Mutations in the Gabrb1 gene promote alcohol consumption through increased tonic inhibition.

Alcohol dependence is a common, complex and debilitating disorder with genetic and environmental influences. Here we show that alcohol consumption increases following mutations to the γ-aminobutyric acidA receptor (GABAAR) ß1 subunit gene (Gabrb1). Using N-ethyl-N-nitrosourea mutagenesis on an alcohol-averse background (F1 BALB/cAnN x C3H/HeH), we develop a mouse model exhibiting strong heritable preference for ethanol resulting from a dominant mutation (L285R) in Gabrb1. The mutation causes spontaneous GABA ion channel opening and increases GABA sensitivity of recombinant GABAARs, coupled to increased tonic currents in the nucleus accumbens, a region long-associated with alcohol reward. Mutant mice work harder to obtain ethanol, and are more sensitive to alcohol intoxication. Another spontaneous mutation (P228H) in Gabrb1 also causes high ethanol consumption accompanied by spontaneous GABA ion channel opening and increased accumbal tonic current. Our results provide a new and important link between GABAAR function and increased alcohol consumption that could underlie some forms of alcohol abuse.

Are extrasynaptic GABAA receptors important targets for sedative/hypnotic drugs?

High-affinity extrasynaptic GABA(A) receptors are persistently activated by the low ambient GABA levels that are known to be present in extracellular space. The resulting tonic conductance generates a form of shunting inhibition that is capable of altering cellular and network behavior. It has been suggested that this tonic inhibition will be enhanced by neurosteroids, antiepileptics, and sedative/hypnotic drugs. However, we show that the ability of sedative/hypnotic drugs to enhance tonic inhibition in the mouse cerebellum will critically depend on ambient GABA levels. For example, we show that the intravenous anesthetic propofol enhances tonic inhibition only when ambient GABA levels are <100 nm. More surprisingly, the actions of the sleep-promoting drug 4,5,6,7-tetrahydroisothiazolo-[5,4-c]pyridin-3-ol (THIP) are attenuated at ambient GABA levels of just 20 nm. In contrast, our data suggest that neurosteroid enhancement of tonic inhibition will be greater at high ambient GABA concentrations. We present a model that takes into account realistic estimates of ambient GABA levels and predicted extrasynaptic GABA(A) receptor numbers when considering the ability of sedative/hypnotic drugs to enhance tonic inhibition. These issues will be important when considering drug strategies designed to target extrasynaptic GABA(A) receptors in the treatment of sleep disorders and other neurological conditions.

Profound desensitization by ambient GABA limits activation of δ-containing GABAA receptors during spillover.

High-affinity extrasynaptic GABA(A) receptors (GABA(A)Rs) are a prominent feature of cerebellar granule neurons and thalamic relay neurons. In both cell types, the presence of synaptic glomeruli would be expected to promote activation of these GABA(A)Rs, contributing to phasic spillover-mediated currents and tonic inhibition. However, the precise role of different receptor subtypes in these two phenomena is unclear. To address this question, we made recordings from neurons in acute brain slices from mice, and from tsA201 cells expressing recombinant GABA(A)Rs. We found that δ subunit-containing GABA(A)Rs of both cerebellar granule neurons and thalamic relay neurons of the lateral geniculate nucleus contributed to tonic conductance caused by ambient GABA but not to spillover-mediated currents. In the presence of a low "ambient" GABA concentration, recombinant "extrasynaptic" δ subunit-containing GABA(A)Rs exhibited profound desensitization, rendering them insensitive to brief synaptic- or spillover-like GABA transients. Together, our results demonstrate that phasic spillover and tonic inhibition reflect the activation of distinct receptor populations.

Conserved site for neurosteroid modulation of GABA A receptors.

This study addresses whether the potentiation site for neurosteroids on GABA(A) receptors is conserved amongst different GABA(A) receptor isoforms. The neurosteroid potentiation site was previously identified in the alpha1beta2gamma2S receptor by mutation of Q241 to methionine or leucine, which reduced the potentiation of GABA currents by the naturally occurring neurosteroids, allopregnanolone or tetrahydrodeoxycorticosterone (THDOC). By using heterologous expression of GABA(A) receptors in HEK cells, in combination with whole-cell patch clamp recording methods, a relatively consistent potentiation by allopregnanolone of GABA-activated currents was evident for receptors composed of one alpha subunit isoform (alpha2-5) assembled with beta3 and gamma2S subunits. Using mutant alphabetagamma receptors, the neurosteroid potentiation was universally dependent on the conserved glutamine residue in M1 of the respective alpha subunit. Studying wild-type and mutant receptors composed of alpha4beta3delta subunits revealed that the delta subunit is unlikely to contribute to the neurosteroid potentiation binding site and probably affects the efficacy of potentiation. Thus, in keeping with the ability of neurosteroids to potentiate GABA currents via a broad variety of GABA(A) receptor isoforms in neurons, the potentiation site is structurally highly conserved on this important neurotransmitter receptor family.

Distinct regulation of beta2 and beta3 subunit-containing cerebellar synaptic GABAA receptors by calcium/calmodulin-dependent protein kinase II.

Modulation of GABA(A) receptor function and inhibitory synaptic transmission by phosphorylation has profound consequences for the control of synaptic plasticity and network excitability. We have established that activating alpha-calcium/calmodulin-dependent protein kinase II (alpha-CaMK-II) in cerebellar granule neurons differentially affects populations of IPSCs that correspond to GABA(A) receptors containing different subtypes of beta subunit. By using transgenic mice, we ascertained that alpha-CaMK-II increased IPSC amplitude but not the decay time by acting via beta2 subunit-containing GABA(A) receptors. In contrast, IPSC populations whose decay times were increased by alpha-CaMK-II were most likely mediated by beta3 subunit-containing receptors. Expressing alpha-CaMK-II with mutations that affected kinase function revealed that Ca(2+) and calmodulin binding is crucial for alpha-CaMK-II modulation of GABA(A) receptors, whereas kinase autophosphorylation is not. These findings have significant consequences for understanding the role of synaptic GABA(A) receptor heterogeneity within neurons and the precise regulation of inhibitory transmission by CaMK-II phosphorylation.

Neurosteroid binding sites on GABA(A) receptors.

Controlling neuronal excitability is vitally important for maintaining a healthy central nervous system (CNS) and this relies on the activity of type A gamma-aminobutyric acid (GABA(A)) neurotransmitter receptors. Given this role, it is therefore important to understand how these receptors are regulated by endogenous modulators in the brain and determine where they bind to the receptor. One of the most potent groups of modulators is the neurosteroids which regulate the activity of synaptic and extrasynaptic GABA(A) receptors. This level of regulation is thought to be physiologically important and its dysfunction may be relevant to numerous neurological conditions. The aim of this review is to summarise those studies that over the last 20 years have focussed upon finding the binding sites for neurosteroids on GABA(A) receptors. We consider the nature of steroid binding sites in other proteins where this has been determined at atomic resolution and how their generic features were mapped onto GABA(A) receptors to help locate 2 putative steroid binding sites. Altogether, the findings strongly suggest that neurosteroids do bind to discrete sites on the GABA(A) receptor and that these are located within the transmembrane domains of alpha and beta receptor subunits. The implications for neurosteroid binding to other inhibitory receptors such as glycine and GABA(C) receptors are also considered. Identifying neurosteroid binding sites may enable the precise pathophysiological role(s) of neurosteroids in the CNS to be established for the first time, as well as providing opportunities for the design of novel drug entities.

Identification of the sites for CaMK-II-dependent phosphorylation of GABA(A) receptors.

Phosphorylation can affect both the function and trafficking of GABA(A) receptors with significant consequences for neuronal excitability. Serine/threonine kinases can phosphorylate the intracellular loops between M3-4 of GABA(A) receptor beta and gamma subunits thereby modulating receptor function in heterologous expression systems and in neurons (1, 2). Specifically, CaMK-II has been demonstrated to phosphorylate the M3-4 loop of GABA(A) receptor subunits expressed as GST fusion proteins (3, 4). It also increases the amplitude of GABA(A) receptor-mediated currents in a number of neuronal cell types (5-7). To identify which substrate sites CaMK-II might phosphorylate and the consequent functional effects, we expressed recombinant GABA(A) receptors in NG108-15 cells, which have previously been shown to support CaMK-II modulation of GABA(A) receptors containing the beta3 subunit (8). We now demonstrate that CaMK-II mediates its effects on alpha1beta3 receptors via phosphorylation of Ser(383) within the M3-4 domain of the beta subunit. Ablation of beta3 subunit phosphorylation sites for CaMK-II revealed that for alphabetagamma receptors, CaMK-II has a residual effect on GABA currents that is not mediated by previously identified sites of CaMK-II phosphorylation. This residual effect is abolished by mutation of tyrosine phosphorylation sites, Tyr(365) and Tyr(367), on the gamma2S subunit, and by the tyrosine kinase inhibitor genistein. These results suggested that CaMK-II is capable of directly phosphorylating GABA(A) receptors and activating endogenous tyrosine kinases to phosphorylate the gamma2 subunit in NG108-15 cells. These findings were confirmed in a neuronal environment by expressing recombinant GABA(A) receptors in cerebellar granule neurons.

Endogenous neurosteroids regulate GABAA receptors through two discrete transmembrane sites.

Inhibitory neurotransmission mediated by GABA(A) receptors can be modulated by the endogenous neurosteroids, allopregnanolone and tetrahydro-deoxycorticosterone. Neurosteroids are synthesized de novo in the brain during stress, pregnancyand after ethanol consumption, and disrupted steroid regulation of GABAergic transmission is strongly implicated in several debilitating conditions such as panic disorder, major depression, schizophrenia, alcohol dependence and catamenial epilepsy. Determining how neurosteroids interact with the GABA(A) receptor is a prerequisite for understanding their physiological and pathophysiological roles in the brain. Here we identify two discrete binding sites in the receptor's transmembrane domains that mediate the potentiating and direct activation effects of neurosteroids. They potentiate GABA responses from a cavity formed by the alpha-subunit transmembrane domains, whereas direct receptor activation is initiated by interfacial residues between alpha and beta subunits and is enhanced by steroid binding to the potentiation site. Thus, significant receptor activation by neurosteroids relies on occupancy of both the activation and potentiation sites. These sites are highly conserved throughout the GABA(A )receptor family, and their identification provides a unique opportunity for the development of new therapeutic, neurosteroid-based ligands and transgenic disease models of neurosteroid dysfunction.

Replacement of asparagine with arginine at the extracellular end of the second transmembrane (M2) region of insect GABA receptors increases sensitivity to penicillin G.

The actions of penicillin-G (PCG) on wild-type and mutant Drosophila GABA receptor (RDL) subunits expressed in Xenopus oocytes were studied under two-electrode voltage-clamp. PCG was found to be a non-competitive antagonist of homomeric Drosophila RDL receptors with an IC(50) of 20.41 +/- 1.66 mM at EC(50) GABA. Substitution of a single amino acid (N318R) at the extracellular end of the channel lining region of the RDL subunit increased the potency of GABA approximately four fold, and increased the IC(50) of PCG to 5.09 +/- 0.38 mM. Although the antagonism by PCG on wild-type RDL receptors was independent of membrane potential, PCG action on the N318R mutant showed pronounced voltage-dependency, being much more effective at positive membrane potentials. Thus, in RDL homomers, the replacement of N318 by R318, a residue present at the equivalent position in vertebrate GABA(A) receptors, confers a vertebrate-like PCG pharmacology to the N318R mutant receptor. The A301S mutation that confers resistance to dieldrin did not significantly affect the antagonism by PCG.

Proton modulation of recombinant GABA(A) receptors: influence of GABA concentration and the beta subunit TM2-TM3 domain.

Regulation of GABA(A) receptors by extracellular pH exhibits a dependence on the receptor subunit composition. To date, the molecular mechanism responsible for the modulation of GABA(A) receptors at alkaline pH has remained elusive. We report here that the GABA-activated current can be potentiated at pH 8.4 for both alphabeta and alphabeta gamma subunit-containing receptors, but only at GABA concentrations below the EC40. Site-specific mutagenesis revealed that a single lysine residue, K279 in the beta subunit TM2-TM3 linker, was critically important for alkaline pH to modulate the function of both alpha1beta2 and alpha1beta2 gamma2 receptors. The ability of low concentrations of GABA to reveal different pH titration profiles for GABA(A) receptors was also examined at acidic pH. At pH 6.4, GABA activation of alphabeta gamma receptors was enhanced at low GABA concentrations. This effect was ablated by the mutation H267A in the beta subunit. Decreasing the pH further to 5.4 inhibited GABA responses via alphabeta gamma receptors, whereas those responses recorded from alphabeta receptors were potentiated. Inserting homologous beta subunit residues into the gamma2 subunit to recreate, in alphabeta gamma receptors, the proton modulatory profile of alphabeta receptors, established that in the presence of beta2(H267), the mutation gamma2(T294K) was necessary to potentiate the GABA response at pH 5.4. This residue, T294, is homologous to K279 in the beta subunit and suggests that a lysine at this position is an important residue for mediating the allosteric effects of both acidic and alkaline pH changes, rather than forming a direct site for protonation within the GABA(A) receptor.

Dynamic mobility of functional GABAA receptors at inhibitory synapses.

Importing functional GABAA receptors into synapses is fundamental for establishing and maintaining inhibitory transmission and for controlling neuronal excitability. By introducing a binding site for an irreversible inhibitor into the GABAA receptor alpha1 subunit channel lining region that can be accessed only when the receptor is activated, we have determined the dynamics of receptor mobility between synaptic and extrasynaptic locations in hippocampal pyramidal neurons. We demonstrate that the cell surface GABAA receptor population shows no fast recovery after irreversible inhibition. In contrast, after selective inhibition, the synaptic receptor population rapidly recovers by the import of new functional entities within minutes. The trafficking pathways that promote rapid importation of synaptic receptors do not involve insertion from intracellular pools, but reflect receptor diffusion within the plane of the membrane. This process offers the synapse a rapid mechanism to replenish functional GABAA receptors at inhibitory synapses and a means to control synaptic efficacy.

Zn2+ ions: modulators of excitatory and inhibitory synaptic activity.

The role of Zn(2+) in the CNS has remained enigmatic for several decades. This divalent cation is accumulated by specific neurons into synaptic vesicles and can be released by stimulation in a Ca(2+)-dependent manner. Using Zn(2+) fluorophores, radiolabeled Zn(2+), and selective chelators, the location of this ion and its release pattern have been established across the brain. Given the distribution and possible release under physiological conditions, Zn(2+) has the potential to act as a modulator of both excitatory and inhibitory neurotransmission. Excitatory N-methyl-D-aspartate (NMDA) receptors are directly inhibited by Zn(2+), whereas non-NMDA receptors appear relatively unaffected. In contrast, inhibitory transmission mediated via GABA(A)receptors can be potentiated via a presynaptic mechanism, influencing transmitter release; however, although some tonic GABAergic inhibition may be suppressed by Zn(2+), most synaptic GABA receptors are unlikely to be modulated directly by this cation. In the spinal cord, glycinergic transmission may also be affected by Zn(2+) causing potentiation. Recently, the penetration of synaptically released Zn(2+) into neurons suggests that this ion has the potential to act as a direct transmitter, by affecting postsynaptic signaling pathways. Taken overall, present studies are broadly supportive of a neuromodulatory role for Zn(2+) at specific excitatory and inhibitory synapses.

Zinc-mediated inhibition of GABA(A) receptors: discrete binding sites underlie subtype specificity.

Zinc ions are concentrated in the central nervous system and regulate GABA(A) receptors, which are pivotal mediators of inhibitory synaptic neurotransmission. Zinc ions inhibit GABA(A) receptor function by an allosteric mechanism that is critically dependent on the receptor subunit composition: alphabeta subunit combinations show the highest sensitivity, and alphabetagamma isoforms are the least sensitive. Here we propose a mechanistic and structural basis for this inhibition and its dependence on the receptor subunit composition. We used molecular modeling to identify three discrete sites that mediate Zn2+ inhibition. One is located within the ion channel, and the other two are on the external amino (N)-terminal face of the receptor at the interfaces between alpha and beta subunits. We found that the characteristically low Zn2+ sensitivity of GABA(A) receptors containing the gamma2 subunit results from disruption to two of the three sites after receptor subunit co-assembly.

An N-terminal histidine regulates Zn(2+) inhibition on the murine GABA(A) receptor beta3 subunit.

1. Whole-cell currents were recorded from Xenopus laevis oocytes and human embryonic kidney cells expressing GABA(A) receptor beta3 subunit homomers to search for additional residues affecting Zn(2+) inhibition. These residues would complement the previously identified histidine (H267), present just within the external portal of the ion channel, which modulates Zn(2+) inhibition. 2. Zinc inhibited the pentobarbitone-gated current on beta3(H267A) homomers at pH 7.4, but this effect was abolished at pH 5.4. The Zn(2+)-sensitive spontaneous beta3 subunit-mediated conductance was also insensitive to block by Zn(2+) at pH 5.4. 3. Changing external pH enabled the titration of the Zn(2+) sensitive binding site or signal transduction domain. The pK(a) was estimated at 6.8 +/- 0.03 implying the involvement of histidine residues. 4. External histidine residues in the beta3 receptor subunit were substituted with alanine, in addition to the background mutation, H267A, to assess their sensitivity to Zn(2+) inhibition. The Zn(2+) IC(50) was unaffected by either the H119A or H191A mutations. 5. The remaining histidine, H107, the only other candidate likely to participate in Zn(2+) inhibition, was substituted with various residues. Most mutants were expressed at the cell surface but they disrupted functional expression of beta3 homomers. However, H107G was functional and demonstrated a marked reduction in sensitivity to Zn(2+). 6. GABA(A) receptor beta3 subunits form functional ion channels that can be inhibited by Zn(2+). Two histidine residues are largely responsible for this effect, H267 in the pore lining region and H107 residing in the extracellular N-terminal domain.

Identification of a beta subunit TM2 residue mediating proton modulation of GABA type A receptors.

GABA type A (GABA(A)) receptors are functionally regulated by external protons in a manner dependent on the receptor subunit composition. Although H(+) can regulate the open probability of single GABA ion channels, exactly what residues and receptor subunits are responsible for proton-induced modulation remain unknown. This study resolves this issue by using recombinant alpha1betai subunit GABA(A) receptors expressed in human embryonic kidney cells. The potentiating effect of low external pH on GABA responses exhibited p(Ka) in accord with the involvement of histidine and/or cysteine residues. The exposure of GABA(A) receptors to the histidine-modifying reagent DEPC ablated regulation by H(+), implicating the involvement of histidine residues rather than cysteines in proton regulation. Site-specific substitution of all conserved external histidines to alanine on the beta subunits revealed that H267 alone, in the TM2 domain, is important for H(+) regulation. These results are interpreted as a direct protonation of H267 on alpha1betai receptors rather than an involvement in signal transduction. The opposing functional effects induced by Zn(2+) and H(+) at this single histidine residue most likely reflect differences in charge delocalization on the imidazole rings in the mouth of the GABA(A) receptor ion channel. Additional substitutions of H267 in beta subunits with other residues possessing charged side chains (glutamate and lysine) reveal that this area of the ion channel can profoundly influence the functional properties of GABA(A) receptors.