Methylparaben stimulates tumor initiating cells in ER+ breast cancer models.

A body of epidemiological evidence implicates exposure to endocrine disrupting chemicals (EDCs) with increased susceptibility to breast cancer. To evaluate the physiological effects of a suspected EDC in vivo, we exposed MCF-7 breast cancer cells and a patient-derived xenograft (PDX, estrogen receptor positive) to physiological levels of methylparaben (mePB), which is commonly used in personal care products as a preservative. mePB pellets (4.4 µg per day) led to increased tumor size of MCF-7 xenografts and ER+ PDX tumors. mePB has been thought to be a xenoestrogen; however, in vitro exposure of 10 nM mePB failed to increase MCF-7 cell proliferation or induction of canonical estrogen-responsive genes (pS2 and progesterone receptor), in contrast to 17ß-estradiol (E2) treatment. MCF-7 and PDX-derived mammospheres exhibited increased size and up-regulation of canonical stem cell markers ALDH1, NANOG, OCT4 and SOX2 when exposed to mePB; these effects were not observed for MDA-MB-231 (ER- ) mammospheres. As tumor-initiating cells (TICs) are also believed to be responsible for chemoresistance, mammospheres were treated with either tamoxifen or the pure anti-estrogen fulvestrant in the presence of mePB. Blocking the estrogenic response was not sufficient to block NANOG expression in mammospheres, pointing to a non-classic estrogen response or an ER-independent mechanism of mePB promotion of mammosphere activity. Overall, these results suggest that mePB increases breast cancer tumor proliferation through enhanced TIC activity, in part via regulation of NANOG, and that mePB may play a direct role in chemoresistance by modulating stem cell activity. Copyright © 2016 John Wiley & Sons, Ltd.

Intrinsic cues and hormones control mouse mammary epithelial tree size.

Organ size control is a long-standing question in biology. In mammals, using conditional cell ablation, two mutually exclusive mechanisms involving either intrinsic or extrinsic programs have been described to control organ size. The mammary gland is an ideal model for such studies, since it undergoes size and morphological changes during puberty and pregnancy. The role of stem cells in controlling mammary epithelial tree size is unclear, although mammary stem cells are able to reconstitute a functional organ on transplantation. Here, we show that mammary gland cellularity was strictly dependent on mammary stem cell number, even following a 20-fold expansion of the mammary stem cell pool at puberty and transient 3-fold expansions with each pregnancy. In addition, the expansion of the mammary stem cell pool was hormone dependent, as demonstrated by female bilateral ovariectomies during puberty and transplants of male-derived cells into female recipients. In these transplants, apart from a mammary stem cell expansion, we also observed the donor cells reconstituting functional mammary glands, developing alveolar structures, and secreting milk after the recipient's parturition. Taken together, these data suggest that in the mammary gland, there is a third organ size control mechanism, combining intrinsic cues throughout the organism's lifetime, with extrinsic hormone signals at particular developmental windows (puberty, pregnancy), where an expansion of the mammary stem cell pool occurs. This mechanism might have strong implications for the understanding of mammary tumorigenesis, since the expansion of the mammary stem cell pool precedes the generation of breast tumors.

Bisphenol A Induces Sox2 in ER+ Breast Cancer Stem-Like Cells.

Bisphenol A (BPA) is an endocrine disrupting compound used in food and beverage plastic containers and has been shown to increase breast cancer cellular proliferation. However, the concentrations of BPA used in these experiments are far higher than the physiological levels of BPA detected in the human body. We observed in vitro that exposure of MCF-7 cells to physiological concentrations of BPA failed to increase cell proliferation or to induce canonical estrogen-responsive genes (pS2 and progesterone receptor (PR)), in contrast to 17ß-estradiol (E2) treatment. However, MCF-7 cells treated with 10 nM BPA induced ALDH1 expression, a marker of human mammary stem cells. When treated with 10 nM BPA, mammospheres derived either from MCF-7 cells, a patient-derived xenograft, or the normal mouse mammary gland exhibited increased size; however, these effects were not observed in MDA-MB-231 mammospheres. Mechanistically, BPA induced SOX2 mRNA and protein in MCF-7 mammospheres, resulting from enhanced CREB phosphorylation, and subsequent binding of pCREB to a SOX2 downstream enhancer. These findings suggest that physiological levels of BPA increase estrogen receptor-positive breast cancer tumor maintenance through enhanced cancer stem-like cell activity via direct regulation of SOX2 transcription.

The natural compound Jatrophone interferes with Wnt/ß-catenin signaling and inhibits proliferation and EMT in human triple-negative breast cancer.

Metastatic breast cancer is the leading cause of worldwide cancer-related deaths among women. Triple negative breast cancers (TNBC) are highly metastatic and are devoid of estrogen receptor (ER), progesterone receptor (PR) and human epidermal growth factor receptor 2 (HER2) amplification. TNBCs are unresponsive to Herceptin and/or anti-estrogen therapies and too often become highly chemoresistant when exposed to standard chemotherapy. TNBCs frequently metastasize to the lung and brain. We have previously shown that TNBCs are active for oncogenic Wnt10b/ß-catenin signaling and that WNT10B ligand and its downstream target HMGA2 are predictive of poorer outcomes and are strongly associated with chemoresistant TNBC metastatic disease. In search of new chemicals to target the oncogenic WNT10B/ß-CATENIN/HMGA2 signaling axis, the anti-proliferative activity of the diterpene Jatrophone (JA), derived from the plant Jatropha isabelli, was tested on TNBC cells. JA interfered with the WNT TOPFLASH reporter at the level between receptor complex and ß-catenin activation. JA efficacy was determined in various subtypes of TNBC conventional cell lines or in TNBC cell lines derived from TNBC PDX tumors. The differential IC50 (DCI50) responsiveness was compared among the TNBC models based on etiological-subtype and their cellular chemoresistance status. Elevated WNT10B expression also coincided with increased resistance to JA exposure in several metastatic cell lines. JA interfered with cell cycle progression, and induced loss of expression of the canonical Wnt-direct targets genes AXIN2, HMGA2, MYC, PCNA and CCND1. Mechanistically, JA reduced steady-state, non-phosphorylated (activated) ß-catenin protein levels, but not total ß-catenin levels. JA also caused the loss of expression of key EMT markers and significantly impaired wound healing in scratch assays, suggesting a direct role for JA inhibiting migration of TNBC cells. These results indicate that Jatrophone could be a powerful new chemotherapeutic agent against highly chemoresistant triple negative breast cancers by targeting the oncogenic Wnt10b/ß-catenin signaling pathway.