Global ETD Search

41	A pharmacodynamic model of the role of 5-HT2A and GABAA receptors in the delay in the onset of action of SSRIS Chan, Patrick G. 01 January 2009 (has links) (PDF) Depression is a common neuropsychiatric illness with a lifetime prevalence of 17% in the United States. The disease can severely impact the daily living and quality of life in patients. The monoamine hypothesis of depression implicates the neurotransmitter serotonin as mediating the pathophysiology. Selective serotonin reuptake inhibitors (SSRIs), a popular and efficacious class of antidepressants, increase serotonin concentrations in the brain. However, full clinical benefit may not be obtained for four to six weeks. This period of waiting for SSRIs to work becomes quite daunting for patients. Research has focused on delineating the control mechanisms surrounding the dorsal raphé nucleus (DRN), the serotonergic control center located in the midbrain. Much evidence points to changes in several receptor systems as the underlying cause of the delay. One particular serotonin receptor, 5-HT 1A , has been established to play a role in affecting the time course of clinical effect. We have targeted another receptor as a possible contributor to the delay: the stimulatory 5-HT 2A heteroreceptors located on GABAergic interneurons of the DRN. The 5-HT 2A receptors of the GABAergic interneurons receive stimulatory input from serotonergic collaterals branching off the DRN serotonergic neurons. The resultant stimulation causes GABA release and inhibition of the serotonergic neurons via GABA A receptors of the DRN, completing a feedback loop. We hypothesize that the 5-HT 2A receptors desensitize under constant stimulation, as in the case with SSRI administration, and as a result contribute to the time delay in the onset of action of SSRIs. Using the microdialysis technique, various receptor agonists and antagonists were administered to examine receptor changes and its influence on serotonin release in male Wistar rats. Our results demonstrate that GABA A receptors exert a large inhibitory influence on serotonergic neurotransmission. Local GABA release results from 5-HT 2A receptor stimulation. Furthermore, serotonin appears to trend back towards basal levels, suggesting a possible desensitization process occurring under constant agonism of 5-HT 2A receptors. The development of our pharmacodynamic model quantitatively shows a slow desensitization process, which may also contribute to the time delay observed with the onset of action of SSRIs. Pharmacology Health and environmental sciences GABAA Selective serotonin reuptake inhibitors Serotonin Pharmacy and Pharmaceutical Sciences
42	A Mechanism-Based Model to Describe GABAA Receptor Trafficking and Benzodiazepine Pharmacoresistance during Status Epilepticus Merrill, Elaine Alice 18 September 2012 (has links) No description available. Pharmacology GABAA receptor PBPK/PD modeling receptor trafficking status epilepticus pharmacoresistance benzodiazepine
43	Brainstem Mechanisms Underlying Ingestion and Rejection Chen, Zhixiong 12 February 2003 (has links) No description available. Central pattern generator NMDA receptor Non-NMDA receptor GABAA receptor Glycine receptor Taste oromotor processing
44	Rôle des inhibitions corticales dans la dynamique temporelle des réponses neuronales dans le cortex auditif aux signaux de communication acoustiques / A Role for Cortical Inhibition in Shaping Temporal Dynamics of Neuronal Responses to Communication Sounds in the Auditory Cortex Gaucher, Quentin 11 December 2013 (has links) Depuis quelques années, l’étude du code neuronal impliqué dans la perception des signaux de communication acoustique est devenue un domaine de recherche considérable. La littérature récente de ce domaine suggère que la discrimination entre ces signaux reposerait plutôt sur une organisation des décharges neuronales en motifs temporels que sur des variations globales de taux de décharge. Ma thèse a eu pour objectif de déterminer dans quelle mesure une régulation des inhibitions corticales peut (i) changer les motifs temporels déclenchés par des vocalisations conspécifiques et hétérospécifiques et (ii) modifier l’information portée par ces motifs sur l’identité des vocalisations. Nous avons enregistré l’activité neuronale dans le cortex auditif de cobayes anesthésiés en 16 sites corticaux lors de la présentation d’un jeu de vocalisations, et avons partiellement bloqué les inhibitions corticales par des applications de Gabazine (4minutes, 10µm). Dans ces conditions, les réponses évoquées sont plus fortes et les motifs temporels plus marqués. L’information mutuelle quantifiée au niveau de chaque site cortical est augmentée mais l’information populationnelle au niveau de l’ensemble des 16 sites enregistrés n’est pas modifiée, un effet qui peut s’expliquer par le fait que la redondance entre les sites corticaux est augmentée. Nous avons ensuite évalué dans quelle mesure une modulation noradrénergique était susceptible de mimer les effets d’un blocage partiel des inhibitions. Bien que les agonistes utilisés (α1, α2 et ) aient tous induit des modifications des réponses évoquées et de la reproductibilité des motifs temporels, aucun d’entre eux n’a induit de changements importants de l’information portée par les réponses neuronales aux vocalisations. En revanche, les effets induits par la phenylephrine, un agoniste α1, sont vraisemblablement sous-tendus par une action sur les inhibitions intra-corticales, ce qui rend plausible l’hypothèse d’une modulation noradrénergique des inhibitions corticales. Il est donc envisageable que l’action coordonnée de plusieurs systèmes neuromodulateurs puisse moduler les inhibitions corticales et ainsi changer la quantité d’information portée par les neurones corticaux sur l’identité des stimuli à discriminer. / Over the last 10 years, the neural code involved in the perception of acoustic communication signals has become a large area of researches. The recent literature suggests that the discrimination between these signals relies more on the temporal organization of neuronal discharges rather than on global changes of firing rate. My PhD thesis aimed at determining to what extent the regulation of cortical inhibition may (i) change the temporal patterns triggered by conspecific and heterospecific vocalizations and (ii) modify the information carried by these patterns on the vocalization identity. Neuronal activity was recorded in the auditory cortex of anesthetized guinea pigs in 16 cortical sites during presentation of a set of vocalizations, and a partial blockage of intra-cortical inhibition was performed by Gabazine application (4 minutes, 10μm). Under these conditions, evoked responses were stronger and the temporal patterns were reinforced. Mutual information quantified at each cortical site was increased but the information computed at the populationnal level did not change, an effect that could be explained by the fact that the redundancy between cortical sites was increased. We then assessed to which extent the noradrenergic modulation can mimic the effects of a partial blockage of inhibitions. Although all the tested drugs modulated both the evoked responses and the spike-timing reliability, none of the noradrenergic agonists used here (α1, α2 and ) induced significant changes in the information carried by neuronal responses. However, the effects induced by phenylephrine, an α1 agonist, seemed to involve an action on the intra-cortical inhibition, which suggests that a noradrenergic modulation of cortical inhibition can operate in the auditory cortex. It is therefore possible to envision that the coordinated action of several neuromodulatory systems modulates cortical inhibition and thus changes the information carried by cortical neurons on the stimuli identity. Cortex auditif Inhibition Enregistrements multi-unitaires Gabazine Récepteurs GABAA Noradrénaline Vocalisations Alpha1 adrenocepteur Cobaye Auditory cortex Inhibition Multi-unit recordings Gabazine GABAA receptors Norepinephrine Vocalizations Alpha1 adrenoceptor Guinea pig
45	Caractérisation de la transmission GABAergique dans le globus pallidus externe chez des modèles rongeurs des maladies de Parkinson et de Huntington / Investigation of GABAergic neurotransmission in the external globus pallidus in rodent models of Parkinson and huntington’s diseases Chazalon, Marine 18 December 2015 (has links) Les ganglions de la base (GB) sont un ensemble de noyaux sous-corticaux impliqués dans les fonctions motrices, mnésiques et cognitives. Le globus pallidus externe (GPe) est un noyau GABAergique, qui tient la place de structure relais entre le striatum et le noyau sous-thalamique au sein du réseau des GB. Les changements de mode et de fréquence de décharge des neurones du GPe sont connus pour être les signatures électro-physiologiques des maladies de Parkinson (MP) et de Huntington (MH). Dans la MP, où les concentrations de GABA extracellulaires sont anormalement élevées dans le GPe, il est admis que la voie striato-pallidale (STR-GPe) est hyperactive, ce qui contribue à l’hypoactivité des neurones pallidaux. A l’inverse dans la MH, il est admis que l’hyperactivité des neurones du GPe est due à la dégénérescence de la voie STR-GPe levant la principale influence inhibitrice du GPe. Cependant, les mécanismes moléculaires impliqués dans ces changements d’activité pallidale sont encore peu connus. Nous avons donc entrepris des expériences de biologie moléculaire, d’immunohistochimie et d’électrophysiologie sur tranches, afin de mieux caractériser l’origine des modifications de transmission GABAergique conduisant aux changements d’activité électro-physiologique des neurones du GPe dans ces deux pathologies à l’aide de modèles animaux. Mes principaux résultats montrent l’apparition d’une inhibition tonique dans les neurones du GPe due à un déficit de recapture du GABA dans la MP et une réduction précoce de la transmission synaptique GABAergique dans la MH. Ces résultats suggèrent que les altérations de la transmission GABAergique contribuent à la physiopathologie de la MP et la MH. / The basal ganglia (BG) are a group of sub-cortical nuclei involved in motor, memory and cognitive functions. In the BG, the GABAergic external globus pallidus (GPe) holds a position of relay nucleus between the striatum (STR) and the sub thalamic nucleus within the indirect pathway of the BG. Modifications of rate and pattern of activity of this nucleus are known to be the electrophysiological signatures of Parkinson’s (PD) and Huntington’s diseases (HD). In PD, hyperactivity of the striato-pallidal (STR-GPe) pathway is thought to be responsible for the increase of the extracellular GABAergic concentrations in the GPe and participate to the hypoactivity of pallidal neurons observed in experimental Parkinsonism. In contrast, during HD, it is recognized that the hyperactivity of GPe neurons is due to the degeneration of striato-pallidal neurons and thus to the reduction of the main source of pallidal GABAergic inhibition. However, the molecular mechanisms involved in these modifications of pallidal activity are not well characterized. Therefore, using PD and HD animal models, the 6-OHDA rodents and the R6-1 transgenic mice respectively, we have performed molecular biology, immunohistochemistry and electrophysiological in vitro experiments in order to better understand the origin of GABAergic transmission alterations leading to changes in electrophysiological activity of GPe neurons into these two pathologies. My main results show the apparition of a tonic GABAergic inhibition due to a deficit of GABA uptake in PD and a early stage reduction of GABAergic synaptic transmission in HD. Altogether, these results suggest that alterations of GABAergic transmission contribute to the pathophysiology of PD and HD. Globus pallidus externe Patch-clamp Transmission synaptique Inhibition tonique Récepteurs GABAA extrasynaptiques Transporteurs du GABA Maladie de Parkinson Maladie de Huntington External globus pallidus Patch-clamp Synaptic transmission Tonic inhibition Extrasynaptic GABAA receptors GABA transporters Parkinson’s disease Huntington’s disease
46	Communication synaptique et non-synaptique entre neurones et cellules précurseurs d’oligodendrocytes dans le cortex somatosensoriel / Synaptic and non-synaptic communication between neurons and oligodendrocyte precursor cells in the somatosensory cortex Maldonado Rojas, Paloma P. 09 December 2013 (has links) Les cellules précurseur d'oligodendrocytes (CPOs) représentent la majeure source d'oligodendrocytesmyélinisants durant le développement post-natal. Ces progéniteurs, identifiés par l'expression du protéoglycane NG2, sont non seulement extrêmement abondants avant la myélinisation, mais ils persistent aussi dans le cerveau mature. À l'instar d'autres cellules non-neuronales, elles expriment un large panel de canaux ioniques et de récepteurs pour des neurotransmetteurs. Cependant, ils sont uniques de part leur capacité à recevoir de véritables contacts synaptiques neuronaux glutamatergiqueset GABAergiques. Durant cette thèse, nous avons caractérisé les propriétés électrophysiologiques des CPOs durant le développement post-natal du cortex en champ de tonneaux de la souris (premier mois post-natal). En effectuant des enregistrements de patch-clamp, des analyses par RT-PCR sur cellule unique et des analyses pharmacologiques, nous avons observé que la courbe I-V à rectification sortante devient linéaire durant le développement, résultant d'une régulation positive de l'expression des canaux potassiques de type Kir4.1. Dotés de ces canaux, les CPOs adultes sont capables de détecter les augmentations locales de potassium extracellulaire générées par l'activité neuronale. Cette régulation positive développementale des canaux Kir4.1 dans les CPOs révèle que ces cellules ont un gain de fonction durant le développement, leur conférant la capacité de communiquer avec les neurones via un mécanisme non-synaptique lié au potassium. Ce changement développemental soutient aussi l'idée que les CPOs sont probablement plus que des progéniteurs. Dans la deuxième partie de cette thèse, nous nous sommes intéressés à l'étude des patrons de connectivité du réseau GABAergique interneurones-CPOs dans le cortex en champ de tonneaux jeune (deuxième semaine post-natale). Dans un premier temps, nous avons tiré avantage de la haute précision latérale et axiale de la photolyse holographique en mono-photon pour stimuler les interneurones GABAergiques avec une résolution à l'échelle de la cellule, de manière à évoquer un potentiel d'action. Nous avons ensuite utilisé cette technique pour cartographier la connectivité entre interneurones et CPOs. Nous avons trouvé que la probabilité de connexion des CPOs est près de moitié moins que celle des cellules pyramidales, et implique plutôt une microcircuitrie locale. De plus, en effectuant des enregistrements pairés, nous avons observé que les CPOs sont contactés transitoirement par des interneurones à décharge rapide et à décharge régulière. Ces connections se caractérisents pour la présence d'un ou deux sites de libération uniquement. Étonnamment, les sites post-synaptiques contenant des récepteurs GABAA avec la sous-unité γ2 sont principalement connectés par les interneurones à décharge rapide, indiquant que ces cellules constituent une afférence spécifique auprès des CPOs. Ici nous décrivons pour la première fois l'émergence de réseaux corticaux spécifiques entre neurones et cellules non-neuronales. / Oligodendrocyte precursor cells (OPCs) are the main source of myelinating oligodendrocytes during postnatal development. These progenitors, identified by the expression of the proteoglycan NG2, are extremely abundant before myelination, but also persist in the mature brain. Similarly to other non-neuronal cells they express a wide range of ionic and ligand-gated ion channels. However, they are unique by their ability to receive truly glutamatergic and GABAergic synaptic contacts from neurons. During this thesis, we characterized the electrophysiological properties of OPCs during the postnatal development of the mouse somatosensory cortex (post postnatal month). By performing patch-clamp recordings, single-cell RT-PCR analyses and pharmacological approaches, we found that outwardly rectifying I-V curves become linear during development, as the result of an upregulation of Kir4.1 potassium channels. Endowed with these channels, adult OPCs are able to sense local extracellular potassium increases generated by neuronal activity. This developmental upregulation of Kir4.1 channels in OPCs revealed that these cells gain physiological properties during development, conferring them the capacity to communicate with neurons, via a non-synaptic potassium-mediated mechanism. This developmental change also supports the view that OPCs are probably more than simple progenitors. In the second part of this thesis, we were interested in study the connectivity patterns underlying the GABAergic interneuron-OPC network in the young somatosensory cortex (second postnatal week). First, we took advantage of the high lateral and axial precision of one-photon holographic photolysis to stimulate GABAergic interneurons at a single cell resolution in order to evoke an action potential. We then used this technique to map the connectivity between interneurons and OPCs. We found that the connectivity probability of OPCs was around half less than that of pyramidal cells and involved more local microcircuits. In addition, by performing paired-recordings, OPCs showed to be transiently contacted by fast-spiking (FSI) and non-fast-spiking (NFSI) interneurons, through single or double release sites. Interestingly, postsynaptic sites containing GABAA receptors with the γ2 subunit were predominantly connected by FSI, indicating that these cells provide a specific input to OPCs. Here we described for the first time the emergence of specific cortical network between neurons and non-neuronal cells. In conclusion, this thesis contributed to get a better understanding of the different modes of communication between neurons and OPCs and the establishment of new signaling mechanisms used by neurons to control the activity of these precursors. Cellules NG2 Précurseurs d'oligodendrocytes Interactions neurones-cellules Récepteurs GABAA Communication non-synaptique Photolyse holographique NG2 cells Oligodendrocyte precursors cells Neuron-OPC interactions GABAA receptors Non-synaptic communication Holographic photolysis 612.823 3
47	Rôle de la somatostatine dans la plasticité synaptique des interneurones somatostatinergiques de l’hippocampe Racine, Anne-Sophie 04 1900 (has links) Dans la région CA1 de l’hippocampe, une population d’interneurones exprimant la somatostatine (SOM-INs) est reconnue pour une potentialisation à long terme (PLT) dépendante des récepteurs métabotropes du glutamate de type 1a (mGluR1a) à leurs synapses excitatrices provenant des cellules pyramidales (CP). Il a récemment été démontré que cette PLT est induite par l’apprentissage contextuel lié à la peur, illustrant l’importance de cette PLT des SOM-INs dans l’apprentissage et la mémoire. Cependant, l’implication du neuropeptide somatostatine (SST) dans cette PLT demeure inconnue. Dans la présente étude, le rôle de la SST dans la PLT dépendante des mGluR1a a été étudié, tout comme, l’effet de la somatostatine-14 (SST-14) exogène aux synapses excitatrices des SOM-INs. Pour ce faire, des souris transgéniques exprimant la « enhanced yellow fluorescent protein » (eYFP) sous le contrôle du promoteur de la SST ont été utilisées. Des enregistrements électrophysiologiques jumelés à une approche pharmacologique ont été réalisés sur ces souris. Les résultats suggèrent que la SST-14 exogène engendre une PLT persistante grâce aux récepteurs à la somatostatine 1-5 (SST1-5), aux synapses excitatrices des SOM-INs, mais n’affecte pas les synapses des CP ou bien des interneurones exprimant la parvalbumine (PV-INs). Cette potentialisation induite par SST-14 était indépendante des récepteurs à l’acide N-méthyl-D-aspartique (NMDAR) et mGluR1a, dépendante de l’activité synaptique concomitante et inhibée par le blocage des récepteurs GABAA. De plus, la PLT dépendante des récepteurs mGluR1a a été affectée par l’inhibition des SST1-5 ou bien par un traitement avec de la cystéamine suggérant un rôle pour de la SST endogène dans cette PLT. Nos résultats suggèrent que la SST endogène pourrait contribuer à la PLT hébbienne aux synapses excitatrices des SOM-INs en contrôlant l’inhibition GABAA. La SST aurait alors un rôle dans la modulation de la plasticité à long terme des SOM-INs qui pourrait être important dans la mémoire dépendante de l’hippocampe. / The CA1 region of the hippocampus includes a population of GABAergic interneurons expressing somatostatin (SOM-INs). This type of interneurons displays a long-term potentiation (LTP) dependant on type 1a metabotropic glutamate receptors (mGluR1a) at their excitatory synapses from pyramidal cells (PC). It was recently demonstrated that mGluR1a dependent LTP can be induce by contextual fear learning showing an important role of this LTP in learning and memory. However, the implication of the peptide somatostatin (SST) in this LTP remains unknown. In the present study, the role of SST in mGluR1 dependent LTP and the effect of exogenous somatostatin-14 (SST-14) onto excitatory synapses of SOM-INs were investigated. To do this, transgenic mice expressing enhanced yellow fluorescent protein (eYFP) under the control of the promoter of SST were used. Patch clamp recordings and pharmacological approaches were used with these mice. Results suggested that application of exogenous SST-14 induces a LTP through type 1-5 somatostatin receptors (SST1-5) of excitatory synapses of SOM-INs but does not affect synapses of PC or parvalbumin-expressing interneurons (PV-INs). This LTP induced by SST-14 was independent of N-methyl-D-aspartate receptor (NMDAR) and mGluR1a, activity dependent, and prevented by blocking GABAA receptors. Furthermore, mGluR1a dependent LTP was prevented by inhibition of SST1-5 and by depletion of SST by cysteamine treatment, suggesting a role of endogenous SST in LTP. Our results indicate that endogenous SST may contribute to Hebbian LTP at excitatory synapses by controlling GABAA inhibition. SST would then have a role in regulating SOM-INs LTP that may be important for hippocampus dependent memory processes. Interneurones GABAergiques Patch clamp PLT hébbienne Récepteurs SST1-5 Inhibition GABAA GABAergic interneurons Hebbian LTP SST1-5 GABAA inhibition
48	Acute and Chronic Effects of Inhalants in Intracranial Self-stimulation Tracy, Matthew 01 January 2016 (has links) Inhalants are a loosely defined diverse group of volatile substances which people abuse. Despite widespread misuse of inhalants, there are limited preclinical methods available to study the reinforcement-like properties of inhalants. One procedure which has demonstrated substantial promise as a tool to investigate inhalant pharmacology is the intracranial self-stimulation (ICSS) procedure. ICSS utilizes pulses of electrical stimulation to the mesolimbic reward pathway to serve as a temporally defined and controlled operant reinforcer with a highly adjustable efficacy. The first aim of the project was to characterize the effects of commonly abused inhalants: including toluene, trichloroethane, nitrous oxide, isoflurane and R134a in ICSS. The second aim was to attenuate inhalant-facilitated ICSS by utilization of compounds which would attenuate the pharmacological actions of toluene on GABAA receptors. The low efficacy benzodiazepine negative modulator Ro15-4513 significantly attenuated the ability of toluene to facilitate ICSS without itself significantly altering baseline ICSS responding. Pretreatment with Ro15-4513 also attenuated methamphetamine ICSS even though there is no evidence of methamphetamine interacting with GABAA receptors. Given these unexpected results, I employed a microdialysis procedure to examine the effect of Ro15-4513 on methamphetamine stimulated dopamine release in the nucleus accumbens. Pretreatment with Ro15-4513 significantly attenuated methamphetamine stimulated dopamine release while having a negligible effect on dopamine release when administered alone. These results suggest that a modest level of benzodiazepine-site negative modulation can reduce the reinforcement enhancing effects of abused drugs regardless of their primary mechanism of action through allosteric modulation of GABAergic neurons within the mesolimbic pathway. Further, these results may have implications for expanding the examination of GABAA negative modulator medications beyond those trials currently being conducted with alcohol. Finally, the effects of chronic intermittent toluene exposure on ICSS and nesting behaviors were examined. Subjects were systemically exposed to air, chronic intermittent toluene (CIT), or escalating chronic intermittent (ECIT) toluene for 15 min at 3300 PPM toluene vapor per exposure. The results show that ECIT resulted in decreased overall responding in ICSS relative to air control and showed a tolerance-like effect to facilitatory effects of 3300 ppm toluene during ICSS compared to CIT group. These results indicate that escalating use of toluene produces reductions in its reward-like effects and may contribute to escalation to other drugs of abuse. icss toluene intracranial self-stimulation reward drug abuse drug GABA GABAA Behavioral Neurobiology Biological Psychology Experimental Analysis of Behavior Pharmacology
49	Neuronal hypothalamic plasticity in chicken Sallagundala, Nagaraja 05 April 2007 (has links) Aufgabe der elektrophysiologischen Studie zur Charakterisierung der neuronalen hypothalamischen Plastizität beim Haushuhn war es, den Einfluss des Alters sowie GABAerger Substanzen auf die Feuerrate und die Temperatursensitivität (thermischer Koeffizient: TC) von Hypothalamusneuronen mittels extrazellulärer Ableitungen in Hirnschnitten zu untersuchen. Im Vergleich zu adulten Vögeln und Säugetieren wurde bei juvenilen Hühnern eine hohe neuronale Kältesensitivität nachgewiesen, die offensichtlich eine spezifische Eigenschaft juveniler Vögel ist. Die Ontogenese der neuronalen hypothalamischen Thermosensitivität ist deutlich artspezifisch. Einige Neurone wiesen eine inherente Kältesensitivität auf. Eine mögliche zentrale Rolle kältesensitiver Neurone im Rahmen der Thermoregulation juveniler Hühner wurde postuliert. Muscimol und Baclofen hemmen signifikant die Feuerrate der Hypothalamusneurone, unabhängig von der jeweiligen Thermosensitivität. Demgegenüber bewirken Bicucullin und CGP35348 einem Anstieg der Feuerrate. Nur bei kältesensitiven Neuronen wurde der TC signifikant durch GABAB-Rezeptor-Liganden verändert (signifikant erhöht durch Baclofen und durch CGP35348 gehemmt). Der Effekt von Muscimol und Baclofen auf Feuerrate und TC wurde durch Co-Perfusion mit einer 10-fach höheren Konzentration der entsprechenden Antagonisten Bicucullin und CGP35348 aufgehoben. Der wesentliche GABAerge Einfluss auf thermosensitive und –insensitive Hypothalamusneurone ist mit dem bei Säugetieren nachgewiesenen vergleichbar. Der einzige Unterschied betrifft die GABAB-Rezeptor vermittelte Änderung des TC. Beim Hühnerküken betraf dies die kältesensitiven und beim Säugetier die wärmesensitiven Neurone. Der grundlegende Mechanismus der GABAergen Beeinflussung thermosensitiver und –insensitiver Neurone scheint einen älteren evolutionären Ursprung zu haben. Eine funktionelle Rolle GABAerger Substanzen im Rahmen der zentralen Kontrolle der Körpertemperatur beim Vogel ist möglich. / In the present electrophysiological studies, characterization of neuronal hypothalamic plasticity in the chicken aims to investigate the influence of age during development by extracellular recordings. High neuronal cold sensitivity has been found in juvenile chicken in contrast to adult mammals and birds. High hypothalamic cold sensitivity seems to be a specific characteristic feature in juvenile birds. Between species a species specificity of the early development of neuronal hypothalamic thermosensitivity could be clearly demonstrated. Existence of inherent nature to a certain degree suggests a possible thermoregulatory role of cold-sensitive neurons in chicken. The effects of the GABAergic substances on neuronal tonic activity (firing rate) and temperature sensitivity (temperature coefficient) in hypothalamic neurons have been examined. Muscimol and baclofen in equimolar concentrations significantly inhibited tonic activity, regardless of their type of thermosensitivity. In contrast bicuculline and CGP 35348 increased firing rate. Temperature coefficient was significantly changed by ligands of GABAB receptors, restricted to cold-sensitive neurons. The TC was significantly increased by baclofen and significantly decreased by CGP 35348. Effects of muscimol and baclofen on firing rate and TC were prevented by co-perfusion of appropriate antagonists bicuculline and CGP 35348, respectively in tenfold higher concentration. Thus the main effects of GABA in chicken are similar with that described in mammals. The only difference is in respect of the GABAB receptors mediated change restricted to cold-sensitive neurons in chicken but in mammals only seen in warm-sensitive neurons. However, the results indicate that the fundamental mechanism of GABAergic influence in chicken are conserved during evolution. The response of hypothalamic neurons to temperature changes suggest a possible functional role of GABAergic substances in the control of body temperature in birds. Haushuhn Neuronale Thermosensitivität Hirnschitte Feurrate juvenile Vögel Temperaturkoeffizient GABAA -Rezeptor-Agonist Muscimol GABAA -Rezeptor-Antagonist Bicuculline GABAB -Rezeptor-Agonist Baclofen GABAB -Rezeptor-Antagonist CGP35348. Chicken Neuronal thermosensitivity Brain slices Fire rate young chicken Temperature co-efficient GABAA -Receptor-Agonist Muscimol GABAA -Receptor-Antagonist Bicuculline GABAB -Receptor-Agonist Baclofen GABAB -Receptor-Antagonist CGP35348 570 Biowissenschaften, Biologie 32 Biologie YG 1804 ddc:570
50	Allopregnanolone effects on food intake and weight gain Holmberg, Ellinor January 2015 (has links) Background Obesity is currently one of the major causes of ill health and it is clear that overeatingis the cause of obesity. However, the actions of many endogenous factors that contribute to overeating are still not well understood. Gamma-aminobutyric acid (GABA)-ergic transmission has been shown to be of great importance for food intake regulation. The progesterone metabolite allopregnanolone is a potent positive GABAA receptor modulating steroid (GAMS) and in humans, elevated allopregnanolone levels have been suggested to be involved in increased food intake, and also with overweight and obesity. GABAA receptors that express the α2 and α3 subunits are proposed to be the main subtypes involved in food intake regulation. Therefore, the aims of the work in this thesis were to further investigate the effect of allopregnanolone on food intake, feeding behaviour, possible effects on weight gain and also to characterize a possible antagonist at α2β3γ2and α3β3γ2 GABAA receptors. Methods Allopregnanolone effects on food intake of different food items were recorded in male Wistar rats. Feeding patterns were analyzed. Food preference tests were also conducted and rats were repeatedly exposed to allopregnanolone under different feeding conditions to elucidate possible effects on body weight gain. To deeper investigate GABAA receptor subtypes suggested to be involved in food intake regulation, electrophysiological whole-cell patch-clamp recordings were performed to identify the specificity of the GAMS antagonist UC1020, at human α2β3γ2 and α3β3γ2 GABAA receptors expressed in HEK293-cells. Results Allopregnanolone increased the intake of standard chow, cookies and a high fat diet in male Wistar rats. Preferentially, allopregnanolone increased the rats´intake of the more calorie dense food type. Allopregnanolone reduced feeding latency and prolonged feeding duration. The increased chow intake induced by allopregnanolone was more pronounced at the beginning of the rats´ active period compared to the inactive. Repeated allopregnanolone administration during 5 consecutive days led to an increased body weight gain, more evident in schedule fed rats on a high fat diet. Both obesity prone and obesity resistant rats gained significantly more weight with repeated allopregnanolone exposure and the increased body weight gain correlated with increased food intake. The compound UC1020 was a potent antagonist of GAMS-enhanced GABA evoked currents at human α3β3γ2 GABAA receptors, whereas it had no effect at α2β3γ2 GABAA receptors. Conclusions Our findings indicate that allopregnanolone induced hyperphagia may be one of the endogenous factors involved in weight gain, especially when the diet is energy-rich. The compound UC1020 may prove useful for investigating the involvement of the α2 and α3 GABAA receptor subtypes in GAMS-induced hyperphagia. allopregnanolone neurosteroid GABA GABAA receptor food intake weight gain obesity hyperphagia diurnal rhythm schedule feeding high fat diet electrophysiology

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