Multi-Recombinase Mouse Models of Flt3-Driven Leukemia Identifies Distinct Trajectories of Mutational Cooperativity and Leukemic Transformation

Genomic studies in acute myeloid leukemia (AML) have generated a near complete catalogue of genes mutated at varying frequencies both across patients and in individual leukemias. The high variability of mutation burden within a given leukemia is suggestive of a stepwise evolutionary process composed of early, clonal, mutations and subsequent subclonal events. The receptor tyrosine kinase, FLT3, is the most commonly mutated gene in AML, with mutations frequently manifesting as internal tandem duplications (ITDs) in the juxtamembrane domain leading to constitutive kinase activation. Although FLT3 is commonly a subclonal mutational event, FLT3 ITD mutations portend a poor prognosis particularly when combined with DNMT3A and NPM1, earlier mutations that drive clonal expansion. Notwithstanding its role as a subclonal driver, previous preclinical FLT3 models have utilized retroviral overexpression or germline mutant expression at the endogenous locus precluding accurate temporal modeling of disease. These efforts have prohibited evaluation of FLT3 mutational acquisition in the context observed in AML patients. Here, we report the development of an endogenously targeted, Flp inducible, Flt3 ITD mouse allele which can be somatically activated subsequent to cooperating disease alleles. When activated with a tamoxifen inducible FlpoER, Flt3 mutant mice developed rapid leukocytosis peaking at 4-6 weeks post activation and resolving by 8-10 weeks, a finding not previously observed in constitutive models. This leukocytosis was disproportionately monocytic and accompanied by pronounced anemia and thrombocytopenia. Long term, these mice develop a myeloproliferative disease , reminiscent of previously reported constitutive alleles. In competitive transplantation studies, Flt3 mutant cells initiated disease and outcompeted wild-type cells. Despite this competitive advantage, disease was incapable of transplanting into secondary recipients. We further observed a non-cell autonomous depletion of SLAM+ LSKs suggesting the Flt3 mutant cells cannot propagate disease in self-renewing stem cells. To evaluate how this allele influenced leukemic evolution we crossed this Flt3 ITD allele to a Flp inducible Npm1 c mouse where a pulse of tamoxifen simultaneously activated both alleles. The combination of mutant Npm1 and Flt3 resulted in progressive leukocytosis which did not resolve. Within 6 weeks of mutational activation, these mice developed a lethal AML with robust anemia, thrombo