Global ETD Search

1	Endocytic trafficking is required for neuron cell death through regulating TGF-beta signaling in <i>Drosophila melanogaster</i> Wang, Zixing 01 August 2011 (has links) Programmed cell death (PCD) is an essential feature during the development of the central nervous system in Drosophila as well as in mammals. During metamorphosis, a group of peptidergic neurons (vCrz) are eliminated from the larval central nervous system (CNS) via PCD within 6-7 h after puparium formation. To better understand this process, we first characterized the development of the vCrz neurons including their lineages and birth windows using the MARCM (Mosaic Analysis with a Repressible Cell Marker) assay. Further genetic and MARCM analyses showed that not only Myoglianin (Myo) and its type I receptor Baboon is required for neuron cell death, but also this death signal is extensively regulated by endocytic trafficking in Drosophila melanogaster. We found that clathrin-mediated membrane receptor internalization and subsequent endocytic events involved in Rab5-dependent early endosome and Rab11-dependent recycling endosome differentially participate in TGF-β [beta] signaling. Two early endosome-enriched proteins, SARA and Hrs, are found to act as a cytosolic retention factor of Smad2, indicating that endocytosis mediates TGF-β [beta] signaling through regulating the dissociation of Smad2 and its cytosolic retention factor. neuronal cell death TGF-beta endocytosis MARCM Genetics and Genomics
2	Le rôle du récepteur NOD-like, Nlrx1 dans la neuroprotection et la mort cellulaire / The role of the NOD-like receptor, Nlrx1 in neuroprotection and cell death Imbeault, Emilie January 2015 (has links) Résumé : La mort cellulaire neuronale est un phénomène qui se produit pendant le développement du cerveau, mais aussi dans les conditions pathologiques. Selon l’environnement où la cellule se retrouve; l’apoptose ou la nécrose peuvent contribuer à cette mort neuronale. La nécrose produit un environnement qui promeut l’inflammation ainsi que la cytotoxicité. L’apoptose est un processus hautement organisé qui permet l’homéostasie tissulaire. Un récepteur NOD récemment découvert, Nlrx1, jouerait un rôle dans la régulation de l’inflammation et de la mort cellulaire pendant les infections. Par conséquent, notre hypothèse suppose que Nlrx1 joue un rôle neuroprotecteur en contrôlant la mort neuronale. Afin de déterminer le mécanisme protecteur de Nlrx1 in vitro, un Knock-Down, un Knock-In et un témoin Scrambled de Nlrx1 dans les cellules N2a ont été générés. Des essais LDH de mort cellulaire avec la staurosporine ou le stress oxydatif comme la roténone, le MPP+ ou le H[indice inférieur 2]O[indice inférieur 2] ont été exécutés. Suite au traitement de 24 heures à la staurosporine, les cellules N2a Knock-In subissent plus de mort cellulaire que les cellules N2a Knock-Down et les cellules Scrambled. Quand ces cellules sont traitées à la roténone ou au H[indice inférieur 2]O[indice inférieur 2], les cellules Knock-In subissent moins de mort cellulaire que les cellules Scrambled. Les cellules N2a Knock-Down ont plus de mort cellulaire que les cellules Scrambled quand elles sont traitées à la roténone ou au MPP+. Les analyses par immunobuvardage de type Western des protéines HSP90 et HMGB1 ainsi que par cytométrie en flux ont montré que les cellules Knock-In ont moins de cellules nécrotiques lorsque traitées à la roténone comparé aux cellules contrôles Scrambled. Le ratio des cellules nécrotiques/cellules apoptotiques était aussi plus élevé dans les cellules Knock-Down comparé aux cellules Scrambled. Par microscopie électronique, il a été possible d’observer que les cellules N2a Knock-In contiennent plus de mitochondries que les cellules Knock-Down et Scrambled en conditions témoins. Ces résultats ont aussi été confirmés par marquage au mitotracker en cytométrie de flux L’immunobuvardage de type Western a montré que dans les cellules Knock-In, il y avait une augmentation de la protéine phosphorylée-DRP1 active, une protéine impliquée dans la fission mitochondriale. Ces résultats pourraient expliquer le nombre augmenté de mitochondries observé dans les cellules Knock-In. Des expériences d’immunoprécipitation ont montré une association entre Nlrx1 et DRP1, ainsi qu’avec la forme active phosphorylée de DRP1. En ajoutant le Mdivi, un inhibiteur de la fission mitochondriale, aux traitements de roténone ou H[indice inférieur 2]O[indice inférieur 2], la mort cellulaire était augmentée dans les cellules Knock-In comparé aux cellules Scrambled. Également, la nécrose était augmentée dans les cellules Knock-In à des niveaux semblables à ceux retrouvés chez les cellules Scrambled et Knock-Down. Ces résultats suggèrent que Nlrx1 serait impliquée dans la régulation de l’équilibre entre la nécrose et l’apoptose, en favorisant la survie cellulaire. Nlrx1 pourrait alors servir de molécule neuroprotectrice dans les maladies médiées par le stress oxydatif. / Abstract : Neuronal cell death is a phenomenon that occurs during brain development as well as in pathological diseases. Depending on the environment in which the cells are; a poptosis or necrosis can contribute to neuronal cell death. Necrosis produces an environment that promotes inflammation and cytotoxicity and apoptosis is a highly organized process that maintains tissue homeostasis. A recently discovered NOD receptor, Nlrx1, is thought to play a role in regulation of inflammation and cell death during infection. Therefore, we hypothesize that Nlrx1 plays a neuroprotective role by controlling cell death in neurons. To determine the protective mechanism of Nlrx1 in vitro, a Knock-Down, a Knock-In and a Scrambled control of Nlrx1 in N2a cells was generated. LDH assays for cell death detection with staurosporine or oxidative stress, such as rotenone, MPP+ or H[subscript 2]O[subscript 2], have been done. After 24h treatment of staurosporine, N2a Knock-In cells showed higher cell death than N2a Knock-Down and Scrambled. When cells were treated with rotenone or H[subscript 2]O[subscript 2], N2a Knock-In cells had less cell death than Scrambled cells. N2a Knock-Down cells resulted in more cell death than Scrambled cells when treated with rotenone or MPP+.Western Blotting of HSP90 and HMGB1 as well as flow cytometry of cell death demonstrated N2a Knock-In cells to have less necrotic cells when treated with rotenone compared to Scrambled. The ratio of necrotic cells on apoptotic cells was also higher in N2a Knock-Down cells compared to Scrambled cells. Electron microscopy of control cells showed that Knock-In cells contains more mitochondria than Knock-Down and Scrambled cells. These results were confirmed by mitotracker staining by flow cytometry. Western blotting showed that there was an increased in Knock-In cells of active phosphorylated-DRP1 protein, a protein implicated in mitochondrial fission. Thus, it could explain the increased number of mitochondria seen in Knock-In cells. Immunoprecipitation showed that Nlrx1 protein interacts with DRP1 as well as active phosphorylated-DRP1. Adding Mdivi, a mitochondrial fission inhibitor, to rotenone or H[subscript 2]O[subscript 2] treatments, cell death was increased in Knock-In cells compared to Scrambled. Also, necrosis was also augmented in Knock-In cells to levels comparable to Scramble and Knoc k-Down cells. These results suggest an implication for Nlrx1 in regulating the balance of necrosis to apoptosis, permitting cells to survive. Nlrx1 could serve as a neuroprotective molecule in diseases mediated by oxidative stress. Nlrx1 N2a Neuroprotection Mort cellulaire Apoptose Nécrose Mort neuronale Neuronal cell death Apoptosis Necrosis
3	Anti-Apoptotic Proteins in Nerve Cell Survival and Neurodegeneration Korhonen, Laura January 2002 (has links) <p>Apoptosis is a genetically regulated cell death program, which shows distinct morphological characteristics. It takes place during neuronal development and in some neurodegenerative diseases. During apoptosis, the intracellular proteins are degraded by various caspases, cysteine aspartases, which are regulated by pro- and anti-apoptotic signals. This thesis elucidates the role of anti-apoptotic proteins in nerve cell survival and neurodegeneration. Studies have focused on Bcl-2 family members and Inhibitor of Apoptosis Proteins (IAP).</p><p>XIAP and RIAP-2 are IAP proteins, which are expressed by neurons in the central nervous system. Kainic acid, a glutamate receptor agonist that induces seizures, increased XIAP immunoreactivity in rat hippocampus, whereas RIAP-2 expression in the same time decreased in degenerating neurons. Both XIAP and RIAP-2 were absent in dying neurons indicating that these proteins have a protective role in kainic acid induced neurodegeneration.</p><p>NAIP, another IAP family member, was shown to interact with the calcium binding protein Hippocalcin using the yeast two-hybrid system and immunoprecipitation experiments. Hippocalcin-NAIP interaction increased motoneuron survival in caspase-3 independent and dependent manners.</p><p>The anti-apoptotic Bcl-2 proteins, Bcl-2 and Bcl-x, were studied using cultured neurons and human neuronal progenitor cells. In the progenitor cells, Bcl-2 overexpression enhanced cell survival and induced downregulation of Caspase-2 (ICH-1) and caspase-3 (YAMA/CPP32). These results suggest a novel mechanism for the action of Bcl-2.</p><p>Estrogen was shown to inhibit death of cultured dorsal root ganglion neurons (DRG) after nerve growth factor withdrawal. The hormone increased the levels of Bcl-x, which may explain the known neuroprotective function of estrogen.</p> Neurosciences neuronal cell death XIAP RIAP-2 Hippocalcin Bcl-2 Bcl-X kainic acid DRG estrogen Neurovetenskap Neurology Neurologi
4	Anti-Apoptotic Proteins in Nerve Cell Survival and Neurodegeneration Korhonen, Laura January 2002 (has links) Apoptosis is a genetically regulated cell death program, which shows distinct morphological characteristics. It takes place during neuronal development and in some neurodegenerative diseases. During apoptosis, the intracellular proteins are degraded by various caspases, cysteine aspartases, which are regulated by pro- and anti-apoptotic signals. This thesis elucidates the role of anti-apoptotic proteins in nerve cell survival and neurodegeneration. Studies have focused on Bcl-2 family members and Inhibitor of Apoptosis Proteins (IAP). XIAP and RIAP-2 are IAP proteins, which are expressed by neurons in the central nervous system. Kainic acid, a glutamate receptor agonist that induces seizures, increased XIAP immunoreactivity in rat hippocampus, whereas RIAP-2 expression in the same time decreased in degenerating neurons. Both XIAP and RIAP-2 were absent in dying neurons indicating that these proteins have a protective role in kainic acid induced neurodegeneration. NAIP, another IAP family member, was shown to interact with the calcium binding protein Hippocalcin using the yeast two-hybrid system and immunoprecipitation experiments. Hippocalcin-NAIP interaction increased motoneuron survival in caspase-3 independent and dependent manners. The anti-apoptotic Bcl-2 proteins, Bcl-2 and Bcl-x, were studied using cultured neurons and human neuronal progenitor cells. In the progenitor cells, Bcl-2 overexpression enhanced cell survival and induced downregulation of Caspase-2 (ICH-1) and caspase-3 (YAMA/CPP32). These results suggest a novel mechanism for the action of Bcl-2. Estrogen was shown to inhibit death of cultured dorsal root ganglion neurons (DRG) after nerve growth factor withdrawal. The hormone increased the levels of Bcl-x, which may explain the known neuroprotective function of estrogen. Neurosciences neuronal cell death XIAP RIAP-2 Hippocalcin Bcl-2 Bcl-X kainic acid DRG estrogen Neurovetenskap Neurology Neurologi
5	Mitochondriální dysfunkce a neurodegenerativní onemocnění / Mitochondrial dysfunction and neurodegenerative diseases Novotná, Veronika January 2018 (has links) Charles University in Prague Faculty of Pharmacy in Hradec Králové Department of Biological and Medical Sciences Author: Bc. Veronika Novotná Supervisor: doc. MUDr. Josef Herink, DrSc. Title of diploma thesis: Mitochondrial dysfunction and neurodegenerative diseases The diploma thesis deals with mitochondrial dysfunction and neurodegenerative diseases and it is divided into two main parts. The first part summarized the classification of neurodegenerative diseases and general charakteristic of mitochondria.Then a describe of the processes of oxidative stress, excitotoxicity, apoptosis and briefly decribe the nervous system. The second part deals with description of mitochondrial dysfunction in selected nerodegenerative diseases. The recent studies refer to connection between mitochondrial dysfunctions and formation of neurodegenerative diseases. Keywords: excitotoxicity, mitochondrial dysfunction, neurodegenerative disorders, neuronal cell death, oxidative damage
6	Roles of bHLH Transcription Factors Neurod1, Neurod2 and Neurod6 in Cerebral Cortex Development and Commissure Formation. Bormuth, Ingo 07 April 2016 (has links) Basische Helix-Loop-Helix (bHLH)-Proteine bilden eine diverse Gruppe evolutionär gut konservierter Transkriptionsfaktoren. Viele transaktivierende bHLH-Proteine werden zelltyp- oder gewebespezifisch exprimiert und fungieren als wichtige Schlüsselregulatoren zellulärer Determinations- und Differenzierungsprozesse. Die eng verwandten neuronalen bHLH-Gene Neurod1, Neurod2 und Neurod6 werden in differenzierenden Pyramidenneuronen des sich entwickelnden zerebralen Kortex exprimiert und stehen schon lange im Verdacht, deren Reifung zu steuern. In der Vergangenheit wurde jedes der drei Gene in Mäusen inaktiviert. Untersuchungen an den einfach-defizienten Tieren konnten jedoch keine wichtigen Funktionen in embryonalen Pyramidenneuronen identifizieren. Da die Aminosäuresequenzen und die Expressionsmuster der Faktoren sehr ähnlich sind, wurde angenommen, dass sie sich redundante Funktionalität teilen. Um dies zu überprüfen, habe ich Neurod2/6-doppel-defiziente Tiere gezüchtet und unter besonderer Berücksichtigung der Differenzierung von Pyramidenneuronen und der Konnektivität des zerebralen Kortex analysiert: Die Experimente zeigen, dass Neurod2 und Neurod6 tatsächlich mehrere bisher unbekannte gemeinsame Funktionen haben, wobei jeder Faktor für den Verlust des jeweils anderen kompensieren kann. Zumindest eines der beiden Gene ist notwendig für (1) die Kontrolle der radialen Migration eines Teils der Pyramidenneurone, (2) die frühe Regionalisierung des zerebralen Kortex und (3) die Bildung kortikaler Projektionen vom Neokortex zum Striatum, zum Thalamus und zur kontralateralen Hemisphäre. Callosale Axone bilden in Neurod2/6-doppel-defizienten Mäusen Faserbündel die tangential in den medialen Kortex einwachsen, aber noch vor Erreichen des ipsilateralen Cingulums und vor dem Kontakt mit der Mittellinie stoppen und defaszikulieren. Es resultiert eine neue Variante der callosalen Agenesie, die nahelegt, dass es bisher nicht identifizierte Wachstumssignale im medialen Kortex gibt. Die Expression von Neurod1, welche sich normalerweise auf die Subventrikularzone beschränkt, persistiert in radial migrierenden Pyramidenneuronen der Intermediärzone und der Kortikalplatte von Neurod2/6-doppel-defizienten Mäusen. Diese ektopische Neurod1-Expression kann dort den Verlust von Neurod2 und Neurod6 kompensieren. In einem weiteren Schritt habe ich konditionale Neurod1/2/6-tripel-defiziente Mäuse gezüchtet. In diesen Tieren wird das Neurod1-Gen durch selektive genetische Rekombination in all jenen Zellen, die über Neurod6-Promoteraktivität verfügen, irreversibel entfernt: Wie erwartet, teilt sich Neurod1 weitere gemeinsame Funktionen mit Neurod2 und Neurod6. Zumindest eines der drei Gene ist notwendig für die Differenzierung hippokampaler Pyramidenzellen und die Hemmung des programmierten Zelltods der unreifen Neuronen des Cornu Ammonis. Während die gemeinsame Inaktivierung von Neurod1/2/6 zur Aplasie des Hippocampus führt, überlebt ein Großteil der neokortikalen Pyramidenzellen. Die terminale neuronale Differenzierung ist jedoch auch im Neokortex gestört und die neokortikale Konnektivität sehr stark reduziert. Diese Arbeit zeigt, dass die Transkriptionsfaktoren der NeuroD-Familie gemeinsam die Differenzierung, das Überleben, die Migration und das axonale Wachstum von pyramidalen Neuronen des sich entwickelnden zerebralen Kortex steuern. Während der Embryonalentwicklung ergeben sich folgende, teils überschneidende Funktionen der NeuroD-Gene: Die Differenzierung und das Überleben von hippocampalen Körnerzellen ist abhängig von Neurod1. Die frühen Schritte der Differenzierung von hippocampalen Pyramidenneuronen und deren Überleben sind eine Funktion von wahlweise Neurod1, Neurod2 oder Neurod6. Spätere neuronale Differenzierungsschritte, die Regionalisierung des Neokortex und das gezielte Wachstum wichtiger neokortikaler Faserzüge basieren auf Funktionen von Neurod2 oder Neurod6, aber nicht von Neurod1. Der postnatale Umbau des somatosensorischen Kortex und die funktionale Integration thalamischer Afferenzen wurden bereits als strikt Neurod2-abhängig beschrieben. 610 Neuroanatomy Brain development Cortex development Corpus callosum Pyramidal neuron bHLH transcription factor Neuronal differentiation Neuronal cell death Medizin (PPN619874732)
7	Glutamate Excitotoxicty Activates a Novel Calcium Permeable Ion Channel in Cultured Hippocampal Neurons Deshpande, Laxmikant Sudhir 01 January 2006 (has links) Glutamate excitotoxicity is the predominant mechanism implicated in neuronal cell death associated with neurological disorders such as stroke, epilepsy, traumatic brain injury and ALS. Excessive stimulation of NMDA subtypes of glutamate receptors leads to protracted intracellular calcium elevations triggering calcium mediated neurotoxic mechanisms culminating in delayed neuronal cell death. In addition, glutamate excitotoxicity induces a NMDA dependent extended neuronal depolarization mediated by continuous calcium influx that correlates with delayed neuronal death. Attempts to prevent neuronal death by blocking calcium entry into the neurons using calcium channel blockers or NMDA receptor antagonists have failed to provide any beneficial effects in clinical trials. Thus, calcium continues to enter the neurons despite the presence of calcium entry blockers. This phenomenon is known as the "calcium paradox of stroke" and represents a major problem in developing effective therapies for treatment of stroke. Here employing a combination of patch clamp recordings, fluorescent calcium imaging and neuronal cell death assays in well-characterized in vivo and in vitro models of glutamate excitotoxicity, we report the discovery of a novel calcium permeable ion channel that is activated by excitotoxic glutamate injury and mediates a calcium current that is an early initiating step in causing neuronal death. Blocking this calcium permeable channel with high concentrations of Zn2+ or Gd3+ by removing extracellular calcium for a significant time period after the initial injury is effective in preventing calcium entry, apoptosis and neuronal death, thus accounting for the calcium paradox. This injury induced-calcium permeable channel provides a unique mechanism for calcium entry following stroke and offers a new target for extending the therapeutic window for preventing neuronal death after the initial excitotoxic (stroke) injury. neurological disorders excitotoxic neuronal cell death NMDA subtypes calcium channel blockers NMDA receptor antagonists calcium paradox of stroke Medical Pharmacology Medical Sciences Medicine and Health Sciences
8	Hypoxie-induzierter Zelltod und Veränderungen der HIF-1-Aktivität in PC12-Zellen Charlier, Nico Nawid 09 February 2004 (has links) Der Transkriptionsfaktor hypoxia inducible factor-1 (HIF-1) trägt zur Expression von adaptiven Genen unter hypoxischen Bedingungen bei. Zusätzlich wurde vermutet, dass HIF-1 eine Rolle in der Regulation des späten neuronalen Zelltodes spielt. Suspensionszellen und adhärenten PC12-Zellen mit Nervenwachstumsfaktor (NGF) behandelt, wurden als ein experimentelles Modell für die Untersuchung der Beziehung zwischen Hypoxie induziertem Zelltod und Aktivität von HIF-1 herangezogen. Zelltod wurde durchflusszytometrisch mit einer Doppelfärbung (Annexin V und Propidium-Jodid) der Zellen und durch eine Analyse der allgemeinen Zelltodparameter wie LDH und die mitochondriale Dehydrogenase bestimmt. Parallel wurden Zellen mit einem Kontrollvektor und einem hypoxiesensitiven Vektor mit drei Hypoxie-bindenden-Elementen (HBE) transfiziert und die durch HIF-1 aktivierte Luciferase gemessen. Hypoxieexposition der NGF-behandelten PC12-Zellen resultierte in einer höheren Zelltodrate verglichen mit den unbehandelten Kontrollzellen. PC12 Zellen, zwei Tage mit NGF behandelt, zeigten eine bis zu 10-fach verminderte HIF-1-Aktivität. Diese Verminderung könnte zu dem erhöhten hypoxie-induzierten Zelltod durch verminderte Expression von HIF-1alpha-regulierten Genen, welche für die Anpassung an Hypoxie verantwortlich sind, beitragen. Die Verminderung der HIF-1 Aktivität und der Anstieg der Hypoxiesensitivität könnte darauf hinweisen, dass NGF als eine Art hierarchisch organisiertes Signalmolekül fungiert. / The transcription factor hypoxia-inducible factor-1 (HIF-1) strongly contributes to the expression of adaptive genes under hypoxic conditions. In addition, HIF-1 has been implicated in the regulation of delayed neuronal cell death. Suspension-grown and adherent PC12 cells treated with NGF were used as an experimental model for studying the relationship between hypoxia-induced cell death and activation of HIF-1. Cell damage was assessed by flow cytometry of double-stained (annexin V and propidiumiodide) cells, and by analysis of the overall death parameters LDH and mitochondrial dehydrogenase. In parallel, cells were transfected with a control and a three-hypoxia-responsive-elements (HRE)-containing vector and HIF-1-driven luciferase activity was determined. Exposure of NGF-treated PC12 cells to hypoxia resulted in a higher cell death rate when compared to untreated controls. PC12 cells exposed for 2 days to NGF exhibited a decrease of HIF-1 activity up to a factor of ten. This decrease may contribute to the enhanced hypoxia-induced cell death via reduced expression of HIF-1alpha-regulated genes resposible for adaptation to hypoxia, like those for glucose transport proteins and enzymes of the glycolytic chain. The decrease in HIF-1 activity and the increase in hypoxia sensitivity may suggest that NGF act as an hierachically organized signaling molecule. Apoptose Nekrose Hypoxie-induzierbarer Faktor Nervenwachstumsfaktor Perinatale Hypoxie Asphyxie Neuronaler Zelltod apoptosis necrosis hypoxia-inducible factor nerve growth factor perinatal hypoxia asphyxia neuronal cell death 610 Medizin 33 Medizin YQ 6600 WW 4120 YC 2600 ddc:610
9	Regulation of excitotoxicity in thiamine deficiency : role of glutamate transporters. Jhala, Shivraj 08 1900 (has links) L’excitotoxicité est un mécanisme physiopathologique majeur impliqué dans la pathogenèse de la déficience en thiamine (DT). Dans les régions cérébrales vulnérables à la DT, on observe une mort cellulaire induite par excitotoxicité dont l’origine semble être la conséquence d’une perturbation du métabolisme énergétique mitochondrial, d’une dépolarisation membranaire soutenue et d’une diminution de l’absorption du glutamate par les astrocytes suite à la diminution de l’expression des transporteurs EAAT1 et EAAT2. Il est clairement établi que le glutamate joue un rôle central dans l’excitotoxicité lors de la DT. Ainsi, la mise en évidence des mécanismes impliqués dans la diminution de l’expression des transporteurs du glutamate est essentielle à la compréhension de la physiopathologie de la DT. L’objectif de cette thèse consiste en l’étude de la régulation des transporteurs astrocytaires du glutamate et la mise au point de stratégies thérapeutiques ciblant la pathogenèse de l’excitotoxicité lors de l’encéphalopathie consécutive à la DT. Les principaux résultats de cette thèse démontrent des perturbations des transporteurs du glutamate à la fois dans des modèles animaux de DT et dans des astrocytes en culture soumis à une DT. La DT se caractérise par la perte du variant d’épissage GLT-1b codant pour un transporteur du glutamate dans le thalamus et le colliculus inférieur, les régions cérébrales affectées lors d’une DT, en l’absence de modification des niveaux d’ARNm. Ces résultats suggèrent une régulation post-transcriptionnelle de l’expression des transporteurs du glutamate en condition de DT. Les études basées sur l’utilisation d’inhibiteurs spécifiques des facteurs de transcription NFkB et de l’enzyme nucléaire poly(ADP)ribose polymérase-1 (PARP-1) démontrent que la régulation de l’expression du transporteur GLT-1 est sous le contrôle de voies de signalisation NFkB dépendantes de PARP-1. Cette étude démontre une augmentation de l’activation de PARP-1 et de NFkB dans les régions vulnérables chez le rat soumis à une DT et en culture d’astrocytes DT. L’inhibition pharmacologique du facteur de transcription NFkB par le PDTC induit une augmentation des niveaux d’expression de GLT-1, tandis que l’inhibition de PARP-1 par le DPQ conduit à l’inhibition de l’hyperactivation de NFkB observée lors de DT. L’ensemble de ces résultats met en évidence un nouveau mécanisme de régulation des transporteurs du glutamate par l’activation de PARP-1. L’accumulation de lactate est une caractéristique de la DT. Un traitement avec le milieu de culture d’astrocytes en condition de DT sur des cultures d’astrocytes naïfs induit une diminution de l’expression de GLT-1 ainsi qu’une inhibition de la capacité d’absorption du glutamate par les astrocytes naïfs. En revanche, l’administration de lactate exogène ne modifie pas le niveau d’expression protéique de GLT-1. Ainsi, des facteurs solubles autres que le lactate sont sécrétés par des astrocytes en condition de perturbation métabolique et peuvent potentiellement réguler l’activité des transporteurs du glutamate et contribuer à la pathogenèse du syncytium astroglial. En outre, la ceftriaxone, un antibiotique de la famille des β-lactamines, augmente de façon différentielle l’expression du variant-d’épissage GLT-1 dans le colliculus inférieur chez le rat DT et en culture d’astrocytes DT. Ces résultats suggèrent que la ceftriaxone peut constituer une avenue thérapeutique dans la régulation de l’activité des transporteurs du glutamate lors de DT. Pour conclure, la mort cellulaire d’origine excitotoxique lors de DT survient en conséquence d’une dysfonction mitochondriale associée à une perturbation du métabolisme énergétique cérébral. La modification de l’expression des transporteurs du gluatamate est sous le contrôle des voies de signalisation NFkB dépendantes du facteur PARP-1. De plus, l’inhibition métabolique et l’augmentation des sécrétions de lactate observées lors de DT peuvent également constituer un autre mécanisme physiopathologique expliquant la diminution d’expression des transporteurs de glutamate. Enfin, la ceftriaxone pourrait représenter une stratégie thérapeutique potentielle dans le traitement de la régulation de l’expression des transporteurs du glutamate et de la perte neuronale associés à l’excitotoxicité observée lors de DT. / Excitotoxicity has been implicated as a major pathophysiological mechanism in the pathogenesis of thiamine deficiency (TD). Excitotoxic-mediated cell death is localized in areas of focal vulnerability in TD and may occur as a consequence of impairment in mitochondrial energy metabolism, sustained cell membrane depolarization and decreased uptake of glutamate by astrocytes due to the loss of excitatory amino acid transporters, (EAAT1 and EAAT2). Over the years, a number of studies have identified glutamate as being a major contributor to excitotoxicity in the pathophysiology of TD. Thus, downregulation of astrocytic glutamate transporters resulting in excitotoxicity is a key feature of TD and understanding the regulation of these transporters is essential to understanding the pathophysiology of the disorder. The objective of the present thesis project was to examine the underlying basis of astrocytic glutamate transporter regulation during TD encephalopathy. Major findings of the studies presented in this thesis project provide evidence for glutamate transporter abnormalities in TD animal models and astrocyte cultures exposed to TD. TD results in the loss of the glutamate transporter splice variant-1b (GLT-1b) in vulnerable areas of brain, i.e. thalamus and inferior colliculus, with no significant alteration in the mRNA levels of the transporters, suggesting that glutamate transporter regulation under conditions of TD is a posttranscriptional event. Studies using a specific inhibitor of the transcription factor, Nuclear factor-kappa B (NF-κB) and a nuclear enzyme poly (ADP)ribose polymerase-1 (PARP-1) provided evidence for the regulation of GLT-1 by PARP-1 dependent NF-κB signalling pathways. The major findings of this study suggested an increase in the activation of PARP-1 and NF-κB molecule in the vulnerable areas of TD rat brain and TD astrocyte cultures. Pharmacological inhibition of NF-κB showed an increase in the levels of GLT-1, while inhibition of PARP-1 using a specific PARP-1 inhibitor, DPQ inhibited the increased activation of NF-κB that was observed during TD. Overall results of this finding provided evidence for a mechanism involving PARP-1 activation in the regulation of glutamate transporters. Given the increased lactate accumulation as a classical feature of TD, we studied the effect of soluble factors produced by astrocytes on glutamate transporter function. Treatment of naïve astrocyte cultures with TD conditioned media resulted in decreased levels of GLT-1 and inhibition of glutamate uptake capacity concomitant with a loss of mitochondrial membrane potential. Administration of exogenous lactic acid produced a similar reduction in glutamate uptake to that resulting from conditioned media. However, lactic acid treatment did not result in a change in GLT-1 protein levels. In addition, the pro-inflammatory cytokine TNF-α was shown to be increased in astrocytes treated with TD along with elevated levels of the phospho-IκB fragment, indicative of increased activation of NFκB. Inhibition of NFκB led to an amelioration of the decrease in GLT-1 that occurs in TD, along with recovery of glutamate uptake. Thus, soluble factors released from astrocytes under conditions of metabolic impairment such as lactate and TNF-α impairment appear to exert a regulatory influence on glutamate transporter function. Ceftriaxone, a β-lactam antibiotic, has the ability to differentially stimulate GLT-1b (splice-variant) expression in the inferior colliculus in TD rats and under in vitro conditions with TD astrocyte cultures. Thus, ceftriaxone may be a potential therapeutic strategy in the regulation of glutamate transporter function during TD. In summary, excitotoxic cell death in TD occurs as a consequence of mitochondrial dysfunction associated with cerebral energy impairment and abnormal glutamate transporter status. A major underlying mechanism for glutamate transporter abnormalities is mediated by PARP-1 dependent NF-κB signaling pathways. In addition, metabolic inhibition with substantial production of lactate and TNF-α may be perhaps another mechanism responsible for glutamate transporter downregulation in TD. Excitotoxicité Excitotoxicity transporteurs du glutamate glutamate transporters stress oxydatif oxidative stress syndrome de Wernicke-Korsakoff Wernicke-Korsakoff syndrome déficience en thiamine thiamine deficiency mort neuronale neuronal cell death
10	Regulation of excitotoxicity in thiamine deficiency : role of glutamate transporters Jhala, Shivraj 08 1900 (has links) No description available. Excitotoxicité Excitotoxicity transporteurs du glutamate glutamate transporters stress oxydatif oxidative stress syndrome de Wernicke-Korsakoff Wernicke-Korsakoff syndrome déficience en thiamine thiamine deficiency mort neuronale neuronal cell death

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