Mutagenesis of the Rat alpha 1 Subunit of the gamma -Aminobutyric AcidA Receptor Reveals the Importance of Residue 101 in Determining the Allosteric Effects of Benzodiazepine Site Ligands

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Vol. 56, Issue 4, 768-774, October 1999

Mutagenesis of the Rat $alpha$ 1 Subunit of the $gamma$ -Aminobutyric Acid_A Receptor Reveals the Importance of Residue 101 in Determining the Allosteric Effects of Benzodiazepine Site Ligands

Susan M. J. Dunn, Martin Davies, Anna Lisa Muntoni, and Jeremy J. Lambert

Department of Pharmacology (S.M.J.D., M.D.) and Division of Neuroscience (S.M.J.D.), Faculty of Medicine, University of Alberta, Edmonton, Alberta, Canada; and Neurosciences Institute, Department of Pharmacology and Neuroscience, Ninewells Hospital and Medical School, University of Dundee, Dundee, Scotland (A.L.M., J.J.L.)

	Summary

Top Abstract Introduction Materials and Methods Results Discussion References

The $gamma$ -aminobutyric acid_A (GABA_A) receptor contains a binding site (or sites) for benzodiazepines and related ligands. Previousstudies have shown that the residue occupying position 101 (ratnumbering) of the $alpha$ subunit is particularly important in determininghow some of these compounds interact with the receptor. We havemade multiple substitutions (F, Y, K, Q, and E) of the histidineat this position of the rat $alpha$ 1 subunit and coexpressed the mutantsubunits with $beta$ 2 and $gamma$ 2 subunits in Xenopus oocytes. The effectsof flunitrazepam, Ro15-1788, and Ro15-4513 on GABA-gated currentswere then examined using electrophysiological techniques. Threesubstitutions (F, Y, and Q) had little effect on the ability offlunitrazepam to potentiate GABA-induced currents and had relativelymodest effects on the EC₅₀ value of the flunitrazepam response.Other mutations (K and E) resulted in drastic reduction of flunitrazepamrecognition. All substitutions also affected the EC₅₀ values forRo15-1788 and Ro15-4513, and some led to dramatic changes in theirefficacy. For example, H101Y, H101K, and H101Q produced receptorsat which Ro15-1788 acted as a partial agonist (maximum potentiationof 164, 159, and 130%, respectively), whereas Ro15-4513 actedas a partial agonist at H101F, H101K, and H101E (potentiationof 122, 138, and 110%, respectively) and an antagonist at H101Yand H101Q. These results indicate that the characteristics ofthe residue at position 101 of the $alpha$ 1 subunit play a crucial rolein determining the efficacy of benzodiazepine-siteligands.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

$gamma$ -Aminobutyric acid (GABA)_A receptors are the most abundant inhibitory neurotransmitter receptors in the mammalian brain andare the site of action of many clinically important compounds,including benzodiazepines, barbiturates, and the general anestheticspropofol and etomidate (Dunn et al., 1994; Sieghart, 1995; Petersand Lambert, 1997). These receptors, which are members of theligand-gated ion channel family, are composed of five subunitsthat are arranged in the membrane in a cylindrical fashion toform a central chloride ion channel (Nayeem et al., 1994). GABA_Areceptor subunits display a high degree of heterogeneity and aredivided into a number of families based on sequence homology,with most families having several members. Thus far, the genesthat encode mammalian GABA_A receptor subunits include $alpha$ 1 to $alpha$ 6, $beta$ 1 to $beta$ 4, $gamma$ 1 to $gamma$ 3, $rho$ 1 to $rho$ 3, $delta$ , $pi$ , and $epsilon$ (Barnard et al., 1998).Although there is evidence for the existence of several differentreceptor types (McKernan and Whiting, 1996), it appears that themajor subtype in mammalian brain contains the $alpha$ 1, $beta$ 2, and $gamma$ 2 subunits(Whiting et al., 1995). In studies of receptor binding sites,heterologous expression approaches have been used to demonstratethat the presence of both an $alpha$ and a $gamma$ subunit is required toform a benzodiazepine binding site (Pritchett et al., 1989b; Zezulaet al., 1996). Furthermore, the manner in which benzodiazepine-siteligands affect GABA-gated chloride ion flux is largely determinedby which specific members of the $alpha$ and $gamma$ subunit families arepresent within the receptor oligomer (Pritchett et al., 1989a;Herb et al., 1992; Puia et al., 1991).

Molecular biological studies have shown that specific regions in the N-terminal domain of both the $alpha$ and $gamma$ subunits are importantfor recognition of benzodiazepines and related ligands. In a manneranalogous to that described for ligand recognition by the nicotinicacetylcholine receptor (Changeux, 1995), residues important forbenzodiazepine-site ligand binding to GABA_A receptors appear tobe clustered within discrete regions of the N termini of specificsubunits (see Sigel and Buhr, 1997). Alterations of amino acidswithin these domains can have significant effects on both theaffinity and efficacy of ligands that interact with this site(Davies et al., 1998; Sigel et al., 1998). One particular residuethat occurs at position 101 (rat numbering) of the $alpha$ 1 subunitappears to be absolutely essential for the recognition of classicagonist benzodiazepines such as diazepam (Wieland et al., 1992).In $alpha$ subunits that confer agonist sensitivity ( $alpha$ 1, $alpha$ 2, $alpha$ 3, and $alpha$ 5), the residue in this position is a histidine, whereas in thesubunits that confer insensitivity ( $alpha$ 4 and $alpha$ 6), an arginine ispresent. The importance of this residue in agonist recognitionwas further emphasized when it was shown that His102 of the bovine $alpha$ 1 subunit is the major site of photoaffinity labeling by [³H]flunitrazepam (FNZ; Duncalfe et al., 1996).

Interestingly, although some ligands such as Ro15-4513 and Ro15-1788 recognize both diazepam-sensitive and -insensitive receptors,their efficacies differ between the two receptor types. Ro15-4513,for example, is a partial inverse agonist at $alpha$ 1-containing receptorsbut acts as a partial agonist in receptors containing the $alpha$ 6 subunit(Hadingham et al., 1996; Wafford et al., 1996). Similarly, Ro15-1788is a partial agonist at $alpha$ 6-containing receptors (Hadingham etal., 1996; Wafford et al., 1996) but an antagonist at $alpha$ 1-containingreceptors. Recently, we constructed a number of mutant rat $alpha$ 1subunits that contained substitutions at the position normallyoccupied by His101 (Davies et al., 1998). It was found that whenthe mutant $alpha$ subunits were incorporated into receptor oligomers,the substitutions had differential effects on the affinity ofdifferent benzodiazepine ligands. In addition, measurements ofthe effects of GABA on their binding provided preliminary evidencefor changes in their pharmacological specificity. Thus, it appearsthat a single amino acid substitution at position 101 of the $alpha$ subunit can change the manner in which benzodiazepine-site ligandsallosterically modulate GABA-gated chlorideflux.

In the present study, we examined in detail the functional changes resulting from amino acid substitutions of His101. Wild-typeor mutated $alpha$ 1 subunits were coexpressed with the $beta$ 2 and $gamma$ 2 subunitsin Xenopus laevis oocytes, and GABA-induced currents were investigatedusing the two-electrode voltage-clamp technique. We characterizedthe effects of three benzodiazepine-site ligands: FNZ, Ro15-1788,and Ro15-4513, which are generally considered to be an agonist,an antagonist, and a partial inverse agonist at this receptortype (Sieghart, 1995).

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

Preparation of Transcripts and Oocyte Injection. Site-directed mutagenesis of $alpha$ 1 subunits was performed as described previously (Davies et al., 1998) using the Altered Siteskit (Promega, Madison, WI). The $alpha$ 1 subunit was subcloned intothe pAlter-1 vector for mutagenesis. Potential mutants were identifiedby the presence of a restriction site that was introduced as asilent mutation by the mutagenic oligonucleotide. The presenceof the correct substitutions was verified by sequencing. The mutant $alpha$ 1 cDNAs were then subcloned into the pcDNA3 expression vector(InVitrogen, San Diego,CA).

cDNAs encoding the $alpha$ 1, $beta$ 2, and $gamma$ 2L subunits in the pcDNA3 vector were linearized, and cRNA transcripts were prepared by standardprocedures as previously described (Hope et al., 1993

). The cRNAtranscripts were injected (50 nl of 1 mg/ml cRNA) into X. laevisoocytes (stage V to VI) that had been previously defolliculatedby treatment with 2 mg/ml collagenase A (Boehringer-Mannheim,Indianapolis, IN) for 3 h at room temperature (Belelli et al.,1996

). Injected oocytes were individually maintained at 19-20°Cfor up to 14 days in 96-well plates containing 200 µl of standardBarth's solution [15 mM HEPES, pH 7.6, 88 mM NaCl, 1 mM KCl, 2.4mM NaHCO₃, 0.5 mM Ca(NO₃)₂, 0.5 mM CaCl₂, 1 mM MgSO₄] supplementedwith 0.1 mg/mlgentamycin.

Electrophysiological Recordings. Oocytes were used for experimentation 2 to 14 days after cRNA injection. The methodology was essentially the same as describedpreviously (Pistis et al., 1997). Briefly, electrical recordingswere made from oocytes voltage-clamped at $-$ 60 mV using a GeneClamp500 amplifier (Axon Instruments, Inc., Foster City, CA) in thetwo-electrode voltage-clamp mode. The oocytes were held in a chamber(0.5 ml) and continuously superfused (7-10 ml/min) with frog Ringer'ssolution (5 mM HEPES, pH 7.4, 120 mM NaCl, 2 mM KCl, and 1.8 mMCaCl₂). The voltage-sensing and current passing electrodes werefilled with 3 M KCl and had resistances of 0.5 to 1.5 M $Omega$ whenmeasured in frog Ringer's solution. Agonist-induced responseswere low pass filtered at 100 Hz, recorded onto videotape, andsimultaneously displayed on a chart recorder. The peak amplitudeof the agonist-evoked response was measured manually. All drugswere applied via the superfusionsystem.

For each oocyte, a maximal concentration of GABA (3 mM) was applied, and the resulting peak current amplitude was measured.This concentration of GABA was reapplied at approximately 20-minintervals until the current amplitude was consistent to within±2% over three successivechallenges.

To investigate the effects of the benzodiazepines, GABA concentrations eliciting a peak current approximately 10% (EC₁₀) or50% (EC₅₀) of the maximum GABA response were used as indicatedin the text. Pharmacological effects were first screened usinga concentration of GABA approximating its EC₅₀ value. Subsequently,the EC₁₀ concentration of GABA was used to examine potentiatingeffects and, unless where noted in the text, the EC₅₀ concentrationof GABA was used to further characterize inverse agonist and antagonisteffects. Benzodiazepines were dissolved in dimethyl sulfoxideto give stock concentrations of 30 mM, and these stocks were storedfrozen at $-$ 20°C. In all experiments, the concentration of dimethylsulfoxide was constant at 0.02%, a concentration that producedno overt vehicle effects. In each experiment, control currentsusing the indicated concentrations of GABA were first recorded.This was followed by 5-min washing with frog Ringer's solutionand then by 3-min perfusion with the benzodiazepine before coapplicationwith the appropriate concentration of GABA. After recording ofthe evoked current, the oocyte was again washed with frog Ringer'sfor at least 5 min before further benzodiazepine perfusion. Duringeach experiment, control currents were recorded periodically toverify that the response remained stable throughout and that anybenzodiazepine effects were fullyreversible.

Data Analysis. All data represent the mean (±S.E.) of observations made from at least three oocytes. Data were analyzed by nonlinear regressiontechniques using InPlot 4 (GraphPad Software, San Diego, CA).The GABA concentration dependence of the observed current wasfit by the equation:

I=<FR><NU>I<UP>max</UP> · [L]n</NU><DE>EC50n+[L]n</DE></FR>

where I is the measured amplitude of the evoked current, [L] is the GABA concentration, EC₅₀ is the concentration of GABAproducing 50% of the maximal response (I_max), and n is the Hillcoefficient. In each experiment, the observed current was normalizedto the I_max (100%), and these normalized data were used to constructconcentration-effectcurves.

Unless otherwise indicated, the effects of the benzodiazepines were fit by the equation:

I=I<SUB>0</SUB>+<FR><NU>(E<SUB><UP>max</UP></SUB><UP>−</UP>I<SUB>0</SUB>)10<SUP>X,n</SUP></NU><DE>10<SUP>X,n</SUP>+10<SUP>C,n</SUP></DE></FR>

where I is the amplitude of the observed current; [X] is the logarithm of the concentration of the benzodiazepine; I₀ andE_max are the currents observed in the absence of benzodiazepineand in the presence of the maximally effective concentration,respectively; C is the logarithm of the EC₅₀ for the benzodiazepineresponse; and n is the Hill coefficient. As shown in the figures,the concentration dependencies of many of the benzodiazepine effectsdeviated from a simple process, giving Hill coefficients of greaterthan or less than 1. Unfortunately, without detailed knowledgeof the mechanisms underlying these allosteric interactions, itis not presently feasible to develop a molecular framework withinwhich to interpret these Hillcoefficients.

Curves that were obviously biphasic were fit by the equation:

I=I<SUB>0</SUB>+<FR><NU>E<SUB>1</SUB> · 10<SUP>X</SUP></NU><DE>10<SUP>C<SUB>1</SUB></SUP>+10<SUP>X</SUP></DE></FR>+<FR><NU>E<SUB>2</SUB> · 10<SUP>X</SUP></NU><DE>10<SUP>C<SUB>2</SUB></SUP>+10<SUP>X</SUP></DE></FR>

where E₁ and E₂ are the amplitudes of the first and second phases, C₁ and C₂ are the logarithms of the corresponding EC₅₀values, and the other parameters are as describedabove.

In experiments to estimate antagonist affinities, the effects of Ro15-1788 or Ro15-4513 on the FNZ-induced potentiation wereinvestigated. IC₅₀ values were calculated from the equation:

I=I<SUB>0</SUB>+<FR><NU>(I<SUB><UP>FNZ</UP></SUB><UP>−</UP>I<SUB>0</SUB>)10<SUP>X,n</SUP></NU><DE>10<SUP>X,n</SUP>+10<SUP>C,n</SUP></DE></FR>

where I is the observed current, I_FNZ is the current in the presence of FNZ, I₀ is the current in the presence of both FNZand a saturating concentration of benzodiazepine antagonist, [X]is the logarithm of the antagonist concentration, C is the logarithmof the IC₅₀ concentration, and n is the Hill coefficient. In theseexperiments, the data were normalized by first expressing themagnitude of the FNZ-induced potentiation of the GABA response(in the absence of antagonist) as 100% and then calculating theinhibition of this current in the presence of different concentrationsofantagonist.

Drugs. GABA and FNZ were obtained from Sigma Chemical Co. (St. Louis, MO). Ro15-4513 and Ro15-1788 were generous gifts from Hoffmann-LaRoche and Co. (Basel,Switzerland).

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

At a holding potential of $-$ 60 mV, oocytes preinjected with cRNAs encoding rat $alpha$ 1, $beta$ 2, and $gamma$ 2 GABA_A receptor subunits respondedto bath-applied GABA with an inward current response. Similarly,receptors carrying the various $alpha$ subunit mutations displayed robustcurrent responses to GABA application. All receptors showed somemodulation by benzodiazepine-site ligands as illustrated for thewild-type and H101Y mutant receptor in Fig. 1. Thus, all receptorsexamined displayed functional coupling between the GABA and benzodiazepinebinding sites.

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Fig. 1. Representative traces showing GABA-evoked currents and their modulation by benzodiazepine-site ligands for (A) the wild-type receptor and (B) the H101Y mutant. The oocytes were perfused with the benzodiazepine-site ligands (+) for 3 min before coapplication with the indicated concentrations of GABA to elicit the observed current (see the text for details). The maximum current (E_max) in each case lay in the range of 1 to 3 µA, and control currents were recorded using GABA concentrations approximating its EC₅₀ or EC₁₀ value for that receptor_. Vertical bars represent 100 nA (A) and 50 nA (B). A, potentiation of the GABA current by FNZ, the rather limited inhibition by 1 µM Ro15-4513, and the lack of effect of Ro15-1788. In all cases, any observed effects were fully reversible as indicated by the control currents obtained after washing out of the modulator (third trace in each panel). Ro15-1788 (1 µM), however, inhibited the potentiation of the current by FNZ (10 nM), indicating that it acts as an antagonist on the wild-type receptor. The data obtained with H101Y (B) also show the reversible potentiation by FNZ (first three traces), but for this receptor, Ro15-4513 had no direct effect on GABA-induced currents, whereas Ro15-1788 potentiated the GABA response. Observed effects were again fully reversible on washout. B, the final three traces show that Ro15-4513 inhibited the FNZ-induced potentiation, suggesting that this ligand is an antagonist of the H101Y receptor complex.

Analysis of the GABA concentration-response curve for the wild-type $alpha$ 1 $beta$ 2 $gamma$ 2 receptor gave an EC₅₀ value of 31.8 ± 3.4 µM (n= 4) and a Hill coefficient of 1.32 ± 0.16 (n = 4). None of theHis101 mutations examined had a dramatic effect on GABA-inducedcurrents (Table 1), and although the EC₅₀ value was slightlyincreased in each case, this remained within a factor of about2 of the wild-type receptor.

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TABLE 1
Effect of mutation of $alpha$ 1 subunit His101 on GABA-induced currents
cRNAs encoding the wild-type or mutated $alpha$ 1 subunits were coexpressed with the $beta$ 2 and $gamma$ 2 subunits in X. laevis oocytes, and currents in response to bath applied GABA were recorded.

Mutations of the $alpha$ 1 subunit His101 to residues of altered chemical specificity did, however, have significant effects on boththe potencies of the benzodiazepine-site ligands and on the mannerin which they modulated GABA-evoked currents. For clarity, thequalitative changes in the pharmacological effects of FNZ, Ro15-1788,and Ro15-4513 are first summarized in Table 2.

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TABLE 2
Qualitative description of the effects of mutation of $alpha$ 1 subunit His101 on the pharmacology of benzodiazepine-site ligands
Mutated $alpha$ 1 subunits were coexpressed with the wild-type $beta$ 2 and $gamma$ 2 subunits in X. laevis oocytes, and the effects of the modulators on GABA-induced currents were recorded.

The effects of FNZ on wild-type receptors were distinctly biphasic (Fig. 2A), suggesting a relatively potent potentiatingeffect (EC₅₀ = 5.8 nM) and a lower affinity inhibitory response(EC₅₀ = 178 nM). In the H101F, H101Y, and H101Q mutants, FNZ potentiatedcurrents to a similar extent (E_max = 217-290% of control; Table3). In contrast, FNZ had no effect on GABA-evoked currents inthe H101K receptor (Fig. 2A), which is consistent with the lackof measurable FNZ binding to this receptor mutant when expressedin tsA201 cells (Davies et al., 1998). In the H101E mutant, whichalso displayed no measurable FNZ binding in mammalian cells, FNZdid have a potentiating effect but only at high ligand concentrations(>1 µM; Fig. 2B). Representative results for the effects of FNZon GABA-induced currents are shown in Fig. 2, and the data aresummarized in Table 3, where their measured EC₅₀ values are comparedwith their apparent affinities, measured in binding assays ofreceptors expressed in tsA201 cells. Thus, FNZ is an agonist ofall receptors that recognize this ligand.

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Fig. 2. Effects of FNZ on GABA-mediated currents in wild-type and mutant receptors. A, concentration dependence of FNZ effects on wild-type currents (

) induced by a concentration of GABA approximately equal to its EC₁₀ value and its lack of effect on the receptor carrying the $alpha$ 1 H101K mutation, again recorded using a GABA concentration approximating its EC₁₀ concentration ( $triangle$ ). B, the effects of FNZ on currents induced by GABA (at a concentration approximately equal to its EC₁₀ value) in the $alpha$ 1 H101Y ( $black-triangle$ ) and H101E (

) mutations are shown. Best-fit values obtained from these curves and for the H101F and H101Q mutants are listed in Table 3.

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TABLE 3
Effects of mutation of $alpha$ 1 subunit His101 on modulation of the $alpha$ 1 $beta$ 2 $gamma$ 2 receptor by FNZ

The consequences of H101 mutations on the effects of Ro15-4513 on functional responses were more complex. In the wild-typereceptor, Ro15-4513 was a very limited inverse agonist, decreasingGABA-evoked currents by only 6 to 10% with an EC₅₀ of 1.8 nM (Fig.3 and Table 4). However, in the H101K and H101E mutants (andto a small extent in the H101Y mutant), this ligand became a partialagonist (see Fig. 3). Ro15-4513 had no direct effect on currentselicited by the H101Q mutant, but it did inhibit the potentiationinduced by FNZ, indicating that it is a potent antagonist of thisreceptor. As previously reported for these receptors expressedin tsA201 cells (Davies et al., 1998), none of the mutations causeda pronounced decrease in the apparent affinities for Ro15-4513,and in some cases, notably H101F and H101Q, the potency of thisligand was increased compared with the wild-type receptor (Fig.3 and Table 4).

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Fig. 3. Effects of Ro15-4513 on GABA-mediated currents. A, data for wild-type (

), H101K ( $triangle$ ), and H101Y ( $black-triangle$ ) receptors, indicating that Ro15-4513 is a poor inverse agonist of the wild-type receptor but becomes a partial agonist after the H101K mutation. B, inhibition of the FNZ potentiation by Ro15-4513 in the H101Y ( $black-triangle$ ) and H101Q ( $diamond$ ) mutant receptors. In each case, both the GABA concentration (50 µM) and the FNZ concentration (100 nM) used were approximately equal to their EC₅₀ values. Best-fit parameters from curve fitting are listed in Table 4.

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TABLE 4
Effect of mutation of $alpha$ 1 subunit His101 on modulation of the $alpha$ 1 $beta$ 2 $gamma$ 2 receptor by Ro15-4513

Figure 4 illustrates the effects of the mutations on the ability of Ro15-1788 to modulate GABA-gated currents. In the wild-typereceptor, this ligand had no direct effect on the GABA-evokedcurrents (Fig. 4A) but inhibited the FNZ-induced potentiationwith an IC₅₀ value of 7.9 ± 1.9 nM (Fig. 4B). In the H101F mutant,Ro15-1788 also acted as an antagonist, but in the H101Y, H101K,and H101E receptors, it became a partial agonist (Fig. 4 and Table5). Ro15-1788 had no direct effect on GABA-evoked currents inthe H101E mutant receptor. Unfortunately, the lack of a robustagonist response of FNZ (Fig. 2B) or Ro15-4513 (Table 4) precludedfurther characterization of its possible antagonist propertieson this receptor.

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Fig. 4. Effects of Ro15-1788 on GABA-mediated currents. A, effects of Ro15-1788 on the wild-type (

), H101K ( $triangle$ ), and H101Y ( $black-triangle$ ) receptors. B, inhibition of the FNZ-evoked potentiation by Ro15-1788 in the H101F ( $open circle$ ) and wild-type (

) mutant receptors. The data for the wild type were obtained using GABA and FNZ concentrations of 30 µM and 10 nM (i.e., approximately equal to their EC₅₀ values). In the case of H101F, the concentrations of GABA and FNZ were 10 µM and 10 nM, respectively. Best-fit parameters obtained from curve fitting are given in Table 5.

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TABLE 5
Effect of mutation of $alpha$ 1 subunit His101 on modulation of the $alpha$ 1 $beta$ 2 $gamma$ 2 receptor by Ro15-1788

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

A central issue concerning the benzodiazepine site of the GABA_A receptor is how its occupation can result in a spectrum ofpharmacological effects ranging from inverse agonism to full agonism.We examined the effects of mutations of His101 of the rat $alpha$ 1 subuniton the pharmacological specificity of FNZ, Ro15-1788, and Ro15-4513(i.e., compounds that are commonly regarded as having agonist,antagonist, and partial inverse agonist properties, respectively).Although it has recently been suggested that His102 (human numbering)is not directly involved in determining the efficacies of benzodiazepine-siteligands (McKernan et al., 1998), the above results demonstratethat the chemical nature of the residue at the homologous positionof the rat $alpha$ 1 subunit has a significant effect on the actionsof thesecompounds.

The mutations that were introduced had relatively minor effects on the concentration dependence of GABA-evoked currents (Table1), suggesting that none of the substitutions had serious adverseeffects on the overall structure of the receptor. Other groupshave, however, reported larger shifts in the EC₅₀ values for GABAactivation when the corresponding residue in the $alpha$ 6 subunit wasmodified (Im et al., 1997).

The shifts in EC₅₀ values obtained for the effects of FNZ, Ro15-1788, and Ro15-4513 on GABA-gated currents tended to parallelthe shifts in binding affinities reported previously (Davies etal., 1998). In most cases, there was excellent agreement betweenthe present functional data for receptors expressed in oocytesand previous binding data using receptors expressed in tsA201cells. One exception is the effect of FNZ on the H101F mutant,where the apparent affinity obtained from binding experimentswas 92.8 ± 9.1 nM compared with 8.6 ± 1.0 nM measured in the functionalstudies. In the absence of any other interpretation, it must beassumed that this is a cell type-specificphenomenon.

The binding of FNZ is particularly sensitive to the nature of the residue occupying position 101. Incorporation of the positivelycharged lysine resulted in receptors that were insensitive toFNZ. This is consistent with previous reports (Wieland et al.,1992; Benson et al., 1998) in which substitution of His101 indifferent $alpha$ subunits by arginine produced receptors that wereinsensitive to diazepam. Similarly, the introduction of the negativelycharged amino acid glutamate drastically affected FNZ binding,and in the H101E mutant, this ligand potentiated GABA-evoked currentsonly at high concentrations. In contrast, substitution by theuncharged glutamine restored sensitivity to FNZ (Table 3). Theability of glutamine to substitute for histidine in the recognitionsite has been discussed previously (Davies et al., 1998). In allmutant receptors that recognized FNZ, this drug acted as a strongagonist, potentiating GABA-induced currents to levels similarto those seen with wild-type receptors. This suggests that althoughthe mutations reduce the affinity for FNZ, they do not producequalitative changes in the protein conformational transitionsthat allosterically modulate GABA-gated chlorideflux.

The efficacies of Ro15-1788 and Ro15-4513 were dramatically altered by some of the mutations, but the pattern of the changesdiffered for the two ligands. In the wild-type receptor, Ro15-4513was a poor inverse agonist, decreasing GABA-evoked currents byless than 10%. Decreases of a similar magnitude have been reportedpreviously in studies using both the human recombinant $alpha$ 1 $beta$ 2 $gamma$ 2subtype (Hadingham et al., 1996) and acutely dissociated rat pyramidalneurons (Smith et al., 1998). As expected from previous studies(Sieghart, 1995), Ro15-1788 acted as an antagonist of the wild-typereceptor. It has previously been shown that both Ro15-4513 andRo15-1788 act as partial agonists in $alpha$ 6 receptors in which arginineis present in this position (Hadingham et al., 1996; Wafford etal., 1996). Recently, the importance of this residue was furtherconfirmed by showing that substitution of His101 by arginine inthe $alpha$ 1, $alpha$ 2, $alpha$ 3, and $alpha$ 5 subunits resulted in Ro15-4513 becominga positive allosteric modulator (Benson et al., 1998). Anothermutation in the $gamma$ 2 subunit has been shown to change the efficacyof Ro15-4513 (Mihic et al., 1994), suggesting that determinantsin both the $alpha$ and $gamma$ subunits affect the interaction of this compoundwith the receptor. A recent report by Im et al. (1997) suggeststhat residues C terminal to position 101 may be involved in determiningthe efficacy of Ro15-1788 at $alpha$ 6-containing receptors. In the presentstudy, we have shown that manipulation of this amino acid, atleast in $alpha$ 1 subunits, is sufficient to bring about changes inefficacy, not only for Ro15-1788 but also for Ro15-4513.

Relatively small differences in the structure of the residue at position 101 had differential effects on receptor modulationby Ro15-1788 and Ro15-4513. This is illustrated by comparing theeffects of these compounds on the H101Y and H101F receptors. Inthe H101Y mutant, Ro15-1788 is an agonist, whereas Ro15-4513 actsas an antagonist. In the H101F receptor, the converse is true.Thus, the pharmacological specificity of these ligands is dictatedby the presence or absence of a hydroxyl group in this position.The affinities for both agents were reduced in the tyrosine mutant,indicating that changes in efficacy do not parallel changes inapparentaffinity.

Because structural information on the GABA_A receptor is lacking, any rationalization of the differential effects of the mutationson the actions of Ro15-4513 and Ro15-1788 is speculative. Molecularmodeling has suggested that agonists, inverse agonists, and antagonistsdifferentially affect the receptor by interacting with differentlipophilic pockets within the binding site or sites. In the modelsproposed by Villar et al. (1989) and Zhang et al. (1995), thelipophilic pocket or pockets occupied by antagonists and inverseagonists are structurally related to each other, but the pocketthat accommodates the 5-phenyl ring of benzodiazepine agonistslies in a much different position. Because of the similaritiesin the binding of antagonists and inverse agonists, small perturbationsin binding site structure may be sufficient to change the particularlipophilic pocket with which these compounds interact, thus changingthe efficacy of a ligand from inverse agonist to antagonist. Toexplain the partial agonism of Ro15-1788 and Ro15-4513 at somemutant receptors, two possibilities must be considered. First,both ligands may interact with the same regions of the bindingcleft as in wild-type receptors but now act as agonists (i.e.,the mutations affect events that are downstream from the initialbinding interaction). Second, the structural changes induced bythe mutations allow these compounds to interact with the lipophilicpocket that is normally "seen" only by agonists (i.e., the signaltransduction mechanism remains the same as in wild-type receptors,but the initial receptor-ligand interaction is altered). We cannotpresently distinguish between these possibilities, but it is hopedthat further information will come from direct identificationof binding domains for different ligands by peptide mapping ofphotolabeled mutantreceptors.

It is generally assumed that agonists, antagonists, and inverse agonists interact with a common binding site because theirbinding is mutually exclusive at equilibrium. However, Buhr etal. (1997) recently showed that a single mutation in the $gamma$ 2 subunitproduced receptors that displayed biphasic displacement curvesin which zolpidem, methyl 6,7-dimethoxy-4-ethyl- $beta$ -carboline-3-carboxylate,and Ro15-1788 were able to displace only about 50% of bound [³H]FNZ. The authors suggested that this may indicate the presenceof two benzodiazepine binding sites within a single receptor molecule.In the present study, we identified one mutant (H101Q) that displaysa shallow concentration dependence (Hill coefficient = 0.45 ±0.11) for FNZ potentiation, suggesting that two benzodiazepinesites of different affinities may be present in these receptors.However, no evidence of binding site heterogeneity was obtainedin direct binding studies in which FNZ was shown to completelydisplace [³H]Ro15-4513 (Davies et al., 1998). Also in the current study,we found that high concentrations of FNZ (>1 µM) potentiated GABA-gatedion flux in the H101E mutant, yet previous competition studiesusing this receptor showed that FNZ at concentrations up to 10µM was unable to displace bound [³H]Ro15-4513. This was previously interpreted to mean that thesereceptors did not recognize FNZ. However, in light of the functionaldata for this mutant, it is possible that there is an additionallow-affinity binding site for FNZ that is distinct from the high-affinitysite for Ro15-4513.

The bell-shaped appearance of the curve for FNZ potentiation of the wild-type $alpha$ 1 $beta$ 2 $gamma$ 2 receptor (Fig. 2A) suggests that thepresence of more than one benzodiazepine site is not exclusiveto the mutant receptors. Evidence for more than one diazepam-responsivecomponent in this subtype has also been reported by others (Aminet al., 1997). Im et al. (1993) showed that an additional benzodiazepinesite may lie at subunit interfaces other than $alpha$ / $gamma$ , and it hasbeen suggested by Sieghart (1995) that GABA_A receptors may carryboth a high-affinity and a low affinity site for benzodiazepineagonists. The significance of the lower-affinity benzodiazepinesite or sites is not yetknown.

In conclusion, the results described above show that His102 of the $alpha$ 1 subunit is an important determinant of both the affinityand pharmacological efficacy of ligands that bind to the benzodiazepinesite of the rat $alpha$ 1 $beta$ 2 $gamma$ 2 GABA_Areceptor.

	Acknowledgments

We thank Dr. D. Weiss for providing us with GABA_A receptor subunit cDNAs and Dr. A. G. Hope for advice and assistance withmolecular biologicaltechniques.

	Footnotes

Received February 9, 1999; Accepted July 16, 1999

This work was supported by the Medical Research Council of Canada (S.M.J.D.), the Savoy Foundation (M.D., S.M.J.D.) and theMedical Research Council of the United Kingdom (J.J.L.).

Send reprint requests to: Dr. Susan M. J. Dunn, Department of Pharmacology, 9-70 Medical Sciences Building, University of Alberta, Edmonton, Alberta, Canada T6G 2H7. E-mail: Susan.Dunn{at}UAlberta.CA

	Abbreviations

GABA, $gamma$ -aminobutyric acid; GABA_A, $gamma$ -aminobutyric acid type A, FNZ, flunitrazepam.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

Amin J, Brooks-Kayal A and Weiss DS (1997) Two tyrosine residues on the $alpha$ subunit are crucial for benzodiazepine binding and allosteric modulation of $gamma$ -aminobutyric acid_A receptors. Mol Pharmacol 51: 833-841[Abstract/Free Full Text].
Barnard EA, Skolnick P, Olsen RW, Mohler H, Sieghart W, Biggio G, Braestrup C, Bateson AN and Langer SZ (1998) International Union of Pharmacology. XV. Subtypes of $gamma$ -aminobutyric acid_A receptors: Classification on the basis of subunit structure and receptor function. Pharmacol Rev 50: 291-313[Abstract/Free Full Text].
Belelli D, Callachan H, Hill-Venning C, Peters JA and Lambert JJ (1996) Interaction of positive allosteric modulators with human and Drosophila recombinant GABA receptors expressed in Xenopus laevis oocytes. Br J Pharmacol 118: 563-576[Medline].
Benson JA, Low K, Keist R, Mohler H and Rudolph U (1998) Pharmacology of recombinant $gamma$ -aminobutyric acid A receptors rendered diazepam-insensitive by point-mutated receptors. FEBS Lett 431: 400-404[Medline].
Buhr A, Buhr R and Sigel E (1997) Subtle changes in residue 77 of the gamma subunit of alpha1beta2gamma2 GABA_A receptors drastically alter the affinity for ligands of the benzodiazepine binding site. J Biol Chem 272: 11799-11804[Abstract/Free Full Text].
Davies M, Bateson AN and Dunn SMJ (1998) Structural requirements for ligand interactions at the benzodiazepine recognition site of the GABA_A receptor. J Neurochem 70: 2188-2194[Medline].
Changeux J-P (1995) The acetylcholine receptor: A model for allosteric membrane proteins. Biochem Soc Trans 23: 195-205[Medline].
Duncalfe LL, Carpenter MR, Smillie LB, Martin IL and Dunn SMJ (1996) The major site of photoaffinity labelling of the GABA_A receptor by [³H]flunitrazepam is histidine 102 of the alpha subunit. J Biol Chem 271: 9209-9214[Abstract/Free Full Text].
Dunn SMJ, Bateson AN and Martin IL (1994) Molecular neurobiology of the GABA_A receptor. Int Rev Neurobiol 35: 51-96.
Hadingham KL, Garret EM, Wafford KA, Bain C, Heavens RP, Sirinathsinghji DJS and Whiting PJ (1996) Cloning of cDNAs encoding the human $gamma$ -aminobutyric acid type A receptor $alpha$ 6 subunit and characterization of the pharmacology of $alpha$ 6-containing receptors. Mol Pharmacol 49: 253-259[Abstract].
Herb A, Wisden W, Lüddens H, Puia G, Vicini S and Seeburg PH (1992) The third $gamma$ subunit of the $gamma$ -aminobutyric acid type A receptor family. Neurobiology 89: 1433-1437.
Hope AG, Downie DL, Sutherland L, Lambert JJ, Peters JA and Burchell B (1993) Cloning and functional expression of an apparent splice variant of the murine 5-HT₃ A receptor subunit. Eur J Pharmacol 245: 187-192[Medline].
Im K, Im WB, Hamilton BJ, Carter DB and Vonvoigtlander PF (1993) Potentiation of $gamma$ -aminobutyric acid-induced chloride currents by various benzodiazepine site agonists with the $alpha$ 1 $gamma$ 2, $beta$ 2 $gamma$ 2 and $alpha$ 1 $beta$ 2 $gamma$ 2 subtypes of cloned $gamma$ -aminobutyric acid type A receptors. Mol Pharmacol 44: 866-870[Abstract].
Im WB, Pregenzer JF, Binder JA, Alberts GL and Im HK (1997) Alterations of the benzodiazepine site of rat $alpha$ 6 $beta$ 2 $gamma$ 2-GABA_A receptor by replacement of several divergent amino-terminal regions with the $alpha$ 1 counterparts. Br J Pharmacol 120: 559-564[Medline].
McKernan R and Whiting PJ (1996) Which GABA_A receptor subtypes really occur in the brain? Trends Neurosci 19: 139-143[Medline].
McKernan RM, Farrar S, Collins I, Emms F, Asuni A, Quirk K and Broughton H (1998) Photoaffinity labelling of the benzodiazepine binding site of $alpha$ 1 $beta$ 3 $gamma$ 2 $gamma$ -aminobutyric acid_A receptors with flunitrazepam identifies a subset of ligands that interact directly with His102 of the $alpha$ subunit and predicts orientation of these within the benzodiazepine pharmacophore. Mol Pharmacol 54: 33-43[Abstract/Free Full Text].
Mihic SJ, Whiting PJ, Klein RL, Wafford KA and Harris RA (1994) A single amino acid of the human $gamma$ -aminobutyric acid type A receptor $gamma$ 2 subunit determines benzodiazepine efficacy. J Biol Chem 269: 32768-32773[Abstract/Free Full Text].
Nayeem N, Green TP, Martin IL and Barnard EA (1994) Quaternary structure of the native GABA_A receptor determined by electron microscopic image analysis. J Neurochem 62: 815-808[Medline].
Peters JA and Lambert JJ (1997) Anaesthetics in a bind? Trends Pharmacol Sci 18: 454-455[Medline].
Pistis M, Belelli D, Peters JA and Lambert JJ (1997) The interaction of general anaesthetics with recombinant GABA_A and glycine receptors expressed in Xenopus laevis oocytes: A comparative study. Br J Pharmacol 122: 1707-1719[Medline].
Pritchett DB, Lüddens H and Seeburg PH (1989a) Type I and type II GABA_A-benzodiazepine receptors produced in transfected cells. Science (Wash DC) 245: 1389-1392[Abstract/Free Full Text].
Pritchett DB, Sontheimer H, Shivers BD, Ymer S, Kettenmann H, Schofield PR and Seeburg PH (1989b) Importance of a novel GABA_A receptor subunit for benzodiazepine pharmacology. Nature (Lond) 338: 582-585[Medline].
Puia G, Vicini S, Seeburg PH and Costa E (1991) Influence of recombinant $gamma$ -aminobutyric-A receptor subunit composition on the action of allosteric modulators of $gamma$ -aminobutyric acid-gated Cl currents. Mol Pharmacol 39: 691-696[Abstract].
Sieghart W (1995) Structure and pharmacology of $gamma$ -aminobutyric acid_A receptor subtypes. Pharmacol Rev 47: 181-234[Medline].
Sigel E and Buhr A (1997) The benzodiazepine binding site of GABA_A receptors. Trends Pharmacol Sci 18: 425-429[Medline].
Sigel E, Schaerer MT, Buhr A and Baur R (1998) The benzodiazepine pocket of recombinant $alpha$ 1 $beta$ 2 $gamma$ 2 $gamma$ -aminobutyric acid_A receptors: Relative orientation of ligands and amino acid side chains. Mol Pharmacol 54: 1097-1105[Abstract/Free Full Text].
Smith SS, Gong QH, Hsu F, Markowitz RS, ffrench-Mullen JM and Li X (1998) GABA_A receptor $alpha$ 4 subunit suppression prevents withdrawal properties of an endogenous steroid. Nature (Lond) 392: 926-930[Medline].
Villar HO, Uyeno ET, Toll L, Polgar W, Davies MF and Loew GH (1989) Molecular determinants of benzodiazepine receptor affinities and anticonvulsant activities. Mol Pharmacol 36: 589-600[Abstract].
Wafford KA, Thompson SA, Thomas D, Sikela J, Wilcox AS and Whiting PJ (1996) Functional characterization of human $gamma$ -aminobutyric acid_A receptors containing the $alpha$ 4 subunit. Mol Pharmacol 50: 670-678[Abstract].
Whiting PJ, McKernan RM and Wafford KA (1995) Structure and pharmacology of vertebrate GABA_A receptor subtypes. Int Rev Neurobiol 38: 95-138[Medline].
Wieland HA, Lüddens H and Seeburg PH (1992) A single histidine in GABA_A receptors is essential for benzodiazepine agonist binding. J Biol Chem 267: 1426-1429[Abstract/Free Full Text].
Zezula J, Slany A and Sieghart W (1996) Interaction of allosteric ligands with GABA_A receptors containing one, two or three subunits. Eur J Pharmacol 301: 207-214[Medline].
Zhang W, Koehler KF, Zhang P and Cook JM (1995) Development of a comprehensive pharmacophore model for the benzodiazepine receptor. Drug Des Discov 12: 193-248[Medline].

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Mutagenesis of the Rat 1 Subunit of the -Aminobutyric AcidA Receptor Reveals the Importance of Residue 101 in Determining the Allosteric Effects of Benzodiazepine Site Ligands

Mutagenesis of the Rat $alpha$ 1 Subunit of the $gamma$ -Aminobutyric Acid_A Receptor Reveals the Importance of Residue 101 in Determining the Allosteric Effects of Benzodiazepine Site Ligands