We report here investigation of the combination of idasanutlin and navitoclax in the context of T-cell acute lymphoblastic leukemia (T-ALL), including detailed mechanistic characterization and in vivo patient derived xenograft results. T-ALL is an aggressive hematologic malignancy with a five-year event-free survival rate that declines with age, ranging from 70-75% for pediatric patients to 21.7% for patients aged 60-79. An unmet clinical need remains for the development of better therapies for T-ALL. Notch pathway activation mutations are present in the majority of T-ALL and are thought to induce transformation, in part, through activation of c-Myc. Typically, increased expression of c-Myc induces apoptosis through the p19(ARF)-Mdm2-p53 tumor suppressor pathway. Unsurprisingly, over 70% of T-ALL cases have inactivating mutations in CDKN2A (p19Arf). However, and critical to our approach, greater than 95% of primary T-ALL cases and 75% of relapsed cases maintain wild type p53. Based on these genetic data, we hypothesized that treatment with MDM2 inhibitors, by bypassing the loss of ARF, would increase p53 expression and lead to T-ALL cell apoptosis. To test this hypothesis, we initially treated T-ALL patient derived xenograft (PDX) lines in vitro with single-agent idasanutlin (a second generation MDM2 inhibitor) and observed upregulation of pro-apoptotic p53 target genes Bax and Puma1. However, only modest T-ALL cell apoptosis was observed in response to MDM2 inhibition alone. Based on these observations, particularly the induction of pro-apoptotic p53 targets, we hypothesized that inhibition of pro-survival BH3 domain proteins would synergize with MDM2 inhibition to kill T-ALL cells. Of note, a prior study showed that most T-ALL (~62%) respond to treatment with navitoclax (ABT-263), an inhibitor of BCL2, BCLXL, and BCLW, although most responses were transient and dose-limiting thrombocytopenia was observed. Combination therapy with idasanutlin could permit on-target inhibition with tolerable dosing. In vitro treatment of a panel of 5 different PDX lines derived from pediatric and adult T-ALL with dual idasanutlin and navitoclax led to robust cell death in all lines. In addition, treatment of a T-ALL PDX line with a matrix of dose combinations showed strong evidence of synergic activity. Synergy was assessed by ZIP (zero interaction potency) score, a statistical method developed by B Yadav et al. (Comput. Struct. Biotechnol. J. 2015) that compares the change in potency of individual dose response curves in the presence of a second agent. Generally, a ZIP score greater than 5 is considered significant; Idasanutlin and navitoclax combination therapy had a global ZIP score=16-18, with the most synergic dose area ZIP score=40-52. Combined treatment resulted in marked apoptosis, with strong induction of pro-apoptotic p53 targets, including PUMA and BAX. Finally, we assessed the in vivo response of four different T-ALL xenografts to dual treatment. In each case, human T-ALL cells were injected into immunodeficient NSG mice and randomized into treatment groups. Monotherapy with idasanutlin or navitoclax resulted in a modest but significant decrease in T-ALL burden in all cases, with the exception of an ETP T-ALL, which was resistant to idasanutlin monotherapy. A marked response to combination treatment with idasanutlin and navitoclax was seen in all four T-ALL xenografts. Specifically, the combination was found to be synergistic in each case based on a modified Bliss Independence test, analyzing average daily change in tumor burden for synergy interaction. Furthermore, overall survival was significantly increased in the combination treatment group. These data suggest that the rational combination of idasanutlin and navitoclax is highly active, with induction of an apoptotic cell death in T-ALL. Figure 1View largeDownload PPTFigure 1View largeDownload PPT Close modal
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