Specific and nonspecific components in the oxidative metabolism of estradiol by the male rat brain in vitro

Comparison of cytochrome P-450 species which catalyze the hydroxylations of the aromatic ring of estradiol and estradiol 17-sulfate

For identification of microsomal cytochrome P-450 (P-450) enzymes which catalyze 2- or 4-hydroxylations of estrogens in the rat liver, estradiol (E2) and estradiol 17-sulfate (E2-17-S) were selected as the substrates and incubated with various kinds of purified P-450 enzymes: PB-1, PB-2, PB-4 and PB-5 obtained from phenobarbital-treated male rats (Sprague-Dawley); MC-1 and MC-5 from 3-methylcholanthrene-treated male rats; and UT-1, UT-2, UT-4 and UT-5 from untreated animals. The reactions were carried out under the P-450-reconstructed system, and the resulting products were determined by HPLC using electrochemical detection. All the enzymes tested were shown to have varying degrees of catalytic activities for 2-hydroxylation of the two substrates; UT-1 and UT-2 had the highest activity. Of the induced P-450 enzymes, PB-2 and MC-1 showed fairly high catalytic activity for 4-hydroxylation of E2. The P-450 enzymes obtained from the untreated male rats, especially UT-4, showed the highest catalytic activity for 4-hydroxylation of the two substrates. From these results and also from kinetic experiments, the P-450 enzymes which catalyze 2- and 4-hydroxylations of estrogen were considered to be different species. A part of E2 was converted to such metabolites as estrone and those having a hydroxyl group at positions 6 beta, 15 alpha or 16 alpha, each production of which was estimated to be catalyzed by single or multiple P-450s.

Hepatic catecholestrogen synthases: differential effect of sex, inducers of cytochromes P-450 and of antibody to the glucocorticoid inducible cytochrome P-450 on NADPH-dependent estrogen-2-hydroxylase and on organic hydroperoxide-dependent estrogen-2/4-hydroxylase activity of rat hepatic microsomes

Formation of catecholestrogens (CE) by rat hepatic microsomes was re-examined because as recently shown; (1) CE formation can be catalyzed by an NADPH-dependent estrogen-4-hydroxylase (E-4-H(NADPH)) and by a peroxidatic, organic hydroperoxide-dependent estrogen-2/4-hydroxylase (E-2/4-H(OHP)), in addition to the established NADPH-dependent estrogen 2-hydroxylase (E-2-H(NADPH)); and (2) the indirect radiometric and the COMT-coupled radioenzymatic assays, used in many previous studies, may fail to provide an accurate measure, in particular, of 4-OH-CE. Using a direct product isolation assay, hepatic microsomes of both male and female rats were shown to express E-2/4-H(OHP) activity with properties similar to those of peroxidatic activity in other tissues. The activities of E-2/4-H(OHP) and E-2-H(NADPH) were affected differently by 5 out of 7 inducers of cytochromes P-450 administered in vivo. Phenobarbital and dexamethasone caused a 4- and 2-3-fold increase in E-2-H(NADPH) activity, respectively, but only a 38 and 20% increase in E-2/4-H(OHP) activity. Ketoconazol and beta-naphtoflavone caused a modest increase in E-2-H(NADPH) activity but a decrease in OHP-dependent activity. Clofibrate decreased peroxidatic activity by 50% and NADPH-dependent activity by approximately 20%. Both activities were increased by ethanol but decreased by isoniazide, an agent which induces the same form of cytochromes P-450 as ethanol. Polyclonal antibody against P-450p, a form of P-450 induced by glucocorticoids, inhibited E-2-H(NADPH) but not E-2/4-H(OHP) activity of untreated and of dexamethasone- and phenobarbital-treated rats. This study establishes that CE formation may occur in liver via the peroxidatic pathway and indicates that this pathway depends on forms of P-450 different from those mediating E-2-H(NADPH) activity. It also confirms and extends previous observations of the involvement of multiple, constitutive and induced forms of cytochrome P-450 in NADPH-dependent 2-hydroxylation in liver.

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.

Inhibition of catechol estrogen formation in rat liver microsomes by hormonal steroids and related compounds

The inhibitory action of a number of different hormonal steroids and related compounds on the 2-hydroxylation of estradiol by male rat liver microsomes was examined by a radiometric assay. Progesterone, Diethylstilbestrol, testosterone and 4-androstenedione were found to be the most potent of the compounds tested but inhibition was also observed with other steroids and a group of androgen analogs which are aromatization inhibitors. The kinetic constant Ki for those steroids which gave linear double reciprocal plots when added to [2-3H]estradiol was determined and the products from [14C]estradiol in the presence of the inhibitors were examined by TLC and autoradiography. The addition of steroids with a 17-hydroxyl group such as testosterone or dihydroequilin resulted in the formation of mainly 2-hydroxyestradiol with smaller amounts of other metabolites while those with a reducible ketonic group such as progesterone, 4-androstenedione, equilin or equilenin gave rise to considerable amounts of estrone in addition to the catechol estrogens. Further purification of the liver microsomes did not alter this effect. The possible role of progesterone and the catechol estrogens in the control of estrogen hydroxylation in liver as well as other aspects of steroid interaction are discussed.

A gas chromatographic/mass spectrometric assay for catechol estrogens in microsomal incubations: comparison with a radiometric assay

A gas chromatographic/mass spectrometric assay for quantifying two catechol estrogens, 2-hydroxyestradiol and 4-hydroxyestradiol, in microsomal preparations is described. The assay employs deuterium-labeled analogs of the catechol estrogens as internal standards and permits quantification of catechol estrogens, in microsomal incubations, at low (1-2) microM concentrations. The compounds are analyzed as their trimethylsilyl derivatives following separation by capillary gas chromatography.

Inducibility of rat brain drug-metabolizing enzymes

Cytochrome P450 from rat brain mitochondrial and microsomal fractions was found to be inducible by 3-methylcholanthrene, both in quantity of enzyme and in activity towards 7-ethoxyresorufin, which is a model substrate for the cytochrome P450 isoform specifically induced by 3-methylcholanthrene. Conversely, a phenobarbital treatment resulted in an induction of the microsomal cytochrome P450 only. On the other hand, the microsomal 1-naphthol-UDP-glucuronosyl transferase and epoxide hydrolase seemed to be non-inducible by 3-methylcholanthrene or by phenobarbital. The toxicological implications of these data are discussed.

Inhibition of the preovulatory LH surge after a catecholestrogen (2-hydroxyestrone) antiserum injection in the third ventricle of cycling female rats

Administration of a catecholestrogen (2-hydroxyestrone, 2-OHE1) antiserum (2-OHE1-AS) in the third ventricle of cycling female rats, on the morning of proestrus, leads to a significant reduction in the afternoon LH surge. These responses are dose-dependent and can be observed even when the 2-OHE1-AS is injected on the diestrus morning. Almost similar results were obtained with an antiserum against 17 beta-estradiol (17 beta-E2). Nevertheless, the fact that the central immunoneutralization of 2-OHE1 impedes the preovulatory surge of LH at a time of high peripheral levels of 17 beta-E2 strengthens the idea of a specific role for 2-OHE1 in the control of cycling LH release.

Prostaglandin H synthase catalyzes regiospecific release of tritium from labeled estradiol

Prostaglandin H synthase (PHS) from ram seminal vesicle microsomes was found to catalyze the release of tritium (3H) from estradiol (E2) regiospecifically labeled in position C-2 or C-4 of ring A but not from positions C-17 alpha, C-16 alpha, or C-6,7. Formation of 3H2O from ring A of E2 is dependent upon native enzyme supplemented with either arachidonic acid, eicosapentaenoic acid, or hydrogen peroxide and proceeds very rapidly as do other cooxidation reactions catalyzed by PHS-peroxidase. The 3H-loss from ring A of E2 reflecting oxidative displacement of this isotope by PHS increases linearly up to 100 microM under our conditions (8-45 nmol/mg x 5 min). Loss of tritium in various blanks is negligible by comparison. Indomethacin (0.07 and 0.2 mM) inhibited the PHS-dependent release of 3H2O from estradiol but less efficiently than it inhibited DES-cooxidation measured in parallel incubations under similar conditions. Addition of EDTA (0.5 mM) had no effect on the regiospecific transfer of 3H from E2 or on DES-oxidation; ascorbic acid (0.5 mM) or NADH (0.33 mM) clearly inhibited both reactions and to a similar extent. These data suggest that estradiol-2/4-hydroxylation can be catalyzed by PHS in vitro probably via its peroxidase activity and point to PHS as an enzyme that could contribute to catechol estrogen formation in vitro by tissue preparations in the presence of unsaturated fatty acids or peroxides.

Brain mitochondrial cytochrome P-450scc: spectral and catalytic properties

The cytochrome P-450-dependent cholesterol side chain cleavage system of the brain has been studied using nonsynaptic mitochondria as the source of enzymatic activity. The system has been found to bind cholesterol and 11-deoxycorticosterone, producing type I difference spectra, whereas the binding of pregnenolone induced a reverse type I difference spectrum. Inhibitors of cytochrome P-450-linked monooxygenase activities produced type II spectra. The formation of labeled pregnenolone after incubation of brain mitochondria with [4-14C]cholesterol has been obtained, and this formation was inhibited by glutethimide, a specific inhibitor of cytochrome P-450scc. The functional significance of this enzymatic activity is discussed.

Substrate dependency of specific and non-specific estrogen-2/4-hydroxylase activities measured by the radio-enzymatic method in rat brain microsomes

Putative specific and non-specific estrogen-2/4-hydroxylase activities which might affect the radio-enzymatic assay were characterized in terms of their requirements for NADPH and their substrate dependency. Using rat brain microsomes and partially purified rat liver COMT three main sources of estrogen-2/4-hydroxylase activity could be distinguished; a COMT-related component and NADPH-dependent and NADPH-independent microsomal components. The COMT-related activity required NADPH and showed about equal preferences for estrone and estradiol. The NADPH-dependent component was highly specific for estradiol, the relative activities observed with estrone and estriol being 7 and 1% of that observed with estradiol. The NADPH-independent component exhibited substrate saturation, was heat-labile and could not be inhibited by alpha-naphthoflavone or metyrapone. It showed a preference for estrone over estradiol, with estriol being a very poor substrate. These findings indicate that non-enzymatic factors contribute very little to product formation in the radio-enzymatic assay. The specificity of the major NADPH-dependent microsomal component towards estradiol suggests a stereo-specific requirement for the D-ring configuration of this estrogen. The use of no-cofactor blanks in the radio-enzymatic assay may be very important when different estrogens are compared as substrates for estrogen-2/4-hydroxylases.

Evidence that estradiol-2/4-hydroxylase activities in rat hypothalamus and hippocampus differ qualitatively and involve multiple forms of P-450: ontogenetic and inhibition studies

Estradiol-2/4-hydroxylase activity was studied in hypothalamic and hippocampal microsomes of male and female Wistar rats between 22 and 75 days after birth. The activity exhibited substrate saturation (50-100 microM estradiol) required NADPH and was inhibited by carbon monoxide, alpha-naphthoflavone and metyrapone. With 30 microM estradiol, 50% inhibition required 50-70 microM alpha-naphthoflavone compared to 200 microM metyrapone. Metyrapone exhibited biphasic inhibition curves which did not differ significantly between hypothalamus and hippocampus, whereas alpha-naphthoflavone was a more potent inhibitor of the hippocampal enzyme than of the hypothalamic enzyme. The Km and Vmax of the hippocampal estradiol-2/4-hydroxylase were significantly greater than that of the hypothalamus in both sexes at all ages studied. In female rats the Km of the hypothalamic enzyme changed from 14 microM at 23 days of age, to 47 microM at 71 days, but remained constant at about 29 microM in males. The Km of the hippocampal enzyme showed no significant change with age in either sex. The present findings indicate that catechol estrogen formation in the brain is catalyzed by multiple forms of microsomal P-450. They also suggest that these enzyme activities in the rat hypothalamus and hippocampus differ qualitatively. Ontogenetic changes in the Km of estradiol-2/4-hydroxylases appeared to be limited to the female hypothalamus. This might reflect a specific biological requirement of the female hypothalamus during critical stages of sexual differentiation of the brain. The relatively high hippocampal activity might reflect the catalytic versatility of different P-450 isozymes and does not necessarily imply a physiologically meaningful role with respect to catechol estrogen biosynthesis in this particular brain area.

The metabolism of estradiol 17-sulfate by pheochromocytoma tissue

The metabolism of estradiol 17-sulfate by subcellular localization enzymes of pheochromocytoma tissue obtained from a 41-year old female was investigated. In any incubations under the presence of NADH and NADPH, metabolites hydroxylated at the C-2, C-4, C-6 beta, C-7 alpha and C-7 beta positions were produced. These hydroxylations are considered to occur without cleavage of the sulfate group. The 2-hydroxylation at the substrate concentration of 100 microM by mitochondria, microsomes and cytosol fractions occurred at rates of 141, 222 and 167 pmol/mg protein/30 min, respectively; the corresponding rates for the 4-hydroxylation were 24, 40 and 38 pmol/mg protein/30 min. Mitochondrial 2- and 4-hydroxylations were enhanced by addition of calcium ion (Ca2+) into the incubation medium.

Metabolism of estradiol by true and pseudoperoxidases

The activation of 14C-labeled estradiol by "true" and "pseudo" peroxidases to form conjugates and other products was compared in four model systems using H2O2, glutathione, Mn2+ or irradiated riboflavin. Albumin was used as acceptor except in the glutathione system. The binding of estradiol to glutathione in the presence of the true peroxidases, lacto- or uterine peroxidase (no H2O2 added), was also examined and the conditions shown to differ from those required with the pseudoperoxidases, microperoxidase or trypsin-digested cytochrome c. The conjugates were purified by chromatography after elution from Amberlite XAD-2 and the relative amounts of these products assessed by autoradiography. The ratio of steroid to glutathione in the main water-soluble metabolite formed with lactoperoxidase was found to be approx 1:1 in a double label experiment with [14C]estradiol and [3H]glutathione. It was also shown, using estradiol labeled with 3H in different positions of the steroid molecule, that lactoperoxidase acts non-specifically in catalyzing the formation of glutathionyl conjugates as indicated by the release of 3H2O. The possible role of peroxidase and glutathione in the metabolism of estrogens and in the formation of artifactual products is discussed.

Regulation of aromatic oxidation of estradiol-17 beta in maternal hepatic, fetal hepatic and placental tissues: comparative effects of a series of inducing agents

The effects of nine separate inducers of cytochrome P-450-dependent monooxygenases on the hydroxylation of estradiol-17 beta (E2) were investigated in near-term pregnant rats. Isosafrole exhibited highly effective inducing properties in the maternal liver (20-fold and 5-fold increases in 4- and 2-hydroxylase activities respectively). Pregnenolone 16 alpha-carbonitrile produced approx 20- and 30-fold increases in measured respective rates of 4- and 2-hydroxylase activities in fetal hepatic tissues; isosafrole produced only 2-fold increases in the same reaction. Only minor changes or slight increases in estrogen hydroxylation rates were observed in maternal hepatic, fetal hepatic or placental tissues following treatment with 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) or other potent 3-methylcholanthrene (MC)-like inducing agents (beta-naphthoflavone, MC, caffeine). Phenobarbital exhibited relatively weak inducing properties and exposure of pregnant rats to ethanol from days 3-19 of gestation was without statistically significant effects on the parameters investigated. Rat placentas exhibited extremely low estrogen hydroxylase activities irrespective of pre-exposure of pregnant rats to the inducers studied. The results suggested separate regulatory controls for estrogen 2- and 4-monooxygenase activities even though relatively high correlation between the two reaction were generally observed in all three tissues.

Studies on oestrogen-2/4-hydroxylase activity in mammalian brain, using a radioenzymatic assay method

The activity of oestrogen-2/4-hydroxylase in brain tissue was studied using a radioenzymatic assay which controlled for non-specific formation of catechol oestrogen. The ontogeny of enzyme activity in male and female rat brain was examined between 1 and 70 days of age. Until 10 days of age, both sexes showed low enzyme activity. Between days 10 and 15 enzyme activity in the female significantly increased but was unchanged in the male. Male brain enzyme activity increased between days 15 and 20 whereas activity was unchanged in the female. Both males and females showed increases in enzyme activity between 20 and 25 days of age. Thereafter enzyme activity plateaued but at all ages between day 20 and day 70 male brain enzyme activity was significantly greater than in the female. A study of the distribution of the oestrogen-2/4-hydrolase in the sheep hypothalamus revealed that the stalk/median eminence had approx 10 times greater activity than either the anterior, medial or posterior hypothalamus. These findings are discussed in relation to sexual differentiation of the brain.

Ontogeny of estradiol-2-hydroxylase activity in discrete brain areas of Wistar rats

Estradiol-2-hydroxylase activity was assayed radio-enzymatically in microsomes of six different brain areas of male and female Wistar rats between 22 and 77 days of age. The hypothalamus consistently showed the lowest activity and the hippocampus the highest, with the other areas falling in between. This pattern was seen in both sexes and at all the ages studied. In both sexes all six brain areas showed a steady increase in activity with increasing age. No statistically significant sexual differences in activity were observed for any area. The relatively low estradiol-2-hydroxylase activity in the hypothalamus is noteworthy since it contradicts the published evidence that this area has the highest in vitro catecholestrogen forming capacity in the brain.

Regiospecific transfer of tritium into 3H2O from labeled estrogens by mushroom tyrosinase

The specificity of mushroom tyrosinase in displacing 3H from estradiol and catechol estrogens labeled at C-1, C-2, C-4 or C-6,7 was investigated under various conditions. [2-3H]E2 Yielded significant amounts of 3H2O, in the presence of NADH, and the rate of 3H loss from the steroid paralleled that of the radioactivity remaining in the aqueous fraction after extraction with organic solvents. NADH had little effect on the release of 3H from [1-3H]E2 or [4-3H]E2 but glutathione was highly active in this respect, with considerable differences being observed between lyophilizable 3H2O and yields of water-soluble products. It is proposed that 3H losses from C-2 of estradiol reflects oxidative displacement of this isotope by tyrosinase while the loss observed from C-1 and C-4 is the result of non-enzymatic conjugation with glutathione after the formation of the catechol estrogen. The difference between lyophilizable 3H2O and the yield of water-soluble products obtained with [1-3H]E2 and [4-3H]E2 provided a measure of the relative amount of conjugation occurring at C-1 and C-4. These findings were confirmed by double label experiments with 3H- and 14C-labeled estrogens and the isolation of the glutathionyl derivatives. The catechol estrogens did not serve as substrates for further hydroxylation by the enzyme even when C-2 was available for this reaction. These experiments give further information about the specificity of tyrosinase in its reaction with aromatic steroids and provide a simple and rapid method for confirming the distribution of 3H at C-2 or C-4 of estradiol.

Charcoal-catalyzed transfer of tritium into 3H2O from regiospecifically-labeled 2-hydroxyestradiol in the presence of thiols

Charcoal was found to catalyze the release of 3H2O from [1-3H]2-hydroxyestradiol-17 beta ([1-3H]2-OHE2) or [4-3H]2-hydroxyestradiol-17 beta ([4-3H]2-OHE2) and this effect was shown to occur in the presence of glutathione or other thiols and to depend on the concentration of free steroid. The radiometric assay for measuring the formation of 3H2O was not affected significantly by subsequent treatment of the incubation mixture with charcoal if the ratio of steroid to tissue (rat brain or liver microsomes) was low and only initial rates of 3H release were measured. 2-Hydroxyestradiol did not show the charcoal effect in the presence of tyrosinase, either when it was generated from its parent estrogen or added to the enzyme. The formation of 3H2O from [4-3H]2-OHE2 in the presence of glutathione was inhibited by ascorbic acid but the addition of dextran or albumin did not protect the catechol estrogen from the charcoal-catalyzed loss of tritium. The reaction with glutathione and charcoal occurred even at 4 degrees C but other adsorbants such as alumina, silica or hydroxylapatite were without effect.