P10.02.B THE PSYCHOTROPIC AGENT THIORIDAZINE IMPEDES MELANOMA BRAIN METASTASIS CELL ACTIVITY THROUGH INHIBITION OF AUTOPHAGY

Abstract

Abstract BACKGROUND Neural tissue and melanocytes share the same germ layer in early embryonic development. It is then perhaps not by coincidence that melanoma is one of the most common cancer types to metastasize to the brain. With aggressive treatment the median survival of melanoma brain metastases (MBM) is now estimated to be approximately 13 months. Targeted therapies and immunotherapy have armed us with new systemic weapons and shown great responses, but unfortunately most of these patient relapse. Drug repurposing, using old drugs for new purposes, has had several successes for other diseases. The anti-psychotic drug thioridazine (THD), a dopamine receptor 2 antagonist, with properties to cross an intact blood brain barrier, has earlier shown promising effects on melanoma cells that escaped prior treatment and on cancer stem cells. However, the therapeutic effects on MBM have not been previously investigated. MATERIAL AND METHODS We used three BRAF V600E (H1, H2 and H10) and one L577F mutated patient derived MBM cell lines (H3) developed in our lab in our experiments. A monolayer viability assay (WST-1) was utilized to determine IC50 doses. Migrational and proliferational effects of THD was studied by IncuCyte live cell imaging. Colony forming properties and the ability of cells to grow in an anchorage independent environment after THD treatment was investigated using a 2D clonogenic assay and a 3D soft agar model. A potential therapeutic window was assessed through normal human astrocytes (NHA) and fetal rat brain organoids (FRBO). Apoptosis and necrosis were studied by Annexin V/propidium iodide (PI) double staining followed by flow cytometric analysis after 72 hours of treatment. Western blots after THD treatment was done to elucidate underlying molecular mechanisms. RESULTS Cell viability studies showed that THD exerted a dose-dependent inhibition of tumor cell viability (IC50 doses between 9-12 µM), while NHA tolerated similar drug concentrations. Tumor cell migration and proliferation were almost completely inhibited with concentrations below the IC50 doses. An inhibition of clonogenic formation and 3D growth was also observed. Bright field microscopy showed changes in MBM morphology in monolayers, but FRBOs were intact after drug treatment. Apoptosis in MBM cells was induced after treatment with THD through PARP/cleaved caspase 3/Bcl-2. Expression levels of LC3B-II and p62 were significant increase in treated cells, indicating inhibition of autophagic flux at a late stage. CONCLUSION Our data shows that THD has a strong selective cytotoxicity in MBM cells through inhibition of autophagic flux, with a minimal effect on NHA and FBRO.