Background-Cigarette smoking is a well-known risk factor for the development of cardiovascular disease, yet the mechanism of action involved is not completely understood. Because cigarette smoke contains superoxide and other reactive oxygen species, it has been hypothesized that some of the adverse effects of smoking may result from oxidative damage to endothelial cells, which results in nitric oxide (NO) shortage. However, little information is available regarding the acute effects of smoking on plasma concentrations of NO and antioxidants. We measured the changes in the combined plasma concentrations of nitrate and nitrite as an index of NO concentration, as well as changes in concentrations of major serum antioxidants (ascorbic acid, cysteine, methionine, and uric acid) in smokers after smoking a single cigarette. Methods and Results-A randomized crossover study of the effects of smoking a single cigarette was performed in 20 smokers. Smoking a sham cigarette induced no significant changes in all assayed parameters. However, smoking a single cigarette significantly decreased nitrate and nitrite plasma concentrations by 3.5Ϯ1.2 and 3.4Ϯ1.1 mol/L, compared with plasma concentrations at presmoking and sham smoking, respectively. The concentrations of ascorbic acid and other antioxidants were also significantly lower after smoking a single cigarette. These parameters returned to preexperimental levels 60 minutes after smoking cessation. Conclusion-The present findings indicate that smoking a single cigarette temporarily decreases nitrate, nitrite, and serum antioxidant concentrations in the plasma. These transient changes may partially contribute to coronary vasoconstriction, which is routinely observed after smoking.
This article is available online at http://dmd.aspetjournals.org ABSTRACT:Limonene, a monocyclic monoterpene, is present in orange peel and other plants and has been shown to have chemopreventive activities. (؉)-and (؊)-Limonene enantiomers were incubated with human liver microsomes and the oxidative metabolites thus formed were analyzed using gas chromatography-mass spectrometry. Two kinds of metabolites, (؉)-and (؊)-trans-carveol (a product by 6-hydroxylation) and (؉)-and (؊)-perillyl alcohol (a product by 7-hydroxylation), were identified, and the latter metabolites were found to be formed more extensively, the former ones with liver microsomes prepared from different human samples. Sulfaphenazole, flavoxamine, and antibodies raised against purified liver cytochrome P450 (P450) 2C9 that inhibit both CYP2C9-and 2C19-dependent activities, significantly inhibited microsomal oxidations of (؉)-and (؊)-limonene enantiomers. The limonene oxidation activities correlated well with contents of CYP2C9 and activities of tolbutamide methyl hydroxylation in liver microsomes of 62 human samples, whereas these activities did not correlate with contents of CYP2C19 and activities of S-mephenytoin 4-hydroxylation. Of 11 recombinant human P450 enzymes (expressed in Trichoplusia ni cells) tested, CYP2C8, 2C9, 2C18, 2C19, and CYP3A4 catalyzed oxidations of (؉)-and (؊)-limonenes to respective carveols and perillyl alcohol. Interestingly, human CYP2B6 did not catalyze limonene oxidations, whereas rat CYP2B1 had high activities in catalyzing limonene oxidations. These results suggest that both (؉)-and (؊)-limonene enantiomers are oxidized at 6-and 7-positions by CYP2C9 and CYP2C19 in human liver microsomes. CYP2C9 may be more important than CYP2C19 in catalyzing limonene oxidations in human liver microsomes, since levels of the former protein are more abundant than CYP2C19 in these human samples. Species-related differences exist in the oxidations of limonenes in CYP2B subfamily in rats and humans.
alpha-Tocopherol is a potent antioxidant that effectively protects biological membranes against oxidative injury through coordination with ascorbic acid. Because propofol has a phenolic structure similar to that of alpha-tocopherol, this intravenous anesthetic may also have similar antioxidant activity. To test this hypothesis, the effect of propofol on oxidative injury of human erythrocytes was examined. Propofol inhibited oxidative hemolysis and cis-parinaric acid oxidation in erythrocyte membranes (ED(50) = 6 microM). Although ascorbic acid alone has no appreciable effect, the protective effect of propofol was enhanced by ascorbic acid. An electron spin resonance (ESR) study showed that propofol-derived radicals (g = 2.005) were continuously generated during the oxidation of erythrocyte membranes by an ascorbic acid-inhibitable mechanism. These and other results suggest that propofol interacts with ascorbic acid, thereby exhibiting potent antioxidant activity in and around membranes as does alpha-tocopherol. Kinetic analysis revealed that propofol increased the membrane fluidity of erythrocytes, thereby increasing their resistance to physical and hemodynamic stress. Further, a greater preservation of red blood cell counts was seen after surgery with propofol compared with conventional sevoflurane anesthesia. Thus, propofol may protect erythrocytes against both oxidative and physical stress, indicating its potential as an efficient and safe antioxidant.
Propofol and midazolam are commonly used as sedatives for critically ill patients. These patients usually suffer from the pathologic effects of oxidative stress, predominantly caused by an imbalance between the generation of reactive oxygen species and the antioxidant defense system. Therefore, the antioxidant activities of propofol and midazolam may be of clinical importance. We investigated the activities of these two sedatives against hydrophilic or lipophilic peroxyl radicals in a homogeneous solution and in the presence of erythrocyte membranes. A chemical analysis of the homogeneous solution revealed that propofol efficiently scavenged hydrophilic peroxyl radicals (50% inhibitory concentration [IC50] = 1.3 x 10(-4) M), whereas midazolam efficiently scavenged lipophilic radicals (IC50 = 1.5 x 10(-5) M). Further, in membrane systems, propofol inhibited the oxidative damage induced by either hydrophilic or lipophilic radicals (IC50 = 1.5 x 10(-5) M for hydrophilic radicals and IC50 = 3.0 x 10(-4) M for lipophilic radicals), whereas midazolam did very little. In previous studies, we demonstrated that antioxidant activity is highly affected by the location and properties of the reaction site. The discrepancy in antioxidant activity between a homogeneous condition and in the presence of membranes can be well explained by this concept, and again emphasizes the importance of membranes in determining antioxidant activity. To further understand the biologic significance of these antioxidant properties, the effect of the two agents on endothelium-dependent relaxation was studied. Application of oxidative stress to aortic rings by treating them with peroxyl radicals led to a significant blockade of acetylcholine-induced relaxation after submaximal contraction with phenylephrine. Propofol pretreatment greatly attenuated the impairment in comparison with midazolam, which agrees with the concept of antioxidant activity in the presence of membranes. The results of the present study suggest that propofol has a greater potential to reduce oxidative stress than midazolam.
(+)-Limonene is reported to cause nephropathy in male rats, but not in female rats and other species of animals including mice, rabbits, guinea pigs, and dogs. Male rats contain high levels of alpha2u-globulin in kidneys, and it has been shown that limonene and/or its metabolites are able to bind noncovalently to alpha2u-globulin, resulting in an accumulation of protein droplets in the renal tubules. In this study, we investigated whether (+)- and (-)-limonene enantiomers are differentially metabolized by liver microsomes of male and female rats. (+)- and (-)-limonene enantiomers were found to be oxidized to their respective trans-carveol (6-hydroxylation) and perillyl alcohol (7-hydroxylation) derivatives in greater amounts by liver microsomes of male rats than those of female rats. The limonene hydroxylation activities were not detected in liver microsomes of rat fetuses and were increased developmentally after birth, only in male rats. Treatment of male rats with phenobarbital significantly increased liver microsomal 6-hydroxylation activities with both enantiomers whereas beta-naphthoflavone, isosafrole, and pregnenolone 16alpha-carbonitrile did not cause such effects. Anti-P450 2C9 which cross-reacts with rat P450 2C11 inhibited limonene hydroxylations catalyzed by liver microsomes of untreated male rats, and it was also found that anti-P450 2B1 suppressed the activities catalyzed by liver microsomes of phenobarbital-treated rats. Possible roles of P450 2C11 and P450 2B1 in the limonene hydroxylation activities were supported by the experiments with purified rat liver P450s in reconstitution systems and with recombinant rat P450s in Trichoplusia ni. Our present results showing that there are sex-related differences in the oxidative metabolism of limonene enantiomers by liver microsomes may provide useful information on the basis of limonene-induced toxicities in different animal species.
1. Oxidation of 1,4-cineole, a monoterpene cyclic ether, was studied in rat and human liver microsomes and recombinant cytochrome P450 (P450 or CYP) enzymes expressed in insect cells in which human P450 and NADPH-P450 reductase cDNAs have been introduced. On analysis with gas chromatography/mass spectrometry, 2-exo-hydroxy-1,4-cineole was identified as a principal oxidation product of 1,4-cineole catalysed by rat and human P450 enzymes. 2. CYP3A4 was a major enzyme involved in the 2-hydroxylation of 1,4-cineole by human liver microsomes, based on the following lines of evidence. First, 1,4-cineole 2-hydroxylation activities catalysed by human liver microsomes were inhibited by ketoconazole, a potent inhibitor of CYP3A activities, and an anti-CYP3A4 antibody. Second, there was a good correlation beteeen CYP3A4 contents and 1,4-cineole 2-hydroxylation activities in liver microsomes of eighteen human samples examined. Finally, of 10 recombinant human P450 enzymes examined, CYP3A4 had the highest activity for 1,4-cineole 2-hydroxylation. 3. Liver microsomal 1,4-cineole 2-hydroxylation activities were induced in rat by pregnenolone 16alpha-carbonitrile and dexamethasone and extensively inhibited by ketoconazole, indicative of the possible roles of CYP3A enzymes in this reaction. 4. Kinetic analysis showed that Vmax/Km for 1,4-cineole 2-hydroxylation catalysed by liver microsomes was higher in a human sample HL-104 (4.6 microM(-1) min(-1)) than those of rat treated with pregnenolone 16alpha-carbonitrile (0.49 microM(-1) min(-1)) and dexamethasone (0.36 microM(-1) min(-1)). 5. 1,8-Cineole, a structurally related monoterpene previously shown to be catalysed by CYP3A enzymes, inhibited 1,4-cineole 2-hydroxylation catalysed by human liver microsomes, whereas 1,4-cineole did not inhibit 1,8-cineole 2-hydroxylation activities. Both compounds caused inhibition of testosterone 6beta-hydroxylation by human liver microsomes, the former compound being more inhibitory than the latter. 6. These results suggest that 1,4-cineole and 1,8-cineole, two plant essential oils present in Citrus medica L. var. acida and Eucalyptus polybractea, respectively, are converted to 2-hydroxylated products by CYP3A enzymes in rat and human liver microsomes. It is unknown at present whether the 2-hydroxylation products of these compounds are more active biologically than the parent compound.
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