Potent enzyme-activated inhibition of aromatase by a 7 alpha-substituted C19 steroid

Enzyme-activated inhibitors of aromatase would result in effective medicinal agents for modulating estrogen-dependent processes and thus may be useful in controlling reproductive processes and in treating estrogen-dependent diseases such as breast and endometrial cancer. A potential enzyme-activated inhibitor of aromatase, 7 alpha-(4'-amino)phenylthio-1,4-androstadiene-3,17-dione (7 alpha-APTADD), was synthesized and examined in vitro with placental aromatase. Under initial velocity conditions, 7 alpha-APTADD exhibited high affinity for the enzyme and is a potent inhibitor of aromatase with an apparent Ki of 9.9 +/- 1.0 nM and with a Km for androstenedione of 52.5 +/- 5.9 nM. This inhibitor produced a rapid time-dependent, first-order inactivation of aromatase in the presence of NADPH, while no inactivation of aromatase activity was observed in the absence of NADPH. Protection of aromatase from inactivation was observed when the substrate, androstenedione, was included in the incubation mixture containing enzyme, inhibitor, and NADPH. On the other hand, nucleophilic trapping agents such as cysteine did not protect the enzyme from inactivation by 7 alpha-APTADD. Additionally, second enzyme pulse experiments demonstrated identical rates of inactivation, suggesting that the enzyme-activated inhibitor was not being released from the active site of the enzyme. The apparent Kinact for 7 alpha-APTADD is 159 +/- 21 nM and represents the inhibitor concentration required to produce a half-maximal rate of inactivation. The half-time of inactivation at infinite inhibitor concentration was 1.38 +/- 0.92 min and is the most rapid enzyme-activated aromatase inhibitor reported to date. Thus, 7 alpha-APTADD is a potent enzyme-activated inhibitor of aromatase, exhibiting high affinity and rapid inactivation. This inhibitor will be useful in probing the biochemistry of aromatase and should also serve as an effective medicinal agent for the treatment of estrogen-dependent cancers.     

Structure-function studies of aromatase and its inhibitors: a progress report

The utilization of computer modeling, site-directed mutagenesis, inhibition kinetic analysis and reaction metabolite analysis allows us to better understand the structure–function relationship between aromatase and its inhibitors. Our results have helped in determining how steroidal and nonsteriodal aromatase inhibitors bind to the active site of the enzyme. This information has also aided in the understanding of the reaction mechanism of aromatase. Furthermore, our structure–function studies of aromatase have generated important information for predicting how environmental chemicals interact with the enzyme. During the last 2 years, a new aromatase computer model based on the X-ray structure of rabbit cytochrome P450 2C5 has been generated and used to evaluate the results obtained from new aromatase mutants produced in this laboratory. In addition, we have succeeded in the expression and purification of functionally active aromatase using an Escherichia coli expression method. The catalytic properties of this recombinant aromatase are similar to those properties exhibited by the human placental aromatase preparation and the mammalian cell-expressed enzyme. The E. coli expressed aromatase will be very useful for further structure–function studies of aromatase. Our laboratory has also evaluated the growth-inhibiting activity of aromatase inhibitors in estrogen receptor-positive breast cancer using three-dimensional cell cultures of aromatase-over expressing MCF-7 and T-47D cell lines (i.e. MCF-7aro and T-47Daro). Our results demonstrate that these three-dimensional cultures are valuable approaches to assess the growth-inhibiting activity of aromatase inhibitors. Finally, we have identified several phytochemicals to be potent inhibitors of aromatase. To demonstrate the impact of the phytochemicals on estrogen formation in vivo, we showed that the intake of anti-aromatase chemicals from red wine was capable of suppressing MCF-7aro-mediated tumor formation in nude mice and aromatase-induced hyperplasia in a transgenic mouse model in which aromatase is over-expressed in the mammary tissue.     

Functional characterization of 102-amino acid-deleted form of human aromatase (delta102-aromatase).

A truncate form of human aromatase cDNA that corresponds to the recently identified rat cortical type aromatase mRNA variant (Yamada-Mouri et al., J. Steroid Biochem. Molec. Biol., 60: 325-329, 1997) has been generated, and the amino-terminus deleted form of the enzyme has been expressed in CHO cells. The resulting product lacking 102 residues from the N-terminus of aromatase (i.e. 102-aromatase) showed an extremely low enzyme activity using an 'In-cell' assay. A strong aromatase activity, however, was observed for the delta102-aromatase using an in vitro method on the solublized preparations. The in vitro activity was dependent on both incubation time and NADPH concentration as well as inclusion of NADPH-cytochrome P450 reductase in the assay mixture. The average turnover rate of aromatization of the reconstituted delta102-aromatase was 6.8 min(-1). The results of the immunosuppression assay suggested that delta102-aromatase still holds the epitope interactive to MAb3-2C2, a monoclonal antibody raised agaist human placental aromatase P450. Furthermore, the IC50 values of MAb3-2C2 were determined to be 24 and 23 microg/ml for the whole homogenate and the 105,000 x g precipitate fractions prepared from the truncated aromatase expressing cells, respectively, whereas an IC50 of 1.3 microg/ml was shown for the full-length human aromatase. These results indicate that the delta102-aromatase P450 can be expressed and is catalytically competent as the full-length enzyme, but the epitope structure for the monoclonal antibody MAb3-2C2 is altered from that of the native enzyme. In addition, the intracellular distribution of delta102-aromatase may be different from that of the wild-type enzyme, explaining why very low activity was measured using an 'In-cell' assay.     

Immunocytochemical studies of aromatase in early and full-term human placental tissues: comparison with biochemical assays

An immunocytochemical method for visualizing the aromatase P450 enzyme with a specific monoclonal antibody has been developed for use with unfixed, frozen tissue sections. We compared both monoclonal and polyclonal aromatase-specific antibodies and found that placental aromatase was consistently and exclusively located in the syncytiotrophoblast layer of chorionic villi. The monoclonal antibody had the highest affinity, with negligible associated background stain. Fixation was found to impair stain reaction. Examination of first trimester and term placentae revealed identical immunostaining patterns of similar intensity in 9 of 10 samples. The immunostain reactions of first trimester and term placentae were compared with their respective microsomal aromatase activity, determined simultaneously by both indirect radiometric tritiated water (3H2O) assay, and direct product isolation by HPLC, using [1, 2, 6, 7(-3)H] androstenedione as substrate. The two assays were found to be comparable for enzyme activity estimates of term placental specimens. However, when first trimester specimens were analyzed, the direct-product measurements were significantly larger than the corresponding 3H2O assay results. Nonetheless, biochemical aromatase activity was found to correlate positively with immunostain reaction. Although 17 beta-hydroxysteroid dehydrogenase activity was not directly measured, differences in the estradiol:estrone product ratio (2.49 +/- 0.68 first trimester vs. 0.89 +/- 0.15 term) suggest differential control of this enzyme at the two stages of pregnancy. One first trimester specimen with an atypical, patchy immunostain distribution also had extremely low aromatase activity. The results indicate that both antibodies recognize functional aromatase enzyme and suggest that immunocytochemical detection is a sensitive, qualitative technique for investigating this important steroidogenic enzyme.     

Human aromatase in high yield and purity by perfusion chromatography and its characterization by difference spectroscopy and mass spectrometry

Expression of human cytochrome P450 aromatase (CYP19A1, aromatase) was accomplished at a high level using a baculovirus expression system in an insect cell suspension culture. Using the relatively new chromatographic technique of perfusion chromatography, a very rapid procedure for purification of the protein from solubilized cells was developed. At extraordinary flow rates of between 3 and 9 column volumes per minute, all chromatographic procedures could be performed, including setup, equilibration, and column regeneration steps, in less than 2 h, not including brief dialysis periods. Total yields were 40-52% and resulted in preparations with specific content values of 17.1 nmol aromatase/mg protein. Final purified preparations showed virtually no typical P450 spectra under standard conditions, but displayed full activity with typical enzyme kinetic parameters. These unusual results suggest that standard methods of P450 measurement are inappropriate when applied to aromatase. The findings are fully consistent with those encountered previously for purified preparations from a human placental source and led us to a new aromatase quantification method based on ligand-induced difference spectroscopy. A new HPLC assay is described which rapidly separates heme and apoprotein while measuring total heme content. Matrix-assisted laser desorption ionization time-of-flight mass spectrometry was employed with both glycosylated and deglycosylated forms of the final purified product to confirm its identity as a glycosylated cytochrome P450.     

Aromatase in the human choriocarcinoma JEG-3: inhibition by R 76 713 in cultured cells and in tumors grown in nude mice

The aromatase enzyme and its inhibition by R 76 713 were characterized in the JEG-3 choriocarcinoma cell line in culture and in JEG-3 tumors grown in nude mice. Optimal cell culture parameters and enzyme reaction conditions for the determination of aromatase activity were established. Under these conditions, in vitro JEG-3 aromatase was inhibited by R 76 713 with IC50-values of 7.6 +/- 0.5 nM and 2.7 +/- 1.1 nM using 500 nM of androstenedione and testosterone as substrate respectively. The Km-value of the aromatase enzyme with androstenedione as substrate was 62 +/- 19 nM; with testosterone as substrate, a value of 166 +/- 27 nM was found. In the presence of increasing concentrations of R 76 713, the Km-values increased while the Vmax remained unchanged. Using androstenedione and testosterone as substrate Lineweaver-Burk analysis of the data showed Ki-values for R 76 713 of 0.43 +/- 0.06 nM and 0.47 +/- 0.39 nM respectively. R 76 713 appeared to competitively inhibit the JEG-3 aromatase. Aromatase could easily be measured in homogenates of JEG-3 tumors grown in nude mice and showed Km-values similar to those found for JEG-3 cells in vitro. IC50-values for inhibition of tumor aromatase by R 76 713 were also similar to those found in cultured cells. Tumor aromatase measured ex vivo, 2 h after a single oral administration of R 76 713 was dose-dependently inhibited. An ED50-value of 0.05 mg/kg was calculated. The JEG-3 choriocarcinoma proved to be a useful aromatase model enabling the comparative study of aromatase inhibition in vitro and in vivo.     

Studies on aromatase inhibition with 4-androstene-3,6,17-trione: its 3 beta-reduction and time-dependent irreversible binding to aromatase with human placental microsomes

The metabolism of 4-androstene-3,6,17-trione (AT), previously described as a suicide substrate for aromatase, and its irreversible binding to aromatase were studied by using human placental microsomes. AT was rapidly converted into 3 beta-reduced metabolite (3-OHAT) with an enzyme other than aromatase in the microsomes in the presence of NADPH under either aerobic or anaerobic conditions. The conversion was efficiently prevented by a steroid 5 alpha-reductase inhibitor. 3-OHAT was characterized as a competitive (Ki = 6.5 microM) and irreversible inhibitor of aromatase. Both 14C-labeled AT and 3-OHAT were demonstrated to be irreversibly bound to aromatase probably through a sulfur atom of the enzyme in time-dependent manners in the presence of NADPH, being accompanied with time-dependent losses of the enzyme activity. It was shown that the process of an apparent time-dependent loss of aromatase activity caused by AT even under conditions allowing its 3 beta-reduction should principally depend on the action of the parent inhibitor AT itself and not on that of the metabolite 3-OHAT.     

A three-dimensional model of CYP19 aromatase for structure-based drug design

Aromatase (CYP450_arom, CYP19) is an enzyme responsible for converting the aliphatic androgens androstenedione and testosterone to the aromatic estrogens estrone and estradiol, respectively. These endogenous hormones are a key factor in cancer tumor formation and proliferation through a cascade starting from estrogen binding to estrogen receptor. To interfere with the overproduction of estrogens especially in tumor tissue, it is possible to inhibit aromatase activity. This can be achieved using aromatase inhibitors. In order to design novel aromatase inhibitors, it is necessary to have an understanding of the active site of aromatase. As no crystal structure of the enzyme has yet been published, we built a homology model of aromatase using the first crystallized mammalian cytochrome enzyme, rabbit 21-progesterone hydroxylase 2C5, as a template structure. The initial model was validated with exhaustive molecular dynamics simulation with and without the natural substrate androstenedione. The resulting enzyme–substrate complex shows very good stability and only two of the residues are in disallowed regions in a Ramachandran plot.     

Structure-function studies of human aromatase

Site-directed mutagenesis experiments have been carried out to determine the structure-function relationship of human aromatase. By sequence comparison, the region in aromatase that corresponds to the distal helix of cytochrome P-450cam has been identified to be Gln-298 to Val-313. Eight aromatase mutants with changes in this region, i.e. C299A, E302L, P308F, D309N, D309A, T310S, T310C, and S312C, have been generated using a mammalian cell stable-expression system. The results from site-directed mutagenesis studies indicate that the region containing Gln-298 to Val-313 is indeed a very important part of the active site of aromatase. The catalytic properties of P308F, D309N, and D309A have been examined in detail and are discussed. Active site-directed labeling is also an important approach to investigate the structure-function relationship of aromatase. HPLC-linked electrospray mass spectrometry is indicated as a useful technique for the characterization of active site-directed probe-modified enzyme. The mass spectral analysis of aromatase suggests that aromatase is glycosylated.     

Catalytic differences between porcine blastocyst and placental aromatase isozymes.

Two isozymes of porcine aromatase, the placental and the blastocyst forms, were expressed in CHO cells using the mammalian cell transfection method. Using an 'in-cell' assay (a 3H-water release method), catalytic parameters of the porcine placental aromatase were found to be very similar to those of the human enzyme; however, the activity of the blastocyst isozyme was found to be one-thirtieth that of the placental isozyme. Product isolation assay (using testosterone as the substrate) revealed that the major steroid products were 17beta-estradiol and 19-nortestosterone. The product ratio of estradiol/19-nortestosterone was found to be 94 : 6 for the porcine placental form, 6 : 94 for the porcine blastocyst form, and 92 : 8 for the human wild-type aromatase. Therefore, the porcine blastocyst aromatase isozyme catalyzes mainly androgen 19-desmethylation rather than aromatization. In addition, inhibition profile analyses on the placental and blastocyst isozymes were performed using three steroidal inhibitors [4-hydroxyandro-stenedione (4-OHA), 7alpha-(4'-amino)phenylthio-1, 4-androstandiene-3,17-dione (7alpha-APTADD), and bridge (2, 19-methyleneoxy) androstene-3,17-dione (MDL 101,003)], and four nonsteroidal inhibitors [aminoglutethimide (AG), CGS 20267, ICI D1033, and vorozole (R83842)]. While the two isozymes of porcine aromatase share 93% amino-acid sequence identity, our results indicate that the two porcine aromatase isozymes have distinct responses to various aromatase inhibitors.     

Biological characterization of A-ring steroids

Hydroxylated 2,19-methylene-bridged androstenediones were designed as potential mimics of enzyme oxidized intermediates of androstenedione. These compounds exhibited competitive inhibition with low micromolar affinities for aromatase. These inhibitory constants (K_i values) were 10 times greater than the 2,19-methylene-bridged androstenedione constant (K_i = 35–70 nM). However, expansion of the 2,19-carbon bridge to ethylene increased aromatase affinity by 10-fold (K_i = 2 nM). Substitution pf a methylene group with oxygen and sulfur in this expanded bridge resulted in K_i values of 7 and 20 nM, respectively. When the substituent was an NH group, the apparent inhibitory kinetics changed from competitive to uncompetitive. All of these analogs exhibited time-dependent inhibition of aromatase activity following preincubation of the inhibitor with human placental microsomes prior to measuring residual enzyme activity. Part of this inhibition was NADPH cofactor-dependent for the 2,19-methyleneoxy- but not for the 2,19-ethylene-bridged androstenedione. The time-dependent inhibition for these four analogs was very rapid since they exhibited τ₅₀ values, the t_1/2 for enzyme inhibition at infinite inhibitor concentration, of 1 to 3 min. These A-ring-bridged androstenedione analogs represent a novel series of potent steroidal aromatase inhibitors. The restrained A-ring bridge containing CH₂, O, S, or NH could effectively coordinate with the heme of the P450 aromatase to allow the tight-binding affinities reflected by their nanomolar K_i values.     

Effects of 10-(2-propynyl)-estr-4-ene-3,17-dione (MDL 18,962)--a mechanism-based irreversible inhibitor of aromatase--in cultured human foreskin fibroblasts

In male subjects, peripheral aromatization of androgens accounts for most of the estrogen production, and skin is an important site of such enzymatic activity. We have studied the effects of a mechanism-based, irreversible aromatase inhibitor, 10-(2-propynyl)-estr-4-ene-3,17-dione (MDL 18,962) on androgen action and metabolism in cultured human foreskin fibroblasts. Cells were incubated simultaneously in the presence of substrate, androstenedione, and inhibitor, MDL 18,962. Aromatase activity was linear with time up to 3 h of incubation at 37 degrees C in the absence and presence of 1.0-10 nM inhibitor. The IC50 for four different cell strains ranged from 4.0 to 8.6 nM MDL 18,962. Kinetic analysis of competitive inhibition by the Eadie-Hofstee method yielded an apparent Ki of 2.75 nM for the inhibitor. Preincubation of cells with MDL 18,962 resulted in irreversible inhibition of aromatase activity which was time- and concentration-dependent. We calculated a Ki of 7.6 nM for MDL 18,962. Preincubation of cells with 25 nM MDL 18,962 suppressed enzyme activity for up to 6 h following removal of the inhibitor, before a return of enzyme activity due to synthesis of new enzyme. MDL 18,962 (0.2-20 microM) did not influence the 5 alpha-reduction of testosterone (200 nM). In addition, binding of dihydrotestosterone (2 nM) to androgen receptors was not affected by MDL 18,962 (25-1000 nM). In summary, MDL 18,962 is a specific, high potency inhibitor of aromatase. By virtue of its high binding affinity to the enzyme active site, it competes very effectively with substrate, resulting in irreversible inactivation of aromatase.     

Aromatase messenger RNA is derived from the proximal promoter of the aromatase gene in Leydig, Sertoli, and germ cells of the rat testis

It has long been recognized that individual cell types within the testes possess the capacity to synthesize estrogen. A number of studies on different species have demonstrated that the levels of aromatase expression and the patterns of regulation are distinct between the different cell types of the testes. Whereas a variety of promoters have been shown to contribute to the patterns of aromatase expression in different cell lineages, studies using ovarian RNA, testis RNA, and Leydig cell tumor lines have demonstrated that the same promoter (promoter II) was used in each. Recent experiments using potent aromatase inhibitors or analysis of animals in which the genes encoding the estrogen receptor-alpha (ER-alpha) or the aromatase, P450, are defective, have confirmed the importance of local estrogen formation in normal testicular function. In order to permit experiments to identify the elements controlling aromatase expression in the individual cell compartments of the testes, we prepared RNA from purified preparations of Leydig, Sertoli, and germ cells. Using specific oligonucleotide primers, the sites of initiation of the aromatase mRNA were determined using rapid amplification of cDNA ends (RACE) and nucleotide sequence analysis of the resulting cDNA fragments. Our results indicate that aromatase mRNA is derived from the proximal promoter (PII) of the aromatase gene in each of the major cell types of the rat testes.     

The expression of a functional cDNA encoding the chicken cytochrome P-450arom (aromatase) that catalyzes the formation of estrogen from androgen

A complementary DNA (cDNA) copy of the aromatase P-450 has been isolated from a chicken ovary library using as probe a partial cDNA believed to encode the human placental aromatase. The predicted amino acid sequence of the chicken aromatase cDNA possesses regions of homology to that of its human counterpart, but only limited homology to other cytochrome P-450 enzymes. The introduction of the cDNA clone into COS-1 cells results in the production of high levels of aromatase activity. The chicken enzyme is targeted to the appropriate subcellular fraction in the transfected COS cells, and the apparent Km of the chicken aromatase activity, measured in microsomes prepared from the transfected cells, is similar to that of the enzyme prepared from chicken ovary microsomes. These findings establish that the cDNA clone encodes chicken ovarian aromatase and demonstrate that this protein can catalyze the three successive oxidation reactions necessary to form estrogen from androgen.     

1-[(Benzofuran-2-yl)phenylmethyl]-triazoles and -tetrazoles - potent competitive inhibitors of aromatase.

The synthesis of a series of novel 1-[(benzofuran-2-yl)phenylmethyl]-triazoles and -tetrazoles is described. The compounds were tested for human placental aromatase inhibition in vitro, using [1beta-3H]-androstenedione as the substrate for the aromatase enzyme, the percentage inhibition and IC50 data is included.