DDDR-09. TARGETED DYSREGULATION OF SPHINGOLIPID RHEOSTAT BALANCE IN IDH1MUT GLIOMAS TRIGGERS PRO-APOPTOTIC METABOLIC AND SIGNALING ACTIVITY

Abstract

Abstract BACKGROUND IDHwt gliomas exhibit sphingolipid rheostat balance that permits tumors to evade apoptosis by elevating the sphingosine-1-phosphate (S1P)-to-ceramide ratio. Overexpression of sphingosine kinase (SPHK) and consequent accumulation of S1P contribute to progression, chemoresistance, migration, and metastasis in malignant glioblastoma (GBM). We discovered that IDH1mut gliomas present a characteristic sphingolipid rheostat in which pro-apoptotic ceramides and sphingosines are elevated over oncopotent S1P. This characteristic involves inherent silencing of the SPHK2; obliging spheroids to rely on SPHK1 exclusively. We postulated that targeting this unique metabolic vulnerability would abrogate the growth-promoting and anti-apoptotic effects of S1P. METHODS IDH1mut glioma cell lines (TS603, BT142 & NCH1681) and empty vector-induced normal human astrocytes (NHAEV) were cultured and treated with a combination of SPHK1 inhibitor, N,N-dimethylsphingosine and C17-sphingosine to dysregulate sphingolipid rheostat. Biostatic response (i.e., IC50) was measured via spectrophotometric assay. Metabolic and signaling mechanisms were investigated by LC-MS lipidomic and RNA sequencing analysis. Mechanism of apoptosis was determined via western-blotting. RESULTS Following combination treatment, a global increase in ceramides, sphingosines, and their derivatives over S1P was detected in the sphingolipid rheostat. A decline in growth-promoting MAPK signaling enzymes and elevation of enzymes indicative of mitochondria-driven apoptosis occurred. Elevation of TNFα-related regulatory enzymes (NR1H3, MYLIP, INSIG, ABCA1) negatively impacted cholesterol homeostasis along with catalytic enzymes involved in cholesterol (and isoprenoid) biosynthesis. The effective concentration against IDH1mut spheroids was not cytotoxic to NHA spheroids. CONCLUSION The combination treatment potentiated a pro-apoptotic shift in sphingolipidome and revealed a novel mechanism of drug action involving concomitant global attenuation of cholesterol metabolism. While previous studies reported that decreasing cholesterol in gliomas compromises viability and induces apoptosis a link between cholesterol and sphingolipid metabolism remains unknown. Our data demonstrated that targeting sphingolipid rheostat triggers a cascade of pro-apoptotic signaling and metabolic activity that lower the threshold for apoptosis in IDHmut gliomas.