Rat pharmacokinetics and pharmacodynamics of a sustained release formulation of the GABAA alpha5-selective compound L-655,708.

The pharmacokinetic and pharmacodynamic (i.e., receptor occupancy) properties of L-655,708, a compound with selectivity for alpha5-over alpha1-, alpha2-, and alpha3-containing GABA(A) receptors, were examined in rats with the aim of developing a formulation that would give sustained (up to 6 h) and selective occupancy of alpha5-containing GABA(A) receptors suitable for behavioral studies. Standard rat pharmacokinetic analyses showed that L-655,708 has a relatively short half-life with kinetics in the brain mirroring those in the plasma. In vivo binding experiments showed that plasma concentrations of around 100 ng/ml gave relatively selective in vivo occupancy of rat brain alpha5-versus alpha1-, alpha2-, and alpha3-containing GABA(A) receptors. Therefore, this plasma concentration was chosen as a target to achieve relatively selective occupancy of alpha5-containing receptors using s.c. implantations of L-655,708 (0.4, 1.5, or 2.0 mg) formulated into tablets of various size (20 or 60 mg) containing different amounts of L-655,708 and combinations of low and high viscosity hydroxypropyl methylcellulose (LV- and HV-HPMC). The optimum formulation, 1.5 mg of L-655,708 compressed into a 60-mg tablet with 100% HV-HPMC, resulted in relatively constant plasma concentrations being maintained for at least 6 h with very little difference between C(max) concentrations (125-150 ng/ml) and plateau concentrations (100-125 ng/ml). In vivo binding experiments confirmed the selective occupancy of rat brain alpha5-over alpha1-, alpha2-, and alpha3-containing GABA(A) receptors.     

In vivo labelling of alpha5 subunit-containing GABA(A) receptors using the selective radioligand [(3)H]L-655,708

L-655,708 is an imidazobenzodiazepine possessing 30-70-fold selectivity for the benzodiazepine binding site of GABA_A receptors containing an α5 rather than α1, α2 or α3 subunit. In the present study, [³H]L-655,708 was used to label mouse brain benzodiazepine binding sites in vivo. When compared to inhibition of in vivo binding of the non-selective ligand [³H]Ro 15-1788, the pharmacology of mouse in vivo [³H]L-655,708 binding was consistent with selective in vivo labelling of α5 subunit-containing GABA_A receptors. Thus, diazepam was equipotent at inhibiting in vivo [³H]L-655,708 and [³H]Ro 15-1788 binding; zolpidem, which has very low affinity for α5-containing GABA_A receptors, gave no inhibition of in vivo [³H]L-655,708 binding despite inhibiting in vivo [³H]Ro 15-1788 binding; and L-655,708 was more potent at inhibiting the in vivo binding of [³H]L-655,708 compared to [³H]Ro 15-1788. This pharmacological specificity of in vivo [³H]L-655,708 binding was confirmed autoradiographically. Hence, the anatomical distribution of in vivo [³H]L-655,708 binding was comparable to the distribution of α5-containing GABA_A receptors identified in vitro. Moreover, this distribution was distinct from that identified using [³H]Ro 15-1788. These data therefore suggest that [³H]L-655,708 can be used to identify α5-containing GABA_A receptors in vivo and that this ligand can be used to measure receptor occupancy of α5-selective ligands.     

Flavan-3-ol derivatives are positive modulators of GABA(A) receptors with higher efficacy for the alpha(2) subtype and anxiolytic action in mice

Recent genetic and pharmacological studies have demonstrated that alpha(2)-containing GABA(A) receptors mediate the anxiolytic effects of benzodiazepines, setting a new strategy in developing novel, non-sedative anxiolytic agents. In this study we show that stereoisomers of 3-acetoxy-4'-methoxyflavan are positive modulators of recombinant alpha(1,2,3,5)beta(2)gamma(2L) and alpha(1)beta(2) GABA(A) receptors expressed in Xenopus laevis oocytes. GABA(C) receptors are insensitive to modulation by these compounds. In each case, the enhancement was evident at low micromolar concentrations and occurred independently of the classical high affinity benzodiazepine site, as it could not be blocked by the antagonist flumazenil. Importantly, the compound Fa131 was significantly more efficacious at enhancing GABA-induced currents (EC(5)) at alpha(2)beta(2)gamma(2L) receptors compared to alpha(1)beta(2)gamma(2L), alpha(3)beta(2)gamma(2L) and alpha(5)beta(2)gamma(2L) receptors (E(max)=21.0+/-1.7 times, compared to 8.5+/-0.7 times at alpha(1)-, 9.5+/-0.6 times at alpha(3)- and 5.2+/-0.4 times at alpha(5)-contaning GABA(A) receptors), suggesting a potential use as an anxiolytic. In mice, this agent (1-30mg/kg i.p.) induced anxiolytic-like action in two unconditioned models of anxiety: the elevated plus maze and the light/dark paradigms. No sedative or myorelaxant effects were detected using the hole board, actimeter and horizontal wire tests, and only weak barbiturate-potentiating effects on the loss of righting reflex test. Fa131 demonstrated improved segregation of anxiolytic and sedative doses when compared to the non-selective agonist diazepam. Finally, flavan derivatives highlight the potential of targeting non-benzodiazepine allosteric sites in the search for new anxioselective drugs.     

The benzodiazepine binding site of GABA(A) receptors as a target for the development of novel anxiolytics

Non-selective benzodiazepine (BZ) binding-site full agonists, exemplified by diazepam, act by enhancing the inhibitory effects of GABA at GABA(A) receptors containing either an alpha1, -2, -3 or -5 subunit. However, despite their proven clinical anxiolytic efficacy, such compounds possess a relatively narrow window between doses that produce anxiolysis and those that cause sedation, and are also associated with physical dependence and a potential for abuse. In the late 1980s and early 1990s a number of non-selective partial agonists, exemplified by bretazenil, pazinaclone and abecarnil, were described. Their reduced intrinsic efficacy relative to full agonists such as diazepam resulted in an improved preclinical pharmacological profile in that there was a large window between anxiolytic and sedative doses and their dependence and abuse liabilities were much lower. Unfortunately, these compounds failed, for a variety of reasons, to translate into clinical benefit, and as the public perception of BZs deteriorated interest in the area waned. However, the advent of molecular genetic and pharmacological approaches has begun to delineate which GABA(A) receptor subtypes are associated with the various pharmacological effects of the non-selective BZs. More specifically, the alpha2- and/or alpha3-containing GABA(A) receptors play a role in anxiety whereas the alpha1 subtype is involved in sedation, raising the possibility of a compound that selectively modulates alpha2- and/or alpha3-containing receptors but does not affect alpha1-containing receptors would be a non-sedating anxiolytic. In order to achieve selectivity for the alpha2/alpha3 subtypes relative to alpha1, two approaches may be used; selective affinity or selective efficacy. Selective affinity relies on a compound binding with higher affinity to the alpha2/alpha3 compared with alpha1 subtypes, but to date no such compounds have been described. On the other hand, subtype-selective efficacy relies on a compound binding to all subtypes but having different efficacies at various subtypes (relative selective efficacy, for example SL654198 or pagoclone) or having efficacy at some subtypes but none at others (absolute selective efficacy; for example, L-838417). The status of these and other BZ site compounds with claimed, but often not explicitly stated, GABA(A) subtype selectivity (such as ELB-139 and ocinaplon) will be reviewed in relation to their development as non-sedating anxiolytics for the treatment of generalised anxiety disorder.     

GABAA receptor subtype-selective modulators. II. α5-selective inverse agonists for cognition enhancement

Benzodiazepine site agonists (such as diazepam) are well-known to impair cognition. Since benzodiazepines exert their effects via modulation of α1-, α2-, α3- and α5-containing GABA(A) receptors, the cognition-impairing effects of diazepam must be associated with one or several of these subtypes. Of these different subtypes, α5-containing GABA(A) receptors represent an attractive option as the "cognition" subtype based upon the preferential localization of these receptors within the hippocampus and the well-established role of the hippocampus in learning and memory. As a result, it is hypothesized that an inverse agonist selective for the α5 subtype should enhance cognition. For example, L-655708, a partial inverse agonist with 50-100-fold higher affinity for the α5 relative to the α1, α2 and α3 subtypes of GABA(A) receptors, enhanced cognitive performance in rats. Unfortunately, however, pharmacokinetic properties of this compound prevented it being developed further. In order to try achieve binding selectivity in a series structurally distinct from the imidazobenzodiazepines, the group at Merck, Sharp & Dohme commenced studies within the triazolopyridazine series. Although a degree of binding selectivity could be achieved (a maximum of 22-125-fold for α5 versus α1, α2 or α3) this approach was dropped in favour of a strategy to identify compounds with either a combination of selective affinity and selective efficacy or purely selective efficacy. With respect to the former, screening of the Merck chemical collection identified a novel, moderately α5-binding selective thiophene series and further optimization of this series produced MRK-536, which demonstrated a modest α5 binding selectivity (~10-fold) as well as α5-efficacy selectivity. However, the structure-activity relationship within this and the analogous tetralone series proved unpredictable and these series were not pursued further. The success of the selective efficacy approach on the α2/α3-selective agonist project led a similar paradigm being adopted for the α5 project. The starting point for this strategy was the triazolopyridazine 3 which, like MRK-536, possessed a degree of both α5 binding- and efficacy-selectivity. By changing the core from a triazolopyridazine to a triazolophthalazine structure, α5 binding selectivity was lost but with subsequent optimization, compounds with the desired profile (low or antagonist efficacy at the α1, α2 and α3 subtypes and marked inverse agonism at α5-containing receptors) could be achieved, allowing the clinical candidate α5IA as well as the structurally-related pharmacological tool compound α5IA-II to be identified. By appending features of the prototypic α2/α3-selective triazolopyridazine L-838417 (t-butyl and 1,2,4 triazole) along with the isoxazole of α5IA to a pyrazolotriazine core, an additional clinical candidate, MRK-016, was identified. Finally, a degree of α5 efficacy selectivity was achieved the pyridazine series but metabolic instability within this chemotype limited its further optimization. Overall, these studies demonstrate the feasibility of adopting a selective efficacy approach in the identification of α5 selective GABA(A) receptor inverse agonists.     

The in vivo properties of pagoclone in rat are most likely mediated by 5'-hydroxy pagoclone

The cyclopyrrolone pagoclone binds with roughly equivalent high affinity (0.7-9.1nM) to the benzodiazepine binding site of human recombinant GABA(A) receptors containing either an alpha1, alpha2, alpha3 or alpha5 subunit. However, whereas it was a partial agonist at alpha1-, alpha2- and alpha5-containing GABA(A) receptors, pagoclone was a full agonist at receptors containing an alpha3 subunit. In the rat elevated plus maze assay pagoclone (3mg/kg) had significant anxiolytic-like activity but at all three doses tested (0.3, 1 and 3mg/kg p.o.) it produced a significant reduction in the total distance travelled. This sedative-like effect was confirmed in rat chain-pulling and spontaneous locomotor assays. Surprisingly, in the plasma and brain samples derived from the elevated plus maze assay, the major metabolite of pagoclone, 5'-hydroxy pagoclone, was present at 10-20-fold higher concentrations relative to the parent compound. In order to establish whether this metabolite might have pharmacological activity, we measured its affinity and efficacy profile and found that both were comparable to those of pagoclone with the exception that efficacy at the alpha1 subtype was considerably greater for 5'-hydroxy pagoclone compared with the parent. This metabolite had significant anxiolytic-like activity in the elevated plus maze but at these same doses (0.3-3mg/kg p.o.) also produced sedation. It is therefore likely that in rats 5'-hydroxy pagoclone mediates the majority of the pharmacological actions following pagoclone administration.     

Kindling induced by pentylenetetrazole in rats is not directly associated with changes in the expression of NMDA or benzodiazepine receptors

Repeated injections of a subconvulsant dose of pentylenetetrazole (PTZ, 30 mg/kg IP three times weekly for 13 injections) in Wistar and hooded Lister rats resulted in kindled seizures, the extent of which varied between strains. Wistar rats achieved stage 4 of clonic-tonic seizures, whereas hooded Lister rats only reached stage 2 of convulsive waves axially through the body. Rats were killed 10 days after their final injection, and radioligand binding was used to measure the expression of NMDA receptors in cortex and hippocampus using [3H]MK-801 and [3H]L-689,560, the latter binding specifically to the NR1 subunit. [3H]Ro 15-1788 measured expression of GABA(A)-benzodiazepine binding sites containing alpha1, alpha2, alpha3, or alpha5 subunits. Specific analysis of GABA(A) receptors containing the alpha5 subunit, which are preferentially localized in the hippocampus, was assessed with [3H]L-655,708. In the cortex, there was no effect of strain or treatment on the K(D) or B(max) of any of the ligands. Similarly, there was no effect of strain or treatment on hippocampal [3H]L-689,560 or [3H]Ro 15-1788 binding. However, in the hippocampus there was a significant, albeit modest, effect of treatment on the B(max) of [3H]MK-801 binding and the B(max) and K(D) of [3H]L-655,708 binding, i.e., PTZ-treated rats had fewer [3H]MK-801 and [3H]L-655,708 binding sites (NMDA and alpha5-containing GABA(A) receptors, respectively), but, these reductions were significant only in the relatively seizure-insensitive hooded Lister strain. This suggests that the increased susceptibility to kindling in Wistar rats is not directly related to alterations in the expression of NMDA or GABA(A) receptors.     

Anxioselective compounds acting at the GABA(A) receptor benzodiazepine binding site

With the exception of obsessive compulsive disorder, benzodiazepines (BZs) remain a major first line treatment for anxiety disorders. However, as well as being anxiolytic, BZs also cause sedation acutely, related to the fact that BZs are also used as hypnotics, and chronically may have abuse potential as well as cause physical dependence which manifests itself as the demonstration of a number of adverse events upon discontinuation. The molecular mechanisms of BZs are now well defined in that they enhance the actions of the inhibitory neurotransmitter GABA by binding to a specific recognition site on GABA(A) receptors containing alpha1, alpha2, alpha3 and alpha5 subunits. Compounds that bind at this modulatory site and enhance the inhibitory actions of GABA are classified as agonists, those that decrease the actions of GABA are termed inverse agonists whereas compounds which bind but have no effect on GABA inhibition are termed antagonists. The clinically used BZs are full agonists and between the opposite ends of the spectrum, i.e. full agonist and full inverse agonist, are a range of compounds with differing degrees of efficacy, such as partial agonists and partial inverse agonists. Attempts have been made to develop compounds which are anxioselective in that they retain the anxiolytic properties of the full agonist BZs but have reduced sedation and dependence (withdrawal) liabilities. Such compounds may interact with all four (i.e. alpha1-, alpha2-, alpha3- and alpha5-containing) GABA(A) receptor subtypes and have partial rather than full agonist efficacies. Examples of nonselective partial agonists include bretazenil, imidazenil, FG 8205, abecarnil, NS 2710, pagoclone, RWJ-51204 and (S)-desmethylzopiclone. Alternatively, a compound might have comparable binding affinity but different efficacies at the various subtypes, thereby preferentially exerting its effects at subtypes thought to be associated with anxiety (alpha2- and/or alpha3-containing receptors) rather than the subtype associated with sedation (alpha1-containing receptors). Examples of efficacy selective compounds include L-838417, NGD 91-3 and SL651498. For each compound, preclinical and where available clinical data will be reviewed. Emerging themes include the lack of definitive intrinsic efficacy data for certain compounds (e.g. abecarnil, ocinaplon, pagoclone) and the difficulty in translating robust anxiolysis and a separation between anxiolytic and sedative doses of non-selective partial agonists in preclinical species into consistent clinical benefit in man (e.g. bretazenil, abecarnil, pagoclone). With respect to efficacy selective compounds, NGD 91-3 was not anxiolytic in man but in the absence of efficacy data, these results are difficult to interpret. Nevertheless, efficacy selective compounds represent a novel approach to targeting specific subtypes of the GABA(A) receptor, the ultimate test of which will be evaluation in the clinic.     

The novel anxiolytic ELB139 displays selectivity to recombinant GABA(A) receptors different from diazepam

A chemically heterogeneous group of compounds acts at the benzodiazepine (BZ) recognition site of the diverse gamma-aminobutyric acid type A (GABA(A)) receptor complexes which can assemble from more than 16 known subunits. Most 1,4-BZs like diazepam recognize all GABA(A)/BZ receptors containing the alpha1-3 or alpha5 together with any beta and the gamma2 subunit. Other compounds differentiate less, e.g. Ro15-4513, that additionally recognizes alpha4- and a6-containing receptors, or differentiate more, e.g. zolpidem, that recognizes preferentially alpha1-containing receptors. Here we describe the functional properties of 1-(4-chloro-phenyl)-4-piperidin-1-yl-1,5-dihydro-imidazol-2-on (ELB139) in the presence and absence of the BZ receptor antagonist flumazenil (Ro15-1788) on recombinant alphaibeta2gamma2 (i=1-5) receptor subtypes expressed in HEK 293 cells. The properties were measured with the whole-cell variation of the patch-clamp technique and compared to those of diazepam. Like the latter, ELB139 did not potentiate GABA-induced currents in alpha4-containing receptors, but it displays functional subtype specificity between alpha1, alpha2, alpha3, and alpha5beta2gamma2 receptors with highest potency in alpha3-containing receptors but highest efficacy in alpha1- or alpha2-containing receptors, respectively. ELB139 acted as a partial agonist on these receptor subtypes reaching 40-50% of the efficacy of diazepam.     

Evaluation of native GABA(A) receptors containing an alpha 5 subunit

The type A receptor for gamma-aminobutyric acid (GABA), or GABA(A) receptor, is a pentamer of highly variable quaternary structure. It includes two alpha subunits, drawn from a pool of six genes, which largely determine benzodiazepine pharmacology of the receptor. In brain sections, both [(3)H]RY-80 (ethyl-8-acetylene-5,6-dihydro-5-methyl-6-oxo-4H-imidazo[1,5a][1,4]benzodiazepine-3-carboxylate) and [(3)H]L-655,708 (ethyl (S)-11,12,13,13a-tetrahydro-7-methoxy-9-oxo-9H-imidazo[1,5-a]pyrrolo[2,1-c][1,4]benzodiazepine-1-carboxylate), which are selective for the benzodiazepine site of alpha 5 subunit-containing receptors, showed high-affinity, specific binding, but to fewer regions than did the nonselective benzodiazepine, [(3)H]flunitrazepam. The pattern mirrored alpha 5 mRNA distribution, and was similar to that previously reported for [(3)H]L-655,708 binding. Displacement of [(3)H]RY-80 bound to hippocampal homogenates, and of [(3)H]flunitrazepam bound to cerebellar and hippocampal homogenates showed comparable displacement by flumazenil (K(i)'s 5--7 nM). However, the K(i)'s for diazepam and for clobazam to displace [(3)H]RY-80 binding in hippocampus were about fourfold higher than for [(3)H]flunitrazepam, and the K(i) for clonazepam was sixfold larger, suggesting that these benzodiazepine receptor agonists bind with relatively lower affinity at hippocampal alpha 5-containing receptors.     

Role of GABAA alpha5-containing receptors in ethanol reward: the effects of targeted gene deletion, and a selective inverse agonist

GABA(A) receptors containing alpha5 subunits have been suggested to mediate the rewarding effects of ethanol. We tested this hypothesis in mice with deletion of alpha5 subunits. alpha5 knockout mice did not differ from wildtypes in operant responding for 10% ethanol/10% sucrose, but responded less for 10% sucrose. The benzodiazepine (BZ) site inverse agonist, Ro 15-4513, has higher affinity for GABA(A) receptors containing 5 subunits and dose-dependently (0-27 mg/kg, i.p.) reduced lever pressing for ethanol/sucrose in wildtype mice, but had less effect in knockout mice; lever pressing for sucrose was unaffected. These data suggest that alpha5 subunits are not essential for ethanol reward, but the reduction of operant responding for ethanol by Ro 15-4513 is mediated by alpha5-containing GABA(A) receptors. In measures of ethanol consumption, alpha5 knockout mice did not differ from wildtypes at low ethanol concentrations (2-8%), but consumed less ethanol at higher concentrations; these differences were not attributable to increased behavioural disruption of the knockout by ethanol, since no differences were seen in sensitivity to ethanol's sedative or ataxic effects. Ro 15-4513's ability to reduce ethanol consumption was unaffected, suggesting that this effect is not mediated by the alpha5 subtype. Secondly, we tested the ability of a novel alpha5-efficacy-selective benzodiazepine receptor ligand, alpha5IA-II, that possesses greater inverse agonist activity at alpha5- than at alpha1-, á2- or alpha3-containing GABA(A) receptors, to influence operant responding. alpha5IA-II (0.03-3 mg/kg) dose-dependently decreased lever pressing for 10% ethanol, the minimally effective dose of 1 mg/kg, corresponding to over 90% receptor occupancy, but did not affect lever pressing for 4% sucrose. Although inverse agonists acting at alpha5-containing receptors reduce ethanol self-administration, alpha5 subunits may not be essential to signaling ethanol reward.     

Identification of a novel,selective GABA(A) alpha5 receptor inverse agonist which enhances cognition

In pursuit of a GABA(A) alpha5-subtype-selective inverse agonist to enhance cognition, a series of 6,7-dihydro-2-benzothiophen-4(5H)-ones has been identified as a novel class of GABA(A) receptor ligands. These thiophenes have higher binding affinity for the GABA(A) alpha5 receptor subtype compared to the GABA(A) alpha1, alpha2, and alpha3 subtypes, and several analogues exhibit high GABA(A) alpha5 receptor inverse agonism. 6,6-Dimethyl-3-(2-hydroxyethyl)thio-1-(thiazol-2-yl)-6,7-dihydro-2-benzothiophen-4(5H)-one (43) has been identified as a full inverse agonist at the GABA(A) alpha5 receptor and is functionally selective over the other major GABA(A) receptor subtypes. 43 readily penetrates into the CNS to give selective occupancy of GABA(A) alpha5 receptors. In addition, 43 enhances cognitive performance in rats in the delayed 'matching-to-place' Morris water maze test-a hippocampal-dependent memory task-without the convulsant or proconvulsant activity associated with nonselective, GABA(A) receptor inverse agonists.     

GABA A/Bz receptor subtypes as targets for selective drugs

The gamma-aminobutyric acid type A (GABA(A)) receptors are the major inhibitory neuronal receptors in the mammalian brain. Their activation by GABA opens the intrinsic ion channel, enabling chloride flux into the cell with subsequent hyperpolarization. Several GABA(A) receptor subunit isoforms have been cloned, the major isoform containing alpha, beta, and gamma subunits, and a regional heterogeneity associated with distinct physiological effects has been suggested. As a variety of allosteric ligands can modulate GABA-gated conductance changes through binding to distinct sites, the development of subtype-selective ligands may lead to the selective treatment of GABA system-associated pathology. In particular, the best characterized binding site is the benzodiazepine site (BzR), localized at the alpha/gamma subunit interface, in which the alpha subunit is the main determinant of BzR ligand action selectivity. The alpha1-containing BzR have been proposed to be responsible for the sedative action; the alpha2 and/or the alpha3 subtypes have been suggested to mediate the anxiolytic activity and the myorelaxation effects, and the alpha5 subtype has been associated with cognition processes. The discovery of alpha-selective subtype ligands may help in the specific treatment of anxiety, sleep disorders, convulsions and memory deficits with fewer side effects. Selectivity may be achieved by two approaches: selective affinity or selective efficacy. Selective affinity needs a compound to bind with a higher affinity to one receptor subtype compared with another, whereas subtype-selective efficacy relies on a compound binding to all subtypes, but having different efficacies at various subtypes. The status of BzR ligands, subdivided on the basis of their main chemical structural features, is reviewed in relation to structure-activity relationships which determine their affinity or efficacy selectivity for a certain BzR subtype.     

Effect of alpha subunit on allosteric modulation of ion channel function in stably expressed human recombinant gamma-aminobutyric acid(A) receptors determined using (36)Cl ion flux

Inhibitory gamma-aminobutyric acid (GABA)(A) receptors are subject to modulation at a variety of allosteric sites, with pharmacology dependent on receptor subunit combination. The influence of different alpha subunits in combination with beta3gamma2s was examined in stably expressed human recombinant GABA(A) receptors by measuring (36)Cl influx through the ion channel pore. Muscimol and GABA exhibited similar maximal efficacy at each receptor subtype, although muscimol was more potent, with responses blocked by picrotoxin and bicuculline. Receptors containing the alpha3 subunit exhibited slightly lower potency. The comparative pharmacology of a range of benzodiazepine site ligands was examined, revealing a range of intrinsic efficacies at different receptor subtypes. Of the diazepam-sensitive GABA(A) receptors (alpha1, alpha2, alpha3, alpha5), alpha5 showed the most divergence, being discriminated by zolpidem in terms of very low affinity, and CL218,872 and CGS9895 with different efficacies. Benzodiazepine potentiation at alpha3beta3gamma2s with nonselective agonist chlordiazepoxide was greater than at alpha1, alpha2, or alpha5 (P < 0.001). The presence of an alpha4 subunit conferred a unique pharmacological profile. The partial agonist bretazenil was the most efficacious benzodiazepine, despite lower alpha4 affinity, and FG8205 displayed similar efficacy. Most striking were the lack of affinity/efficacy for classical benzodiazepines and the relatively high efficacy of Ro15-1788 (53 +/- 12%), CGS8216 (56 +/- 6%), CGS9895 (65 +/- 6%), and the weak partial inverse agonist Ro15-4513 (87 +/- 5%). Each receptor subtype was modulated by pentobarbital, loreclezole, and 5alpha-pregnan-3alpha-ol-20-one, but the type of alpha subunit influenced the level of potentiation. The maximal pentobarbital response was significantly greater at alpha4beta3gamma2s (226 +/- 10% increase in the EC(20) response to GABA) than any other modulator. The rank order of potentiation for pregnanolone was alpha5 > alpha2 > alpha3 = alpha4 > alpha1, for loreclezole alpha1 = alpha2 = alpha3 > alpha5 > alpha4, and for pentobarbital alpha4 = alpha5 = alpha2 > alpha1 = alpha3.     

SL651498, a GABAA receptor agonist with subtype-selective efficacy,as a potential treatment for generalized anxiety disorder and muscle spasms

SL651498 (6-fluoro-9-methyl-2-phenyl-4-(pyrrolidin-1-yl-carbonyl)-2,9-dihydro-1H-pyrido[3,4-b]indol-1-one) was identified as a drug development candidate from a research program designed to discover subtype-selective GABA(A) receptor agonists for the treatment of generalized anxiety disorder and muscle spasms. The drug displays high affinity for rat native GABA(A) receptors containing alpha(1) (K(i) = 6.8 nM) and alpha(2) (K(i) = 12.3 nM) subunits, and weaker affinity for alpha5-containing GABA(A) receptors (K(i) = 117 nM). Studies on recombinant rat GABA(A) receptors confirm these findings and indicate intermediate affinity for the alpha(3)beta(2)gamma(2) subtype. SL651498 behaves as a full agonist at recombinant rat GABA(A) receptors containing alpha(2) and alpha(3) subunits, and as a partial agonist at recombinant GABA(A) receptors expressing alpha(1) and alpha(5) subunits. SL651498 produced anxiolytic-like and skeletal muscle relaxant effects qualitatively similar to those of benzodiazepines (BZs) [minimal effective dose (MED): 1 to 10 mg/kg, i.p. and 3 to 10 mg/kg, p.o.]. However, unlike these latter drugs, SL651498 induced muscle weakness, ataxia or sedation at doses much higher than those having anxiolytic-like activity (MED: 30 to 100 mg/kg, i.p. or p.o.). Moreover, in contrast to BZs, SL651498 did not produce tolerance to its anticonvulsant activity or physical dependence. It was much less active than BZs in potentiating the depressant effects of ethanol or impairing cognitive processes in rodents. The differential profile of SL651498 as compared to BZs may be related to its selective efficacy at the alpha(2)- and alpha(3)-containing GABA(A) receptors. This suggests that selectively targeting GABA(A) receptor subtypes can lead to drugs with increased clinical specificity. SL651498 represents a promising alternative to agents currently used for the treatment of anxiety disorders and muscle spasms without the major side effects seen with classical BZs.     

3-Heteroaryl-2-pyridones: benzodiazepine site ligands with functional delectivity for alpha 2/alpha 3-subtypes of human GABA(A) receptor-ion channels

A novel series of 3-heteroaryl-5,6-bis(aryl)-1-methyl-2-pyridones were developed with high affinity for the benzodiazepine (BZ) binding site of human gamma-aminobutyric acid (GABA(A)) receptor ion channels, low binding selectivity for alpha 2- and/or alpha 3- over alpha 1-containing GABA(A) receptor subtypes and high binding selectivity over alpha 5 subtypes. High affinity appeared to be associated with a coplanar conformation of the pyridone and sulfur-containing 3-heteroaryl rings resulting from an attractive S.O intramolecular interaction. Functional selectivity (i.e., selective efficacy) for alpha 2 and/or alpha 3 GABA(A) receptor subtypes over alpha1 was observed in several of these compounds in electrophysiological assays. Furthermore, an alpha 3 subtype selective inverse agonist was proconvulsant and anxiogenic in rodents while an alpha 2/alpha 3 subtype selective partial agonist was anticonvulsant and anxiolytic, supporting the hypothesis that subtype selective BZ site agonists may provide new anxiolytic therapies.     

Differential contribution of GABA(A) receptor subtypes to the anticonvulsant efficacy of benzodiazepine site ligands

Non-selective benzodiazepines, such as diazepam, interact with equivalent affinity and agonist efficacy at GABA(A) receptors containing either an alpha1, alpha2, alpha3 or alpha5 subunit. However, which of these particular subtypes are responsible for the anticonvulsant effects of diazepam remains uncertain. In the present study, we examined the ability of diazepam to reduce pentylenetetrazoLe (PTZ)-induced and maximal electroshock (MES)-induced seizures in mice containing point mutations in single (alpha1H101R, alpha2H101R or alpha5H105R) or multiple (alpha125H-->R) alpha subunits that render the resulting GABA(A) receptors diazepam-insensitive. Furthermore, the anticonvulsant properties of diazepam, the alpha1- and alpha3-selective compounds zolpidem and TP003, respectively, and the alpha2/alpha3 preferring compound TP13 were studied against PTZ-induced seizures. In the transgenic mice, no single subtype was responsible for the anticonvulsant effects of diazepam in either the PTZ or MES assay and neither the alpha3 nor alpha5 subtypes appeared to confer anticonvulsant activity. Moreover, whereas the alpha1 and alpha2 subtypes played a modest role with respect to the PTZ assay, they had a negligible role in the MES assay. With respect to subtype-selective compounds, zolpidem and TP003 had much reduced anticonvulsant efficacy relative to diazepam in both the PTZ and MES assays whereas TP13 had high anticonvulsant efficacy in the PTZ but not the MES assay. Taken together, these data not only indicate a role for alpha2-containing GABA(A) receptors in mediating PTZ and MES anticonvulsant activity but also suggest that efficacy at more than one subtype is required and that these subtypes act synergistically.     

Anxiogenic properties of an inverse agonist selective for alpha3 subunit-containing GABA A receptors

Alpha3IA (6-(4-pyridyl)-5-(4-methoxyphenyl)-3-carbomethoxy-1-methyl-1H-pyridin-2-one) is a pyridone with higher binding and functional affinity and greater inverse agonist efficacy for GABA(A) receptors containing an alpha3 rather than an alpha1, alpha2 or alpha5 subunit. If doses are selected that minimise the occupancy at these latter subtypes, then the in vivo effects of alpha3IA are most probably mediated by the alpha3 subtype. Alpha3IA has good CNS penetration in rats and mice as measured using a [(3)H]Ro 15-1788 in vivo binding assay. At doses in rats that produce relatively low levels of occupancy (12%) in the cerebellum (i.e. alpha1-containing receptors), alpha3IA (30 mg kg(-1) i.p.), like the nonselective partial inverse agonist N-methyl-beta-carboline-3-carboxamide (FG 7142), not only caused behavioural disruption in an operant, chain-pulling assay but was also anxiogenic in the elevated plus maze, an anxiogenic-like effect that could be blocked with the benzodiazepine antagonist Ro 15-1788 (flumazenil). Neurochemically, alpha3IA (30 mg kg(-1) i.p.) as well as FG 7142 (15 mg kg(-1) i.p.) increased the concentration of the dopamine metabolite 3,4-dihydroxyphenylacetic acid in rat medial prefrontal cortex by 74 and 68%, respectively, relative to vehicle-treated animals, a response that mimicked that seen following immobilisation stress. Taken together, these data demonstrate that an inverse agonist selective for GABA(A) receptors containing an alpha3 subunit is anxiogenic, and suggest that since alpha3-containing GABA(A) receptors play a role in anxiety, then agonists selective for this subtype should be anxiolytic.     

6,2'-Dihydroxyflavone, a subtype-selective partial inverse agonist of GABAA receptor benzodiazepine site

Neuroactivity of a number of flavonoids is mediated by modulation of type A gamma-aminobutyric acid (GABA(A)) receptor function via benzodiazepine sites, mostly as partial agonists. In the present study, 6,2'-dihydroxyflavone (DHF) was characterized for potential inverse agonistic activity, and its mechanism of action was explored for receptor subtype selectivity. In whole-cell patch clamp studies on neuroblastoma IMR-32 cells expressing native GABA(A) receptors, DHF decreased GABA-induced currents, to an extent similar to that induced by the partial inverse agonist FG-7142, which could be blocked by flumazenil, a BZ site antagonist. In mouse behavioral models, DHF elicited significant anxiogenic-like effects in the elevated plus-maze test, and enhanced cognitive performance in the step-through passive avoidance test, as expected for an inverse agonist. However, DHF did not exhibit any proconvulsant effects, a typical action of inverse agonists. In electrophysiological studies on subtypes of recombinant GABA(A) receptors expressed in HEK 293T cells, DHF decreased GABA-induced currents in alpha(1)beta(3)gamma(2), alpha(2)beta(3)gamma(2), or alpha(5)beta(3)gamma(2), but not alpha(3)beta(3)gamma(2) receptors. The results demonstrated DHF as a partial inverse agonist-like modulator of GABA(A) receptors with selectivity in receptor subtypes as well as behavioral effects. The DHF subtype-selectivity suggested that alpha(3)-containing subtypes could be a mediator of the convulsion activities of GABA(A) receptor inverse agonists. Moreover, the pharmacological profile displayed in mouse behavioral models supported DHF as a useful lead compound for the development of cognition-enhancing agents devoid of convulsion side effects.     

Residues in transmembrane domains I and II determine gamma-aminobutyric acid type AA receptor subtype-selective antagonism by furosemide.

GABAA receptors in cerebellar granule cells are unique in expressing a subtype containing the alpha6 subunit. This receptor subtype has high affinity for GABA and produces a degree of tonic inhibition on cerebellar granule cells, modulating the firing of these cells via spillover of GABA from GABAergic synapses. This receptor subtype also has selective affinity for the diuretic furosemide over receptors containing other alpha-subunits. Furosemide exhibits approximately 100-fold selectivity for alpha6-containing receptors over alpha1-containing receptors. By making alpha1/alpha6 chimeras we have identified a transmembrane region (209-279) responsible for the high furosemide sensitivity of alpha6beta3gamma2s receptors. Within the alpha1 transmembrane region, a single amino acid was identified that when mutated from threonine to isoleucine, increased furosemide sensitivity by 20-fold. We demonstrate the beta-subunit selectivity of furosemide to be due to asparagine 265 in the beta2 and beta3 transmembrane-domain II similar to that observed with potentiation by the anticonvulsant loreclezole. We also show that Ile in transmembrane-domain I accounts for the increased GABA sensitivity observed at alpha6beta3gamma2s compared with alpha1beta3gamma2s receptors, but did not affect direct activation by pentobarbital or potentiation by the benzodiazepine flunitrazepam. Location of these residues within transmembrane domains leads to speculation that they may be involved in the channel-gating mechanism conferring increased receptor activation by GABA, in addition to conferring furosemide sensitivity.