However, the effect of RECK silencing in several cancer cells in a hypoxic microenvironment has not been fully identified. Here we investigated that hypoxia suppresses RECK expression

and restoration of RECK by using the strategy of HDAC inhibition inhibits cancer cell migration and invasion. HDAC inhibitors including trichostatin A (TSA) completely restored RECK expression suppressed by hypoxia in the H-Ras MCF10A cell line (human breast cancer) and the HT1080 cell lines (human fibrosarcoma). TSA suppressed the selleckchem activity of MMP-2 and MMP-9 induced by hypoxia and significantly inhibited the hypoxia-stimulated migration and invasion of both cancer cells. RECK overexpression significantly learn more inhibited the hypoxia-induced migration and invasion, suggesting the inhibitory role for RECK in hypoxic conditions. We also demonstrate that silencing of HDAC1 using small interfering (si) RNA suppressed hypoxia-induced RECK downregulation. In conclusion, the inhibition of HDAC successfully restored the expression of RECK under hypoxic conditions. This resulted in the inhibition of cancer cell migration and invasion through the repression of MMP-2 and MMP-9 activity. Poster No. 131 Probing the Role of E-cadherin in

4SC-202 clinical trial Metastasis Using Real-Time Protein Modulation and Intravital Imaging Hon Leong 1 , Shruti Nambiar1, Balaji Iyengar1, BCKDHA Ann F. Chambers1, John Lewis1 1 Oncology, London Regional Cancer Program, London Health Sciences Centre, London, ON, Canada The ability of tumor cells to migrate, invade and intravasate requires the deregulation of interactions with adjacent cells and the extracellular matrix. A major challenge of cancer biology is to observe the dynamics of the proteins involved in this process in their functional and physiologic context. To address this, we developed an E-cadherin chimera fused to both GFP and a FKBP-destabilization domain (DD) that constitutively targets the protein for proteasome degradation until stabilized by SHIELD-1, a small

molecule that binds reversibly to the DD. This approach allows one to dynamically modulate E-cadherin activity at the post-translational level by varying the levels of SHIELD-1. Using the highly metastatic MDA-MB-231-LN cell line, we demonstrate that in the absence of SHIELD-1, E-cadherin is observed only in punctate cytoplasmic vacuole pools that co-localize with 20S proteasome. Within 30 minutes of SHIELD-1 treatment, a shift in localization to the plasma membrane is seen with concurrent formation of cell-cell adherens junctions. SHIELD-mediated induction of E-cadherin significantly reduces cell migration and invasion compared to un-induced MDA-MB-231LN cells expressing the E-cadherin chimera and vector control MDA-MB-231LN cell line.