DNA strand scission by the nephrotoxin [2,2′-bipyridine]-3,3′,4,4′-tetrol-1,1′-dioxide and related compounds in the presence of iron

The capacity of non-illuminated nephrotoxin orellanine ([2,2′-bipyridine]-3,3′,4,4′-tetrol-1,1′-dioxide) to induce DNA damage in the presence of ferrous iron and dioxygen has been evaluated. Maximal single-strand breaks in plasmid DNA were obtained with a metal to ligand ratio 1:3. Instantaneous oxidation of Fe²⁺ in presence of orellanine under air was responsible for oxy-radical production concomitant to a stable ferric complex Fe(III)Or₃ formation, leading to oxidative DNA breakage at physiological pH. DNA damage was lowered in the presence of SOD and catalase or DMSO, indicating a set of reactions that leads to oxyradical generation. Iron chelators such as DTPA and EDTA had no protecting effect, Desferal slightly protected. GSH acted as an oxy-radical scavenger, whereas cysteine induced stronger damage.

Closely related bipyridine compounds were also studied in presence of Fe²⁺ and O₂ using a combination of spin-trapping and DNA-nicking experiments, none of which were able to chelate iron and induce damage at pH 7. Both catecholic moieties and aminoxide groups are required for observing breakage at physiological pH.     

DNA Single Strand Breakage by H2O2 and Ferric or Cupric Ions: Its Modulation by Histidine

The role of histidine on DNA breakage induced by hydrogen peroxide (H₂O₂) and ferric ions or by H₂O₂ and cupric ions was studied on purified DNA. L-histidine slightly reduced DNA breakage by H₂O₂ and Fe³⁺ but greatly inhibited DNA breakage by H₂O₂ and Cu²⁺. However, only when histidine was present, the addition of EDTA to H₂O₂ and Fe³⁺ exhibited a bimodal dose response curve depending on the chelator metal ratio. The enhancing effect of histidine on the rate of DNA degradation by H₂O₂ was maximal at a chelator metal ratio between 0.2 and 0.5, and was specific for iron. When D-histidine replaced L-histidine, the same pattern of EDTA dose response curve was observed. Superoxide dismutase greatly inhibited the rate of DNA degradation induced by H₂O₂, Fe³⁺, EDTA and L-histidine involving the superoxide radical.

These studies suggest that the enhancing effect of histidine on the rate of DNA degradation by H₂O₂ and Fe³⁺ is mediated by an oxidant which could be a ferrous-dioxygen-ferric chelate complex or a chelate-ferryl ion.     

Oxygen Toxicity. The Influence of Adenine-Nucleotides and Phosphate on Fe2+ Autoxidation

Fecl₂, in Na phosphate buffer autoxidizes forming active oxygen species which damage deoxyribose. Di-and triphosphate adenine-nucleotides inhibit both Fe²⁺ autoxidation and deoxyribose damage in Na phosphate buffer pH 7.4. The inhibition is related to the number of charges of the adenine-nucleotide molecule: ATP at pH 7.4 is a better inhibitor than ADP; at a pH (6.5) close to the pK's of the third and fourth charge of ADP and ATP, ADP inhibition is greatly decreased whereas ATP inhibition is slightly affected. The extent of ATP inhibition of Fe²⁺ autoxidation depends both on ATP/Mg²⁺ and ATP/Fe²⁺ ratios in the reaction mixture. Formation of a Fe²⁺ -nucleotide complex appears to be the mechanism through which ATP and ADP inhibit autoxidation and thus the generation of active oxygen species. These findings are discussed in relation to physiological and pathological fluctuations of nucleotide concentrations.     

Studies in bioluminescence IV. Properties of luciferin from Pholas dactylus

Light could be obtained by the addition of Fe²⁺ to purified luciferin from Pholas dactylus in the absence of luciferase. The total light emitted was proportional to the concentration of luciferin used. The characteristics of this nonenzymic emission correspond to those of the fast reaction previously described. It may have a physiological importance since iron is present in the luciferin. The injection of Fe²⁺ alone was not sufficient; the presence of a complexing agent such as phosphate or CN⁻ or EDTA was also necessary. Light emission could also be obtained by the addition of H₂O₂, in the presence of Fe²⁺, to luciferin. It has been demonstrated that, for a given amount of luciferin, the total light emitted by the action of varying ratios of Fe²⁺ and luciferase is constant.     

Protection by tropolones against H2O2-induced DNA damage and apoptosis in cultured Jurkat cells

Tropolones, the naturally occurring compounds responsible for the durability of heartwood of several cupressaceous trees, have been shown to possess both metal chelating and antioxidant properties. However, little is known about the ability of tropolone and its derivatives to protect cultured cells from oxidative stress-mediated damage. In this study, the effect of tropolones on hydrogen peroxide-induced DNA damage and apoptosis was investigated in cultured Jurkat cells. Tropolone, added to the cells 15 min before the addition of glucose oxidase, provided a dose dependent protection against hydrogen peroxide induced DNA damage. The IC₅₀ value observed was about 15 μM for tropolone. Similar dose dependent protection was also observed with three other tropolone derivatives such as trimethylcolchicinic acid, purpurogallin and β-thujaplicin (the IC₅₀ values were 34, 70 and 74 μM, respectively), but not with colchicine and tetramethyl purpurogallin ester. Hydrogen peroxide-induced apoptosis was also inhibited by tropolone. However, in the absence of exogenous H₂O₂ but in the presence of non-toxic concentrations of exogenous iron (100 μM Fe³⁺), tropolone dramatically increased the formation of single strand breaks at molar ratios of tropolone to iron lower than 3 to 1, while, when the ratio increased over 3, no toxicity was observed. In conclusion, the results presented in this study indicate that the protection offered by tropolone against hydrogen peroxide-induced DNA damage and apoptosis was due to formation of a redox-inactive iron complex, while its enhancement of iron-mediated DNA damage at ratios of [tropolone]/[Fe³⁺] lower than 3, was due to formation of a lipophilic iron complex which facilitates iron transport through cell membrane in a redox-active form.     

Self-reduction of the iron(III)-doxorubicin complex

The Fe³⁺-doxorubicin complex undergoes reactions that suggest that the complex self-reduces to a ferrous oxidized-doxorubicin free radical species. The Fe³⁺-doxorubicin system is observed to reduce ferricytochrome c, consume O₂ and react with 2,2′-bipyridine. Bipyridine acts as a “ferrous ion scavenger” as it reacts with the ferrous ion produced by Fe³⁺-doxorubicin self-reduction. In the absence of O₂, a ferrous doxorubicin complex accumulates. In the presence of oxygen, Fe²⁺ recycles back to Fe³⁺. The rates of these reactions were measured and the Fe³⁺-doxorubicin self-reduction was determined to be the rate-determining step. The Fe³⁺-doxorubicin induced inactivation of cytochrome c oxidase and NADH cytochrome c reductase on beef heart submitochondrial particles occurs at a rate similar to Fe³⁺-doxorubicin self-reduction. Thus the rate at which damage to these mitochondrial enzymes occurs may be controlled by a nonezymatic Fe³⁺-doxorubicin self-reduction.     

The lactate-dependent enhancement of hydroxyl radical generation by the Fenton reaction

The effect of lactic acid (lactate) on Fenton based hydroxyl radical (^·OH) production was studied by spin trapping, ESR, and fluorescence methods using DMPO and coumarin-3-carboxylic acid (3-CCA) as the ^·OH traps respectively. The ^·OH adduct formation was inhibited by lactate up to 0.4mM (lactate/iron stoichiometry = 2) in both experiments, but markedly enhanced with increasing concentrations of lactate above this critical concentration. When the H₂O₂ dependence was examined, the DMPO-OH signal was increased linearly with H₂O₂ concentration up to 1 mM and then saturated in the absence of lactate. In the presence of lactate, however, the DMPO-OH signal was increased further with higher H₂O₂ concentration than 1 mM, and the saturation level was also increased dependent on lactate concentration. Spectroscopic studies revealed that lactate forms a stable colored complex with Fe³⁺ at lactate/Fe³⁺ stoichiometry of 2, and the complex formation was strictly related to the DMPO-OH formation. The complex formation did not promote the H₂O₂ mediated Fe³⁺ reduction. When the Fe³⁺-lactate (1:2) complex was reacted with H₂O₂, the initial rate of hydroxylated 3-CCA formation was linearly increased with H₂O₂ concentrations. All the data obtained in the present experiments suggested that the Fe³⁺-lactate (1:2) complex formed in the Fenton reaction system reacts directly with H₂O₂ to produce additional ^·OH in the Fenton reaction by other mechanisms than lactate or lactate/Fe³⁺ mediated promotion of Fe³⁺/Fe²⁺ redox cycling.     

Iron (III) Stimulation of Lipid Hydroperoxide-Dependent Lipid Peroxidation

In an experimental system where both Fe²⁺ autoxidation and generation of reactive oxygen species is negligible, the effect of FeCl₂ and FeCl₃ on the peroxidation of phosphatidylcholine (PC) liposomes containing different amounts of lipid hydroperoxides (LOOH) was studied; Fe²⁺ oxidation, oxygen consumption and oxidation index of the liposomes were measured. No peroxidation was observed at variable FeCl₂/FeCl₃ ratio when PC liposomes deprived of LOOH by triphenyl-phosphine treatment were utilized. By contrast, LOOH containing liposomes were peroxidized by FeCl₂. The FeCl₂ concentration at which Fe²⁺ oxidation was maximal, defined as critical Fe²⁺ concentration [Fe²⁺]*, depended on the LOOH concentration and not on the amount of PC liposomes in the assay. The LOOH-dependent lipid peroxidation was stimulated by FeCl₃, addition; the oxidized form of the metal increased the average length of radical chains, shifted to higher values the [Fe²⁺]* and shortened the latent period. The iron chelator KSCN exerted effects opposite to those exerted by FeCl₃ addition. The experimental data obtained indicate that the kinetics of LOOH-dependent lipid peroxidation depends on the Fe²⁺/Fe³⁺ ratio at each moment during the time course of lipid peroxidation. The results confirm that exogenously added FeCl₃ does not affect the LOOH-independent but the LOOH-deendent lipid peroxidation; and suggest that the Feg, endogenously generated exerts a major role in the control of the LOOH-dependent lipid peroxidation.     

Peroxidase-Mediated Oxidation, a Possible Pathway for Activation of the Fungal Nephrotoxin Orellanine and Related Compounds. ESR and Spin-Trapping Studies

Orellanine is the tetrahydroxylated and di-N-oxidized bipyridine toxin extracted from several Cortinarius mushrooms among them C. orellanus. The pathogenic mechanism involved in the C. orellanus-poisoning by orellanine leading to kidney impairment is not yet fully understood until now. Electron spin resonance (ESR) spectroscopy has been used to study the activation of orellanine by horseradish peroxidase/H₂O₂ system at physiological pH. Evidence for a one-electron oxidation of the toxin by this enzymatic system to an ortho-semiquinone radical intermediate is presented.

The orellanine ortho-semiquinone generated by the peroxidase/H₂O₂ system abstracts hydrogen from glutathione, generating the glutathionyl radical which is spin-trapped by 5,5'-dimethyl-1-pyrroline N-oxide (DMPO) and subsequently detected by ESR spectroscopy. Similarly, the ortho-semiquinone abstracts hydrogen from ascorbic acid to generate the ascorbyl radical which is detected by direct ESR. The peroxidatic oxidation of orellanine to semiquinone followed by its reduction by glutathione or ascorbic acid does not induce dioxygen uptake. The relationship between chemical structure and HRP oxidation of orellanine-related molecules, namely orelline and DHBPO₂ (the parent molecule lacking of hydroxyl groups in 3 and 3' position) has been investigated in absence or in presence of reducing agents. None of the orellanine-related compounds can be oxidized by the HRP/H₂O₂ system, showing that both catecholic moieties and aminoxide groups are necessary for observing the formation of the ortho-semiquinone form of orellanine. As shown for the (photo)chemical oxidation of orellanine, the mechanism of toxicity could be correlated with a depletion of glutathione and ascorbate levels which are implicated in the defence against oxidative damage.     

Efficient iron plaque formation on tea(Camellia sinensis) roots contributes to acidic stress tolerance

Tea plants grow in acidic soil, but to date, their intrinsic mechanisms of acidic stress tolerance have not been elucidated. Here, we assessed the tea plant response to growth on NHt4 nutrient media having different p H and iron levels. When grown in standard NHt4 nutrient solution(iron insufficient, 0.35 mg Là1 Fe2t), tea roots exhibited significantly lower nitrogen accumulation, plasma membrane Ht-ATPase activity, and protein levels; net Htefflux was lower at pH 4.0 and 5.0 than at pH 6.0. Addition of30 mg Là1 Fe2t(iron sufficient, mimicking normal soil Fe2tconcentrations) to the NHt4 nutrient solution led to more efficient iron plaque formation on roots and increased root plasma membrane Ht-ATPase levels and activities at p H 4.0 eland 5.0, compared to the p H 6.0 condition. Furthermore,plants grown at pH 4.0 and 5.0, with sufficient iron,exhibited significantly higher nitrogen accumulation than those grown at pH 6.0. Together, these results support the hypothesis that efficient iron plaque formation, on tea roots, is important for acidic stress tolerance. Furthermore,our findings establish that efficient iron plaque formation is linked to increased levels and activities of the tea root plasma membrane Ht-ATPase, under low pH conditions.     

Lipid Peroxidation. Definition of Experimental Conditions for Selective Study of the Propagation and Termination Phases

To find experimental conditions to selectively study the propagation phase of lipoperoxidation we studied the lipoperoxidation, catalyzed by FeCl₂, of liposomes in a buffering condition where Fe²⁺ autoxidation and oxygen active species generation does not occur. Liposomes from egg yolk phosphatidylcholine. prepared by vortex mixing, do not oxidize Fe²⁺: on the contrary they oxidize Fe²⁺ when prepared by ultrasonic irradiation. Dimyristoyl phosphatidylcholine liposomes prepared by ultrasonic irradiation do not oxidize Fe²⁺. During sonication polyunsaturated fatty acid residues autoxidize and lipid hydroperoxides (LOOH) are generated. Only when LOOH are present in the liposimes Fe²⁺ oxidizes and its rate of oxidation depends on the amount of LOOH in the assay. The reaction results in the generation of both LOOH and thiobarbituric acid reactive material (TBAR): it is inhibited by butylated hydroxytoluene and has a acidic pH optimum; it is not inhibited by catalase and OH' scavengers. The reaction studied. thus, appears to be the chain branching and propagation phase of lipoperoxidation. When we studied the dependence of Fe²⁺ oxidation, LOOH and TBAR generation on FeCl₂ concentration, we observed that at high FeCl₂ concentrations the termination phase of lipoperoxidation was prevalent. Thus. by selecting the appropriate FeCl₂ concentration the proposed experimental system allows study of either the propagation or the termination phase of lipoperoxidation.     

Mechanisms of Saccharomyces Cerevisiae PMA1 H+-ATPase inactivation by Fe2+, H2O2 and Fenton reagents

Although considerably more oxidation-resistant than other P-type ATPases, the yeast PMA1 H⁺-ATPase of Saccharomyces cerevisiae SY4 secretory vesicles was inactivated by H₂O₂, Fe²⁺, Fe- and Cu-Fenton reagents. Inactivation by Fe²⁺ required the presence of oxygen and hence involved auto-oxidation of Fe²⁺ to Fe³⁺. The highest Fe^2- (100 μM) and H₂O₂ (100 mM) concentrations used produced about the same effect. Inactivation by the Fenton reagent depended more on Fe²⁺ content than on H₂O₂ concentration, occurred only when Fe²⁺ was added to the vesicles first and was only slightly reduced by scavengers (mannitol, Tris, NaN₃, DMSO) and by chelators (EDTA, EGTA, DTPA, BPDs, bipyridine, 1, 10-phenanthroline). Inactivation by Fe- and Cu- Fenton reagent was the same; the identical inactivation pattern found for both reagents under anaerobic conditions showed that both reagents act via OH^·. The lipid peroxidation blocker BHT prevented Fenton-induced rise in lipid peroxidation in both whole cells and in isolated membrane lipids but did not protect the H⁺-ATPase in secretory vesicles against inactivation. ATP partially protected the enzyme against peroxide and the Fenton reagent in a way resembling the protection it afforded against SH-specific agents. The results indicate that Fe²⁺ and the Fenton reagent act via metal-catalyzed oxidation at specific metal-binding sites, very probably SH-containing amino acid residues. Deferrioxamine, which prevents the redox cycling of Fe²⁺, blocked H⁺-ATPase inactivation by Fe²⁺ and the Fenton reagent but not that caused by H₂O₂, which therefore seems to involve a direct non-radical attack. Fe-Fenton reagent caused fragmentation of the H⁺-ATPase molecule, which, in Western blots, did not give rise to defined fragments bands but merely to smears.     

Effect of ascorbic acid, sodium citrate, sodium bicarbonate, and their combination effect on the binding of Fe and Fe to plasma membrane of lactating mouse mammary gland

Isolated plasma membranes of lactating mouse mammary gland were treated with different concentrations of ascorbate, sodium citrate, sodium bicarbonate, combinations of them (from 16 x 10⁻¹⁰ to 4 x 10⁻⁶ moles/L) and studied for the binding of ⁵⁹Fe²⁺ and ⁵⁹Fe³⁺ at pH 7.4. The results show that the Fe³⁺ form of iron is under a greater influence of anions used in these experiments. The Fe²⁺ form of iron is weakly bounded and affected. It is suggested that the form with a greater positive electric charge is more effectively bound to the receptors in plasma membranes.     

A Kinetic and ESR Investigation of Iron(II) Oxalate Oxidation by Hydrogen Peroxide and Dioxygen as a Source of Hydroxyl Radicals

The reaction of Fe^II oxalate with hydrogen peroxide and dioxygen was studed for oxalate concentrations up to 20 mM and pH 2-5, under which conditions mono- and bis-oxalate comlexes (Fe^II(ox) and Fe^II(ox)₂^2-) and uncomplexed Fe²⁺ must be considered. The reaction of Fe^II oxalate with hydrogen peroxide (Fe²⁺ + H₂O₂ → Fe³⁺ + *OH + OH^-) was monitored in continuous flow by ESR with t-butanol as a radical trap. The reaction is much faster than for uncomplexed Fe²⁺ and a rate constant, k = 1 × 10⁴ M-¹ s^-1 is deduced for Fe^II(ox). The reaction of Fe^II oxalate with dioxygen is strongly pH dependent in a manner which indicates that the reactive species is Fe^II(ox)₂^2-, for which an apparent second order rate constant, k = 3.6 M^-1 s^-1, is deduced. Taken together, these results provide a mechanism for hydroxyl radical production in aqueous systems containing Fe^II complexed by oxalate. Further ESR studies with DMPO as spin trap reveal that reaction of Fe^II oxalate with hydrogen peroxide can also lead to formation of the carboxylate radical anion (CO₂^*-), an assignment confirmed by photolysis of Fe^III oxalate in the presence of DMPO.     

Aluminum ions stimulate the oxidizability of low density lipoprotein by Fe2+: implication in hemodialysis mediated atherogenic LDL modification

Objective: Al³⁺ stimulates Fe²⁺ induced lipid oxidation in liposomal and cellular systems. Low-density lipoprotein (LDL) oxidation may render the particle atherogenic. As elevated levels of Al³⁺ and increased lipid oxidation of LDL are found in sera of hemodialysis patients, we investigated the influence of Al³⁺ on LDL oxidation.

Materials and methods: Using different LDL modifying systems (Fe²⁺, Cu²⁺, free radical generating compounds, human endothelial cells, hemin/H₂O₂ and HOCl), the influence of Al³⁺ on LDL lipid and apoprotein alteration was investigated by altered electrophoretic mobility, lipid hydroperoxide-, conjugated diene- and TBARS formation.

Results: Al³⁺ could stimulate the oxidizability of LDL by Fe²⁺, but not in the other systems tested. Al³⁺ and Fe²⁺ were found to bind to LDL and Al³⁺could compete with Fe²⁺ binding to the lipoprotein. Fluorescence polarization data indicated that Al³⁺ does not affect the phospholipid compartment of LDL.

Conclusions:The results indicate that increased LDL oxidation by Fe²⁺ in presence of Al³⁺ might be due to blockage of Fe²⁺ binding sites on LDL making more free Fe²⁺ available for lipid oxidation.     

Chemical reactivity of the carbon-centered free radicals and ferrous iron in coals: Role of bioavailable Fe2+ in coal workers' pneumoconiosis

Striking differences in the prevalence of coal workers' pneumoconiosis (CWP) exist between different coal mine regions. The major factors responsible for the observed regional differences in CWP have not yet been identified. In the present study, chemical reactivity of the carbon-centered free radicals in coals and lung tissues, as well as ferrous iron in the coals, were studied by ESR techniques. The ESR spectra clearly demonstrated the presence of at least two types of carbon-centered free radical species, which might respectively attribute to the macromolecular phase and the molecular phase of coal. Grinding produced free radicals in coals. Exposure of freshly ground coal to air for 28 h induced a slight increase of free radicals for most of the coals, and a slight decrease after 4 months' exposure. The lung tissue samples of coal workers deceased of CWP showed similar ESR spectra as coal samples, and these radicals were highly stable in the lung. After incubation of coals with glutathione, hydrogen peroxide, sodium formate or oxygen, the coal sample from the Gardanne mine which has never induced CWP, and thus is the least hazardous coal, showed the most significant change in the carbon-centered free radical concentration. No significant changes were observed among other coals reported to induce CWP. On the other hand, we found that the coals released different amounts of Fe²⁺ in an acidic medium. Interestingly, the prevalence of CWP correlates positively with the released Fe²⁺ content in these coals and with the amount of oxygen radicals produced by the interaction of Fe²⁺ with O₂ in the acidified coal filtrates. Our studies indicate that the carbon-centered free radicals may not be biologically relevant to coal dust-induced pneumoconiosis, whereas the acid soluble Fe²⁺, which may be dissolved in the phagolysosomes of macrophages, can then lead to Fe²⁺-induced oxidative stress and eventual CWP development.     

Direct NAD(P)H hydrolysis into ADP-ribose(P) and nicotinamide induced by reactive oxygen species: a new mechanism of oxygen radical toxicity

The effect of different oxygen radical-generating systems on NAD(P)H was determined by incubating the reduced forms of the pyridine coenzymes with either Fe²⁺-H₂O₂ or Fe³⁺-ascorbate and by analyzing the reaction mixtures using a HPLC separation of adenine nucleotide derivatives. The effect of the azo-initiator 2,2'-azobis(2-methylpropionamidine)dihydrochloride was also tested. Results showed that, whilst all the three free radical-producing systems induced, with different extent, the oxidation of NAD(P)H to NAD(P)⁺, only Fe²⁺-H₂O₂ also caused the formation of equimolar amounts of ADP-ribose(P) and nicotinamide. Dose-dependent experiments, with increasing Fe²⁺ iron (concentration range 3-180 μM) or H₂O₂ (concentration range 50-1000 μM), were carried out at pH 6.5 in 50 mM ammonium acetate. NAD(P)⁺, ADP-ribose(P) and nicotinamide formation increased by increasing the amount of hydroxyl radicals produced in the medium. Under such incubation conditions NAD(P)⁺/ADP-ribose(P) ratio was about 4 at any Fe²⁺ or H₂O₂ concentration. By varying pH to 2.0, 3.0, 4.0, 4.5, 5.0, 5.5, 6.0, 7.0 and 7.4, NAD(P)⁺/ADP-ribose(P) ratio changed to 5.5, 3.2, 1.8, 1.6, 2.0, 2.5, 3.0, 5.4 and 6.5, respectively. Kinetic experiments indicated that 90-95% of all compounds were generated within 5s from the beginning of the Fenton reaction. Inhibition of ADP-ribose(P), nicotinamide and NAD(P)⁺ production of Fe²⁺-H₂O₂-treated NAD(P)H samples, was achieved by adding mannitol (10-50 mM) to the reaction mixture. Differently, selective and total inhibition of ADP-ribose(P) and nicotinamide formation was obtained by performing the Fenton reaction in an almost completely anhydrous medium, i.e. in HPLC-grade methanol. Experiments carried out in isolated postischemic rat hearts perfused with 50 mM mannitol, showed that, with respect to values of control hearts, this hydroxyl radical scavenger prevented reperfusion-associated pyridine coenzyme depletion and ADP-ribose formation. On the basis of these results, a possible mechanism of action of ADP-ribose(P) and nicotinamide generation through the interaction between NAD(P)H and hydroxyl radical (which does not involve the C-center where “conventional” oxidation occurs) is presented. The implication of this phenomenon in the pyridine coenzyme depletion observed in postischemic tissues is also discussed.     

The Mechanism of Iron (III) Stimulation of Lipid Peroxidation

A study conducted on Fe²⁺ autoxidation showed that its rate was extremely slow at acidic pH values and increased by increasing the pH; it was stimulated by Fe³⁺ addition but the stimulation did not present a maximum at a Fe²⁺/Fe³⁺ ratio approaching 1:1. The species generated during Fe³⁺-catalyzed Fe²⁺ autoxidation was able to oxidize deoxyribose; the increased Fe²⁺ oxidation observed at higher pHs was paralleled by increased deoxyribose degradation. The species generated during Fe³⁺-catalyzed Fe²⁺ autoxidation could not initiate lipid peroxidation in phosphatidylcholine liposomes from which lipid hydroperoxides (LOOH) had been removed by treatment with triph-enylphosphine. Neither Fe²⁺ oxidation nor changes in the oxidation index of the liposomes due to lipid peroxidation were observed at pHs where the Fe³⁺ effect on Fe²⁺ autoxidation and on deoxyribose degradation was evident. In our experimental system, a Fe²⁺/Fe³⁺ ratio ranging from 1:3 to 2:1 was unable to initiate lipid peroxidation in LOOH-free phosphatidylcholine liposomes. By contrast Fe³⁺ stimulated the peroxidation of liposomes where increasing amounts of cumene hydroperoxide were incorporated. These results argue against the participation of Fe³⁺ in the initiation of LOOH-independent lipid peroxidation and suggest its possible involvement in LOOH-dependent lipid peroxidation.     

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.     

The oxidation of chlorophyll a in alcohols

Oxidation potentials for the chlorophyll (Chl/Chl⁺) couple, relative to that of the Fe²⁺/Fe³⁺ couple, were determined in methanol, ethanol, and isopropanol from the initial extent of reaction of chlorophyll with FeCl₃. The presence of 4,7-dimethylphenanthroline was necessary to get sufficient oxidation of chlorophyll in isopropanol. The values were +0.75 V, +0.865 V, and approx. +1.0 V, respectively, based on an assumed value of +0.77 V for the Fe²⁺/Fe³⁺ potential. It is suggested that alcohols, especially methanol, may stabilize Chl⁺ by adding to the carbonyl group or the conjugated double bond system.