Mutations in ALK signaling pathways conferring resistance to ALK inhibitor treatment lead to collateral vulnerabilities in neuroblastoma cells
Berlak, Mareike; Tucker, Elizabeth; Dorel, Mathurin; Winkler, Annika; McGearey, Aleixandria; Rodriguez-Fos, Elias; da Costa, Barbara Martins; Barker, Karen; Fyle, Elicia; Calton, Elizabeth; Eising, Selma; Ober, Kim; Hughes, Deborah; Koutroumanidou, Eleni; Carter, Paul; Stankunaite, Reda; Proszek, Paula; Jain, Neha; Rosswog, Carolina; Dorado-Garcia, Heathcliff; Molenaar, Jan Jasper; Hubank, Mike; Barone, Giuseppe; Anderson, John; Lang, Peter; Deubzer, Hedwig Elisabeth; Künkele, Annette; Fischer, Matthias; Eggert, Angelika; Kloft, Charlotte; Henssen, Anton George; Boettcher, Michael; Hertwig, Falk; Blüthgen, Nils; Chesler, Louis; Schulte, Johannes Hubertus
(2022) Molecular Cancer, volume 21, issue 1, pp. 1 - 19
(Article)
Abstract
Background: Development of resistance to targeted therapies has tempered initial optimism that precision oncology would improve poor outcomes for cancer patients. Resistance mechanisms, however, can also confer new resistance-specific vulnerabilities, termed collateral sensitivities. Here we investigated anaplastic lymphoma kinase (ALK) inhibitor resistance in neuroblastoma, a childhood cancer frequently affected by
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activating ALK alterations. Methods: Genome-wide forward genetic CRISPR-Cas9 based screens were performed to identify genes associated with ALK inhibitor resistance in neuroblastoma cell lines. Furthermore, the neuroblastoma cell line NBLW-R was rendered resistant by continuous exposure to ALK inhibitors. Genes identified to be associated with ALK inhibitor resistance were further investigated by generating suitable cell line models. In addition, tumor and liquid biopsy samples of four patients with ALK-mutated neuroblastomas before ALK inhibitor treatment and during tumor progression under treatment were genomically profiled. Results: Both genome-wide CRISPR-Cas9-based screens and preclinical spontaneous ALKi resistance models identified NF1 loss and activating NRASQ61K mutations to confer resistance to chemically diverse ALKi. Moreover, human neuroblastomas recurrently developed de novo loss of NF1 and activating RAS mutations after ALKi treatment, leading to therapy resistance. Pathway-specific perturbations confirmed that NF1 loss and activating RAS mutations lead to RAS-MAPK signaling even in the presence of ALKi. Intriguingly, NF1 loss rendered neuroblastoma cells hypersensitive to MEK inhibition. Conclusions: Our results provide a clinically relevant mechanistic model of ALKi resistance in neuroblastoma and highlight new clinically actionable collateral sensitivities in resistant cells.
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Keywords: ALK, Ceritinib, Collateral sensitivity, CRISPR screening, Lorlatinib, Neuroblastoma, NF1, NRAS, Resistance, Trametinib, Molecular Medicine, Oncology, Cancer Research
ISSN: 1476-4598
Publisher: BioMed Central
Note: Funding Information: Open Access funding enabled and organized by Projekt DEAL. Mareike Berlak is supported by the Berlin School of Integrative Oncology (BSIO). Elias Rodrigue-Fos is supported by the Alexander von Humboldt Foundation. Anton George Henssen is supported by the Deutsche Forschungsgemeinschaft (DFG, GermanResearch Foundation)–398299703 and the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program (grant agreement No.949172). Annette Künkele is participant in the BIH-Charité Advanced Clinician Scientist Pilotprogram funded by the Charité –Universitätsmedizin Berlin and the Berlin Institute of Health. Johannes Hubertus Schulte has received funding from the Innovative Medicines Initiative 2 Joint Undertaking under grant agreement No 116064-ITCC-P4-H2020-JTI-IMI2–2015-07. We also received funding by the German Cancer Consortium (DKTK) for sequencing experiments. Mike Hubank, Paula Proszek and Paul Carter were supported by the National Institute for Health Research (NIHR) Biomedical Research Centre at The Royal Marsden NHS Foundation Trust and The Institute of Cancer Research, London. Reda Stankunaite was funded by Christopher’s Smile. Deborah Hughes and Eleni Koutroumanidou were supported by Children with Cancer UK/Cancer Research UK SMPaeds (17–235/A24566). Louis Chesler was supported by the Institute of Cancer Research and The Higher Education Funding Council for England. Louis Chesler, Elizabeth Tucker, Barbara Martins da Costa, Karen Barker and Elicia Fyle were supported by the Cancer Research UK Programme Grant A28278. Elizabeth Calton was supported by Children with Cancer UK Clinical Research Fellowship – CWL022X. John Anderson was supported by the National Institute for Health Research (NIHR) Great Ormond Street Biomedical Research Centre. Neha Jain was supported by the Great Ormond Street Hospital Children’s Charity Ollie Anstey Brighter Future Fund. The research group of Jan Jasper Molenaar was supported by the COMPASS consortium (Award No. ERAPERMED2018–121 within the ERAPerMed framework). Funding Information: We especially thank Joern Toedling for developing a R code to evaluate Incucyte results and support throughout the project. We thank Filippos Klironomos for the Brunello plasmid pool sequence analysis, Kathy Astrahantseff for manuscript editing, Susan Cohn (University of Chicago) for providing the NBLW-R cell line and Louisa-Marie Kruetzfeldt for data upload to the sequencing read archive (SRA). The authors thank the Genomics and Proteomics Core facilities at DKFZ for sequencing support. Publisher Copyright: © 2022, The Author(s).
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