [³H]GABA release because activation of nicotinic receptors is knownto excite the neurons (Gray et al., 1996; Jones and Yakel, 1997;Albuquerque et al., 1998; McQuiston and Madison, 1999). Thus,it is concluded that the direct activation of interneuronal nAChRby nicotine treatment was responsible for the potentiation ofelectrical depolarization-dependent [³H]GABA outflow. The effect of nicotine, ACh, and choline dependedon their concentration; however, nicotine, above 100 µM, and ACh,above 3 mM, did not enhance the evoked [³H]GABA release significantly, which may result from uncouplingof intracellular signaling machineries to supramaximal activationof nAChR or recruitment of other nAChRs at these concentrationthat directly or indirectly inhibits GABA release. Another nicotinicagonist DMPP was ineffective to induce significant potentiationof evoked [³H]GABA release, indicating that it is a weak agonist at this receptor,similarly to chick $alpha$ 7 expressed in Xenopus oocytes (Bertrand etal., 1992). Moreover, DMPP shows anomalous behavior consistentwith channel block at rat $alpha$ 7 (Seguela et al., 1993) and exhibitsCa²⁺-independent and mecamylamine-insensitive action when tested onstriatal [³H]dopamine efflux (El-Bizri and Clarke, 1994; Clarke and Reuben,1996).

Nicotinic Receptor Subunits Participating in the Modulation of Evoked [³H]GABA Release. In this study we have described the effect of different nicotinic receptor agonists on electrically evoked [³H]GABA release, and the sensitivity of nicotine-enhanced evoked[³H]GABA release to the blockade by a variety of nAChR antagonists.The reversal of the effect of nicotine by $alpha$ -BTX or MLA, whichare $alpha$ 7 subtype-selective antagonists in nanomolar range (Alkondonet al., 1992; Clarke and Reuben, 1996), and the effectivenessof the $alpha$ 7 subtype-selective agonist choline to elicit a similarpotentiation (Alkondon et al., 1999) strongly suggest the participationof $alpha$ 7 subunit-bearing nAChR in the effect of nicotine. In contrast,DH $beta$ E at nanomolar concentration, at which it antagonizes $alpha$ 4 $beta$ 2receptors mediated currents in culture (Alkondon and Albuquerque,1993) and in slice (Alkondon et al., 1999), had no effect. AlthoughDH $beta$ E, when applied at high concentration, and MEC, the nonselectivenAChR antagonist, also prevented the action of nicotine, whichwould be suggestive for the involvement of other subunit assemblies,these findings rather indicate that DH $beta$ E and MEC have activityon hippocampal $alpha$ 7-type nAChR. Indeed, $alpha$ 7 receptor-mediated typeIA currents have been also shown to be sensitive to DH $beta$ E in themicromolar range in hippocampal neurons (Alkondon and Albuquerque,1993), slice (Alkondon et al., 1999), and Xenopus oocyte (Bertrandet al., 1992). Similarly, ACh-evoked, $alpha$ 7-mediated currents recordedfrom hippocampal neurons (Alkondon and Albuquerque, 1993), andfrom interneurons in the hippocampal slice (Jones and Yakel, 1997),were inhibited by MEC in concentrations that used in our study.Furthermore, GABA release initiated by $alpha$ 4 $beta$ 2-like receptor activationproved to be $alpha$ -BTX insensitive and only partly TTX sensitive inhippocampal synaptosomes (Lu et al., 1998), whereas both $alpha$ -BTXand TTX completely abolished potentiation of [³H]GABA release by nicotine in the present study. These findingssuggest that the receptor population responsible for the two effectsis different, and the involvement of the $alpha$ 4 $beta$ 2 subtype in thisparticular effect of nicotine does not appearlikely.

Mechanism Underlying the Facilitation of [³H]GABA Release by Nicotine. Neuronal nAChR are ligand-gated ion channels that are more permeable to Ca²⁺ than their neuromuscular nAChR counterpart (Seguela et al., 1993).ACh, by opening the ion channel of its receptors and causing abrief inward Ca²⁺ and Na⁺ current, can elicit action potentials, which may result in subsequentCa²⁺ influxes via voltage-dependent Ca²⁺ channels (Barrantes et al., 1995), and may also regulate targetcell function via Ca²⁺ level-dependent processes in a longer time scale (in the rangeof minutes) (Berridge, 1993).

In fluorescence ratio-imaging measurements, nicotine, administered by perfusion like in the [³H]GABA release experiments, caused a [Ca²⁺]_i transient in about one-third of the investigated interneurons,which was comparable or even higher than the field stimulation-inducedtransients. The proportion of nicotine-responsive interneuronswas somewhat less than observed in electrophysiological studies(Alkondon et al., 1999

, McQuiston and Madison, 1999

), which mightbe explained by the different application protocol used in ourexperiments. Nevertheless, nicotine perfusion did not affect [Ca²⁺]_i transient in response to the subsequent electrical stimulus,indicating that the potentiation of GABA release by nicotine mightbe the result of nicotine-induced elevation of [Ca²⁺]_i, but not due to the potentiation of electrical stimulation-inducedsomatodendritic Ca²⁺ signal. In addition, inhibitors of signal transduction systems,known to be coupled to nAChR, such as Cl channel (Seguela et al., 1993

) and PKC (Nishizaki and Sumikawa,1998

) inhibitors were ineffective to reverse the effect ofnicotine.

On the other hand, the stimulatory action of nicotine on evoked [³H]GABA release has been found to be completely prevented by TTX,the sodium channel inhibitor, when it was perfused during butnot after nicotine application. These findings implicate thatthe effect of nicotine to induce GABA release needs depolarizationand activation of Na⁺ channels before the subsequent electrical depolarization. Furthermore,nicotine-induced potentiation was dependent upon the depolarizationparadigm used for stimulation of GABA release (Fig. 4), and didnot manifest without electrical depolarization (Fig. 1 and datawith KCl depolarization). These observations all suggest thatthe key event in the nicotine-induced potentiation of GABA releaseis the membrane depolarization and subsequent sodium channel activation,whereby activation signal initiated at the receptor site couldspread to the release sites in the nerve terminals. Because itis well known that sodium accumulation due to prolonged depolarizationmay reverse the direction of GABA transporters and produce GABAliberation (Nicholls, 1989

; Bernath et al., 1993

), the participationof membrane transporters in the effect of nicotine was also tested.Indeed, when GABA transporters were inhibited by decreasing thebath temperature to 12°C, or by the selective GAT1 GABA transporterinhibitor nipecotic acid, no potentiation of evoked [³HGABA release by nicotine was observed. As TTX prevented thiseffect when applied after nicotine application, it appears thatthe effect of nicotine on the GABA transporter is indirect, andthe underlying mechanism might be the sodium-dependent reversalof thecarrier.

In summary, nicotine and ACh, activating the nAChRs located on interneurons, elicit a long-lasting facilitation of depolarization-inducedGABA release by the reversal of the GABA uptake system. This processprobably involves the $alpha$ 7 subtype of nAChR, requires the activationof sodium channels, depends on the nature of depolarization, andlasts for approximately 30 min after removal of nicotine. Becauserecent observations suggest that nicotine-responsive interneuronsprimarily innervate the input area of CA1 pyramidal cells (McQuistonand Madison, 1999

) mediating feed forward and feedback inhibitionand leaving unaffected their output area, long-lasting potentiationof GABA release from these neurons is a potential mechanism wherebythe synchronous activity of pyramidal cells could be effectivelycontrolled. Given the current view that tonic low-dose exposureof nicotine, analogous with smoking, rather desensitize than activatenicotinic receptors (Olale et al., 1997

) removal of this inhibitorycontrol therefore enhances the synchronization of large ensemblesof pyramidal cells and may serve as an explanation of the wellknown memory enhancement in response to the abuse drugnicotine.

	Acknowledgment

We thank Dr. Norbert Hàjos for continuous expert support with the hippocampal slice preparation used in [Ca²⁺]_i imagingexperiments.

	Footnotes

Accepted for publication June 27, 2000.

Received for publication April 3, 2000.

¹ This work was supported by a Philip Morris research grant and by the grants of Hungarian Research Foundation (OTKA), and theHungarian Medical Research Council (ETT). Some information containedin this article was presented in preliminary form at the 29thAnnual Meeting of Society for Neuroscience in Miami Beach, Florida(Sperlágh et al., 1999).

Send reprint requests to: Beáta Sperlágh, Institute of Experimental Medicine, Hungarian Academy of Sciences, P.O. Box 67, Budapest, H-1450, Hungary. E-mail: sperlagh{at}koki.hu

	Abbreviations

nAChR, nicotinic acetylcholine receptor; ACh, acetylcholine; GABA, $gamma$ -aminobutyric acid; [³H]GABA, 4-amino-n-[2,3-³H]butyric acid; AP-5, (±)-2-amino-5-phosphonopentanoic acid; CNQX, 6-cyano-7-nitroquinoxaline-2,3-dione; NMDA, N-methyl-D-aspartate; DMPP, 1,1-dimethyl-4-phenylpiperazinium iodide; DH $beta$ E, dihydro- $beta$ -erythroidine; $alpha$ -BTX, $alpha$ -bungarotoxin; MEC, mecamylamine; MLA, methyllycaconitine; TTX, tetrodotoxin; PKC, protein kinase C; S, stimulation-evoked release; AUC, area-under-the-curve; ACSF, artificial cerebrospinal fluid; fura-2/AM, fura-2 acetoxymethyl ester.

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