Comparative modes of chromatin engagement by PAX::FOXO1 fusions in rhabdomyosarcoma

SUMMARY Fusion positive rhabdomyosarcoma (FP-RMS) is an aggressive soft-tissue sarcoma that most frequently affects children and adolescents. Treatment options and outcomes for children with this cancer remain poor, non-specific, and broadly toxic despite decades of research. The defining molecular drivers of the more aggressive fusion-positive subtype of the disease arise from chromosomal translocations that fuse PAX3 or PAX7 to FOXO1 to form PAX3::FOXO1 or PAX7::FOXO1, encoding fusion oncoprotein transcription factors. Despite their high degree of similarity, PAX3::FOXO1 correlates with worse patient overall survival than PAX7::FOXO1. Previous work from our groups and others has revealed evidence focused in chromatin accessibility contexts that PAX3::FOXO1 has key characteristics of a pioneer transcription factor, a specialized subclass of transcription factors that can bind nucleosomal DNA prior to generation of local accessibility. However, evidence at the genome scale for PAX3/7::FOXO1 direct nucleosome targeting, prior to the accessibility step in pioneering, has remained elusive and challenging to capture methodologically for RMS fusion oncoproteins. In this work, we compare the cellular functions of these PAX::FOXO1 fusions, including new approaches for identifying nucleosome targeting at the genome scale. We find that in zebrafish RMS initiation models, the fusions initially activate similar neural transcriptional programs but to different extents, and we further evaluate their mechanisms in RMS cells at the genome scale with modified MNase XChIP to detect nucleosome and subnucleosome fusion/chromatin binding. In establishing our cross-species comparative oncology approach, we report, to our knowledge, the first high resolution nucleosome positioning data in rhabdomyosarcoma. We find that both PAX::FOXO1 fusions bind nucleosomal DNA, but with varied motif preferences and histone mark co-localization patterns. Altogether, we establish the nucleosome targeting functions of PAX7::FOXO1 and PAX3::FOXO1 pioneering and uncover key mechanistic distinctions for chromatin engagement of the two most common RMS fusion oncoproteins. HIGHLIGHTS Partially overlapping gene signatures are activated by PAX3/7::FOXO1 in vivo Modified MNase ChIP reveals PAX3/7::FOXO1 bind nucleosomal and subnucleosomal DNA PAX7::FOXO1 binds degenerate paired/homeobox motifs within nucleosome targets Each fusion engages distinct nucleosomal gene targets Competing Interest Statement The authors have declared no competing interest.