Supplementary Methods, Figure Legends, Figures S1 - S6, Tables S1, S3 - S6, S8 - S15, S17 from The Genomic Landscape of Pediatric Ewing Sarcoma

Crompton, Brian D.; Stewart, Chip; Taylor-Weiner, Amaro; Alexe, Gabriela; Kurek, Kyle C.; Calicchio, Monica L.; Kiezun, Adam; Carter, Scott L.; Shukla, Sachet A.; Mehta, Swapnil S.; Thorner, Aaron R.; de Torres, Carmen; Lavarino, Cinzia; Suñol, Mariona; McKenna, Aaron; Sivachenko, Andrey; Cibulskis, Kristian; Lawrence, Michael S.; Stojanov, Petar; Rosenberg, Mara; Ambrogio, Lauren; Auclair, Daniel; Seepo, Sara; Blumenstiel, Brendan; DeFelice, Matthew; Imaz-Rosshandler, Ivan; Schwarz-Cruz y Celis, Angela; Rivera, Miguel N.; Rodriguez-Galindo, Carlos; Fleming, Mark D.; Golub, Todd R.; Getz, Gad; Mora, Jaume; Stegmaier, Kimberly

doi:10.1158/2159-8290.22530080.v1

Supplementary Methods, Figure Legends, Figures S1 - S6, Tables S1, S3 - S6, S8 - S15, S17 from The Genomic Landscape of Pediatric Ewing Sarcoma

journal contribution

posted on 2023-04-03, 20:44 authored by Brian D. Crompton, Chip Stewart, Amaro Taylor-Weiner, Gabriela Alexe, Kyle C. Kurek, Monica L. Calicchio, Adam Kiezun, Scott L. Carter, Sachet A. Shukla, Swapnil S. Mehta, Aaron R. Thorner, Carmen de Torres, Cinzia Lavarino, Mariona Suñol, Aaron McKenna, Andrey Sivachenko, Kristian Cibulskis, Michael S. Lawrence, Petar Stojanov, Mara Rosenberg, Lauren Ambrogio, Daniel Auclair, Sara Seepo, Brendan Blumenstiel, Matthew DeFelice, Ivan Imaz-Rosshandler, Angela Schwarz-Cruz y Celis, Miguel N. Rivera, Carlos Rodriguez-Galindo, Mark D. Fleming, Todd R. Golub, Gad Getz, Jaume Mora, Kimberly Stegmaier

This file contains supplementary methods, supplementary references, supplementary figures S1-S6, supplementary tables S1, S3-S6, S8-S15, and S17, and legends for all supplementary figures and tables. Supplementary Figure S1. Summary of Ewing sarcoma tumor and cell line cohorts. Supplementary Figure S2. RNASeq validation of mutations identified by WES and WGS. Supplementary Figure S3. Power calculations for the detection of significantly mutated genes. Supplementary Figure S4. Copy number variants in Ewing sarcoma tumors. Supplementary Figure S5. ETS1 deletions associated with EWS/FLI rearrangements. Supplementary Figure S6. Copy number variants in diagnostic vs. treated Ewing sarcoma tumors. Supplementary Figure S7. SCNAs in paired Ewing sarcoma tumor samples. Supplementary Table S1. Tissue samples. Supplementary Table S3. Multiply mutated genes. Supplementary Table S4. Rearrangements and fusions detected by WGS and RNASeq. Supplementary Table S5. Mutational significance for tumor/normal pairs. Supplementary Table S6. Rate of coding mutations in Ewing sarcoma tumors. Supplementary Table S8. Mutational significance for all tumors. Supplementary Table S9. Gene set enrichment analyses of mutated genes. Supplementary Table S10. Significance of arm-level SCNAs. Supplementary Table S11. Multiply mutated genes of interest in all sample cohorts. Supplementary Table S12. Immunohistochemical staining of STAG2 in Ewing sarcoma tumors. Supplementary Table S13. Gene set enrichment analyses of STAG2 expressing vs. STAG2 loss. Supplementary Table S14. Gene and gene-fragment RPKM Values for EWS and ETS genes. Supplementary Table S15. ETS1 copy-number changes. Supplementary Table S17. Gene set enrichment analyses of tumors vs. cell lines.

History

ARTICLE ABSTRACT

Pediatric Ewing sarcoma is characterized by the expression of chimeric fusions of EWS and ETS family transcription factors, representing a paradigm for studying cancers driven by transcription factor rearrangements. In this study, we describe the somatic landscape of pediatric Ewing sarcoma. These tumors are among the most genetically normal cancers characterized to date, with only EWS–ETS rearrangements identified in the majority of tumors. STAG2 loss, however, is present in more than 15% of Ewing sarcoma tumors; occurs by point mutation, rearrangement, and likely nongenetic mechanisms; and is associated with disease dissemination. Perhaps the most striking finding is the paucity of mutations in immediately targetable signal transduction pathways, highlighting the need for new therapeutic approaches to target EWS–ETS fusions in this disease.Significance: We performed next-generation sequencing of Ewing sarcoma, a pediatric cancer involving bone, characterized by expression of EWS–ETS fusions. We found remarkably few mutations. However, we discovered that loss of STAG2 expression occurs in 15% of tumors and is associated with metastatic disease, suggesting a potential genetic vulnerability in Ewing sarcoma. Cancer Discov; 4(11); 1326–41. ©2014 AACR.This article is highlighted in the In This Issue feature, p. 1243