Translational Control of FLT3-Mutated AML Cell Survival

Acute Myeloid Leukemia (AML) is the most common acute leukemia in adults with a five-year survival rate of ~30%. Approximately 30% of AML patients harbor an internal tandem duplication (ITD) mutation in the FMS related receptor tyrosine kinase 3 (FLT3) gene, which is an indicator of poor overall survival and a high relapse rate. These mutations cause constitutive activation of the FLT3 receptor, which amplify proliferation and survival signaling that supports leukemia progression and chemotherapy resistance. Although FLT3 inhibitors (FLT3i) improve median survival by a couple of months, and they have reduced toxicity relative to conventional chemotherapy in clinical trials, patients eventually acquire resistance and relapse. Clinical trials have revealed that AML blasts in the bone marrow (BM) were not effectively eliminated compared to AML blasts in peripheral blood, suggesting a protective role of the BM microenvironment that counteracts FLT3i therapy. A clear understanding of FLT3-mutated AML biology and how it is influenced by the microenvironment is imperative for developing new molecular approaches for improving efficacy of FLT3i-based therapies.

We have discovered that BM stromal cell mediated regulation of Ataxia Telangiectasia Mutated (ATM) promotes Mammalian Target of Rapamycin Complex 1 (mTORC1) activity despite FLT3 inhibition, which maintains translation of oxidative phosphorylation genes that are critical for AML cell survival upon treatment with FLT3i [PMID: 36259537]. Key findings show that FLT3i inhibits mTOR and mTOR-dependent translation leading to cell death. However, in the presence of BM stromal factors, survival is restored upon FLT3i by regulating ATM/mTOR-dependent translation of essential phosphorylation genes to overcome FLT3i. Moreover, we demonstrated that the combination of FLT3i and mTORC1 inhibition (mTORC1i) synergistically kills human FLT3-mutated AML cells in vitro and substantially reduces tumor burden and prevents relapse in mouse models of FLT3-mutated AML. Further studies measuring translation in FLT3-mutated AML cells revealed that there are at least two different translation pathways dictated by FLT3. One of these pathways is mTOR-dependent, as expected, and the other is mTOR-independent.

Additional studies have sought to characterize FLT3-controlled translation, independent of mTOR, and its importance for FLT3-mutated AML cell survival. Although highly sensitized to FLT3i, we observed that ATM/mTOR-deficient cells maintain near-normal translation and survival. Additionally, mounting evidence suggests that there are other kinases, such as CDK1, GSK3β, and p38, that drive mTOR-independent translation by phosphorylating 4E-BP1. With this knowledge, we took an unbiased approach and used O-Propargyl Puromycin (OPP)-translation assays to assess the impact of inhibitors against these kinases on translation activity in FLT3-mutated AML cell lines. This approach revealed CDK1 as a critical regulator of translation downstream of FLT3. Interestingly, myeloid progenitors reprogram to an mTOR-independent translational program requiring phosphorylation of 4E-BP1 by CDK1 [PMID: 32386556], which could be relevant for myeloid leukemias. Further corroborating my findings, RNA sequencing data suggest that FLT3 positively regulates CDK1 expression/activity, suggesting a downstream position in parallel with mTOR. In conclusion, we have uncovered a FLT3-controlled translation pathway that promotes FLT3-mutated AML cell survival independent of mTOR. Further characterization of this pathway could help predict mechanisms of resistance to FLT3 and mTOR inhibitors in AML and could identify new targets to promote more durable remissions in patients.