Global ETD Search

11	Dysfonctions mitochondriales et homéostasie bioénergétique des motoneurones dans un modèle de sclérose latérale amyotrophique / Mitochondrial dysfunctions and bioenergetic homeostasis of motor neurons in a model of amyotrophic lateral sclerosis Allard, Ludivine 16 December 2013 (has links) La sclérose latérale amyotrophique (SLA) est une maladie neurodégénérative fatale de l'âge adulte, caractérisée par une perte de motoneurones, conduisant à une atrophie et une faiblesse musculaires. Des mutations de la superoxyde dismutase-1 (SOD1) provoquent une forme génétique de SLA. Comme chez les patients atteints de SLA, le modèle animal de SLA, SOD1 mutant, révèle que tous les motoneurones sont inégalement sensibles à l'évolution de la maladie. Les mitochondries, centrales énergétiques des cellules, sont des organelles précocement touchées dans la pathologie de la SLA. Un mécanisme attrayant qui sous-tend la susceptibilité différentielle est la nécessité bioénergétique variable de sous-ensembles distincts de motoneurones. Cela implique que dans le système nerveux central, la demande bioénergétique pourrait moduler le seuil pathologique. Même en l'absence de perte bioénergétique, on peut imaginer une situation dans laquelle une contrainte pathologique modifie le niveau à partir duquel la production ou la livraison de l'ATP devient insuffisant, précipitant la chute des neurones les plus vulnérables. Dans les neurones, la majorité de l'ATP est produite par les mitochondries et l'homéostasie des gradients d'ions est le procédé le plus énergivore. La fonction mitochondriale est moindre pour modifier les propriétés électriques des motoneurones si la disponibilité en ATP devient insuffisante pour permettre aux pompes ioniques de maintenir des gradients appropriés. Nous avons démontré que la concentration intracellulaire basale d’ATP dans des cultures de neurones moteurs est diminuée dans les cellules mutées SOD1 par rapport au type sauvage. Paradoxalement à ce résultat, le taux de consommation d'oxygène des mitochondries est augmenté dans les motoneurones SOD1m et il n'existe aucune preuve d'une augmentation de la consommation. Nos résultats appuient l'hypothèse intéressante qu'il y a un découplage entre la chaîne respiratoire et la production d'ATP. Ce découplage peut être utilisé comme une stratégie pour minimiser les propriétés toxiques des mitochondries hyper stimulées. / Amyotrophic lateral sclerosis (ALS) is a fatal adult-onset neurodegenerative disorder characterized by a loss of motor neurons, leading to muscle wasting and weakness. Mutations in superoxide dismutase-1 (SOD1) cause a form of ALS. As in ALS patients, the mutant SOD1 animal model of ALS reveals that not all motor neurons are equally susceptible to the disease process. An attractive mechanism underlying differential susceptibility is the variable bioenergetics need of distinct subsets of motor neurons. This implies that within the CNS, bioenergetics can modulate the pathological threshold. Even in the absence of loss in bioenergetics, one can envision a situation in which a pathological stress alters the level at which either the production or delivery of ATP becomes insufficient, precipitating the demise of the most vulnerable neuron types. In neurons, majority of ATP is produced by mitochondria and the homeostasis of ion gradients is the most energy-consuming process. Reduced mitochondrial function will modify the electrical properties of motor neurons if ATP availability becomes insufficient to allow ion pumps to maintain appropriate gradients. We demonstrated that the basal ATP intra-cellular concentration in motor neuron cultures lower in SOD1 mutated cells compared to wild type. Paradoxically to this result, the oxygen consumption rate of mitochondria is increase in mSOD1 cells and there is no evidence for an increase of consumption. Our results support the interesting hypothesis that there is an uncoupling between the respiratory chain and the ATP production. This uncoupling might be used as a strategy to minor the toxic properties of hyper stimulated mitochondrion. Mitochondrie Motoneurone Bioénergétique Découplage SOD1 SLA Mitochondria Motoneurons Bioenergetic Uncoupling SOD1 ALS
12	Etude de la voie de la SUMOylation dans la sclérose latérale amyotrophique associée à des mutations de SOD1 / Study of pathway of SUMOylation in Amyotrophic Lateral Sclerosis associated with SOD1 gene mutation Dangoumau, Audrey 15 October 2014 (has links) La sclérose Latérale Amyotrophique (SLA) est une maladie neurodégénérative des motoneurones impliquant des facteurs environnementaux et génétiques. Notre étude porte sur l’étude des relations entre la voie de la SUMOylation post-Traductionnelle des protéines et les effets du stress oxydant et de mutants SOD1. Nous montrons tout d’abord que 2 nouveaux mutants, SOD1V31A et SOD1E121G identifiés chez des patients SLA à évolution lente, entraîne la formation d’agrégats cellulaires Ub/SUMO dans la formation des agrégats était suggérée. Nous montrons 1) que les NSC-34 exposées à un stress oxydant et exprimant SOD1 mutée présentent une modification d’expression de plusieurs gènes des voies de l’Ub/SUMO ; 2) que l’expression de SOD1 mutée réduit le pool de protéine SUMO-1 libre dans les cellules motoneuronales, possible conséquence d’une séquestration dans les agrégats ; 3) qu’inhiber la SUMOylation de SOD1 mutée réduit la quantité de cellules avec agrégats. Nos résultats indiquent qu’une meilleure connaissance de la voie de SUMO pourrait conduire à de nouvelles cibles thérapeutiques intéressantes dans la SLA. / Amyotrophic Lateral Sclerosis (ALS) is a neurodegenerative disease of motor neurones involving a combination of environmental and genetics factors. Ours work focuses on the relathionship between the SUMOylation pathway and the effects of oxidative stress and SOD1 mutants. We first show that 2 new mutants, SOD1V31A and SOD1E121G identified in ALS patients with a slowly progressive disease, induce the formation of Ub/SUMO positive aggregates in motor neuronal cells NSC-34. The implication of the Ub/SUMO pathways has been proposed in the formation of aggregates in ALS. We show 1) modification of expression of several genes of the Ub/SUMO pathways in NSC-34 exposed to oxidative stress and expressing various mutated SOD1 proteins; 2) that the expression of mutants SOD1 reduces free-SUMO1 concentration in motor neuronal cell, perhaps by a sequestration in aggregates; 3) that the inhibition of SUMIylation of various mutants SOD1 reduces the amount of cells with aggregates. Our results support further studies on the SUMO pathway that may lead to new therapeutics targets in ALS. SLA Motoneurones SOD1 Agrégats SUMO Ubiquitine ALS Motor neuron SOD1 Aggregates SUMO Ubiquitin
13	Acylation of Superoxide Dismutase 1 (SOD1) at K122 Alters SOD1 Localization and SOD1-Mediated Inhibition of Mitochondrial Respiration Rodriguez, Nathan William 01 July 2017 (has links) Cu/Zn Superoxide Dismutase (SOD1), is a ubiquitous antioxidant enzyme with several emerging roles outside of its canonical function. SOD1 is also emerging in central roles in cancer and neurodegenerative pathologies. Little is known about SOD1 regulation, particularly at a post-translational level. Post-translational modifications (PTMs) play an important role in enabling proteins to rapidly respond to their environment. Therefore, identifying specific PTMs involved in protein regulation represents a powerful opportunity to interfere with any associated pathologies. This work employs proteomics to identify mechanisms of post-translation regulation on cell survival signaling proteins. We focused on SOD1, which protects cells from oxidative stress. We found that acylation of K122 on SOD1, while not impacting SOD1 catalytic activity, suppressed the ability of SOD1 to inhibit mitochondrial metabolism at respiratory complex I. We found that deacylase depletion increased K122 acylation on SOD1, which blocked suppression of respiration in a K122-dependent manner. In addition, we found that acyl-mimicking mutations at K122 decreased SOD1 accumulation in mitochondria, initially hinting that SOD1 may inhibit respiration directly within the intermembrane space (IMS). However, surprisingly, we found that forcing the K122 acyl mutants into the mitochondria with an IMS-targeting tag did not recover their ability to suppress respiration. Moreover, we found that suppressing or boosting respiration levels toggled SOD1 in or out of the mitochondria, respectively. These findings place SOD1-mediated inhibition of respiration upstream of its mitochondrial localization. Interestingly, we also found that K122 acyl mutants were sufficient to prevent mitochondrial accumulation of the G93A SOD1 clinical mutant. We observed increased autophagic activity in G93A expressing cells compared to WT or G93A/K122-acyl mimic double mutants, and found that this double mutant was just as prone to aggregate as G93A SOD1—suggesting that SOD1 aggregation is more toxic when in the mitochondria. We observed increased protein turnover rates in cells expressing SOD1 G93A, in support of increased autophagy. Lastly, deletion-rescue experiments show that a respiration-defective mutant of SOD1 is also impaired in its ability to rescue cells from toxicity caused by SOD1 deletion. Together, these data suggest a new interplay between SOD1 acylation, metabolic regulation, SOD1 aggregate toxicity, and SOD1-mediated cell survival. superoxide dismutase SOD1 mitochondria SIRT5 respiration PTM autophagy Chemistry
14	Investigating the Effects of CyPPA on Small-Conductance Calcium-Activated Potassium Channels in SOD1G93A Transgenic Mouse Model Murphy, Matthew M. 22 May 2020 (has links) No description available. Neurosciences ALS SK Channel SOD1 Amyotrophic Lateral Sclerosis CyPPA
15	Oxidative stress induces DNA strand breaks may lead to genomic instability in ovarian tumorigenesis Moreno-Ortiz, Harold-Humberto 30 April 2011 (has links) Oxidative stress (OS) occurs when DNA repair mechanisms are overcome by the amount of single and double strand DNA breaks caused by an accumulation of reactive oxygen species (ROS). Genomic instability (GI) by microsatellite instability (MSI) accumulation is characterized by changes in DNA single tandem repeats (STR) as a direct result of ROS. Deregulation of DNA repair and tumor suppressor pathways have been described as causes of tumor progression and metastasis. Studies in mammals have focused on GI and the implications of increased mutation frequency due to accumulation of MSI leading to development of diseases, including infertility and cancer. Ovarian cancer is a deadly disease displaying the highest mortality rate among gynecological cancers. Hereditary ovarian cancer displays GI that can be established early in primordial germinal cells (PCGs) development and migration across the genital ridge, where PGCs are exposed to ROS damage. The hypothesis of this study was ROS-induced GI is marked by the accumulation of MSI on repetitive sequences of DNA that override DNA repair, tumor suppressor and redox homeostasis pathways. In this study, we induced ROS in human ovarian cell lines by hydrogen peroxide (H2O2) exposure, as well as evaluated mouse PGCs to determine whether MSI occurs in specific regions of human and mouse genomes. Our results show that MSI was present in specific markers after ROS-induced damage in human ovarian cells and in mouse Sod1 knockout PGCs during cell migration, both of which accumulate specific mutations caused by free radical damage. Ovarian tumor cells and mouse PGCs showed an increase of MSI in 12 human and 5 mouse repetitive markers that are located near important genes related to DNA repair, tumor suppression, cell proliferation, apoptosis and differentiation. This could be a signal that leads to tumor initiation, formation and progression in adult ovarian cells due to improper DNA repair and tumor suppression mechanisms or in disruption of PGC migration that determines germinal cell pool selection during early embryonic development due to absence of cell antioxidant mechanisms. Therefore, these specific unstable STRs are novel biomarkers that could be useful in early diagnostics, prognosis, and successful therapy of ovarian tumorigenesis. BRCA1 ROS MMR genomic instability Ovarian cancer SOD1
16	Kv2.1 Channel Clustering in the SOD1-G93A Mouse Model of ALS Harris, Joshua Christopher 28 August 2020 (has links) No description available. Biomedical Engineering Neurosciences ALS SOD1-G93A Kv2 channels motor neuron
17	Investigation of two early events in amyotrophic lateral sclerosis -MRNA oxidation and up-regulation of a novel protective factor MSUR1- Chang, Yueming 10 December 2007 (has links) No description available. Biology, Neuroscience RNA Oxidation Amyotrophic lateral sclerosis SOD1(G93A) neurodegeneration
18	Alterações na homeostase redox das células beta pancreáticas em resposta à glicose. / Modulation of the redox state by glucose in pancreatic beta cells. Valle, Maíra Mello Rezende 02 October 2014 (has links) As espécies reativas de oxigênio são capazes de influenciar a secreção de insulina, porém ainda não está clara a influência da glicose, principal secretagogo deste hormônio, sobre a homeostase redox das células beta pancreáticas. Incubações por 1 e 48 horas com diferentes concentrações de glicose (2,8; 5,6; 8,3; 11,1; 16,7 e 20 mM) demonstraram que esta é capaz de alterar não só o conteúdo de superóxido, produzido pela mitocôndria e NADPH oxidase, mas também o sistema antioxidante, alterando a concentração de GSH e a expressão das enzimas antioxidantes. Além disso, aumenta a interação Rac1/Sod1, que mantém a NADPH oxidase ativa. Porém, não apresenta endossomas de sinalização redox, os redoxossomas, em resposta a glicose. Estas alterações podem afetar eventos chave para este tecido endócrino, como a secreção de insulina e a morte celular. / ROS production in pancreatic beta cells has been associated with the insulin secretion process but the mechanism by which glucose affects the redox state in these cells remains unknown. In order to address this issue, we evaluated the effect of 1 or 48 hours incubation of pancreatic beta cells with various glucose concentrations (2.8, 5.6, 8.3, 11.1, 16.7 and 20 mM). Glucose loading induced superoxide production by mitochondria and NADPH oxidase complex, and enhanced the antioxidant capacity by increasing GSH content and modulate expression of antioxidant enzymes. Glucose also promoted Rac1/Sod1 interaction that maintains NADPH oxidase activated. These cells however did not present redox endosomes, the redoxosomes, in response to glucose loading. These effects might be associated with the process of insulin secretion and pancreatic beta cell death. Espécies reativas de oxigênio Glicose Glucose Ilhotas pancreáticas Nox2 Nox2 Pancreatic islets Rac1 Rac1 Reactive oxygen species Sod1 Sod1 Superoxide Superóxido
19	Misfolded superoxide dismutase-1 in amyotrophic lateral sclerosis / Felveckat superoxiddismutas-1 i amyotrofisk lateralskelros Zetterström, Per January 2011 (has links) Amyotrophic lateral sclerosis (ALS) is a disease in which the motor neurons die in a progressive manner, leading to paralysis and muscle wasting. ALS is always fatal, usually through respiratory failure when the disease reaches muscles needed for breathing. Most cases are sporadic, but approximately 5–10% are familial. The first gene to be linked to familial ALS encodes the antioxidant enzyme superoxide dismutase-1 (SOD1). Today, more than 160 different mutations in SOD1 have been found in ALS patients. The mutant SOD1 proteins cause ALS by gain of a toxic property that should be common to all. Aggregates of SOD1 in motor neurons are hallmarks of ALS patients and transgenic models carrying mutant SOD1s, suggesting that misfolding, oligomerization, and aggregation of the protein may be involved in the pathogenesis. SOD1 is normally a very stable enzyme, but the structure has several components that make SOD1 sensitive to misfolding. The aim of the work in this thesis was to study misfolded SOD1 in vivo. Small amounts of soluble misfolded SOD1 were identified as a common denominator in transgenic ALS models expressing widely different forms of mutant SOD1, as well as wild-type SOD1. The highest levels of misfolded SOD1 were found in the vulnerable spinal cord. The amounts of misfolded SOD1 were similar in all the different models and showed a broad correlation with the lifespan of the different mouse strains. The misfolded SOD1 lacked the C57-C146 intrasubunit disulfide bond and the stabilizing zinc and copper ions, and was prinsipally monomeric. Forms with higher apparent molecular weights were also found, some of which might be oligomers. Misfolding-prone monomeric SOD1 appeared to be the principal source of misfolded SOD1 in the CNS. Misfolded SOD1 in the spinal cord was found to interact mainly with chaperones, with Hsc70 being the most important. Only a minor proportion of the Hsc70 was sequestered by SOD1, however, suggesting that chaperone depletion is not involved in ALS. SOD1 is normally found in the cytoplasm but can be secreted. Extracellular mutant SOD1 has been found to be toxic to motor neurons and glial cells. Misfolded SOD1 in the extracellular space could be involved in the spread of the disease between different areas of the CNS and activate glial cells known to be important in ALS. The best way to study the interstitium of the CNS is through the cerebrospinal fluid (CSF), 30% of which is derived from the interstitial fluid. Antibodies specific for misfolded SOD1 were used to probe CSF from ALS patients and controls for misfolded SOD1. We did find misfolded SOD1 in CSF, but at very low levels, and there was no difference between ALS patients and controls. This argues against there being a direct toxic effect of extracellular SOD1 in ALS pathogenesis. In conclusion, soluble misfolded SOD1 is a common denominator for transgenic ALS model mice expressing widely different mutant SOD1 proteins. The misfolded SOD1 is mainly monomeric, but also bound to chaperones, and possibly exists in oligomeric forms also. Misfolded SOD1 in the interstitium might promote spread of aggregation and activate glial cells, but it is too scarce to directly cause cytotoxicity. ALS SOD1 protein misfolding SOD1 conformation disulfide-reduced transgenic mice cerebrospinal fluid protein-protein interaction antibodies Clinical chemistry Klinisk kemi
20	Alterações na homeostase redox das células beta pancreáticas em resposta à glicose. / Modulation of the redox state by glucose in pancreatic beta cells. Maíra Mello Rezende Valle 02 October 2014 (has links) As espécies reativas de oxigênio são capazes de influenciar a secreção de insulina, porém ainda não está clara a influência da glicose, principal secretagogo deste hormônio, sobre a homeostase redox das células beta pancreáticas. Incubações por 1 e 48 horas com diferentes concentrações de glicose (2,8; 5,6; 8,3; 11,1; 16,7 e 20 mM) demonstraram que esta é capaz de alterar não só o conteúdo de superóxido, produzido pela mitocôndria e NADPH oxidase, mas também o sistema antioxidante, alterando a concentração de GSH e a expressão das enzimas antioxidantes. Além disso, aumenta a interação Rac1/Sod1, que mantém a NADPH oxidase ativa. Porém, não apresenta endossomas de sinalização redox, os redoxossomas, em resposta a glicose. Estas alterações podem afetar eventos chave para este tecido endócrino, como a secreção de insulina e a morte celular. / ROS production in pancreatic beta cells has been associated with the insulin secretion process but the mechanism by which glucose affects the redox state in these cells remains unknown. In order to address this issue, we evaluated the effect of 1 or 48 hours incubation of pancreatic beta cells with various glucose concentrations (2.8, 5.6, 8.3, 11.1, 16.7 and 20 mM). Glucose loading induced superoxide production by mitochondria and NADPH oxidase complex, and enhanced the antioxidant capacity by increasing GSH content and modulate expression of antioxidant enzymes. Glucose also promoted Rac1/Sod1 interaction that maintains NADPH oxidase activated. These cells however did not present redox endosomes, the redoxosomes, in response to glucose loading. These effects might be associated with the process of insulin secretion and pancreatic beta cell death. Espécies reativas de oxigênio Glicose Ilhotas pancreáticas Nox2 Rac1 Sod1 Superóxido Glucose Nox2 Pancreatic islets Rac1 Reactive oxygen species Sod1 Superoxide

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