Effect of thiourea on microsomal oxidation of alcohols and associated microsomal functions

Tertiary-Butanol: a toxicological review

Tert-Butanol is an important intermediate in industrial chemical synthesis, particularly of fuel oxygenates. Human exposure to tert-butanol may occur following fuel oxygenate metabolism or biodegradation. It is poorly absorbed through skin, but is rapidly absorbed upon inhalation or ingestion and distributed to tissues throughout the body. Elimination from blood is slower and the half-life increases with dose. It is largely metabolised by oxidation via 2-methyl-1,2-propanediol to 2-hydroxyisobutyrate, the dominant urinary metabolites. Conjugations also occur and acetone may be found in urine at high doses. The single-dose systemic toxicity of tert-butanol is low, but it is irritant to skin and eyes; high oral doses produce ataxia and hypoactivity and repeated exposure can induce dependence. Tert-Butanol is not definable as a genotoxin and has no effects specific for reproduction or development; developmental delay occurred only with marked maternal toxicity. Target organs for toxicity clearly identified are kidney in male rats and urinary bladder, particularly in males, of both rats and mice. Increased tumour incidences observed were renal tubule cell adenomas in male rats and thyroid follicular cell adenomas in female mice and, non-significantly, at an intermediate dose in male mice. The renal adenomas were associated with alpha(2u)-globulin nephropathy and, to a lesser extent, exacerbation of chronic progressive nephropathy. Neither of these modes of action can function in humans. The thyroid tumour response could be strain-specific. No thyroid toxicity was observed and a study of hepatic gene expression and enzyme induction and thyroid hormone status has suggested a possible mode of action.

Ultraviolet-B-induced oxidative DNA base damage in primary normal human epidermal keratinocytes and inhibition by a hydroxyl radical scavenger

To evaluate the effects of ultraviolet-induced environmental trauma on human skin cells, primary normal human epidermal keratinocytes were exposed to ultraviolet-B radiation (290-320 nm). We found that relatively low doses of ultraviolet-B (62.5-500 mJ per cm2) caused dose-dependent increases in 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxo-dG), a biomarker of oxidative DNA damage. Unirradiated normal human epidermal keratinocytes contained 1.49 (+/- 0.11) 8-oxo-dG per 10(6) 2'-deoxyguanosine (dG) residues in cellular DNA, which increased linearly to as high as 6.24 (+/- 0.85) 8-oxo-dG per 10(6) dG after irradiation with 500 mJ per cm2. Further, this oxidative damage was reduced by 60.7% when the cells were pretreated with 1 mM mannitol. As hydrogen peroxide (H2O2) is known to be generated during oxidative stress, its accumulation in ultraviolet-B-irradiated normal human epidermal keratinocytes was also assessed and correlated to 8-oxo-dG formation. An ultraviolet-B-induced increase in H2O2 was observed in normal human epidermal keratinocytes and its production was inhibited by the addition of catalase. Based on the ability of a neutral molecule like H2O2 to permeate membranes, our data indicate that, after ultraviolet-B irradiation, H2O2 migrates from the cytosol to the nucleus where it participates in a Fenton-like reaction that results in the production of hydroxyl radicals (OH*), which may then cause 8-oxo-dG formation in cellular DNA. This conclusion is supported by our data showing that OH* scavengers, such as mannitol, are effective inhibitors of oxidative DNA base damage. Although increased levels of 8-oxo-dG were previously found in immortalized mouse keratinocytes exposed to ultraviolet-B radiation, we now report the induction of 8-oxo-dG in normal human skin keratinocytes at ultraviolet-B doses relevant to human skin exposure.

Thiourea protects against copper-induced oxidative damage by formation of a redox-inactive thiourea-copper complex

Although thiourea has been used widely to study the role of hydroxyl radicals in metal-mediated biological damage, it is not a specific hydroxyl radical scavenger and may also exert antioxidant effects unrelated to hydroxyl radical scavenging. Thus, we investigated the effects of thiourea on copper-induced oxidative damage to bovine serum albumin (1 mg/ml) in three different copper-containing systems: Cu(II)/ascorbate, Cu(II)/H(2)O(2), and Cu(II)/H(2)O(2)/ascorbate [Cu(II), 0.1 mM; ascorbate, 1 mM; H(2)O(2), 1 mM]. Oxidative damage to albumin was measured as protein carbonyl formation. Thiourea (0.1-10 mM) provided marked and dose-dependent protection against protein oxidation in all three copper-containing systems. In contrast, only minor protection was observed with dimethyl sulfoxide and mannitol, even at concentrations as high as 100 mM. Strong protection was also observed with dimethylthiourea, but not with urea or dimethylurea. Thiourea also significantly inhibited copper-catalyzed oxidation of ascorbate, and competed effectively with histidine and 1,10-phenanthroline for binding of cuprous, but not cupric, copper, as demonstrated by both UV-visible and low temperature electron spin resonance measurements. We conclude that the protection by thiourea against copper-mediated protein oxidation is not through scavenging of hydroxyl radicals, but rather through the chelation of cuprous copper and the formation of a redox-inactive thiourea-copper complex.

Thiourea and dimethylthiourea inhibit peroxynitrite-dependent damage: nonspecificity as hydroxyl radical scavengers

Thiourea and, more recently, dimethylthiourea, have been used as hydroxyl radical (OH.) scavengers in experiments both in vitro and in vivo. We show that both compounds can inhibit nitration of the amino acid tyrosine on addition of peroxynitrite, and also the inactivation of alpha1-antiproteinase by peroxynitrite. Hence, protective effects of (dimethyl) thiourea could be due to inhibition of peroxynitrite-dependent damage as well as to OH. scavenging, and these compounds must not be regarded as specific OH. scavengers.

Increased cytotoxicity of 3-morpholinosydnonimine to HepG2 cells in the presence of superoxide dismutase. Role of hydrogen peroxide and iron

3-Morpholinosydnonimine (SIN-1) is widely used to generate nitric oxide (NO(x).) and superoxide radical (O2-.). The effect of SOD on the toxicity of SIN-1 is complex, depending on what is the ultimate species responsible for toxicity. SIN-1 (< 1 mM) was only slightly toxic to HepG2 cells. Copper, zinc superoxide dismutase (Cu,Zn-SOD) or manganese superoxide dismutase (Mn-SOD) increased the toxicity of SIN-1. Catalase abolished, while sodium azide potentiated, this toxicity, suggesting a key role for H2O2 in the overall mechanism. Depletion of GSH from the HepG2 cells also potentiated the toxicity of SIN-1 plus SOD. Although Me2SO, sodium formate, and mannitol had no protective effect, iron chelators, thiourea and urate protected the cells against the SIN-1 plus Cu,Zn-SOD-mediated cytotoxicity. The cytotoxic effect of Cu,Zn-SOD but not Mn-SOD, showed a biphasic dose response being most pronounced at lower concentrations (10-100 units/ml). In the presence of SIN-1, Mn-SOD increased accumulation of H2O2 in a concentration-dependent manner. In contrast, Cu,Zn-SOD increased H2O2 accumulation from SIN-1 at low but not high concentrations of the enzyme, suggesting that high concentrations of the Cu,Zn-SOD interacted with the H2O2. EPR spin trapping studies demonstrated the formation of hydroxyl radical from the decomposition of H2O2 by high concentrations of the Cu,Zn-SOD. The cytotoxic effect of the NO donors SNAP and DEA/NO was only slightly enhanced by SOD; catalase had no effect. Thus, the oxidants responsible for the toxicity of SIN-1 and SNAP or DEA/NO to HepG2 cells under these conditions are different, with H2O2 derived from O2-. dismutation playing a major role with SIN-1. These results suggest that the potentiation of SIN-1 toxicity by SOD is due to enhanced production of H2O2, followed by site-specific damage of critical cellular sites by a transition metal-catalyzed reaction. These results also emphasize that the role of SOD as a protectant against oxidant damage is complex and dependent, in part, on the subsequent fate and reactivity of the generated H2O2.

Kinetics of the competitive degradation of deoxyribose and other molecules by hydroxyl radicals produced by the Fenton reaction in the presence of ascorbic acid

The competition method in which the Fenton reaction is employed as an .OH radical generator and deoxyribose as a detecting molecule, has been used to determine the rate constants for reactions of the .OH radical with its scavengers. Nonlinear competition plots were obtained for those scavengers which reacted with the Fenton reagents (Fe2+ or H2O2). Ascorbic acid is believed to overcome this problem. We have investigated the kinetics of deoxyribose degradation by .OH radicals generated by the Fenton reaction in the presence of ascorbic acid, and observed that the inclusion of ascorbic acid in the Fenton system greatly increased the rate of .OH radical generation. As a result, the interaction between some scavengers and the Fenton reagents became negligeable and linear competition plots of A degree/A vs scavenger concentrations were obtained. The effects of experimental conditions such as, the concentrations of ascorbic acid, deoxyribose, H2O2 and Fe(2+)-EDTA, the EDTA/Fe2+ ratio as well as the incubation time, on the deoxyribose degradation and the determination of the rate constant for mercaptoethanol chosen as a reference compound were studied. The small standard error, (6.76 +/- 0.21) x 10(9) M-1s-1, observed for the rate constant values for mercaptoethanol determined under 13 different experimental conditions, indicates the latter did not influence the rate constant determination. This is in fact assured by introducing a term, kx, into the kinetic equation. This term represents the rate of .OH reactions with other reagents such as ascorbic acid, Fe(2+)-EDTA, H2O2 etc. The agreement of the rate constants obtained in this work with that determined by pulse radiolysis techniques for cysteine, thiourea and many other scavengers, suggests that this simple competition method is applicable to a wide range of compounds, including those which react with the Fenton reagents and those whose solubility in water is low.

Determination by enhanced luminescence technique of liver antioxidant capacity

A simple approach to quantitative determination of antioxidant capacity of rat liver homogenate is proposed. It consists of measuring chemiluminescence generated by a suitable system "detector" for .OH radicals produced from sodium perborate. The system generating the light signal contained luminol and compounds producing enhancement of light emission, such as sodium benzoate and indophenol. Two different methods, utilizing the same technique of enhanced luminescence, were set up. In a previous work, a parameter b, contained in the equation, which best describes the dependence of the intensity of light emission (E) on liver homogenate concentration (C) (E = a.C/exp(b.C), was found to be related to the level of antioxidants in the homogenate. Therefore, in the first method, the light emission from several dilutions of both liver homogenates, and homogenate and antioxidant mixtures, stressed with sodium perborate, was detected by a luminometer. The best fitting of data to theoretical equation provided b values, which were introduced in a system of equations relating such values to the antioxidant concentration. The solution of above system supplied the antioxidant concentration in the homogenate in terms of the equivalent concentration of the antioxidant used. In the other method, evaluations of the antioxidant capacity of liver homogenates were obtained by the determination of the ability of 10% homogenates to quench the light emission induced by either peroxidase or cytochrome c in comparison to the ability of antioxidant solutions. Both methods are able to evidence the decrease of the antioxidant concentration of liver homogenates after oxidative stress with ter-butylhydroperoxide. The value of both concentration changes and standard errors indicates that the method using a standard curve obtained with peroxidase, such as catalyst of radical reaction, and deferoxamine, such as antioxidant, is to be preferred.

Oxygen tolerance estimates in Campylobacter species depend on the testing medium

Oxygen tolerance of the microaerophile Campylobacter jejuni subsp. jejuni varied with different brands of complex media which were used for plating the dilute cell suspensions. The tryptone component was one factor. With some tryptones growth occurred at 21% oxygen whereas with others there was no growth at oxygen levels of 15% or higher. A chemically-defined, agar-solidified plating medium was used to estimate the oxygen tolerance of Camp. jejuni subsp. jejuni, Camp. coli and Camp. fetus subsp. fetus, and also to assess the effect of added scavengers of reactive oxygen intermediates on the oxygen tolerance. Some scavengers such as allopurinol, azelaic acid, caffeine, cimetidine, TEMPOL and pyruvate enhanced oxygen tolerance markedly whereas others such as carnosine, dimethyl thiourea, spermidine and superoxide dismutase had little effect.

Kinetics of the competitive degradation of deoxyribose and other biomolecules by hydroxyl radicals produced by the Fenton reaction

The objective of this work is to reexamine the competitive degradation of deoxyribose by hydroxyl radicals (.OH) produced by the reaction between H2O2 and Fe(2+)-EDTA. The .OH radicals produced attack deoxyribose (D, rate constant kD) and eventually an .OH scavenger (S, rate constant kS). First, we examined the effect of [D], [H2O2], [Fe(2+)-EDTA], [EDTA]/[Fe2+] ratio and reaction time on the rate of D degradation, measured as the absorbance of the chromogen formed between the product of the reaction D + .OH (malondialdehyde) and thiobarbituric acid. In particular, it was showed that under our experimental conditions ([D] = 3 mM, [H2O2] = 0.85 mM, [Fe2+] = 0.13 mM), the rate of overall process is first order in Fe2+, zero order in H2O2 and is maximal for a ratio [EDTA]/[Fe2+] = 1.1. Second, the kinetics of .OH radical reaction in competition experiments between D and S (mannitol) was investigated. The results show that the ratio of the rates of D degradation in the absence (VD) and in the presence (VDS) of S should be represented by VD/VDS = 1 + ks[S]/(kD[D] + kx) where kx accounts for the rate of .OH reactions with other reagents such as Fe(2+)-EDTA, H2O2 etc . . . After having determined kx for each set of experimental conditions, we obtained the values of kS/kD by determining the variations of VD/VDS as a function of [S] and [D]. By taking kD = 1.9 x 10(9) M-1s-1 a value of kS = 1.9 x 10(9) M-1s-1 was obtained, very close to that obtained by pulse radiolysis. Finally, the validity of the established relation was confirmed for other biomolecules (methionine, k = 5.6 x 10(9)M-1s-1 and alanine, k = 3.3 x 10(8) M-1s-1). By contrast, it was not applicable to cysteine, thiourea and mercaptoethanol which was attributed to an interaction of the latter scavengers with Fe2+ and/or H2O2.

Cellular mechanism of U78517F in the protection of porcine coronary artery endothelial cells from oxygen radical-induced damage

1. The aim of this study was to clarify the role of lipid peroxidation in cellular injury as assessed by lactate dehydrogenase (LDH) release from cultured coronary artery endothelial cells of the pig. Cells exposed to H2O2 at concentrations of 0.1 to 20 mM or to a xanthine and xanthine oxidase (X/XO) reaction mixture released LDH into the medium. Significant release from X/XO-treated cells took place with a delay of 2 h. 2. Superoxide dismutase (SOD), catalase or dimethylthiourea attenuated the release of LDH from X/XO-treated cells. Similarly the putative inhibitor of lipid peroxidation, U78517F attenuated the release of LDH by X/XO with an IC50 of 0.08 microM. 3. H2O2 was continuously produced by the addition of X/XO to the medium alone. However, in the presence of endothelial cells, H2O2 was eliminated at 1 h. U78517F had no effect on either process. 4. The oxygen radical-induced release of LDH was associated with malondialdehyde (MDA) formation. U78517F inhibited the formation of MDA with an IC50 of 0.27 microM. 5. Reduction of the Ca2+ concentration in the incubation medium from 1.6 mM to 0.016 mM markedly attenuated the release of LDH from endothelial cells. Nifedipine (1 microM) did not attenuate the LDH release from the cells. 6. It is likely that porcine coronary artery endothelial cells can be thus injured by oxygen radicals presumably through hydroxyl radicals formed and consequent lipid peroxidation, and that the extracellular Ca2+ concentration plays an important role in the genesis of such endothelial cell damage.

Metal chelators reverse the action of hydrogen peroxide in rat luteal cells

In rat luteal cells hydrogen peroxide (H2O2) interferes with the functional coupling of the luteinizing hormone (LH) receptor and blocks cAMP-dependent progesterone production. To test if this action of H2O2 is dependent on the generation of hydroxyl radicals, the effects of metal chelators and hydroxyl radical scavengers were evaluated. The heavy metal chelator o-phenanthroline prevented H2O2 inhibition of LH-sensitive cAMP and progesterone accumulation and depletion of ATP. Tetrakis(2-pyridylmethyl)ethylenediamine (TPEN) partially reversed inhibition of cAMP accumulation by H2O2 and completely prevented H2O2-induced ATP depletion, but had no effect on H2O2 inhibition of progesterone synthesis. Three other heavy metal chelators, deferoxamine, bathocuproinedisulfonic acid (BA) and penicillamine, as well as hydroxyl radical scavengers ethanol, thiourea and N-(2-mercaptopropionyl)glycine (MPG), had no effect on the luteolytic actions of H2O2. Differential effects of the chelators were probably due to differences in their cell permeability and subcellular compartmentalization. We conclude that metal chelators block the luteolytic actions of H2O2 by a mechanism probably linked to inhibition of hydroxyl radical generation.

Oxygen radical scavengers selectively inhibit interleukin 8 production in human whole blood

The hydroxyl radical (OH.) scavenger dimethyl sulfoxide (DMSO) was found to dose-dependently inhibit interleukin 8 (IL-8) production in LPS-stimulated human whole blood. At a concentration of 1% (vol/vol), DMSO blocked IL-8 release by approximately 90% in the presence of 1 microgram/ml LPS at a 24-h time point, but did not affect cell viability or reduce the production of tumor necrosis factor (TNF), interleukin 6, or interleukin-1 beta (IL-1 beta). DMSO was found to directly inhibit IL-8 expression at the level of transcription. Furthermore, this effect was not LPS-specific, in that IL-8 production was reduced by DMSO to a similar extent upon stimulation of blood with phytohemagglutinin, aggregated immune complexes, TNF, or IL-1 beta. Other oxygen radical scavengers that have been shown to inhibit OH.-dependent reactions (dimethyl thiourea, thiourea, mannitol, and ethanol) also inhibited IL-8 production. Conversely, addition of H2O2 caused a dose-dependent stimulation of IL-8 release. These results provide evidence that reactive oxygen metabolites play an important role in the regulation of IL-8 production and suggest that reduction of IL-8 release may contribute to the beneficial effects of antioxidants in experimental models of inflammation and ischemia/reperfusion injury.

Dimethylthiourea, an oxygen radical scavenger, protects isolated cardiac myocytes from hypoxic injury by inhibition of Na(+)-Ca2+ exchange and not by its antioxidant effects

Myocardial reoxygenation injury may be attenuated by oxygen free radical scavengers, arguing for a role of oxygen radicals in this process. To determine whether free radical scavengers affect reoxygenation injury in isolated cardiac myocytes, resting rat ventricular myocytes were exposed to hypoxic (PO2 less than 0.02 mm Hg) glucose-free buffer alone (n = 50) or with the addition of the oxygen radical scavengers 1,3-dimethyl-2-thiourea (DMTU, 25 mM, n = 46), human recombinant superoxide dismutase (SOD, 1,000 units/ml, n = 40), or the combination of these agents (n = 41). All cells responded by undergoing contracture to a rigor form. Hypoxia was then continued for a second period (T2), the duration of which correlates inversely with survival. After reoxygenation, cells either retained their rectangular shape (survival) or hypercontracted to a rounded form (death). For the group of cells with a T2 period greater than 30 minutes, no cell exposed to buffer alone (n = 20) or to SOD (n = 16) survived, in contrast to 15 of 24 (63%) cells exposed to DMTU. The addition of SOD to DMTU offered no advantage to DMTU alone. The protective effect of DMTU was not observed when it was added at reoxygenation, suggesting that this agent has an important effect during the hypoxic period when intracellular Ca2+ is known to rise, most likely because of the reversal of Na(+)-Ca2+ exchange. Therefore, the effects of DMTU on Ca2+ regulation (indexed by indo-1 fluorescence) during hypoxia were studied. DMTU significantly blunted the [Ca2+] rise during the hypoxic period.(ABSTRACT TRUNCATED AT 250 WORDS)

Aqueous cigarette tar extracts damage human alpha-1-proteinase inhibitor

The elastase inhibitory capacity (EIC) of human alpha-1-proteinase inhibitor (alpha 1PI) is severely compromised by aqueous cigarette tar extract (ACTE). An aqueous extract of the tar from two cigarettes causes a loss of EIC of at least 60% in 24 h at 37 degrees C (pH 7.4) and the damaging capability of the ACTE is retained for many hours. Hydrogen peroxide appears to be an essential component of the mechanism by which ACTE damages alpha 1 PI, since catalase substantially protects alpha 1PI from ACTE-mediated damage. Only mild protection is offered by 10 mM diethylenetriamine pentaacetic acid, indicating only a minor role for transition metal ions in the alpha 1PI-damaging process. Hydroxyl radicals are unlikely agents of alpha 1PI damage in the ACTE system, as judged from hydroxyl radical scavenger studies. Ascorbate and various thiols offer protection to different degrees, dependent on the incubation conditions. Of several amino acids tested, cysteine and methionine (but not methionine sulfoxide) are the only two that protect alpha 1PI. We suggest that components of cigarette smoke particulate matter extracted into the aqueous lung fluid environment may cause local deficiencies in alpha 1PI in smokers' lungs.

The influence of pH on OH. scavenger inhibition of damage to deoxyribose by Fenton reaction

Hydroxyl radicals (OH.) can be formed in aqueous solution by direct reaction of hydrogen peroxide (H2O2) with ferrous salt (Fenton reaction). OH. damage to deoxyribose, measured as formation of thiobarbituric acid-reactive material, was evaluated at different pHs to study the mechanism of action of classical OH. scavengers. OH. scavenger effect on Fe2+ oxidation was also evaluated in the same experimental conditions. In the absence of OH. scavengers, OH. damage to deoxyribose is higher at acidic compared to neutral and moderately basic pH. At acidic pH deoxiribose is per se able to inhibit Fe2+ oxidation by H2O2. Most of OH. scavengers tested inhibit deoxyribose damage and Fe2+ oxidation in a similar manner: both inhibitions are most relevant at acidic pH and decrease by increasing the pH. These results are not due to OH. scavenger inhibition of Fenton reaction. The influence of pH on the parameters studied appears to be due to the competition of deoxyribose and OH. scavengers for iron. These results suggest the prominent role of iron binding in the degradation of deoxyribose and in the OH. scavenging ability of different compounds. Results obtained with triethylenetetramine, a iron chelator with a low rate constant with OH., confirm that both deoxyribose and the OH. scavengers interact with iron bringing about a site specific Fenton reaction; that the OH. formed at these sites oxidize these molecules to their radical forms which in turn reduce the Fe3+ produced by Fenton reaction. The results presented indicate that most of classical OH. scavengers exert their effect predominantly by preventing the site specific reaction between Fe2+ and H2O2 on the deoxyribose molecule.

ADP-iron as a Fenton reactant: radical reactions detected by spin trapping, hydrogen abstraction, and aromatic hydroxylation

A mixture of ADP, ferrous ions, and hydrogen peroxide (H2O2) generates hydroxyl radicals (OH) that attack the spin trap DMPO (5,5-dimethyl-pyrollidine-N-oxide) to yield the hydroxyl free radical spin-adduct, degrade deoxyribose and benzoate with the release of thiobarbituric acid-reactive material, and hydroxylate benzoate to give fluorescent products. Inhibition studies, with scavengers of the OH radical, suggest that the behavior of iron-ADP in the reaction is complicated by the formation of ternary complexes with certain scavengers and detector molecules. In addition, iron-ADP reacting with H2O2 appears to release a substantial number of OH radicals free into solution. During the generation of OH radicals the ADP molecule was, as expected, damaged by the iron bound to it. Damage to the iron ligand in this way is not normally monitored in reaction systems that use specific detector molecules for OH radical damage. Under certain reaction conditions the ligand may be the major recipient of OH radical damage thereby leading to the incorrect assumption that the iron ligand is a poor Fenton reactant.

Superoxide-dependent formation of hydroxyl radicals from ferric-complexes and hydrogen peroxide: an evaluation of fourteen iron chelators

When a variety of ferric chelates are reacted with hydrogen peroxide in phosphate buffer deoxyribose is damaged and this damage is protected against by formate, thiourea and mannitol. Damage done by ferric complexes of citrate, EDTA, NTA, EGTA and HEDA is substantially inhibited by superoxide dismutase (SOD) whereas complexes of PLA, ADP and CDTA are moderately inhibited by SOD. The effects of SOD argue against hydrogen peroxide acting as a reductant in Fenton chemistry driven by ferric complexes and hydrogen peroxide. EDTA has proved to be a useful model for Fenton chemistry that is inhibited by SOD although, it is not unique in this respect.

Oxidation of dimethylsulphoxide to formaldehyde by oxyhaemoglobin and oxyleghaemoglobin in the presence of hydrogen peroxide is not mediated by "free" hydroxyl radicals

In the presence of excess hydrogen peroxide, human oxyhaemoglobin and oxyleghaemoglobin from soybean root nodules cause oxidation of dimethylsulphoxide to formaldehyde. This reaction is inhibited by thiourea but not by phenylalanine, HEPES, mannitol or arginine. It is concluded that dimethylsulphoxide oxidation is not mediated by "free" hydroxyl radicals, consistent with previous conclusions that intact haemoglobin, leghaemoglobin or myoglobin molecules do not react with H2O2 to form hydroxyl radicals detectable outside the protein.

Oxidative modification of lens crystallins by H2O2 and chelated iron

Crystallins are the soluble structural proteins that constitute approximately 90% of the dry mass of the eye lens. The present study attempts to elucidate possible mechanisms whereby the H2O2 present in the eye could contribute to the oxidative modification of lens crystallins. The data indicate that exposure of solutions of crystallins to H2O2 and EDTA-chelated iron leads to covalent crosslinking of polypeptides, loss of intrinsic protein fluorescence, and the generation of a novel fluorophor emitting in the 420 nm range. These changes closely mimic oxidative modifications that occur in lens proteins in vivo. Exposure of the proteins to H2O2 in the absence of chelated iron failed to generate detectable levels of these modifications. These findings are contrasted with earlier studies of lenses in organ culture where H2O2 alone produced marked damage while the further addition of chelated iron protected the lenses from oxidation.

Formation of hydroxyl radicals from hydrogen peroxide in the presence of iron. Is haemoglobin a biological Fenton reagent?

The ability of oxyhaemoglobin and methaemoglobin to generate hydroxyl radicals (OH.) from H2O2 has been investigated using deoxyribose and phenylalanine as 'detector molecules' for OH.. An excess of H2O2 degrades methaemoglobin, releasing iron ions that react with H2O2 to form a species that appears to be OH.. Oxyhaemoglobin reacts with low concentrations of H2O2 to form a 'reactive species' that degrades deoxyribose but does not hydroxylate phenylalanine. This 'reactive species' is less amenable to scavenging by certain scavengers (salicylate, phenylalanine, arginine) than is OH., but it appears more reactive than OH. is to others (Hepes, urea). The ability of haemoglobin to generate not only this 'reactive species', but also OH. in the presence of H2O2 may account for the damaging effects of free haemoglobin in the brain, the eye, and at sites of inflammation.

Ferrous-salt-promoted damage to deoxyribose and benzoate. The increased effectiveness of hydroxyl-radical scavengers in the presence of EDTA

Hydroxyl radicals (OH.) in free solution react with scavengers at rates predictable from their known second-order rate constants. However, when OH. radicals are produced in biological systems by metal-ion-dependent Fenton-type reactions scavengers do not always appear to conform to these established rate constants. The detector molecules deoxyribose and benzoate were used to study damage by OH. involving a hydrogen-abstraction reaction and an aromatic hydroxylation. In the presence of EDTA the rate constant for the reaction of scavengers with OH. was generally higher than in the absence of EDTA. This radiomimetic effect of EDTA can be explained by the removal of iron from the detector molecule, where it brings about a site-specific reaction, by EDTA allowing more OH. radicals to escape into free solution to react with added scavengers. The deoxyribose assay, although chemically complex, in the presence of EDTA appears to give a simple and cheap method of obtaining rate constants for OH. reactions that compare well with those obtained by using pulse radiolysis.

The specificity of thiourea, dimethylthiourea and dimethyl sulphoxide as scavengers of hydroxyl radicals. Their protection of alpha 1-antiproteinase against inactivation by hypochlorous acid

Thiourea and dimethylthiourea are powerful scavengers of hydroxyl radicals (.OH), and dimethylthiourea has been used to test the involvement of .OH in several animal models of human disease. It is shown that both thiourea and dimethylthiourea are scavengers of HOCl, a powerful oxidant produced by neutrophil myeloperoxidase. Hence the ability of dimethylthiourea to protect against neutrophil-mediated tissue damage cannot be used as evidence for a role of .OH in causing such damage. Dimethyl sulphoxide also reacts with HOCl, but at a rate that is probably too low to be biologically significant at dimethyl sulphoxide concentrations up to 10 mM. Neither mannitol nor desferrioxamine, at the concentrations normally used in radical-generating systems, appears to react with HOCl.

Role of hydrogen peroxide and hydroxyl radical formation in the killing of Ehrlich tumor cells by anticancer quinones

The cytotoxicity of the clinically important antineoplastic quinones doxorubicin, mitomycin C, and diaziridinylbenzoquinone for the Ehrlich ascites carcinoma was significantly reduced or abolished by the antioxidant enzymes catalase and superoxide dismutase, the hydroxyl radical scavengers dimethyl sulfoxide, diethylurea, and thiourea, and the iron chelators deferoxamine, 2,2-bipyridine, and diethylenetriaminepentaacetic acid. However, tumor cell killing by 5-iminodaunorubicin, a doxorubicin analog with a modified quinone function that prohibits oxidation-reduction cycling, was not ameliorated by any of the free radical scavengers tested. Furthermore, treatment of intact tumor cells with doxorubicin, mitomycin C, and diaziridinylbenzoquinone but not 5-iminodaunorubicin generated the hydroxyl radical, or a related chemical oxidant, in vitro in a process that required hydrogen peroxide, iron, and intact tumor cells. These results suggest that drug-induced hydrogen peroxide and hydroxyl radical production may play a role in the antineoplastic action of redox active anticancer quinones.

Cobalt(II) ion as a promoter of hydroxyl radical and possible 'crypto-hydroxyl' radical formation under physiological conditions. Differential effects of hydroxyl radical scavengers

Co(II) ions react with hydrogen peroxide under physiological conditions to form a 'reactive species' that can hydroxylate aromatic compounds (phenol and salicylate) and degrade deoxyribose to thiobarbituric-acid-reactive material. Catalase decreases the formation of this species but superoxide dismutase or low concentrations of ascorbic acid have little effect. EDTA, present in excess over the Co(II), can accelerate deoxyribose degradation and aromatic hydroxylation. In the presence of EDTA, deoxyribose degradation by the reactive species is inhibited competitively by scavengers of the hydroxyl radical (.OH), their effectiveness being related to their second-order rate constants for reaction with .OH. In the absence of EDTA the scavengers inhibit only at much higher concentrations and their order of effectiveness is changed. It is suggested that, in the presence of EDTA, hydroxyl radical is formed 'in free solution' and attacks deoxyribose or an aromatic molecule. In the absence of EDTA, .OH radical is formed in a 'site-specific' manner and is difficult to intercept by .OH scavengers. The relationship of these results to the proposed 'crypto .OH' radical is discussed.

Hydrogen peroxide causes dimethylthiourea consumption while hydroxyl radical causes dimethyl sulfoxide consumption in vitro

Addition of increasing concentrations of hydrogen peroxide (H2O2) caused progressive decreases in dimethylthiourea (DMTU) concentrations which were inhibitable by simultaneous addition of catalase, but not the superoxide anion (O2-.) scavenger, superoxide dismutase (SOD), or hydroxyl radical (.OH) scavengers, such as mannitol, sodium benzoate or dimethyl sulfoxide (DMSO). In parallel, addition of increasing concentrations of H2O2 with FE++/EDTA (but not H2O2 alone) caused decreases in DMSO concentrations which were inhibitable by simultaneous addition of .OH scavengers but not SOD or catalase. Addition of DMTU, but not DMSO, also decreased H2O2 concentrations in vitro. The results indicate the relative scavenging specificities of DMTU and DMSO for H2O2 and .OH, respectively. The findings also suggest that measurement of DMTU or DMSO consumption could help assess the contribution of O2 metabolites in biological systems.

The importance of free radicals and catalytic metal ions in human diseases

The study of free radical reactions is not an isolated and esoteric branch of science. A knowledge of free radical chemistry and biochemistry is relevant to an understanding of all diseases and the mode of action of all toxins, if only because diseased or damaged tissues undergo radical reactions more readily than do normal tissues. However it does not follow that because radical reactions can be demonstrated, they are important in any particular instance. We hope that the careful techniques needed to assess the biological role of free radicals will become more widely used.

Production of formaldehyde and acetone by hydroxyl-radical generating systems during the metabolism of tertiary butyl alcohol

t-Butyl alcohol is not a substrate for alcohol dehydrogenase or for the peroxidatic activity of catalase and, therefore, it is used frequently as an example of a non-metabolizable alcohol. t-Butyl alcohol is, however, a scavenger of the hydroxyl radical. The current report demonstrates that t-butyl alcohol can be oxidized to formaldehyde plus acetone by hydroxyl radicals generated from four different systems. The systems studied were: (a) two chemical systems, namely, the iron catalyzed oxidation of ascorbic acid and the Fenton reaction between H2O2 and iron; (b) an enzymatic system, the coupled oxidation of xanthine by xanthine oxidase; and (c) a membrane-bound system, NADPH-dependent microsomal electron transfer. The oxidation of t-butyl alcohol appeared to be mediated by hydroxyl radicals, or by a species with the oxidizing power of the hydroxyl radical, because the production of formaldehyde plus acetone was (a) inhibited by competing scavengers of the hydroxyl radical; (b) stimulated by the addition of iron-EDTA; and (c) inhibited by catalase. The last observation suggests that H2O2 served as the precursor of the hydroxyl radical in all three systems. A possible mechanism is hydrogen abstraction to form the alkoxyl radical [CH3)3-C-O.), spontaneous fission of the alkoxyl radical to produce acetone and the methyl radical (CH3.), interaction of the methyl radical with O2 to form the methyl peroxy radical (CH300.), and decomposition of the later to formaldehyde. These results extend the alcohol oxidizing capacity of the microsomal alcohol oxidizing system to a tertiary alcohol. Since t-butyl alcohol is not a substrate for alcohol dehydrogenase or catalase, the ability of microsomes to oxidize t-butyl alcohol lends further support for a role for hydroxyl radicals in the microsomal alcohol oxidation system. In view of the production of formaldehyde, and the reactivity as well as further metabolism of this aldehyde, caution should be used in interpreting experiments in which t-butyl alcohol is used as a presumed "non-metabolizable" alcohol. t-Butyl alcohol may be a valuable probe for the detection of hydroxyl radicals in intact cells and in vivo.

Increased microsomal oxidation of hydroxyl radical scavenging agents and ethanol after chronic consumption of ethanol

The oxidation of ethanol by rat liver microsomes is increased after chronic ethanol consumption. Previous experiments indicated that hydroxyl radicals play a role in the mechanism whereby microsomes oxidize ethanol. Experiments were therefore carried out to evaluate the role of these radicals in ethanol oxidation by microsomes from ethanol-fed rats, and to determine whether the increase in ethanol oxidation by these induced microsomes correlates with an increase in the generation of hydroxyl radicals. Rat liver microsomes from ethanol-fed rats catalyzed the oxidation of two typical hydroxyl radical scavenging agents, dimethylsulfoxide and 2-keto-4-thiomethylbutyric acid, at rates which were two- to threefold greater than rates found with control microsomes. This increased rate of oxidation of hydroxyl radical scavengers was similar to the increased rate of microsomal oxidation of ethanol. Azide, which inhibits contaminating catalase in microsomes, increased the oxidation of dimethyl sulfoxide and 2-keto-4-thiomethylbutyric acid by both microsomal preparations. This suggests that H2O2 may serve as the microsomal precursor of the hydroxyl radical. Cross competition for oxidation between ethanol and the hydroxyl radical scavenging agents was observed. Moreover, the oxidation of ethanol, dimethyl sulfoxide, or 2-keto-4-thiomethylbutyric acid was inhibited by other compounds which interact with hydroxyl radicals, e.g., benzoate, and the free-radical, spin-trapping agent, 5,5-dimethyl-1-pyrroline-N-oxide. These results suggest that the increase in the rate of ethanol oxidation found with microsomes from ethanol-fed rats may be due, at least in part, to an increase in the rate of production of hydroxyl radicals by these induced microsomes. Increased production of oxyradicals may possibly result in oxidative damage to the liver cell as a result of ethanol consumption.

Inhibition of microsomal oxidation of alcohols and of hydroxyl-radical-scavenging agents by the iron-chelating agent desferrioxamine

Rat liver microsomes (microsomal fractions) catalyse the oxidation of straight-chain aliphatic alcohols and of hydroxyl-radical-scavenging agents during NADPH-dependent electron transfer. The iron-chelating agent desferrioxamine, which blocks the generation of hydroxyl radicals in other systems, was found to inhibit the following microsomal reactions: production of formaldehyde from either dimethyl sulphoxide or 2-methylpropan-2-ol (t-butylalcohol); generation of ethylene from 4-oxothiomethylbutyric acid; release of 14CO2 from [I-14C]benzoate; production of acetaldehyde from ethanol or butanal (butyraldehyde) from butan-1-ol. Desferrioxamine also blocked the increase in the oxidation of all these substrates produced by the addition of iron-EDTA to the microsomes. Desferrioxamine had no effect on a typical mixed-function-oxidase activity, the N-demethylation of aminopyrine, nor on the peroxidatic activity of catalase/H2O2 with ethanol. H2O2 appears to be the precursor of the oxidizing radical responsible for the oxidation of the alcohols and the other hydroxyl-radical scavengers. Chelation of microsomal iron by desferrioxamine most likely decreases the generation of hydroxyl radicals, which results in an inhibition of the oxidation of the alcohols and the hydroxyl-radical scavengers. Whereas desferrioxamine inhibited the oxidation of 2-methylpropan-2-ol, dimethyl sulphoxide, 4-oxothiomethylbutyrate and benzoate by more than 90%, the oxidation of ethanol and butanol could not be decreased by more than 45-60%. Higher concentrations of desferrioxamine were required to block the metabolism of the primary alcohols than to inhibit the metabolism of the other substrates. The desferrioxamine-insensitive rate of oxidation of ethanol was not inhibited by competitive hydroxyl-radical scavengers. These results suggest that primary alcohols may be oxidized by two pathways in microsomes, one dependent on the interaction of the alcohols with hydroxyl radicals (desferrioxamine-sensitive), the other which appears to be independent of these radicals (desferrioxamine-insensitive).

On the significance of the cytochrome P-450-dependent hydroxyl radical-mediated oxygenation mechanism

1. Reconstituted membrane vesicles containing purified preparations of cytochrome P-450 LM2 and NADPH-cytochrome P-450 reductase effectively destroyed 2-deoxy-D-ribose in an NADPH-dependent process. 2. The destruction was mediated by hydroxyl radicals formed in an iron-catalysed Haber-Weiss reaction between superoxide anions and hydrogen peroxide liberated from the haemoprotein. 3. Administration of ethanol or benzene to rabbits, compounds known to be oxygenated by the hydroxyl radical-dependent mechanism, resulted in induction of a species of cytochrome P-450 effective in the radical-dependent metabolism of both chemicals. 4. Benzene treatment of rabbits also resulted in an enhanced hydroxyl radical-dependent metabolism of ethanol and benzene in liver microsomes. 5. It is suggested that, for certain substrates, hydroxyl radical-mediated cytochrome P-450-dependent oxygenation reactions are of importance for the microsomal metabolism of these compounds. 6. It is speculated that radical-producing species of cytochrome P-450 may contribute to hydroxyl radical-mediated cell damage.

Role of catalase and hydroxyl radicals in the oxidation of methanol by rat liver microsomes

In view of the presence of adventitious catalase in isolated microsomes, and the requirement for H2O2, it has been suggested that NADPH-dependent oxidation of methanol by rat liver microsomes was mediated exclusively by the peroxidatic activity of catalase. However, H2O2 may also serve as a precursor of the hydroxyl radical, and methanol reacts with hydroxyl radicals to produce formaldehyde. Inhibition of H2O2 production should therefore decrease methanol oxidation by either a hydroxyl radical-dependent pathway or a catalase-dependent pathway. To attempt to clarify some of the controversies concerning the roles of H2O2 and catalase in the microsomal pathway of oxidation of short chain alcohols, studies were carried out to determine the nature of the pathway responsible for methanol oxidation by isolated microsomes. In the absence of the catalase inhibitor azide, methanol may be oxidized primarily by the peroxidatic activity of catalase since there was little effect on methanol oxidation by competing hydroxyl radical scavengers. Azide, which inhibited catalase activity greater than 95%, inhibited NADPH-dependent oxidation of methanol by 30-50%. The azide-insensitive (catalase-independent) pathway of methanol oxidation was inhibited by scavengers of hydroxyl radicals. The inhibition of the scavengers reflected the rate constant for interaction with hydroxyl radicals and was greater at lower concentrations of methanol than at higher concentrations, suggesting competition between the scavengers and methanol. The addition of H2O2 stimulated the oxidation of methanol in the presence of azide; H2O2 may serve as a precursor of the hydroxyl radical. Iron-EDTA, which is known to increase hydroxyl radical production, stimulated the oxidation of methanol in the absence and presence of azide. The stimulation by iron-EDTA was blocked by the competing hydroxyl radical scavengers even in the absence of azide, suggesting that the added iron-EDTA favorably with microsomal catalase for H2O2 to produce hydroxyl radicals (or a species with the oxidizing power of the hydroxyl radical). These results suggest that in microsomes, depending on the absence or presence of azide, methanol may be oxidized by two primary pathways, one involving the peroxidatic activity of catalase, and the other in which hydroxyl radicals, generated from microsomal electron transfer, play a role. In view of the crucial role played by H2O2 in both pathways, inhibition of H2O2 formation should not be interpreted solely as evidence for a role for catalase in the microsomal oxidation of alcohols.