Lipid peroxidation and benzo[a]pyrene activation to mutagenic metabolites: in vivo influence of vitamins A, E and C and glutathione in both dietary vitamin A sufficiency and deficiency

Rats fed with either a sufficient-vitamin A or a vitamin A-free diet were pretreated with 750 mg/kg body weight of retinyl palmitate, alpha-tocopherol acetate, ascorbic acid or glutathione. Benzo[a]pyrene (BaP) metabolism and BaP-induced mutagenesis in Salmonella typhimurium TA98 were investigated and related to lipid peroxidation activities in postmitochondrial (S9) liver fraction. The microsomal mixed-function oxidase activities were decreased by vitamin A deficiency and weakly affected by scavenger treatment. The rate of lipid peroxidation of microsomal membranes was unaffected by vitamin A deficiency because of decreased polyunsaturated fatty acids and increased vitamin E contents. However, lipid peroxidation was decreased by pretreatment with fat-soluble vitamins (chiefly vitamin E) and increased by ascorbic acid. Within each experimental group both BaP metabolism and BaP mutagenic activity were closely correlated with the rate of lipid peroxidation. In vitamin A deficiency, the increased BaP metabolism and mutagenicity could be related to a decrease in cytosolic contents of scavengers (vitamin A and glutathione). In Ames test conditions, the free radical pathway became a route for BaP metabolism and thus the BaP activation to mutagenic metabolites is related to the cellular status in free radical scavengers.     

Interplay between lipoic acid and glutathione in the protection against microsomal lipid peroxidation

Reduced glutathione (GSH) delays microsomal lipid peroxidation via the reduction of vitamin E radicals, which is catalyzed by a free radical reductase (Haenen, G.R.M.M. et al. (1987) Arch. Biochem. Biophys. 259, 449-456). Lipoic acid exerts its therapeutic effect in pathologies in which free radicals are involved. We investigated the interplay between lipoic acid and glutathione in microsomal Fe2+ (10 microM)/ascorbate (0.2 mM)-induced lipid peroxidation. Neither reduced nor oxidized lipoic acid (0.5 mM) displayed protection against microsomal lipid peroxidation, measured as thiobarbituric acid-reactive material. Reduced lipoic acid even had a pro-oxidant activity, which is probably due to reduction of Fe3+. Notably, protection against lipid peroxidation was afforded by the combination of oxidized glutathione (GSSG) and reduced lipoic acid. It is shown that this effect can be ascribed completely to reduction of GSSG to GSH by reduced lipoic acid. This may provide a rationale for the therapeutic effectiveness of lipoic acid.     

Microsomal reduction of low-molecular-weight Fe3+ chelates and ferritin: enhancement by adriamycin, paraquat, menadione, and anthraquinone 2-sulfonate and inhibition by oxygen

Reduction of iron is important in promoting xenobiotic-enhanced, microsomal lipid peroxidation, yet there is little evidence that Fe3+ chelates that promote lipid peroxidation can be reduced by the microsomal system. We have shown that rat liver microsomes catalyse NADPH-dependent reduction of Fe3+ without chelator, as well as Fe3+(ADP), Fe3+(ATP), Fe3+(citrate), Fe3+(EDTA), and ferrioxamine in N2. The NADPH oxidation that accompanied Fe3+ reduction was inhibited by CO for all chelates, except Fe3+ (EDTA). This implies that, except for Fe3+ (EDTA), cytochrome P450 was involved in reduction of the complexes. Adriamycin, paraquat, and anthraquinone 2-sulfonate (AQS) enhanced reduction of all the Fe3+ chelates, whereas menadione enhanced reduction only of Fe3+(ADP) and Fe3+(citrate). All the compounds enhanced oxidation of NADPH in the presence or absence of iron. This was not inhibited by CO, and the results are compatible with Fe3+ reduction occurring via the xenobiotic radicals produced by cytochrome P450 reductase. Microsomal reduction of the xenobiotics, except menadione, enabled the reduction and release of iron from ferritin. Fe3+ chelate reduction, both with and without xenobiotic, was inhibited by O2, although it still proceeded in air at 10-20% of the rate in N2. Iron-dependent lipid peroxidation was promoted by ADP and ATP, inhibited 50% by citrate, and completely inhibited by EDTA and desferrioxamine. Of the xenobiotics, only Adriamycin enhanced microsomal lipid peroxidation. These results indicate that the effects of chelators and xenobiotics on Fe3+ reduction do not correlate with lipid peroxidation and, although reduction is necessary, there must be other factors involved.     

The role of iron in oxygen radical mediated lipid peroxidation

The role of iron in the peroxidation of polyunsaturated fatty acids is reviewed, especially with respect to the involvement of oxygen radicals. The hydroxyl radical can be generated by a superoxide-driven Haber-Weiss reaction or by Fenton's reaction; and the hydroxyl radical can initiate lipid peroxidation. However, lipid peroxidation is frequently insensitive to hydroxyl radical scavengers or superoxide dismutase. We propose that the hydroxyl radical may not be involved in the peroxidation of membrane lipids, but instead lipid peroxidation requires both Fe2+ and Fe3+. The inability of superoxide dismutase to affect lipid peroxidation can be explained by the fact that the direct reduction of iron can occur, exemplified by rat liver microsomal NADPH-dependent lipid peroxidation. Catalase can be stimulatory, inhibitory or without affect because H2O2 may oxidize some Fe2+ to form the required Fe3+, or, alternatively, excess H2O2 may inhibit by excessive oxidation of the Fe2+. In an analogous manner reductants can form the initiating complex by reduction of Fe3+, but complete reduction would inhibit lipid peroxidation. All of these redox reactions would be influenced by iron chelation.     

Role of cytochrome P-450 in ochratoxin A-stimulated lipid peroxidation.

The role of cytochrome P-450 in the stimulation of lipid peroxidation by the nephrotoxic mycotoxin ochratoxin A has been investigated. Ochratoxin A was previously shown to markedly stimulate lipid peroxidation in a reconstituted system consisting of phospholipid vesicles, NADPH-cytochrome P-450 reductase, Fe3+, ethylenediaminetetraacetic acid (EDTA), and reduced nicotinamide adenine dinucleotide phosphate (NADPH). We now show that purified cytochrome P-450IIB1 could effectively replace EDTA in stimulating lipid peroxidation suggesting that it could mediate the transfer of electrons from NADPH to Fe3+. Cobalt protoporphyrin is known to cause an extensive and long-lasting depletion of hepatic cytochrome P-450 in rats, and it has been used to evaluate the role of hepatic cytochrome P-450 in xenobiotic metabolism and toxicity. We have observed that microsomes isolated from livers of cobalt protoporphyrin-pretreated rats underwent ochratoxin A-dependent lipid peroxidation much more slowly than control microsomes. Also, the level of ethane exhaled (an index of in vivo lipid peroxidation) on ochratoxin A administration was much lower in cobalt protoporphyrin-pretreated rats than in control rats. Taken together, these results provide evidence for the stimulatory role of cytochrome P-450 in ochratoxin A-induced lipid peroxidation in a reconstituted system and strongly implicate its role in microsomal and in vivo ochratoxin A-induced lipid peroxidation.     

Microsomal lipid peroxidation: the role of NADPH--cytochrome P450 reductase and cytochrome P450

The role of NADPH--cytochrome P450 reductase and cytochrome P450 in NADPH- and ADP--Fe3(+)-dependent lipid peroxidation was investigated by using the purified enzymes and liposomes prepared from either total rat-liver phospholipids or a mixture of bovine phosphatidyl choline and phosphatidyl ethanolamine (PC/PE liposomes). The results suggest that NADPH- and ADP--Fe3(+)-dependent lipid peroxidation involves both NADPH--cytochrome P450 reductase and cytochrome P450. Just as in the case of cytochrome P450-linked monooxygenations, the role of these enzymes in lipid peroxidation may be to provide two electrons for O2 reduction. The first electron is used for reduction of ADP--Fe3+ and subsequent addition of O2 to the perferryl radical (ADP--Fe3(+)-O2-), which then extracts an H atom from a polyunsaturated lipid (LH) giving rise to a free radical (LH.) that reacts with O2 yielding a peroxide free radical (LOO.). The second electron is then used to reduce LOO. to the lipid hydroperoxide (LOOH). In the latter capacity, reduced cytochrome P450 can be replaced by EDTA--Fe2+ or by the superoxide radical as generated through redox cycling of a quinone such as menadione.     

Rabbit liver microsomal lipid peroxidation. The effect of lipid on the rate of peroxidation

Rat and rabbit liver microsomes catalyze an NADPH-cytochrome P-450 reductase-dependent peroxidation of endogenous lipid in the presence of the chelate, ADP-Fe3+. Although liver microsomes from both species contain comparable levels of NADPH-cytochrome P-450 reductase and cytochrome P-450, the rate of lipid peroxidation (assayed by malondialdehyde and lipid hydroperoxide formation) catalyzed by rabbit liver microsomes is only about 40% of that catalyzed by rat liver microsomes. Microsomal lipid peroxidation was reconstituted with liposomes made from extracted microsomal lipid and purified protease-solubilized NADPH-cytochrome P-450 reductase from both rat and rabbit liver microsomes. The results demonstrated that the lower rates of lipid peroxidation catalyzed by rabbit liver microsomes could not be attributed to the specific activity of the reductase. Microsomal lipid from rabbit liver was found to be much less susceptible to lipid peroxidation. This was due to the lower polyunsaturated fatty acid content rather than the presence of antioxidants in rabbit liver microsomal lipid. Gas-liquid chromatographic analysis of fatty acids lost during microsomal lipid peroxidation revealed that the degree of fatty acid unsaturation correlated well with rates of lipid peroxidation.     

NADPH-dependent drug redox cycling and lipid peroxidation in microsomes from human term placenta

1. NADPH-dependent iron and drug redox cycling, as well as lipid peroxidation process were investigated in microsomes isolated from human term placenta. 2. Paraquat and menadione were found to undergo redox cycling, catalyzed by NADPH:cytochrome P-450 reductase in placental microsomes. 3. The drug redox cycling was able to initiate microsomal lipid peroxidation in the presence of micromolar concentrations of iron and ethylenediaminetetraacetate (EDTA). 4. Superoxide was essential for the microsomal lipid peroxidation in the presence of iron and EDTA. 5. Drastic peroxidative conditions involving superoxide and prolonged incubation in the presence of iron were found to destroy flavin nucleotides, inhibit NADPH:cytochrome P-450 reductase and inhibit propagation step of lipid peroxidation. 6. Reactive oxo-complex formed between iron and superoxide is proposed as an ultimate species for the initiation of lipid peroxidation in microsomes from human term placenta as well as for the destruction of flavin nucleotides and inhibition of NADPH:cytochrome P-450 reductase as well as for impairment of promotion of lipid peroxidation under drastic peroxidative conditions.     

Effects of superoxide generated in vitro on glucuronidation of benzo[a]pyrene metabolites by mouse liver microsomes

Glucuronidation of benzo[a]pyrene (B[a]P) metabolites, generated in situ by oxidative pathways, was studied using mouse liver uninduced microsomes. No coupling was evident between UDP-glucuronyltransferase and oxygenation of B[a]P. UDPGA protected microsomal macromolecules against binding of reactive B[a]P metabolites. Superoxide, and other reactive oxygen species decreased both the overall B[a]P metabolism and glucuronidation of some B[a]P metabolic products, and caused more extensive binding to macromolecules; UDPGA was less protective in this condition. Peroxidation of microsomes differentially affected glucuronidation of various metabolites of B[a]P, and of various model substrates, indicating that multiple glucuronyltransferases are involved in the conjugation of hydroxylated metabolites of B[a]P.     

Complement-component-C3-opsonized immunoglobulin G anti-DNA antibodies do not bind effectively to red blood cells unless aggregated on a high-Mr DNA matrix.

The significance of microsomal vitamin E in protecting against the free-radical process of lipid peroxidation was evaluated with the low-level-chemiluminescence technique in microsomal fractions from vitamin E-deficient and control rats. The induction period that normally precedes the ascorbate/ADP/Fe3+-induced lipid peroxidation was taken as reflecting the microsomal vitamin E content and was found to be 5-6-fold decreased in microsomal fractions from vitamin E-deficient rats. Supplementation of microsomal fractions from vitamin E-deficient rats with exogenous vitamin E partially restores the induction period observed in that from control rats. The decrease in chemiluminescence intensity and the increase in the induction period both correlate linearly with the amount of vitamin E added. However, the efficiency of exogenous vitamin E is about 50-fold lower than that exerted by the naturally occurring vitamin E in microsomal membranes. These observations are discussed in terms of the process of re-incorporation of vitamin E into membranes, the experimental model for lipid peroxidation selected, and the method to evaluate lipid peroxidation, namely low-level chemiluminescence.     

A new and suitable reconstructed system for NADPH-dependent microsomal lipid peroxidation

In order to evaluate the O-2 participation in NADPH-dependent microsomal lipid peroxidation, we used reconstructed system which contained detergent-solubilized NADPH-dependent cytochrome P-450 reductase, cytochrome P-450, phospholipid liposomes, NADPH and Fe3+-ADP. Lipid peroxidation, monitored by the formation of thiobarbituric acid-reactive substance, was increased with increasing concentration of detergent-solubilized NADPH cytochrome P-450 reductase, cytochrome P-450 or Fe3+-ADP. Cytochrome P-450-dependent lipid peroxidation was parallel to O-2 generation monitored by chemiluminescence probe with 2-methyl-6-(p-methoxyphenol)-3,7-dihydroimidazo[1,2-a]pyrazin++ +-3-one. Lipid peroxidation was significantly inhibited by superoxide dismutase, but not by catalase or sodium benzoate. The reconstructed system herein described is considered to be very close to NADPH-dependent microsomal lipid peroxidation system.     

Importance of the polyunsaturated fatty acid to vitamin E ratio in the resistance of rat lung microsomes to lipid peroxidation

Rat lung microsomes and liposomes made from isolated lung microsomal lipids were found to be much more resistant to lipid peroxidation than those from liver in both enzymatic and nonenzymatic systems. The polyunsaturated fatty acid (PUFA) content of isolated lung microsomal lipids was 28% of total fatty acids, while liver was 54%. The vitamin E (α-tocopherol) content of isolated lung microsomal lipids was 2.13 nmol/μmol lipid phosphate and that of liver was 0.43. Individually, neither the lower PUFA content nor higher vitamin E levels could account for the resistance of lung microsomal lipids to peroxidation. Distearoyl-L-a-phosphatidylcholine and/or α-tocopherol were added to liver microsomal lipids to achieve different PUFA to vitamin E ratios at PUFA contents of 28% or 54%, and the resulting liposomes were subjected to an NADPH-dependent lipid peroxidation system utilizing cytochrome P450 reductase, EDTA-Fe⁺³, and ADP-Fe⁺³. Liposomes having PUFA to vitamin E ratios less than approximately 250 nmol PUFA/nmol vitamin E were resistant to peroxidation, whereas lipid peroxidation, as evidenced by malondialdehyde production, occurred in liposomes having higher ratios. When lipid peroxidation occurred, 40%–60% of the liposomal vitamin E was irreversibly oxidized. Irreversible oxidation did not occur in the absence of lipid peroxidation. These studies indicated that the low PUFA to vitamin E ratio in lung microsomes and isolated microsomal lipids was sufficient to account for the observed resistance to lipid peroxidation.     

The involvement of iron in lipid peroxidation. Importance of ferric to ferrous ratios in initiation

Intense lipid peroxidation of brain synaptosomes initiated with Fenton's reagent (H2O2 + Fe2+) began instantly upon addition of Fe2+ and preceded detectable OH. formation. Although mannitol or Tris partially blocked peroxidation, concentrations required were 10(3)-fold in excess of OH. actually formed, and inhibition by Tris was pH dependent. Lipid peroxidation also was initiated by either Fe2+ or Fe3+ alone, although significant lag phases (minutes) and slowed reaction rates were observed. Lag phases were dramatically reduced or nearly eliminated, and reaction rates were increased by a combination of Fe3+ and Fe2+. In this instance, lipid peroxidation initiated by optimal concentrations of H2O2 and Fe2+ could be mimicked or even surpassed by providing optimal ratios of Fe3+ to Fe2+. Peroxidation observed with Fe3+ alone was dependent upon trace amounts of contaminating Fe2+ in Fe3+ preparations. Optimal ratios of Fe3+:Fe2+ for the rapid initiation of lipid peroxidation were on order of 1:1 to 7:1. No OH. formation could be detected with this system. Although low concentrations of H2O2 or ascorbate increased lipid peroxidation by Fe2+ or Fe3+, respectively, high concentrations of H2O2 or ascorbate (in excess of iron) inhibited lipid peroxidation due to oxidative or reductive maintenance of iron exclusively in Fe2+ or Fe3+ form. Stimulation of lipid peroxidation by low concentrations of H2O2 or ascorbate was due to the oxidative or reductive creation of Fe3+:Fe2+ ratios. The data suggest that the absolute ratio of Fe3+ to Fe2+ was the primary determining factor for the initiation of lipid peroxidation reactions.     

Mechanism of cobalt (II) ion inhibition of iron-supported phospholipid peroxidation

Co2+ inhibited nonenzymatic iron chelate-dependent lipid peroxidation in dispersed lipids, such as ascorbate-supported lipid peroxidation, but not iron-independent lipid peroxidation. Histidine partially abolished the Co2+ inhibition of the iron-dependent lipid peroxidation. The affinity of iron for phosphatidylcholine liposomes in Fe(2+)-PPi-supported systems was enhanced by the addition of an anionic lipid, phosphatidylserine, and Co2+ competitively inhibited the peroxidation, while the inhibiting ability of Co2+ as well as the peroxidizing ability of Fe(2+)-PPi on liposomes to which other phospholipids, phosphatidylethanolamine, or phosphatidylinositol had been added was reduced. Co2+ inhibited microsomal NADPH-supported lipid peroxidation monitored in terms of malondialdehyde production and the peroxidation monitored in terms of oxygen consumption. The inhibitory action of Co2+ was not associated with iron reduction or NADPH oxidation in microsomes, suggesting that Co2+ does not affect the microsomal electron transport system responsible for lipid peroxidation. Fe(2+)-PPi-supported peroxidation of microsomal lipid liposomes was markedly inhibited by Co2+.     

铝离子对二价铁离子启动的卵磷脂脂质体脂质过氧化的影响

利用化学发光、ＴＢＡ 反应与测量共轭二烯的方法观测了Ａｌ３ ＋ 对Ｆｅ２ ＋ 启动的卵磷脂脂质体脂质过氧化的影响。实验结果显示,在生理ｐＨ 条件下,Ａｌ３ ＋ 对Ｆｅ２ ＋ 启动的脂质过氧化有增强作用,表现为缩短潜伏期和加快脂质过氧化的反应速率, Ａｌ３ ＋ 的增强作用与脂质体中原先存在的过氧化物有关。这可能是因为在脂质体存在的条件下,Ａｌ３ ＋ 加速了Ｆｅ２ ＋ 的氧化,且加速作用与脂质体中原先存在的过氧化物的含量有关;另一方面,Ａｌ３ ＋ 可以引起脂质体的聚集,表现为浊度的增加;测量脂质体上标记的脂肪酸自旋标记物５ － Ｄｏｘｙｌ ｓｔｅａｒｉｃ ａｃｉｄ 的ＥＳＲ 波谱发现： Ａｌ３ ＋ 降低了脂质体的膜脂的流动性。研究表明： Ａｌ３ ＋ 对Ｆｅ２ ＋ 启动的卵磷脂脂质体的过氧化的增强作用可能与Ａｌ３ ＋ 加速了Ｆｅ２ ＋ 的氧化和改变了脂质体的物理状态有关     

Lipid peroxidation and cytotoxicity of Ehrlich ascites tumor cells by ferric nitrilotriacetate

Ferric nitrilotriacetate, which causes in vivo organ injury, induced lipid peroxidation and cell death in Ehrlich ascites tumor cells in vitro. The process was inhibited by butylated hydroxyanisole and enhanced by vitamin C and linolenic acid, indicating a close relationship between cytotoxicity and the lipid peroxidizing ability of Fe3+ NTA. The cytotoxicity was suppressed by glucose and a temperature below 20 degrees C. Lipid peroxidation of Fe3+ NTA-treated cells was greater at 0 degree C than at 37 degrees C, contrary to results with Fe3+ NTA-treated plasma membranes of Ehrlich ascites tumor cell. These results suggested that metabolism and membrane fluidity are important factors in the expression of the Fe3+ NTA-induced cytotoxicity. H2O2 showed a lower cytotoxicity than did Fe3+ NTA but a greater lipid peroxidizing ability. H2O2 appeared to damage the cells less, and was quenched rapidly by cellular metabolism unlike Fe3+ NTA. In transferrin-free medium, Ehrlich ascites tumor cell readily incorporated Fe3+ NTA, and iron uptake was greater than NTA-uptake in Fe3+ NTA-treated cells, suggesting that Ehrlich ascites tumor cell incorporated iron from Fe3+NTA and metabolized it into an inert form such as ferritin.     

Ferric(III) ions inhibits copper(II)/hydrogen peroxide-catalyzing lipid peroxidation in human erythrocyte membranes.

1. Effect of ferric ions (Fe3+) on the lipid peroxidation catalyzed by copper ions (Cu2+) and hydrogen peroxide (H2O2) was studied in human erythrocyte membranes. 2. The formation of thiobarbituric acid-reactive products elicited by CuCl2/H2O2 was inhibited by FeCl3 in a concentration-dependent manner; 0.25 mM FeCl3 were enough to cause 50% inhibition of the formation of peroxides. 3. The inhibitory effect of FeCl3 is not due to competition against Cu2+. 4. FeCl3 inhibited the initiation, but did not inhibit the propagation of Cu2+/H2O2-catalyzing lipid peroxidation. 5. In the heat- or trypsin-treated erythrocyte membranes, FeCl3 had no inhibitory effect on Cu2+/H2O2-catalyzing lipid peroxidation. 6. Sodium azide, an inhibitor of catalase, had no effect on the inhibitory effect of FeCl3. 7. These results suggest that a protein factor(s), which is not catalase, is involved in the inhibition of Cu2+/H2O2-catalyzing lipid peroxidation by Fe3+.     

The consequences of lipid peroxidation in isolated hepatocytes.

Lipid peroxidation was initiated by the addition of either ADP-complexed Fe3+ or cumene hydroperoxide to isolated rat hepatocytes and the resultant biochemical and morphological alterations investigated. As previously observed with microsomes, malonaldehyde formation was associated with the inactivation of glucose-6-phosphatase. Inhibition of microsomal oxidative drug metabolism was correlated with the release and subsequent inactivation of NADPH-cytochrome c reductase, whereas cytochrome P-450 destruction occurred only in the presence of high concentrations of the organic hydroperoxide which were associated with extensive malonaldehyde formation. Under these conditions there were also marked ultrastructural alterations in the hepatocytes which were not apparent after incubation in the presence of iron (less than or equal to 187 muM Fe3+). The latter treatment was, however, associated with moderate biochemical effects such as glucose-6-phosphatase inactivation and increased membrane permeability. The cellular defence system against lipid peroxidation is discussed and it is concluded that the isolated liver cell system provides a valuable tool for the study of lipid peroxidation and its pathological implications.     

Lipid peroxidation in rat liver microsomes. II. Response of hydroperoxide formation to iron concentration

When rat liver microsomes were incubated with NADPH, the major products were hydroperoxides which increased with time indicating that endogenous iron content is able to promote lipid peroxidation. The addition of either 5 microM Fe2+ or Fe3+ ions strongly enhanced the hydroperoxide formation rate. However, due to the hydroperoxide breakdown, hydroperoxide concentration decreased with time in this case. Higher ferrous or ferric iron concentration did not change the situation much, in that both hydroperoxide breakdown and formation were similar to those when NADPH only was present in the incubation medium. After lipid peroxidation, analysis of fatty acids indicated that the highest amount of peroxidized PUFA occurred in the presence of 5 microM of either Fe2+ or Fe3+. This analysis also showed that after 8 min incubation with low iron concentration, PUFA depletion was about 77% of that observed after 20 min, whereas without any iron addition or in the presence of 30 microM of either Fe3+, PUFA decrease was only about 37% of that observed after 20 min. As far as the optimum Fe2+/Fe3+ ratio required to promote the initiation of microsomal lipid peroxidation in rat liver is concerned, the highest hydroperoxide formation was observed with a ratio ranging from 0.5 to 2. These results indicate that microsomal lipid peroxidation induced by endogenous iron is speeded up by the addition of low concentrations of either Fe2+ or Fe3+ ions, probably because free radicals generated by hydroperoxide breakdown catalyze the propagation process. In experimental conditions unfavourable to hydroperoxide breakdown the principal process is that of the initiation of lipid peroxidation.     

Fe2+-supported in vivo lipid peroxidation induced by compounds undergoing redox cycling

Treatment of male mice with the redox cycling compounds nitrofurantoin, paraquat, diquat or menadione failed to elicit in vivo lipid peroxidation as evidenced by ethane exhalation. The first three led to an enhanced ethane production, however, when the animals were pretreated with a low dose of Fe2+. While GSH-depletion by phorone pretreatment alone had no influence on the in vivo lipid peroxidation as evidenced by ethane expiration in the presence of either compound, the combined treatment with phorone, Fe2+ and nitrofurantoin, paraquat or diquat led to a further enhancement of ethane exhalation. These results indicate that redox cycling compounds do not initiate lipid peroxidation by themselves, but are well capable of stimulating the iron-induced LPO.