Global ETD Search

11	Stress réticulaire et maladie d'Alzheimer : contribution du facteur de transcription XBP-1s / Reticular stress in the Alzheimer's disease : role of the XBP-1s transcription factor Gerakis, Yannis 07 November 2016 (has links) La maladie d'Alzheimer est une pathologie neurodégénérative progressive liée à l'âge qui détériore premièrement les fonctions liées aux mémoires de travail et épisodiques, avant de s'étendre à l'ensemble des procédures mémorielles dans les stades plus avancés. L'ensemble des traitements existant à ce jour sont palliatifs. Au niveau histologique, la maladie d'Alzheimer est caractérisée par l'accumulation extra- et intracellulaire de différentes protéines agrégées (appelées amyloïde) dans les tissus cérébraux, entrainant des dysfonctions importantes du circuit neuronal. De fait, la majorité des approches thérapeutiques en développement consistent à tenter de réduire ou supprimer ces agrégats protéiques. Cependant, la maladie d'Alzheimer étant étroitement corrélée au vieillissement, certaines de ses caractéristiques biologiques sont parfois confondues avec celles du vieillissement non pathologique. L'une de ces caractéristiques est la diminution des différents mécanismes liés à l'homéostasie protéique (protéostasie). L'hypothèse réalisée au cours de mes travaux est que le rétablissement de ces mécanismes diminués par l'âge constituerait une approche thérapeutique crédible, complémentaire aux approches actuelles, à la pathologie complexe qu'est la maladie d'Alzheimer. C'est en suivant cette optique que je me suis intéressé au rôle et à la régulation de l'un des systèmes majeusr du contrôle de la protéostasie : l'UPR (unfolded protein response), et en particulier au facteur de transcription XBP-1s, considéré comme l'une des pièces maîtresses de ce réseau de signalisation cellulaire / Alzheimer's disease is a neurodegenerative pathology strongly correlated to aging. Its symptoms are characterized by an impaired short term memory process in the early stages of the disease and later on by a loss of all type of memory process. There is actually no cure for this pathology. At the histo-pathological levels, the disease show an accumulation of aggregated proteins in the brain (called amyloid protein) in the intra or extra cellular space, which act as a disruptor of the normal neuronal function and activity. Thus, most of the therapeutic approach to treat the disease aim at removing those proteins aggregates from the brain. However, some of the Alzheimer's disease characteristics could be melded with normal aging : One such case is the global decrease of the proteostasis mechanism in the cell which normally happen in normal brain. The assumption made during this work is that the recovery of these mechanisms impaired by age would constitute a credible therapeutic approach, complementary to the other existing approaches to the complex disease that is Alzheimer's disease. Following this hypothesis I was interested in the role and regulation of one of the major system controlling proteostasis: the UPR (unfolded protein response), and particulary to the XBP-1s transcription factor , considered one of the master regulator of this cellular network Alzheimer Neurodégénérescence UPR Protéostasie Peptide amyloïde Alzheimer Neurodegeneration UPR Proteostasis Amyloid peptide
12	O papel do aminoácido leucina na modulação da atividade do peptídeo beta amiloide em células SH-SY5Y / The role of leucine in the modulation of beta amyloid peptide activity in SH-SY5Y cells Lorenzeti, Fabio Medici 04 December 2014 (has links) Estudos demonstram que a indução do estresse oxidativo pelo peptídeo beta amiloide (A?) exerce um importante papel no desencadeamento da excitotoxicidade neuronal o que pode resultar no desenvolvimento de doenças neurodegenerativas. A formação do peptídeo A? se deve a alterações na proteína precursora de amiloide (APP) que é clivada para a formação do peptídeo A?. Por sua vez, os mecanismos de ação do A? no S.N.C. ocorrem através da sinalização do receptor NMDA (N-metil D-aspartato) receptor este que quando ativado pelo glutamato exerce importante papel fisiológico no S.N.C., visto que apresenta atividade ionotrópica que permite o influxo de Na+ e Ca2+ para as células neuronais, auxiliando nos processos de formação da memória e aprendizagem. Entretanto, apesar do seu papel fisiológico, a ativação excessiva do receptor NMDA é fortemente correlacionada com lesões no S.N.C. decorrente da excessiva permeabilidade do íon Ca2+ para o citosol das células neuronais. Com isso as concentrações de glutamato na fenda sináptica são estritamente controladas para que não haja ativação excessiva dos receptores com atividade glutamatérgica, como o receptor NMDA. Estudos indicam que o transporte de glutamina/glutamato através da barreira hematoencefálica é menor do que de outros aminoácidos, sendo que cerca de 25% a 30% do transporte de aminoácidos dos vasos sanguíneos para o cérebro através da barreira hematoencefálica é ocupado pelo aminoácido leucina, sendo este um grande responsável pela síntese de glutamato/glutamina no S.N.C. Com isso, estudos tem demonstrado que dietas enriquecidas com aminoácidos de cadeia ramificada, dentre eles a leucina, é responsável por alterar o metabolismo do glutamato e aumentar a susceptibilidade à excitotoxicidade de células neurais. A fim de testar esta hipótese utilizamos um modelo de cultura de células de neuroblastoma humano e realizamos o tratamento com diferentes concentrações de aminoácido leucina associado com o tratamento de peptídeo beta-amilóide. Realizamos as analises de citotoxicidade (LDH), viabilidade celular (MTT) e apoptose celular por citometria de fluxo (marcação com PE Anexina V e 7-AAD). Nossos resultados indicam que houve diferenças apenas entre o controle em relação aos demais grupos de tratamento / Studies demonstrate that induction of oxidative stress by beta amyloid peptide (A?) plays an important role in triggering neuronal excitotoxicity which can result in the development of neurodegenerative diseases. The formation of A? peptide are due to changes in the amyloid precursor protein (APP) which is cleaved to form the peptide A?. On the other hand, the mechanisms of action of A? in the C.N.S. occur through signaling of the NMDA (N-methyl-D-aspartate) receptor that when activated by glutamate plays an important physiological role in the C.N.S., as has inotropic activity that allows the influx of Na+ and Ca2+ into the neuronal cells, assisting in procedures of memory formation and learning. However, despite its physiological role, the excessive activation of the NMDA receptor is strongly correlated with C.N.S. lesions due to excess permeability of Ca2+ ions into the cytosol of neuronal cells. Thus the concentrations of glutamate in the synaptic cleft are strictly controlled so that there is excessive activation of receptors with glutamatergic activity, as the NMDA receptor. Studies indicate that the transport of glutamine/glutamate across the blood brain barrier is lower than that of other amino acids, of which about 25% to 30% of the amino acid transport blood vessels to the brain through the blood brain barrier is occupied by leucine this being one largely responsible for the synthesis of glutamate/glutamine in the C.N.S. Thus, studies have shown that diets enriched in branched chain amino acids, including leucine, are responsible for altering the metabolism of glutamate and excitotoxic increase susceptibility to neural cells. To test this hypothesis we used a cell culture model of human neuroblastoma and carry out the treatment with different concentrations of leucine associated with the processing of amyloid-beta peptide. We performed analysis of cytotoxicity (LDH), cell viability (MTT assay) and apoptosis using flow cytometry (Annexin V staining with PE and 7-AAD). Our results indicate that there were differences only between the control compared to the other treatment groups Aminoácido leucina Apoptose celular Beta-amyloid peptide Cellular apoptosis Células SH-SY5Y Leucine Peptídeo beta-amilóide SH-SY5Y cells
13	Hypothyroïdie et processus neurodégénératifs associés à la maladie d’Alzheimer / Hypothyroïdism and Neurodegenerative Processes Associated with Alzheimer’s Disease Chaalal, Amina 18 December 2014 (has links) La maladie d’Alzheimer (MA) est une maladie multifactorielle et à ce jour aucune cause des formes sporadiques de la maladie, qui représente plus de 99% des cas, n’a été mise en évidence. Des données émergentes de la littérature suggèrent l’existence d’un lien entre les dysfonctionnements thyroïdiens et la MA. Dans ce contexte, l’objectif de cette étude était de préciser l’implication de l’hypothyroïdie dans les processus neuropathologiques de la MA. En utilisant un modèle de rats rendus hypothyroïdiens par un traitement au propylthiouracile (PTU), nous avons montré que l’hypothyroïdie favorise la mise en place de lésions caractéristiques de la MA dans l’hippocampe, structure du cerveau précocement altérée dans la maladie et qui joue un rôle crucial dans les processus de mémoire. Une étude d’IRM in vivo a révélé une diminution progressive du volume cérébral des rats hypothyroïdiens. Dans l’hippocampe, l’hypothyroïdie s’accompagne d’une augmentation de la production de peptides amyloïdes, d’une hyperphosphorylation de la protéine Tau et d’une augmentation de la libération de plusieurs cytokines pro-Inflammatoires. Ces lésions, caractéristiques de la MA, sont associées à des troubles de la mémoire spatiale à court et long terme et à une altération de deux voies de signalisation connues pour jouer un rôle important dans les processus de plasticité synaptique et de mémoire : la voie calcique et la voie ERK-MAPK. Afin d’évaluer le potentiel de restauration de ces lésions, une partie des rats hypothyroïdiens a reçu des injections intra-Péritonéales de triiodothyronine (T3), forme active des hormones thyroïdiennes. Nos résultats montrent que l’administration de T3 permet de restaurer les déficits de mémoire spatiale à court terme, mais pas à long terme. En outre, ce même traitement permet de restaurer les niveaux de cytokines pro-Inflammatoires, de peptides amyloïdes ainsi que les voies « calcique » et « ERK-MAPK ». Ces données renforcent l’existence d’un lien entre l’hypothyroïdie et la MA : elles suggèrent que l’hypothyroïdie pourrait représenter un facteur important pouvant impacter le risque de développer des formes sporadiques de la MA. / Alzheimer’s disease (AD) is a multifactorial disease and to date no single cause for the sporadic forms, which accounts for over 99% of the cases, has been established. Converging evidence suggests a possible link between thyroid dysfunctions and AD. The aim of the present study was to explore the possibility that adult hypothyroidism represents an etiopathogenic mechanism of AD. In this context, using a hypothyroid rat model induced by propylthiouracil (PTU) treatment, we report that hypothyroidism is associated with several AD-Associated hallmarks in the hippocampus, a brain structure affected in early stages of AD and which plays a crucial role in memory processes. In vivo MRI revealed a progressive decrease in cerebral volume of hypothyroid-Rats. In the hippocampus, hypothyroidism resulted in Tau hyperphosphorylation, increased levels of amyloid peptide and of several pro-Inflammatory cytokines. These AD-Related pathological hallmarks were associated with impaired short- and long-Term spatial memory and alteration of hippocampal signalling pathways important for synaptic plasticity and memory, including calcium and ERK-MAPK pathways. To test the potential reversion of PTU-Induced lesions, we injected hypothyroid rats with triiodothyronine (T3), the active form of thyroid hormone. Our results show that intraperitoneal injections of T3 restored spatial short-Term, but not long-Term memory in hypothyroid-Treated rat. Furthermore, levels of pro-Inflammatory cytokines, amyloid peptide and of proteins involved in calcium and ERK-MAPK signalling were restored. These data strengthen the link between hypothyroidism and AD, supporting the idea that hypothyroidism may represent an important factor impacting the risk for developing sporadic forms of AD. Maladie d’Alzheimer Hypothyroïdie Neuroinflammation Tau Peptide amyloïde Mémoire Rat Alzheimer’s disease Hypothyroidism Neuroinflammation Tau Amyloid peptide Memory Rats
14	Molecular studies of the γ-secretase complex activity and selectivity towards the two substrates APP and Notch Bakir, Ilyas January 2010 (has links) <p>Alzheimer Disease (AD) is the most common neurodegenerative disorder in the world. One of the neuropathological hallmarks of AD is the senile plaques in the brain. The plaques are mainly composed of the amyloid β (Aβ) peptide. Aβ is generated from the amyloid precursor protein, APP, when it is first cleaved by the β-secretase and subsequently the γ-secretase complex. The γ-secretase complex cleaves at different sites, called γ and ε, where the γ-cleavage site generates Aβ peptides of different lengths and ε-cleavage generates the APP intracellular domain (AICD). The two major forms of Aβ is 40 and 42 amino acids long peptides, where the latter is more prone to aggregate and is the main component in senile plaques. The γ-secretase complex is composed of four proteins; Pen-2, Aph-1, nicastrin and presenilin (PS). The PS protein harbours the catalytic site of the complex, where two aspartate residues in position 257 and 385 (Presenilin 1 numbering) are situated. Most Familial AD (FAD) mutations in the PS gene cause a change in the γ-cleavage site, leading to a shift from producing Aβ40 to the longer more toxic variant Aβ42. Frequently, this often leads to impairments of the AICD production. Another substrate for the γ-secretase complex is Notch. It is important to maintain the Notch signaling since an intracellular domain (NICD) is formed after cleavage by the γ-secretase complex in the membrane (S3-site) and this domain is involved in transcription of genes important for cell fate decisions.</p><p>It has been reported that certain APP luminal juxtamembrane mutations could drastically alter Aβ secretion, however their effect on AICD production remains unknown. In this study we want to analyse wether the juxtamembrane region is important for the AICD production. To gain more insight into the luminal juxtamembrane function for γ-secretase-dependent proteolysis, we have made a juxtamembrane chimeric construct. A four-residue sequence preceding the transmembrane domain (TMD) of APP (GSNK), was replaced by its topological counterpart from the human Notch1 receptor (PPAQ). The resulting chimeric vector C99GVP-PPAQ and the wildtype counterpart were expressed in cells lacking PS1 and PS2 (BD8) together with PS1wt. We observed that the chimeric construct did not alter production of AICD when using a cell based luciferase reporter gene assay monitoring AICD production. We also introduced a PS1 variant lacking a big portion of the large hydrophilic loop, PS1∆exon10, since our group has previously observed that this region affect Aβ production<sup>143</sup>. We found that the absence of the large hydrophilic loop in PS1 gave a 2-fold decrease in AICD-GVP formation from C99GVPwt compared to PS1wt. The activity of PS1wt and PS1Δexon10 using C99GVP-PPAQ as a substrate gave similar result as the C99GVPwt substrate, i.e. a 2-fold decrease in AICD-GVP formation when comparing PS1Δexon10 with PS1wt. From this data we therefore suggest that the four residues in the juxtramembrane domain (JMD) (GSNK) is not altering ε-cleavage of APP when changed to Notch1 counterpart, PPAQ. Furthermore, we also show that the 2-fold decrease in AICD-production by the PS1Δexon10 molecule is not changed between the two substrates C99GVPwt and C99GVP-PPAQ. This indicates that the luminal region of APP is not directly involved in the ε-site processing. If the luminal region is affecting processing in the γ-cleavage sites, remains however to be investigated.</p> Alzheimer’s disease APP γ-secretase gamma-secretase β-amyloid peptide APP intracellular domain Notch Ilyas Bakir Biochemistry Biokemi
15	Molecular studies of the γ-secretase complex activity and selectivity towards the two substrates APP and Notch Bakir, Ilyas January 2010 (has links) Alzheimer Disease (AD) is the most common neurodegenerative disorder in the world. One of the neuropathological hallmarks of AD is the senile plaques in the brain. The plaques are mainly composed of the amyloid β (Aβ) peptide. Aβ is generated from the amyloid precursor protein, APP, when it is first cleaved by the β-secretase and subsequently the γ-secretase complex. The γ-secretase complex cleaves at different sites, called γ and ε, where the γ-cleavage site generates Aβ peptides of different lengths and ε-cleavage generates the APP intracellular domain (AICD). The two major forms of Aβ is 40 and 42 amino acids long peptides, where the latter is more prone to aggregate and is the main component in senile plaques. The γ-secretase complex is composed of four proteins; Pen-2, Aph-1, nicastrin and presenilin (PS). The PS protein harbours the catalytic site of the complex, where two aspartate residues in position 257 and 385 (Presenilin 1 numbering) are situated. Most Familial AD (FAD) mutations in the PS gene cause a change in the γ-cleavage site, leading to a shift from producing Aβ40 to the longer more toxic variant Aβ42. Frequently, this often leads to impairments of the AICD production. Another substrate for the γ-secretase complex is Notch. It is important to maintain the Notch signaling since an intracellular domain (NICD) is formed after cleavage by the γ-secretase complex in the membrane (S3-site) and this domain is involved in transcription of genes important for cell fate decisions. It has been reported that certain APP luminal juxtamembrane mutations could drastically alter Aβ secretion, however their effect on AICD production remains unknown. In this study we want to analyse wether the juxtamembrane region is important for the AICD production. To gain more insight into the luminal juxtamembrane function for γ-secretase-dependent proteolysis, we have made a juxtamembrane chimeric construct. A four-residue sequence preceding the transmembrane domain (TMD) of APP (GSNK), was replaced by its topological counterpart from the human Notch1 receptor (PPAQ). The resulting chimeric vector C99GVP-PPAQ and the wildtype counterpart were expressed in cells lacking PS1 and PS2 (BD8) together with PS1wt. We observed that the chimeric construct did not alter production of AICD when using a cell based luciferase reporter gene assay monitoring AICD production. We also introduced a PS1 variant lacking a big portion of the large hydrophilic loop, PS1∆exon10, since our group has previously observed that this region affect Aβ production143. We found that the absence of the large hydrophilic loop in PS1 gave a 2-fold decrease in AICD-GVP formation from C99GVPwt compared to PS1wt. The activity of PS1wt and PS1Δexon10 using C99GVP-PPAQ as a substrate gave similar result as the C99GVPwt substrate, i.e. a 2-fold decrease in AICD-GVP formation when comparing PS1Δexon10 with PS1wt. From this data we therefore suggest that the four residues in the juxtramembrane domain (JMD) (GSNK) is not altering ε-cleavage of APP when changed to Notch1 counterpart, PPAQ. Furthermore, we also show that the 2-fold decrease in AICD-production by the PS1Δexon10 molecule is not changed between the two substrates C99GVPwt and C99GVP-PPAQ. This indicates that the luminal region of APP is not directly involved in the ε-site processing. If the luminal region is affecting processing in the γ-cleavage sites, remains however to be investigated. Alzheimer’s disease APP γ-secretase gamma-secretase β-amyloid peptide APP intracellular domain Notch Ilyas Bakir Biochemistry Biokemi
16	La Drosophile comme modèle pour l'étude de la maladie d'Alzheimer : rôle de la protéine précurseur Amyloïde dans la mémoire olfactive / Drosophila Melanogaster as a model for Alzheimer disease's study : Role of the Amyloid Precursor Protein in olfactory memory Bourdet, Isabelle 26 September 2014 (has links) La maladie d’Alzheimer (MA) est un trouble neurodégénératif qui se manifeste, entre autres, par une détérioration progressive de la mémoire. Le peptide amyloïde (Aβ), composant principal des plaques séniles retrouvées dans le cerveau des patients, a longtemps été considéré comme le principal responsable de ce dysfonctionnement mnésique. Néanmoins, les mécanismes moléculaires à l’origine du déclin de la mémoire restent à ce jour inconnus. Le peptide Aβ est produit par la protéolyse d’une protéine transmembranaire appelée Protéine Précurseur Amyloïde (APP). Il a été proposé qu’en plus de l’effet néfaste de l'accumulation d’Aβ, une perte de fonction d’APP puisse jouer un rôle dans le dysfonctionnement cognitif associé à la MA, en particulier au début de la maladie. La drosophile possède un orthologue d’APP, APP-like (APPL), soumis à deux voies de maturation similaires à celles d’APP. Le laboratoire a mis en évidence l’implication d’APPL chez la mouche adulte dans la mémoire olfactive associative (Goguel et al., 2011). Au cours de ma thèse, nous avons poursuivi deux objectifs : 1) identifier le ou les métabolites d’APPL impliqués dans la mise en place de la mémoire, et 2) analyser l’incidence de la surexpression de la voie amyloïdogénique chez le jeune adulte. Nous avons mis à jour deux types d’interaction fonctionnelle entre APPL et ses métabolites : une interaction positive entre les formes sécrétées et membranaires, qui pourrait sous-tendre la mise en place de la mémoire dans des conditions physiologiques, et une interaction négative entre APPL et dAβ, qui pourrait au contraire participer à l’aggravation des déficits mnésiques observés au cours de l’évolution de la MA. / Alzheimer's disease (AD) is a neurodegenerative disorder characterized by a progressive deterioration of memory. The amyloid peptide (Aβ), the principal component of senile plaques found in patients’ brains, has been considered as the main cause of memory dysfunction. However, the exact molecular mechanisms that underlie memory decline remain unknown. Aβ is produced by the proteolysis of a transmembrane protein named Amyloid Precursor Protein (APP). It has been suggested that in addition to the accumulation of Aβ, APP loss of function may play a crucial role in the cognitive dysfunction associated with AD, especially at the onset of the disease. Drosophila contains a single APP ortholog APP-like (APPL), that undergoes processing pathways similar to that of APP. We have previously highlighted in young flies the involvement of APPL in associative olfactory memory (Goguel et al., 2011). During my thesis, we sought firstly to identify which form of APPL, among its numerous metabolites, is critical for memory, and secondly, to analyze the effect of promoting the amyloidogenic pathway in the young adult brain. Our results suggest several types of functional interactions between APPL and its metabolites: a positive interaction between the full length membrane and the secreted form - which would underlie implementation of memory under physiological conditions - and a negative interaction between APPL and dAβ - which would rather participate to the progression of the memory decline observed during AD. Maladie d'Alzheimer Drosophile Protéine Précurseur Amyloïde Mémoire associative olfactive Alpha-sécrétase Beta-sécrétase Alzheimer's disease Amyloid peptide 616.83
17	Rôle potentiel du virus herpes simplex de type I dans la maladie d'Alzheimer / Potential role of herpes simplex virus type 1 in Alzheimer’s disease Albaret, Marie Alexandra 16 July 2009 (has links) L'étiologie de la forme sporadique de la maladie d'Alzheimer (AD) reste largement inconnue. Toutefois, une adéquation entre des facteurs environnementaux et génétiques est fortement probable. C'est ainsi que de nombreux arguments suggèrent que le virus herpes simplex de type 1 (HSV1) en infectant et en se répliquant dans le système nerveux central, puisse être un co-facteur impliqué dans le déclenchement et le développement de l'AD. Pour éprouver cette hypothèse, nous avons développé un modèle cellulaire constitué de neurones de rat infectés par HSV1 pour analyser les modifications viro-induites de leur expression génique. Il a été mis en évidence dans les neurones infectés : i) une augmentation de la production du peptide amyloïde Aβ42 et de Tau phosphorylée, ainsi que leur agrégation dans un agrésome intracellulaire ; ii) des variations du niveau de transcription de nombreux gènes très similaires à celles observées chez des patients AD. Par ailleurs, l'étude des mécanismes moléculaires de l'apoptose viro-induite dans ce modèle original a permis de mettre en évidence une corrélation entre l'activation des caspases et la production d'Aβ42 et une corrélation entre le phénomène d'apoptose avortée (abortosis) et la formation d'agrésome. De l'ensemble des ces résultats, il apparait que ce modèle cellulaire est représentatif de certains aspects des stades précoces de l'AD et conforte l'hypothèse qu'HSV1 serait un co-facteur dans la maladie d'Alzheimer / The origin of the sporadic form of the Alzheimer's disease (AD) remains still widely unknown. However, an adequacy between environmental and genetic factors is highly probable. Numerous arguments suggest that the virus herpes simplex of type 1 (HSV1) by infecting and replicating in the central nervous system, could be a co-factor involved in the AD process. To evaluate this hypothesis, we set up a model made of rat neurons infected by HSV1 in order to analyse the virally-induced modifications of their gene expression. Using this model we have shown: i) an over-production of the amyloid peptide Aß42 and of phosphorylated form of Tau accompanied by their concentration within an intracellular aggresome; ii) variations of the transcription levels of numerous genes equivalent to that observed in AD patients. Furthermore, the study of the molecular mechanisms underlying the virally-induced apoptosis allowed to point out a correlation between caspase activation and Aß42 production as well as a correlation between abortosis and aggresome formation. All together these results demonstrate that this cellular model represents, at least in part, some aspects of the early stages of AD and bring evidences that HSV1 could be a co-factor in the AD process Alzheimer HSV1 Peptide amyloïde Tau phosphorylée Apoptose Abortosis Agrésome Alzheimer HSV1 Amyloid peptide Phosphorylated form of Tau Apoptosis Abortosis Aggresome 616.8
18	O papel do aminoácido leucina na modulação da atividade do peptídeo beta amiloide em células SH-SY5Y / The role of leucine in the modulation of beta amyloid peptide activity in SH-SY5Y cells Fabio Medici Lorenzeti 04 December 2014 (has links) Estudos demonstram que a indução do estresse oxidativo pelo peptídeo beta amiloide (A?) exerce um importante papel no desencadeamento da excitotoxicidade neuronal o que pode resultar no desenvolvimento de doenças neurodegenerativas. A formação do peptídeo A? se deve a alterações na proteína precursora de amiloide (APP) que é clivada para a formação do peptídeo A?. Por sua vez, os mecanismos de ação do A? no S.N.C. ocorrem através da sinalização do receptor NMDA (N-metil D-aspartato) receptor este que quando ativado pelo glutamato exerce importante papel fisiológico no S.N.C., visto que apresenta atividade ionotrópica que permite o influxo de Na+ e Ca2+ para as células neuronais, auxiliando nos processos de formação da memória e aprendizagem. Entretanto, apesar do seu papel fisiológico, a ativação excessiva do receptor NMDA é fortemente correlacionada com lesões no S.N.C. decorrente da excessiva permeabilidade do íon Ca2+ para o citosol das células neuronais. Com isso as concentrações de glutamato na fenda sináptica são estritamente controladas para que não haja ativação excessiva dos receptores com atividade glutamatérgica, como o receptor NMDA. Estudos indicam que o transporte de glutamina/glutamato através da barreira hematoencefálica é menor do que de outros aminoácidos, sendo que cerca de 25% a 30% do transporte de aminoácidos dos vasos sanguíneos para o cérebro através da barreira hematoencefálica é ocupado pelo aminoácido leucina, sendo este um grande responsável pela síntese de glutamato/glutamina no S.N.C. Com isso, estudos tem demonstrado que dietas enriquecidas com aminoácidos de cadeia ramificada, dentre eles a leucina, é responsável por alterar o metabolismo do glutamato e aumentar a susceptibilidade à excitotoxicidade de células neurais. A fim de testar esta hipótese utilizamos um modelo de cultura de células de neuroblastoma humano e realizamos o tratamento com diferentes concentrações de aminoácido leucina associado com o tratamento de peptídeo beta-amilóide. Realizamos as analises de citotoxicidade (LDH), viabilidade celular (MTT) e apoptose celular por citometria de fluxo (marcação com PE Anexina V e 7-AAD). Nossos resultados indicam que houve diferenças apenas entre o controle em relação aos demais grupos de tratamento / Studies demonstrate that induction of oxidative stress by beta amyloid peptide (A?) plays an important role in triggering neuronal excitotoxicity which can result in the development of neurodegenerative diseases. The formation of A? peptide are due to changes in the amyloid precursor protein (APP) which is cleaved to form the peptide A?. On the other hand, the mechanisms of action of A? in the C.N.S. occur through signaling of the NMDA (N-methyl-D-aspartate) receptor that when activated by glutamate plays an important physiological role in the C.N.S., as has inotropic activity that allows the influx of Na+ and Ca2+ into the neuronal cells, assisting in procedures of memory formation and learning. However, despite its physiological role, the excessive activation of the NMDA receptor is strongly correlated with C.N.S. lesions due to excess permeability of Ca2+ ions into the cytosol of neuronal cells. Thus the concentrations of glutamate in the synaptic cleft are strictly controlled so that there is excessive activation of receptors with glutamatergic activity, as the NMDA receptor. Studies indicate that the transport of glutamine/glutamate across the blood brain barrier is lower than that of other amino acids, of which about 25% to 30% of the amino acid transport blood vessels to the brain through the blood brain barrier is occupied by leucine this being one largely responsible for the synthesis of glutamate/glutamine in the C.N.S. Thus, studies have shown that diets enriched in branched chain amino acids, including leucine, are responsible for altering the metabolism of glutamate and excitotoxic increase susceptibility to neural cells. To test this hypothesis we used a cell culture model of human neuroblastoma and carry out the treatment with different concentrations of leucine associated with the processing of amyloid-beta peptide. We performed analysis of cytotoxicity (LDH), cell viability (MTT assay) and apoptosis using flow cytometry (Annexin V staining with PE and 7-AAD). Our results indicate that there were differences only between the control compared to the other treatment groups Aminoácido leucina Apoptose celular Células SH-SY5Y Peptídeo beta-amilóide Beta-amyloid peptide Cellular apoptosis Leucine SH-SY5Y cells
19	SUMO-1 conjugation blocks beta-amyloid-induced astrocyte reactivity. Hoppe, J.B., Rattray, Marcus, Tu, H., Salbego, C.G., Cimarosti, H. 06 1900 (has links) No / Astrocyte reactivity is implicated in the neuronal loss underlying Alzheimer's disease. Curcumin has been shown to reduce astrocyte reactivity, though the exact pathways underlying these effects are incompletely understood. Here we investigated the role of the small ubiquitin-like modifier (SUMO) conjugation in mediating this effect of curcumin. In beta-amyloid (Aβ)-treated astrocytes, morphological changes and increased glial fibrillary acidic protein (GFAP) confirmed reactivity, which was accompanied by c-jun N-terminal kinase activation. Moreover, the levels of SUMO-1 conjugated proteins, as well as the conjugating enzyme, Ubc9, were decreased, with concomitant treatment with curcumin preventing these effects. Increasing SUMOylation in astrocytes, by over-expression of constitutively active SUMO-1, but not its inactive mutant, abrogated Aβ-induced increase in GFAP, suggesting astrocytes require SUMO-1 conjugation to remain non-reactive. Alzheimer's disease Beta-amyloid peptide c-Jun N-terminal kinase Curcumin Reactivity
20	Polymeric nanoparticles as original theranostic approach for alzheimer‟s disease / Nanoparticules polymériques pour le diagnostic et la thérapie de la maladie d'Alzheimer Brambilla, Davide 11 January 2012 (has links) La preuve de concept d‟une approche theranostique pour la Maladie de Alzheimer basée sur les nanotechnologies a été explorée. Des nouvelles nanoparticules polymeriques fluorescentes on été conçus, et leur internalisation et aptitude à traverser un nouveau modèle in vitro de barrière hémato-encéphalique humaine on été étudiées en détails. Une petite librairie de nanoparticules polymerique a été préparés, et leur capacité de capturer le peptide β-Amyloïde1-42, considéré comme une des principales causes de la dégénérescence neuronale, a été évaluées et quantifiées en utilisant une méthode expressément conçus. / The proof of concept of an original nanotechnology-based theranostic approach for Alzheimer‟s disease has been explored. Novel fluorescently tagged nanoparticles have been designed and employed for internalization and transcytosis studies across a recently developed human in vitro blood-brain barrier model. A small library of polymeric nanoparticles have been designed and their ability to capture the Amyloid β1-42 peptide, considered one of the causes of the Alzheimer‟s disease, has been investigated and quantified using an on purpose designed method. Barrière hémato-encéphalique Peptide β-Amyloïde Poly(alkyl cyanocrylate) nanoparticles Alzheimer‟s disease Blood-brain barrier Β-amyloid peptide

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