Drug Repurposing in a Zebrafish AML Model

Abstract

Acute myeloid leukemia (AML) is a genetically heterogeneous hematological malignancy. AML arises from the stepwise accumulation of mutations in hematopoietic stem cells (HSCs). The t(9;11)(p22;q23) translocation is a translocation detected in about 5 to 7% of AML patients, which gives rise to the KMT2A/MLLT3 or MLL/AF9 ( MA9) fusion gene. Zebrafish (ZF) are well-established model organisms for investigating human hematopoiesis. Approximately 70% of human genes have corresponding orthologues in zebrafish, and over 80% of disease-related genes are conserved between the two species. Previously, we established a transgenic MA9 zebrafish AML model (Runx1+23:MA9), in which the AML was serially transplantable. Our investigations revealed that MA9 expression alters hematopoiesis in transgenic embryos before the onset of AML, leading to myeloid expansion. Whole-mount in situ hybridization (WISH) of embryos showed increased expression of granulocyte markers such as lyz 24 and 48 hours after fertilization (hpf). Based on these findings, we developed a Runx1+23:MA9/lyz-EGFP zebrafish leukemia line, in which lyz-expressing myeloid cells are EGFP positive. This model provides a phenotype-based platform to evaluate the therapeutic potential of any drug that can affect the myeloid cell population. We used this ZF model to investigate the therapeutic potential of nine drugs in MA9-driven AML. MA9 transgenic fish (Runx1+23:MA9) were crossed with lyz-EGFP fish to generate a MA9/lyz-EFGP line. In this line, myeloid cells can be visualized with a fluorescent microscope. The expression of lyz in the MA9/lyz-EFGP transgenic embryos was compared to that in the lyz-EGFP line. In our previous study on MA9 transgenic leukemic fish, RNA-seq analysis had revealed higher expression of genes acting in the EGFR, MEK, RAF, KRAS pathways and downregulation of genes in TP53. Based on these results, we selected nine drugs that are known to affect some of these pathways as well as drugs that are used to treat leukemia for screening in our model. Control and MA9/lyz-EFGP ZF 48 hpf embryos were treated with 10 µM of each drug. 24 hrs after drug treatment, the number of lyz expressing cells was analyzed by visualizing the embryos under a fluorescent microscope, and lyz transcript levels were measured by qPCR. Treatment with erlotinib, lapatinib, cytarabine, and gefitinib led to a visible reduction in the number of lyz-expressing cells in the MA9 transgenic embryos but not in the controls (Figure 1). In comparison, treatment with decitabine resulted in a decrease in the number of lyz expressing cells in both the MA9/lyz-EGFP and the control embryos. Treatment with doxorubicin, zoledronic and arsenic trioxide did not have an effect on the number of lyz-expressing population in the transgenic nor in the control embryos. These results were confirmed by qPCR, which showed that expression of lyz was reduced by 33% to 51% in the erlotinib, lapatinib, cytarabine, and gefitinib treated MA9 transgenic embryos (Figure 2). Treatment with these drugs did not significantly change the lyz expression in lyz-EFGP control embryos. Our results provide strong evidence for the successful establishment of a zebrafish model of KMT2A-rearranged AML that can be used for low to medium-throughput drug screening by employing the expression level of an endogenous gene (lyz) as a read-out. This model is a valuable tool to assess the drug's specificity in targeting oncogene-expressing cells and normal hematopoietic cells and, therefore, to identify novel therapeutic agents that can target the cancer cells with fewer side effects on normal hematopoietic cells.