Specificity of low dose fadrozole hydrochloride (CGS 16949A) as an aromatase inhibitor

Atractylenolide-I covalently binds to CYP11B2, selectively inhibits aldosterone synthesis, and improves hyperaldosteronism

Hyperaldosteronism is a common disease that is closely related to endocrine hypertension and other cardiovascular diseases. Cytochrome P450 11B2 (CYP11B2), an important enzyme in aldosterone (ALD) synthesis, is a promising target for the treatment of hyperaldosteronism. However, selective inhibitors targeting CYP11B2 are still lacking due to the high similarity with CYP11B1. In this study, atractylenolide-I (AT-I) was found to significantly reduce the production of ALD but had no effect on cortisol synthesis, which is catalyzed by CYP11B1. Chemical biology studies revealed that due to the presence of Ala320, AT-I is selectively bound to the catalytic pocket of CYP11B2, and the C8/C9 double bond of AT-I can be epoxidized, which then undergoes nucleophilic addition with the sulfhydryl group of Cys450 in CYP11B2. The covalent binding of AT-I disrupts the interaction between heme and CYP11B2 and inactivates CYP11B2, leading to the suppression of ALD synthesis; AT-I shows a significant therapeutic effect for improving hyperaldosteronism.

Inhibitors of Aldosterone Synthase

The mineralocorticoid aldosterone is an important regulator of blood pressure and electrolyte balance. However, excess aldosterone can be deleterious as a driver of inflammation, vascular remodeling and tissue fibrosis associated with cardiometabolic diseases. Mineralocorticoid receptor antagonists (MRA) and renin-angiotensin-aldosterone system (RAAS) antagonists are current clinical therapies used to antagonize deleterious effects of aldosterone in patients. MRAs compete with aldosterone for binding at its cognate receptor thereby limiting its effect while RAS antagonists reduce aldosterone levels indirectly by blocking the stimulatory effect of angiotensin. Both MRAs and RAS antagonists can result in incomplete inhibition of the harmful effects of excess aldosterone. Aldosterone synthase (AS) inhibitors (ASI) attenuate the production of aldosterone directly and have been proposed as an alternative to MRAs and RAS blockers. Cortisol synthase (CS) is an enzyme closely related to AS and responsible for generating the important glucocorticoid cortisol, required for maintaining critical metabolic and immune responses. The importance of selectivity against CS is shown by early examples of ASIs that were only modestly selective and as such, attenuated cortisol responses when evaluated in patients. Recently, next-generation, highly selective ASIs have been described and are presently being evaluated in the clinic as an alternative to angiotensin and MR antagonists for cardiometabolic disease. Herein we provide a brief review of the challenges associated with discovery of selective ASIs and the transition from the early compounds that paved the way toward the next-generation of highly selective ASIs currently under development.

Selectivity of BI 689648, a Novel, Highly Selective Aldosterone Synthase Inhibitor: Comparison with FAD286 and LCI699 in Nonhuman Primates

The mineralocorticoid aldosterone is an important regulator of blood pressure, volume, and electrolyte balance. However, excess aldosterone can be deleterious as a driver of vascular remodeling and tissue fibrosis associated with cardiometabolic diseases. Aldosterone synthase (AS) inhibitors (ASI) attenuate the production of aldosterone directly and have been proposed as an alternative to mineralocorticoid receptor antagonists for blocking the pathologic effects of excess aldosterone. Discovery of selective ASIs has been challenging because of the high sequence identity (93%) AS shares with cortisol synthase (CS), and the low identity of rodent AS compared with human (63%). Using cynomolgus (cyno) monkey-based models, we identified BI 689648 [6-(5-methoxymethyl-pyridin-3-yl)-3,4-dihydro-2H-[1,8]naphthyridine-1-carboxylic acid amide], a novel, highly selective ASI that exhibits an in vitro IC50 of 2 nM against AS and 300 nm against CS (150-fold selectivity) compared with the recently described ASIs FAD286 [4-(5,6,7,8-tetrahydroimidazo[1,5-a]pyridin-5-yl)benzonitrile] (3 nM AS; 90 nM CS; 40-fold) and LCI699 (4-[(5R)-6,7-dihydro-5H-pyrrolo[1,2-c]imidazol-5-yl]-3-fluorobenzonitrile) (10 nM AS; 80 nM CS; 8-fold). After oral administration in cyno monkeys, BI 689648 (5 mg/kg) exhibits a peak plasma concentration of ∼500 nM. For in vivo profiling we used an adrenocorticotropin-challenge model in which BI 689648 was >20-fold more selective compared with FAD286 and LCI699. Because both FAD286 and LCI699 failed to provide adequate selectivity for CS when tested in patients, the desire for more selective molecules to test the ASI hypothesis remains high. Therefore, highly selective aldosterone synthase inhibitors such as BI 689648 represent an important step forward toward developing ASIs with greater potential for clinical success in cardiometabolic diseases.

Fetal safety profile of aromatase inhibitors: Animal data

Aromatase inhibitors (AIs) are a class of drugs that act by blocking the production of estrogens from androgens. The current review concentrates on the prenatal developmental toxicity of AIs in experimental models. Available data indicate that AIs may affect pregnancy at human therapeutic or lower doses. The window of vulnerability to AIs is not limited to organogenesis, but also includes the preimplantation stage and fetal periods. Decreased embryo/fetal survival was the prominent treatment-related effect. Morphological anomalies noted in fetuses exposed to AIs included skeletal anomalies, abnormal head morphology, increased ano-genital distance in female fetuses, and minor urinary tract system anomalies. Placental enlargement was consistently reported in rats and non-human primates after maternal treatment with several AIs. In conclusion, data from basic scientific research suggest that low intensity exposure to AIs applied during a wide gestational window can profoundly affect prenatal development.

Recent Progress in the Discovery of Next Generation Inhibitors of Aromatase from the Structure-Function Perspective

Human aromatase catalyzes the synthesis of estrogen from androgen with high substrate specificity. For the past 40 years, aromatase has been a target of intense inhibitor discovery research for the prevention and treatment of estrogen-dependent breast cancer. The so-called third generation aromatase inhibitors (AIs) letrozole, anastrozole, and the steroidal exemestane were approved in the U.S. in the late 1990s for estrogen-dependent postmenopausal breast cancer. Efforts to develop better AIs with higher selectivity and lower side effects were handicapped by the lack of an experimental structure of this unique P450. The year 2009 marked the publication of the crystal structure of aromatase purified from human placenta, revealing an androgen-specific active site. The structure has reinvigorated research activities on this fascinating enzyme and served as the catalyst for next generation AI discovery research. Here, we present an account of recent developments in the AI field from the perspective of the enzyme's structure-function relationships.

Letrozole

IMPORTANCE OF THE FIELD

Aromatase is an enzyme which converts adrenal androgens to estrogens in postmenopausal women. Given the importance of estrogens in breast cancer growth, aromatase inhibitors are used to treat breast cancer in different settings. This review focuses on letrozole, a third generation aromatase inhibitor, encompassing pharmacodynamic and pharmacokinetic aspects as well as its clinical efficacy and safety.

AREAS COVERED IN THIS REVIEW

A literature search and review of the studies published on letrozole were carried out using the MEDLINE database up to November 2009.

WHAT THE READER WILL GAIN

The paper provides the reader with information about pharmacodynamic and pharmacokinetic aspects of letrozole, its preclinical and clinical efficacy and its safety.

TAKE HOME MESSAGE

Letrozole is a well-tolerated and effective drug in metastatic breast cancer in postmenopausal women. Two clinical trials conducted in early breast cancer have confirmed its role in the adjuvant setting in postmenopausal women. More recently, data have confirmed its efficacy as neoadjuvant treatment in breast cancer. Future developments include the combination of letrozole with new biologic agents and tailoring of treatment with gene expression profiling studies.

The discovery and mechanism of action of letrozole

Because estrogen contributes to the promotion and progression of breast cancer, a greater understanding of the role of estrogen in breast cancer has led to therapeutic strategies targeting estrogen synthesis, the estrogen receptor, and intracellular signaling pathways. The enzyme aromatase catalyses the final step in estrogen biosynthesis and was identified as an attractive target for selective inhibition. Modern third-generation aromatase inhibitors (AIs) effectively block the production of estrogen without exerting effects on other steroidogenic pathways. The discovery of letrozole (Femara^®) achieved the goal of discovering a highly potent and totally selective AI. Letrozole has greater potency than other AIs, including anastrozole, exemestane, formestane, and aminoglutethimide. Moreover, letrozole produces near complete inhibition of aromatase in peripheral tissues and is associated with greater suppression of estrogen than is achieved with other AIs. The potent anti-tumor effects of letrozole were demonstrated in several animal models. Studies with MCF-7Ca xenografts successfully predicted that letrozole would be clinically superior to the previous gold standard tamoxifen and also indicated that it may be more effective than other AIs. An extensive program of randomized clinical trials has demonstrated the clinical benefits of letrozole across the spectrum of hormone-responsive breast cancer in postmenopausal women.

Mechanistic Computational Model of Ovarian Steroidogenesis to Predict Biochemical Responses to Endocrine Active Compounds

Sex steroids, which have an important role in a wide range of physiological and pathological processes, are synthesized primarily in the gonads and adrenal glands through a series of enzyme-mediated reactions. The activity of steroidogenic enzymes can be altered by a variety of endocrine active compounds (EAC), some of which are therapeutics and others that are environmental contaminants. A steady-state computational model of the intraovarian metabolic network was developed to predict the synthesis and secretion of testosterone (T) and estradiol (E2), and their responses to EAC. Model predictions were compared to data from an in vitro steroidogenesis assay with ovary explants from a small fish model, the fathead minnow. Model parameters were estimated using an iterative optimization algorithm. Model-predicted concentrations of T and E2 closely correspond to the time-course data from baseline (control) experiments, and dose-response data from experiments with the EAC, fadrozole (FAD). A sensitivity analysis of the model parameters identified specific transport and metabolic processes that most influence the concentrations of T and E2, which included uptake of cholesterol into the ovary, secretion of androstenedione (AD) from the ovary, and conversions of AD to T, and AD to estrone (E1). The sensitivity analysis also indicated the E1 pathway as the preferred pathway for E2 synthesis, as compared to the T pathway. Our study demonstrates the feasibility of using the steroidogenesis model to predict T and E2 concentrations, in vitro, while reducing model complexity with a steady-state assumption. This capability could be useful for pharmaceutical development and environmental health assessments with EAC.

Investigation of aldosterone-synthase inhibition in rats

BACKGROUND

In-vivo investigation of aldosterone-synthase inhibitors requires experimental models to characterize the biological effects of these compounds.

METHODS

Seven successive experiments were performed in groups of 2-month-old male spontaneously hypertensive rats. Urinary free aldosterone was the main end-point measured during two contrasted diets: low sodium-high potassium (LS), inducing high urinary aldosterone (839 pmol/24 h, 95% confidence interval 654-1077), and high sodium-normal potassium (HS), inducing low urinary aldosterone (38.1 pmol/24 h; 95% confidence interval, 32.4-44.9).

RESULTS

FAD 286 A (10 and 30 mg/kg) decreased urinary free aldosterone by 53 and 87% on the LS diet, and 50 and 75% on the HS. Plasma renin concentration increased three-fold after a 4-week treatment of 30 mg/kg FAD 286 A on the LS diet and did not change on the HS. The combination of FAD 286 A (30 mg/kg) and spironolactone (30 mg/kg) on the LS diet induced a biological picture of severe hypoaldosteronism and was not tolerated, whereas the HS diet prevented these abnormalities. The combination of FAD 286 A (30 mg/kg) and furosemide (30 mg/kg) on the HS diet corrected the diuretic-induced hypokalemia (4.1 +/- 0.2 versus 3.7 +/- 2.2 mEq/l, P < 0.033).

CONCLUSION

This experimental model will be useful to screen future aldosterone-synthase inhibitors and study their biological effects in various experimental conditions.

Synthesis and evaluation of imidazolylmethylenetetrahydronaphthalenes and imidazolylmethyleneindanes: potent inhibitors of aldosterone synthase

Elevated plasma aldosterone levels play a detrimental role in certain forms of congestive heart failure and myocardial fibrosis. We proposed aldosterone synthase (CYP11B2) as a novel target for the treatment of these diseases. In this study, the synthesis and biological evaluation of substituted E- and Z-imidazolylmethylenetetrahydronaphthalenes and E- and Z-imidazolylmethyleneindanes (compounds 1a,b-9a,b) is described. The compounds were prepared by a Wittig-like reaction. They were tested for activity using bovine CYP11B and human CYP11B2 expressed in fission yeast and V79 MZh cells. Selectivity was determined toward human CYP11B1, CYP19, and CYP17. Especially in the case of CYP11B1 (steroid 11beta-hydroxylase), selectivity is a crucial issue, since sequence homology between this enzyme and the target enzyme is very high (93%). On the basis of the X-ray structure of human CYP2C9, a protein model of CYP11B2 was developed and docking experiments with the title compounds were performed. The biological results revealed highly potent inhibitors of CYP11B2 (IC(50) = 4-93 nM). The Z-isomers usually were more active than the corresponding E-isomers. Different inhibitory profiles could be observed: rather selective inhibitors of CYP11B1, dual inhibitors of both enzymes, and rather selective inhibitors of CYP11B2. The chloro derivative 8b was found to be a highly potent CYP11B2 inhibitor (IC(50) = 4 nM) showing a 5-fold selectivity for CYP11B1 (IC(50) = 20 nM). This compound could be an interesting lead for further optimization as a therapeutic agent. It also could be used as well as the CYP11B1 selective compounds as a pharmacological tool.

Adolescent Caucasian mothers have reduced adult hip bone density

OBJECTIVE

To determine the long-term effect of full term teen pregnancy on peak hip bone mineral density.

DESIGN

Longitudinal observational study.

SETTING

Academic clinical research center.

PATIENT(S)

Sixteen non-Hispanic white females: 4 cases and 12 matched controls who are part of The Penn State Young Women's Health Study and have been studied from ages 12 to 21.

MAIN OUTCOME MEASURES

Four of the subjects had uncomplicated full-term pregnancies between ages 16.5 and 19.5 years.

INTERVENTION(S)

The cases and controls were matched for body mass index at age 12 years, total body bone mineral content at age 12 years, age of menarche, and sports-exercise score during ages 12-18 years. They were then compared with respect to bone measures, cardiovascular disease risk factors, and endocrine profiles at ages 19-21 years.

RESULT(S)

The four teen mothers had significantly lower adult hip bone mineral density than did the controls (0.89 g/cm(2) vs. 0.99 g/cm(2); P=.03). The reproductive hormone patterns of the cases were not statistically significantly different from those of the controls, yet the cases showed a postmenopausal blood lipid pattern.

CONCLUSION(S)

The persistent reduction in hip bone mineral density of the cases is consistent with significantly increased risk of future hip fracture.

Aromatase inhibitors: past, present and future

For the cellular physiology of sex steroid sensitive cells, the androgen/estrogen ratio may be more important than only one hormone action per se, in both sexes. This ratio is controlled in vertebrates by aromatase; its gene expression can be inhibited in different ways, and this is crucial for the treatment of estrogen-dependent diseases such as breast cancer, or gynecomastia in males for instance. To reach this goal, new steroidal and non-steroidal inhibitors are continuously being developed, and some of them are used as first or second line agents. Aromatase inhibition is also an essential tool for studying the role of estrogens in the adult, or during development. Aromatase inhibitors have shown in particular that estrogens are essential also in males for skeletal maturation and bone mineralization, development of masculine dendritic morphology in male brain linked to mating behaviour, and testicular function. Testosterone is often the prohormone converted in situ in active estrogens, at these levels. Several strategies can be used for aromatase inhibition. The first ones employed were blind screening or deductions from in vivo observations, which led for instance to the discovery of the role of aminoglutethimide in aromatase inhibition. Subsequently, in the years 1975-1990, the molecular modeling of compounds to mimic the substrate shape of the enzyme constituted the major idea. Hundreds of chemicals were synthesized by numerous authors, ranging from the well-known and very efficient 4-OHA to complicated imidazole or indane derivatives tested by sophisticated comparative molecular field analyses. Reticulum-bound active aromatase has not as yet been X-ray analyzed. Thus, aromatase inhibitors were also used more recently to probe and understand the active site conformation of the enzyme and its modelization was obtained from comparisons with bacterial-related cytochromes. We developed a mammalian model considerably closer to human aromatase in order to study the active site shape with new potent aromatase non-steroidal inhibitors. This model is equine aromatase. This enzyme was biochemically characterized, purified, and cloned by our group. It allowed testing, by site-directed mutagenesis, predictive hypotheses in human aromatase which contributed to designing of new inhibitors. The understanding of the functioning of an essential member of the cytochrome P450 family, which is necessary for cellular detoxification, was also facilitated. Inhibition of aromatase activity has also been carried out with antibodies directed to the catalytic site and at the gene level by knock-out or by control of factor-specific promoters. This may result in different mRNA synthesized by alternative splicing. We have also obtained specific inhibition of aromatase activity in human cells with antisense stable phosphorothioate oligodeoxynucleotides directed against aromatase mRNA tertiary structures. Besides known steroidal and non-steroidal inhibitors, the antiaromatase effects of compounds found in our daily environment such as dietary flavonoids or xenobiotic pollutants have also been described. Finally, we underline that all these aromatase inhibitors, or methods of aromatase inhibition, can modulate the estrogenic balance essential not only for female, but also for male physiology, including gonadal function.

Effect of the potent aromatase inhibitor fadrozole hydrochloride (CGS 16949A) in postmenopausal women with breast carcinoma

BACKGROUND

Fadrozole hydrochloride (CGS 16949A) is a highly potent, nonsteroidal aromatase inhibitor that significantly lowers estrogen levels in postmenopausal women and can be effective therapy for patients with advanced hormone-dependent breast carcinoma. Circulating estradiol, estrone, and estrone sulfate are reduced to undetectable levels within weeks of the initiation of therapy. Before this study, it was not known whether this decrease in serum estrogen levels results in altered parameters associated with cardiovascular disease. The authors examined the levels of several critical blood parameters that are important to cardiovascular risk for heart disease and thromboembolic disorders in patients treated with fadrozole.

METHODS

Cholesterol, triglyceride, low density lipoprotein (LDL), high density lipoprotein (HDL), very low density lipoprotein (VLDL), antithrombin III, protein C, protein S, and fibrinogen were serially measured in 21 postmenopausal women with advanced breast carcinoma treated with various doses of fadrozole (1.8 mg/day, n=3; 2.0 mg/day, n=13; 4.0 mg/day, n=5) over 3-24 months (mean, 15.8 months). A repeated measure analysis of variance was applied to each cardiovascular variable to assess changes in the response over time. Analyses were performed separately for each dose group and were also pooled over the dose groups.

RESULTS

There was no statistically significant change over time in lipid parameters, namely, total cholesterol (P=0.57), triglyceride (P=0.27), LDL (P=0.99), HDL (P=0.30), and VLDL (P=0.43), over the 24 months of therapy. There were also no significant changes in coagulation factors, namely, antithrombin III (P=0.41), protein C (P=0.49), or protein S (P=0.31), over the 24 months. However, an increase in fibrinogen that occurred over time did reach statistical significance (P=0.011).

CONCLUSIONS

With the exception of acute phase reactant fibrinogen, this study did not identify an increase in parameters associated with cardiovascular disease in women treated with fadrozole, a potent aromatase inhibitor.

Endocrine therapy in metastatic breast cancer

Endocrine therapy represents a mainstay of effective, minimally toxic, palliative treatment for metastatic breast cancer. Research focusing on the mechanism of action of endocrine agents will provide new insights leading to new hormonal approaches in breast cancer treatment. Development of new agents, especially the 'pure' antiestrogens, is of great interest. Combining endocrine therapy with biologic agents, especially antiproliferative compounds, may lead to more effective treatment in the adjuvant as well as the advanced setting. Tables 4 and 5 summarize response rates to the different groups of endocrine agents used in metastatic breast cancer and doses of commonly used agents, respectively. At present, tamoxifen is the drug of choice as first-line endocrine therapy for metastatic breast cancer with no or minimal symptoms in premenopausal or postmenopausal women. Second-line therapy usually consists of megace. Aromatase inhibitors may be used as second- or third-line therapy in postmenopausal women. In premenopausal women, LHRH analogues are a reasonable choice. The other hormonal agents may be beneficial as salvage therapy. More effective endocrine approaches are under development.

Hormonal effects of MPV-2213ad, a new selective aromatase inhibitor, in healthy male subjects. A phase I study

AIMS

A novel non-steroidal competitive inhibitor of the aromatase enzyme, MPV-2213ad, was entered into an open dose-escalation study. The objective of this study was to investigate the tolerability and efficiency of this new compound with assessment of the hormonal effects after study drug administration.

METHODS

MPV-2213ad was given to 39 healthy male volunteers. Single increasing oral doses of 0.003, 0.03, 0.3, 3, 9, 30 and 100 mg were given to three subjects at each dose level, after which ten subjects received the 300 mg dose and eight subjects the highest 600 mg dose of MPV-2213ad.

RESULTS

Serum oestradiol levels were suppressed by 58-65% when MPV-2213ad was given at doses between 0.3 and 30 mg. A reduction in serum oestradiol levels by 83% from baseline was achieved with the 300 mg dose. No additional decrease was seen with the highest dose. The suppression lasted longer with higher doses of MPV-2213ad. After the 300 and 600 mg doses serum oestradiol returned to baseline within 4 days. Marked increases in serum concentrations of testosterone, androstenedione, 17-OH-progesterone, LH and FSH were also observed at doses between 100 and 600 mg of MPV-2213ad. The drug was well-tolerated and the adverse events were mild or moderate including hot flushes, mild vertigo, nausea, acne and gastrointestinal discomfort.

CONCLUSIONS

MPV-2213ad has a potent, dose-dependent inhibitory effect on serum oestradiol. It was selective for the aromatase enzyme with no signs of adreno-cortical suppression or haematological or biochemical toxicity.

Fadrozole hydrochloride in postmenopausal patients with metastatic breast carcinoma

BACKGROUND

Fadrozole hydrochloride (CGS-16949A) belongs to the class of aromatase inhibitors that lowers circulating estrogen levels by inhibiting the conversion of androgens to estrogens, thereby causing tumor regression in patients with breast carcinoma.

METHODS

This was a prospective, randomized, Phase II study of fadrozole hydrochloride in postmenopausal patients with metastatic breast carcinoma. The three treatment groups received, respectively, fadrozole hydrochloride 0.6 mg three times daily, 1 mg twice daily, and 2 mg twice daily orally.

RESULTS

Fifty-six patients were entered on protocol and 54 were eligible (2 patients were perimenopausal). Eight patients had received no prior therapy, 15 patients had received prior hormonal therapy, 5 patients had received prior chemotherapy, and 28 patients had received both. After 12 weeks of treatment, 2 complete and 3 partial responses were observed. Forty patients continued treatment beyond 12 weeks, and 3 additional responses were achieved. Thus, 8 of 56 patients responded (14% overall response rate). Responses did not appear to be dose-related. The median duration of response was 36 months (range, 8-45 months). Subjective toxicity was mild to moderate and appeared more frequent on the 2 mg twice daily dosing schedule. No objective toxicity in laboratory parameters was observed. No patient had severe or life-threatening toxicity. Fadrozole hydrochloride plasma concentrations (obtained every 2 weeks for 12 weeks) appeared to be dose-dependent and noncumulative.

CONCLUSIONS

This study confirms modest activity of fadrozole hydrochloride in a heterogeneous group of patients with breast carcinoma treated at three different dose levels.

Fadrozole HCL (CGS-16949A) versus megestrol acetate treatment of postmenopausal patients with metastatic breast carcinoma: results of two randomized double blind controlled multiinstitutional trials

BACKGROUND

Breast cancer patients with prior response to endocrine therapy achieve subsequent benefit from additional endocrine therapies. The efficacy and safety of an aromatase inhibitor, fadrozole HCL, were compared with megestrol acetate in post menopausal patients who had disease progression after receiving antiestrogen therapy either for metastatic disease or as adjuvant therapy.

METHODS

In 2 multiinstitutional prospective trials, 683 postmenopausal patients were randomized to receive either fadrozole HCL, 1 mg twice daily, or megestrol acetate, 40 mg 4 times daily, in a double blind fashion after progression on first-line hormonal therapy. Objective response rates, time to progression, survival and safety of the two regimens were compared.

RESULTS

Results of intent-to-treat analyses are presented in this study. No significant differences were detected between the two treatment groups in time to progression, objective response rates, duration of response, and survival in either trial. There were no clinically meaningful differences between the treatment groups in the incidence and severity of adverse experiences, except that weight gain, fluid retention, and dyspnea were observed in more patients in the megestrol acetate group compared with those receiving fadrozole HCL, whereas nausea and vomiting were observed in more patients in the fadrozole HCL group compared with those receiving megestrol acetate.

CONCLUSIONS

Fadrozole HCL was as efficacious as megestrol acetate in postmenopausal patients with metastatic breast carcinoma after one hormonal therapy. Adverse experiences were mild with both therapies, but megestrol acetate was associated wiht a higher frequency of weight gain, fluid retention and dyspnea, whereas fadrozole HCL was associated with a higher frequency of nausea and vomiting.

Arimidex (ZD1033): a selective, potent inhibitor of aromatase in postmenopausal female volunteers

Two multiple-dose studies were conducted in healthy post-menopausal female volunteers to investigate the pharmacokinetics and effects on endocrinology of Arimidex (ZD1033). Volunteers in the first trial were dosed with 3 mg of ZD1033 daily over 10 days to assess the effects on endocrinology of ZD1033 and establish a pharmacokinetic profile. In the second trial volunteers received 14 daily doses of either 0.5 or 1.0 mg of ZD1033 to assess the pharmacokinetics of ZD1033 and the effects of low doses of ZD1033 on serum oestradiol concentrations. Following multiple dosing a significant reduction in the concentration of serum oestradiol of approximately 80% of baseline was obtained with all three doses; no recovery in oestradiol was apparent for up to 144 h after the last dose. There was no overall difference in the level of oestradiol suppression between the 0.5 or 1.0 mg doses of ZD1033. However, comparison of the number of volunteers with oestradiol concentrations below the limits of detection of the assay, 24 h after the last dose of ZD1033, suggested that 1.0 mg was the minimal dose required for maximal suppression of oestradiol. No significant effect was recorded on serum concentrations of gonadotrophins over the dosing period. Serum concentrations of a range of adrenal steroids were not affected by administration of ZD1033; furthermore, steroid response to standard adrenocorticotrophic hormone (ACTH) challenge was unimpaired by ZD1033. Together these data demonstrate the potency, tolerability and selectivity of ZD1033. The pharmacokinetic profile of ZD1033 supports its use as a once-daily treatment given orally.

Aromatase inhibitor development for treatment of breast cancer

Inhibition of estrogen production provides effective therapy for patients with hormone-dependent breast cancer. The source of estrogens in premenopausal women is predominantly the ovary, but after the menopause, estradiol is synthesized in peripheral tissues through the aromatization of androgens to estrogens. Uptake from plasma is the primary mechanism for maintenance of estradiol concentrations in breast cancer tissue in premenopausal women, whereas several steps may be operant in postmenopausal women. These include enzymatic synthesis of estradiol via sulfatase, aromatase, and 17 beta-hydroxysteroid dehydrogenase in the tumor itself. Aromatization of androgens secreted by the adrenal to estrogens in peripheral tissues and transport to the tumor via circulation in the plasma provides another means of maintaining breast tumor estradiol levels in postmenopausal women. These various sources contribute to the high tissue estrogen levels measured in breast tumor tissue. To effectively suppress tissue concentrations of estrogens and circulating estradiol in postmenopausal patients, various aromatase inhibitors have been developed recently. These include steroidal inhibitors such as 4-hydroxy-androstenedione as well as non-steroidal compounds with imidazole and triazole structures. The most potent of these, CGS 20267, is reported to suppress levels of active estrogens (i.e., estrone, estrone sulfatase, and estradiol) by more than 95%. This compound can suppress both serum and 24-hr urine estrogens to a greater extent than produced by the second generation inhibitor, CGS 16949A. CGS 20267 is highly specific since it does not affect cortisol and aldosterone serum levels during ACTH stimulation tests nor sodium and potassium balance in 24-hr urine samples.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of Fadrozole (CGS 16949A) and Letrozole (CGS 20267) on the inhibition of aromatase activity in breast cancer patients

Fadrozole Hydrochloride (CGS 16949A) and Letrozole (CGS 20267), are two of the newest non-steroidal, orally active aromatase inhibitors currently being evaluated as second line treatment of patients with hormone dependent forms of metastatic breast cancer. In a phase I clinical efficacy study, we examined the ability of these two imidazole derivatives to suppress the synthesis of estrogen in a cohort of postmenopausal patients with metastatic breast cancer. Both medications at relatively low doses were potent and rapid inhibitors of aromatase activity as evidenced by their ability to suppress the level of blood and urine estradiol and estrone as well as blood estrone sulfate in these patients. Letrozole appeared to be the more potent of the two, with over 95% suppression of both plasma and urinary estrogens observed within 2 weeks of therapy. Letrozole appeared to be more selective than Fadrozole in inhibiting aromatase activity in that no compromise in cortisol and aldosterone output was evident with Letrozole therapy at all of the doses tested, a compromise clearly seen with Fadrozole. The inhibition of aromatase activity by these imidazole derivatives as second line therapy for patients with hormone dependent breast cancer appears to be a favorable alternative form of hormone ablative therapy and holds considerable promise for the treatment of this malignancy.

Endocrine changes with the aromatase inhibitor fadrozole hydrochloride in breast cancer

Fadrozole hydrochloride is a potent aromatase inhibitor with proven clinical effectiveness. However, its optimal dose and its effects on serum aldosterone levels/electrolyte balance have been disputed. To resolve these issues, a double-blind randomised endocrine study of three doses of fadrozole hydrochloride [0.5 mg twice daily (bd); 1.0 mg bd; 2.0 mg bd] was conducted in 80 (68 evaluable) postmenopausal patients with advanced breast cancer over a period of 3 months. There were substantial falls in the serum levels of oestradiol, oestrone and oestrone sulphate. For oestrone only, there was a significant effect of dose (on-treatment means: 0.5 mg, 38.0 pmol/l; 1.0 mg, 25.0 pmol/l; 2.0 mg, 23.9 pmol/l). All oestrogens showed a similar pattern in relation to time, with the 3-month mean being higher than those at 1 and 2 months, and this was significant for oestradiol (P = 0.012). There was an indication that complete suppression of oestradiol and oestrone was not maintained throughout the 12-h dosing period, but the data and its interpretation are complicated by a minor diurnal rhythm in these parameters. There were significant increases in 17-hydroxyprogesterone and androstenedione which may be due to a block of 11 beta-hydroxylase. There was a statistically non-significant fall in aldosterone levels (P = 0.06) during treatment (median pretreatment, 446 pmol/l; median decrease, 125 pmol/l). However, the concurrent significant fall in the plasma sodium: potassium ratio indicated that changes in aldosterone secretion did occur. None of these effects on adrenal pathways was of a degree which is likely to have clinically relevant consequences. It is concluded that fadrozole hydrochloride achieves near maximal suppression of oestrogens at 1 mg bd, and that its effects on aldosterone synthesis are unlikely to be of clinical significance.

Sex hormone levels in postmenopausal women with advanced metastatic breast cancer treated with CGS 169 49A

30 postmenopausal patients with metastatic breast cancer were treated with three different doses of fadrozole hydrochloride (CGS 169 49A), a non-steroidal competitive aromatase inhibitor. The effect of 0.5, 1 and 2 mg given twice daily upon the levels of oestrogens, their androgen precursors and upon the concentration of sex hormone binding globulin (SHBG) was investigated after 1 and 3 months and then every 3 months until progression of disease. A significant reduction in the serum concentration of oestrone (P < 0.0001) was obtained at all doses. Also, the serum concentration of oestrone sulphate was significantly reduced (P < 0.0001). However, after 1 month, the concentration was significantly different from pretreatment levels (P < 0.01) only at the 4 mg daily dose. A decline was also observed in the concentration of SHBG (P < 0.05), with a concomitant elevation of the percentage non-SHBG-bound oestradiol. The androgens, testosterone and dehydroepiandrosterone sulphate, were unaltered during treatment, while androstendione was significantly elevated at the 2 mg daily dose (P < 0.001).

Aromatase, its inhibitors and their use in breast cancer treatment

Aromatase, a cytochrome P450 enzyme, catalyses the rate-limiting step in the biosynthesis of estrogens. Many processes in male and female development and reproduction and especially in the growth of hormone-dependent cancers, are dependent on estrogens. Therefore, controlling estrogen production by inhibition of aromatase is a logical treatment strategy. Two classes of aromatase inhibitors, steroidal and non-steroidal compounds, are now coming into use. Among the steroid substrate analogs, 4-hydroxyandrostenedione has been shown to be effective in breast cancer patients with advanced disease and was recently approved for treatment in the United Kingdom. Several highly potent and selective non-steroidal inhibitors are now in clinical trials. The variety of compounds that act as aromatase inhibitors should provide breast cancer patients with a number of new treatment options.

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 cells 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 in breast cancer tissue.

The effects of long term fadrozole hydrochloride treatment in patients with advanced stage breast cancer

Fadrozole hydrochloride at a dose of 2 mg b.i.d. has been shown to be an effective aromatase inhibitor in advanced stage breast cancer patients as determined by its ability to significantly suppress endogenous estrogen biosynthesis over a 12-week period. Continued suppression of circulating estrogen levels over a prolonged period has not yet been examined in published reports. In this study, we report the extended use of fadrozole hydrochloride at a maintenance dose of 2 mg b.i.d. in a cohort of 11 patients extending to 973 days of therapy. Results show that the degree of suppression of plasma and urinary estrogens was maintained in all patients throughout the extended period of drug use. Continued estradiol suppression of over 50% or greater from baseline was observed, as was continued suppression of estrone to over 80% from baseline. Cortisol determinations after 9 months of treatment showed no suppression from baseline. The aldosterone values and responses to cortrosyn stimulation continued to be suppressed as first noted following the initial 3 months of the core clinical trial. Objective tumor response noted in the core clinical trial did not change until disease progression. These findings suggest that fadrozole hydrochloride maintains its ability to suppress the aromatase enzyme during long term use. No observable escape from suppression of plasma and urinary estrogens occurred during prolonged treatment.

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.

Plasma and 24 h-urinary catecholamine concentrations in normal and patient populations

Using a single HPLC-ECD methodology, plasma catecholamine data were compiled from 545 patients and 144 healthy subjects, and 24 h urinary free catecholamine data from 106 patients. From these data, normal reference ranges were derived for the clinical investigation of suspected phaeochromocytomas, specifically to address the question as to when a result is normal and when further investigation may be required. We have shown that noradrenaline and adrenaline concentrations in plasma and urine are not normally distributed, and basal plasma noradrenaline is significantly lower in normal volunteers than in hospital patients. We have also demonstrated that a reference range which does not take account of these factors will give a significant number of false-positive results. Age and sex did not appear to be significant variables for either plasma or urinary catecholamines. In the investigation of phaeochromocytoma, 95% confidence limits may be used as a warning to repeat sampling and 99% confidence limits as rendering the diagnosis extremely probable. In patients with phaeochromocytomas, urinary catecholamines had a 99.5% specificity and 100% sensitivity in the diagnosis, and thus provide for a rapid and efficient diagnostic screen.

Clinical use of aromatase inhibitors in the treatment of breast cancers

Estrogens are the major hormones supporting the growth of human breast cancer. Aromatization of androgen precursors in peripheral tissues, including the breast cancer itself, is the major source of estrogens in postmenopausal women. Therefore, inhibition of the aromatase enzyme offers an effective means of inducing regression of hormone-responsive breast cancer. Aminoglutethimide, the first and most widely tested aromatase inhibitor, suppresses estrogen production to the level of adrenalectomy and exerts an anti-tumor action comparable to other standard endocrine therapies such as tamoxifen. However, conventional doses of the drug (1000 mg daily) cause moderate toxicity and inhibit other critical cytochrome P-450 steroidogenic enzymes, thus requiring concomitant glucocorticoid administration. New non-steroidal, competitive aromatase inhibitors with greater selectivity and less toxicity are being developed. The second generation compound, fadrazole (CGS 16949), lowers estrogen production to a degree similar to aminoglutethimide (50-80%), but at much lower doses (approximately 2 mg daily) and is associated with minimal toxicity. Although not totally specific, this drug is sufficiently selective not to require simultaneous cortisol replacement. CGS 16949 has been shown to possess significant anti-tumor action in pilot studies and is currently being tested in Phase III trials. Recently, a third generation inhibitor, CGS 20267, has been found to have virtually complete selectivity for the aromatase enzyme. Furthermore, this drug suppresses estrogen biosynthesis to a greater extent (approximately 90%) than previously observed with other aromatase inhibitors. Such enhanced activity may lead to a superior anti-tumor action, and may extend the use of this drug to a variety of other conditions where optimal suppression of estrogen biosynthesis is desired.

Aromatase inhibitors: clinical pharmacology and therapeutic implications in breast cancer

Aminoglutethimide was the first aromatase inhibitor to be used in breast cancer therapy but, since it interacts with the synthetic glucocorticoids, hydrocortisone must also be given as a replacement. The most important side-effects of aminoglutethimide are at the level of the central nervous system. Other aromatase inhibitors with greater potency and selectivity are being developed. Pyridoglutethimide, a compound resulting from modifications to the structure of aminoglutethimide, seems to be devoid of sedative properties according to preliminary tests on the central nervous system. 4-Hydroxyandrostenedione is significantly more potent and better tolerated than aminoglutethimide. Fadrozole (CGS 16,949 A) is 200-400 times more potent than aminoglutethimide and is now in phase II of its clinical development. CGS 20,267 has no effect on adrenal steroidogenesis and is currently in phase I of its clinical development. Availability of newer aromatase inhibitors could make a worthwhile contribution to endocrine therapy in breast cancer.