Global ETD Search

1	Post- and Presynaptic GABA(B) Receptor Activation in Neonatal Rat Rostral Ventrolateral Medulla Neurons in Vitro Lin, H. H., Dun, N. J. 21 May 1998 (has links) Whole-cell patch recordings were made from immature (six- to 12-day- old) rat rostral ventrolateral medulla neurons in brainstem slices. GABA or the specific GABA(B) receptor agonist (-)baclofen (10-50 μM) by superfusion or by pressure ejection induced an outward current or a hyperpolarization, which persisted in a tetrodotoxin (0.3 μM)-containing Krebs' solution in nearly every cell tested. The GABA(B) receptor antagonists 2-hydroxy saclofen (50-200 μM) and CGP 35348 (50-200 μM) dose-dependently suppressed baclofen- currents. Baclofen-currents were suppressed by barium (1 mM) but not by tetraethylammonium (20 mM), low Ca2+ (0.24 mM) solution or in a solution containing the Ca2+ chelator BAPTA-AM (10 μM). The outward current had an estimated reversal potential of -98, -77 and -52 mV in 3.1, 7 and 15 mM [K+](o). Pre-incubation of slices with pertussis toxin (500 μg/ml for 5-7 h) or intracellular dialysis with GDP-β-S (500 μM) markedly reduced baclofen-currents. Baclofen in low concentrations (1-3 μM) that caused slight or no change of holding currents and of inward or outward currents induced by exogenously applied glutamate or glycine/GABA, decreased excitatory and inhibitory postsynaptic currents by an average of 86.5 ± 4.3% and 78.4 ± 2.7%. The GABA(B) antagonist CGP 35348 (100 μM) increased the excitatory postsynaptic currents by an average of 64%, without causing a significant change in holding currents in 10/18 cells tested. Our results indicate the presence of post- and presynaptic GABA(B) receptors in the rostral ventrolateral medulla neurons. Activation of postsynaptic GABA(B) receptors induces an outward K+ current which is barium-sensitive, Ca2+- independent and may be coupled to a pertussis-sensitive G-protein. Activation of presynaptic GABA(B) receptors attenuates excitatory or inhibitory synaptic transmission. More importantly, the observation that CGP 35348 enhanced excitatory synaptic currents implies a removal of tonic activation of presynaptic GABA(B) receptors by endogenously released GABA (disinhibition), supporting the hypothesis that these receptors may have a physiological role in regulating the input and output ratio in a subset of rostral ventrolateral medulla neurons in vivo. baclofen GABA GABA(B) receptors medulla brainstem pre- and postsynaptic mechanism
2	Mecanismos neurais envolvidos no retardo do esvaziamento gástrico de íiquidos em ratos induzido através do infarto recente do miocardio / Neural mechanisms involved in the delay of gastric emptying of liquids in rats induced by myocardial infarction recent Ramirez Nuñez, Wilson Ranú, 1973- 20 August 2004 (has links) Orientador: Eros Antonio de Almeida / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-20T19:20:03Z (GMT). No. of bitstreams: 1 RamirezNunez_WilsonRanu_D.pdf: 1943462 bytes, checksum: 1cb7938d9770774612068d3048db5b0e (MD5) Previous issue date: 2012 / Resumo: O esvaziamento gástrico (EG) consiste na transferência ordenada do conteúdo do estômago para o duodeno, Situações patológicas como alterações hemodinâmicas modificam a velocidade do E.G. e função motora do trato gastrointestinal. O infarto do miocárdio determina retarde do E.G. em ratos, possivelmente pelo estresse causado pela ligadura da artéria coronária. O sistema nervoso central (SNC) afeta as funções motora e secretora gastrintestinais, frente a uma situação de estresse existe aumento da retenção gástrica (RG) induzindo o retarde do E.G. O sistema parassimpático pode estar envolvido neste fenômeno. Por outro lado o sistema simpático controla o E.G., interrompendo a motilidade e a secreção, frente a uma situação de estresse como a do infarto do miocárdio o retarde do E.G., pode estar relacionado à atuação desse sistema. O objetivo deste trabalho foi Avaliar complacência gástrica (CG) em ratos submetidos a infarto recente do miocárdio, participação do nervo vago, sistema nervos simpático, efeito da injeção intra-cerebro-ventricular de GABAb e efeito da lesão do núcleo paraventricular no retarde do EG observado no infarto recente do miocárdio em ratos. Utilizados ratos Wistar, machos, entre 220 - 300g, adaptados ás condições do laboratório, divididos em 3 grupos: grupo INF; grupo SH e grupo NA. Infarto realizado por ligadura da artéria coronária descendente anterior esquerda. Animais após cirurgia permaneceram em jejum alimentar recebendo água ad libitum. Vinte e quatro horas após foi avaliado EG de 1,5 ml/100g de peso do animal de uma refeição de prova (RP) salina marcada com fenol vermelho. EG foi avaliado indiretamente, através da determinação da % de retenção gástrica (RG) da RP, 10 min. após administração orogástrica. Resultados mostraram que para o estudo da complacência gástrica não houve diferença significativa de pressão intragástrica entre os três grupos, nos três pontos de medida da pressão intragástrica (PIG) e em complementação as CGs não apresentaram diferenças significativas quando comparados entre si. No estudo da Vagotomia subdiafragmatica houve diferença significativa das RG (%) entre os subgrupos SH+Sh vs SH+Inf, o subgrupo Vgx+Inf apresentou diferença significativa em relação ao subgrupo SH+Inf e não diferiu do subgrupo Vgx+Sh. Para o estudo do efeito da injeção intra-cerebro-ventricular de GABAb houve diferença significativa entre os grupos SH+Sal e SH+Bac e Inf+Sal e Inf+Bac. No estudo da Simpatectomia química, grupo Inf+Sal apresentou diferença significativa quando comparados aos ratos SH+Sal, e grupo Inf+Pra com grupo SH+Sal não apresentaram diferenças significativas. O grupo Inf+Pra e Inf+Sal apresentaram diferença significativa e ratos SH+Pra e SH+Sal apresentaram diferença significativa quando comparados, No estudo da lesão do Núcleo paraventricular houve diferença significativa das RG (%) entre os subgrupos SH+Sh vs SH+Inf, os grupos PVN+Inf e SH+Inf apresentaram diferença significativa. Conclusões: 1) infarto recente do miocárdio não induz modificações no tônus gástrico em ratos, 2) Existe participação do nervo vago no retarde do EG causado pelo infarto recente do miocárdio, 3) Retardo EG mostrado pelos ratos infartados tem participação, pelo menos em parte, dos receptores alpha-1 adrenérgicos do sistema nervos simpático. 4) Existe participação do núcleo paraventricular no retardo do EG induzido pelo infarto recente do miocárdio / Abstract: Gastric emptying (GE) is the orderly transfer of stomach contents into the duodenum, pathological situations as hemodynamic changes modify GE speed and motor function of the gastrointestinal tract. Myocardial infarction determines GE delayed in rats, possibly due to stress caused by coronary artery ligation. Central nervous system (CNS) affects gastrointestinal secretory and motor functions, in a stressful situation there is increased gastric retention (GR) inducing GE delay. Parasympathetic system may be involved in this phenomenon. On the other hand sympathetic nervous system controls GE, disrupting motility and secretion, compared to a stressful situation such as myocardial infarction, GE delay, may be related to performance of this system. The objective of this study was to evaluate gastric compliance (GC) in rats submitted to recent myocardial infarction, involvement of vagus nerve, sympathetic nervous system, intra-cerebro-ventricular of GABAb injectin effect and paraventricular nucleus lesion effect on GE delay observed in recent myocardial infarction in rats. Used male Wistar rats, between 220-300g, adapted to laboratory conditions, divided into three groups: INF, SH and NA groups. Infarction performed by left anterior descending coronary artery ligation. After surgery, animals were fasted receiving water ad libitum. Twenty four hours after was evaluated GE of 1.5ml/100g body weight of a saline test meal (TM) labeled with red phenol. GE was indirectly estimated by determining % of gastric retention (GR) of test meal. 10 min. after orogastric administration. Results showed that gastric compliance study there was no significant difference in intragastric pressure between the three groups, in the three points of measurement of intragastric pressure (IGP) and complementation in GC showed no significant differences when compared with each other. In subdiaphragmatic vagotomy study, significant difference of GR (%) between subgroups SH+Sh vs SH+Inf, subgroup Vgx+Inf significant difference in the subgroup SH+Inf and did not differ in subgroup Vgx+Sh. To study the effect of intracerebroventricular injection of GABAb significant difference between groups SH+Sal vs SH+Bac and Inf+Sal vs Inf+Bac. To study the chemical simpatectomy by prazosin, the Inf+Sal group showed significant difference when compared to SH+Sal rats, and the group Inf+Pra with SH+Sal group showed no significant difference. The group Inf+Pra and Inf+Sal showed significant differences and the rats SH+Pra and SH+Sal showed significant difference when compared, for the study of the lesion of paraventricular nucleus of GR significant difference (%) between subgroups SH+Sh vs SH+Inf, the group PVN+Inf and SH+Inf showed significant difference. Conclusions: 1) recent myocardial infarction does not induce changes in gastric tone in rats, 2) there is involvement of the vagus nerve in GE delay caused by recent myocardial infarction, 3) GE delayed in infracted rats have participation, at least in part, of alpha-1 adrenergic receptors of the sympathetic nervous system, 4) there is participation of the paraventricular nucleus of GE delayed induced by recent myocardial infarction / Doutorado / Ciencias Basicas / Doutor em Clínica Médica Esvaziamento gástrico Infarto do miocárdio Núcleo hipotalâmico paraventricular Receptores adrenérgicos Receptores de GABA-B Gastric Emptying Myocardial infarction Paraventricular hypothalamic nucleus Receptors, Adrenergic Receptors, GABA-B
3	GABA-b receptors and calcium homeostasis in medullo-spinal CSF-contacting neurons / Récepteurs GABA-b et homéostasie calcique dans les neurones qui contactent le LCR médullo-spinal Jurcic, Nina 20 May 2019 (has links) Au niveau du canal central (CC) du tronc cérébral et de la moelle épinière, on trouve des neurones au contact avec le liquide céphalorachidien (Nc-LCR). Les Nc-LCR sont GABAergiques et projettent une seule dendrite dans le CC qui se termine par une large protrusion. Ils expriment sélectivement le canal PKD2L1 pour lequel des fonctions de chimio- et mécanorécepteur ont été démontrées. Compte tenu de leur localisation, de leur morphologie et de l’expression sélective de PKD2L1, les Nc-LCR représenteraient une nouvelle population de neurones sensoriels dans le SNC. Au cours de ma thèse, je me suis concentrée sur la caractérisation des canaux Ca2+ et les mécanismes de signalisation Ca2+ dans les Nc-LCR bulbo-spinaux de souris. Je rapporte que les Nc-LCR expriment des canaux Ca2+ qui sont modulés par les récepteurs métabotropiques GABAB et muscarinique. Je montre aussi l'implication des stocks intracellulaires dans la régulation du Ca2+ intracellulaire. Ensuite, je démontre pour la première fois la relation fonctionnelle entre la protrusion et le soma et indique que la protrusion serait dépourvu de conductance ionique active. Enfin, pour aborder le rôle des Nc-LCR, j'ai développé des modèles chimiogénétiques (DREADDs) et optogénétiques (channelrhodopsin) chez la souris afin de manipuler sélectivement l'activité Nc-LCR. Dans l'ensemble, les résultats de mon étude de doctorat contribuent à mieux comprendre les Nc-LCR bulbo-spinaux des mammifères en en contribuant à la caractérisation de leur physiologie et modulation. Ils ouvrent également la voie à de futures études qui permettront de démontrer le rôle de cette population neuronale dans la régulation de l'activité du SNC. / Cerebrospinal fluid-contacting neurons (CSF-cNs) located in the ependymal region around the central canal (CC) in the brainstem and the spinal cord are GABAergic neurons that project a single dendrite to the CSF and ends with a large protrusion. They selectively express PKD2L1 channel suggested to act as chemo- and mechanoreceptor. Considering their localization, morphology and selective expression of PKD2L1 channel, CSF-cNs would represent a novel population of sensory neurons within the CNS. To better understand the role of CSF-cNs in mammals, it is necessary to describe the physiological properties and modulation of CFS-cNs. In the present study, I focused on Ca2+ channels and Ca2+ signaling mechanisms in mouse medullo-spinal CSF-cNs. I report that Ca2+ channels in CSF-cNs undergo modulation by metabotropic GABAB and muscarinic acetylcholine receptors. I further show the involvement of intracellular Ca2+ stores in the regulation of intracellular Ca2+. Next, I demonstrate for the first time functional relationship between bud and soma and indicate that the bud would be devoid of active ionic conductance. Finally, to address the role of CSF-cNs, I developed chemogenetic (DREADDs) and optogenetic (channelrhodopsin) mice models to be able to selectively manipulate CSF-cN activity. Altogether, the results of my PhD study contribute to better understanding mammalian medullo-spinal CSF-cNs by providing valuable information on their physiology and modulation. They also set ground for further studies carried out in ex-vivo preparation or in vivo models to demonstrate their role in the regulation of CNS activity. Neurones au contact du LCR PKD2L1 canal Calcium Récepteur GABA-B Souris Moelle épinière CSF-Contacting neurons PKD2L1 channel Calcium GABA-B receptor Mouse Spinal cord
4	GABAB and cannabinoid receptors in substantia nigra pars reticulata. January 1998 (has links) by Priscilla, Ka-Yee Chan. / Thesis (M.Phil.)--Chinese University of Hong Kong, 1998. / Includes bibliographical references (leaves 77-100). / Abstract also in Chinese. / ACKNOWLEDGEMENTS --- p.4 / ABSTRACT --- p.5 / ABSTRACT (Chinese) --- p.7 / PUBLICATION --- p.8 / ABBREVIATION --- p.9 / Chapter CHAPTER 1 --- INTRODUCTION --- p.10 / Chapter 1.1 --- Overview of the study --- p.10 / Chapter 1.2. --- Substantia nigra pars reticulata (SNR) --- p.12 / Chapter 1.2.1 --- SNR and the basal ganglia / Chapter 1.2.2 --- GABA neurotransmission in SNR / Chapter 1.2.3 --- SNR and epilepsy / Chapter 1.3 --- GABAb receptors --- p.18 / Chapter 1.3.1 --- GABA receptors / Chapter 1.3.2 --- GABAb receptors and their classification / Chapter 1.3.3 --- Agonists and antagonists of GABAb receptor / Chapter 1.3.4 --- Distribution of GAB AB receptor / Chapter 1.3.5 --- GABAb receptors in epilepsy and the involvement of SNR / Chapter 1.4 --- Cannabinoid receptors --- p.24 / Chapter 1.4.1 --- Cannabinoid receptors and their classification / Chapter 1.4.2 --- Agonists and antagonists of cannabinoid receptor / Chapter 1.4.3 --- Distribution of cannabinoid receptors / Chapter 1.4.4 --- Cannabinoid receptors in epilepsy and the involvement of SNR / Chapter CHAPTER 2 --- METHODS --- p.31 / Chapter 2.1 --- Brain slice preparation and maintenance --- p.31 / Chapter 2.2 --- Experimental set-up --- p.32 / Chapter 2.2.1 --- Visualization of neurones / Chapter 2.2.2 --- Electrophysiological recordings / Chapter 2.2.3 --- Evoked stimulation / Chapter 2.2.4 --- Drug preparation and administration / Chapter 2.3 --- Identification of GAB A and dopamine neurones --- p.36 / Chapter 2.4 --- Data analysis --- p.37 / Chapter 2.4.1 --- Construction of dose-response curve / Chapter 2.4.2 --- Analysis of synaptic currents / Chapter 2.4.3 --- Statistics / Chapter CHAPTER 3 --- RESULTS --- p.39 / Chapter 3.1 --- Basic characteristics of IPSCs in SNR --- p.39 / Chapter 3.1.1 --- Spontaneous and miniature IPSCs / Chapter 3.1.2 --- Evoked IPSCs / Chapter 3.2 --- GABAb receptors in SNR --- p.42 / Chapter 3.2.1 --- Postsynaptic GABAb receptors in SNR neurones / Chapter 3.2.1.1 --- Baclofen-activated postsynaptic response / Chapter 3.2.1.2 --- Effects of GABAb receptor antagonist on IPSCs / Chapter 3.2.2 --- Presynaptic GABAb receptors / Chapter 3.2.3 --- Effects of GAB A uptake blocker / Chapter 3.3 --- Cannabinoid receptors in SNR --- p.51 / Chapter 3.3.1 --- Postsynaptic cannabinoid receptors in SNR neurones / Chapter 3.3.2 --- Presynaptic action of cannabinoids / Chapter CHAPTER 4 --- DISCUSSION and CONCLUSION --- p.55 / Chapter 4.1 --- General properties of IPSCs --- p.55 / Chapter 4.2 --- GABAb receptors in SNR neurones --- p.58 / Chapter 4.2.1 --- Postsynaptic GABAB receptors in SNR neurones / Chapter 4.2.2 --- GABAb component in spontaneous and evoked IPSCs / Chapter 4.2.3 --- Presynaptic GABAb receptors in SNR / Chapter 4.2.4 --- Role of GABA uptake / Chapter 4.3 --- Cannabinoid receptors in SNR neurones --- p.67 / Chapter 4.3.1 --- Postsynaptic cannabinoid receptors in SNR neurones / Chapter 4.3.2 --- Presynaptic cannabinoid receptors in SNR / Chapter 4.4 --- SNR GABAb and cannabinoid receptors - their role in epilepsy --- p.72 / Chapter 4.5 --- Concluding remarks and future direction --- p.75 / REFERENCES --- p.77 Neural Inhibition--physiology Substantia Nigra--physiology Receptors, GABA-B--physiology Cannabinoids
5	Estudos moleculares em epilepsias da infância e da adolescência : o potencial de aplicação clínica dos testes de genética molecular / Molecular studies in childhood and adolescence epilepsies : evaluating the potential clinical applicability of molecular genetic testing Gonsales, Marina Coelho, 1985- 23 August 2018 (has links) Orientador: Iscia Teresinha Lopes Cendes / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-23T06:36:18Z (GMT). No. of bitstreams: 1 Gonsales_MarinaCoelho_D.pdf: 5961380 bytes, checksum: 501b9df1659eb15a6a8545ae0943d967 (MD5) Previous issue date: 2013 / Resumo: As epilepsias são distúrbios cerebrais caracterizados por uma predisposição persistente para a geração de crises epilépticas, que são interrupções transitórias no funcionamento normal do sistema nervoso. Acredita-se que a maioria das epilepsias relacionadas com idade de inicio precoce possui etiologia presumivelmente genética. Sendo assim, elas representam um grupo para o qual o uso de testes genéticos seria potencialmente benéfico. Os objetivos principais deste trabalho foram: a caracterização das bases moleculares de diferentes formas de epilepsia da infância e da adolescência e a avaliação do potencial dos genes candidatos estudados para a utilização em testes genéticos para fins clínicos. A estratégia empregada foi à triagem de mutações nos seguintes genes: SCN1A, em pacientes com síndromes de Dravet e de Doose; SCL2A1 em pacientes com síndrome de Doose e epilepsias idiopáticas generalizadas (EIGs), especialmente a epilepsia mioclonica juvenil (EMJ); e EFHC1 e GABRA1, em pacientes com EMJ e outras formas comuns de EIGs. A triagem de mutações foi realizada por sequenciamento automático pela técnica de Sanger. As alterações potencialmente deletérias foram investigadas em um grupo controle composto por 100 indivíduos sem epilepsia. O potencial deletério das substituições que resultam em troca do resíduo de aminoácido na proteína codificada foi estimado utilizando-se diferentes algoritmos de predição. As mutações previamente descritas na literatura foram compiladas e analisadas quanto a sua provável localização na proteína e predição de efeito deletério. Analises por Multiplex Ligation-dependent Probe Amplification (MLPA) foram realizadas para a detecção de variações no numero de copias de SCN1A. A analise de mutações no gene SCN1A revelou alterações potencialmente deletérias em 81% dos pacientes com síndrome de Dravet, e em apenas um paciente com síndrome de Doose. Esses dados, juntamente com os resultados das analises de compilação das mutações descritas na literatura, sugerem que o teste genético em SCN1A para fins clínicos seria altamente recomendável em indivíduos com síndrome de Dravet, mas não para os com síndrome de Doose típica. O gene SLC21A não parece estar envolvido na etiologia da síndrome de Doose e das EIGs em nossa casuística. A frequencia de alterações potencialmente deletérias no gene EFHC1 em indivíduos com EMJ foi relativamente baixa, sugerindo que esse gene não seja o principal causador dessa epilepsia, embora possa ser um fator de predisposição. Por fim, o gene GABRA1 não parece conferir predisposição para as EIGs comuns em nossa casuística / Abstract: Epilepsy is a brain disorder characterized by a long lasting predisposition to generate epileptic seizures, which are transient interruptions of normal brain function. Most epilepsies with early onset presumably have a genetic etiology. Thus, they represent a group for which the use of genetic testing would be potentially beneficial. The main goals of this study were to characterize the molecular basis of different forms of epilepsy in childhood and adolescence and to evaluate the potential clinical use of genetic testing in the context of these disorders. To achieve these goals we searched for mutations in the following genes: SCN1A in patients with Dravet and Doose syndromes; SLC2A1 in patients with Doose syndrome and idiopathic generalized epilepsies (IGEs), particularly juvenile myoclonic epilepsy (JME); and EFHC1 and GABRA1 in patients with JME and other common forms of IGEs. Mutation screening was performed by automated Sanger sequencing using capillary electrophoresis. Potentially deleterious nucleotide changes found were subsequently investigated in a control group of 100 individuals without epilepsy. In addition, the deleterious potential of amino acid changes identified was estimated using different prediction algorithms. Mutations previously described in the literature were compiled and analyzed regarding their putative location on the protein and predicted deleterious effect. Furthermore, Multiplex Ligation-dependent Probe Amplification (MLPA) analyzes were performed to detect the presence of copy number variations in SCN1A. Our results showed potentially deleterious variants in SCN1A in 81% of patients with Dravet syndrome, but only in one patient with Doose syndrome. These data, along with the results of the compilation of mutations reported in the literature suggest that genetic testing for SCN1A is clinically relevant in Dravet syndrome, but not in typical Doose syndrome. SLC21A does not seem to be involved in the etiology of Doose syndrome and EIGs in our cohort. The frequency of potentially deleterious changes in EFHC1 in individuals with JME was relatively low, suggesting that this gene is not the main cause of this form of epilepsy, although it may be a predisposing factor. Lastly, GABRA1 does not seem to confer predisposition to common EIGs in our cohort / Doutorado / Fisiopatologia Médica / Doutora em Ciências Neurogenética Mutação Canais iônicos Receptores de GABA-B EFHC1 Neurogenetics Mutation Ion channels Receptors, GABA EFHC1
6	The role of GABA-B in sensorigating processing disorders in rat models, an autoradiographic study Zhuang, Alex 19 July 2019 (has links) INTRODUCTION: The process of sensorimotor gating is a neurological phenomenon referring to the brain’s ability to process and filter out stimuli in order to prevent an overflow of information. This phenomenon can be operationally measured by prepulse inhibition, which is the attenuation of a stimulus-induced startle response by introducing a milder preceding stimulus. Studies have shown that impairment of prepulse inhibition (PPI) has been correlated with diseases such as schizophrenia and autism spectrum disorder. Many brain areas, including the superior colliculus (SC), inferior colliculus (IC), mediodorsal thalamus (MD), basolateral amygdala (BLA), anterior cingulate cortex (ACC), and ventral hippocampus (VHPC), have been implicated in playing important roles in prepulse inhibition. While many studies have implicated GABA-A receptors in playing a role in PPI regulation, little work has been done on GABA-B receptors. An established rat model with induced prepulse inhibition impairment was used in this study. PPI impairment was induced via injection of the glutamate receptor antagonist dizocilpine. A subgroup of rats was also treated with the antihistamine pyrilamine to reverse the effects of dizocilpine. OBJECTIVES: The aims of this study are to: 1. Expand the understanding of prepulse inhibition in the context of neurological and developmental diseases such as autism spectrum disorder (ASD) and schizophrenia; 2. Identify potential significant differences within GABA-B receptor densities in the rat SC, IC, MD, BLA, ACC, or VHPC between treatment groups with and without dizocilpine and groups with and without pyrilamine. METHODS: Histological brain slides harvested from 36 Sprague-Dawley rats were provided by Dr. Edward Levin from Duke University’s Neurobehavioral Research Lab for this study. The brain slides were incubated in a radioligand solution specific for GABA-B receptors and exposed to autoradiograph film for approximately 12 weeks. The films were developed in a dark room and scanned electronically. GABA-B receptor densities were measured from the images and the data was analyzed using ANOVA and independent T tests. RESULTS: ANOVA testing revealed significant differences between treatment groups in the MD and VHPC. However, only the MD was found to have significant GABA-B receptor differences when comparing the dizocilpine and pyrilamine treatment groups to the control group. The VHPC was found to have significant differences in GABA-B receptor densities when directly comparing the dizocilpine group to the pyrilamine treatment group, rather than to the control group. There were no significant differences in GABA-B receptor densities as a result of either dizocilpine or pyrilamine treatment in the SC, IC, BLA, ACC, or VHPC. CONCLUSION: Changes in GABA-B receptor levels appear to play a role in both the impairment and rescue of PPI in the rat MD. It does not appear to play a role in the SC, IC, BLA, ACC, or VHPC for either the impairment or rescue of PPI function. Neurosciences Autism spectrum disorder Autoradiography GABA-B Prepulse inhibition Sensorigating processing
7	Central vestibular compensation : the role of the GABA B receptor / Magnusson, Anna K., January 2002 (has links) (PDF) Diss. Linköping : Univ., 2003. / Härtill 4 uppsatser.
8	Couplage du récepteur à sept domaines transmembranaires GABA-B1 aux voies intracellulaires de signalisation en absence de GABA-B2 Richer, Maxime 02 1900 (has links) Le GABA est le principal neurotransmetteur inhibiteur du SNC et est impliqué dans le développement du cerveau, la plasticité synaptique et la pathogénèse de maladies telles que l’épilepsie, les troubles de l’anxiété et la douleur chronique. Le modèle actuel de fonctionnement du récepteur GABA-B implique l’hétérodimérisation GABA-B1/B2, laquelle est requise au ciblage à la surface membranaire et au couplage des effecteurs. Il y est cependant des régions du cerveau, des types cellulaires et des périodes du développement cérébral où la sous-unité GABA-B1 est exprimée en plus grande quantité que GABA-B2, ce qui suggère qu’elle puisse être fonctionnelle seule ou en association avec des partenaires inconnus, à la surface cellulaire ou sur la membrane réticulaire. Dans le cadre de cette thèse, nous montrons la capacité des récepteurs GABA-B1 endogènes à activer la voie MAPK-ERK1/2 dans la lignée dérivée de la glie DI-TNC1, qui n’exprime pas GABA-B2. Les mécanismes qui sous-tendent ce couplage demeurent mal définis mais dépendent de Gi/o et PKC. L’immunohistochimie de récepteurs endogènes montre par ailleurs que des anticorps GABA-B1 dirigés contre la partie N-terminale reconnaissent des protéines localisées au RE tandis des anticorps C-terminaux (CT) marquent une protéine intranucléaire. Ces données suggèrent que le domaine CT de GABA-B1 pourrait être relâché par protéolyse. L’intensité des fragments potentiels est affectée par le traitement agoniste tant en immunohistochimie qu’en immunobuvardage de type western. Nous avons ensuite examiné la régulation du clivage par le protéasome en traitant les cellules avec l’inhibiteur epoxomicine pendant 12 h. Cela a résulté en l’augmentation du marquage intranucléaire de GABA-B1-CT et d’un interacteur connu, le facteur de transcription pro-survie ATF-4. Dans des cellules surexprimant GABA-B1-CT, l’induction et la translocation nucléaire d’ATF-4, qui suit le traitement epoxomicine, a complètement été abolie. Cette observation est associée à une forte diminution du décompte cellulaire. Étant donné que les trois derniers résidus de GABA-B1-CT (LYK) codent un ligand pseudo-PDZ et que les protéines à domaines PDZ sont impliquées dans la régulation du ciblage nucléaire et de la stabilité de protéines, en complément de leur rôle d’échaffaud à la surface cellulaire, nous avons muté les trois derniers résidus de GABA-B1-CT en alanines. Cette mutation a complètement annulé les effets de GABA-B1-CT sur l’induction d’ATF-4 et le décompte cellulaire. Cette deuxième série d’expériences suggère l’existence possible de fragments GABA-B1 intranucléaires régulés par le traitement agoniste et le protéasome dans les cellules DI-TNC1. Cette régulation d’ATF-4 dépend des résidus LYK de GABA-B1-CT, qui modulent la stabilité de GABA-B1-CT et favorisent peut-être la formation d’un complexe multiprotéique incluant GABA-B1-CT, ATF-4, de même qu’une protéine d’échaffaudage inconnue. En somme, nous démontrons que les sous-unités GABA-B1 localisées au RE, lorsque non-hétérodimérisées avec GABA-B2, demeurent capables de moduler les voies de signalisation de la prolifération, la différentiation et de la survie cellulaire, via le couplage de protéines G et possiblement la protéolyse régulée. Les mécanismes de signalisation proposés pourraient servir de nouvelle plate-forme dans la compréhension des actions retardées résultant de l’activation des récepteurs 7-TMs. / GABA is the principal inhibitory neurotransmitter in the CNS and is implicated in brain development, synaptic plasticity and the pathogenesis of diseases such as epilepsy, anxiety disorders and chronic pain. In the current model of GABA-B function, there is a requirement for GABA-B1/B2 dimerization for targetting to the cell surface and effector coupling. However, there are certain brain regions (putamen), cell types (glial cells) and times during brain development where GABA-B1 is expressed in higher amounts than GABA-B2, suggesting that GABA-B1 might be functional alone or in association with unidentified partners, either at the cell surface or on the ER membranes. In this thesis, we first show the capacity of endogenous GABA-B1 receptors to activate the MAPK-ERK1/2 pathway in the DI-TNC1 glial-derived cell line which does not express GABA-B2. The underlying mechanisms remain incompletely defined but depend on Gi/o and PKC. Immunohistochemistry of endogenous receptors shows that GABA-B1 N-terminal antibodies recognize ER-localized proteins and that C-terminal (CT) antibody shows intranuclear distribution. This data suggests that fragments of the GABA-B1 receptor are generated by proteolysis and indeed we show that agonist treatment affects the intensity of certain C-terminal GABA-B1 fragments both in immunohistochemistry and western blots suggesting that the GABA-B1 receptor is subjected to regulated proteolysis. Since a 13-residue potential PEST sequence was localized immediately distal to the ER retention motif in the GABA-B1 CT, we examined proteasome regulation of the cleavage event. Following a 12h treatment with the proteasome inhibitor, epoxomicin, we detected increases in intranuclear staining for both GABA-B1 and a known interactor, the pro-survival transcription factor ATF-4, using confocal microscopy and by western blotting of nuclear extracts. These increases are due either to proteasome inhibition or activation of the ER stress pathway. In cells overexpressing GABA-B1-CT, ATF-4 induction and nuclear translocation, which normally follows epoxomicin treatment, was completely abolished. This observation was associated to a strong decrease in cell number. Since the last three residues of GABA-B1-CT (LYK) encode a pseudo-PDZ ligand and that PDZ domain protein regulate nuclear targeting and protein stability, in complement to their role in scaffolding at the cell surface, we mutated the last three residues of GABA-B1-CT to alanines. This mutation completely reversed the effect of GABA-B1-CT on ATF-4 induction and on cell number. This second set of data suggests the existence of agonist and proteasome-regulated intranuclear GABA-B1 fragments in DI-TNC1 cells. Further, the GABA-B1-CT pseudo-PDZ ligand appears to be critically important in regulating ATF-4 induction by modulating GABA-B1-CT stability and perhaps by favoring the formation of a multiprotein complex with ATF-4, ATF-4 interactors and an unknown scaffolding protein. Overall, we show that ER-localised GABA-B1 subunits, when not dimerized with GABA-B2, can still modulate proliferation, differentiation and survival pathways, both through G-protein coupling and regulated proteolysis. The signalling mechanisms which we propose could serve as a new platform in understanding the long term effects of 7-TM receptor activation. RCPGs GABA-B Signalisation MAPK-ERK1/2 ATF-4 Protéolyse PDZ GPCRs Signaling MAPK Proteolysis
9	Couplage du récepteur à sept domaines transmembranaires GABA-B1 aux voies intracellulaires de signalisation en absence de GABA-B2 Richer, Maxime 02 1900 (has links) Le GABA est le principal neurotransmetteur inhibiteur du SNC et est impliqué dans le développement du cerveau, la plasticité synaptique et la pathogénèse de maladies telles que l’épilepsie, les troubles de l’anxiété et la douleur chronique. Le modèle actuel de fonctionnement du récepteur GABA-B implique l’hétérodimérisation GABA-B1/B2, laquelle est requise au ciblage à la surface membranaire et au couplage des effecteurs. Il y est cependant des régions du cerveau, des types cellulaires et des périodes du développement cérébral où la sous-unité GABA-B1 est exprimée en plus grande quantité que GABA-B2, ce qui suggère qu’elle puisse être fonctionnelle seule ou en association avec des partenaires inconnus, à la surface cellulaire ou sur la membrane réticulaire. Dans le cadre de cette thèse, nous montrons la capacité des récepteurs GABA-B1 endogènes à activer la voie MAPK-ERK1/2 dans la lignée dérivée de la glie DI-TNC1, qui n’exprime pas GABA-B2. Les mécanismes qui sous-tendent ce couplage demeurent mal définis mais dépendent de Gi/o et PKC. L’immunohistochimie de récepteurs endogènes montre par ailleurs que des anticorps GABA-B1 dirigés contre la partie N-terminale reconnaissent des protéines localisées au RE tandis des anticorps C-terminaux (CT) marquent une protéine intranucléaire. Ces données suggèrent que le domaine CT de GABA-B1 pourrait être relâché par protéolyse. L’intensité des fragments potentiels est affectée par le traitement agoniste tant en immunohistochimie qu’en immunobuvardage de type western. Nous avons ensuite examiné la régulation du clivage par le protéasome en traitant les cellules avec l’inhibiteur epoxomicine pendant 12 h. Cela a résulté en l’augmentation du marquage intranucléaire de GABA-B1-CT et d’un interacteur connu, le facteur de transcription pro-survie ATF-4. Dans des cellules surexprimant GABA-B1-CT, l’induction et la translocation nucléaire d’ATF-4, qui suit le traitement epoxomicine, a complètement été abolie. Cette observation est associée à une forte diminution du décompte cellulaire. Étant donné que les trois derniers résidus de GABA-B1-CT (LYK) codent un ligand pseudo-PDZ et que les protéines à domaines PDZ sont impliquées dans la régulation du ciblage nucléaire et de la stabilité de protéines, en complément de leur rôle d’échaffaud à la surface cellulaire, nous avons muté les trois derniers résidus de GABA-B1-CT en alanines. Cette mutation a complètement annulé les effets de GABA-B1-CT sur l’induction d’ATF-4 et le décompte cellulaire. Cette deuxième série d’expériences suggère l’existence possible de fragments GABA-B1 intranucléaires régulés par le traitement agoniste et le protéasome dans les cellules DI-TNC1. Cette régulation d’ATF-4 dépend des résidus LYK de GABA-B1-CT, qui modulent la stabilité de GABA-B1-CT et favorisent peut-être la formation d’un complexe multiprotéique incluant GABA-B1-CT, ATF-4, de même qu’une protéine d’échaffaudage inconnue. En somme, nous démontrons que les sous-unités GABA-B1 localisées au RE, lorsque non-hétérodimérisées avec GABA-B2, demeurent capables de moduler les voies de signalisation de la prolifération, la différentiation et de la survie cellulaire, via le couplage de protéines G et possiblement la protéolyse régulée. Les mécanismes de signalisation proposés pourraient servir de nouvelle plate-forme dans la compréhension des actions retardées résultant de l’activation des récepteurs 7-TMs. / GABA is the principal inhibitory neurotransmitter in the CNS and is implicated in brain development, synaptic plasticity and the pathogenesis of diseases such as epilepsy, anxiety disorders and chronic pain. In the current model of GABA-B function, there is a requirement for GABA-B1/B2 dimerization for targetting to the cell surface and effector coupling. However, there are certain brain regions (putamen), cell types (glial cells) and times during brain development where GABA-B1 is expressed in higher amounts than GABA-B2, suggesting that GABA-B1 might be functional alone or in association with unidentified partners, either at the cell surface or on the ER membranes. In this thesis, we first show the capacity of endogenous GABA-B1 receptors to activate the MAPK-ERK1/2 pathway in the DI-TNC1 glial-derived cell line which does not express GABA-B2. The underlying mechanisms remain incompletely defined but depend on Gi/o and PKC. Immunohistochemistry of endogenous receptors shows that GABA-B1 N-terminal antibodies recognize ER-localized proteins and that C-terminal (CT) antibody shows intranuclear distribution. This data suggests that fragments of the GABA-B1 receptor are generated by proteolysis and indeed we show that agonist treatment affects the intensity of certain C-terminal GABA-B1 fragments both in immunohistochemistry and western blots suggesting that the GABA-B1 receptor is subjected to regulated proteolysis. Since a 13-residue potential PEST sequence was localized immediately distal to the ER retention motif in the GABA-B1 CT, we examined proteasome regulation of the cleavage event. Following a 12h treatment with the proteasome inhibitor, epoxomicin, we detected increases in intranuclear staining for both GABA-B1 and a known interactor, the pro-survival transcription factor ATF-4, using confocal microscopy and by western blotting of nuclear extracts. These increases are due either to proteasome inhibition or activation of the ER stress pathway. In cells overexpressing GABA-B1-CT, ATF-4 induction and nuclear translocation, which normally follows epoxomicin treatment, was completely abolished. This observation was associated to a strong decrease in cell number. Since the last three residues of GABA-B1-CT (LYK) encode a pseudo-PDZ ligand and that PDZ domain protein regulate nuclear targeting and protein stability, in complement to their role in scaffolding at the cell surface, we mutated the last three residues of GABA-B1-CT to alanines. This mutation completely reversed the effect of GABA-B1-CT on ATF-4 induction and on cell number. This second set of data suggests the existence of agonist and proteasome-regulated intranuclear GABA-B1 fragments in DI-TNC1 cells. Further, the GABA-B1-CT pseudo-PDZ ligand appears to be critically important in regulating ATF-4 induction by modulating GABA-B1-CT stability and perhaps by favoring the formation of a multiprotein complex with ATF-4, ATF-4 interactors and an unknown scaffolding protein. Overall, we show that ER-localised GABA-B1 subunits, when not dimerized with GABA-B2, can still modulate proliferation, differentiation and survival pathways, both through G-protein coupling and regulated proteolysis. The signalling mechanisms which we propose could serve as a new platform in understanding the long term effects of 7-TM receptor activation. RCPGs GABA-B Signalisation MAPK-ERK1/2 ATF-4 Protéolyse PDZ GPCRs Signaling MAPK Proteolysis
10	Mécanismes de régulation du trafic et de l’activité du récepteur GABAB Lahaie, Nicolas 04 1900 (has links) L’acide γ-aminobutyrique (GABA) est le principal neurotransmetteur inhibiteur du système nerveux central et est impliqué dans diverses pathologies incluant l’épilepsie, l’anxiété, la dépression et la dépendance aux drogues. Le GABA agit sur l’activité neuronale par l’activation de deux types de récepteurs; le canal chlorique pentamérique GABAA et l’hétérodimère obligatoire de récepteurs couplés aux protéines G (RCPG) GABAB. Chacun des récepteurs est responsable de phases distinctes de la réponse cellulaire au GABA. Lors d’une stimulation par le GABA, il est essentiel pour la cellule de pouvoir contrôler le niveau d’activité des récepteurs et au besoin, de limiter leur activation par des mécanismes de désensibilisation et de régulation négative. La désensibilisation nécessite le découplage du récepteur de ses effecteurs, ainsi que sa compartimentation hors de la membrane plasmique dans le but de diminuer la réponse cellulaire à l’agoniste. Les mécanismes de contrôle de l’activité de GABAB semblent anormaux pour un RCPG et sont encore mal moléculairement caractérisés. L’objet de cette thèse est d’étudier la régulation du récepteur GABAB et de sa signalisation par la caractérisation de nouvelles protéines d’interactions étant impliquées dans la désensibilisation, l’internalisation et la dégradation du récepteur. Une première étude nous a permis d’identifier la protéine NSF (N-ethylmaleimide sensitive factor) comme interagissant avec le récepteur hétérodimérique. Nous avons caractérisé le site d’interaction au niveau du domaine coiled-coil de chacune des deux sous-unités de GABAB et constaté la dépendance de cette interaction au statut de l’activité ATPasique de NSF. Nous avons observé que cette interaction pouvait être dissociée par l’activation de GABAB, induisant la phosphorylation du récepteur par la protéine kinase C (PKC) parallèlement à la désensibilisation du récepteur. L’activation de PKC par le récepteur est dépendante de l’interaction NSF-GABAB, ce qui suggère une boucle de rétroaction entre NSF et PKC. Nous proposons donc un modèle où, à l’état basal, le récepteur interagit avec NSF, lui permettant d’activer PKC en réponse à la stimulation par un agoniste, et où cette activation permet à PKC de phosphoryler le récepteur, induisant sa dissociation de NSF et sa désensibilisation. Nous avons par la suite étudié la dégradation et l’ubiquitination constitutive de GABAB et la régulation de celles-ci par PKC et l’enzyme de déubiquitination USP14 (ubiquitin-specific protease 14). Au niveau basal, le récepteur est ubiquitiné, et présente une internalisation et une dégradation rapide. L’activation de PKC augmente l’ubiquitination à la surface cellulaire et l’internalisation, et accélère la dégradation du récepteur. USP14 est en mesure de déubiquitiner le récepteur suite à l’internalisation, mais accélère aussi la dégradation par un mécanisme indépendant de son activité enzymatique. Nos résultats suggèrent un mécanisme où l’ubiquitination promeut l’internalisation et où USP14 cible le récepteur ubiquitiné vers un processus de dégradation lysosomale. La troisième étude porte sur la régulation de la densité de récepteurs à la membrane plasmique par la protéine Grb2 (growth factor receptor-bound protein 2). Nous avons déterminé que Grb2 interagit avec GABAB1 au niveau de la séquence PEST (riche en proline, glutamate, sérine et thréonine) du domaine carboxyl-terminal, et que cette interaction module l’expression à la surface du récepteur hétérodimérique en diminuant l’internalisation constitutive par un mécanisme encore inconnu. Cette inhibition de l’internalisation pourrait provenir d’une compétition pour le site de liaison de Grb2 à GABAB1, ce site étant dans une région interagissant avec plusieurs protéines impliquées dans le trafic du récepteur, tels le complexe COPI et la sous-unité γ2S du récepteur GABAA (1, 2). En proposant de nouveaux mécanismes moléculaires contrôlant l’activité et l’expression à la membrane du récepteur GABAB par les protéines NSF, PKC, USP14 et Grb2, les études présentées dans cette thèse permettent de mieux comprendre les processus d’internalisation et de dégradation, ainsi que du contrôle de l’activité de GABAB par la désensibilisation, ouvrant la porte à une meilleure compréhension de la signalisation GABAergique. / γ-aminobutyric acid (GABA) is the principal inhibitory neurotransmitter of the central nervous system and is involved in diverse pathologies such as epilepsy, anxiety, depression and drug addiction. GABAergic modulation of neuronal activity involves two different subsets of receptors: the GABAA receptor chlorine channel and the heterodimer of G protein coupled receptors (GPCR) GABAB. Each of these receptors is responsible for mediating distinct parts of the GABA-induced signaling. Upon stimulation, it is vital for the cell to control the signaling input and prevent overstimulation, using mechanisms such as functional desensitization and down-regulation to achieve this. The processes controlling GABAB receptor activity are atypical for a GPCR and have yet to be fully characterized. The aim of this thesis is to elucidate the mechanisms controlling GABAB activity by discovering novel proteins interactions mediating receptor desensitization, internalization and ubiquitination. In the first study, we identified the N-ethylmaleimide sensitive factor (NSF) as a GABAB interacting protein and characterized its interaction site as the coiled-coil structure on both GABAB sub-units. We also showed that this interaction is sensitive to the ATPase state of NSF and that agonist treatment of GABAB led to dissociation of NSF from the receptor in a protein kinase C (PKC) dependent manner. Interestingly, GABA-induced PKC activation was dependent on the NSF-GABAB interaction, suggesting a feedback mechanism for PKC. Both PKC and NSF were involved in mediating receptor desensitization, suggesting a novel role of NSF in receptor signaling regulation. In the proposed model, NSF interacts with GABAB at the basal state, and upon agonist stimulation, PKC is activated and can phosphorylate the receptor, promoting NSF dissociation and GABAB desensitization. We then studied constitutive GABAB ubiquitination and degradation and its regulation by PKC and the deubiquitinating enzyme USP14 (Ubiquitin-specific protease 14). GABAB shows a high constitutive ubiquitination and internalization level. Activation of PKC promotes both phenomena and accelerates the rate of lysosomal receptor degradation. In contrast, USP14 promotes post-endocytic deubiquitination of the receptor, but also accelerates receptor degradation in a catalytically-independent manner. Our results suggest a mechanism where PKC-induced cell surface ubiquitination promotes GABAB endocytosis and USP14 interaction promotes endosomal sorting toward lysosomal degradation. In the third study, we identified the growth factor receptor-bound protein 2 (Grb2) as a protein interacting with the PEST (proline, glutamate, serine, threonine rich) sequence of GABAB1 through a SH3-domain interaction and forming a ternary complex with the functional GABAB heterodimer. We showed that Grb2 can regulate cell surface density of GABAB by decreasing constitutive endocytosis, suggesting that this interaction can compete for binding of the PEST sequence with proteins such as the GABAA γ2S sub-unit or the COPI complex (1, 2), promoting higher cell surface stability. In proposing novel molecular mechanisms controlling GABAB signaling and cell surface expression through NSF, PKC, USP14 and Grb2, this thesis highlights the complex regulation of GABAB activity by its functional desensitization, ubiquitination, endocytosis and degradation. Acide gamma-aminobutyrique (GABA) G protein coupled receptors (GPCR) desensitization deubiquitination désensibilisation Déubiquitination Gamma-aminobutyric acid (GABA) Growth receptor bound protein 2 (Grb2) Ubiquitin-specific protease 14 (USP14) N-ethylmaleimide sensitive factor (NSF) Metabotropic GABA receptor (GABA(B)) ubiquitination Protein kinase C (PKC)

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