Background: Estrogen is known to have important effects on both reproductive and non-reproductive tissues. Moreover, there is increasing interest in developing compounds that may have selective effects on bone versus reproductive tissues. Methods: Since mouse models are often used in these studies, we administrated increasing doses of estradiol (E 2 ) (0 to 500 mg/kg/day) by slow release pellets to ovariectomized 6-month-old C57BL/6 mice and assessed skeletal and uterine responses following 2 months of treatment. Results: The mice lost bone at multiple sites following ovariectomy (OVX); however, while the lowest E 2 dose of 5 mg/kg/day completely prevented loss of cancellous bone (at the lumbar spine and tibial metaphysis), it had no stimulatory effects on the uterus. Higher doses of E 2 resulted in further increases in bone mineral density, with eventual stimulation of the uterus at a dose of 40 mg/kg/day. By contrast, when 3-month-old C57BL/6 mice were administered the same doses of E 2 and studied after 1 month, the 5 mg/kg/day dose resulted in uterine hypertropy, but was not able to prevent loss of cancellous bone. Conclusions: Thus these results (i) provide data on the dose -response for the effects of E 2 on mouse bone and (ii) indicate that the relative effects of E 2 on bone versus the uterus are highly dependent on the particular experimental conditions used. This issue needs to be considered in evaluating agents with potential 'selective' effects on bone versus reproductive tissues.
Background: A major issue surrounding the use of therapeutic drugs for the treatment of breast cancer is the eventual development of resistance. Endoxifen, the most potent tamoxifen metabolite, is being developed as a novel endocrine therapy for the treatment of endocrine responsive breast cancer patients. While numerous studies have investigated the process of tamoxifen resistance, no such data exist regarding the mechanism by which cells develop resistance to endoxifen. Here, we describe the development and characterization of a novel endoxifen resistant MCF7 breast cancer cell line and the identification of a specific treatment to effectively target these resistant cells. Methods: MCF7 cells were chronically exposed to concentrations of endoxifen previously demonstrated to be associated with the greatest reductions in estrogen stimulated proliferation and transcription (1000 nM). Changes in the physiological and molecular properties of these cells were monitored during the course of resistance using a wide range of techniques. Results: Following 15 months of endoxifen exposure, an epithelial to mesenchymal transition (EMT) was induced in MCF7 cells, characterized by loss of E-cadherin expression, up-regulation of fibronectin and vimentin expression and increased responsiveness to TGFβ. Resistant cells exhibit a 7-fold increase in their proliferation rates relative to parental cells and display basal like properties (triple negative) due to silencing of ERα , progesterone receptor and CD24 expression. Resistant cells were confirmed to be estrogen insensitive through the use of cell proliferation and gene expression studies. Wound healing and cell migration assays revealed that resistant cells are highly aggressive with a significant level of metastatic potential. Microarray analysis revealed over 7500 genes to be differentially expressed in the resistant cell line relative to parental cells using a 2-fold cutoff, of which only 52 genes (0.7%) were determined to be up-regulated. Interestingly, a number of the most highly altered genes have previously been implicated in the development of EMT and/or resistance including Twist2, IGF binding protein 5, GATA and β-tubulin. Based on the identification of P-tubulin as the most up-regulated gene in resistant cells, 2-methoxyestradiol (2ME2) was recognized as a candidate drug to specifically target this resistant cell line due to it known roles in blocking tubulin polymerization. Indeed, 2ME2 exposure resulted in the induction of apoptosis and significant cell death in vitro. Conclusions: Chronic exposure of MCF7 cells to high concentrations of endoxifen led to induction of EMT with cells that are basal like, estrogen and SERM insensitive, highly TGFP responsive with significantly increased proliferation rates and metastatic potential relative to parental cells. These findings suggest that the mechanisms of resistance to endoxifen may differ from those observed with long term exposure to tamoxifen and have identified 2ME2 as a potentially successful alternative therapy for endoxifen resistant breast cancer cells. Citation Information: Cancer Res 2010;70(24 Suppl):Abstract nr PD05-11.
#19 Background: Tamoxifen (TAM) is a standard endocrine therapy for the treatment of women with estrogen receptor (ER) positive breast cancer. TAM is activated by the cytochrome P450 2D6 enzyme system into two potent and active metabolites, 4-hydroxytamoxifen (4HT) and 4-hydroxy-N-desmethyl-tamoxifen (endoxifen). While human concentrations of 4HT are negligible and vary little in plasma (5-10 nM), endoxifen concentrations vary widely (10-180 nm), and women with genetically impaired CYP2D6 metabolism have significantly reduced endoxifen levels and a higher risk of breast cancer recurrence. Despite these observations, endoxifen's contribution to tamoxifen's overall drug effectiveness is uncertain.
 Methods: Using cells endogenously expressing ERa (MCF7, T47D) and cells stably transfected with ERa (Hs578T and U2OS), we examined the relative effects of TAM and its primary metabolites on ERa protein levels by western blotting, ERa transcriptional activity by luciferase reporter assays and real-time RT-PCR, and on ER positive breast cancer cell growth through the use of proliferation assays.
 Results: We have discovered that endoxifen induces ERa protein turnover through proteasomal degradation similar to that of ICI in a concentration and time-dependent manner. These findings are in stark contrast to TAM, N-desmethyl-tamoxifen (NDT) and 4HT, which stabilize the ER. Optimal degradation occurs only at endoxifen concentrations observed in human CYP2D6 extensive metabolizers (> 40 nM) and persists even in the presence of TAM (300 nM), 4HT (7 nM), and NDT (700 nM) at concentrations observed in patients receiving tamoxifen therapy. In contrast, reducing endoxifen concentrations to those observed in a CYP2D6 poor metabolizer (20 nM), without altering TAM, 4HT, and NDT, results in ER stabilization. High endoxifen concentrations (100-1000 nM) completely block estrogen (E2)-induced ER transcriptional activity even in the presence of TAM, 4HT, and NDT, while low endoxifen concentrations (20-40 nM) do not. Further, low concentrations of endoxifen (20 nM) do not significantly alter E2-induced cell proliferation; however, high concentrations of endoxifen (100-1000 nM) completely block this process. Discussion: Our data demonstrate that endoxifen is a potent anti-estrogen that targets ERa for proteasomal degradation, blocks ERa transcriptional activity and inhibits E2-induced breast cancer cell proliferation. Importantly, these effects of endoxifen are observed at concentrations found in CYP2D6 extensive metabolizers and are maintained even in the presence of TAM, 4HT and NDT. These studies suggest that endoxifen may be the primary metabolite responsible for tamoxifen's effectiveness in the treatment of ER positive breast cancer and provide the impetus to evaluate whether TAM-related side-effects, such as thrombo-embolism and endometrial hyperplasia/carcinoma, are inversely associated with a patient's ability to metabolically activate tamoxifen. Citation Information: Cancer Res 2009;69(2 Suppl):Abstract nr 19.
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