Global ETD Search

71	Estudio de procesos de Migración y Plasticidad en el Sistema Nervioso Central: Papel de Semaforina 4F y kinasa de adhesión focal (FAK) García García, Beatriz 15 February 2013 (has links) La presente tesis doctoral presenta varios resultados fundamentales para la ampliación del conocimiento actual de procesos importantes en la generación de los circuitos neuronales, como son la migración y la ramificación de células neurales. En primer lugar, se ha determinado la expresión de la semaforina transmembranal 4F en cerebro de ratón en desarrollo y adulto. Así, se ha visto que se expresa en diversas áreas del cerebro, y se ha encontrado expresión de esta proteína en precursores neuronales y en neuronas maduras, principalmente en dendritas, y en células del linaje oligodendroglial. Para profundizar más en este aspecto se llevaron a cabo varios marcajes dobles de Sema4F con proteínas marcadoras de oligodendrocitos, observándose marca en el nervio óptico y otras regiones cerebrales, incluídas la materia blanca y vías de migración de oligodendrocitos. La localización de esta semaforina en el nervio óptico a edades embrionarias y su expresión en células precursoras de oligodendrocitos (OPCs), comprobada in vitro, nos llevó a sugerir que Sema4F funciona controlando la migración de OPCs. Una serie de experimentos con explantes de nervio óptico tratados con medio control o medio condicionado 4F nos permitió determinar que Sema4F actúa inhibiendo la migración de OPCs, sin afectar a su proliferación. Además, Sema4F induce la diferenciación de OPCs a oligodendrocitos maduros. Todos estos datos sugieren un posible papel de Sema4F en procesos de remielinización. Los efectos negativos de Sema4F sobre la migración de OPCs deben cursar con cambios en el citoesqueleto celular. La kinasa de adhesión focal (FAK) es un importante mediador de señales extracelulares (como factores tróficos, interacción de integrinas con proteínas de matriz extracelular, etc…) y el interior de las células. Actúa sobre el citoesqueleto de actina y de tubulina, influyendo en la generación de filopodios, lamelipodios y fibras de estrés. Tiene un papel crucial en migración, de modo que dedicimos estudiar si Sema4F ejerce sus efectos en OPCs a través FAK. Hemos visto que Sema4F es capaz de inducir la fosforilación en varios residuos tirosina de FAK en pocos minutos, y que ambas proteínas por separado ejercen efectos opuestos en la migración de oligodendrocitos. La vía de señalización de 4F, de la que se desconoce incluso el receptor, podría cursar mediante la modulación del estado de activación de FAK, aunque faltan experimentos definitivos. FAK presenta varias isoformas específicas del sistema nervioso central, originadas mediante procesos de splicing alternativo. En la presente tesis hemos determinado con gran especificidad la forma mayoritaria expresada en varias áreas cerebrales y en el desarrollo embrionario o el adulto, tanto en neuronas como en células de la glía. FAK responde a neurotrofinas y participa en procesos de ramificación neuronal, si bien su efecto final es controvertido. Otra proteína que responde a neurotrofinas, y actúa promoviendo la ramificación axonal, es la kinasa dependiente de cdc-42 activada 1 (Ack1). En esta tesis hemos determinado que ambas proteínas interaccionan en cerebro específicamente, de manera independiente de la isoforma de FAK presente. Mediante el uso de inhibidores hemos visto que la activación de FAK es necesaria para la fosforilación de Ack1 y viceversa. FAK es la responsable de la atracción ejercida por netrina-1, y hemos determinado que la ausencia de Ack1 elimina el efecto de esta molécula de señalización. Con técnicas de Espetrometría de Masas hemos identificado algunos posibles interactores de ambas proteínas. Además, hemos observado cambios en el estado de fosforilación de varios residuos de FAK y Ack1 en función del estado de desarrollo (ratones P5 Vs. Adultos) y del estado general de activación del cerebro (ratones inyectados con la droga epileptogénica PTZ Vs. Control). / This thesis presents several results related to important processes regarding neural circuit formation, i.e. migration and ramification of Central Nervous System (CNS) cells. First, we have determined the expression of transmembrane semaphorin 4F (Sema4F) in developing and adult mice brain. Expression of this protein is high in neuronal and oligodendrocyte precursor cells (OPCs), and in different areas including optic nerve (ON) and different migratory pathways. In vitro experiments confirmed Sema4F expression in OPCs. We investigated the role of this protein in functions important for OPC physiology, and found that Sema4F inhibits OPC migration from ON explants and induces their differentiation into mature progenitors. Negative effects of Sema4F in migration must involve cytoskeleton changes. Focal adhesion kinase (FAK) is an important integrator of different extracellular signals and modulates cytoskeleton dynamics to control generation of lamellipodia, fillopodia and stress fibers. In the present project we found that Sema4F is able to phosphorylate FAK, and that FAK enhances OPC migration. The exact implications of Sema4F-FAK relationship remain to be elucidated. FAK exists in different spliced isoforms, expressed preferentially in brain. In this project, we characterised the exact isoform expressed in different areas of the brain and by different cell types. Finally, FAK response to neurotrophins is well characterised. FAK also participates in ramification processes, with controversial final effects in neurons. Ack1 is a crucial transducer of neurotrophin-induced ramification. In this thesis we show that both proteins interact specifically in neurons. We have also found that the activation of FAK is necessary for Ack1 phosphorylation upon stimulation, and viceversa. FAK mediates netrin-1 attraction, and here we have determined that knocking-down Ack1 avoids netrin-1 effects in hippocampal explants. By Mass Spectrometry (MS) techniques, we have observed changes in the phosphorylation state of both proteins depending on the developmental stage of the brain (P5 mice) or its activation state (epileptic mice). Processos de ramificació FAK Procesos de ramificación Branching processes Sema4F Oligodendròcits Oligodendrocitos Oligodendrocytes Migració neuronal Migración neuronal Neuronal migration Ciències Experimentals i Matemàtiques 576
72	Exosomes act as molecular vehicles contributing to cellular cholesterol efflux / Exosomen tragen als molekulare Vehikel zum zellulären Cholesterinefflux bei Katrin, Strauss 07 February 2011 (has links) No description available. 500 Naturwissenschaften Medicine Niemann-Pick Typ C Exosomen Cholesterin Flotillin Oligodendrozyten Niemann-Pick type C exosomes cholesterol flotillin oligodendrocytes Molekularbiologie Zellbiologie Biologie Zellbiologie
73	Neue Behandlungsansätze für neuropsychiatrische Erkrankungen basierend auf der Identifizierung molekularer Krankheitsdeterminanten / Novel treatment approaches based on identification of molecular determinants in neuropsychiatric diseases Sargin, Derya 22 October 2008 (has links) No description available. 570 Biowissenschaften Biologie Erythropoietin Kälteläsion Kognition Schizophrenie Oligodendrozyten Mikroglia Erythropoietin cryolesion cognition schizophrenia oligodendrocytes microglia 42.15 WH 000: Cytologie {Biologie}
74	Quantitative Untersuchung der Oligodendrozytendichte im Kortex von Callithrix-jacchus Marmosetten mit Experimenteller Autoimmuner Enzephalomyelitis / Quantitative analysis of oligodendroglial densitiy in the cortex of callithrix-jacchus marmosets with experimental autoimmune encephalomyelitis Vondran, Andrea Christina 26 November 2013 (has links) No description available. 610 Multiple sclerosis oligodendrocytes cortical lesions Medizin (PPN619874732)
75	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
76	The molecular regulation of neural stem cell lineage progression in the postnatal subventricular zone by Galectin-3 Al Dalahmah, Osama Ahmad Odeh January 2015 (has links) Neurogenesis continues postnatally in two major neural stem cell (NSC) niches: The subventricular zone (SVZ) and dentate gurus of the hippocampus. SVZ NSCs self-renew and produce transit amplifying progenitor cells that, in turn, divide and give rise to neuroblasts. These neuroblasts migrate to the olfactory bulbs, via the rostral migratory stream (RMS), where they terminally differentiate into mature neurons. The postnatal SVZ (pSVZ) is more gliogenic than its adult counterpart (aSVZ), contributing to robust postnatal astrocytogenesis and oligodendrogenesis in the surrounding brain parenchyma. Studies examining Galectin-3 (Gal-3) in the aSVZ showed it has functions in regulating neuroblast migration, microglial activation, oligodendrocytic differentiation, and angiogenesis. However, the role of Gal-3 in pSVZ lineage progression is unknown. This thesis aims to unravel the roles of Gal-3 in regulating pSVZ lineage progression, fate choices, and NSC activation. In doing so, the thesis tackles the molecular pathways possibly involved in mediating the effects of Gal-3. I found through co-immunoprecipitation that Gal-3 was bound to β-catenin and both proteins were co-expressed in the aSVZ. In addition, expression of Gal-3 and Wnt/β-catenin signalling were downregulated as SVZ cells progressed through the lineage and became migratory. I hypothesised that Gal-3 may regulate lineage progression through regulation of Wnt/β-catenin signalling. To explore this hypothesis, Gal-3 overexpression, knockdown or control plasmids were co-electroporated with a Wnt/β-catenin reporter into the SVZ of postnatal day two mice. I found lineage progression was not altered by Gal-3 overexpression. Surprisingly, contrary to evidence described in the cancer literature, Gal-3 overexpression reduced Wnt/β-catenin signalling. This was accompanied by an acute reduction in proliferation. Also, more cells expressed p27/Kip1 in the SVZ, and more cells migrated into the RMS, suggesting increased cell cycle exit. However, NSC proliferation and clonal neurosphere forming capacity were not altered by Gal-3 overexpression, indicating that NSC activation was not influenced by Gal-3. While olfactory neuronogenesis was not altered by Gal-3 overexpression, striatal astrocytogenesis was increased while oligodendrogenesis was dampened. Further experiments revealed phosphorylation of Smad proteins 1/5/8 was increased in vivo and in vitro after Gal-3 overexpression. These findings indicate that Gal-3 positively regulated BMP signalling in the SVZ, possibly contributing to Gal-3's pro-gliogenic effects. Taken together, this thesis supports a model whereby a subpopulation of Gal-3-responsive pSVZ cells reacted to Gal-3 overexpression by acutely exiting the cell cycle, and possibly through the same mechanisms, switched from oligodendrocytic to astrocytic fate. These cellular responses might have been brought about, at least partially, by acute suppression of Wnt/β-catenin and activation of BMP signalling. These novel findings emphasise the regulatory actions of Gal-3 on pSVZ lineage progression through Wnt/β- catenin and BMP signalling. 612.8
77	Th17 cells – oligodendrocytes interactions in multiple sclerosis : damage, death and adhesion mechanisms Jamann, Hélène 08 1900 (has links) La sclérose en plaques (SP) est une maladie neuro-inflammatoire caractérisée par l’invasion de cellules immunitaires périphériques dans le système nerveux central (SNC), entraînant une perte de myéline à des endroits bien délimités appelés « plaques » ou lésions. Les processus neuroinflammatoires sont associés au dommage des neurones et oligodendrocytes (OLs) en SP. Les mécanismes sous-tendant cette dégradation des OLs par les cellules immunitaires en SP sont toutefois encore mal compris. Les lymphocytes T CD4 activés, notamment les sous-types proinflammatoires Th1 et Th17, jouent un rôle clé dans la pathobiologie de la SP et de son modèle murin l’encéphalite auto-immune expérimentale (EAE). Nous avons donc choisi d’investiguer leur contribution à l’endommagement des OLs en neuroinflammation. Pour ce faire, nous avons premièrement caractérisé les interactions entre les lymphocytes Th17 et les OLs matures in vivo à l’aide de l’imagerie intravitale chez la souris EAE (microscopie deux photons) et in vitro en utilisant des cultures primaires humaines. Ceci nous a permis de mettre en évidence que les lymphocytes pro-inflammatoires Th17 adhèrent de façon prolongée aux OLs et leur causent plus de dommage que les lymphocytes anti-inflammatoires Th2. Après avoir établi que le contact avec les lymphocytes Th17 entraîne tout d’abord la perte des prolongements cellulaires puis la mort des OLs, nous avons identifié deux mécanismes à l’origine de ces dommages. En effet, tandis que la sécrétion de glutamate par les lymphocytes Th17 à proximité des OLs entraîne une perte des prolongements cellulaires de ces derniers et une diminution de leur capacité à myéliniser, la sécrétion de granzyme B mène à la mort des OLs. Dans le but de comprendre comment prévenir les dommages causés par les lymphocytes Th17 aux OLs en SP, nous avons par la suite étudié les mécanismes sous-tendant le contact entre les deux types cellulaires. Comme nous avons confirmé que les OLs matures n’expriment pas le MHC II au niveau protéique, nous avons caractérisé l’expression par les OLs de molécules d’adhérence cellulaire (CAMs) qui seraient susceptibles de sous-tendre l’adhérence des lymphocytes Th17. Nous avons découvert que cette interaction est notamment médiée par ALCAM, et que bloquer cette molécule permet de diminuer le dommage aux OLs médié par les Th17 in vitro. A l’inverse, l’expression et/ou la sécrétion d’ICAM-1 par les OLs semble avoir un effet protecteur face aux lymphocytes Th17. En résumé, nous avons distingué de nouveaux mécanismes impliqués dans le dommage aux OLs en neuroinflammation et identifié de nouvelles cibles thérapeutiques prometteuses pour la protection des OLs en SP. / Multiple Sclerosis (MS) is a neuroinflammatory disease characterized by infiltration of immune cells into the central nervous system (CNS), demyelination in multifocal areas called “plaques” or lesions, and damage to neurons and oligodendrocytes (OLs). The mechanisms underlying immune-mediated injury to OLs in MS remains only partially understood. Activated CD4 T cells, in particular pro-inflammatory subsets Th1 and Th17, play an important role in the pathobiology of MS and its animal model experimental autoimmune encephalitis (EAE). We set out to investigate their contribution to immune-mediated oligodendrocytic damage in neuroinflammation. We first characterized the interactions between Th17 cells and mature OLs in vivo using live imaging of EAE mice (two photon microscopy) and in vitro using human primary cell cultures. We found that pro-inflammatory Th17 cells form prolonged contacts with OLs and cause greater harm compared to anti-inflammatory Th2 cells. After demonstrating that contact with Th17 cells leads first to destruction of cell processes and then death of OLs, we identified two mechanisms underlying these deleterious impacts. Indeed, while secretion of glutamate by Th17 cells in contact with OLs is associated with damage to OLs cell processes and impairment of their myelinating capacity, secretion of granzyme B leads to OLs death. To better understand how to prevent Th17-mediated OLs injury in MS, we next studied mechanisms involved in the interaction between these two cell types. As we confirmed that mature OLs do not express MHC II at the protein level, we characterized expression of cell adhesion molecules (CAMs) by OLs that could mediate Th17 cell adhesion. We discovered that ALCAM contributes to OLs and Th17 cells interactions, and that blocking this olecule reduces Th17-mediated OL damage in vitro. Inversely, ICAM-1 expression and/or secretion by OLs seems to have a protective effect in neuroinflammatory conditions. In summary, we have uncovered new mechanisms implicated in OLs njury in neuroinflammation and have identified potential novel therapeutic targets for neuroprotection in MS. sclérose en plaques (SP) oligodendrocytes (OLs) lymphocytes Th17 melanoma cell adhesion molecule (MCAM) multiple sclerosis (MS) oligodendrocytes (OLs) Th17 lymphocytes cell adhesion molecule (CAMs)
78	Neurodegeneration in toxin-mediated demyelinating animal models of Multiple Sclerosis / Neurodegeneration in Toxin-vermittelte demyelinisierende Tiermodellen der Multiplen Sklerose Manrique Hoyos, Natalia 16 October 2012 (has links) Myelin wird durch einem speziellen Membran von Oligodendrozyten im ZNS hergestellt. Diese mehrschichtige Struktur umhüllt Axonen mit ihner trophischen Unterstützung und erleichtert die schnelle Übertragung von elektrischen Signalen. Um die kurzfristigen Auswirkungen der Demyelinisierung zu untersuchen, die histologische Analyse in einem Maus-Modell wurde durchgeführt, wo die myelinisierende Oligodendrozyten wurden abgetragen durch die Expression von Diphtherie-Toxin-Rezeptor in reifen Oligodendrozyten und systemische Diphtherie-Toxin Injektionen. Wir beobachteten, dass so eine Abtragung in einer tödlichen Krankheit resultiert, wo Demyelinisierung der weißen Substanz Bahnen durch Mikroglia Aktivierung von der axonalen Schäden begleitet wurde. Wir haben gezeigt, dass dieses Modell daher auch für das Studium von der kurzfristigen Demyelinisierung-vermittelte axonale Schädigung und Myelin Abbau geeignet ist. Um die Auswirkungen der reversibel Demyelinisierungepisoden auf langfristige Bewegungsapparates Leistung und neuro-axonalen Integrität zu untersuchen, wurden Cuprizon-behandelten Tieren mit motorischen Sequenz (MOSS) überwachtet. Mit MOSS haben wir beobachtet, ob eine funktionelle Erholung erreicht und in langfristig erhalten konnte. Trotz die komplette scheinbare Erholung, die behandelte Tieren zeigten eine late-onset motorischen Beeinträchtigung und laufenden akuten axonalen Schädigung. Dieses Modell imitiert viele Aspekte der axonalen Pathologie bei chronisch progredienter MS und könnte daher bei der Untersuchung der Faktoren, die Initiierung, Aufrechterhaltung oder Kompensation axonalen Schädigunggenutzt werden. Schließlich, weil Myelin Neuroprotektionwahrscheinlich eine direkte Kommunikation zwischen Axonen und Oligodendrozyten beinhaltet/braucht , Proteomanalyse der Myelin-Fraktionen in axo glialen Regionen ist durchgeführt, um neue Kandidaten in axo-glialen Interaktion im Rahmen des Myelin Biogenese beteiligt sind zu finden. Zahlreiche funktionalle Assays wurden gegründet und verwenden, um identifizierten Kandidaten zu bewerten, um ihre Rolle in axoglial Kommunikation und Myelinbildung zu bestimmen. Wir haben festgestellt, dass einige Mitglieder der IgLON Familie binden beide Oligodendrozyten und Axone. Wir beobachteten, dass diese Proteine kein Effekt auf die Migration, Proliferation, Differenzierung von der Oligodendrozyte-Vorläuferzellen haben. Allerdings beobachteten wir, dass ein Mitglied, Ntm wirkt sich negativ auf die frühen Phasen der Myelinisierung. 570 Biowissenschaften Biologie YNS000 Myelin Oligodendrozyten Axonen Demyelinisierung Diphtherietoxin Cuprizon Multiple Sklerose Myelin oligodendrocytes axons demyelination diphtheria toxin cuprizone multiple sclerosis 30 Naturwissenschaften allgemein
79	Selective transfer of exosomes from oligodendrocytes to microglia by macropinocytosis / Selektiver Transfer von Exosomen von Oligodendrozyten zu Mikroglia durch Makropinozytose Schnaars, Mareike 24 January 2011 (has links) No description available. 570 Biowissenschaften, Biologie Medicine Makropinozytose Mikroglia Myelin Oligodendrozyten Exosomen Macropinocytosis Microglia Myelin Oligodendrocytes Exosomes 44.90 42.15 MED 341: Immunologie {Medizin} MED 280: Biologie WH 000: Cytologie {Biologie}
80	Multiple Sklerose und Dopamin-Rezeptoren / Multiple sclerosis and dopamine receptors Schumacher, Jakob 13 April 2011 (has links) No description available. 610 Medizin, Gesundheit Medicine 44.90

Search results