Type-A receptors for the neurotransmitter GABA (gamma-aminobutyric acid) are ligand-gated chloride channels that mediate inhibitory neurotransmission. Each subunit of the pentameric receptor protein has ligand-binding sites in the amino-terminal extracellular domain and four membrane-spanning regions, one of which forms a wall of the ion channel. Each subunit also has a large intracellular loop that may be a target for protein kinases and be required for subcellular targeting and membrane clustering of the receptor, perhaps by anchoring the receptor to the cytoskeleton. Neurotransmitter receptors need to be positioned in high density in the cell membrane at sites postsynaptic to nerve terminals releasing that neurotransmitter. Other members of the superfamily of ligand-gated ion-channel receptors associate in postsynaptic-membrane clusters by binding to the proteins rapsyn or gephyrin. Here we identify a new cellular protein, GABA(A)-receptor-associated protein (GABARAP), which can interact with the gamma2 subunit of GABA(A) receptors. GABARAP binds to GABA(A) receptors both in vitro and in vivo, and co-localizes with the punctate staining of GABA(A) receptors on cultured cortical neurons. Sequence analysis shows similarity between GABARAP and light chain-3 of microtubule-associated proteins 1A and 1B. Moreover, the N terminus of GABARAP is highly positively charged and features a putative tubulin-binding motif. The interactions among GABA(A) receptors, GABARAP and tubulin suggest a mechanism for the targeting and clustering of GABA(A) receptors.
␥-Aminobutyric acid type A receptors (GABARs) have long been implicated in mediating ethanol (EtOH) actions, but so far most of the reported recombinant GABAR combinations have shown EtOH responses only at fairly high concentrations (>60 mM). We show that GABARs containing the ␦-subunit, which are highly sensitive to ␥-aminobutyric acid, slowly inactivating, and thought to be located outside of synapses, are enhanced by EtOH at concentrations that are reached with moderate, social EtOH consumption. Reproducible ethanol enhancements occur at 3 mM, a concentration six times lower than the legal blood-alcohol intoxication (driving) limit in most states (0.08% wt͞vol or 17.4 mM). GABARs responsive to these low EtOH concentrations require the GABAR ␦-subunit, which is thought to be associated exclusively with ␣4-and ␣6-subunits in vivo, and the 3-subunit, which has recently been shown to be essential for the in vivo anesthetic actions of etomidate and propofol. GABARs containing 2-instead of 3-subunits in ␣4␦-and ␣6␦-receptor combinations are almost 10 times less sensitive to EtOH, with threshold enhancement at 30 mM. GABARs containing ␥2-instead of ␦-subunits with ␣4 and ␣6 are three times less sensitive to EtOH, with threshold responses at 100 mM, a concentration not usually reached with social EtOH consumption. These combined findings suggest that ''extrasynaptic'' ␦-subunit-containing GABARs, but not their ''synaptic'' ␥-subunit-containing counterparts, are primary targets for EtOH. Despite the fact that ethanol (EtOH) is the most widely used psychoactive agent, its actions on brain functions are poorly understood. Several types of receptors and channels have been shown to be functionally altered by EtOH, which include Nmethyl-D-aspartate (1) and non-N-methyl-D-aspartate glutamate receptors (2, 3), serotonin (4), glycine (5, 6), and GABARs (7,8), and G protein-coupled inwardly rectifying K ϩ channels (9, 10). With a few exceptions (3,(8)(9)(10)(11)(12), EtOH effects on these targets are seen only at fairly high concentrations (Ն60 mM).The GABAR, the major inhibitory neurotransmitter receptor, has been a long-time focus for studies on EtOH and anesthetic actions. For example, it has been shown that EtOH at low intoxicating concentrations was able to enhance Cl Ϫ flux in synaptoneurosomes (13,14) and cultured neurons (15). However, electrophysiological studies of GABARs in single neurons and recombinant receptors showed current enhancement only at fairly high concentrations (Ͼ50 mM) of EtOH (5,7,16), which now appears to be due to the fact that these studies focused on synaptic and͞or ␥-subunit-containing receptors. It is thought that replacement of the ␥-subunit in the GABAR 2␣-2-1␥ pentameric complex by the ␦-subunit changes not only the localization of the receptor from mainly postsynaptic to extrasynaptic, but also leads to up to a 50-fold increase in ␥-aminobutyric acid (GABA) affinity and slower desensitization (17)(18)(19). These functional properties are consistent with ␣␦ GABARs, which are activat...
␥-Aminobutyric acid (GABA) type A receptors mediate fast inhibitory synaptic transmission and have been implicated in responses to sedative͞hypnotic agents (including neuroactive steroids), anxiety, and learning and memory. Using gene targeting technology, we generated a strain of mice deficient in the ␦ subunit of the GABA type A receptors. In vivo testing of various behavioral responses revealed a strikingly selective attenuation of responses to neuroactive steroids, but not to other modulatory drugs. Electrophysiological recordings from hippocampal slices revealed a significantly faster miniature inhibitory postsynaptic current decay time in null mice, with no change in miniature inhibitory postsynaptic current amplitude or frequency. Learning and memory assessed with fear conditioning were normal. These results begin to illuminate the novel contributions of the ␦ subunit to GABA pharmacology and sedative͞hypnotic responses and behavior and provide insights into the physiology of neurosteroids.
The major type of receptor for the inhibitory neurotransmitter gamma-aminobutyric acid (GABA), called the GABAA receptor, is a member of a gene superfamily of ligand-gated ion channels. This receptor is a hetero-oligomeric protein composed of several distinct polypeptide types (alpha, beta, gamma, and delta). Molecular cloning of these polypeptides reveals that they show 20-40% identity with each other, and 10-20% identity with polypeptides of the nicotinic acetylcholine receptors and strychnine-sensitive glycine receptor. Each polypeptide type is also represented by a family of genes whose members have 60-80% amino acid sequence identity. Regions of conserved and variable amino acid sequence suggest structural and functional domains within each polypeptide. All of the polypeptides when expressed in heterologous cells produce GABA-activated chloride channels, and the different subtypes express different pharmacological properties. The distributions of mRNAs for the different GABAA receptor polypeptides and their subtypes show significant brain regional variation consistent with pharmacological and biochemical evidence for receptor heterogeneity. Subpopulations of GABAA receptors with different cellular and regional locations show differential sensitivity to GABA, to modulators like steroids, to physiological regulation, to disease processes, and to pharmacological manipulation by drugs such as benzodiazepines. The properties of the different subpopulations of GABAA receptors are determined by which one or more of the different polypeptides and their subtypes are expressed in a given cell to produce a variety of different oligomeric protein structures. Molecular cloning techniques have produced rapid advances in understanding the GABAA receptor protein family.
Neuronal mechanisms underlying alcohol intoxication are unclear. We find that alcohol impairs motor coordination by enhancing tonic inhibition mediated by a specific subtype of extrasynaptic GABA A receptor (GABAR), α6β3δ, expressed exclusively in cerebellar granule cells. In recombinant studies, we characterize a naturally occurring single-nucleotide polymorphism that causes a single amino acid change (R100Q) in α6 (encoded in rats by the Gabra6 gene). We show that this change selectively increases alcohol sensitivity of α6β3δ GABARs. Behavioral and electrophysiological comparisons of Gabra6 100R/100R and Gabra6 100Q/100Q rats strongly suggest that alcohol impairs motor coordination by enhancing granule cell tonic inhibition. These findings identify extrasynaptic GABARs as critical targets underlying low-dose alcohol intoxication and demonstrate that subtle changes in tonic inhibition in one class of neurons can alter behavior.Humans have been consuming alcohol for thousands of years, and the use of alcoholic beverages pervades human culture and society and can have substantial health effects 1 . Different mechanisms by which ethanol might depress brain function have been proposed based on ethanol's ability to modulate a wide variety of ion channels 2-4 , neurotransmitter receptors 5-10 and transporters 11 . Among these diverse targets, however, GABARs are arguably the most attractive candidates. This is in part because other classes of known GABAR modulators such as benzodiazepines, barbiturates and certain anesthetics lead to behavioral effects that closely resemble ethanol intoxication. Yet despite strong evidence implicating GABARs in ethanol's action, critical details remain unclear. For instance, although it is known that native GABARs are heteropentamers assembled from 19 possible subunits 12,13 , it has not been possible to link the activity of particular GABAR subunits to changes in behavioral sensitivity to ethanol.Recent studies suggest that specific combinations of GABAR subunits (those containing α4β3δ and α6β3δ) are uniquely sensitive to ethanol, showing dose dependencies that mirror blood alcohol levels associated with intoxication in humans 9,10 . GABARs containing α4 and δ subunits are expressed in many brain regions 14,15 , but α6 is found in only two types of neurons (cerebellar granule cells and granule cells in the cochlear nucleus) and is expressed together with δ only in cerebellar granule cells 14,16,17 . In granule cells α6 and δ combine with β subunits Correspondence should be addressed to M.W. (mwallner@mednet.ucla.edu) or T.S.O. (otist@ucla.edu). 3 These authors contributed equally to this work. COMPETING INTERESTS STATEMENTThe authors declare that they have no competing financial interests. We set out to examine whether such extrasynaptic GABARs containing α6 and δ subunits account for behavioral effects of ethanol at moderately intoxicating doses. To link these particular GABARs to behavioral sensitivity, we first characterized a naturally occurring single-nucleotide polymo...
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