Global ETD Search

421	Morphologie der Mikroglia in Assoziation zu Amyloidablagerungen und Tau-Pathologien im caninen Gehirn Schmidt, Franziska 20 November 2014 (has links) (PDF) Altersassoziiert entwickeln Hunde eine Erkrankung, die in vielen Aspekten der Alzheimer-Krankheit des Menschen ähnelt. Das canine kognitive Dysfunktionssyndrom äußert sich klinisch u.a. durch Desorientierung in vertrauter Umgebung, Vergessen von Kommandos und einen gestörten Schlaf-Wach-Rhythmus. Aus der Literatur ist bekannt, dass in den Gehirnen von alten Hunden regelmäßig Aβ- und selten Tauablagerungen zu beobachten sind. Allerdings erfolgte bisher kein Nachweis des hochgradig zytotoxischen und modifizierten pE3Aβ. Auch Veränderungen der mikroglialen Morphologie wurden bisher nicht beschrieben. Insgesamt lagen in dieser Studie 24 euthanasierte Rasse- und Mischlingshunde verschiedenen Alters vor. Fünf dieser Tiere besaßen ein durchschnittliches Alter von 2,1 Jahren und dienten als Kontrollgruppe. Die anderen 19 Hunde waren 8 bis 19 Jahre alt und wurden entsprechend ihrer Größe und des Gewichts in die drei Kategorien kleine (≤ 10 kg), mittelgroße (10 – 25 kg) und große Hunde (> 25 kg) unterteilt. Die Gehirne wurden aus den Schädeln präpariert und in 4 % Paraformaldehyd fixiert. Anschließend erfolgte die Präparation des frontalen und entorhinalen Kortex sowie der Hippokampusformation, die in 30%iger Saccharoselösung vitrifiziert und mittels Methylbutan bei -80 °C eingefroren wurden. Von den Regionen wurden Kryoschnitte mit einer Dicke von 40 µm angefertigt und diese anhand immunhistologischer Färbungen auf das Vorhandensein von Ablagerungen, bestehend aus den Amyloidsubtypen Aβ8-17 und pE3Aβ, sowie aus hyperphosphorylierten Tau, untersucht. Die Morphologie und das Aktivitätsstadium der Mikroglia wurden mit Antikörpern gegen Iba1 und TAL.1B5 analysiert. Zusätzlich erfolgte eine Untersuchung anhand des Filament Tracer. Stereologische Analysemethoden wurden zur Quantifizierung der Aβ-Ablagerungen und der Mikroglia angewandt. Disseminierte Plaques fanden sich bereits ab 9 Jahren. In den untersuchten Gehirnregionen von alten Hunden zeichnete sich ein progressiver Verlauf der Ablagerungen ab. Da insbesondere kleinere Hunde ein höheres Alter erreichten als mittelgroße und große Hunde konnten in dieser Kategorie vermehrt Plaques beobachtet werden. Den alten Tieren gemein war, dass in den untersuchten Gehirnregionen pE3Aβ-Plaques häufiger vorlagen als Plaques, die aus Aβ8-17 bestanden. Kleinere parenchymale und meningeale Gefäße des frontalen Kortex schienen besonders anfällig gegenüber pE3Aβ-Ablagerungen zu sein. Im entorhinalen Kortex von kleinen Hunden war die Menge an gefäßassoziierten Aβ8-17- und pE3Aβ-Ablagerungen annähernd gleich. Bei mittelgroßen und großen Hunden dominierte im entorhinalen Kortex und ventralen Hippokampus die Anzahl an gefäßassoziierten Aβ8-17-Ablagerungen. Bei kleinen Hunden existierten im ventralen Hippokampus signifikant mehr gefäßassoziierte Aβ8-17- als pE3Aβ-Ablagerungen. Hyperphosphoryliertes Tau fand sich in der Hippokampusformation von drei Hunden im Alter von 11 bzw. 15 Jahren. Der Schweregrad war unterschiedlich ausgeprägt, sodass nur ein Hund eine hochgradige Pathologie mit NFTs und neuritischen Plaques aufwies. Einhergehend mit dem Alter und einer assoziierten Proteinpathologie fanden sich Veränderungen der mikroglialen Morphologie. Neben ramifizierten Mikroglia lagen in den untersuchten Gehirnregionen aktivierte Mikroglia vor. Einige Mikroglia wiesen Zeichen einer Seneszenz auf und waren insbesondere in den Gehirnen von Hunden mit einer hochgradigen Aβ- bzw. Tau-Pathologie vorhanden. Zusammenfassend ist festzustellen, dass mit dieser Studie eine nähere Charakterisierung des caninen kognitiven Dysfunktionssyndroms erfolgte. Die Befunde sind von hoher translationaler Bedeutung und fördern die Etablierung des Hundes als natürliches Modelltier zur Untersuchung von Alterungsprozessen des Gehirns und für die Erforschung des initialen Stadiums der Alzheimer-Krankheit. / Dogs develop an age-associated cognitive dysfunction syndrome with several aspects resembling Alzheimer\\\'s disease. Affected animals show signs of dis-orientation in their familiar surroundings, dementia, and a disturbed circadian rhythm. The underlying neurodegenerative disease is associated with patho-logic changes in the brain including regularly deposition of β-pleated amyloid and rarely hyperphosphorylated tau accumulation. However, there have been no reports of the highly cytotoxic and modified pE3Aβ in the canine brain. Equally, altered microglial morphology has not been documented so far. For this study 24 euthanized thoroughbred dogs and mongrels of different ages were available. Five of these animals had an average age of 2.1 years and served as control group. The remaining 19 dogs were 8 to 19 years old. Accor-ding to their height and weight these dogs were divided into 3 different categories including small (≤ 10 kg), medium (11 - 25 kg) and large dogs (> 25 kg). Brains were dissected from the skulls and fixed in 4 % paraformaldehyde. Afterwards the frontal and entorhinal cortex as well as the hippocampal for-mation were isolated, vitrificated in 30 % sucrose solution and frozen to -80 °C by methylbutane. These regions were sliced into 40 µm thick sections and subsequently stained by immunohistology in order to detect deposits of Aβ8-17, pE3Aβ and hyperphosphorylated tau, respectively. Antibodies against Iba1 and TAL.1B5 were used to analyze microglial morphology and activation status. Additionally further investigations were made with the Filament Tracer of Imaris software. Stereological analysis methods served for the quantification of Aβ depositions and microglia. Disseminated Aβ plaques were detected in dogs from 9 years on. Within the examined brain regions of elderly dogs a progressive course of Aβ depositions was observed. Especially small dogs had a longer lifespan than medium and large dogs with the result that more plaques were deposited in the brains of small dogs. Elderly dogs had in common that pE3Aβ-plaques where more often located in the examined brain regions than plaques containing Aβ8-17. Minor parenchymal and meningeal vessels seemed to be susceptible especially to pE3Aβ depositions. The amount of vessel-associated Aβ8-17 and pE3Aβ in the entorhinal cortex of small dogs was almost equal. Within the entorhinal cortex of medium and large dogs the amount of vessel-associated Aβ8-17 predominated. The ventral hippocampus of small dogs showed significantly more vessel-associated Aβ8-17 than pE3Aβ depositions. Hyperphosphorylated tau was present in the hippocampal formations of 3 dogs with an age of 11 and 15 years, respectively. The degree of severity varied with the result that only one dog showed a high-grade pathology with development of NFTs and neuritic plaques. Accompanied by age and associated protein pathology altered microglial morphology was detected. Alongside with ramified microglia, activated cells were identified in the examined brain regions. Several microglia showed signs of senescence and were present in the brains of dogs with severe Aβ and tau pathology. Summarizing, this study facilitated a further characterization of the canine cognitive dysfunction syndrome. The results are of highly translational importance and encourage the establishment of the dog as a natural animal model for studying age-associated processes and the initial stage of Alzheimer’s disease. Hund Altern Canines kognitives Dysfunktionssyndrom Mikroglia Amyloid Tau Alzheimer-Krankheit dog aging canine cognitive dysfunction syndrome microglia amyloid tau Alzheimer\\\'s disease ddc:636.089
422	Mikroglia fördert die Invasivität von Karzinomzellen / Microglia promotes invasiveness of carcinoma cells Abenstein, Anne Kathrin 23 March 2010 (has links) No description available. 610 Medizin, Gesundheit Medicine Mikroglia Invasivität Karzinomzellen Tumor-assoziierte Makrophagen Hirnmetastasen microglia invasiveness carcinoma cells tumor-associated macrophages brain metastasis 44.03 44.81 44.86 44.45 MED 424: Onkologie
423	La rigidité artérielle, induite par une calcification des carotides, altère l’homéostasie cérébrale chez la souris Sadekova, Nataliya 04 1900 (has links) La rigidité artérielle est considérée comme un facteur de risque important pour le développement du déclin cognitif. Toutefois, les effets précis de la rigidité artérielle sur le cerveau sont peu connus et, à ce jour, aucun modèle animal ne permet d’étudier l’effet isolé de ce facteur sur l’homéostasie cérébrale. Dans cette étude, nous avons développé un nouveau modèle de rigidité artérielle qui se base sur la calcification de l’artère carotide chez la souris. Au niveau artériel, ce modèle présente une fragmentation de l’élastine, une augmentation de la distribution du collagène et de l’épaisseur intima-média ainsi qu’une diminution de la compliance et de la distensibilité artérielles démontrant la rigidité artérielle. De plus, le modèle ne présente pas d’augmentation de pression artérielle ni de changement de rayon du lumen indiquant une absence d’hypoperfusion globale et d’anévrisme. Au niveau cérébral, les résultats montrent que la rigidité artérielle induit une augmentation de la pulsatilité du flux sanguin cérébral menant ainsi à une augmentation du stress oxydatif. Ce dernier induit une inflammation cérébrale, détectée par l’activation de la microglie et des astrocytes, induisant ultimement une neurodégénérescence. Ces effets sont surtout observés au niveau de l’hippocampe, la région cruciale pour la mémoire et la cognition. Ainsi, cette étude montre que la rigidité artérielle altère l’homéostasie cérébrale et mérite d’être considérée comme une cible potentielle dans la prévention et le traitement des dysfonctions cognitives chez les personnes âgées. / Arterial stiffness is considered as an important risk factor for the development of cognitive decline in the elderly population. However, its precise effects on the brain are unknown and, to date, no animal model allows to study the precise outcome of arterial stiffness on the brain homeostasis. In this study, we developed a new animal model of arterial stiffness based on the calcification of the carotid artery in mice. On the arterial level, this model shows a fragmentation of elastin, increased collagen distribution and intima-media thickness as well as decreased arterial compliance and distensibility, thus fulfilling the major arterial stiffness properties. In addition, this model does not a show an increase in blood pressure or change in arterial lumen radius indicating a lack of global hypoperfusion and aneurysm. Regarding the brain, the results show that arterial stiffness induces an increase in cerebral blood flow pulsatility leading to increased oxidative stress. Oxidative stress induces brain inflammation, detected by the activation of microglia and astrocytes, ultimately leading to neurodegeneration. These effects are particularly observed in the hippocampus, a crucial area for memory and cognition. Thus, this study shows that arterial stiffness alters brain homeostasis and therefore should be considered as a potential therapeutical target for the prevention and treatment of cognitive dysfunction in the elderly. Rigidité artérielle Artère carotide Calcification Cerveau Microglie Astrocytes Stress oxydatif Arterial stiffness Carotid artery Calcification Brain Microglia Astrocytes Oxidative stress
424	Transcriptional regulation of CD40 and class II MHC molecules in macrophages and microglia by statins Lee, Sun Jung, January 2008 (has links) (PDF) Thesis (Ph. D.)--University of Alabama at Birmingham, 2008. / Title from first page of PDF file (viewed June 6, 2008). Includes bibliographical references.
425	Efeito benéfico do enriquecimento ambiental sobre o déficit de memória e a plasticidade celular hipocampal em ratos diabéticos tipo 1 Piazza, Francele Valente January 2012 (has links) O diabetes mellitus tipo 1 (DMT1) tem sido associado com complicações a longo prazo no sistema nervoso central, além dos efeitos periféricos comuns relacionados à doença, causando disfunções cognitivas no encéfalo. Por outro lado, o enriquecimento ambiental (EA) induz mecanismos de plasticidade dependentes da experiência, especialmente no hipocampo, melhorando o desempenho dos animais em testes de aprendizado e memória. Assim, nosso objetivo foi avaliar a influência do EA sobre o déficit de memória, a atividade locomotora, os níveis de corticosterona, a imunorreatividade da proteína sinaptofisina, e a densidade e a ativação de astrócitos e microglia no giro denteado (GD) do hipocampo de ratos diabéticos tipo 1. Para isso, ratos Wistar machos com 21 dias de idade, foram expostos ao EA ou mantidos em caixamoradia padrão (controles, C) por 3 meses. Quando adultos, os animais tanto C quanto EA foram randomicamente divididos e induziu-se diabetes através de injeção de estreptozotocina em metade dos animais de cada grupo, sendo mantidas as respectivas condições ambientais para cada um dos grupos. A memória espacial dependente de hipocampo foi avaliada em todos os grupos através do teste de reconhecimento de objeto reposicionado, no 41o dia após a indução do diabetes, bem como a locomoção geral dos animais no campo aberto durante o mesmo teste. Os níveis séricos de corticosterona foram medidos ao final do experimento, a imunorreatividade da sinaptofisina foi avaliada por imunoistoquímica, e a densidade e a ativação de astrócitos e da microglia por imunofluorescência no hilo do GD do hipocampo. Nossos resultados mostraram que o EA foi capaz de prevenir ou atrasar o desenvolvimento do déficit de memória causado pelo diabetes em ratos, porém não reverteu o déficit motor observado nos animais diabéticos. Não houve diferença significativa na imunorreatividade da sinaptofisina entre os grupos. Além disso, embora o EA não tenha modificado a densidade e a ativação dos astrócitos nos animais diabéticos, o enriquecimento atenuou os efeitos prejudiciais da hiperglicemia sobre a ativação microglial, bem como reduziu os níveis séricos de corticosterona nos ratos diabéticos adultos. Assim, o EA ajudou a amenizar as comorbidades cognitivas associadas ao diabetes, possivelmente por atenuar a hiperatividade do eixo HPA e a ativação microglial nos animais diabéticos. / Type 1 diabetes mellitus (T1DM) has been associated with long-term complications in central nervous system, besides peripheral common adverse effects, causing neurocognitive dysfunction in the brain. On the other hand, enriched environment (EE) induces mechanisms of experiencedependent plasticity especially in hippocampus, improving the performance of animals in learning and memory tasks. Thus, our objective was to investigate the influence of the EE on memory deficits, locomotion, corticosterone levels, synaptophysin protein immunoreactivity, and density and activation of astrocytes and microglia in the hippocampal dentate gyrus (DG) of type 1 diabetic rats. For this, male Wistar rats, 21 days old, were exposed to the EE or maintained in standard housing (controls, C) for 3 months. At adulthood, C and EE animals were randomly divided and half of them induced to diabetes by streptozotocin, being maintained the respective environmental conditions for each animal groups. Hippocampus-dependent spatial memory was evaluated in all groups in the novel object-placement recognition task, on 41th day after diabetes induction, as well as the general locomotion in the open field at the same test. Serum corticosterone levels were measured in the end of the experiment, contents of synaptophysin was evaluated by immunohistochemistry, and density and activation of both astrocytes and microglia by immunofluorescence in the hilus of the DG in hippocampus. Our results showed that EE was able to prevent or delay the development of memory deficits caused by diabetes in rats, however did not revert the motor impairment observed in group diabetic. There was no significant difference in synaptophysin immunoreactivity among the groups. Furthermore, although the EE did not modify the density and activation of astrocytes in diabetic animals, it attenuated the injurious effect of hyperglycemia over microglial activation, as well as decreased the serum level of corticosterone in diabetic adult rats. Thus, the EE has helped to ameliorate cognitive comorbidities associated with T1DM, possibly by reducing the hyperactivity of HPA axis and the microglial activation in diabetic animals. Enriquecimento ambiental Encefalopatias Diabetes mellitus Hipocampo Memória Corticosterona Sinaptofisina Astrócitos Imuno-histoquímica Diabetic encephalopathy Enriched environment Hippocampus Memory Corticosterone Synaptophysin Astrocytes Microglia Immunohistochemistry
426	Efeito benéfico do enriquecimento ambiental sobre o déficit de memória e a plasticidade celular hipocampal em ratos diabéticos tipo 1 Piazza, Francele Valente January 2012 (has links) O diabetes mellitus tipo 1 (DMT1) tem sido associado com complicações a longo prazo no sistema nervoso central, além dos efeitos periféricos comuns relacionados à doença, causando disfunções cognitivas no encéfalo. Por outro lado, o enriquecimento ambiental (EA) induz mecanismos de plasticidade dependentes da experiência, especialmente no hipocampo, melhorando o desempenho dos animais em testes de aprendizado e memória. Assim, nosso objetivo foi avaliar a influência do EA sobre o déficit de memória, a atividade locomotora, os níveis de corticosterona, a imunorreatividade da proteína sinaptofisina, e a densidade e a ativação de astrócitos e microglia no giro denteado (GD) do hipocampo de ratos diabéticos tipo 1. Para isso, ratos Wistar machos com 21 dias de idade, foram expostos ao EA ou mantidos em caixamoradia padrão (controles, C) por 3 meses. Quando adultos, os animais tanto C quanto EA foram randomicamente divididos e induziu-se diabetes através de injeção de estreptozotocina em metade dos animais de cada grupo, sendo mantidas as respectivas condições ambientais para cada um dos grupos. A memória espacial dependente de hipocampo foi avaliada em todos os grupos através do teste de reconhecimento de objeto reposicionado, no 41o dia após a indução do diabetes, bem como a locomoção geral dos animais no campo aberto durante o mesmo teste. Os níveis séricos de corticosterona foram medidos ao final do experimento, a imunorreatividade da sinaptofisina foi avaliada por imunoistoquímica, e a densidade e a ativação de astrócitos e da microglia por imunofluorescência no hilo do GD do hipocampo. Nossos resultados mostraram que o EA foi capaz de prevenir ou atrasar o desenvolvimento do déficit de memória causado pelo diabetes em ratos, porém não reverteu o déficit motor observado nos animais diabéticos. Não houve diferença significativa na imunorreatividade da sinaptofisina entre os grupos. Além disso, embora o EA não tenha modificado a densidade e a ativação dos astrócitos nos animais diabéticos, o enriquecimento atenuou os efeitos prejudiciais da hiperglicemia sobre a ativação microglial, bem como reduziu os níveis séricos de corticosterona nos ratos diabéticos adultos. Assim, o EA ajudou a amenizar as comorbidades cognitivas associadas ao diabetes, possivelmente por atenuar a hiperatividade do eixo HPA e a ativação microglial nos animais diabéticos. / Type 1 diabetes mellitus (T1DM) has been associated with long-term complications in central nervous system, besides peripheral common adverse effects, causing neurocognitive dysfunction in the brain. On the other hand, enriched environment (EE) induces mechanisms of experiencedependent plasticity especially in hippocampus, improving the performance of animals in learning and memory tasks. Thus, our objective was to investigate the influence of the EE on memory deficits, locomotion, corticosterone levels, synaptophysin protein immunoreactivity, and density and activation of astrocytes and microglia in the hippocampal dentate gyrus (DG) of type 1 diabetic rats. For this, male Wistar rats, 21 days old, were exposed to the EE or maintained in standard housing (controls, C) for 3 months. At adulthood, C and EE animals were randomly divided and half of them induced to diabetes by streptozotocin, being maintained the respective environmental conditions for each animal groups. Hippocampus-dependent spatial memory was evaluated in all groups in the novel object-placement recognition task, on 41th day after diabetes induction, as well as the general locomotion in the open field at the same test. Serum corticosterone levels were measured in the end of the experiment, contents of synaptophysin was evaluated by immunohistochemistry, and density and activation of both astrocytes and microglia by immunofluorescence in the hilus of the DG in hippocampus. Our results showed that EE was able to prevent or delay the development of memory deficits caused by diabetes in rats, however did not revert the motor impairment observed in group diabetic. There was no significant difference in synaptophysin immunoreactivity among the groups. Furthermore, although the EE did not modify the density and activation of astrocytes in diabetic animals, it attenuated the injurious effect of hyperglycemia over microglial activation, as well as decreased the serum level of corticosterone in diabetic adult rats. Thus, the EE has helped to ameliorate cognitive comorbidities associated with T1DM, possibly by reducing the hyperactivity of HPA axis and the microglial activation in diabetic animals. Enriquecimento ambiental Encefalopatias Diabetes mellitus Hipocampo Memória Corticosterona Sinaptofisina Astrócitos Imuno-histoquímica Diabetic encephalopathy Enriched environment Hippocampus Memory Corticosterone Synaptophysin Astrocytes Microglia Immunohistochemistry
427	Efeito benéfico do enriquecimento ambiental sobre o déficit de memória e a plasticidade celular hipocampal em ratos diabéticos tipo 1 Piazza, Francele Valente January 2012 (has links) O diabetes mellitus tipo 1 (DMT1) tem sido associado com complicações a longo prazo no sistema nervoso central, além dos efeitos periféricos comuns relacionados à doença, causando disfunções cognitivas no encéfalo. Por outro lado, o enriquecimento ambiental (EA) induz mecanismos de plasticidade dependentes da experiência, especialmente no hipocampo, melhorando o desempenho dos animais em testes de aprendizado e memória. Assim, nosso objetivo foi avaliar a influência do EA sobre o déficit de memória, a atividade locomotora, os níveis de corticosterona, a imunorreatividade da proteína sinaptofisina, e a densidade e a ativação de astrócitos e microglia no giro denteado (GD) do hipocampo de ratos diabéticos tipo 1. Para isso, ratos Wistar machos com 21 dias de idade, foram expostos ao EA ou mantidos em caixamoradia padrão (controles, C) por 3 meses. Quando adultos, os animais tanto C quanto EA foram randomicamente divididos e induziu-se diabetes através de injeção de estreptozotocina em metade dos animais de cada grupo, sendo mantidas as respectivas condições ambientais para cada um dos grupos. A memória espacial dependente de hipocampo foi avaliada em todos os grupos através do teste de reconhecimento de objeto reposicionado, no 41o dia após a indução do diabetes, bem como a locomoção geral dos animais no campo aberto durante o mesmo teste. Os níveis séricos de corticosterona foram medidos ao final do experimento, a imunorreatividade da sinaptofisina foi avaliada por imunoistoquímica, e a densidade e a ativação de astrócitos e da microglia por imunofluorescência no hilo do GD do hipocampo. Nossos resultados mostraram que o EA foi capaz de prevenir ou atrasar o desenvolvimento do déficit de memória causado pelo diabetes em ratos, porém não reverteu o déficit motor observado nos animais diabéticos. Não houve diferença significativa na imunorreatividade da sinaptofisina entre os grupos. Além disso, embora o EA não tenha modificado a densidade e a ativação dos astrócitos nos animais diabéticos, o enriquecimento atenuou os efeitos prejudiciais da hiperglicemia sobre a ativação microglial, bem como reduziu os níveis séricos de corticosterona nos ratos diabéticos adultos. Assim, o EA ajudou a amenizar as comorbidades cognitivas associadas ao diabetes, possivelmente por atenuar a hiperatividade do eixo HPA e a ativação microglial nos animais diabéticos. / Type 1 diabetes mellitus (T1DM) has been associated with long-term complications in central nervous system, besides peripheral common adverse effects, causing neurocognitive dysfunction in the brain. On the other hand, enriched environment (EE) induces mechanisms of experiencedependent plasticity especially in hippocampus, improving the performance of animals in learning and memory tasks. Thus, our objective was to investigate the influence of the EE on memory deficits, locomotion, corticosterone levels, synaptophysin protein immunoreactivity, and density and activation of astrocytes and microglia in the hippocampal dentate gyrus (DG) of type 1 diabetic rats. For this, male Wistar rats, 21 days old, were exposed to the EE or maintained in standard housing (controls, C) for 3 months. At adulthood, C and EE animals were randomly divided and half of them induced to diabetes by streptozotocin, being maintained the respective environmental conditions for each animal groups. Hippocampus-dependent spatial memory was evaluated in all groups in the novel object-placement recognition task, on 41th day after diabetes induction, as well as the general locomotion in the open field at the same test. Serum corticosterone levels were measured in the end of the experiment, contents of synaptophysin was evaluated by immunohistochemistry, and density and activation of both astrocytes and microglia by immunofluorescence in the hilus of the DG in hippocampus. Our results showed that EE was able to prevent or delay the development of memory deficits caused by diabetes in rats, however did not revert the motor impairment observed in group diabetic. There was no significant difference in synaptophysin immunoreactivity among the groups. Furthermore, although the EE did not modify the density and activation of astrocytes in diabetic animals, it attenuated the injurious effect of hyperglycemia over microglial activation, as well as decreased the serum level of corticosterone in diabetic adult rats. Thus, the EE has helped to ameliorate cognitive comorbidities associated with T1DM, possibly by reducing the hyperactivity of HPA axis and the microglial activation in diabetic animals. Enriquecimento ambiental Encefalopatias Diabetes mellitus Hipocampo Memória Corticosterona Sinaptofisina Astrócitos Imuno-histoquímica Diabetic encephalopathy Enriched environment Hippocampus Memory Corticosterone Synaptophysin Astrocytes Microglia Immunohistochemistry
428	Perfil de expressão gênica da micróglia humana e suas alterações relacionadas ao glioma / Human microglia expression profile and its alterations related to glioma Thais Fernanda de Almeida Galatro 12 September 2016 (has links) A micróglia é essencial para a homeostase do Sistema Nervoso Central (SNC), função neuro-imune inata, e exerce papel importante na neurodegeneração, envelhecimento cerebral e tumorigênese. Gliomas difusos são tumores cerebrais primários caracterizados por crescimento infiltrativo e altas taxas de heterogeneidade, o que torna a doença praticamente incurável. Avanços em análises genéticas caracterizaram alterações moleculares relacionadas ao tempo de sobrevida e à resposta clínica desses pacientes, especialmente em glioblastomas (GBM). No entanto, a tumorigenicidade dos gliomas não é controlada unicamente por suas alterações genéticas. As interações entre as células tumorais, a micróglia residente e os macrófagos/monócitos infiltrados desempenham um papel crucial na modulação do crescimento e agressividade do glioma. Neste estudo, analisamos o fenótipo de ativação da micróglia/macrófagos em gliomas, incluindo astrocitomas e oligodendroglimas de diferentes graus de malignidade, apresentamos o perfil de expressão gênica da população pura de micróglia cortical e do tecido cerebral total correspondente. Usando sequenciamento de DNA de alta performance, classificamos as amostras de GBM em Proneural, Clássico e Mesenquimal. Em seguida, avaliamos os status de ativação da micróglia/macrófagos dessas amostras. Apesar do alto grau de heterogeneidade, pudemos observar níveis mais altos dos marcadores mielóides (IBA1, CD11b and CD68) em tumores astrocíticos comparados a tumores de origem oligodendrocítica e ao tecido não-neoplásico. Marcadores de anti-inflamação, como CD163, foram mais abundantes em astrocitomas, bem como em GBMs do subtipo Mesenquimal e Clássico; enquanto que marcadores de pró-inflamação, como IL1-beta, mostraram uma expressão mais heterogênea entre as amostras. Em seguida, micróglia foi isolada de 25 amostras de córtex parietal provenientes de autópsia de indivíduos cognitivamente preservados e foi feito o RNA-seq. Os resultados foram comparados à micróglia de camundongo e a outras células mielóides. Boa parte dos genes expressos pela micróglia humana foram similares àqueles expressos pela micróglia murina, como CX3CR1, P2YR12 e ITGAM. Porém, foram identificados genes de característica imune, abundantemente expressos na micróglia humana e não identificados na micróglia de camundongos, como TLR, Fcy, receptores do tipo SIGLEC, e fatores de transcrição NLRC5 e CIITA. A comparação dos dados de expressão gênica da micróglia com monócitos e macrófagos identificou novos marcadores que distinguem a micróglia humana de outras células mielóides. Nossos dados sobre a micróglia em gliomas sugerem características de imunossupressão e de pró-crescimento em tumores de pior prognóstico, ligado a um fenótipo específico de ativação das células mielóides. Este é o primeiro estudo a identificar o transcriptoma da micróglia humana pura, demonstrando que ela é claramente diferente da micróglia murina e de outras células mielóides. Esses resultados abrem portas para estudos de populações específicas de células mielóides em gliomas / Microglia are essential for central nervous system (CNS) homeostasis and innate neuroimmune function, and play important roles in neurodegeneration, brain aging and tumorigenesis. Diffuse gliomas are primary brain tumors characterized by infiltrative growth and high heterogeneity, which renders the disease mostly incurable. Advances in genetic analysis have characterized molecular alterations leading to impact on patients\' overall survival and clinical outcome, particularly in glioblastoma (GBM). However, glioma tumorigenicity is not controlled uniquely by its genetic alterations. The crosstalk between tumor cells, resident microglia and infiltrating monocytes/macrophages plays a crucial role in modulating glioma growth and aggressiveness. Here, we assess the activation status of microglia/macrophages in gliomas,including astrocytomas and oligodendrogliomas of different grades of malignancy, and present the gene expression profile of pure cortical human microglia and corresponding unsorted brain tissue. Using high-throughput DNA sequencing, we have classified GBM samples in Proneural, classical and mesenchymal. Next, we evaluated the activation status of microglia/macrophages within these samples. Despite the great heterogeneity, we observed higher levels of myeloid markers (IBA1, CD11b and CD68) in astrocytic tumors compared to oligodendrocytic ones and to non-neoplastic (NN) tissue. Anti-inflammation markers, such as CD163, are also more abundant in astrocytomas, as well as in the mesenchymal and classical GBM subtypes, while pro-inflammation markers, such as IL1-beta, show a more widespread expression throughout samples. Next, microglia were isolated from the parietal cortex of 25 autopsy samples of cognitively preserved humans and RNA sequenced. Overall, genes expressed by human microglia are similar to mouse microglia, such as CX3CR1, P2YR12, and ITGAM. Interestingly, a number of immune genes, not identified as mouse microglia signature genes, were abundantly expressed in human microglia, such as TLR, Fcy and SIGLEC receptors and NLRC5 and CIITA transcription factors. Comparison of microglia to monocyte and macrophage expression data underscored the CNS-specific functions of microglia and new markers were identified that distinguish human microglia from other myeloid cells. Our glioma-related data suggests an immune-suppressive and growth supportive characteristic for tumors with worse clinical outcome, linked to an activation profile of myeloid cells. This data is the first comprehensive pure human microglia gene expression profile; human microglia clearly differ from mouse microglia and other myeloid cells. These results will help further studies focusing on pure myeloid cells populations in glioma Citometria de fluxo Expressão gênica Glioblastoma Glioma Micróglia Mutação Flow cytometry Gene expression Glioblastoma Glioma High-throughput nucleotide sequencing Microglia Mutation
429	Host-parasite interactions in the dissemination of Toxoplasma gondii Kanatani, Sachie January 2017 (has links) Toxoplasma gondii is an obligate intracellular parasite that infects virtually all warm-blooded organisms. Systemic dissemination of T. gondii in the organism can cause life-threatening infection that manifests as Toxoplasma encephalitis in immune-compromised patients. In addition, mounting evidence from epidemiological studies indicates a link between chronic Toxoplasma infection and mental disorders. To better understand the pathogenesis of toxoplasmosis, basic knowledge on the host-parasite interactions and the dissemination mechanisms are essential. Previous findings have established that, upon infection with T. gondii, dendritic cells (DCs) and microglia exhibit enhanced migration, which was termed the hypermigratory phenotype. As a result of this enhanced migration, DCs and microglia are used as vehicle cells for dissemination (‘Trojan horse’) which potentiates dissemination of T. gondii in mice. However, the precise mechanisms behind the hypermigratory phenotype remained unknown. In this thesis, we characterized host-parasite interactions upon infection with T. gondii and investigated the basic mechanisms behind the hypermigratory phenotype of T. gondii-infected DCs and microglia. In paper I, we observed that upon infection with T. gondii, DCs underwent rapid morphological changes such as loss of adhesiveness and podosomes, with integrin redistribution. These rapid morphological changes were linked to hypermotility and were induced by active invasion of T. gondii within minutes. T. gondii-infected DCs exhibited up-regulation of the C-C chemokine receptor CCR7 and chemotaxis towards the CCR7 chemotactic cue, CCL19. In paper II, we developed a 3-dimensional migration assay in a collagen matrix, which allowed us to characterize the hypermigratory phenotype in a more in vivo-like environment. The migration of T. gondii-infected DCs exhibited features consistent with integrin-independent amoeboid type of migration. T. gondii-induced hypermigration of DCs was further potentiated in the presence of CCL19 in a 3D migration assay. In paper III, we identified a parasite effector molecule, a Tg14-3-3 protein derived from parasite secretory organelles. Tg14-3-3 was sufficient to induce the hypermigratory phenotype. Transfection with Tg14-3-3-containing fractions or recombinant Tg14-3-3 protein induced the hypermigratory phenotype in primary DCs and in a microglial cell line. In addition, Tg14-3-3 localized in the parasitophorous vacuolar space and host 14-3-3 proteins were rapidly recruited around the parasitophorous vacuole. In paper IV, we found that mouse DCs dominantly express the L-type voltage-dependent calcium channel, Cav1.3. Cav1.3 was linked to the GABAergic signaling-induced hypermigratory phenotype. Pharmacological inhibition of Cav1.3 and knockdown of Cav1.3 abolished the hypermigratory phenotype in T. gondii infected DCs. Blockade of voltage-dependent calcium channels reduced the dissemination of T. gondii in a mouse model. In paper V, we showed that microglia, resident immune cells in the brain, also exhibited rapid morphological changes and hypermotility upon infection with T. gondii. However, an alternative GABA synthesis pathway was shown to be involved in the hypermigratory phenotype in microglia. In summary, this thesis describes novel host-parasite interactions, including host cell migratory responses and key molecular mechanisms that mediate the hypermigratory phenotype. The findings define a novel motility-related signaling axis in DCs. Thus, T. gondii employs GABAergic non-canonical pathways to hijack host cell migration and facilitate dissemination. We believe that these findings represent a significant step forward towards a better understanding of the pathogenesis of T. gondii infection. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 4: Manuscript. Paper 5: Manuscript.</p> Apicomplexa dendritic cells microglia cell migration 14-3-3 proteins GABAergic signaling voltage-dependent calcium channel host-parasite interaction Biological Sciences Biologiska vetenskaper
430	Expression, distribution et fonction du récepteur B1 des kinines dans la rétine lors du diabète et de la néovascularisation choroïdienne chez le rat Hachana, Soumaya 11 1900 (has links) No description available. Récepteur B1 des kinines Rétinopathie diabétique VEGF Microglie Néovascularisation Kinin B1 receptor diabetic retinopathy age-related macular degeneration microglia

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