Estrogen switches pure mucinous breast cancer to invasive lobular carcinoma with mucinous features.

Mucinous breast cancer (MBC) is mainly a disease of postmenopausal women. Pure MBC is rare and augurs a good prognosis. In contrast, MBC mixed with other histological subtypes of invasive disease loses the more favorable prognosis. Because of the relative rarity of pure MBC, little is known about its cell and tumor biology and relationship to invasive disease of other subtypes. We have now developed a human breast cancer cell line called BCK4, in which we can control the behavior of MBC. BCK4 cells were derived from a patient whose poorly differentiated primary tumor was treated with chemotherapy, radiation and tamoxifen. Malignant cells from a recurrent pleural effusion were xenografted in mammary glands of a nude mouse. Cells from the solid tumor xenograft were propagated in culture to generate the BCK4 cell line. Multiple marker and chromosome analyses demonstrate that BCK4 cells are human, near diploid and luminal, expressing functional estrogen, androgen, and progesterone receptors. When xenografted back into immunocompromised cycling mice, BCK4 cells grow into small pure MBC. However, if mice are supplemented with continuous estradiol, tumors switch to invasive lobular carcinoma (ILC) with mucinous features (mixed MBC), and growth is markedly accelerated. Tamoxifen prevents the expansion of this more invasive component. The unexpected ability of estrogens to convert pure MBC into mixed MBC with ILC may explain the rarity of the pure disease in premenopausal women. These studies show that MBC can be derived from lobular precursors and that BCK4 cells are new, unique models to study the phenotypic plasticity, hormonal regulation, optimal therapeutic interventions, and metastatic patterns of MBC.

Unliganded progesterone receptors attenuate taxane-induced breast cancer cell death by modulating the spindle assembly checkpoint.

Whether the presence of steroid receptors in luminal breast cancers renders them resistant to taxanes remains uncertain. Here we assess the role of progesterone receptors (PR) on taxane-induced cell death. We previously showed that estrogen receptor (ER)-positive human breast cancer cells that inducibly express PR-A or PR-B isoforms were protected from taxane-stimulated apoptosis when compared to the identical cells lacking PR. Surprisingly, PR-dependent protection occurred in the absence of progesterone, demonstrating that the unliganded receptors were biologically active. The present studies demonstrate that unliganded PR, focused on PR-A, protect breast cancer cells from taxane-stimulated apoptosis. The studies identify genes regulated by taxanes in isogenic ER-positive cells that either lack or express PR-A. We show that unliganded PR-A alters the gene expression pattern controlled by taxanes, especially multiple genes involved in the spindle assembly checkpoint, a group of proteins that insure proper attachment of microtubules to kinetochores during mitosis. Importantly, taxanes and unliganded PR regulate many of these genes in opposite directions. As a result, mitotic slippage is exacerbated by the presence of PR, leading to an increase in the number of multinucleated cells both in vitro and in xenograft tumors. We describe a simple new assay for assessing multinucleation in paraffin sections. We speculate that rather than inducing cell death, unliganded PR exploits multinucleation to promote cell survival from taxane therapy. This can be prevented with antiprogestin.

Vascular endothelial growth factor secreted by activated stroma enhances angiogenesis and hormone-independent growth of estrogen receptor-positive breast cancer.

"Reactive" or activated stroma characterizes many malignancies including breast cancers. Recently, we isolated a reactive mouse mammary gland stromal cell line called BJ3Z. These cells express alpha-smooth muscle actin and stromal cell-derived factor 1 (SDF-1) and are tumorigenic when injected into mice. Here we show that, in vivo, BJ3Z cells influence the angiogenesis and proliferation of xenografted estrogen receptor (ER)-positive MCF-7 human breast cancer cell-derived solid tumors. The growth-promoting effects of BJ3Z cells are equivalent to those of estradiol (E(2)). BJ3Z cells also increase the proliferation of normal mouse mammary luminal cells adjacent to tumors. In vitro, BJ3Z cells reorganize and increase the proliferation of cocultured malignant MCF-7 and normal human breast MCF10A cells grown as organoids in three-dimensional culture. The effects of BJ3Z cells on MCF-7 cells are equivalent to those of E(2). In contrast, BJ3Z cells do not alter the growth of highly aggressive ER-negative MDA-MB-231 human breast cancer cells. We show that BJ3Z cells secrete vascular endothelial growth factor (VEGF). The growth of MCF-7 organoids induced by BJ3Z can be inhibited by antagonists of VEGF and SDF-1. Conversely, recombinant VEGF stimulates the proliferation of MCF-7, but not MDA-MB-231, organoids. We conclude that, in addition to angiogenesis, VEGF released by activated stroma increases the growth of ER-positive malignant epithelial cells and of adjacent normal epithelium. Because activated stroma can substitute for E(2) and fosters hormone-independent growth of ER-positive tumors, we suggest that breast cancers exhibiting intrinsic hormone resistance may respond to antiangiogenic therapies.