Regioselective reaction of thiols with catechol estrogens and estrogen-O-quinones

Incubations of [3H]estradiol and [3H]2-hydroxyestradiol (2-OHE2) with rat liver microsomes and mushroom tyrosinase were carried out in the presence of glutathione and 2-mercaptoethanol. A ratio of about 3.5:1 for the C-4 and C-1 thioether conjugates of 2-OHE2 was observed. Chemical reaction of estradiol-2, 3-O-quinone with various thiols showed that alkyl and phenyl thiols gave about a 1:1 ratio of C-4 to C-1 thioethers. However, reaction of the O-quinone with 4-nitrothiophenol gave a C-4/C-1 ratio of 0.25 while 4-bromothiophenol gave a C-4/C-1 ratio of 4.0. These studies suggest that the regioselectivity of the reaction of thiols with estrogen catechols and O-quinones may be dependent on the nature of the thiol compounds and less on steric hindrance.     

Characterization of estrogen and antiestrogen binding to the cytosol and microsomes of breast tumors

The binding of [3H]estradiol and [3H]hydroxytamoxifen to the cytosol and microsomal fractions of several human breast tumors was investigated. By washing microsomal membranes with a KCl-free or a KCl-containing medium we could distinguish between intrinsic, extrinsic and contaminant estradiol binding sites in these membranes. We observed that treatment of the microsomes with low salt medium removes about 80% of the total estradiol binding sites, whereas 20% are not extractable. The concentration of unextractable [3H]estradiol binding sites in the microsomes varies in proportion to the level of cytosolic estrogen receptors (ER). About 10% of the total extranuclear specific estrogen binding sites was consistently found tightly associated to the microsomal fraction, which displays an affinity for estradiol (Kd = 0.1-0.6 nM) similar to that of the cytosolic ER. The displacement of [3H]estradiol with unlabeled hormone or with the antiestrogens, nafoxidine, enclomiphene and tamoxifen (TAM) exhibits identical IC50 values either in the cytosol or in the microsomal membranes. On the other hand, the microsomal fraction of breast tumors also binds [3H]hydroxyTAM, but with higher capacity and lower affinity than those of the cytosolic fraction. Furthermore, we did not observe correlation between the concentrations of ER and of antiestrogen binding sites (AEBS) in the tumors. These results indicate that microsomal membranes of human breast tumors contain estrogen binding sites which may be related to the cytosol ER recycling and that specific AEBS are predominantly localized in this membrane system. Furthermore, it is shown that the magnitude of estradiol binding to microsomes depends on the ER positive degree of the tumors, whereas the magnitude of the antiestrogen binding to the microsomes is independent of the ER status of the tumors.     

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].     

Estrogen metabolism in primary kidney cell cultures from Syrian hamsters

Estrogen metabolism was evaluated in freshly isolated kidney and liver microsomes and in primary kidney cell cultures from Syrian hamsters, a potential experimental model for examining the possible role(s) of estrogens in tumor initiation and development. Initial velocity studies of the conversion of estradiol to 2-hydroxyestradiol, as determined by the 3H2O release assay with the substrate [2-3H]estradiol, resulted in similar apparent Kms of estrogen 2-hydroxylase of 2.85 and 6.25 microM for liver and renal microsomes, respectively. The apparent Vmax for freshly prepared liver microsomes was 0.13 nmol.mg-1.min-1, while that for renal microsomes was 0.040 nmol.mg-1.min-1. Evaluation of estrogen metabolism was also performed in primary cell cultures of hamster kidney cells, consisting of 75% epithelial cells. [6,7-3H]Estradiol (10 microM) was incubated for 0, 24 and 48 h in primary kidney cell cultures, and the organic soluble metabolites analyzed by reverse-phase HPLC. The cultures from untreated, castrated hamsters metabolize [3H]estradiol to yield small quantities of estrone and significant amounts of polar metabolites, while no catechol estrogens were isolated. Estrogen metabolism by diethylstilbestrol-treated (DES-treated) hamster kidney cell cultures also provided small quantities of estrone and no evidence of catechol estrogens. Additionally, larger amounts of additional polar metabolites were isolated in the cultures from DES-treated hamsters. Finally, levels of estrogen 2-hydroxylase were detected in these cultures using the 3H2O release assay. Thus, the short-term primary kidney cell cultures from the Syrian hamster are capable of metabolizing estrogens. Furthermore, the enzymatic processes appear to be available for the conversion of any catechol estrogens formed into more polar metabolites. These investigations in intact cells, capable of performing all biochemical processes, complement both in vivo and subcellular biochemical studies and may aid in elucidating the roles of estrogens and estrogen metabolism in the initiation and development of estrogen-induced, estrogen-dependent kidney tumors in the Syrian hamster.     

Immunological probe of estrogen biosynthesis. Evidence for the 2 beta-hydroxylative pathway in aromatization of androgens

The terminal hydroxylation in placental estrogen biosynthesis from androgens is at the 2 beta position. The 2 beta-hydroxy-19-oxoandrogen derivative collapses nonenzymatically to estrogen and is therefore the proximate precursor of the female hormone. To establish the role of this pathway in biological aromatization, an immunological approach was employed in which an antibody was obtained which recognizes 2 beta-hydroxy-19-oxygenated androgens but not intermediates oxygenated at C-19 only. Binding of the 2 beta-hydroxy-19-oxo intermediate by the antibody stabilizes it so that its nonenzymatic transformation to estrogen is delayed and results in slower estrogen formation. When placental microsomes were incubated with [1,2-3H]androstenedione in the presence of the antibody antiserum, a 50% decrease in [3H]estradiol formation and 3H2O release was observed when compared with identical incubations containing normal rabbit serum alone. This inhibition is blocked when the antibody is inactivated by presaturation with 2 beta, 19-dihydroxyandrostenedione. Precipitation of immunoglobulins from the incubations followed by heating liberated the 2 beta-hydroxy-19-oxo intermediate (30%) from the antibody, and resulted in its nonenzymatic collapse to estrogen with concomitant release of 3H2O. Control normal rabbit serum or blocked antibody incubations did not show a similar increase in [3H]estradiol or 3H2O yields in the precipitate. Heat treatment (90 degrees C) of the antibody but not normal rabbit serum incubations resulted in a similar increase in [3H]estradiol and 3H2O yields. These results are consistent with the hypothesis that the final and rate-determining hydroxylation in aromatization of androgens is at the 2 beta position and that this pathway is the dominant, if not the sole, route of estrogen biosynthesis by placental aromatase. The antibody probe also permits the characterization of aromatization mechanisms in tissues other than the placenta.     

Diaryl dimers of estradiol and of estrone may be formed as major metabolites by mouse mammary glands

The formation of a novel estrogen metabolite by mammary tissues was investigated. Polar and nonpolar metabolites of endogenous estrogens are formed in liver and other tissues. Polar products such as the catechol estrogens are implicated in tumorigenesis in breast tissue, whereas a nonpolar metabolite, 2-methoxyestradiol, may be protective. Diaryl ether dimers, as a novel form, have been reported as nonpolar products from liver microsomes. We have noted major amounts of nonpolar metabolites in other tissues that were neither 2-methoxyestrogens nor estrogen fatty acid esters. The possible formation of such novel metabolites by breast tissues from adult nulliparous mice with [³H]-labeled estrogens as substrates was considered. Steroids were recovered from media by solid-phase extraction and profiles were obtained from HPLC (acetonitrile:water). Saponification was done with an internal standard of estradiol stearate. Major amounts of nonpolar metabolites were formed in all instances, with one or two principal peaks. Alkaline hydrolysis had no effect on the nonpolar product(s) but released estradiol from its stearate. Strong acid treatment also had no effect as shown by HPLC. Thus, it is suggested that diaryl dimers of estrogens may be formed as major metabolites by mouse mammary glands.     

Characterization of metabolic activation of pentachlorophenol to quinones and semiquinones in rodent liver

Pentachlorophenol (PCP), a widely used biocide, induces liver tumors in mice but not in rats. Metabolic activation of PCP to chlorinated quinones and semiquinones in liver cytosol from Sprague-Dawley rats and B6C3F1 mice was investigated in vitro (1) with microsomes in the presence of either beta-nicotinamide adenine dinucleotide phosphate (NADPH) or cumene hydroperoxide (CHP), (2) with CHP in the absence of microsomes, and (3) with horseradish peroxidase (HRP) and H2O2. Mono-S- and multi-S-substituted adducts of tetrachloro-1,4-benzoquinone (Cl4-1,4-BQ) and Cl4-1,2-BQ and their corresponding semiquinones [i.e. tetrachloro-1,4-benzosemiquinone (Cl4-1,4-SQ) and tetrachloro-1,2-benzosemiquinone (Cl4-1,2-SQ)] were measured by gas chromatography-mass spectrometry (GC-MS). Qualitatively, the metabolites of PCP were the same in both rats and mice for all activation systems. Induction of PCP metabolism by either 3MC or PB-treated microsomes was observed in NADPH- but not in CHP-supported systems. In rats, the amount of induction was comparable with either 3MC or PB. 3MC was a stronger inducer than PB in mice and also induced a greater amount of metabolism than in rats. This suggests that induction of specific P450 isozymes may play a role in the toxicity of PCP to mice. Both HRP/H2O2 and CHP led to production of the full spectrum of chlorinated quinones and semiquinones, confirming the direct oxidation of PCP. CHP (with or without microsomes) converted PCP into much greater quantities of quinones and semiquinones than did microsomal P450/NADPH or HRP/H2O2 in both species. This implies that, under conditions of oxidative stress, endogenous lipid hydroperoxides may increase PCP metabolism sufficiently to enhance the toxicity and carcinogenicity of PCP.     

A comparison of the in vitro metabolism of estrone,estradiol-17β and estrone-3-sulfate by the livers of young virgin female,pregnant and female fetal guinea-pigs

The metabolism, $\text{in vitro}$, of [³H]-estrone, [³H]-estradiol-17β and [³h]-estrone-3-sulfate by the livers of pregnant, young virgin female and female fetus guinea-pigs has been compared using 900 g supernatants and microsomes. The ability of the guinea-pig livers to synthesize polyhydroxylated estrogens has been found to be small. The major metabolites isolated were unconjugated estrone and estradiol-17β or their glucuronides. The percentage of sulfates was lower after incubations with [³H]-estrone than with [³H]-estradiol-17β. A kinetic study with microsomes has shown a direct conversion of estrone-sulfate to estradiol sulfate. Fetal microsomes have been found to exhibit a more active hydrogenation of estrone to estradiol-17β than microsomes from young female or pregnant animals.     

High affinity estrogen binding by rabbit liver

Macromolecular binding components for [3H]estradiol-17beta are present to cytosol prepared from rabbit liver. When cytosol from sexually mature male liver was incubated with [3H]estradiol and analyzed for binding on low ionic strength sucrose gradients, two peaks of binding activity were detected. One peak had a sedimentation coefficient of 4--5 S and the other had a sedimentation coefficient of 8--9 S. The two components differed from each other regarding steroid specificity and various physiocochemical parameters. [3H]estradiol binding to the 4--5 S component was not inhibited by estrogens, 5alpha-dihydrotestosterone, progesterone or cortisol. Binding to this component did not appear to be saturable and label was rapidly stripped from it by charcoal. Estradiol binding to the 8--9 S component was estrogen specific, saturable and of high affinity. The specific binder dissociates on high ionic strength sucrose gradients and sediments as a 4--5 S moiety. The specific binding protein has a Kd of 3.05 . 10(-10) M and a dissociation half-time of 33 h and there are 35.2 fmol of binding sites/mg cytosol protein. Estrogen binders are also present in liver cytosol from sexually mature female and sexually immature male rabbits. During prolonged incubation of [3H]estradiol with mature male liver cytosol at 0--5 degrees C polar metabolites of estradiol are produced.     

Tyrosinase-like activity and estradiol binding in rat uterine nuclear extracts.

Nuclear extracts from the uteri of estradiol-implanted rats contain a tyrosinase-like enzyme that has three activities: monophenolase or cresolase, diphenolase or catecholase, and estrogen binding. When [3H]estradiol was used as a substrate, 3H2O was released from the A ring in the presence of copper and ascorbic acid. The optimal concentrations of these cofactors for the cresolase activity were established. The cresolase activity was lost on attempts at further purification. Estradiol binding was observed in conjunction with the enzymatic activity and was dependent on the presence of ascorbic acid and copper. The most potent inhibitors of 3H2O release from [3H]estradiol were those with a dihydroxyphenol moiety. The reaction was also sensitive to sulfhydryl reagents. These features of the enzyme are distinctive from other oxidases capable of attacking the aromatic ring of estrogens.     

Radiochemical evidence for estradiol-17-fatty acid esters in human blood

The C-17 fatty acid esters of estradiol, known as the lipoidal derivatives of estradiol, LE2, are metabolites of estradiol that were originally isolated from various tissues after in vitro incubations with estradiol. These steroidal esters are active estrogens with extremely prolonged potencies. The present study investigates the existence of LE2 in human blood using a radiochemical isotope dilution technique. The LE2 fraction from blood was isolated, saponified, and the hydrolyzed estradiol was then acetylated with [3H]acetic anhydride. It was found that 3H was incorporated into estradiol diacetate, demonstrating that LE2 is present in human blood. Thus these steroidal esters represent a new class of endogenous estrogens which have not been previously considered in the physiology of the female sex steroids.     

Studies on the mechanism of action of the aromatase inhibitor, 4-hydroxyandrostenedione

[1 beta-3H], [1 alpha,2 alpha-3H] and [1 beta,2 beta-3H] 4-Hydroxyandrostenedione (4-OH-A) were synthesized to study the mechanism of inhibition of aromatase by 4-OH-A. Incubations of [1 beta-3H] and [1 beta,2 beta-3H] 4-OH-A with placental microsomes in the presence of NADPH showed very little loss of tritium, with aromatization of 4-OH-A ranging from 0.3 to 0.6 percent. No loss of tritium was observed in the absence of NADPH. The extent of covalent binding of 4-OH-A to microsomal proteins was higher with incubations in the absence of NADPH than with those in the presence of NADPH. These results are discussed in light of what has been proposed for the mechanism of androgen aromatization.     

Covalent binding to proteins of reactive intermediates resulting from prostaglandin H synthase-catalyzed oxidation of stilbene and steroid estrogens

Prostaglandin H synthase (PSH) is known to metabolically activate a variety of xenobiotics in vitro by means of its peroxidase activity. Recently, stilbene and steroid estrogens have been found to be cooxidized by ram seminal vesical microsomes, a rich source of PHS, to nonextractable metabolites bound to microsomal protein. To investigate further the nature of this protein binding, different radiolabeled estrogens were incubated with purified PHS, holoenzyme in the presence of various amounts of albumin (BSA), and radioactivity bound to protein was determined after gel electrophoretic separation. Diethylstilbestrol (DES), its analog hexestrol, and the steroid estrogens estrone and 2-hydroxy-estrone were cooxidized by PHS in vitro to metabolites that bound covalently to PHS and to BSA. Although a preferential binding of DES to PHS was found in the presence of excess BSA, reactive intermediates derived from DES, or from the other estrogens, were sufficiently stable to react with the competing nucleophile BSA as well. With respect to the metabolic reactions catalyzed by PHS, in addition to one-electron oxidation of phenolic functions, PHS catalyzed the aromatic hydroxylation of synthetic and steroid estrogens as shown by 3H2O release from regiospecifically labeled compounds and confirmed by product identification. Although DES was extensively metabolized by PHS, its aromatic hydroxylation was minor by comparison to estradiol, a difference possibly related to the compounds' redox potentials. Thus, cooxidation of estrogens in vitro resulted in phenoxy radicals, semiquinones and quinones, reactive intermediates capable of protein binding that may contribute to the adverse effects of stilbene and steroid estrogen observed in vivo and in short-term assays.     

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.     

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.     

The microsomal metabolism of pentachlorophenol and its covalent binding to protein and DNA

The microsomal metabolism of pentachlorophenol (PCP) was investigated, with special attention to the conversion dependent covalent binding to protein and DNA. The two metabolites detected were tetrachloro-1,2- and tetrachloro-1,4-hydroquinone. Microsomes from isosafrole (ISF)-induced rats were by far the most effective in catalyzing the reaction: the rate of conversion was increased 7-fold over control microsomes. All other inducers tested (hexachlorobenzene (HCB), phenobarbital (PB) and 3-methylcholanthrene (3MC) gave 2--3-fold increases over control. There are indications that the 1,2- and 1,4-isomers are produced in different ratio's by various cytochrome P-450 isoenzymes: Microsomes from PB- and HCB-treated rats produced the tetrachloro-1,4- and tetrachloro-1,2-hydroquinone in a ratio of about 2, while microsomes from rats induced with 3 MC and ISF showed a ratio of about 1.3. When PCP was incubated with microsomes from rats treated with HCB, a mixed type inducer of P-450, the ratio between formation of the 1,4- and 1,2-isomers decreased with increasing concentration of PCP, suggesting the involvement of at least two P-450 isoenzymes with different Km-values. The overall apparent Km-value for HCB-microsomes was 13 microM both for the formation of the soluble metabolites and the covalent binding to microsomal protein, suggesting both stem from the same reaction. The covalent binding could be inhibited by ascorbic acid and this inhibition was accompanied by an increase in formation of tetrachlorohydroquinones (TCHQ). Although a large variation was observed in rates of conversion between microsomes treated with different (or no) inducers, the rate of covalent binding to microsomal protein was remarkably constant. A conversion-dependent covalent binding to DNA was observed in incubations with added DNA which was 0.2 times the amount of binding to protein (37 pmol/mg DNA).     

Further characterization of the estrogen binding macromolecule in human pancreas

The estrogen binding protein in human pancreas has been purified from pancreatic cytosol by chromatography on Concanavalin-A-Sepharose and hydroxyl-apatite followed by ion-exchange chromatography carried out using a fast-protein liquid chromatography apparatus (FPLC). The purified protein, still able to bind labelled [3H]estradiol, appeared as one single band corresponding to 31 K in SDS-gel electrophoresis. Total amino acid analysis revealed high levels of histidine, glutamic acid and leucine. The capacity of the purified protein to bind estrogens could be increased more than 4-fold by addition of a cytosolic factor, probably being a small peptide, that is present in crude cytosol, but lost during the purification procedure. The iodinated protein does not bind to DNA-cellulose or phosphocellulose, and shows no similarities to estrogen receptor proteins.     

Metabolism of 7,12-dimethylbenz[a]anthracene and its methyl-hydroxylated metabolites: formation of phenolic metabolites at the 2-positions.

The 1- and 2-positions of 7,12-dimethylbenz[a]anthracene (DMBA) were thought not to be involved in biotransformation to 1,2-epoxide and 1,2-dihydrodiol because of steric hindrance from the 12-methyl group (Biochem. Biophys. Res. Commun. $\text{85}$: 357–362, 1978). However, we have identified four 2-phenols as rat liver microsomal metabolites of DMBA and its methyl-hydroxylated metabolites, 7-hydroxymethyl-12-methylbenz[a]anthracene, 7-methyl-12-hydroxymethylbenz[a]-anthracene, and 7,12-dihydroxymethylbenz[a]anthracene. Our findings suggest that neither the 12-methyl group nor the 12-hydroxymethyl group blocks the microsomal oxygenations of the 1,2 positions of DMBA or its methyl-hydroxylated derivatives. The 2-phenols may be formed as nonenzymatic rearrangement products of the 1,2-epoxide intermediates, although their formations by a direct hydroxylation mechanism cannot be ruled out.     

High affinity estrogen binding by rabbit liver

Macromolecular binding components for [³H]estradiol-17β are present to cytosol prepared from rabbit liver. When cytosol from sexually mature male liver was incubated with [³H]estradiol and analyzed for binding on low ionic strength sucrose gradients, two peaks of binding activity were detected. One peak had a sedimentation coefficient of 4–5 S and the other had a sedimentation coefficient of 8–9 S. The two components differed from each other regarding steroid specicity and various physiocochemical parameters. [³H]-estradiol binding to the 4–5 S component was not inhibited by estrogens, 5α-dihydrotestosterone, progesterone or cortisol. Binding to this component did not appera to be saturable and lavel was rapidly stripped from it by cahrcoal. Estradiol bindng to the 8–9 S component was estrogen specific, saturable and of high affinity. The specific binder dissociates on high ionic strength sucrose gradients and sediments as a 4–5 S moiety. The specific binding protein has a K_d of 3.05 · 10⁻¹⁰ M and a dissociation half-time of 33 h and there are 35.2 fmol of binding sites/mg cytosol protein. Estrogen binders are also present in liver cytosol from sexually mature female and sexually immature male rabbits. During prolonged incbuation of [³H]estradiol with mature male liver cytosol at 0–5°C polar metabolites of estradiol are produced.     

Active nonaromatic intermediates in the conversion of steroidal estrogens into catechol estrogens

A mechanism is proposed for mixed-function oxidase-catalyzed formation of the catechol estrogens 2-hydroxy- and 4-hydroxyestradiol from estradiol. This mechanism involves nonaromatic epoxyenones as intermediates. The isomeric 1 alpha,2 alpha-epoxy-17 beta-hydroxyestr-4-en-3-one and 1 beta,2 beta-epoxy-17 beta-hydroxyestr-4-en-3-one (the latter as its 17-acetate) were synthesized from 17 beta-hydroxy-5 alpha-estran-3-one. The isomeric 4 alpha,5 alpha-epoxy-17 beta-hydroxyestr-1-en-3-one and 4 beta,5 beta-epoxy-17 beta-hydroxyestr-1-en-3-one were prepared from 19-nortestosterone. From incubations of [6,7-3H]estradiol with microsomes from MCF-7 human breast cancer cells, which principally catalyze the formation of 2-hydroxyestradiol from estradiol, we were able to isolate a 3H-labeled product with the chromatographic properties of 1 beta, 2 beta-epoxy-17 beta-hydroxyestr-4-en-3-one (as its 17-acetate). The soluble protein fraction of homogenates of rat liver, which is devoid of estrogen 2-/4-hydroxylase activity, has been shown to catalyze the formation of 2- and 4-hydroxyestradiol from the 1 alpha,2 alpha-epoxide and from the 4 alpha,5 alpha- and 4 beta,5 beta-epoxides, respectively. We suggest that these results taken together strongly support a role for epoxyenones as intermediates in the formation of catechol estrogens.