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31	L'effet pathologique du monoxyde d'azote est diminué dans les myocytes cardiaques hypertrophiés El-Helou, Viviane January 2004 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Myocyte cardiaque Monoxyde d'azote Oxyde nitrique synthase Hypertrophie Synthèse d'ADN Superoxide dismutase Peroxynitrite
32	Acetilação radicalar de amino ácidos, peptídeos e nucleobases pelos sistemas biacetilo/peroxinitrito e metilglioxal/peroxinitrito / Radical acetylation of aminoacids, peptides, and nucleobases by the biacetyl or methylglyoxal/peroxynitrite systems Tokikawa, Rita 24 May 2012 (has links) Biacetilo (2,3-butanediona) é um contaminante de comida e cigarro, também implicado na hepatoxicidade do álcool e em doenças pulmonares. O metilglioxal (MG), um α-oxoaldeído reativo frequentemente associado ao diabetes e envelhecimento, é produto da fragmentação oxidativa de trioses fosfato, acetona e aminoacetona. Por sua vez, peroxinitrito - um potente oxidante, agente nitrante e nucleófilo formado in vivo pela reação controlada por difusão do ânion radical superóxido com o radical óxido nítrico (k ~1010 M-1s-1) é capaz de se adicionar a CO2 e compostos carbonílicos, gerando produtos potencialmente tóxicos ou sinalizadores celulares. Aminoácidos, peptídeos e nucleobases podem ser acetilados nos grupos amina e na porção desoxiribose. Relativamente ao tratamento com peroxinitrito isolado, níveis superiores de 3-nitrotirosina foram detectados quando tirosina foi tratada com peroxinitrito/biacetilo ou metilglioxal. Ambos os grupos amina de lisina (Lys) ou um deles de derivados de lisina bloqueados e um deles (Ac-Lys-OMe, Z-Lys-OMe) foram acetilados pelo sistema biacetilo ou metilglioxal/peroxinitrito. Em tetrapeptídeos sintéticos contendo lisina como aminoácido amino-terminal (H-KALA-OH, Ac-KALA-OH and H-K(Boc)ALA-OH), a lisina foi acetilada pelo sistemas dicarbonilico/peroxinitrito no grupo α-amina (em maior extensão) e/ou no ε-amina (em menor extensão). No conjunto, estes resultados podem ser interpretados à luz do mecanismo proposto para a reação de compostos α-dicarbonílicos com peroxinitrito, o qual envolve sequencialmente: (i) adição nucleofílica de peroxinitrito à carbonila; (ii) homólise do aduto peroxinitroso formado, liberando •NO2 e um radical oxila do reagente carbonílico; (iii) β-clivagem do radical oxila a um ácido carboxílico (ácido acético no caso de biacetilo e ácido fórmico, a partir de metilglioxal) e radical acetila; (iv) captação do radical acetila pelo oxigênio molecular dissolvido dando acetato, ou por aminoácido ou nucleobase, se presentes, gerando o produto acetilado. Tais resultados são interessantes ao levantar a hipótese de acetilação radicalar como mecanismo de modificação pós-traducional de proteínas, até então considerado um processo realizado apenas por acetilases. / Diacetyl (2,3-butanedione) is a food and cigarette contaminant recently implicated in alcohol hepatotoxicity and lung disease. In turn, methylglyoxal (MG) is an α-oxoaldehyde frequently associated with diabetes and aging that is putatively formed by the oxidative fragmentation of trioses phosphate, acetone and aminoacetone. Peroxynitrite - a potent oxidant, nitrating agent and nucleophile formed in vivo by the diffusion-controlled reaction of superoxide radical with nitric oxide (k ~1010 M-1s-1) - is able to form adducts with carbon dioxide and carbonyl compounds. When initially present in the reaction mixtures before addition of ONOO-, amino acids, peptides and nucleobases undergo acetylation at the amino group and purine moieties in the presence of biacetyl or methylglyoxal. Higher levels of 3-nitrotyrosine nitration were measured when peroxynitrite/biacetyl or metilglioxal was added to tyrosine, in comparison with peroxynitrite alone. Both amino groups of L-lysine or one of the amino groups of L-lysine derivatives (Z-Lys-OH and Ac-Lys-OH) were acetylated by biacetyl and methylglyoxal/peroxynitrite system. Using tetrapeptides containing lysine at the terminal amino acid (H-KALA-OH, Ac-KALA-OH and H-K(Boc)ALA-OH), the lysine residue was acetylated at both or either α-amino (major adduct) and ε-amino group (minor adduct). Altogether these data can be interpreted by the mechanism proposed to describe the reaction of α-dicarbonyls with peroxynitrite as follows: (i) nucleophilic addition of peroxynitrite to the carbonyl group of the reagent; (ii) homolysis of the formed peroxynitroso carbonyl adduct to •NO2 and a carbonyloxyl radical; (iii) β-cleavage of the oxyl radical to acetyl radical plus acetic acid (from diacetyl) or formic acid (from methylglyoxal); (iv) competitive scavenging of the acetyl radical by dissolved molecular oxygen and by added amino acid, peptide or nucleobase, ultimately yielding acetate or acetylated biomolecule. If occurring in vivo, these radical reactions may contribute to the post-translational modification of proteins catalyzed by transacetylases. Acetilação radicalar Biacetilo Biacetyl Biochemistry Bioquímica Lisina Lysine Methylglyoxal Metilglioxal Peroxinitrito Peroxynitrite Radical Acetylation
33	Acetilação radicalar de amino ácidos, peptídeos e nucleobases pelos sistemas biacetilo/peroxinitrito e metilglioxal/peroxinitrito / Radical acetylation of aminoacids, peptides, and nucleobases by the biacetyl or methylglyoxal/peroxynitrite systems Rita Tokikawa 24 May 2012 (has links) Biacetilo (2,3-butanediona) é um contaminante de comida e cigarro, também implicado na hepatoxicidade do álcool e em doenças pulmonares. O metilglioxal (MG), um α-oxoaldeído reativo frequentemente associado ao diabetes e envelhecimento, é produto da fragmentação oxidativa de trioses fosfato, acetona e aminoacetona. Por sua vez, peroxinitrito - um potente oxidante, agente nitrante e nucleófilo formado in vivo pela reação controlada por difusão do ânion radical superóxido com o radical óxido nítrico (k ~1010 M-1s-1) é capaz de se adicionar a CO2 e compostos carbonílicos, gerando produtos potencialmente tóxicos ou sinalizadores celulares. Aminoácidos, peptídeos e nucleobases podem ser acetilados nos grupos amina e na porção desoxiribose. Relativamente ao tratamento com peroxinitrito isolado, níveis superiores de 3-nitrotirosina foram detectados quando tirosina foi tratada com peroxinitrito/biacetilo ou metilglioxal. Ambos os grupos amina de lisina (Lys) ou um deles de derivados de lisina bloqueados e um deles (Ac-Lys-OMe, Z-Lys-OMe) foram acetilados pelo sistema biacetilo ou metilglioxal/peroxinitrito. Em tetrapeptídeos sintéticos contendo lisina como aminoácido amino-terminal (H-KALA-OH, Ac-KALA-OH and H-K(Boc)ALA-OH), a lisina foi acetilada pelo sistemas dicarbonilico/peroxinitrito no grupo α-amina (em maior extensão) e/ou no ε-amina (em menor extensão). No conjunto, estes resultados podem ser interpretados à luz do mecanismo proposto para a reação de compostos α-dicarbonílicos com peroxinitrito, o qual envolve sequencialmente: (i) adição nucleofílica de peroxinitrito à carbonila; (ii) homólise do aduto peroxinitroso formado, liberando •NO2 e um radical oxila do reagente carbonílico; (iii) β-clivagem do radical oxila a um ácido carboxílico (ácido acético no caso de biacetilo e ácido fórmico, a partir de metilglioxal) e radical acetila; (iv) captação do radical acetila pelo oxigênio molecular dissolvido dando acetato, ou por aminoácido ou nucleobase, se presentes, gerando o produto acetilado. Tais resultados são interessantes ao levantar a hipótese de acetilação radicalar como mecanismo de modificação pós-traducional de proteínas, até então considerado um processo realizado apenas por acetilases. / Diacetyl (2,3-butanedione) is a food and cigarette contaminant recently implicated in alcohol hepatotoxicity and lung disease. In turn, methylglyoxal (MG) is an α-oxoaldehyde frequently associated with diabetes and aging that is putatively formed by the oxidative fragmentation of trioses phosphate, acetone and aminoacetone. Peroxynitrite - a potent oxidant, nitrating agent and nucleophile formed in vivo by the diffusion-controlled reaction of superoxide radical with nitric oxide (k ~1010 M-1s-1) - is able to form adducts with carbon dioxide and carbonyl compounds. When initially present in the reaction mixtures before addition of ONOO-, amino acids, peptides and nucleobases undergo acetylation at the amino group and purine moieties in the presence of biacetyl or methylglyoxal. Higher levels of 3-nitrotyrosine nitration were measured when peroxynitrite/biacetyl or metilglioxal was added to tyrosine, in comparison with peroxynitrite alone. Both amino groups of L-lysine or one of the amino groups of L-lysine derivatives (Z-Lys-OH and Ac-Lys-OH) were acetylated by biacetyl and methylglyoxal/peroxynitrite system. Using tetrapeptides containing lysine at the terminal amino acid (H-KALA-OH, Ac-KALA-OH and H-K(Boc)ALA-OH), the lysine residue was acetylated at both or either α-amino (major adduct) and ε-amino group (minor adduct). Altogether these data can be interpreted by the mechanism proposed to describe the reaction of α-dicarbonyls with peroxynitrite as follows: (i) nucleophilic addition of peroxynitrite to the carbonyl group of the reagent; (ii) homolysis of the formed peroxynitroso carbonyl adduct to •NO2 and a carbonyloxyl radical; (iii) β-cleavage of the oxyl radical to acetyl radical plus acetic acid (from diacetyl) or formic acid (from methylglyoxal); (iv) competitive scavenging of the acetyl radical by dissolved molecular oxygen and by added amino acid, peptide or nucleobase, ultimately yielding acetate or acetylated biomolecule. If occurring in vivo, these radical reactions may contribute to the post-translational modification of proteins catalyzed by transacetylases. Acetilação radicalar Biacetilo Bioquímica Lisina Metilglioxal Peroxinitrito Biacetyl Biochemistry Lysine Methylglyoxal Peroxynitrite Radical Acetylation
34	Kinetics and Mechanism of S-Nitrosation and Oxidation of Cysteamine by Peroxynitrite Mbiya, Wilbes 05 September 2013 (has links) Cysteamine (CA), which is an aminothiol drug medically known as Cystagon® was studied in this thesis. Cysteamine was reacted with a binary toxin called peroxynitrite (PN) which is assembled spontaneously whenever nitric oxide and superoxide are produced together and the decomposition of peroxyinitrite was monitored. PN was able to nitrosate CA in highly acidic medium and excess CA to form S-nitrosocysteamine (CANO) in a 1:1 with the formation of one mole of CANO from one mole of ONOOH. In excess oxidant (PN) the following 1:2 stoichiometric ratio was obtained; ONOO- + 2CA → CA-CA + NO2- + H2O . In alkali medium the oxidation of CA went through a series of stages from sulfenic acid, sulfinic acid and then sulfonic acid which was followed by the cleavage of the C-S bond to form a reducing sulfur leaving group, which is easily oxidized to sulfate. The nitrosation reaction was first order in peroxynitrite, thus implicating it as a nitrosating agent in highly acidic pH conditions. Acid catalyzes nitrosation reaction, whitst nitrate catalyzed and increased the amount of CANO product, This means that the nitrosonium cation, NO+ which is produced from the protonation of nitrous acid(in situ) as also contributing to the nitrosation of CA species in highly acidic environments. The acid catalysis at constant peroxynitrite concentrations suggests that the protonated peroxynitrous acid nitrosates at a much higher rate than the peroxynitrite and peroxynitrous acid. Bimolecular rate constants for the nitrosation of CA, was deduced to be 10.23 M-1 s-1. A linear correlation was obtained between the initial rate constants and the pH. The oxidation of CA was modeled by a simple reaction scheme containing 12 reactions. Thiols -- Reactivity -- Research Thiols -- Oxidation -- Research Nitrosation -- Research Chemical Actions and Uses Organic Chemicals
35	Cerium Oxide Nanoparticles Act As A Unique Catalyst And Scavenge Nitric Oxide And Peroxynitrite And Decrease Rns In Vitro And In Vivo Dowding, Janet 01 January 2012 (has links) Cerium oxide nanoparticles (CeO2 NPs)(nanoceria) have been shown to possess a substantial oxygen storage capacity via the interchangeable surface reduction and oxidation of cerium atoms, cycling between the Ce4+ and Ce3+ redox states. Reduction of Ce4+ to Ce3+ causes oxygen vacancies or defects on the surface of the crystalline lattice structure of the particles, generating a cage for redox reactions to occur. The study of the chemical and biological properties of CeO2 NPs has expanded recently, and the methods used to synthesize these materials are also quite diverse. This has led to a plethora of studies describing various preparations of CeO2 NPs for potential use in both industry and for biomedical research. Our own work has centered on studies that measure the ability of water-based CeO2 NPs materials to reduce reactive oxygen and nitrogen species in biological systems, and correlating changes in surface chemistry and charge to the catalytic nature of the particles. The application in experimental and biomedical research of CeO2 NPs began with the discovery that water-based cerium oxide nanoparticles could act as superoxide dismutase mimetics followed by their ability to reduce hydrogen dioxide similar to catalase. While their ROS scavenging ability was well established, their ability to interact with specific RNS species, specifically nitric oxide (·NO) or peroxynitrite (ONOO- ) was not known. The studies described in this dissertation focus on the study of RNS and cerium oxide nanoparticles. Our in vitro work revealed that CeO2 NPs that have higher levels of reduced cerium sites (3+) at the surface (which are effective SOD mimetics) are also capable of accelerating the iv decay of peroxynitrite in vitro. In contrast, CeO2 NPs that have fewer reduced cerium sites at the particle surface (which also exhibit better catalase mimetic activity) have ·NO scavenging capabilities as well as some reactivity with peroxynitrite. Our studies and many others have shown cerium oxide nanoparticles can reduce ROS and RNS in cell culture or animal models. The accumulation of ROS and RNS is a common feature of many diseases including Alzheimer’s disease (AD). Testing our CeO2 NPS in cortical neurons, we used addition of Aβ peptide as an AD model system. CeO2 NPs delayed Aβ-induced mitochondrial fragmentation and neuronal cell death. When mitochondrial ROS levels are increased, mitochondrial fission is activated by DRP1 S616 phosphorylation. Specifically, our studies showed the reduction of phosphorylated DRP1 S616 in the presence of CeO2 NPs. Results from our studies have begun to unravel the molecule mechanism behind the catalytic nature of how CeO2 NPs reduce ROS/RNS in biological systems and represents an important step forward to test the potential neuroprotective effects of CeO2 NPs in model systems of AD. A plethora of studies describing various preparations of CeO2 NPs for potential use in both industry and for biomedical research have been described in the past five years. It has become apparent that the outcomes of CeO2 NPs exposure can vary as much as the synthesis methods and cell types tested. In an effort to understand the disparity in reports describing the toxicity or protective effects of exposure to CeO2 NPs, we compared CeO2 NPs synthesized by three different methods; H2O2 (CNP1), NH4OH (CNP2) or hexamethylenetetramine (HMT-CNP1). Exposure to HMT-CNP1 led to reduced metabolic activity (MTT) at a 10-fold lower concentration than CNP1 or CNP2 and surprisingly, exposure to HMT-CNP1 led to substantial v decreases in the ATP levels. Mechanistic studies revealed that HMT-CNP1 and CNP2 exhibited robust ATPase (phosphatase) activity, whereas CNP1 lacked ATPase activity. HMT-CNP1 were taken up into HUVECs far more efficiently than the other preparations of CeO2 NPs. Taken together, these results suggest the combination of increased uptake and ATPase activity of HMT-CNP1 may underlie the mechanism of the toxicity of this preparation of CeO2 NPs, and may suggest ATPase activity should be considered when synthesizing CeO2 NPs for use in biomedical applications. Overall the studies have uncovered two new catalytic activities for water-based CeO2 NPs (·NO scavenging and accelerated decay of peroxynitrite), demonstrated their ability to reduce RNS in an AD cell culture model as well as identifying a catalytic activity (phosphatase) that may underlie the observed toxicity of CeO2 NPs reported in other studies. Cerium oxide nanoparticles rns ros nitric oxide peroxynitrite alzheimer's disease phosphatase Molecular Biology
36	The Nitroxidative Response to Traumatic Brain Injury Wagner, Michael R. 02 June 2020 (has links) No description available. Biochemistry Chemistry Neurosciences Nitric oxide peroxynitrite S-nitrosylation traumatic brain injury proteomics electrochemistry nanosensors
37	Nitric Oxide/Peroxynitrite Imbalance Induces Adhesion of Cancer Cells to Lymphatic Endothelium - Clinical Implications for Cancer Metastasis Tang, Yuanyuan 17 September 2015 (has links) No description available. Chemistry Biochemistry Analytical Chemistry nitric oxide peroxynitrite cell adhesion lymphatic endothelial cells cancer cells
38	MODIFIED ELECTRODES WITH GRAFTED DNA AND OLIGONUCLEOTIDES FOR DETECTION AND QUANTIFICATION OF PEROXYNITRITE Salim, Heba Azmy 25 May 2016 (has links) No description available. Chemistry Peroxynitrite DNA biosensors electrochemical sensors mismatch detection layer by layer
39	Nitric Oxide and Peroxynitrite Imbalance Triggers Cortical Hyper-Excitability and Migraine Headaches Mahmud, Farina J. 15 June 2017 (has links) No description available. Biochemistry Neurosciences Molecular Chemistry Migraine nitric oxide peroxynitrite cortical spreading depression
40	Nitroxidative Stress Induced Neurodegeneration In Intracerebral Hemorrhagic Stroke-a Nanomedical Approach Madajka, Maria H. January 2007 (has links) No description available. Intracerebral Hemorrhage Stroke Nitric Oxide Synthase Nitric Oxide Superoxide Peroxynitrite L-arginine

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