Activation of Mitogen-Activated Protein Kinase in Estrogen Receptor α–Positive Breast Cancer Cells In vitro Induces an In vivo Molecular Phenotype of Estrogen Receptor α–Negative Human Breast Tumors

Abstract

Breast cancer presents as either estrogen receptor alpha (ERalpha) positive or negative, with ERalpha+ tumors responding to antiestrogen therapy and having a better prognosis. By themselves, mRNA expression signatures of estrogen regulation in ERalpha+ breast cancer cells do not account for the vast molecular differences observed between ERalpha+ and ERalpha- cancers. In ERalpha- tumors, overexpression of epidermal growth factor receptor (EGFR) or c-erbB-2, leading to increased growth factor signaling, is observed such that mitogen-activated protein (MAP) kinase (MAPK) is significantly hyperactivated compared with ERalpha+ breast cancer. In ERalpha+/progesterone receptor-positive, estrogen-dependent MCF-7 breast cancer cells, we stably overexpressed EGFR or constitutively active erbB-2, Raf, or MAP/extracellular signal-regulated kinase kinase, resulting in cell lines exhibiting hyperactivation of MAPK, estrogen-independent growth, and the reversible down-regulation of ERalpha expression. By global mRNA profiling, we found a "MAPK signature" of approximately 400 genes consistently up-regulated or down-regulated in each of the MAPK+ cell lines. In several independent profile data sets of human breast tumors, the in vitro MAPK signature was able to accurately distinguish ER+ from ER- tumors. In addition, our in vitro mRNA profile data revealed distinct mRNA signatures specific to either erbB-2 or EGFR activation. A subset of breast tumor profiles was found to share extensive similarities with either the erbB-2-specific or the EGFR-specific signatures. Our results confirm that increased MAPK activation causes loss of ERalpha expression and suggest that hyperactivation of MAPK plays a role in the generation of the ERalpha- phenotype in breast cancer. These MAPK+ cell lines are excellent models for investigating the underlying mechanisms behind the ERalpha- phenotype.