To detect targeted antileukemia agents we have designed a novel, high-content in vivo screen using genetically engineered, T-cell reporting zebrafish. We exploited the developmental similarities between normal and malignant T lymphoblasts to screen a small molecule library for activity against immature T cells with a simple visual readout in zebrafish larvae. After screening 26 400 molecules, we identified Lenaldekar (LDK), a compound that eliminates immature T cells in developing zebrafish without affecting the cell cycle in other cell types. LDK is well tolerated in vertebrates and induces longterm remission in adult zebrafish with cMYCinduced T-cell acute lymphoblastic leukemia (T-ALL). LDK causes dephosphorylation of members of the PI3 kinase/AKT/mTOR pathway and delays sensitive cells in late mitosis. Among human cancers, LDK selectively affects survival of hematopoietic malignancy lines and primary leukemias, including therapy-refractory B-ALL and chronic myelogenous leukemia samples, and inhibits growth of human T-ALL xenografts. This work demonstrates the utility of our method using zebrafish for antineoplastic candidate drug identification and suggests a new approach for targeted leukemia therapy. Although our efforts focused on leukemia therapy, this screening approach has broad implications as it can be translated to other cancer types involving malignant degeneration of developmentally arrested cells. (Blood. 2012;119(24):5621-5631) IntroductionThe yearly incidence in the US for all leukemia types, including acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), and chronic myelogenous leukemia (CML), was estimated at more than 40 000 men and women in 2010, with a yearly death rate of 50%. 1 More than 2000 cases of ALL are diagnosed in US children every year, making it the most common childhood cancer. 2 T-cell ALL (T-ALL) represents approximately 15% and 25% of pediatric and adult ALL cases, respectively. 3 Although leukemia treatment has become increasingly efficient over the past 50 years, mortality from ALL is still 20% for children and more than 40% for adults, and T-ALL has been more difficult to treat than B-cell ALL (B-ALL). 4 Currently, research efforts are devoted to molecularbased risk stratification of patients and the development of targeted therapies to limit side effects [5][6][7] and to increase treatment efficacy.Development of targeted cancer therapies typically requires knowledge of the molecular target. 8 In the absence thereof, an alternative approach may use a robust readout designed to screen large numbers of compounds for specific effects 9 against the malignant cell type in question. More than 50% of patients with T-ALL have deregulated NOTCH1, 10 and in a recent study 47% had mutations in the PI3 kinase/AKT/mTOR (P/A/mT) pathway. 11 NOTCH1 signaling requires proteolytic cleavage by ␥-secretase and other proteases 12 to release the intracytoplasmic domain, providing severalpotential targets for therapeutic intervention. Targeted treatment approaches for T-ALL using...
Zebrafish models continue to gain popularity as in vivo models for drug discovery. Described in this overview are advantages and challenges of zebrafish drug screening, as well as a novel in vivo screen for immunomodulatory compounds using transgenic, T cell reporting zebrafish larvae designed for discovery of compounds targeting T cell leukemia. This assay system allows rapid screening of large numbers of compounds while avoiding the pitfalls of assays based on cell cultures, which lack biologic context and are afflicted by genomic instability. The rationale for this approach is based on similarities of immature normal T cells and developmentally arrested, malignant lymphoblasts in mammalian species. The screening algorithm has been used to identify a nontoxic compound with activity in both acute leukemia models and models of multiple sclerosis, demonstrating the utility of this screening procedure.
A Drug Screen in Zebrafish Identifies a New Therapeutic Agent Active in Acute Lymphoblastic Leukemia
2129 Objectives: T cell lineage is an independent high risk factor in acute lymphoblastic leukemia (ALL). T-ALL requires high dose multi-agent chemotherapy, conferring many toxic side effects. T-ALL treatment therefore needs new, targeted agents that preserve or improve current treatment efficacy, yet cause fewer side effects than existing chemotherapeutic regimens. To identify such drugs, we pioneered an in vivo screen using transgenic zebrafish with T cell-specific green fluorescent protein (GFP) expression. We reasoned that immature T cells in 5-day-old zebrafish larvae are developmentally analogous to T-ALL lymphoblasts, and likely rely upon similar signaling pathways. Hence, compounds that specifically eliminate T cells in zebrafish larvae might likewise selectively target T-ALL cells. An added benefit of our in vivo screen is that drugs added to the water housing fish larvae must cross an epithelial barrier, can be metabolized by the liver, and can be renally cleared, characteristics not assessed in in vitro-based screening strategies. In addition, by using early larvae as our subjects, drugs lacking T cell specificity will likely impair normal development and/or survival, which we postulate is a predictor of unwanted toxicities. In these ways, our screen mimicked the scenario encountered in patients. Our use of the transgenic p56lck::EGFP zebrafish line facilitated rapid visual assessment of efficacy of a large number of compounds in 96-well format. Materials and Results: In a proof-of-principle experiment, we identified several known anti-T-ALL drugs, most prominently glucocorticoids, from the “Spectrum” library (MicroSource Discovery Systems, Inc., Gaylordsville, CT) of well-characterized compounds. We then screened 39,200 small molecules from the “ChemBridge DIVERSet” combinatorial chemistry library (ChemBridge Corp., San Diego, CA) for those active against zebrafish larval T cells. Of 20 novel “hits” identified, one compound, dubbed Lenaldekar (“LDK”), met additional prioritization criteria. LDK does not impair the cell cycle of developing zebrafish, is well tolerated and orally bioavailable with favorable pharmacokinetic properties in mice. In addition, pilot studies with LDK indicate it is efficacious in treating T-ALL in juvenile and adult fish from an established transgenic rag2::ER-human cMyc T-ALL model. LDK kills all of several murine T-lymphocytic malignancies, induces apoptosis in all human T-ALL lines tested, and shows some activity in human B-ALL lines. However, glioblastoma, colon carcinoma, melanoma, or immortalized human embryonic kidney cell lines are not affected by LDK, even at high concentration (up to 25μM). Using the recently established “phosflow” technique we measured phosphorylation status of key signaling proteins in permeabilized T- and B-ALL lines. Regardless of PTEN status, PDK1, AKT and mTOR downstream targets p4EBP1 and p70S6kinase were dephosphorylated by LDK treatment, as was the p65 subunit of NFκB on serine 529. Results were corroborated by conventional Western blots. However, phosphorylation of STAT3, STAT5, pERK1-2, and p38 were not affected by LDK. LDK's action is distinguished from other AKT/mTOR inhibitors by its lack of activity against AKT-dependent glioblastoma and melanoma cell lines, and its lack of effect on cell size. Finally, LDK decreased tumor burden of human T-ALL in murine xenografts. Conclusions: In view of its apparent lymphocyte selectivity, we posit that LDK modulates a pathway relatively unique to ALL (and immature lymphoblast) cells. This suggests that LDK can serve as a novel molecular tool for studies of normal and malignant lymphocyte biology. Moreover, with its favorable pharmacokinetics, apparent lack of toxicity, and in vivo efficacy in two vertebrate ALL models, LDK is an attractive molecule for development into a targeted treatment for ALL and perhaps other lymphocytic malignancies. Disclosures: No relevant conflicts of interest to declare.
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