Abstract 4410: ZEB2 drives cell motility and metastasis in ER+ breast cancer cells through a novel, E-cadherin independent pathway

Abstract

Abstract Breast cancer is the most commonly diagnosed cancer in women, with the second highest mortality rate. The overwhelming majority of breast cancer deaths are a direct result of distant metastatic spread to vital organs such as lung, bone, and brain. The zinc finger transcription factor ZEB2 has been implicated as a driver of cancer cell motility, tissue invasion and metastasis in a number of diverse malignancies, but its role in breast cancer is not completely understood. We chose to examine the effects of direct overexpression of ZEB2 in the MCF-7 cell line, a luminal and estrogen receptor positive (ER+) derived breast cancer line. MCF-7-ZEB2 cells demonstrated significantly increased migration and invasion as well as an altered morphology in vitro compared to that of vector. Additionally, MCF-7-ZEB2 cells exhibited increased lung metastasis in vivo when implanted in an orthotopic xenograft mouse model. ZEB2 function in metastasis has canonically been attributed to transcriptional repression of the cell junction protein E-Cadherin. Here we establish that in ER+ breast cancer cells, ZEB2 fails to repress E-cadherin and promotes cell motility and metastasis through the induction of an E-cadherin independent signaling cascade. Next generation RNA sequencing analysis of the MCF-7-ZEB2 cells compared to vector revealed alteration of the MAPK signaling cascade, evidenced by enhanced expression of key motility and MAPK associated genes, including PLAU, EGF, ACTA2, and MMP9. Pharmacological inhibition of MAPK pathway completely abrogated ZEB2 induced migration, cell morphology changes and expression of target motility genes, confirming a necessary role for MAPK signaling in ZEB2-driven cell motility in ER+ breast cancer. Together these results indicate that the ZEB2 transcription factor drives motility in breast cancer cells through a novel MAPK dependent pathway, warranting further investigation into the mechanisms involved in ZEB2 action. Elucidating the pathways involved in ZEB2 function which are specific to ER+ breast cancer is an important step in understanding the processes underlying metastasis and has the potential to yield new therapeutic targets. Citation Format: Hope E. Burks, Lyndsay V. Rhodes, Elizabeth C. Martin, Van T. Hoang, Steven Elliott, Melody Badoo, Theresa Phamduy, Aaron Buechlein, Douglas Rusch, Douglas Chrisey, Erik Flemington, Kenneth Nephew, Bridgette Collins-Burow, Matthew E. Burow. ZEB2 drives cell motility and metastasis in ER+ breast cancer cells through a novel, E-cadherin independent pathway. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 4410.