Abstract Fusion-positive rhabdomyosarcoma is an aggressive pediatric cancer lacking curative therapies, and outcomes for children with this disease have not improved in decades. The chimeric transcription factor PAX3::FOXO1 is the most common and lethal driver of fusion-positive rhabdomyosarcoma, and it consists of the DNA binding domains of PAX3 fused to the transactivation domain of FOXO1. Despite its well-established essentiality for tumorigenesis, how PAX3::FOXO1 initially generates a tumorigenic cell state has been challenging to study due to the lack of in vivo models expressing the fusion-oncogene at accessible early developmental time points. Here, we developed a novel zebrafish mRNA injection model that ubiquitously expresses PAX3::FOXO1 during gastrulation representing all three germ layers. Using this high-throughput model, we used ChIP-seq to identify initial in vivo PAX3::FOXO1 binding sites and targets. PAX3::FOXO1 has pioneering activity, where it can utilize partial-motif recognition to bind to inaccessible chromatin and alter chromatin structure. With biochemical and 2D chromatin sequencing approaches in our model, we find evidence for in vivo PAX3::FOXO1 pioneering activity. PAX3::FOXO1 consists of two DNA binding domains, a paired and homeobox domain, and we demonstrate a new mode of pioneering activity driven by its homeobox domain given a strong enrichment of homeobox-related motifs at PAX3::FOXO1 binding sites. PAX3::FOXO1 activity in developing zebrafish embryos results in an arrested development phenotype and transcriptional signatures enriched for pathways such as an inhibition of segmentation and myogenic development. Critically, we find that PAX3::FOXO1 directly activates neural-related gene targets by increasing chromatin accessibility and re-distribution of the active histone mark H3K27Ac to these loci. These discoveries are particularly striking because rhabdomyosarcoma is traditionally associated with skeletal muscle characteristics. With our findings, we hypothesize neural gene activation is a critical mechanism for fusion-positive rhabdomyosarcoma tumor initiation and could be a critical pathway across various stages of rhabdomyosarcoma tumorigenesis. This hypothesis agrees with our previous discovery of a novel PAX3::FOXO1 cooperating neural transcription factor, HES3, which we find is directly activated by PAX3::FOXO1 in our mRNA injection model. Our long-term goal is to utilize this versatile model to functionally evaluate cooperation between PAX3::FOXO1 and both canonical rhabdomyosarcoma and neural transcription factors. Our approach will employ a cross-species comparative analysis across this injection model, our zebrafish tumor models, other model systems, and patient data. This work will identify conserved targets and mechanisms of PAX3::FOXO1 tumorigenesis that could become new therapeutic vulnerabilities. Citation Format: Jack Kucinski, Cenny Taslim, Alexi Tallan, Matthew Cannon, Katherine Silvius, Benjamin Stanton, Genevieve Kendall. Rhabdomyosarcoma fusion-oncogene alters the chromatin landscape to initially drive a neural signature in vivo [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 2861.
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