Peter Wardman

Reduction Potentials of One‐Electron Couples Involving Free Radicals in Aqueous Solution

Reduction of an electron acceptor (oxidant), A, or oxidation of an electron donor (reductant), A2 −, is often achieved stepwise v i a one‐electron processes involving the couples A/A⋅− or A⋅−/A2 − (or corresponding prototropic conjugates such as A/AH⋅ or AH⋅/AH2). The intermediate A⋅−(AH⋅) is a free radical. The reduction potentials of such one‐electron couples are of value in predicting the direction or feasibility, and in some instances the rate constants, of many free‐radical reactions.Electrochemical methods have limited applicability in measuring these properties of frequently unstable species, but fast, kinetic spectrophotometry (especially pulse radiolysis) has widespread application in this area. Tables of c a. 1200 values of reduction potentials of c a. 700 one‐electron couples in aqueous solution are presented. The majority of organic oxidants listed are quinones, nitroaryl and bipyridinium compounds. Reductants include phenols, aromatic amines, indoles and pyrimidines, thiols and phenothiazines. Inorganic couples largely involve compounds of oxygen, sulfur, nitrogen and the halogens. Proteins, enzymes and metals and their complexes are excluded.

Fenton chemistry: an introduction.

In 1876, Fenton described a colored product obtained on mixing tartaric acid with hydrogen peroxide and a low concentration of a ferrous salt. Full papers in 1894 and 1896 showed the product was dihydroxymaleic acid. Haber, Weiss and Willstätter proposed in 1932-1934 the involvement of free hydroxyl radicals in the iron(II)/hydrogen peroxide system, and Baxendale and colleagues around 1950 suggested that superoxide reduces the iron(III) formed on reaction, explaining the catalytic nature of the metal. Since Fridovich and colleagues discovered the importance of superoxide dismutase in 1968, numerous studies have sought to explain the deleterious effects of cellular oxidative stress in terms of superoxide-driven Fenton chemistry. There remain questions concerning the involvement of free hydroxyl radicals or reactions of metal/oxo intermediates. However, these outstanding questions may obscure a wider appreciation of the importance of Fenton chemistry involving hypohalous acids rather than hydrogen peroxide as the oxidant.

Electron-Affinic Sensitization VII. A Correlation between Structures, One-Electron Reduction Potentials, and Efficiencies of Nitroimidazoles as Hypoxic Cell Radiosensitizers

Radiosensitization efficiencies for seven different 2-nitroimidazoles including Ro-07-0582 and its urinary metabolite, Ro-05-9963, and two 5-nitroimidazoles including metronidazole, have been determined in hypoxic Chinese Hamster cells, line V79-379A, X-irradiated in vitro. All the compounds were active hypoxic cell sensitizers with the enhancement ratios increasing with drug concentration. The 2-nitroimidazoles were all more efficient than the 5-nitroimidazoles. Overall, the efficiencies, defined as the concentration required to give a particular enhancement ratio, varied by a factor of about 200. Electron-affinities of the sensitizers were determined by pulse radiolysis as the one-electron reduction potentials and these correlate well with the sensitization efficiencies of the compounds. The correlation extends beyond the nitroimidazole series as is shown by data for p-nitroacetophenone, nifuroxime (a nitrofuran) and oxygen itself. The nitroimidazoles varied by a factor of 70 in their octanol/water part...

[3] Kinetic factors that control the fate of thiyl radicals in cells

Publisher Summary A thiyl radical (RS) is produced when a thiol (RSH) loses the hydrogen atom from the S–H group, or loses an electron from sulfur, followed by a proton. The two processes are stoichiometrically equivalent and may be difficult to distinguish experimentally, because proton transfer reactions to solvent water are usually fast. Because the S–H bond strength is lower than that of many C–H bonds, numerous carbon-centered radicals are repaired by thiols by hydrogen (or electron/proton) donation. Thiols can also act as cellular antioxidants by electron transfer to oxidizing species, producing thiyl radicals. Radicals derived from DNA bases—such as those produced on reaction of guanine moieties with OH—are repaired (but not restituted) by thiols. Xenobiotic radicals produced by one-electron oxidation of drugs are often reactive toward thiols. The fate of thiyl radicals in cells reflects the kinetics of reactions that produce and remove them. The main experimental technique for measuring the kinetics of thiyl radical reactions is pulse radiolysis. This chapter discusses the kinetic factors controlling the reaction pathways of thiyl radicals in cells and the experimental problems in quantitation.

Free hydroxyl radicals are formed on reaction between the neutrophil-derived species Superoxide anion and hypochlorous acid

Superoxide anion reacts with hypochlorous acid to yield free hydroxyl radicals, as shown by the hydroxylation of benzoate. This reaction is analogous to the Haber‐Weiss reaction but in the absence of metal ions is at least six orders of magnitude faster.

Oxygen inhibition of nitroreductase: Electron transfer from nitro radical-anions to oxygen

Abstract The inhibition of many nitroreductases by oxygen has been explained by Mason and Holtzman in terms of electron transfer to oxygen from the nitro radical-anions, which have been identified as the first intermediate in some reductase systems. We have used the pulse radiolysis technique to measure the bimolecular rate constants of this electron-transfer reaction for over 20 nitro compounds, including substituted 2- and 5-nitroimidazoles of interest as antiprotozoal drugs and radiosensitizers, nitrofurans in use as antibacterial agents, and substituted nitrobenzenes previously used as model substrates for nitroreductases. The logarithm of the rate constant for the reaction of the nitro radical-anion with oxygen is linearly related to the one-electron reduction potential of the nitro compound.

The spontaneous and enzymatic reaction of N-acetyl-p-benzoquinonimine with glutathione: A stopped-flow kinetic study

The spontaneous and glutathione (GSH) transferase catalyzed reactions of GSH and N-acetyl-p-benzoquinonimine (NABQI) have been studied by stopped-flow kinetics. The spontaneous reaction was shown to be first order in NABQI, GSH and inversely proportional to the H+ concentration; e.g., at pH 7.0 and 25 degrees C the second-order rate constant was 3.2 X 10(4) M-1 s-1. Data for the enzymatic reaction gave values for Km of 27, 1.3, 7, and 7 microM and values for kappa cat of 90, 37, 5.1, and 165 s-1 for rat liver GSH transferases 1-1, 2-2, 3-3, and 7-7, respectively. Over a wide range of reactant concentrations and pH, the spontaneous reaction yields three products, namely a GSH conjugate, 3-(glutathion-S-yl)acetaminophen; a reduction product, acetaminophen; and an oxidation product, glutathione disulfide in the proportions 2:1:1. Analysis of products formed after enzymatic reaction showed that both GSH conjugation and the reduction of NABQI to acetaminophen were catalyzed to an extent characteristic of each isoenzyme. With respect to GSH conjugation, GSH transferase isoenzymes were effective in the order 7-7 greater than 2-2 greater than 1-1 greater than 3-3 greater than 4-4, and with respect to NABQI reduction these isoenzymes were effective in the order 1-1 greater than 2-2 greater than 7-7 the position of isoenzymes 3-3 and 4-4 being uncertain. Human GSH transferases delta, mu, and pi behave similarly to the homologous rat enzymes, i.e., toward conjugation in the order pi greater than delta greater than mu and the reduction delta greater than mu greater than pi (for nomenclature see W. B. Jakoby, B. Ketterer, and B. Mannervik, (1984) Biochem. Pharmacol. 33, 2539-2540). Possible mechanisms of the reaction and its effect on the toxicity of NABQI are discussed.

Reactivity of hydrogen sulfide with peroxynitrite and other oxidants of biological interest

Hydrogen sulfide (H(2)S) is an endogenously generated gas that can also be administered exogenously. It modulates physiological functions and has reported cytoprotective effects. To evaluate a possible antioxidant role, we investigated the reactivity of hydrogen sulfide with several one- and two-electron oxidants. The rate constant of the direct reaction with peroxynitrite was (4.8±1.4)×10(3)M(-1) s(-1) (pH 7.4, 37°C). At low hydrogen sulfide concentrations, oxidation by peroxynitrite led to oxygen consumption, consistent with a one-electron oxidation that initiated a radical chain reaction. Accordingly, pulse radiolysis studies indicated that hydrogen sulfide reacted with nitrogen dioxide at (3.0±0.3)×10(6)M(-1) s(-1) at pH 6 and (1.2±0.1)×10(7)M(-1) s(-1) at pH 7.5 (25°C). The reactions of hydrogen sulfide with hydrogen peroxide, hypochlorite, and taurine chloramine had rate constants of 0.73±0.03, (8±3)×10(7), and 303±27M(-1) s(-1), respectively (pH 7.4, 37°C). The reactivity of hydrogen sulfide was compared to that of low-molecular-weight thiols such as cysteine and glutathione. Considering the low tissue concentrations of endogenous hydrogen sulfide, direct reactions with oxidants probably cannot completely account for its protective effects.

Oxidative activation of indole-3-acetic acids to cytotoxic species— a potential new role for plant auxins in cancer therapy

Indole-3-acetic acid (IAA) and some derivatives can be oxidised by horseradish peroxidase (HRP) to cytotoxic species. Upon treatment with IAA/HRP, liposomes undergo lipid peroxidation, strand breaks and adducts are formed in supercoiled plasmid DNA, and mammalian cells in culture lose colony-forming ability. IAA is only toxic after oxidative decarboxylation; no effects are seen when IAA or HRP is incubated independently in these systems at equivalent concentrations. Toxicity is similar in both hamster fibroblasts and some human tumour cells. The effect of IAA/HRP is thought to be due in part to the formation of 3-methylene-2-oxindole, which may conjugate with DNA bases and protein thiols. Our hypothesis is that IAA/HRP could be used as the basis for targeted cancer therapy involving antibody-, polymer-, or gene-directed approaches. HRP can thus be targeted to a tumour allowing non-toxic IAA delivered systemically to be activated only in the tumour. Exposure to newly synthesised analogues of IAA shows a range of four orders of magnitude difference in cellular toxicity but no structure-activity relationships are apparent, in contrast to well-defined redox dependencies of oxidation by HRP intermediates or rates of decarboxylation of radical-cation intermediates.

Radiation chemistry comes before radiation biology.

Purpose: This article seeks to illustrate some contributions of radiation chemistry to radiobiology and related science, and to draw attention to examples where radiation chemistry is central to our knowledge of specific aspects. Radiation chemistry is a mature branch of radiation science which is continually evolving and finding wider applications. This is particularly apparent in the study of the roles of free radicals in biology generally, and radiation biology specifically. The chemical viewpoint helps unite the spatial and temporal insight coming from radiation physics with the diversity of biological responses. While historically, the main application of radiation chemistry of relevance to radiation biology has been investigations of the free-radical processes leading to radiation-induced DNA damage and its chemical characterization, two features of radiation chemistry point to its wider importance. First, its emphasis on quantification and characterization at the molecular level helps provide links between DNA damage, biochemical repair processes, and mutagenicity and radiosensitivity. Second, its central pillar of chemical kinetics aids understanding of the roles of ‘reactive oxygen species’ in cell signalling and diverse biological effects more generally, and application of radiation chemistry in the development of drugs to enhance radiotherapy and as hypoxia-specific cytotoxins or diagnostic agents. The illustrations of the broader applications of radiation chemistry in this article focus on their relevance to radiation biology and demonstrate the importance of synergy in the radiation sciences. Conclusions: The past contributions of radiation chemistry to radiation biology are evident, but there remains considerable potential to help advance future biological understanding using the knowledge and techniques of radiation chemistry.