Abstract PR009: Discovery of covalent NRAS inhibitors targeting the Palmitoylation site through imaging-based high-throughput screening

Abstract

Abstract NRAS mutations play a crucial role as oncogenic drivers of tumor cell growth and chemo-resistance in melanoma and acute myeloid leukemia (AML). In melanoma, NRAS mutations occur in approximately 25% of cases, and are generally mutually exclusive with BRAF-mutations. NRAS mutant tumors often exhibit an aggressive phenotype, such as thicker lesions, increased mitotic activity, and higher rates of lymph node metastasis. Surgical resection of NRAS mutant melanoma has a poor prognosis with a lower median overall survival (OS) compared to non-NRAS-mutant melanoma (8.2 vs. 15.1 months for stage IV disease). Current treatment strategies for stage III/IV non-resectable metastatic NRAS mutant melanoma include immunotherapy and indirect targeting of NRAS associated signaling pathways, highlighting the urgent need to develop small molecule NRAS inhibitors. NRAS palmitoylation is essential for its oncogenic function by regulating its trafficking and anchoring to the plasma membrane. Unlike other RAS isoforms, NRAS relies on a single palmitoylation site (C181) for its plasma membrane localization and this unique dependency makes NRAS more sensitive to palmitoylation inhibitors. To identify selective NRAS inhibitors that covalently modify C181 and prevent its palmitoylation, we employed an imaging-based NRAS translocation high-throughput screen using a library of 23,000 covalent molecules. We identified a set of covalent inhibitors that selectively target NRAS translocation but do not affect HRAS localization. We further confirmed the direct binding of these compound hits to NRAS at its palmitoylation site (C181) using intact mass spectrometry and chemo-proteomic peptide mapping techniques. Moreover, we validated the functional impact of these compound hits by demonstrating their selective inhibition of cell growth in mutant NRAS-driven melanoma cell lines. In conclusion, our study presents the first direct inhibitor for NRAS, discovered through a high-throughput covalent screening approach. This finding holds promising implications for the development of novel targeted therapies for NRAS mutant tumors. Citation Format: Zhao Wang, Keith Moore, Simon Ng, Chao Wang, Ronald Tomlinson, Huay-Keng Loke, Jamie Rice, Ivan Cornella. Discovery of covalent NRAS inhibitors targeting the Palmitoylation site through imaging-based high-throughput screening [abstract]. In: Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics; 2023 Oct 11-15; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2023;22(12 Suppl):Abstract nr PR009.