Expression of GABA Receptor ρ Subunits in Rat Brain

Abstract: The GABA receptor ρ1, ρ2, and ρ3 subunits are expressed in the retina where they form bicuculline-insensitive GABA_C receptors. We used northern blot, in situ hybridization, and RT-PCR analysis to study the expression of ρ subunits in rat brains. In situ hybridization allowed us to detect ρ-subunit expression in the superficial gray layer of the superior colliculus and in the cerebellar Purkinje cells. RT-PCR experiments indicated that (a) in retina and in domains that may contain functional GABA_C receptors, ρ2 and ρ1 subunits are expressed at similar levels; and (b) in domains and in tissues that are unlikely to contain GABA_C receptors, ρ2 mRNA is enriched relative to ρ1 mRNA. These results suggest that both ρ1 and ρ2 subunits are necessary to form a functional GABA_C receptor. The use of RT-PCR also showed that, except in the superior colliculus, ρ3 is expressed along with ρ1 and ρ2 subunits. We also raised an antibody against a peptide sequence unique to the ρ1 subunit. The use of this antibody on cerebellum revealed the rat ρ1 subunit in the soma and dendrites of Purkinje neurons. The allocation of GABA_C receptor subunits to identified neurons paves the way for future electrophysiological studies.     

The α5(H105R) mutation impairs α5 selective binding properties by altered positioning of the α5 subunit in GABAA receptors containing two distinct types of α subunits

GABA_A receptors are pentameric ligand-gated ion channels that are major mediators of fast inhibitory neurotransmission. Clinically relevant GABA_A receptor subtypes are assembled from α5(1-3, 5), β1-3 and the γ2 subunit. They exhibit a stoichiometry of two α, two β and one γ subunit, with two GABA binding sites located at the α/β and one benzodiazepine binding site located at the α/γ subunit interface. Introduction of the H105R point mutation into the α5 subunit, to render α5 subunit-containing receptors insensitive to the clinically important benzodiazepine site agonist diazepam, unexpectedly resulted in a reduced level of α5 subunit protein in α5(H105R) mice. In this study, we show that the α5(H105R) mutation did not affect cell surface expression and targeting of the receptors or their assembly into macromolecular receptor complexes but resulted in a severe reduction of α5-selective ligand binding. Immunoprecipitation studies suggest that the diminished α5-selective binding is presumably due to a repositioning of the α5(H105R) subunit in GABA_A receptor complexes containing two different α subunits. These findings imply an important role of histidine 105 in determining the position of the α5 subunit within the receptor complex by determining the affinity for assembly with the γ2 subunit.     

Molecular Determinants of General Anesthetic Action: Role of GABAA Receptor Structure

Abstract: Using receptors expressed from mouse brain mRNA in Xenopus oocytes, we found that enhancement of type A γ-aminobutyric acid (GABA_A) receptor-gated Cl⁻ channel response is a common action of structurally diverse anesthetics, suggesting that the GABA_A receptor plays an important role in anesthesia. To determine if GABA_A receptor subunit composition influences actions of anesthetics, we expressed subunit cRNAs in Xenopus oocytes and measured effects of enflurane on GABA-activated Cl⁻ currents. Potentiation of GABA-activated currents by enflurane was dependent on the composition of GABA_A receptor protein subunits; the order of sensitivity was α₁β₁ > α₁β₁γ_2s=α₁β₁γ_2L > total mRNA. The results suggest that anesthetics with simple structures may act on the GABA_A receptor protein complex to modulate the Cl⁻ channel activity and provide a molecular explanation for the synergistic clinical interactions between benzodiazepines and general anesthetics.     

The Subunit Composition of a GABAA/Benzodiazepine Receptor from Rat Cerebellum

Abstract: The pentameric subunit composition of a large population (36%) of the cerebellar granule cell GABA_A receptors that show diazepam (or clonazepam)-insensitive [³H]Ro 15-4513 binding has been determined by immunoprecipitation with subunit-specific antibodies. These receptors have α₆, α₁, γ_2S, γ_2L, and β₂ or β₃ subunits colocalizing in the same receptor complex.     

Evidence that GABAA Receptor Subunit mRNA Expression During Development Is Regulated by GABAA Receptor Stimulation

Abstract: The expression of six mRNA species (α2, α3, α5, β2, β3, and γ2) encoding for GABA_A receptor subunits was followed in cultured early postnatal cortical neurons by in situ hybridization histochemistry. In untreated control cultures it was found that these subunit mRNA expression profiles closely follow those seen during development in vivo. α3, α5, and β3 subunit expression declined, α2 expression increased, whereas β2 and γ2 subunit mRNA expression remained relatively constant. To test the hypothesis that GABA_A receptor stimulation regulates these expression profiles, we tested the effect of a GABA_A receptor positive modulator, allopregnanolone, and a GABA_A receptor noncompetitive antagonist, tert -butylbicyclophosphorothionate (TBPS). It was found that allopregnanolone augmented the rate at which the α3, α5, or β3 subunit mRNA expression declined and prevented the increase in α2 subunit mRNA expression. As well, allopregnanolone down-regulated β2 subunit mRNA expression. TBPS, on the other hand, up-regulated α3, α5, β2, and β3 subunit mRNA expression. It also down-regulated the expression of α2 subunit mRNA. Both allopregnanolone and TBPS had no effect on γ2 subunit mRNA expression. These results imply that the developmental switchover of GABA receptor subunit mRNA expression is regulated by GABA_A receptor activity.     

Levels of Benzodiazepine Receptor Subtypes and GABAA Receptor α-Subunit mRNA Do Not Correlate During Development

Abstract: Developmental changes in the pharmacological properties of the GABA_A receptor have been suggested to result from changes in the subunit composition of the receptor complex. The nicotinic acetylcholine receptor is structurally related to the GABA_A receptor and undergoes a developmental subunit switch at the neuromuscular synapse. To examine the mechanistic similarities between these systems we sought to find whether the changes in GABA_A receptor subunits are controlled by changes in messenger RNA levels, as they are for the nicotinic acetylcholine receptor. We found a 10-fold increase in the level of α1-subunit mRNA, and a small increase in levels of GABA_A/benzodiazepine receptors from day 1 to day 24 of rat cerebellar development. We also found that the levels of α1-subunit mRNA were higher than the levels of mRNA encoding other α subunits at all developmental time points. The low levels of messenger RNA for α2, α3, and α5 subunits are inconsistent with the high levels of type II benzodiazepine binding in the rat cerebellum at birth because these α subunits have been shown to form GABA_A receptors with type II benzodiazepine binding. These findings are inconsistent with simple models that would explain the developmental differences in GABA_A receptor pharmacology simply as a result of changes in α-subunit gene expression.     

Distinct Loci Mediate the Direct and Indirect Actions of the Anesthetic Etomidate at GABAA Receptors

Abstract: Most general anesthetics produce two distinct actions at GABA_A receptors. Thus, these drugs augment GABA-gated chloride currents (referred to as an indirect action) and, at higher concentrations, elicit chloride currents in the absence of GABA (referred to as a direct action). Because a β subunit appears to be required for the direct action of intravenous anesthetics in recombinant GABA_A receptors, site-directed mutagenesis of the β3 subunit was performed to identify amino acid residues that are critical for this action. In HEK293 cells expressing a prototypical GABA_A receptor composed of α1β3γ2 subunits, mutation of amino acid 290 from Asn to Ser dramatically reduced both etomidate-induced chloride currents and its ability to stimulate [³H]flunitrazepam binding. By contrast, the ability of etomidate to augment GABA-gated chloride currents and GABA-enhanced [³H]flunitrazepam binding was retained. The demonstration that the direct, but not the indirect, actions of etomidate are dependent on β3(Asn²⁹⁰) indicates that the dual actions of this intravenous anesthetic at GABA_A receptors are mediated via distinct loci.     

Redox modulation of homomeric rho1 GABA receptors

The activity of many receptors and ion channels in the nervous system can be regulated by redox-dependent mechanisms. Native and recombinant GABA_A receptors are modulated by endogenous and pharmacological redox agents. However, the sensitivity of GABA_C receptors to redox modulation has not been demonstrated. We studied the actions of different reducing and oxidizing agents on human homomeric GABAρ₁ receptors expressed in Xenopus laevis oocytes. The reducing agents dithiothreitol (2 mM) and N -acetyl- l -cysteine (1 mM) potentiated GABA-evoked Cl⁻ currents recorded by two-electrode voltage-clamp, while the oxidants 5-5'-dithiobis-2-nitrobenzoic acid (500 μM) and oxidized dithiothreitol (2 mM) caused inhibition. The endogenous antioxidant glutathione (5 mM) also enhanced GABAρ₁ receptor-mediated currents while its oxidized form GSSG (3 mM) had inhibitory effects. All the effects were rapid and easily reversible. Redox modulation of GABAρ₁ receptors was strongly dependent on the GABA concentration; dose–response curves for GABA were shifted to the left in the presence of reducing agents, whereas oxidizing agents produced the opposite effect, without changes in the maximal response to GABA and in the Hill coefficient. Our results demonstrate that, similarly to GABA_A receptors and other members of the cys-loop receptor superfamily, GABA_C receptors are subjected to redox modulation.     

Benzodiazepine Treatment Causes Uncoupling of Recombinant GABAA Receptors Expressed in Stably Transfected Cells

Abstract: GABA_A and benzodiazepine receptors are allosterically coupled, and occupation of either receptor site increases the affinity of the other. Chronic exposure of primary neuronal cultures to benzodiazepine agonists reduces these allosteric interactions. Neurons express multiple GABA_A receptor subunits, and it has been suggested that uncoupling is due to changes in the subunit composition of the receptor. To determine if uncoupling could be observed with expression of defined subunits, mouse Ltk⁻ cells stably transfected with GABA_A receptors (bovine α1, β1, and γ2L subunits) were treated with flunitrazepam (Flu) or clonazepam. The increase in [³H]Flu binding affinity caused by GABA (GABA shift or coupling) was significantly reduced in cells treated chronically with the benzodiazepines, whereas the K _D and B _max of [³H]Flu binding were unaffected. The uncoupling caused by clonazepam treatment occurred rapidly with a t _1/2 of ∼30 min. The EC₅₀ for clonazepam treatment was ∼0.3 µ M , and cotreatment with the benzodiazepine antagonist Ro 15-1788 (5.6 µ M ) prevented the effect of clonazepam. The uncoupling observed in this system was not accompanied by receptor internalization, is unlikely to be due to changes in receptor subunit composition, and probably represents posttranslational changes. The rapid regulation of allosteric coupling by benzodiazepine treatment of the stably transfected cells should provide insights to the mechanisms of coupling between GABA_A and benzodiazepine receptors as well as benzodiazepine tolerance.     

Polyclonal Antibodies Directed Against an Epitope Specific for the α4-Subunit of GABAA Receptors Identify a 67-kDa Protein in Rat Brain Membranes

Abstract: Polyclonal antibodies were raised to the C-terminal part of the γ-aminobutyric acid_A (GABA_A) receptor α4-subunit. These anti-peptide α4 (517–523) antibodies specifically identified a protein with apparent molecular mass 67 kDa in rat brain membranes. This protein was enriched by immunoaffinity chromatography of brain membrane extracts on Affigel 10 coupled to the anti-peptide α4 (517–523) antibodies and could then be identified by the anti-α4-antibodies as well as by the GABA_A receptor subunit-specific monoclonal antibody bd-28. This appears to indicate that the 67-kDa protein is the α4-subunit of GABA_A receptors. Intact GABA_A receptors appeared to be retained by the immunoaffinity column because other GABA_A receptor subunit proteins like the β2/β3-subunits and the γ2-subunit were detected in the immunoaffinity column eluate. Furthermore, in addition to the 67-kDa protein, a 51-kDa protein could be detected by the antibody bd-28 and the anti-peptide α4 (517–523) antibody in the immunoaffinity column eluate. A protein with similar apparent molecular mass was identified by the α1-subunit-specific anti-peptide α1 (1–9) antibody. In contrast to the α1-subunit, the 51-kDa protein identified by the anti-α4 antibody could not be deglycosylated by N -Glycanase. The identity of the 51-kDa protein identified by the anti-α4-antibodies thus must be further investigated.     

Small N-Terminal Deletion by Splicing in Cerebellar α6 Subunit Abolishes GABAA Receptor Function

Abstract: Sequence variation was found in cDNA coding for the extracellular domain of the rat γ-aminobutyric acid type A (GABA_A) receptor α6 subunit. About 20% of polymerase chain reaction (PCR)-amplified α6 cDNA prepared from rat cerebellar mRNA lacked nucleotides 226–255 as estimated by counting single-stranded phage plaques hybridized specifically to the short (α6S) and long (wild-type) forms of the α6 mRNA. Genomic PCR revealed an intron located upstream of the 30-nucleotide sequence. Both splice forms were detected in the cerebellum by in situ hybridization. Recombinant receptors, resulting from coexpression of the α6S subunit with the GABA_A receptor β2 and γ2 subunits in human embryonic kidney 293 cells, were inactive at binding [³H]muscimol and [³H]Ro 15-4513. In agreement, injection of complementary RNAs encoding the same subunits into Xenopus oocytes produced only weak GABA-induced currents, indistinguishable from those produced by β2γ2 receptors. Therefore, the 10 amino acids encoded by the 30-nucleotide fragment may be essential for the correct assembly or folding of the α6 subunit-containing receptors.     

CaMKII associates with CaV1.2 L-type calcium channels via selected β subunits to enhance regulatory phosphorylation

Calcium/calmodulin-dependent kinase II (CaMKII) facilitates L-type calcium channel (LTCC) activity physiologically, but may exacerbate LTCC-dependent pathophysiology. We previously showed that CaMKII forms stable complexes with voltage-gated calcium channel (VGCC) β_1b or β_2a subunits, but not with the β₃ or β₄ subunits ( Grueter et al. 2008 ). CaMKII-dependent facilitation of Ca_V1.2 LTCCs requires Thr498 phosphorylation in the β_2a subunit ( Grueter et al. 2006 ), but the relationship of this modulation to CaMKII interactions with LTCC subunits is unknown. Here we show that CaMKII co-immunoprecipitates with forebrain LTCCs that contain Ca_V1.2α₁ and β₁ or β₂ subunits, but is not detected in LTCC complexes containing β₄ subunits. CaMKIIα can be specifically tethered to the I/II linker of Ca_V1.2 α₁ subunits in vitro by the β_1b or β_2a subunits. Efficient targeting of CaMKIIα to the full-length Ca_V1.2α₁ subunit in transfected HEK293 cells requires CaMKII binding to the β_2a subunit. Moreover, disruption of CaMKII binding substantially reduced phosphorylation of β_2a at Thr498 within the LTCC complex, without altering overall phosphorylation of Ca_V1.2α₁ and β subunits. These findings demonstrate a biochemical mechanism underlying LTCC facilitation by CaMKII.     

An mRNA Encoding a Putative GABA-Gated Chloride Channel Is Expressed in the Human Cardiac Conduction System

Abstract: GABA-gated chloride channels are the main inhibitory neurotransmitter receptors in the CNS. Conserved domains among members of previously described GABA_A receptor subunits were used to design degenerate sense and antisense oligonucleotides. A PCR product from this amplification was used to isolate a full-length cDNA. The predicted protein has many of the features shared by other members of the ligand-gated ion channel family. This channel subunit has significant amino acid identity (25–40%) with members of GABA_A and GABA_C receptor subunits and thus may represent a new subfamily of the GABA receptor channel. Although we cannot rule out that this clone encodes a receptor for an unidentified ligand, it was termed GABA _χ. This gene is mainly expressed in placenta and in heart; however, placenta appears to express only an unspliced mRNA. In situ hybridization reveals that the GABA _χ subunit mRNA is present in the electrical conduction system of the human heart. Our results suggest that novel GABA receptors expressed outside of the CNS may regulate cardiac function.     

Replacement of histidine in position 105 in the α₅ subunit by cysteine stimulates zolpidem sensitivity of α₅β₂γ₂ GABA(A) receptors

Zolpidem is a positive allosteric modulator of GABA_A receptors with sensitivity to subunit composition. While it acts with high affinity and efficacy at GABA_A receptors containing the α₁ subunit, it has a lower affinity to GABA_A receptors containing α₂, α₃, or α₅ subunits and has a very weak efficacy at receptors containing the α₅ subunit. Here, we show that replacing histidine in position 105 in the α₅ subunit by cysteine strongly stimulates the effect of zolpidem in receptors containing the α₅ subunit. The side chain volume of the amino acid residue in this position does not correlate with the modulation by zolpidem. Interestingly, serine is not able to promote the potentiation by zolpidem. The homologous residues to α₅H105 in α₁, α₂, and α₃ are well-known determinants of the action of classical benzodiazepines. Other studies have shown that replacement of these histidines α₁H101, α₂H101, and α₃H126 by arginine, as naturally present in α₄ and α₆, leads to benzodiazepine insensitivity of these receptors. Thus, the nature of the amino acid residue in this position is not only crucial for the action of classical benzodiazepines but in α₅ containing receptors also for the action of zolpidem.     

Chronic Ethanol Administration Regulates the Expression of GABAA Receptor α1 and α5 Subunits in the Ventral Tegmental Area and Hippocampus

Abstract: Ethanol dependence and tolerance involve perturbation of GABAergic neurotransmission. Previous studies have demonstrated that ethanol treatment regulates the function and expression of GABA_A receptors throughout the CNS. Conceivably, changes in receptor function may be associated with alterations of subunit composition. In the present study, a comprehensive (1–12 weeks) ethanol treatment paradigm was used to evaluate changes in GABA_A receptor subunit expression in several brain regions including the cerebellum, cerebral cortex, ventral tegmental area (VTA) (a region implicated in drug reward/dependence), and the hippocampus (a region involved in memory/cognition). Expression of α₁ and α₅ subunits was regulated by ethanol in a region-specific and time-dependent manner. Following 2–4 weeks of administration, cortical and cerebellar α₁ and α₅ subunit immunoreactivity was reduced. In the VTA, levels of α₁ subunit immunoreactivity were significantly decreased after 12 weeks but not 1–4 weeks of treatment. Hippocampal α₁ subunit immunoreactivity and mRNA content were also significantly reduced after 12 but not after 4 weeks of treatment. In contrast, α₅ mRNA content was increased in this brain region. These data indicate that chronic ethanol administration alters GABA_A receptor subunit expression in the VTA and hippocampus, effects that may play a role in the abuse potential and detrimental cognitive effects of alcohol.     

Evidence for the Existence of Differential O-Glycosylated α5-Subunits of the γ-Aminobutyric AcidA Receptor in the Rat Brain

Abstract: Polyclonal antibodies were raised to synthetic peptides having amino acid sequences corresponding with the N- or C-terminal part of the γ-aminobutyric acid_A (GABA_A) receptor α₅-subunit. These anti-peptide α₅(2–10) or anti-peptide α₅(427–433) antibodies reacted specifically with GABA_A receptors purified from the brains of 5–10-day-old rats in an enzyme-linked immunosorbent assay and were able to dose-dependently immunoprecipitate up to 6.3 or 13.1% of the GABA_A receptors present in the incubation, respectively. In immunoblots, each of these antibodies reacted with the same two protein bands with apparent molecular mass of 53 or 57 kDa. After exhaustive treatment of purified GABA_A receptors with N -Glycanase, each of these antibodies identified two proteins with apparent molecular masses of 46 and 48 kDa. Additional treatment of GABA_A receptors with neuraminidase and O -Glycanase resulted in an apparently single protein with molecular mass of 47 kDa, which again was identified by both the anti-peptide α₅(2–10) and the anti-peptide α₅(427–433) antibody. These results indicate the existence of at least two different α₅-sub-units of the GABA_A receptor that differ in their carbohydrate content. In contrast to other α- or β-subunits of GABA_A receptors so far investigated, at least one of these two α₅-subunits contains O-linked carbohydrates.     

Differential Effects of 4'-Chlorodiazepam on Expressed Human GABAA Receptors

Abstract: The interactions of the atypical benzodiazepine 4'-chlorodiazepam (Ro 5-4864) with functionally expressed human GABA_A receptor cDNAs were determined. Cotransfection of human α₂, β₁, and γ₂ subunits was capable of reconstituting a 4'-chlorodiazepam recognition site as revealed by a dose-dependent potentiation of t -[³⁵S]butylbicyclophosphorothionate ([³⁵S]TBPS) binding to the GABA-activated chloride channel. This site is found on GABA_A receptor complexes containing sites for GABA agonist-like benzodiazepines and neuroactive steroids. The importance of the α subunit was further demonstrated as substitution of either α₁ or α₃ for the α₂ subunit did not reconstitute a 4'-chlorodiazepam recognition site that was capable of modulating [³⁵S]TBPS binding under the same experimental conditions. The 4'-chlorodiazepam modulatory site was shown to be distinct from the benzodiazepine site, but the phenylquinolines PK 8165 and PK 9084 produced effects similar to 4'-chlorodiazepam, consistent with the previous analysis of the 4'-chlorodiazepam site in brain homogenates. Further analysis of the subunit requirements revealed that coexpression of α₂ and β₁ alone reconstituted a 4'-chlorodiazepam recognition site. It is interesting, however, that the 4'-chlorodiazepam site was found to inhibit [³⁵S]TBPS binding to the GABA-activated chloride channel. Thus, the 4'-chlorodiazepam site may be reconstituted with only the α and β polypeptides.     

In Situ Hybridization Evidence of Differential Modulation by Pentobarbital of GABAA Receptor α1- and β3-Subunit mRNAs

Abstract: Tolerance to and withdrawal from pentobarbital were induced in rats by continuous intracerebroventricular infusion via subcutaneously implanted osmotic minipumps. In situ hybridization of GABA_A receptor α₁- and β₃-subunit mRNA was conducted using synthetic 3'- end ³⁵S-dATP-labeled oligodeoxynucleotide probes. Results were quantified by film densitometry. In animals that were tolerant to pentobarbital, levels of α₁-subunit mRNA were decreased in hippocampus, superior colliculus, and inferior colliculus, but levels of β₃-subunit mRNA were not affected. Dramatically increased levels of GABA_A receptor subunit mRNA were observed in animals 24 h after withdrawal from chronic pentobarbital treatment. These increases occurred in cerebral cortex and cerebellum for the α₁ subunit and in cerebral cortex only for the β₃-subunit. These data provide further support to the structural and pharmacological GABA_A receptor heterogeneity in discrete brain areas. The observed changes of subunit expression may underlie, at least in part, the receptor up- and down-regulation observed in receptor ligand binding studies.