Reaction of hematin with allylic fatty acid hydroperoxides: identification of products and implications for pathways of hydroperoxide-dependent epoxidation of 7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene

Reaction of 10-hydroperoxyoctadec-8-enoic acid (10-OOH-18:1) (50 microM) with hematin (0.5 microM) in sodium phosphate buffer containing Tween 20 (200 microM) generates 10-oxooctadec-8-enoic acid, 10-oxodec-8-enoic acid (10-oxo-10:1), and 10-hydroxyoctadec-8-enoic acid in relative yields of 79, 4, and 17%, respectively. The product profile and relative distribution are unaffected by 1 mM butylated hydroxyanisole. Approximately 5% of the hydroperoxide isomerizes from the 10- to the 8-position. 10-Oxo-10:1 most likely arises via beta-scission of an intermediate alkoxyl radical to the aldehyde and the n-octyl radical. To test this, 10-hydroperoxyoctadeca-8,12-dienoic acid was reacted with hematin under identical conditions. 10-Oxooctadeca-8,12-dienoic acid, 10-oxodec-8-enoic acid, and 10-hydroxyoctadeca-8,12-dienoic acid are formed in relative yields of 50, 45, and 5%, respectively. The product ratios are constant with time and hydroperoxide to catalyst ratio and unaffected by inclusion of phenolic antioxidants. The higher yield of 10-oxo-10:1 from 10-OOH-18:2 compared to 10-OOH-18:1 is due to the higher rate of beta-scission of the intermediate alkoxyl radical from the former to the resonance-stabilized octenyl radical. Two products of reaction of the 2-octenyl radical with O2, octenal and octenol, were detected in 10% yield relative to 10-oxo-10:1. Inclusion of 7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene (BP-7,8-diol) led to epoxidation by both 10-OOH-18:1 and 10-OOH-18:2. Studies with isotopically labeled hydroperoxide or O2 indicated approximately 65% of the epoxide oxygen was derived from O2 and 35% from hydroperoxide oxygen, consistent with the involvement of peroxyl free radicals as the oxidizing agents. The available evidence indicates that hematin reduces the fatty acid hydroperoxides homolytically to alkoxyl radicals that are oxidized to ketones, reduced to alcohols, or undergo beta-scission to aldehydes. Carbon radicals generated during these reactions couple to O2, generating peroxyl free radicals that epoxidize BP-7,8-diol. The smaller percentage of epoxidation that results from hydroperoxide oxygen may arise from oxidation of the hydroperoxide group to peroxyl radicals or from heterolytic cleavage of the hydroperoxide to alcohol and an iron-oxo complex.     

Conversion of linoleic acid hydroperoxide to hydroxy, keto, epoxyhydroxy, and trihydroxy fatty acids by hematin

We have carried out a study of the reaction of 13-hydroperoxy-9-cis,11-trans-octadecadienoic acid (linoleic acid hydroperoxide) with hematin. The major products are erythro-11-hydroxy-12,13-epoxy-9-octadecenoic acid, threo-11-hydroxy-12,13-epoxy-9-octadecenoic acid, 9,12,13-trihydroxy-10-octadecenoic acid, 13-keto-9,11-octadecadienoic acid, and 13-hydroxy-9,11-octadecadienoic acid. Several minor products have also been identified, including 9-hydroxy-12,13-epoxyoctadecenoic acid, 11-hydroxy-9,10-epoxy-12-octadecenoic acid, 9-hydroxy-10,12-octadecadienoic acid, and 9-keto-10,12-octadecadienoic acid. Oxygen labeling studies indicate that the observed products arise by at least two pathways. In the major pathway, hematin reduces 13-hydroperoxy-9,11-octadecadienoic acid by one electron to an alkoxyl radical that cyclizes to an adjacent double bond to form an epoxy allylic radical. The allylic radical either couples to the hydroxyl radical coordinated to hematin or diffuses from the solvent cage and couples to O2, forming a peroxyl radical. In the minor pathway, the hydroperoxide is oxidized by one electron to a 13-peroxyl radical that undergoes beta-scission to a pentadienyl radical and O2. Exchange of hydroperoxide-derived O2 for dissolved O2 occurs at this stage followed by coupling of O2 to either terminus of the pentadienyl radical. Both pathways of hydroperoxide metabolism generate significant quantities of peroxyl radicals that epoxidize the isolated double bonds of dihydroaromatic molecules. The products of hydroperoxide reaction with hematin and the oxygen labeling patterns are very similar to the products of unsaturated fatty acid hydroperoxide metabolism by platelets, aorta, and lung. Our results not only provide a mechanism for the formation of a series of mammalian metabolites of linoleic and arachidonic acids but also offer an estimate of the yield of peroxyl radicals generated during the process.     

Oxygen radical-dependent epoxidation of (7S,8S)-dihydroxy-7,8-dihydrobenzo[a]pyrene in mouse skin in vivo. Stimulation by phorbol esters and inhibition by antiinflammatory steroids.

(7S,8S)--Dihydroxy--7,8--dihydrobenzo[a]pyrene ((+)-BP-7,8-diol) is epoxidized to (7S,8R)-dihydroxy-(9S,10R)-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene ((+)-syn-BPDE) by cytochrome P-450 isoenzymes and to (7S,8R)-dihydroxy-(9R,10S)-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene ((-)-anti-BPDE) by peroxyl free radicals. 32P postlabeling analysis of the diastereomeric BPDE-DNA adducts was used to investigate the pathways of (+)-BP-7,8-diol oxidation in mouse skin in vivo. The pattern of deoxynucleoside 3',5'-bisphosphate adducts in epidermal scrapings from female CD-1 mice indicated that cytochrome P-450 was the major oxidant. Similar results were obtained when the tumor-promoting phorbol ester tetradecanoylphorbolacetate (TPA) was coadministered with (+)-BP-7,8-diol. However, when animals were pretreated with TPA 24 h before coadministration of TPA and (+)-BP-7,8-diol, the pattern of BPDE-DNA adducts indicated that peroxyl radicals made a major contribution to (+)-BP-7,8-diol epoxidation. Peroxyl radical-dependent epoxidation was maximal when the time between the two TPA administrations was 24-72 h. No increase in (-)-anti-BPDE-DNA was observed when the non-tumor-promoting phorbol ester 4-O-methyl-TPA was substituted for TPA. The calcium ionophore A23187 stimulated peroxyl radical generation when substituted for the first, but not the second, TPA treatment. The antiinflammatory steroid fluocinolone acetonide inhibited (-)-anti-BPDE-DNA adduct formation when coadministered with the first but not the second TPA treatment. These findings demonstrate the existence of two independent pathways of metabolic activation of (+)-BP-7,8-diol in mouse epidermis, one dependent on cytochrome P-450 and the other dependent on peroxyl free radicals. The results also suggest that repetitive topical administration of tumor-promoting phorbol esters remodels epidermal metabolism leading to a significant increase in free radical generation.     

Hydroperoxide-dependent oxygenation of trans-7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene by ram seminal vesicle microsomes. Source of the oxygen

Incubation of 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid with ram seminal vesicle microsomes (RSVM) triggers the oxygenation of $\text{trans}$-7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene (BP-7,8-diol). The principal oxidation products are 7,8,9,10-tetrahydroxy-7,8,9,10-tetrahydrobenzo[a]pyrenes which are non-enzymatic hydrolysis products of r-7,t-8-dihydroxy-t-9,10-oxy-7,8,9,10-tetrahydrobenzo[a]pyrene. At short incubation times, an additional product is isolated which is identified as r-7,t-8,t-9-trihydroxy-c-10-methoxy-7,8,9,10-tetrahydrobenzo[a]pyrene. This product appears to arise by solvolysis of the extracted diolepoxide during high performance liquid chromatography using methanol-water solvent systems. The incubation of ¹⁸O-labeled 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid with BP-7,8-diol and RSVM leads to very little incorporation of ¹⁸O into the stable solvolysis products (analyzed by gc-ms of their peracetates). Parallel incubations conducted with ¹⁶O-labeled hydroperoxide under an ¹⁸O₂ atmosphere indicate that the principle source of the epoxide oxygen is molecular oxygen.     

A direct electron spin resonance and spin-trapping investigation of peroxyl free radical formation by hematin/hydroperoxide systems

Direct electron spin resonance was used to detect tert-alkylperoxyl radicals generated by hematin and the corresponding hydroperoxides at near-physiological pH values. The spin-trapping method was necessary to detect the less persistent primary ethylperoxyl radical. Under a nitrogen atmosphere, the electron spin resonance signal of the tert-alkylperoxyl radicals decreased, and the ethylperoxyl spin-adduct concentration did not change. Concomitant studies, using a Clark oxygen electrode, show that oxygen was consumed by the hematin-tert-alkyl hydroperoxide systems, but was released by the hematin-ethyl hydroperoxide reaction. Thus, molecular oxygen seems to play a subsidiary role in the hematin-catalyzed decomposition of hydroperoxides. Based on the electron spin resonance and oxygen electrode results, a mechanism for the continuous production of the peroxyl free radicals is proposed for hematin/hydroperoxide systems. The present spectroscopic methodology can be used to search for peroxyl free radical formation by hemoprotein/hydroperoxide systems.     

Phenylbutazone-dependent epoxidation of 7,8-dihydroxy-7,8-dihydrobenzo(a)pyrene. A new mechanism for prostaglandin H synthase-catalyzed oxidations

The nonsteroidal anti-inflammatory drug phenylbutazone markedly enhances the hydroperoxide-dependent epoxidation of 7,8-dihydroxy-7,8-dihydrobenzo(a)pyrene catalyzed by microsomal and Tween-20 solubilized preparations of prostaglandin H synthase. Furthermore, phenylbutazone radically alters the hydroperoxide specificity of 7,8-dihydroxy-7,8-dihydrobenzo(a)pyrene epoxidation. In the absence of phenylbutazone, only allylic hydroperoxides are effective in initiating epoxidation, whereas in the presence of phenylbutazone the reaction can be initiated by t-butyl hydroperoxide, cumene hydroperoxide, and hydrogen peroxide. All effects are dependent on the concentration of phenylbutazone present. The primary event is the oxidation of phenylbutazone by prostaglandin H synthase. This pathway yields a peroxy radical of phenylbutazone which appears to be the epoxidizing agent. This activation of a primary substrate by a peroxidase resulting in metabolism of a secondary substrate is analogous to the halogenation reactions catalyzed by chloroperoxidase. This represents a new class of oxidation reactions catalyzed by prostaglandin H synthase.     

Oxidation of benzo(a)pyrene and 7,8-dihydro-7,8-dihydroxy benzo(a)pyrene by horseradish peroxidase-H2O2 intermediate: fluorometric study

The capacity of oxidation of benzo(a)pyrene (BP) and its analog to be oxidized by peroxidases in several tissues has been studied. The kinetics of the horseradish peroxidase (HRP) oxidation of BP and 7,8-dihydro-7,8-dihydroxy benzo(a)pyrene (BP-7,8-diol) were examined. Effective ratios of H2O2 and HRP for catalytic oxidation were 13.74 for BP and 4.58 for BP-7,8-diol. The maximum ratio was approximately 90 for both hydrogen donors (BP and BP-7,8-diol) to the ES complex. The maximum ratio of oxidized BP and BP-7,8-diol to HRP was 5.7. Ks values for H2O2 were 1.68 and 6.35 microM for BP and BP-7,8-diol, respectively. The mean values of the rate constants, k5, for the oxidation of BP and BP-7,8-diol were 0.56 X 10(5) M-1 sec-1 and 4.1 X 10(5) M-1 sec-1, respectively, at low concentrations. At low concentrations a Hill plot of the oxidation of BP showed a negative value (nH = 0.5) and at high concentrations nH = 1.0. On the other hand, that of BP-7,8-diol showed positive cooperativeness (nH = 1.8). These oxidation reactions caused substrate (donor) inhibition at high concentrations. The inhibition constants, KA', were 9.8 and 5.65 microM for BP and BP-7,8-diol, respectively. The reactivity of the oxidation of BP-7,8-diol was five to six times larger than that of BP.     

Singlet oxygen production by bleomycin. A comparison with heme-containing compounds

Fe(III)-bleomycin catalyzes the decomposition of 13-hydroperoxylinoleic acid and of 15-hydroperoxyarachidonic acid to produce small quantities of singlet oxygen. No singlet oxygen is produced when hydrogen peroxide, ethyl hydroperoxide, cumene hydroperoxide, and t-butyl hydroperoxide are used as substrates. The heme-containing catalysts, methemoglobin and hematin, have identical hydroperoxide substrate requirements for singlet oxygen production. The hydroperoxide requirements for singlet oxygen production correlate with those reported by Dix et al. (Dix, T.A., Fontana, R., Panthani, A., and Marnett, L.J. (1985) J. Biol. Chem. 260, 5358-5365) for the production of peroxyl radicals in the hematin-catalyzed decomposition of hydroperoxides. The bimolecular reaction of peroxyl radicals is a plausible reaction mechanism for the singlet oxygen production in the systems studied.     

Hematin- and peroxide-catalyzed peroxidation of phospholipid liposomes

The effect of hydroperoxides on hematin-catalyzed initiation and propagation of lipid peroxidation was examined utilizing soybean phosphatidylcholine liposomes as model membranes. Polarographic and spectrophotometric methods revealed a bimodal pseudocatalytic activity for hematin. A slow initiation phase of peroxidation was observed in the presence of low peroxide concentrations, whereas a fast propagative phase was observed at higher peroxide levels. Peroxide levels were manipulated enzymatically by the combination of phospholipase A2 and lipoxidase or by the direct addition of linoleic acid hydroperoxide, cumene hydroperoxide, or hydrogen peroxide. In addition, the effect of two different techniques for liposome preparation, i.e., sonication and extrusion, were compared on the basis of peroxidation kinetics. High pressure liquid chromatography analysis showed that sonicated liposomes contained higher levels of endogenous peroxides than the extruded ones. These sonicated liposomes also exhibited more rapid peroxidation following hematin addition. Extruded liposomes were more resistant to hematin-catalyzed peroxidation but became better substrates when exogenous hydroperoxides were added. All three peroxides reacted with hematin during which decomposition of peroxide and irreversible oxidation of hematin took place. Spectral analysis of hematin indicated that a higher oxidation state of hematin iron may be transiently formed during reaction with hydroperoxides and accounts for the propagation of lipid peroxidation when reactions proceed in the presence of soybean phosphatidylcholine liposomes. Of the three peroxides studied, linoleic acid hydroperoxide was most efficient in supporting hematin-catalyzed lipid peroxidation. The relevance of our findings is discussed in terms of the concentration dependence for lipid peroxides in determining the rate and extent of radical propagation chain reactions catalyzed by heme-iron catalysts such as hematin. Variation of hematin and linoleic hydroperoxide concentrations may provide an efficient and reproducible method for inducing and manipulating the rates and extent of lipid peroxidation through facilitation of the propagative phase of lipid peroxidation. In addition, we address a problem inherent to in vitro studies of heme-catalyzed lipid peroxidation where preparations of peroxide-free membranes should be of concern.     

The kinetics of benzo(a)pyrene anti-7,8-dihydrodiol 9, 10-epoxide formation from benzo(a)pyrene and regulatory membrane effects

r-7,c-10,t-8,t-9-Tetrahydroxybenzo(a)pyrene (7,10/8,9-tetrol), which is the principal hydrolysis product of r-7,t-8-dihydroxy-t-9,10-oxy-7,8,9,10-tetrahydrobenzo(a)pyrene (anti-diol-epoxide), was resolved and measured by HPLC in organic extracts of incubations which contained induced rat liver microsomes and BP. Kinetic analyses showed that: (a) following a 5- to 7-min lag period, anti-diol-epoxide formation was linear, and (b) levels of anti-diol-epoxide formed were highly dependent upon the starting BP concentration. anti-Diol-epoxide production increased at starting BP concentrations of 0–12 μm and decreased in incubations containing 12–25 μm BP. However, between 25 and 100 μm BP, anti-diol-epoxide formation was stable at a level representing 65% of the peak production which occurred at a starting BP concentration of 12 μm. BP oxidation was competitively inhibited by (?)-trans-BP-7,8-dihydrodiol and about five times less effectively by the (+)-trans-BP-7,8-dihydrodiol. The inability of a severalfold excess of BP (25–100 μm) to totally inhibit BP-7,8-dihydrodiol oxidation was explained by the presence of a microsomal substrate compartment which was saturated at only 6–8 μm BP, the remaining BP present as aggregates in the aqueous compartment. Purification of microsomes by Sepharose 2B gel filtration after reaction with [³H]BP also indicated that BP-7,8-dihydrodiol was preferentially concentrated in the microsome compartment leading to a net increase in the ratio of BP-7,8-dihydrodiol to BP in the microsomal compartment, which favored BP-7,8-dihydrodiol oxidation to yield the biologically active anti-diol-epoxide.     

The epimeric 20-hydroperoxy-5-pregnen-3 -ols: thermal and enzymatic decomposition

The isolation of 20α-hydroperoxy-5-pregnen-3β-ol and its 20β-isomer from air aged cholesterol is described. The structures of these new steroids are deducted from their physicochemical properties and confirmed by borohydride reduction to the known epimeric 5-pregnene-3β, 20-diols. Formation of the 20α-hydroperoxy-5-pregnen-3β-ol during the autoxidation process is suggested to result from the interaction of molecular oxygen with a 3β-hydroxy-5-pregnen-20α-yl radical, a specie which may be formed upon decomposition of the 25-hydroperoxy-5-cholesten-3β-ol. Formation of the 20β-hydroperoxy-epimer is shown to result partially from isomerization of the 20α-hydroperoxy-5-pregnen-3β-ol. Thermal decomposition of both isomers gives pregnenolone (3β-hydroxy-5-pregnen-20-one) as the major product together with the corresponding 5-pregnene-3β, 20-diol, 5-androsten-3β-ol and a small amount of 5-androstene-3β, 17β-diol and 5, 16-androstadien-3β-ol. Incubation of either hydroperoxide with adrenocortex microsomal and mitochondrial preparations gave pregnenolone and the corresponding steroid alcohol as the sole products. These results are discussed in comparison with the earlier reported studies on the 20α-hydroperoxy-5-cholesten-3β-ol and in terms of the possible role of steroid hydroperoxides as transit species in the biogenesis of steroid hormones.     

The oxidation of benzo[a]pyrene-7,8-dihydrodiol mediated by lipid peroxidation in the rat intestine and the effect of dietary lipids

This study has demonstrated that the microsomal fraction of the rat small intestinal mucosa has the capacity to catalyse the oxidation of benzo[a]pyrene(BP)-7,8-diol to BP-diol-epoxides (BPDEs) both by a mechanism involving the mixed-function oxidase system (NADPH-dependent) and as a result of the initiation of peroxidation of the membrane phospholipids by ferrous ions, ascorbate and ADP. The NADPH-dependent reaction was fastest in the proximal part of the intestine and resulted in the formation of approximately equal amounts of BPDE I and BPDE II. The lipid peroxidation-catalysed reaction favoured the production of BPDE I and was maximal in the middle region of the intestine, closely paralleling the rate of lipid peroxidation in the intestinal sections. Feeding rats on a cod liver oil diet, rich in C20:5 and C22:6, significantly increased the incorporation of these fatty acids into the microsomal fractions. This resulted in a greatly increased rate of lipid peroxidation in vitro and a significantly higher rate of lipid peroxidation-catalysed BP-7,8-diol oxidation compared to rats fed fat-free, mono-unsaturated lard or corn oil (58% C18:2) diets. Thus the rate of conversion of BP-7,8-diol to its ultimate carcinogenic forms during lipid peroxidation in the intestinal fractions of rats fed a polyunsaturated fat was quantitatively more important than the NADPH-catalysed reaction as measured in vitro.     

The homolytic and heterolytic fatty acid hydroperoxide lyase-like activities of hematin

Pentenols and pentene dimers are biosynthetized in plants by homolytic fatty acid hydroperoxide lyase (HPL) or HPL-like enzymes. It has been found that these compounds can modify the flavor of olive oil. Reactions between hematin and 13-hydroperoxyoctadecatrienoic acid resulted in the formation of the same compounds via a free radical reaction in which an alkoxyl radical derived from linolenic acid hydroperoxide undergoes a beta-scission. (Z)-3-Hexenal has also been detected as a minor product of the reaction. It is bioconversed from the same substrate in plants by heterolytic HPL. Thanks to the redox cycle of its central iron, hematin has both homolytic and heterolytic HPL-like activities.     

Metabolism of benzo[a]pyrene and persistence of DNA adducts in the brown bullhead (Ictalurus nebulosus).

1. The in vitro metabolism of [3H]benzo[a]pyrene (BP) and [14C]benzo[a]pyrene-7,8-dihydrodiol (BP-7,8-diol) by liver of brown bullhead (Ictalurus nebulosus) was characterized, as was the formation and persistence of BP-DNA adducts in vivo. 2. Compared to rat liver microsomes, bullhead liver microsomes produced relatively larger amounts of BP-7,8-diol (predominantly the [-] enantiomer) and smaller amounts of of BP-7,8-diol (predominantly the [-] enantiomer) and smaller amounts of BP-4,5-diol. 3. BP phase I metabolites were efficiently converted by freshly isolated bullhead hepatocytes to conjugates, predominantly glucuronides. 4. BP-7,8-diol was metabolized by hepatocytes 4-fold more rapidly than was BP and was converted to approximately equal amounts of glucuronides, glutathione conjugates and sulfates. 5. BP-DNA adducts formed in bullhead liver with a lag time of several days and maximum adduct formation at 25-30 days. The major adduct was anti-BPDE-deoxyguanosine.     

Host-mediated mutagenicity experiments with benzo[a]pyrene and two of its metabolites

Benzo[a]pyrene (BP) and two of its major metabolites, the ultimate mutagen BP-4,5-oxide and the proximate mutagen trans-7,8-dihydro-7,8-dihydroxybenzo[a]pyrene (BP-7,8-diol) were investigated for mutagenicity in Salmonella typhimurium TA1538, TA98 and TA100 using an intrasanguineous host-mediated assay. BP and BP-4,5-oxide were not mutagenic under any experimental conditions. BP-7,8-diol was inactive with the strain TA1538 but was mutagenic with the strains TA98 and TA100. The effect was potentiated by pretreatment of the host mice with the cytochrome P-450 inducer 5,6-benzoflavone. We conclude: (i) one of the reasons for the observed insensitivity of the intrasanguineous host-mediated assay towards BP is that BP-4,5-oxide, which contributes to the microsome-mediated mutagenicity of BP, is inactive in the host-mediated assay; (ii) the finding that BP-7,8-diol is mutagenic in the host-mediated assay demonstrates that the lack of mutagenicity of BP is not intrinsic; (iii) the potentiated mutagenicity after treatment of the hosts with 5,6-benzoflavone suggests that cytochrome P-450 is more important in the activation of BP-7,8-diol in this system than other enzymes (e.g. prostaglandin synthase) that can also activate this compound in vitro.     

In vivo thiyl free radical formation from hemoglobin following administration of hydroperoxides

Although free radical formation due to the reaction between red blood cells and organic hydroperoxides in vitro has been well documented, the analogous in vivo ESR spectroscopic evidence for free radical formation has yet to be reported. We successfully employed ESR to detect the formation of the 5,5-dimethyl-1-pyrroline-N-oxide (DMPO)/hemoglobin thiyl free radical adduct in the blood of rats dosed with DMPO and tert-butyl hydroperoxide, cumene hydroperoxide, ethyl hydrogen peroxide, 2-butanone hydroperoxide, 15(S)-hydroperoxy-5,8,11,13-eicosatetraenoic acid, or hydrogen peroxide. We found that pretreating the rats with either buthionine sulfoximine or diethylmaleate prior to dosing with tert-butyl hydroperoxide decreased the concentration of nonprotein thiols within the red blood cells and significantly enhanced the DMPO/hemoglobin thiyl radical adduct concentration. Finally, we found that pretreating rats with the glutathione reductase inhibitor 1,3-bis(2-chloroethyl)-1-nitrosourea prior to dosing with tert-butyl hydroperoxide enhanced the DMPO/hemoglobin thiyl radical adduct concentration and induced the greatest decrease in nonprotein thiol concentration within the red blood cells.     

Hydroperoxide-dependent epoxidation of 3,4-dihydroxy-3,4-dihydrobenzo[a]anthracene by ram seminal vesicle microsomes and by hematin

Addition of arachidonic acid to ram seminal vesicle microsomes oxidizes 3,4-dihydroxy-3,4-dihydrobenzo[a]anthracene (BA-3,4-diol) to five more polar products. Four of the products are identified by chromatographic and spectroscopic analysis as tetrahydrotetraols, which are solvolysis products of dihydrodiolepoxides. The fifth product is a 10-methyl ether formed by methanolysis of the anti-diolepoxide. Quantitation of the individual products indicates that anti-diolepoxides predominate over syn-diolepoxides by approximately 2:1. Identical product profiles are detected from the reaction of BA-3,4-diol with hematin and 13-hydroperoxy-octadecadienoic acid in the presence of Tween 20. No other products are detected in either system, which indicates that peroxyl radicals oxidize BA-3,4-diol exclusively by epoxidation of the 1,2-double bond. The stereochemical and regiochemical differences between oxidation of BA-3,4-diol by peroxyl radicals and cytochrome P-450 are dramatic and suggest that BA-3,4-diol is uniquely suited as a probe to quantitate peroxyl radical-dependent epoxidation in vitro and in vivo.     

Lipoxygenase-catalyzed epoxidation of benzo(a)pyrene-7,8-dihydrodiol

Metabolism of resolved radioactive stereoisomer, [14C](+)-benzo-(a)pyrene-trans-7,8-dihydrodiol by highly purified soybean lipoxygenase plus linoleic acid was investigated. Trans-anti-7,8,9,10-tetrahydrotetrol, the product of hydrolytic breakdown of ultimate mutagenic benzo(a)pyrene-anti-7,8-dihydrodiol,9,10-epoxide, was detected as a major metabolite. The epoxidation, depended on the enzyme concentration and was inhibited by nordihydroguaiaretic acid. This study provides evidence on the ability of lipoxygenase to catalyze the epoxidation of benzo(a)pyrene-7,8-dihydrodiol.     

Macrophage mediated protein hydroperoxide formation and lipid oxidation in low density lipoprotein are inhibited by the inflammation marker 7,8-dihydroneopterin

The formation of oxidised low density lipoprotein (LDL) within the atherosclerotic plaque appears to be a factor in the development of advanced atherosclerotic plaques. LDL oxidation is dependent on the balance of oxidants and antioxidants within the intima. In addition to producing various oxidants, human macrophages release 7,8-dihydroneopterin which in vivo is oxidised to the inflammation marker neopterin. Using macrophage-like THP-1 cells and human monocyte-derived macrophages, we demonstrate that 7,8-dihydroneopterin is a potent inhibitor of cell-mediated LDL oxidation. 7,8-Dihydroneopterin scavenges the chain propagating lipid peroxyl radical, inhibiting both lipid and protein hydroperoxide formation. A significant amount of the hydroperoxide formed during cell-mediated LDL oxidation was protein hydroperoxide. 7,8-Dihydroneopterin oxidation to 7,8-dihydroxanthopterin was only observed in the presence of both cells and LDL, showing that 7,8-dihydroneopterin had no effect on initiating oxidant generation by the cells. 7,8-Dihydroneopterin did not regenerate alpha-tocopherol but competed with it for the lipid peroxyl radical. Although stimulation of both cell types with gamma-interferon failed to produce sufficient 7,8-dihydroneopterin to inhibit LDL oxidation in tissue culture, analysis of advanced atherosclerotic plaque removed from patients showed that total neopterin levels could reach low micromolar concentrations. This suggests that 7,8-dihydroneopterin synthesis by macrophages could play a significant role in the development of atherosclerotic plaques.     

Induction of cytochrome P-450IA1 gene expression in human breast tumour cell lines

The induction of cytochrome P-450IA1 by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) was studied in eight human breast tumour cell lines. The cells were treated with various concentrations of TCDD for 24 h, and total RNA was isolated. The level of P-450IA1 RNA induced by 1 nM TCDD followed the order: MCF-7 greater than T47-D greater than ZR-75-1 greater than 3909 greater than 3522. AL-1, BT-20 and CAMA-1 did not respond to TCDD at the concentrations used. Northern blot analysis revealed 2 bands at 2.7 and 2.0 Kb, respectively, with the larger band being 6-fold more intense. The ratio was not changed by the TCDD treatment. TCDD induction did not change the benzo[a]pyrene-7,8-diol (BP-7,8-diol) metabolite profile compared with control cells, when cells were incubated with [3H]BP-7,8-diol for 24 h following the treatment with TCDD. These results demonstrate that different breast tumour cell lines vary greatly with respect to the basal expression levels of P-450IA1 RNA and its inducibility by TCDD. Furthermore, TCDD treatment does not change the relative distribution of BP-7,8-diol metabolites.