The hegemonic EWSR1::ETS oncogene overrules core regulatory circuitry mechanisms in Ewing sarcoma [ChIP-seq]

Ewing sarcoma is an aggressive bone tumor of adolescence characterized by a hallmark EWSR1::FLI1 fusion oncogene. This chimeric protein drives tumorigenesis by reshaping transcriptional and epigenetic landscapes. However, how it is transcriptionally regulated and whether additional master transcription factors (MTFs) form a core regulatory circuit (CRC) in Ewing sarcoma remain unclear. Here, using an extensive panel of Ewing sarcoma cell lines and primary tumors, we mapped super-enhancers and identified strong enrichment of GGAA microsatellites, confirming their specificity to Ewing sarcoma as compared to other pediatric cancers and normal tissues. Integrating transcriptomic, epigenetic, 3D chromatin conformation, and dependency data, we predicted a set of MTFs potentially comprising a CRC. However, functional validation demonstrated that these MTFs neither establish auto-regulatory loops nor confer proliferative dependencies typical of CRC s in other pediatric tumors. Instead, EWSR1::FLI1 emerged as an “hegemonic” oncogene, regulating the expression of these MTFs without reciprocal regulation. Knockdown (KD) of EWSR1::FLI1 strongly reduced Ewing sarcoma cell proliferation and shifted H3K27ac profiles toward mesenchymal states, whereas silencing of individual or combined MTFs did not alter cell growth or EWSR1::FLI1 expression. These findings highlight the absence of a classical CRC in Ewing sarcoma and emphasize EWSR1::FLI1 as the dominant oncogene but also as a major vulnerability in this disease. Overall design: ChIP-seq (H3K27ac and FLI1) were performed to complete the actual catalog of Ewing sarcoma cell line. We also generate H3K27ac profile after inhibiting the oncogene EWSR1::ETS and in some MSC models. Some transcription factors defined as CRC candidates were also sequenced (IKZF2, POU3F2, SOX6)