Effects of the antiestrogens tamoxifen, toremifene, and ICI 182,780 on endometrial cancer growth.

BACKGROUND: Tamoxifen has been shown to promote the growth of human endometrial tumors implanted in athymic mice, and it has been associated with a twofold to threefold increase in endometrial cancer. Toremifene, a chlorinated derivative of tamoxifen, and ICI 182,780, a pure antiestrogen, are two new antiestrogens being developed for the treatment of breast cancer. The effects of these drugs on endometrial cancer are currently unknown. Our objective was to evaluate the effects of toremifene and ICI 182,780 on the growth of human endometrial cancer in athymic mice. METHODS: Athymic, ovariectomized mice were implanted with human endometrial tumors and treated with estrogen, tamoxifen, or the new antiestrogens. RESULTS: The effects of tamoxifen and toremifene on the growth of either tamoxifen-stimulated or tamoxifen-naive endometrial tumors in athymic mice were not substantially different. ICI 182,780 inhibited the growth of tamoxifen-stimulated endometrial cancer, in both the presence and the absence of estrogen. CONCLUSIONS: Toremifene and tamoxifen produce identical effects in our endometrial cancer models. Therefore, it is possible that toremifene, like tamoxifen, may be associated with an increased incidence of endometrial cancer. In contrast, ICI 182,780 inhibited tamoxifen-stimulated endometrial cancer, both in the presence and in the absence of estrogen, suggesting that this drug may be safe with regard to the endometrium, even if it is used following tamoxifen, and that it may not result in an increased incidence of endometrial cancer. Indeed, it is even possible that ICI 182,780 may prove useful as an adjuvant agent in early stage endometrial cancer.

Characterization of a point mutation in the hormone binding domain of the estrogen receptor from an breast tumor.

It is clear that growth of the MCF-7 breast cancer cell line is stimulated by estrogen and when estrogen is removed, growth slows. We have observed a tumor derived from MCF-7 cells that grows in athymic mice in the absence of estrogen stimulation. We hypothesized that a mutation in the estrogen receptor (ER) could be responsible for this constitutive growth. Using single stranded conformational polymorphism (SSCP) and DNA sequencing analysis, we have identified an ER containing a point mutation at position 415 (gly to val) within the hormone binding domain. The functional activity of this mutant was assessed in vitro and in vivo. Using transient transfection into an ER negative breast cancer cell with an ERE luciferase reporter gene, we found that both the wild-type and mutant receptors have similar efficacy. Additionally, the estrogenic responses were blocked by antiestrogens in a concentration related manner. We also found that tumors with the mutant receptor show similar growth response in athymic mice as wild-type: stimulation with estradiol and inhibition with antiestrogens. We conclude that the point mutation at position 415 (gly to val) is not responsible for constitutive growth.

Laboratory models of breast and endometrial cancer to develop strategies for antiestrogen therapy.

Laboratory models for breast and endometrial cancer have had an enormous impact on the clinical development of antiestrogens. Results from the DMBA-induced rat mammary cancer model has provided the scientific principles required to evaluate long-term adjuvant tamoxifen therapy. Similarly, the athymic mouse model allowed the identification of clinically relevant mechanisms of drug resistance to tamoxifen and a model system to test new agents for cross resistance. Additionally, the endometrial cancer model has allowed the identification of agents that cause a slight increase in the risk of endometrial cancer long before the data would have be available from clinical studies. However, it should be stressed that this model is really only relevant for agents to be tested as preventives in normal women. The risks of developing endometrial cancer during tamoxifen therapy are slight compared with the survival benefit in controlling breast cancer.Finally the discovery of the carcinogenic potential of tamoxifen in the rat liver, 20 years after it was first introduced into clinical practice, raises an interesting issue. If the studies of liver carcinogenicity had been completed and published in the early 1970's there would be no tamoxifen and tens of thousands of women with breast cancer would have died prematurely. In fact there would have been no incentive to develop new agents as alternatives to tamoxifen or following tamoxifen failure. Most importantly, we would not have any knowledge about the target-site or selective actions of antiestrogens. All the current interest in selective estrogen receptor modulators (SERMs) is based on the huge clinical data base obtained by studying tamoxifen. The success of tamoxifen as an agent that preserves bone density, lowers cholesterol and prevents contralateral breast cancer(43) has become a classic example of a multimechanistic drug. These concepts have acted as a catalyst to develop new agents for new applications. The laboratory studies of raloxifene(44-46)) provided the scientific rationale for the use of raloxifene as a preventive for osteoporosis(47)) but with the goal of preventing breast cancer in post-menopausal women(48,49)) (Fig 5). It is clear that the close collaboration between laboratory and clinical research has revolutionized the prospects for women's health care in the 21st century.

Mutations of the estrogen receptor in endometrial carcinoma: evidence of an association with high tumor grade.

The majority (60-70%) of endometrial cancers express estrogen receptor. Typically, estrogen-receptor-positive endometrial tumors are associated with a more favorable outcome. Despite this, there is often a discrepancy between estrogen receptor expression and clinical outcome of the disease. Although little is known about the exact role of the estrogen receptor in endometrial malignancies, in breast cancer, where such information is abundant, a number of mutations of the estrogen receptor have been identified. To investigate whether mutations of the estrogen receptor gene occur in endometrial cancers we performed single-stranded conformational polymorphism analysis (SSCP) on 35 human endometrial tumors. We detected four point mutations in three different patients. Interestingly, all the mutations were detected in patients who had aggressive endometrial tumors (grade 3). Although we found the incidence of mutations of the estrogen receptor to be low (8.5%) and thus unlikely to be associated with the majority of endometrial cancers, further investigation is needed to elucidate the role of aberrant estrogen receptor expression in the progression of endometrial malignancies.

An analysis of tamoxifen-stimulated human carcinomas for mutations in the AF-2 region of the estrogen receptor.

The estrogen receptor (ER) contains two transcriptional activation domains: AF-1 and AF-2. AF-2 is dependent on a highly species-conserved region of the ER. It has been shown that site-directed point mutations of conserved hydrophobic amino acids within this region reduce estrogen-dependent transcriptional activation. In addition, when these mutated ERs are transfected into HeLa cells, both tamoxifen and ICI 164,384 become strong agonists. The implication is that mutations in this region could account for the tamoxifen-stimulated tumors seen clinically. We performed single stranded conformational polymorphism (SSCP) analysis spanning the entire ER along with DNA sequencing of the AF-2 region of the ER isolated from two different tamoxifen-stimulated breast cancers, MCF-7/TAM and MCF-7/MT2, and a tamoxifen-stimulated endometrial cancer, EnCa 101. In addition, a tamoxifen-stimulated endometrial carcinoma cell line, the Ishikawa cell line, was also studied. There were no mutations found by SSCP analysis and sequencing of all four AF-2 regions also revealed no mutations. Mutations within the AF-2 region of the human ER do not appear to account for the growth of human breast and endometrial carcinomas that are used as reproducible laboratory models of tamoxifen-stimulated growth observed clinically.