The use of BCR-ABL1 tyrosine kinase inhibitors (TKI) has led to excellent clinical responses in patients with chronic phase chronic myeloid leukemia (CML). However these inhibitors have been less effective as single agents in the terminal blast phase (BP). We show that pyrvinium, a FDA-approved anthelminthic drug, selectively targets BP-CML CD34+ progenitor cells. Pyrvinium is effective in inducing apoptosis, inhibiting colony formation and self-renewal capacity of CD34+ cells from TKI-resistant BP-CML patients, while cord blood CD34+ are largely unaffected. The effects of pyrvinium are further enhanced upon combination with dasatinib, a second generation BCR-ABL1 TKI. In a CML xenograft model pyrvinium significantly inhibits tumor growth as a single agent, with complete inhibition in combination with dasatinib. While pyrvinium has been shown to inhibit the Wnt/β-catenin signalling pathway via activation of casein kinase 1α, we find its activity in CML is not dependent on this pathway. Instead, we show that pyrvinium localizes to mitochondria and induces apoptosis by inhibiting mitochondrial respiration. Our study suggests that pyrvinium is a useful addition to the treatment armamentarium for BP-CML and that targeting mitochondrial respiration may be a potential therapeutic strategy in aggressive leukemia.
The resistance of chronic myeloid leukaemia (CML) to tyrosine kinase inhibitors (TKIs) remains a significant clinical problem. Targeting alternative pathways, such as protein prenylation, is known to be effective in overcoming resistance. Simvastatin inhibits 3-hydroxy-3-methylglutaryl-CoA reductase (a key enzyme in isoprenoid-regulation), thereby inhibiting prenylation. We demonstrate that simvastatin alone effectively inhibits proliferation in a panel of TKI-resistant CML cell lines, regardless of mechanism of resistance. We further show that the combination of nilotinib and simvastatin synergistically kills CML cells via an increase in apoptosis and decrease in prosurvival proteins and cellular proliferation. Mechanistically, simvastatin inhibits protein prenylation as shown by increased levels of unprenylated Ras and rescue experiments with mevalonate resulted in abrogation of synergism. The combination also leads to an increase in the intracellular uptake and retention of radiolabelled nilotinib, which further enhances the inhibition of Bcr-Abl kinase activity. In primary CML samples, this combination inhibits clonogenicity in both imatinib-naive and resistant cells. Such combinatorial effects provide the basis for utilising these Food and Drug Administrationapproved drugs as a potential clinical approach in overcoming resistance and improving CML treatment.
Introduction Treatment-resistant acute lymphoblastic leukemia (ALL) remains a significant clinical issue. Recently, genomic profiling has identified a new subtype of high-risk ALL termed Philadelphia-chromosome-like (Ph-like) ALL, associated with a poor outcome1. Ph-like ALL has a gene expression profile similar to Ph+ (BCR-ABL1+) ALL, characterized by the presence of fusion genes converging on kinase and cytokine signaling pathways. These pathways have been shown to be targetable both in vitro and in case reports by tyrosine kinase inhibitors (TKIs). Despite well-documented efficacy profiles, it is known from TKI-use in chronic myeloid leukemia (CML) andPh+ ALL that resistance is likely, resulting in relapse. Our study aims to model and understand mechanisms of TKI-resistance inPh-like ALL, informing future therapeutic strategies that may avert or overcome resistance, potentially improving patient outcomes. Methods Three Ph-like ALL lines were generated via retroviral-transduction from plasmids of fusion genes identified in patient cohorts (RANBP2-ABL1, SSBP2-CSF1R and PAX5-JAK2, a kind gift from C. Mullighan)2 into Ba/F3 pro-B cells. Transformation was confirmed via growth of cells in the absence of IL-3. Cells were tested for sensitivity to a panel of TKIs (imatinib, dasatinib, ponatinib, ruxolitinib and BMS-911543) via Annexin-V/7-AAD flow-cytometry and western blotting of downstream effector proteins. Drug resistance was generated through exposure of cells to incrementally increasing concentrations of TKIs over a period of 3-6 months, and cell death LD50 determined byAnnexin-V/7-AAD. Sanger sequencing of the 3-prime partner gene of each fusion was performed to identify the emergence of any kinase-domain mutations. Results Ba/F3 Ph-like cells demonstrated sensitivity to TKIs at clinically relevant doses (RANBP2-ABL1: 1 μM imatinib, 5 nM dasatinib & 5 nM ponatinib; SSBP2-CSF1R: 1 μM imatinib, 6 nM dasatinib; PAX5-JAK2: 1 μM ruxolitinib & 2 μM BMS-911543). This correlated with decreased levels of relevant downstream signaling proteins including p-Stat5, p-Erk and p-CrkL. TKI-resistant Ph-like ALL lines were tolerant to a significantly higher concentration of TKIs compared to control (RANBP2-ABL1: 10 μM imatinib, 200 nM dasatinib & 200 nM ponatinib; SSBP2-CSF1R: 10 μM imatinib, 200 nM dasatinib; PAX5-JAK2: 10μMruxolitinib & 10μM BMS-911543; Table 1). Sequencing analysis revealed that Ba/F3 RANBP2-ABL1 imatinib and dasatinib resistant cells acquired the clinically significant ABL1 T315I (c.944C>T) kinase-domain mutation, which was ultimately targetable using the third-generation TKI ponatinib (LD50: 25 nM). An ABL1 E255K (c.763G>A) and c-terminus deletion was discovered in the ponatinib-resistant line. In Ba/F3 SSBP2-CSF1R cells, a novel CSF1R L785M (c.2566C>A) mutation was identified in imatinib-resistant cells whereas a deletion spanning the SSBP2-CSF1R breakpoint was acquired in the dasatinib-resistant line. A JAK2 Y931C (c.3286A>G) point mutation previously associated with resistance to ATP-competitive inhibitors was acquired in Ba/F3 PAX5-JAK2ruxolitinib and BMS-911543 resistant lines. Conclusion In vitro modeling of Ph-like ALL resistance has identified novel kinase domain mutations and deletions that may arise as a result of targeted TKI therapy. In addition, previously identified mutations (T315I and E255K) were also identified. Detection of these mutations is important because alterations in drug-binding regions are known to result in significantly reduced TKI sensitivity, leading clinically to relapse3. This study describes an in vitro platform that can be utilized to inform future clinical approachesincluding the development of rational therapeutic approaches (and/or combination therapies) to avert resistance inPh-like ALL cases treated with rationally targeted therapies. Abbreviations: ABL1 - Abelson tyrosine protein kinase 1 CSF1R - Colony stimulating factor 1 receptor JAK2 - Janus kinase 2 PAX5 - Paired box 5 RANBP2 - RAN-binding protein 2 SSBP2 - Single-stranded DNA binding protein 2 References: 1 Den Boer et al, Lancet Oncology 2009; 10(2):125-34 2 Roberts et al, Cancer Cell 2012; 22(2):153-66 3 Barouch-Bentov & Sauer, Expert Opinion on Investigational Drugs 2011; 20(2);153-208 Disclosures Hughes: Bristol-Myers Squibb: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Novartis Pharmaceuticals: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Ariad: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Australasian Leukaemia and Lymphoma Group (ALLG): Other: Chair of the CML/MPN Disease Group. White:Bristol-Myers Squibb: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Novartis Pharmaceuticals: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Ariad: Consultancy, Honoraria, Research Funding.
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