DDRE-15. Sema3C SIGNALING CONFERS RESISTANCE TO Wnt INHIBITION IN GLIOBLASTOMA

Abstract

Abstract BACKGROUND Wnt signaling is widely dysregulated in cancer. The therapeutic potential of Wnt inhibitors appears promising in preclinical studies. However, they have uniformly failed clinical trials. How cancer cells develop Wnt inhibitor resistance is poorly understood. Current Wnt inhibitors are designed targeting either ligand or receptor. We hypothesized cancer cells will bypass ligand-receptor interaction through an unknown mechanism. We focused on the neurodevelopmental signaling program of Semaphorin 3C (Sema3C) that is upregulated in 85% of GBM and regulates glioma stem-cell-driven tumor progression. RESULTS Porcupine inhibitor LGK974 reduced TCF1 expression in the GBM tumor mouse models, suggesting successful target engagement in vivo. However, it failed to prolong the overall survival. Sema3C expression strongly correlated with TCF1 expression in human GBM samples by immunohistochemical analysis. Genetic inhibition of Sema3C and TCF1 together prolonged animal survival more than either alone, indicating better control of Wnt pathway signaling with dual pathway blockade. Immunofluorescence and cell fractionation studies revealed that Sema3C signaling drove β-catenin nuclear accumulation. Sema3C regulates transactivation of Wnt target genes including TCF1, c-Myc and c-Met. Sema3C pathway activates Rac1. It is reported that Rac1 activates β-catenin and promotes β-catenin nuclear accumulation. In GSCs, constitutively active Rac1 restored β-catenin nuclear localization and rescued TCF1 and c-Myc down-regulation in the setting of Sema3C silencing. Sema3C can drive canonical Wnt signaling even when Wnt ligand secretion is blocked. Together, the data support that GSCs can escape Wnt inhibition through Sema3C and Rac1. CONCLUSIONS Sema3C signaling drives canonical Wnt signaling, providing an escape mechanism for cancer cells despite Wnt ligand-receptor interruption. Sema3C-β-catenin signaling promotes GSC self-renewal and tumor progression. Upstream Wnt pathway inhibition alone is insufficient to control tumors. Our data provide a therapeutic strategy of dual blockade of Wnt and Sema3C pathways to provide clinically significant tumor control.