Abstract
Abstract NPM1 mutations are among the most common mutations in CN-AML (Cytogenetically Normal-AML) and are known to enhance chemosensitivity in AML patients. Across multiple co-operative group studies, in the absence of deleterious mutations, patients with NPM1 mutations show superior overall and relapse-free survival. The FOXM1 regulatory network is a major predictor of poor prognosis in human cancers of different origin, including AML. Early AML cell line and patient sample data from our lab demonstrated that nuclear NPM colocalizes with nuclear FOXM1 while mutant NPM sequesters FOXM1 in the cytoplasm. Applying RNAseq differential expression results from published FOXM1 knockout experiments on KG-1 cells and MLL-AF9-transformed mice to Beat AML RNAseq data, we developed a ~200-gene FOXM1 signature that was significantly associated with inferior CR/CRi rate (OR=0.44 [95% CI: 0.21–0.95], p=0.037) in wild type NPM1, wild type FLT3 de novo AML patients. Notably, this FOXM1 signature was not significantly associated with CR/CRi in mutated NPM1, wild type FLT3 patients (OR=1.78 [95% CI: 0.15–21.51], p=0.651). These data suggest that inactivation of FOXM1 may underlie the chemosensitivity conferred by the highly prevalent NPM1 mutation in favorable risk AML. Using our novel network-centric approach, we found a first-in-class small molecule (STL427944) that affects a pathway that limits FOXM1 expression and significantly disrupts the associated regulatory network. To directly address the role of FOXM1 in chemosensitivity of AML cells, we tested two FOXM1-specific inhibitory compounds: STL427944 and its derivative, STL001 (their structures will be disclosed). From a medicinal chemistry standpoint, STL427944 has two main metabolic liabilities, a hydrolytically labile furane-carboxylic acid phenolic ester and a hydrazone. We applied several paths of structural activity relationship (SAR) optimization to overcome these issues from removal of liabilities to bio-isosteric replacement to cyclizations. The ring replacement is likely to have significantly improved the overall stability observed in STL001, resulting in at least !0-fold more active compound with better ‘drug-like’ properties and thus enhanced potency. We showed that 500nM of STL001 partially suppressed expression of FOXM1 protein in AML, while 5mM of STL001 (versus 50mM of STL427944) fully suppressed FOXM1 and sensitized AML cells to venetoclax and cytarabine treatment. Ex vivo treatment of AML patient samples with STL427944 and STL001 resulted in inhibition of nuclear FOXM1 expression according to IHC and downregulation of canonical FOXM1 transcriptional targets as indicated by real-time PCR. This treatment potentiated the efficacy of venetoclax in inhibiting colony forming activity in AML patient samples. Our data suggest that targeting FOXM1 in AML patients with wild type NPM1 may recapitulate NPM1 mutations and will have a robust therapeutic effect leading to more favorable outcome for AML patients. Citation Format: Irum Khan, Sandjeev Raghuwanshi, Andy Kaempf, Jeff Tyner, Alex Domling, Carlos Camacho, Andrei Gartel. Targeting of FOXM1 recapitulates NPM1 mutations in chemo-sensitization of AML [abstract]. In: Proceedings of the AACR Special Conference: Acute Myeloid Leukemia and Myelodysplastic Syndrome; 2023 Jan 23-25; Austin, TX. Philadelphia (PA): AACR; Blood Cancer Discov 2023;4(3_Suppl):Abstract nr A09.
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