Identification of radicals formed in the reaction mixtures of rat liver microsomes with ADP, Fe3+ and NADPH using HPLC EPR and HPLC EPR MS

The reaction of rat liver microsomes with Fe(3+), ADP and NADPH was examined using EPR, HPLC-EPR and HPLC-EPR-MS combined use of spin trapping technique. A prominent EPR spectrum (alpha(N) = 1.58 mT and alpha(H)beta = 0.26 mT) was observed in the complete reaction mixture. The EPR spectrum was hardly observed for the complete reaction mixture without rat liver microsomes. The radicals appear to be derived from microsomal components. The EPR spectrum was also hardly observed in the absence of Fe(3+). Addition of some iron chelators such as EDTA, citrate and ADP resulted in the dramatic change in the EPR intensity. Iron ions seem to be essential for this reaction. For the complete reaction mixture with boiled microsomes, a weak EPR spectrum was observed, suggesting that enzymes participate in the reaction. Five peaks were separated on the HPLC-EPR elution profile of the complete reaction mixture of rat liver microsomes with ADP, Fe(3+) and NADPH. The retention times of the peaks 1 to 5 were 19.4, 22.5, 27.3, 29.8 and 31.4 min, respectively. To identify the radical adducts, HPLC-EPR-MS analyses were performed for the three prominent peaks. The HPLC-EPR-MS analyses showed that a new radical adduct, 4-POBN/1-hydroxypentyl radical, in addition to 4-POBN/ethyl radical adducts, forms in a reaction mixture of rat liver microsomes with ADP, Fe(3+) and NADPH.     

Investigating the free radical trapping ability of NXY-059, S-PBN and PBN

The spin trapping ability of the nitrones 2,4-disulphophenyl-N-tert-butyl nitrone (NXY-059), 2-sulphophenyl-N-tert-butyl nitrone (S-PBN) and α-phenyl-N-tert-butyl nitrone (PBN) for both hydroxyl and methanol radicals was investigated using electron paramagnetic resonance (EPR) spectroscopy. The radicals of interest were generated in situ in the spectrometer under constant flow conditions in the presence of each nitrone. The spin adducts formed were detected by EPR spectroscopy. This approach allowed for quantitative comparison of the EPR spectra of the spin adducts of each nitrone. The results obtained showed that NXY-059 trapped a greater number of hydroxyl and methanol radicals than the other two nitrones, under the conditions studied.     

Inhibition of Fe2+- and Fe3+- induced hydroxyl radical production by the iron-chelating drug deferiprone

Deferiprone (L1) is an effective iron-chelating drug that is widely used for the treatment of iron-overload diseases. It is known that in aqueous solutions Fe²⁺ and Fe³⁺ ions can produce hydroxyl radicals via Fenton and photo-Fenton reactions. Although previous studies with Fe²⁺ have reported ferroxidase activity by L1 followed by the formation of Fe³⁺ chelate complexes and potential inhibition of Fenton reaction, no detailed data are available on the molecular antioxidant mechanisms involved. Similarly, in vitro studies have also shown that L1–Fe³⁺ complexes exhibit intense absorption bands up to 800 nm and might be potential sources of phototoxicity. In this study we have applied an EPR spin trapping technique to answer two questions: (1) does L1 inhibit the Fenton reaction catalyzed by Fe²⁺ and Fe³⁺ ions and (2) does UV–Vis irradiation of the L1–Fe³⁺ complex result in the formation of reactive oxygen species. PBN and TMIO spin traps were used for detection of oxygen free radicals, and TEMP was used to trap singlet oxygen if it was formed via energy transfer from L1 in the triplet excited state. It was demonstrated that irradiation of Fe³⁺ aqua complexes by UV and visible light in the presence of spin traps results in the appearance of an EPR signal of the OH spin adduct (TMIO–OH, a(N)=14.15 G, a(H)=16.25 G; PBN–OH, a(N)=16.0 G, a(H)=2.7 G). The presence of L1 completely inhibited the OH radical production. The mechanism of OH spin adduct formation was confirmed by the detection of methyl radicals in the presence of dimethyl sulfoxide. No formation of singlet oxygen was detected under irradiation of L1 or its iron complexes. Furthermore, the interaction of L1 with Fe²⁺ ions completely inhibited hydroxyl radical production in the presence of hydrogen peroxide. These findings confirm an antioxidant targeting potential of L1 in diseases related to oxidative damage.     

Free Radical Metabolism of Alcohols by Rat Liver Microsomes

By using e.s.r. spectroscopy coupled with the spin trapping technique we have detected the formation of free radical intermediates by rat liver microsomes incubated with either ethanol, 2-propanol or 2-butanol in the presence of a NADPH regenerating system and 4-pyridyl-l-oxide-t-butyl nitrone (4-POBN) as spin trap. The e.s.r. spectra have been identified as due to the hydroxyalkyl free radical adducts of 4-POBN.

The free radical formation depends upon the activity of the microsomal monoxygenase system and is blocked by omitting NADP⁺ from the incubation mixture, by anaerobic incubation or by enzyme denaturation. The involvement of hydroxyl radicals (OH) produced through a Fenton-type reaction from endogenously formed hydrogen peroxide is suggested by the opposite effects exerted on the e.s.r. signal intensity by azide and catalase. Consistently, iron chelation by desferrioxamine inhibits the free radical formation, while the supplementation of EDTA-iron increases it by several fold. Inhibitors of cytochrome P₄₅₀-dependent monoxygenase system reduce to various extents the production of free radical intermediates suggesting that reactive oxygen species might be formed at the active site of cytochrome P₄₅₀ where they react with alkyl alcohol molecules.

The data presented support the hypothesis that free radical species are generated during the microsomal metabolism of alcohols and suggest the possibility that ethanol-derived radicals might play a role in the pathogenesis of the liver lesions consequent upon alcoholic abuse.     

Metabolic activation of sulfur mustard leads to oxygen free radical formation

We recently published electron paramagnetic resonance (EPR) spin trapping results that demonstrated the enzymatic reduction of sulfur mustard sulfonium ions to carbon-based free radicals using an in vitro system containing sulfur mustard, cytochrome P450 reductase, NADPH, and the spin trap α-(4-pyridyl-1-oxide)-N-tert-butylnitrone (4-POBN) in buffer (A.A. Brimfield et al., 2009, Toxicol. Appl. Pharmacol. 234:128-134). Carbon-based radicals have been shown to reduce molecular oxygen to form superoxide and, subsequently, peroxyl and hydroxyl radicals. In some cases, such as with the herbicide paraquat, a cyclic redox system results, leading to magnified oxygen free radical concentration and sustained tissue damage. Low mustard carbon radical concentrations recorded by EPR in our in vitro system, despite a robust (4.0mM) sulfur mustard starting concentration, led us to believe a similar oxygen reduction and redox cycling process might be involved with sulfur mustard. A comparison of the rate of mustard radical-POBN adduct formation in our in vitro system by EPR at atmospheric and reduced oxygen levels indicated a sixfold increase in 4-POBN adduct formation (0.5 to 3.0 μM) at the reduced oxygen concentration. That result suggested competition between oxygen and POBN for the available carbon-based mustard radicals. In parallel experiments we found that the oxygen radical-specific spin trap 5-tert-butoxycarbonyl-5-methylpyrroline-N-oxide (BMPO) detected peroxyl and hydroxyl radicals directly when it was used in place of POBN in the in vitro system. Presumably these radicals originated from O(2) reduced by carbon-based mustard radicals. We also showed that reactive oxygen species (ROS)-BMPO EPR signals were reduced or eliminated when mustard carbon radical production was impeded by systematically removing system components, indicating that carbon radicals were a necessary precursor to ROS production. ROS EPR signals were completely eliminated when superoxide dismutase and catalase were included in the complete in vitro enzymatic system, providing additional proof of oxygen radical participation. The redox cycling hypothesis was supported by density functional theory calculations and frontier molecular orbital analysis.     

Spin-trapping studies of hydroxyl radical production involved in lipid peroxidation.

Evidence presented in this report suggests that the hydroxyl radical (OH.), which is generated from liver microsomes is an initiator of NADPH-dependent lipid peroxidation. The conclusions are based on the following observations: 1) hydroxyl radical production in liver microsomes as measured by esr spin-trapping correlates with the extent of NADPH induced microsomal lipid peroxidation as measured by malondialdehyde formation; 2) peroxidative degradation of arachidonic acid in a model OH · generating system, namely, the Fenton reaction takes place readily and is inhibited by thiourea, a potent OH · scavenger, indicating that the hydroxyl radical is capable of initiating lipid peroxidation; 3) trapping of the hydroxyl radical by the spin trap, 5,5-dimethyl-1-pyrroline-1-oxide prevents lipid peroxidation in liver microsomes during NADPH oxidation, and in the model system in the presence of linolenic acid. The possibility that cytochrome P-450 reductase is involved in NADPH-dependent lipid peroxidation is discussed. The optimal pH for the production of the hydroxyl radical in liver microsomes is 7.2. The generation of the hydroxyl radical is correlated with the amount of microsomal protein, possibly NADPH cytochrome P-450 reductase. A critical concentration of EDTA (5 × 10^?5m) is required for maximal production of the hydroxyl radical in microsomal lipid peroxidation during NADPH oxidation. High concentrations of Fe²⁺-EDTA complex equimolar in iron and chelator do not inhibit the production of the hydroxyl radical. The production of the hydroxyl radical in liver microsomes is also promoted by high salt concentrations. Evidence is also presented that OH radical production in microsomes during induced lipid peroxidation occurs primarily via the classic Fenton reaction.     

Spin trapping and its application in the study of lipid peroxidation and free radical production with liver microsomes.

Lipid peroxidation in microsomes was studied using a spin-trapping technique. Free radical adducts of phenyltertiarybutylnitrone (PBN) were produced as detected by electron spin resonance during induced lipid peroxidation of microsomes with a system consisting of NADPH, Fe²⁺, and pyrophosphate. The adducts were identified as intermediates of the substrates added to the microsomal system and not OH · or HO₂ radicals. The production of the adduct parallels the NADPH-dependent formation of malondialdehyde (MDA). Analyses of the electron spin resonance hyperfine splitting constants allowed in some instances identification of the adducts. Purified preparations of cytochrome P-450 mimic the results of the microsomes. The carcinogens dimethyl and diethylnitrosoamine were metabolized in this system yelding reactive free radicals and free NO, suggesting an alternate mechanism for the activity of these compounds as ultimate carcinogens.     

Spin trapping of free radical species produced during the microsomal metabolism of ethanol

Liver microsomes incubated with a NADPH regenerating system, ethanol and the spin trapping agent 4-pyridyl-1-oxide-t-butyl nitrone (4-POBN) produced an electron spin resonance (ESR) signal which has been assigned to the hydroxyethyl free radical adduct of 4-POBN by using 13C-labelled ethanol. The free radical formation was dependent upon the activity of the microsomal monoxygenase system and increased following chronic feeding of the rats with ethanol. The production of hydroxyethyl free radicals was stimulated by the addition of azide, while catalase and OH. scavengers decreased it. This suggested that hydroxyl radicals (OH.) produced in a Fenton-type reaction from endogenously formed hydrogen peroxide were involved in the free radical activation of ethanol. Consistently, the supplementation of iron, under various forms, also increased the intensity of the ESR signal which, on the contrary, was inhibited by the iron-chelating agent desferrioxamine. Microsomes washed with a solution containing desferrioxamine and incubated in a medium treated with Chelex X-100 in order to remove contaminating iron still produced hydroxyethyl radicals, although at a reduced rate. Under these conditions the free radical formation was apparently independent from the generation of OH. radicals, whereas addition of cytochrome P-450 inhibitors decreased the hydroxyethyl radical formation, suggesting that a cytochrome P-450-mediated process might also be involved in the activation of ethanol. Reduced glutathione (GSH) was found to effectively scavenge the hydroxyethyl radical, preventing its trapping by 4-POBN. The data presented suggest that ethanol-derived radicals could be generated during the microsomal metabolism of alcohol probably through two different pathways. The detection of ethanol free radicals might be relevant in understanding the pathogenesis of the liver lesions which are a consequence of alcohol abuse.     

Cloning and characterization of the rat TIS11 gene

Pirfenidone (Pf), a new broad-spectrum anti-fibrotic agent, is known to offer protection against lung fibrosis in vivo in laboratory animals, and against mitogenesis and collagen formation by human lung fibroblasts in vitro. Because reactive oxygen species are thought to be involved in these events, we investigated the mechanism(s) by which Pf ameliorates oxidative stress and its effects on NADPH-dependent lipid peroxidation. Pf has been shown to cause inhibit NADPH-dependent lipid peroxidation in sheep liver microsomes in a dose-dependent manner. The concentration of Pf required to cause 50% inhibition of lipid peroxidation was ~ 6 mM. Pf was found to be ineffective as a superoxide radical scavenger. Pf was also ineffective in decomposing H₂O₂ and chelating iron. In deoxyribose degradation assays, Pf was a potent scavenger of hydroxyl radicals with a rate constant of 5.4 × 10⁹ M^-1 sec^-1. EPR spectroscopy in combination with spin trapping techniques, using a Fenton type reaction and DMPO as a spin-trapping agent, Pf scavenged hydroxyl radicals in a dose-dependent manner. The concentration of Pf required to inhibit 50% signal height was ~ 2.5 mM. Because iron was used in the Fenton reaction, the ability of Pf in chelating iron was verified in a fluorescent competitive assay using calcein as the fluorescent probe. Pf up to 10 mM concentration was ineffective in chelating either Fe²⁺ or Fe³⁺ in this system. We propose that Pf exerts its beneficial effects, at least in part, through its ability to scavenge toxic hydroxyl radicals.     

Oxygen Radical Formation in Well-Washed Rat Liver Microsomes: Spin Trapping Studies

The generation of hydroxyl radicals by rat liver microsomes was monitored by spin trapping with 5, 5-dimethylpyrroline N-oxide (DMPO). The results confirm and extend previous data which demonstrated that hydroxyl radicals are produced by microsomes in the presence of NADPH and O₂, and without the exogenous addition of iron. No EPR signals could be detected unless catalase activity which was associated with the microsomes could be substantially diminished. Addition of azide was the most effective means of eliminating catalase activity, but azide also reacted rapidly with hydroxyl radicals, forming azidyl radicals which were in turn trapped by DMPO. Extensive washing and preincubation of microsomes with 3-amino-1, 2,4-triazole in the presence of H₂O₂ were evaluated as alternative methods of decreasing the catalase contamination of microsomes. Although neither method completely eliminated microsomal catalase activity, addition of azide was no longer necessary for hydroxyl radical detection with DMPO. When highly washed microsomal preparations were tested, weak signals of the superoxide radical adduct of DMPO could also be detected. These data indicate that the sensitivity of spin trapping in microsomal systems can be improved substantially when care is taken to eliminate cytosolic contaminants such as catalase.     

Trace transition metal-catalyzed reactions in the microsomal metabolism of alkyl hydrazines to carbon-centered free radicals.

Radical production from alkyl hydrazines (i.e. phenelzine and benzylhydrazine) in rat liver microsomes has been proposed to occur via cytochrome P-450-catalyzed one-electron oxidation followed by beta-scission of an alkyl radical. In microsomes treated with phenelzine (2-phenylethylhydrazine), NADPH, and the spin trap alpha-(4-pyridyl 1-oxide)-N-tert-butylnitrone (4-POBN), the 4-POBN/2-phenylethyl radical adduct was detected by electron paramagnetic resonance spectroscopy. The addition of catalase and superoxide dismutase resulted in a 28.5 and 24% decrease in radical production, respectively. The concentration of the 4-POBN/2-phenylethyl radical adduct decreased significantly in the presence of metal chelators, i.e. EDTA, diethylenetriaminepentaacetic acid (DTPA), or deferoxamine mesylate. When phenelzine was incubated with deferoxamine mesylate-washed microsomes and NADPH in Chelex-treated incubation buffer, no significant radical adduct formation was detected. Addition of iron-chelator complexes (either Fe(3+)-DTPA or Fe(3+)-EDTA) greatly stimulated production of the 4-POBN/2-phenylethyl radical adduct in this system. These results show that the 2-phenylethyl radical produced from phenelzine in a microsomal system arises via a trace transition metal-catalyzed reaction. This reaction may occur through oxidation of phenelzine by the hydroxyl radical, which has also been spin-trapped with 4-POBN in this system.     

Nitrofuran enhancement of microsomal electron transport, superoxide anion production and lipid peroxidation

Addition of nifurtimox (a nitrofuran derivative used for the treatment of Chagas' disease) to rat liver microsomes produced an increase of (a) electron flow from NADPH to molecular oxygen, (b) generation of both superoxide anion radical (O₂^?) and hydrogen peroxide, and (c) lipid peroxidation. The nifurtimox-stimulated NADPH oxidation was greatly inhibited by NADP⁺ and p-chloromercuribenzoate, and to a lesser extent by SKF-525-A and metyrapone. These inhibitions reveal the function of both the NADPH-cytochrome P-450 (c) reductase and cytochrome P-450 in nifurtimox reduction. Superoxide dismutase, catalase (in the presence of superoxide dismutase), and hydroxyl radical scavengers (mannitol, 5,5-dimethyl-1-pyrroline-1-oxide) inhibited the nifurtimox-stimulated NADPH oxidation, in accordance with the additional operation of a reaction chain including the hydroxyl radical. Further evidence supporting the role of superoxide anion and hydroxyl radicals in the nifurtimox-induced NADPH oxidation resulted from the effect of specific inhibitors on NADPH oxidation by O₂^? (generated by the xanthine oxidase reaction) and by OH. (generated by an iron chelate or the Fenton reaction). Production of O₂^? by rat kidney, testes and brain microsomes was significantly stimulated by nifurtimox in the presence of NADPH. It is postulated that enhanced formation of free radicals is the basis for nifurtimox toxicity in mammals, in good agreement with the postulated mechanism of the trypanocide effect of nifurtimox on Trypanosoma cruzi.     

Degradation of DMPO Adducts from Hydroxyl and 1-Hydroxyethyl Radicals by Rat Liver Microsomes

Hydroxyl and 1-hydroxyethyl radical adducts of 5, 5-dimethylpyrroline N-oxide (DMPO) were prepared by photolysis, and mechanisms for loss of their EPR signals in rat liver microsomal suspensions were evaluated. Rates of NADPH-dependent EPR signal loss were more rapid in phosphate buffer than in Tris buffer. Addition of superoxide dismutase (SOD) partially protected the adducts when Tris was used as a buffer, but was relatively ineffective in the presence of phosphate. The ferrous iron chelator bathophenanthrolene partially protected the spin adducts in the presence and absence of phosphate, but complete protection was observed when SOD was also added. The spin adducts were unstable in the presence of Fe⁺² and K₃Fe(CN)₆, but Fe⁺³ alone had little effect on the EPR signals. The data are consistent with two mechanisms for microsomal degradation of DMPO spin adducts under these conditions. Microsomes form superoxide in the presence of oxygen and NADPH, which attacks these DMPO spin adducts directly. The spin adducts are also degraded in the presence of Fe⁺², and phosphate stimulates this iron-dependent destruction of DMPO spin adducts.     

Evidence of in vivo Free Radical Generation by Spin Trapping with α-Phenyl N-Tert-Butyl Nitrone During Ischemia/Reperfusion in Rabbit Kidneys

By using α-phenyl N-tert-butyl nitrone (PBN) as spin trap molecule and the electron paramagnetic resonance (EPR) technique, we obtained the first direct evidence of in vivo intervention of free radicals during an ischemia (50 minutes) reperfusion phenomenon in kidney of an intact rabbit.

An EPR signal (triplet of doublets) characterized by coupling constants a_N = 14.75–15 G and a^H_s = 2.5–3 G was detected in blood samples. The signal was consistent with a nitroxyl-radical adduct resulting from the spin trapping by PBN of either oxygen-or carbon-centered radicals. Control experiments indicated that the EPR signal was not due to a toxic effect of the spin trap molecule.     

Identification of a radical formed in the reaction mixture of rat brain homogenate with a ferrous ion/ascorbic acid system using HPLC–EPR and HPLC–EPR–MS

Identification of a free radical is performed for the reaction mixture of rat brain homogenate with a ferrous ion/ascorbic acid system using EPR, high performance liquid chromatography–electron paramagnetic resonance spectrometry (HPLC–EPR) and high performance liquid chromatography–electron paramagnetic resonance–mass spectrometry (HPLC–EPR–MS). EPR measurements of the reaction mixtures showed prominent signals with hyperfine coupling constants (α^N = 1.58 mT and α^Hβ = 0.26 mT). No EPR spectrum was detectable without rat brain homogenate, suggesting that the radical is derived from rat brain homogenate. An HPLC–EPR analysis of the reaction mixture showed a peak with retention time of 33.7 min. An HPLC–EPR–MS analysis of the peak gave two ions at m/z 224 and 137, suggesting that α-(4-pyridyl-1-oxide)-N-tert-butylnitrone (4-POBN)/ethyl radical adduct forms in the reaction mixture.     

An NADPH-induced change in lipid bilayer of rat liver microsomes as observed by spin-labeled phosphatidylcholine.

Lipid bilayer of rat liver microsomes was spin-labeled by incubating with liposomes of 1-acyl 2-(12-doxylstearoyl) glycero-3-phosphorylcholine. When NADPH was added to the labeled microsomes, there appeared a rapidly tumbling component of spin label in the EPR spectrum. NADH was less effective than NADPH. The appearance of the sharp signal was prevented under anaerobic conditions or in the presence of either carbon monoxide, phenyl isocyanide or cytochrome $\text{c}$. The appearance of the rapidly tumbling component in the EPR spectrum was found to be due to the release of spin moiety from the membrane into the aqueous phase. That the release was associated with superoxide anion formation or with lipid peroxidation is unlikely, since 1) superoxide dismutase had little effect, 2) addition of either α-tocopherol or EDTA did not inhibit the release. These observations suggest that electron transfer from NADPH to oxygen $\text{via}$ cytochrome P-450 system induces a physical perturbation in the lipid bilayer resulting in the release of its component into the aqueous phase.     

HTHQ (1-O-hexyl-2,3,5-trimethylhydroquinone), an anti-lipid-peroxidative compound: its chemical and biochemical characterizations

Recently, it has become apparent that reactive oxygen species (ROS) play many important roles in biological systems. For example, relationships between many diseases, such as cancer, cardiac infarction and arteriosclerosis, and ROS have been found. It is also well known that anti-oxidative agents scavenge ROS in biological systems, which in turn prevents ROS-related diseases. In our previous efforts to develop effective anti-oxidative compounds, we found that 1-O-hexyl-2,3,5-trimethylhydroquinone (HTHQ), which is a hydroquinone monoalkyl ether, is a potent anti-oxidative agent. Here, the scavenging activities of HTHQ against ROS, such as superoxide anion radicals, hydroxyl radicals, t-butyl peroxyl radicals and singlet oxygens, were examined by the ESR (electron spin resonance)-spin trapping method. Among ROS, HTHQ scavenged t-butyl peroxyl radicals most effectively (IC₅₀=0.31±0.04 mM), showing approximately twice the activity of a well-known lipophilic anti-oxidant, d,l-α-tocopherol (IC₅₀=0.67±0.06 mM), as measured by IC₅₀ values defined as the 50% inhibition concentration of the generated ROS. In addition, a relatively stable ESR spectrum of free radicals due to HTHQ was observed during the reaction of HTHQ and t-butyl peroxyl radicals, indicating a direct reaction of HTHQ and t-butyl peroxyl radicals. The free radicals due to HTHQ were more stable than those derived from d,l-α-tocopherol under the same conditions examined. On the basis of these results, we evaluated anti-lipid-peroxidative activity of HTHQ in three systems involving micelles, liposomes and rat liver microsomes. HTHQ exhibited a similar anti-oxidative activity to that of d,l-α-tocopherol against lipid peroxidation in linolate micelles initiated by addition of Fe²⁺. On the other hand, HTHQ exhibited approximately 4.8-fold higher anti-lipid-peroxidation activity than that of d,l-α-tocopherol against the peroxidation in phosphatidylcholine liposomes initiated by addition of Fe²⁺. Furthermore, HTHQ scavenged the lipid peroxides at a rate approximately 150 times higher than that of d,l-α-tocopherol against Fe³⁺-ADP-induced lipid peroxidation in rat liver microsomes, indicating that the anti-lipid-peroxidation activity of HTHQ might be substantially elevated in biological systems in comparison with that of d,l-α-tocopherol. Based on these results, we suggest that HTHQ reacts directly with peroxyl radicals, such as t-butyl peroxyl radicals and peroxides of linolate micelles, liposomes and microsomes, by scavenging them to form stable free radicals. The resulting free radicals are presumed to be reduced by several reducing mechanisms in biological systems similarly to those of d,l-α-tocopherol, and then the lipid-peroxidation reactions will be terminated. In conclusion, HTHQ was found to be a potent anti-lipid-peroxidative compound and its anti-oxidation activity to be extremely elevated in biological systems, such as that of liver microsomes via the generation of stable free radicals. We propose that HTHQ is a potent anti-oxidative agent for use in future treatments for lipid-peroxide relevant diseases.     

The mechanism of liver microsomal lipid peroxidation

In the presence of Fe³⁺ and complexing anions, the peroxidation of unsaturated liver microsomal lipid in both intact microsomes and in a model system containing extracted microsomal lipid can be promoted by either NADPH and NADPH : cytochrome c reductase or by xanthine and xanthine oxidase. Erythrocuprein effectively inhibits the activity promoted by xanthine and xanthine oxidase but produces much less inhibition of NADPH-dependent peroxidation. The singlet-oxygen trapping agent, 1,3-diphenylisobenzofuran, had no effect on NADPH-dependent peroxidation but strongly inhibited the peroxidation promoted by xanthine and xanthine oxidase. NADPH-dependent lipid peroxidation was also shown to be unaffected by hydroxyl radical scavengers.. The addition of catalase had no effect on NADPH-dependent lipid peroxidation, but it significantly increased the rate of malondialdehyde formation in the reaction promoted by xanthine and xanthine oxidase. These results demonstrate that NADPH-dependent lipid peroxidation is promoted by a reaction mechanism which does not involve either superoxide, singlet oxygen, HOOH, or the hydroxyl radical. It is concluded that NADPH-dependent lipid peroxidation is initiated by the reduction of Fe³⁺ followed by the decomposition of hydroperoxides to generate alkoxyl radicals. The initiation reaction may involve some form of the perferryl ion or other metal ion species generated during oxidation of Fe²⁺ by oxygen.     

New heteroaryl nitrones with spin trap properties: Identification of a 4-furoxanyl derivative with excellent properties to be used in biological systems

A new series of heteroaryl nitrones, 1–7, bearing furoxanyl and thiadiazolyl moieties, were evaluated for their free radical-trapping properties. The physicochemical characterization by electron paramagnetic resonance (EPR) demonstrated its capability to trap and stabilize oxygen-, carbon-, sulfur-, and nitrogen-centered free radicals. The 4-furoxanyl nitrone 3 (FxBN), α(Z)-(3-methylfuroxan-4-yl)-N-tert-butylnitrone, showed appropriate solubility in aqueous solution and taking into account that this physicochemical property is very important for biological applications, we studied it deeply in terms of its trapping and kinetic behaviors. For this, kinetic studies of the hydroxyl adduct decay gave rate constants k_ST of 1.22 × 10¹⁰ dm³ mol^?1 s^?1 and half-live up to 7200 s at physiological pH, without any artifactual signals. The ability of FxBN to directly traps and stabilizes superoxide free radical, with a half-life of 1620 s at physiological pH, was also demonstrated. Besides, FxBN-hydroxyl and -superoxide adducts exhibited distinct and characteristic EPR spectral patterns. Finally, we confirmed the ability of FxBN to act as spin trap in a specific biological system, that is, in the free radical production of experimental anti-trypanosomatid drugs using Trypanosoma cruzi microsomes as biological system. Moreover, previous observations of low FxBN toxicity transform it in a good candidate for in vivo spin trapping.     

Hydroxyl Radicals are Generated by Hepatic Microsomes During Nadph Oxidation: Relationship to Ethanol Metabolism

Ethanol is metabolized to acetaldehyde by hepatic microsomes in a reaction that requires cytochrome P-450, and a role for hydroxyl radicals has been implicated in this process. However, previous spin trapping experiments have failed to demonstrate the production of hydroxyl radicals by liver microsomes unless iron or other metal catalysts have been added. The spin trapping experiments described in this report provide unambiguous evidence that liver microsomes form hydroxyl radicals during oxidation of NADPH, that the addition of exogenous iron is unnecessary for this process, and that hydroxyl radicals participate in the metabolism of ethanol. Liver microsomes are known to metabolize ethanol to the 1-hydroxyethyl radical, and our experimental data support the conclusion that a significant part of the production of the 1-hydroxethyl radical occurs as a consequence of hydroxyl radical attack on ethanol. Lack of previous observation of microsomal hydroxyl radical production in spin trapping experiments is shown to be related to the contamination of the microsomes with catalase.