Background:The antibody cetuximab, targeting epidermal growth factor receptor (EGFR), is used to treat metastatic colorectal cancer (mCRC). Clinical trials suggest reduced benefit from the combination of cetuximab with oxaliplatin. The aim of this study was to investigate potential negative interactions between cetuximab and oxaliplatin.Methods:Thiazolyl blue tetrazolium bromide (MTT) assay and Calcusyn software were used to characterize drug interactions. Reactive oxygen species (ROS) were measured by flow cytometry and real-time polymerase chain reaction oxidative stress arrays identified genes regulating ROS production. Chromatin immunoprecipitation (ChIP) measured signal transducer and activator of transcription 1 (STAT-1) binding to dual oxidase 2 (DUOX2) promoter. SW48, DLD-1 KRAS wild-type cell lines and DLD-1 xenograft models exposed to cetuximab, oxaliplatin, or oxaliplatin + cetuximab (control [saline]; n = 3 mice per treatment group) were used. Statistical tests were two-sided.Results:Cetuximab and oxaliplatin exhibited antagonistic effects on cellular proliferation and apoptosis (caspase 3/7 activity reduced by 1.4-fold, 95% confidence interval [CI] = 0.78 to 2.11, P = .003) as opposed to synergistic effects observed with the irinotecan metabolite 7-Ethyl-10-hydroxycamptothecin (SN-38). Although both oxaliplatin and SN-38 produced ROS, only oxaliplatin-mediated apoptosis was ROS dependent. Production of ROS by oxaliplatin was secondary to STAT1-mediated transcriptional upregulation of DUOX2 (3.1-fold, 95% CI = 1.75 to 2.41, P < .001). Inhibition of DUOX2 induction and p38 activation by cetuximab reduced oxaliplatin cytotoxicity.Conclusions:Inhibition of STAT1 and DUOX2-mediated ROS generation by cetuximab impairs p38-dependent apoptosis by oxaliplatin in preclinical models and may contribute to reduced efficacy in clinical settings. Understanding the rationale for unexpected trial results will inform improved rationales for combining EGFR inhibitors with chemotherapeutic agents in future therapeutic use.
Targeting the DNA damage response (DDR) in tumors with defective DNA repair is a clinically successful strategy. The RAS/RAF/MEK/ERK signalling pathway is frequently deregulated in human cancers. In this study, we explored the effects of MEK inhibition on the homologous recombination pathway and explored the potential for combination therapy of MEK inhibitors with DDR inhibitors and a hypoxia-activated prodrug.We studied effects of combining pimasertib, a selective allosteric inhibitor of MEK1/2, with olaparib, a small molecule inhibitor of poly (adenosine diphosphate [ADP]-ribose) polymerases (PARP), and with the hypoxia-activated prodrug evofosfamide in ovarian and pancreatic cancer cell lines. Apoptosis was assessed by Caspase 3/7 assay and protein expression was detected by immunoblotting. DNA damage response was monitored with γH2AX and RAD51 immunofluorescence staining. In vivo antitumor activity of pimasertib with evofosfamide were assessed in pancreatic cancer xenografts.We found that BRCA2 protein expression was downregulated following pimasertib treatment under hypoxic conditions. This translated into reduced homologous recombination repair demonstrated by levels of RAD51 foci. MEK inhibition was sufficient to induce formation of γH2AX foci, suggesting that inhibition of this pathway would impair DNA repair. When combined with olaparib or evofosfamide, pimasertib treatment enhanced DNA damage and increased apoptosis. The combination of pimasertib with evofosfamide demonstrated increased anti-tumor activity in BRCA wild-type Mia-PaCa-2 xenograft model, but not in the BRCA mutated BxPC3 model.Our data suggest that targeted MEK inhibition leads to impaired homologous recombination DNA damage repair and increased PARP inhibition sensitivity in BRCA-2 proficient cancers.
Myeloproliferative neoplasms (MPNs) are hematological diseases that are driven by somatic mutations in hematopoietic stem and progenitor cells. These mutations include JAK2, CALR and MPL mutations as the main disease drivers, mutations driving clonal expansion, and mutations that contribute to progression of chronic MPNs to myelodysplasia and acute leukemia. JAK-STAT pathway has played a central role in the disease pathogenesis of MPNs. Mutant JAK2, CALR or MPL constitutively activates JAK-STAT pathway independent of the cytokine regulation. Symptomatic management is the primary goal of MPN therapy in ET and low-risk PV patients. JAK2 inhibitors and interferon-α are the established therapies in MF and high-risk PV patients.
Somatic mutations of calreticulin (CALR)have been identified as one of the main disease drivers of myeloproliferative neoplasms (MPNs), suggesting that developing drugs targeting mutant CALR is of great significance. Site-directed mutagenesis in the N-glycan binding domain (GBD)abolishes the ability of mutant CALRto oncogenically activate the thrombopoietin receptor (MPL).We thus hypothesized that a small molecule targeting the GBD might inhibit the oncogenicity of the mutant CALR. Using an in-silico molecular docking study, we identified candidate binders to the GBD of CALR. Further experimental validation of the hits identified a group of catechols inducing selective growth inhibitory effect on cells that depend on oncogenic CALRs for survival and proliferation. Apoptosis-inducing effects by the compound were significantly higher in the CALR mutated cells than in CALR wild type cells. Additionally, knockout or C-terminal truncation of CALR abolished the drug hypersensitivity in CALR mutated cells. We experimentally confirmed the direct binding of the selected compound to CALR, the disruption of the mutant CALR-MPL interaction, the inhibition of the JAK2-STAT5 pathway, and reduction of intracellular level of mutant CALR upon the drug treatment. Our data conclude that small molecules targeting the GBD of CALR can selectively kill CALR mutated cells by disrupting the CALR-MPL interaction and inhibiting the oncogenic signaling.
The data on the pharmacology of 4‐thiazolidinones showed that 5‐ene‐2‐(imino)amino‐4‐thiazolidinones are likely to comprise one of the most promising groups of compounds possessing anticancer properties. A series of 5‐arylidene‐2‐(4‐hydroxyphenyl)aminothiazol‐4(5H)‐ones was designed, synthesized, and studied against 10 leukemia cell lines, including the HL‐60, Jurkat, K‐562, Dami, KBM‐7, and some Ba/F3 cell lines. The structure–activity relationship analysis shows that almost all tested 5‐arylidene‐2‐(4‐hydroxyphenyl)aminothiazol‐4(5H)‐ones were characterized by ІС50 values lower or comparable to that of the control drug chlorambucil. Among the tested compounds, (5Z)‐5‐(2‐methoxybenzylidene)‐ (12), (5Z)‐(2‐ethoxybenzylidene)‐ (21), (5Z)‐5‐(2‐benzyloxybenzylidene)‐ (25), and (5Z)‐5‐(2‐allyloxybenzylidene)‐2‐(4‐hydroxyphenylamino)thiazol‐4(5H)‐ones (28) possessed the highest antileukemic activity at submicromolar concentrations (ІС50 = 0.10–0.95 µM).
Myeloproliferative neoplasms (MPNs) are characterized by a pathologic expansion of myeloid lineages. Mutations in JAK2, CALR and MPL genes are known to be three prominent MPN disease drivers. Mutant CALR (mutCALR) is an oncoprotein that interacts with and activates the thrombopoietin receptor (MPL) and represents an attractive target for targeted therapy of CALR mutated MPN. We generated a transgenic murine model with conditional expression of the human mutant exon 9 (del52) from the murine endogenous Calr locus. These mice develop essential thrombocythemia like phenotype with marked thrombocytosis and megakaryocytosis. The disease exacerbates with age showing prominent signs of splenomegaly and anemia. The disease is transplantable and mutCALR stem cells show proliferative advantage when compared to wild type stem cells. Transcriptome profiling of hematopoietic stem cells revealed oncogenic and inflammatory gene expression signatures. To demonstrate the applicability of the transgenic animals for immunotherapy, we treated mice with monoclonal antibody raised against the human mutCALR. The antibody treatment lowered platelet and stem cell counts in mutant mice. Secretion of mutCALR did not constitute a significant antibody sink. This animal model not only recapitulates human MPN but also serves as a relevant model for testing immunotherapeutic strategies targeting epitopes of the human mutCALR.
Myeloproliferative neoplasms (MPNs) are a group of hematopoietic stem cell disorders driven by mutations that constitutively activate physiologic signal transduction pathways essential for hematopoiesis. The majority of patients with classical MPNs harbor mutations within the Janus activated kinase 2 (JAK2), calreticulin (CALR), or thrombopoietin receptor (MPL) genes. The occurrence of driver mutations among patients is mutually exclusive but rare double positive cases have been reported. Employment of targeted sequencing methods for diagnostics revealed more double positive cases and reviewing published studies we estimate the CALR and JAK2 double positive MPN frequency to be about 0.5% in all MPNs and 2% in essential thrombocythemia. However, the mutual exclusivity of CALR and JAK2 mutations in double positive cases was confirmed at single cell level in few studies where clonogenic assays were performed with subsequent genotyping of colonies. In our MPN biobank of over 800 samples, we identified one case diagnosed with PMF, carrying both in JAK2 and CALR, with allelic burdens of 8% and 41%, respectively. Using a clonogenic assay, we confirmed mutual exclusivity of the mutations at CFU level confirming previous findings. Mutations can be mutually exclusive due to their synthetic lethal interaction. Such synthetic lethal interaction has been recently described in splicing factor mutated MDS, showing that SF3B1 and SRSF2 double mutant hematopoietic cells (HSC) have reduced fitness in vivo providing explanation why such patients are never observed. In this study, we tested the hypothesis that JAK2-V617F and CALR-del52 mutations are synthetic lethal if they occur in the same HSC. We have generated mice that co-expresses both JAK2-V617F and CALR-del52 mutations in hematopoietic lineages and analyzed their phenotype. First, we co-expressed JAK2-V617F and CALR-del52 on the Vav1-Cre backgound in which Cre recombinase activates the floxed transgenes in embryonic HSC. Double positive offspring were born at expected Mendelian frequency compared to single positive littermates, suggesting no signs of synthetic lethality in utero. The phenotype of the JAK2-V617F and CALR-del52 double positive mice was significantly more severe compared to single mutant mice. More specifically, double positive mice showed more pronounced splenomegaly, higher white blood cell, lymphocyte, granulocyte, monocyte, and platelet counts in peripheral blood. In the bone marrow, double positive mice had more prominent megakaryocyte dyspoiesis and altered myeloid to erythroid ratios, without evident myelofibrosis as observed in histological sections. This increase in megakaryocyte numbers was also confirmed by FACS. In addition, double positive mice had more obscured follicular architecture and more signs of enhanced extramedullary hematopoiesis in the spleen, and more pronounced megakaryocytic sequestration in the lungs when compared to the JAK2-V617F histology findings. These mice also had lower overall survival compared to the JAK2-V617F and CALR-del52 mice. Next, we performed competitive bone marrow transplantation (BMT) to examine HSC fitness in primary and secondary transplants. Wild type bone marrow (BM) derived from F1 hybrid CD45.1/CD45.2 mice was mixed with BM form either mice bearing single mutation or double mutations (CD45.2), and ingrafted into CD45.1 recipients. The changes in chimerism were followed in peripheral blood by FACS. Double positive BM engrafted recipients equally well as JAK2-V617F or CALR-del52 cells suggesting no functional defect at HSC level. Same results were seen also in secondary BMT. In summary, double positive mice have an enhanced MPN phenotype with lower overall survival compared to single positive JAK2-V617F and CALR-del52 animals. Our results suggest that the mutual exclusivity of MPN driver mutations JAK2-V617F and CALR-del52 is not due to synthetic lethality or loss of HSC fitness. It is possible that once the second mutation is acquired, JAK2-V617F and CALR-del52 double positive cells do not gain additional competitive advantage over single positive HSCs, and therefore, do not grow out into a significant population. Another reason why we do not observe JAK2-V617F and CALR-del52 double positive colonies in patients is the very low likelihood of such HSC arising. Our data shows that such MPN patients may be found and very likely will have more severe MPN. Disclosures No relevant conflicts of interest to declare.
Mutations of calreticulin (CALR) are the second most prevalent driver mutations in essential thrombocythemia and primary myelofibrosis. To identify potential targeted therapies for CALR mutated myeloproliferative neoplasms, we searched for small molecules that selectively inhibit the growth of CALR mutated cells using high-throughput drug screening. We investigated 89 172 compounds using isogenic cell lines carrying CALR mutations and identified synthetic lethality with compounds targeting the ATR-CHK1 pathway. The selective inhibitory effect of these compounds was validated in a co-culture assay of CALR mutated and wild-type cells. Of the tested compounds, CHK1 inhibitors potently depleted CALR mutated cells, allowing wild-type cell dominance in the co-culture over time. Neither CALR deficient cells nor JAK2V617F mutated cells showed hypersensitivity to ATR-CHK1 inhibition, thus suggesting specificity for the oncogenic activation by the mutant CALR. CHK1 inhibitors induced replication stress in CALR mutated cells revealed by elevated pan-nuclear staining for γH2AX and hyperphosphorylation of RPA2. This was accompanied by S-phase cell cycle arrest due to incomplete DNA replication. Transcriptomic and phosphoproteomic analyses revealed a replication stress signature caused by oncogenic CALR, suggesting an intrinsic vulnerability to CHK1 perturbation. This study reveals the ATR-CHK1 pathway as a potential therapeutic target in CALR mutated hematopoietic cells.
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