Global ETD Search

151	Rôle de l’altération des récepteurs de NMDA dans l’épilepsie associée à la Sclérose Tubéreuse de Bourneville étudié sur un modèle animal et le tissu humain / The role of NMDA receptors alteration in the epilepsy related to Tuberos Sclerosis Complex studied on the animal model and human tissue Gataullina, Svetlana 27 January 2015 (has links) La sclérose tubéreuse de Bourneville (STB) est une maladie génétique et multi-systémique à transmission autosomique dominante due à des mutations d’un gène TSC1 ou TSC2 qui codent respectivement pour hamartine et tuberine ayant une action inhibitrice sur la voie de signalisation mTOR. L’épilepsie précoce et pharmacorésistante est la manifestation neurologique la plus fréquente et la plus délétère de la STB. Elle débute souvent dans la première année de vie par des spasmes infantiles qui évoluent avec l’âge et en absence de traitement vers des crises toniques ou tonico-cloniques. Bien que les crises soient supposées être générées dans des tubers corticaux, les mécanismes de l’épilepsie ne sont pas bien élucidés et le traitement reste souvent inefficace. Des études morphologiques ont montré une altération de l’expression ARNm des récepteurs au glutamate dans les cellules géantes et les neurones dysplasiques des tubers, mais leur implication fonctionnelle restait à montrer. Les différentes sous-unités NMDA ont une expression âge-dépendante et région-spécifique, les plus grands changements survenant au début de la vie quand l’épilepsie de la STB apparaît. Ce travail avait pour but d’étudier à l’aide de méthodes électrophysiologiques in vitro et in vivo l’expression fonctionnelle des sous-unités NMDA aberrantes et de déterminer leur rôle dans l’épileptogènese chez les souris hétérozygotes Tsc1+/- et sur le tissu humain STB post-opératoire. Nous avons pu démontrer que : i) Les souris hétérozygotes pour le gène Tsc1 sont spontanément épileptiques in vivo et in vitro dans une courte fenêtre dévelopmentale de P9 à P18. ii) Elles présentent une altération d’expression des récepteurs NMDA couche-spécifique et mTOR dépendante avec une surexpression des sous-unités GluN2C/D dans la couche 4 et 2/3 et GluN2B dans les couches 2/3. Cette expression anormale est prévenue par l’administration d’un inhibiteur de la voie mTOR, la rapamycine. iii) Les mêmes altérations d’expression des récepteurs NMDA, sont montrées sur les tissus post-opératoires, non seulement de tubers de STB mais aussi des dysplasies corticales focales (DCF), ces deux malformations ayant des similarités étiologiques et physiopathologiques. iv) La RT-PCR quantitative confirme une expression excessive de GluN2C dans le cortex de souris Tsc1+/- et sur le tissu humain des tubers et DCF. v) Les décharges épileptiques chez la souris Tsc1+/- sont générées dans la couche granulaire 4 du cortex avant de se propager vers les couches superficielles et les couches profondes, empruntant ainsi les microcircuits corticaux. vi) L’expression excessive de la sous-unité GluN2C dans le cortex contribue à l’hyperexcitabilité neuronale chez la souris Tsc1+/- et sur des tissus humains de tubers et de DCF puisque les crises et les décharges sont bloquées par les antagonistes sélectifs de GluN2C/D. vii) Les crises chez la souris Tsc1+/- suivent une séquence âge-dépendante évoluant du type «spasms-like» vers «tonic-clonic like», rappelant celle de l’épilepsie humaine, avec deux pics de haute incidence de crises à P13 et P16 correspondant chez l’homme respectivement l’âge des spasmes infantiles et celui des crises toniques. L’évolution avec l’âge du délai de propagation inter-hémisphérique pourrait contribuer à ce changement de types de crises. Ces résultats montrent donc pour la première fois qu’une happloinsuffisance pour le gène Tsc1 chez les souris Tsc1+/- sans tubers suffit à produire une altération de l’expression des récepteurs NMDA de manière mTOR dépendante et contribuer ainsi à l’épileptogènese dans la STB. La souris Tsc1+/- est le premier modèle génétique sans anomalies morphologiques présentant une épilepsie spontanée qui évolue des spasmes vers des crises toniques et tonico-cloniques. Néanmoins cette épilepsie diffère de l’épilepsie humaine de la STB par l’absence de crises focales et de pharmacorésistance, ce qui pourrait être expliqué par l’absence de tubers chez la souris Tsc1+/-. (...) / Tuberous sclerosis complex (TSC) is a genetic multisystemic disease with autosomal dominant transmission due to mutations in a gene TSC1 or TSC2 respectively which encode hamartin and tuberin proteins having an inhibitory action on the mTOR signaling pathway. Early refractory epilepsy is the most common and most deleterious neurological manifestation. The epilepsy often begins in the first year of life by infantile spasms that change in the lack of treatment to tonic or tonic-clonic seizures in age-dependent manner. Although seizures are thought to be generated in cortical tubers, epilepsy mechanisms are not well understood and treatment is often ineffective. Morphological studies showed the altered expression of glutamate receptor mRNA in the giant cells and dysplastic neurons of tubers, but their functional involvement remains unknown. The different NMDA subunits have an age-dependent and region-specific expression, the greatest changes occurring early in life when the TSC epilepsy appears. This work aimed to study the functional expression of aberrant NMDA subunits expression and their role in the epileptogenesis in heterozygous Tsc1+/- mice and post-surgical human tissue of TSC patients using in vitro and in vivo electrophysiological methods. The study reveal that: i) Heterozygous tuber-free Tsc1+/- mice show spontaneous epilepsy in vivo and in vitro in a short developmental window from P9 to P18. ii) These mice exhibit an altered NMDA receptor expression in mTOR dependent and layer-specific manner with GluN2C/D subunits overexpression in layers 4 and 2/3, and GluN2B ovexpression in layers 2/3. This abnormal NMDA receptors expression is prevented by the administration of an mTOR inhibitor, rapamycin. iii) The same alterations of NMDA receptors’ expression are shown in post-surgical tissues not only in tubers from TSC patients, but also in focal cortical dysplasia (FCD), these two malformations sharing etiological and pathophysiological similarities. iv) Quantitative RT-PCR confirms the excessive GluN2C subunit expression in Tsc1+/- mouse cortex and human tissue of tubers and DCF. v) Epileptic discharges in Tsc1+/- mice are generated in the granular layer 4 of the cortex before spreading to the superficial and then to deep layers, thus borrowing the cortical microcircuits. vi) Excessive expression of GluN2C subunit in the cortex contributes to neuronal hyperexcitability in Tsc1+/- mice, as well as in human tubers and DCF tissues, since epileptic discharges are blocked by selective GluN2C/D antagonists. vii) Seizures in Tsc1+/- mice follow the age-dependent sequence, evolving from "spasms-like" to "tonic-clonic like" thus reminding the human epilepsy, with two peaks of highest seizure incidence at P13 and P16 corresponding respectively to age of infantile spasms and of tonic seizures in human. The age-dependent evolution of interhemispheric propagation delay could contribute to this change in seizure type. These results show for the first time that TSC1 happloinsuffisancy in tuber-free Tsc1+/- mice is sufficient to produce an alteration in NMDA receptor expression in an mTOR dependent manner, and thus contributes to epileptogenesis in TSC. The Tsc1+/- mouse line is the first genetic model of TSC without morphological abnormalities presenting with early spontaneous seizures which evolves from “spasms-like” to “tonic-clonic like” seizures. However, the epilepsy in Tsc1+/- mice differs from human TSC epilepsy by the absence of focal seizures and of drug-resistance. Both could be explained by the lack of tubers in the Tsc1+/- mice. It remains to determine whether the expression of GluN2C subunit is also transitional in Tsc1+/- mice and whether other factors contribute to determine the age-dependent epilepsy. This study opens new therapeutic perspectives of TSC epilepsy targeting GluN2C subunit of NMDA receptors. Épilepsie STB Souris Tissu humain Spasme Crise EEG NMDA GluN2C Epilepsy TSC Mice Human tissue Spasm Seizure EEG NMDA GluN2C 616.8
152	Sinalização via receptor N-Metil-D-Aspartato e modulação da Na+, K+-ATPase em camundongos hipomórficos para klotho: efeitos em hipocampo e cerebelo. / N-Methyl-D-Aspartate receptor signaling and modulation of NA+,K+-ATPase in klotho hypomorphic mice: effects in hippocampus and cerebellum. Cararo, Marina Minto 04 April 2017 (has links) Alterações no receptor N-metil-D-aspartato(NMDAR) marcam o envelhecimento. Um dos efeitos desta via é a ativação da óxido nítrico sintase (NOS) e a produção GMP cíclico (GMPc), promovendo modulação da Na+,K+-ATPase. A proteína αKlotho tem função anti-envelhecimento, e os animais hipomórficos para klotho (kl-/-) são caracterizados por danos periféricos e no Sistema Nervoso Central (SNC). O objetivo deste trabalho é verificar possíveis alterações na via NMDAR-NOS-GMPc e na Na+,K+-ATPase no SNC de camundongos kl-/-. Os dados obtidos apontam para um aumento da fosforilação do NMDAR , atividade da NOS, e redução de GMPc em hipocampo. Em cerebelo ocorre uma redução na fosforilação do NMDAR, atividade da NOS, sem alterações nos níveis de GMPc. Diferenças na expressão das subunidades GluN2 do NMDAR ocorrem em ambas estruturas. Também, observamos uma redução na atividade da α2/α3-Na+,K+-ATPase em cerebelo, e alterações na expressão de α2 e α3 em hipocampo e de α2 em cerebelo. Os dados reforçam a participação destas vias nas alterações em SNC dos animais kl-/-. / Alterations in N-Methyl-D-Aspartate receptor (NMDAR) are typical features of aging. Nitric oxide synthase (NOS) activation and cyclic GMP (cGMP) production, promoting Na+,K+-ATPase modulation are key events in NMDAR signaling. αKlotho protein has anti-aging function, and mice carrying hypomorph allele for klotho gene (kl-/-) are characterized by systemic and central nervous system (CNS) damage. The aim of this work is to verify whether alterations in NMDAR-NOS-cGMP pathway and in Na+,K+-ATPase occur in the CNS of kl-/- mice. Present data point for an increase in NMDAR phosphorylation, NOS activity and reduction in cGMP levels. In cerebellum, a decrease in NMDAR phosphorylation and NOS activity occur, with no changes in cGMP levels. Both situations are followed by changes in GluN2 subunity expression. Furthermore, we saw a reduction in α2/α3-Na+,K+-ATPase activity in cerebellum, and alterations in α2 and α3 in hippocampus and in cerebellar α2. Data presented support these pathways participation in age related conditions, using kl-/- mice as a model to study CNS damage. αKlotho αKlotho Aging Envelhecimento Na,K-ATPase Na,K-ATPase Nitric oxide sintase NMDA receptor Óxido nítrico sintase Receptor NMDA
153	Mediação do medo condicionado contextual por glicocorticóides e mecanismos glutamatérgicos no córtex pré-frontal medial / Mediation of contextual conditioned fear by glucocorticoids and glutamatergic mechanisms in the medial prefrontal cortex. Reis, Fernando Midea Cuccovia Vasconcelos 07 October 2015 (has links) Alterações no sistema glutamatérgico e mudanças no funcionamento do córtex pré-frontal medial (CPFm) têm sido associadas a diversos distúrbios psiquiátricos, dentre os quais a ansiedade. Também é reconhecido que alterações nas concentrações circulantes de glicocorticóides podem induzir alterações nas sinapses e circuitos glutamatérgicos e, consequentemente, modificar a reatividade emocional dos animais. Embora se saiba que os glicocorticóides influenciam a liberação de glutamato no CPFm, a interação entre os efeitos mediados pelos receptores mineralocorticóides (MR) ou glicocorticóides (GR) e o sistema glutamatérgico, na expressão da resposta condicionada de medo, ainda não está elucidada. Nesse sentido, os objetivos do presente estudo foram investigar (i) a influência dos glicocorticóides na expressão do medo condicionado contextual e seus efeitos sobre a atividade do CPFm em ratos, (ii) o papel dos receptores MR e GR localizados no córtex prelímbico (PrL) na expressão da resposta condicionada de congelamento e (iii) a interação entre os mecanismos mediados pelos glicocorticoides e o sistema glutamatérgico, via receptores do tipo NMDA, na expressão dessa resposta. Ratos Wistar machos foram tratados com veículo ou metirapona, um bloqueador de síntese de corticosterona, e expostos a um contexto previamente pareado com choque nas patas. Foram avaliados o tempo de medo contextual (comportamento de congelamento) e a expressão de proteína Fos em diferentes regiões do CPFm. Os resultados mostraram que a exposição ao contexto aversivo levou a um aumento significativo da expressão de congelamento e de proteína Fos no PrL, nas áreas do córtex cingulado anterior 1 e 2 (Cg1 e Cg2), mas não no córtex infralímbico. A administração de metirapona levou a uma diminuição da expressão de congelamento e de proteína Fos no PrL, Cg1 e Cg2. A administração bilateral de espironolactona, um antagonista de receptores MR, no PrL antes do teste diminuiu as respostas de medo e o pré-tratamento com RU38486, um antagonista de receptores GR, aboliu este efeito. Os resultados também mostraram que a diminuição da resposta de congelamento induzida por injeções intra-PrL de corticosterona foi abolida pela administração prévia de RU38486, mas não por espironolactona, indicando que a corticosterona recruta preferencialmente os receptores GR para produzir esses efeitos. A administração prévia do antagonista de receptor NMDA também preveniu os efeitos induzidos pelo tratamento com corticosterona sugerindo que, no PrL, parte dos efeitos rápidos do glicocorticóides sobre a expressão do medo condicionado se dá por uma interação com o sistema glutamatérgico. A administração de NMDA no PrL, antes do teste, induziu efeitos similares ao tratamento com corticosterona nessa região. De modo geral, os resultados sugerem que a liberação de corticosterona durante a apresentação de um estímulo condicionado aversivo influencia a atividade do CPFm de maneira que, uma mudança no equilíbrio das atividades mediadas por MR e GR, por meio de um aumento da atividade de GR, interage com o sistema glutamatérgico via aumento da atividade dos receptores NMDA influenciando a expressão da resposta de medo condicionado contextual. Sugere-se que a redução na expressão do medo condicionado observada após a administração local de corticosterona no PrL também seja decorrente de mudanças no equilíbrio entre MR e GR em direção a um aumento de suas ações mediadas por GR, assim como um aumento na liberação de glutamato e maior atividade de receptores NMDA nessa região. / Changes in the glutamatergic system and in the functioning of the medial prefrontal cortex (mPFC) have been associated with different psychiatric disorders, including anxiety. It is also recognized that changes in circulating levels of glucocorticoids can induce changes in glutamatergic synapses and circuits and therefore alter the emotional reactivity of animals. Although is known that glucocorticoids can influence the release of glutamate in the mPFC, the interaction between mineralocorticoid receptors (MR) and glucocorticoid receptors (GR) activation and the glutamatergic activity on the expression of conditioned fear response is not yet elucidated. The aims of the present study were to investigate (i) the influence of glucocorticoids on the expression of contextual conditioned fear and its effects in the activity of the mPFC in rats, (ii) the role of MR and GR in the prelimbic cortex (PrL) on expression of conditioned freezing response and (iii) a possible interaction between the effects mediated by the glucocorticoids and the glutamatergic system, via NMDA receptors on the expression of this response. Male Wistar rats were treated with vehicle or metyrapone, a corticosterone synthesis blocker, and exposed to a context previously paired with footshock. The time of contextual fear (freezing behavior) and Fos protein expression in different regions of mPFC were evaluated. The results showed that exposure to the aversive context induced a significant increase in freezing and Fos protein expression in the PrL, in the anterior cingulate cortex, areas 1 and 2 (Cg1 and Cg2), but not in the infralimbic cortex. The administration of metyrapone induced a decrease on the expression of freezing and Fos in PrL, Cg1 and Cg2. Bilateral administration of spironolactone (a MR antagonist) in PrL before the test, decreased conditioned fear response and the pretreatment with RU38486 (a GR antagonist) abolished this effect. The results also showed that the decrease of freezing response induced by intra-PrL corticosterone injections was abolished by prior administration of RU38486, but not by spironolactone, indicating that corticosterone recruits preferentially GR to produce the observed effects. Prior administration of the NMDA receptor antagonist also prevented the effects induced by corticosterone treatment in the PrL, suggesting that part of rapid effects of glucocorticoids on the expression of conditioned fear occurs by an interaction with the glutamatergic system. Additionally, NMDA administration in the PrL prior to the test induced similar effects to corticosterone treatment in this region. Overall, the results suggest that the release of corticosterone during the presentation of a conditioned aversive stimulus influences the mPFC activity so that a change in the balance of the activities mediated by MR and GR through an increase in GR activity interacts with the glutamatergic system by increasing the activity of NMDA receptors influencing the expression of contextual fear conditioning response. It is suggested that the reduction in the expression of conditioned fear observed after local administration of corticosterone in the PrL is also due to changes in the balance between MR and GR towards an increase in the actions mediated by GR, as well as an increase in the release of glutamate and a greater NMDA receptor activity in this region. contextual conditioned fear córtex pré-frontal medial corticosterona corticosterone glucocorticoid receptor medial prefrontal cortex medo condicionado contextual mineralocorticoid receptor NMDA NMDA receptor glicocorticóide receptor mineralocorticóide
154	Roles of astroglial cannabinoid type 1 receptors (CB1) in memory and synaptic plasticity / Rôles du récepteur aux cannabinoïdes de type 1 des astrocytes dans la mémoire et la plasticité synaptique Robin, Laurie 30 November 2018 (has links) Le système endocannabinoïde est un important modulateur des fonctions physiologiques. Il est composé des récepteurs aux cannabinoïdes, de ses ligands lipides endogènes (les endocannabinoïdes) et de la machinerie enzymatique pour leur synthèse et leur dégradation. Les récepteurs aux cannabinoïdes de type 1 (CB1) sont exprimés dans différents types cellulaires dans le cerveau et sont connus pour être impliqués dans les processus mnésiques. Les endocannabinoïdes sont mobilisés dépendamment de l’activité notamment dans les régions cérébrales impliquées dans la mémoire telle que l’hippocampe. Dans cette région, les récepteurs CB1 sont exprimés au niveau des terminaisons neuronales présynaptiques où leur stimulation inhibe la libération de neurotransmetteurs, modulant ainsi différentes formes d’activité synaptique. Outre leur expression sur les neurones, les récepteurs CB1 sont également exprimés par les astrocytes. Avec l’élément pré- et post-synaptique, les astrocytes font partis de la « synapse tripartite » où ils participent à la plasticité synaptique et les processus mnésiques associés. De manière intéressante, la stimulation des récepteurs CB1 astrocytaires facilite la transmission glutamatergique dans l’hippocampe. Dans cette région, les astrocytes régulent l’activité des N-methyl-Daspartate receptors (NMDARs) à travers le contrôle des niveaux synaptiques de leur co-agoniste, la D-serine, modulant ainsi la plasticité synaptique à long terme. Cependant, le mécanisme entrainant la libération de D-serine par les astrocytes n’est pas identifié. De manière intéressante, notre laboratoire a montré que les effets délétères des cannabinoïdes exogènes sur la mémoire de travail spatial sont médiés par les récepteurs CB1 astrocytaires à travers un mécanisme dépendant des NMDARs dans l’hippocampe. Cependant, le rôle physiologique des récepteurs CB1 astrocytaires restent méconnus. Une des formes de mémoire impliquant le récepteurs CB1 est la mémoire de reconnaissance d’objet (NOR). La stimulation exogène des récepteurs CB1 hippocampique inhibe la consolidation de la NOR mais la délétion constitutive des récepteurs CB1 n’affecte pas la NOR, suggérant que la signalisation des récepteurs CB1 endogènes n’est pas nécessaire. Cependant, de récentes études soulignent que la délétion globale du gène CB1 pourrait masquer le rôle des récepteurs CB1 des différents types cellulaires. Ceci indique la nécessité de nouveaux outils plus sophistiqués afin de totalement comprendre le rôle physiologique du système endocannabinoïde dans des comportements complexes. Dans cette étude, nous avons étudié le rôle physiologique des récepteurs CB1 astrocytaires dans la formation de la NOR et la plasticité synaptique. En utilisant une combinaison d’approches génétiques, comportementales, électro-physiologiques, d’imagerie et de biochimie, nous avons montré que l’activation endogène des récepteurs CB1 astrocytaires est nécessaire pour la consolidation de la NOR à long terme, et ceci à travers un mécanisme impliquant l’apport en D-sérine, afin de stimuler l’activité des NMDARs synaptiques de l’hippocampe dorsal. Cette étude révèle un mécanisme inattendu à la base de la libération de D-sérine, entrainant l’activité des NMDARs et la formation de la mémoire à long terme. / The endocannabinoid system is an important modulator of physiological functions. It is composed of cannabinoid receptors, their endogenous lipid ligands (the endocannabinoids) and the enzymatic machinery for endocannabinoid synthesis and degradation. The type-1 cannabinoid receptors (CB1) are expressed in different cell types of the brain and are known to be involved in memory processes. Endocannabinoids are mobilized in an activity-dependent manner in brain areas involved in the modulation of memory such as the hippocampus. In this brain region, CB1 receptors are mainly expressed at neuronal pre-synaptic terminals where their stimulation inhibits the release of neurotransmitters, thereby modulating several forms of synaptic activity. Besides their expression in neurons, CB1 receptors are also expressed in astrocytes. Along with the pre- and post-synaptic neurons, astrocytes are part of the “tripartite synapse”, where they participate in synaptic plasticity and associated memory processes. Interestingly, modulation of astroglial CB1 receptors has been proposed to facilitate glutamatergic transmission in the hippocampus. In this brain area, astrocytes regulate the activity of N-methyl-D-aspartate receptors (NMDARs) through the control of the synaptic levels of their co-agonist D-serine, thereby mediating long-term synaptic plasticity. However, the mechanisms inducing D-serine release by astrocytes are still not identified. Interestingly, our laboratory showed that the negative effect of exogenous cannabinoids on spatial working memory is mediated by astroglial CB1 receptors through a NMDAR-dependent mechanism in the hippocampus, but the physiological role of astroglial CB1 remains unknown. One of the forms of memory involving CB1 receptors is novel object recognition (NOR) memory. The exogenous stimulation of hippocampal CB1 receptors inhibits the consolidation of long-term NOR formation. Constitutive global deletion of CB1 receptors in mice leaves NOR memory intact, suggesting that endogenous CB1 receptor signaling is not necessary for long-term NOR. However, recent studies pointed-out that, likely due to compensatory mechanisms, the global deletion of the CB1 gene might mask cell type-specific roles of CB1 receptors, indicating that more sophisticated tools are required to fully understand the physiological roles of the endocannabinoid system in complex behavioral functions. In this work, we investigated the physiological role of the astroglial CB1 receptors on NOR memory formation and synaptic plasticity. By using a combination of genetic, behavioral, electrophysiological, imaging and biochemical techniques, we showed that endogenous activation of astroglial CB1 receptors is necessary for the consolidation of long-term NOR memory, through a mechanism involving the supply of D-serine to enhance synaptic NMDARs-dependent plasticity in the dorsal hippocampus. This study uncovers an unforeseen mechanism underlying D-serine release, triggering NMDARs activity and long-term memory formation.ory. Astrocytes Récepteurs CB1 astrogliaux Mémoire Ltp Récepteurs Nmda D-Sérine Hippocampe Astrocytes Astroglial Cb1 receptors Memory Ltp Nmda receptors D-Serine Hippocampus
155	Inibição do receptor de glutamato do tipo NMDA em um modelo de hipóxia-isquemia prenatal: avaliação morfofuncional do cerebelo / Inhibition of glutamate NMDA receptor in a prenatal hipoxia-ischemia model: morphofunctional analises of cerebellum Tiago Savignon Cardoso Machado 26 March 2013 (has links) Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Lesões sistêmicas peri e pré-natais alteram o desenvolvimento do SNC, levando a problemas cognitivos e motores em crianças que podem perdurar por toda a vida. Um tipo particular de lesão é a hipóxia-isquemia (HI), caracterizada pela interrupção momentânea ou permanente do fluxo sanguíneo. Um dos mecanismos propostos para as lesões decorrentes da HI é a excitotoxicidade glutamatérgica. O uso de inibidores da neurotransmissão glutamatérgica tem sido estudados em diversos modelos de HI. Neste trabalho, avaliamos os efeitos morfofuncionais da administração de um antagonista não-competitivo do receptor de glutamato NMDA sobre o desenvolvimento do cerebelo. Ratas no 18 dia de gestação foram anestesiadas, os cornos uterinos expostos e as 4 artérias uterinas obstruídas por 45 minutos (Grupo H). Animais controle tiveram os úteros expostos, sem a obstrução (Grupo S). Após a cirurgia a gestação prosseguiu. Somente animais nascidos a termo foram utilizados. Um dia após o nascimento, metade de cada ninhada foi designada para receber MK801, 0,3mg/kg/dia, (grupos SM e HM) e a outra metade recebeu solução salina (grupos SS e HS), por 5 dias. Após anestesia e perfusão-fixação com paraformaldeído 4% aos 9, 23, 30 e 60 dias pós-natais, cortes parassagitais do cerebelo foram obtidos em criótomo e submetidos à imunohistoquímica para calbindina, GFAP, GLAST, PDGFRα e MBP. A partir de 45 dias de vida, os animais foram testados em vários de testes comportamentais: labirinto em cruz elevado (LCE), campo vazado (CV), ROTAROD, teste de caminhada sobre barras (ladder test) e teste do comprimento da passada (stride length). Aos 9 dias, a espessura da árvore dendrítica era menor nos animais SM, HS/HM, demonstrando efeitos deletérios tanto do MK801 quanto da HI. Menor número de células PDGFRα+ foi observado nos animais HS/HM, sem efeitos da administração de MK801. Aos 23 dias, maior número de células PDGFRα+ foi observado nos animais HM comparado aos outros 3 grupos, indicando efeito neuroprotetor do MK801. Nessa idade, menor número de fibras mielinizadas (MBP+) foi observada nos animais HS, e a administração de MK801 parece reverter estes efeitos. Aos 9 dias a distribuição de GLAST estava alterada nos animais HS, com os efeitos da HI parcialmente revertidos pelo MK801. Não foram observados efeitos da HI ou do MK801 sobre comportamentos relacionados a ansiedade pelo LCE, assim como na latência de queda no ROTAROD. HI piora a performance motora no ladder test. No teste do CV, não observamos efeitos da HI sobre a busca por novidade assim como sobre a atividade locomotora espontânea. No entanto, MK801 diminui comportamentos de autolimpeza e a atividade locomotora espontânea. Menor variação das passadas foi observada em decorrência da administração de MK801 no stride length, com nenhum efeito da HI. Nossos resultados demonstram que a inibição do receptor NMDA tem um efeito neuroprotetor sobre os progenitores de oligodendrócitos e mielinização, provavelmente pela manutenção da capacidade proliferativa por um período maior. A atividade do receptor NMDA exerce importante papel na diferenciação das células de Purkinje, assim como na distribuição do transportador GLAST, corroborando a importância deste receptor na gênese das lesões causadas pela HI. / Peri and prenatal systemic lesions alter CNS development leading to motor and cognitive problems in children that might persist throughout life. A particular kind of injury, the hypoxic ischemic (HI), is characterized by a permanent or temporary blockage of blood flow. One of the proposed mechanisms downstream from a HI event is called glutamatergic excitotoxicity. The administration of glutamate inhibitors has been studied in HI models for several years. In this work, we evaluated the effects of administration of a non-competitive antagonist of glutamate receptor, NMDA, on cerebellar development and behavioral tests of HI animals. Pregnant rats in the 18th gestational day were anesthetized, the uterine horns were exposed and the four uterine arteries were clamped for 45 minutes (group H). Sham controls had the uterine horns exposed, but no arteries were clamped (group S). Gestation proceeded after surgery. Only full term animals were used. One day after birth half the animals was assigned to receive either SALINE (groups SS and HS) or MK801 (groups SM and HM). Animals were anesthetized and perfused with 4% paraformaldehyde at 9, 23, 30 and 60 days of age. Parasagittal cerebellar sections were submitted to Calbindin, GFAP, GLAST, PDGFRα and MBP immunohistochemistry. Beginning at P45 animals were subjected to a battery of behavioral tests: elevated plus maze (EPM), hole board (HB), ROTAROD, ladder test and stride length. At P9 the dendritic tree of Purkinje cells were thinner in SM, HS/HM animals, indicating that both HI and MK801 are deleterious regarding this Purkinje cell differentiation. A lower number of PDGFRα+ cells was observed in HS/HM animals, with no effects of MK801 administration. At P23 a greater number of PDGFRα+ cells was found in HM animals when compared to the other 3 groups, demonstrating a neuroprotector effect of MK801. A lower number of myelinated fibers (MBP+) was observed in HS animals at P9, and MK801 administration reverse this effect. At P9, GLAST distribution was altered in HS animals, and MK801 partially reverse this altered distribution. No effects of HI and MK801 were observed in the EPM and ROTAROD tests. HI decreased motor performance of hind limbs in the ladder test, though no effect of MK801 was noted. In the HB test, we do not observe HI effects regarding the novelty seeking behavior and locomotor activity, otherwise the administration of MK801 decreased the number of grooming and locomotor activity. In the stride length test, we do not observed effects of HI although MK801 augmented the length variation of the fore limbs. Our results show that inhibition of NMDA receptors exerts a neuroprotector effect on oligodendrocyte progenitor cells and myelination, probably by temporarily inhibiting differentiation of those, providing more time to proliferate. NMDA activity exerts a crucial role in Purkinje cell differentiation as well as in GLAST distribution. Taken together our results lead us to conclude that NMDA receptor activity has an important role in the genesis of lesions caused by HI events. Hipóxia-isquemia prenatal Cerebelo Receptor NMDA Células de Purkinje Oligodendrócitos Mielina Prenatal hipóxia-ischemia Cerebellum NMDA receptor Purkinje cells Oligodendrocytes Myelin NEUROFISIOLOGIA
156	Atividade antinociceptiva de Borreira verticillata (L.) G. Mey. e modo de interação com a cicloxigenase COX-2 e receptor N-metil-D-aspartato NMDA / Antinociceptive activity of Borreira verticillata (L.) G. Mey. And mode of interaction with COX-2 cyclooxygenase and NMDA N-methyl-D-aspartate receptor Silva, Rosa Helena Moraes 19 October 2016 (has links) Submitted by Rosivalda Pereira (mrs.pereira@ufma.br) on 2017-06-14T17:55:12Z No. of bitstreams: 1 RosaHelenaSilva.pdf: 2716670 bytes, checksum: 07dee1e77d704e91281c33c31e8c4938 (MD5) / Made available in DSpace on 2017-06-14T17:55:12Z (GMT). No. of bitstreams: 1 RosaHelenaSilva.pdf: 2716670 bytes, checksum: 07dee1e77d704e91281c33c31e8c4938 (MD5) Previous issue date: 2016-10-19 / Borreria verticillata (L.) G. Mey species known as broom vassourinha has antibacterial, antimalarial, hepatoprotective, antioxidative, analgesic and antiinflammatory activities; however, its antinociceptive action still demands more thorough investigation. The present study was to assess the antinociceptive activity of B. verticillata crude hydroalcoholic extract (EHBv) and the ethyl acetate fraction (FAc) by means of in vivo and in silico studies. In vivo assessment included the paw edema test, the writhing test, the formalin test and the tail flick test. Wistar rats and Swiss mice were divided into 6 groups and given the following treatments oral: 0.9% NaCl control group (CTL), 10 mg/kg memantine (MEM), 10 mg/kg indomethacin (INDO), 500 mg/kg EHBv (EHBv 500), 25 mg/kg FAC (FAc 25), 50 mg/kg and FAc (FAC 50). EHBv, FAc 25 and 50 treatments exhibited anti-edematous and peripheral antinociceptive effects. For in silico assessment, compounds found in FAc were subjected to molecular docking, and the leading compound was selected for molecular dynamics (MD) simulations. Ursolic acid exhibited better affinity parameters with the enzyme COX-2 and the NMDA receptor subunits GluN1a and GluN2B on molecular docking. In MD simulations, AU exhibited highly frequent interactions with residues Arg120 and Glu524 in the COX-2 active site and NMDA, whereby it might prevent COX-2 and NMDA receptor activation. Treatment with ursolic acid 10mg / Kg (AU) showed peripheral and central antinoceceptivo effect. The antinociceptive effect of B. verticillata might be predominantly attributed to peripheral actions, including the participation of anti-inflammatory components. Ursolic acid is the main active component and seems to be a promising source of COX-2 inhibitors and NMDA receptor antagonists / Borreria verticillata (L.) G. Mey espécie conhecida como vassourinha apresenta atividade antibacteriana, antimalárica, hepatoprotetora, antioxidante, analgésica e anti-inflamatória, entretanto sua atividade antinociceptiva é pouco estudada. O objetivo deste trabalho foi avaliar atividade antinociceptiva do extrato hidroalcoólico bruto (EHBv) e fração acetato de etila (FAc) de B. verticillata realizando estudos in vivo e in silico. Para avaliação in vivo, foram utilizados os testes do edema de pata, contorções abdominais, formalina e tail flick. Ratos Wistar e camundongos Swiss foram tratados via oral e divididos em 6 grupos: controle-NaCl 0.9%(CTL), memantina 10 mg/Kg (MEM), indometacina 10 mg/Kg (INDO), EHBv 500 mg/kg (EHBv 500), FAc 25 mg/Kg (FAc 25), FAc 50 mg/Kg (FAc 50). O tratamento com EHBv 500, FAc 25 e 50 apresentou efeito antiedematogênico e antinociceptivo periférico. Para avaliação in silico os compostos identificados na FAc foram submetidos a docagem molecular, o melhor composto foi selecionado para simulações de dinâmica e testado in vivo molecular. O ácido ursólico apresentou melhores parâmetros de afinidade com COX-2, GluN1a e GluN2B durante a docagem molecular. Nas simulações por dinâmica molecular, o ácido ursólico apresentou alta frequência de contatos com Arg120 e Glu524 do local ativo da COX- 2 e com o domínio LBD da Glun1a e GluN2B podendo com isso, impedir a ativação da COX-2 e do receptor NMDA. O tratamento com ácido ursólico 10mg/Kg (AU) apresentou efeito antinoceceptivo periférico e central. Sugere-se que o efeito antinociceptivo periférico de B. verticillata pode ser atribuído predominantemente à ação de compostos com ação anti-inflamatória. O ácido ursólico é o principal composto ativo, sendo um composto promissor para o desenvolvimento de fármacos inibidores da COX-2 e antagonistas dos receptores NMDA. Borreria verticillata COX-2 Receptor NMDA Docagem molecular Simulações de dinâmica molecular Borreria verticillata NMDA receptor Molecular docking Molecular dynamics simulations Ciências da Saúde Farmacognosia
157	Estudo do envolvimento da via NMDA-NO do eixo dorso-ventral do hipocampo sobre o comportamento induzido pelo estresse de nado forçado / Involvement of the NMDA-NO pathway of the dorso/ventral hippocampal axis in the modulation of behavioral responses elicited by the forced swimming test Cassiano Ricardo Alves Faria Diniz 31 January 2013 (has links) Acredita-se que diferenças hodológicas e diferente padrão de expressão gênica ao longo do eixo dorso/ventral do hipocampo seriam responsáveis pela distinta função entre a porção dorsal (HD) e ventral do mesmo (HV). HD seria responsável por processos cognitivos, tais como memória e aprendizagem espacial, e o HV pelas respostas neuroendócrinas e emocional-motivacionais ao estresse. No entanto, não há muitos estudos acerca de diferenças entre HD e HV na modulação de comportamentos relacionados à neurobiologia da depressão. Há, contudo, dados indicando que o bloqueio de receptores glutamatérgicos do tipo NMDA ou da síntese de NO no HD induz efeito semelhante ao dos antidepressivos (i.e. do tipo antidepressivo) no teste do nado forçado (TNF). Quanto ao HV, a função da neurotransmissão glutamatérgica/nitrérgica na neurobiologia da depressão permanece não investigado. Dessa forma, o objetivo do presente estudo foi realizar o bloqueio reversível do HD ou do HV, em diferentes momentos, em animais submetidos ao TNF. O próximo passo foi realizar a micro-injeção intra-HD ou intraHV do antagonista NMDA AP-7 ou do inibidor da óxido nítrico sintase neuronal (nNOS), N-PLA, ou do inibidor da guanilato ciclase solúvel (sGC), ODQ. Os resultados mostram que o bloqueio do HD ou do HV com cloreto de cobalto (CoCl2, bloqueador da neurotransmissão sináptica dependente de cálcio) não modificou o comportamento dos animais no TNF. No entanto a administração de AP-7 ou N-PLA ou ODQ no HV antes do teste, reduziu o tempo de imobilidade no TNF. Por outro lado, a injeção dessas drogas no HD foi capaz de reduzir o tempo de imobilidade quando administradas tanto depois do pré-teste quanto antes do teste. Estes resultados sugerem que as vias NMDA-NO do HD e do HV, estariam envolvidas na modulação da resposta comportamental frente ao estresse do nado forçado. Além disso, os dados indicam que a participação dessas estruturas é importante em diferentes momentos após a exposição ao estresse. / It is believed that hodological and genetic pattern of expression differences along dorsal/ventral hippocampal axis would be responsible for distinct functions attributed to its dorsal (DH) and ventral (VH) poles. DH would be responsible for cognitive process, such as spatial memory and learning, whereas the VH would be responsible for neuroendocrine and emotional-motivation responses to stress. However, there is no many studies about possible differences between DH and VH in the modulation of behavioral responses related to the neurobiology of depression. Though, there are data showing that the blockade of glutamatergic NMDA receptors blockers or NO synthesis inhibition within the DH induces similar effect to that of antidepressant drugs (like antidepressant effect) in the forced swimming test (FST). On the VH, The role of the glutamatergic/nitrergic neurotransmission remains to be investigated. Thus, the aim of this work was to perform the reversible blockade of DH or VH, at different times, in animals subjected to FST. Additionally, the next step was to perform a microinjections into the DH or the VH of NMDA antagonist (AP-7), inhibitor of neuronal nitric oxide synthase (nNOS, N-PLA), or the inhibitor of soluble guanylate cyclase (sGC, ODQ). The results show that blocking the VH or the DH (cobalt chloride, calcium dependent neurotransmission inhibitor) did not modify the behavior of animals during the TNF. However administration of AP-7, N-PLA or ODQ intra-HV, before testing, caused antidepressant-like effects. Moreover, injection of such drugs, intra-HD, was able to induce similar results when administered both after the pre-test and before testing. These results suggest that NMDA-NO pathway of both VH and DH is involved in the modulation of emotional responses to the forced swim stress, although there may be an interest differential participation of these structures at different times after exposure to stress. Hipocampo dorsal e ventral Óxido nítrico Receptor glutamatérgico NMDA Teste do nado forçado Dorsal and ventral hippocampus Forced swimming test Glutamatergic NMDA receptor Nitric oxide
158	Estudo do envolvimento da via NMDA-NO do eixo dorso-ventral do hipocampo sobre o comportamento induzido pelo estresse de nado forçado / Involvement of the NMDA-NO pathway of the dorso/ventral hippocampal axis in the modulation of behavioral responses elicited by the forced swimming test Diniz, Cassiano Ricardo Alves Faria 31 January 2013 (has links) Acredita-se que diferenças hodológicas e diferente padrão de expressão gênica ao longo do eixo dorso/ventral do hipocampo seriam responsáveis pela distinta função entre a porção dorsal (HD) e ventral do mesmo (HV). HD seria responsável por processos cognitivos, tais como memória e aprendizagem espacial, e o HV pelas respostas neuroendócrinas e emocional-motivacionais ao estresse. No entanto, não há muitos estudos acerca de diferenças entre HD e HV na modulação de comportamentos relacionados à neurobiologia da depressão. Há, contudo, dados indicando que o bloqueio de receptores glutamatérgicos do tipo NMDA ou da síntese de NO no HD induz efeito semelhante ao dos antidepressivos (i.e. do tipo antidepressivo) no teste do nado forçado (TNF). Quanto ao HV, a função da neurotransmissão glutamatérgica/nitrérgica na neurobiologia da depressão permanece não investigado. Dessa forma, o objetivo do presente estudo foi realizar o bloqueio reversível do HD ou do HV, em diferentes momentos, em animais submetidos ao TNF. O próximo passo foi realizar a micro-injeção intra-HD ou intraHV do antagonista NMDA AP-7 ou do inibidor da óxido nítrico sintase neuronal (nNOS), N-PLA, ou do inibidor da guanilato ciclase solúvel (sGC), ODQ. Os resultados mostram que o bloqueio do HD ou do HV com cloreto de cobalto (CoCl2, bloqueador da neurotransmissão sináptica dependente de cálcio) não modificou o comportamento dos animais no TNF. No entanto a administração de AP-7 ou N-PLA ou ODQ no HV antes do teste, reduziu o tempo de imobilidade no TNF. Por outro lado, a injeção dessas drogas no HD foi capaz de reduzir o tempo de imobilidade quando administradas tanto depois do pré-teste quanto antes do teste. Estes resultados sugerem que as vias NMDA-NO do HD e do HV, estariam envolvidas na modulação da resposta comportamental frente ao estresse do nado forçado. Além disso, os dados indicam que a participação dessas estruturas é importante em diferentes momentos após a exposição ao estresse. / It is believed that hodological and genetic pattern of expression differences along dorsal/ventral hippocampal axis would be responsible for distinct functions attributed to its dorsal (DH) and ventral (VH) poles. DH would be responsible for cognitive process, such as spatial memory and learning, whereas the VH would be responsible for neuroendocrine and emotional-motivation responses to stress. However, there is no many studies about possible differences between DH and VH in the modulation of behavioral responses related to the neurobiology of depression. Though, there are data showing that the blockade of glutamatergic NMDA receptors blockers or NO synthesis inhibition within the DH induces similar effect to that of antidepressant drugs (like antidepressant effect) in the forced swimming test (FST). On the VH, The role of the glutamatergic/nitrergic neurotransmission remains to be investigated. Thus, the aim of this work was to perform the reversible blockade of DH or VH, at different times, in animals subjected to FST. Additionally, the next step was to perform a microinjections into the DH or the VH of NMDA antagonist (AP-7), inhibitor of neuronal nitric oxide synthase (nNOS, N-PLA), or the inhibitor of soluble guanylate cyclase (sGC, ODQ). The results show that blocking the VH or the DH (cobalt chloride, calcium dependent neurotransmission inhibitor) did not modify the behavior of animals during the TNF. However administration of AP-7, N-PLA or ODQ intra-HV, before testing, caused antidepressant-like effects. Moreover, injection of such drugs, intra-HD, was able to induce similar results when administered both after the pre-test and before testing. These results suggest that NMDA-NO pathway of both VH and DH is involved in the modulation of emotional responses to the forced swim stress, although there may be an interest differential participation of these structures at different times after exposure to stress. Dorsal and ventral hippocampus Forced swimming test Glutamatergic NMDA receptor Hipocampo dorsal e ventral Nitric oxide Óxido nítrico Receptor glutamatérgico NMDA Teste do nado forçado
159	Développement cérébral postnatal, sommeil et activité épileptique : impact de l'invalidation de la sous-unité GluN2A des récepteurs NMDA impliquée dans le spectre des épilepsies-aphasies / Postnatal brain development, sleep, and epileptic activity : impact of the invalidation of GluN2A subunit NMDA receptor involved in the epilepsy-aphasia spectrum Salmi, Manal 22 November 2018 (has links) Les récepteurs NMDA (NMDARs) sont des canaux cationiques activés par le glutamate. Les NMDARs participent au développement cérébral, à la plasticité synaptique, à l'apprentissage, à la mémoire et aux fonctions cognitives supérieures. Des variants pathogènes de GRIN2A, codant pour la sous-unité GluN2A des NMDARs, peuvent causer des épilepsies focales et encéphalopathies épileptiques de l'enfance avec troubles du langage et de la parole, connue sous le nom de spectre des épilepsies-aphasies (EAS). Les caractéristiques communes de l'EAS comprennent une activité épileptiforme âge-dépendante activée pendant le sommeil lent associées à des troubles de la parole, de la cognition et du comportement qui peuvent persister à l'âge adulte. Afin de commencer à identifier les événements précoces possiblement associés aux altérations de GluN2A, nous avons exploré le modèle correspondant de souris knock-out (KO) du gène Grin2a. Nous avons notamment recherché des altérations précoces de la communication vocale, de la (micro)structure cérébrale, et de l'activité électrique néocorticale. Nos données démontrent l'existence de plusieurs altérations à ces différents niveaux, parfois transitoirement à des stades spécifiques. De plus, les enregistrements néocorticaux mettent en évidence des anomalies de divers types liées au sommeil lent. Nos résultats indiquent également un rôle de GluN2A dans la communication vocale, dans l'organisation de la microstructure cérébrale, et dans la maturation des activités d’ondes lentes. Ces données suggèrent que les souris KO Grin2a représentent un modèle fiable pour appréhender les mécanismes physiopathologiques associés à l’EAS et leur séquence temporelle. / NMDA receptors (NMDARs) are cation channels that are gated by glutamate - the major excitatory neurotransmitter of the central nervous system. NMDARs participate in brain development, synaptic plasticity, learning, memory and high cognitive functions. Pathogenic variants in the GRIN2A gene, which encodes the GluN2A subunit of the NMDARs, can cause a group of childhood focal epilepsies and epileptic encephalopathies with speech and language dysfunction, known as the epilepsy-aphasia spectrum (EAS). Features shared in common by EAS disorders include age-dependent epileptiform activity activated in sleep associated with speech, neuropsychological and behavioral deficits that may persist in adulthood. In order to start in deciphering the early events possibly associated with the dysfunctioning of GluN2A-containing NMDARs, we have explored the corresponding Grin2a knock-out (KO) mouse model. That consisted in looking for early alterations of vocal communication, of brain (micro)structure, and of neocortical electrical activity. Our data demonstrated the existence of several alterations at those various levels. Some alterations were transient only, being detected at selective stages; also, neocortical recordings pointed for sleep-related anomalies of various types. Our data also indicated a role for GluN2A-containing NMDA receptors in vocal communication, fine organization of brain microstructure, and proper maturation of slow wave activity in sleep. Altogether, our data suggest that the Grin2a KO mice represent a reliable model to further elucidate the pathophysiological mechanisms associated with the disorders of EAS and their temporal sequences. Epilepsies aphasies LKS CSWSS Sommeil Développement cérebral Récepteur NMDA Epilepsy aphasia spectrum LKS CSWSS Sleep Brain development NMDA receptor In vivo neocortical recordings 612
160	Are nAChRs and NMDA receptors involved in low dose ethanol-nicotine toxicity in SH-SY5Y cells? Jonsson, Karl January 2013 (has links) Consumption of alcohol and tobacco is common all around the world and these drugs are frequently consumed concomitantly. It has been estimated that 70-80 % of alcoholics are smokers and non-alcoholic drinkers are more often smokers than teetotallers. Alcohol and tobacco may affect the risk of developing neurological diseases and might influence this risk differently when combined compared to when only one of these compounds is consumed. Some in vitro-research have shown that non-toxic concentrations of ethanol and nicotine, in combination, can exert toxicity, and might do so in a synergistic way. In this work, investigations were made to see if the neuronal nicotinic acetylcholine receptors (nAChRs) and NMDA receptors are involved in this interactive behaviour between ethanol and nicotine. A human neuroblastoma SH-SY5Y cell line was treated with ethanol and nicotine at different concentrations and cell viability was measured through an MTT-assay. A significant reduction in cell viability was induced by chronic treatment with a low-dose combination of ethanol and nicotine. The cell viability reduction was completely inhibited by pretreatment with the non-specific nAChR antagonist mecamylamine. This suggests that nAChRs are involved in low-dose ethanol-nicotine interactions. The NMDA receptor antagonist memantine did not affect the ethanol-nicotine effect, which implies that NMDA receptors are not involved in low-dose ethanol-nicotine interactions in SH-SY5Y cells. However, it is unclear if the SH-SY5Y cell line expresses fully functional NMDA receptors. The expression of NMDA receptors might vary with cell passage number. Further research has to be done to uncover the contribution of specific nAChR subtypes to the ethanol-nicotine interaction. There also remains to be revealed if human neuroblastoma SH-SY5Y cells express fully functional NMDA receptors and how cell passage number affects the expression of these receptors. alcohol ethanol nicotine SH-SY5Y nAChR interaction toxicity NMDA mecamylamine memantine alkohol etanol nikotin SH-SY5Y interaktion toxicitet NMDA nikotinreceptor nAChR mecamylamin memantin

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