Abstract
Abstract 870
p53 is a transcription factor that prevents abnormal cell growth. Cellular levels of p53 are critically regulated by MDM2, which is frequently over-expressed in AML. Nutlin-3a disrupts MDM2-p53 interaction, increases cellular levels of p53 in both nucleus and cytoplasm, and activates p53 signaling in cells. p53 status is the major determinant of response to MDM2 inhibitors. p53 is shuttled between the nucleus and the cytoplasm, and CRM1 mediates its nuclear export. Karyopharm Therapeutics has developed novel, potent and irreversible small molecule selective inhibitors of CRM1. We hypothesized that CRM1 inhibition would enhance the nuclear activity of p53, thereby enhancing p53-mediated transcription-dependent apoptotic signaling in AML. We measured CRM1 expression in primary AML samples and investigated if blockade of nuclear export of p53 by CRM1 inhibition would enhance MDM2 inhibitor-induced apoptosis in AML.
CRM1 expression was investigated in 511 patient AML samples using a validated robust reverse-phase protein array. Higher levels of CRM1 were associated with higher marrow and peripheral blast percentages (P < 0.00001). Expression was lower in those with favorable cytogenetics compared to those with intermediate or unfavorable cytogenetics (P = 0.029). CRM1 levels were higher in patients with FLT3 mutations (P = 0.003). In 3-way correlation (using distance weighted least squares), there was a clear interaction with p53 levels being highest when CRM1 was high and MDM2 levels were low. Overall survival progressively worsened as CRM1 levels increased, with median survival of 66 weeks for those with CRM1 expression in the lowest third, 47 weeks for middle third and 37 weeks in the highest third (P = 0.007). CRM1 levels did not affect remission duration (P = 0.33).
The CRM1 inhibitor KPT-185 exhibited dose-dependent anti-proliferative and cytotoxic activity in AML cell lines, as evidenced by low IC50 values and high Annexin V positivity (= low ED50 values). IC50 values for wild-type p53 cells ranged from 27 to 38 nM, and for mutant p53 cells from 48 to 112 nM, suggesting that KPT-185 potently inhibits AML cell growth largely independent of p53. In contrast, apoptosis induction by KPT-185 was much more prominent in p53 wild-type than in p53-defective cells: ED50 values for Annexin V induction were 150, 90 and 85 nM in p53 wild-type and > 1000 nM in 5 of 6 p53 mutant cell lines. Stable p53 knockdown (> 90% efficiency) rendered AML cells resistant to KPT-induced apoptosis. KPT-185 induced p53 target genes TP53I3, GDF15, MDM2 and ZMAT3 partially in a p53-dependent manner. Hence, p53 was identified as major determinant of CRM1 inhibition-induced apoptosis in AML.
MDM2-inhibitor Nutlin-3a induced p53 in both nucleus and cytoplasm, while CRM1 inhibition accumulated p53 in the nucleus. Treatment with KPT-185 or Nutlin-3a caused time-dependent increase in cellular p53 levels. The KPT-185/Nutlin-3a combination induced p53 more efficiently than the individual agents by accumulating p53 exclusively in the nucleus, and synergistically induced apoptosis and cell death. p53 knockdown abrogated these synergistic effects.
In primary AML cells, both KPT-185 (24.7 – 36.7% Annexin V) and Nutlin-3a (13.6 – 59.8%) induced apoptosis in a dose-dependent manner. Importantly, both KPT-185 and Nutlin-3a induced apoptosis in CD34+CD38- progenitor cell populations as effectively as they did in bulk AML cells, suggesting high sensitivity of CD34+CD38- cells to CRM1 inhibition and MDM2 inhibition. KPT-185 and Nutlin-3a synergized in the induction of apoptosis in both bulk and CD34+CD38- AML progenitor cells: combination index (CI) values were 0.26 (bulk) and 0.30 (CD34+CD38-) for ED50 and 0.93 (bulk) and 0.46 (CD34+CD38-) for ED75, indicating highly synergistic (CI < 1) efficacy in apoptosis induction. The relation between p53 status and sensitivity to Nutlin-induced apoptosis has been well established. Nutlin-resistant samples were much less sensitive to KPT-185 than Nutlin-sensitive cases (12.2 ± 0.06 % versus 30.9 ± 0.04 % Annexin V, P < 0.05). Synergistic induction of apoptosis was not observed in normal cord blood CD34+CD38- cells.
Collectively, CRM1 inhibition offers a novel therapeutic strategy for AML that mostly retains wild-type p53. We propose to develop novel combinatorial approaches for the therapy of AML, aimed at maximal activation of p53 and apoptosis signaling by concomitant MDM2 and CRM1 inhibition.
Shacham:Karyopharm Therapeutics: Employment. Kauffman:Karyopharm Therapeutics: Employment. Andreeff:Hoffmann-La Roche: Research Funding; Karyopharm Therapeutics: Unrestricted gift, Unrestricted gift Other.
Author notes
Asterisk with author names denotes non-ASH members.
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