An electron spin resonance study of free radicals from catechol estrogens

Electron spin resonance spectroscopy has been used to demonstrate production of semiquinone free radicals from the oxidation of the catechol estrogens 2- and 4-hydroxyestradiol and 2,6- and 4,6-dihydroxyestradiol. Radicals were generated by horseradish peroxidase/H2O2 or tyrosinase/O2, or by autoxidation, and were detected as their complexes with spin-stabilizing metal ions (Zn2+ and/or Mg2+). Radical production occurs via one- or two-electron oxidation of catechol estrogens, depending on the type of activating system. Autoxidation of catechol estrogens produces superoxide and H2O2 at physiological pH values. The present results also indicate a difference in the reactivity of quinones derived from 2- and 4-hydroxyestradiol. The toxicological significance of these reactions is discussed.     

Identification by electron spin resonance spectroscopy of free radicals produced during autoxidative melanogenesis

Free radicals produced during the autoxidation of 3,4-dihydroxyphenylalanine (DOPA) and other catechol(amine)s to melanins have been studied using electron spin resonance spectroscopy. Magnetic parameters for the radical intermediates have been determined, allowing the radicals to be unambiguously identified. Three types of radical are formed: the primary radical from one-electron oxidation of the parent catechol(amine); and two secondary radicals, one formed via OH- substitution, the other via cyclization. The formation of these radical species can be linked to molecular products formed during catecholamine oxidation and melanin formation.     

Identification by electron spin resonance spectroscopy of free radicals produced during autoxidative melanogenesis

Free radicals produced during the autoxidation of 3,4-dihydroxyphenylalanine (DOPA) and other catechol(amine)s to melanins have been studied using electron spin resonance spectroscopy. Magnetic parameters for the radical intermediates have been determined, allowing the radicals to be unambiguously identified. Three types of radical are formed: the primary radical from one-electron oxidation of the parent catechol(amine); and two secondary radicals, one formed via OH⁻ substitution, the other via cyclization. The formation of these radical species can be linked to molecular products formed during catecholamine oxidation and melanin formation.     

Electron spin resonance of electrochemically generated free radicals from diaziquone and its derivatives

The one-electron electrochemical reduction of diaziquone (AZQ) and 12 analogs is analyzed using ESR spectroscopy and cyclic voltammetry. The hyperfine coupling constants arising from the interaction of the unpaired electron with the aziridine nitrogen nuclei fall within 1.20 and 2.26 G. Smaller couplings are observed arising from the protons and nitrogens in the carboethoxyamino groups. The in vitro activity of AZQ and its analogs is examined. Methyl groups in the aziridine rings increase the activity of some analogs. In the absence of aziridines, a chloroquinone compound with only carboethoxyamino groups was surprisingly active. This compound has a more positive cathodic peak than diaziquone.     

Formation of iminoxyl and nitroxide free radicals from nitrosonaphthols: an electron spin resonance study

The possible metabolic activation of nitrosonaphthols, suspected carcinogens, was investigated by electron spin resonance (ESR) spectroscopy. Free radicals were found to be the primary metabolites formed during both the reduction and oxidation of these compounds. Whereas the one-electron oxidation of nitrosonaphthols is enzymatic and catalyzed by the peroxidase prototype, horseradish peroxidase, their one-electron reduction by reducing cofactors such as NADH or NADPH was not enhanced by rat liver microsomal enzymes. The ESR spectra of the radicals found during the oxidation of nitrosonaphthols were analyzed and characterized as iminoxyl free radicals. The reduction pathway leads to nitroxide free radicals with unusually low nitrogen hyperfine constants.     

An electron paramagnetic resonance study of free radicals in cells

An electron paramagnetic resonance study was performed on cell lines of the following strains: HeLa, 37RC, L, FLC, NRK/RSV, 3T3/SV40.Unsynchronized and synchronized HeLa cells were studied with particular attention paid to the relation between growth and free radical concentration. Free radical levels were shown to be a function of the growth stage and different phases of the cell cycle.     

An electron paramagnetic resonance study of free radicals in cells.

An electron paramagnetic resonance study was performed on cell lines of the following strains: HeLa, 37RC, L, FLC, NRK/RSV, 3T3/SV40. Unsynchronized and synchronized HeLa cells were studied with particular attention paid to the relation between growth and free radical concentration. Free radical levels were shown to be a function of the growth stage and different phases of the cell cycle.     

Electron spin resonance study of free radicals generated from retinyl- and ionyl-derivatives

Free radicals generated from alpha- and beta-ionyl bromides gave well resolved ESR spectra, but retinyl bromide and chloride gave only broad signals. Delocalised radicals were also spectroscopically observed on hydrogen abstraction from alpha-ionane, alpha-ionyltrimethylsilylether and buten-3-ynyl-2,6,6-trimethyl-2-cyclohexene. Retinyl and beta-ionyl radicals, derived from the corresponding xanthates, were successfully spin trapped with nitrosodurene. The results suggested that the secondary sites C(7) and C(9) were the most reactive in the beta-ionyl radical and that the secondary sites C(7) and C(11) and probably the primary site C(15) were the most reactive in the retinyl radical.     

An electron spin resonance (ESR) study of free radicals formed from hematoxylin on tissue sections after blueing (alkalization)

Summary A free radical signal of 12 G width and g=2.0045 can be observed in hematoxylin stained tissue blocks and sections. The amount of paramagnetic centres in stained specimens is significantly larger than in unstained ones. After alkalization simultaneously with the colour change the former free radical is detectable in hemalum precipitate and on stained paper strips. After solution of the stain in dioxane and alkalization, a well resolved hyperfine structure could be seen which could be assigned to three different radicals with the same g value as observed in the rigid matrix (tissue and paper). Quantitative evaluation of free radical concentration is also carried out for tissue sections.     

An electron spin resonance (ESR) study of free radicals formed from hematoxylin on tissue sections after blueing (alkalization)

A free radical signal of 12 G width and g = 2.0045 can be observed in hematoxylin stained tissue blocks and sections. The amount of paramagnetic centres in stained specimens is significantly larger than in unstained ones. After alkalization simultaneously with the colour change the former free radical is detectable in hemalum precipitate and on stained paper strips. After solution of the stain in dioxane and alkalization, a well resolved hyperfine structure could be seen which could be assigned to three different radicals with the same g value as observed in the rigid matrix (tissue and paper). Quantitative evaluation of free radical concentration is also carried out for tissue sections.     

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.     

Electron spin resonance spectra of free radicals formed in the reaction of metmyoglobins with ethylhydroperoxide

Free radicals of myoglobins were measured at room temperature with an ESR spectrometer equipped with a flow apparatus. When horse heart MetMb was mixed with an equimolar amount of ethyl hydroperoxide (EtOOH), a well resolved ESR spectrum with 6 lines and a shoulder was observed. It reached a maximum in a few seconds and decayed with a half-life of about 10 s when the final concentrations of MetMb and EtOOH were 200 microM. This decay rate was the same at a MetMb concentration of 50 microM. The maximum molar radical concentration amounted to about half of the total myoglobin. In the case of sperm whale myoglobin, a similar 6-line spectrum reached a maximum in 1 s and decayed with a half-life of a few seconds. In this case, however, a small and poorly resolved doublet spectrum remained, the half-life of which was about 8 min. An effect of O2 on the signal decay was evident for horse heart myoglobin, but not for sperm whale myoglobin.     

Identification by electron spin resonance of free radicals formed during the oxidation of 4-hydroxyanisole catalyzed by tyrosinase

We have observed the formation of free radicals during the oxidation of the melanocytotoxic agent 4-hydroxyanisole with the enzyme tyrosinase as a catalyst. The first free radical to form is identified as the 4-methoxy-1,2-benzosemiquinone radical anion. The peak concentration of this radical increases with tyrosinase concentration; a minimum concentration of 50 micrograms/ml of tyrosinase was needed to observe this radical. The peak concentration of this radical is independent of 4-hydroxyanisole concentration. This radical is produced by reverse dismutation of the primary product, 4-methoxy-1,2-benzoquinone and 4-methoxycatechol produced indirectly.     

Detection of peroxyl and alkoxyl radicals produced by reaction of hydroperoxides with heme-proteins by electron spin resonance spectroscopy

ESR spin trapping using the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO) has been used to directly detect alkoxyl radicals (with hyperfine coupling constants aN 1.488, aH 1.600 mT and aN 1.488, aH 1.504 mT for the tBuO. and PhC(CH3)2O. adducts, respectively) and peroxyl radicals (aN 1.448, aH 1.088, aH 0.130 mT and aN 1.456, aH 1.064, aH 0.128 mT for the tBuOO. and PhC(CH3)2OO. adducts, respectively) produced from t-butyl or cumene hydroperoxides by a variety of heme-containing substances (purified cytochrome P-450, metmyoglobin, oxyhemoglobin, methemoglobin, cytochrome c, catalase, horseradish peroxidase) and the model compound hematin. The observed species exhibit a complicated dependence on reagent concentrations and time, with maximum concentrations of the peroxyl radical adducts being observed immediately after mixing of the hydroperoxide with low concentrations of the heme-compound. Experiments with inhibitors (CN-, N3-, CO, metyrapone and imidazole) suggest that the major mechanism of peroxyl radical production involves high-valence-state iron complexes in a reaction analogous to the classical peroxidase pathway. The production of alkoxyl radicals is shown to arise mainly from the breakdown of peroxyl radical spin adducts, with direct production from the hydroperoxide being a relatively minor process.     

Direct detection of circulating free radicals in the rat using electron spin resonance spectrometry.

We developed a new technique for directly observing in vivo free radical formation in the circulating blood of living rats using electron spin resonance (ESR) spectrometry without any labeling or trapping agents. It was found that a doublet peak spectrum was obtained following ferric citrate and ascorbic acid injection. The signals were confirmed in different ways to be due to ascorbic acid radicals. These results provide evidence to support the involvement of free radical intermediates in iron-ascorbic acid reactions, and further confirm the suggested mechanisms of both the adverse and protective effects of ascorbic acid in biological systems. Furthermore, this method of direct observation is a new application of ESR spectrometry to living animals.