The reaction of xanthine oxidase with aldehydic products of lipid peroxidation.

A quantitative structure-activity relationship for the reaction of xanthine oxidase with a homologous series of alpha, beta-unsaturated aldehydes, which are known to be products of lipid peroxidation, was investigated. Aldehydes in the series 2-butenal through 2-nonenal and 4-hydroxy-2-nonenal, displayed differential reactivity toward xanthine oxidase as measured by production of the superoxide radical anion. Kinetic parameters for the rate of superoxide production and substrate affinity were determined via the superoxide dismutase-sensitive reduction of cytochrome c. Trends in kinetic parameters as a function of carbon number for the series of trans-2-enals was consistent with a dependence on substrate hydrophobicity. Log kw', a hydrophobicity constant widely employed as a model for the octanol/water partition coefficient, was determined by reversed phase liquid chromatography for the alpha, beta-unsaturated aldehydes in this study. Linear relationships for the correlation of substrate binding (pKm) and efficiency of superoxide production (log kcat/Km) with substrate hydrophobicity (log kw') were found. The mode of inhibition of xanthine oxidation by 2-butenal is shown to be noncompetitive, suggesting distinct binding sites for purine and aldehydic substrates. It is suggested that the reaction of xanthine oxidase with unsaturated aldehydes could be an important route of amplification of oxidative damage in cells.

Single electron reduction of xenobiotic compounds by glucose oxidase from Aspergillus niger.

Various species of fungi express glucose oxidase that catalyzes formation of gluconolactone from glucose with concomitant, direct divalent reduction of molecular oxygen to hydrogen peroxide. A physiological function ascribed to this extracellular enzyme is production of hydrogen peroxide for use in lignin degradation catalyzed by lignin peroxidases. Herein, we show that glucose oxidase can catalyze one-electron reduction of several different classes of xenobiotic compounds resulting in generation of free radical products. Electron spin resonance (ESR) spectroscopy was used to visualize the one-electron reduction products of 4-nitropyridine-N-oxide (4NPO), 1,4-naphthoquinone (1,4NQ), and dichlorophenolindolphenol (DCPIP). Hyperfine splitting constants were used to generate computer simulations of the spectra confirming the presence of free radical products.

Beta carotene and its oxidation products have different effects on microsome mediated binding of benzo[a]pyrene to DNA.

The effects of beta-carotene (betaC) and its oxidation products on the binding of benzo[a]pyrene (BaP) metabolites to calf thymus DNA was investigated in the presence of rat liver microsomes. Mixtures of betaC oxidation products (betaCOP) as well as separated, individual betaC oxidation products were studied. One set of experiments, for example, involved the use of the mixture of betaCOP obtained after a 2-h radical-initiated oxidation. For this data set, the incorporation of unoxidized betaC into microsomal membranes caused the level of binding of BaP metabolites to DNA to decrease by 29% over that observed in the absence of betaC; however, the incorporation of the mixture of betaCOP caused the binding of BaP metabolites to DNA to increase 1.7-fold relative to controls without betaC. Two variations of this experiment were studied: (1) When no NADPH was added, betaC decreased the binding of BaP metabolites to DNA by 19%, but the mixture of betaCOP increased binding by 3.3-fold relative to that observed in the absence of betaC. (2) When NADPH was added under near-anaerobic conditions, betaC caused an almost total (94%) decrease in binding whereas betaCOP had no effect on the amount of binding relative to that observed in the absence of betaC. Both betaCOP and cumene hydroperoxide caused BaP metabolites to bind to DNA even when NADPH was omitted from the incubation mixture. Separation of the mixture of betaC oxidation products into fractions by HPLC allowed preliminary testing of individual betaC oxidation products separately; of the various fractions tested, the products tentatively identified as 11,15'-cyclo-12,15-epoxy-11,12,15,15'-tetrahydro-beta-carotene and beta-carotene-5,6-epoxide appeared to cause the largest increase in BaP-DNA binding. Microsomes from rats induced with 3-methylcholanthrene (3MC) or Aroclor 1254 produced different levels of binding in some experimental conditions. We hypothesize that, under some conditions, the incorporation of betaC into microsomal membranes can be protective against P450-catalyzed BaP binding to DNA; however, the incorporation of betaCOP facilitates the formation of BaP metabolites that bind DNA, although only certain P450 isoforms catalyze the binding process.

tert-Butyl hydroperoxide-induced radical production in rat liver mitochondria.

When rat liver mitochondria are treated with tert-butyl hydroperoxide (TBHP) in the presence of the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO), electron paramagnetic resonance (EPR) signals are detected attributable to spin adducts resulting from the trapping of methyl, tert-butoxyl, and tert-butylperoxyl radicals. The addition of respiratory substrate results in a 3- to 7.5-fold increase in the signal intensity of the DMPO/methyl adduct, no change in the signal intensity of the DMPO/tert-butoxyl adduct, and complete loss of the DMPO/tert-butylperoxyl adduct signal. The magnitude of increase of methyl radical production in the presence of respiratory substrate is related to the respiratory control ratio (RCR) of the mitochondrial preparation. In the presence of antimycin A, which blocks electron flow between cytochromes b and c1, no stimulation of methyl radical production is detected with respiratory substrate. Stimulation of methyl radical production by the addition of respiratory substrate is detected in cytochrome c-depleted mitochondria. A similar increase in methyl radical production is detected when ferrous cytochrome c is treated with TBHP in the presence of DMPO (as compared to when ferricytochrome c is used). These results indicate that TBHP is reduced directly by either cytochrome c1, cytochrome c, or by both of these electron transport chain components in mitochondria undergoing state 4 respiration.

A rapid gas chromatographic assay for determining oxyradical scavenging capacity of antioxidants and biological fluids.

Herein, we report a new, rapid,and reliable method for measuring the protective antioxidant potential of pure antioxidant solutions or biological tissues. Peroxyl radicals generated by thermal homolysis of 2,2'-azobis-amidinopropane (ABAP) cause the oxidation of alpha-keto-gamma-methiolbutyric acid (KMBA) to ethylene; ethylene formation is monitored by gas chromatographic analysis of head space from the reaction vessel. The partial inhibition of ethylene formation in the presence of antioxidants that compete with KMBA for oxyradicals is the basis of the Total Oxyradical Scavenging Capacity Assay (TOSCA). The assay is shown to be reliable for quantifying ROS scavenging potential. The quantifiable parameters are consistent with the relative order of those predicted by the fluorescence- and oxygen electrode-based assays reported in the literature. Antioxidants competing for peroxyl radicals influenced the rate of KMBA oxidation in different ways, but the calculation of TOSC was not affected by such variations. Responses were linear over a wide range of sample concentrations and the TOSC values of classical soluble antioxidants showed the following relative order: Trolox > uric acid > ascorbic acid > GSH. The KMBA method was reliable for biological tissues; the TOSC for 1 microg rat liver cytosolic protein was 0.40 +/- 0.02 and for the microsomal membrane, 0.15 +/- 0.03. Soluble antioxidants accounted for 77% of the protective antioxidant potential in rat liver cytosol. When incorporated into the microsomal membrane, alpha-tocopherol markedly enhances antioxidant protection against peroxyl radical; thus, the assay is suitable for the assessment of fat-soluble antioxidants.

Effects of chronic ethanol ingestion on liver glycogen phosphorylase in male and female rats.

The effects of chronic ethanol ingestion on a preparation of liver glycogen phsophorylase have been studied. A coupled assay in the direction of glycogenolysis was used. In the absence of AMP, a significant decrease in specific activity was observed in both males (19%) and females (30%). AMP additions stimulated phosphorylase activity and completely obliterated the ethanol-induced decreases in both sexes of animal. Kinetic studies, done in the absence of AMP, showed that only the apparent Vmax had been altered by ethanol. These data suggest that decreases in liver glycogen after chronic ethanol ingestion may not be related to the specific activity of glycogen phosphorylase. Using both glucose and caffeine as negative effectors, addditional studies demonstrated that the inhibitory effects of caffeine had been altered by ethanol in both males and females and that the inhibitory effects of glucose had been altered only in females. Even though the specific activity for phosphorylase did not directly implicate this enzyme in the ethanol-induced decrease in liver glycogen stores, the latter data regarding glucose and caffeine suggest that chronic ethanol ingestion has altererd this enzyme and that differences exist between males and females.

Differential effects of the cytochrome P-450/reductase ratio on the oxidation of ethanol and the hydroxyl radical scavenging agent 2-keto-4-thiomethylbutyric acid (KMBA).

NADPH-cytochrome P-450 reductase catalyzes a low rate of oxidation of hydroxyl radical scavenging agents such as ethanol and 2-keto-4-thiomethylbutyric acid (KMBA), in a reaction markedly stimulated by the addition of ferric-EDTA. The effect of various ratios of cytochrome P-450 (phenobarbital-inducible isozyme)/reductase on the oxidation of ethanol and KMBA was determined: There was essentially no increase in KMBA oxidation over the range of ratios from 0.5 to 5 as compared to the reductase-catalyzed rate. High ratios actually caused some decrease in KMBA oxidation, which was especially notable under conditions of increased rates of hydroxyl radical generation (presence of increasing amounts of ferric-EDTA). This decrease at high P-450/reductase ratios could reflect tight coupling of reductase to P-450-PB, therefore decreasing electron transfer from reductase to ferric-EDTA, or could involve non-specific scavenging of .OH by P-450-PB. Indeed, native, but not boiled, P-450 inhibited KMBA oxidation by the xanthine oxidase system. By contrast, the oxidation of ethanol was stimulated at all concentrations of P-450-PB, and this increase was not sensitive to desferrioxamine. However, under conditions of high rates of .OH production, the ethanol oxidation profile tended to resemble the KMBA oxidation profile with respect to the effect of P-450-PB, whereas the two profiles were different under conditions of low rates of .OH production. These results suggest that P-450-PB does not catalyze the oxidation of .OH scavengers or promote the production of .OH, even at ratios of P-450/reductase approaching those found with intact microsomes and even in the presence of excess iron-EDTA, whereas ethanol is directly oxidized by P-450-PB, as are typical drug substrates. However, the P-450-PB-dependent oxidation of ethanol can be masked under conditions in which .OH production is increased.

Induction time course of cytochromes P450 by phenobarbital and 3-methylcholanthrene pretreatment in liver microsomes of Alligator mississippiensis.

Alligator mississippiensis has at least two classes of inducible hepatic microsomal cytochromes P450 (CYP): (1) those induced by 3-methylcholanthrene (3MC), and (2) those induced by phenobarbital (PB). The rates of induction by these xenobiotic compounds are significantly slower than those reported for mammals. Carbon monoxide binding, western blots, and enzymatic activity measurements indicated that at least 48-72 hr are required to reach full induction. A methoxy-, ethoxy-, pentoxy, and benzyloxyphenoxazone (resorufin) O-dealkylation (MROD, EROD, PROD, and BROD) profile was indicative of substrate selectivity typical of 3MC- and PB-induced P450s. MROD and BROD showed the greatest ability to discriminate between alligator hepatic microsomes induced by 3MC and PB, respectively. This is in contrast to mammals, in which EROD is a biomarker of polycyclic aromatic hydrocarbon exposure because of its ability to discriminate the induction of CYP 1A. In a similar manner, PROD is a highly preferred activity of CYP 2B in mammals; thus, it is used to indicate CYP 2B induction. The induction of P450 by PB is a general phenomenon in mammals and birds. To the best of our knowledge, this is the first report demonstrating PB induction of P450 activities typical of the mammalian CYP 2 family isoforms in alligator or any reptilian liver. The importance of this finding to the evolution of CYP 2 family regulation by PB is heightened by the fact that induction by this xenobiotic is not common to fish and other lower vertebrates (Ertl RP and Winston GW, Comp Biochem Physiol, in press). Although indicating the presence of CYP 1A- and CYP 2B-like isoforms in alligator, it remains to be established how closely related these alligator P450s are to mammalian isoforms.

Activation and detoxification of dinitropyrenes by cytosol and microsomes from Aroclor-pretreated rats in the Ames and umu assays.

1,3-, 1,6-, and 1,8-Dinitropyrene (1,3-, 1,6-, and 1,8-DNP) are direct-acting mutagens in that they do not require an exogenous source of enzymes for activation to mutagens in the Ames assay. However, the addition of mammalian S9 preparations, or the microsomal and cytosolic compartments comprising S9, modulate the mutagenic response of these DNPs. In this study, we compared the mutagenic response of these DNPs in the presence of cytosol and microsomal fractions from the liver of Aroclor-pretreated (AR) and control rats, in the Ames mutagenicity assay and umu gene induction assay. 1,3- and 1,8-DNP were deactivated to a greater extent by microsomes from AR-induced and control rats than was 1,6-DNP, in both the umu and Ames assays. In the Ames assay, S9 was more potent in deactivating the DNP than an equivalent concentration of microsomes from the same S9 preparation. Also, S9 from AR-pretreated rats deactivated the isomers to a greater extent than S9 from control rats. In contrast to the constant deactivation of all the isomers in the two assays catalyzed by microsomes and S9, the response with cytosol from AR-pretreated rats differed with respect to the three isomers in the Ames and umu assays. When cytosol from AR-treated rats was added, the mutagenicity of 1,3- and 1,6-DNP, but not 1,8-DNP, was significantly (P < 0.05) increased in the Ames assay while the mutagenicity of the three DNPs was increased in the umu assay. Also, a biphasic response was observed in the umu assay with 1,6- and 1,8-DNP, in that AR-cytosol enhanced the mutagenicity at low protein concentrations (5-50 micrograms protein/reaction) but abrogated the response at higher protein concentrations. The effect of cytosol from control rats depended on the isomer tested; 1,3-DNP was activated above the background level in both assays (nearly towfold) while 1,6-DNP and 1,8-DNP were only activated at low protein concentrations in the umu assay. In the Ames assay, cytosol from AR-pretreated rats did not alter the mutagenic response with 1,8-DNP, while control cytosol significantly (P < 0.05) deactivated 1,8-DNP at all substrate concentrations tested. In summary, this study showed that the mutagenicity of 1,3-DNP was similar in the two assays but the responses with 1,6- and 1,8-DNP differed in the two assays. These isomeric differences could be due to the varying metabolic pathways of the three DNPs as well as the detectable end points of the two assays.

Inhibition of rat heart mitochondrial electron transport in vitro: implications for the cardiotoxic action of allylamine or its primary metabolite, acrolein.

Allylamine (3-aminopropene) is a specific cardiac toxicant that causes aortic, valvular and myocardial lesions in many species. Myocardial necrosis can be observed 24 h after a single dose. Acute toxicity is believed to involve metabolism of allylamine to highly reactive acrolein (2-propenal). Allylamine has been shown to bind to mitochondria from aorta and heart, suggesting that the subcellular site of injury is at or near the mitochondrion. The present investigation compared the effect of allylamine and its primary metabolite, acrolein, on electron transport and oxidative phosphorylation in mitochondria isolated from rat heart (RHM). Both compounds weakly inhibited mitochondrial electron transport with either the combination of glutamate, malate, and malonate (GMM, NADH-linked) or succinate as substrate. Comparisons of the slopes of concentration-effect regression (range of concentrations tested, 0.20-2.0 mM) lines showed acrolein to have significantly greater inhibitory effects than allylamine (range of concentrations tested, 0.22-6.4 mM) on GMM oxidation, while no significant difference in the abilities of the compounds to inhibit succinate oxidation were observed, indicating site preferences for inhibitory action. The addition of an uncoupling agent could not reverse inhibition with either substrate system. These results indicate that both the parent compound and its proposed metabolite primarily inhibit electron transport with little direct effect on the coupling mechanism. The State III EC50 (effective concentrations for 50% inhibition of control mitochondrial enzyme activities) for allylamine (2.29 mM with succinate as substrate and 1.22 mM with GMM) and acrolein (0.80 mM with succinate as substrate and 0.39 mM with GMM) are probably too great to invoke the direct action of either the parent compound or its oxidized metabolite on mitochondrial electron transport as a primary mechanism in the cardiotoxic action of allylamine.

Disodium tetrachloropalladate (Na2PdCl4), an inhibitor of rat liver mitochondrial electron transport.

The effects of Na2PdCl4 were studied on isolated rat liver mitochondrial electron transport and oxidative phosphorylation in vitro. Significant reductions in ADP-stimulated respiration were observed with increasing Na2PdCl4 concentrations with both succinate and NADH-linked substrate oxidations. Concentration necessary for half-maximal inhibition of oxygen uptake (EC50) for an NADH-linked substrate system was 18 muM while with succinate as substrate the EC50 was 15 muM. At 64 muM both systems were inhibited maximally at 60 and 80%, respectively. At concentrations of Na2PdCl4 sufficient to inhibit acceptor-stimulated oxygen uptake, there was a concomitant decrease in the rate of ADP phosphorylation as measured by proton absorption. Uncoupling agents had no effect on Na2PdCl4 inhibited mitochondria. Mg-ATPase activity and phosphate acceptor limited (State 4) respiratory activity were not stimulated by any Na2PdCl4 concentration used in these investigations. Data from these experiments indicate that Na2PdCl4 inhibits the mitochondrial respiratory chain in vitro.

Arylamine activation following chronic ethanol ingestion by rats: studies on the liver S9, microsomal and cytosolic fractions and comparison with Aroclor 1254 pretreatment.

That enzyme fractions derived from animals chronically fed alcohol can alter the metabolism of carcinogenic xenobiotic compounds has been documented. To further understand this relationship the mutagenicity of 3 aromatic amines was determined in the Ames test, employing activation systems derived from rats maintained on an alcohol-containing liquid diet, an isocaloric control liquid diet or Aroclor 1254-pretreated animals fed standard laboratory chow. Depending upon protein and substrate concentrations, S9 from ethanol-fed rats was 30-50% less efficient than S9 from pair-fed rats in activating arylamines (2-aminofluorene, 2-aminoanthracene and 2-acetylaminofluorene) to mutagens in Salmonella typhimurium TA98 and TA100. Cytosolic fractions from ethanol-fed animals always resulted in greater arylamine activation than that of controls whereas the opposite was true of the microsomal compartment in which the ethanol-treated group was consistently less active than the controls. The cytosolic N-acetyltransferase activities with respect to 2 different substrates, isoniazid and 2-aminofluorene, were unaffected by ethanol consumption, indicating that this activity probably does not account for the different activation profiles exhibited by the ethanol and pair-fed cytosolic systems. Both the cytosolic and microsomal compartments are required for maximal expression of the mutagenicity of each arylamine however, each compartment can activate arylamines independently of the other. Reconstituting cytosol with microsomes from ethanol- and pair-fed rats, but not Aroclor-pretreated rats, resulted in a synergistic activation of the aromatic amines and displayed an effect similar to that of S9. Compared to Aroclor pretreatment and pair-fed controls, microsomes from ethanol-fed rats displayed the least capacity for activating any of the arylamines to mutagens. Microsomes from Aroclor-pretreated rats accounted for at least 80% of the S9-mediated activation of each of the arylamines to mutagenic metabolites which was in marked contrast to the contribution of the microsomal fractions to the S9 activity in the ethanol- (5-20% of S9 activity) and pair-fed systems (22-30% of S9 activity). The data indicate that 2 opposing reactions occur in S9, a cytosolic activity that augments and a microsomal activity that attenuates the mutagenicity of arylamines. Both activities are modified by ethanol consumption and Aroclor pretreatment.

Modulation of the mutagenicity of three dinitropyrene isomers in vitro by rat-liver S9, cytosolic, and microsomal fractions following chronic ethanol ingestion.

The effects of chronic ethanol feeding of rats on the ability of liver fractions to modulate the bacterial mutagenicity of three dinitropyrene isomers (1,3-, 1,6- and 1,8-DNP), which require bacterial enzymes but not an exogenous enzyme source for activation, were studied. The mutagenicity of the DNP isomers toward S. typhimurium TA98 and TA100 was attenuated in the presence of post-mitochondrial supernatants (S9) from both ethanol-fed and pair-fed rats albeit, that from the ethanol-fed group was more efficient in lowering the mutagenicity. The cytosolic fraction from ethanol-fed rats enhanced the mutagenicity of all of the DNP isomers in TA100. The most notable enhancement was with 1,3-DNP in which a more than 4-fold enhancement was obtained. Cytosol from pair-fed rats enhanced only the mutagenicity of 1,3-DNP, this by 2.9-fold. Cytosolic NADPH-nitroreductase activity from ethanol-treated rats toward 1,6-, 1,8- and 1,3-DNP was increased 2.8-, 1.7- and 1.3-fold, respectively over pair-fed controls. Cytosolic NADH-nitroreductase from ethanol-fed rats was increased with 1,3-DNP (1.7-fold) and 1,8-DNP (1.4-fold) as substrates, but not with 1,6-DNP. Microsomes decreased the mutagenicity of DNP similarly to S9, i.e., fractions from ethanol-fed rats were more efficient than those of pair-fed rats in deactivating all the DNP isomers. Per mg of protein, detoxification of DNP by S9 was more efficient than with microsomes, thus both cytosolic and microsomal enzymes are required for maximal detoxification. In summary, ethanol feeding modulates both the augmented cytosolic activation of DNP to mutagens and the deactivation of the direct-acting mutagenicity of DNP by microsomes. In combination, as is the case with S9, the microsomal detoxifying activity outcompetes the cytosolic activation.

Mutant frequency of lacI in transgenic mice following benzo[a]pyrene treatment and partial hepatectomy.

The Big Blue, transgenic mouse provides an in vivo mutation system that permits the study of pharmacodynamic parameters on mutant frequency (MF) following xenobiotic exposure. We have studied the effects of cellular proliferation on the frequency of mutations in the lacl transgene by evaluating the MF in the liver of male C57B1/6 Big Blue mice following treatment with benzo[a]pyrene (B[a]P) and a partial hepatectomy. Mice received either 40 mg/kg of B[a]P in corn oil or corn oil alone by i.p. injection on three consecutive days, followed by a partial hepatectomy on the fourth day. Three days later (i.e., 7 days following the initial B[a]P injection), the animals were sacrificed and the MF in the liver was compared to the MF observed in the liver of the same mouse at the time of hepatectomy. Induction of cytochrome P-450 1A (CYP1A) following B[a]P treatment was evident by Western blot analysis. The MF in untreated control animals was not significantly different at hepatectomy (4.7 +/- 0.8 x 10(-5)) and 3 days later, at sacrifice (3.0 +/- 0.4 x 10(-5)). Neither was the MF observed in the B[a]P-treated mice at the time of sacrifice (12.0 +/- 2.1 x 10(-5)) significantly different from the MF observed at the time of hepatectomy (10.6 +/- 5.3 x 10(-5)). However, B[a]P-treatment resulted in a 4.0-fold increase in MF at sacrifice which was significantly different (p < 0.05), when compared to the untreated controls. The B[a]P-treated mice at hepatectomy showed a modest 2.2-fold increase in MF which was not statistically significantly different from the untreated controls. In addition, both control and B[a]P-treated tissues gave sectored mutant plaques. The sectored plaque frequency (SPF) was significantly elevated (p < 0.05) in the B[a]P-treated mice at hepatectomy (4.2 +/- 1.0 x 10(-5)) and sacrifice (7.3 +/- 2.4 x 10(-5)) as compared to the respective frequency in the control mice at hepatectomy (1.9 +/- 0.7 x 10(-5)) and sacrifice (1.4 +/- 0.2 x 10(-5)). One explanation for this data is the persistence of the B[a]P adducts in the mouse genomic DNA that was packaged into the lambda phage, and ultimately fixed as mutations in Escherichia coli.

Evidence for two ethanol oxidizing pathways in reconstituted mixed-function oxidase systems.

The oxidation of ethanol and typical hydroxyl radical scavengers by NADPH-cytochrome P-450 reductase and cytochrome P-450 purified from phenobarbital-treated rats were studied. Ethanol and the scavengers could be oxidized by the reductase system itself. This system was inhibited by superoxide dismutase, competing hydroxyl radical scavengers and desferrioxamine, but stimulated by either EDTA or iron. These results suggest that an iron-catalyzed Haber-Weiss reaction might be involved in the mechanism by which the reductase mediates the oxidation of typical hydroxyl radical scavengers and ethanol. The addition of cytochrome P-450 had no effect on the oxidation of the scavengers, whereas the oxidation of ethanol was enhanced two-to three-fold over the reductase-dependent rate. The oxidation of ethanol was dependent on both the amount of reductase and P-450. There was no effect of competing scavengers, superoxide dismutase or desferrioxamine on the increased rate of ethanol oxidation produced upon addition of cytochrome P-450. Organic hydroperoxides supported the oxidation of ethanol, but not that of the scavengers when added directly to cytochrome P-450. These results suggest that two independent pathways are operative in supporting NADPH-dependent microsomal oxidation of ethanol. One pathway involves hydroxyl radicals which can be generated by the reductase, whereas the other pathway requires the combined presence of both the reductase and cytochrome P-450, and appears to be independent of oxygen radicals.

Sex-related responses to oxidative stress in primary cultured hepatocytes of European flounder (Platichthys flesus L.).

Effects of oxidative stress induced by xenobiotic compounds were studied in primary cultures of isolated hepatocytes of immature European flounder (Platichthys flesus L.) of both sexes caught in a relatively unpolluted area of the German Bight (North Sea). Cells were exposed to oxidative stressors such as 100 microM hydrogen peroxide (H2O2), 100 microM benzo[a]pyrene (B[a]p) and 50 microM nitrofurantoin (N-(5-nitro-2-furfurylidene)-1-aminohydantoin; NF) for 2 and 24 h. Cell mortality was determined with the use of the fluorescent ethidium homodimer-1 and calcein. Oxidative stress response was assessed by quantitative analysis of (1) intracellular reactive oxygen species (ROS) formation with dihydrorhodamine 123, (2) lipid peroxidation on the basis of concentrations of lipid hydroperoxides and the lipid peroxidation products malondialdehyde (MDA) and 4-hydroxynonenal (4-HNE) and (3) cellular total oxidant-scavenging capacity (TOSC) using the TOSC assay (Winston et al., 1998). An increase in ROS formation was detected as early as 2 h after exposure to H2O2, B[a]p and NF. After 24 h, stress responses were lower, except following exposure to NF. The pattern of responses differed with the different oxidative stressors. Lipid peroxidation and the capacity to scavenge ROS were increased significantly in both sexes only after exposure to H2O2, whereas B[a]p and NF provoked sex-dependent responses. B[a]p-induced lipid peroxidation and increase in scavenging capacity were observed only in hepatocytes of females, whereas NF initiated these responses only in cells of males. Sex differences in oxidative stress response only after exposure to pro-oxidants that require enzymatic activation infer the importance of biotransformation pathways in stress responses. Because of their sensitivity to oxidative stress, flounder hepatocytes provide a useful model for early risk assessment of xenobiotics.

Seasonal variations of susceptibility to oxidative stress in Adamussium colbecki, a key bioindicator species for the Antarctic marine environment.

The area of free radical biology is of increasing interest for marine organisms since the enhanced formation of reactive oxygen species (ROS) is a common pathway of toxicity induced by stressful environmental conditions. In polar environments responses of the antioxidant system could be useful as an early detection biomarkers of unforeseen effects of human activities which are progressively increasing in these remote areas. However, the characterization of antioxidant defences in appropriate sentinel species is of particular value also in terms of a possible adaptation to this extreme environment. The scallop, Adamussium colbecki, is a key species for monitoring the Antarctic environment and, besides single antioxidants, the total oxyradical scavenging capacity (TOSC) assay has been recently used for quantifying the overall ability of this organism to neutralize peroxyl radicals (ROO*), hydroxyl radicals (*OH) and peroxynitrite (HOONO). The aim of this work was to obtain a better characterization of these biological responses which can indicate the occurrence of biological disturbance; in this study the total oxyradical scavenging capacity was further analyzed to assess the presence of seasonal fluctuations in the susceptibility to oxidative stress in this species. The capability to neutralize peroxyl radicals and hydroxyl radicals increased at the end of December, while resistance towards peroxynitrite did not show any significant variations during the Antarctic summer. These results suggest the occurrence of metabolic changes which mainly influence intracellular formation of ROO* and *OH, with more limited effects on HOONO. Despite the limited time window analyzed, as a typical constraint in Antarctic research at Terra Nova Bay, an increased resistance to these specific oxyradicals might be related to the period of highest feeding activity, or to other intrinsic factors in the animals' physiology such as the phase of reproductive cycle.

The microsomal mixed function oxidase system of amphibians and reptiles: components, activities and induction.

This article reviews current research in amphibian and reptilian cytochromes P450, important to the overall understanding of xenobiotic metabolism in the ecosystem and the evolution of P450s. Amphibians and reptilians contain the normal mixed function oxidase system (MFO). In general the MFO content and activities are less than those found in mammals, but only a few of the known activities have been examined in these vertebrate classes. Research to date has focused on two families of cytochromes P450, CYP1 and 2. The isoforms examined catalyze the classic activities but there have been notable absences. The total number of isoforms present and the breadth of substrates metabolized are yet unknown. Induction by foreign compounds (xenobiotics) is lengthier and yields lower levels of induced activity than is typically found in mammals. When these animals are pretreated with 3-methylcholanthrene (3MC) and beta-naphthaflavone (BNF), which are known to induce the same isoform in mammals, multiple isoforms are induced with different activities. Phenobarbital-pretreatment in turtles and alligators induces cytochromes P450 and suggestive data indicates induction in the lizard Agama lizard and the newt Pleurodeles waltl. In amphibians and reptiles a CYP2B protein does appear to be present along with constitutive activities associated with the 2 family of cytochromes P450. The markedly different response to classic inducers combined with lower or absent activities alters the view of how amphibians and reptilians respond to xenobiotic challenges.

Spectral analysis and catalytic activities of the microsomal mixed-function oxidase system of the sea anemone (phylum: Cnidaria).

Cnidarians are primarily marine organisms with a wide and diverse habitat worldwide. Previous studies from our laboratory demonstrated the presence of proteins in the molecular mass range of 50-60 KDa that were recognized by several antibodies raised against fish cytochromes P450 of the CYP 1, 2, and 3 families in microsomes prepared from the columnar regions of 5 species of sea anemones (Heffernan et al. Mar Environ Res 1996;42:353-357). Pursuant to those studies we report herein results of spectral analyses, NAD(P)H-oxidoreductase and ethoxyresorufin O-dealkylase (EROD) of sea anemone microsomal fractions. The predominant feature in the difference spectrum of dithionite (DTN)-reduced, CO-liganded anemone microsomes was a peak with lambda max of approximately 418 nm, which slowly increased for about 20 min and decreased after about 40 min. A relatively lower amplitude 450 nm peak was attained within 5 min of CO addition and was stable for up to 90 min. The 450 nm peak did not increase concomitant to the decrease in the 418 nm peak suggesting that the latter is not denatured P450. A significantly larger 450 nm peak was attained in CO-difference spectra when DTN was added prior to CO. NADPH-dependent cytochrome c (P450) reductase of the sea anemones was 1.8-3.9 nmol/min/mg protein, which is at the lower end of the range observed in invertebrates. NADH-cytochrome c reductase was 9-25 nmol/min/mg protein, while the NADH-ferricyanide (b5) reductase ranged from 73-232 nmol/min/mg protein. When microsomal EROD activity was measured under conditions in which the reaction was linear with respect to protein concentration, a decrease in fluorescence was typically observed for the initial 15 min of the time course and then increased linearly for up to 90 min; initial velocities were determined from the increasing linear region. NADPH was the preferred cofactor for EROD activity and the NAD(P)H-EROD activity was higher in Anthopleura elegantissima than Anthopleura xanthogrammica. The Bunodosoma cavernata NADPH-EROD activity was barely noted at the detection limit of the assay and NADH-EROD activity was not detected. These results are consistent with a functional P450-dependent MFO system in cnidarians, with characteristics both similar to and unique from other marine invertebrates.

Benzo[a]pyrene metabolism by the hepatopancreas and green gland of the red swamp crayfish, Procambarus clarkii, in vitro.

The aim of this study was to determine the potential of activating the pro-carcinogen benzo[a]pyrene (B[a]P), elucidating B[a]P metabolite profiles, and to determine pyridine nucleotide-independent peroxygenase activity of Procambarus clarkii hepatopancreas and green gland microsomal cytochromes P450 in vitro. We compare these data to metabolite profiles generated with the rat (Rattus norvegicus) system. The major NAD(P)H-dependent metabolite formed by both hepatopancreas and green gland microsomal fractions was 3-OH-B[a]Pi; cumene hydroperoxide-dependent metabolism of B[a]P produced primarily B[a]P-quinones. B[a]P hydroxylase activity is limited by low microsomal NAD(P)H-dependent cytochrome P450 reductase levels and activity.