Global ETD Search

111	Clusterin and Megalin in The Spinal Cord Wicher, Grzegorz January 2006 (has links) <p>Nerve injury induces up-regulation of the chaperone protein clusterin in affected neurons and adjacent astrocytes but the functional significance of this response is unclear. We find that motor neuron survival is significantly greater in clusterin(+/+) compared to (-/-) mice. These results suggest that endogenous expression of clusterin is neuroprotective after nerve injury. However, motor neuron survival in clusterin overexpressing mice was not different from that in wildtype mice. In contrast, treatment of neuronal cultures with clusterin-TAT recombinant protein is neuroprotective, including a positive effect on neuronal network complexity.</p><p>Since extracellular clusterin complexes are endocytosed after binding to various receptors, we examined the expression of known clusterin binding receptors in the spinal cord. We find that megalin is expressed in the nuclei of two cell populations in the mouse spinal cord: i) oligodendrocytes in late postnatal and adult spinal cord white matter, and ii) transiently (E11-15) in a population of immature astrocytes in the dorsal spinal cord. We find no correlation between clusterin and megalin in the intact or injured spinal cord. However, intranuclear localization of megalin, suggesting signalling properties, is supported by the co-localization with γ-secretase, the enzyme responsible for endodomain cleavage of megalin. Megalin deficient mice display a pronounced deformation of the dorsal part of spinal cord, an almost complete absence of oligodendroglial progenitor cells, and a marked reduction in the population of mature astrocytes at later prenatal developmental stages.</p><p>Taken together, our findings indicate that megalin is a novel signalling molecule for distinct populations of glial cells in the pre- and postnatal spinal cord. The functional role(s) of megalin is unknown. However, its expression patterns and cellular localization suggest that megalin regulates differentiation of oligodendrocytes and astrocytes in the prenatal spinal cord, as well as the function of myelinating oligodendrocytes in the postnatal spinal cord.</p> Neurosciences nerve degeneration hypoglossal nerve chaperone apolipoprotein development transcription factor astrocyte glial differentiation myelin cell signalling Neurovetenskap
112	Clusterin and Megalin in The Spinal Cord Wicher, Grzegorz January 2006 (has links) Nerve injury induces up-regulation of the chaperone protein clusterin in affected neurons and adjacent astrocytes but the functional significance of this response is unclear. We find that motor neuron survival is significantly greater in clusterin(+/+) compared to (-/-) mice. These results suggest that endogenous expression of clusterin is neuroprotective after nerve injury. However, motor neuron survival in clusterin overexpressing mice was not different from that in wildtype mice. In contrast, treatment of neuronal cultures with clusterin-TAT recombinant protein is neuroprotective, including a positive effect on neuronal network complexity. Since extracellular clusterin complexes are endocytosed after binding to various receptors, we examined the expression of known clusterin binding receptors in the spinal cord. We find that megalin is expressed in the nuclei of two cell populations in the mouse spinal cord: i) oligodendrocytes in late postnatal and adult spinal cord white matter, and ii) transiently (E11-15) in a population of immature astrocytes in the dorsal spinal cord. We find no correlation between clusterin and megalin in the intact or injured spinal cord. However, intranuclear localization of megalin, suggesting signalling properties, is supported by the co-localization with γ-secretase, the enzyme responsible for endodomain cleavage of megalin. Megalin deficient mice display a pronounced deformation of the dorsal part of spinal cord, an almost complete absence of oligodendroglial progenitor cells, and a marked reduction in the population of mature astrocytes at later prenatal developmental stages. Taken together, our findings indicate that megalin is a novel signalling molecule for distinct populations of glial cells in the pre- and postnatal spinal cord. The functional role(s) of megalin is unknown. However, its expression patterns and cellular localization suggest that megalin regulates differentiation of oligodendrocytes and astrocytes in the prenatal spinal cord, as well as the function of myelinating oligodendrocytes in the postnatal spinal cord. Neurosciences nerve degeneration hypoglossal nerve chaperone apolipoprotein development transcription factor astrocyte glial differentiation myelin cell signalling Neurovetenskap
113	Mécanismes moléculaires responsables des propriétés migratoires des gliomes [Texte imprimé] : rôle et dynamique des jonctions adhérentes dans la migration des astrocytes sains et tumoraux Peglion, Florent 14 September 2012 (has links) (PDF) Les gliomes sont les tumeurs cérébrales primitives les plus fréquentes. Dérivant des cellules gliales et majoritairement des astrocytes, les gliomes malins évoluent rapidement et sont associés à un très mauvais pronostic, en partie causé par leur nature invasive. Les cellules de gliomes infiltrent activement le parenchyme cérébral, ce qui leur permet d'échapper aux thérapies focales (chirurgie et radiothérapie), et de donner naissance à de nouveaux foyers tumoraux au voisinage direct ou à distance de la tumeur initiale. En analysant le transcriptome de plus de 130 gliomes de différents grades et en me focalisant uniquement sur les variations d'expression de gènes connus pour être impliqués dans la migration, l'invasion, l'adhérence et la polarité astrocytaire, j'ai mis en évidence une altération des jonctions adhérentes dans les gliomes et suggéré une corrélation inverse entre le niveau de la p120ctn et l'invasivité des gliomes in vitro et in vivo.. En contrôlant une boucle de recyclage inédite de la N-cadhérine dans les cellules en migration, la p120ctn régule spatialement les forces d'adhérence intercellulaire, et assure une migration collective dirigée. L'altération de sa fonction dans les astrocytes sains entraîne une augmentation de la dispersion des cellules, la perturbation de leur directionnalité et in fine une augmentation de leur vitesse de migration ; des caractéristiques identiques aux cellules de gliomes en migration. L'ensemble de ces résultats définit la p120ctn comme une nouvelle cible thérapeutique potentielle pour le traitement des gliomes diffus et comme un potentiel marqueur de l'invasivité des gliomes. [SDV:BC] Life Sciences/Cellular Biology Gliome astrocyte invasion tumorale migration collective jonctions adhérentes trafic et recyclage membranaire p120-caténine flux rétrograde
114	A Mathematical Model of CA1 Hippocampal Neurons with Astrocytic Input Ferguson, Katie January 2009 (has links) Over time astrocytes have been thought to function in an auxiliary manner, providing neurons with metabolic and structural support. However, recent research suggests they may play a fundamental role in the generation and propagation of focal epileptic seizures by causing synchronized electrical bursts in neurons. It would be helpful to have a simple mathematical model that represents this dynamic and incorporates these updated experimental results. We have created a two-compartment model of a typical neuron found in the hippocampal CA1 region, an area often thought to be the origin of these seizures. The focus is on properly modeling the astrocytic input to examine the pathological excitation of these neurons and subsequent transmission of the signals. In particular, we consider the intracellular astrocytic calcium fluctuations which are associated with slow inward currents in neighbouring neurons. Using our model, a variety of experimental results are reproduced, and comments are made about the potential differences between graded and “all-or-none” astrocytes. applied math neuroscience mathematical model astrocyte hippocampus epilepsy epileptiform burst seizure pyramidal neuron CA1 neuron Applied Mathematics
115	A Mathematical Model of CA1 Hippocampal Neurons with Astrocytic Input Ferguson, Katie January 2009 (has links) Over time astrocytes have been thought to function in an auxiliary manner, providing neurons with metabolic and structural support. However, recent research suggests they may play a fundamental role in the generation and propagation of focal epileptic seizures by causing synchronized electrical bursts in neurons. It would be helpful to have a simple mathematical model that represents this dynamic and incorporates these updated experimental results. We have created a two-compartment model of a typical neuron found in the hippocampal CA1 region, an area often thought to be the origin of these seizures. The focus is on properly modeling the astrocytic input to examine the pathological excitation of these neurons and subsequent transmission of the signals. In particular, we consider the intracellular astrocytic calcium fluctuations which are associated with slow inward currents in neighbouring neurons. Using our model, a variety of experimental results are reproduced, and comments are made about the potential differences between graded and “all-or-none” astrocytes. applied math neuroscience mathematical model astrocyte hippocampus epilepsy epileptiform burst seizure pyramidal neuron CA1 neuron Applied Mathematics
116	Traumatically-Induced Degeneration and Reactive Astrogliosis in 3-D Neural Co-Cultures: Factors Influencing Neural Stem Cell Survival and Integration Cullen, Daniel Kacy 29 November 2005 (has links) Traumatic brain injury (TBI) results from a physical insult to the head and often results in temporary or permanent brain dysfunction. However, the cellular pathology remains poorly understood and there are currently no clinically effective treatments. The overall goal of this work was to develop and characterize a novel three-dimensional (3-D) in vitro paradigm of neural trauma integrating a robust 3-D neural co-culture system and a well-defined biomechanical input representative of clinical TBI. Specifically, a novel 3-D neuronal-astrocytic co-culture system was characterized, establishing parameters resulting in the growth and vitality of mature 3-D networks, potentially providing enhanced physiological relevance and providing an experimental platform for the mechanistic study of neurobiological phenomena. Furthermore, an electromechanical device was developed that is capable of subjecting 3-D cell-containing matrices to a defined mechanical insult, with a predicted strain manifestation at the cellular level. Following independent development and validation, these novel 3-D neural cell and mechanical trauma paradigms were used in combination to develop a mechanically-induced model of neural degeneration and reactive astrogliosis. This in vitro surrogate model of neural degeneration and reactive astrogliosis was then exploited to assess factors influencing neural stem cell (NSC) survival and integration upon delivery to this environment, revealing that specific factors in an injured environment were detrimental to NSC survival. This work has developed enabling technologies for the in vitro study of neurobiological phenomena and responses to injury, and may aid in elucidating the complex biochemical cascades that occur after a traumatic insult. Furthermore, the novel paradigm developed here may provide a powerful experimental framework for improving treatment strategies following neural trauma, and therefore serve as a valid pre-animal test-bed. Astrocyte Traumatic brain injury Neural stem cells Reactive astrogliosis Neuron Cellular biomechanics Three-dimensional In vitro Neural cell culture
117	Effect of human equilibrative nucleoside transporter 1 (hENT1) and ecto-5' nucleotidase (eN) in adenosine formation by neurons and astrocytes under ischemic conditions. Chu, Stephanie S.T.Y. 17 August 2012 (has links) Adenosine (ADO) is an endogenous neuroprotectant. Under ischemic conditions ADO levels rise in the brain up to 100-fold. ADO in the brain is dependent on the movement across cell membranes by equilibrative nucleoside transporters (ENT) or produced from membrane bound ecto-5’ nucleotidase (eN). We used transgenic neurons with neuronal specific expression of human ENT1 (hENT1) and eN knockout (CD73 KO) astrocytes. The aim of this research was to determine the role of ENT1 and eN in ADO release from ischemic-like conditions in primary cultured neurons, astrocytes or co-cultures. Neurons primarily release intracellular ADO via ENTs; this effect was blocked by transporter inhibitor, dipyridamole (DPR). Astrocytes primarily convert ADO extracellularly from eN; this effect was with eN inhibitor α, β-methylene ADP (AOPCP). Combined neuron and KO astrocytes produced less ADO, extracellular ADO was inhibited by DPR but not AOPCP. Overall these results suggest that eN is prominent in the formation of ADO but other enzymes or pathways contribute to rising ADO levels in ischemic conditions. Adenosine ecto 5' nucleotidase (CD73) cerebral ischemia NMDA neuron astrocyte cell culture oxygen-glucose deprivation
118	Effect of human equilibrative nucleoside transporter 1 (hENT1) and ecto-5' nucleotidase (eN) in adenosine formation by neurons and astrocytes under ischemic conditions. Chu, Stephanie S.T.Y. 17 August 2012 (has links) Adenosine (ADO) is an endogenous neuroprotectant. Under ischemic conditions ADO levels rise in the brain up to 100-fold. ADO in the brain is dependent on the movement across cell membranes by equilibrative nucleoside transporters (ENT) or produced from membrane bound ecto-5’ nucleotidase (eN). We used transgenic neurons with neuronal specific expression of human ENT1 (hENT1) and eN knockout (CD73 KO) astrocytes. The aim of this research was to determine the role of ENT1 and eN in ADO release from ischemic-like conditions in primary cultured neurons, astrocytes or co-cultures. Neurons primarily release intracellular ADO via ENTs; this effect was blocked by transporter inhibitor, dipyridamole (DPR). Astrocytes primarily convert ADO extracellularly from eN; this effect was with eN inhibitor α, β-methylene ADP (AOPCP). Combined neuron and KO astrocytes produced less ADO, extracellular ADO was inhibited by DPR but not AOPCP. Overall these results suggest that eN is prominent in the formation of ADO but other enzymes or pathways contribute to rising ADO levels in ischemic conditions. Adenosine ecto 5' nucleotidase (CD73) cerebral ischemia NMDA neuron astrocyte cell culture oxygen-glucose deprivation
119	Efeito cerebroprotetor do pré-condicionamento isquêmico sobre aspectos celulares e funcionais no modelo de hemorragia intracerebral focal em ratos Wistar adultos Delgado, Thamiris Fenalti January 2017 (has links) O Acidente Vascular Encefálico (AVE) Hemorrágico representa mais de 10% de todos os casos de AVE e possui altas taxas de morbidade e de mortalidade. Os pacientes que sobrevivem a este evento permanecem com alguma disfunção motora, que algumas vezes é incapacitante. O extravasamento de sangue em um AVE hemorrágico ocorre, geralmente, em regiões onde há bifurcação de pequenas arteríolas penetrantes, como na região dos núcleos da base. O estriado, importante componente dessa região, está relacionado a funções motoras superiores, como o planejamento e a execução do movimento. Alguns estudos demonstram que o pré-condicionamento (PC) isquêmico pode gerar a tolerância a outros eventos que acometem o sistema nervoso. O PC é definido como fenômeno decorrente da exposição de um tecido ou órgão a um insulto sub-letal capaz de resultar em adaptações determinantes para a tolerância tecidual. Isso ocorre mesmo quando esses dois estímulos são de origens diferentes; neste caso diz-se que o PC desenvolveu tolerância cruzada. Desta forma, o presente estudo dedicou-se ao estudo de efeitos celulares e funcionais do pré-condicionamento isquêmico, por oclusão bilateral das artérias carótidas durante 10 minutos, sobre o modelo de hemorragia intracerebral (HIC), por administração intraestriatal de colagenase do tipo IV-S em ratos. A hipótese de trabalho era de que o PC causaria tolerância cruzada para a HIC, e consequente neuroproteção avaliada por testes motores, volume de lesão, com envolvimento de astrocitose e de micróglia reativa Foram usados 67 ratos machos Wistar adultos, divididos em 4 grupos: Sham (controle cirúrgico), PC, HIC, PC+HIC. Assim, os animais dos grupos PC e PC+HIC foram submetidos ao pré-condicionamento e 24 horas depois os animais HIC e PC+HIC receberam a injeção de colagenase, enquanto os animais Sham e PC receberam uma injeção de salina. A avaliação motora dos animais foi realizada a partir dos testes do cilindro e do Staircase. Trinta e quatro dias após a HIC os animais foram perfundidos e o estriado ipsilateral à injeção foi dissecada para obtenção de amostras teciduais necessárias à avaliação da perda tecidual e quantificação de intensidade de fluorescência de GFAP (proteína glial fibrilar ácida) e OX-42, importantes marcadores de astrócitos e microglia, respectivamente. Os resultados demonstram que: a) a HIC causa deficits motores em ambos os testes realizados, e que o PC reverte este efeito; b) a HIC causa lesão estriatal que não é revertido pelo pré-condicionamento; c) a HIC causa aumento da intensidade de fluorescência para GFAP e para OX-42, e o PC reverte apenas a reatividade da micróglia. Em conjunto, sugere-se que o pré-condicionamento isquêmico causa tolerância cruzada com a hemorragia intracerebral experimental, resultando em proteção funcional, mas não morfológica, possivelmente associada a uma diminuição da reatividade da microglia após o evento hemorrágico. / Hemorrhagic Vascular Stroke (EVA) represents more than 10% of all stroke cases with high rates of morbidity and mortality. Patients who survive this event, remain with some motor dysfunction, which is sometimes disabling. The extravasation of blood in a hemorrhagic stroke occurs, generally, in regions where there is bifurcation of small vessels, as in the region of striatum. The striatum is related to the higher motor functions, such as the planning and execution of the movement. Some studies have shown that preconditioning (PC) can generate a tolerance to other events that accompany the nervous system. The PC is presented as the source of the exposure of a sub-lethal, resulting in an adaptation of determinants to a tissue tolerance. Thus, the present study aimed shows the ischemic preconditioning effects, by bilateral occlusion of the carotid arteries for 10 minutes, on the intracerebral hemorrhage (ICH) model, by intra- striatum administration of type IV S collagenase in rats. The working hypothesis was tolerance to HIC, and consequent neuroprotection by motor function, lesion volume, astrocytosis and reactive microglia. A total of 84 male Wistar adult rats were divided into 4 groups: Sham (surgical control), PC, HIC, PC + HIC Thus, the animals of the PC and PC + HIC groups were introduced to the preconditioning and 24 hours later, the HIC and PC + HIC animals received a collagenase injection, while the Sham and PC animals received a saline injection. The evaluation of the animal function was performed from cylinder and Staircase tests. Thirty-four days after the surgery, the striatum was dissected and prepared to lesion volume analysis and fluorescence intensity of GFAP quantification (acid glial fibrillary protein) and OX-42, important astrocyte and microglia markers respectively. The results demonstrate that: a) an HIC causes motor deficits in both tests performed, and that the PC reverses this effect; b) an ICH causes a striatal lesion that is not reversed by preconditioning; c) an HIC promoted high fluorescence intensity for GFAP and OX-42, and PC reverses the microglia reactivity. Taken together, we suggest that ischemic preconditioning combined with experimental intracerebral hemorrhage, promotes functional but not morphological protection, being associated with the microglial reactivity decrease after the hemorrhagic event. Acidente vascular cerebral Precondicionamento isquêmico Hemorragia cerebral Microglia Astrócitos Precondicioning Intracerebral hemorrhage Cross-tolerance Astrocyte Microglia rat
120	Efeito cerebroprotetor do pré-condicionamento isquêmico sobre aspectos celulares e funcionais no modelo de hemorragia intracerebral focal em ratos Wistar adultos Delgado, Thamiris Fenalti January 2017 (has links) O Acidente Vascular Encefálico (AVE) Hemorrágico representa mais de 10% de todos os casos de AVE e possui altas taxas de morbidade e de mortalidade. Os pacientes que sobrevivem a este evento permanecem com alguma disfunção motora, que algumas vezes é incapacitante. O extravasamento de sangue em um AVE hemorrágico ocorre, geralmente, em regiões onde há bifurcação de pequenas arteríolas penetrantes, como na região dos núcleos da base. O estriado, importante componente dessa região, está relacionado a funções motoras superiores, como o planejamento e a execução do movimento. Alguns estudos demonstram que o pré-condicionamento (PC) isquêmico pode gerar a tolerância a outros eventos que acometem o sistema nervoso. O PC é definido como fenômeno decorrente da exposição de um tecido ou órgão a um insulto sub-letal capaz de resultar em adaptações determinantes para a tolerância tecidual. Isso ocorre mesmo quando esses dois estímulos são de origens diferentes; neste caso diz-se que o PC desenvolveu tolerância cruzada. Desta forma, o presente estudo dedicou-se ao estudo de efeitos celulares e funcionais do pré-condicionamento isquêmico, por oclusão bilateral das artérias carótidas durante 10 minutos, sobre o modelo de hemorragia intracerebral (HIC), por administração intraestriatal de colagenase do tipo IV-S em ratos. A hipótese de trabalho era de que o PC causaria tolerância cruzada para a HIC, e consequente neuroproteção avaliada por testes motores, volume de lesão, com envolvimento de astrocitose e de micróglia reativa Foram usados 67 ratos machos Wistar adultos, divididos em 4 grupos: Sham (controle cirúrgico), PC, HIC, PC+HIC. Assim, os animais dos grupos PC e PC+HIC foram submetidos ao pré-condicionamento e 24 horas depois os animais HIC e PC+HIC receberam a injeção de colagenase, enquanto os animais Sham e PC receberam uma injeção de salina. A avaliação motora dos animais foi realizada a partir dos testes do cilindro e do Staircase. Trinta e quatro dias após a HIC os animais foram perfundidos e o estriado ipsilateral à injeção foi dissecada para obtenção de amostras teciduais necessárias à avaliação da perda tecidual e quantificação de intensidade de fluorescência de GFAP (proteína glial fibrilar ácida) e OX-42, importantes marcadores de astrócitos e microglia, respectivamente. Os resultados demonstram que: a) a HIC causa deficits motores em ambos os testes realizados, e que o PC reverte este efeito; b) a HIC causa lesão estriatal que não é revertido pelo pré-condicionamento; c) a HIC causa aumento da intensidade de fluorescência para GFAP e para OX-42, e o PC reverte apenas a reatividade da micróglia. Em conjunto, sugere-se que o pré-condicionamento isquêmico causa tolerância cruzada com a hemorragia intracerebral experimental, resultando em proteção funcional, mas não morfológica, possivelmente associada a uma diminuição da reatividade da microglia após o evento hemorrágico. / Hemorrhagic Vascular Stroke (EVA) represents more than 10% of all stroke cases with high rates of morbidity and mortality. Patients who survive this event, remain with some motor dysfunction, which is sometimes disabling. The extravasation of blood in a hemorrhagic stroke occurs, generally, in regions where there is bifurcation of small vessels, as in the region of striatum. The striatum is related to the higher motor functions, such as the planning and execution of the movement. Some studies have shown that preconditioning (PC) can generate a tolerance to other events that accompany the nervous system. The PC is presented as the source of the exposure of a sub-lethal, resulting in an adaptation of determinants to a tissue tolerance. Thus, the present study aimed shows the ischemic preconditioning effects, by bilateral occlusion of the carotid arteries for 10 minutes, on the intracerebral hemorrhage (ICH) model, by intra- striatum administration of type IV S collagenase in rats. The working hypothesis was tolerance to HIC, and consequent neuroprotection by motor function, lesion volume, astrocytosis and reactive microglia. A total of 84 male Wistar adult rats were divided into 4 groups: Sham (surgical control), PC, HIC, PC + HIC Thus, the animals of the PC and PC + HIC groups were introduced to the preconditioning and 24 hours later, the HIC and PC + HIC animals received a collagenase injection, while the Sham and PC animals received a saline injection. The evaluation of the animal function was performed from cylinder and Staircase tests. Thirty-four days after the surgery, the striatum was dissected and prepared to lesion volume analysis and fluorescence intensity of GFAP quantification (acid glial fibrillary protein) and OX-42, important astrocyte and microglia markers respectively. The results demonstrate that: a) an HIC causes motor deficits in both tests performed, and that the PC reverses this effect; b) an ICH causes a striatal lesion that is not reversed by preconditioning; c) an HIC promoted high fluorescence intensity for GFAP and OX-42, and PC reverses the microglia reactivity. Taken together, we suggest that ischemic preconditioning combined with experimental intracerebral hemorrhage, promotes functional but not morphological protection, being associated with the microglial reactivity decrease after the hemorrhagic event. Acidente vascular cerebral Precondicionamento isquêmico Hemorragia cerebral Microglia Astrócitos Precondicioning Intracerebral hemorrhage Cross-tolerance Astrocyte Microglia rat

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