Estrogen 1,2-epoxides or estrogen quinones/semiquinones

Metabolic activation of estradiol leading to the formation of catechol estrogens is a prerequisite for its genotoxic activity. Both estrogen-o-quinones/semiquinones and estrogen 1,2-epoxides have been proposed to be responsible for this activity. Incubations of [3H]estradiol and [3H]1 alpha,2 alpha-epoxy-4-estrene-3-one-17 beta-ol (ketotautomer of estradiol 1,2-epoxide) with rat liver microsomal and cytosol preparations were carried out in the presence of SKF 525A, ascorbic acid, glutathione and cysteine. Ascorbic acid decreased binding to proteins and aqueous-soluble fraction with both [3H] estradiol and [3H]epoxyestrenolone in incubations with microsomes but no effect with cytosol fraction. Incubations of microsomes with thiols gave water-soluble metabolites which were characterized as 1(4)-thioether derivatives of 2-hydroxyestradiol and incubations of [3H]epoxyestrenolone with cytosol and thiols gave estradiol-2-thioether. Incubations with ascorbic acid and thiols resulted in decreased formation of water-soluble metabolites in microsomal incubations but not in cytosol incubations. These studies indicate that the major pathway for irreversible binding of estrogens to macromolecules involves estrogen-o-quinones/semiquinones and not estrogen 1, 2-epoxide.     

Activation and irreversible binding of regiospecifically labeled catechol estrogen by rat liver microsomes: evidence for differential cytochrome P-450 catalyzed oxidations

Estradiol and 2-hydroxyestradiol labeled with 3H at different positions in rings A or B were incubated with male rat liver microsomes, and their oxidative transformation was followed by the transfer of 3H into 3H2O. 14C-labeled estrogen or catechol estrogen was used to determine the fraction that becomes bound covalently to microsomal protein. The further metabolism of 2-hydroxyestradiol involves activation of the steroid at C-4 and, to a much lesser extent at C-1, by a cytochrome P-450 mediated reaction as indicated by the effects of NADPH, spermine, SKF-525A, and CO in the microsomal system. Glutathione promoted the loss of 3H from C-4 of either estradiol or 2-hydroxyestradiol but had less effect on this reaction at C-1 and inhibited it at C-6,7. It also abolished the irreversible binding of 14C-labeled estradiol and 2-hydroxyestradiol to microsomal protein. NADPH was needed specifically for glutathione to exert its effect both on the transfer of 3H into 3H2O and on the formation of water-soluble products from catechol estrogen by rat liver microsomes. It could not be replaced by NADP, NAD, or NADH. Ascorbic acid inhibited these enzymatic reactions but did not affect significantly the initial 2-hydroxylation of estradiol. Evidence is also provided for the further hydroxylation of 2-hydroxyestradiol at C-6 (or C-7). These results indicate that cytochrome P-450 activates catechol estrogens by an electron abstraction process.     

Estrogen metabolism in rat liver microsomal and isolated hepatocyte preparations--II. Inhibition studies

The abilities of various inhibitors and metabolism modifiers to alter the metabolism of estradiol and the irreversible binding of estradiol to proteins were examined in subcellular microsomal incubations and in intact hepatocyte preparations. In studies with rat liver microsomal preparations containing estradiol and an NADPH-generating system, the irreversible binding of radiolabeled steroid metabolite(s) to the microsomal proteins was 77.59 pmol/mg/min (SD 6.1; 7.6% of total steroid). 2-Bromoestradiol and 4-bromoestradiol, inhibitors of estrogen 2-hydroxylase, effectively decreased this irreversible binding of radiolabeled estradiol metabolite(s) to microsomal proteins to 17 pmol mg-1 min-1 (2.1% of total estradiol). These haloestrogens were also effective inhibitors in the intact hepatocyte cells, decreasing the amounts of organic metabolites, aqueous-soluble conjugates, and protein-bound materials. The HPLC radiochromatograms of the organic-extracted fractions from the 2 h hepatocyte incubations demonstrate that the catechol estrogen products, i.e. 2-hydroxyestrogens and 2-methoxyestrogens, were present in lower amounts in the incubations containing the bromoestrogens than in control incubations containing no inhibitor. Ascorbic acid and cysteine, general modifiers of oxidative pathways of metabolism, also affected estradiol metabolism in microsomal and hepatocyte preparations. Both these agents were able to decrease the irreversible binding of estradiol to proteins in the microsomal assays. Ascorbic acid decreased the general metabolism of estradiol in the hepatocyte incubations but did not decrease irreversible binding to proteins. The addition of cysteine to the hepatocyte incubation resulted in an increased metabolism of estradiol and the production of more aqueous-soluble radiolabeled metabolites than the control incubations; however, cysteine did not decrease the amounts of estradiol metabolite(s) irreversibly bound to proteins. Investigations of steroid metabolism in the isolated hepatocytes thus provide an effective in vitro technique for examining the overall oxidative, reductive, and conjugative pathways that are functional in the liver and enables one to investigate the abilities of inhibitors, regulators, and modifiers to affect the metabolic processes. Also, these hepatocyte studies demonstrate that the inhibitors of estrogen 2-hydroxylase, 2-bromoestradiol and 4-bromoestradiol, can enter and act in the intact cells. Consequently, these agents may be useful pharmacological probes for examining the functions of catechol estrogens in other tissues.     

Mutagenicity and irreversible binding of the hepatocarcinogen, 2,4-diaminotoluene.

Mutagenicity of 2,4-diaminotoluene (DAT) in the Salmonella mutagenicity assay was increased with liver fractions from phenobarbital (PB) or beta-naphthoflavone (BNF) treated rats. Substitutions of the hydrogens in the methyl group of 2,4-DAT with deuterium resulted in a decrease in mutagenicity. Incubation of rat liver microsomes with tritiated 2,4-DAT in the presence of NADPH led to the formation of irreversibly bound products to microsomal protein. The rates of binding were not increased using microsomes from PB or BNF-treated rats and was not altered by deuterium substitution in the methyl group. Addition of superoxide dismutase, glutathione (GSH) or rat liver supernatant reduced 2,4-DAT irreversible binding, whereas 2,4-DAT mutagenicity was unaffected by superoxide dismutase addition. Injection of tritiated 2,4-DAT 100 mg/kg to rats lead to its irreversible binding to liver protein and ribosomal RNA and to kidney protein in vivo, again protein binding was not increased after prior treatment with PB or BNF. No irreversible interaction of tritiated 2,4-DAT with DNA either in vitro or in vivo could be demonstrated.     

Irreversible protein binding of metabolites of ethynylestradiol in vivo and in vitro

During incubation of 6,7-³H-ethynylestradiol with rat liver microsomes up to 20 % of the radioactivity was bound irreversibly to the microsomal proteins. Incubations in presence of albumin resulted in a further radioactive labelling of the albumin. The irreversible nature of the steroid-protein bond was established by solvent extraction and charcoal treatment. Further evidence was obtained after hydrolyzing the microsomal protein with trypsin and submitting the labelled tryptic peptides to ion exchange chromatography and electrophoresis. The labelled albumin was applied to sephadex gel filtration which showed the association of the ethynylestradiol radioactivity to the albumin peak.The binding reaction required supply of NADPH, could be stimulated by pretreatment of the animals with phenobarbital and was inhibited by CO and SKF 525 A. On these characteristics the concept was based that, in analogy to the well known binding of estradiol and estrone, 2hydroxylation is also an essential prerequisite for the binding of ethynylestradiol. The concept was confirmed by trapping off the 2-hydroxy-ethynylestradiol with glutathione, which led to a decrease of the ethynylestradiol-protein binding.Further evidence resulted from experiments $\text{in vivo}$, dosing rats with 6,7-3H-ethynylestradiol and 6,7-3H-estradiol 48 hrs prior to sacrifice and examining the amount of radioactivity irreversibly bound to the liver endoplasmic reticulum. 3H-ethynylestradiol caused a radioactive labelling of microsomes twice as much as that after ³H-estradiol.     

Cytochrome P-450-mediated oxidation of 2-hydroxyestrogens to reactive intermediates

2-Hydroxyestradiol, 2-hydroxyestrone and 2-hydroxy-17α-ethynylestradiol, oxidation products of naturally occurring estrogens and synthetic estrogens in some oral contraceptives were found to be converted by rat liver microsomes to reactive metabolites that become irreversibly bound to microsomal protein. The irreversible binding required microsomes, oxygen and NADPH. The NADPH could be replaced by a xanthine-xanthine oxidase system which is known to generate superoxide anions. The irreversible binding was substantially inhibited by superoxide dismutase, 30% in those incubations containing NADPH and 98% in those incubations containing the xanthine-xanthine oxidase system. Further studies with 2-hydroxyestradiol showed that microsomal cytochrome P-450 was rate limiting in the NADPH-dependent irreversible binding, because the binding was inhibited 62% by an antibody against NADPH-cytochrome $\text{c}$ reductase and 70% in an atmosphere of CO:O₂ (9:1) when compared to an atmosphere of N₂:O₂ (9:1). Phenobarbital, a known inducer of cytochrome P-450, had no effect on the irreversible binding of 2-hydroxyestradiol, whereas another inducer of P-450, pregnenolone-16α-carbonitrile, markedly increased the irreversible binding. In contrast, cobaltous chloride, an inhibitor of the synthesis of cytochrome P-450, decreased both P-450 and the irreversible binding. These results are consistent with a mechanism for irreversible binding of estrogens and 2-hydroxyestrogens to microsomes that requires oxidation of the catechol nucleus by cytochrome P-450-generated superoxide anion.     

Irreversible binding of DOPA and dopamine metabolites to protein by rat liver microsomes.

Rat liver microsomes catalyze NADPH-dependent irreversible binding of metabolites of DOPA and DOPAmine to microsomal protein and to BSA. Binding is inhibited by cysteine and the singlet oxygen quencher 1,4-diaza-bicyclo(2.2.2)octane. Irreversible binding to BSA is also catalyzed by mushroom tyrosinase, xanthine oxidase, and NADPH-cytochrome c reductase. The results suggest that in the microsomal system the participation of the hemoprotein, cytochrome P-450, is not an absolute requirement for the irreversible binding of metabolites of DOPA and DOPAmine to proteins.     

4-Hydroxyestradiol is conjugated with thiols primarily at C-2: evidence from regiospecific displacement of tritium by rat liver microsomes or tyrosinase

4-Hydroxyestradiol bearing a 3H label specifically at C-2 was prepared chemically and incubated with male rat liver microsomes or mushroom tyrosinase. A very high proportion (80-90%) of the 3H was displaced from the labeled steroid when either glutathione or N-acetylcysteine was present, and tyrosinase was shown not to require NADPH as cofactor for this reaction. In either case, only negligible amounts (less than 3%) of the 3H radioactivity were found associated with water-soluble adducts in contrast to 3H-labeled 2-hydroxyestradiol, which gave rise to about 25% of such products. The effect of ascorbic acid on the microsomal reaction with regiospecifically labeled estradiol, 2-hydroxyestradiol, and 4-hydroxyestradiol was also investigated, and the results are discussed in terms of the reactivity at different carbon atoms in ring A of the catechol estrogens. All the evidence points to conjugation of 4-hydroxyestradiol with glutathione or N-acetylcysteine at C-2 but not C-1 of this highly reactive catechol estrogen. Measuring the displacement of 3H as 3H2O from specific positions in the steroid ring provides a useful and sensitive method to assess the formation of adducts in cases where their isolation and characterization is particularly difficult.     

Irreversible protein binding of norethisterone (norethindrone) epoxide.

14,15-3H-Norethisterone-4 beta, 5 beta-epoxide, a metabolite of norethisterone, was incubated with several proteins and nucleic acids. After 30 min incubation 0.19 nmol of the epoxide were irreversibly bound per mg albumin which contains free sulfhydryl groups; proteins without SH-groups, such as concanavalin A, gamma-globulin, DNA and RNA, did not irreversibly bind norethisterone epoxide. A superoxide (O2) generating enzyme system comprised of xanthine oxidase and hypoxanthine was capable of catalyzing the irreversible binding of the parent compound, norethisterone, to albumin, indicating that an oxidation product was formed which reacted with the protein. When norethisterone epoxide was incubated for 60 min with hepatic microsomes of rats in absence of NADPH, about 2.0 nmol of the epoxide were irreversibly incorporated per mg microsomal protein. This binding was increased to 5.2 nmol by addition of a NADPH regenerating system. Addition of glutathione and cytosol decreased only the NADPH-dependent protein binding; phenobarbital pretreatment of rats induced this NADPH-dependent binding of norethisterone epoxide to microsomal protein by a factor of 2. In presence of NADPH, binding of the epoxide to microsomal protein depended on substrate concentration used. The results indicate that norethisterone epoxide is able to chemically react with proteins. In addition, hepatic microsomal enzymes convert the epoxide to another metabolite which also can react with proteins.     

Oxidative metabolism and de-ethynylation of 17alpha-ethynylestradiol by baboon liver microsomes.

Incubations of tritiated 17alpha-ethynylestradiol (EE2) with liver explants of baboon and mouse showed the primate species to be more efficient in the removal of the ethynyl group. Liver microsomes from sexually immature male and female baboons were then incubated with tritiated EE2 and estradiol (E2). Each hormone bound irreversibly to the microsomal pellet. Addition of glutathione reduced the irreversible or covalent association. Incubations with E2 demonstrated significant conversion to estrone (E1). The EE2 experiments demonstrated a conversion to estrone only in the presence of an NADPH-generating system, and the addition of SKF-525A reduced the conversion of EE2 to E1. The cleavage reaction appears to be an oxidative event.     

Differential effect of Cu2+ and Zn2+ on the formation and further metabolism of catechol estrogen by rat liver microsomes

The action of a number of different divalent metal ions on the rat liver microsomal release of 3H2O from estradiol and 2-hydroxyestradiol labeled with 3H at C-2 or C-4 was investigated. Cu2+ at low concentration (10 microM) produced a marked and specific inhibition of the 2-hydroxylation of estradiol with virtually no effect on the further oxidative activation of catechol estrogen. In contrast, Zn2+ inhibited the interaction of 2-hydroxyestradiol with microsomal protein as measured by the release of 3H from C-4 of the labeled steroids but did not influence 2-hydroxylation, except at high concentration. Other metal ions tested produced little or no change. Cu2+ inhibited the irreversible binding of estradiol to protein but activated this reaction with the catechol estrogen as substrate. The action of both Cu2+ and Zn2+ was reversed by glutathione. The differential effect of these metal ions on estrogen metabolism gives additional support for two different mechanisms in the cytochrome P-450-catalyzed formation of catechol estrogens and their further activation to form protein conjugates.     

Esterification of cholesterol and 25-hydroxycholesterol by rat liver microsomes

The properties of an enzyme in rat liver microsomes was described that catalyzed the formation of 25-hydroxycholesteryl ester in the presence of labeled sterol and oleoyl-CoA. The reaction was similar in several respects to that of cholesteryl ester formation by acyl-CoA: cholesterol acyltransferase. Trypsin pretreatment of microsomes inhibited the esterification of both sterols and a similar dose-dependent inhibition was produced by addition of progesterone and several androgens. Microsomes with an enhanced cholesterol content resulting from in vivo treatment with ethinyl estradiol showed increased esterifying activity towards both cholesterol and 25-hydroxycholesterol. Esterification of endogenous microsomal cholesterol was increased by the addition of 25-hydroxycholesterol, concomitant with 25-hydroxycholesteryl ester formation. To assess the relationship between the association of sterols with membranes and sterol ester formation, microsomes were preincubated with either sterol, reisolated by ultracentrifugation in a density gradient and then analyzed chemically or enzymatically. Cholesterol and 25-hydroxycholesterol both associated with microsomes and the added sterol was subsequently esterified. Maximal esterification was only partially dependent on the amount bound. Progesterone, which inhibited sterol esterification, did not bind to microsomes and no inhibition was observed in reisolated microsomes, indicating that the inhibition produced by progesterone was reversible.     

Estrogen carcinogenesis in Syrian hamster tissues: role of metabolism

Evidence for a role of estrogen metabolism in hormonal carcinogenesis was obtained with the Syrian hamster as an in vivo model system. Both natural and synthetic estrogens are capable of inducing a high incidence of renal carcinomas in this species. A high incidence of hepatocellular carcinomas can also be induced in the hamster with synthetic estrogens such as ethinyl estradiol or diethylstilbestrol, provided alpha-naphthoflavone (ANF) is present in the diet. Although steroid receptor-mediated hormonal events appear to be intimately involved in the process of in vivo cell transformation of both tissues, certain observations strongly suggest that nonhormonal events are also important. Despite their potent estrogenic activity at the doses used, ethinyl estradiol and alpha-zearalanol induce relatively low renal tumor incidences after 9.0 and 10.0 months of continuous treatment, respectively. A role for the metabolism of estrogens to reactive intermediates is also suggested by studies showing estrogen-induced renal tumorigenesis can be partially inhibited by concomitant administration of ANF or ascorbic acid. Consistent with this is the general correlation between the amount of catechol estrogen formed by a compound, as mediated by estrogen 2-/4-hydroxylase, and renal carcinogenicity data. Recently, additional supporting evidence has been obtained from studies involving the irreversible binding of reactive metabolites of steroidal or stilbene estrogens to hamster liver microsomal proteins.     

Biotransformation of chloroform by rat and human liver microsomes; in vitro effect on some enzyme activities and mechanism of irreversible binding to macromolecules.

The effects of chloroform on some rat microsomal enzyme activities were studied in vitro. Maximum inhibition of oxygen consumption, NADPH oxidase and NADPH-cytochrome c reductase was observed at 0.5 mM chloroform; prior metabolization of CHCl3 by microsomal monooxygenases increased inhibition by about 50% at 0.2-0.5 mM chloroform. Higher concentrations produced a paradoxical reversal of inhibition, whereas p-nitroanisole demethylase was steadily inhibited by about 50% up to 10 mM chloroform. Irreversible binding of 14CHCl3 was confirmed to depend on chloroform metabolization by monooxygenases. The increased irreversible binding due to phenobarbital induction is accompanied by a diminished affinity towards chloroform as shown by increased KM of irreversible binding, and a higher spectral dissociation constant KS. Aminoacids with nucleophilic functions (histidine, cysteine) partially prevented the irreversible binding of chloroform metabolites to microsomes; non-volatile radioactive derivatives were recovered in trichloracetic acid supernatants when microsomes were incubated with cysteine, but not with histidine. Phosgene has been demonstrated as a biological metabolite of chloroform: its possible reactions with nucleophilic groups of macromolecules, water and added aminoacids partly explain these experimental data. Similar results were obtained with human microsomes, showing that chloroform hepatotoxicity in man could involve the same mechanisms.     

Drug protein conjugates--III. Inhibition of the irreversible binding of ethinylestradiol to rat liver microsomal protein by mixed-function oxidase inhibitors, ascorbic acid and thiols

The metabolism of [6,7-3H]ethinylestradiol [( 3H]EE2) by rat liver microsomes was studied in vitro. After incubation of [3H]EE2 with rat liver microsomes for 20 min, 90% of the substrate was metabolised and 18% of the 3H-labelled material irreversibly bound to microsomal protein. Ascorbic acid (1 mM) decreased irreversible binding of 3H and produced an accumulation of 2-hydroxyethinylestradiol (2OH-EE2), while mixed-function oxidase inhibitors (0.5 mM) decreased binding of 3H to protein by inhibiting EE2 2-hydroxylation. Addition of thiols gave water-soluble metabolites which were characterised as 1(4)-thioether derivatives of 2OH-EE2 by co-chromatography with synthetic products. The results are consistent with the hypothesis that the chemically reactive metabolite of EE2 formed in vitro is either a quinone or o-semiquinone derived from 2OH-EE2 [1].     

Microsomal activation of estrogens and binding to nucleic acids and proteins.

Natural and synthetic estrogens can be activated by rat liver microsomes to bind covalently to polyguanylic acid, single-stranded DNA, nucleotides and proteins. Incubation of polyG, estrone and liver microsomes (0.5 nmole cytochrome P-448 or P-450) from 3-methylcholanthrene-induced, phenobarbital-induced or control rats showed that the former microsomes gave better $\text{net}$ binding of estrogens to polyG than the other two. Estradiol incubated with 3MC-induced microsomes did bind to DNA but marginally to polyG. Mestranol and estrone sulfate, both constituents of oral contraceptive formulations, bound to polyG whereas progesterone and cholesterol did not bind. We present also preliminary data on the characterization of estrogen-nucleic acid interactions using nucleases, proteinase K and high-pressure liquid chromatography.     

Drug residue formation from ronidazole, a 5-nitroimidazole. I. Characterization of in vitro protein alkylation

The metabolic activation of [14C]ronidazole by rat liver enzymes to metabolite(s) bound to macromolecules was investigated. The alkylation of protein by [14C]ronidazole metabolite(s) was catalyzed most efficiently by rat liver microsomes, in the absence of oxygen utilizing NADPH as a source of reducing equivalents. Based on a comparison of total ronidazole metabolized versus the amount bound to microsomal protein, approximately one molecule alkylates microsomal protein for every 20 molecules of ronidazole metabolized. Protein alkylation was strongly inhibited by sulfhydryl-containing compounds such as cysteine and glutathione whereas methionine had no effect. Based on HPLC analysis of ronidazole, cysteine was found not to inhibit microsomal metabolism of ronidazole ruling out a decrease in the rate of production of the reactive metabolite(s) as the mechanism of cysteine inhibition.     

Activation of microsomal glutathione S-transferase activity by sulfhydryl reagents.

Rat liver microsomes exhibit glutathione S-transferase activity with 1-chloro-2,4-dinitrobenzene as the second substrate. This activity can be stimulated 8-fold by treatment of the microsomes with N-ethylmaleimide and 4-fold with iodoacetamide. The corresponding glutathione S-transferase activity of the supernatant fraction is not affected by such treatment. These findings suggest that rat liver microsomes contain glutathione S-transferase distinct from those found in the cytoplasmic and that the microsomal transferase can be activated by modification of microsomal sulfhydryl group(s).     

Stereochemistry of the microsomal glutathione S-transferase catalyzed addition of glutathione to chlorotrifluoroethene

The stereochemistry of S-(2-chloro-1,1,2-trifluoroethyl)glutathione formation was studied in rat liver cytosol, microsomes, N-ethylmaleimide-treated microsomes, 9000g supernatant fractions, purified rat liver microsomal glutathione S-transferase, and isolated rat hepatocytes. The absolute configuration of the chiral center generated by the addition of glutathione to chlorotrifluoroethene was determined by degradation of S-(2-chloro-1,1,2-trifluoroethyl)glutathione to chlorofluoroacetic acid, followed by derivatization to form the diastereomeric amides N-(S)-alpha-methylbenzyl-(S)-chlorofluoacetamide and N-(S)-alpha-methylbenzyl-(R)-chlorofluoroacetamide, which were separated by gas chromatography. Native and N-ethylmaleimide-treated rat liver microsomes, purified rat liver microsomal glutathione S-transferase, rat liver 9000g supernatant, and isolated rat hepatocytes catalyzed the formation of 75-81% (2S)-S-(2-chloro-1,1,2-trifluoroethyl)glutathione; rat liver cytosol catalyzed the formation of equal amounts of (2R)- and (2S)-S-(2-chloro-1,1,2-trifluoroethyl)glutathione. In rat hepatocytes, microsomal glutathione S-transferase catalyzed the formation of 83% of the total S-(2-chloro-1,1,2-trifluoroethyl)glutathione formed. These observations show that the microsomal glutathione S-transferase catalyzes the first step in the intracellular, glutathione-dependent bioactivation of the nephrotoxin chlorotrifluoroethene.     

Influence of the fermentative cross-seams on the structure of the microsomal membrane

In rat liver microsomes freezing with subsequent thawing led to irreversible redistribution of protein-lipid packing. This redistribution was detected by a change in the efficiency of energy transfer between protein aromatic groups of membrane protein and lipid-soluble fluorescent probe pyrene. Transglutaminase pretreatment of microsomes prevented the irreversible redistribution. The enzyme is shown to bind no more than 15 per cent of the whole membrane protein. This smaller part of the microsomal protein is supposed to play the decisive role in the movements of its remaining part.