Abstract A38: Biophysical Regulation of Breast Cancer Metastasis

Abstract

Abstract Introduction: Despite many advances in our understanding of breast cancer biology over the last decades, there are no therapies that can effectively prevent or treat metastatic cancer. During the growth of the primary tumor mass and its dissemination through the body during metastasis, cancer cells are exposed to a host of mechanical environments generated by the local matrix compliance, pressure and tension from tumor mass expansion, and fluidic shear stresses from interstitial and vascular fluid flow. These biophysical forces are emerging as powerful regulators of cancer growth, quiescence and metastasis; however, our understanding of the mechanisms of the biomechanical regulation of tumor biology remains very limited. The overall goal was to identify the role of mechanical forces in regulating key steps in tumor metastasis and progression. Results: We recently developed a mesofluidic system that allows the high throughput study of tumor cell interactions under flow. This device allows us to simulate the adhesion of cancer cells to endothelial cells under physiological flow conditions to model this step of the metastatic cascade and to apply shear forces to cells in a 96-well format. In addition, we have designed a system to apply mechanical stretch to cells in a high throughput format (576 wells simultaneously). Using these two systems, we examined the interplay between mechanical cues and the propensity of breast cancer cells to metastasize and undergo epithelial-to-mesenchymal transition (EMT). Mechanical strain increases circulating tumor cell adhesion to endothelial cells and extracellular matrix (ECM). We applied cyclic mechanical strain (5% maximal strain) to MDA-MB-231 and MCF-7 cancer cells for 24 hours and then performed adhesion assays of the cancer cells to activated and non-activated endothelial cells (ECS) and purified ECM proteins. We found that cyclic strain increased cancer cell adhesion to activated ECs in comparison to non-strained cells. In addition cancer cells exposed to mechanical strain adhered more to collagen I, laminin, and vitronectin, while they adhered less to collagen II and fibronectin in comparison to non-strained control cells. To determine which integrins were involved in the strain-induced change in adhesion, we treated the cells with a library of integrin inhibitors while applying strain for 24 hours. Cilengitide, P11, ATN-161, Bio 1211, and RGDS peptides reduced the adhesion of cancer cells back to the level of non-strained cancer cells, indicating the role of αvβ3, αvβ5, α5β1, and α4β1 integrins in the biophysical regulation of circulating tumor cell adhesion. Cyclic strain alters the ability of breast cancer cells to invade through an endothelial monolayer. We next used the high throughput system to apply multiple levels of strain to the cancer cell lines (0, 2.5, 5, 7.5, 10, 12.5, 15 and 17.5% strain). We then trypsinized the cells and measured their invasion in a Transwell assay with a confluent layer of endothelial cells cultured on a porous membrane. We found that the mid-level strains ranging from 7.5-15% strain decreased the invasiveness of the MDA-MB-231 cells compared to the non-strained control cells. For the MCF-7 cells, mechanical strain of 5% or higher led to decreased invasion through the endothelial layer. Mechanical forces alter signaling through the TGF-β and Yap/Taz pathways as well the expression of markers of epithelial-to-mesenchymal transition (EMT). We applied cyclic strain at multiple levels (2.5-17.5% strain) to breast cancer cells for 24 hours then immunostained for various signaling proteins. In MDA-MB-231 cells, we saw a significant decrease in the intensity of Smad2/3 and nuclear phospho-Smad2/3 at mid-range strains (5-12.5% strain) as well as an increase in the nuclear localization of Yap/Taz using fluorescent immunostaining. At high levels of strain (15 and 17.5% strain), there was increased nuclear p-Smad2/3 intensity. Consistent with these findings, we found increased Smad activity in the cells using a luciferase reporter assay. An analysis of EMT markers using PCR, western blotting and immunostaining showed a reduction in mesenchymal markers including α−SMA, Slug, ZEB, fibronectin and vimentin with mid-range mechanical strain levels. Conclusion: Together, our studies demonstrate that mechanical forces can profoundly alter the propensity of cancer cells to adhere and invade during metastasis. Moreover, the response to mechanical strain is dependent on the magnitude of the strain and cancer cell type. These effects are mediated, in part, through integrin interactions and the differential regulation of the TGF-β and Hippo pathways by biophysical forces. Citation Format: Adrianne Spencer, Jason Lee, Katerina Lee, Darshil Choksi, Jerry Wang, Christopher Spruell, Aaron Baker. Biophysical Regulation of Breast Cancer Metastasis. [abstract]. In: Proceedings of the AACR Special Conference on Engineering and Physical Sciences in Oncology; 2016 Jun 25-28; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2017;77(2 Suppl):Abstract nr A38.