Bicuculline and Gabazine Are Allosteric Inhibitors of Channel Opening of the GABAA Receptor

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Volume 17, Number 2, Issue of January 15, 1997 pp. 625-634
Copyright ©1997 Society for Neuroscience

Bicuculline and Gabazine Are Allosteric Inhibitors of Channel Opening of the GABA_A Receptor

Shinya Ueno¹, John Bracamontes¹, Chuck Zorumski², David S. Weiss³, and Joe Henry Steinbach¹
Departments of ¹ Anesthesiology and ² Psychiatry, Washington University School of Medicine, St. Louis, Missouri 63110, and ³ University of Alabama at Birmingham, Neurobiology Research Center and Department of Physiology and Biophysics, Birmingham, Alabama 35294-0021

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Anesthetic drugs are known to interact with GABA_A receptors, both to potentiate the effects of low concentrations of GABAand to directly gate open the ion channel in the absence of GABA;however, the site(s) involved in direct gating by these drugsis not known. We have studied the ability of alphaxalone (an anestheticsteroid) and pentobarbital (an anesthetic barbiturate) to directlyactivate recombinant GABA_A receptors containing the $alpha$ 1, $beta$ 2, and $gamma$ 2L subunits. Steroid gating was not affected when either of twomutated $beta$ 2 subunits [ $beta$ 2(Y157S) and $beta$ 2(Y205S)] are incorporatedinto the receptors, although these subunits greatly reduce theaffinity of GABA binding. These observations indicate that steroidbinding and subsequent channel gating do not require these particularresidues, as already shown for barbiturates. Bicuculline or gabazine(two competitive antagonists of GABA binding) reduced the currentselicited by alphaxalone and pentobarbital from wild-type GABA_Areceptors; however, gabazine produced only a partial block ofresponses to pentobarbital or alphaxalone, and bicuculline onlypartially blocked responses to pentobarbital. These observationsindicate that the blockers do not compete with alphaxalone orpentobarbital for a single class of sites on the GABA_A receptor.Finally, at receptors containing $alpha$ 1 $beta$ 2(Y157S) $gamma$ 2L subunits, bothbicuculline and gabazine showed weak agonist activity and actuallypotentiated responses to alphaxalone. These observations indicatethat the blocking drugs can produce allosteric changes in GABA_Areceptors, at least those containing this mutated $beta$ 2 subunit.We conclude that the sites for binding steroids and barbituratesdo not overlap with the GABA-binding site. Furthermore, neithergabazine nor bicuculline competes for binding at the steroid orbarbiturate sites. The data are consistent with a model in whichboth gabazine and bicuculline act as allosteric inhibitors ofchannel opening for the GABA_A receptor after binding to the GABA-bindingsite.
Key words: GABA_A receptor; GABA; neurosteroids; bicuculline; inverse agonist; anesthetics; allosteric inhibitor

INTRODUCTION

GABA activates a ligand-gated ion channel (the GABA_A receptor), which underlies most rapid inhibition in the brain. Variousother compounds also bind to the GABA_A receptor and can gate thechannel or modulate channel function (Macdonald and Olsen, 1993).In particular, steroids and barbiturates are each able to directlygate the GABA_A receptor channel (in the absence of GABA), andthey can also enhance the activation produced by low concentrationsof GABA. It is not known whether the same sites are involved inproducing direct gating and in potentiating the effects of GABA.For the sites involved in potentiation, however, the steroid-bindingsite and the barbiturate-binding site are distinct from each otherand are also distinct from the GABA-binding site (Macdonald andOlsen, 1993). Because the characterized sites for steroid andbarbiturate binding differ from the GABA-binding site, it is puzzlingthat a competitive antagonist of GABA binding, bicuculline, isalso a potent blocker of channel gating by steroids (Barker etal., 1987) or pentobarbital (Nicoll and Wojtowicz, 1980). We areinterested in defining the sites on the GABA_A receptor that areinvolved in direct gating by anesthetics, and we have initiatedstudies of channel activation by alphaxalone (an anesthetic steroidanalog) and pentobarbital (an anesthetic barbiturate).

Accordingly, we have examined the ability of alphaxalone to gate mutated GABA_A receptors, and we found that residues thatare important in determining the binding affinity of GABA do notaffect activation by steroids. We also examined the actions ofblocking drugs and found that neither bicuculline nor gabazineare competitive inhibitors of currents gated by alphaxalone orpentobarbital. Finally, both gabazine and bicuculline act as weakagonists for GABA_A receptors containing the $beta$ 2(Y157S) mutatedsubunit. These data indicate that steroids and barbiturates donot bind to the GABA-binding site when they directly gate thechannel of the GABA_A receptor. Furthermore, the data support theidea that bicuculline and gabazine act as negative allostericmodulators of function of GABA_A receptors.

MATERIALS AND METHODS
All chemicals were from Sigma (St. Louis, MO) unless specified otherwise. Gabazine (SR-95531) and alphaxalone were obtainedfrom Research Biochemicals International (Natick, MA).

A complementary DNA construct for the rat $alpha$ 1 subunit of the GABA receptor was provided by Dr. A. Tobin (University of CaliforniaLos Angeles). The rat $gamma$ 2L and $beta$ 2 subunits and the point mutants $beta$ 2(Y205S) and $beta$ 2(Y157S) have been described (Amin and Weiss, 1993).GABA receptor subunit cDNAs were transferred to the eucaryoticexpression vector pcDNA3 (Invitrogen, San Diego, CA), for expressionin QT6 cells. Direct sequencing of the mutated $beta$ 2 subunits confirmedthat the constructs contained the appropriate base changes (Sequenaseversion 2 kit; Amersham, Arlington Heights, IL).

Quail fibroblasts (QT6 cells; initially provided by Dr. J. Merlie, Washington University) were maintained in Medium 199 (Earle'ssalts) containing 5% fetal bovine serum (Hyclone, Logan, UT),10% tryptose phosphate broth (Life Technologies, Grand Island,NY), 1% dimethylsulfoxide (DMSO), and penicillin (100 U/ml) plusstreptomycin (100 µg/ml) in a humidified atmosphere containing5% CO₂. Calcium phosphate precipitation was used to transfectQT6 cells (Chen and Okayama, 1987), with the additional step ofan initial wash to remove tryptose phosphate broth (Phillips etal., 1991). QT6 cells were used for expression because of anomalousresults obtained when subunits were expressed in HEK293 cells(Ueno et al., 1996b).

Cells that expressed a high level of protein from exogenous cDNA were identified using the bead-labeling technique describedby Jurman et al. (1994). We inserted a flag epitope tag into theN-terminal region of the $alpha$ 1 subunit (Ueno et al., 1996b). Startingwith the N terminus of the predicted mature peptide, the predictedsequence of the resulting peptide is YGQPSQDELKDNTT,where the introduced residues are shown underlined. This constructwas identified on the surface of intact cells using a mouse monoclonalantibody to the FLAG epitope (M2, Eastman Kodak Scientific ImagingSystems, New Haven, CT), which had been adsorbed to beads withcovalently attached goat anti-mouse IgG antibody (Dynal, GreatNeck, NY). Control experiments indicated that the tag had no functionaleffects on receptors incorporating the tagged $alpha$ 1 subunit (Uenoet al., 1996b).

Recordings were made using standard whole-cell methods (Hamill et al., 1981) 24-72 hr. after transfection. All experimentswere performed at room temperature (21-23°C), and drugs were dissolvedin external solution. In all cases, data were obtained from isolatedsingle cells. Experiments were performed in two laboratories.In the Steinbach laboratory (Ueno et al., 1996a), drugs were appliedwith a polyethylene "Y tube." The bath was perfused continuouslywith normal external solution from a separate perfusion line,and solution was removed from the bath with a Leiden aspirator(Medical Systems, Greenvale, NY). In the Zorumski laboratory (Huet al., 1993), drugs were applied by pressure ejection from "puffer"pipettes positioned within 5 µm of the patch-clamped cell, usinga 500 msec pulse of air pressure (10-20 psi) to the back of thepipette. The data shown in Figure 1A,B,D were obtained with pufferapplications, the other data with Y-tube applications. Bicucullinemethiodide was dissolved in saline and used within 2 hr. Stocksolutions of steroids were prepared in DMSO. The maximal concentrationof DMSO in the final working solution was 0.2%, which had no effecton GABA-elicited currents (Rodgers-Neame et al., 1992). Sodiumpentobarbital was dissolved in saline.
Fig. 1. Activation of GABA_A receptors containing $beta$ 2 or $beta$ 2(Y205S) subunits. Each panel shows concentration-response curves for an agonist:GABA (A), pentobarbital (PENT, B), alphaxalone (ALPH, C), andDHP-OH (D). In each panel, the open symbols show responses fromQT6 cells transfected with $alpha$ 1 $beta$ 2 $gamma$ 2L subunits, whereas filled symbolsshow responses from cells transfected with $alpha$ 1 $beta$ 2(Y205S) $gamma$ 2L subunits.GABA produced no gating of receptors containing the mutated subunit(points at 100 and 1000 µM GABA in A). For the other agoniststested, the data from receptors containing wild-type or mutatedsubunits were indistinguishable. The lines in A through C showpredictions derived from fitting an allosteric blocking modelto data from receptors containing wild-type subunits (see Results).Symbols show mean for data from two to nine cells; error barsrepresent SD.
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Concentration-effect curves were fit with the Hill equation using SigmaPlot (Jandel Scientific Software, San Rafael, CA).The ability of an allosteric blocking model to describe the observationswas assessed by eye (see Results), using QuattroPro (Borland International,Scotts Valley, CA) to generate predicted blocking curves. Figureswere produced using SigmaPlot.

RESULTS

Direct gating of GABA_A receptors containing mutated $beta$ 2 subunits
We initially examined GABA_A receptors that contain a mutated $beta$ 2 subunit, which had already been shown to have greatly reducedefficacy for gating by GABA but normal gating by pentobarbital(Amin and Weiss, 1993). Quail fibroblast cells (QT6) were transfectedwith cDNAs for $alpha$ 1 and $gamma$ 2L subunits and for either wild-type $beta$ 2or $beta$ 2(Y205S) mutated subunits. Responses were measured by whole-cellpatch-clamp recordings. We found that direct gating by alphaxalone(Fig. 1C) or 5 $alpha$ -pregnan-3 $alpha$ -ol-20-one (DHP-OH; Fig. 1D) was indistinguishablefor receptors containing the wild-type or mutated $beta$ 2 subunits.We also confirmed that gating by pentobarbital was unaltered (Fig.1B) (Amin and Weiss, 1993) and that cells expressing $alpha$ 1 $beta$ 2(Y205S) $gamma$ 2Lsubunits showed no response to GABA (100-1000 µM; Fig. 1A) (Aminand Weiss, 1993). Receptors containing a second point mutant ofthe $beta$ 2 subunit $beta$ 2(Y157S) could also be gated by 10 µM alphaxalone(Fig. 4), although the concentration-response relationship wasnot examined.
Fig. 4. Responses to alphaxalone of cells expressing mutated $beta$ 2 subunits. Each panel shows traces recorded from a cell exposed to10 µM alphaxalone (dotted trace) and then to 10 µM alphaxaloneplus 1 mM of an antagonist (solid trace). Actions of 1 mM gabazineare shown in the top row and of 1 mM bicuculline in the bottomrow. Cells transfected with $alpha$ 1 $beta$ 2(Y157S) $gamma$ 2L subunits (left) showedpotentiation between alphaxalone and either gabazine or bicuculline.Cells transfected with $alpha$ 1 $beta$ 2(Y205S) $gamma$ 2L subunits showed block byeither compound, but the block produced by bicuculline was reducedover that seen with wild-type receptors, whereas the block producedby gabazine was increased (see Figs. 3, 6). Calibration in eachpanel: 20 pA, 10 sec.
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The responses to 30 mM pentobarbital showed a decrease from responses to 10 mM pentobarbital (data not shown), in agreementwith previous results showing that high concentrations of pentobarbitalproduce "autoinhibition" (Akaike et al., 1987a). The maximal concentrationsof steroids (alphaxalone and DHP-OH) were limited by the aqueoussolubility, so that concentrations above 100 µM could not be used.

Inhibition by bicuculline or gabazine of currents gated by alphaxalone or pentobarbital from wild-type receptors
We then examined the ability of competitive inhibitors of GABA binding to block gating of GABA_A receptors containing wild-type $beta$ 2 subunits by GABA, alphaxalone, or pentobarbital. Both bicucullineand gabazine (SR 95531) have been characterized as competitiveinhibitors of GABA binding to the GABA_A receptor (see Discussion).Both drugs were able to reduce currents elicited by each of thethree agonists (Fig. 2). Bicuculline was approximately equallypotent at blocking responses to 10 µM alphaxalone, 3 µM GABA,and 300 µM pentobarbital (Fig. 3A). When the concentration-effectcurves were described by the Hill equation, the concentrationsrequired to reduce the response by 50% (the IC₅₀) were 0.9 µM,0.9 µM, and 1.0 µM, whereas the Hill coefficients were 0.94, 1.01,and 0.77, respectively, for responses to alphaxalone, GABA, andpentobarbital. It is interesting that the IC₅₀ values are so similar,because this might be expected if bicuculline blocked responsesof all three agonists by binding to a single type of site. Theobservation that the Hill coefficients were close to 1 suggeststhat block can be produced after the binding of a single antagonistmolecule.
Fig. 2. Action of blocking drugs on responses elicited from cells expressing $alpha$ 1 $beta$ 2 $gamma$ 2L receptors. Each panel shows traces recorded froma cell exposed to an agonist (dotted trace), or the same concentrationof the agonist plus 10 µM of a blocking agent (solid trace). Allcells were transfected with wild-type ( $alpha$ 1 $beta$ 2 $gamma$ 2L) subunits. Theleft column shows the action of 10 µM bicuculline, whereas theright column shows the action of gabazine. Currents were elicitedwith 3 µM GABA (top row), 10 µM alphaxalone (middle row), or 300µM pentobarbital (bottom row). Calibration in each panel: 20 pA,10 sec. These records and those shown in Figures 4 and 5 wererecorded at a holding potential of 0 mV, with a reversal potentialfor the responses of approximately $-$ 30 mV. Hence, the evoked currentsare inward. Drugs were applied with a Y tube.
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Fig. 3. Bicuculline and gabazine block responses to GABA, pentobarbital, and alphaxalone. The agonists GABA (3 µM, open circles),alphaxalone (10 µM, filled triangles), and pentobarbital (300µM, inverted open triangles) were applied to cells transfectedwith $alpha$ 1 $beta$ 2 $gamma$ 2L subunits, in the absence of a blocking drug and thenin the presence of various concentrations of bicuculline (A) orgabazine (B). The figure shows the ratio of the response in thepresence of a blocker to the response in the same cell in theabsence of a blocker. The lines superimposed on the data (dottedlines, 3 µM GABA; solid lines, 10 µM alphaxalone; dashed lines,300 µM pentobarbital) show predictions derived from fitting anallosteric blocking model to data from receptors containing wild-typesubunits (see Results). Symbols show mean for data from two tosix cells; error bars represent SD.
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We extended these observations by examining the ability of gabazine (SR 95531) to block currents gated by alphaxalone. Gabazineis more potent than bicuculline at blocking currents elicitedby GABA (Fig. 3B), with an IC₅₀ for currents elicited by 3 µMGABA of ~0.2 µM and a Hill coefficient of 1.0. Gabazine, however,could only reduce the currents elicited by 10 µM alphaxalone by~30%, for responses of receptors containing wild-type $beta$ 2 subunits(Fig. 3B). The concentration of gabazine required to produce halfthe maximal block was ~0.2 µM. Gabazine also could only producea partial block of currents gated by 300 µM pentobarbital. Themaximal reduction, again, was ~30%, and the concentration of gabazinerequired to produce half the maximal block was ~0.15 µM (Fig.3B). Again, the IC₅₀ values are similar for currents elicitedby all three agonists.

The observation that gabazine cannot produce a complete block demonstrates that it cannot compete for a single class of sitesfor activation by either alphaxalone or pentobarbital.

Actions of bicuculline and gabazine on receptors containing mutated $beta$ 2 subunits
To explore further the interactions between alphaxalone and blocking agents, the effects of bicuculline and gabazine on GABA_Areceptors containing mutated $beta$ 2 subunits were examined. Becausethe affinity of GABA is greatly reduced in receptors containingthese mutated subunits (Amin and Weiss, 1993), it was expectedthat the blocking potency of bicuculline and gabazine would alsobe reduced.

Bicuculline was much less potent at blocking currents elicited by 10 µM alphaxalone from receptors containing the mutated $beta$ 2(Y205S) subunit (Fig. 6A). Even at 1 mM bicuculline, the currentwas reduced only to 0.66 × control. The IC₅₀ cannot be estimated,because the maximal block is not known, but it appears to be 1mM or more.
Fig. 6. Actions of bicuculline and gabazine on alphaxalone-elicited responses of GABA_A receptors containing mutated $beta$ 2 subunits. Relativeresponses are shown to 10 µM alphaxalone applied to cells containing $alpha$ 1 $beta$ 2 $gamma$ 2L subunits (open circles, dotted lines), $alpha$ 1 $beta$ 2(Y205S) $gamma$ 2Lsubunits (filled squares, dashed lines), or $alpha$ 1 $beta$ 2(Y157S) $gamma$ 2L subunits(filled triangles, solid lines). The data obtained with bicucullineare shown in A, data with gabazine are shown in B. The lines simplyconnect the points. Also shown are the responses of receptorscontaining $alpha$ 1 $beta$ 2(Y157S) $gamma$ 2L subunits to blocker applied in the absenceof alphaxalone (open triangles). Symbols show mean for data fromtwo to five cells; error bars represent SD .
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Surprisingly, bicuculline did not block currents activated by alphaxalone from receptors containing $alpha$ 1 $beta$ 2(Y157S) $gamma$ 2L subunits.Instead, 1 mM bicuculline potentiated the response to 10 µM alphaxalone(Figs. 4, 6A). The EC₅₀ cannot be estimated, because the maximalpotentiation is not known, but it must be >100 µM (Fig. 6A). Furthermore,bicuculline acted as a weak agonist at receptors containing the $beta$ 2(Y205S) subunit, so that 1 mM bicuculline applied alone produceda response ~10% the size of the response to 10 µM alphaxalone(Fig. 6A).

Gabazine was more efficacious at blocking alphaxalone-elicited responses from receptors containing $beta$ 2(Y205S) subunits thanfor those containing wild-type $beta$ 2 subunits. With wild-type $beta$ 2subunits, the current elicited by 10 µM alphaxalone in the presenceof 1 mM gabazine was 0.75 × that seen in the absence of gabazine(0.75 ± 0.07, n = 3; mean ± SD), whereas with the $beta$ 2(Y205S) subunitthe current was reduced to 0.30 (± 0.07, n = 5; the differenceis significant at p < 0.0001 by Student's two-tailed t test).However, the IC₅₀ for block by gabazine was shifted to ~100 µM(Fig. 6B).

In agreement with the observations made with bicuculline, gabazine was a weak agonist for receptors containing the $beta$ 2(Y157S)subunit (Figs. 5, 6B). The concentration of gabazine producinghalf-maximal current is likely to be between 10 and 100 µM (Fig.5). There was strong potentiation when gabazine and alphaxalonewere applied together (Figs. 4, 6B). The concentration producinghalf-maximal potentiation appears to be between 10 and 100 µM(Fig. 6B).
Fig. 5. Partial agonist action of gabazine on cells expressing $alpha$ 1 $beta$ 2(Y157S) $gamma$ 2L subunits. The responses of a single cell to applicationsof 10 µM alphaxalone (top trace, dotted) and 1000, 100, and 10µM gabazine alone. Calibration in the top panel: 20 pA and 10sec for all traces.
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The concentration dependence of the actions of bicuculline and gabazine is consistent with the idea that affinities for bothdrugs are reduced by both point mutations, as expected. The $beta$ 2(Y157S)mutation, however, also converts the blockers into weak agonists,whereas the $beta$ 2(Y205S) mutation increases the efficacy of gabazineas a blocker.

Dependence of inhibition by bicuculline on the concentration of GABA, alphaxalone, or pentobarbital
Gabazine clearly does not act as a competitive inhibitor of currents elicited by steroids or barbiturates, because it producesonly a partial block with wild-type receptors. To gain more insightinto the mechanism of inhibition by bicuculline, we examined blockingcurves at different doses of agonists using cells expressing $alpha$ 1 $beta$ 2 $gamma$ 2L(wild-type) GABA_A receptors. The concentration-response curvefor activation of these receptors by GABA can be described bythe Hill equation, with an EC₅₀ of 8 µM and a Hill coefficientof 1.7 (Fig. 1A). Activation by pentobarbital can be describedby the Hill equation, with an EC₅₀ of 590 µM and a Hill coefficientof 2.0 (Fig. 1B). Unfortunately, the low aqueous solubility ofalphaxalone and other steroids limits the concentrations thatcan be applied, so the concentration-response curve is not wellcharacterized (Fig. 1C) and the EC₅₀ is not known. The data arepresented as blocking curves at a given agonist concentration,rather than as concentration-response curves for agonists at givenblocker concentrations. This second format is often used to demonstratecompetitive inhibition, which is predicted to produce a parallelshift with no change in maximal current for the agonist. Unfortunately,the experiments could not be performed in this fashion. The maximalresponse for alphaxalone could not be measured under any conditionsbecause of low aqueous solubility, whereas concentrations of pentobarbital>10 mM produce autoinhibition (see above).

GABA was tested at concentrations of 3, 10, and 30 µM, to cover the EC₅₀ without using such high concentrations that desensitizationbecame a major problem. As shown in Figure 7A, the IC₅₀ for bicucullinein blocking responses to GABA increased at higher GABA concentrations,from 0.9 µM with 3 µM GABA to 1.6 µM (10 µM GABA) and 5.8 µM (30µM GABA). The block appeared to be complete at high enough bicucullineconcentrations (Fig. 7A), and the Hill coefficients were closeto 1 (1.01, 0.95, and 0.97, respectively).
Fig. 7. The blocking effect of bicuculline depends on the concentration of agonist used. Cells transfected with wild-type receptors( $alpha$ 1 $beta$ 2 $gamma$ 2L subunits). Relative responses are shown for responsesto three concentrations of agonist. For each concentration oragonist, the responses in the presence of a blocker are normalizedto the response of that cell to the same concentration of agonistalone. A shows data obtained with GABA as agonist: 3 µM GABA (opencircles, solid line), 10 µM GABA (solid triangles, dotted line),and 30 µM GABA (open squares, dashed line). B shows data obtainedwith pentobarbital as agonist: 100 µM pentobarbital (open circles,solid line), 300 µM pentobarbital (solid triangles, dotted line),and 1000 µM pentobarbital (open squares, dashed line). C showsdata obtained with alphaxalone as agonist: 10 µM alphaxalone (opencircles, solid line), 30 µM alphaxalone (solid triangles, dottedline), and 100 µM alphaxalone (open squares, dashed line). Thelines superimposed on the data show predictions derived from fittingan allosteric blocking model to data from receptors containingwild-type subunits (see Results).
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The action of bicuculline on currents elicited by pentobarbital was more complex. Concentrations of 100, 300, and 1000 µMpentobarbital were used. At the highest concentration of pentobarbital,bicuculline was not able to block the response by more than ~70%,even at 1 mM bicuculline (Fig. 7B). The IC₅₀ values did not dependstrongly on the concentration of pentobarbital, being 1.2 µM (100µM pentobarbital), 0.9 µM (300 µM), and 2.4 µM (1000 mM). TheHill coefficients were close to 1 (0.91, 0.77, and 0.79, respectively).We were concerned that 1 mM pentobarbital might have effects notmediated by GABA_A receptors, so untransfected cells were tested.One millimole pentobarbital did not produce a conductance increasein untransfected cells (six cells tested).

Alphaxalone was used at concentrations of 10, 30, and 100 µM. The IC₅₀ for block by bicuculline increased only very slightlyat higher alphaxalone concentrations (Fig. 7C), from 0.9 µM to1.0 µM and 1.3 µM. The Hill coefficients, again, were close to1 (0.94, 0.87, and 1.2, respectively). The unblocked current athigh concentrations of bicuculline did not differ significantlyfrom zero.

The data in Figure 7 do not support the idea that bicuculline or gabazine act as open channel blockers. An open channel blockerwould be expected to block more effectively as the probabilityof being open increased (Adams, 1976); this is not the case whenblock of currents elicited by different agonists or at differentagonist concentrations are compared.

Bicuculline clearly does not act as a competitive antagonist for pentobarbital: the maximal block was not complete when 1mM pentobarbital was used. The data for alphaxalone are more difficultto interpret, because the maximal concentration was limited byaqueous solubility and was likely to be less than the EC₅₀ forgating by alphaxalone. Block of currents elicited by GABA, onthe other hand, can be described by a competitive interactionbetween bicuculline and GABA. The calculated dissociation constantfor bicuculline is ~1.7 µM, assuming simple competition and theparameters for gating by GABA that are shown in Table 1. (Inthe case of gabazine interacting with GABA, the calculated dissociationconstant for bicuculline is ~0.4 µM.)

Table 1. Values used in an allosteric blocking model

Agonists K1 (µM) K2 (µM) P1 P2

GABA 50 500 350 -

+Bicuculline 50 500 350 -

+Gabazine 50 500 350 -

Pentobarbital 5000 5000 100 -

+Bicuculline 5000 5000 100 600

+Gabazine 5000 5000 100 100

Alphaxalone 200 - 6 -

+Bicuculline 200 - 6 6

+Gabazine 200 - 6 6

Blockers L1 (µM) L2 (µM) Q

Bicuculline 80 80 60

Gabazine 0.6 0.6 0.6

Parameters are defined in Results and Figure 8. A dash indicates that the parameter was not used in a particular fit. It wasassumed that GABA bound to two sites with different microscopicdissociation constants (K1, K2). In the cases of pentobarbital,bicuculline, and gabazine, the microscopic dissociation constantsare assumed to be identical. For alphaxalone, only a single sitewas assumed to exist. The equilibrium constants for activationare shown with only agonist bound (P1), or in the cases of pentobarbitaland alphaxalone for activation with both agonist and blocker bound(P2). The blocking allosteric constant is shown as Q.

An allosteric model can describe the block by gabazine or bicuculline
The observations summarized in Figures 3 and 7 include the following points. First, the IC₅₀ values for block by bicucullineof currents elicited by relatively low concentrations of GABA,alphaxalone, or pentobarbital are similar (Fig. 3A). Second, bicucullinecannot produce a complete block of a response to a high concentrationof pentobarbital (Fig. 7B). Third, the IC₅₀ values for block bygabazine of currents elicited by relatively low concentrationsof GABA, alphaxalone, and pentobarbital are similar (Fig. 3B).Fourth, gabazine cannot produce a complete block of currents elicitedby either alphaxalone or pentobarbital (Fig. 3B). Fifth, the blockingcurves have Hill coefficients near 1. The similarities in IC₅₀values suggest that block results from the binding of antagonistto a single set of sites, no matter which agonist was used toelicit the response. The Hill coefficients suggest that bindingof a single molecule of bicuculline or gabazine is sufficientto produce most of the block seen. The incomplete maximal blockdemonstrates that there cannot be a simple competitive interactionat a single site between the blockers and alphaxalone or pentobarbital.

One model for block that is consistent with these qualitative observations is an "allosteric model." In this model, gabazineor bicuculline do not bind to the sites for alphaxalone or pentobarbital,but bind to distinct sites and produce inhibition by reducingthe probability that the channel of the GABA_A receptor will openafter binding of alphaxalone or pentobarbital. In the particularversion of the model that will be presented, it is assumed thatbicuculline and gabazine bind to the GABA-binding site (see below).Hence, bicuculline and gabazine are assumed to act as "inverseagonists" at the GABA-binding site, as well as to prevent bindingof GABA to that site.

The ability of an allosteric model to describe the data were tested by implementing simplified kinetic schemes (Fig. 8) andexamining the steady-state predictions. We assumed that the receptorcan adopt only three states. The first is the "resting" state(R), which has a closed channel but is activable. The restingstate exists in various states of ligation by agonists and antagonists.The second state is the "active" state (R*), which is likely tobe a complex of states, including the open state and some short-liveddesensitized states (Maconochie et al., 1994; Jones and Westbrook,1995). The active state, therefore, is not identical to the "open"state of the receptor. The third state is the "dead" state (r),which is a state induced after the binding of blocker. The deadstate has a nonconducting channel and is mutually exclusive withthe active state. The dead state was chosen as one way to modelthe effects of blockers. Alternative schemes would include aneffect of blocker binding on agonist binding or a direct effecton the channel-opening rates for agonists. The choice of a deadstate was made for two reasons. First, some evidence suggestedthat blockers can induce conformational changes in the GABA_A receptor(see Results and Discussion). Second, the postulated dead statewas treated as being determined solely by the blocking drug, ratherthan requiring an interaction between blocker and agonist, andso the mechanism seemed to be aesthetically preferable becauseit allowed us to set parameters for blocker interactions withthe receptor, independent of the agonist used.
Fig. 8. A diagram of the kinetic models used to assess the ability of a simplified allosteric model to describe the data. The modelsare described in Results. A shows the binding of blocker (X, bicucullineor gabazine) and the ensuing conformational change to the "dead"state (r). Note that the equilibrium constants (L1, L2, and Q)are omitted from B-D to simplify the figure. B-D show schemesfor GABA, pentobarbital, and alphaxalone, respectively. Receptorstates with open channels are boxed. B, GABA (G) was assumed tobind to the same two sites as blockers, so fewer heteroligandedforms of the receptor can occur. Furthermore, the channel canonly activate when two GABA molecules are bound. C, Pentobarbital(B) was also assumed to bind to two sites, but in this case bothpentobarbital and blockers can occupy sites on the same receptor.It was assumed that two pentobarbital molecules must be boundfor a channel to activate and that dead receptors cannot activate.D, Alphaxalone (A) was assumed to bind to only a single site,but otherwise the scheme is identical to that for pentobarbital.Some binding steps (e.g., to the r state) are omitted for clarityin the figure.
[View Larger Version of this Image (23K GIF file)]

We postulated the minimal number of sites required by the data as two sites for GABA, two sites for pentobarbital, and onesite for alphaxalone (see below). We assumed that the blockingdrugs bind to both of the GABA-binding sites and that bindingof GABA and a blocker is mutually exclusive. We also constrainedthe parameters by requiring that there be minimal interactionbetween the drugs. For example, the dissociation constants foragonists are assumed to be independent of blocker binding andvice versa.

The interactions of the blocking drugs (symbolized as X; bicuculline or gabazine) with the receptor are shown in Figure 8A.Each can bind to two sites on the resting GABA_A receptor (R).The number of sites was chosen to match the minimal number ofGABA-binding sites, as GABA activation requires at least two sites(see below). It was assumed that the microscopic dissociationconstant is the same for the two sites (L), so the microscopicdissociation constants are identical (L1 = L2 = L). After binding,the receptor can change state to the dead condition (r). For simplicity,the forward conformational change constant was assumed to be independentof the state of ligation, and Q gives the ratio Xr/XR. The observationthat the Hill coefficient for block is close to 1 is consistentwith this simplifying idea.

The interactions of GABA (G) are shown in Figure 8B. GABA was assumed to bind to two sites, because the Hill coefficient forgating is >1 (Fig. 1A). We show different microscopic dissociationconstants for the two binding steps (K1 and K2), based on theresults obtained by Maconochie et al. (1994). After two GABA moleculeshave bound, the resting receptor can change conformation to theactive state (R*), with an activation equilibrium constant P1= G₂R*/G₂R. We have neglected the contribution of open channelswith only a single GABA molecule bound (Twyman et al., 1990).This was performed to simplify the model, but it seems justifiablebecause the Hill coefficient for activation by GABA suggests thatmost receptors with open channels also have two molecules of GABAbound. We assumed that GABA and the blocking drugs bind competitivelyto the same sites, so that the receptor cannot be activated byGABA if a blocker is bound to either site. Hence, there is onlyone state with an open channel, G₂R*. To simplify the scheme,we assumed that parameters for blocker interaction (L, Q) arethe same whether GABA is bound to one site or not.

The interactions of pentobarbital (B) are shown in Figure 8C. Pentobarbital was assumed to bind to two sites, because theHill coefficient for gating is >1 (Fig. 1B). In fitting the scheme,we assumed that the microscopic dissociation constant is identicalfor the two sites (because there are no data to indicate otherwise),so the microscopic dissociation constants are the same (K1 = K2= K). We assumed that pentobarbital binding is unaffected by blockerand that channel opening could occur so long as the receptor isnot dead (that is, so long as the receptor was not in the r state).Hence, there are three states with an open channel: B₂R*, B₂XR*,and B₂X₂R*. As shown in the scheme, we allowed for the possibilitythat channel activation could differ for receptors with only pentobarbitalbound (P1) or with both pentobarbital and blocker bound (P2).Again, we assumed that parameters for blocker interaction (L,Q) are the same whether pentobarbital is bound or not.

The interactions of alphaxalone (A) are shown in Figure 8D. Alphaxalone was assumed to bind to a single site, because theconcentration-effect relationship had a limiting slope of only1 (Fig. 1C). (Our data, however, would also be consistent withmore than one site, depending on gating properties of variousstates of ligation.) The other assumptions were identical to thosefor pentobarbital.

The quality of the fit of the predictions to the data was assessed by eye while the parameters were adjusted. For each agonist,the concentration-response curve (Fig. 1) was fit by adjustingK and P1. In the case of GABA, we used values for K1 and K2 basedon the data in Maconochie et al. (1994) and adjusted only P1.For pentobarbital and alphaxalone, the values for K and P1 wereadjusted without additional constraints. As mentioned above, inthe case of pentobarbital it was assumed that the microscopicdissociation constants were the same for the two sites. As shownin Figure 1A-C, the parameters used can provide an adequate descriptionof the concentration-response curves for agonists.

The parameters for bicuculline and gabazine (L and Q) were then estimated using the data for block of currents elicited bymultiple concentrations of agonists (Figs. 3, 7). Finally, thevalues for P2 (the activation equilibrium constant for receptorswith both agonist and blocker bound) were adjusted for alphaxaloneand pentobarbital (Figs. 3, 7).

Overall, it was possible to obtain an excellent match to the data (Figs. 3, 7). The parameter estimates are shown in Table1. The overriding consideration was to have a single set of valuesthat could be used for all conditions. Accordingly, parametersfor agonists (K, P1) were fixed at the values used to describethe data in Figure 1, and the same values for L and Q were usedto describe the blocking effects on currents elicited by all theagonists.

As described above, this particular model was chosen because it separated actions of agonists and antagonists. It was assumedthat no interactions between agonists and antagonists occurredfor binding (that is, values for K and L were assumed to be independentof occupancy). Also, the conformational change induced by antagonist(described by Q) was assumed to be independent of the bindingof agonists. All other possible interactions between blocker andagonist were included in the free parameter used to describe theactivation equilibrium constant for receptors with both blockerand agonist bound (P2) for alphaxalone and pentobarbital. As shownin Table 1, for most pairs of agonist and antagonist the samevalue was used for P1 and P2; however, it was necessary to havedifferent values for P1 (100) and P2 (600) to describe the interactionof pentobarbital and bicuculline. If the same value were usedfor P1 and P2, the predicted response to 1 mM pentobarbital plushigh bicuculline reached a plateau at ~0.1 of control, ratherthan the 0.3 seen in the data (Fig. 7B). On the face of it, thiswould indicate that bicuculline is a "co-agonist" for pentobarbital;however, as just discussed, the interpretation of this parameteris not obvious, because it might actually include an effect onbinding (e.g., lower affinity for bicuculline when two pentobarbitalmolecules were bound) or conformational changes (e.g., lower valuefor Q when two pentobarbital molecules were bound).

The values for parameters seem to be reasonable. The intrinsic affinity of GABA for the resting receptor is likely to be ratherlow, based on independent results obtained using rapid applicationsof GABA (Maconochie et al., 1994). Pentobarbital is predictedto have even lower affinity, but direct data are not yet availablefor comparison. Gating by alphaxalone could only be approximated,because the maximal response could not be observed. The measuredEC₅₀ for channel gating occurs at lower agonist concentrationsthan the estimated affinities for the resting receptor, becausethe high equilibrium activation constant shifts the overall equilibriumto favor the activated state (for more discussion, see Maconochieet al., 1994).

Both GABA and pentobarbital are effective activators (P1 $>>$ 1), whereas alphaxalone may be less effective. It should be emphasizedthat P1 is not necessarily directly related to the opening andclosing rates for the receptor, because the postulated "active"state likely includes both open-channel and closed-channel states.Some independent information is available for channel activationby rapid applications of GABA (Maconochie et al., 1994). The maximalactivation rate is ~6000 sec¹. The rate for leaving the active state is in the range of 5-100sec¹, depending on which experimental parameter is taken as the bestestimate. The low concentration asymptote for the rate of currentdevelopment is ~10 sec¹, whereas the components present in the decay of current afterthe removal of GABA have decay rates of ~5 sec¹ and ~80 sec¹. Hence, P1 for GABA may lie in the range of 60-1000. The predictedmaximal probability of being active is P1/(1 + P1), which is ratherdifferent from the maximal probability of being open [Po = (openingrate)/(opening rate + closing rate)]. As a consequence, the relativevalues for P1 do not directly address the question of the maximalresponses to agonists. Depending on what fraction of time theactive receptor spends in the open state, two agonists with identicalvalues for P1 might have different maximal responses. Finally,this last point emphasizes the fact that the parameters are estimatedunder the assumption that activation processes have equilibrated,including some possible rapid transitions to closed states involvedin the active state.

For $alpha$ 1 $beta$ 2 $gamma$ 2L receptors, bicuculline is much better at inducing the conformational change to the dead state (Q = 60) than gabazine(Q = 0.6). Because the measured IC₅₀ values at low agonist concentrationsare comparable for the two blockers, the actions of bicucullineare described by a lower affinity for the resting receptor thangabazine.

We conclude that it is possible to describe our data with a simplified version of an allosteric model. Hence, the overallmodel remains viable. Additional evidence that provides circumstantialsupport for an allosteric model is presented in the Discussion.

Potentiation between responses to steroids and pentobarbital
We found that steroids and pentobarbital interact essentially normally at receptors composed of $alpha$ 1 $beta$ 2(Y205S) $gamma$ 2L subunits, inthat the combined applications of a steroid and pentobarbitalresult in potentiation of the response. Responses of cells weredetermined when 250 µM pentobarbital was applied alone or in thepresence of 10 µM DHP-OH. Responses of $alpha$ 1 $beta$ 2 $gamma$ 2L (wild-type) receptorswere enhanced ninefold (9.3 ± 4.3-fold; mean ± SD for responsesfrom nine cells), whereas responses from receptors containing $alpha$ 1 $beta$ 2(Y205S) $gamma$ 2L subunits were enhanced sevenfold (7.2 ± 2.2; eightcells). The difference is not statistically significant. Theseresults demonstrate that the sites involved in potentiation betweensteroids and barbiturates do not involve the $beta$ 2(Y205) residue.The interactions between gabazine or bicuculline and alphaxaloneat receptors containing the $beta$ 2(Y157S) mutant also indicate thatpotentiation by steroids is not removed by this mutation. Thedata do not directly address the question of whether the bindingsites involved in direct gating are the same as those involvedin potentiation; however, these experiments have not demonstrateda dissociation between the two actions.

DISCUSSION

Point mutations do not affect gating by steroids
Mutation of two residues in the $beta$ 2 subunit, $beta$ 2(Y205S) and $beta$ 2(Y157S), did not affect direct gating by steroids of GABA_A receptorsformed from the $alpha$ 1, $gamma$ 2L, and mutated $beta$ 2 subunits. However, thesemutations reduced the affinity of bicuculline or gabazine, asassayed by effects on gating by steroids, suggesting that theyform important determinants of inhibitor binding and/or a subsequentconformational change. Previous studies had shown that these mutationsgreatly reduced the binding affinity of GABA but did not affectgating by pentobarbital (Amin and Weiss, 1993). We conclude thatthese particular residues are not required for the binding ofsteroids or barbiturates or for the subsequent conformationalchanges that result in channel opening.

Mechanism for inhibition of gating produced by steroids and barbiturates
There are two basic models that are consistent with the results we obtained on the concentration dependence of block by gabazineand bicuculline. The first is the "many-sites" model. In thiscase, alphaxalone or pentobarbital is postulated to bind to atleast two classes of sites on each GABA_A receptor, occupancy ofeither of which can result in channel opening. Gabazine or bicucullineare postulated to act as competitive antagonists with differentaffinities at the two sites. The sites required for direct gatingby steroids may differ from those required for gating by barbiturates.This model would include a multiplicity of parameters to specifythe dissociation constants for drugs at the many sites and themany possible activation equilibrium constants. We are confidentthat the many-sites model could describe the data satisfactorily.One particular version of this model should be mentioned. Themany sites might not be located on a single receptor, but insteadmight result from the expression of a heterogeneous populationof receptors with different representations or arrangements ofsubunits. Our data cannot exclude this possibility. The concentration-responsecurves for pentobarbital and GABA are consistent with the ideathat a single population of receptors exists, as is the observationthat blocking curves have Hill coefficients near 1 (multiple populationswould tend to produce low Hill coefficients in either assay).

The second model is the "allosteric" model described in Results. In this case, gabazine or bicuculline do not bind to thesites for alphaxalone or pentobarbital, but they produce inhibitionby favoring an inactivated state of the receptor so that bindingof alphaxalone or pentobarbital does not result in channel activation.As presented in Results, the allosteric model can accommodatequalitative observations which are more difficult to reconcilewith competitive models, especially the similar IC₅₀ values againstmultiple agonists and incomplete maximal block. The modeling calculationsindicate that a relatively constrained allosteric model can describemajor quantitative features of the data with an internally consistentset of parameters. The allosteric model also has the aestheticappeal that the total number of postulated sites is lower thanfor the many-sites model and the circumstantial support that inverseagonists are known for other sites on the GABA_A receptor (Macdonaldand Olsen, 1993).

Whatever precise model is eventually supported, the data clearly rule out the possibility that gabazine blocks currents elicitedby either steroids or barbiturates by simple competition at asingle site. Results from other studies (see below) and the presentobservations with mutated $beta$ 2 subunits support the idea that bothgabazine and bicuculline bind directly to the GABA-binding site,rather than binding to yet another site on the GABA_A receptor.Hence, although they may also produce conformational changes inthe receptor, a primary action is to occupy the GABA-binding site.Overall, then, we conclude that at least one site for bindingsteroids (and one for barbiturates) is sufficiently distant fromthe GABA-binding site that relatively bulky blocking drugs boundto the GABA-binding site do not overlap with steroid or barbituratesites. Furthermore, both gabazine and bicuculline can reduce activationof the GABA_A receptor by an allosteric inhibition of channel activationafter the binding of either alphaxalone or pentobarbital.

Point mutations alter the binding and actions of bicuculline and gabazine
Both the $beta$ 2(Y157S) and $beta$ 2(Y205S) mutations reduce the apparent affinity of gabazine and bicuculline in a fashion expectedfrom the effects of the mutations on GABA binding (Amin and Weiss,1993), as assayed from effects on alphaxalone-gated currents;however, two additional changes occur. The first is that the $beta$ 2(Y157S)mutation converts both bicuculline and gabazine to weak agonists.The second is that the $beta$ 2(Y205S) mutation changes the efficacyof gabazine at blocking steroid-gated currents, so that the maximalinhibition is increased over wild type. The conversion to partialagonism indicates that both drugs have the potential to causeconformational changes in GABA_A receptors. Furthermore, the changein efficacy of gabazine is consistent with the idea of an allostericmechanism for inhibition, although it is also possible that thepostulated "many sites" for steroids might differ in receptorscontaining this mutated subunit. These observations demonstratethat both residues, $beta$ 2(Y157) and $beta$ 2(Y205), are involved in determiningthe binding affinity and subsequent conformational changes forgabazine and bicuculline.

Point mutations of a residue in the $alpha$ 1 subunit (F64) have also been shown to reduce the affinity of GABA, bicuculline, andgabazine (Sigel et al., 1992); however, in this case, no partialagonist activity of bicuculline or gabazine was noted. A pointmutation of the glycine receptor $alpha$ 1 subunit has been describedthat changes the action of picrotoxin from inhibition to potentiation(Lynch et al., 1995).

Previous studies of bicuculline and gabazine suggest an allosteric mechanism for inhibition
Bicuculline and gabazine are viewed as classic competitive inhibitors of GABA binding to the GABA_A receptor (Macdonald andOlsen, 1993), but there are indications that they can induce conformationalchanges in the GABA_A receptor. A recent analysis of recombinantreceptors expressed in HEK293 cells found that both bicucullineand gabazine reduced the binding of t-butylbicyclophosphorothionate(TBPS; Luddens and Korpi, 1995). In most cases the inhibitionwas only partial, and the efficacy of the two drugs depended onthe subunit combination expressed. In the case of the $alpha$ 1 $beta$ 2 $gamma$ 2 combination(which we examined in the present studies), gabazine had no effecton TBPS binding. Bicuculline reduced the binding by ~50%, withan IC₅₀ of ~1-5 µM. The greater effect of bicuculline is consistentwith our observation that bicuculline is a more effective antagonistof gating by steroids or barbiturates. In terms of the allostericmodel, this difference arises from a larger allosteric constant(Q) for bicuculline. There are also results from binding studiesthat bicuculline and gabazine interact allosterically with barbituratesor steroids. Pentobarbital has been reported to inhibit the bindingof labeled bicuculline (Wong et al., 1984) and gabazine (McCabeet al., 1988) by allosteric mechanisms. Similarly, studies ofTBPS binding suggest that bicuculline allosterically inhibitsalphaxalone binding (Gee et al., 1987). A quantitative comparisoncannot be made to our data, because the binding studies are performedon isolated receptors in an unknown physiological state. The observations,however, agree qualitatively with our interpretations, and ithas already been suggested that bicuculline and gabazine may actas inverse agonists at the GABA-binding site (Luddens and Korpi,1995).

Studies of the inhibition of GABA-elicited responses have shown that both bicuculline (Akaike et al., 1987b) and gabazine(Hamann et al., 1988) shift the concentration-response curve tohigher GABA concentrations but do not depress the maximal response.These data demonstrate that the binding of GABA and the inhibitorsis mutually exclusive; however, they do not demonstrate whetherbicuculline or gabazine has effects on the receptor in additionto preventing GABA binding. The effects of point mutations ofthe $beta$ 2 subunit on the apparent affinity of GABA, bicuculline,and gabazine provide support for the idea that these three drugsbind to the same site on the GABA_A receptor.

It has been known for a number of years that bicuculline blocks currents elicited by pentobarbital (Nicoll and Wojtowicz,1980) or alphaxalone (Barker et al., 1987; Peters et al., 1988).A recent study examined receptors composed of $alpha$ 6 $beta$ 3 $gamma$ 2S subunitsexpressed in Xenopus oocytes (Thompson et al., 1996). Pentobarbitalwas an effective agonist at these receptors, but neither bicucullinenor gabazine blocked pentobarbital-gated currents. Thompson etal. (1996) concluded that pentobarbital does not bind to the GABA-bindingsite. They suggested that the contradiction between the lack ofblock observed in their work and previous observations resultedfrom potentiation between pentobarbital and endogenous GABA inother preparations. It seems more likely that the differencesreflect properties of the particular GABA_A subunit combinationstudied (Luddens and Korpi, 1995), and these observations areconsistent with an allosteric mechanism for block of pentobarbital-gatedcurrents.

Bicuculline can also block activation of GABA_A receptors by n-octanol (Arakawa et al., 1992), isoflurane (Yang et al., 1992),or propofol (Hara et al., 1993). The general efficacy of bicucullinein blocking channel activation provides some circumstantial supportfor the idea that it acts allosterically to inhibit channel activation.

Implications for gating of GABA_A receptors
These results support the idea that the agonists GABA, alphaxalone, and pentobarbital produce activation of the GABA_A receptorafter binding to different sites on the receptor. Occupation ofthe GABA-binding site by bicuculline or gabazine antagonizes gatingby alphaxalone or pentobarbital by an allosteric mechanism. Itis not known how many distinct conformational changes can occurto produce receptors with open or closed channel states. For exampledoes bicuculline "lock the gate" or "close a second gate"? Theeffects of the point mutants, however, suggest that transductionof the occupancy of different agonist-binding sites into channelopening may require the presence of different specific residuesin the $beta$ subunit.

FOOTNOTES

Received Aug. 15, 1996; revised Oct. 31, 1996; accepted Nov. 15, 1996.

This research was supported by National Institutes of Health (NIH) Grant PO1 GM47969 to J.H.S. and C.Z., NIH Grants AA09212and NS35291 to D.S.W., National Institute of Mental Health ResearchScientist Development Award MH00964 to C.Z., and funds from theAnesthesiology Department, Washington University School of Medicine.We thank A. Tobin for the $alpha$ 1 subunit cDNA.

Correspondence should be addressed to Joe Henry Steinbach, Department of Anesthesiology, Washington University School of Medicine,660 South Euclid, St. Louis, MO 63110.

Dr. Ueno's present address: Division of Pharmacology, National Institute of Health Sciences, 1-18-1 Kamiyoga, Tokyo 158, Japan.

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Copyright ©1997 Society for Neuroscience

Bicuculline and Gabazine Are Allosteric Inhibitors of Channel Opening of the GABA_A Receptor