A benchmark for Monte Carlo simulations in gamma-ray spectrometry Part II: True coincidence summing correction factors.

The goal of this study is to provide a benchmark for the use of Monte Carlo simulation when applied to coincidence summing corrections. The examples are based on simple geometries: two types of germanium detectors and four kinds of sources, to mimic eight typical measurement conditions. The coincidence corrective factors are computed for four radionuclides. The exercise input files and calculation results with practical recommendations are made available for new users on a dedicated webpage.

Brain GABAA receptors studied with subunit-specific antibodies.

Brain GABAA/benzodiazepine receptors are highly heterogeneous. This heterogeneity is largely derived from the existence of many pentameric combinations of at least 16 different subunits that are differentially expressed in various brain regions and cell types. This molecular heterogeneity leads to binding differences for various ligands, such as GABA agonists and antagonists, benzodiazepine agonists, antagonists, and inverse agonists, steroids, barbiturates, ethanol, and Cl- channel blockers. Different subunit composition also leads to heterogeneity in the properties of the Cl- channel (such as conductance and open time); the allosteric interactions among subunits; and signal transduction efficacy between ligand binding and Cl- channel opening. The study of recombinant receptors expressed in heterologous systems has been very useful for understanding the functional roles of the different GABAA receptor subunits and the relationships between subunit composition, ligand binding, and Cl- channel properties. Nevertheless, little is known about the complete subunit composition of the native GABAA receptors expressed in various brain regions and cell types. Several laboratories, including ours, are using subunit-specific antibodies for dissecting the heterogeneity and subunit composition of native (no reconstituted) brain GABAA receptors and for revealing the cellular and subcellular distribution of these subunits in the nervous system. These studies are also aimed at understanding the ligand-binding, transduction mechanisms, and channel properties of the various brain GABAA receptors in relation to synaptic mechanisms and brain function. These studies could be relevant for the discovery and design of new drugs that are selective for some GABAA receptors and that have fewer side effects.

Immunocytochemical localization of GABAA receptors in goldfish and chicken retinas.

A monoclonal antibody (mAb 62-3G1) to the GABAA receptor/benzodiazepine receptor/Cl- channel complex from bovine brain was used with light and electron microscopy in goldfish retina and light microscopy in chicken retina to localize GABAA receptor immunoreactivity (GABAr-IR). GABAr-IR was found in the outer plexiform layer (OPL) in both species, in three broad bands in the inner plexiform layer (IPL) of goldfish, and in seven major bands of the chicken IPL. A small percentage of amacrine cell bodies (composing at least three types) were stained in chicken. In goldfish OPL, GABAr-IR was localized intracellularly and along the plasma membrane of cone pedicles, whereas rod spherules were lightly stained, but always only intracellularly. In chicken, all three sublayers of the OPL were GABAr-IR. The presence of GABAr-IR on photoreceptor terminals is consistent with data indicating feedback from GABAergic horizontal cells to cones. In the goldfish IPL, GABAr-IR was localized to postsynaptic sites of amacrine cell synapses; intracellular staining of processes in the IPL also was observed in presumed "GABAergic" targets. A comparison of GABAr-IR with the distributions of 3H-muscimol uptake/binding, glutamate decarboxylase-IR, GABA-IR, and 3H-GABA uptake in the IPL showed either a reasonable correspondence or mismatch, depending on the marker, species, and lamina within the IPL. The distribution of GABAr-IR in the retina corresponded better with the 3H-muscimol than with 3H-benzodiazepine binding patterns yet overall was in excellent agreement with many other physiological and anatomical indicators of GABAergic function. We suggest that intracellular GABAr-IR represents the biosynthetic and/or degradative pathway of the receptor and we conclude that mAb 62-3G1 is a valid marker of GABAA receptors in these retinas and will serve as a useful probe with which to address the issue of mismatches between the localization of GABAA receptors and indicators of presynaptic GABAergic terminals.

Immunocytochemical localization of the alpha 6 subunit of the gamma-aminobutyric acidA receptor in the rat nervous system.

The localization in the rat central nervous system and retina of the alpha 6 subunit peptide of the gamma-aminobutyric acid (GABAA) receptor has been studied by light microscopy immunocytochemistry with a specific anti-alpha 6 antibody. The alpha 6 subunit was present in the granule cells of the cerebellum, the granule cells of the dorsal cochlear nucleus, axons of the olfactory nerve including the glomerular endings, layer II of the dorsal horn of the spinal cord, and in the retinal synaptic layers, particularly the inner plexiform layer. Thus, contrary to the general belief, the alpha 6 subunit is not exclusively localized in the granule cells of the cerebellum. It is also expressed in some sensory neurons and other neurons involved in the initial processing of sensory information.

Distribution of immunoreactivity for the beta 2 and beta 3 subunits of the GABAA receptor in the mammalian spinal cord.

The localization of GABAA receptors in cat and rat spinal cord was analyzed using two monoclonal antibodies specific for an epitope shared by the beta 2 and beta 3 subunits of the receptor. beta 2/beta 3-subunit immunoreactivity was the most intense in inner lamina II, lamina III, and lamina X, and it was the least intense in lamina IX. In laminae I-III, generally, the staining had a rather diffuse appearance, but the surfaces of small cell bodies in these laminae were outlined clearly by discrete labeling, as were many cell bodies and dendrites in deeper laminae. Rhizotomy experiments and ultrastructural observations indicated that beta 2/beta 3-subunit immunoreactivity in the dorsal horn was largely localized in intrinsic neuropil elements rather than in the terminals of primary afferent fibers, even though labeling overlapped with the terminal fields of different types of primary afferents and was also detected on the membranes of dorsal root ganglion neurons. With few exceptions (most notably, a highly immunoreactive group of dorsolaterally located cells in the cat lumbar ventral horn), motoneurons expressed low levels of beta 2/beta 3-subunit immunoreactivity. Labeling of neuronal membranes was fairly continuous, but focal accumulations of beta 2/beta 3-subunit immunoreactivity were also detected using immunofluorescence. Focal "hot spots" correlated ultrastructurally with the presence of synaptic junctions. Dual-color immunofluorescence revealed that focal accumulations of beta 2/beta 3-subunit immunoreactivity were frequently apposed by glutamic acid decarboxylase (GAD)-immunoreactive terminals. However, the density of continuous-membrane beta 2/beta 3 immunolabeling and GAD terminal density were not correlated in many individual neurons. The results suggest the existence of "classical" (synaptic) and "nonclassical" (paracrine) actions mediated via spinal cord GABAA receptors. The study also revealed the relative paucity of beta 2/beta 3-subunit immunoreactivity postsynaptic to certain GABAergic terminals, particularly those presynaptic to motoneurons or primary afferent terminals.

Immunocytochemical localization of the beta 2 subunit of the gamma-aminobutyric acidA receptor in the rat brain.

An antiserum to the beta 2 subunit of the rat gamma-aminobutyric acid (GABAA) receptor was prepared by immunizing a rabbit with a fusion protein expressed in bacteria. The fusion protein had the large, intracellular loop expanding between the putative M3 and M4 transmembrane domains of the beta 2 subunit fused to staphylococcal protein A (SPA). The antiserum immunoprecipitated both the solubilized and the affinity-purified GABAA receptors. The anti-beta 2 antibodies were affinity purified on immobilized beta 2 intracellular loop peptide. The antibodies recognized a 55-57 kDa peptide in immunoblots of either crude membranes from rat cerebral cortex or affinity-purified GABAA receptors from bovine cerebral cortex. Immunocytochemistry with the affinity-purified antibody has revealed for the first time the localization of the beta 2 subunit in the rat brain. A comparative study of the regional and cellular immunoreactivities of the affinity-purified anti-beta 2 antibody and the monoclonal antibody 62-3G1 (which recognizes both beta 2 and beta 3 subunits) is presented. The procedure described for generating and preparing specific anti-beta 2 subunit antibodies that are valuable for immunocytochemistry could be extended to other GABAA receptor subunits.

Immunocytochemical localization of the beta(3) subunit of the gamma-aminobutyric acid(A) receptor in the rat brain.

A novel anti-beta(3) subunit-specific GABA(A) receptor (GABA(A)R) antibody has been prepared by immunizing a rabbit with a bacterial fusion protein of the large intracellular loop of the beta(3) subunit. The antiserum immunoprecipitated the solubilized GABA(A) receptor. The anti-beta(3) antibody was affinity purified on immobilized beta(3) large intracellular loop peptide. In immunoblots, the purified antibody reacted with a 57 KDa peptide. Immunocytochemistry with the affinity-purified antibody has revealed the localization of the beta(3) subunit in the rat brain. A comparative study with the immunocytochemical distribution of the beta(2) subunit has also been performed. There are areas of the brain and cell types where the distribution of beta(2) and beta(3) overlap (i.e., cerebral cortex, cerebellum,and most layers of the olfactory bulb). There are also clear differences in the expression of beta(3) and beta(2) in other brain areas and cell types. Thus, high beta(3) but low or no beta(2) expression was observed in the corpus striatum and in granule cells of the olfactory bulb. In the hippocampus the expression of beta(3) was considerably higher than that of beta(2), but some hippocampal interneurons showed high expression of beta(2). High beta(2) but little or no expression of beta(3) was observed in thalamic nuclei, substantia nigra, globus pallidus, inferior colliculus and the short axon cells of the olfactory bulb.

Estimation of the number of monoclonal hybridomas in a cell fusion experiment. Effect of post-fusion cell dilution on hybridoma survival.

A practical method is described for the estimation of the number of monoclonal hybridomas in a cell fusion experiment as a function of the percent of culture dishes showing hybridoma growth. Our method is based on the Poisson probability model. A justification for the method is included. The application of this model to our experimental results indicates that the probability of hybridoma survival decreases with post-fusion cell dilution even in the presence of a constant number of feeder cells.

The alpha 4 subunit of the GABAA receptors from rat brain and retina.

A novel anti-alpha 4 antibody has been used for the purification and characterization of the alpha 4-containing GABAA receptors in the rat brain and for studying the immunocytochemical distribution of the alpha 4 subunit peptide in rat brain and retina. The anti-alpha 4 antibody recognized a 66 kDa peptide in brain membranes and immunoprecipitated 10-28% of the brain GABAA receptors in various brain regions as determined by [3H]muscimol binding. The highest immunoprecipitation values were obtained in the thalamus and the lowest in the cerebellum. Surprisingly, the receptors immunoprecipitated by anti-alpha 4 showed little or no diazepam-insensitive or diazepam-sensitive [3H]Ro15-4513 binding sites in any brain region. In the cerebellum, where 25% of the [3H]Ro15-4513 binding is diazepam-insensitive, much of the latter was immunoprecipitated by an anti-alpha 6 antibody but not by the anti-alpha 4 antibody. Immunoblots of immunoaffinity-purified GABAA receptors from the cerebral cortex on immobilized anti-alpha 4 revealed molecular colocalization of alpha 4 and gamma 2. However, the absence of significant benzodiazepine binding in these GABAA receptors suggests that the assembly of the alpha 4 and gamma 2 subunits in the cerebral cortex and in other brain regions is such that they do not normally form diazepam-insensitive [3H]Ro15-4513 binding sites. This result contrasts with the presence of diazepam-insensitive [3H]Ro15-4513 binding sites in the GABAA receptors expressed in heterologous systems resulting from the combination of alpha 4, gamma 2 and beta 2 subunits. Immunocytochemistry has revealed the abundance of alpha 4 peptide immunoreactivity in the thalamus and dentate gyrus (mainly in the hilar neurons and the inner third of the granule cell layer). The alpha 4 immunoreactivity is also present in the external plexiform layer of the olfactory bulb and in all layers of the neocortex and pyriform cortex. In the retina, alpha 4 is concentrated on ganglion cells (including some giant ganglion cells), the inner plexiform layer and to a lesser extent in the outer plexiform layer.

Normal electrophysiological and behavioral responses to ethanol in mice lacking the long splice variant of the gamma2 subunit of the gamma-aminobutyrate type A receptor.

The gamma subunit of the gamma-aminobutyric acid type A receptor (GABA(A)-R) is essential for bestowing both normal single channel conductance and sensitivity to benzodiazepines on native GABA(A)-Rs. The long splice variant of the gamma2 subunit (gamma2L) has been postulated to be essential in mediating the modulatory actions of ethanol at the GABA(A)-R. In order to evaluate this hypothesis, gene targeting was used to delete the 24bp exon which distinguishes gamma2L from the short splice variant (gamma2S). Mice homozygous for this exon deletion (gamma2L-/-) are viable and indistinguishable from wild-type (gamma2L+/+) mice. No gamma2L mRNA was detected in these mice, nor could gamma2L-containing GABA(A)-R protein be detected by specific antibodies. Radioligand binding studies showed the total amount of gamma2 subunit protein to be not significantly changed, suggesting that gamma2S replaces gamma2L in the brains of the knockout animals. Electrophysiological recordings from dorsal root ganglion neurons revealed a normal complement of functional receptors. There was no difference in the potentiation of GABA currents by ethanol (20-200 mM) observed in neurons from gamma2L+/+ or gamma2L-/- mice. Several behavioral effects of ethanol, such as sleep time, anxiolysis, acute functional tolerance, chronic withdrawal hyperexcitability and hyperlocomotor activity were also unaffected by genotype. It is concluded that gamma2L is not required for ethanol's modulatory action at the GABA(A)-R or whole animal behavioral effects.

Aging-related subunit expression changes of the GABAA receptor in the rat hippocampus.

Aging-related changes in the subunit expression of some hippocampal GABAA receptors have been found. Quantitative in situ hybridization has revealed that alpha 1, subunit messenger RNA expression was significantly increased in the hippocampus (34%) of old rats. The largest increases were observed in the dentate gyrus (76%) and in the CA1 field (30%). Quantitative immunocytochemistry also showed increased protein expression of the alpha 1 subunit in the dentate gyrus (19%) and CA1 (14%) of old rats. The increased alpha 1 messenger RNA and protein expression led to increased proportions of assembled GABAA receptors that contained alpha 1 subunits, as revealed by quantitative immunoprecipitation of (3H)flunitrazepam and (3H)muscimol binding. In contrast, there were no significant changes in the expression of beta 2, beta 3 and total gamma 2 (gamma 2S + gamma 2L) subunits, although a slightly increased expression of gamma 2L peptide was detected in the hippocampus proper (7%), but not in the dentate gyrus. The results are consistent with the notion that in the rat hippocampus there is an aging-related change in the subunit composition of some GABAA receptors.

Biochemical analysis of GABA(A) receptor subunits alpha 1, alpha 5, beta 1, beta 2 in the hippocampus of patients with Alzheimer's disease neuropathology.

Alzheimer's disease (AD) is characterized by selective vulnerability of specific neuronal populations within particular brain regions. For example, hippocampal glutamatergic cell populations within the CA1/subicular pyramidal cell fields have been found to be particularly vulnerable early in AD progression. In contrast, hippocampal GABA-ergic neurons and receptors appear resistant to neurodegeneration. Despite relative sparing of GABA(A) receptors in AD, it is possible that the specific subunit composition of these receptors may undergo alterations with disease progression. In order to address this issue, we employed quantitative Western blot analysis to examine protein levels of GABA(A) receptor subunits alpha 1, alpha 5, beta 1, beta 2 in the hippocampus of subjects displaying increasing severity of AD neuropathology. Subjects were categorized into three groups based upon Braak staging pathologic criteria: pathologically mild (stages I/II, n=9); moderate (stages III/IV, n=8); and severe (stages V/VI, n=7). Across all subject groups, levels of subunit protein were heterogeneously distributed throughout the five hippocampal subregions analyzed (subiculum, CA1-3, dentate gyrus). Statistical analyses revealed differential preservation of GABA(A) receptor subunits in AD. In particular, alpha 1, beta 1, and beta 2 displayed little difference in protein levels among pathologically mild, moderate, and severe subject groups. In contrast, although relatively modest, protein levels of the alpha 5 subunit were significantly reduced between subjects with severe neuropathology compared with pathologically mild subjects (13.5% reduction). Collectively, our data provide evidence for heterogeneous distribution and relative sparing of GABA(A) receptor subunits in the hippocampus of AD patients.

Antibodies to the rat beta 3 subunit of the gamma-aminobutyric acid A receptors.

Polymerase chain reaction was used to amplify the cDNA region that codes for the large intracellular loop of the beta 3 subunit of the gamma-aminobutyric acidA/benzodiazepine receptors (GABAAR/BZDR) from rat brain. The amplified cDNA was inserted into the prokaryotic expression vector pGEX-3X and a fusion protein containing glutathione-S-transferase and beta 3 intracellular loop moieties was expressed in bacteria. The fusion protein was affinity-purified and it was used to raise a rabbit anti-beta 3 antiserum. The anti-beta 3 antiserum immunoprecipitated the gamma-aminobutyric acidA receptor from rat and bovine brain. Immunoblots of the affinity-purified GABAAR/BZDR from bovine brain revealed that the anti-beta 3 antiserum reacted with a 57 kDa peptide, whereas the monoclonal antibody 62-3G1 that recognized both beta 2 and beta 3 reacted with 55 and 57 kDa peptides. The anti-beta 3 antiserum showed specificity for the beta 3 subunit vs beta 2 and beta 1.

Molecular characterization of type I GABAA receptor complex from rat cerebral cortex and hippocampus.

The molecular composition of the native gamma-aminobutyric acidA (GABAA) receptor complex is actually unknown. In the present communication we report a novel approach to characterize the minimal molecular conformation of the native GABAA receptor complex. This novel approach is based on the combination of subunit specific antibodies and specific 3H-labeled ligands in immunoprecipitation experiments. We have determined the presence of beta 2/3 and gamma 2 subunits in the Type I GABAA receptor complex, from rat cerebral cortex and hippocampus, by using two antibodies, the monoclonal 62-3G1 (specific for beta 2/3) and the polyclonal anti-gamma 2 (to the large intracellular loop of the gamma 2 short form) together with the Type I-specific ligand [3H]zolpidem. The association of gamma 2 and beta 2/3 subunits with the GABAA receptor complex was also tested using [3H]flumazenil. The results indicated that both gamma 2 and beta 2/3 were the most abundant subunits associated to either Type I or total benzodiazepine receptors from both cortex and hippocampus. Between 70-80% of Type I or total benzodiazepine binding activity was immunoprecipitated by either antibody. In addition, we have also investigated the coexistence of both subunits as part of the same population of Type I GABAA receptor complex by cross-immunoprecipitation experiments with 62-3G1 and anti-gamma 2. The results indicated that, in cerebral cortex, both gamma 2 and beta 2/3 subunits were part of the same population of Type I receptors. In hippocampus, an additional 20% of Type I receptors displayed either gamma 2 or beta 2/3 but not both subunits.(ABSTRACT TRUNCATED AT 250 WORDS)

GABAA/benzodiazepine receptor gamma 2 subunit gene expression in developing normal and mutant mouse cerebellum.

Recent studies have identified several subunits (alpha, beta, gamma and delta) of the gamma-aminobutyric acidA/benzodiazepine receptor; each consists of several variants. The gamma 2 subunit appears to mediate the interaction of the alpha and beta subunits making the receptor capable of modulation by benzodiazepines. In the present studies, the expression of mRNA encoding the gamma 2 subunit was examined in the cerebellum during development and in adult Purkinje cell degeneration, lurcher and reeler mutant mice. In the normal adult cerebellum, in situ hybridization with [35S]cRNA probes revealed a strong signal over the Purkinje cell layer and deep cerebellar nuclei, and a weaker signal over basket, stellate and granule cells. Labeling over Purkinje cells was detectable at birth, gradually becoming stronger and more punctate during postnatal weeks 1 and 2, as Purkinje cells formed a monolayer between the molecular and granule cell layers. Adult levels of grain density were reached by P20. The external germinal layer, which contained proliferating granule cells, was unlabeled throughout development; however, weak labeling was detected over the internal granular layer at the end of postnatal week 1, as granule cells began their migration across the molecular layer. During the second postnatal week, punctate labeling became visible over the molecular layer in a distribution indicative of basket and stellate cells. In adult Purkinje cell degeneration and lurcher mutants, in which Purkinje cells have degenerated, no punctate labeling characteristic of mature Purkinje cells was detected. In adult and developing reeler mutants, where all classes of cells are malpositioned throughout the cerebellum, the punctate hybridization signal was present and clearly associated with Purkinje cells in all cortical regions. Our results suggest that developing Purkinje cells express the gamma 2 gene at a time prior to receiving GABAergic inhibitory input, and that the continued expression in the adult is not affected by the absence of afferents.

Differential expression of the short and long forms of the gamma 2 subunit of the GABAA/benzodiazepine receptors.

The distribution of the mRNAs encoding the gamma 2S and gamma 2L subunits of the GABAA receptor in the rat brain has been revealed by in situ hybridization, northern blot and dot blot analysis using specific antisense oligonucleotides. In addition, the quantitative distribution of the gamma 2S and gamma 2L subunit peptides participating in the fully assembled GABAA receptors/benzodiazepine receptors has been mapped by immunoprecipitation with specific anti-gamma 2S and anti-gamma 2L antibodies. Several neuronal types and brain regions are enriched in gamma 2L such as neurons of the layer II of striate cortex and cerebellar Purkinje cells as well as the inferior colliculus, superior colliculus, deep cerebellar nuclei, medulla and pons. Other neuronal types and regions are enriched in gamma 2S such as the mitral cells of the olfactory bulb, pyramidal neurons of the pyriform cortex, layer VI of the neocortex, granule cells of the dentate gyrus and pyramidal cells of the hippocampus. Other cortical areas and cerebellar granule cells express both gamma 2S and gamma 2L in comparable amounts. There is a good correlation between the relative expression of gamma 2S and gamma 2L mRNAs and the relative presence of these protein subunits in fully assembled and mature receptors in the studied brain regions. The differential distribution of gamma 2S and gamma 2L might result in differential ethanol sensitivity of the neurons expressing these GABAA receptor subunits.

Altered expression of gamma 2L and gamma 2S GABAA receptor subunits in the aging rat brain.

Aging-related alterations in both protein and mRNA expression of gamma 2S and gamma 2L subunits of the GABAA receptors have been observed in several brain areas of Sprague-Dawley and Fischer 344 rats. Subunit-specific antibodies to gamma 2S and gamma 2L as well as a riboprobe to the large intracellular loop of gamma 2, which recognizes both gamma 2S and gamma 2L mRNAs, in conjunction with computerized image analysis were used for quantitative immunocytochemistry and in situ hybridization. In addition, specific oligonucleotide probes to gamma 2S or gamma 2L mRNA were used for quantitative dot blot hybridization. A large increase in the number of heavily immunostained neurons with the anti-gamma 2L antibody was detected in the cerebral cortex (115%) of old rats. However, only a small (but significant) aging-related increase in the density of gamma 2L immunostaining (7%) was observed throughout the cerebral cortex whereas no significant aging-related change in gamma 2L mRNA was detected in this brain region. Contrary to gamma 2L, the gamma 2S immunostaining did not show aging-related increased number of heavily immunostained neurons in cerebral cortex. Moreover, the density of gamma 2S immunostaining and the expression of gamma 2S mRNA were significantly decreased in the cerebral cortex (9-24%). Important aging-related changes were also found in the cerebellum of old rats where the expression of both gamma 2S and gamma 2L peptides was significantly decreased (24% and 23% respectively). This decrease in gamma 2 protein expression was accompanied by decreased expression of gamma 2S (16-38%) and gamma 2L (24%) mRNAs. Nevertheless, the most important decrease of gamma 2S (48%) and gamma 2L protein (20%) was revealed in the molecular layer of the cerebellum. In addition, the expression of gamma 2S protein was increased (14%) whereas the expression of gamma 2L was decreased (13%) in the granule cell layer. Therefore, the relative expression of gamma 2S protein in both layers was reversed in old animals. The observed aging-related changes in the expression of GABAA receptor subunits might lead to altered GABAA receptor/benzodiazepine receptor subunit composition.

GABAA receptor subunit expression changes in the rat cerebellum and cerebral cortex during aging.

Significant aging-related decreased expression of various GABAAR subunit mRNAs (alpha 1, gamma 2, beta 2, beta 3 and sigma) was found in both cerebellum and cerebral cortex using quantitative dot blot and in situ hybridization techniques. Contrary to the other subunits, the alpha 6 mRNA expression was significantly increased in the aged cerebellum. Parallel age-related changes in protein expression for gamma 2 and beta 2/3 (decrease) and alpha 6 (increase) were revealed in cerebellum by quantitative immunocytochemistry. However, no significant changes in alpha 1 protein expression nor in the number or affinity of [3H]zolpidem binding sites were detected in cerebellum even though alpha 1 mRNA expression was significantly decreased in the aged rat. Age-related increased expression of alpha 6 mRNA and protein in the cerebellum was accompanied by no significant changes in the number of diazepam-insensitive [3H]Ro15-4513 binding sites. In the cerebral cortex, no changes in the protein expression of the main GABAA receptor subunits (alpha 1, gamma 2 and beta 2/3) were observed which contrasted with the age-related decreased expression of the corresponding mRNAs. No significant changes in the number or affinity of [3H]zolpidem binding sites were observed in the cerebral cortex. Thus, age-related changes in the mRNA expression of a particular subunit does not necessarily lead to similar changes in protein or assembly into mature GABAA receptors. The results reveal the existence of complex regulatory mechanisms of GABAA receptor expression, at the transcriptional, translational and post-translational and/or assembly levels, which vary with the subunit and brain area.

Mapping of benzodiazepine-like immunoreactivity in the rat brain as revealed by a monoclonal antibody to benzodiazepines.

A monoclonal antibody against benzodiazepines (21-7F9) was used to study the distribution of benzodiazepine-like immunoreactivity in the rat brain. Immunodensitometry in combination with image analysis were used for quantification. The results showed a ubiquitous distribution of benzodiazepine-like immunoreactivity throughout the brain. Very high levels of benzodiazepine-like immunoreactivity were found in the Purkinje cell layer of the cerebellum, in the primary olfactory cortex, in the stratum pyramidale of the hippocampus and in the mitral cell layer of the olfactory bulb. High densities of benzodiazepine-like immunoreactivity were found in the granule cell layer of the cerebellum, the pyramidal cell layer of the olfactory tubercle, the granule layer of the dentate gyrus, the arcuate nucleus of the hypothalamus, the mammillary bodies, the interstitial nucleus of Cajal and superficial grey layer of superior colliculus. The substantia nigra pars compacta, the islands of Calleja and layers II, III, V and VI of the cerebral cortex had moderate levels of benzodiazepine-like immunoreactivity. Lower densities were found in the internal granular layer and the external plexiform layer of the olfactory bulb, in the molecular layer of the dentate gyrus, in layers I and IV of the cerebral cortex, in the nucleus caudate-putamen and most of the thalamic nuclei. The lowest density of immunoreactivity was found in the globus pallidus, and the strata radiatum, oriens and lacunosum-moleculare of the hippocampus. The distribution of endogenous benzodiazepine-like immunoreactivity was compared with the distribution of the GABA/benzodiazepine receptor by using both immunocytochemistry and receptor autoradiography. Our studies have shown a clear mismatch between the localization of the benzodiazepine-like immunoreactivity and the GABA/benzodiazepine receptors.

Dopamine D2 receptor effects on GABA(A) receptor expression may modify melanotrope peptide release.

Stimulation of melanotrope dopamine D2 receptors decreases mitotic rate, calcium channel activity, and the biosynthesis of several proteins. This study demonstrates that D2 receptor activation also affects GABA(A) receptor beta2/beta3 subunit immunoreactivity. Following chronic treatment with haloperidol, a D2 receptor antagonist, GABA(A) receptor immunoreactivity increased, whereas it decreased after chronic treatment with bromocriptine, a dopamine D2 receptor agonist. Thus, these data indicate that D2 function regulates GABA(A) receptor expression in melanotropes, a mechanism by which peptide release may be modified.