Abstract
Personalized medicine holds tremendous promise for improving safety and efficacy of drug therapies by optimizing treatment regimens. Rapidly developed patient-derived xenografts (pdx) could be a helpful tool for analyzing the effect of drugs against an individual’s tumor by growing the tumor in an immunodeficient animal. Severe combined immunodeficiency (SCID) mice enable efficient in vivo expansion of vital tumor cells and generation of personalized xenografts. However, they are not amenable to large-scale rapid screening, which is critical in identifying new compounds from large compound libraries. The development of a zebrafish model suitable for pdx could facilitate large-scale screening of drugs targeted against specific malignancies. Here, we describe a novel strategy for establishing a zebrafish model for drug testing in leukemia xenografts. We used chronic myelogenous leukemia and acute myeloid leukemia for xenotransplantation into SCID zebrafish to evaluate drug screening protocols. We showed the in vivo efficacy of the ABL inhibitor imatinib, MEK inhibitor U0126, cytarabine, azacitidine and arsenic trioxide. We performed corresponding in vitro studies, demonstrating that combination of MEK- and FLT3-inhibitors exhibit an enhanced effect in vitro. We further evaluated the feasibility of zebrafish for transplantation of primary human hematopoietic cells that can survive at 15 day-post-fertilization. Our results provide critical insights to guide development of high-throughput platforms for evaluating leukemia.
Highlights
Human hematopoietic and leukemia cells in vivo
These 2 dpf xenografts were used as the 0 dpi control group, which represented the initial amounts of human cells being transplanted by this microinjection protocol and were used to compare at later time points after cell proliferation inside the zebrafish host
We evaluated the drug effect on cancer cells in the zebrafish xenografts, demonstrating that the cancer cells could adapt to the host environment and proliferate inside the zebrafish
Summary
Human hematopoietic and leukemia cells in vivo The development of such advanced techniques as transgenesis and knock-in approaches over the last few decades has made zebrafish a compelling model for drug testing. Zebrafish/tumor xenografts have been established by other researchers and our laboratory to visualize and functionally analyze the role of cancer cells and monitor their interactions with the microenvironment during tumor angiogenesis, metastasis and in response to drug treatment[11,12,13,14,15,16,17,18]. This, combined with the capability of optical imaging, makes zerbrafish highly attractive models for investigating different drug combination therapies against patient-derived xenografts for leukemia[2,29,30,31,32,33]. The zebrafish xenograft model can be a useful tool for translational research: for example, drug screening on patient-derived xenografts in preclinical s ettings[34,35]
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