Ji Ping Wang scite author profile

Development of breast cancer involves genetic factors as well as lifetime exposure to estrogen. The precise molecular mechanisms whereby estrogens influence breast tumor formation are poorly understood. While estrogen receptor α (ERα) is certainly involved, nonreceptor mediated effects of estradiol (E2) may also play an important role in facilitating breast tumor development. A “reductionist” strategy allowed us to examine the role of ERα independent effects of E2 on mammary tumor development in ERα knockout (ERKO) mice bearing the Wnt-1 oncogene. Exogenous E2 “clamped” at early follicular and midluteal phase levels (i.e., 80 and 240 pg/ml) accelerated tumor formation in a dose-related fashion in ERKO/Wnt-1 animals (p = 0.0002). Reduction of endogenous E2 by oophorectomy (p < 0.001) or an aromatase inhibitor (AI) (p = 0.055) in intact ERKO/Wnt-1 animals delayed tumorigenesis as further evidence for an ER-independent effect. The effects of residual ERα or β were not involved since enhancement of tumor formation could not be blocked by the antiestrogen fulvestrant. 17α-OH-E2, a metabolizable but ER-impeded analogue of E2 stimulated tumor development without measurable uterine stimulatory effects. Taken together, our results suggest that ER-independent actions of E2 can influence breast tumor development in concert with ER dependent effects. These observations suggest 1 mechanism whereby AIs, which block E2 synthesis, would be more effective for breast cancer prevention than use of antiestrogens, which only block ER-mediated effects.

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Estrogen utilization of IGF-1-R and EGF-R to signal in breast cancer cells

Song

Chen

Zhang

et al. 2010

The Journal of Steroid Biochemistry and Molecular Biology

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As breast cancer cells develop secondary resistance to estrogen deprivation therapy, they increase their utilization of non-genomic signaling pathways. Our prior work demonstrated that estradiol causes an association of ERα with Shc, Src and the IGF-1-R. In cells developing resistance to estrogen deprivation (surrogate for aromatase inhibition) and to the anti-estrogens tamoxifen, 4-OHtamoxifen, and fulvestrant, an increased association of ERα with c-Src and the EGF-R occurs. At the same time, there is a translocation of ERα out of the nucleus and into the cytoplasm and cell membrane. Blockade of cSrc with the Src kinase inhibitor, PP-2 causes relocation of ERα into the nucleus. While these changes are not identical in response to each anti-estrogen, ERα binding to the EGF-R is increased in response to 4-OH-Tamoxifen when compared with tamoxifen. The changes in EGF-R interactions with ERα impart an enhanced sensitivity of tamoxifen resistant cells to the inhibitory properties of the specific EGF-R tyrosine kinase inhibitor, AG 1478. However, with long term exposure of tamoxifen-resistant cells to AG 1478, the cells begin to re-grow but can now be inhibited by the IGF-R tyrosine kinase inhibitor, AG 1024. These data suggest that the IGF-R system becomes the predominant signaling mechanism as an adaptive response to the EGF-R inhibitor. Taken together, this information suggests that both the EGF-R and IGF-R pathways can mediate ERα signaling.To further examine the effects of fulvestrant on ERα function, we examined the acute effects of fulvestrant, on non-genomic functionality. Fulvestrant enhanced ERα association with the membrane IGF-1 receptor (IGF-1R). Using siRNA or expression vectors to knock-down or knock-in selective proteins, we further demonstrated that the ERα/IGF-1R association is Src-dependent. Fulvestrant rapidly induced IGF-1R and MAPK phosphorylation. The Src inhibitor PP2 and IGF-1R inhibitor AG1024 greatly blocked fulvestrant-induced ERα/IGF-1R interaction leading to a further depletion of total cellular ERα induced by fulvestrant and further enhanced fulvestrant-induced cell growth arrest. More dramatic was the translocation of ERα to the plasma membrane in combination with the IGF-1-R as shown by confocal microscopy. Taken in aggregate, these studies suggest that secondary resistance to hormonal therapy results in usage of both IGF-R and EGF-R for non-genomic signaling.

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Estrogen Stimulation of Cell Migration Involves Multiple Signaling Pathway Interactions

Wang

Santen

et al. 2010

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Hormone-dependent breast cancers respond to inhibitors of estrogen synthesis or action with tumor regression and with a reduction of new metastases. The mechanisms underlying the effects of estrogen on metastasis likely differ from those on tumor regression. Cell migration is a key first step in the metastatic process. Based on our prior work and other published data, we designed and tested a working model that suggested that estrogen receptor α, epidermal growth factor receptor, focal adhesion kinase (FAK), paxillin, phosphatidylinositol 3 kinase, p60 Src tyrosine kinase (c-Src), c-Jun N-terminal kinase, and MAPK interact to facilitate estradiol (E(2))-induced cell migration. Accordingly, we examined the effect of E(2) on activation of these pathways and demonstrated mechanistic effects by blocking each component and assessing cell migration as a biologic endpoint. Initial studies validated a robust cell migration assay characterized by highly reproducible, dose-dependent responses to E(2). Examining various mechanisms involved in migration, we showed that E(2) induced activation of c-Src, FAK, and paxillin with early peaks within 5-30 min and later peaks at 24 h. ERK and protein kinase B phosphorylation exhibited only early peaks. Blockade of various steps in these signaling pathways with use of small interfering RNA or specific inhibitors demonstrated mechanistic effects of these signaling molecules on cell migration. Our results suggest that the effects of E(2) on cell migration involve multiple, interacting signaling pathways. Important effects are mediated by the MAPK, phosphatidylinositol 3 kinase, and c-Jun N-terminal kinase pathways and use FAK, paxillin, and c-Src for activation. Each pathway represents a potential target for blocking cell migration and metastasis of breast cancer cells.

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Mechanisms of Resistance to Structurally Diverse Antiestrogens Differ under Premenopausal and Postmenopausal Conditions: Evidence from in Vitro Breast Cancer Cell Models

Fan

Yue

Wang

et al. 2009

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This study questioned whether the mechanisms of resistance to antiestrogens differ when acquired under premenopausal (Pre-M) vs. postmenopausal (PM) conditions and whether structurally diverse antiestrogens induce adaptation of differing signaling pathways. To address this issue, we conducted systematic studies under Pre-M vs. PM culture conditions with long-term exposure to different antiestrogens and examined the resultant "specific biologic signatures" of the various resistant cells. Estradiol stimulated growth and inhibited apoptosis of "pre-menopausal" antiestrogen-resistant cells but exerted opposite effects on their "post-menopausal" counterparts. Under Pre-M conditions, tamoxifen (TAM)-resistant cells exhibited a marked translocation of estrogen receptor alpha from the nucleus into the cytoplasm, whereas this occurred to a lesser extent under PM conditions. MCF-7 cells exposed to PM but not Pre-M conditions exhibited up-regulation of basal epidermal growth factor (EGF) receptor (EGFR) levels, an effect exaggerated in cells exposed to 4-hydroxytamoxifen. Differing effects occurred in response to structurally divergent antiestrogens. Long-term treatment with both 4-hydroxytamoxifen and ICI182,780 increased EGFR levels, but this was not seen in response to TAM. Surprisingly, EGF administration slightly increased cell number in TAM-resistant cells, whereas only increasing cell weight and decreasing cell number in EGFR overexpressing-resistant cells. To assess potential differences among various parental cell lines, we induced resistance in cell lines obtained from other laboratories and confirmed the results from our own parental cells with minor differences. Together, these data demonstrate that culture of breast cancer cells under Pre-M and PM conditions and structurally diverse antiestrogens results in adaptive responses with differing biological signatures.

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Ji Ping Wang

Estrogen receptor-dependent and independent mechanisms of breast cancer carcinogenesis

Effects of estrogen on breast cancer development: Role of estrogen receptor independent mechanisms

Estrogen utilization of IGF-1-R and EGF-R to signal in breast cancer cells

Estrogen Stimulation of Cell Migration Involves Multiple Signaling Pathway Interactions

Mechanisms of Resistance to Structurally Diverse Antiestrogens Differ under Premenopausal and Postmenopausal Conditions: Evidence from in Vitro Breast Cancer Cell Models

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