Spin-trapping of methyl radical in the oxidative metabolism of 1,2-dimethylhydrazine

Unveiling the Mechanism of Photodamage to Sphingolipid Molecules via Laser Flash Photolysis and EPR

Sphingolipids are involved in the maintenance of the skin barrier function and regulate cellular processes of keratinocytes. The work reported here is designed to uncover details of the mechanism of damage to such lipids by UV radiation. Our approach employs laser flash photolysis and electron paramagnetic resonance (EPR) spectrometry to explore the mechanism of the decay reactions, and to determine the associated kinetic parameters. To interpret our experiments, we computed both excitation energies and EPR parameters of radicals formed during photolysis. Employing the spin-trap EPR method confirmed the formation of both carbon- and nitrogen-centered radicals. Thus, we can conclude that the photodecomposition of sphingolipids and their analogues proceeds by Norrish type I reactions with the formation of both nitrogen-centered and alkyl radicals.

Spin Trapping Hydroxyl and Aryl Radicals of One-Electron Reduced Anticancer Benzotriazine 1,4-Dioxides

Hypoxia in tumors results in resistance to both chemotherapy and radiotherapy treatments but affords an environment in which hypoxia-activated prodrugs (HAP) are activated upon bioreduction to release targeted cytotoxins. The benzotriazine 1,4-di-N-oxide (BTO) HAP, tirapazamine (TPZ, 1), has undergone extensive clinical evaluation in combination with radiotherapy to assist in the killing of hypoxic tumor cells. Although compound 1 did not gain approval for clinical use, it has spurred on the development of other BTOs, such as the 3-alkyl analogue, SN30000, 2. There is general agreement that the cytotoxin(s) from BTOs arise from the one-electron reduced form of the compounds. Identifying the cytotoxic radicals, and whether they play a role in the selective killing of hypoxic tumor cells, is important for continued development of the BTO class of anticancer prodrugs. In this study, nitrone spin-traps, combined with electron spin resonance, give evidence for the formation of aryl radicals from compounds 1, 2 and 3-phenyl analogues, compounds 3 and 4, which form carbon C-centered radicals. In addition, high concentrations of DEPMPO (5-(diethoxyphosphoryl)-5-methyl-1-pyrroline N-oxide) spin-trap the •OH radical. The combination of spin-traps with high concentrations of DMSO and methanol also give evidence for the involvement of strongly oxidizing radicals. The failure to spin-trap methyl radicals with PBN (N-tert-butylphenylnitrone) on the bioreduction of compound 2, in the presence of DMSO, implies that free •OH radicals are not released from the protonated radical anions of compound 2. The spin-trapping of •OH radicals by high concentrations of DEPMPO, and the radical species arising from DMSO and methanol give both direct and indirect evidence for the scavenging of •OH radicals that are involved in an intramolecular process. Hypoxia-selective cytotoxicity is not related to the formation of aryl radicals from the BTO compounds as they are associated with high aerobic cytotoxicity.

Comparative DFT study of the spin trapping of methyl, mercapto, hydroperoxy, superoxide, and nitric oxide radicals by various substituted cyclic nitrones

The thermodynamics of the spin trapping of various cyclic nitrones with biologically relevant radicals such as methyl, mercapto, hydroperoxy, superoxide anion, and nitric oxide was investigated using computational methods. A density functional theory (DFT) approach was employed in this study at the B3LYP/6-31+G(d,p)//B3LYP/6-31G(d) level. The order of increasing favorability for Delta G(rxn) (kcal/mol) of the radical reaction with various nitrones, in general, follows a trend similar to their respective experimental reduction potentials as well as their experimental second-order rate constants in aqueous solution: NO (14.57) < O2*- (-7.51) < *O2H (-13.92) < *SH (-16.55) < *CH3 (-32.17) < *OH (-43.66). The same qualitative trend is predicted upon considering the effect of solvation using the polarizable continuum model (PCM): i.e., NO (14.12) < O2*- (9.95) < *O2H (-6.95) < *SH (-13.57) < *CH3 (-32.88) < *OH (-38.91). All radical reactions with these nitrones are exoergic, except for NO (and O2*- in the aqueous phase), which is endoergic, and the free energy of activation (Delta G) for the NO additions ranges from 17.7 to 20.3 kcal/mol. This study also predicts the favorable formation of certain adducts that exhibit intramolecular H-bonding interactions, nucleophilic addition, or H-atom transfer reactions. The spin density on the nitronyl N of the superoxide adducts reveals conformational dependences. The failure of nitrones to trap NO at normal conditions was theoretically rationalized due to the endoergic reaction parameters.

ESR and HPLC-EC analysis of the interaction of hydroxyl radical with DMSO: rapid reduction and quantification of POBN and PBN nitroxides

The low stability of hydroxyl radical (OH.)-derived nitroxides is a limiting factor for direct spin-trapping of OH. in biological systems. The latter experimental difficulty is partly solved with the introduction of dimethyl sulfoxide (DMSO) into the studied systems. Hydroxyl radical oxidizes DMSO to methyl radical, which forms relatively stable nitroxides. The results of the present work provide evidence that in alpha-(4-pyridyl-1-oxide)-N-tert-butylnitrone (POBN) and alpha-phenyl-N-tert-butylnitrone (PBN) spin-trapping experiments aimed to detect methyl radical in biological systems, the nitroxides formed can be reduced to their ESR-"silent" hydroxylamine derivatives. The nitroxides and their hydroxylamine derivatives were successfully analyzed by HPLC with electrochemical (EC) and UV detection. The lowest limits of UV and EC detection of POBN/CH3 hydroxylamine was evaluated to be in the micro- and nanomolar range, respectively. In parallel ESR and HPLC-EC analysis of the metabolism of menadione by either HepG2 cells or isolated rat hepatocytes in the presence of DMSO, the HPLC-EC method has proven to be more sensitive in detecting the production of methyl radical. The use of the HPLC-EC detection of POBN/CH3 and PBN/CH3 is expected to be advantageous in detection of hydroxyl radical in biological systems in the presence of DMSO.

Activation of alkylhydrazines to free radical intermediates by ethanol-inducible cytochrome P-4502E1 (CYP2E1)

Electron spin resonance (EPR) spectroscopy analysis using the spin trapping agent 4-pyridyl-1-oxide-t-butyl nitrone (4-POBN) was used to measure the formation of free radical intermediates during NADPH-dependent oxidation of 1-methyl-, 1-ethyl-, and 1-isopropylhydrazine in rat liver microsomes and in reconstituted enzyme systems. The experiments in microsomes revealed that the specific activation of the hydrazines, as measured by the EPR signal intensities, was about two-fold higher, when expressed per nmol of P-450, in microsomes from rats treated with ethanol (EtOH) as compared to membranes isolated from either phenobarbital (PB)-, beta-naphthoflavone (beta-NF)-treated or control rats. Furthermore, kinetic experiments revealed that EtOH-microsomes had an apparent affinity for 1-ethylhydrazine about one order of magnitude higher than PB-microsomes. In reconstituted vesicular systems composed of phospholipids, NADPH cytochrome P-450 reductase and P-450, the intensities of EPR signals produced by the formation of the methyl-, ethyl- and isopropyl-free radicals, were 3- to 5-fold more intense in membrane vesicles containing ethanol-inducible CYP2E1 than phenobarbital-inducible CYP2B1. By contrast, CYP1A2, CYP2B4 and CYP2C4 were inefficient catalysts of radical formation. Desferrioxamine, catalase and superoxide dismutase did not influence the extent of ethyl radicals formed in EtOH-microsomes, indicating that hydroxyl radicals are not involved in the CYP2E1-dependent activation of 1-ethylhydrazine. Addition of cytochrome b5, an efficient donor of the second electron to P-450 and hence an inhibitor of the formation of the oxy-cytochrome P-450 complex, increased to be consistent with the results, did not influence the amount of ethyl radicals trapped. In liver microsomes from untreated rats selective substrates of CYP2E1, such as diethyl-dithiocarbamate and p-nitrophenol, as well as anti-CYP2E1-IgG, inhibited the free radical formation from 1-ethylhydrazine by about 60%. The anti-CYP2E1 IgG used significantly inhibited ethyl radical production also in human liver microsomes incubated with 1-ethylhydrazine and 4-POBN. Taken together, these results indicate that CYP2E1, as compared to other rat liver cytochromes P-450, is an efficient catalyst of transformation of alkylhydrazines to free radical intermediates, a finding that might be of importance in the development of the toxicity of these compounds.

Alkylation and cleavage of DNA by carbon-centered radical metabolites

Although carbon-centered radicals are formed during the metabolism of several genotoxic compounds, they have received little attention as DNA damaging agents. Carbon-centered radicals, however, can both cleave the DNA backbone and alkylate DNA bases, as has been demonstrated to occur in chemical and biochemical systems. Also, in vivo DNA alkylation by methyl radicals has been evidenced by isolation of C8-methylguanine in hydrolysates of DNA from rats administered 1,2-dimethylhydrazine. While most of the studies related to DNA damage by free radicals have been focused on oxyradicals, further studies on DNA alterations promoted by carbon-centered radicals may be necessary to elucidate the mechanisms of action of chemical mutagens and carcinogens.

Possible role of free radical intermediates in hepatotoxicity of hydrazine derivatives

Hydrazine derivatives constitute a wide group of compounds and have found application in industry, agriculture, and (as therapeutical agents) medicine. In spite of their widely spread use, several hydrazine derivatives are known to exert hepatotoxic effects and are carcinogenic. Free radical species are produced during the hepatic biotransformation of alkylhydrazines by both rat and humans liver microsomes. Cytochrome P-450 dependent monoxygenase system is responsible for the production of these reactive species and specific cytochrome P-450 isoenzymes appear to catalyze the formation of free radical intermediates. Free radicals generated during the metabolism of alkylhydrazines are capable of inducing oxidative stress in isolated hepatocytes and might contribute to the development of cell injury.

Free radical activation of monomethyl and dimethyl hydrazines in isolated hepatocytes and liver microsomes

Isolated hepatocytes and liver microsomes incubated with monomethyl-1,1 dimethyl- and 1,2 dimethyl-hydrazines produced free radical intermediates which were detected by ESR spectroscopy by using 4-pyridyl-1-oxide-t-butyl nitrone (4-POBN) as spin trapping agent. The spectral features of the spin adducts derived from all three hydrazine derivatives corresponded to the values reported for the methyl free radical adduct of 4-POBN. In the microsomal preparations inhibitors of the mixed function oxidase system and the destruction of cytochrome P450 by pretreating the rats with CoCl2 all decreased the free radical formation. Methimazole, an inhibitor of FAD-containing monoxygenase system, similarly decreased the activation of 1,1 dimethyl-hydrazine, but not that of monomethyl- and 1,2 dimethyl-hydrazines. The addition to liver microsomes of physiological concentrations of glutathione (GSH) lowered by approx. 80% the intensities of the ESR signals. Consistently, incubation of isolated hepatocytes with methyl-hydrazines decreased the intracellular GSH content, suggesting that GSH can effectively scavenge the methyl free radicals. The results obtained suggest that methyl free radicals could be the alkylating species responsible for the toxic and/or carcinogenic effect of methyl-hydrazines.

Hemoglobin-mediated oxidation of the carcinogen 1,2-dimethylhydrazine to methyl radicals

Oxidation of 1,2-dimethylhydrazine (SDMH) catalyzed by hemoglobin is investigated by oxygen consumption studies, ESR spin-trapping experiments, and gas chromatography. Kinetic analysis and the study of the effects of superoxide dismutase, catalase, and azide on reaction rates indicate that SDMH oxidation is primarily dependent on ferric hemoglobin and autoxidatively formed H2O2. SDMH oxidation generates both methyl and hydroxyl radicals as ascertained by spin-trapping experiments with alpha-(4-pyridyl-1-oxide)-N-tert-butylnitrone, 5,5-dimethyl-1-pyrroline-N-oxide, and tert-nitrosobutane. Quantitative estimates indicate that the yield of the methyl radical trapped by alpha-(4-pyridyl-1-oxide)-N-tert-butylnitrone is about 8% of the consumed oxygen. Analysis of the gaseous products by gas chromatography shows methane formation at a yield 10 times lower than that obtained for the spin-trap methyl adduct. These results are discussed within the context of the spin-trapping technique. The relative efficiencies of oxyhemoglobin in catalyzing SDMH, 2-phenylethylhydrazine, and phenylhydrazine oxidation, defined as Vmax/KM, are estimated as 1, 13, and 386, respectively. The higher efficiency obtained for the monosubstituted derivatives leads us to suggest that hemoglobin-catalyzed oxidation could be a detoxification route for these compounds. By contrast, SDMH oxidation requires a peroxidase-like activity, a fact that may be related to the efficacy and specificity of this carcinogen.

Spin trapping of free radical intermediates produced during the metabolism of isoniazid and iproniazid in isolated hepatocytes

By the use of spin trapping agents phenyl-t-butyl nitrone (PBN) and 4-pyridyl-1-oxide-t-butyl nitrone (4-POBN) free radical species were detected in isolated hepatocytes incubated with either isoniazid, iproniazid and their respective metabolites acetyl-hydrazine and isopropyl-hydrazine. The addition of bis-nitrophenyl phosphate, an inhibitor of the acylamidase enzymes, to isolated hepatocytes decreased the free radical activation of isoniazid and iproniazid, but not that of acetyl- and isopropyl-hydrazine, confirming that the radical species were originating from the biotransformation of these latter compounds. The ESR spectra were ascribed to the trapping of, respectively, acetyl and isopropyl free radicals on the basis of the analogies of the spectral feature with those of chemically-prepared spin adducts. Comparable ESR spectra were also observed during the metabolism of acetyl- and isopropyl-hydrazines by liver microsomes and their formation was inhibited by the omission of NADP+, anaerobic incubation and enzyme denaturation. In the microsomal preparations inhibitors of the mixed function oxidase system decreased to various extents the free radical formation and a similar effect was also observed following the destruction of cytochrome P-450 induced by pretreating the rats with CoCl2. The addition of reduced glutathione also decreased the radical trapping indicating that GSH can effectively compete with the spin traps for the reaction with the free radicals. The incubation of isolated hepatocytes with isoniazid or acetyl-hydrazine reduced by 20-25% the intracellular GSH content, while a 50% decrease in GSH was present in the cells exposed to iproniazid and isopropyl-hydrazine. In the same hepatocyte preparations stimulation of lipid peroxidation and leakage of LDH were also observed during cell incubation with iproniazid and isopropyl-hydrazine, but not with isoniazid or acetyl-hydrazine and the extent of both phenomena correlated with the susceptibility of the above compounds to the free radical activation.

Applications of electron spin resonance spectroscopy to the identification of radicals produced during lipid peroxidation

Electron spin resonance (ESR) spectroscopy, which is the only commonly available method for directly detecting free radicals in biological systems, has now been quite extensively used to study radicals produced by metabolism of xenobiotic chemicals and the interaction of such species with lipid molecules. This review examines a variety of different xenobiotic systems and tissues and summarises the information obtained from these studies, with particular reference to the elucidation of the nature of the radicals involved in the initiation and propagation of lipid peroxidation.

Application of ESR spectroscopy in toxicology

Spin trapping in vivo was first achieved in the author's laboratory and is shown to be a feasible method for demonstrating that highly reactive free radical intermediates are generated in the tissues of intact animals as a result of the exposure to certain toxic compounds and to ionizing radiation. The method is based on the property of spin trapping agents (nitrones) to react readily with reactive free radicals to produce stable radical adducts at the site of their origin in target organs. The radical adducts can then be detected by electron spin resonance spectroscopy to determine the intensity of radical production (i.e., number of radicals which were trapped), and, in most cases, identify the nature of the radical that was produced. The type of spin trapping agent employed determines the type of radicals which can be trapped and, at this stage of development of the technique, the number of useful in vivo trapping agents is rather limited.

Detection of free radical intermediates in the oxidative metabolism of carcinogenic hydrazine derivatives

Hydrazine derivatives are widely used in agriculture, in industry, as rocket propellants, and in medicine. Hydrazines also occur naturally in tobacco and mushrooms. Many hydrazines tested in animal studies appear to be carcinogenic and induce tumors in various target tissues in mice, hamsters, and rats. The use of hydrazine derivatives in humans is often complicated by adverse side-effects such as liver injury and rheumatoid arthritis. A number of studies have demonstrated that hydrazine derivatives are activated to reactive intermediates, such as free radicals, through a variety of cellular oxidative metabolic pathways. The aim of this work is to demonstrate the occurrence of free radical intermediates during the metabolic activation of various hydrazine derivatives and to characterize the enzymatic system(s) responsible for the activation to free radical species. The hydrazines studied are acetylhydrazine, isoniazid, isopropylhydrazine, iproniazid, methylhydrazine, 1,1-dimethylhydrazine, and 1,2-dimethylhydrazine. The model systems chosen are those of rat liver microsomes and isolated hepatocytes. Free radical intermediates have been demonstrated by the electron spin resonance spectroscopy coupled to spin trapping technique. The activation mechanism has been characterized using inhibitors of the mixed function oxidase system and of the FAD-dependent oxygenase system. Glutathione was able to scavenge, with high efficiency, the free radicals produced.

Spin trapping: ESR parameters of spin adducts

Spin trapping has become a valuable tool for the study of free radicals in biology and medicine. The electron spin resonance hyperfine splitting constants of spin adducts of interest in this area are tabulated. The entries also contain a brief comment on the source of the radical trapped.

Spin trapping of a free radical intermediate formed during microsomal metabolism of hydrazine

A radical formed during oxidative metabolism of hydrazine in rat liver microsomes was spin-trapped with alpha-phenyl-t-butylnitrone. The trapped species was identified as hydrazine radical by comparison of its ESR parameters and mass spectrum with those of the adduct formed during CuCl2 catalyzed oxidation of hydrazine. The requirement for oxygen and NADPH in the microsomal oxidation and the occurrence of a typical binding spectrum by difference spectroscopy suggest the involvement of the participation of the cytochrome P-450 enzyme system in the formation of hydrazine radical which must be a precursor of diimide during microsomal oxidation of hydrazine.