The efficacy of CGS 20267 in suppressing estrogen biosynthesis in patients with advanced stage breast cancer

The pharmacologic inhibition of aromatase activity has been the focus of clinical trials in patients with advanced stage breast cancer. Recent developments with imidazole compounds that inhibit aromatase activity suggest their clinical use as potent inhibitors of estrogen biosynthesis in postmenopausal breast cancer patients. In this Phase I, open-label, dose-range finding study, we examined the inhibitory potency of CGS 20267 on blood and urine levels of estradiol, estrone and estrone sulfate in 8 patients with metastatic breast cancer. Studies included evaluation of adrenal and thyroid function to look for evidence of general hydroxylase inhibition at dose levels effective for aromatase blockade. Patients were administered CGS 20267 at doses of 0.1 and 0.25 mg, once a day in ascending doses over a 12-week period. Preliminary data reveal that CGS 20267 elicits a striking suppression in plasma estradiol, estrone and estrone sulphate which was observed in some patients as quickly as within 24 h of the first dose. Estrogen suppression of over 90% was achieved within 2 weeks of therapy. No alterations in either baseline or ACTH (cortrosyn) stimulated cortisol and aldosterone levels were observed through the 12 weeks of therapy. In addition, 24 h urine sodium and potassium values were not appreciably altered during therapy. We conclude that CGS 20267 is a potent, specific inhibitor of estrogen biosynthesis in postmenopausal patients with metastatic breast cancer and effectively reduces blood and urine estrogens to undetectable levels.     

Aromatase inhibitor and 17alpha-methyltestosterone cause sex-reversal from genetical females to phenotypic males and suppression of P450 aromatase gene expression in Japanese flounder (Paralichthys olivaceus)

The sex of Japanese flounder (Paralichthys olivaceus) is easily altered by water temperature or sex steroid hormone treatment during the period of sex determination. We have previously shown that rearing the genetically female larvae at high water temperature caused the suppression of P450 aromatase (P450arom) gene expression in the gonad and phenotypic sex-reversal of the individuals to males (Kitano et al. 1999. J Mol Endocrinol 23:167-176). In the present study, we show that treatment of genetically female larvae with fadrozole (aromatase inhibitor) or 17alpha-methyltestosterone induces sex-reversal as well as suppression of P450arom gene expression. The effect of fadrozole was counteracted by co-administration of estradiol-17beta. Effective periods for fadrozole treatment to induce sex-reversal were similar to those for high water temperature treatment. RT-PCR did not detect P450arom mRNA in gonad of the sex-reversed, phenotypic males. These results indicate that sex-reversal of the genetically female larvae by aromatase inhibitor (or 17alpha-methyltestosterone) may be due to the suppression of P450arom gene expression and the resultant decrease in the amount of estrogen.     

Effect of androstenedione on growth of untransfected and aromatase-transfected MCF-7 cells in culture

Aromatase is present in human breast tumors and in breast cancer cell lines suggesting the possibility of in-situ estrogen production via the androstenedione to estrone and estradiol pathway. However, proof of the biologic relevance of aromatase in breast cancer tissue requires the demonstration that this enzyme mediates biologic effects on cell proliferation. Accordingly, we studied the effects of the aromatase substrate, androstenedione, on the rate of proliferation of wild-type and aromatase-transfected MCF-7 breast cancer cells. Androstenedione did not increase cell growth in wild-type MCF-7 cells which contained relatively low aromatase activity and produced 4-fold more estrone than estradiol. In contrast, aromatase-transfected cell contained higher amounts of aromatase, produced predominantly estradiol, and responded to androstenedione with enhanced growth. An aromatase inhibitor fadrozole hydrochloride, blocked the proliferative effects of androstenedione providing evidence for the role of aromatase in this process. As further evidence of the requirement for aromatase, cells transfected with the neomycin resistance expression plasmid but lacking the aromatase cDNA did not respond to androstenedione. These studies provide evidence that aromatase may have a biologic role for in-situ synthesis of estrogens of breast cancer tissue.     

Acute and chronic effects of an aromatase inhibitor on territorial aggression in breeding and nonbreeding male song sparrows

Many studies have demonstrated that male aggression is regulated by testosterone. The conversion of testosterone to estradiol by brain aromatase is also known to regulate male aggression in the breeding season. Male song sparrows (Melospiza melodia morphna) are territorial not only in the breeding season, but also in the nonbreeding season, when plasma testosterone and estradiol levels are basal. Castration has no effect on nonbreeding aggression. In contrast, chronic (10 day) aromatase inhibitor (fadrozole) treatment decreases nonbreeding aggression, indicating a role for estrogens. Here, we show that acute (1 day) fadrozole treatment decreases nonbreeding territoriality, suggesting relatively rapid estrogen effects. In spring, fadrozole decreases brain aromatase activity, but acute and chronic fadrozole treatments do not significantly decrease aggression, although trends for some behaviors approach significance. In gonadally intact birds, fadrozole may be less effective at reducing aggression in the spring. This might occur because fadrozole causes a large increase in plasma testosterone in intact breeding males. Alternatively, estradiol may be more important for territoriality in winter than spring. We hypothesize that sex steroids regulate male aggression in spring and winter, but the endocrine mechanisms vary seasonally.     

Plasma estrogen suppression with aromatase inhibitors evaluated by a novel, sensitive assay for estrone sulphate

Aromatase inhibition is a well-defined treatment option for postmenopausal breast cancer. Although several aromatase inhibitors such as aminoglutethimide, formestane, fadrozole have been found to inhibit in vivo aromatization by>85%, previous studies reported plasma estrogen levels to be sustained at approximately 20–50% of their control level during treatment with these drugs. The discrepancy could be due to lack of sensitivity or non-specific crossreactions in the radioimmunoassay (RIA) methods. Mean plasma levels of estrone (E₁) and estradiol (E₂) in postmenopausal women are approximately 80 and 20 pmol/l, respectively; on the contrary, mean plasma levels of the estrogen conjugate estrone sulphate (E₁S) are approximately 4–500 pmol/l. Most RIA methods for plasma E₂ and E₁ measurements have sensitivity limits in the range of 2–3 and 7–10 pmol/l, respectively; accordingly, the suppression of plasma estrogens by more than 80–90% will produce hormone values below the sensitivity limit of the method in many patients. Recently, we developed a new method to determine plasma E₁S. This assay has a sensitivity limit of 2.7 pmol/l. In theory, this method may allow the determination of plasma E₁S levels suppressed to less than 2% of control values in the majority of patients. Using this method, we found different aromatase inhibitors such as formestane, aminoglutethimide, formestane and aminoglutethimide administered in concert or anastrozole to suppress plasma E₁S levels down to 24, 13, 7 and 4%, respectively. The suppression of plasma E₁S evaluated with this method thus approaches the percentage aromatase inhibition measured with tracer studies.     

Comparison between aromatase inhibitors and sequential use

The biochemical efficacy of aromatase inhibitors and inactivators in vivo may be determined by two types of methods; by measuring plasma or tissue estrogen levels, or assessment of the conversion of the androgen substrate (in practice, androstenedione) into estrogens (estrone) by the use of tracer methods. While methods to determine plasma and tissue estrogens are limited through lack of sensitivity required to measure the very low concentrations recorded in postmenopausal women on treatment with these compounds, measurement of in vivo aromatization is an extensive procedure, applicable to a limited number of patients only. While we may correlate the mean level of aromatase inhibition achieved with different compounds to clinical efficacy, data correlating individual estrogen suppression to clinical outcome among patients treated with a specific compound is limited. The now well-characterized phenomenon of lack of cross-resistance between non-steroidal aromatase inhibitors and steroidal aromatase inactivators are likely due to biochemical effects not related to differences in total body aromatase inhibition.     

Aromatase inhibitors and their application in breast cancer treatment*

Estrogens are known to be important in the growth of breast cancers in both pre- and postmenopausal women. The number of breast cancer patients with hormone-dependent disease increases with age, as does the incidence of breast cancer. Although estrogens are no longer made in the ovaries after menopause, peripheral tissues produce sufficient concentrations to stimulate tumor growth. Because aromatase catalyzes the rate-limiting step in the biosynthesis of estrogen, inhibitors of this enzyme have been developed in the last few years as a logical treatment strategy. Two classes of aromatase inhibitors, steroidal and nonsteroidal compounds, are now in use. Among the steroid substrate analogs, formestane and examestane have been shown to be effective in breast cancer patients with advanced disease. Highly potent and selective nonsteroidal inhibitors have recently been found to suppress plasma and urinary estrogens by more than 95% in breast cancer patients. Two of these compounds recently were approved in the United States and have been shown to be more effective than other second-line agents in terms of overall response rates and treatment failure, as well as better tolerated. Although studies of the efficacy of these agents in earlier stage disease are awaited, it is evident that aromatase inhibitors can extend the duration of treatment in breast cancer patients.     

Mechanisms of the actions of aromatase inhibitors 4-hydroxyandrostenedione, fadrozole, and aminoglutethimide on aromatase in JEG-3 cell culture

Selective inhibition of estrogen production with aromatase inhibitors has been found to be an effective strategy for breast cancer treatment. Most studies have focused on inhibitor screening and in vitro kinetic analysis of aromatase inhibition using placental microsomes. In order to determine the effects of different inhibitors on aromatase in the whole cell, we have utilized the human choriocarcinoma cell line, JEG-3 in culture to compare and study three classes of aromatase inhibitors, 4-hydroxyandrostenedione, fadrozole (CGS 16949A), and aminoglutethimide. Fadrozole is the most potent competitive inhibitor and aminoglutethimide is the least potent among the three. However, stimulation of aromatase activity was found to occur when JEG-3 cells were preincubated with aminoglutethimide. In contrast, 4-OHA and fadrozole caused sustained inhibition of aromatase activity in both JEG-3 cells and placental microsomes, which was not reversed even after the removal of the inhibitors. 4-OHA bound irreversibly to the active site of aromatase and caused inactivation of the enzyme which followed pseudo-first order kinetics. However, 4-OHA appears to be metabolized rapidly in JEG-3 cells. Sustained inhibition of aromatase induced by fadrozole occurs by a different mechanism. Although fadrozole bound tightly to aromatase at a site distinct from the steroid binding site, the inhibition of aromatase activity by fadrozole does not involve a reactive process. None of the inhibitors stimulated aromatase mRNA synthesis in JEG-3 cells during 8 h treatment. The stimulation of aromatase activity by AG appeared to be due to stabilization of aromatase protein. According to these results, 4-OHA and fadrozole would be expected to be more beneficial in the treatment of breast cancer patients than AG. The increase in aromatase activity by AG may counteract its therapeutic effect and might be partially responsible for relapse of breast cancer patients from this treatment.     

Aromatase inhibitors: assessment of biochemical efficacy measured by total body aromatase inhibition and tissue estrogen suppression

The implementation of aromatase inhibitors for treatment of early and metastatic breast cancer has been one of the major improvements in endocrine therapy of breast cancer. Measurement of endocrine effects of aromatase inhibition in vivo has been a major tool in the process of evaluating novel compounds. Biochemical efficacy of aromatase inhibitors in vivo may be determined from their effects on “total body aromatization” as well changes in plasma and tissue estrogen levels. Due to high sensitivity, tracer methods allowing calculation of whole body aromatase inhibition are still considered the gold standard. The method developed by our group in collaboration with the Royal Marsden Hospital and the results of this joint program are summarized and discussed. These studies allowed classification of the different aromatase inhibitors and their optimal dosage, selecting the best compounds for clinical evaluation. In vivo total body aromatase assessment is a work-consuming method, allowing such studies to be conducted in a limited number of patients only. In contrast, plasma estrogen measurement is a cruder but simpler method, allowing screening of larger groups of patients. As plasma estrogens arise through passive diffusion of estrogens synthesized in different body compartments, plasma estrogens, as well as total body aromatase assessment, present a rough estimate of total body tissue estrogen production, and changes associated with treatment with aromatase inhibitors reflect the effects on tissue estrogen production in general. However, plasma estrogen levels do not correlate to breast cancer tissue estrogen levels. This is due to the endocrine autonomy of breast cancer tissue with significant local estrogen production in some tumors. Thus, direct measurement of intratumor estrogens is demanded to evaluate the effects of aromatase inhibitors in malignant target tissues. Our group has developed a highly sensitive HPLC-RIA for the simultaneous measurement of estrone, estradiol, and estrone sulfate in malignant breast tissue samples, and we are currently using this method to assess alterations in intratumor estrogen levels during treatment with different aromatase inhibitors.     

Tamoxifen induces masculinization of genetic females and regulates P450 aromatase and Müllerian inhibiting substance mRNA expression in Japanese flounder (Paralichthys olivaceus)

Japanese flounder, Paralichthys olivaceus, provides an excellent model to elucidate the roles of sex steroid hormones in gonadal sex differentiation because the sex is easily altered by sex steroid treatments or water temperature control during the sex differentiation. We have previously shown that high water temperature, an aromatase inhibitor (fadrozole), or 17alpha-methyltestosterone treatment causes the sex-reversal from genetic females to phenotypic males and suppression of mRNA expression of ovary-type P450 aromatase (P450arom), which is a steroidogenic enzyme responsible for the conversion of androgens to estrogens, in Japanese flounder. In the present study, we demonstrate that treatment of the genetic females with anti-estrogen (tamoxifen) leads to their masculinization, suppresses P450arom mRNA expression, and induces mRNA expression of Müllerian inhibiting substance (MIS), a member of the transforming growth factor-beta (TGF-beta) superfamily, while it has no effect on mRNAs expression of estrogen receptor-alpha (ERalpha) and ERbeta. In contrast, 17beta-estradiol counteracted masculinization of the genetic females by tamoxifen or high water temperature treatment, up-regulated P450arom mRNA expression, and down-regulated MIS mRNA expression. These results strongly suggest that estrogen signaling through ERs dramatically influences the gonadal sex differentiation by regulating P450arom and MIS mRNA expression.     

Inhibition of aromatase: insights from recent studies

Aromatase is the rate limiting enzyme that catalyzes the conversion of androgens to estrogens. Blockade of this step allows treatment of diseases that are dependent upon estrogen. Over the past two decades, highly potent and specific aromatase inhibitors have been developed which block total body aromatization by over 99%. An important recent question is whether aromatase inhibitors are superior to the antiestrogens for treatment of hormone-dependent breast cancer. The third generation aromatase inhibitors have been compared to tamoxifen for the treatment of breast cancer in the advanced, adjuvant, and neoadjuvant settings. All of these studies suggest the superiority of aromatase inhibitors over tamoxifen. The mechanism responsible for the superiority of the aromatase inhibitors relates to the estrogen agonistic effects of tamoxifen. During exposure to estrogen deprived conditions and to tamoxifen, breast cancer cells adapt and upregulate the MAP kinase and PI-3 kinase pathways. These growth factor signaling pathways potentiate the estrogen agonistic properties of tamoxifen. Data from a large adjuvant therapy trial (ATAC trial) provide evidence that the aromatase inhibitors may also be superior for breast cancer prevention. The mechanism for superiority in this setting probably relates to the genotoxic effects of estradiol metabolites. The aromatase inhibitors may be also useful for the treatment of endometriosis and for ovulation induction as evidenced by preliminary data. The recent advances in development of the aromatase inhibitors clearly demonstrate the utility of these agents for treatment of breast cancer and potentially for other indications.     

Recent progress in development of aromatase inhibitors

In postmenopausal women with breast cancer, aromatase, which is the enzyme converting androstenedione to estrone and testosterone to estradiol, is the rate-limiting step in estrogen biosynthesis. The currently available aromatase inhibitor, aminogluethimide, effectively blocks estrogen production and produces tumor regressions in patients previously treated with tamoxifen. This drug, however, produces frequent side effects and blocks steroidogenic steps other than the aromatase enzyme. Thus, newer aromatase inhibitors with greater potency and specificity are under intense study. More than 20 such compounds have recently been developed. In several clinical trials, 4-hydroxyandrostenedione, given parenterally, has been highly active and specific for aromatase inhibition in patients with breast cancer. In two large recent studies, one-third of heavily pretreated women experienced objective tumor regression with this therapy. CGS 16949A, a newer agent, is also Phase II clinical trials. This compound is an imidazole derivative with nearly 1000-fold greater potency than aminoglutethimide. An initial Phase I study compared the potency of 0.6–16 mg daily in 12 postmenopausal women and found maximal suppression of urinary and plasma estrogens with 2 mg daily. The degree of inhibition was similar to that induced by aminoglutethimide or by surgical adrenalectomy. No CNS, hematologic or biochemical toxicity was observed. A larger Phase II study in 54 patients confirmed this high degree of potency of CGS since a plateau effect was observed at the 1.8, 2 and 4 mg daily doses. The endocrine effects were not absolutely specific as a blunting of ACTH-stimulated but not basal aldosterone levels were observed. This and other emerging aromatase inhibitors offer promise as pharmacologic methods to inhibit estrogen production specifically and without side effects.     

Estrogen mediation of injury-induced cell birth in neuroproliferative regions of the adult zebra finch brain

Estrogens influence neuronal differentiation, migration, and survival in intact brains. In injured brains, estrogens can also be neuroprotective. In Experiment 1, following a unilateral penetrating injury to the hippocampus (HP), adult female zebra finches were injected once with BrdU to label mitotic cells then sacrificed 2 h, 1 day, or 7 days postinjection. Cell proliferation was dramatically enhanced in the ipsilateral HP, as well as in neuroproliferative areas including the subventricular zone (SVZ) proximal to the injury. This increase was seen at all time points investigated. Ovariectomy (OVX) substantially suppressed proliferation bilaterally especially in the SVZ indicating that gonadal hormones influenced cell proliferation in both the intact and injured hemisphere. To determine if estrogens were directly involved, estrogen was depleted in Experiment 2 through either OVX or administration of the aromatase inhibitor fadrozole (FAD). Birds were implanted with estradiol or blank followed 2 weeks later by a unilateral penetrating lesion to the HP. Injury-induced substantial proliferation, which was again significantly suppressed bilaterally in both OVX and FAD birds. Estrogen replacement reversed this effect in FAD but not OVX birds therefore the suppression following OVX may be due in part to nonestrogenic influences. Suppression of cell birth in FAD birds was indeed due to the removal of endogenous sources of estrogen. Results therefore indicate that estrogens are directly involved in the brain's response to injury and may be acting to provide a rich environment for the production and perhaps protection of new cells.     

Individual differences in estrogen receptor alpha in select brain nuclei are associated with individual differences in aggression

Steroid hormones play an important role in modulating social behavior in many species. Estrogens are thought to act on an interconnected network of hypothalamic and limbic brain areas to affect aggressive behavior, although the specific nuclei unknown remain unspecified. We show that individual variation in estrogen receptor alpha (ERalpha) immunoreactivity in the lateral septum (LS), ventral bed nucleus of the stria terminalis (vBNST), and anterior hypothalamus (AHA) of CD-1 mice is positively correlated with aggressive behavior. When males were treated with fadrozole (an aromatase inhibitor), aggressive behavior was reduced, although castration did not reduce aggression. These results suggest that estrogens modulate aggressive behavior by acting on a circuit that includes the LS, vBNST, and AHA and that the source of estrogens is non-gonadal. Fadrozole also decreased c-fos expression in the lateral septum following aggressive encounters. Although the effects of estrogen on aggression appear to involve regulation of neuronal activity in the LS, additional processes are likely involved. These results suggest that estrogen acts in a specific subset of a complex network of nuclei to affect aggressive behavior.     

Stepwise estrogen suppression manipulating the estrostat

Estrogen suppression is an effective endocrine treatment option in pre- as well as postmenopausal breast cancer patients. The fact that it produces clinical benefits not only in these two groups of patients that differ significantly with respect to plasma estrogen levels but also among patients with very low plasma estrogen levels due to previous hypophysectomy, adrenalectomy or treatment with first/second generation aromatase inhibitors, suggests estrogen deprivation to work independent of pretreatment plasma estrogen levels. Interestingly, in vitro studies have revealed MCF-7 cells to respond to estrogen deprivation by sensitization, causing maximum estradiol stimulation at a concentration 10⁻⁵ to 10⁻⁴ the concentration needed in wild-type cells. While results from recent phase III studies comparing novel aromatase inhibitors and inactivators to conventional therapy have suggested that a more effective hormone ablation may be translated into an improved clinical efficacy, the biochemical rationale for lack of complete cross-resistance between aromatase inhibitors and inactivators or aromatase inhibitors and megestrol acetate remains to be explained. Interestingly, patients becoming resistant to estrogen deprivation may still respond to estrogens administered in pharmacological doses. Future studies are warranted to explore alterations in gene expression and signaling mechanisms in response to different therapies in tumor tissue in vivo.     

Structure-activity relationships and binding model of novel aromatase inhibitors

The use of aromatase inhibitors is an established therapy for oestrogen-dependent breast cancer in postmenopausal women. However, the sole commercially available aromatase inhibitor, aminoglutethimide, is not very selective. We have therefore developed fadrozole hydrochloride and CGS 20 267, which are both currently under clinical evaluation. This report will present an analysis of structure-activity relationships in the azole series of inhibitors and give an account of the further optimization of our development compounds, starting from CGS 20 267 over CGP 45 688 and leading to CGP 47 645, the most potent aromatase inhibitors in vivo reported to date. In addition, on the basis of comparisons of these azole-type inhibitors with the most potent steroidal inhibitors published in the literature, we propose a CAMM-generated model describing the relative binding modes of these two classes of compounds at the active site of the enzyme.     

Hormonal effects of aromatase inhibitors: focus on premenopausal effects and interaction with tamoxifen

Third generation aromatase inhibitors have excellent specificity. Some reports indicate that letrozole may have a minor effect on cortisol synthesis but these were not confirmed: valid comparisons with other aromatase inhibitors requires randomised study.

The putative use of a third generation inhibitor as a single agent in premenopausal women has been investigated using YM511. It was hypothesised that in this situation site-specific suppression of estrogens in breast carcinomas, without systemic effects, may lead to a down-regulation of tumour proliferation. Plasma levels of androstenedione and testosterone were significantly increased by 2 weeks treatment with YM511. Mean plasma estrone levels were suppressed, but some plasma estradiol levels were abnormally high and others abnormally low. These differential effects of YM511 on circulating estrogens supported the concept that peripheral synthesis of estrogens might be suppressed while ovarian production remained high. However, YM511 did not demonstrate anti-proliferative effects in hormone sensitive breast carcinomas.

Consideration of the pharmacology of the estrogen receptor during tamoxifen therapy indicates that tamoxifen effectively saturates the receptor (>99.94% occupancy) in postmenopausal women. The addition of an aromatase inhibitor in this situation would be very unlikely to affect the biological activity of the estrogen receptor. This provides a possible explanation why the clinical efficacy of tamoxifen combined with an aromatase inhibitor appears to be equivalent to that of tamoxifen alone.     

Role of steroid sulfatase in local formation of estrogen in post-menopausal breast cancer patients

More than two-thirds of breast cancers occur in post-menopausal women, and depend on the estrogens for their proliferation and survival. For the treatment of estrogen-dependent breast cancers, two major treatment options are now available. One is selective estrogen receptor modulator (SERM) such as Tamoxifen and another is aromatase inhibitor such as Anastrozole, Letrozole and Exemestane, which reduce local in situ formation of estrogens. Although these therapies are clinically active for advanced and early breast cancers, de novo and/or acquired resistance to SERM and/or aromatase inhibitors are also clinical problem. Recent studies suggest that local formation of estrogens in the breast tumors is more important than circulating estrogen in plasma for the growth and survival of estrogen-dependent breast cancer in post-menopausal women. The rationale for the importance of local formation of estrogens is based on the following evidences. Estradiol (E2) levels in breast tumors are equivalent to those of pre-menopausal patients, although plasma E2 levels are 50-fold lower after menopause. E2 concentrations in breast tumors of post-menopausal women are 10–40 times higher than serum level. Biosynthesis of estrogens in breast tumors tissues occurs via two major different routes, one is aromatase pathway and another is steroid-sulfatase (STS) pathway. Whereas many studies has been reported about aromatase inhibitor and its clinical trial results in breast cancer patients, limited information are available regarding to other estrogen regulating enzymes including STS, its role in breast tumors and STS inhibitors. STS is the enzyme that hydrolyses estrone 3-sulfate (E₁S) and dehydroepiandrosterone-sulfate (DHEA-S) to their active un-sulfoconjugated forms, thereby stimulating the growth and survival of estrogen-dependent breast tumors. It has been well known that E₁S level are much higher than E2 level both in plasma and tumor of post-menopausal patients. Recent reports show that more than 80% of breast tumors are stained with anti-STS antibody and the expression of STS is an independent prognostic factor in breast cancer. Taking these findings into consideration, local formation of estrogens could be partially synthesized from large amount of E₁S by STS, which exist in breast cancer. On the other hand, aromatase localizes in stroma and adipocyte surrounding breast cancer. Furthermore, since estrogen formation from E₁S and DHEA-S (STS pathway) cannot be blocked by aromatase inhibitors, STS is thought to be a new molecular target for the treatment of estrogen-dependent tumor post-SERM and/or aromatase inhibitors. In this symposium, these recent rationale for the importance of STS in post-menopausal breast cancer patients is reviewed as well as STS inhibitor.     

Growth suppression of MCF-7 human breast cancer cells by aromatase inhibitors: A new system for aromatase inhibitor screening

In our previous study we found that MCF-7 cells possess aromatase activity and stimulate estrogen receptor-mediated growth. The pathways through which androgens are converted to estrogens by aromatase and estrogens interact with estrogen receptors contribute significantly to growth stimulation. The administration of aromatase inhibitor results in suppression of growth stimulation by androgens. This system enabled us to assess directly the biological activities of aromatase inhibitors. Aromatase activity was inhibited in a dose-dependent manner by the addition of aminoglutethimide and CGS 16949A, competitive inhibitors, and of 14-hydroxy-4-androstene-3,6,17-trione and 4-hydroxy-androstenedione, mechanism-based inhibitors. After preincubation with mechanism-based inhibitors, aromatase activity was significantly suppressed, whereas after preincubation with competitive inhibitors, it was adversely increased. These effects were concentration- and time-dependent. Preincubation with competitive inhibitors resulted in augmentation of subsequent androgen stimulation of thymidine incorporation, while preincubation with mechanism-based inhibitors resulted in diminished stimulation by subsequent androgen administration. These results suggest that in MCF-7 cells competitive inhibitors adversely induce aromatase and accelerate the subsequent androgen stimulation of DNA synthesis. Suicide inhibitors are more effective than competitive inhibitors. This system will be useful for aromatase inhibitor screening.     

Estrogen provision by reactive glia decreases apoptosis in the zebra finch (Taeniopygia guttata)

Upregulation of aromatase (estrogen synthase) in glia around the site of neural injury may limit neural degeneration. Systemic administration of estrogen limits neural damage, but the specific role of local estrogen provision in this effect is unclear. In male zebra finches, we tested the effect of local aromatase inhibition and estrogen replacement on type of cellular degeneration and the distance of this degeneration from the source of insult. Subjects received injections of the aromatase inhibitor fadrozole into one telencephalic lobe and fadrozole and estradiol into the contralateral lobe. Seventy-two hours later, we used Fluoro-Jade B and TUNEL to label dying and apoptotic cells, respectively. Since each subject was its own control, we were able to assess the influence of local estrogen replacement in relative distinction from circulating steroids and constitutive aromatization. Cellular degeneration around the lesion was measured with Fluoro-Jade B, TUNEL, and indirectly with aromatase expression. Additionally, the glial nature of aromatase-positive cells around the injury was queried by co-localization with vimentin. The estrogen replaced injury had fewer apoptotic cells clustered more closely around the injury compared to the hemisphere injected with fadrozole alone. Since Fluoro-Jade B and TUNEL labeled similar numbers of cells, and the distance of these cells from the injection was identical, we suggest that estrogen replacement functions primarily to restrict apoptosis in the current paradigm. Lastly, aromatase-positive cells around injuries co-localize vimentin, establishing their glial nature. Thus, glial estrogen provision at sites of neural insult may be critical in limiting the cellular degeneration caused by injury via an inhibition of apoptosis.