Regulation of the subcellular distribution and gene expression of GABA(A) receptor by microtubules and microfilaments in cultured brain neurons

Mechanisms underlying the intracellular transport of gamma-aminobutyric acid(A) receptor (GABA(A)R) were examined in the cultured neurons derived from chicken embryo brains. In situ trypsinization of the cultures and (3)H-flunitrazepam (FNZ) binding assay were employed to determine the cell surface and intracellular distribution of the receptor. A 3-h treatment of the cells with 1 microM of colchicine, a microtubule depolymerizer, reversibly raised the proportion of intracellular GABA(A)R density by about 36% and decreased that of the cell surface receptors by 18% from respective control values, whereas the 3-h incubation with 2 microM of cytochalasin D, a microfilament disrupter, did not cause significant changes. These treatments failed to alter the total number of the (3)H-FNZ binding sites of the neurons and the affinity of the ligand. Moreover, the exposure to colchicine seemed to produce a stronger cytoplasmic immunostaining of the GABA(A)R alpha subunits in many neurons without affecting the total cellular level of the proteins, in accordance with the increased fraction of intracellular (3)H-FNZ binding. However, in the neurons exposed to cytochalasin D, there was an increase of around 28% in the total content of alpha(1)+51kDa proteins. In addition, the colchicine or cytochalasin D treatment inhibited approximately 21 or 18% of the rate of general protein synthesis in the culture. Notably, in situ hybridization assay showed that the GABA(A)R alpha(1) or alpha(2) mRNA was present in 92 +/- 2% or 94 +/- 2% of the cytochalasin D-treated neurons, both of which were higher than 71 +/- 2-74 +/- 3% of the control and colchicine-treated cells. The data suggest that by regulating the intracellular transport, the microtubular system participates in the maintenance of normal subcellular distribution of GABA(A)R in the neurons. By contrast, the organization of microfilaments may play a role in modulating the gene expression of GABA(A)R subunits.     

Actions of avermectin B1a on the γ-aminobutyric AcidA receptor and chloride channels in rat brain

The interaction of avermectin B_1a (AVM) with the γ-aminobutyric acid (GABA) receptor of rat brain was studied using radioactive ligand binding and tracer ion flux assays. Avermectin potentiated the binding of [³H]flunitrazepam and inhibited the binding of both [³H]muscimol and [³⁵S]t-butylbicyclo-phosphorothionate to the GABA_A receptor. Inhibition of muscimol binding by AVM suggested competitive displacement. Two kinds of ³⁶chloride (Cl) flux were studied. The ³⁶Cl efflux from preloaded microsacs was potentiated by AVM and was highly inhibited by the Cl-channel blocker 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid (DIDS). However, it was not potentiated by GABA nor was it sensitive to the convulsants picrotoxin or bicuculline. On the other hand, ³⁶Cl-influx measurement in a different microsac preparation of rat brain was very sensitive to GABA and other GABA-ergic drugs. Avermectin induced ³⁶Cl influx into these microsacs in a dose–dependent manner, but to only 35% of the maximal influx induced by GABA. The AVM-induced ³⁶Cl influx was totally blocked by bicuculline. It is suggested that AVM opens the GABA_A-receptor Cl channel by binding to the GABA recognition site and acting as a partial receptor agonist, and also opens a voltage–dependent Cl channel which is totally insensitive to GABA but is very sensitive to DIDS.     

Acrylamide disturbs the subcellular distribution of GABAA receptor in brain neurons

Mechanisms underlying the action of acrylamide on neurons were studied by monitoring the expression of GABA(A) receptor (R) in cultured brain neurons derived from chicken embryos. In situ trypsinization of the neurons and 3H-flunitrazepam binding assay were employed to examine the subcellular distribution of GABA(A)R. A 3-h exposure of the cultured neurons to 10 mM of acrylamide raised reversibly the proportion of intracellular (trypsin-resistant) 3H-flunitrazepam binding sites by about 48% and decreased cell surface binding 24% from respective control values, without altering total cellular binding and the affinity of the ligand. Moreover, the acrylamide treatment induced more intense perikaryal immunostaining of GABA(A)R alpha subunit proteins than that in control neurons but did not change the total level of cellular alpha immunostain, in accordance with the binding data. In the cell bodies of acrylamide-treated neurons, the level of neurofilament-200 kDa proteins was similar to control, whereas the tubulin protein content was significantly lowered approximately 51% from control, as revealed by quantifying the immunostained cytoskeletal elements. In addition, electron microscopic observations found reductions in the numbers of microtubules and neurofilaments in the perikarya of acrylamide-treated neurons. As exhibited by the 3H-leucine and 3H-monosaccharide incorporation experiments, the exposure to acrylamide inhibited the rate of general protein synthesis in the culture by 21%, while the rate of glycosylation remained unaltered. Furthermore, in situ hybridization analysis showed that acrylamide did not modify the expression of GABA(A)R alpha subunit mRNAs. Taken together, these data suggest that acrylamide may downregulate the microtubular system and disintegrate neurofilaments, and thereby block the intracellular transport of GABA(A)R, resulting in the accumulation of intracellular receptors.     

Heterodimerization of γ-aminobutyric acid B receptor subunits as revealed by the yeast two-hybrid system

Several lines of evidence suggested that the first gamma-aminobutyric acid B receptor to be cloned required an additional factor for functional expression. GABA(B1) was retained within the endoplasmic reticulum and failed to couple to signal transduction pathways on stimulation with agonists. In radioligand binding experiments it was found that although the affinity of antagonists showed a close agreement between rat brain membranes and membranes expressing the cloned receptor, agonist ligands were significantly weaker at recombinant receptors. Using the C-terminal tail as bait, a yeast two-hybrid screen was run against a human brain cDNA library and identified a second receptor, GABA(B2), as a major interacting protein. This interaction was confirmed by coimmunoprecipitation as well as extensive colocalization studies. Coexpression of the two seven-transmembrane proteins generated a fully functional receptor, which was expressed at the cell surface confirming the importance of receptor heterodimerization for GABA(B) receptor activity.     

Cloning and expression of the A2a adenosine receptor from guinea pig brain

A full-length complementary DNA (cDNA) clone encoding the guinea pig brain A₂ adenosine receptor has been isolated by polymerase chain reaction (PCR) and low-stringency-hybridization screening of a guinea pig brain cDNA library. This cDNA contains a long open reading frame encoding a 409-amino acid-residue protein which is highly homologous to the A₂ adenosine receptors previously cloned from other species. Hydrophobicity analysis of the deduced protein sequence reveals seven hydrophobic regions, characteristic of a member of the G-protein-coupled receptor superfamily. Radioligand binding assay and functional (GTPase and cAMP) assays of the receptor, transiently expressed in mammalian cells, demonstrate typical characteristics of the A₂ type adenosine receptor. The messenger RNA (mRNA) of this A₂ receptor is found in the brain, heart, kidney and spleen. Receptor autoradiography with [³H]CGS21680, a specific A₂ agonist, and in situ hybridization with A₂ cRNA probe in guinea pig brain indicate that the receptor is expressed exclusively in the caudate nucleus. The pharmacological profile and anatomical distribution of this receptor indicate that it is of the A_2a subtype. This work represents the first cloning of an A_2a receptor in a rodent species, offers a complete pharmacological characterization of the receptor and provides an anatomical comparison between binding profile and gene expression of the receptor.Abbreviations ADAC adenosine amine congener - BA N⁶-benzyladenosine - bp nucleotide base pair - cAMP cyclic adenosine 3,5-monophosphate - CCPA 2-chloro-N⁶-cyclopentyladenosine - CGS 21680 2-p-(2-carboxyethyl)phenethylamino-5-N-ethylcarboxamido adenosine hydrochloride - CHA N⁶-cyclohexyladenosine - CNS central nervous system - CPA N⁶-cyclohexyladenosine - CNS central nervous system - CPA N⁶-cyclopentyladenosine - CPX 8-cyclopentyl-1,3-dipropylxanthine - DME Dulbecco's modified Eagle's medium - DMPX 3,7-dimethyl-1-propargylxanthine - DPMX 1,3-dipropyl-7-methylxanthine - DPX 1,3-dipropyl-8-(2-amono-4-chlorophenyl)xanthine - FCS fetal calf serum - IBMX 3-isobutyl-1-methylxanthine - KHB Kreb-HEPES buffer - MECA 5-N-methylcarboxamidoadenosine - NECA 5-N-ethylcarboxamidoadenosine - D-PBS Dulbecco's phosphate buffered saline - PCR polymerase chain reaction - R-PIA R(–)-N⁶-(2-phenylisopropyl)adenosine - SSPE sodium chloride-sodium phosphate-EDTA buffer - TM transmembrane domain - XAC xanthine amine congener Special issue dedicated to Dr. Bernard W. Agranoff     

Assembly,trafficking and function of α1β2γ2 GABAA receptors are regulated by N‐terminal regions,in a subunit‐specific manner

GABA_A receptors are pentameric ligand‐gated ion channels that mediate inhibitory fast synaptic transmission in the central nervous system. Consistent with recent pentameric ligand‐gated ion channels structures, sequence analysis predicts an α‐helix near the N‐terminus of each GABA_A receptor subunit. Preceding each α‐helix are 8–36 additional residues, which we term the N‐terminal extension. In homomeric GABA_C receptors and nicotinic acetylcholine receptors, the N‐terminal α‐helix is functionally essential. Here, we determined the role of the N‐terminal extension and putative α‐helix in heteromeric α1β2γ2 GABA_A receptors. This role was most prominent in the α1 subunit, with deletion of the N‐terminal extension or further deletion of the putative α‐helix both dramatically reduced the number of functional receptors at the cell surface. Conversely, deletion of the β2 or γ2 N‐terminal extension had little effect on the number of functional cell surface receptors. Additional deletion of the putative α‐helix in the β2 or γ2 subunits did, however, decrease both functional cell surface receptors and incorporation of the γ2 subunit into mature receptors. In the β2 subunit only, α‐helix deletions affected GABA sensitivity and desensitization. Our findings demonstrate that N‐terminal extensions and α‐helices make key subunit‐specific contributions to assembly, consistent with both regions being involved in inter‐subunit interactions.

     

Localization of estrogen receptor‐α and ‐βmRNA in brain areas controlling sexual behavior in Japanese quail

Two estrogen receptors (ERs), denoted ERα and ERβ, have been identified in humans and various animal species, including the Japanese quail. Estrogens play a key role in sexual differentiation and in activation of sexual behavior in Japanese quail. The distribution of ERα in the brain of male and female adult quail has previously been studied using immunohistochemistry, whereas in situ hybridization has been employed to study the distribution of ERβ mRNA in males only. In this article, we used in situ hybridization to study the distribution of mRNAs for both ERα and ERβ in brain areas controlling sexual behavior of Japanese quail. Our results show that both ERα mRNA and ERβ mRNA are localized in areas important for sexual behavior, such as the preoptic area and associated limbic areas, in both males and females. Moreover, we found differences in distribution of mRNA for the two receptors in these areas. The results of this article support previously reported data and provide novel data on localization of ER mRNAs in adult quail brain of both sexes. © 2005 Wiley Periodicals, Inc. J Neurobiol, 2005     

The alteration of γ-aminobutyric acid-transaminase expression in the gerbil hippocampus induced by seizure

It is well established that GABA degradation may play a key role in epileptogenesis. However, whether or not the expression of GABA-transaminase (GABA-T), which catalyzes GABA degradation and participates in the neuronal metabolism via GABA shunt, changes chronologically after on-set of seizure remains to be clarified. To identify the change of GABA-T expression in seizure, GABA-T expression in the gerbil hippocampus, associated with different sequelae of spontaneous seizures, was investigated. The distribution pattern of GABA-T immunoreactive neurons in the hippocampus between the seizure-resistant and pre-seizure group of seizure sensitive gerbils was similar. Interestingly, at 30 min postictal, the enhancement of GABA-T immunoreactivity in the perikarya was apparently observed. This contrasted with the decline in GABA-T immunoreactivity in the granular and pyramidal layer. At 12–24 h postictal, GABA-T immunoreactivity in the hilar neurons had declined significantly. However, the GABA-T immunoreactivity in the granular layer increased. These findings suggest that in the gerbil, the alteration in GABA-T expressions may play an important role in the self-recovery mechanism from seizure attack via both GABA degradation and regulation of neuronal metabolism.     

The importance of valine 114 in ligand binding in β2‐adrenergic receptor

G‐protein coupled receptors (GPCRs) are transmembrane signaling molecules, with a majority of them performing important physiological roles. β₂‐Adrenergic receptor (β₂‐AR) is a well‐studied GPCRs that mediates natural responses to the hormones adrenaline and noradrenaline. Analysis of the ligand‐binding region of β₂‐AR using the recently solved high‐resolution crystal structures revealed a number of highly conserved amino acids that might be involved in ligand binding. However, detailed structure‐function studies on some of these residues have not been performed, and their role in ligand binding remains to be elucidated. In this study, we have investigated the structural and functional role of a highly conserved residue valine 114, in hamster β₂‐AR by site‐directed mutagenesis. We replaced V114 in hamster β₂‐AR with a number of amino acid residues carrying different functional groups. In addition to the complementary substitutions V114I and V114L, the V114C and V114E mutants also showed significant ligand binding and agonist dependent G‐protein activation. However, the V114G, V114T, V114S, and V114W mutants failed to bind ligand in a specific manner. Molecular modeling studies were conducted to interpret these results in structural terms. We propose that the replacement of V114 influences not only the interaction of the ethanolamine side‐chains but also the aryl‐ring of the ligands tested. Results from this study show that the size and orientation of the hydrophobic residue at position V114 in β₂‐AR affect binding of both agonists and antagonists, but it does not influence the receptor expression or folding.     

Regulation of c‐Ret,GFRα1, and GFRα2 in the substantia nigra Pars compacta in a rat model of Parkinson's disease

Glial cell line‐derived neurotrophic factor (GDNF) family members have been proposed as candidates for the treatment of Parkinson's disease because they protect nigral dopaminergic neurons against various types of insult. However, the efficiency of these factors depends on the availability of their receptors after damage. We evaluated the changes in the expression of c‐Ret, GFRα1, and GFRα2 in the substantia nigra pars compacta in a rat model of Parkinson's disease by in situ hybridization. Intrastriatal injection of 6‐hydroxydopamine (6‐OHDA) transiently increased c‐Ret and GFRα1 mRNA levels in the substantia nigra pars compacta at 1 day postlesion. At later time points, 3 and 6 days, the expression of c‐Ret and GFRα1 was downregulated. GFRα2 expression was differentially regulated, as it decreased only 6 days after 6‐OHDA injection. Triple‐labeling studies, using in situ hybridization for the GDNF family receptors and immunohistochemistry for neuronal or glial cell markers, showed that changes in the expression of c‐Ret, GFRα1, and GFRα2 in the substantia nigra pars compacta were localized to neurons. In conclusion, our results show that nigral neurons differentially regulate the expression of GDNF family receptors as a transient and compensatory response to 6‐OHDA lesion. © 2002 Wiley Periodicals, Inc. J Neurobiol 52: 343–351, 2002     

The versatility of the αβ T‐cell antigen receptor

The T‐cell antigen receptor is a heterodimeric αβ protein (TCR) expressed on the surface of T‐lymphocytes, with each chain of the TCR comprising three complementarity‐determining regions (CDRs) that collectively form the antigen‐binding site. Unlike antibodies, which are closely related proteins that recognize intact protein antigens, TCRs classically bind, via their CDR loops, to peptides (p) that are presented by molecules of the major histocompatibility complex (MHC). This TCR‐pMHC interaction is crucially important in cell‐mediated immunity, with the specificity in the cellular immune response being attributable to MHC polymorphism, an extensive TCR repertoire and a variable peptide cargo. The ensuing structural and biophysical studies within the TCR‐pMHC axis have been highly informative in understanding the fundamental events that underpin protective immunity and dysfunctional T‐cell responses that occur during autoimmunity. In addition, TCRs can recognize the CD1 family, a family of MHC‐related molecules that instead of presenting peptides are ideally suited to bind lipid‐based antigens. Structural studies within the CD1‐lipid antigen system are beginning to inform us how lipid antigens are specifically presented by CD1, and how such CD1‐lipid antigen complexes are recognized by the TCR. Moreover, it has recently been shown that certain TCRs can bind to vitamin B based metabolites that are bound to an MHC‐like molecule termed MR1. Thus, TCRs can recognize peptides, lipids, and small molecule metabolites, and here we review the basic principles underpinning this versatile and fascinating receptor recognition system that is vital to a host's survival.