Aromatase and testosterone fatty acid esters: the search for a cryptic biosynthetic pathway to estradiol esters.

The estradiol fatty acid esters (lipoidal derivatives, LE2) are extremely potent estrogens that accumulate in fat, including fat of menopausal women. These steroidal esters are protected from metabolism and are converted to the free, biologically active steroid through the action of esterases. Previous studies have shown that biosynthetic pathways in the adrenal gland exist in which steroid fatty acid esters are substrates. This led us to determine whether a cryptic aromatase pathway exists in which testosterone esters could be converted directly into LE2. We tested a representative fatty acid ester, testosterone stearate, both as an inhibitor and as a substrate for the aromatase enzyme from human placental microsomes. This ester had neither activity. In addition, we tested [1 beta-3H]testosterone acetate as a substrate for this enzyme complex, measuring the production of 3H2O as evidence of aromatization. Although the rate of reaction was considerably slower than that of testosterone, 3H2O was produced. However, when [2, 4, 6, 7-3H]testosterone acetate was incubated and the steroidal products isolated, we found that hydrolysis of the substrate had occurred. Both [3H]-labeled testosterone and estradiol were found, and very little if any [3H]estradiol acetate was formed. Thus, we conclude that an aromatase pathway involving testosterone esters does not exist and that the sole source of LE2 is through direct esterification of estradiol.     

Steroidal fatty acid esters

Several years ago we discovered an unexpected family of steroidal metabolites, steroidal fatty acid esters. We found that fatty acid esters of 5-ene-3β-hydroxysteroids, pregnenolone and dehydroisoandrosterone are present in the adrenal. Subsequently, others have shown the existence of these non-polar 5-ene-3β-hydroxysteroidal esters in blood, brain and ovaries. Currently, almost every family of steroid hormone is known to occur in esterified form. We have studied the esters of the estrogens and glucocorticoids in some detail, and have found that these two steroidal families are esterified by separate enzymes. In a biosynthetic experiment performed simultaneously with estrodiol and corticosterone, we established that the fatty acid composition of the steroidal esters is quite different. The corticoid is composed predominantly of one fatty acid, oleate, while the estradiol esters are extremely heterogeneous. Our studies have demonstrated that the estrogens are extremely long-lived hormones, that they are protected by the fatty acid from metabolism. They are extremely potent estrogens, with prolonged activity. Esterification appears to be the only form of metabolism that does not deactivate the biological effects of estradiol. We have demonstrated the biosynthesis of fatty acid esters of estriol, monoesters at both C-16 and C-17β. They too are very potent estrogens. These fatty acid esters of the estrogens are the endogenous analogs of estrogen esters, like benzoate, cypionate, etc., which have been used for decades, pharmacologically because of their prolonged therapeutic potency. We have found that the estradiol esters are located predominantly in hydrophobic tissues, such as fat. Sequestered in these tissues, they are an obvious reservoir of estrogenic reserve, requiring only an esterase for activation. To the contrary the biological activity of the fatty acid esters of the glucocorticoid, corticosterone, is not different from that of its free parent steroid. We have shown that the rapid kinetics of its induction of gluconeogenic responses is caused by its labile C-21 ester which is rapidly hydrolyzed by esterase enzymes. While it appears that the physiological role of the estrogen esters may be related to their long-lived hormonal activity, the role of the other families of steroidal esters is not yet apparent. They, and perhaps the estrogen esters as well, must serve other purposes. Indeed they may serve important biological functions beyond those which we ordinarily associate with steroid hormones.     

A comparison of the fatty acid esters of estradiol and corticosterone synthesized by tissues of the rat

The biosynthesis of the fatty acid esters of the corticoid (corticosterone) and estrogen (estradiol) was compared in parallel incubations of corticosterone and estradiol with several tissues of the rat. The fatty acid composition of the esters of the two steroids was characterized in mammary and uterine tissue. In both of these tissues, the esters of estradiol were extremely heterogeneous. To the contrary, in the same tissues only one predominant ester of corticosterone, corticosterone-21-oleate, was formed. It comprised 70-80% of the total. The oleate ester of estradiol accounted for only 20% of the esters of this estrogen. In addition, fatty acid esters of an A-ring reduced metabolite of corticosterone, 5 beta-dihydrocorticosterone, was also identified. Its fatty acid composition is identical to that of corticosterone. In other experiments the fatty acid esters of both steroids were isolated from several tissues and quantified. When the amount of steroidal ester formed was compared, there was over a 100-fold difference among the various tissues in the ratio of estradiol to corticosterone ester synthesized. Thus, the rate of synthesis of the fatty acid esters of each class of steroid varies dramatically from tissue to tissue, and their fatty acid composition differs markedly as well. If the same enzyme synthesized both the estrogen and corticoid esters, then it would be expected that the relative amount of both esters synthesized in various tissues should be constant and likewise that their composition should be the same. Since neither occurred, these results suggest that the enzyme which produces the C-17 fatty acid esters of the estrogens may be different from the one which synthesizes the C-21 esters of the corticoids. The existence of separate enzyme systems for the synthesis of the fatty acid esters of these steroid hormones opens the possibility of specific physiological controls of each of these unusual steroidal metabolites.     

The naturally occurring C-17 fatty acid esters of estradiol are long-acting estrogens

C-17 fatty acid esters of estradiol are naturally occurring biosynthetic metabolites of estradiol. A representative component of this family of esters, estradiol-17-stearate, was studied in order to determine the estrogenic properties of these unusual hydrophobic steroids. Following the classical estrogen bioassay, a solution of this ester in oil was injected subcutaneously into immature rats once a day for 3 days. There was little effect on the uterus on the first day after the third injection. However, on subsequent days a large stimulation of uterine growth occurred. The course of this estrogenic effect was exactly opposite to that obtained with estradiol. In order to eliminate the possibility that this effect on the time course of estrogenic stimulation was caused by increased solubility of the hydrophobic esters in the carrier oil, the steroids were administered to adult ovariectomized animals in aqueous medium via a single intravenous injection. The uterotrophic response to estradiol was maximal at 12 h and was completely dissipated in 48-60 h. Estradiol-17-stearate produced a uterotrophic effect of twice the duration of estradiol. In the immature rat, aqueous intravenous injections of estradiol-17-stearate produced a greater uterotrophic effect than estradiol and this effect was still maximal 96 h later. In addition, this single injection of estradiol-17-stearate advanced the time of vaginal opening, a marker for puberty in the female rat. The mechanism of the prolonged estrogenic stimulation was investigated by studying the steroidal content of the uterus after injecting [3H]estradiol and [3H]estradiol-17 -stearate i.v. into immature rats. At 1 and 4 h there was significantly more radioactivity in the uteri of the [3H]estradiol treated animals. At later times (8 h and onwards) the total radioactivity in the uterus did not differ appreciably between the two groups. However at these later times, the amount of [3H]estradiol was far greater in the uteri of animals receiving [3H]estradiol-17-stearate. Consequently, the prolonged estrogenic effects of the endogenous C-17 fatty acid esters of estradiol are caused by the increased duration of the estrogenic signal. It is hypothesized that one of the roles of the fatty acid is to protect the steroid nucleus from metabolism and thereby prolong the life of the parent C18 steroid. Thus, the results of these experiments are consistent with the family of endogenous alkyl esters of estradiol having a physiological role as long-acting estrogens.     

Platinum(II) complexes with steroidal esters of L-methionine and L-histidine: synthesis, characterization and cytotoxic activity

Twelve steroidal platinum(II) complexes were synthesized by reaction of potassium tetrachloroplatinate with steroidal esters of L-methionine and L-histidine. The steroidal esters coordinated as bidentate ligands via S and N donor atoms of L-methionine and via two N donor atoms of L-histidine. Cholesterol, cholestanol, diosgenine, pregnenolone, dehydroepiandrosterone, testosterone, estrone, and estradiol were used as the steroidal compounds. The esters and complexes prepared were characterized by infrared, mass, and (1)H NMR spectroscopy and elemental analysis. Platinum complexes were tested for in vitro cytotoxicity against several cancer cell lines: T-lymphoblastic leukemia CEM, breast carcinoma MCF-7, lung carcinoma A-549, multiple myeloma RPMI 8226, and one normal cell line human fibroblast BJ.     

A male specific hepatic estrogen binding protein: characteristics and binding properties

Mammalian liver is a sex-steroid responsive tissue in that androgen and estrogen receptors are present and mediate differential hepatic hormonal effects. Further, we and others have found a sexual dimorphism in the hepatic cytosolic content of estrogen binding proteins. In addition to the estrogen receptor, the male has a high-capacity (12.0-15.0 pmol/mg protein) estrogen binding protein (MEB) which demonstrates a moderate affinity for estradiol (Kd = 31.0-43.2 nM) if estradiol metabolizing enzymes are first precipitated with protamine sulfate. This protein exhibits a unique specificity for steroidal estrogens: 2-methoxyestriol greater than estradiol greater than estriol = 2-methoxyestradiol greater than 2-hydroxyestradiol greater than estrone greater than 2-methoxyestrone greater than estriol 3-glucuronide greater than 2-hydroxyestrone = 3-methoxyestriol greater than androstanediol greater than dihydrotestosterone greater than testosterone. Other androgens such as androstenedione and methyltrienolone, nonsteroidal estrogens such as diethylstilbestrol, and the antiestrogens tamoxifen and 4-hydroxytamoxifen do not compete for [3H]estradiol ([3H]E2) binding. MEB is a relatively small-molecular-weight protein with a Sr of 20.4 A as determined by gel filtration on Sephadex G-100. The kinetics of [3H]E2 association and dissociation at 4 degrees C are very rapid, with t1/2 values of less than 5 s. Sodium molybdate, generally used to stabilize steroid receptors, inhibits MEB-[3H]estradiol binding activity in cytosol in a time- and dose-dependent manner, an effect not observed with partially purified MEB. Magnesium chloride inhibits binding activity of the Sephadex G-100 MEB pool, an effect reversed by EDTA. Other divalent cations also inhibit binding: Mn2+ greater than Mg2+ greater than Ca2+. Furthermore, EDTA complexes of these cations slightly enhance binding relative to EDTA alone: Ca2+ EDTA greater than Mg2+ EDTA greater than Mn2+ EDTA. These results demonstrate that MEB is a unique sex-steroid binding protein, albeit of unknown function, which is distinct from hepatic steroid receptors.     

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.     

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.     

Highly sensitive determination of estrone and estradiol in human serum by liquid chromatography-electrospray ionization tandem mass spectrometry

A highly sensitive and specific quantification method of estrone and estradiol in human serum was described based upon the use of picolinoyl derivatization and liquid chromatography-electrospray ionization mass spectrometry (LC-ESI-MS) in a positive mode. Estrogens were treated with picolinoyl chloride hydrochloride or picolinic acid and 2-methyl-6-nitrobenzoic anhydride followed by a solid-phase extraction with ODS cartridge. Picolinoyl derivatization proceeded quantitatively even in a microscale, and the picolinoyl esters provided simple positive ESI-mass spectra showing [M+H](+) as base peaks for these estrogens. The picolinoyl derivatives of these estrogens showed 100-fold higher detection response compared to underivatized intact molecules by LC-ESI-MS (selected reaction monitoring). Using this derivatization, estrogens spiked in the charcoal treated human serum samples were analyzed with limit of quantification (LOQ), intra-day accuracy and precision of 1.0pg/ml, 96.0% and 9.9% for estrone, and 0.5pg/ml, 84.4% and 12.8% for estradiol, respectively. Estrone and estradiol added to the crude serum samples were recovered with comparable LOQ and accuracy obtained for the charcoal treated serum samples as well.     

Studies on the stoichiometry of estrogen oxidation catalyzed by purified prostaglandin-H-synthase holoenzyme

Prostaglandin-H-synthase (PHS) is a key enzyme in the biosynthesis of prostaglandins (PGs) from arachidonic acid and can oxidatively metabolize synthetic and steroidal estrogens. To investigate the relationship between estrogen cooxidation and PG synthesis, purified PHS-holoenzyme was incubated with radiolabeled arachidonic acid and various estrogens, namely diethylstilbestrol (DES), estradiol (E2), 2-hydroxyestradiol (2-OHE2), and 2-methoxyestradiol (2-MeOE2). The amount and pattern of PGs synthesized were analyzed by TLC and HPLC, estrogen metabolism was studied by HPLC. All tested compounds increased conversion of arachidonic acid to PG H2-derived prostanoids. A stoichiometric ratio between net estrogen oxidation and net PG H2 formation of approximately 2:1 for monophenolic compounds (2-MeOE2, E2) and of 1:1 for diphenolic estrogens (DES, 2-OHE2) was found, indicating that estrogens are apparently acting as electron donors for the PHS-peroxidase. In contrast, glutathione was not found to provide electrons for the reduction of PGG2 to PGH2, and rather decreased the conversion of arachidonic acid. The results of this in vitro study are discussed with respect to its implications for the in vivo situation.     

An estrogen-dependent esterase activity in MCF-7 cells

The presence of steroidal esters in hormonally sensitive tissues lends importance to the esterases which convert the biologically inactive adducts to the parent potent forms. Accordingly, esterase-activities were studied in a human breast cancer model--the MCF-7 cell line. Tritiated estradiol esters- estradiol-17-acetate (EA), estradiol-17-valerate (EV) and estradiol-17-stearate (ES) were tested systematically, but 3 beta-ol esters of androgens, and phorbol diesters were also investigated. All compounds tested, except the phorbol diesters were hydrolyzed either when added to growing cultures or to the 28,000 g supernate of homogenized MCF-7 cells. Among the estrogens, the relative rates of hydrolysis were EA greater than EV greater than ES. The esterase for EA was different as it was not inhibited by saturating concentrations of EV or ES, and unlike the others its activity was stimulated by the addition of estradiol to the culture medium. The antiestrogen keoxifene,[(6-Hydroxy-2-(4-hydroxyphenyl)benzo less than b greater than thien-3-yl greater than less than 4- less than 2-(1-piperidinyl)ethoxy greater than phenyl greater than methanone], negated the stimulatory effect. Other major classes of steroids did not influence EA esterase activity. Results of inhibition experiments indicated that the esterases are of the serine active-site types. The significance of the estrogen-dependent esterase activity can be assessed when the natural substrate(s) for the enzyme is elucidated.     

In vitro metabolism of (6,7-H3)estrone and of (6,7-H3) estradiol by the liver in pregnant guinea pigs]

Slices of pregnant guinea pig liver were incubated with (6,7-3H)estrone and with (6,7-3H)estradiol. Free, glucuro- and sulfo-conjugated fractions were isolated by specific extraction and hydrolysis. The radioactivity distribution in these 3 fractions demonstrated a predominance of conjugated compounds (95% of isolated estrogens) with slightly more glucuro-conjugated than sulfo-conjugated compounds. After isolating estrogens by TLC, we were able to determine estrone and estradiol in these 3 fractions from incubations with 3H-estrone or with 3H-estradiol by means of specific activity recrystallisation. Estriol was determined in glucuro-and sulfo-conjugated fractions after incubation with 3H-estrone as well as in sulfo-conjugated fraction after incubation with 3H-estradiol. Glucuro- or sulfo-conjugated estrone was the predominant estrogen after incubation with 3H-estrone just as after incubation with 3H-estradiol. This led us to conclude to an important 17beta-hydroxysteroid-dehydrogenase activity. The 16alpha-hydroxylastic-activity is weaker since estriol represented only 1,43 % of estrogens isolated after incubation with 3H-estrone and 0.82% after incubation with 3H-estradiol.     

Estradiol esters can replace 17 beta-estradiol in the stimulation of DNA and esterase synthesis by MCF-7 cells: a possible role for the estrogen-sensitive MCF-7 cell esterase

In this communication we extend our earlier observations on estrogen-sensitive carboxyl esterases in MCF-7 human breast cancer cells able to hydrolyze esters of estradiol. Using either estradiol acetate or p-nitrophenyl hexanoate as substrates, esterase activity was found to increase 2-3-fold in MCF-7 cells maintained in the presence of 10(-8) M estradiol. Following sucrose density centrifugation, over 85% of total esterase activity was found in the cytoplasmic fraction. No esterase activity was found in spent media from growing cells. By size exclusion chromatography, estradiol acetate esterase activity exhibited a mol. wt of 45-50 kDa. Attempts to demonstrate incorporation of [3H]estradiol into estradiol fatty acid esters by the above MCF-7 cell line (203P) were unsuccessful, although, such incorporation could be demonstrated in two other MCF-7 cell sublines. Incubation of the 203P cells with 10 nM [3H]estradiol in the presence of 0.5 mM radioinert estradiol acetate resulted in the incorporation of 35 +/- 12% of the label into the estradiol acetate in 10 min. In the absence of radioinert estradiol acetate, no incorporation was observed. When MCF-7 cells were incubated with [3H]estradiol in the presence of a large excess of radioinert estradiol valerate, label was found only in estradiol valerate. Similarly, when the incubation was carried out in the presence of a mixture of radioinert estradiol acetate and valerate, label was incorporated into both esters. We conclude that the apparent formation of radiolabeled estradiol esters by MCF-7 cells incubated under the above conditions, results at least in part, from an esterase-catalyzed exchange reaction. Under conditions where no ester hydrolysis could be detected in the absence of cells, valerate and stearate esters of estradiol were found to be as effective as unesterified estradiol in stimulating esterase synthesis and the incorporation of [3H]thymidine into DNA. These results are consistent with a model in which an intracellular esterase in MCF-7 cells can generate estradiol from an exogenous lipoidal steroid and elicit an estrogen response.     

Aromatization of androstenedione by normal and neoplastic endometrium of the uterus

The ability of human uterine endometrium to aromatize androstenedione to estrogens was investigated using 10 normal and neoplastic tissues. Normal and neoplastic endometrial homogenates were incubated with [6,7-3H]androstenedione (A) and NADPH. Estrone (E1) and estradiol (E2) were subsequently isolated in amounts ranging from 0-17600 fmol/h/g and 0-377 fmol/h/g, respectively, from the incubates after purifications by using Bio-Rad AG1-X2 column, thin layer chromatographies and co-crystallization. The conversion of A to E1 and E2 was significantly higher in neoplastic tissues.     

The biosynthesis of D-ring fatty acid esters of estriol

Biological esterification with fatty acids is a feature that is now known to be common to most steroids. The esterification of estradiol in the D-ring at the 17 beta-hydroxyl leads to a family of extremely active estrogens. Similarly, esterification of the weaker estrogen, estriol (E3), has an even greater impact on its hormonal potency. We have recently shown that synthetic long chain esters of E3 at either 16 alpha- or 17 beta- are highly potent estrogens. The estrogenic activity of the synthetic E3 esters led us to determine whether E3 is biologically esterified, and if so, to characterize the resulting esters. Incubation of E3 with rat lung, a tissue which is highly active in esterifying estradiol, produces a nonpolar metabolite which upon saponification is converted back into E3. There was no evidence for the formation of a diester. Purification by high performance liquid chromatography separates the non-polar metabolite into two peaks, one the C-16 alpha- (approximately 60%) and the other the C-17 beta-ester (approximately 40%). The two fractions were further purified and characterized; each is a mixture of fatty acid esters of E3. The composition of the C-16 alpha- and the C-17 beta-fatty acid esters of E3 is identical. The predominant fatty acids are arachidonate, 34%, palmitate, 26%, followed by oleate 14%, linoleate 13%, stearate 8%, and palmitoleate 5%. The similarity of the esters at C-16 and C-17 may indicate that the fatty acid precursor for the acyltransferase is the same for both hydroxyl groups. It may also suggest that the same enzyme esterifies both positions in the D-ring. Since synthetic estriol fatty acid esters are extremely potent and long-lived estrogens, the enzymatic esterification of estriol produces powerful estrogens with considerable physiological potential.     

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.     

Absence of reactive intermediates in the formation of catechol estrogens by rat liver microsomes

Release of 3H2O from regiospecifically labeled estradiol was measured during 2-hydroxylation of this estrogen by rat liver microsomes. The amount of tritium remaining in the isolated catechol estrogen was also determined. Virtually all the tritium was removed from C-2 during the reaction confirming the absence of an NIH shift. About 20% of the tritium at C-1 was also lost without any such change occurring at C-4 or C-6,7 of the steroid molecule. These findings provide evidence for the formation of an arene oxide or o-semiquinone intermediate during the conversion of estradiol to 2-hydroxyestradiol. No indication of adduct formation at either C-1 or C-4 during this biotransformation was obtained although the 2-hydroxylated product was able to react with a nucleophile such as glutathione. The different regiospecificity of tritium loss in the generation of catechol estrogens and in their subsequent reaction leads to the important conclusion that the reactive intermediates in the two processes must be different. The possible role of catechol estrogens in neoplastic transformation is discussed.     

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.     

Influence of indole-3-carbinol on the hepatic microsomal formation of catechol estrogens.

The oral administration of indole-3-carbinol (IC), present in cabbage and other members of the Cruciferae family, to female rats almost doubled their ability to convert estradiol to catechol estrogens in the liver. This was determined by the release of 3H from C-2 of the estrogen and also by isolation of the 14C-labeled catechol derivative after incubation with hepatic microsomal fractions. The yield of 4-hydroxyestradiol was also elevated and these effects were similar to those produced by 3-methylcholanthrene (MC), a well-characterized cytochrome P450 inducer. Further evidence for the involvement of a mixed-function oxidase was provided by a 70% to 80% decrease in the yield of 3H2O and water-soluble radioactivity by SKF-525A (0.1 mM) when added to the microsomal fractions isolated from the livers of control or IC-treated rats. In addition, NADPH could not be replaced by NADH in these experiments. Pretreatment with ethionine prevented the increase in estradiol metabolism brought about by oral administration of IC. Both IC and MC inhibited catechol estrogen formation when added directly to the liver microsomal system, confirming earlier findings that in vivo inducers can act as in vitro inhibitors. However, IC was less inhibitory than MC, supporting the theory that IC is converted to a more active product in the stomach. Thus, IC may be conferring protection against estrogen-dependent neoplasia by increasing the hepatic oxidation of estradiol, thereby lowering the amount of available active estrogen.     

Differential interactions of estrogens and antiestrogens at the 17 beta-hydroxy or counterpart function with the estrogen receptor

The action of diethylpyrocarbonate on lamb uterine estrogen receptor produced an homogeneous population of the receptor (approximately 55%) which still bound triarylethylene antiestrogens such as 4-hydroxytamoxifen with a high affinity but bound classical potent estrogens such as estradiol or diethylstilbestrol with a very low affinity. To specify the structural features of the ligands involved in the decrease of ligand affinity upon modification of the estrogen receptor, we determined the relative affinity constants of 17 steroidal estrogens or antiestrogens (deriving from estradiol by a 7 alpha- or 11 beta-substitution) and 14 nonsteroidal estrogens or antiestrogens (all including the 1,2-trans-diphenylethylene structure of diethylstilbestrol) for native and diethylpyrocarbonate-modified estrogen receptors. Then the ratio of the relative affinity constant for the native receptor to that for the modified receptor (rho) was calculated for each ligand, to compare the variation in the affinity of the ligand upon modification of the receptor to that of 4-hydroxytamoxifen (rho = 1). The results showed that the strong decrease of ligand affinity upon modification of the receptor displayed by classical estrogens (rho greater than or equal to 200) is strictly dependent on the presence of the 17 beta-hydroxyl group in steroidal compounds or its alpha-4- and beta-4-counterparts in diethylstilbestrol-related compounds. However, for the 7 alpha- or 11 beta-derivatives of estradiol displaying potent antiestrogenic properties, the relative decrease in affinity was much more limited (rho less than or equal to 19). For 11 beta-derivatives displaying a relative estrogenic activity weaker than that of estradiol itself, an average decrease in affinity was observed (23 less than or equal to rho less than or equal to 62). With the diethylstilbestrol-related compounds, bearing or not the alpha-4-hydroxyl and/or the beta-4-hydroxy functions and showing either weak relative estrogenic or antiestrogenic properties, the relative variation in affinity was weak (0.6 less than or equal to rho less than or equal to 24). These results indicate that the interaction of 7 alpha- or 11 beta-substituted steroidal antiestrogens and of 1,2-trans-diphenylethylene or triphenylethylene derivatives, displaying either weak relative estrogenic or antiestrogenic properties with the receptor, differs at the 17 beta-hydroxy or at the alpha-4-/beta-4-hydroxy functions from that of potent estrogens. They suggest that the strong decrease in the relative affinity of ligands upon receptor modification may reflect the high efficiency of the ligands to activate the receptor properly.(ABSTRACT TRUNCATED AT 400 WORDS)