Abstract

Abstract The aggressive biology and poor response to therapy resulting in relapse of patients with GBM is attributed to the existence of Brain Tumour Initiating Cells (BTICs) with stem cell properties. Targeting BTICs in isolation of their surrounding tumour microenvironment (TME) has proven ineffective. Determining the molecular effects of the TME on BTICs is an evolving area that requires more focus. OUR APPROACH: Using innovative patient-derived organoid co-culture models paired with an in vivo zebrafish xenograft system our multidisciplinary team is exploring the biology of BTICs in the context of their microenvironment in search for novel therapeutic options that will benefit GBM patients. RESULTS: Our data supports an important role for activated cancer associated fibroblasts and endothelial cells in driving BTIC expansion and resistance to therapy. We further show that these effects, at least in part, are attributed to changes in the composition of the TME. Using semi-conducting conjugated polymer nanoparticles designed to selectively disrupt microenvironment interactions with BTICs, we show a reduction in anti-apoptotic and proliferation markers and a decreased self-renewal in functional assays. In vitro and in vivo drug response assays reveal this combined approach sensitizes to standard of care Temozolomide. CONCLUSIONS: Our data reveals novel aspects of the TME that play an essential role in the biology of GBM and in resistance to therapy. We propose that this offers unique opportunities for drug targeting that may improve patient outcomes for this aggressive disease.

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