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O papel do óleo de peixe na via L-arginina-óxido nítrico e no estresse oxidativo em eritrócitos: um estudo dose-resposta / The role of fish oil on L-arginine-nitric oxide and oxidative stress in erythrocytes: a dose-response studyMarcela Anjos Martins 30 March 2012 (has links)
Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro / Os ácidos graxos poli-insaturados n-3 derivados do óleo de peixe estão associados a benefícios cardiovasculares, que podem ser decorrentes da ativação da óxido nítrico sintase (NOS). Assim como as células endoteliais, os eritrócitos possuem NOS endotelial (eNOS) e induzível (iNOS) e, portanto, são capazes de sintetizar óxido nítrico (NO). O presente estudo testou a capacidade que diferentes concentrações de óleo de peixe tem de ativar a via L-arginina-NO e, em seguida, alterar os níveis de guanosina monofosfato cíclica (GMPc) em eritrócitos de camundongos alimentados com dieta hiperlipídica. Além disso, foram analisados os marcadores de estresse oxidativo nos eritrócitos, objetivando investigar a biodisponibilidade do NO. O transporte de L-arginina, avaliado através da incubação com L-[3H]-arginina, mostrou-se ativado quando da administração de dietas contendo elevadas concentrações de óleo de peixe, em comparação com as dietas contendo baixas concentrações e controle. A atividade da NOS, medida pela conversão de L-[3H]-arginina em L-[3H]-citrulina, e a expressão da eNOS também aumentaram nos animais que se alimentaram com dietas ricas em óleo de peixe. Apesar da ativação da via L-arginina-óxido nítrico observada em nossos experimentos, os níveis de GMPc intraeritrocitário não foram afetados. O dano oxidativo nos eritrócitos aumentou linearmente conforme o óleo de peixe era acrescido na dieta, sem afetar a atividade das enzimas antioxidantes. Além do endotélio, os eritrócitos contribuem para o metabolismo do NO. Desta forma, a ativação da via L-arginina-NO nessas células pode ser benéfica para saúde cardiovascular. Estudos futuros poderão investigar outros marcadores de estresse oxidativo durante o consumo de óleo de peixe para assegurar que o seu uso não resulta em efeitos prejudiciais secundários e para garantir a biodisponibilidade de NO. / The n-3 polyunsaturated fatty acids derived from fish oil are associated with cardiovascular benefits and it has been suggested that the activation of nitric oxide synthase (NOS) would be a potential mechanism responsible for its effects. Beside endothelial cells, red blood cells (RBC) possess endothelial NOS (eNOS) and inducible NOS (iNOS), and thus are capable of synthesizing their own nitric oxide (NO). The present study tested the capacity of different amounts of fish oil to activate L-arginine-NO pathway and therefore alter cyclic guanosine monophosphate (cGMP) levels in RBC from mice fed on a high fat diet. Additionally, the oxidative status in RBC was performed to investigate NO bioavailability. L-arginine transport, assessed by incubation with L-[3H]-arginine, was activated by higher doses of fish oil, compared to control diet and to lowest doses of fish oil. RBC NOS activity, measured by the conversion of L-[3H]-arginine into L-[3H]-citrulline, and eNOS expression were also enhanced by diets rich in fish oil. Despite the L-arginine-NO activation, no effect on intra RBC cGMP basal levels was seen among the groups. Oxidative damage of RBC rises linearly with increasing amounts of fish oil in the diet without affecting the activity of antioxidant enzymes. Besides endothelium, red blood cells also contribute regulating the NO bioactivity. Therefore, the activation of L-arginine-NO pathway in RBC by fish oil would be beneficial in cardiovascular health. Future studies testing other oxidant markers during dietary fish oil supplementation will be necessary to verify that its consumption does not result in detrimental secondary effects and to ensure NO bioavailability.
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Mecanismos moleculares e celulares envolvidos na modulação da via L-arginina-óxido nítrico em hipertensão e insuficiência renal crônica. / Molecular and cellular mechanisms involved in the modulation of L-arginine, nitric oxide pathway in hypertension and chronical renal failureMonique Bandeira Moss 30 July 2010 (has links)
Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro / A insuficiência renal crônica (IRC) e a hipertensão arterial sistêmica (HAS) são patologias com alta morbidade e mortalidade, consumindo grandes verbas de saúde pública. A disfunção endotelial presente tanto na IRC, como na hipertensão, contribui para a manutenção de elevada resistência periférica, favorecendo complicações como a aterosclerose. Esta disfunção endotelial é parte de um estado pró-trombótico, levando à ocorrência de eventos cardiovasculares, principal causa de morte nestas patologias. O óxido nítrico (NO) tem um papel importante na modulação da atividade plaquetária. Anormalidades na síntese e/ou inativação do NO são descritas tanto na insuficiência renal crônica como na hipertensão. Estudos prévios demonstraram uma redução do influxo de L-arginina em eritrócitos e plaquetas de pacientes hipertensos e em um modelo animal de hipertensão. Além disso, em IRC, nosso grupo mostrou uma ativação da via L-arginina-NO em plaquetas. O objetivo dessa tese é avaliar a via L-arginina-NO na HAS e em diferentes estágios da IRC, bem como investigar o ciclo da uréia, e a presença de marcadores de estresse nesses pacientes. De acordo com o presente estudo pôde-se verificar que não houve alteração na síntese de NO em eritrócitos na hipertensão, todavia ocorre uma ativação do ciclo da uréia, que pode ser dada pelo aumento do influxo de L-arginina eritrocitário previamente demonstrado. Não foi demonstrada diferença significativa na peroxidação lipídica sistêmica, em plaquetas ou eritrócitos na HAS. Em plaquetas, no entanto, houve uma redução da atividade da NO sintase (NOS), que não foi acompanhada por alteração da expressão das isoformas da NOS, da arginase, da fosfodiesterase 5 (PDE5) ou da guanilato ciclase (GC) solúvel. Essa redução na síntese de NO em plaquetas pode ser explicada por um menor influxo de L-arginina que está presente na hipertensão. Os eritrócitos de pacientes renais crônicos em hemodiálise mostraram um maior influxo de L-arginina associado a um aumento da expressão e da atividade da arginase, não havendo diferença na atividade da NOS. Além disso, apesar e não ter sido mostrado alteração nos marcadores de peroxidação lipídica em eritrócitos e plaquetas, foi detectado um aumento dos mesmos no soro de pacientes com IRC em hemodiálise. Por outro lado, as plaquetas dos mesmos pacientes apresentaram uma maior expressão da eNOS, da iNOS e da GC solúvel, acompanhada de uma redução da atividade da arginase, o que pode justificar a disfunção plaquetária que existe nesses pacientes. Plaquetas de pacientes portadores de IRC em tratamento conservador mostraram um aumento da atividade da NOS associado com maior expressão tanto da iNOS como da eNOS. Curiosamente foram detectados menores concentrações de 35-monofosfato de guanosina cíclica (GMPc), não havendo no entanto, diferença nos padrões de agregação plaquetária induzida por colágeno ou adenosina difosfato (ADP). As descobertas aqui apresentadas certamente contribuirão para uma melhor compreensão da fisiopatologia da HAS e da IRC. / Chronic renal failure (CRF) and essential hypertension (EH) are diseases associated with high rates of morbidity and mortality, consuming huge amounts of money from the public health system. The endothelial dysfunction existent in both diseases, CRF and EH, contributes to the maintenance of the high peripheral resistance, and contribute to circulatory complications such as atherosclerosis. This endothelial dysfunction is part of a pro-thrombotic state, leading to cardiovascular events, which are the major cause of death in these disorders. Nitric oxide (NO) plays an important role in the modulation of platelet function. Abnormalities of NO synthesis or inactivation are described in CRF and EH. It was previously reported an inhibition of L-arginine transport in erythrocytes of hypertensive patients and in an animal model of hypertension. Moreover, we have also demonstrated an activation of L-arginine-NO pathway in platelets taken from uraemic patients. The aim of the present thesis is to investigate L-arginine-NO pathway in arterial hypertension and in different stages of chronic renal failure. It will also be evaluated urea cycle and the presence of oxidative stress markers in these patients. According to the present study it was not detected any alteration in erythrocytres NO synthesis in hypertension, however, there was an activation of urea cycle, which could be explained by an increase in L-arginine influx. The present study has not demonstrated significative difference in markers of lipid peroxidation in the serum, platelets or erythrocytes in hypertension. In platelets however, there was an inhibition of NO synthase (NOS) activity without any alterations of NOS isoforms, arginase, phosphodiesterase 5 (PDE5) or soluble guanylyl cyclase (sGC) expression. This reduction of NO synthesis may be explained by a lower influx of L-arginine that is present on hypertension. Erythrocytes from chronic renal failure patients under haemodyalysis have shown an increased influx of L-arginine associated with a higher expression and activity of arginase with no difference in NOS activity. Therefore, although it was not shown abnormalities of lipid per oxidation markers in erythrocytes and platelets, it was detected increased levels of these markers in the serum of chronic renal failure patients under hemodyalysis. On the other hand, platelets from the same patients exhibited increased expression of eNOS, iNOS and soluble guanylyl cyclase associated with reduced arginase activity, which can explain the platelet dysfunction observed in these patients. Platelets taken from patients with chronic renal failure under conservative treatment have shown increased NOS activity associated with higher expression of both iNOS and eNOS. Curiously, it was been detected a lower concentration of cyclic guanosine monophosphate (cGMP), although there was no difference in the patterns of platelet aggregation induced by collagen or adenosine diphosphate (ADP). The findings reported in this study may contribute to a better understanding of EH and CRF physiopathology.
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Function of Vascular Endothelial Cells in Aging and Hypothermia: Clinical ImplicationsOsama, Mohammad January 2018 (has links)
No description available.
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The role of the JNK/AP-1 pathway in the induction of iNOS and CATs in vascular cellsZamani, Marzieh January 2013 (has links)
Nitric oxide (NO) is an important biological molecule within the body, which over production of this molecule in response to different stimulations can cause various inflammatory diseases. Over production of this molecule is caused by the induction of the inducible nitric oxide synthase (iNOS) enzyme. This enzyme uses L-arginine as a substrate and therefore the presence and transport of this amino acid into the cells can be a key factor in regulating NO over production. Different signalling mechanisms have been implicated in the regulation of this pathway and one of which involves the Mitogen Activated Protein Kinases (MAPK). This family of proteins respond to inflammatory conditions and may mediate effects induced by inflammatory mediators. Of the MAPKs, the role of the c-Jun-N-terminal kinase (JNK) pathway in the induction of iNOS is still controversial. JNK and its downstream target, the transcription factor Activator Protein-1 (AP-1), have shown contradictory effects on iNOS induction leading to controversies over their role in regulating iNOS expression in different cell systems or with various stimuli. The studies described in this thesis have determined the role of JNK/AP-1 on iNOS expression, NO production, L-arginine uptake and also on the transporters responsible for L-arginine transport into the cells. The studies were carried out in two different cell types: rat aortic smooth muscle cells (RASMCs) and J774 macrophages which are both critically associated with the over production of NO in vascular inflammatory disease states. The first approach was to block the expression of the inducible L-arginine-NO pathway using SP600125 and JNK Inhibitor VIII which are both pharmacological inhibitors of JNK. The results from these studies showed that the pharmacological intervention was without effect in RASMCs, but inhibited iNOS, NO and L-arginine transport in J774 macrophages. In contrast, the molecular approach employed using two dominant negative constructs of AP-1 (TAM-67 and a-Fos) revealed a different profile of effects in RASMCs, where a-Fos caused an induction in iNOS and NO while TAM-67 had an inhibitory effect on iNOS, NO, L-arginine transport and CAT-2B mRNA expression. The latter was unaffected in RASMCs but suppressed in J774 macrophages by SP600125. Examination of JNK isoforms expression showed the presence of JNK1 and 2 in both cell systems. Moreover, stimulation with LPS/IFN- or LPS alone resulted in JNK phosphorylation which did not reveal any difference between smooth muscle cells and macrophages. In contrast, expression and activation of AP-1 subunits revealed differences between the two cell systems. Activation of cells with LPS and IFN- (RASMCs) or LPS alone (J774 macrophages) resulted in changes in the activated status of the different AP-1 subunit which was different for the two cell systems. In both cell types c-Jun, JunD and Fra-1 were increased and in macrophages, FosB activity was also enhanced. Inhibition of JNK with SP600125 caused down-regulation in c-Jun in both cell types. Interestingly this down-regulation was in parallel with increases in the subunits JunB, JunD, c-Fos and Fra-1 in RASMCs or JunB and Fra-1 in J774 macrophages. Since, SP600125 was able to exert inhibitory effects in the latter cell type but not in RASMCs, it is possible that the compensatory up-regulation of certain AP-1 subunits in the smooth muscle cells may compensate for c-Jun inhibition thereby preventing suppression of iNOS expression. This notion clearly needs to be confirmed but it is potentially likely that hetero-dimers formed between JunB, JunD, c-Fos and Fra-1 could sustain gene transcription in the absence of c-Jun. The precise dimer required has not been addressed but unlikely to exclusively involve JunB and Fra-1 as these are up-regulated in macrophages but did not sustain iNOS, NO or induced L-arginine transport in the presence of SP600125. To further support the argument above, the dominant negatives caused varied effects on the activation of the different subunits. a-Fos down-regulated c-Jun, c-Fos, FosB, Fra-1 whereas TAM-67 reduced c-Jun and c-Fos but marginally induced Fra-1 activity. Associated with these changes was an up-regulation of iNOS-NO by a-Fos and inhibition by TAM-67. Taken together, the data proposes a complex mechanism(s) that regulate the expression of the inducible L-arginine-NO pathway in different cell systems and the complexity may reflect diverse intracellular changes that may be different in each cell type and not always be apparent using one experimental approach especially where this is pharmacological. Moreover, these findings strongly suggest exercising caution when interpreting pure pharmacological findings in cell-based systems particularly where these are inconsistent or contradictory.
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