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Glial Control of Synapse Assembly at the <em>Drosophila</em> Neuromuscular Junction: A DissertationKerr, Kimberly S. 06 September 2012 (has links)
Emerging evidence in both vertebrates and invertebrates is redefining glia as active and mobile players in synapse formation, maturation and function. However, the molecular mechanisms through which neurons and glia interact with each other to regulate these processes is not well known. My thesis work begins to understand how glia use secreted factors to modulate synaptic function. We use Drosophila melanogaster, a simple and genetically tractable model system, to understand the molecular mechanisms by which glia communicate with neurons at glutamatergic neuromuscular junctions (NMJs). We previously showed that a specific subtype of glia, subperineurial peripheral glia cells (SPGs), establish dynamic transient interactions with synaptic boutons of the NMJ and is required for synaptic growth. I identified a number of potential functional targets of the glial transcription factor, reverse polarity (repo) using ChIP-chip. I found that one novel target of Repo, Wg, is expressed in SPGs and is regulated by repo in vivo. Wnt/Wg signaling plays a pivotal role during synapse development and plasticity, including the coordinated development of the molecular architecture of the synapse. While previous studies demonstrated that Wg is secreted by motor neurons, herein I provide evidence that a significant amount of Wg at the NMJ is additionally provided by glia. I found that Wg derived from SPGs is required for proper GluR distribution and electrophysiological responses at the NMJ. In summary, my results show that Wg expression is regulated by Repo in SPGs and that glial-derived Wg, together with motor neuron-derived Wg, orchestrate different aspects of synapse development. My thesis work identifies synapse stabilization and/or assembly as a new role for SPGs and demonstrates that glial secreted factors such as Wg regulate synaptic function at the Drosophila NMJ.
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Role of Astrocytes in Sculpting Neuronal Circuits in the Drosophila CNS: A DissertationTasdemir-Yilmaz, Ozge E. 01 April 2014 (has links)
The nervous system is composed of neurons and glia. Glial cells have been neglected and thought to have only a supportive role in the nervous system, even though ~60% of the mammalian brain is composed of glia. Yet, in recent years, it has been shown that glial cells have several important functions during the development, maintenance and function of the nervous system. Glial cells regulate both pre and post mitotic neuronal survival during normal development and maintenance of the nervous system as well as after injury, are necessary for axon guidance, proper axon fasciculation, and myelination during development, promote synapse formation, regulate ion balance in the extracellular space, are required for normal synaptic function, and have immune functions in the brain. Although glia have crucial roles in nervous system development and function, there are still much unknown about the underlying molecular mechanisms in glial development, function and glial-neuronal communication.
Drosophila offers great opportunity to study glial biology, with its simple yet sophisticated and stereotypic nervous system. Glial cells in flies show great complexity similar to the mammalian nervous system, and many cellular and molecular functions are conserved between flies and mammals. In this study, I use Drosophila as a model organism to study the function of one subtype of glia: astrocytes. The role of astrocytes in synapse formation, function and maintenance has been a focus of study. However, their role in engulfment and clearance of neuronal debris during development remains unexplored.
I generated a driver line that enables the study of astrocytes in Drosophila.In chapter two of this thesis, I characterize astrocytes during metamorphosis, when extensive neuronal remodeling takes place. I found that astrocytes turn into phagocytes in a cell-autonomous, steroid-dependent manner, by upregulating the phagocytic receptor Draper and forming acidic phagolysosomal structures. I show that astrocytes clear neuronal debris during nervous system remodeling and that this is a novel function for astrocytes during the development of nervous system. I analyzed two different neuronal populations: MB γ neurons that prune their neurites and vCrz+ neurons that undergo apoptosis. I discovered that MB γ axons are engulfed by astrocytes using the Draper and Crk/Mbc/dCed-12 pathways in a partially redundant way. Interestingly, Draper is required for clearance of vCrz+ cell bodies, while Crk/Mbc/dCed-12, but not Draper, are required for clearance of vCrz+ neurites. Surprisingly, I also found that loss of Draper delayed vCrz+ neurite degeneration, suggesting that glia facilitate neurite destruction through engulfment signaling.
Taken together, my work identifies a novel function for astrocytes in the clearance of synaptic and neuronal debris during developmental remodeling of the nervous system. Additionally, I show that Crk/Mbc/dCed-12 act as a new glial signaling pathway required for pruning, and surprisingly, that glia use different engulfment pathways to clear neuronal debris generated by cell death versus local pruning.
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Characteristics of Primary Cilia and Centrosomes in Neuronal and Glial Lineages of the Adult BrainBhattarai, Samip Ram 05 1900 (has links)
Primary cilia are sensory organelles that are important for initiating cell division in the brain, especially through sonic hedgehog (Shh) signaling. Several lines of evidence suggest that the mitogenic effect of Shh requires primary cilia. Proliferation initiated by Shh signaling plays key roles in brain development, in neurogenesis in the adult hippocampus, and in the generation of glial cells in response to cortical injury. In spite of the likely involvement of cilia in these events, little is known about their characteristics. Centrosomes, which are associated with primary cilia, also have multiple influences on the cell cycle, and they are important in assembling microtubules for the maintenance of the cell’s cytoskeleton and cilia. The cilia of terminally differentiated neurons have been previously examined with respect to length, incidence, and receptors present. However, almost nothing is known about primary cilia in stem cells, progenitors, or differentiated glial cells. Moreover, it is not known how the properties of cilia and centrosomes may vary with cell cycle or proliferative potential, in brain or other tissues. This dissertation focuses first on neurogenesis in the hippocampal subgranular zone (SGZ). The SGZ is one of the few brain regions in mammals that gives rise to a substantial number of new neurons throughout adulthood. The neuron lineage contains a progression of identifiable precursor cell types with different proliferation rates. This present study found that primary cilia were present in every cell type in the neuronal lineage in SGZ. Cilium length and incidence were positively correlated among these cell types. Ciliary levels of adenylyl cyclase type III (ACIII) levels relative to ADP-ribosylation factor-like protein 13b (Arl13b) was higher in neurons than in precursor cells and glia, and also changed with the cell cycle. G-protein coupled receptors, SstR3, MCHR1, and Gpr161 receptors were only found in neuronal cilia. The levels and distribution of three centrosomal proteins, γ-tubulin, pericentrin and cenexin in neurons was different from the distributions in precursors and glia. The second focus of study is glial responses to injury in the neocortex, which has been widely studied as an injury model. This study found that in the normal adult somatosensory cortex, primary cilia were present in astrocytes and polydendrocytes but not in microglia. Following injury, the incidence of primary cilia decreased in astrocytes. Also, a new cell type expressing GFAP, NG2 and Olig2 was seen 3 days following injury, but was not present in normal mice. The characteristics of primary cilia and centrosome described here suggest that in stem cells and progenitors their characteristics may be well suited for proliferation, whereas in neurons, the cilia and centrosomes are important for other sensory functions.
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Examining potential cellular alterations within the anterior cingulate cortex in major depression and suicideHercher, Christa. January 2008 (has links)
No description available.
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Estudo da distribuição da proteína S100<font face=\"symbol\">b em encéfalo de ratos. / Distribution of the S100<font face=\"symbol\">b protein specific in brain of the rats.Campos, Leila Maria Guissoni 18 December 2007 (has links)
A proteína S100<font face=\"symbol\">b no cérebro é produzida e secretada pela célula da glia astrócito, e exerce de acordo com sua quantidade extracelular, ação trófica ou tóxica sobre os neurônios. Investigamos a distribuição da proteína S100<font face=\"symbol\">b, no animal em condição basal, realizando o mapeamento em diferentes áreas do encéfalo, com a técnica imuno-histoquímica, explorando a hipótese do aparecimento de S100<font face=\"symbol\">b em áreas encefálicas preferenciais. A distribuição da proteína foi analisada pela técnica do imuno-histoquímica, com utilização de anticorpo anti-S100 (<font face=\"symbol\">b subunidade). O mapeamento da proteína S100<font face=\"symbol\">b ao longo do eixo AP, permitiu observar marcação de elementos gliais distribuídos pelo telencéfalo, diencéfalo, e tronco encefálico, onde a proteína apresentou-se preferencialmente distribuída, na comparação dos animais. Nossos resultados sugerem que a proteína pode estar relacionada ao fato dessa distribuição ser conservada como padrão dentro da espécie. / S100<font face=\"symbol\">b protein is expressed primarily by astroglia in the brain, and practice functional implication of S100<font face=\"symbol\">b secretion by astrocytes into the extracellular space is scant but there is substantial evidence that secreted glial S100<font face=\"symbol\">b exerts trophic or toxic effects depending on its concentration. We provide here a detailed description of the distribution of the calcium-binding protein S100<font face=\"symbol\">b in and glial elements in the encefalo of rats. The distribution of S100-like immunoreactivity was analyzed by antisera: monoclonal, the b subunit (S100b) of this protein. All sera showed glial positive elements, which were more abundant in the brainstem than in the prosencephalon. S100-immunoreactive was detected in glial elements, in different regions of the telencephalon, diencephalon and mesencephalon. This distribution appears very similar to that, as well as to sparse observations on different vertebrates. Therefore, our results suggest that the distribution pattern of this protein in glial elements is highly conserved between the species.
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Estudo da distribuição da proteína S100<font face=\"symbol\">b em encéfalo de ratos. / Distribution of the S100<font face=\"symbol\">b protein specific in brain of the rats.Leila Maria Guissoni Campos 18 December 2007 (has links)
A proteína S100<font face=\"symbol\">b no cérebro é produzida e secretada pela célula da glia astrócito, e exerce de acordo com sua quantidade extracelular, ação trófica ou tóxica sobre os neurônios. Investigamos a distribuição da proteína S100<font face=\"symbol\">b, no animal em condição basal, realizando o mapeamento em diferentes áreas do encéfalo, com a técnica imuno-histoquímica, explorando a hipótese do aparecimento de S100<font face=\"symbol\">b em áreas encefálicas preferenciais. A distribuição da proteína foi analisada pela técnica do imuno-histoquímica, com utilização de anticorpo anti-S100 (<font face=\"symbol\">b subunidade). O mapeamento da proteína S100<font face=\"symbol\">b ao longo do eixo AP, permitiu observar marcação de elementos gliais distribuídos pelo telencéfalo, diencéfalo, e tronco encefálico, onde a proteína apresentou-se preferencialmente distribuída, na comparação dos animais. Nossos resultados sugerem que a proteína pode estar relacionada ao fato dessa distribuição ser conservada como padrão dentro da espécie. / S100<font face=\"symbol\">b protein is expressed primarily by astroglia in the brain, and practice functional implication of S100<font face=\"symbol\">b secretion by astrocytes into the extracellular space is scant but there is substantial evidence that secreted glial S100<font face=\"symbol\">b exerts trophic or toxic effects depending on its concentration. We provide here a detailed description of the distribution of the calcium-binding protein S100<font face=\"symbol\">b in and glial elements in the encefalo of rats. The distribution of S100-like immunoreactivity was analyzed by antisera: monoclonal, the b subunit (S100b) of this protein. All sera showed glial positive elements, which were more abundant in the brainstem than in the prosencephalon. S100-immunoreactive was detected in glial elements, in different regions of the telencephalon, diencephalon and mesencephalon. This distribution appears very similar to that, as well as to sparse observations on different vertebrates. Therefore, our results suggest that the distribution pattern of this protein in glial elements is highly conserved between the species.
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Caracterização de parâmetros astrocíticos encefálicos em ratos jovens expostos prenatalmente ao ácido valpróicoSilvestrin, Roberta Bristot January 2013 (has links)
Os Transtornos do Espectro do Autismo, aqui tratados coletivamente sob o termo “autismo”, são distúrbios do desenvolvimento caracterizados por prejuízo no uso da linguagem e na comunicação, redução na interação social e comportamentos e interesses restritos e repetitivos. Evidências sugerem que o autismo é um transtorno multifatorial uma vez que se sabe da existência de um componente genético mas também da contribuição de fatores ambientais como infecções e uso de anticonvulsivantes ao logo da gestação. Apesar do grande número de estudos, a causa do transtorno é desconhecida, não existe tratamento e nenhum marcador diagnóstico foi identificado até o momento. O modelo animal baseado na administração pré-natal de ácido valpróico em ratos foi utilizado como ferramenta de estudo no presente trabalho e, através deste, foram realizadas análises de parâmetros astrocíticos no córtex frontal, hipocampo, estriado e cerebelo de ratos com 4 e 15 dias de idade, além de análises no hipocampo de animais de 120 dias. Os animais de 4 dias de idade apresentam níveis aumentados da proteína glial fibrilar ácida (GFAP) no cerebelo Já os animais de 15 dias apresentam maiores níveis de GFAP em todas as estruturas estudadas. Além disso, há aumento nos níveis de vimentina no hipocampo e no conteúdo de S100B no córtex frontal e estriado. A atividade da glutamina sintetase encontra-se aumentada no hipocampo e reduzida no cerebelo e estriado. Além disso, nossos dados mostraram efeito do VPA sobre a transmissão glutamatérgica uma vez que houve aumento na captação desse transmissor, somada à maior expressão de GLT1 e conteúdo de GSH, além de diminuição na atividade da GS em 120 dias. Nossos resultados indicam que o VPA induz um processo de astrogliose reativa no encéfalo e que o cerebelo parece ser uma estrutura particularmente vulnerável. Sugere-se que os padrões regionais específicos das alterações encefálicas sejam causados pela heterogeneidade dos astrócitos e que a astrogliose pode ter papel no estabelecimento das características fisiopatológicas do autismo. Estudos adicionais são necessários para compreender a origem dessas alterações bem como suas consequências e suas implicações no diagnóstico e tratamento do autismo. / Autism Spectrum Disorders, which will be called “autism” in the present work, consist of a group of developmental disorders characterized by deficits in language and communication, low social interaction and restricted and repetitive behaviors and interests. It is known as a multifactorial disorder including both genetic and environmental components such as maternal infections and anticonvulsant used during pregnancy. Despite of the increasing number of publications in this area, the cause of autism is still unknown and there is neither treatment nor clinical marker. The animal model of autism based on the prenatal exposure to valproic acid in rats was used here to study different astrocytic parameters in the frontal cortex, hippocampus, striatum and cerebellum of male rats with 4 (P4) and 15 (P15) days of age. Additional analyses were done in the hippocampus of 120 days old rats (P120). The expression of GFAP increased in the cerebellum of P4 and in all brain structures from P15 rats. The number of vimentin+ astrocytes increased in hippocampus from P15 group and S100B levels increased in striatum and prefrontal cortex. The activity of GS in P15 increased in hippocampus and decreased in cerebellum and striatum. The effect of VPA on glutamatergic transmission was investigated in P120 were there was an increase in glutamate uptake, GLT1 expression and GSH content and reduced GS activity. Our results indicate that VPA induces early reactive astrogliosis and that cerebellum seems to be especially vulnerable. Regional patterns of brain alterations are probably due to astrocytic heterogeneity and astrogliosis seems to be relevant in establishing autistic neuropathological features. Additional studies are needed to better understand what triggers these alterations and what are their consequences and implications in autism diagnosis and treatment.
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Exposição à concentração subletal de metilmercúrio: genotoxicidade e alterações na proliferação celularMALAQUIAS, Allan Costa 01 April 2015 (has links)
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Previous issue date: 2015 / FAPESPA - Fundação Amazônia de Amparo a Estudos e Pesquisas / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / O mercúrio é um metal que se destaca dos demais por se apresentar líquido em temperatura e pressão normais. Este xenobiótico se apresenta como a maior fonte de poluição em várias partes do mundo e tem como característica ser altamente tóxico ao Sistema Nervoso Central (SNC). O despejo é na forma líquida diretamente no solo e leito dos rios. Este metal pesado é complexado com vários elementos presentes no solo ou sedimentos sendo convertido à metilmercúrio (MeHg) pela microbiota aquática. O MeHg apresenta a capacidade de se acumular ao longo da cadeia trófica, um evento conhecido como biomagnificação, o qual afeta diretamente a vida humana. Nesse sentido, a Região Amazônica se destaca por possuir todos os componentes necessários para a manutenção do ciclo biogeoquímico do mercúrio, além de populações cronicamente expostas a este metal pesado, sendo este fato considerado um problema de saúde pública. Tem-se conhecimento que este xenobiótico após a exposição aguda a altas doses promove desordens relacionadas ao surgimento de processos degenerativos no SNC, entretanto, os efeitos a baixas concentrações ainda não são totalmente conhecidos. Nesse sentido, se destacam as células gliais que atuam como mediadores no processo de neurotoxicidade desse metal, principalmente em baixas concentrações. Apesar de este tipo celular exibir um importante papel no processo de intoxicação mercurial, a ação deste metal sobre as células glias é pouco conhecida, principalmente sobre o genoma e a proliferação celular. Desta forma, este trabalho se propõe a avaliar o efeito da exposição a este xenobiótico em baixa concentração sobre o material genético e a proliferação celular em células da linhagem glial C6. As avaliações bioquímica (atividade mitocondrial – medida pelo ensaio de MTT –) e morfofuncional (integridade da membrana – avaliada pelo ensaio com os corantes BE e AA –) confirmaram a ausência de morte celular após a exposição ao metal pesado na concentração de 3 μM por um intervalo de 24 horas. Mesmo sem promover processos de morte celular, o tratamento com esta concentração subletal de MeHg foi capaz de aumentar significativamente os níveis dos marcadores de genotoxicidade (fragmentação do DNA, formação de micronúcleos, pontes nucleoplásmica e brotos nucleares). Ao mesmo tempo, foi possível observar uma alteração no ciclo celular através do aumento do índice mitótico e uma mudança no perfil do ciclo celular com aumento da população celular nas fases S e G2/M, sugerindo um aprisionamento nessa etapa. Esta mudança no ciclo celular, provocada por 24h de exposição ao MeHg, foi seguida de uma redução no número de células viáveis e confluência celular 24h após a retirada do MeHg e substituição do meio de cultura, além do aumento no tempo de duplicação da cultura do mesmo. Este estudo demonstrou pela primeira vez que a exposição ao metilmercúrio em concentração baixa e subletal é capaz de promover eventos genotóxicos e distúrbios na proliferação celular em células de origem glial. / Mercury is a metal that stands out from the rest for present liquid under normal temperature and pressure. This xenobiotic is the largest source of pollution in many parts of the world and has been characterized toxic to the central nervous system (CNS). After dumping in liquid form directly into soil and riverbed, this heavy metal complex with various organic elements or it is converted to methylmercury (MeHg) by aquatic microbiota. The MeHg can move up the food chain, an event known as biomagnification, which directly affects human life. Thereby, the Amazon stands out for having all the components necessary for the maintenance of biogeochemical cycle of mercury as well as populations chronically exposed with this heavy metal. And this metal is considered a public health problem. It is well known that this xenobiotic after acute exposure to high doses promotes disorders related to the emergence of degenerative processes in the CNS, however, the effects at low concentrations are not yet fully described. Despite this cell type play an important role in the mercury intoxication process, the role of this metal on glial cells is not well known, especially on the genome and cell proliferation. Thus, this study aimed to evaluate the effect of exposure to this xenobiotic at low concentration on DNA and cell proliferation in C6 glial lineage cells. The biochemical (mitochondrial activity - measured by MTT assay -) and morphofunctional evaluations (membrane integrity - measured by the assay with dyes and AA BE -) confirmed the absence of cell death after exposure to heavy metals in a concentration of 3 μM for 24 hours. Even without causing cell death processes, the treatment with sublethal concentration of MeHg that was able to significantly increase the levels of markers of genotoxicity (DNA fragmentation, micronuclei, nuclear nucleoplasmic bridges and nuclear bud). At the same time, it was possible to observe a change in the cell cycle by increasing the mitotic index and a change in the cell cycle profile with increased cell population in S and G2 / M phases, suggesting an arrest cell cycle arrest. This change in cell cycle caused by MeHg exposure was followed by number of viable cells and cell confluence decrease, 24 hours after the withdrawal of MeHg of culture medium. The C6 cell line culture in addition showed an increase on doubling time parameter. This study demonstrates for the first time exposure to methylmercury low and sublethal concentration can promote genotoxic events and disturbances in cell proliferation in glial cell origin.
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Molecular basis for the anti-inflammatory properties of chlomethiazole /Simi, Anastasia, January 2003 (has links)
Diss. (sammanfattning) Stockholm : Karol. inst., 2003. / Härtill 5 uppsatser.
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Genetic networks modulating retinal injury /Vazquez-Chona, Felix. January 2006 (has links) (PDF)
Thesis (Ph. D.)--University of Tennessee, Memphis, 2006. / The electronic version of this thesis is available at http://d.utmem.edu/CAMPUS-ACCESS-ONLY/2006-001-chona.pdf Includes bibliographical references (leaves 128-136).
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