Abstract
Abstract Background: AML is a genetically heterogenous disease with poor prognosis and new treatments are needed. MPS1 is the main kinase of the spindle assembly checkpoint (SAC), critical for segregation of chromatids during mitosis. A hallmark of cancer cells is chromosomal instability caused by deregulated cell cycle checkpoints and SAC dysfunction. MPS1 inhibition has been investigated in several solid tumors but not yet in AML. Here, we demonstrate the efficacy of the small molecule MPS1 inhibitor (MPS1i) S81694 in AML cell lines, primary cells and mouse models. Materials and Methods: Cell viability, cell stress and apoptosis were assessed by MTS assays, DiOC2(3) or annexin-V modifications and PI incorporation after exposure to S81694. Cell-cycle and polyploidy were determined by cytofluorometry and FISH. Phosphorylation of MPS1 was detected in synchronized cells by immunofluorescence detecting phosphorylated Thr33/Ser37 residues. Protein modifications were studied by WB. Time-lapse microscopy was used to determine mitosis duration using cells stained with the SiR-DNA live cell probe. Bone marrow cells from patients were obtained after informed consent and incubated on a MSC feeder or in methylcellulose for colony formation assays. All animal studies were performed in accordance with the animal ethics committee's guidelines. NSG mice were sub-lethally-irradiated and injected with AML-NS8 or AML-PS patient derived xenografts. Mice were treated intravenously with S81694 or with vehicle. Results: IC50 for viability after S81694 exposure alone was <1000nM in a panel of 8 AML cell lines. Three cell lines had IC50 >1000nM: the NPM1cmut cell line OCI-AML3, OCI-AML3-TP53mut and K562. In the most sensitive cell lines, including OCI-AML2, S81694 led to inhibition of MPS1 auto-phosphorylation, induced significant cell stress and apoptosis as detected by mitochondrial membrane potential loss, phosphatidylserine exposure and PI incorporation. In these cell lines, the cell cycle was strongly affected by treatment with S81694 showing aberrant 2n/4n ploidy distribution due to SAC abrogation as well as polyploidy (8n and 16n). S81694 exposure triggered mitotic exit as shown by cyclin B1 downregulation and significantly accelerated mitosis. For treated OCI-AML2 and OCI-AML3 cells we observed induction of gamma-H2AX (ser139), p53 upregulation and downstream caspase-3 and PARP cleavage indicating that S81694 induces p53 dependent apoptosis. Furthermore, MPS1i induced downregulation of anti-apoptotic proteins MCL-1 and BCLXL. Finally, for AML patient derived blast cells cells we observed apoptosis after exposure to S81694 and significant reduction of colony number. In two AML PDX models, intravenous administration of S81694 was shown to improve significantly median survival time, as compared to control, by 28 to 41 days and by 33 to 46 days respectively. Conclusion: The MPS1i S81694 shows significant preclinical activity in vitro and in vivo in AML. Combinations with different drugs active in AML are ongoing. Citation Format: Anna Kaci, Emilie Adicéam, Etienne De Braekeleer, Marine Garrido, Jeannig Berrou, Mélanie Dupont, Hanane Djamai, Virginie Eclache, Baruchel André, Claude Gardin, Hervé Dombret, Mike Burbridge, Thorsten Braun. The MPS1 inhibitor S81694 is active in acute myeloid leukemia (AML) [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 608.
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