TMIC-12. RAB27 REGULATION OF VASCULAR WALL INTEGRITY MEDIATES T-CELL INFILTERATION IN GLIOBLASTOMA

Abstract

Abstract Endothelial secretome exerts a potent influence on the phenotype of cancer cells and immune microenvironment. Recently, we have reported that glioblastoma stem cells acquire a more aggressive mesenchymal state under influence of vascular endothelial cell derived extracellular vesicles (EVs). Since Rab27, GTPases involved in multiple aspects of EV (exosome) biogenesis, has been implicated in control of angiogenic pathways through regulation of VEGFR1 turnover and possibly other mechanisms, we interrogated the role of Rab27 in the function of normal and glioblastoma associated brain microvasculature. Using mice with disrupted Rab27a and Rab27b isoforms, we documented that these proteins control development and stability of the brain vasculature including pathological angiogenesis in glioblastoma. Thus, relative to wild-type C57bl/6 (WT) and double heterozygous Rab27a+/-;Rab27b+/- (dHET) mice, animals with Rab27a/b double knock-out (Rab27a/b-dKO) exhibit reduced microvascular density in brain cortices. When neoangiogensis was induced following orthotopic inoculation of mouse glioma cells (GL261), multiple morphological anomalies were observed in the tumour vasculature relative to tumours established in control mice. Moreover, vascular permeability of tumours in Rab27a/b-dKO mice markedly exceeded that of similar tumours in wild type or heterozygous controls resulting in augmented T-cell infiltration into the otherwise ‘cold’ brain tumor microenvironment. Our results suggest that key switches in the cellular secretome, such as Rab27a and Rab27b, may impact endothelial membrane dynamic and intercellular interactions capabilities, whereby they may play a critical role in ensuring the stability and sustained cellular barrier function of the vasculature during brain tumour progression. Therapeutic implications of these findings are being explored.