Aromatase inhibitors: Role in postmenopausal breast cancer

Postmenopausal women are at high risk of developing breast cancer due to estrogen production in peripheral tissues of the body other than ovaries. Aromatase is present in breast tissue, leading to local estrogen production which can be inhibited by a variety of steroidal and nonsteroidal aromatase inhibitors. There are many aromatase inhibitors available in clinical practice like exemestane, formestane, anastrozole, letrozole, fadrozole, vorozole, and so forth, but the major challenge in anti-breast cancer therapy is the toxicity associated with aromatase inhibitors, especially the steroidal class of drugs. It is, therefore, urgently required to develop novel anticancer drugs having better safety and efficacy for the treatment of breast cancer. This study highlights the aromatase inhibitors reported in the current literature as well as the recent advances in the management of breast cancer.     

Inhibitory effect of an isopropanolic extract of black cohosh on the invasiveness of MDA-mB 231 human breast cancer cells

BACKGROUND: The isopropanolic extract of black cohosh (iCR)b has recently been reported to exert antiproliferative and apoptosis-inducing effects on estrogen receptor-positive MCF-7, as well as estrogen receptor-negative MDA-MB 231 human breast cancer cells. To broaden observations, the anti-invasive effects of iCR and its two major fractions triterpene glycosides (TTG) and cinnamic acid esters (CAE) were tested in highly invasive MDA-MB 231 cells. MATERIALS AND METHODS: The effect of drugs upon the invasive potential of MDA-MB231 cells was studied in BD Biocoat Matrigel invasion chambers over a period of 24 h. RESULTS: The suppression of invasion reached 51.8% at 77.4 microg/ml of iCR, an extract concentration where 89% of MDA-MB231 cells were viable. TTG and CAE reduced cell invasion by 34% and 25.5%, respectively, at a dose of 5 microg/ml. The motility of cells was only moderately reduced. CONCLUSION: In this study iCR was found to suppress tumor cell invasion without affecting cell viability. This result together with the antiproliferative and apoptosis-inducing effect of iCR suggest its use as a secure agent in postmenopausal hormone replacement therapy with additional chemopreventive activity.     

Comprehensive pharmacology and clinical efficacy of aromatase inhibitors.

The goal of hormone therapy is to deprive breast tumours of estrogens, since estrogens have been implicated in the development or progression of tumours. This can be accomplished by the use of antiestrogens that block estrogen action or by inhibiting aromatase, the enzyme that catalyses the final and rate-limiting step in estrogen biosynthesis. A number of steroidal and nonsteroidal compounds have been developed as aromatase inhibitors. This review highlights the valuable role that a few of these aromatase inhibitors have played, and continue to play, in the treatment of breast cancer. Following background information regarding the biochemistry of aromatase, the rationale for its inhibition, and an outline of the test systems for evaluating and characterising aromatase inhibitors, the discussion focuses on the new generation of aromatase inhibitors that are in clinical trials or clinically available. Specifically, it discusses the pharmacology and clinical efficacy of formestane, exemestane, rogletimide, fadrozole, vorozole, anastrozole and letrozole. The role of these agents as the optimal second-line agents (after tamoxifen) for the treatment of advanced breast cancer has been established; their prospects in other clinical settings and as potential breast cancer chemopreventives are warranted but are yet to be fully determined.     

Aromatase inhibitors: a new paradigm in breast cancer treatment

Microsomal cytochrome P450 (CYP 450) enzyme aromatase belongs to CYP 19 super family. It is involved in the conversion of androgens to estrogens. In postmenopausal women the main sites of aromatisation are skin, adipose tissue and breast. Aromatase localized in breast tumor produces sufficient estrogen for its proliferation. Hence it is an important target for the treatment of hormone dependent breast cancer in postmenopausal women. There are mainly two types of aromatase inhibitors, one is steroidal another is nonsteroidal type. The first and second generation aromatase inhibitors encounter the undesirable drug- drug interactions besides being not very specific and plagued with pharmacokinetic problems. Third generation aromatase inhibitors developed recently are more potent and specific with a greater capacity to annihilate circulating estrogen levels. These agents have satisfactory pharmacokinetic profiles and are devoid of major drug-drug interactions. Third generation aromatase inhibitors became drugs of choice for both first and second line treatment of advanced breast cancer. Aromatase inhibitors can also be used for neoadjuvant therapy of breast cancer in which they have achieved better therapeutic efficacy than tamoxifen. Early results of ATAC (Armidex Tamoxifen Alone or Combination) trial suggest that anastrozole is superior to tamoxifen in adjuvant setting for disease free survival, particularly in receptor positive patients, and in reducing the incidence of contralateral breast cancer. Therapeutic potential of aromatase inhibitors stretches beyond the postmenopausal breast cancer treatment as they also play a role in the treatment of estrogen dependent benign and malignant conditions such as gynaecomastia, prostate cancer, fibroadenomata and the induction of ovulation. By virtue of their ability to reduce estrogen levels they pose problems like demineralization of bone, hot flushes and anti-implantation effects.     

Structure-activity relationships of new A,D-ring modified steroids as aromatase inhibitors: design, synthesis, and biological activity evaluation

Inhibition of aromatase is an efficient approach for the prevention and treatment of breast cancer. New A,D-ring modified steroid analogues of formestane and testolactone were designed and synthesized and their biochemical activity was investigated in vitro in an attempt to find new aromatase inhibitors and to gain insight into their structure-activity relationships (SAR). All compounds tested were less active than formestane. However, the 3-deoxy steroidal olefin 3a and its epoxide derivative 4a proved to be strong competitive aromatase inhibitors (K(i) = 50 and 38 nM and IC50 = 225 and 145 nM, respectively). According to our findings, the C-3 carbonyl group is not essential for anti-aromatase activity, but 5alpha-stereochemistry and some planarity in the steroidal framework is required. Furthermore, modification of the steroidal cyclopentanone D-ring, by construction of a delta-lactone six-membered ring, decreases the inhibitory potency. From the results obtained, it may be concluded that the binding pocket of the active site of aromatase requires planarity in the region of the steroid A,B-rings and the D-ring structure is critical for the binding.     

Genistein induces breast cancer-associated aromatase and stimulates estrogen-dependent tumor cell growth in in vitro breast cancer model

In breast cancer, the interaction between estrogen-producing breast adipose fibroblasts (BAFs) and estrogen-dependent epithelial tumor cells is pivotal. Local estrogen production is catalyzed by aromatase, which is differentially regulated in disease-free and tumorigenic breast tissue. The use of aromatase inhibitors to block local estrogen production has proven effective in treatment of estrogen-dependent breast cancer. However, a major problem during breast cancer treatment is the sudden onset of menopause and many women seek for alternative medicines, such as the soy isoflavone genistein. In this study, we show that genistein can induce estrogen-dependent MCF-7 tumor cell growth and increase breast cancer-associated aromatase expression and activity in vitro. We have previously developed an in vitro breast cancer model where the positive feedback loop between primary BAFs and estrogen-dependent MCF-7 tumor cells is operational, thereby representing a more natural in vitro model for breast cancer. In this model, genistein could negate the growth inhibitory action of the aromatase inhibitor fadrozole at physiologically relevant concentrations. These data suggest that soy-based supplements might affect the efficacy of breast cancer treatment with aromatase inhibitors. Considering the high number of breast cancer patients using soy supplements to treat menopausal symptoms, the increasing risk for adverse interactions with breast cancer treatment is of major concern and should be considered with care.     

Evaluation of cell death caused by triterpene glycosides and phenolic substances from Cimicifuga racemosa extract in human MCF-7 breast cancer cells

We previously reported that the antiproliferative effect of an isopropanolic-aqueous extract of black cohosh (iCR) on MCF-7 estrogen-responsive breast cancer cell line was due to the induction of apoptosis. Here we address the question to what extent apoptosis induction can be ascribed to one of the two major fractions of iCR, the triterpene glycosides (TTG) or the cinnamic acid esters (CAE). Furthermore, as black cohosh is routinely administered orally, we studied whether its pharmacological effects would withstand simulated liver metabolism. The antiproliferative activity of TTG and CAE as well as of rat liver microsomal S9 fraction-pretreated iCR on MCF-7 cells were investigated by WST-1 assay. The features of cell death induced were tested for apoptosis by flow cytometry (light scatter characteristics, Annexin V binding). Irrespective of S9-pretreatment, 72 h iCR treatment induced a dose-dependent down regulation of cell proliferation with the same IC50 of 55.3 microg/ml dry residue which corresponds to 19.3 microg/ml TTG and 2.7 microg/ml CAE. The degree of apoptotic MCF-7 cells was also comparable. Both, isolated TTG and CAE fractions inhibited cell growth, the IC50 being 59.3 microg/ml and 26.1 microg/ml, respectively. Interestingly, whereas IC50 and apoptosis induction correspond well for the whole extract, TTG and CAE fractions induced apoptosis at concentrations (25 and 5 microg/ml) well below those required for significant growth inhibition. Observation of this study firstly showed that the cell death induced by iCR withstood a metabolic activation system. In addition, TTG and CAE compounds significantly contributed to its apoptotic effect, CAE being the more potent inhibitor of proliferation and apoptosis inducer.     

Pharmacological and clinical profile of exemestane (Aromasin), a novel irreversible aromatase inhibitor

Aromatase is the rate-limiting enzyme playing a role at the final step of estrogen biosynthesis, which is attracting attention as the target enzyme of hormone therapy of postmenopausal breast cancer. Exemestane (Aromasin) is a novel steroidal irreversible aromatase inhibitor that was approved in Japan as a therapeutic drug for postmenopausal breast cancer. Exemestane selectively inhibits aromatase activity in vitro, in a time-dependent and irreversible manner, suggesting the mechanism of action that exemestane covalently binds to aromatase as a pseudo-substrate and inactivates the enzyme. In vivo studies show the inhibitory effect of exemestane on the ovarian aromatase activity and plasma estradiol level of PMSG-primed rats. In studies using DMBA-induced rat mammary tumor models, exemestane shows antitumor activity in both conventional (premenopausal) and ovariectomized, testosterone-treated postmenopausal models. Despite its steroidal structure, exemestane does not have hormonal or anti-hormonal activity, except for a slight androgenic activity. In the early and late phase II clinical trials conducted in Japan on postmenopausal breast cancer patients who received 25 mg/day of exemestane, the response rates were 31.4% and 24.2%, respectively. Blood estrogen levels were also markedly reduced. These results confirmed the clinical relevance of non-clinical study results, as well as the possibility of extrapolation to foreign trial data.     

Update on the use of aromatase inhibitors in breast cancer

Estrogens are biosynthesised from androgens by the CYP450 enzyme complex called aromatase. Aromatase is expressed in the ovary, placenta, brain, bone, adipose tissue and breast tissue. In breast cancer, intratumoural aromatase is the source for local estrogen production in the tissue. Inhibition of aromatase is an important approach for reducing growth stimulatory effects of estrogens in estrogen-dependent breast cancer. The potent and selective third-generation aromatase inhibitors anastrozole, letrozole and exemestane were introduced to the market as endocrine therapy in postmenopausal patients failing anti-estrogen therapy alone, or multiple hormonal therapies. Anastrozole and letrozole are both non-steroidal aromatase inhibitors that compete with the substrate for binding to the enzyme active site. Exemestane is a mechanism-based steroidal inhibitor that mimics the substrate, is converted by the enzyme to a reactive intermediate, and results in inactivation of aromatase. These third-generation aromatase inhibitors are currently approved as first-line therapy for the treatment of postmenopausal women with metastatic estrogen-dependent breast cancer. The use of an aromatase inhibitor as initial therapy, or after treatment with tamoxifen, is now recommended as adjuvant hormonal therapy for postmenopausal women with hormone-dependent breast cancer. Several clinical studies of aromatase inhibitors focus on the use of these agents in the adjuvant setting, for the treatment of early breast cancer. Recently published results show improved responses with these agents compared with tamoxifen.     

治疗乳腺癌的抗雌激素药物研究进展

抗雌激素疗法是雌激素受体依赖型乳腺癌内分泌疗法的重要手段之一.抗雌激素药物主要包括选择性雌激素受体调节剂（SERMs）和纯抗雌激素剂.SERMs有三苯乙烯类、苯并噻吩类、萘类、苯并吡喃类、吲哚类等类型,纯抗雌激素剂有甾体类和非甾体类.芳构化酶抑制剂通过抵抗雌激素生成显示类似抗雌激素疗效.抗雌激素药物主要通过消除雌激素与雌激素受体的相互作用促使癌细胞凋亡.现综述抗雌激素药物和芳构化酶抑制剂的作用机制、作用特点及最新研究进展.     

Drug safety evaluation of exemestane

INTRODUCTION: Hormone-dependent breast cancer can be successfully treated by either blocking the estrogen receptor, as with tamoxifen, or reducing the production of estrogens, as with aromatase inhibitors. Exemestane is a third-generation aromatase inhibitor used in the treatment of estrogen-receptor-positive breast cancer in postmenopausal women. In various trials, exemestane has shown superiority over tamoxifen in both efficacy and safety. Furthermore, aromatase inhibitors are gaining territory in the metastatic, as well as the early, setting for treating patients with breast cancer. AREAS COVERED: The authors describe the mechanism of action and pharmacokinetic/pharmacodynamic characteristics of exemestane and discuss its efficacy and safety within the framework of currently approved and potential new indications. The reader can expect a full update on the characteristics of exemestane, including its efficacy and safety profile compared with tamoxifen and other third-generation aromatase inhibitors. EXPERT OPINION: Exemestane is a safe drug due to its steroidal structure, which blocks aromatase at a different site to nonsteroidal AIs (eg., anastrozole and letrozole). Noncross-resistance with nonsteroidal aromatase inhibitors makes it an attractive alternative for all clinical indications of aromatase inhibitors in patients with breast cancer.     

Risks and benefits of aromatase inhibitors in postmenopausal breast cancer.

Aromatase inhibitors were first reported in the early 1970s and have been used to treat breast cancer since that time. Until recently, essentially the only agent available in this class was aminoglutethimide, a nonspecific inhibitor with multiple adverse effects and drug interactions. Selective and potent aromatase inhibitors are now available (formestane, exemestane, fadrozole, anastrozole and letrozole), and we review the risks and benefits of these agents in order to assist clinicians in making treatment decisions. Formestane is an injectable steroidal aromatase inhibitor with significant activity against metastatic breast cancer. It has been shown to have similar efficacy and superior tolerability compared with megestrol, and is similar to tamoxifen in the metastatic setting. Exemestane is an oral steroidal aromatase inhibitor. It has been shown to be effective third-line therapy after tamoxifen and megestrol in postmenopausal patients with metastatic breast cancer. All the nonsteroidal (imidazole/triazole) aromatase inhibitors are orally available. Fadrozole has similar activity to megestrol and tamoxifen in the setting of metastasis, but has been shown in phase II trials to inhibit cortisol and aldosterone production. Anastrozole and letrozole have similar toxicity profiles. Compared with megestrol, anastrozole improves overall survival and has superior tolerability. Letrozole is superior to megestrol and aminoglutethimide in terms of overall survival and time to progression, and is also better tolerated. Although there is a strong rationale for using these agents in the treatment of breast cancer, the information presently available is insufficient to recommend any one agent over another. Direct comparative studies are lacking, and comparing agents across studies is limited by many biases and may not be valid. Formestane is only available as an injection and exemestane is not commercially available in many countries, making these agents more difficult to recommend over the other 3 agents. Fadrozole is less potent and less selective in inhibiting aromatase than letrozole. The efficacies of fadrozole, megestrol and tamoxifen appear to be similar; however, comparative data show no advantage of fadrozole over letrozole. Anastrozole and letrozole are generally considered to be similar agents. The clinical future of the selective aromatase inhibitors is promising, and these agents may change the way postmenopausal breast cancer is treated at all stages of the disease.     

Exemestane in advanced breast cancer

Exemestane is an orally active steroidal aromatase inhibitor that has demonstrated efficacy in the treatment of postmenopausal patients with advanced breast cancer. This compound exhibits a good tolerability and safety profile, which may result from its highly selective mechanism of action. Exemestane binds irreversibly to the aromatase enzyme causing inactivation of the enzyme. This irreversible loss of enzyme may contribute to the sustained inhibition of estrogen synthesis noted following exemestane administration. Exemestane is a potent inhibitor of aromatization reducing estrogen synthesis in vivo by greater than 97%. The recommended dose of exemestane is 25 mg once daily. Although dosages up to 600 mg/day have been tested, the maximum tolerated dose of exemestane has not been reached in clinical study. The most frequently reported drug-related adverse events are hot flushes, nausea and fatigue, which are consistent with the estrogen-suppressive effects of the drug. Discontinuation due to adverse events is rare. Exemestane is a safe and well-tolerated alternative for the treatment of postmenopausal patients with advanced breast cancer.     

Tamoxifen resistant and refractory breast cancer: the value of aromatase inhibitors

Tamoxifen has dominated endocrine treatment of breast cancer for over two decades. It is useful in metastatic breast cancer, adjuvant therapy, preoperative treatment, ductal carcinoma-in-situ and chemoprevention. However, breast cancer may be refractory to tamoxifen or develop resistance to it with ongoing treatment. This resistance involves several mechanisms including receptor mutation causing 'estrogen hypersensitivity' and an increasing agonist effect of tamoxifen. Megestrol (megestrol acetate), in North America, and aminoglutethimide, in Europe, have been the traditional second line therapies after tamoxifen in advanced breast cancer. Aromatase (estrogen synthetase) inhibitors are a logical alternative to tamoxifen to antagonise the effects of estrogen on breast cancer. The third-generation non-steroidal aromatase inhibitors anastrozole, letrozole and vorozole, and the steroidal inhibitor exemestane, have been studied after tamoxifen versus either megestrol or aminoglutethimide. They showed enhanced efficacy and significantly superior toxicity profiles. Compliance with the inhibitors was also significantly better than with the traditional treatments. Aromatase inhibitors have most recently been shown to be superior to tamoxifen as initial therapy and are being extensively tested in the adjuvant setting after, or instead of, tamoxifen. Pilot studies of chemoprevention are also being undertaken. The aromatase inhibitors are an important new addition to the armamentarium of breast cancer therapy.     

Synthesis and aromatase inhibitory activity of novel pyridine-containing isoflavones

Aromatase, a cytochrome P450 hemoprotein that is responsible for estrogen biosynthesis by conversion of androgens into estrogens, has been an attractive target in the treatment of hormone-dependent breast cancer. As a result, a number of synthetic steroidal or nonsteroidal aromatase inhibitors have been successfully developed. In addition, there are several classes of natural products that exert potent activities in aromatase inhibition, with the flavonoids being most prominent. Previous studies have exploited flavone and flavanone scaffolds for the development of new aromatase inhibitors. In this paper, we describe the design, synthesis, and biological evaluation of a novel series of 2-(4'-pyridylmethyl)thioisoflavones as the first example of synthetic isoflavone-based aromatase inhibitors.     

Drug safety evaluation of exemestane

Introduction: Hormone-dependent breast cancer can be successfully treated by either blocking the estrogen receptor, as with tamoxifen, or reducing the production of estrogens, as with aromatase inhibitors. Exemestane is a third-generation aromatase inhibitor used in the treatment of estrogen-receptor-positive breast cancer in postmenopausal women. In various trials, exemestane has shown superiority over tamoxifen in both efficacy and safety. Furthermore, aromatase inhibitors are gaining territory in the metastatic, as well as the early, setting for treating patients with breast cancer.

Areas covered: The authors describe the mechanism of action and pharmacokinetic/pharmacodynamic characteristics of exemestane and discuss its efficacy and safety within the framework of currently approved and potential new indications. The reader can expect a full update on the characteristics of exemestane, including its efficacy and safety profile compared with tamoxifen and other third-generation aromatase inhibitors.

Expert opinion: Exemestane is a safe drug due to its steroidal structure, which blocks aromatase at a different site to nonsteroidal AIs (eg., anastrozole and letrozole). Noncross-resistance with nonsteroidal aromatase inhibitors makes it an attractive alternative for all clinical indications of aromatase inhibitors in patients with breast cancer.     

乳腺癌患者术后长期内分泌治疗的不良反应及治疗策略

内分泌治疗是乳腺癌患者术后治疗的重要手段，目前临床应用的主要药物有选择性雌激素受体调节剂他莫昔芬和芳香化酶抑制剂阿那曲唑、来曲唑及依西美坦。乳腺癌术后辅助内分泌治疗通常需要5年，部分患者可长达10年。他莫昔芬治疗引起的不良反应主要包括妇科和心血管系统不良反应。处理措施为定期检测子宫内膜及血压、血脂等指标，对症处理。芳香化酶抑制剂治疗引起的不良反应主要包括：（1）骨不良反应。处理措施为根据情况予以维生素D和钙剂治疗，必要时给予双膦酸盐类药物。（2）关节肌肉症状。病情较轻者可补充维生素D和钙剂，并进行适当体育锻炼；疼痛明显者可服用非甾体类抗炎药，也可以考虑停药3-4周。（3）心血管系统不良反应。处理措施为对症处理。     

Acute effects of tamoxifen and third-generation aromatase inhibitors on menopausal symptoms of breast cancer patients

Endocrine treatments of breast cancer patients antagonize estrogen and may lead to consequences of estrogen deprivation including menopausal symptoms. We analyzed the changes in frequency and severity of menopausal symptoms in patients receiving tamoxifen or aromatase inhibitors and identified factors influencing these symptoms. One hundred and eighty-one consecutive postmenopausal breast cancer patients scheduled to start endocrine treatment were included in this prospective study. A menopause symptom questionnaire covering vasomotor, atrophic, psychological, cognitive and somatic symptoms was filled in at baseline, and after 1 and 3 months of therapy. Both first-line tamoxifen and aromatase inhibitors induced an increase in the occurrence and severity of hot flashes (p<0.0001 and p=0.014, respectively). Musculoskeletal pain and dyspareunia significantly increased under first-line non-steroidal aromatase inhibitors (p=0.0039 and p=0.001, respectively), while patients under tamoxifen had significant decrease in sexual interest (p< or =0.0001). Younger age was associated with more hot flashes and vaginal dryness at baseline, and after 1 and 3 months of therapy (all p<0.02). We conclude that there are significant differences between the early effects of tamoxifen and aromatase inhibitors on menopausal symptoms of breast cancer patients. Our results underscore the need for safe and effective non-hormonal interventions to alleviate vasomotor and musculoskeletal symptoms which were the most prevalent and severe symptoms.     

芳香化酶的结构、催化机制及其抑制剂研究进展

芳香化酶是体内负责雌激素生物转化的限速酶。通过抑制芳香化酶活性调节雌激素水平成为治疗乳腺癌的另一途径。本文首先简要介绍了芳香化酶的结构和催化机制, 随后综述了甾体类和非甾体类芳香化酶抑制剂的研究进展, 并着重介绍了近年来发现的具有抑制芳香化酶活性的天然产物类抑制剂, 包括黄酮类、氧杂蒽酮类、香豆素类及倍半萜烯类化合物, 并分析了这些化合物的构效关系。