Inhibition of liver microsomal lipid peroxidation by 13-cis-retinoic acid

The effects of 13-cis-retinoic acid on iron/ascorbate-dependent lipid peroxidation were investigated with rat liver microsomes. 13-cis-retinoic acid effectively inhibited malondialdehyde generation and molecular oxygen consumption associated with lipid peroxidation. Under the conditions employed, inhibition was complete at concentrations as low as 25 microM and the IC50 was 10 microM. Evidence for concomitant retinoid oxidation by microsomal unsaturated fatty acid-derived peroxyl radicals was demonstrated by detection of several retinoid-derived metabolites, including 5,8-oxy-13-cis-retinoic acid, generated during lipid peroxidation. The data indicate that 13-cis-retinoic acid inhibits lipid peroxidation by scavenging lipid peroxyl radicals with its conjugated polyene system. Its antioxidant properties may contribute to the pharmacological activities of this and related retinoids.     

Hydroperoxide-dependent epoxidation of unsaturated fatty acids in the broad bean (Vicia faba L.)

Incubation of linoleic acid with the 105,000g particle fraction of the homogenate of the broad bean (Vicia faba L.) led to the formation of the following products: 13(S)-hydroxy-9(Z),11(E)-octadecadienoic acid, 9,10-epoxy-12(Z)-octadecenoic acid (9(R),10(S)/9(S)/10(R), 80/20), 12,13-epoxy-9(Z)-octadecenoic acid (12(S),13(R)/12(R)/13(S), 64/36), and 9,10-epoxy-13(S)-hydroxy-11(E)-octadecenoic acid (9(S),10(R)/9(R),10(S), 91/9). Oleic acid incubated with the enzyme preparation in the presence of 13(S)-hydroperoxy-9(Z),11(E)-octadecadienoic acid or cumene hydroperoxide was converted into 9,10-epoxyoctadecanoic acid (9(R),10(S)/9(S),10(R), 79/21). Two enzyme activities were involved in the formation of the products, an omega 6-lipoxygenase and a hydroperoxide-dependent epoxygenase. The lipoxygenase, but not the epoxygenase, was inhibited by low concentrations of 5,8,11,14-eicosatetraynoic acid and nordihydroguaiaretic acid. In contrast, the epoxygenase, but not the lipoxygenase, was readily inactivated in the presence of 13(S)-hydroperoxy-9(Z),11(E)-octadecadienoic acid. Studies with 18O2-labeled 13(S)-hydroperoxy-9(Z),11(E)-octadecadienoic acid showed that the epoxide oxygens of 9,10-epoxyoctadecanoic acid and of 9,10-epoxy-13(S)-hydroxy-11(E)-octadecenoic acid were derived from hydroperoxide and not from molecular oxygen.     

Synthesis and preliminary biological evaluation of beta-carotene and retinoic acid oxidation products

Synthesis of the beta-carotene oxidation product, 2,3-dihydro-5,8-endoperoxy-beta-apo-carotene-13-one (1) was achieved in six steps starting from beta-ionone. Photo-oxygenation of all trans-retinoic acid (8) and 13-cis-retinoic acid (9) produced a mixture of 5S*,8S*-epidioxy-5,8-dihydroretinoic acid (10) and 13-cis-5S*,8S*-epidioxy-5,8-dihydroretinoic acid (11). Methylation of the crude photo-oxygenation mixture afforded the corresponding methyl esters 12 and 13, respectively, both of which underwent ready aerial oxidation yielding hitherto unknown oxidation products of retinoic acid identified as methyl 5S*,8S*-epidioxy-9,10beta-epoxy-5,8,9,10-tetrahydroretinoate (14) and methyl 13-cis-5S*,8S*-epidioxy-9,10beta-epoxy-5,8,9,10-tetrahydroretinoate (15). Evaluation of 1, all trans-retinoic acid (8), 13-cis-retinoic acid (9), and the photo-oxygenation products 10-15 in a panel of five cancer cell lines showed 1 to be inactive and that 11 is significantly cytotoxic compared with the other retinoic acid analogs suggesting the requirement of the carboxylic acid moiety and the cis-geometry of the 13(14) double bond for cytotoxic activity.     

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.     

Enhancement of hydroperoxide-dependent lipid peroxidation in rat liver microsomes by ascorbic acid

Simultaneous addition of ascorbic acid and organic hydroperoxides to rat liver microsomes resulted in enhanced lipid peroxidation (approximately threefold) relative to incubation of organic hydroperoxides with microsomes alone. No lipid peroxidation was evident in incubations of ascorbate alone with microsomes. The stimulatory effect of ascorbate on linoleic acid hydroperoxide (LAHP)-dependent peroxidation was evident at all times whereas stimulation of cumene hydroperoxide (CHP)-dependent peroxidation occurred after a lag phase of up to 20 min. EDTA did not inhibit CHP-dependent lipid peroxidation but completely abolished ascorbate enhancement of lipid peroxidation. Likewise, EDTA did not significantly inhibit peroxidation by LAHP but dramatically reduced ascorbate enhancement of lipid peroxidation. The results reveal a synergistic prooxidant effect of ascorbic acid on hydroperoxide-dependent lipid peroxidation. The inhibitory effect of EDTA on enhanced peroxidation suggests a possible role for endogenous metals mobilized by hydroperoxide-dependent oxidations of microsomal components.     

Quantitative studies of hydroperoxide reduction by prostaglandin H synthase. Reducing substrate specificity and the relationship of peroxidase to cyclooxygenase activities

The peroxidase activity of prostaglandin H (PGH) synthase catalyzes reduction of 5-phenyl-4-pentenyl hydroperoxide to 5-phenyl-4-pentenyl alcohol with a turnover number of approximately 8000 mol of 5-phenyl-4-pentenyl hydroperoxide/mol of enzyme/min. The kinetics and products of reaction establish PGH synthase as a classical heme peroxidase with catalytic efficiency similar to horseradish peroxidase. This suggests that the protein of PGH synthase evolved to facilitate peroxide heterolysis by the heme prosthetic group. Comparison of an extensive series of phenols, aromatic amines, beta-dicarbonyls, naturally occurring compounds, and nonsteroidal anti-inflammatory drugs indicates that considerable differences exist in their ability to act as reducing substrates. No correlation is observed between the ability of compounds to support peroxidatic hydroperoxide reduction and to inhibit cyclooxygenase. In addition, the resolved enantiomers of MK-410 and etodolac exhibit dramatic enantiospecific differences in their ability to inhibit cyclooxygenase but are equally potent as peroxidase-reducing substrates. This suggests that there are significant differences in the orientation of compounds at cyclooxygenase inhibitory sites and the peroxidase oxidation site(s). Comparison of 5-phenyl-4-pentenyl hydroperoxide reduction by PGH synthase and horseradish peroxidase reveals considerable differences in reducing substrate specificity. Both the cyclooxygenase and peroxidase activities of PGH synthase inactivate in the presence of low micromolar amounts of hydroperoxides and arachidonic acid. PGH synthase was most sensitive to arachidonic acid, which exhibited an I50 of 0.6 microM in the absence of all protective agents. Inactivation by hydroperoxides requires peroxidase turnover and can be prevented by reducing substrates. The I50 values for inactivation by 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid are 4.0 and 92 microM, respectively, in the absence and presence of 500 microM phenol, a moderately good reducing substrate. The ability of compounds to protect against hydroperoxide-induced inactivation correlates directly with their ability to act as reducing substrates. Hydroquinone, an excellent reducing substrate, protected against hydroperoxide-induced inactivation when present in less than 3-fold molar excess over hydroperoxide. The presence of a highly efficient hydroperoxide-reducing activity appears absolutely essential for protection of the cyclooxygenase capacity of PGH synthase. The peroxidase activity is, therefore, a twin-edged sword, responsible for and protective against hydroperoxide-dependent inactivation of PGH synthase.(ABSTRACT TRUNCATED AT 400 WORDS)     

The role of cytochrome P-450 in the hydroperoxide-catalyzed oxidation of alcohols by rat-liver microsomes.

The organic hydroperoxide cumene hydroperoxide is capable of oxidizing ethanol to acetaldehyde in the presence of either catalase, purified cytochrome P-450 or rat liver microsomes. Other hemoproteins like horseradish peroxidase, cytochrome c or hemoglobin were ineffective. In addition to ethanol, higher alcohols like 1-propanol, 1-butanol and 1-pentanol are also oxidized to their corresponding aldehydes to a lesser extent. Other organic hydroxyperoxides will replace cumene hydroperoxide in oxidizing ethanol but less effectively. The cumene-hydroperoxide-dependent ethanol oxidation in microsomes was inhibited partially by cytochrome P-450 inhibitors but was unaffected by catalase inhibitors. Phenobarbital pretreatment of rats increased the specific activity of the cumene-hydroperoxide-dependent ethanol oxidation per mg of microsomes about seven-fold. The evidence suggests that cytochrome P-450 rather than catalase is the enzyme responsible for hydroperoxide-dependent ethanol oxidation. However, when H2O2 is used in place of cumene hydroperoxide, the microsomal ethanol oxidation closely resembles the catalase system.     

Structural elucidation of some orange juice carotenoids

The structure of some carotenoids of Valencia orange juice were elucidated by chemical tests and MS of the free pigments and their derivatives. A new apocarotenal was shown to be 3-hydroxy-5,8-epoxy-5,8-dihydro-8′-apo-β-caroten-8′-al. Two UV-fluorescent apocarotenols found recently in avocado were also present. For the pigments previously designated trollixanthin and trollichrome, the new structures 5,6-dihydro-β,β-carotene-3-3′,5,6-tetrol and 5,8-epoxy-5,8,5′,6′-tetrahydro-β,β-carotene-3,3′,5′,6′-tetrol are assigned, both containing a trihydroxylated ring as in heteroxanthin.     

Structures of persicaxanthin,persicachrome and other apocarotenols of various fruits

The structure of persicaxanthin and persicachrome, two UV-fluorescent pigments found in French plum of the Sagiv cv, was elucidated by chemical tests and mass spectroscopy. They are C₂₅-epoxyapocarotenols, their respective structures being 5,6-epoxy-5,6-dihydro- 12′-apo-β-carotene-3,12′-diol and 5,8-epoxy-5,8-dihydro-12′-apo-β-carotene-3,12′-diol. The former is obtained by reduction of apo-12′-violaxanthal, which was also detected in the fruit in small amounts. Its proposed structure, 5,6-epoxy-3-hydroxy-5,6-dihydro- 12′-apo-β-caroten-12′-al, was confirmed. The number of natural apocarotenols of known structure has thus increased to five, including two other C₂₇-epoxyapocarotenols and a C₃₀-apocarotenol, which were also isolated from various fruits.     

Stereoselectivity of the epoxidation of 7,8-dihydrobenzo[a]pyrene by prostaglandin H synthase and cytochrome P-450 determined by the identification of polyguanylic acid adducts

The stereoselectivity of the oxidation of 7,8-dihydrobenzo[a]pyrene (H2BP) to 9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (H4BP-epoxide) by prostaglandin H (PGH) synthase and cytochrome P-450 has been studied using microsomal preparations from ram seminal vesicles and rat liver. Incubations were performed in the presence of polyguanylic acid and the adducts formed between H4BP-epoxide and guanosine were isolated following the recovery and hydrolysis of the poly(G). When (+/-)-H4BP-epoxide was reacted with poly(G), four diastereomeric adducts were formed by the cis and trans addition of the exocyclic amino group of guanine to the benzylic carbon of the epoxide enantiomers. Each diastereomer was identified by a combination of ultraviolet, nuclear magnetic resonance, circular dichroism, and mass spectroscopy. Under comparable conditions, ram seminal vesicle microsomes in the presence of arachidonic acid triggered the binding of H2BP to poly(G) to a greater extent than rat liver microsomes from untreated and phenobarbital- and methylcholanthrene pretreated animals in the presence of NADPH. Quantitation of the (-)-cis- and (+)-cis-guanosine adducts revealed the degree of stereoselectivity of epoxidation. The ratio of (-)/(+) adducts was 54:46 for PGH synthase and 89:11 (control), 62:38 (phenobarbital), and 69:31 (methylcholanthrene) for cytochrome P-450-catalyzed reactions. PGH synthase catalyzed the epoxidation of H2BP with little or no stereoselectivity in contrast to cytochrome P-450. The utility of the poly(G) binding technique for the elucidation of the stereoselective generation of chiral electrophiles is discussed along with the mechanistic implications of the results.     

Carotene epoxides of Lycopersicon esculentum

A series of oxygenated carotenoids has been isolated from tomatoes. Two of these compounds have been identified, by comparison of their chromatographic and spectroscopic properties with those of semisynthetic samples, as epoxides of lycopene (1,2-epoxy-1,2-dihydro-ψ,ψ-carotene and 5,6-epoxy-5,6-dihydro-ψ,ψ-carotene). The other related compounds have been identified by their chromatographic, spectroscopic and chemical properties as mutatochrome (5,8-epoxy-5,8-dihydro-β,β-carotene) and epoxides of phytoene (1,2-epoxy-1,2,7,8,11,12,7′,8′,11′,12′-decahydro-ψ, ψ-carotene), phytofluene (1,2-epoxy-1,2,7,8, 11,12,7′,8′-octahydro-ψ,ψ-carotene and 1,2-epoxy-1,2,7,8,7′,8′,11′,12′-octahydro-ψ,ψ-carotene) and ξ-carotene (1,2-epoxy-1,2,7,8,7′,8′-hexahydro-ψ,ψ-carotene). The presence in tomatoes of apo-6′-lycopenal (6′-apo-ψ-caroten-6′-al), 8′-apo-lycopenal (8′-apo-ψ-caroten-8′-al) and lycoxanthin (ψ,ψ-caroten-16-ol) has been confirmed by comparison with authentic samples.     

Activities of fatty acid desaturases and fatty acid composition of liver microsomes in rats fed beta-carotene and 13-cis-retinoic acid

The fatty acid composition of microsomal lipids and the activities of delta 9- and delta 6-desaturases in liver microsomes of rats fed diets supplemented with beta-carotene and two levels of 13-cis-retinoic acid were studied. Four groups of male, weanling rats were fed semipurified diets containing 0 or 100 mg beta-carotene per kg diet, and 20 or 100 mg 13-cis-retinoic acid per kg diet. After 11 weeks of feeding, the rats were killed, liver microsomes were prepared and assayed for delta 9-desaturase and delta 6-desaturase activities. The activity of delta 9-desaturase was lower in liver microsomes of rats fed beta-carotene-supplemented diet or the diet supplemented with the higher level of 13-cis-retinoic acid. Microsomal delta 6-desaturase activity was, however, higher in liver of rats fed 13-cis retinoic acid; there was no effect of beta-carotene on delta 6-desaturase activity. The fatty acid compositional data on total lipids of liver microsomes were consistent with the diet-induced changes in fatty acid desaturases. Phospholipid composition of liver microsomes was also altered as a result of feeding beta-carotene or 13-cis-retinoic acid-containing diets. The proportions of phosphatidylethanolamine were generally higher, whereas those of phosphatidylcholine were lower in the experimental groups as compared with the control.     

Epoxyalcohol synthase activity of the CYP74B enzymes of higher plants

The CYP74B subfamily of fatty acid hydroperoxide transforming cytochromes P450 includes the most common plant enzymes. All CYP74Bs studied yet except the CYP74B16 (flax divinyl ether synthase, LuDES) and the CYP74B33 (carrot allene oxide synthase, DcAOS) are 13-hydroperoxide lyases (HPLs, synonym: hemiacetal synthases). The results of present work demonstrate that additional products (except the HPL products) of fatty acid hydroperoxides conversion by the recombinant StHPL (CYP74B3, Solanum tuberosum), MsHPL (CYP74B4v1, Medicago sativa), and CsHPL (CYP74B6, Cucumis sativus) are epoxyalcohols. MsHPL, StHPL, and CsHPL converted the 13-hydroperoxides of linoleic (13-HPOD) and α-linolenic acids (13-HPOT) primarily to the chain cleavage products. The minor by-products of 13-HPOD and 13-HPOT conversions by these enzymes were the oxiranyl carbinols, 11-hydroxy-12,13-epoxy-9-octadecenoic and 11-hydroxy-12,13-epoxy-9,15-octadecadienoic acid. At the same time, all enzymes studied converted 9-hydroperoxides into corresponding oxiranyl carbinols with HPL by-products. Thus, the results showed the additional epoxyalcohol synthase activity of studied CYP74B enzymes. The 13-HPOD conversion reliably resulted in smaller yields of the HPL products and bigger yields of the epoxyalcohols compared to the 13-HPOT transformation. Overall, the results show the dualistic HPL/EAS behaviour of studied CYP74B enzymes, depending on hydroperoxide isomerism and unsaturation.     

Hepatic microsomal conversion of pregnenolone to 3β,5,6β-trihydroxy-5α-pregnan-20-one via pregnenolone α- and β-epoxides

In the presence of ferrous ion, ADP, and an NADPH-generating system, [4-¹⁴C]pregnenolone was oxidized by bovine liver microsomes to its α-epoxide (5,6α-epoxy-3β-hydroxy-5α-pregnan-20-one), β-epoxide (5,6β-epoxy-3β-hydroxy-5β-pregnan-20-one), trihydroxypregnanone (3β,5,6β-trihydroxy-5β-pregnan-20-one) which were separated, isolated on an octadecylsilicone column in 70% aq. methanol by high performance liquid chromatography, identified with respective synthetic specimens by gas-liquid chromatography-mass spectrometry. The microsomal Δ⁵-oxidation products of pregnenolone were detected in trace yield either when EDTA was added to the incubation mixture or when ferrous ion was omitted from the mixture. The microsomal oxidation system generated malondialdehyde significantly. It, however, was retarded to a negligible extent either by the addition of EDTA or by the omission of ferrous ion. Therefore, the microsomal formation of the significant yields of Δ⁵-oxygenated pregnenolones was reasonably attributed to a reaction linked to microsomal lipid peroxidation. The ratio of pregnenolone α- to β-epoxides formed was 1:3. A comparable study carried out under the same conditions by using [4-¹⁴C]cholesterol as the substrate resulted in the similar Δ⁵-epoxidation with concomitant formation of cholestane-3β,5α,6β-triol; cholesterol α- and β-epoxides formed were in the ratio 1:4.Both pregnenolone α- and β-epoxides were hydrolyzed by the microsomes to trihydroxypregnanone as the sole metabolite at a relative rate of 0.6:1. A similar relative value was also obtained in the microsomal hydrolysis of cholesterol α- and β-epoxides to the cholestanetriol.     

Novel biological transformations of 15-Ls-hydroperoxy-5,8,11,13-eicosatetraenoic acid

[1-14C]Arachidonic acid was incubated with homogenates of the fungus, Saprolegnia parasitica. The products consisted of comparable amounts of two epoxy alcohols, 15-Ls-hydroxy-11,12-epoxy-5cis,8cis,13trans- eicosatrienoic acid and 15-hydroxy-13,14-epoxy-5cis,8cis,11cis-eicosatrienoic acid. Results of incubations carried out in the presence of nordihydroguaiaretic acid, 5,8,11,14-eicosatetraynoic acid, p-hydroxymercuribenzoate as well as glutathione peroxidase plus reduced glutathione demonstrated that transformation of arachidonic acid into epoxy alcohols occurred with the formation of 15-Ls-hydroperoxy-5cis,8cis,11cis,13trans- eicosatetraenoic acid (15-HPETE) as an intermediate. The pathway involved a lipoxygenase catalyzing the oxygenation of arachidonic acid at the 15L position to produce 15-HPETE, and a hydroperoxide isomerase activity which catalyzed conversion of 15-HPETE into the two epoxy alcohols. Studies with 15-[18O2]HPETE demonstrated that both oxygens of 15-HPETE were retained in the epoxy alcohols. Furthermore, experiments with mixtures of 15-[18O2]-and 15-[16O2]HPETE showed that conversion of 15-HPETE into epoxy alcohols occurred by an intramolecular transfer of hydroperoxide oxygen.     

On the mechanism of prostacyclin and thromboxane A2 biosynthesis

The present research describes studies which address the mechanism of prostacyclin (PGI2) and thromboxane A2 (TXA2) biosynthesis. In addition to prostaglandin H1 (PGH1), PGG2, PGH2, and PGH3, also 8-iso-PGH2, 13(S)-hydroxy-PGH2, and 15-keto-PGH2 were applied to determine the substrate specificities and kinetics of prostacyclin and thromboxane synthase in more detail. Human platelet thromboxane synthase converted PGH1, 8-iso-PGH2, 13(S)-hydroxy-PGH2 and 15-keto-PGH2 into the corresponding heptadecanoic acid (C17) plus malondialdehyde, whereas the thromboxane derivative was formed only from PGG2, PGH2, and PGH3 together with the corresponding C17 metabolite and malondialdehyde in a 1:1:1 ratio. In contrast, PGG2, PGH2, 13(S)-hydroxy-PGH2, 15-keto-PGH2 and PGH3 were almost completely isomerized to the corresponding prostacyclin derivative by bovine aortic prostacyclin synthase, whereas PGH1 and 8-iso-PGH2 only produced the corresponding C17 hydroxy acid plus malondialdehyde. Isotope-labeling experiments with [5,6,8,9,11,12,14,15-2H]PGH2 revealed complete retention of label and no isotope effect in the course of thromboxane biosynthesis, but the loss of one 2H atom at C-6 with an isotope effect of 1.20 during PGI2 formation. Prostacyclin and thromboxane synthase bind both 9,11-epoxymethano-PGF2 alpha and 11,9-epoxymethano-PGF2 alpha at the heme iron, but according to their difference spectra in opposite ways with respect to the 9- and 11-position. In agreement with published model studies, a cage radical mechanism is proposed for both enzymes according to which the initial radical process is terminated through oxidation of carbon-centered radicals by the iron-sulfur catalytic site, followed by ionic rearrangement to PGI2 or TXA2. Various Fe(III) model compounds as well as liver microsomes or cytochrome P-450CAM can also form small amounts of PGI2 and TXA2, but mainly yield 12(S)-hydroxy-5,8,10-heptadecatrienoic acid plus malondialdehyde probably by a radical fragmentation pathway.     

Inverse correlation between cyclic GMP and tyrosine aminotransferase degradation in rat hepatoma tissue culture cells

[1,2-³H]Cholesterol was epoxidized to radioactive cholesterol α- and β-epoxides (5,6α-epoxy-5α- and 5,6β-epoxy-5β-cholestan-3β-ols) in the ratio 1:4 by hepatic microsomal lipid hydroperoxides (MsOOH, 1 mM as active oxygen) in the presence of ferrous ion. MsOOH could be replaced by methyl linoleate hydroperoxides (MOOH) under the same conditions although the latter was less effective than the former. None of cumene hydroperoxide, t-butyl hydroperoxide, and hydrogen peroxide was an effective oxidant even at 10 mM. Neither ADP nor EDTA had an effect on the epoxidation of cholesterol by MsOOH as well as by MOOH. Ferrous ion could not be replaced by ferric ion in the hydroperoxide-mediated epoxidation. Cyanide anion potentially inhibited the reaction.     

The mechanism of cumene hydroperoxide-dependent lipid peroxidation: the significance of oxygen uptake

The addition of limiting amounts of cumene hydroperoxide to rat liver microsomes prepared from phenobarbital-treated rats resulted in the rapid uptake of molecular oxygen, the formation of thiobarbituric acid reactive products, and the loss of hydroperoxide over a similar time course. Maximal activity was observed at pH 7-8. The addition of cumene hydroperoxide to boiled microsomes did not initiate oxygen uptake or produce thiobarbituric acid reactive products. Oxygen uptake was required for the formation of thiobarbituric acid reactive products, but not for the loss of hydroperoxide. The extent of oxygen uptake and thiobarbituric acid reactive product formation was linearly dependent on the concentration of cumene hydroperoxide and independent of the amount of microsomes. For each nanomole of cumene hydroperoxide utilized, 1.5 nmol of oxygen was consumed and 0.11 nmol of thiobarbituric acid reactive products was formed. In addition, a saturable reaction having a high affinity for cumene hydroperoxide was observed that was associated with little or no oxygen uptake and thiobarbituric acid reactive product formation. Butylated hydroxytoluene at substoichiometric concentrations inhibited the extents and initial rates of oxygen uptake and thiobarbituric acid reactive product formation, indicating that cumene hydroperoxide-dependent lipid peroxidation may be an autocatalytic free radical process.     

13-cis-retinoic acid metabolism in vivo. The major tissue metabolites in the rat have the all-trans configuration

The liver and intestinal metabolites of orally dosed 13-cis-[11-3H]retinoic acid were analyzed in normal and 13-cis-retinoic acid treated rats 3 h after administration of the radiolabeled retinoid. all-trans-Retinoic acid was identified as a liver and intestinal mucosa metabolite in normal rats given physiological doses of 13-cis-[3H]retinoic acid. all-trans-Retinoyl glucuronide was identified as the most abundant radiolabeled metabolite in mucosa and a prominent liver metabolite under the same conditions. Thus, the major 13-cis-retinoic acid metabolites retained in liver and mucosa, two retinoid target tissues, had the all-trans configuration. These data indicate that the isomerization of 13-cis-retinoic acid to all-trans-retinoic acid and the subsequent conversion to all-trans-retinoyl glucuronide are central events in the in vivo metabolism of 13-cis-retinoic acid in the rat. Moreover, the all-trans-retinoic acid detected in vivo could account for a significant fraction of the physiological activity of 13-cis-retinoic acid. The tissue disposition and metabolism of orally dosed 13-cis-[3H]retinoic acid are modulated by retinoid treatment. Chronic 13-cis-retinoic acid treatment apparently increased the intestinal accumulation of all-trans-retinoic acid, all-trans-retinoyl glucuronide, and 13-cis-retinoyl glucuronide. The liver concentrations of tritiated all-trans-retinoic acid and all-trans-retinoyl glucuronide were also elevated in 13-cis-retinoic acid treated rats.     

Biosynthesis of 12-oxo-10,15(Z)-phytodienoic acid: identification of an allene oxide cyclase

Incubation of 13(S)-hydroperoxy-9(Z),11(E),15(Z)-octadecatrienoic acid with corn (Zea mays L.) hydroperoxide dehydrase led to the formation of an unstable allene oxide derivative, 12,13(S)-epoxy-9(Z),11,15(Z)-octadecatrienoic acid. Further conversion of the allene oxide yielded two major products, i.e. alpha-ketol 12-oxo-13-hydroxy-9(Z),15(Z)-octadecadienoic acid, and 12-oxo-10,15(Z)-phytodienoic acid (12-oxo-PDA). 12-Oxo-PDA was formed from allene oxide by two different pathways, i.e. spontaneous chemical cyclization, leading to racemic 12-oxo-PDA, and enzyme-catalyzed cyclization, leading to optically pure 12-oxo-PDA. The allene oxide cyclase, a novel enzyme in the metabolism of oxygenated fatty acids, was partially characterized and found to be a soluble protein with an apparent molecular weight of about 45,000 that specifically catalyzed conversion of allene oxide into 9(S),13(S)-12-oxo-PDA.