Furazolidone-enhanced production of free radicals by avian cardiac and hepatic microsomal membranes

Furazolidone produces a dilative cardiomyopathy and hepatitis in turkeys exposed to this drug in their diets. The ability of furazolidone to enhance free radical reactions when incubated with turkey cardiac or hepatic membranes was determined to evaluate if free radical reactions might contribute to the pathology. Furazolidone (0.135 mM) incubated with NADPH and hepatic microsomes increased oxygen consumption 350% over control incubations. Superoxide dismutase and catalase attenuated the furazolidone-mediated stimulation of oxygen consumption, indicating that the drug promoted the formation of superoxide and hydrogen peroxide. Lipid peroxidation was also stimulated by furazolidone incubated with microsomes, NADPH, and ferric chloride. At concentrations as low as 0.017 mM, lipid peroxidation was more than doubled by furazolidone. Incubation of cardiac sarcosomes with NADPH and furazolidone (0.135 mM) increased oxygen consumption 72% the rate of cytochrome c reduction 72%, and epinephrine oxidation 238% over control. Epinephrine oxidation was enhanced by concentrations of furazolidone as low as 0.017 mM (69% increase over control). This effect of furazolidone was blocked by superoxide dismutase or incubation in an argon atmosphere. These data establish the potential for furazolidone to enhance free radical reactions in cardiac, as well as hepatic tissue. Free radical reactions are therefore potential determinants of furazolidone-mediated hepatic and cardiac toxicities.     

Not all aromatic nitro compounds form free radicals

One-electron reduction of the aromatic nitro-containing drug, clonazepam, by rat hepatic microsomes was found to produce a nitro anion radical which was observable by electron paramagnetic resonance (EPR) spectrometry under anaerobic conditions. It was determined that NADPH-cytochrome P-450 reductase may be the enzyme responsible for this reduction and that this free radical reacts rapidly with oxygen to produce superoxide. The vasodilator nifedipine, another aromatic nitro-containing drug, was found not to be reduced by rat hepatic microsomes to a free radical nor to stimulate superoxide production. Based on a series of experiments, we propose that the inability of nifedipine to be bioreduced to its nitro anion free radical is the result of geometric restrictions which prevent the transfer of an electron from cytochrome P-450 reductase to nifedipine.     

Hydroxyl radical scavenging action of tinoridine

Radical scavenging action of tinoridine, a non-steroidal anti-inflammatory drug with a potent anti-peroxidative activity, was investigated. Tinoridine reduced a stable free radical, diphenyl-p-picryl-hydrazyl, in the molar ratio of about 1:2, indicating its free radical scavenging ability. Tinoridine inhibited the lipid peroxidation in rat liver microsomes induced by xanthine-xanthine oxidase system in the presence of ADP and Fe2+, in which hydroxyl radical (. OH) is formed. Tinoridine was demonstrated to be oxidized in the course of the lipid peroxidation by following the fluorescence derived from the oxidation product of tinoridine. It was also oxidized by the xanthine-xanthine oxidase system in the presence of Fe2+, but its oxidation was slow in the absence of Fe2+ and almost completely inhibited by catalase. Tinoridine was also oxidized by H2O2-Fe2+ system producing . OH (Fenton reaction), but it did not affect the reduction of cytochrome c caused by superoxide radical. These results indicate that tinoridine is able to scavenge . OH and the main active oxygen species responsible for the lipid peroxidation is . OH. The anti-peroxidative and . OH scavenging ability of tinoridine should contribute to its anti-inflammatory action.     

Metabolic activation of oxygen by nitrofurantoin in the young chick

Anaerobic incubations containing nitrofurantoin, and NADPH-generating system, and chick hepatic microsomes produced an electron spin resonance spectrum identified as the nitro anion free radical. Aerobically, nitrofurantoin markedly stimulated oxygen consumption, superoxide formation, and NADPH oxidation in hepatic microsomal preparations from control and selenium-deficient chicks. The nitrofurantoin-stimulated oxidation of NADPH was inhibited by superoxide dismutase (SOD). The superoxide-dependent oxidation of NADPH did not appear to be mediated by an NADP^? radical, as has been shown for lactate dehydrogenase. Further, the aerobic metabolism of the nitro drug was also affected by SOD, suggesting the existence of a previously unreported metabolic pathway for nitrofurantoin. These studies support the growing body of evidence which suggests that nitrofurantoin toxicity is mediated, at least in part, by the metabolic activation of oxygen by the nitro aromatic anion radical. Further, these data suggest that superoxide may be involved in the oxidative metabolism of the aromatic nitro compounds.     

Generation of free radicals during the reductive metabolism of nilutamide by lung microsomes: possible role in the development of lung lesions in patients treated with this anti-androgen.

The pulmonary metabolism of nilutamide, a nitroaromatic anti-androgen drug leading to pulmonary lesions in a few recipients, has been investigated in rats. Incubation of nilutamide (1 mM) with rat lung microsomes and NADPH under anaerobic conditions led to the formation of the nitro anion free radical, as indicated by ESR spectroscopy. The steady state concentration of this radical was not decreased by CO or SKF 525-A (two inhibitors of cytochrome P450), but was decreased by NADP+ (10 mM) or p-chloromercuribenzoate (0.47 mM) (two inhibitors of NADPH-cytochrome P450 reductase activity). Anaerobic incubations of [3H]nilutamide (0.1 mM) with rat lung microsomes and a NADPH-generating system resulted in the in vivo covalent binding of [3H]nilutamide metabolites to microsomal proteins; covalent binding required NADPH; it was decreased in the presence of NADP+ (10 mM), or in the presence of the nucleophile glutathione (10 mM), but was unchanged in the presence of carbon monoxide. Under aerobic conditions, in contrast, the nitro anion free radical was reoxidized by oxygen, and its ESR signal was not detected. Covalent binding was essentially suppressed. Instead, there was consumption of NADPH and oxygen, and production of superoxide anion and hydogen peroxide. We conclude that nilutamide is reduced by rat lung microsomes NADPH-cytochrome P450 reductase into a nitro anion free radical. In anaerobiosis, the radical is reduced further to covalent binding species. In the presence of oxygen, in contrast, this nitro anion free radical undergoes redox cycling, with the generation of reactive oxygen species.     

The effect of the anthrapyrazole antitumour agent CI941 on rat liver microsome and cytochrome P-450 reductase mediated free radical processes. Inhibition of doxorubicin activation in vitro

The anthrapyrazole CI941 is one of a new series of DNA complexing drugs which displays high level broad spectrum antitumour activity in mice. In view of the proposed role of drug free radical formation, superoxide generation and lipid peroxidation in anthracycline and anthraquinone induced toxicities, the redox biochemistry of CI941 has been investigated. Studies have been performed in vitro using rat liver microsomes and purified cytochrome P-450 reductase. In addition, the ability of CI941 to undergo chemical reduction has been examined. Pulse radiolysis of CI941 demonstrated that the drug can undergo chemical reduction with a one electron reduction potential of E1(7) = -538 +/- 10 mV. However, electron spin resonance (ESR) spectroscopy studies using either NADPH fortified microsomes or cytochrome P-450 reductase, failed to detect a drug free radical signal. Unlike doxorubicin, CI941 (150 microM) inhibited basal rate microsomal NADPH consumption by 45%. Furthermore, CI941 (50-200 microM) antagonised doxorubicin stimulated (1.8-fold) NADPH oxidation by over 50%. CI941 also antagonised the formation of a doxorubicin free radical ESR signal in a concentration dependent manner. CI941 induced minimal superoxide generation in the presence of either microsomes or cytochrome P-450 reductase and inhibited doxorubicin induced (50 microM) superoxide formation by up to 80% (50-200 microM CI941). Importantly, CI941 inhibits both basal rate and doxorubicin (100 microM) stimulated lipid peroxidation (52% inhibition at 5 microM CI941). These data suggest that CI941 is unlikely to induce free radical mediated tissue damage in vivo. On the contrary, CI941 may have a protective role if used in combination with doxorubicin.     

Metabolic activation of procarbazine. Evidence for carbon-centered free-radical intermediates

The metabolism of procarbazine was studied using spin-trapping techniques. The oxidation of procarbazine, catalyzed by horseradish peroxidase, prostaglandin synthetase [ram seminal vesicle (RSV) microsomes] or rat hepatic microsomal cytochrome P-450, produced carbon-centered free radicals. Cytochrome P-450 also catalyzed this oxidation in the presence of hydrogen peroxide. Horseradish peroxidase activation of procarbazine formed both the methyl radical and the N-isopropylbenzylamide radical [(CH3)2CHNHCO(C6H4)CH2.]. In the presence of RSV or rat hepatic microsomes, mostly the benzyl-type radical was trapped, presumably due to the reactivity of the methyl radical.     

Self-catalyzed inactivation of cytochrome P-450 during microsomal metabolism of cannabidiol

When cannabidiol (CBD) was incubated with hepatic microsomes of mice in the presence of an NADPH-generating system, a significant decrease of cytochrome P-450 content was observed by measuring its carbon monoxide difference spectra. The decrease of cytochrome P-450 by CBD required NADPH and molecular oxygen. The effect was partially inhibited by SKF 525-A but not by various scavengers of active oxygen species, superoxide anion, hydroxyl radical and singlet oxygen. The incubation of CBD with hepatic microsomes did not affect total heme but decreased significantly free sulfhydryl contents in the microsomes. The derivatives of CBD modified in the resorcinol moiety, CBD-monomethyl- and dimethylethers, almost lost the effect on cytochrome P-450, whereas those modified in the terpene moiety, 8,9-dihydro- and 1,2,8,9-tetrahydro-CBDs exhibited some potency to inactivate cytochrome P-450. The inactivation of cytochrome P-450 by CBD and related compounds led to the inhibition of hepatic microsomal p-nitroanisole O-demethylase and aniline hydroxylase activities. These results suggest that the resorcinol moiety of CBD plays some role in the inactivation of cytochrome P-450 by the cannabinoid.     

Carbon tetrachloride-induced lipid peroxidation: A spin trapping study

It has been suggested that the active species responsible for carbon tetrachloride-induced lipid peroxidation is trichloromethyl radical (· CCl₃). Direct evidence for the existence of this reactive species can be obtained by spin trapping techniques, however, there are conflicting reports as to the identity of this free radical trapped.

We have found that upon addition of carbon tetrachloride to a mixture of rat hepatic microsomes, NADPH and the spin trap, (4-pyridinyl-1-oxide)-N-t-butyl nitrone (4-POBN) an electron paramagnetic resonance (epr) spectrum appeared. This spectrum was identical to that observed in the absence of carbon tetrachloride, except for enhanced rate of formation. We were able to identify this free radical, using model systems as a lipid peroxyl radical (LOO ·).     

Mechanism of paraquat-stimulated lipid peroxidation in mouse brain and pulmonary microsomes.

Paraquat-stimulated NADPH-dependent lipid peroxidation in mouse brain and pulmonary microsomes was inhibited by superoxide dismutase and singlet oxygen quenchers, but not by catalase or hydroxyl radical scavengers. MnCl2, which might form a salt with unsaturated lipid, inhibited the lipid peroxidation in brain microsomes, but not that in pulmonary microsomes. These findings suggest that activated oxygen species, especially superoxide and singlet oxygen, may play a major role in the stimulation of microsomal lipid peroxidation by paraquat in both brain and lung, and that the nature of the lipids exposed to peroxidative attack may be different in microsomes of the two organs.     

Detection of free radicals as a consequence of dog tracheal epithelial cellular xenobiotic metabolism

1. Spin-trapping techniques have been used to examine the metabolism of three xenobiotics known to produce free radicals during their metabolism. Reaction with oxygen generated superoxide, the location of which was dependent upon the xenobiotic. 2. Paraquat was metabolized by dog trachea epithelial cells under anaerobiosis to the paraquat free radical, some of which diffused into the extracellular milieu. With the addition of oxygen, superoxide was spin-trapped both intra- and extracellularly. 3. When menadione was metabolized by epithelial cells, superoxide was spin-trapped within the cell and in the surrounding media. However, in this case, extracellular superoxide arose as the result of the disproportionation reaction of menadione and menadiol, resulting from DT-diaphorase reduction of menadione followed by diffusion into extracellular space, to give the menadione semiquinone. Reduction of oxygen resulted in formation of superoxide. 4. For nitrazepam, only intracellular superoxide was generated, resulting from the one-electron reduction of this drug to its corresponding nitro anion free radical. Reaction with oxygen produced superoxide.     

In vitro studies of the phototoxic potential of the antidepressant drugs amitriptyline and imipramine

Amitriptyline and imipramine, two tricyclic antidepressant drugs, have been studied to evaluate their phototoxic potential using various models. Reactive oxygen species production was investigated. A negligible production of singlet oxygen was observed for both compounds whereas a significant production of superoxide anion was noted for amitriptyline in particular. Moderate red blood cell lysis under UVA light (365 nm) was induced in the presence of the two drugs at a concentration of 50 microM. Cellular phototoxicity was investigated on a murine fibroblast cell line (3T3). The two drugs were phototoxic causing cell death at a concentration of 100 microM and a UVA dose in the range of 3.3-6.6 J/cm2. Furthermore, the two drugs photosensitized the peroxidation of linoleic acid, as monitored by the formation of dienic hydroperoxides. The presence of BHA and GSH, two free radical scavengers, significantly reduced the lipid oxidation photoinduced by the drugs, suggesting a predominant involvement of radical species. Finally, the involvement of nucleic acids in the phototoxicity mechanism was also investigated using a pBR322 plasmid DNA as a model.     

Lipid peroxidation and generations of oxygen radicals induced by cephaloridine in renal cortical microsomes of rats

To investigate whether oxygen radicals would be generated by cephaloridine (CER) in the renal cortical microsomes obtained from rats and whether the microsomal lipid peroxidation would be promoted by CER, the microsomes were incubated under a pure oxygen atmosphere in a medium containing the reduced nicotinamide adenine dinucleotide phosphate regenerating system, under various conditions. Generations of superoxide anion and hydrogen peroxide and malondialdehyde formation were all dependent on microsomal protein concentrations, incubation periods and CER concentrations. Scavengers of the microsomal lipid peroxidation induced by CER, (+)-cyanidanol-3, mannitol, sodium benzoate and N-acetyl tryptophan, which are scavengers of hydroxyl free radicals, inhibited the CER-stimulated lipid peroxidation in the microsomes. Histidine, a scavenger of hydroxyl free radicals and singlet oxygen, and alpha-tocopherol, reduced-glutathione and NN'-diphenyl-p-phenylenediamine, the three of which are non-specific antioxidants, also inhibited the CER-stimulated lipid peroxidation in the microsomes. Accordingly, our findings may strongly support that CER generates not only superoxide anions and hydrogen peroxide but also hydroxyl free radicals in the kidney, and these generated oxygen radicals react with the membrane lipids to induce peroxidation and nephrotoxicity.     

Action of xanthine-xanthine oxidase system on microsomal benzo(a)pyrene metabolism in vitro

The effect of superoxide anion-radical and other reactive oxygen species on the metabolism of benzo(a)pyrene was studied with isolated mouse liver microsomes. Reactive oxygen species were generated in vitro by xanthine-xanthine oxidase plus Fe3+ X FeEDTA and benzo(a)pyrene metabolism was followed by reverse-phase high pressure liquid chromatography. The following results were obtained: The reactive oxygen species induced one-electron oxidation of benzo(a)pyrene and increased production of free epoxide as well as protein-binding intermediates. The reactive oxygen species triggered microsomal lipid peroxidation in the presence of Fe3+ X FeEDTA. As a result of microsomal lipid peroxidation a decreased activity of cytochrome P-450, epoxide hydrolase and UDP-glucuronyltransferase was found. It is suggested that active oxygen species changed the balance between bioactivation and conjugation of benzo(a)pyrene metabolites causing accumulation of the epoxide and protein-binding intermediates. The role of iron ions and chelates in this process is discussed.     

Antioxidant effects of albumin-bound sulfur in lipid peroxidation of rat liver microsomes.

The antioxidant potential of albumin-bound sulfur (SBA) was investigated in rat liver microsomes using lipid peroxidation systems in vitro. Sulfur bound to protein is a reduced metabolite which is produced from cystine by gamma-cystathionase. Lipid peroxidation was induced either chemically by ferrous ions and ascorbate or enzymatically by carbon tetrachloride or tert-butyl hydroperoxide as indicated by the increase in thiobarbituric acid reactive substances (TBA-RS) and oxygen consumption. Although the antioxidant effect of SBA was weak on the non-enzymatic lipid peroxidation system, the addition of SBA significantly inhibited TBS-RS formation and oxygen consumption compared with non-treated bovine serum alubumin (BSA) in a microsomal lipid peroxidation system induced enzymatically. The sulfur bound to albumin disappeared during incubation with liver microsomes. However, slight differences in the disappearance were observed depending on whether or not lipid peroxidation was induced in the enzymatic systems. In the CCl4-induced lipid peroxidation system, the cytochrome P-450 level was significantly decreased by the addition of SBA. Therefore, in cytochrome P-450 dependent lipid peroxidation system, the potential effects of sulfur bound to albumin are due to an inhibition of cytochrome P-450 rather than by the oxidation itself caused by radical trapping.     

Rat liver microsomal and nuclear activation of methanol to hydroxymethyl free radicals

Recent studies from other laboratories reported that during methanol intoxication lipid peroxidation and protein oxidation in liver occurred. Further, they detected free radicals-PBN adducts in bile and urine of methanol poisoned rats. In this work, we report the presence in liver microsomes and nuclei of NADPH dependent processes of hydroxymethyl (HMet) radical formation. The detection of HMet radicals was performed by GC/MS of the trimethylsilyl derivatives of the PBN (N-tert-butyl-a-phenylnitrone)-radical adducts. The formation of HMet radicals was observed only under nitrogen, in these in vitro conditions. Formation of formaldehyde from methanol was observed in aerobic incubation mixtures containing either microsomes or nuclei but also under nitrogen using microsomes. The latter process was not inhibited by diphenyleneiodonium while the anaerobic microsomal one producing HMet was strongly inhibited by it. This shows that they are independent processes. Results suggest that both, liver nuclei and microsomes are able to generate free radicals during NADPH-mediated methanol biotransformation.     

Lipid peroxidation as a possible secondary mechanism of sterigmatocystin toxicity.

Sterigmatocystin (Stg), a major secondary metabolite of Aspergillus versicolor and A. nidulans, is the precursor of aflatoxin B1. In this study, male albino rats were treated with Stg-contaminated diet for 30 days, resulting in reduced levels of glutathione, ascorbic acid, and alpha-tocopherol. The activity of catalase in liver was reduced, whereas an increase in the activities of superoxide dismutase and glutathione peroxidase was observed. The levels of cytochrome P450, cytochrome b5, cytochrome b5 reductase, cytochrome c reductase, hydroxyl radical, and hydrogen peroxide formation significantly increased in the Stg- treated rat liver microsomes. Hepatic parenchymal cell injury, necrosis, and Kupffer cells proliferation were noticed in histological sections of liver from animals treated with Stg. Overall results suggest that generation of free radicals imposes depletion of antioxidants. This led to enhanced lipid peroxidation. The observed elevation of hepatic thiobarbituric acid reactive substances appears to originate mainly from the damaged Kupffer cells. As a result, elevated levels of serum marker enzymes were also observed.     

The role of oxygen free radicals and phospholipase A2 in ischemia-reperfusion injury to the liver

The focus of this study was to investigate the influences of enzymatic scavengers of active oxygen metabolites and phospholipase A₂ inhibitor on hepatic secretory and microsomal function during hepatic ischemia/reperfusion. Rats were pretreated with free radical scavengers such as superoxide dismutase (SOD), catalase, deferoxamine and phospholipase A₂ inhibitor such as quinacrine and then subjected to 60 min. no-flow hepatic ischemiain vivo. After 1, 5 hr of reperfusion, bile was collected, blood was obtained from the abdominal aorta, and liver microsomes were isolated. Serum aminotransferase (ALT) level was increased at 1 hr and peaked at 5 hr. The increase in ALT was significantly attenuated by SOD plus catalase, deferoxamine and quinacrine especially at 5 hr of reperfusion. The wet weight-to-dry weight ratio of the liver was significantly increased by ischemia/reperfusion. SOD and catalase treatment minimized the increase in this ratio. Hepatic lipid peroxidation was elevated by ischemia/reperfusion, and this elevation was inhibited by free radical scavengers and quinacrine. Bile flow and cholate output, but not bilirubin output, were markedly decreased by ischemia/reperfusion and quinacrine restored the secretion. Cytochrome P₄₅₀ content was decreased by ischemia/reperfusion and restored by free radical scavengers and quinacrine to the level of that of the sham operated group. Aminopyrine N-demethylase activity was decreased and anilinep-hydroxylase was increased by ischemia/reperfusion. The changes in the activities of the two enzymes were prevented by free radical scavengers and quinacrine. Our findings suggest that ischemia/reperfusion diminishes hepatic secretory functions as well as microsomal drug metabolizing systems by increasing lipid peroxidation, and in addition to free radicals, other factors such as phospholipase A₂ are involved in pathogenes of hepatic dysfunction after ischemia/reperfusion.     

Enhancement of reactive oxygen-dependent mitochondrial membrane lipid peroxidation by the anticancer drug adriamycin

Mitochondrial degeneration is a consistently prominent morphological alteration associated with adriamycin toxicity which may be the consequence of adriamycin-enhanced peroxidative damage to unsaturated mitochondrial membrane lipids. Using isolated rat liver mitochondria as an in vitro model system to study the effects of the anticancer drug adriamycin on lipid peroxidation, we found that NADH-dependent mitochondrial peroxidation--measured by the 2-thiobarbituric acid method--was stimulated by adriamycin as much as 4-fold. Marker enzyme analysis indicated that the mitochondria were substantially free of contaminating microsomes (less than 5%). Lipid peroxidation in mitochondria incubated in KCl-Tris-HCl buffer (pH 7.4) under an oxygen atmosphere was optimal at 1-2 mg of mitochondrial protein/ml and with NADH at 2.5 mM. Malonaldehyde production was linear with time to beyond 60 min, and the maximum enhancement of peroxidation was observed with adriamycin at 50-100 microM. Interestingly, in contrast to its stimulatory effect on NADH-supported mitochondrial peroxidation, adriamycin markedly diminished ascorbate-promoted lipid peroxidation in mitochondria. Superoxide dismutase, catalase, 1,3-dimethylurea, reduced glutathione, alpha-tocopherol and EDTA added to incubation mixtures inhibited endogenous and adriamycin-augmented NADH-dependent peroxidation of mitochondrial lipids, indicating that multiple species of reactive oxygen (superoxide anion radical, hydrogen peroxide and hydroxyl radical) and possibly trace amounts of endogenous ferric iron participated in the peroxidation reactions. In submitochondrial particles freed of endogenous defenses against oxyradicals, lipid peroxidation was increased 7-fold by adriamycin. These observations suggest that some of the effects of adriamycin on mitochondrial morphology and biochemical function may be mediated by adriamycin-enhanced reactive oxygen-dependent mitochondrial lipid peroxidation.     

Stimulation by adriamycin of rat heart and liver microsomal NADPH-dependent lipid peroxidation

Rat liver and heart microsomes catalyze the transfer of single electrons from NADPH to adriamycin forming semiquinone radicals which, in turn, activate molecular oxygen. This process stimulated lipid peroxidation 5- to 7-fold as measured by malonaldehyde formation. Adriamycinaugmented lipid peroxidation was linear with time to 60 min, optimal at 1.0 mg of microsomal protein/ml and pH 7.5, and was proportional to the adriamycin concentration up to 100 μM. An NADPH-generating system was superior to NADPH, and an oxygen atmosphere tripled the rate of peroxidation as compared to air. Nitrogen abolished adriamycin-stimulated peroxidation. Superoxide dismutase, reduced glutathione, α-tocopherol, EDTA, dioxopiperazinylpropane (ICRF-187), and dimethylurea were effective inhibitors of lipid peroxidation. This suggests that Superoxide anion and possibly hydroxyl radical may be formed by the oxidation of the adriamycin semiquinone radical and thus stimulate the peroxidation of microsomal unsaturated fatty acids. Although adriamycin failed to stimulate lipid peroxidation in heart microsomes from control animals, peroxidation was dramatically increased when adriamycin was added to cardiac microsomes from α-tocopherol-deficient rats. Lipid peroxidation in α-tocopheroldeficient liver microsomes was four times greater than in control microsomes with the NADPH-generating system, and adriamycin did not further increase that high rate of peroxidation; however, when NADPH was used as the source of electrons in place of the NADPH-generating system, adriamycin stimulated peroxidation more than 2-fold. These results suggest that microsomal lipid peroxidation may play a role in the cytotoxicity and cardiotoxicity of adriamycin.