STEM-01. GLIOMA STEM CELLS ACTIVATE PLATELETS BY PLASMA-INDEPENDENT THROMBIN PRODUCTION TO PROMOTE GBM TUMORIGENESIS

Abstract

Abstract The interaction between platelets and cancer cells has been underexplored in solid tumor models that do not metastasize, for example glioblastoma (GBM) for which metastasis is rare. Histologically, it is known that glioma stem cells (GSCs) are found in perivascular and pseudsopalisading regions of GBM, which are also areas of platelet localization. High platelet counts have been associated with poor clinical outcome in many cancers. While platelets are known to promote progression of other tumors, mechanisms by which platelets influence GBM oncogenesis are unknown. Here, we aimed to understand how the bidirectional interaction between platelets and GSCs drives GBM oncogenesis. Male and female NSG mice were transplanted with patient derived GSC lines and treated with antiplatelet and anti-thrombin inhibitors. Immunofluorescence, qPCR, and Western blots were used to determine expression of coagulation mechanism in GBM tissue and subsequent GSC lines. We demonstrate that GSCs co-opt and activate platelets to promote GBM tumor progression. GSCs endogenously produce all coagulation factors of the intrinsic and extrinsic cascade generating thrombin and activating platelets in the absence of plasma. Conversely, inhibition of platelet activation and of thrombin production by GSCs abrogates platelet-mediated GSC self-renewal and growth (p< 0.0005). Similarly, inhibiting intratumoral thrombin production and function decreases tumor formation in vivo (p< 0.005). These studies challenge and revise the longstanding view that the complete coagulation cascades are found only in the liver and plasma demonstrating that cancer stem cells readily execute a highly liver-specific gene expression program that is mechanistically linked to GBM oncogenesis. We show that cancer cells can co-opt non-cancer cells to promote tumor growth, by uncovering the preferential relationship between platelets and GSCs that drive GBM malignancies and identifies a therapeutically targetable novel interaction.