Expression Of Neurotransmitter Receptors Research Articles

Exogenous brain-derived neurotrophic factor prevents postischemic downregulation of [ 3H]muscimol binding to GABA A receptors in the cortical penumbra

We have previously shown that exogenous application of brain-derived neurotrophic factor (BDNF) reduces infarct volume in the cortical ischemic penumbra after experimental focal ischemia [Stroke 31 (2000) 2212–2217]. Since BDNF is known to modulate the expression and function of various neurotransmitter receptors, we addressed the question whether BDNF may act via modification of postischemic ligand binding to excitatory NMDA and AMPA and/or inhibitory GABA A receptors, respectively. Transient focal cerebral ischemia was induced in male Wistar rats for 2 h using the suture occlusion technique. A period of 30 min after occlusion of the middle cerebral artery, BDNF (300 μg/kg per hour in vehicle; n=5) or vehicle alone ( n=5) was continuously infused intravenously for 3 h. Using quantitative receptor autoradiography, postischemic ligand binding of [ 3H]MK-801, [ 3H]AMPA and [ 3H]muscimol was analyzed in the ischemic core, the ischemic cortical penumbra and corresponding regions of the contralateral hemisphere. Transient focal ischemia caused a significant reduction of [ 3H]muscimol binding to GABA A receptors within the ischemic cortical penumbra of placebo-treated rats. This was largely prevented by exogenous application of BDNF. [ 3H]MK-801 and [ 3H]AMPA binding values were also reduced in the cortical penumbra and the corresponding area of the contralateral hemisphere. Our data suggest that the neuroprotective effect of BDNF against ischemic damage in the cortical penumbra may be mediated in part by maintained activity of the inhibitory GABAergic system which likely counteracts glutamate induced excitotoxicity.

Expression and function of presynaptic neurotransmitter receptors in the chemoafferent pathway of the rat carotid body.

Hypoxic chemotransmission in the carotid body (CB) is mediated by the release of neurotransmitters (NTs) from type I cells onto adjacent sensory (petrosal) nerve endings (Gonzalez et al. 1994; Urena et al. 1994). In the rat, there is strong evidence of a role for the co-release of fast-acting neurotransmitters, including acetylcholine (ACh) and ATP (Zhang et al. 2000), in chemosensory signalling. In contrast, little is known about the roles of NTs in mediating autoreceptor feedback mechanisms which are thought to play a role in modulating chemoreceptor output from the CB. Here, we present evidence for the involvement of two distinct NTs, ¦Ã-aminobutyric acid (GABA) and serotonin (5-HT), in mediating autoreceptor feedback onto type I cells during hypoxia. Although their actions are directly opposite, activation of receptors for either transmitter appears to regulate the activity of O2-sensitive K+ channels, such as the background K+ channel Kcnk3 (Buckler et al. 2000). 5-HT receptor activation also regulates the activity of the O2-sensitive large-conductance Ca2+-activated K+ channel (Peers, 1990). These results demonstrate the roles of NTs in regulating secretion from type I cells, by converging signals from different sources onto the same K+ channels involved in O2 sensing and control of the receptor potential.KeywordsCarotid BodyChemosensory SignallingPresynaptic DepolarisationCarotid Body TypeDepolarise Receptor PotentialThese keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Light-dependent development of asymmetry in the ipsilateral and contralateral thalamofugal visual projections of the chick

Light-exposure of the chick embryo induces development of asymmetry in the thalamofugal visual projections to the Wulst regions of the forebrain since the embryo is turned so that it occludes its left and not its right eye. This asymmetry can be reversed by occluding the embryo's right eye and exposing its left eye to light. Here we show that three sub-regions of the thalamus (two in the dorsolateral anterior thalami (DLA) and one more caudal) have differing asymmetries of contralateral and/or ipsilateral projections. Hence the effect of asymmetrical light stimulation is regionally specific within the thalamus. Lateralised light stimulation appears to promote the development of ipsilateral projections from DLA pars dorsolateralis pars anterioris and contralateral projections from the caudal regions (the nucleus superficialis parvocellularis especially) but it may suppress the development of contralateral projections from the nucleus dorsolateralis anterior thalami pars lateralis rostralis. We also show that the light stimulation causes lateralised expression of c-fos and receptors for neurotransmitters.

Expression of human epileptic temporal lobe neurotransmitter receptors in Xenopus oocytes: An innovative approach to study epilepsy.

Poly(A(+)) RNA was extracted from the temporal lobe (TL) of medically intractable epileptic patients which underwent surgical TL resection. Injection of this mRNA into Xenopus oocytes led to the expression of ionotropic receptors for gamma-aminobutyric acid (GABA), kainate (KAI) and alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA). Membrane currents elicited by GABA inverted polarity at -15 mV, close to the oocyte's chloride equilibrium potential, were inhibited by bicuculline, and were potentiated by pentobarbital and flunitrazepam. These basic characteristics were also displayed by GABA currents elicited in oocytes injected with mRNAs isolated from human TL glioma (TLG) or from mouse TL. However, the GABA receptors expressed by the epileptic TL mRNA exhibited some unusual properties, consisting in a rapid current run-down after repetitive GABA applications and a large EC(50) (125 microM). AMPA alone evoked very small or nil currents, whereas KAI induced larger currents. Nevertheless, upon cyclothiazide treatment, AMPA elicited substantial currents that, like the KAI currents, were inhibited by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX). Furthermore, the glutamate receptor 5 (GluR5) agonist, ATPA, failed to evoke an obvious current although both RT-PCR and Western blot analyses showed GluR5 expression in the epileptic TL. Oocytes injected with mouse TL or human TLG mRNAs generated KAI and AMPA currents similar to those evoked in oocytes injected with epileptic TL mRNA but, in contrast to these, the mouse TL and human TLG oocytes were also responsive to ATPA. Our findings are in accord with the concept that both a depression of GABA inhibition and a dysfunction of the KAI-receptor system maintain a high neuronal excitability that results in epileptic seizures.

Neuregulin 1 and Susceptibility to Schizophrenia

The cause of schizophrenia is unknown, but it has a significant genetic component. Pharmacologic studies, studies of gene expression in man, and studies of mouse mutants suggest involvement of glutamate and dopamine neurotransmitter systems. However, so far, strong association has not been found between schizophrenia and variants of the genes encoding components of these systems. Here, we report the results of a genomewide scan of schizophrenia families in Iceland; these results support previous work, done in five populations, showing that schizophrenia maps to chromosome 8p. Extensive fine-mapping of the 8p locus and haplotype-association analysis, supplemented by a transmission/disequilibrium test, identifies neuregulin 1 (NRG1) as a candidate gene for schizophrenia. NRG1 is expressed at central nervous system synapses and has a clear role in the expression and activation of neurotransmitter receptors, including glutamate receptors. Mutant mice heterozygous for either NRG1 or its receptor, ErbB4, show a behavioral phenotype that overlaps with mouse models for schizophrenia. Furthermore, NRG1 hypomorphs have fewer functional NMDA receptors than wild-type mice. We also demonstrate that the behavioral phenotypes of the NRG1 hypomorphs are partially reversible with clozapine, an atypical antipsychotic drug used to treat schizophrenia.

Expression of functional neurotransmitter receptors in Xenopus oocytes after injection of human brain membranes.

The Xenopus oocyte is a very powerful tool for studies of the structure and function of membrane proteins, e.g., messenger RNA extracted from the brain and injected into oocytes leads to the synthesis and membrane incorporation of many types of functional receptors and ion channels, and membrane vesicles from Torpedo electroplaques injected into oocytes fuse with the oocyte membrane and cause the appearance of functional Torpedo acetylcholine receptors and Cl(-) channels. This approach was developed further to transplant already assembled neurotransmitter receptors from human brain cells to the plasma membrane of Xenopus oocytes. Membranes isolated from the temporal neocortex of a patient, operated for intractable epilepsy, were injected into oocytes and, within a few hours, the oocyte membrane acquired functional neurotransmitter receptors to gamma-aminobutyric acid, alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid, kainate, and glycine. These receptors were also expressed in the plasma membrane of oocytes injected with mRNA extracted from the temporal neocortex of the same patient. All of this makes the Xenopus oocyte a more useful model than it already is for studies of the structure and function of many human membrane proteins and opens the way to novel pathophysiological investigations of some human brain disorders.

Altered Expression of Autonomic Neurotransmitter Receptors and Proliferative Responses in Lymphocytes from a Chronic Mild Stress Model of Depression: Effects of Fluoxetine

We studied β-adrenergic and muscarinic cholinergic receptor (MR) expression and proliferative response in lymphocytes from animals under chronic mild stress (CMS) model of depression (CMS animals). Animals were subjected to CMS (periods of food or water deprivation, changes in lighting conditions, tilted cage, etc.) for 12 weeks. CMS lymphocytes showed an altered mitogen-induced proliferation. CMS-B and -T lymphocytes showed an increment on β-adrenoceptor number and on intracellular responses to a β-agonist. CMS-T cells showed higher MR expression and lower cGMP responses than normal lymphocytes. MR were not detectable in normal B cells while CMS-B cells showed both MR expression and cGMP response. Beta and muscarinic stimulation influenced lymphocyte proliferative responses, in accordance with cAMP and cGMP responses. After 12 weeks of the CMS procedure, animals were treated with fluoxetine while the CMS procedure continued. Fluoxetine treatment reverted the alterations induced by CMS. These findings suggest a possible mechanism for the immune alterations found in depressive disorders and for the effect of fluoxetine treatment on immune response.

Solution Structure of Human GABAA Receptor-associated Protein GABARAP: IMPLICATIONS FOR BIOLOGICAL FUNCTION AND ITS REGULATION

Control of neurotransmitter receptor expression and delivery to the postsynaptic membrane is of critical importance for neural signal transduction at synapses. The gamma-aminobutyric acid, type A (GABA(A)) receptor-associated protein GABARAP was reported to have an important role for movement and sorting of GABA(A) receptor molecules to the postsynaptic membrane. GABARAP not only binds to GABA(A) receptor gamma2-subunit but also to tubulin, gephyrin, and ULK1. We present for the first time the high resolution structure of human GABARAP determined by nuclear magnetic resonance in aqueous solution. One part of the molecule, despite being well ordered and rigid on a MHz time scale, exists in at least two different conformations that interchange with each other on a time scale slower than 25 Hz. An important feature of the solution structure is the observation that amino- and carboxyl-terminal ends of the protein directly interact with each other, which is not seen in recently reported crystal structures. The possible biological relevance of these observations for the regulation of GABARAP interactions and functions is discussed.

Biochemical and physiological mechanisms of female genital sexual arousal.

Limited studies are available concerning physiological and biochemical mechanisms involved in female sexual function and dysfunction. The paucity of physiological and biochemical data pertaining to genital sexual arousal function is attributed, in part, to lack of reliable experimental models and tools for the investigation of female sexual arousal. This review summarizes research efforts from a number of laboratories in which several experimental models have been established. These include the development of in vivo animal models, organ bath studies, and the establishment of cell cultures. The availability of such experimental model systems have facilitated efforts aimed at defining the neurotransmitters responsible for vaginal smooth muscle relaxation, the role of sex steroid hormones and their receptors in modulating genital hemodynamics, smooth muscle contractility, and neurotransmitter receptor expression. A comprehensive and integral understanding of female sexual function requires detailed investigation of the vascular, neurological (central and peripheral), and structural components of this complex physiological process.

Evaluation of the tetracycline- and ecdysone-inducible systems for expression of neurotransmitter receptors in mammalian cells.

Establishing a stable cell line that expresses a particular protein of interest is often a laborious and time-consuming experience. With constitutive expression systems, a gradual loss of the highly expressing clones over a given time span and/or a severe counter-selection due to toxicity of the expressed protein for the host cell line are major drawbacks. In both cases, inducible expression systems offer a valuable alternative. Over the years, many regulated expression systems have been developed and evaluated. In the present study, we compare the efficiency, the advantages and the drawbacks of a tetracycline- and an ecdysone-inducible system for expression of the reporter protein chloramphenicol acetyltransferase and of different G-protein-coupled serotonin (5-HT) receptors. A high level of expression of different 5-HT receptors was obtained with the tetracycline-inducible system. In the cell line L929, which stably expresses the tetracycline-responsive transactivator, a maximum ligand binding of 20,000 and 9500 fmol/mg protein was measured for the h5-HT(1B) and h5-ht(1F) receptors, respectively. In the HEK293rtTA cell line, levels of 15,700, 3000, and 9100 fmol bound ligand/mg protein were obtained for the h5-HT(1B), h5-ht(1F) and h5-HT(4b) receptors, respectively. These high expression levels remained stable for several months of continuous culture. Although the ecdysone-inducible expression system was useful for tightly regulated expression, the levels were far lower than those obtained with the tetracycline system (e.g. 640 fmol bound ligand/mg protein for the h5-ht(1F) receptor in HEK293EcR).

Maturational Aspects of Epilepsy Mechanisms and Consequences for the Immature Brain

Maturational Aspects of Epilepsy Mechanisms and Consequences for the Immature Brain

Maturation of channels and receptors: Consequences for excitability

Clinical studies have documented that the behavioral features and pathophysiology of epilepsy in the young are not the same as in the adult. Seizure frequency is, especially high in the newborn, and an age-dependent predisposition to seizures may influence or determine the appearance of epileptic disorders later in life. Maturational changes in cortical circuits as well as in neurotransmitter receptor and ion channel function likely underlie these developmental differences and should be taken into consideration when trying to identify the cellular mechanisms of seizure initiation. These maturational changes must also be considered when designing or implementing antiepileptic therapies as therapeutic interventions may produce different effects at different ages. This chapter provides an overview of neocortical development and organization. The expression, maturation, activation, and function of ion channels and neurotransmitter receptors in developing neurons are considered. The chapter discusses the relationship of receptor and channel maturation to epileptogenesis and illustrates this with several examples of mutations in channel or receptor proteins that lead to epilepsy.

Regulation of Transcription in the Neuronal Nicotinic Receptor Subunit Gene Cluster by a Neuron-selective Enhancer and ETS Domain Factors

Expression of neurotransmitter receptors encoded by the nicotinic acetylcholine receptor (nAchR) subunit gene cluster depends on coexpression of the beta4, alpha3, and alpha5 subunits in certain kinds of neurons. One way in which coexpression might be achieved is through the regulation of promoters in the cluster by neuron-selective enhancers. The beta43' enhancer is located between the beta4 and alpha3 promoters and it directs cell type-specific expression in cell lines. It is not known, however, whether beta43' is active in neurons. Therefore, we assayed beta43' in dissociated rat sympathetic ganglia cultures, which contain nAchR-positive neurons as well as nAchR-negative non-neuronal cells. Reporters controlled by the alpha3 promoter and beta43' were expressed in a neuron-selective manner; greater than 90% and up to 100% of luciferase expression was detected in neurons. Neuron selectivity was maintained when beta43' was placed next to ubiquitously active viral promoters. In contrast, replacing beta43' with the SV40 enhancer eliminated neuron selectivity. The enhancer is composed of at least two separate but functionally interdependent elements, each of which interacts with a different type of ETS domain factor. These findings support a model in which beta43' controls neuronal expression of one or more genes in the cluster through interactions with a combination of ETS factors.

A minimal promoter for the GABA(A) receptor alpha6-subunit gene controls tissue specificity.

The ability of nerve cells to regulate the expression of specific neurotransmitter receptors is of central importance to nervous system function, but little is known about the DNA elements that mediate neuron specific gene expression. The type A gamma-aminobutyric acid (GABA(A)) receptor alpha6-subunit gene, which is expressed exclusively in cerebellar granule cells, presents a unique opportunity to study the cis elements involved in restricting gene expression to a distinct neuronal population. In an effort to identify the regulatory elements that govern cerebellar granule cell-specific gene expression, the proximal 5' flanking regions for the human, rat, and mouse alpha6 genes were cloned and sequenced, and a major transcriptional initiation site was identified in the rodent genes. Functional analysis of rat alpha6 gene-reporter constructs in primary neuronal cultures reveals that a 155-bp TATA-less promoter region (-130 to +25 bp) constitutes a minimal promoter that can drive cerebellar granule cell-specific expression. Internal deletion and decoy competition studies demonstrate that the minimal promoter contains a 60-bp region (-130 to -70 bp) that is critical for enhanced promoter activity in cerebellar granule cells. Activity of the compromised promoter containing the deletion cannot be rescued by placing the 60-bp region downstream of the reporter gene, demonstrating that it is not a classical enhancer but rather a positionally dependent regulator. An additional cerebellar-specific activating sequence is located between -324 and -130 bp, and a downstream negative regulatory region (+158 to +294) has been shown to be active in fibroblasts but inactive in cerebellar granule cells. Taken together, the results suggest a possible mechanism for the control of cerebellar granule cell-specific expression of the GABA(A) receptor alpha6 subunit gene.

154. Differential effects of antipsychotics on neurotransmitter receptor expression

154. Differential effects of antipsychotics on neurotransmitter receptor expression

7] Reduction of neurotransmitter receptor and G-protein expression in vivo and in vitro by antisense oligodeoxynucleotide treatment

The use of antisense oligodeoxynucleotides (ODNs) to reduce or eliminate the expression of specific proteins has become an increasingly important research tool. Although there is some disagreement about the precise mechanism of its action, the exquisite specificity of the ODN for its target is hardly disputed. The increased popularity and utilization of this approach have also spurred the establishment of many new businesses dedicated to the custom synthesis of antisense ODNs, in any number of shapes, forms, and styles, all at increasingly more affordable rates. This combination of specificity, availability, and affordability has allowed more and more investigators to utilize this molecular approach without the added expense of establishing a costly traditional molecular biology dimension within their laboratories. The use of ODNs has been especially fruitful when applied to neurotransmitter receptors and components of second-messenger systems and has allowed addressing questions about receptor/second-messenger interactions and second-messenger-mediated downstream events that have been difficult to answer. This chapter describes how antisense ODNs may be used in cultured cell lines and in intact animals to reduce the expression of neurotransmitter receptors and glyco (G) proteins.

Up-regulation of the metabotropic glutamate receptor mGluR4 in hippocampal neurons with reduced seizure vulnerability

Selective hippocampal cell loss and altered neurotransmitter receptor expression have been proposed as pathogenic mechanisms in the development of chronic mesial temporal lobe epilepsy (TLE). Studies in animal models point to metabotropic glutamate receptors (mGluRs) as modulators of hippocampal epileptogenesis. In addition, mGluRs may constitute specific targets for the development of novel anticonvulsive drugs. As mGluR4 represents an inhibitory class III mGluR associated with the reduction of intracellular cyclic AMP levels and calcium influx, we have analyzed the regional and cellular expression of mGluR4 in surgical hippocampal specimens obtained from patients with TLE by using immunohistochemistry and in situ hybridization. Although the hippocampi of control specimens (n = 11) were almost devoid of mGluR4 immunolabeling, all TLE specimens (n = 35) showed a striking up-regulation of mGluR4 immunoreactivity, in particular within the dentate gyrus. Immunoelectron microscopy localized the receptor protein to the periphery of presynaptic and postsynaptic membranes. In situ hybridization revealed increased transcript levels of mGluR4 in dentate granule cells and residual CA4 neurons of TLE specimens compared with controls. Our results suggest a potential role of mGluR4 in counteracting excitatory hippocampal activity and in modulating seizure-associated vulnerability of hippocampal neurons. These data may also provide a basis for pharmacological studies of mGluR4 agonists as potential novel drugs in the treatment of TLE.

The importance of being receptive

Neuroendocrine system and immune system can communicate via the use of soluble mediators like hormones, neurotransmitters and cytokines. The level of mediators secreted by either of these systems creates the milieu in which immune and neuroendocrine responses take place. For adequate communication between the systems, receptors for hormones, neurotransmitters and cytokines are required. This review describes the role of regulated expression and function of receptors for hormones and neurotransmitters within the immune system in neuroendocrine-immune communication.

Development of peripheral autonomic synapses: neurotransmitter receptors, neuroeffector associations and neural influences.

1. The functional innervation of autonomic target tissues occurs early during development, at a time when both the nerves and post-synaptic target tissues are still differentiating. 2. Physiological responses appear soon after the arrival of the first fibres when uptake and release mechanisms within the nerves are already functional. Initial responses differ from those in the mature animal, both in the form and, frequently, in the subtypes of receptors involved. 3. Results of a number of studies suggest that the initial expression of neurotransmitter receptors during development is largely independent of neural influences. Changes recorded in neurotransmitter receptor expression during development appear to be similarly independent of neural influences. 4. While signal transduction pathways coupling adrenergic neurotransmitter receptors to effector responses appear to develop independently of the nerves, the efficient coupling of muscarinic receptors often requires the action of the neurotransmitter, acetylcholine. 5. During the period of synapse formation, the neural plexus continues to expand. While developing varicosities can release the neurotransmitter, the capacity for neurotransmitter retention appears to be restricted. Developmental changes in the neurotransmitters that produce functional responses, while well known in the sweat glands, may also be seen in more subtle forms in other target tissues. 6. Ultrastructural studies suggest that close physical associations between the membranes of the release sites of the developing nerves and the target cells may form early during development when physiological responses are still immature. These close associations could enable more specific reciprocal interactions between nerves and target cells involving known and novel growth factors, neuropeptides and cytokines important in shaping the mature synaptic characteristics.

Altered neurotransmitter receptor expression in transgenic mouse models of Huntington's disease.

Alterations in neurotransmitter receptors are a pathological hallmark of the neurodegeneration seen in Huntington's disease (HD). However, the significance of these alterations has been uncertain, possibly reflecting simply the loss of brain cells. It is not known for certain whether the alteration of neurotransmitter receptors occurs before the onset of symptoms in human HD. Recently we developed transgenic mice that contain a portion of a human HD gene and develop a progressive abnormal neurological phenotype. Neurotransmitter receptors that are altered in HD (receptors for glutamate, dopamine, acetylcholine and adenosine) are decreased in the brain transgenic mice, in some cases before the onset of behavioural or motor symptoms. In transgenic mice, neurotransmitter receptor alterations occur before neuronal death. Further, receptor alterations are selective in that certain receptors, namely N-methyl-D-aspartate and gamma-aminobutyric acid receptors, are unaltered. Finally, receptor decreases are preceded by selective decreases in the corresponding mRNA species, suggesting the altered transcription of specific genes. These results suggest that (i) receptor decreases precede, and therefore might contribute to, the development of clinical symptoms, and (ii) altered transcription of specific genes might be a key pathological mechanism in HD.