1. Prospective Clinical Genomic Profiling of Ewing Sarcoma: ERF and FGFR1 Mutations as Recurrent Secondary Alterations of Potential Biologic and Therapeutic Relevance
- Author
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Ogura, Koichi, Elkrief, Arielle, Bowman, Anita S, Koche, Richard P, de Stanchina, Elisa, Benayed, Ryma, Mauguen, Audrey, Mattar, Marissa S, Khodos, Inna, Meyers, Paul A, Healey, John H, Tap, William D, Hameed, Meera, Zehir, Ahmet, Shukla, Neerav, Sawyers, Charles, Bose, Rohit, Slotkin, Emily, and Ladanyi, Marc
- Subjects
Biomedical and Clinical Sciences ,Oncology and Carcinogenesis ,Biotechnology ,Pediatric Cancer ,Genetics ,Human Genome ,Pediatric ,Clinical Research ,Cancer ,2.1 Biological and endogenous factors ,Aetiology ,Adult ,Biological Products ,Genomics ,Humans ,Mutation ,Neuroectodermal Tumors ,Primitive ,Peripheral ,Prospective Studies ,Receptor ,Fibroblast Growth Factor ,Type 1 ,Repressor Proteins ,Sarcoma ,Ewing ,United States ,Oncology and carcinogenesis - Abstract
PurposeEwing sarcoma (ES) is a primitive sarcoma defined by EWSR1-ETS fusions as the primary driver alteration. To better define the landscape of cooperating secondary genetic alterations in ES, we analyzed clinical genomic profiling data of 113 patients with ES, a cohort including more adult patients (> 18 years) and more patients with advanced stage at presentation than previous genomic cohorts.MethodsThe data set consisted of patients with ES prospectively tested with the US Food and Drug Administration-cleared Memorial Sloan Kettering-Integrated Mutation Profiling of Actionable Cancer Targets large panel, hybrid capture-based next-generation sequencing assay. To assess the functional significance of ERF loss, we generated ES cell lines with increased expression of ERF and lines with knockdown of ERF. We assessed cell viability, clonogenic growth, and motility in these ES lines and performed transcriptomic and epigenetic analyses. Finally, we validated our findings in vivo using cell line xenografts.ResultsNovel subsets were defined by recurrent secondary alterations in ERF, which encodes an ETS domain transcriptional repressor, in 7% of patients (five truncating mutations, one deep deletion, and two missense mutations) and in FGFR1 in another 2.7% (one amplification and two known activating mutations). ERF alterations were nonoverlapping with STAG2 alterations. In vitro, increased expression of ERF decreased tumor cell growth, colony formation, and motility in two ES cell lines, whereas ERF loss induced cellular proliferation and clonogenic growth. Transcriptomic analysis of cell lines with ERF loss revealed an increased expression of genes and pathways associated with aggressive tumor biology, and epigenetic, chromatin-based studies revealed that ERF competes with EWSR1-FLI1 at ETS-binding sites.ConclusionOur findings open avenues to new insights into ES pathobiology and to novel therapeutic approaches in a subset of patients with ES.
- Published
- 2022