Abstract 3710: Establishment of a patient-derived acute myeloid leukemia (AML) ex vivo platform for evaluation of novel therapeutic agents

Acute myelogenous leukemia (AML) is the most common acute leukemia in adults. A hematologic cancer, the disease is highly heterogeneous, with multiple subtypes. Despite advances in treatment, the long-term survival for AML remains poor and the development of novel treatments is an unmet need. Due to the highly divergent subtypes and mutation profiles in AML, the use of patient-derived models may improve drug discovery and development. To address this, we have established a short-term culture system that supports the growth of primary AML cells ex vivo to permit the evaluation and/or screening of candidate agents. Our AML bank is comprised of patient-derived specimens across a range of subtypes (which includes M1, M2, M4, M5, and others), and includes models with common mutations in FLT3 (ITD), IDH1/IDH2 and NPM. Primary AML specimens were characterized for common mutations by TruSight sequencing and for surface marker expression by flow cytometry. The ex vivo assay system was evaluated for the ability to support the survival and expansion of 22 primary AML specimens. Among these, 15 had evidence of proliferation, 5 had no net expansion, and 2 failed to survive. Extension of the culture period for up to 14 days was feasible, with most models having equal or increased cell numbers by the end of the culture period (8 of 10 evaluated). All models stably expressed CD33 throughout the assay. To verify the applicability of this system for drug testing, a standard of care agent cytarabine (ara-C) was assessed for each of the AML models. Cell growth/viability was assessed using Celltiter-Glo assay. Concentration-dependent responses to ara-C were observed across multiple models (IC50 10 nM to 150 nM), indicating a range of relatively sensitive to resistant AML models. A cohort of models were evaluated in vivo for sensitivity to ara-C. Engraftment of the systemic patient-derived xenograft AML models (into NOG or NOG-EXL mice) was evaluated in circulation by flow cytometry. When engrafted, AML-bearing mice were randomized into ara-C or vehicle control groups. Two weeks later, mice were evaluated for the presence of human CD45+CD33+ AML cells. Models that were relatively sensitive to Ara C ex vivo (IC50 < 30 nM) showed a greater in vivo response as evidenced by a 60-80% reduction in the mean circulating AML cells versus models with >100 nM IC50 values, that had little response. In conclusion, Champions offers over 30 well characterized models of AML for study in ex vivo culture and in vivo systemic xenograft models. The diversity in these AML models is reflective of patient diversity, enhancing their utility in the evaluation of novel therapeutic candidates. These data indicate the feasibility of utilization of these primary models, ex vivo as well as in vivo, for drug discovery for AML, from screening to preclinical efficacy modeling. Citation Format: Bhavna Verma, Swetha Tati, Bruce Ruggeri, Amy Wesa. Establishment of a patient-derived acute myeloid leukemia (AML) ex vivo platform for evaluation of novel therapeutic agents [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 3710.