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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
51

Neuropatia diabética : estudo dos mecanismos moleculares envolvidos com a neurotoxicidade do metilglioxal e do glicolaldeído em células diferenciadas de neuroblastoma humano SH-SY5Y

Londero, Giovana Ferreira January 2012 (has links)
Neuropatia é a complicação mais comum e mais debilitante da Diabetes Mellitus, a longo prazo presente em mais de 50% dos pacientes que possuem a doença. A hiperglicemia induz estresse oxidativo nos neurônios de diabéticos acarretando a ativação de múltiplas vias bioquímicas, as quais são potenciais alvos terapêuticos para a neuropatia diabética. Está claro que compostos carbonil reativos são mediadores glicotóxicos do estresse oxidativo através da formação de produtos finais de glicação avançada como resultado direto da hiperglicemia. Metilglioxal e glicolaldeído são compostos carbonil reativos inevitavelmente produzidos pelo metabolismo, os quais são encontrados em maior quantidade em situações de hiperglicemia. Recentemente, tem sido dada muita atenção para o envolvimento de espécies reativas na toxicidade do metilglioxal e do glicolaldeído, e tem-se demonstrado que essas glicotoxinas têm potencial para induzir estresse oxidativo, parar o crescimento celular e promover morte por apoptose ou necrose. O metilglioxal e o glicolaldeído interagem com grupamentos sulfidril de moléculas de glutationa e de enzimas, inibindo sua atividade; entretanto, os mecanismos moleculares relacionados aos efeitos tóxicos dessas glicotoxinas e as vias pelas quais elas levam a formação de espécies reativas não estão completamente elucidados. Neste estudo nós buscamos esclarecer a relação entre o metabolismo do metilglioxal e do glicolaldeído e a produção de espécies reativas, e investigamos as possíveis rotas de morte celular envolvidas. Utilizamos a linhagem celular de neuroblastoma humano SH-SY5Y diferenciada, pois este é um modelo neuronal bem caracterizado para estudos de compostos neurotóxicos. Nós avaliamos a produção de espécies reativas induzida por metilglioxal e glicolaldeído através da técnica da diclorofluoresceína, e avaliamos, também, seus efeitos sob o conteúdo de glutationa celular. Além disso, investigamos a ativação das caspase-3, -8 e -9 e a contribuição de diferentes sistemas peroxidases (glutationa-redutase e a tioredoxina-redutase), na defesa neuronal contra essas glicotoxinas. Como resultados encontramos que o tratamento com ambas glicotoxinas rapidamente provocou um aumento na produção de espécies reativas e diminuição do conteúdo de glutationa, com concomitante ativação das caspases-8 e -9 e, posteriormente, também houve ativação da caspase-3 pelo tratamento com metilglioxal. Vimos que a tioredoxina-redutase possui um papel mais importante na defesa celular contra a toxicidade do metilglioxal do que contra o glicolaldeído, enquanto que a glutationa-redutase tem papel semelhante na defesa celular contra ambas glicotoxinas. Nossos resultados demonstraram que o estresse oxidativo é um importante mecanismo da toxicidade do metilglioxal e do glicolaldeído nas células diferenciadas SHSY5Y e, que enzimas redutoras de grupamentos sulfidril contribuem de diferentes formas na defesa celular contra cada uma dessas glicotoxinas. / Neuropathy is the most common and debilitating complication of Diabetes Mellitus present in more than 50% of the patients with long-standing disease. Hyperglycemia induces oxidative stress in neurons from diabetic patients and results in activation of multiple biochemical pathways. These activated pathways are a major source of damage and are potential therapeutic targets in diabetic neuropathy. A large body of evidence has implicated reactive carbonyl compounds as glycotoxic mediators of oxidative stress by forming advanced glycation endproducts as a direct result of hyperglycemia. Methylglyoxal and glycolaldehyde are reactive carbonil compounds inevitably produced by the metabolism, but they are found in increased rates under hyperglycemia condition. Recently, the attention has been focused on the involvement of reactive species in methylglyoxal and glycolaldehyde toxicities, resulting in oxidative stress and leading to cell growth arrest, apoptotic or necrosis death. These glycotoxins interact with sulfhydryl-groups of glutathione molecules enzymes, inhibiting their activity; however, the molecular mechanism underlying methylglyoxal and glycolaldehyde cytotoxic effects and reactive species generation are not fully understood. In this study we have pursued to establish the role of methylglyoxal and glycolaldehyde metabolisms and reactive species production, and have looked for the possible death routes involved with the toxic effects of these glycotoxins. Here we used the differentiated human neuroblastoma SH-SY5Y cells as neuronal experimental model to investigate the pathological effects of various neurotoxic compounds. We have evaluated the methylglyoxal and glycolaldehyde capacity to reactive species generation by dichlorofluorescein assay and their effects upon cellular glutathione content. Also, we have assessed the caspase-3, -8 and -9 activation and the contribution of different peroxidases systems (glutathione reductase and thioredoxin reductase) in the neuronal defense against methylglyoxal and glycolaldehyde cytotoxicities. We found that both glycotoxins promptly provoke reactive species generation and decrease the cell glutathione content, as well induce caspase-8 and -9 activation. Later caspase-3 activation was found in methylglyoxal treatment. We demonstrate that thioredoxin reductase has a most important role in cell defense against methylglyoxal toxicity than against glycolaldehyde, meanwhile there is no difference in the glutathione reductase role. Our results show that oxidative stress is an important mechanism in the methylglyoxal and glycolaldehyde toxicities and sulfhydryl reductases contributes differently in the cellular defense against these glycotoxins.
52

Caracterização e utilização de arroz vermelho (Oryza glaberrima) e preto (Oryza sativa) e seus subprodutos para a produção de filmes biodegradáveis

Vargas, Carolina Galarza January 2018 (has links)
O crescente interesse científico relacionado ao estudo das propriedades dos grãos de arroz vermelho (Oryza glaberrima) e preto (Oryza sativa) está atrelado ao elevado teor nutricional desses grãos. Quando submetidos ao processo de beneficiamento, eles geram subprodutos, entre os quais a quirera e o farelo, ricos em amido e compostos fenólicos, respectivamente. Uma vez consideradas as diferenças varietais dos grãos e o potencial uso dos seus subprodutos, os objetivos deste trabalho foram, primeiramente, determinar a composição química e o perfil de compostos bioativos desses grãos e, sequencialmente, avaliar sua atividade antioxidante por meio da análise do efeito protetor de células SH- SY5Y. Posteriormente, esses grãos e seus subprodutos foram utilizados como material para o desenvolvimento de filmes biodegradáveis. A identificação e quantificação de compostos fenólicos foi avaliada em extratos da fração farelo de ambos os grãos, por ser essa a fração que contém sua maior concentração. Os resultados evidenciaram que o ácido ferúlico foi o principal composto fenólico encontrado em ambas as amostras. Enquanto no farelo de arroz preto a cianidina-3-glicosídeo foi a antocianina majoritária, no farelo de arroz vermelho foi identificada a presença de proantocianidinas Com relação à atividade antioxidante, o ensaio realizado em cultura de células SH-SY5Y, demonstrou que os extratos de ambos os farelos de arroz, nas duas concentrações testadas (10 and 50 μg/mL), apresentam um efeito protetor contra as espécies reativas geradas pelo H2O2 (ensaio DCFH-DA) e, esse resultado foi relacionado à presença de compostos bioativos, especialmente ácidos fenólicos e antocianinas. Devido às propriedades físico-químicas e antioxidantes, amido e farinha de arroz vermelho foram utilizados para o desenvolvimento de filmes biodegradáveis. Foram desenvolvidas formulações contendo diferentes proporções de farinha e amido (10:0, 9:1, 7:3, 5:5 e 0:10, p/p). A incorporação de amido nos filmes de farinha promoveu melhora das propriedades mecânicas e estruturais e, redução da permeabilidade ao vapor de água. Baseado na excelente atividade de sequestro do radical DPPH. e no menor custo de produção, a formulação 9:1 foi escolhida para ser aplicada na forma de sachê para análise da estabilidade de óleo de girassol armazenado sob condições de oxidação acelerada. Os resultados demonstraram que os filmes foram eficazes como embalagem protetora impedindo a formação de produtos de degradação primários (peróxidos e dienos conjugados) e secundários (trienos conjugados) durante o armazenamento. A partir dos resultados obtidos neste trabalho, fica evidenciada a possibilidade de utilização dos grãos de arroz vermelho e preto e seus subprodutos como matérias-primas promissoras para o desenvolvimento de embalagens biodegradáveis fonte de compostos antioxidantes. / The increase scientific interest related to the study of the properties of red (Oryza glaberrima) and black rice (Oryza sativa) grains is related to the high nutritional content of these grains. When submitted to the polishing process, they generate by-products, among them broken grains and bran, rich in starch and phenolic compounds, respectively. Once considered varietal differences of the grains, and the potential use of their by-products, the goals of this work were, firstly, to determine the chemical composition and the bioactive compounds profile of these grains and, sequentially evaluate their antioxidant activity by analyzing the protective effect of SH-SY5Y cells. Subsequently, these grains and their by-products were used as material for the development of biodegradable films. The identification and quantification of phenolic compounds was evaluated in extracts of the bran fraction of both grains, since this is the fraction that contains the highest concentration of them. The results showed that ferulic acid was the main phenolic compound found in both samples. While in the black rice bran cyanidin-3-glycoside was the major anthocyanin, in the red rice bran the presence of proanthocyanidins was identified. In relation to the antioxidant activity, the SHSY5Y cell culture assay showed that the extracts from both rice bran, at both concentrations tested (10 and 50 μg/ mL), had a protective effect against the reactive species generated by H2O2 (DCFH-DA assay) and this result was related to the presence of bioactive compounds, especially phenolic acids and anthocyanins. Due to the physicochemical and antioxidant properties, starch and red rice flour were used for the development of biodegradable films Formulations containing different ratios of flour and starch (10:0, 9:1, 7:3, 5:5 and 0:10, w/w) were developed. The incorporation of starch in the flour films promoted improved mechanical and structural properties, and reduced permeability to water vapor. Based on excellent scavenging activity of DPPH radical and lowest production cost, the 9: 1 formulation was chosen to be applied in the form of sachets to analyze the stability of sunflower oil stored under accelerated oxidation conditions. The results demonstrated that the films were effective as protective packaging preventing the formation of primary degradation products (peroxides and conjugated dienes) and secondary (conjugated trienes) during the storage. Based on the results obtained in this work, it was confirmed the possibility of using red and black rice grains and their by-products as promising raw materials for the development of biodegradable packaging source of antioxidant compounds.
53

Caracterização da diferenciação neural induzida por ácido retinóico da linhagem de neuroblastoma humano SH-SY5Y e seu uso como ferramenta para pesquisa em neurociências

Lopes, Fernanda Martins January 2012 (has links)
Os mecanismos moleculares que levam ao dano da via nigroestriatal durante a progressão da Doença de Parkinson (DP) ainda não estão totalmente elucidados. Dessa forma, existe a necessidade de desenvolver modelos experimentais adequados para o estudo desse distúrbio neurodegenerativo. A linhagem de neuroblastoma humano SH-SY5Y tratada com neurotoxinas indutoras deste distúrbio (ex.: 6-hidroxidopamina - 6-OHDA) é amplamente utilizada como modelo in vitro da DP. Muitos estudos mostram que esta linhagem pode ser diferenciada em células dopaminérgicas através da combinação da diminuição do soro fetal bovino (SFB) em meio de cultura e da adição de neurotrofinas como o ácido retinóico (AR). No entanto, há poucos estudos mostrando as diferenças entre células proliferativas e diferenciadas da linhagem de neuroblastoma SH-SY5Y, além do efeito do tratamento com 6-OHDA. Ainda, não há um consenso nos protocolos de diferenciação. Dessa forma, o objetivo deste estudo foi estabelecer um protocolo de diferenciação dopaminérgica da linhagem de neuroblastoma humano SH-SY5Y, bem como avaliar a potencialidade do modelo como plataforma para o screening de neurotoxicidade/neuroproteção de compostos e a possibilidade de manipulação gênica. As células proliferativas SH-SY5Y foram mantidas em meio de cultura DMEM/F12 (1:1) suplementado com 10% de SFB. A diferenciação foi induzida pela combinação de 10 μM de AR e meio de cultura com 1% de SFB durante 4, 7 e 10 dias. Foram avaliados parâmetros morfológicos (presença de neuritos) e neuroquímicos, através marcadores de diferenciação neuronal (DAT- transportador de dopamina; TH – tirosina hidroxilase; ENS – enolase neurônio específica; NeuN – proteína nuclear de neurônio; Nestina). Ainda, avaliamos parâmetros de estresse oxidativo através da atividade de enzimas antioxidantes e dos níveis de tióis reduzidos. Nossos dados mostraram que as células SH-SY5Y diferenciadas por 7 dias apresentaram mudanças morfológicas e o aumento do imunoconteúdo de todos os marcadores neuronais testados, e a concomitantemente diminuição do imunoconteúdo de nestina (marcador de células indiferenciadas). Além disso, o fenótipo neuronal apresentou uma maior atividade de alguns sistemas antioxidantes. Também foi avaliada a citotoxicidade frente ao H2O2 e à 6-OHDA nos dois fenótipos. As células diferenciadas se mostraram mais resistentes ao dano causado pelo H2O2 e mais sensíveis à 6-OHDA. Dessa forma, a citotoxicidade da 6-OHDA pode estar relacionada com o aumento do imunoconteúdo do DAT, visto que a neurotoxina entra na célula dopaminérgica através deste transportador. Interessantemente, as células diferenciadas apresentaram aumento dos níveis da proteína neuroprotetora DJ-1, que está relacionada a uma forma prematura de Parkinsonismo em humanos. Após a caracterização do modelo, nós utilizamos o fenótipo diferenciado como plataforma experimental para o screening de compostos neuroprotetores como os organocalcogênios. Nós determinamos a citotoxidade destes compostos em células diferenciadas da linhagem de neuroblastoma SH-SY5Y. A partir destes dados, foram selecionados compostos com baixa citotoxicidade e avaliamos a morfologia celular (densidade de neuritos). Nós verificamos que antes da perda de viabilidade, ocorre a perda de neuritos, sendo que este parâmetro é outra vantagem do modelo de célula diferenciada para avaliação da neurototoxicidade. Ainda, verificamos que estes compostos são capazes de prevenir o dano celular causado pela 6-OHDA. Além disso, nós caracterizamos a capacidade do modelo de ser manipulado geneticamente através da transfecção e superexpressão de plasmídeo contendo a proteína verde fluorescente, onde verificamos que a expressão é mantida durante a diferenciação. Dessa forma, nossos dados mostraram a eficácia da padronização da diferenciação induzida por AR da linhagem de neuroblastoma humano SH-SY5Y, pois estas células apresentam características morfológicas e neuroquímicas adequadas de neurônio dopaminérgico bem como pode ser aplicado não só para avaliação de neurototoxicidade/neuroproteção, mas também pode ser manipulado geneticamente. / The molecular mechanisms underlying the massive cellular loss found in the nigrostriatal pathway during the progression of Parkinson’s disease (PD) are not completely understood. Therefore, it is important to develop more suitable experimental models to study the molecular mechanisms of this neurodegenerative disorder. Proliferative human neuroblastoma cell line SH-SY5Y challenged with neurotoxins (e.g.: 6-hydroxydopamine – 6-OHDA) has been widely used as an in vitro model for PD. Many lines of evidence showed that this cell line differentiates with the combination of lower fetal bovine serum (FBS) and retinoic acid (RA) to dopaminergic-like neural cell. However, there are few studies addressing the differences between proliferative and RA-differentiated SH-SY5Y cells as well as their responses to 6-OHDA cytotoxicity. Moreover, there is no consensus in differentiation protocols. Hence, the objective of this study was to establish a RAinduced dopaminergic differentiation protocol and also evaluate its capabilities for drug screening of neurotoxicity/neuroprotection and genetic manipulation. Exponentially growing SH-SY5Y cells were maintained with DMEM/F12 (1:1) medium plus 10% FBS. Differentiation was triggered by the combination of 10 μM of RA plus medium with 1% of FBS during 4, 7 and 10 days. We evaluated the cell morphology (neurites) and the neuronal markers (Dopamine Transporter- DAT, Tyrosine Hydroxylase-TH, Neuron-Specific Enolase-NSE, Neuronal Nuclei Protein- NeuN, and Nestin immunocontent). Furthermore, we verify the activity of antioxidant enzymes and the reduced thiol levels. Our data demonstrated that SH-SY5Y cells differentiated for 7 days expresses all neuronal markers tested with concomitant decrease in nondifferentiated marker (nestin). Besides, they showed a higher activity of some antioxidant systems. We also evaluated the cytotoxicity of H2O2 and 6-OHDA in both phenotypes. Differentiated cells are more resistant to H2O2 and more sensitive to 6- OHDA. Hence, the damage caused by 6-OHDA could be related with the increase of DAT immuncontent, because this neurotoxin enters into the dopaminergic cell through this transporter. Interestingly, the differentiated cells have more levels of neuroprotective DJ-1 protein, which is related with a juvenile Parkinsonism. After establish the conditions of differentiation, we used the neuronal phenotype to perform a drug screening with organoselenide compounds. We verify the cytotoxicity of these compounds in differentiated cells. From these data, we selected compounds with low toxicity and evaluated the cell morphology (neurites density). We verify that before the loss of viability, there is a loss of neurites. This parameter is another advantage of the differentiated cells model to neurotoxicity evaluation. Moreover, these compounds were able to prevent neuronal cell death caused by 6-OHDA. We also characterized the ability of the model to be manipulated genetically through transfection and overexpression of a green fluorescent protein (GFP) plasmid. We verify that the expression of GFP is maintained during the differentiation. Hence, our data showed the efficacy of the RA-induced differentiation protocol of the neuroblastoma cell line SH-SY5Y, because these cells have morphological and neurochemical characteristics of dopaminergic neurons. Furthermore, the neuronal phenotype can be applyed not only to evaluate neurocytotoxicity/neuroprotection but also can be manipulated genetically.
54

Caracterização da diferenciação neural induzida por ácido retinóico da linhagem de neuroblastoma humano SH-SY5Y e seu uso como ferramenta para pesquisa em neurociências

Lopes, Fernanda Martins January 2012 (has links)
Os mecanismos moleculares que levam ao dano da via nigroestriatal durante a progressão da Doença de Parkinson (DP) ainda não estão totalmente elucidados. Dessa forma, existe a necessidade de desenvolver modelos experimentais adequados para o estudo desse distúrbio neurodegenerativo. A linhagem de neuroblastoma humano SH-SY5Y tratada com neurotoxinas indutoras deste distúrbio (ex.: 6-hidroxidopamina - 6-OHDA) é amplamente utilizada como modelo in vitro da DP. Muitos estudos mostram que esta linhagem pode ser diferenciada em células dopaminérgicas através da combinação da diminuição do soro fetal bovino (SFB) em meio de cultura e da adição de neurotrofinas como o ácido retinóico (AR). No entanto, há poucos estudos mostrando as diferenças entre células proliferativas e diferenciadas da linhagem de neuroblastoma SH-SY5Y, além do efeito do tratamento com 6-OHDA. Ainda, não há um consenso nos protocolos de diferenciação. Dessa forma, o objetivo deste estudo foi estabelecer um protocolo de diferenciação dopaminérgica da linhagem de neuroblastoma humano SH-SY5Y, bem como avaliar a potencialidade do modelo como plataforma para o screening de neurotoxicidade/neuroproteção de compostos e a possibilidade de manipulação gênica. As células proliferativas SH-SY5Y foram mantidas em meio de cultura DMEM/F12 (1:1) suplementado com 10% de SFB. A diferenciação foi induzida pela combinação de 10 μM de AR e meio de cultura com 1% de SFB durante 4, 7 e 10 dias. Foram avaliados parâmetros morfológicos (presença de neuritos) e neuroquímicos, através marcadores de diferenciação neuronal (DAT- transportador de dopamina; TH – tirosina hidroxilase; ENS – enolase neurônio específica; NeuN – proteína nuclear de neurônio; Nestina). Ainda, avaliamos parâmetros de estresse oxidativo através da atividade de enzimas antioxidantes e dos níveis de tióis reduzidos. Nossos dados mostraram que as células SH-SY5Y diferenciadas por 7 dias apresentaram mudanças morfológicas e o aumento do imunoconteúdo de todos os marcadores neuronais testados, e a concomitantemente diminuição do imunoconteúdo de nestina (marcador de células indiferenciadas). Além disso, o fenótipo neuronal apresentou uma maior atividade de alguns sistemas antioxidantes. Também foi avaliada a citotoxicidade frente ao H2O2 e à 6-OHDA nos dois fenótipos. As células diferenciadas se mostraram mais resistentes ao dano causado pelo H2O2 e mais sensíveis à 6-OHDA. Dessa forma, a citotoxicidade da 6-OHDA pode estar relacionada com o aumento do imunoconteúdo do DAT, visto que a neurotoxina entra na célula dopaminérgica através deste transportador. Interessantemente, as células diferenciadas apresentaram aumento dos níveis da proteína neuroprotetora DJ-1, que está relacionada a uma forma prematura de Parkinsonismo em humanos. Após a caracterização do modelo, nós utilizamos o fenótipo diferenciado como plataforma experimental para o screening de compostos neuroprotetores como os organocalcogênios. Nós determinamos a citotoxidade destes compostos em células diferenciadas da linhagem de neuroblastoma SH-SY5Y. A partir destes dados, foram selecionados compostos com baixa citotoxicidade e avaliamos a morfologia celular (densidade de neuritos). Nós verificamos que antes da perda de viabilidade, ocorre a perda de neuritos, sendo que este parâmetro é outra vantagem do modelo de célula diferenciada para avaliação da neurototoxicidade. Ainda, verificamos que estes compostos são capazes de prevenir o dano celular causado pela 6-OHDA. Além disso, nós caracterizamos a capacidade do modelo de ser manipulado geneticamente através da transfecção e superexpressão de plasmídeo contendo a proteína verde fluorescente, onde verificamos que a expressão é mantida durante a diferenciação. Dessa forma, nossos dados mostraram a eficácia da padronização da diferenciação induzida por AR da linhagem de neuroblastoma humano SH-SY5Y, pois estas células apresentam características morfológicas e neuroquímicas adequadas de neurônio dopaminérgico bem como pode ser aplicado não só para avaliação de neurototoxicidade/neuroproteção, mas também pode ser manipulado geneticamente. / The molecular mechanisms underlying the massive cellular loss found in the nigrostriatal pathway during the progression of Parkinson’s disease (PD) are not completely understood. Therefore, it is important to develop more suitable experimental models to study the molecular mechanisms of this neurodegenerative disorder. Proliferative human neuroblastoma cell line SH-SY5Y challenged with neurotoxins (e.g.: 6-hydroxydopamine – 6-OHDA) has been widely used as an in vitro model for PD. Many lines of evidence showed that this cell line differentiates with the combination of lower fetal bovine serum (FBS) and retinoic acid (RA) to dopaminergic-like neural cell. However, there are few studies addressing the differences between proliferative and RA-differentiated SH-SY5Y cells as well as their responses to 6-OHDA cytotoxicity. Moreover, there is no consensus in differentiation protocols. Hence, the objective of this study was to establish a RAinduced dopaminergic differentiation protocol and also evaluate its capabilities for drug screening of neurotoxicity/neuroprotection and genetic manipulation. Exponentially growing SH-SY5Y cells were maintained with DMEM/F12 (1:1) medium plus 10% FBS. Differentiation was triggered by the combination of 10 μM of RA plus medium with 1% of FBS during 4, 7 and 10 days. We evaluated the cell morphology (neurites) and the neuronal markers (Dopamine Transporter- DAT, Tyrosine Hydroxylase-TH, Neuron-Specific Enolase-NSE, Neuronal Nuclei Protein- NeuN, and Nestin immunocontent). Furthermore, we verify the activity of antioxidant enzymes and the reduced thiol levels. Our data demonstrated that SH-SY5Y cells differentiated for 7 days expresses all neuronal markers tested with concomitant decrease in nondifferentiated marker (nestin). Besides, they showed a higher activity of some antioxidant systems. We also evaluated the cytotoxicity of H2O2 and 6-OHDA in both phenotypes. Differentiated cells are more resistant to H2O2 and more sensitive to 6- OHDA. Hence, the damage caused by 6-OHDA could be related with the increase of DAT immuncontent, because this neurotoxin enters into the dopaminergic cell through this transporter. Interestingly, the differentiated cells have more levels of neuroprotective DJ-1 protein, which is related with a juvenile Parkinsonism. After establish the conditions of differentiation, we used the neuronal phenotype to perform a drug screening with organoselenide compounds. We verify the cytotoxicity of these compounds in differentiated cells. From these data, we selected compounds with low toxicity and evaluated the cell morphology (neurites density). We verify that before the loss of viability, there is a loss of neurites. This parameter is another advantage of the differentiated cells model to neurotoxicity evaluation. Moreover, these compounds were able to prevent neuronal cell death caused by 6-OHDA. We also characterized the ability of the model to be manipulated genetically through transfection and overexpression of a green fluorescent protein (GFP) plasmid. We verify that the expression of GFP is maintained during the differentiation. Hence, our data showed the efficacy of the RA-induced differentiation protocol of the neuroblastoma cell line SH-SY5Y, because these cells have morphological and neurochemical characteristics of dopaminergic neurons. Furthermore, the neuronal phenotype can be applyed not only to evaluate neurocytotoxicity/neuroprotection but also can be manipulated genetically.
55

Neuropatia diabética : estudo dos mecanismos moleculares envolvidos com a neurotoxicidade do metilglioxal e do glicolaldeído em células diferenciadas de neuroblastoma humano SH-SY5Y

Londero, Giovana Ferreira January 2012 (has links)
Neuropatia é a complicação mais comum e mais debilitante da Diabetes Mellitus, a longo prazo presente em mais de 50% dos pacientes que possuem a doença. A hiperglicemia induz estresse oxidativo nos neurônios de diabéticos acarretando a ativação de múltiplas vias bioquímicas, as quais são potenciais alvos terapêuticos para a neuropatia diabética. Está claro que compostos carbonil reativos são mediadores glicotóxicos do estresse oxidativo através da formação de produtos finais de glicação avançada como resultado direto da hiperglicemia. Metilglioxal e glicolaldeído são compostos carbonil reativos inevitavelmente produzidos pelo metabolismo, os quais são encontrados em maior quantidade em situações de hiperglicemia. Recentemente, tem sido dada muita atenção para o envolvimento de espécies reativas na toxicidade do metilglioxal e do glicolaldeído, e tem-se demonstrado que essas glicotoxinas têm potencial para induzir estresse oxidativo, parar o crescimento celular e promover morte por apoptose ou necrose. O metilglioxal e o glicolaldeído interagem com grupamentos sulfidril de moléculas de glutationa e de enzimas, inibindo sua atividade; entretanto, os mecanismos moleculares relacionados aos efeitos tóxicos dessas glicotoxinas e as vias pelas quais elas levam a formação de espécies reativas não estão completamente elucidados. Neste estudo nós buscamos esclarecer a relação entre o metabolismo do metilglioxal e do glicolaldeído e a produção de espécies reativas, e investigamos as possíveis rotas de morte celular envolvidas. Utilizamos a linhagem celular de neuroblastoma humano SH-SY5Y diferenciada, pois este é um modelo neuronal bem caracterizado para estudos de compostos neurotóxicos. Nós avaliamos a produção de espécies reativas induzida por metilglioxal e glicolaldeído através da técnica da diclorofluoresceína, e avaliamos, também, seus efeitos sob o conteúdo de glutationa celular. Além disso, investigamos a ativação das caspase-3, -8 e -9 e a contribuição de diferentes sistemas peroxidases (glutationa-redutase e a tioredoxina-redutase), na defesa neuronal contra essas glicotoxinas. Como resultados encontramos que o tratamento com ambas glicotoxinas rapidamente provocou um aumento na produção de espécies reativas e diminuição do conteúdo de glutationa, com concomitante ativação das caspases-8 e -9 e, posteriormente, também houve ativação da caspase-3 pelo tratamento com metilglioxal. Vimos que a tioredoxina-redutase possui um papel mais importante na defesa celular contra a toxicidade do metilglioxal do que contra o glicolaldeído, enquanto que a glutationa-redutase tem papel semelhante na defesa celular contra ambas glicotoxinas. Nossos resultados demonstraram que o estresse oxidativo é um importante mecanismo da toxicidade do metilglioxal e do glicolaldeído nas células diferenciadas SHSY5Y e, que enzimas redutoras de grupamentos sulfidril contribuem de diferentes formas na defesa celular contra cada uma dessas glicotoxinas. / Neuropathy is the most common and debilitating complication of Diabetes Mellitus present in more than 50% of the patients with long-standing disease. Hyperglycemia induces oxidative stress in neurons from diabetic patients and results in activation of multiple biochemical pathways. These activated pathways are a major source of damage and are potential therapeutic targets in diabetic neuropathy. A large body of evidence has implicated reactive carbonyl compounds as glycotoxic mediators of oxidative stress by forming advanced glycation endproducts as a direct result of hyperglycemia. Methylglyoxal and glycolaldehyde are reactive carbonil compounds inevitably produced by the metabolism, but they are found in increased rates under hyperglycemia condition. Recently, the attention has been focused on the involvement of reactive species in methylglyoxal and glycolaldehyde toxicities, resulting in oxidative stress and leading to cell growth arrest, apoptotic or necrosis death. These glycotoxins interact with sulfhydryl-groups of glutathione molecules enzymes, inhibiting their activity; however, the molecular mechanism underlying methylglyoxal and glycolaldehyde cytotoxic effects and reactive species generation are not fully understood. In this study we have pursued to establish the role of methylglyoxal and glycolaldehyde metabolisms and reactive species production, and have looked for the possible death routes involved with the toxic effects of these glycotoxins. Here we used the differentiated human neuroblastoma SH-SY5Y cells as neuronal experimental model to investigate the pathological effects of various neurotoxic compounds. We have evaluated the methylglyoxal and glycolaldehyde capacity to reactive species generation by dichlorofluorescein assay and their effects upon cellular glutathione content. Also, we have assessed the caspase-3, -8 and -9 activation and the contribution of different peroxidases systems (glutathione reductase and thioredoxin reductase) in the neuronal defense against methylglyoxal and glycolaldehyde cytotoxicities. We found that both glycotoxins promptly provoke reactive species generation and decrease the cell glutathione content, as well induce caspase-8 and -9 activation. Later caspase-3 activation was found in methylglyoxal treatment. We demonstrate that thioredoxin reductase has a most important role in cell defense against methylglyoxal toxicity than against glycolaldehyde, meanwhile there is no difference in the glutathione reductase role. Our results show that oxidative stress is an important mechanism in the methylglyoxal and glycolaldehyde toxicities and sulfhydryl reductases contributes differently in the cellular defense against these glycotoxins.
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The effect of selected medicinal plants on rotenone-induced toxicity in SH-SY5Y neuroblastoma cells

Seoposengwe, K.M. (Keabetswe Millicent) January 2013 (has links)
Parkinson's disease (PD) is the second most common chronic neurodegenerative disease characterized by dopamine decrease in the substantia nigra. Currently, there is no promising cure for PD and this has resulted in extensive research into alternative medicines. The aim of this study was to investigate the effect of methanol and ethyl acetate extracts of Lannea schweinfurthii (Engl. Engl) (Anacardiaceae), Zanthoxylum capense (Thunb. Harv) (Rutaceae), Scadoxus puniceus ((L.) Friis & Nordal) (Amaryllidaceae) and Crinum bulbispermum (Burm. f.) Milne-Redh. & Schweick) (Amaryllidaceae) on rotenone-induced toxicity in SH-SY5Y neuroblastoma cells. The latter which mimics PD symptoms in vitro. Cytotoxicity of the plant extracts was assessed using sulforhodamine B (SRB) assay. Intracellular reactive oxygen species (ROS) were measured fluorometrically with the use of the fluorescent dye 2‟,7‟-dichlorodihydrofluorescein diacetate (H2DCF-DA). Intracellular glutathione content was measured fluorometrically after staining with monochlorobimane (MCB). Fluorescent dye 5,5‟ ,6,6‟ -tetrachloro-1,1‟ ,3,3‟ -tetraethylbenzimidazolcarbocyanine iodide (JC-1) was used to assess the mitochondrial membrane potential (MMP) status of cells. Apoptosis was assessed by determining caspase-3 activity through detection of 7-amino-4-methylcoumarin (AMC) which is a product of caspace-3 substrate, acetyl-Asp-Glu-Val-Asp 7-amino-4-methylcoumarin (Ac-DEVD-AMC), cleaved by the caspase-3 enzyme. Rotenone was used as an in vitro model to induce PD-like symptoms. Cytotoxicity studies for methanol extract of Zanthoxylum capense revealed the highest IC50 value of 121.3 μg/mL, indicating low toxicity. The ethyl acetate extract of Crinum bulbispermum was observed to have no effect on the normal proliferation of the SH-SY5Y cells and produced an IC50 value >100 μg/mL. The calculated IC50 value obtained from rotenone cytotoxicity studies was 112 iv nM. Zanthoxylum capense and Scadoxus puniceus plant extracts were observed to be neuroprotective against rotenone-induced toxicity. A decrease in intracellular glutathione content as well as MMP was also observed in cells exposed to rotenone alone (50 nM). There was no intracellular ROS generation observed in cells exposed to rotenone alone (50 nM) after 24 h and 72 h. However, apoptotic cell death was observed in cells treated with rotenone (50 nM). Intracellular ROS production was observed to be elevated by methanol and ethyl acetate extracts of C. bulbispermum. Methanol extracts of Z. capense was observed to increase intracellular glutathione content. MMP was increased effectively following treatment with ethyl acetate extract of C. bulbispermum. Moreover, both methanol and ethyl acetate plant extracts were found to decrease caspase-3 activity significantly (p<0.05), in cells exposed to 50 nM rotenone. Z. capense methanol extract reduced caspase-3 activity the most effectively. Treatment with plant extracts was protective and decreased cell death. Furthermore, L. schweinfurthii, Z. capense, S. puniceus and C. bulbispermum, demonstrated strong antioxidant and anti-apoptotic effects against rotenone-toxicity, making them potential agents in developing therapies for treating PD. / Dissertation (MSc)--University of Pretoria, 2013. / gm2014 / Pharmacology / unrestricted
57

In vitro cellular models for neurotoxicity studies : neurons derived from P19 cells

Popova, Dina January 2017 (has links)
Humans are exposed to a variety of chemicals including environmental pollutants, cosmetics, food preservatives and drugs. Some of these substances might be harmful to the human body. Traditional toxicological and behavioural investigations performed in animal models are not suitable for the screening of a large number of compounds for potential toxic effects. There is a need for simple and robust in vitro cellular models that allow high-throughput toxicity testing of chemicals, as well as investigation of specific mechanisms of cytotoxicity. The overall aim of the thesis has been to evaluate neuronally differentiated mouse embryonal carcinoma P19 cells (P19 neurons) as a model for such testing. The model has been compared to other cellular models used for neurotoxicity assessment: retinoic acid-differentiated human neuroblastoma SH-SY5Y cells and nerve growth factor-treated rat pheochromocytoma PC12 cells. The chemicals assessed in the studies included the neurotoxicants methylmercury, okadaic acid and acrylamide, the drug of abuse MDMA (“ecstasy”) and a group of piperazine derivatives known as “party pills”. Effects of the chemicals on cell survival, neurite outgrowth and mitochondrial function have been assessed. In Paper I, we describe a fluorescence-based microplate method to detect chemical-induced effects on neurite outgrowth in P19 neurons immunostained against the neuron-specific cytoskeletal protein βIII-tubulin. In Paper II, we show that P19 neurons are more sensitive than differentiated SH-SY5Y and PC12 cells for detection of cytotoxic effects of methylmercury, okadaic acid and acrylamide. Additionally, in P19 neurons and differentiated SH-SY5Y cells, we could demonstrate that toxicity of methylmercury was attenuated by the antioxidant glutathione. In Paper III, we show a time- and temperature-dependent toxicity produced by MDMA in P19 neurons. The mechanisms of MDMA toxicity did not involve inhibition of the serotonin re-uptake transporter or monoamine oxidase, stimulation of 5-HT2A receptors, oxidative stress or loss of mitochondrial membrane potential. In Paper IV, the piperazine derivatives are evaluated for cytotoxicity in P19 neurons and differentiated SH-SY5Y cells. The most toxic compound in both cell models was TFMPP. In P19 neurons, the mechanism of action of TFMPP included loss of mitochondrial membrane potential. In conclusion, P19 neurons are a robust cellular model that may be useful in conjunction with other models for the assessment of chemical-induced neurotoxicity.
58

Optical techniques for the investigation of a mechanical role for FRMD6/Willin in the Hippo signalling pathway

Goff, Frances January 2019 (has links)
The mammalian hippo signalling pathway controls cell proliferation and apoptosis via transcriptional co-activators YAP and TAZ, and as such is a key regulator of organ and tissue growth. Multiple cellular components converge in this pathway, including the actin cytoskeleton, which is required for YAP/TAZ activity. The precise mechanism by which the mechanical actomyosin network regulates Hippo signalling, however, is unknown. Optical methods provide a non-invasive way to image and study the biomechanics of cells. In the past two decades, super-resolution fluorescence microscopy techniques that break the diffraction limit of light have come to the fore, enabling visualisation of intracellular detail at the nanoscale level. Optical trapping, on the other hand, allows precise control of micron-sized objects such as cells. Here, super resolution structured illumination microscopy (SIM) and elastic resonator interference stress microscopy (ERISM) were used to investigate a potential role for the FERM-domain protein FRMD6, or Willin, in the mechanical control of the Hippo pathway in a neuronal cell model. A double optical trap was also integrated with the Nikon-SIM with the aim of cell stretching. Willin expression was shown to modify the morphology, neuronal differentiation, actin cytoskeleton and forces of SH-SY5Y cells. Optical trapping from above the SIM objective, however, was demonstrated to be ineffective for manipulation of adherent cells. The results presented here indicate a function for Willin in the assembly of actin stress fibres that may be the result of an interaction with the Hippo pathway regulator AMOT. Further investigation, for example by direct cell stretching, is required to elucidate the exact role of Willin in the mechanical control of YAP/TAZ.
59

Bax-Inhibitor-1-vermittelte Neuroprotektion / Bax-Inhibitor-1 mediated neuroprotection

Siedenberg, Sandra 26 June 2007 (has links)
No description available.
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ADAM30 et métabolisme de l'APP : implication dans le développement physiopathologique de la maladie d'Alzheimer / ADAM30 and APP metabolism : an involment in Alzheimer's disease physiopathological development

Letronne, Florent 17 December 2014 (has links)
L’accumulation cérébrale progressive de peptides amyloïdes générés à partir du clivage du précurseur du peptide amyloïde (APP) par les sécrétases est un mécanisme central de la maladie d’Alzheimer. C’est pourquoi, améliorer la compréhension de la régulation et de l’homéostasie du métabolisme de l’APP est devenu primordial. Partant de ce constat, nous avons supposé qu’une partie de la réponse pourrait être apportée par la caractérisation de nouveaux acteurs du métabolisme de l’APP. De part leurs rôles cruciaux dans le cerveau (développement, plasticité et réparations) et dans le métabolisme de l’APP (&#945;-sécrétases), les ADAMs sont des protéines d’intérêt dont certaines fonctions ou rôles restent à déterminer. Précédemment, par une approche transcriptomique ciblant la famille des ADAMs dans des cerveaux de patients et de contrôles, ADAM30 a été retrouvée sous-exprimée dans le cerveau des patients atteints de la pathologie. Dans deux modèles cellulaires nous avions constaté que la sous-expression d’ADAM30 entraînait une augmentation de tous les produits du métabolisme de l’APP comme chez les patients. Le résultat opposé a été obtenu lors de la sur-expression d’ADAM30 dans ces cellules. Pour tenter de répliquer ces résultats dans un modèle plus proche de la physiopathologie humaine, nous avons développé un modèle de souris triples transgéniques surexprimant l’APPSweInd et ADAM30 de manière conditionnelle. Dans ce modèle nous avons observé et mesuré une diminution des dépôts amyloïdes dans le cerveau des souris exprimant ADAM30. Dans un second temps puisqu’il avait été montré au laboratoire qu’ADAM30 ne module pas l’activité des sécrétases et ne clive pas directement l’APP, nous avons cherché à déterminer les substrats d’ADAM30 dans le cadre du métabolisme de l’APP. Par une approche systématique nous avons pu déterminer que la Cathepsine D (CTSD) et l’Insuline Receptor Substrat 4 (IRS4) sont deux substrats potentiels d’ADAM30. Dans nos modèles cellulaires et de souris, nous avons pu constater qu’ADAM30 est capable de cliver et d’activer la CTSD. L’activité de la CTSD semble nécessaire pour l’action d’ADAM30 sur le métabolisme de l’APP. Nous avons pu déterminer que l’action spécifique d’ADAM30 pour la CTSD est dépendante de la séquence d’adressage au lysosome située dans l’extrémité C-terminale de l’APP. Comme la CTSD est une protéine Lysosomale, ADAM30 pourrait favoriser spécifiquement l’activation de la CTSD augmentant ainsi la dégradation de l’APP au sein de la voie endosome/lysosome. Ce mécanisme limiterait l’entrée de l’APP dans son métabolisme et donc la production de peptides amyloïdes. Afin de mieux comprendre la spécificité d’action d’ADAM30 pour la CTSD et l’APP, nous avons commencé à travailler sur le rôle potentiel d’IRS4 et la relation entre la voie de signalisation de l’Insuline et le métabolisme de l’APP. Nos travaux nous ont donc permis de mettre en évidence un nouvel acteur du métabolisme de l’APP, ADAM30, intervenant dans la régulation et la dégradation de ce dernier et ainsi d’améliorer notre compréhension des mécanismes de régulations fins impliqués dans le processus physiopathologique de la maladie d’Alzheimer. / Progressive intra-cerebral accumulation of amyloid peptides formed after sequential cleavage of the amyloid peptide precursor (APP) by secretases , is a central mecanism for Alzheimer’s disease. Therefore, a better understanding of APP regulation and homeostasy is now crucial. With this background, we postulate that the characterization of new actors in the APP metabolism could provide a more subtle understanding of this APP metabolism and trafficking. From their obvious implication in brain (development, plasticity and repair) and in APP metabolism (&#945;-secretases), ADAMs (A Disintegrin And Metalloprotease) are an important protein proteins family which still have some undetermined function or role. Previously, a transcriptomic approach targeting ADAMs family bas been done at the laboratory on Alzheimer’s patient or control brains and found ADAM30 as under-expressed in Alzheimer’s patient brains. On cellular models, we confirmed that ADAM30 under-expression was associate with an increase in production/secretion of all the APP metabolim byproducts. Opposite results were found with ADAM30 over-expression. To replicate those results in another model closest to human pathophysiology, we have developed a triple transgenic mice model over-expressing APPSweInd and conditionally over-expressing ADAM30. In this model, we have observed and measured a decrease in amyloid deposits in mice brains over-expressing ADAM30. Secondly, because ADAM30 did not modulate secretase activities and did not cleave APP directly, we decided to determine ADAM30 substrats in the APP metabolism context. With a systematic approach, we have determined that Cathepsin D (CTSD) and Insulin Receptor Substrat 4 (IRS4) are two ADAM30 potential substrats. In our cellular models, we have found that ADAM30 is able to cleave and activate CTSD. This CTSD activity is required for ADAM30 action on APP metabolism. We have determined that ADAM30 specific action for CTSD is dependent on lysosome adressing sequence localised in APP C-terminal part. CTSD is a lysosomal protein and so ADAM30 would make CTSD specific activation easier. This mecanism would be able to increase APP degradation in endosome/lysosome pathway and reduce APP entry in its metabolism. To better understand ADAM30 specific action on CTSD and APP, we begin to investigate the potential role of IRS4 and the relation between insulin signaling pathway ans APP metabolism. Combined together, those data suggest that ADAM30 is a new APP metabolism actor, involved in an early APP regulation and degradation pathway dependent on lysosome activation. This study participate in a better understanding of the fine mecanism regulations involved in Alzheimer’s disease pathophysiological process.

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