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Effects of Nitric Oxide in Cells and Tissues: Biochemical Reactivity of Nitric Oxide: J. Torres and M.T. Wilson, Interaction of Cytochrome-c Oxidase with Nitric Oxide. D. Salvemini and J.L. Masferrer,Interactions of Nitric Oxide with Cyclooxygenase: In Vitro, ex Vivo, and in Vivo Studies. J.-C. Drapier and J.B. Hibbs, Jr., Aconitases: A Class of Metalloproteins Highly Sensitive to Nitric Oxide Synthesis. A. Hausladen and I. Fridovich, Measuring Nitric Oxide and Superoxide: Rate Constants for Aconitase Reactivity. E.V. Arnold and D.S. Bohle, Isolation and Oxygenation Reactions of Nitrosylmyoglobins. Tissue-Specific Effects of Nitric Oxide: L.J. Robinson and T.Michel, Endothelial Nitric Oxide Synthase Expression in Heterologous Systems. M.C. Carreras, J.J. Poderoso, E. Cadenas, and A. Boveris, Measurement of Nitric Oxide and Hydrogen Peroxide Production from Human Neutrophils. C.H. Evans, S.C. Watkins, and M. Stefanovic-Racic, Nitric Oxide and Cartilage Metabolism. M.W. Radomski, T. Zakar, and E. Salas, Nitric Oxide in Platelets. D.D. Ku, Nitric Oxide- and Nitric Oxide Donor-Induced Relaxation. Nitric Oxide and Cellular Signaling: J.E. Brenman and D.S. Bredt, Nitric Oxide Signaling in the Nervous System. E. Southam and J. Garthwaite, Nitric Oxide–Cyclic GMP Pathway in Brain Slices. A.J. Hobbs and L.J. Ignarro, Nitric Oxide–Cyclic GMP Signal Transduction System. T.M. Lincoln, T.L. Cornwell, P. Komalavilas, and N. Boerth, Cyclic GMP-Dependent Protein Kinase in Nitric Oxide Signaling. B.B. Aggarwal and K. Mehta, Determination and Regulation of Nitric Oxide Production from Macrophages by Lipopolysaccharides, Cytokines, and Retinoids. Pathological and Clinical Aspects of Nitric Oxide: Fingerprints of Pathological Actions: Nitrosylation, Nitration, and Nitrosation: A. van der Vliet, J.P. Eiserich, H. Kaur, C.E. Cross, and B. Halliwell, Nitrotyrosine as Biomarker for Reactive Nitrogen Species. J.P. Crow and H. Ischiropoulos, Detection and Quantitation of Nitrotyrosine Residues in Proteins: In Vivo Marker of Peroxynitrite. M.S. Ramezanian, S. Padmaja, and W.H. Koppenol, Nitration and Hydroxylation of Phenolic Compounds by Peroxynitrite. Y.Z. Ye, M. Strong, Z.-Q. Huang, and J.S. Beckman, Antibodies That Recognize Nitrotyrosine. J.B. Sampson, H. Rosen, and J.S. Beckman, Peroxynitrite-Dependent Tyrosine Nitration Catalyzed by Superoxide Dismutase, Myeloperoxidase, and Horseradish Peroxidase. Interaction of Nitric Oxide with Membranes, Proteins, and Nucleic Acids: J. Kanner, Nitric Oxide and Metal-Catalyzed Reactions. S. Tamir, T. de Rojas-Walker, J.S. Wishnok, and S.R. Tannenbaum, DNA Damage and Genotoxicity by Nitric Oxide. M.H..L. Green, J.E. Lowe, C.A. Delaney, and I.C. Green, Comet Assay to Detect Nitric Oxide-Dependent DNA Damage in Mammalian Cells. S. Christen,P. Gee, and B.N. Ames, Mutagenicity of Nitric Oxide in Base Pair Specific Salmonella Tester Strains: TA7000 Series. K.-D. Krincke and V. Kolb-Bachofen, Detection of Nitric Oxide Interaction with Zinc Finger Proteins. Peroxynitrite: R.M. Uppu, G.L. Squadrito, R. Cueto, and W.A. Pryor, Selecting the Most Appropriate Synthesis of Peroxynitrite. W.H. Koppenol, R. Kissner, and J.S. Beckman, Syntheses of Peroxynitrite: To Go with the Flow or on Solid Grounds? D.S. Bohle,P.A. Glassbrenner, and B. Hansert, Synthesis of Pure Tetramethylammonium Peroxynitrite. R.M. Uppu, G.L. Squadrito, R. Cueto, and W.A. Pryor, Synthesis of Peroxynitrite by Azide–Ozone Reaction. R.M. Uppu and W.A. Pryor, Biphasic Synthesis of High Concentrations of Peroxynitrite Using Water-Insoluble Alkyl Nitrite and Hydrogen Peroxide. T.P. Hamilton, H.-H. Tsai, and J.S. Beckman, Predicting Physical Properties of Peroxynitrite by Quantum Mechanics. O. Augusto, R. Radi, R.M. Gatti, and J. Vaquez-Vivar, Detection of Secondary Radicals from Peroxynitrite-Mediated Oxidations by Electron Spin Resonance. R. Radi, Kinetic Analysis of Reactivity of Peroxynitrite with Biomolecules. G.L. Squadrito, X. Jin, R.M. Uppu, and W.A.Pryor, Distinguishing Reactivities of Peroxynitrite and Hydroxyl Radical. R. Patel and V.M. Darley-Usmar, Using Peroxynitrite as Oxidant with Low Density Lipoprotein. H. Rubbo and B.A. Freeman, Nitric Oxide Regulation of Lipid Oxidation Reactions: Formation and Analysis of Nitrogen-Containing Oxidized Lipid Derivatives. P. DiMascio, K. Briviba, E.J.H. Bechara, M.H.G. Medeiros, and H. Sies, Reaction of Peroxynitrite and Hydrogen Peroxide to Produce Singlet Molecular Oxygen ([V]1delta g). Tissue and Cellular Cytotoxicity: B. Brane and E.G. Lapetina, Nitric Oxide-Induced Covalent Modification of Glycolytic Enzyme Glyceraldehyde-3-Phosphate Dehydrogenase. M.E. Ross and C. Iadecola, Nitric Oxide Synthase Expressionin Cerebral Ischemia: Neurochemical, Immunocytochemical, and Molecular Approaches. K. Fehsel, K.-D. Krincke, and V. Kolb-Bachofen, Assays for Detection of Nitric Oxide-Induced Apoptosis. Clinical Aspects: D.N. Granger and P. Kubes, Nitric Oxide as Anti-inflammatory Agent. R. Rossaint, T. Busch, and K. Falke, Nitric Oxide Inhalation Therapy in Acute Respiratory Distress Syndrome: Intended Effects and Possible Side Effects. P. Vallance, Use of L-Arginine and Its Analogs to Study Nitric Oxide Pathway in Humans. C.A. Byrnes, A. Bush, and E.A. Shinebourne, Measuring Expiratory Nitric Oxide in Humans. M. Inoue, Y. Minamiyama, and S. Takemura, Dynamic Aspects of Nitric Oxide Metabolism in Circulation and Tissues. AuthorIndex. Subject Index.
Nitric oxide, recently named"Molecule of the Year"by the journal Science, impinges on a wide range of fields in biological research, particularly in the areas of biomedicine and cell and organismal biology, as well as in fundamental chemistry. This volume and its companion Volume 268 highlight methods used to research the physiology and toxicity of nitric oxide in cellular and organismal systems. It will be a valuable resource for the experienced researcher as well as for those newly entering the field.
- Effects of nitric oxide in cells and tissues
- Biochemical reactivity
- Tissue-specific effects
- Endothelial nitric oxide synthase expressions in heterologous systems
- Cellular signaling
- Pathological and clinical aspects of NO
- Fingerprints of pathological action
- Interaction with membranes, proteins, and nucleic acids
- Tissue and cellular cytotoxicity
- Clinical aspects
Biochemists, molecular biologists, physiologists, pharmacologists, cell biologists, biomedical researchers, and neuroscientists
- No. of pages:
- © Academic Press 1996
- 28th August 1996
- Academic Press
- Hardcover ISBN:
- eBook ISBN:
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California Institute of Technology, Division of Biology, Pasadena, U.S.A.
The Salk Institute, La Jolla, CA, USA
Helmut Sies, MD, PhD (hon), studied medicine at the universities of Tübingen, Munich, and Paris. He was the professor and chair of the Institute for Biochemistry and Molecular Biology I at Heinrich-Heine-University Düsseldorf, Germany, where he is now professor emeritus. He is a member of the German National Academy of Sciences Leopoldina and was the president of the North Rhine-Westphalian Academy of Sciences and Arts. He was named ‘Redox Pioneer’; was the president of the Society for Free Radical Research International (SFRRI). Helmut Sies introduced the concept of “Oxidative Stress” in 1985, and was the first to reveal hydrogen peroxide as a normal constituent of aerobic cell metabolism. His research interests comprise redox biology, oxidants, antioxidants, micronutrients.
Heinrich-Heine-University Düsseldorf, Germany
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