The Interactions of Hexachlorocyclohexane Isomers with Human gamma -Aminobutyric AcidA Receptors Expressed in Xenopus Oocytes

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Vol. 282, Issue 3, 1557-1564, 1997

The Interactions of Hexachlorocyclohexane Isomers with Human $gamma$ -Aminobutyric Acid_A Receptors Expressed in Xenopus Oocytes

L. S. Aspinwall¹ , I. Bermudez, L. A. King and K. A. Wafford

School of Biological and Molecular Sciences, Oxford Brookes University, Gipsy Lane Campus, Oxford, OX3 0BP (L.S.A., I.B., L.A.K.) and Merck Sharp & Dohme Research Laboratories, Neuroscience Research Centre, Terlings Park, Eastwick Road, Harlow, Essex, CM20 2QR (K.A.W.)

	Abstract

Top Abstract Introduction Methods Results Discussion References

The effects of $gamma$ -hexachlorocyclohexane ( $gamma$ -HCH) and its $alpha$ , $beta$ and $delta$ isomers on the $gamma$ -aminobutyric acid (GABA) responses of human $alpha$ 1 $beta$ 3 $gamma$ 2S and $alpha$ 6 $beta$ 3 $gamma$ 2S GABA_A receptors expressed in Xenopus oocyteswere examined by conventional two-electrode voltage-clamp techniques. $gamma$ -HCH induced partial inhibition of EC₅₀ GABA responses, whereasthe $alpha$ and $delta$ isomers produced potentiation of EC₂₀ GABA currents.In contrast, $beta$ -HCH had no effect on GABA currents, even at concentrationsas high as 100 µM. The effects of the active HCH isomers werenot influenced by alpha subunit composition because there wasno significant difference in either the inhibition or potentiationof $alpha$ 1 $beta$ 3 $gamma$ 2S or $alpha$ 6 $beta$ 3 $gamma$ 2S GABA_A receptors. $delta$ - and $gamma$ -HCH antagonizedpicrotoxin inhibition and caused displacement of specific [³⁵S]t-butylbicyclophosphorothionate binding. $delta$ -HCH potentiationwas found to be additive with steroid, loreclezole and lanthanumpotentiation, but nonadditive with potentiation by pentobarbitaland propofol, which suggested that its activity was linked tothe barbiturate site.

	Introduction

Top Abstract Introduction Methods Results Discussion References

The GABA_A receptor is a transmembrane protein complex that forms an ion channel that is selectively permeable to chlorideions. The channel is directly gated by GABA, and the protein subunitsthat make up the receptor have specific binding sites for convulsantssuch as picrotoxin and TBPS, as well as barbiturates, benzodiazepinesand the anesthetic steroids. Cloning of the GABA_A receptor subunitcDNAs has revealed considerable heterogeneity, with at least sixalpha, four beta, three gamma, one delta and two rho subunits,which provides a molecular basis for multiple GABA_A receptor subtypeswhich distribute throughout the brain (McKernan and Whiting, 1996).

Organochlorine insecticides such as $gamma$ -HCH or lindane also interact with the GABA_A receptor, inducing convulsions of the GrandMal type (Tussel et al., 1987; Portig and Schnorr, 1988) and inhibitingGABA-induced chloride flux in a wide range of mammalian brainpreparations (Abalis et al., 1986; Bloomquist et al., 1986; Poméset al., 1994) and in Xenopus oocytes expressing rat GABA_A receptors(Woodward et al., 1992). Studies showing that $gamma$ -HCH displaces[³⁵S]TBPS from its binding site in rat brain membrane homogenates(Lawrence and Casida, 1984; Llorens et al., 1990) suggest thatthis insecticide acts by interacting with the picrotoxin siteof the GABA_A receptor. In contrast, the $alpha$ , $beta$ and $delta$ isomers of $gamma$ -HCH have been reported to have only weak effects or act as centralnervous system depressants (McNamara and Krup, 1948). The siteof action of these isomers in the mammalian central nervous systemhas not been determined yet, although studies, which show themto potentiate GABA-activated chloride channels in Xenopus oocytes(Woodward et al., 1992) and in primary cultures of cortical (Poméset al., 1994) and dorsal root ganglion neurons (Nagata and Narahashi,1995), indicate that they interact with the GABA_A receptor. Herewe report studies of [³⁵S]TBPS binding in membrane homogenates of a mammalian clonal cellline expressing the human $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptor subtype and voltage-clamprecordings of human GABA_A receptors expressed in Xenopus oocytes,which suggests that $gamma$ -HCH is a partial inverse agonist of thepicrotoxin site and that $delta$ -HCH interacts with a site linked tothe barbiturate locus of the GABA_A receptor.

	Methods

Top Abstract Introduction Methods Results Discussion References

Human GABA_A receptor subunit cDNAs. Complementary DNAs encoding human GABA_A $alpha$ 1, $alpha$ 6, $beta$ 3 and $gamma$ 2S receptor subunits have been described elsewhere (Hadingham et al.,1993a,b, 1996).

Electrophysiology. To obtain oocytes, adult Xenopus frogs were anesthetized by immersion for 30 to 45 min in a solution of 0.4% ethyl m-aminobenzoate(Tricaine), and a small piece of ovary was removed through anincision in the abdominal wall. Stage V and VI oocytes were isolatedand the theca and epithelial cell layer were removed mechanicallywith fine watchmaker forceps. Follicle cells were removed by an8-min treatment in Sigma type IA collagenase (0.5 mg/ml) dissolvedin MBS (88 mM NaCl, 1 mM KCl 10 mM HEPES, 0.82 mM MgSO₄, 0.33mM Ca(NO₃)₂, 0.91 mM CaCl₂, 2.4 mM NaHCO₃, pH 7.5). Oocyte nucleiwere directly injected with 10 to 20 nl of sterile buffer (88mM NaCl, 1 mM KCl, 15 mM HEPES, pH 7.4) containing different combinationsof human GABA_A subunit cDNAs engineered into the expression vectorspcDM8 or pcDNAI/Amp. Oocytes were incubated for 1 to 2 days inMBS supplemented with 2 mM sodium pyruvate, 2 ml/l penicillinstreptomycin solution (containing 100 U/ml penicillin, 10 mg/mlstreptomycin), and 50 mg/l gentamycin. For recording, oocyteswere placed in a 50-µl bath and perfused with MBS at 4 to 6 ml/min.Cells were impaled with two 1 to 3 megohm agarose-cushion electrodescontaining 2 M KCl and were voltage-clamped at $-$ 70 mV. Drugs wereapplied in the perfusate and GABA was applied until the peak ofthe response, which for most of the oocytes was 30 sec or less.To measure potentiation by allosteric modulators a submaximalconcentration of 20% was chosen, which gave optimal potentiationwhile remaining on the linear portion of the curve. To measureinhibition of GABA responses an EC₅₀ concentration was chosen,which gave a robust signal without the run-down problems associatedwith continuous challenging with a maximum concentration. Aftermaximal response to GABA (3 mM), constant responses to an EC₂₀or EC₅₀ concentration were obtained. An EC₂₀/₅₀ concentrationwas the concentration of agonist that produced 20% or 50% of themaximal response for that agonist. At least 3 min were allowedbetween each drug application to prevent desensitization. Concentration-responsecurves were fitted by use of GraFit (Erithacus software, fromSigma-Aldrich Ltd., Poole, Dorset, U.K.) to the equation: f(x)= B_max/[1 + (EC₅₀/X)ⁿ], where B_max is the response at saturating concentration of ligand;EC₅₀, the concentration of ligand producing a half-maximal response;X, the concentration of ligand; and n, the Hill coefficient. Arithmeticmean values were calculated from data obtained from a number (n)of different cells. The statistical significance of differencesbetween mean values were assessed by Student's two-tailed t tests,wherever appropriate.

GABA_A receptor cell line. Mouse fibroblasts stably expressing the human $alpha$ 1 $beta$ 3 $gamma$ 2 GABA_A receptor were maintained as described previously (Hadingham etal., 1992). Semiconfluent cells containing the human $alpha$ 1 $beta$ 3 $gamma$ 2s GABA_Areceptor were induced with 2 µM dexamethasone for 8 days to gainmaximum expression of the recombinant receptor.

[³⁵S]TBPS binding assay in membranes of induced mouse clonal cells. Eight-day induced cells were washed off culture flasks with phosphate-buffered saline (pH 7.4). Cells were washed twice for5 min at 200 × g, resuspended in 5 ml of ice-cold 5 mM Tris citrate(pH 7.4) containing 1 mM ethylenediaminetetraacetic acid, 1 mMphenylmethylsulfonyl fluoride, 1 mM benzamidine hydrochloride,1 mM leupeptin and 0.5 mM soybean trypsin, pH 7.4. Cells werethen broken up by probe sonication on ice, for a total of 30 sec(three 10-sec bursts to prevent overheating). The homogenate wascentrifuged for 5 min to remove nuclear material (200 × g; 4°C),and the supernatant was centrifuged for 1 hr at 90,000 × g, at4°C. The resulting pellet was resuspended in 5 ml of 50 mM Triscitrate, pH 7.4, and quickly frozen and thawed. The thawed homogenatewas then incubated for 30 min in 50 mM Tris citrate containing0.01% Triton X-100 at 37°C. The homogenate was then washed twicein 50 mM Tris citrate buffer, pH 7.4, by centrifugation at 90,000× g for 1 hr. The final pellet was resuspended in the requiredvolume of 50 mM Tris citrate buffer. Protein content was determinedusing a commercially available Bio-Rad kit.

[³⁵S]TBPS binding to membranes was measured by incubating 100-µl samples of the membrane (25 µg) at room temperature for 2 hrin the presence of 50 µl of [³⁵S]TBPS (5 nM final concentration; 98.5 Ci/mmol; NEN Products,Stevenage, Herts, U.K.) and 100 µl of assay buffer with or withoutcompeting ligand ( $alpha$ -HCH, $beta$ -HCH, $delta$ -HCH and $gamma$ -HCH) at concentrationsranging from 1 nM to 100 µM. Nonspecific binding was determinedwith use of 100 µM cold TBPS. Bound [³⁵S]TBPS was separated from free [³⁵S]TBPS by vacuum filtration through Whatman GF/B filters. Allexperiments were performed in triplicate. Displacement data werefit to the equation described above.

Drugs. Drugs used were: GABA (Sigma-Aldrich), picrotoxin (Sigma-Aldrich), $gamma$ - and $delta$ -HCH (Sigma-Aldrich), loreclezole (a gift of Jannsens),5 $alpha$ -pregnan-3 $alpha$ -ol-20-one (5 $alpha$ ,3 $alpha$ -DHP) (Sigma-Aldrich), lanthanum(Sigma-Aldrich), pentobarbital (Sigma-Aldrich) and propofol (AldrichChemical Co., Gillingham, Dorset, U.K.). The $alpha$ - and $beta$ -HCH isomerswere a gift from Dr Stuart Dunbar, Zeneca Agrochemicals, U.K.Solutions of GABA were made in saline, while loreclezole, 5 $alpha$ ,3 $alpha$ -DHP,lanthanum, picrotoxin, propofol and HCH isomers were preparedas 10¹ M or 10² M stocks in DMSO, while pentobarbital was supplied as a 60 mg/mlsolution in ethanol. The highest concentration of DMSO or ethanolvehicle perfusing the oocyte was 1%, which had no effects on GABA-inducedcurrents.

	Results

Top Abstract Introduction Methods Results Discussion References

Effects of $gamma$ -HCH and its $alpha$ , $beta$ and $delta$ isomers on GABA responses. $gamma$ -HCH and its $alpha$ , $beta$ and $delta$ isomers (fig. 1) were studied on recombinant human GABA_A $alpha$ 1 $beta$ 3 $gamma$ 2S receptors to investigate their effecton GABA-mediated responses. The isomers (100 µM) were applied30 sec before the coapplication of an EC₂₀ GABA concentration(or EC₅₀ for $gamma$ -HCH). As shown in figure 2, the $alpha$ - and $delta$ -HCH isomerspotentiated the GABA-mediated response by about 150% and 185%,respectively, as well as the $delta$ isomer producing a small amountof receptor activation in the absence of GABA. In contrast, $gamma$ -HCHinhibited the GABA EC₅₀ response by approximately 30%, and the $beta$ isomer had no significant effect. To elucidate the mechanismunderlying the two opposite effects of the HCH isomers, we characterizedthe actions of $gamma$ -HCH and its $delta$ isomer in more detail.

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Fig. 1. Structures of the $alpha$ -, $beta$ -, $gamma$ - and $delta$ -HCH stereoisomers.

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Fig. 2. Effects of HCH isomers on GABA responses in oocytes expressing human $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors. Oocytes were clamped at $-$ 70mV, and EC₂₀ or EC₅₀ GABA responses were elicited in the presenceor absence of 100 µM HCH isomer. To study potentiation of theGABA_A receptor, a submaximal EC₂₀ concentration was chosen in(a), (b) and (d). To measure inhibition with $gamma$ -HCH (c), an EC₅₀concentration was used (see "Methods"). $gamma$ -HCH inhibited EC₅₀ GABAresponses, whereas the $alpha$ and $delta$ isomers clearly potentiated EC₂₀GABA responses, with $delta$ -HCH having an additional direct actionon GABA_A receptors. $beta$ -HCH had no effect on EC₂₀ GABA-mediatedcurrents.

$gamma$ - and $delta$ -HCH concentration-response curves. To determine the potency and efficacy of the two isomers on GABA responses in oocytes expressing human $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors,concentration-response curves were constructed with an EC₂₀ concentrationof GABA for the potentiation by the $delta$ isomer and EC₅₀ for theinhibition by the $gamma$ isomer determined on individual oocytes. Figure3A shows that the effect of $gamma$ -HCH was concentration-dependent,giving a maximum inhibition of 33.8 ± 3.6% (n = 7), and gave nofurther inhibition at concentrations greater than 10 µM. The EC₅₀for $gamma$ -HCH was 1.0 ± 0.3 µM (n = 7). Similar results have alsobeen reported for Xenopus oocytes expressing RNA from rat cerebralcortex (Woodward et al., 1992). Concentration-response curvesfor $delta$ -HCH potentiation of GABA responses demonstrated a potentiationof the GABA EC₂₀ with a maximum of 216 ± 31% (n = 7) (fig. 3B).The EC₅₀ value for $delta$ -HCH potentiation was 15.3 ± 3.7 µM (n = 7).

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Fig. 3. Concentration-response curves for the effects of $gamma$ - and $delta$ -HCH on GABA responses on oocytes expressing human $alpha$ 1 $beta$ 3 $gamma$ 2S (filledcircles) or $alpha$ 6 $beta$ 3 $gamma$ 2S (open circles) GABA_A receptors. (a) The inhibitoryaction of increasing concentrations of $gamma$ -HCH on EC₅₀ GABA responseswas studied. (b) The effect of the $delta$ isomer was analyzed on EC₂₀GABA responses (see "Methods").

The alpha subunit of the GABA_A receptor influences the pharmacology of the GABA (Ebert et al., 1994

), benzodiazepine (Pritchettet al., 1989

; Wafford et al., 1993

) and barbiturate (Thompsonet al., 1996

) sites. To determine whether alpha subunit compositioncould also influence the effects of $gamma$ -HCH and its $delta$ isomer onGABA responses, we tested the effect of these compounds on oocytesexpressing the human $alpha$ 6 $beta$ 3 $gamma$ 2S GABA_A receptor subtype. As shownin figure 3A, the effects of $gamma$ -HCH on the GABA responses mediatedby $alpha$ 6 $beta$ 3 $gamma$ 2S GABA_A receptors were not significantly different fromthe effects observed with the $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors, showingthe same degree of maximal inhibition (30.8 ± 3.8%; n = 6) andEC₅₀ (1.3 ± 0.4 µM; n = 6). The maximum potentiation (342 ± 52%;n = 6) of the $alpha$ 6 $beta$ 3 $gamma$ 2S receptor by the $delta$ isomer was not significantlyhigher than the value determined for the $alpha$ 1 $beta$ 3 $gamma$ 2S subunit combination(fig. 3B). The EC₅₀ was also similar to that on $alpha$ 1 $beta$ 3 $gamma$ 2S (13.8± 3.4 µM; n = 6).

In addition to its positive allosteric effect, $delta$ -HCH directly activated the GABA_A receptor, which resembled the effects ofpentobarbital (Thompson et al., 1996

), propofol (Orser et al.,1994

) and neuroactive steroids (Puia et al., 1990

). The directeffect was observed at concentrations higher than 1 µM, whichis similar to the concentration range at which barbiturate, propofoland neuroactive steroids activate GABA_A receptors. The maximumefficacy and EC₅₀ were similar for both $alpha$ 1 $beta$ 3 $gamma$ 2 (22.7 ± 2.6% ofa maximum GABA response; 53.6 ± 10.5 µM; n = 5) and $alpha$ 6 $beta$ 3 $gamma$ 2 (18± 3.3% of a maximum GABA response; 39.2 ± 5.2 µM; n = 7) subunitcombinations (fig. 4).

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Fig. 4. Concentration-response curve for the direct effect of $delta$ -HCH on oocytes expressing $alpha$ 1 $beta$ 3 $gamma$ 2S (filled circles) or $alpha$ 6 $beta$ 3 $gamma$ 2S (opencircles) GABA_A receptors. Each point represents the arithmeticmean ± S.E.M. calculated as a percentage of the response obtainedwith a maximum concentration of GABA (3 mM).

Effects of $gamma$ - and $delta$ -HCH on picrotoxin inhibition of GABA responses of $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors. Because $gamma$ -HCH gave only partial inhibition of the GABA EC₅₀ response, we determined whether either of the isomers could interactwith the picrotoxin binding site. We studied the effect of thesecompounds on picrotoxin inhibition of GABA responses on the $alpha$ 1 $beta$ 3 $gamma$ 2Ssubunit combination. As shown in figure 5A, both $gamma$ -HCH and the $delta$ isomer when coapplied with picrotoxin could reverse the inhibitoryeffect of picrotoxin on GABA responses. Figure 5B shows that theconcentration-response curve for picrotoxin inhibition of GABAresponses was shifted to the right by coapplication of $gamma$ -HCH ina dose-dependent manner, with EC₅₀ values of 1.3 ± 0.3 µM (n =4), 7.0 ± 2.1 µM (n = 4) in 10 µM $gamma$ -HCH, and 116.2 ± 30.9 µM (n= 5) in 100 µM $gamma$ -HCH, which suggested that $gamma$ -HCH is a competitiveinhibitor at the picrotoxin site. The $delta$ isomer also produced asimilar rightward shift of the picrotoxin dose-response curve(fig. 5B), which suggested that this isomer too displaces picrotoxinfrom its binding site.

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Fig. 5. The effect of $gamma$ - and $delta$ -HCH on picrotoxin-mediated inhibition of GABA responses on oocytes expressing human $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors.(a) Both $gamma$ - and $delta$ -HCH reversed the inhibitory action of picrotoxinon EC₅₀ GABA responses. Cells were voltage-clamped at $-$ 70 mV andexposed to GABA, picrotoxin and HCH isomers as indicated by thebars above each trace. (b) The effect of 10 µM (open triangles)and 100 µM (open squares) $gamma$ -HCH, and 100 µM $delta$ -HCH (filled triangles)on concentration-response curves for picrotoxin-mediated inhibitionof EC₅₀ GABA responses (filled circles). Each point representsthe arithmetic mean ± S.E.M. of four or five experiments.

To confirm that $gamma$ - and $delta$ -HCH interact competitively with the picrotoxin site, we carried out [³⁵S]TBPS displacement studies in membrane homogenates of a mousecell line expressing $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors. Figure 6 shows theeffect of $gamma$ -HCH and its $alpha$ , $beta$ and $delta$ isomers on the binding of 5nM [³⁵S]TBPS. Both $gamma$ -HCH and $delta$ -HCH inhibited the specific binding of5 nM [³⁵S]TBPS in a concentration-dependent manner with IC₅₀ values of60 ± 10 nM (n = 4) and 1.2 ± 0.02 µM (n = 4), respectively. $alpha$ -HCHalso inhibited [³⁵S]TBPS binding (IC₅₀ = .5 ± 0.08 µM). As expected, the $beta$ isomerhad no significant effect on [³⁵S]TBPS binding.

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Fig. 6. Concentration-effect curves for the inhibition of [³⁵S]TBPS-specific binding by HCH isomers in a mouse fibroblast cell lineexpressing human $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors. HCH isomers plottedare $alpha$ -HCH (open hexagon); $beta$ -HCH (open triangle); $delta$ -HCH (filledsquare); and $gamma$ -HCH (filled circle). The data for each HCH isomerrepresent four independent experiments. HCH isomers (1 nM to 100µM) were incubated with membrane homogenates and 5 nM [³⁵S]TBPS.

The effect of $gamma$ -HCH on $delta$ -HCH-dependent potentiation of GABA responses of $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors. To test whether $gamma$ -HCH had any effect on the positive potentiating action of $delta$ -HCH, we examined the effect of 10 µM and 100µM $gamma$ -HCH on the concentration-response curve of $delta$ -HCH potentiationin oocytes expressing $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors. As shown in figure7, 10 µM $gamma$ -HCH reduced the maximum potentiation of the GABA EC₂₀induced by the $delta$ isomer from 216 ± 31% to 139 ± 13% without causinga shift in the EC₅₀ value of the $delta$ -HCH-dependent potentiation.When the experiment was repeated with 100 µM $gamma$ -HCH, the potentiationwas completely blocked (fig. 7). These studies suggest that $gamma$ -HCHcan allosterically affect the potentiation of GABA responses bythe $delta$ isomer.

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Fig. 7. The effect of $gamma$ -HCH on $delta$ -HCH-mediated potentiation of GABA responses on oocytes expressing the human $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors.The concentration-response curve for $delta$ -HCH-induced potentiationof EC₂₀ GABA responses was obtained in the absence (open circles)and presence of 10 µM (open square) or 100 µM (filled circle) $gamma$ -HCH. Each point represents the arithmetic mean ± S.E.M. of fouror seven experiments.

Effects of $delta$ -HCH on other positive modulators of the GABA_A receptor. To characterize in more detail the effect of the $delta$ isomer, we tested the effect of 100 µM $delta$ -HCH on the positive allostericaction of several modulators of the GABA_A receptor. As shown infigure 8 saturating concentrations of loreclezole (10 µM), 5 $alpha$ -pregnan-3 $alpha$ -ol-20-one(300 nM), lanthanum (1 mM), pentobarbital (100 µM) and propofol(10 µM) caused a potentiation of the GABA response. Coapplicationof 100 µM $delta$ -HCH had an additive effect with the potentiation mediatedby loreclezole, 5 $alpha$ -pregnan-3 $alpha$ -ol-20-one and lanthanum, which indicatedthat $delta$ -HCH potentiation is not mediated through any of these bindingsites. In contrast, $delta$ -HCH either gave no further potentiation,or reduced the potentiation mediated by either pentobarbital orpropofol (fig. 8, D and E, respectively), which suggested thatthat $delta$ -HCH may act through a site common to both propofol andpentobarbital. To determine whether pentobarbital and propofolinteracted with the same site, we carried out additive experimentswith these two compounds. As shown in figure 8F, the effects ofpropofol and pentobarbital show some additivity when combined.In addition, $delta$ -HCH inhibited the direct activation of the receptorby pentobarbital (data not shown).

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Fig. 8. Effects of $delta$ -HCH on the potentiation of GABA responses induced by positive allosteric modulators of the GABA_A receptor. Oocytesexpressing human $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors were voltage-clampedat $-$ 70 mV and exposed to an EC₂₀ concentration of GABA (G), followedby the allosteric modulator alone, followed by this in combinationwith 100 µM $delta$ -HCH ( $delta$ -HCH), as indicated by the bars above eachtrace. Traces show (a) 10 µM loreclezole (Lor), (b) 300 nM 5 $alpha$ -pregnan-3 $alpha$ -ol-20-one(5 $alpha$ ), (c) 1 mM lanthanum (Lan), (d) 100 µM pentobarbital (Pen)and (e) 10 µM propofol (Pro). Trace (f) shows the combinationof pentobarbital (100 µM) and propofol (10 µM). Traces are typicalof at least four experiments in each case.

Effects of $gamma$ -HCH on pentobarbital potentiation of the GABA response. In light of the previous finding that $gamma$ -HCH could allosterically inhibit $delta$ -HCH potentiation, we investigated whether $gamma$ -HCHhad any effect on the potentiation by the barbiturate pentobarbital.As shown in figure 9, 100 µM $gamma$ -HCH inhibited the dose-dependentpotentiation of the EC₂₀ GABA responses of $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptorsby pentobarbital, which suggested that, in addition to its effecton the picrotoxin binding site, $gamma$ -HCH has an allosteric effectinhibiting barbiturate potentiation.

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Fig. 9. Concentration-response curves for pentobarbital, with (filled circle) and without (open circle) 100 µM $gamma$ -HCH, on oocytes expressinghuman $alpha$ 1 $beta$ 3 $gamma$ 2S GABA_A receptors. Each point represents the arithmeticmean ± S.E.M. of four experiments and calculated as percentageof EC₂₀ potentiation.

	Discussion

Top Abstract Introduction Methods Results Discussion References

In the present study, we have shown that $gamma$ -HCH and its $alpha$ and $delta$ isomers interact with human $alpha$ 1 $beta$ 3 $gamma$ 2S or $alpha$ 6 $beta$ 3 $gamma$ 2S GABA_A receptorsexpressed in oocytes, which supports the view that these substancesact primarily at GABA_A receptors. In contrast, we found that the $beta$ isomer is essentially inactive on either GABA responses or [³⁵S]TBPS binding, confirming previous suggestions that this isomeris essentially a non-GABAergic HCH isomer (Woodward et al., 1992;Nagata and Narahashi, 1995). However, a depressant action forthe $beta$ isomer has been well substantiated (Vohland et al., 1981;Stark et al., 1986), and Pomés et al. (1994) has demonstrateda biphasic action (positive modulation at concentrations lowerthan 1 µM and inhibition at higher concentrations) of $beta$ -HCH onGABA-dependent ³⁶Cl uptake into primary cultures of rat neocortical neurons. It isnot easy to solve these discrepancies, but it is possible thatdifferences in intracellular signaling mechanisms in differentpreparations and the ability of HCH isomers to interact with intracellulartargets such as ryanodine-sensitive calcium channels (Pessah etal., 1992) may account for them. Thus, the presence of HCH-sensitiveintracellular receptors in a preparation may result in the activationof kinase enzymes, which are known to modulate the activity ofGABA_A receptors (Leidenheimer et al., 1992).

$gamma$ -HCH suppresses GABA-induced currents in dorsal root ganglion neurons (Nagata and Narahashi, 1995), insect neurons (Waffordet al., 1988; Bermudez et al., 1991) and oocytes expressing mammalianGABA_A (Woodward et al., 1992) or Drosophila GABA (Zhang et al.,1994; Belelli et al., 1995) receptors. $gamma$ -HCH also inhibited GABAcurrents on oocytes expressing human $alpha$ 1 $beta$ 3 $gamma$ 2S or $alpha$ 6 $beta$ 3 $gamma$ 2S GABA_Areceptors with an EC₅₀ value of about 1 µM, which is in agreementwith values reported for other mammalian preparations (Woodwardet al., 1992; Nagata and Narahashi, 1995). Our studies showed $gamma$ -HCH to be a partial inhibitor of GABA_A receptors, suppressingEC₅₀ GABA responses by a maximum of 34%. Partial inhibition ofGABA-induced currents by $gamma$ -HCH has also been demonstrated by Woodwardet al. (1992) in Xenopus oocytes expressing rat or bovine GABA_Areceptors. However, full $gamma$ -HCH-induced inhibition has been reportedfor dorsal root ganglion neurons (Nagata and Narahashi, 1995)and Xenopus oocytes expressing a Drosophila GABA receptor subunit(Zhang et al., 1994). This suggests that the degree of efficacymay depend on the type of GABA receptor subunits present; we haveshown here that it is unlikely to be caused by different alphasubunits.

$gamma$ -HCH acts in a similar fashion to picrotoxin. For example, there are several reports showing $gamma$ -HCH-induced inhibition of[³⁵S]TBPS binding to neuronal membranes (Lawrence and Casida, 1984;Llorens et al., 1990) and GABA-mediated ³⁶Cl fluxes (Abalis et al., 1986; Pomés et al., 1994). The bindingsite of picrotoxin is likely to be in the M2 region of the Clchannel as suggested by site-directed mutagenesis studies of theputative M2 domain of rho receptors (Wang et al., 1995), $beta$ -glycinereceptor subunits (Pribilla et al., 1992) and a Drosophila GABAsubunit (ffrench-Constant et al., 1993; Belelli et al., 1995).Interestingly, mutations of the picrotoxin site (alanine 302)in a Drosophila GABA subunit decreases the potency of both picrotoxinand $gamma$ -HCH inhibition (Zhang et al., 1994; Belelli et al., 1995),which suggests that these two compounds interact with identicalresidues in the M2 region of GABA_A receptors.

It is not clear as yet whether picrotoxin, and hence $gamma$ -HCH, inhibits GABA responses by merely obstructing the Cl channel orby allosteric blockade. Studies showing that picrotoxin bindspreferentially to the desensitized conformation of GABA_A receptorsin sympathetic rat neurons (Newland and Cull-Candy, 1992), andthat $gamma$ -HCH accelerates the desensitization of GABA_A receptorsin dorsal root ganglion neurons (Nagata and Narahashi, 1995),suggest that picrotoxin and $gamma$ -HCH are allosteric inhibitors ofthe GABA_A receptor. Thus, by analogy to the benzodiazepine site,we propose that picrotoxin is a full inverse agonist of the picrotoxinmodulatory site. In contrast, $gamma$ -HCH, which both partially blocksGABA responses mediated by GABA_A receptors expressed in Xenopusoocytes (this study; Woodward et al., 1992) and relieves picrotoxin-inducedinhibition of human GABA_A receptors (this study), behaves as apartial inverse agonist of the picrotoxin site. This action issimilar to that of fluorinated methylbutyrolactone, which hasalso been proposed to be a partial inverse agonist of the picrotoxinsite (Yoon et al., 1990). In other preparations such as dorsalroot ganglion neurons, $gamma$ -HCH may act as a full inverse agonist,presumably reflecting species or GABA receptor subtype differences.

$delta$ -HCH potentiates GABA responses in Xenopus oocytes expressing rat and bovine GABA_A (Woodward et al., 1992), Drosophila GABA(Belelli et al., 1996) receptors, dorsal root ganglion (Nagataand Narahashi, 1995) and cortical (Pomés et al., 1994) neurons.We also observed $delta$ -HCH-dependent potentiation of human $alpha$ 1 $beta$ 3 $gamma$ 2Sand $alpha$ 6 $beta$ 3 $gamma$ 2S GABA_A receptors. $delta$ -HCH potentiation was not influencedby alpha subunit composition, which is in contrast to other positiveallosteric modulators of the GABA_A receptor such as barbiturates(Thompson et al., 1996) and benzodiazepines (Wafford et al., 1993)

Several lines of evidence argue against the idea of an identical binding locus for the $delta$ and $gamma$ isomers. First, a A302S mutantof a Drosophila GABA subunit receptor shows reduced susceptibilityto inhibition by picrotoxin and $gamma$ -HCH without changes in its affinitytoward the positive allosteric modulator $delta$ -HCH (Belelli et al.,1995). Second, rho receptors are endowed with a picrotoxin bindinglocus but lack a site for positive allosteric modulation by the $delta$ isomer (Woodward et al., 1992; Wang et al., 1995). However,the two sites may be close, adjacent or even overlapping, whichcould explain the inhibition of $delta$ -HCH-dependent effects by the $gamma$ isomer, as well as the inhibition of picrotoxin antagonism bythe $delta$ isomer. Alternatively the $delta$ -HCH activity at the picrotoxinsite may be masked by its potentiating effect, and only when pentobarbitalis used as an agonist is the inhibition observed. The inhibitionof $delta$ -HCH potentiation by $gamma$ -HCH is clearly not a competitive interactionbecause the inhibition cannot be overcome at high concentrations,and the $delta$ -HCH EC₅₀ is not affected. This would suggest an allostericinteraction between the two sites.

Clues as to where the $delta$ -HCH site might be located come from our observation that the $delta$ isomer reduces the positive allostericaction of both pentobarbital and propofol. Although neither thebarbiturate or propofol sites have been defined as yet, thereis neurochemical evidence to suggest that they are separate entities(Concas et al., 1991), with the alpha and beta subunits probablycontributing to the barbiturate site (Amin and Weiss, 1993; Thompsonet al., 1996). The effect of $delta$ -HCH on the enhancement action ofpentobarbital and propofol may be explained then by postulatingthat the $delta$ -HCH locus overlaps with the barbiturate and propofolsites, which are close or adjacent to each other. The observationthat rho receptors, which are insensitive to positive allostericmodulation by $delta$ -HCH are insensitive to barbiturates and propofol(Bormann and Feigenspan, 1995) further support the idea of threeseparate though overlapping loci. It is unlikely that the $delta$ -HCHsite is linked to other sites such as the benzodiazepine site,because flumazenil, an antagonist of the benzodiazepine site,has no effect on $delta$ -HCH-mediated potentiation of GABA responses(Woodward et al., 1992).

We demonstrated a direct action of $delta$ -HCH on GABA_A receptors, which has not been reported previously. This action resembledthe direct activation of GABA_A receptors by barbiturates (Belelliet al., 1996; Thompson et al., 1996) and propofol (Orser et al.,1994; Belelli et al., 1996). Direct activation of GABA_A receptorsby barbiturates (Mathers and Barker, 1980; Thompson et al., 1996)and propofol (Orser et al., 1994) is not mediated through theGABA binding site (Thompson et al., 1996; Ueno et al., 1997),which suggests that the site for direct activation by the $delta$ isomeris a separate locus from the agonist site. Recent evidence suggeststhat homomeric beta subunits form receptors that can be gatedby barbiturates and propofol (Sanna et al., 1995; Krishek et al.,1996), but only weakly by GABA, which suggests a role for thebeta subunit in this activation. Because the $delta$ -HCH isomer seemsto be acting via a site common to these compounds, it may alsobe activating the receptor in a similar manner, although to alesser extent than pentobarbital or propofol. A single channelapproach as well as the use of pharmacological tools such as competitiveinhibitors of the GABA binding site might help to define moreprecisely this site.

	Footnotes

Accepted for publication May 5, 1997.

Received for publication February 25, 1997.

¹ Supported by a CASE BBSRC PhD studentship with Merck Sharp & Dohme, U.K.

Send reprint requests to: Dr Keith A Wafford, Merck Sharp & Dohme Research Labs, Terlings Park, Eastwick Road, Harlow, Essex CM20 2QR United Kingdom.

	Abbreviations

GABA, $gamma$ -aminobutyric acid; MBS, modified Barth's solution; HCH, hexachlorocyclohexane; TBPS, t-butylbicyclophosphorothionate; 5 $alpha$ , 3 $alpha$ -DHP, 5 $alpha$ -pregnan-3 $alpha$ -ol-20-one; HEPES, 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid.

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