Oxidations of 17beta-estradiol and estrone and their interconversions catalyzed by liver, mammary gland and mammary tumor after acute and chronic treatment of rats with indole-3-carbinol or beta-naphthoflavone.

Altered cytochrome P450-catalyzed metabolism of 17beta-estradiol (E2) and estrone (E1) in the liver and (or) extrahepatic tissues may affect estrogen-sensitive tumorigenesis. We examined the effects of oral treatments of (i) indole-3-carbinol (13C) at 250 or 500 mg/kg or beta-naphthoflavone (beta-NF) at 40 mg/kg of body weight (bw)/day from 51 to 54 days of age (acute regimen), and (ii) 13C at 250 mg/kg or beta-NF at 20 mg/kg bw given 3x/week from 10 to 22 weeks of age (chronic regimen) in female Sprague-Dawley rats. We determined the effects of these treatments on the P450 content and P450 (CYP)-specific activities in the liver, P450-dependent metabolism of E2 and E1 by the liver and mammary gland, and interconversion of E1 and E2 catalyzed by 17beta-hydroxysteroid dehydrogenase (17beta-HSD) in these tissues and malignant mammary tumors. 13C at the two levels of acute regimen elicited similar responses. Acute and chronic treatments with 13C, but not beta-NF, increased P450 content approximately 2-fold. 13C, and to a lesser extent beta-NF, increased CYP1A1 and CYP1A2 probe activities in liver up to 117- and 27- fold, respectively, and after acute regimens, that of CYP3A by approximately 1.8-fold. 13C also increased activity of CYP2B up to 100-fold. Overall hepatic metabolism of E2 and E1, which was approximately 2-fold greater at 55 than 155 days of age, was increased (approximately 2.8-fold) by 13C with 2-, 4-, 16alpha-, 6alpha-, 6beta-, and 15alpha-hydroxy (OH) comprising > or = 54, 3, 2, approximately 2, approximately 5, 7, and 2%, respectively, of E1 and E2 metabolites. Acute regimens of beta-NF increased 2- and 15alpha-OH-E2 (62 and 5% of total) from E2 and 2-, 4-, and 6alpha-OH-E1 + 6beta-OH-E1 (32, 13, and 4% of total) from E1. Mammary gland metabolized E2 to E1 and small amounts of 15alpha-, 4-, 16alpha-, 6beta-, and 6alpha-OH-E2. After the acute IC3 regimen, E2 was also converted to 2-OH-E2. 17Beta-HSD-catalyzed oxidation of E2 was favored in the liver and reduction of E1 was favored in mammary gland and tumor (= 1% of hepatic activity). An increased (approximately 2-fold) ratio of reductive to oxidative activities in malignant mammary tumors by chronic 13C regimen may stimulate tumor growth. This is the first report showing that after chronic oral regimens, the 13C-, but not beta-NF-, induced changes in CYP complement led to elevated E2 and E1 metabolism. The persistent effects of increased putative carcinogenic and estrogenic 4- and 16alpha-OH as well as 6alpha- and 6beta-OH-E2 and 6beta-OH-E1 might counteract those of the less estrogenic 2-OH metabolites, thus accounting for the lack of suppression of mammary tumorigenesis by 13C in our previous study.

Reductions of nitro and 9-Oxo groups of environmental nitrofluorenes by the rat mammary gland in vitro.

Nitrofluorenes and C-9-oxidized nitrofluorenes are widespread environmental genotoxins which may be relevant for breast cancer on the basis of their carcinogenicities, particularly of 2, 7-dinitrofluorene (2,7-diNF), for the rat mammary gland. Since their metabolism to active carcinogens may involve nitroreduction, this study examined the reduction of 2-nitrofluorene (2-NF) and 2,7-diNF and their 9-oxo- and 9-hydroxy (OH) derivatives by the rat mammary gland. Cytosolic fractions catalyze NADH- and NADPH-dependent reductions of the 2-nitro and 9-oxo to the respective 2-amino and 9-OH compounds at rates 4- and >/=10-fold greater than those with microsomes. Rates of amine formation catalyzed by cytosol from 2, 7-diNF are greater than the rate from 2-NF and increase for C-9-oxidized derivatives: 9-oxo-2-NF > 9-OH-2-NF > 2-NF and 9-OH-2, 7-diNF >> 9-oxo-2,7-diNF > 2,7-diNF. Nitroreduction is inhibited by O(2) or allopurinol (20 microM), dicoumarol (100 microM), and rutin (50 microM). 9-Oxoreduction is inhibited by rutin, dicoumarol, and indomethacin (100 microM), but not by O(2) or allopurinol. Pyrazole or menadione does not inhibit nitro or 9-oxoreduction. Xanthine, hypoxanthine, 2-hydroxypyrimidine, and N'-methylnicotinamide support cytosol-catalyzed nitro, but not 9-oxo, reduction. The data suggest that the nitroreduction is catalyzed largely by a xanthine oxidase and partially by a diaphorase and 9-oxoreduction by a carbonyl reductase. The extents of the nitro and carbonyl reductions of the nitrofluorenes may determine their reactivities with DNA, and thus genotoxicities for the mammary gland.

Nitroreduction of nitrated and C-9 oxidized fluorenes in vitro.

Widespread environmental pollution with mutagenic and carcinogenic nitrofluorenes contributes to human health risks. Since nitroreduction leads to activation of many nitro compounds, nitroreduction of the nitrofluorene (NF) derivatives by one- and two-electron reductants was examined. Rates of nitroreduction catalyzed by xanthine oxidase (XO)/hypoxanthine and measured via stimulation of acetylated cytochrome c reduction increased with the number of nitro groups and oxidation at C-9: 9-oxo-2,4,7-triNF > 9-oxo-2,7-diNF > 2,7-diNF > 9-oxo-2-NF = 2,5-diNF > 9-hydroxy-2-NF > 2-NF. Ascorbate catalyzed one-electron reduction to nitro anion radicals which reacted with molecular O2 to yield superoxide. Rates of O2 uptake with 9-oxo-2,4,7-triNF and 9-oxo-2,7-diNF were 63 and 0.17 times those, respectively, with equivalent concentrations of nitrofurazone, a classical substrate. Superoxide formation was indicated by the approximately 75% regeneration of O2 upon addition of superoxide dismutase and catalase. 9-Oxo-2,4,7-triNF stimulated O2 uptake in the presence of XO/NADH with typical Michaelis-Menten kinetics with an apparent Km of 0.476 +/- 0.054 microM versus a Km of 6.18 +/- 0.719 microM for nitrofurazone. HPLC analyses of products from reduction catalyzed by XO or diaphorase of Clostridium with NADH showed the following trends for the rates of amine formation from 9-oxo-2,7-diNF > 2,7-diNF; 9-oxo-2-NF > 9-hydroxy-2-NF > 2-NF; 2,7-diNF > 2-NF; and 9-oxo-2,7-diNF > 9-oxo-2-NF. Little or no amine was formed in 95% O2, suggesting O2-labile intermediates. The data herein suggest that oxidation at C-9 and multiple nitro groups increase the potential for nitroreduction of the nitrofluorenes in vivo which may lead to genotoxic effects.

Effect of ovariectomy on the in vitro and in vivo activation of carcinogenic N-2-fluorenylhydroxamic acids by rat mammary gland and liver.

N-Hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA) and its benzamide analogue N-OH-2-FBA are mammary gland carcinogens in the female Sprague-Dawley rat. Ovariectomy inhibits tumorigenicity of topically applied N-OH-2-FAA suggesting modulation of carcinogen-activating enzymes in the gland. This study concerned the activation of N-OH-2-FAA and N-OH-2-FBA by the mammary gland and liver, a chief site of metabolism, from 50-day-old female rats and effects on the activation of ovariectomy performed at 22 days of age. The levels of N-debenzolyation of N-OH-2-FBA to N-hydroxy-N-2-fluorenamine (N-OH-2-FA), catalyzed by microsomal carboxylesterases in mammary gland and liver were similar and increased 1.5- and 1.7-fold, respectively, by ovariectomy. N-Debenzoylating activity in cytosols of both tissues appeared to be partially of microsomal origin. Mammary gland cytosol contained N-, O- and N,O-acyltransferase activities at levels 40-50% those of liver. N-Acyltransferase activity was determined via acetyl coenzyme A (AcCoA)-dependent acetylation of 2-FA and a new assay, N-OH-2-FAA-dependent acetylation of 9-oxo-2-FA. The latter activity was decreased in mammary gland by ovariectomy. Microsomal N-acyltransferase activities were <36% those of cytosols. AcCoA-dependent binding of N-OH-2-[ring-[3H]FBA to DNA, catalyzed by cytosol, was consistent with a two-step activation of N-OH-2-FBA involving esterase-catalyzed N-debenzoylation to N-OH-2-FA and its O-acyltransferase-catalyzed acetylation to the electrophilic N-acetoxy-2-FA. O-Acetyltransfer by mammary gland appeared to be rate-limiting since ovariectomy-dependent increases in N-debenzoylation did not increase binding with S9 fraction. Little or no sulfotransferase-catalyzed binding of N-OH-2-[ring-3H]FBA-derived N-OH-2-[ring-3H]FA was detected in the liver or mammary gland cytosol, respectively. The level of binding of N-OH-2-[ring-3H]FAA to DNA catalyzed by cytosolic N,O-acyltransferase was decreased approximately 23% in mammary gland and increased 1.2-fold in liver by ovariectomy. 32P-Postlabeling analyses indicated a single adduct N-(deoxyguanosin-8-yl)-2-fluorenamine in DNA of both tissues 24 h after one intraperitoneal injection of N-OH-2-FBA or N-OH-2-FAA. Respective levels were 3.6- and 5.5-fold greater in liver than mammary gland. After ovariectomy, the adduct levels from N-OH-2-FBA increased 1.8-fold in mammary gland and from N-OH-2-FAA decreased approximately 50% in both tissues. Thus, the ovariectomy-dependent changes in levels of enzymes activating N-OH-2-FBA and N-OH-2-FAA were consistent with in vivo DNA adduct levels in the target mammary gland, but not in the liver.

Debenzoylating and deacetylating activities of rat liver and mammary gland microsomes. Effect of ovariectomy.

This study compared the rates of N-deacylations of N-hydroxy-N-2-fluorenylbenzamide (N-OH-2-FBA) with those of its analogue, N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA), by the mammary gland (tumor target for both compounds) and the liver of female Sprague-Dawley rats and examined the effect of ovariectomy on these activities. N-Debenzoylation of N-OH-2-FBA was catalyzed by the mammary and liver microsomes of 50-day-old female rats at similar rates (approximately 24 nmol/min/mg). The activity of both tissues increased (up to 1.8 times) after ovariectomy at 42, 32 and, especially, 22 days of age. The rapid hydrolysis appeared to be unique for the benzoyl group since N-OH-2-FAA was deacylated only approximately 0.05 and 0.004 times as fast by the liver and mammary microsomes, respectively, and these low rates were unaffected by ovariectomy. Since such substrate specificity would be of significance in the metabolism of xenobiotics and drug design, esterase activity and its sensitivity to ovariectomy at 22 days of age were examined with several acetylated and benzoylated substrates in the liver and mammary microsomes and compared with those of male liver. Tissues of rats of both sexes had a greater capacity to hydrolyze carboxyl esters than amides. Expect for N-2-fluorenylacetamide (2-FAA) and o-nitrophenylacetate (o-NPA), all substrates were hydrolyzed by liver microsomes of the male up to 3.9 times faster than by those of the female. Microsomes of female liver hydrolyzed acetylated substrates 1.2 to 25 times faster than benzoylated analogues except for N-OH-2-FBA and benzamide. By contrast, mammary gland microsomes hydrolyzed benzoylated compounds 1.4 to 333 times faster except for 2-naphthyl benzoate. Respective rates of hydrolysis of o-NPA by microsomes of liver and mammary gland were 1.7 and 0.6 times those of p-NPA. After ovariectomy, deacylating activities increased (up to 1.6 times) except for those of 2-FAA and acetanilide. All deacylations were > 98% inhibited by 0.1 mM paraoxon, indicating catalysis by serine hydrolases. The results suggest involvement of multiple carboxylesterases and indicate that certain benzoylated xenobiotics may have a greater effect on the mammary gland than acetylated xenobiotics because of their greater vulnerability to hydrolysis by esterases of mammary gland.

Detection of N-(deoxyguanosin-8-yl)-2-fluorenamine in DNA of peritoneal serosa and liver after intraperitoneal exposure of rats to N-hydroxy-N-2-fluorenylbenzamide or N-hydroxy-N-2-fluorenylacetamide.

DNA adduct formation was examined in rat peritoneal serosa, a tumor target for i.p. administered aqueous suspensions of N-hydroxy-N-2-fluorenylbenzamide (N-OH-2-FBA) and N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA), and compared to that in the liver, which is a tumor target for N-OH-2-FAA in the male rat. 32P-Postlabeling analyses showed the presence of a single adduct, N-(deoxyguanosin-8-yl)-2-fluorenamine (dG-C8-FA), from activation of both hydroxamic acids by the serosa and liver in vitro and in vivo. The relatively low levels of dG-C8-FA (60-80 fmol/micrograms DNA) from N-OH-2-FBA in vitro were increased 2.7- and 35-fold upon the addition of acetyl coenzyme A (AcCoA) to the serosal cytosol and hepatic cytosol or microsomes respectively. By contrast, addition of AcCoA led to a decrease (approximately 34%) in the high level of dG-C8-FA (4330 fmol/micrograms DNA) from activation of N-OH-2-FAA by hepatic cytosol and did not alter the levels from activation by hepatic microsomes and serosal cytosols (530 and 78.3 fmol/micrograms DNA respectively). These data and the previously reported hydroxamic acid activation enzyme activities in the serosa and liver indicated that the precursor of dG-C8-FA, N-acetoxy-N-2-fluorenamine, was formed from N-OH-2-FAA chiefly via an intramolecular N,O-acetyltransfer and from N-OH-2-FBA via a two-step sequence of N-debenzoylation and AcCoA-dependent O-acetylation. The levels of dG-C8-FA were approximately 2- to 3-fold higher in the serosal DNA (up to 515 and 1012 fmol/micrograms DNA) after one (30 mumol/rat) and ten or eleven (cumulative dose of approximately 275 mumol/rat) injections of N-OH-2-FBA or N-OH-2-FAA than in the hepatic DNA. This correlated with the carcinogenicities of the hydroxamic acids, but was inversely proportional to the rates and extents of their activation in vitro. Multiple injections affected hepatic enzyme activities related to the activation of the hydroxamic acids in that the cytosolic N-debenzoylation of N-OH-2-FBA increased (approximately 1.7-fold) whereas N-OH-2-FAA acetyltransferase and sulfotransferase activities decreased. The effect of treatment with N-OH-2-FBA was greater than that with N-OH-2-FAA and was greater on the sulfotransferase activity (approximately 88% decrease). The latter suggested that N-OH-2-FBA, although a poor acceptor for an enzymatic sulfate transfer, may be carcinogenic for the rat liver.(ABSTRACT TRUNCATED AT 400 WORDS)

Peroxidative metabolism of carcinogenic N-arylhydroxamic acids: implications for tumorigenesis.

Peroxidative oxidations of chemical carcinogens including N-substituted aryl compounds could result in their metabolic activation because the products react with cellular molecules and lead to cytotoxicity, mutagenicity, and carcinogenicity. In vivo, peroxidative activities are chiefly of neutrophilic leukocyte origin. Neutrophils may be attracted to the site(s) of exposure to carcinogen and, via phagocytosis and respiratory burst, release oxidants that catalyze carcinogen activation and/or cause DNA damage. Our studies, presented herein, concern oxidations of carcinogenic N-arylhydroxamic acids, N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA), and N-hydroxy-N-2-fluorenylbenzamide (N-OH-2-FBA), by enzymatic and chemical systems simulating those of neutrophils, myeloperoxidase and hydrogen peroxide (H2O2) +/- halide, and hypohalous acid and halide at the physiologic concentrations (0.1 M Cl- and/or 0.1 mM Br-) and the pH (4-6.5) of phagocytosis. Studies also concern oxidations of the hydroxamic acids by rat peritoneal neutrophils stimulated to undergo respiratory burst and release myeloperoxidase in medium-containing 0.14 M Cl- +/- 0.1 mM Br-. The metabolites formed in the presence of exogenous H2O2 are consistent with two peroxidative mechanisms: one electron-oxidation to a radical that dismutates to equimolar 2-nitrosofluorene (2-NOF) and the ester of the respective hydroxamic acid and halide-dependent oxidative cleavage, especially efficient in the presence of Br-, to equimolar 2-NOF and the respective acyl moiety. 2-NOF and the esters undergo further enzymatic and nonenzymatic conversions to unreactive products and/or may bind to cellular macromolecules. The results suggest that peroxidative metabolism of N-arylhydroxamic acids by neutrophils, yielding the potent direct mutagen 2-NOF and the electrophilic esters, occurs in vivo and is involved in the activation and thus local tumorigenicities of the hydroxamic acids at the site(s) of application.

Activation of the carcinogens N-hydroxy-N-2-fluorenylbenzamide and N-hydroxy-N-2-fluorenylacetamide via deacylations and acetyl transfers by rat peritoneal serosa and liver.

Intraperitoneally administered N-hydroxy-N-2-fluorenylbenzamide (N-OH-2-FBA) and N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA) are carcinogenic for rat peritoneum. The potential of peritoneal serosa to activate these compounds via deacylations and acyl transfers was compared to that of liver. N-Deacylations of N-OH-2-FBA and N-OH-2-FAA to N-2-fluorenylhydroxylamine (N-OH-2-FA) were faster by liver than serosa and by microsomes than cytosols. N-Debenzoylations of N-OH-2-FBA were 73- to 123-fold faster than N-deacetylations of N-OH-2-FAA. The esters, N-benzoyloxy-2-FBA and N-acetoxy-2-FAA, were O- and N-deacylated to N-OH-2-FA by liver, and the benzoate by serosa. Inhibition by paraoxon of the above deacylations implicated a serine carboxylesterase. Liver and serosa cytosols catalyzed acetyl CoA-, but not benzoyl CoA-, dependent and iodoacetamide (IAA)-sensitive N-acylation of N-2-fluorenamine (2-FA), implicating an acetyltransferase. In hepatic microsomes this activity was IAA-insensitive and partially inhibited by paraoxon. Liver cytosol, but not microsomes, used N-OH-2-FAA as an acyl donor and neither used N-OH-2-FBA. Liver and serosa catalyzed binding to DNA of N-OH-2-[ring-3H]FBA which was paraoxon-sensitive and increased by acetyl CoA, but not benzoyl CoA. Binding to DNA of N-OH-2-[ring-3H]FAA catalyzed by cytosols was approximately 22-fold greater in liver than in serosa and was IAA-sensitive. Microsome-catalyzed binding of this compound in both tissues was increased approximately 2-fold by acetyl CoA. The results support a two-step activation of N-OH-2-FBA in the liver consisting of esterase-catalyzed N-debenzoylation to N-OH-2-FA and an acyltransferase-catalyzed O-acetylation to the putative electrophile N-acetoxy-2-FA. In the serosa, binding to DNA appears to be due to rapid N-debenzoylation to N-OH-2-FA, a fraction of which is O-acetylated. Whereas activation of N-OH-2-FAA by liver and serosa microsomes may also involve N-OH-2-FA and/or its O-acetate, activation by the cytosols is consistent with N,O-acetyltransfer of N-OH-2-FAA to yield N-acetoxy-2-FA. The study provides first evidence for activation of N-OH-2-FBA by rat liver and of both compounds by peritoneum in vitro.

Metabolism of the carcinogen N-hydroxy-N-2-fluorenylacetamide by rat peritoneal neutrophils.

The in vitro metabolism of a locally carcinogenic N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA) by rat peritoneal polymorphonuclear leukocytes (PMNL), chiefly neutrophils, elicited with intraperitoneal injections of proteose peptone, was examined. At 10(6) PMNL/ml in media containing halide (X-), 0.14 M Cl- +/- 0.1 mM Br- (without Ca++ and Mg++), addition of 10 nM phorbol myristate acetate (PMA) resulted in generation of superoxide anion and H2O2. Subsequent cetyltrimethylammonium Cl- (Cetac) addition at 0.002% effected myeloperoxidase (MPO) activity release. PMNL treated with PMA and/or Cetac did not metabolize N-OH-2-FAA (30 microM). However, 1-2 pulses of H2O2 (50 microM) after Cetac addition resulted in oxidation of N-OH-2-FAA to N-acetoxy-2-FAA (< 0.5 microM) and 2-nitrosofluorene (2-NOF) (1-2 microM). In the presence of Br- 2-NOF was increased (3-5 microM). The results are consistent with oxidation of N-OH-2-FAA by MPO/H2O2 and MPO/H2O2/X- via two pathways: one electron oxidation leading to N-acetoxy-2-FAA and 2-NOF, and X(-)-dependent oxidation to 2-NOF. N-Acetoxy-2-FAA (10 microM) incubated with PMNL under similar conditions was converted non-enzymatically to 4-OH-2-FAA (< or = 5 microM) and enzymatically to N-OH-2-FAA (< or = 3 microM). In the presence of H2O2, smaller amounts of these products were formed. Formation of N-OH-2-FAA was prevented by paraoxon (0.1 mM) suggesting O-deacetylase activity. However, accountability for N-acetoxy-2-FAA decreased with time, presumably because of binding to cellular macromolecules. With H2O2 addition, 2-NOF (10 microM) was converted to 0.5 or 0.25 microM 2-nitrofluorene by active PMNL or heat-inactivated cell lysates, respectively. Low recoveries of 2-NOF were also attributed to binding. The results suggest that PMNL may be involved in activation of the carcinogenic N-arylhydroxamic acids in vivo.

Activation of the carcinogen N-hydroxy-N-(2-fluorenyl)benzamide via chemical and enzymatic oxidations. Comparison to oxidations of the structural analogue N-hydroxy-N-(2-fluorenyl)acetamide.

Chemical or enzymatic oxidations of the carcinogen N-hydroxy-N-(2- fluorenyl)benzamide (N-OH-2-FBA) were investigated under the conditions facilitating one-electron oxidation or oxidative cleavage of N-hydroxy-N-(2-fluorenyl)acetamide (N-OH-2-FAA). HPLC methods were developed for separation and quantitation of the above hydroxamic acids and their respective oxidation products. To identify the products of oxidation of N-OH-2-FBA, N-(benzoyloxy)-2-FBA (N-BzO-2-FBA) was synthesized and shown to undergo ortho rearrangement to 1- and 3-BzO-2-FBA. Oxidation of N-OH-2-FBA (4.88 mM) with alkaline K3Fe(CN)6 in benzene was complete and yielded equimolar amounts of 2-nitrosofluorene (2-NOF) and the ester (chiefly N-BzO-2-FBA), indicative of one-electron oxidation to nitroxyl free radical which undergoes bimolecular dismutation. However, one-electron oxidation of N-OH-2-FBA (30 or 10 microM) by horseradish peroxidase/H2O2 at pH 7 or myeloperoxidase/H2O2 at pH 6.5 yielded only approximately 10% as much product as N-OH-2-FAA (30 microM). The addition of 0.1 mM Br- +/- 0.1 M Cl- at pH 4 to 6.5 increased 2-NOF formation in MPO/H2O2-catalyzed oxidations. Simulations of these oxidations with HOCl/Cl- or HOBr/Br- showed that the latter was more efficient, converting N-OH-2-FAA almost completely and less than or equal to 62% of N-OH-2-FBA to 2-NOF. The amounts of the ester (N- and o-BzO-2-FBA), which by itself did not contribute to 2-NOF formation or significant substrate regeneration, indicated that approximately 10% of 2-NOF originated from one-electron oxidation.(ABSTRACT TRUNCATED AT 250 WORDS)

Chromosome mosaicism in hypomelanosis of Ito.

Our finding of chromosome mosaicism with a ring 22 in a retarded black boy with hypomelanosis of Ito prompted a review of this "syndrome." Most patients have a variety of non-dermal defects, particularly those affecting CNS function. Among karyotyped patients, most are chromosome mosaics of one sort or another. Hypomelanosis of Ito turns out to be a causable non-specific phenotype, i.e., a clinical marker for chromosome mosaicism of all different types in individuals with a dark enough skin to show lighter patches. Consequently, cytogenetic evaluation is indicated in all patients with this skin finding.

Oxidations of the carcinogen N-hydroxy-N-(2-fluorenyl)acetamide by enzymatically or chemically generated oxidants of chloride and bromide.

The oxidations of the carcinogen N-hydroxy-N-(2-fluorenyl)acetamide (N-OH-2-FAA) via one-electron (1e-) oxidation to equimolar 2-nitrosofluorene (2-NOF) and N-acetoxy-2-FAA and via oxidative cleavage to 2-NOF by chemically and myeloperoxidase (MPO)/H2O2 generated oxidants of Cl- and/or Br- were investigated. 2-NOF was determined spectrophotometrically in the reaction mixtures and by HPLC of their extracts; N-acetoxy-2-FAA was determined by HPLC. In the presence of individual or mixed halides at their physiologic concentrations (0.1 M Cl- and/or 0.1 mM Br-) and pH 4-6, MPO/H2O2-catalyzed oxidation of N-OH-2-FAA to 2-NOF via oxidative cleavage was much greater than 1e- oxidation. At the respective pH optima, oxidation was much more rapid with Br- and Br- + Cl- than with Cl-. HOBr or HOCl + Br- oxidized N-OH-2-FAA more rapidly than HOCl, also chiefly via oxidative cleavage. This suggested that, in the presence of MPO/H2O2 + Cl- + Br-, oxidation was due to HOBr from HOCl oxidation of Br- and/or oxidation of Br- by MPO/H2O2. In the presence of taurine (1 or 10 mM), a scavenger of hypohalous acids, MPO/H2O2 catalysis of oxidative cleavage was unaffected with Br-, prevented with Cl-, and partially prevented with Cl- + Br-. These results were linked to N-halotaurine formation since it was found that N-bromotaurine, but not N-chlorotaurine, oxidized N-OH-2-FAA chiefly to 2-NOF. With time N-chlorotaurine and N-bromotaurine appeared to undergo a pH-dependent halide exchange with Br- and Cl-, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Determination of peroxidative halogenation in mixtures of chloride and bromide.

A method for the differentiation of chlorinated and brominated products from peroxidative oxidation of mixtures of the halides is presented. Chlorination or bromination of monochlorodimedone (MCD) by fungal chloroperoxidase (CPO) was measured by loss of MCD absorbance. Although the Vmax was similar for both halides [approximately 0.08 mM (2 min)-1], the apparent Km for chlorination was 10 times greater than that for bromination (5.88 vs 0.67 mM). Chlorination was also quantitated as I3- produced from N-chlorotaurine and I-. The Vmax [0.076 mM (2 min)-1] and apparent Km (6.31 mM) determined by this method agreed with those determined with MCD. Selective reduction by H2O2 of the I-oxidizing potential of N-bromotaurine allowed determination of the brominated product from the difference between the amounts of halogenated MCD and N-chlorotaurine. The brominated product predominated at saturating and at physiologic halide levels. Hence, it is suggested that Br- plays a significant role in halogenation even though in vivo levels of Cl- are equal to or greater than 1000 times those Br-.

Peroxidative metabolism of a carcinogen, N-hydroxy-N-2-fluorenylacetamide, by rat uterus and mammary gland in vitro.

Lactoperoxidase-catalyzed metabolism of N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA) may be via one-electron oxidation to nitroxyl free radical which dismutates to equimolar N-acetoxy-N-2-fluorenylacetamide and 2-nitrosofluorene (2-NOF) and/or a Br(-)-dependent oxidative cleavage to 2-NOF. Hence, the 2-NOF:N-acetoxy-N-2-fluorenylacetamide ratios reflect the relative contributions of the two peroxidative pathways to the metabolism of N-OH-2-FAA. Peroxidative activities of rat uterus (UT) and mammary gland (MG) were extracted with a cationic detergent, cetyltrimethylammonium bromide (Cetab). MG extracts had 1 to 5% the specific activity of UT extracts when assayed with guaiacol as hydrogen donor. At 0.004% Cetab, which in the incubation media corresponds to the approximate physiological levels of 0.1 mM Br(-), oxidation of N-OH-2-FAA by UT extracts yielded a product ratio indicative of both peroxidative pathways with Br(-)-dependent oxidation prevailing. At 0.4% Cetab, one-electron oxidation was negligible and Br(-)-dependent conversion of N-OH-2-FAA to 2-NOF was markedly enhanced. At both 0.004 and 0.4% Cetab, MG extracts yielded only 2-NOF, suggesting solely Br(-)-dependent oxidation. With equivalent guaiacol units of peroxidative activities, MG extracts produced much lower amounts of 2-NOF than did UT extracts. The low specific activities of MG extracts necessitated the use of larger amounts of protein, which might have interfered with peroxidative metabolism. At 0.004% Cetab, formation of 2-NOF by the Br(-)-dependent pathway was greater at pH 5.5 than at 7.4. At acid pH, small amounts of 2-nitrofluorene were also formed by UT and MG extracts and could be attributed to further oxidation of 2-NOF. Peroxidative activities of the UT and MG extracts may be of granular leukocyte origin and their potential role in carcinogen activation and tumorigenesis is discussed.

A novel oxidation of the carcinogen N-hydroxy-N-2-fluorenylacetamide catalyzed by peroxidase/H2O2/Br-.

N-Hydroxy-N-2-fluorenylacetamide, a proximate carcinogenic metabolite of N-2-fluorenylacetamide, is oxidized largely to 2-nitrosofluorene by lactoperoxidase or extract of peroxidative activity of rat uterus in an H2O2- and Br- -dependent reaction. Evidence is presented that the oxidizing species includes OBr- (HOBr). This novel oxidation may be involved in carcinogenesis by N-arylhydroxamic acids.

Microsomal metabolism of the carcinogen, N-2-fluorenylacetamide, by the mammary gland and liver of female rats. I. Ring- and N-hydroxylations of N-2-fluorenylacetamide.

We determined ring- and N-hydroxylations of a systemic mammary gland carcinogen, N-2-fluorenylacetamide (2-FAA), by microsomal fractions of liver and mammary gland of female rats and the effects of in vivo and/or in vitro modifiers of these oxidations. Pretreatment of lactating rats with 3-methylcholanthrene (3-MC) or beta-naphthoflavone (beta-NF) and non-lactating (50-day old virgin) rats with beta-NF showed similar effects in that the formation of 3-, 5-, 7-, 9- and N-hydroxy-2-FAA by hepatic microsomes was increased manyfold and the formation of 1-hydroxy-2-FAA was induced. In mammary gland microsomes, the formation of 3-, 5- and 7-hydroxy-2-FAA was likewise increased, but of 9-hydroxy-2-FAA was unaffected. Only mammary microsomes of lactating rats had capacity for N-hydroxylation which was increased approximately 3 times by pretreatment of rats with 3-MC or beta-NF. All of the induced increases of metabolites of 2-FAA in hepatic and mammary microsomes were inhibited by 0.1 mM alpha-naphthoflavone (alpha-NF) in vitro. Pretreatment of non-lactating rats with phenobarbital increased only the formation of 7-hydroxy-2-FAA in hepatic microsomes which was further stimulated by alpha-NF in vitro. The latter also stimulated the formation of 7- and 9- hydroxy-2-FAA by hepatic microsomes of the uninduced rats, but had no effects in mammary microsomes, in which 9-hydroxy-2-FAA was a major metabolite. Hence, the data showed qualitative and quantitative differences between lactating and non-lactating rats in metabolism of 2-FAA by mammary microsomes which may result from differences in the levels (e.g., of cytochrome P-450) and activities of microsomal enzymes determined herein. In hepatic microsomes of these rats, differences in quantities of metabolites of 2-FAA (3-, 7-, 9- and N-hydroxy-2-FAA) were found in corn oil-treated rats only. The solvent (methanol or acetone) used for addition of 2-FAA to the incubation mixtures altered quantitatively the metabolite profiles in hepatic and mammary microsomes of 3-MC or beta-NF treated rats. The formations of 1- and 3- or 5- and 7-hydroxy-2-FAA were greater in the presence of acetone or methanol, respectively. The results of this study suggest that the formation of phenolic and N-hydroxy metabolites of 2-FAA in both hepatic and mammary microsomes of lactating rats is catalyzed by similar form(s) of cytochrome P-450 induced by pretreatment with 3-MC or beta-NF.(ABSTRACT TRUNCATED AT 400 WORDS)

Modifications of carcinogen metabolism in hepatic microsomes of suckling young by 3-methylcholanthrene or beta-naphthoflavone administered to lactating rats.

The effects of treating lactating rats with 3-methylcholanthrene (3-MC) or beta-naphthoflavone (beta-NF) (three i.p. injections of 20 or 40 mg compound/kg of body weight) on hepatic microsomal enzymes of their suckling young were examined. This treatment had no apparent effect on the contents of cytochromes P-450 and b5 or on the activities of NADH- and NADPH-cytochrome c reductases in hepatic microsomes of the pups. However, these microsomes had 8- and 6-fold increased capacities for hydroxylations of benzo[a]pyrene (B[a]P) and N-2-fluorenylacetamide (2-FAA) respectively. These increases were about 5-fold greater in the hepatic microsomes of the dams, in which they were inhibited by 0.1 mM alpha-naphthoflavone (alpha-NF) in vitro 72-81 and 89-95% and by 0.1 mM beta-NF in vitro 12-41 and 60-76% respectively. In the pups, the induced activities were also inhibited, whereas the basal hydroxylations of B[a]P and 2-FAA were stimulated by alpha-NF 2.7- and 5.0-fold and by beta-NF 1.4- and 2.4-fold respectively. The inhibition of the induced hydroxylations by alpha-NF and beta-NF may be explained by their higher affinities (Ks, 0.14 and 0.28 microM, respectively) than those of B[a]P and 2-FAA (Ks, 4.4 to 8.8 and 2.4 to 3.1 microM, respectively) for cytochrome P-450. Whereas beta-NF gave a type I binding spectrum, alpha-NF gave a spectrum composed of type I and reverse-type I elements. Analysis of metabolites of 2-FAA showed differences in their type and amounts formed by hepatic microsomes of beta-NF-treated lactating rats and their pups. Thus, in the dams the formation of 1-, 3-, 5-, 7-, 9- and N-hydroxy-2-FAA was increased by 9-, 30-, 40-, 5-, 20- and 5-fold respectively. In the pups, the formation of 1-, 3-, 5-, 7- and N-hydroxy-2-FAA was increased by 2-, 30-, 18-, 4- and 27-fold respectively. All these increased hydroxylations were inhibited by 0.1 mM alpha-NF in vitro. In the hepatic microsomes of pups from the corn oil-treated dams, alpha-NF stimulated all ring-hydroxylations, but not N-hydroxylation of 2-FAA. The results support earlier findings that microsomal enzymes differ in immature and mature rat liver and suggest that N-hydroxylation of 2-FAA, the activation required for carcinogenesis, and specific ring-hydroxylations are catalyzed by different cytochrome P-450 isozymes.(ABSTRACT TRUNCATED AT 400 WORDS)

Cytochrome c/H2O2-mediated one electron oxidation of carcinogenic N-fluorenylacetohydroxamic acids to nitroxyl free radicals.

The oxidation of carcinogenic hydroxamic acids, N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA) and N-hydroxy-N-3-fluorenylacetamide (N-OH-3-FAA) catalyzed by horseradish peroxidase (HRP) or cytochrome c in the presence of H2O2 was investigated. HRP/H2O2 was a more efficient system in oxidation of both hydroxamic acids and the standard substrate, guaiacol, then cytochrome c/H2O2. Peroxidative activity of cytochrome c was shown after incubation with Triton X-100 and H2O2 for 20 min at room temperature in 0.05 M phosphate buffer (pH 7.5) or in 0.1 M sodium acetate (pH 6.0) without Triton X-100. Both hydroxamic acids were oxidized to nitroxyl free radicals as shown by electron spin resonance (ESR) spectroscopy. These radicals dismutated to equimolar amounts of 2- or 3-nitrosofluorene and acetate esters of the corresponding hydroxamic acids as shown by thin layer chromatography and spectrophotometric analysis of the products. In addition, large amounts of the N-fluorenylamides were generated in the reactions with cytochrome c/H2O2 system. Of the products, only 2- or 3-nitrosofluorene per se or when generated from the oxidation of the hydroxamic acids, interacted with lecithin (1 mg/ml) to yield ESR signals of the immobilized nitroxyl free radicals. In contrast to HRP/H2O2 system, in which the initial velocity of the radical formation was too fast to measure and the maximal concentrations of the nitroxyl free radicals of both hydroxamic acids were similar, in the cytochrome c/H2O2 system the nitroxyl free radical of N-OH-2-FAA formed at a 6-fold faster rate and accumulated at a 2-fold higher concentration than the radical of N-OH-3-FAA. In both enzyme systems, the persistence of the signal and the length of time before it had decreased to one half its maximum were several-fold longer for the nitroxyl free radical of N-OH-3-FAA than for that of N-OH-2-FAA. These data showed that these nitroxyl free radicals differed in their kinetic properties. One electron oxidation of N-OH-3-FAA by HRP/H2O2 system and of both isomeric hydroxamic acids by cytochrome c/H2O2 system are reported for the first time in this work and may be considered an activation reaction in carcinogenesis by these compounds.

Pathobiologic and metabolic aspects of mammary gland tumorigenesis by N-substituted aryl compounds.

Metabolic or synthetic N-hydroxylation of N-arylamides yields N-arylacylhydroxamic acids considerably more carcinogenic for the rat mammary gland than the parent amides both by systemic and topical administration. The size of the aryl moiety, the position of the nitrogen relative to the aryl moiety and the type of acyl group are determinants of the carcinogenic potency of N-arylacylhydroxamic acids. Induction of mammary tumors required ovarian hormones. Receptors for estrogen, androgen and progesterone were shown in the N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA)-induced mammary carcinoma. This tumor involved epithelial and stromal components of the mammary gland that were separated in culture and produced tumors of their respective origin in the isologous host. Both mammary epithelial cells and fibroblasts are capable of metabolism of carcinogens. The enzymes potentially involved in metabolic activation of N-arylamides and N-arylacylhydroxamic acids in the mammary gland include: a cytochrome P-450(P(1)-450) system, UDP-glucuronyltransferase, N,O-acyltransferases and peroxidases. Mammary microsomes in which cytochrome P(1)-450 was induced generated small amounts of N-OH-2-FAA from 2-FAA. N-OH-2-FAA and its carcinogenic isomer, N-OH-3-FAA, were oxidized by cytochrome c/H(2)O(2) to the nitroxyl free radicals which dismutated to the respective acetate esters and nitrosofluorenes. The addition of unsaturated lipid to either the free radicals or to the nitrosofluorenes gave electron spin resonance signals characteristic of immobilized radicals. It is proposed that interactions of carcinogens with lipids and with DNA play a role in mammary tumorigenesis.

Mixed function oxidase in the mammary gland and liver microsomes of lactating rats. Effects of 3-methylcholanthrene and beta-naphthoflavone.

Mammary gland and liver microsomes of lactating rats were examined for the components of mixed function oxidase and related enzyme activities. Cytochrome b5, NADH- and NADPH- dependent cytochrome c reductase activities were 15-, 6- and 10-fold lower, respectively, in the mammary gland than in the liver microsomes. The determination of cytochrome P-450 (P-448) in the mammary gland microsomes required elimination of the spectral interferences by hemoglobin and cytochrome aa3. The presence of the latter in this fraction was also shown by cytochrome c oxidase activity. Cytochrome aa3 was reduced by anaerobic incubation of mammary gland microsomes, in the presence of antimycin A, with sodium succinate, phenazine ethosulfate, and sodium ascorbate for 30 min at room temperature. Spectral resolution of the dithionite-reduced cytochrome P-450 (P-488) carbon monoxide complex occurred 30 min after gassing. The basal level of cytochrome P-450 was about 500-fold greater in the liver than in the mammary gland microsomes. Pretreatment of lactating rats with the inducers of hepatic cytochrome P-448, 3-methylcholanthrene and beta-naphthoflavone, increased the cytochrome content 3- to 10-fold, in the mammary gland and liver microsomes, respectively. The induction of cytochrome P-448 in microsomes of both tissues was also shown by type I binding spectra obtained with N-2-fluorenylacetamide. Using hydroxylation of benzo[a]pyrene and N-2-fluorenylacetamide as a measure of mixed function oxidase activity, we found that the basal activities, which were 4- to 8-fold greater in the liver microsomes, were increased in both tissues after treatment of rats with the inducers. The induced activities were inhibited by 0.1 micrometers alpha-napthoflavone in vitro, indicating a dependence on cytochrome P-448. The data suggest that the mammary gland, an extrahepatic target for carcinogens, is capable of their metabolism.