Acute Effects of Ethanol on Kainate Receptors with Different Subunit Compositions

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Vol. 288, Issue 3, 1199-1206, March 1999

Acute Effects of Ethanol on Kainate Receptors with Different Subunit Compositions¹

C. Fernando Valenzuela and Rita A. Cardoso

Department of Neurosciences, University of New Mexico Health Sciences Center, Albuquerque, New Mexico (C.F.V.); and Department of Pharmacology, University of Colorado Health Sciences Center, Denver, Colorado (R.A.C.)

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

Previous studies showed that recombinant homomeric GluR6 receptors are acutely inhibited by ethanol. This study examined theacute actions of ethanol on recombinant homomeric and heteromerickainate (KA) receptors with different subunit configurations.Application of 25 to 100 mM ethanol produced inhibition of a similarmagnitude of both GluR5-Q and GluR6-R KA receptor-dependent currentsin Xenopus oocytes. Ethanol decreased the KA E_max without affectingthe EC₅₀ and its effect was independent of the membrane holdingpotential for both of these receptors subtypes. Ethanol also inhibitedhomomeric and heteromeric receptors transiently expressed in humanembryonic kidney (HEK) 293 cells. In these cells, the expressionof heteromeric GluR6-R subunit-containing receptors was confirmedby testing their sensitivity to 1 mM $alpha$ -amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid. Ethanol inhibited to a similar extent KA-gatedcurrents mediated by receptors composed of either GluR6 or GluR6+ KA1 subunits, and to a slightly lesser extent receptors composedof GluR6 + KA2 subunits. Acute ethanol's effects were tested onGluR5 KA receptors that are expressed as homomers (GluR5-Q) orheteromers (GluR5-R + KA1 and GluR5-R + KA2). Homomeric and heteromericGluR5 KA receptors were all inhibited to a similar extent by ethanol;however, there was slightly more inhibition of GluR5-R + KA2 receptors.Thus, recombinant KA receptors with different subunit compositionsare all acutely inhibited to a similar extent by ethanol. In lightof recent reports that KA receptors regulate neurotransmitterrelease and mediate synaptic currents, we postulate that thesereceptors may play a role in acute ethanolintoxication.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

Ionotropic glutamate receptors are cation-conducting channels that belong to a superfamily of ligand-gated ion channels. Thethree major families of ionotropic glutamate receptors have beendenoted as the N-methyl-D-aspartate (NMDA), $alpha$ -amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA), and kainate (KA) receptor families. TheKA family of glutamate receptors comprises the GluR5-7 and KA1-2subunits (Hollmann and Heinemann 1994). Similar to GluR2 AMPAreceptor subunits, RNA editing takes place in the M2 domain Q/Rsite of both GluR5 and GluR6 subunits (reviewed in Ozawa et al.,1998). GluR5-Q, GluR6-Q, and GluR6-R subunits can form homomericchannels, whereas GluR5-R subunits only form functional channelswhen coexpressed with KA1 or KA2 subunits (Herb et al., 1992).KA1 and KA2 subunits do not form homomeric channels but coexpresswith GluR5-7 subunits forming receptors with new pharmacologicaland functional properties. For instance, GluR6 homomeric receptorsare not activated by 1 mM AMPA, whereas it activates heteromericreceptors composed of GluR6 plus either KA1 or KA2 subunits (Herbet al., 1992; Sakimura et al., 1992). Although the subunit compositionof native KA receptors in most neurons remains unknown, a numberof biochemical and functional studies suggest that some KA receptorsexist in vivo as heteromers (Sahara et al., 1997; reviewed inOzawa et al., 1998).

Previous studies showed that KA receptors are acutely modulated by ethanol. Dildy-Mayfield and Harris (1995) demonstratedthat concentrations of ethanol as low as 35 mM inhibited KA-gatedcurrents in Xenopus oocytes expressing recombinant GluR6 receptors.We recently reported that recombinant GluR6 receptors expressedin human embryonic kidney (HEK) 293 cells are also inhibited byethanol and that its mechanism of action does not involve proteinphosphorylation (Valenzuela et al., 1998b). Moreover, we recentlyshowed that pharmacologically isolated native KA receptors areacutely inhibited by ethanol in cerebellar granule neurons (Valenzuelaet al., 1998a). However, ethanol's effects on KA receptors withdifferent subunit compositions are unknown. In this article, wereport the results of electrophysiological studies on the acuteeffects of ethanol on homomeric and heteromeric recombinant KAreceptors composed of GluR5 or R6 subunits in the absence or presenceof KA1 or KA2subunits.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

Cell Culture and DNA Transfections. HEK 293 cells were purchased from American Type Tissue Culture Collection (ATCC, Rockville, MD). Rat GluR5-Q, GluR5-R, GluR6-R,KA1, and KA2 receptor subunit cDNAs were subcloned in cytomegaloviruspromoter-containing vectors and were generously provided by Drs.Yael Stern-Bach and Steve Heinemann (Salk Institute, La Jolla,CA). HEK 293 cells were maintained in minimum essential media(Hyclone, Logan, UT) plus 10% (v/v) fetal bovine serum (GeminiBioproducts, Calabasas, CA), 2 mM glutamine, 100 U/ml penicillin,and 0.1 mg/ml streptomycin (all from Sigma Chemical Co., St. Louis,MO) at 37°C 5% CO₂ in a humidified atmosphere; these cells weretransiently transfected by the calcium phosphate precipitationmethod (Chen and Okayama 1987).

Experiments with Xenopus Oocytes. The techniques for injection, culture, and two-voltage clamp electrophysiological recording from Xenopus oocytes used in thisstudy are described in detail elsewhere (Dildy-Mayfield and Harris,1995). Oocytes were injected with rat GluR5-Q or GluR6-R receptorcRNAs, which were transcribed in vitro with the mRNA capping kitfrom Stratagene (La Jolla, CA). Concanavalin A (2 µM) was preappliedfor 1 min before KA application to prevent desensitization. Ethanolwas coapplied with KA for 30 s and effects of drugs were calculatedas the percentage of change from an average of control and washoutresponses.

Patch-Clamp Electrophysiological Recording. For electrophysiological recording, HEK 293 cells were plated on sterile 12-mm glass round coverslips coated with poly-L-lysineand transfected as described above. Cells were used for recording48 to 72 h after transfection. Immediately before recording, coverslipswere transferred to a perfusion chamber (Warner Instruments, Hampden,CT) and visualized under a Leitz Fluovert inverted microscope(Wetzlar, Germany) equipped with Hoffman modulation optics (Greenvale,NY). Currents were measured in the whole-cell patch clamp configuration.Membrane potential was clamped at $-$ 60 mV with an Axopatch 200amplifier (Axon Instruments, Foster City, CA). Recording pipettes(borosilicate capillaries with filament, A. 1.5 mm, Sutter Instruments,Novato, CA) were prepared with a two-step puller (Narishige InstrumentCo, Tokyo, Japan) and had resistances between 5 and 7 M $Omega$ . Theexternal solution (all chemicals were from Sigma) contained: 130mM NaCl, 5 mM KCl, 2 mM CaCl₂, 1 mM MgCl_2, 10 mM HEPES (pH 7.3),11 mM glucose, and 1 µM concanavalin A. The internal solutioncontained: 130 mM KCl, 10 mM HEPES, 0.1 mM CaCl₂, 1 mM EGTA, 2mM ATP, and 0.2 mM GTP (all chemicals were from Fluka, Milwaukee,WI). Drugs were applied with a fast-exchange flow-tube perfusionsystem that was driven by motor (Warner Instrument Co.) and controlledby a Master-8 stimulator (A.M.P.I, Jerusalem, Israel). Agonistswere applied at 60-s intervals. Ethanol was coapplied with agonistand was also present in the buffer syringe. Data was acquiredand analyzed with the Neuropro software package (RC Electronics,Santa Barbara, CA). Effects of drugs were calculated as the percentageof change from an average of control and washoutresponses.

Statistical Analysis. All statistical analysis and curve fitting was performed using GraphPad Prizm software (San Diego, CA). KA dose-response curveswere fitted to a four-parameter logistic equation (sigmoid). Effectsof ethanol were analyzed by one-sample Student's t test (againsta theoretical mean of zero) and by one- or two-way ANOVA. Numbersgiven in parentheses (n =) refer to the number of individual cellsor oocytes used in the statistical analysis. Data is presentedas mean ± S.E.M. in allcases.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Effects of Ethanol on KA Receptors Expressed in Xenopus Oocytes. Application of KA in the presence of concanavalin A (2 µM) activated GluR5-Q receptors with an EC₅₀ of 27 µM (95% confidenceinterval 22-33 µM) and a Hill slope of 0.7 (95% confidence interval0.6-0.8; n = 6-7; Fig. 1), and GluR6-R receptors with an EC₅₀of 1.7 µM (95% confidence interval 0.9-3.2 µM) and a Hill slopeof 0.8 (95% confidence interval 0.5-1; n = 7 - 8; Fig. 1). Ethanol(75 mM) inhibited GluR5-Q receptor-dependent KA currents by 40± 7, 28 ± 6, 31 ± 3, 24 ± 4, and 27 ± 3% at KA concentrationsof 1 µM, 5 µM, 25 µM, 100 µM, and 5 mM, respectively (Fig. 1,inset). Ethanol (75 mM) inhibited GluR6-R receptor-dependent KAcurrents by 42 ± 6, 36 ± 4, 27 ± 4, 22 ± 3, and 19 ± 2% at KAconcentrations of 0.5, 1, 3, 10, and 100 µM, respectively (Fig.1, inset). It should be noted that ethanol did not change theKA EC₅₀ or Hill coefficient for these receptors. For GluR5-Q receptors,the EC₅₀ value in the presence of ethanol was 34 µM (95% confidenceinterval 20-59 µM) and the Hill coefficient was 0.7 (95% confidenceinterval 0.5-0.9; n = 6-7). For GluR6-R receptors, the EC₅₀ valuein the presence of ethanol was 2.7 µM (95% confidence interval1.5-5.3 µM) and the Hill coefficient was 0.8 (95% confidence interval0.5-1.1; n = 8). The GluR5Q receptor E_max was decreased to 72%of control (95% confidence interval 63-82%) and the GluR6 receptorE_max was decreased to 80% of control (95% confidence intervals68-98%).

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Fig. 1. Effect of 75 mM ethanol on KA dose-response curve for homomeric GluR5-Q and GluR6-R receptors expressed in Xenopus oocytes. Currents were recorded in two-electrode voltage clamp configuration in the absence ( $black-square$ ) and presence of ethanol (

). Data were fitted to a four- parameter logistic equation (sigmoid) using GraphPad Prizm software. Each point represents average currents ± S.E.M. recorded from six to eight oocytes. Data were normalized with respect to maximal KA responses (5 mM for GluR5-Q and 100 µM for GluR6-R). Inset, ethanol-induced percentage of change of KA receptor currents as a function of the KA concentration used.

We then tested the effects of ethanol on KA responses at or below the EC₅₀ (Fig. 2). Appropriate KA concentrations were determinedfor each individual oocyte by measuring maximal KA responses andchoosing a concentration that produced currents correspondingto 50% or less of these responses. In GluR5-Q receptors, ethanolconcentrations of 25, 50, 75, and 100 mM decreased the amplitudeof KA activated currents by 7 ± 2, 19 ± 4, 27 ± 5, and 40 ± 1%,respectively (n = 4; Fig. 2). In GluR6-R receptors, ethanol concentrationsof 25, 50, 75, and 100 mM decreased the amplitude of KA activatedcurrents by 13± 5, 19 ± 4, 24 ± 2, and 35 ± 4%, respectively (n= 4-5; Fig. 2). Statistical analysis (one-sample Student's t testversus a theoretical mean of zero and one-way ANOVA followed byDunnett's multiple comparison test) revealed that ethanol producedsignificant (p < .05) inhibition of GluR5-Q and GluR6-R receptor-dependentKA currents at all concentrations tested. Two-way ANOVA revealedthat ethanol did not produce significantly different inhibitionof GluR5-Q versus GluR6-R receptors.

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Fig. 2. Comparison of ethanol's effect on GluR5-Q versus GluR6-R receptors expressed in Xenopus oocytes. Upper panel, representative tracings of effects of 50 mM ethanol. Lower panel, summary of effects of 25 to 100 mM ethanol. Ethanol was tested on receptors activated by concentrations at or below the KA EC₅₀. Each point represents mean ± S.E.M. of four oocytes. Scale bar, 50 nA by 30 s.

The effect of ethanol on GluR5-Q and GluR6-R receptor function was independent of the membrane holding potential (Fig. 3).Ethanol (75 mM) inhibited GluR5-Q receptor function by 22 ± 4,31 ± 3, and 24 ± 2% (n = 5) at $-$ 90, $-$ 60, and $-$ 30 mV membrane holdingpotentials, respectively (Fig. 3). Ethanol inhibited GluR6-R receptorfunction by 24 ± 3, 25 ± 4, and 27 ± 5% (n = 5-7) at $-$ 90, $-$ 60,and $-$ 30 mV membrane holding potentials, respectively (Fig. 3).

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Fig. 3. Effects of ethanol on current/voltage relationships for GluR5-Q and GluR6-R receptors expressed in Xenopus oocytes. Currents were measured at indicated membrane holding potentials in the absence ( $black-square$ ) and presence (

) of 75 mM ethanol. Each point represents mean ± S.E.M. of five to seven determinations. KA concentration was 5 µM. Currents were normalized with respect to responses obtained at $-$ 90 mV in the absence of ethanol. Inset, summary of percent change induced by ethanol at different holding membrane potentials.

Effects of Ethanol on Receptors Expressed in HEK 293 Cells. HEK 293 cells transfected with GluR6-R, GluR6-R + KA1, or GluR6-R + KA2 subunits were tested for sensitivity to 100 µM KAand 1 mM AMPA (Fig. 4). Homomeric GluR6 receptors were virtuallyinsensitive to 1 mM AMPA. Conversely, 1 mM AMPA produced significantcurrents in cells transfected with GluR6-R plus either KA1 orKA2 (Fig. 4). It should be noted that all of the results reportedin this article on heteromeric GluR6-R + KA1 or KA2 receptorswere obtained from cells that significantly responded to 1 mMAMPA.

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Fig. 4. Representative tracings of currents gated by different GluR6-R subunit-containing KA receptors used in this study. Left, comparison of currents produced by 100 µM KA versus 1 mM AMPA. Right, effects of 25 to 100 mM ethanol on currents gated by KA ( $<=$ EC₅₀).

KA activated GluR6-R receptors with an EC₅₀ of 2.7 µM (confidence interval 1.9-3.9 µM) and a Hill slope of 1.0 (confidenceinterval 0.7-1.3; n = 3-5; Fig. 5). KA activated GluR6 + KA1 receptorswith an EC₅₀ of 1.7 µM (confidence interval 1.2-2.4 µM) and aHill slope of 1.0 (confidence interval 0.7-1.2; n = 5-6; Fig.5), and it activated GluR6 + KA2 receptors with an EC₅₀ of 0.45µM (confidence interval 0.38-0.54 µM) and a Hill slope of 1.4(confidence interval 1-1.6; n = 3 - 4; Fig. 5). Two-way ANOVAindicated that the dose-response curve for GluR6 + KA2 was significantlydifferent from the curves for both GluR6 and GluR6 + KA1 receptors(p < .001).

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Fig. 5. Studies with KA receptors containing GluR6-R subunits with and without KA1 or KA2 subunits. Upper, KA dose-response curves. Data were fitted to a four-parameter logistic equation (sigmoid) using GraphPad Prizm software. Each point represents average currents ± S.E.M. recorded from three to six cells. Data were normalized with respect to maximal KA responses (100 µM). Lower, acute effect of 25 to 100 mM ethanol on receptors activated by submaximal ( $<=$ EC₅₀) KA concentrations. Each point represents mean ± S.E.M. of currents recorded from 6 to 14 cells. For results of statistical analyses, see text.

We then tested the effects of ethanol on KA responses at or below the EC₅₀, where the responses do not show desensitizationunder our recording conditions (i.e., in the presence of concanavalinA) and the effect of ethanol is independent of the KA concentrationused (Fig. 1; Valenzuela et al., 1998b

). Appropriate KA concentrationswere determined for each individual cell by measuring maximalKA (100 µM) responses and choosing a KA concentration that producedcurrents corresponding to $<=$ 50% of these responses. In cells expressingGluR6 receptors, ethanol concentrations of 25, 50, 75, and 100mM inhibited KA currents by 11 ± 3, 15 ± 2, 27 ± 4, and 30 ± 4%(n = 10-14), respectively (Figs. 4 and 5). In cells expressingGluR6 + KA1 receptors, the same ethanol concentrations inhibitedKA currents by 4 ± 3, 12 ± 3, 15 ± 4, and 22 ± 1, respectively(n = 6; Figs. 4 and 5). In cells expressing GluR6 + KA2 receptors,the same ethanol concentrations inhibited KA currents by 4 ± 3,8 ± 2, 13 ± 3, and 14 ± 4%, respectively (n = 8; Figs. 4 and 5).No change in the decay of any of the KA currents (recorded inthe presence of concanavalin A) was appreciable in the presenceof ethanol (Fig. 4). Statistical analysis (one-sample Student'st test versus a theoretical mean of zero and one-way ANOVA followedby Dunnett's multiple comparison test) revealed that 25 to 100mM ethanol produced significant (p < .05) inhibition of KA currentsmediated by all homomeric and heteromeric receptors containingGluR6-R subunits. It also revealed that the effects of 25 versus50 mM ethanol were not significantly different; the effects of75 and 100 mM ethanol were significantly different from its effectsat 25 and 50 mM concentrations. Two-way ANOVA revealed that GluR6+ KA2 receptors were inhibited significantly less by ethanol (p< .001).

The effect of ethanol on homomeric and heteromeric KA receptors containing GluR5 subunits was also tested. The effects ofethanol were tested only on homomeric GluR5-Q receptors, becauseGluR5-R receptors do not express homomerically. Reproducible currentswere obtained by activating these receptors with domoate; theEC₅₀ for GluR5-Q receptor activation was 0.27 µM (95% confidenceinterval 0.21-0.34 µM) and the Hill coefficient was 1.4 (95% confidenceinterval 1-1.9; n = 5-6; Fig. 6). Ethanol concentrations of 25,50, 75, and 100 mM inhibited domoate-gated currents (EC_20-30)by 3 ± 2, 9 ± 4, 17 ± 4, and 24 ± 8%, respectively (n = 6-8; Fig.6). Statistical analysis (one-sample Student's t test versus atheoretical mean of zero and one-way ANOVA followed by Dunnett'smultiple comparison test) revealed that ethanol produced significant(p < .05) inhibition of KA currents mediated by these receptorsat all concentrations tested. It also revealed that the effectsof 25 to 75 mM ethanol were not significantly different from eachother; the effects of 100 mM ethanol were significantly differentfrom its effects at 25 to 75 mM concentrations.

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Fig. 6. Studies with homomeric GluR5-Q KA receptors. Upper, domoate dose-response curves. Data were fitted to a four-parameter logistic equation (sigmoid) using GraphPad Prizm software. Each point represents average currents ± S.E.M. recorded from five to six cells. Data were normalized with respect to maximal domoate responses (25 µM). Middle and lower, sample tracings and summary of acute effect of 25 to 100 mM ethanol on submaximal ( $<=$ EC_20-30) domoate currents. Each point in lower panel represents mean ± S.E.M. of currents recorded from eight cells. For results of statistical analyses, see text.

Effects of ethanol on heteromeric GluR5 receptors were tested with GluR5-R receptors plus KA1 or KA2, because GluR5-R receptorsproduce functional currents only as heteromers. We did not testGluR5-Q plus KA1 or KA2 subunits because there is not a straightforwardtest to determine whether the receptors are indeed heteromericon each cell where ethanol's effects are tested; i.e., GluR5-Qreceptors in the presence or absence of KA1 or KA2 subunits areactivated to a similar extent by 1 mM AMPA (Herb et al., 1992

;Korczak et al., 1995

). Reproducible currents were obtained byactivating these receptors with KA; the EC₅₀ for activation ofGluR5-R + KA1 receptors was 4.2 µM (95% confidence interval 3.4-5.1µM) and the Hill coefficient was 0.9 (95% confidence interval0.7-1.0; n = 3; Fig. 7). The EC₅₀ for activation of GluR5-R +KA2 receptors was 6.6 µM (95% confidence interval 5.0-8.7 µM)and the Hill coefficient was 0.9 (95% confidence interval 0.7-1.0;n = 5-6; Fig. 7). Ethanol concentrations of 25, 50, 75, and 100mM inhibited GluR5-R + KA1 receptor currents (EC_20-50) by4 ± 2, 14 ± 3, 14 ± 5, and 16 ± 3%, respectively (n = 5-6; Fig.7). Ethanol concentrations of 25, 50, 75, and 100 mM inhibitedGluR5 + KA2 receptor currents (EC_20-50) by 8 ± 4, 21 ± 3,23 ± 4, and 27 ± 7%, respectively (n = 5; Fig. 7). Statisticalanalysis (one-sample Student's t test versus a theoretical meanof zero and one-way ANOVA followed by Dunnett's multiple comparisontest) revealed that ethanol produced significant (p < .05) inhibitionof KA currents mediated by these receptors at all concentrationstested. It also indicated that there was not any significant differencein the inhibition produced by the different concentrations ofethanol tested. Two-way ANOVA revealed that GluR5-R + KA2 receptorswere inhibited significantly more by ethanol than GluR5-Q andGluR5-R + KA1 receptors (p < .001).

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Fig. 7. Studies with KA receptors containing GluR5-R subunits plus KA1 or KA2 subunits. Upper, sample tracings of the acute effect of 25 to 100 mM ethanol on submaximal ( $<=$ EC_20-50) KA currents. Lower left, KA dose-response curves. Data were fitted to a four-parameter logistic equation (sigmoid) using GraphPad Prizm software. Each point represents average currents ± S.E.M. recorded from four to eight cells. Data were normalized with respect to maximal KA responses (100 µM). Lower right, summary of ethanol's effects on these receptors. Each point in lower panel represents mean ± S.E.M. of currents recorded from five to six cells. For results of statistical analyses, see text.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The results of the present study demonstrate that the function of recombinant KA receptors with different subunit compositionsis acutely inhibited by ethanol. Previous studies on the actionsof ethanol on recombinant KA receptors focused on homomeric GluR6receptors expressed in Xenopus oocytes or HEK 293 cells, and thesestudies reported that 25 to 100 mM ethanol acutely inhibited thefunction of these receptors by 10 to 30% (Dildy-Mayfield and Harris1995; Valenzuela et al., 1998b). We now report the effects ofethanol on homomeric KA receptors composed of GluR5-Q and heteromericKA receptors composed of GluR6-R or GluR5-R plus KA1 or KA2 subunits.We found that ethanol inhibits, to a similar extent, KA receptorswith all of these subunit compositions. We detected statisticallysignificant differences in only two cases: GluR6 + KA2 receptorswere inhibited significantly less than GluR6 and GluR6 + KA1 receptors,and GluR5-R + KA2 receptors were inhibited significantly morethan GluR5-Q and GluR5-R + KA1 receptors. However, the differencesbetween receptors with different subunit compositions were relativelysmall.

Present results with recombinant KA receptors are in agreement with a recent study from our laboratory with native KA receptors.We reported that acute exposure to 25 to 100 mM ethanol inhibitedpharmacologically isolated KA receptor currents by 5 to 25% incerebellar granule cells (Valenzuela et al., 1998a). In thesecells, the majority of KA receptors were reported to contain eitherGluR5-R, GluR5-Q, or GluR6-Q subunits; GluR6-Q subunits appearto associate to KA2 subunits in these cells (Savidge et al., 1997;Pemberton et al., 1998). In cerebellar granule cells, we foundthat ethanol acutely inhibited NMDA receptors to a greater extentthan either AMPA or KA receptors (Valenzuela et al., 1998a). Thus,NMDA receptors may be more important targets than KA receptorsin the acute actions of pharmacologically relevant concentrationsof ethanol. It should be emphasized, however, that the magnitudeof ethanol's acute effects on KA receptor function might dependon the brain region studied. We recently found that KA receptor-mediatedsynaptic currents in the CA3 region of the hippocampus are inhibitedby 11 to 50% in the presence of 20 to 80 mM ethanol (J. L. Weiner,T. V. Dunwiddie, and C. F. Valenzuela, unpublished observation).It would be interesting to study ethanol's actions on KA receptorsexpressed in neurons from central nervous system (CNS) regionsother than the hippocampus and cerebellum and to establish thefactors that determine this differential sensitivity of KA receptorsto ethanol. This study and a previous one (Valenzuela et al.,1998b) suggest that neither subunit composition nor protein phosphorylationmodulate acute ethanol's actions on recombinant KA receptors.Whether these factors, or other factors such as receptor clustering,localization and/or association with neuronal specific proteins,play a role in determining the sensitivity of native KA receptorsto ethanol remains to beelucidated.

A challenging question for future study will be to locate the molecular site of action of ethanol on KA receptors and otherionotropic glutamate receptors. In the case of $gamma$ -aminobutyricacid_A (GABA_A) and glycine receptors, ethanol was reported to interactwith a specific binding pocket located between transmembrane domainsM2 and M3 (Mihic et al., 1997; Wick et al., 1998). Minami et al.(1998) found that in GluR6 receptors a specific amino acid, residueGly-819 in M4, is important for the actions of the volatile anestheticshalothane, isoflurane, and enflurane. However, this residue doesnot appear to play a role in ethanol's actions on GluR6 KA receptors.Thus, more work will be required to determine the mechanism ofaction of ethanol on KA receptors at the molecularlevel.

Another question for future research will be to determine whether the acute effects of ethanol on KA receptors contributesignificantly to the pathophysiology of acute intoxication. Toanswer this question, we need to learn more about the roles playedby KA receptors in the CNS. KA receptors are found throughoutmany regions and they are particularly abundant in the granularcell layer of the cerebellum, CA3 region of the hippocampus, cerebralcortex, caudate/putamen, hypothalamus, reticulothalamic nucleus,and pontine nuclei (Petralia et al., 1994). Selective AMPA receptorantagonists such as LY300168 (GYKI-53655) were recently used todetermine that presynaptic GluR5 KA receptors reduce the effectivenessof GABAergic synaptic inhibition in the rat hippocampus (Clarkeet al., 1997; Rodriguez-Moreno et al., 1997). Moreover, KA receptorsappear to be more complex than previously expected by acting notonly as ionotropic receptors but also as metabotropic G protein-coupledreceptors (Rodriguez-Moreno and Lerma, 1998). KA receptors mediatesynaptic currents in neurons of the CA3 region of the hippocampus(Castillo et al., 1997; Vignes and Collingridge, 1997), and thesecurrents are absent in GluR6 knockout mice (Mulle et al., 1998).KA receptor activation in interneurons increases tonic GABAergicinhibition of pyramidal cells (Cossart et al., 1998) and increasesthe frequency of spontaneous inhibitory postsynaptic currents(Frerking et al., 1998). Thus, decreases in synaptic KA receptorfunction in specific areas of the CNS may be important for acuteethanol intoxication. It is possible that relatively small effectsof ethanol on KA receptors located in neuronal pathways wherealcohol also affects the function of NMDA, GABA_A, voltage-gatedion channels, and/or metabotropic receptors, could contributeto the pathophysiology of acute ethanol intoxication. Clearly,more work will be required to test this hypothesis. For instance,it would be interesting to measure the acute effects of ethanolon the GluR6 knockout mice developed by Mulle et al. (1998).

In conclusion, we found that recombinant KA receptors composed of GluR5 or GluR6 subunits in the absence and presence of KA1or KA2 subunits are all acutely inhibited by ethanol. Ethanolinhibited to a similar extent these recombinant KA receptors withdifferent subunit compositions. It would be interesting to determinewhether alcohol modulates in a similar manner native KA receptorswith different subunit configurations in neurons of various CNSregions.

	Acknowledgments

We thank Dr. Adron Harris for support and advise, Dr. Marilee Wick for assistance with recombinant DNA techniques, and Dr.Jeff Weiner for helpfuldiscussions.

	Footnotes

Accepted for publication October 19, 1998.

Received for publication September 1, 1998.

¹ This work was supported by National Institutes of Health Grant AA00227 (to C.F.V.)

Send reprint requests to: C. Fernando Valenzuela, M.D., Ph.D., Department of Neurosciences, University of New Mexico, Health Sciences Center, Basic Medical Sciences Building, Room 235 Albuquerque, NM 87131-5223. E-mail: fvalenzuela{at}salud.unm.edu

	Abbreviations

NMDA, N-methyl-D-aspartate; AMPA, $alpha$ -amino-3-hydroxy-5-methyl-4-isoxazole propionic acid; HEK, human embryonic kidney; KA, kainate; CNS, central nervous system; GABA_A, $gamma$ -aminobutyric acid_A.

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