Abstract Diffuse intrinsic pontine glioma (DIPG) and atypical teratoid/rhabdoid tumors (AT/RT) are deadly pediatric brain tumors. There is an urgent need of better therapeutics for improving survival and quality of life for these patients. Additionally, we need improved animal models to accelerate identification of novel therapeutics and improve through-put. In line with our long-term interests of validating therapies and developing model systems for pediatric brain tumors, we tested a repurposed drug quinacrine as a potential therapy using a new and faster model system in zebrafish. Quinacrine is a safe and widely used treatment for pediatric malaria and parasitic infections. We hypothesized that quinacrine will increase tumor cell death and decrease tumorigenicity of DIPG and ATRT. We used quinacrine in six patient-derived cell lines: three AT/RT (BT37, CHLA-05, CHLA-266) and three DIPG (JHHDIPG1, SUDIPGXIII, SF7761). In all tumor cell lines, quinacrine caused a dose-dependent reduction in proliferation (BrdU) and increase in apoptosis (cleaved caspase-3 and cleaved PARP) compared to vehicle-treated cells (P<0.01). Quinacrine had no effect on growth of normal hindbrain neural stem and progenitor cells. Using quinacrine fluorescence as a surrogate, we achieved micromolar concentration of quinacrine in the mouse and zebrafish brain without overt toxicity. Treatment of mice bearing ATRT flank tumors with quinacrine resulted in decreased tumor volume compared to vehicle-treated mice (P<0.05). To validate quinacrine orthotopically in DIPG, we developed a novel model in zebrafish wherein we injected fluorescent DIPG cells into the developing zebrafish blastula. Two days post injection, DIPG cells had homed to the zebrafish brain. Treatment of xenografted zebrafish with quinacrine for 72 hours decreased DIPG growth by 40% as measured by fluorescence, suggesting that minor groove binding drugs like quinacrine are a viable treatment strategy for these tumors. Using this new system, we were able to validate a potential therapeutic in 7 days versus 7 months in mice. Future studies are aimed at investigating the mechanism of quinacrine in these tumors and optimizing our zebrafish model for high-throughput screening of potential drugs. Citation Format: Harpreet Kaur, Huizi Guo, Kevin Emmerich, David White, Peter Green, Alara Michelle Hector, Sepehr Akhtarkhavari, Anukriti Bhargava, Allison Martin, Smit Shah, Charles G. Eberhart, Jeffrey Mumm, Eric H. Raabe. A novel rapid zebrafish model for validation of potential therapies for fatal pediatric brain tumors [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 3449.
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