The ubiquitin-like protein Plic-1 enhances the membrane insertion of GABAA receptors by increasing their stability within the endoplasmic reticulum

Gamma-aminobutyric acid receptors (GABA(A)R) are the major sites of fast inhibitory neurotransmission in the brain, and a critical determinant for the efficacy of neuronal inhibition is the number of these receptors that are expressed on the neuronal cell surface. GABA(A)Rs are heteropentamers that can be constructed from seven subunit classes with multiple members; alpha, beta, gamma(1-3), delta, epsilon(1-3), theta, and pi. Receptor assembly occurs within the endoplasmic reticulum, and it is evident that transport-competent combinations exiting this organelle can access the cell surface, whereas unassembled subunits are ubiquitinated and subject to proteasomal degradation. In a previous report the ubiquitin-like protein Plic-1 was shown to directly interact with GABA(A)Rs and promote their accumulation at the cell surface. In this study we explore the mechanisms by which Plic-1 regulates the membrane trafficking of GABA(A)Rs. Using both recombinant and neuronal preparations it was apparent that Plic-1 increased the stability of endoplasmic reticulum resident GABA(A)Rs together with an increase in the abundance of poly-ubiquitinated receptor subunits. Furthermore, Plic-1 elevated cell surface expression levels by selectively increasing their rates of membrane insertion. Thus, Plic-1 may play a significant role in regulating the strength of synaptic inhibition by increasing the stability of GABA(A)Rs within the secretory pathway and thereby promoting their insertion into the neuronal plasma membrane.     

Two pools of Triton X-100-insoluble GABA(A) receptors are present in the brain, one associated to lipid rafts and another one to the post-synaptic GABAergic complex

Rat forebrain synaptosomes were extracted with Triton X-100 at 4 degrees C and the insoluble material, which is enriched in post-synaptic densities (PSDs), was subjected to sedimentation on a continuous sucrose gradient. Two pools of Triton X-100-insoluble gamma-aminobutyric acid type-A receptors (GABA(A)Rs) were identified: (i) a higher-density pool (rho = 1.10-1.15 mg/mL) of GABA(A)Rs that contains the gamma2 subunit (plus alpha and beta subunits) and that is associated to gephyrin and the GABAergic post-synaptic complex and (ii) a lower-density pool (rho = 1.06-1.09 mg/mL) of GABA(A)Rs associated to detergent-resistant membranes (DRMs) that contain alpha and beta subunits but not the gamma2 subunit. Some of these GABA(A)Rs contain the delta subunit. Two pools of GABA(A)Rs insoluble in Triton X-100 at 4 degrees C were also identified in cultured hippocampal neurons: (i) a GABA(A)R pool that forms clusters that co-localize with gephyrin and remains Triton X-100-insoluble after cholesterol depletion and (ii) a GABA(A)R pool that is diffusely distributed at the neuronal surface that can be induced to form GABA(A)R clusters by capping with an anti-alpha1 GABA(A)R subunit antibody and that becomes solubilized in Triton X-100 at 4 degrees C after cholesterol depletion. Thus, there is a pool of GABA(A)Rs associated to lipid rafts that is non-synaptic and that has a subunit composition different from that of the synaptic GABA(A)Rs. Some of the lipid raft-associated GABA(A)Rs might be involved in tonic inhibition.     

Cell surface stability of gamma-aminobutyric acid type A receptors. Dependence on protein kinase C activity and subunit composition

Type A gamma-aminobutyric acid receptors (GABA(A)), the major sites of fast synaptic inhibition in the brain, are believed to be composed predominantly of alpha, beta, and gamma subunits. Although cell surface expression is essential for GABA(A) receptor function, little is known regarding its regulation. To address this issue, the membrane stability of recombinant alpha(1)beta(2) or alpha(1)beta(2)gamma(2) receptors was analyzed in human embryonic kidney cells. Alpha(1)beta(2)gamma(2) but not alpha(1)beta(2) receptors were found to recycle constitutively between the cell surface and a microtubule-dependent, perinuclear endosomal compartment. Similar GABA(A) receptor endocytosis was also seen in cultured hippocampal and cortical neurons. GABA(A) receptor surface levels were reduced upon protein kinase C (PKC) activation. Like basal endocytosis, this response required the gamma(2) subunit but not receptor phosphorylation. Although inhibiting PKC activity did not block alpha(1)beta(2)gamma(2) receptor endocytosis, it did prevent receptor down-regulation, suggesting that PKC activity may block alpha(1)beta(2)gamma(2) receptor recycling to the cell surface. In agreement with this observation, blocking recycling from endosomes with wortmannin selectively reduced surface levels of gamma(2)-containing receptors. Together, our results demonstrate that the surface stability of GABA(A) receptors can be dynamically and specifically regulated, enabling neurons to modulate cell surface receptor number upon the appropriate cues.     

Identification of amino acid residues important for assembly of GABA receptor alpha1 and gamma2 subunits

Comparative models of GABA(A) receptors composed of alpha1 beta3 gamma2 subunits were generated using the acetylcholine-binding protein (AChBP) as a template and were used for predicting putative engineered cross-link sites between the alpha1 and the gamma2 subunit. The respective amino acid residues were substituted by cysteines and disulfide bond formation between subunits was investigated on co-transfection into human embryonic kidney (HEK) cells. Although disulfide bond formation between subunits could not be observed, results indicated that mutations studied influenced assembly of GABA(A) receptors. Whereas residue alpha1A108 was important for the formation of assembly intermediates with beta3 and gamma2 subunits consistent with its proposed location at the alpha1(+) side of GABA(A) receptors, residues gamma2T125 and gamma2P127 were important for assembly with beta3 subunits. Mutation of each of these residues also caused an impaired expression of receptors at the cell surface. In contrast, mutated residues alpha1F99C, alpha1S106C or gamma2T126C only impaired the formation of receptors at the cell surface when co-expressed with subunits in which their predicted interaction partner was also mutated. These data are consistent with the prediction that the mutated residue pairs are located close to each other.     

Agonist-dependent single channel current and gating in alpha4beta2delta and alpha1beta2gamma2S GABAA receptors

The family of gamma-aminobutyric acid type A receptors (GABA(A)Rs) mediates two types of inhibition in the mammalian brain. Phasic inhibition is mediated by synaptic GABA(A)Rs that are mainly comprised of alpha(1), beta(2), and gamma(2) subunits, whereas tonic inhibition is mediated by extrasynaptic GABA(A)Rs comprised of alpha(4/6), beta(2), and delta subunits. We investigated the activation properties of recombinant alpha(4)beta(2)delta and alpha(1)beta(2)gamma(2S) GABA(A)Rs in response to GABA and 4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridin-3(2H)-one (THIP) using electrophysiological recordings from outside-out membrane patches. Rapid agonist application experiments indicated that THIP produced faster opening rates at alpha(4)beta(2)delta GABA(A)Rs (beta approximately 1600 s(-1)) than at alpha(1)beta(2)gamma(2S) GABA(A)Rs (beta approximately 460 s(-1)), whereas GABA activated alpha(1)beta(2)gamma(2S) GABA(A)Rs more rapidly (beta approximately 1800 s(-1)) than alpha(4)beta(2)delta GABA(A)Rs (beta < 440 s(-1)). Single channel recordings of alpha(1)beta(2)gamma(2S) and alpha(4)beta(2)delta GABA(A)Rs showed that both channels open to a main conductance state of approximately 25 pS at -70 mV when activated by GABA and low concentrations of THIP, whereas saturating concentrations of THIP elicited approximately 36 pS openings at both channels. Saturating concentrations of GABA elicited brief (<10 ms) openings with low intraburst open probability (P(O) approximately 0.3) at alpha(4)beta(2)delta GABA(A)Rs and at least two "modes" of single channel bursting activity, lasting approximately 100 ms at alpha(1)beta(2)gamma(2S) GABA(A)Rs. The most prevalent bursting mode had a P(O) of approximately 0.7 and was described by a reaction scheme with three open and three shut states, whereas the "high" P(O) mode ( approximately 0.9) was characterized by two shut and three open states. Single channel activity elicited by THIP in alpha(4)beta(2)delta and alpha(1)beta(2)gamma(2S) GABA(A)Rs occurred as a single population of bursts (P(O) approximately 0.4-0.5) of moderate duration (approximately 33 ms) that could be described by schemes containing two shut and two open states for both GABA(A)Rs. Our data identify kinetic properties that are receptor-subtype specific and others that are agonist specific, including unitary conductance.     

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.     

Gel-based mass spectrometric analysis of recombinant GABA(A) receptor subunits representing strongly hydrophobic transmembrane proteins

GABA(A) receptors are the major inhibitory transmitter receptors in mammalian brain and are composed of several protein subunits that can belong to different subunit classes, leading to enormous heterogeneity. To establish techniques for the analysis of GABA(A) receptors in complex mixtures such as brain tissue, recombinant receptors composed of alpha1 and His-tagged beta3 subunits expressed in insect cells were purified by affinity chromatography and run on blue native gels. After denaturing, receptors were subjected to one- or two-dimensional electrophoresis in SDS-gels. Proteins were cleaved by multienzyme proteolysis and subjected to nano-ESI-LC-MS/MS. Both GABA(A) receptor subunits were well-separated and unambiguously identified by sequence coverage of 99.1% (alpha1) and 92.9% (beta3).     

Closed-state cross-linking of adjacent beta1 subunits in alpha1beta1 GABAa receptors via introduced 6' cysteines

The pore structural changes associated with Cys-loop receptor gating are currently the subject of considerable interest. Several functional approaches have shown that surface exposure of pore-lining side chains does not change significantly during activation. However, a disulfide trapping study on alpha1(T6'C)beta1(T6'C) gamma-aminobutyric acid type A (GABA(A)) receptors (GABA(A)Rs), which showed that adjacent beta subunits cross-link in the open state only, concluded that channel gating is mediated by beta subunits contra-rotating through a summed angle of approximately 120 degrees. Such a large rotation is not easily reconciled with other evidence. The present study initially sought to investigate an observation that appeared inconsistent with the rotation model: namely that alpha1(T6'C)beta1(T6'C) GABA(A)Rs expressed in HEK293 cells form 6' cysteine-mediated disulfide bonds in the closed state. On the basis of electrophysiological and Western blotting experiments, we conclude that adjacent beta(T6'C) subunits dimerise efficiently in the closed state via cross-links between their respective 6' cysteines and that this locks the channels closed. This questions the beta subunit contra-rotation model of activation and raises the question of how the closed state cross-links form. We propose that beta subunit 6' cysteines move into sufficiently close proximity for disulfide formation via relatively large amplitude random thermal motions that appear to be a unique feature of beta subunits. Because dimerized channels are locked closed, we conclude either that the spontaneous beta subunit movements or asymmetries in the movements of adjacent beta subunits during activation are essential for pore opening. Our results identify a novel feature of GABA(A)R gating that may be important for understanding its activation mechanism.     

Intracellular trafficking of GABA(A) receptors

Some of the mechanisms that control the intracellular trafficking of GABA(A) receptors have recently been described. Following the synthesis of alpha, beta, and gamma subunits in the endoplasmic reticulum, ternary receptor complexes assemble slowly and are inefficiently inserted into surface membranes of heterologous cells. While beta3, beta4, and gamma2S subunits appear to contain polypeptide sequences that alone are sufficient for surface targeting, these sequences are neither conserved nor essential for surface expression of heteromeric GABA(A) receptors formed from alpha1beta or alpha1betagamma subunits. At the neuronal surface, native GABA(A) receptor clustering and synaptic targeting require a gamma2 subunit and the participation of gephyrin, a clustering protein for glycine receptors. A linker protein, such as the GABA(A) receptor associated protein (GABARAP), may be necessary for the formation of GABA(A) receptor aggregates containing gephyrin. A substantial fraction of surface receptors are sequestered by endocytosis, another process which apparently requires a GABA(A) receptor gamma2 subunit. In heterologous cells, constitutive endocytosis seems to predominate while, in cortical neurons, internalization is evoked when receptors are occupied by GABA(A) agonists. After constitutive endocytosis, receptors are relatively stable and can be rapidly recycled to the cell surface, a process that may be regulated by protein kinase C. On the other hand, a portion of the intracellular GABA(A) receptors derived from ligand-dependent endocytosis is apparently degraded. The clustering of GABA(A) receptors at synapses and at coated pits are two mechanisms that may compete for a pool of diffusable receptors, providing a model for plasticity at inhibitory synapses.     

GABAA receptor associated proteins: a key factor regulating GABAA receptor function

gamma-Aminobutyric acid (GABA), an important inhibitory neurotransmitter in both vertebrates and invertebrates, acts on GABA receptors that are ubiquitously expressed in the CNS. GABA(A) receptors also represent a major site of action of clinically relevant drugs, such as benzodiazepines, barbiturates, ethanol, and general anesthetics. It has been shown that the intracellular M3-M4 loop of GABA(A) receptors plays an important role in regulating GABA(A) receptor function. Therefore, studies of the function of receptor intracellular loop associated proteins become important for understanding mechanisms of regulating receptor activity. Recently, several labs have used the yeast two-hybrid assay to identify proteins interacting with GABA(A) receptors, for example, the interaction of GABA(A) receptor associated protein (GABARAP) and Golgi-specific DHHC zinc finger protein (GODZ) with gamma subunits, PRIP, phospholipase C-related, catalytically inactive proteins (PRIP-1) and (PRIP-2) with GABARAP and receptor gamma2 and beta subunits, Plic-1 with some alpha and beta subunits, radixin with the alpha5 subunit, HAP1 with the beta1 subunit, GABA(A) receptor interacting factor-1 (GRIF-1) with the beta2 subunit, and brefeldin A-inhibited GDP/GTP exchange factor 2 (BIG2) with the beta3 subunit. These proteins have been shown to play important roles in modulating the activities of GABA(A) receptors ranging from enhancing trafficking, to stabilizing surface and internalized receptors, to regulating modification of GABA(A) receptors. This article reviews the current studies of GABA(A) receptor intracellular loop-associated proteins.     

Mechanisms involved in the reduction of GABAA receptor alpha1-subunit expression caused by the epilepsy mutation A322D in the trafficking-competent receptor

A mutation in the alpha1-subunit (A322D) of GABA(A)Rs is responsible for juvenile myoclonic epilepsy in a large Canadian family. Previous work has identified that this mutant affects the cell expression and function of recombinant GABA(A)Rs, expressed in HEK293 cells. Here we have extended these observations by showing that the mutation promotes association with the endoplasmic reticulum chaperone calnexin and accelerates the degradation rate of the subunits approximately 2.5-fold. We also find that the mutation causes the subunit to be degraded largely by a lysosomal-dependent process. Furthermore, we find that the mutation results in receptors that are inserted into the plasma membrane but are more rapidly endocytosed by a dynamin and caveolin1-dependent mechanism. These results suggest that the mutant subunit can form functional receptors, but that these have a shorter lifetime on the plasma membrane.     

Antisense suppression of GABA(A) receptor beta subunit levels in cultured cerebellar granule neurons demonstrates their importance in receptor expression

GABA(A) receptors in the CNS are pentameric molecules composed of alpha, beta, gamma, delta, epsilon and theta subunits. Studies on transfected cells have shown that GABA(A) receptor beta subunit isoforms can direct alpha1 subunit localization within the cell. To examine the role of selected subunits in governing GABA(A) receptor expression in neurons, cultures of rat cerebellar granule cells were grown with antisense or sense oligodeoxynucleotides (ODNs) specific for the alpha 1, beta 2 or gamma 2 subunits. These subunits are all expressed in granule neurons where they are thought to contribute to an abundant receptor type. Following ODN treatment, subunit expression and distribution were examined by western blotting, immunocytochemistry and RT-PCR. Treatment of the cultures with the antisense, but not the corresponding sense, ODNs reduced the levels of the targeted subunit polypeptides. In addition, the beta 2 antisense ODN reduced the level of the alpha1 subunit polypeptide without altering the level of its mRNA. In contrast, treatment with the beta 2 subunit antisense ODN did not alter gamma 2 subunit polypeptide expression, distribution or mRNA level. These findings suggest that the alpha1 subunit requires a beta subunit for assembly into GABA(A) receptors in cerebellar granule neurons.     

Identification of subunits mediating clustering of GABA(A) receptors by rapsyn.

Human embryonic kidney 293 cells transfected with alpha1beta1gamma2, alpha1beta2gamma2, alpha1beta3gamma2, alpha1beta1, alpha1beta2, alpha1beta3, beta3gamma2, or beta3 subunits formed gamma-aminobutyric acidA receptors on the cell surface that could be clustered by rapsyn. In contrast, alpha1, beta1, beta2, or gamma2 subunits, or alpha1gamma2 subunit combinations could not be detected on the surface of transfected cells and could not be clustered by rapsyn. Experiments investigating the ability of rapsyn to cluster chimeras consisting of the N-terminus of the beta3 subunit and the remaining part of the alpha1, beta2 or gamma2 subunits indicated that the intracellular domains of beta1, beta2, beta3 or gamma2 subunits, but not those of alpha1 subunits are able to form sites mediating clustering by rapsyn. These results demonstrate that rapsyn has the potential to cluster the majority of GABA(A) receptor subtypes via beta or gamma2 subunits. Further experiments will have to clarify the physiological importance of this observation.     

Alcohol effects on gamma-aminobutyric acid type A receptors: are extrasynaptic receptors the answer?

GABA(A) receptors have long been implicated in mediating at least part of the actions of ethanol in mammalian brain. However, until very recently, reports of the actions of EtOH on recombinant receptors have required very high doses of ethanol and animals lacking receptor subunits shown to be important for ethanol actions in vitro did not support the view that these subunits are crucial in ethanol actions. Recombinant alpha4beta3delta and alpha6beta3delta GABA(A) receptors are uniquely sensitive to ethanol, with a dose-response relationship mirroring the well known effects of alcohol consumption on the human brain. Receptors containing the delta subunit are thought to be located extrasynaptically and it will be important to determine if these extrasynaptic GABA(A) receptor subunit combinations mediate low dose alcohol effects in vivo.     

Endoplasmic reticulum retention and associated degradation of a GABAA receptor epilepsy mutation that inserts an aspartate in the M3 transmembrane segment of the alpha1 subunit

A GABA(A) receptor alpha1 subunit epilepsy mutation (alpha1(A322D)) introduces a negatively charged aspartate residue into the hydrophobic M3 transmembrane domain of the alpha1 subunit. We reported previously that heterologous expression of alpha1(A322D)beta2gamma2 receptors in mammalian cells resulted in reduced total and surface alpha1 subunit protein. Here we demonstrate the mechanism of this reduction. Total alpha1(A322D) subunit protein was reduced relative to wild type protein by a similar amount when expressed alone (86 +/- 6%) or when coexpressed with beta2 and gamma2S subunits (78 +/- 6%), indicating an expression reduction prior to subunit oligomerization. In alpha1beta2gamma2S receptors, endoglycosidase H deglycosylated only 26 +/- 5% of alpha1 subunits, consistent with substantial protein maturation, but in alpha1(A322D)beta2gamma2S receptors, endoglycosidase H deglycosylated 91 +/- 4% of alpha1(A322D) subunits, consistent with failure of protein maturation. To determine the cellular localization of wild type and mutant subunits, the alpha1 subunit was tagged with yellow (alpha1-YFP) or cyan (alpha1-CFP) fluorescent protein. Confocal microscopic imaging demonstrated that 36 +/- 4% of alpha1-YFPbeta2gamma2 but only 5 +/- 1% alpha1(A322D)-YFPbeta2gamma2 colocalized with the plasma membrane, whereas the majority of the remaining receptors colocalized with the endoplasmic reticulum (55 +/- 4% alpha1-YFPbeta2gamma2S, 86 +/- 3% alpha1(A322D)-YFP). Heterozygous expression of alpha1-CFPbeta2gamma2S and alpha1(A322D)-YFPbeta2gamma2S or alpha1-YFPbeta2gamma2S and alpha1(A322D)-CFPbeta2gamma2S receptors showed that membrane GABA(A) receptors contained primarily wild type alpha1 subunits. These data demonstrate that the A322D mutation reduces alpha1 subunit expression after translation, but before assembly, resulting in endoplasmic reticulum-associated degradation and membrane alpha1 subunits that are almost exclusively wild type subunits.     

Spontaneous cross-link of mutated alpha1 subunits during GABA(A) receptor assembly

gamma-Aminobutyric acid, type A (GABA(A)) receptor alpha1 subunits containing a cysteine mutation at a position in the channel mouth (H109C) surprisingly formed a spontaneous cross-link with each other in receptors composed of alpha1H109C, beta3, and gamma2 subunits. Cross-linking of two alpha1H109C subunits did not significantly change the affinity of [(3)H]muscimol or [(3)H]Ro15-1788 binding in alpha1H109Cbeta3gamma2 receptors, but GABA displayed a reduced potency for activating chloride currents. On reduction of the disulfide bond, however, GABA activation as well as diazepam modulation was similar in mutated and wild-type receptors, suggesting that these receptors exhibited the same subunit stoichiometry and arrangement. Disulfide bonds could not be reoxidized by copper phenanthroline after having been reduced in completely assembled receptors, suggesting that cross-linking can only occur at an early stage of assembly. The cross-link of alpha1H109C subunits and the subsequent transport of the resulting homodimers to the cell surface caused a reduction of the intracellular pool of alpha1H109C subunits and a reduced formation of completely assembled receptors. The formation of alpha1H109C homodimers as well as of correctly assembled GABA(A) receptors containing cross-linked alpha1H109C subunits could indicate that homodimerization of alpha1 subunits via contacts located in the channel mouth might be one starting point of GABA(A) receptor assembly. Alternatively the assembly mechanism might have started with the formation of heterodimers followed by a cross-link of mutated alpha1 subunits at the heterotrimeric stage. The formation of cross-linked alpha1H109C homodimers would then have occurred independently in a separate pathway.     

Identification of an amino acid sequence within GABA(A) receptor beta3 subunits that is important for receptor assembly

GABA(A) receptors are chloride ion channels that can be opened by GABA, the most important inhibitory transmitter in the CNS. In the mammalian brain the majority of these pentameric receptors is composed of two alpha, two beta and one gamma subunit. To achieve the correct order of subunits around the pore, each subunit must form specific contacts via its plus (+) and minus (-) side. To identify a sequence on the beta3 subunit important for assembly, we generated various full-length or truncated chimeric beta3 constructs and investigated their ability to assemble with alpha1 and gamma2 subunits. It was demonstrated that replacement of the sequence beta3(76-89) by the homologous alpha1 sequence impaired assembly with alpha1 but not with gamma2 subunits in alpha1beta3gamma2-GABA(A) receptors. Other experiments indicated that assembly was impaired via the beta3(-) side of the chimeric subunit. Within the sequence beta3(76-89) the sequence beta3(85-89) seemed to be of primary importance for assembly with alpha1 subunits. A comparison with the structure of the acetylcholine-binding protein supports the conclusion that the sequence beta3(85-89) is located at the beta3(-) side and indicates that it contains amino acid residues that might directly interact with the (+) side of the neighbouring alpha1 subunit.     

Enhanced behavioral sensitivity to the competitive GABA agonist, gaboxadol, in transgenic mice over-expressing hippocampal extrasynaptic alpha6beta GABA(A) receptors

The behavioral and functional significance of the extrasynaptic inhibitory GABA(A) receptors in the brain is still poorly known. We used a transgenic mouse line expressing the GABA(A) receptor alpha6 subunit gene in the forebrain under the Thy-1.2 promoter (Thy1alpha6) mice ectopically expressing alpha6 subunits especially in the hippocampus to study how extrasynaptically enriched alphabeta(gamma2)-type receptors alter animal behavior and receptor responses. In these mice extrasynaptic alpha6beta receptors make up about 10% of the hippocampal GABA(A) receptors resulting in imbalance between synaptic and extrasynaptic inhibition. The synthetic GABA-site competitive agonist gaboxadol (4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridin-3-ol; 3 mg/kg) induced remarkable anxiolytic-like response in the light : dark exploration and elevated plus-maze tests in Thy1alpha6 mice, while being almost inactive in wild-type mice. The transgenic mice also lost quicker and for longer time their righting reflex after 25 mg/kg gaboxadol than wild-type mice. In hippocampal sections of Thy1alpha6 mice, the alpha6beta receptors could be visualized autoradiographically by interactions between gaboxadol and GABA via [(35)S]TBPS binding to the GABA(A) receptor ionophore. Gaboxadol inhibition of the binding could be partially prevented by GABA. Electrophysiology of recombinant GABA(A) receptors revealed that GABA was a partial agonist at alpha6beta3 and alpha6beta3delta receptors, but a full agonist at alpha6beta3gamma2 receptors when compared with gaboxadol. The results suggest strong behavioral effects via selective pharmacological activation of enriched extrasynaptic alphabeta GABA(A) receptors, and the mouse model represents an example of the functional consequences of altered balance between extrasynaptic and synaptic inhibition.