Project description:The crizotinib–resistant ALKF1174L mutation arises de novo in neuroblastoma (NB) and is acquired in ALK translocation-driven cancers, lending impetus to the development of novel ALK inhibitors with different modes of action. The diaminopyrimidine TAE684 and its derivative ceritinib (LDK378), which are structurally distinct from crizotinib, are active against NB cells expressing ALKF1174L. Here we demonstrate acquired resistance to TAE684 and LDK378 in ALKF1174L-driven human NB cells that is linked to overexpression and activation of the AXL tyrosine kinase and epithelial-to-mesenchymal transition (EMT). AXL phosphorylation conferred TAE684 resistance to NB cells through upregulated ERK signaling. Inhibition of AXL partly rescued TAE684 resistance, resensitizing these cells to this compound. AXL activation in resistant cells was mediated through increased expression of the active form of its ligand, GAS6, which also served to stabilize the AXL protein. Although ectopic expression of AXL and TWIST2 individually in TAE684-sensitive parental cells led to the elevated expression of mesenchymal markers and invasive capacity, only AXL overexpression induced resistance to TAE684 as well. TAE684-resistant cells showed greater sensitivity to HSP90 inhibition than did their parental counterparts, with downregulation of AXL and AXL-mediated ERK signaling. Our studies indicate that aberrant AXL signaling and development of an EMT phenotype underlie resistance of ALKF1174L-driven NB cells to TAE684 and its derivatives. We suggest that the combination of ALK and AXL or HSP90 inhibitors be considered to delay the emergence of such resistance. In order to understand the molecular mechanisms driving resistance to ALK inhibition in ALK-mutated neuroblatoma, we established cell line models of resistance to TAE684, an ALK inhibitor, by treating SH-SY5Y cells (bearing the ALKF1174L mutation) with increasing concentration of this compound over time. We then performed an analysis of gene expression changes genome wide using Affymetrix U133 Plus 2 arrays, by comparing the TAE684-sensitive parental SH-SY5Y cells to the TAE684-resistant SH-SY5Y cells (named SY5Y-TR1). For that experiment, we analyzed gene expression variations by comparing the parental SH-SY5Y (control sample) to the resistant SY5Y-TR1 cells. So 2 samples were analyzed, with 3 replicates run for each.

Project description:Anaplastic lymphoma kinase tyrosine kinase inhibitors (ALK-TKIs) induce a dramatic response in non–small cell lung cancer (NSCLC) patients with the ALK fusion gene. However, acquired resistance to ALK-TKIs in lung cancer cells remains an inevitable problem: ALK secondary mutations and bypass pathways have been reported as major resistance mechanisms. In this study, we aimed to discover a novel mechanism of acquired resistance to ALK-TKIs and a strategy to conquer ALK-positive lung cancer. We established three types of ALK-TKI (crizotinib, alectinib and ceritinib)–resistant H2228 non-small cell lung cancer cell lines by high exposure and stepwise methods. We found these cells showed a loss of ALK signaling, overexpressed AXL with epithelial–mesenchymal transition (EMT), and had cancer stem cell–like properties. Similarly, we demonstrated that TGF-β1 treated H2228 cells also showed AXL overexpression with EMT features and ALK-TKI–resistance. The AXL inhibitor, R428, or HSP90 inhibitor, ganetespib, were effective in reversing ALK-TKI–resistance and EMT changes in both ALK-TKI–resistant and TGF-β1–exposed H2228 cells. Progression-free survival of ALK-positive NSCLC patients with AXL overexpression was shorter than that of patients who underwent crizotinib therapy and showed low AXL expression. Thus, we found ALK signaling-independent AXL overexpression and EMT features were commonly involved in intrinsic and acquired resistance to first and second generation ALK-TKIs. This suggests AXL and HSP90 inhibitors may be promising therapeutic drugs to overcome tumor cells in ALK-positive NSCLC patients.

Project description:Despite the initial benefit of the tyrosine kinase inhibitors targeting ALK gene fusions in non-small cell lung cancer, resistance to ALK inhibitors is almost inevitable. To determine the acquired resistance mechanism to ALK inhibition, we generated crizotinib-resistant ALK lines by chronically treating H3122 cells (driven by EML4-ALK) with an ALK inhibitor, crizotinib for approximately 3 months. RNA-seq and differential expression analyses were performed to determine the transcriptional changes of H3122-CR cells in comparison to parental H3122 cells. Because we demonstrated EGFR could mediate the early adaptive resistance to crizotinib, we further explored the mechanism that contributes to the resistance to the combination of crizotinib and afatinib. H3122-CAR (crizotinib and afatinib-resistant) cells were generated by treating them with a combination of crizotinib and afatinib for approximately 6 months and then profiled by RNA-seq to determine the associated transcriptional reprogramming.

Project description:Starting with H3122 cells, which harbor the EML4-ALK E13;A20 fusion and are known to be sensitive to ALK tyrosine kinase inhibitors, we generated isogenic pairs of ALK TKI sensitive and ALK TKI resistant cell lines using established methods (see Chmeliecki, J et al Science Trans Med 2011). We modeled resistance against the currently FDA approved ALK TKI, crizotinib (also called PF-1066). We also modeled resistance against a novel more potent ALK inhibitor, X-376 (ref: Lovly, CM et al Cancer Research 2011). We compared gene expression profiles between the 'parental' (ALK TKI sensitive) H3122 cells and the drug resistant cells (H3122 CR for Crizotinib resistant cells and H3122 XR for X-376 resistant cells).

Project description:We analyzed the chromatin occupancies of active (H3K27ac and H3K4me3) and repressive (H3K27me3) histone marks in adrenergic (SH-SY5Y parental) and mesenchymal (SH-SY5Y LDK-resistant and SH-EP) neuroblastoma cells.

Project description:Crizotinib is a first-line targeted therapy against EML4-ALK fusion in non-small cell lung cancer (NSCLC), but the increased resistance limits its clinical application. However, the mechanisms underlying such resistance are largely unexplored. The present study identified ALK protein overexpression in crizotinib-resistant H3122CR cells through immunoblotting. Then, liquid chromatography tandem mass spectrometry-based metabolomics was adopted to investigate metabolic responses. Crizotinib resistance was associated with the reduction of the total lipid content and the increase of organic acid, featuring the upregulation of lipid metabolism. Fatty acid β-oxidation pathway reprogrammed crizotinib-sensitive metabolome to crizotinib-resistant metabolome, resulting in crizotinib resistance. These findings reveal a previously unknown mechanism of crizotinib resistance and suggest promising applications of this approach in prognostic prediction and tailored therapeutics of NSCLC patients.

Project description:<p>The purpose of the study was to compare gene expression profiles from a cohort of crizotinib-resistant ALK-rearranged lung tumors and a cohort of treatment-naive ALK-rearranged lung tumors. Expression profiles were generated by RNA-seq. In parallel, gene expression profiles were obtained from ALK-rearranged lung cancer cell lines in the presence or absence of the ALK inhibitor TAE684. Gene expression profiles were also obtained from ALK-rearranged cells ectopically expressing genes associated with ALK inhibitor resistance that were identified from a functional genetic study.</p>

Project description:Aberrant activation of Anaplastic Lymphoma Kinase (ALK) drives neuroblastoma (NB). Previous work has identified the RET receptor tyrosine kinase (RTK) as a downstream target of ALK activity in NB models. We show here that ALK activation in response to ALKAL2 ligand results in the rapid phosphorylation of RET in NB cells, providing additional insight into the contribution of RET to the ALK driven gene signature in NB. To further address the role of RET in NB, RET knock-out (KO) SK-N-AS cells were generated by CRISPR/Cas9 genome engineering. Gene expression analysis of RET KO NB cells identified a reprogramming of NB cells to a mesenchymal (MES) phenotype that was characterized by increased migration and upregulation of the AXL and MET RTKs as well as integrins and extracellular matrix components. Strikingly, the upregulation of AXL in the absence of RET reflects the development timeline observed in the neural crest as progenitor cells undergo differentiation during embryonic development. Together, these findings suggest that a MES phenotype is promoted in mesenchymal NB cells in the absence of RET, reflective of a less differentiated developmental status.

Project description:To investigate a possible candidate for overcoming the acquired resistance to ALK-TKI, we established an in vitro model of acquired resistance to crizotinib (H3122-CR) by exposing EML4-ALK–positive H3122 lung cancer cells to increasing doses of crizotinib.

Project description:We used a CRISPR-Cas9-based genome-wide guide RNA (sgRNA) library to identify genes responsible for driving drug resistance in ALK+ ALCL cells under crizotinib treatment.We screened 4 diffrerent ALK+ ALCL cell lines, TS, SU-DHL1, COST and KARPAS299. Every cell line was transduced with GeCKO A and GeCKO B sgRNA libraries separately. After puromycin selection, cells were splitted into 3 groups: Day 0 (baseline time point), crizotinib treated group (treated for 14 days) and DMSO treated group (treated for 14 days). TS and SU-DHL1 cells were treated with 40nM criztonib for 14 days and at the end of this period crizotinib concentration was increased to 80nM. COST cells received 50nM crizotinib for 14 days. KARPAS299 cells first received 50nM crizotinib for 14 days and at the end of this period crizotinib concentration was increased to 100nM. Crizotinib concentrations were determined based on their sensitivity for crizotinib for each cell line. The screening was repeated twice for TS and SU-DHL1 ALK+ ALCL cells. DNA isolotation was performed from all groups and each sgRNA sequence served as a barcode for Next Generation Illumina-based DNA sequencing. We compared enriched sgRNA sequences between Day 0 and DMSO conditions. We found that while PTPN2 was a top hit for all 4 ALK+ ALCL cells, PTPN1 was a top hit for TS and SU-DHL1 cells. We subsequently validated roles of PTPN1 and PTPN2 in crizotinib resistance separately. We demonstrated that both PTPN1 and PTPN2 can drive crizotinib resistance in ALK+ ALCL cells. In this study, we found two phosphatases, PTPN1 and PTPN2, involved in drug resitance in ALK+ ALCL using a CRSIPR Cas9-based screening approach. These two phosphatases regulate ALK phospharylation and therefore affect downstream signalling pathways involved in tumor growth and proliferation.