Project description:Fusion-positive rhabdomyosarcoma is an aggressive pediatric cancer molecularly characterized by arrested myogenesis. The defining genetic driver, PAX3::FOXO1, encodes a chimeric gain-of-function transcription factor. An incomplete understanding of PAX3::FOXO1’s in vivo chromatin regulatory mechanisms has hindered therapeutic development. Here, we establish a PAX3::FOXO1 zebrafish injection model and a semi-automated ChIP-seq normalization strategy to evaluate how PAX3::FOXO1 initially interfaces with and modulates chromatin in a developmental context. We find that PAX3::FOXO1 interacts with inaccessible chromatin through partial/homeobox motif recognition consistent with pioneering activity. However, PAX3::FOXO1-genome binding through a composite paired box/homeobox motif alters chromatin accessibility and redistributes H3K27ac to activate neural transcriptional programs. We uncover neural signatures that are highly representative of clinical rhabdomyosarcoma gene expression programs that are enriched following chemotherapy. Overall, we identify partial/homeobox motif recognition as a key mode for PAX3::FOXO1 pioneer function and identify neural signatures as a potentially critical PAX3::FOXO1 tumor initiation event. 

Project description:Fusion-positive rhabdomyosarcoma is an aggressive pediatric cancer molecularly characterized by arrested myogenesis. The defining genetic driver, PAX3::FOXO1, encodes a chimeric gain-of-function transcription factor. An incomplete understanding of PAX3::FOXO1’s in vivo chromatin regulatory mechanisms has hindered therapeutic development. Here, we establish a PAX3::FOXO1 zebrafish injection model and a semi-automated ChIP-seq normalization strategy to evaluate how PAX3::FOXO1 initially interfaces with and modulates chromatin in a developmental context. We find that PAX3::FOXO1 interacts with inaccessible chromatin through partial/homeobox motif recognition consistent with pioneering activity. However, PAX3::FOXO1-genome binding through a composite paired box/homeobox motif alters chromatin accessibility and redistributes H3K27ac to activate neural transcriptional programs. We uncover neural signatures that are highly representative of clinical rhabdomyosarcoma gene expression programs that are enriched following chemotherapy. Overall, we identify partial/homeobox motif recognition as a key mode for PAX3::FOXO1 pioneer function and identify neural signatures as a potentially critical PAX3::FOXO1 tumor initiation event. 

Project description:PAX3-FOXO1 is a fusion transcription factor characteristic for the majority of alveolar rhabdomyosarcoma tumors. It is the main oncogenic driver and deregulates expression of PAX3 target genes. The PAX3-FOXO1 target gene signature was determined in the Rh4 alveolar rhabdomyosarcoma cell line.

Project description:To investigate the effect of PAX3-FOXO1 and B7-H3 in rhabdomyosarcoma, Rh-30 (PAX3-FOXO1 positive rhabdomyosarcoma cell line) was transfected by siPAX3-FOXO1 or siB7-H3. After knockdown, total RNA was extracted and analyzed. As a result, some genes and pathways, such as chemotaxis, differentiation, and INF-gamma production were comonnly effected by PAX3-FOXO1 and B7-H3.

Project description:PAX3-FOXO1 is a fusion transcription factor that is the main driver of tumorigenesis leading to the development of alveolar rhabdomyosarcoma (aRMS). Since aRMS cells are addicted to PAX3-FOXO1 activity, the fusion protein also represents a major target for therapeutic interference, which is however challenging as transcription factors usually cannot be inhibited directly by small molecules. Hence, characterization of the biology of PAX3-FOXO1 might lead to the discovery of new possibilities for an indirect inhibition of its activity. Here, our goal was to characterize the proteomic neighborhood of PAX3-FOXO1 and to find candidates potentially affecting its activity and tumor cell viability. Towards this aim, we expressed BirA fused versions of PAX3-FOXO1 (N- and C-terminal) in HEK293T cells under presence of biotin. In the control setup, we expressed the BirA enzyme alone. After Streptavidin purification of biotinylated proteins, we performed mass spectrometry and quantified relative abundances compared to control conditions. This enabled us to determine PAX3-FOXO1 proximal proteins, which we investigated further in orthogonal endogenous systems.

Project description:Rhabdomyosarcoma (RMS), a malignancy of impaired myogenic differentiation, is the most common soft tissue pediatric cancer. PAX3-FOXO1 oncofusions drive the majority of the clinically more aggressive fusion-positive rhabdomyosarcoma (FP-RMS). Recent studies have established an epigenetic basis for PAX3-FOXO1-driven oncogenic processes. However, details of PAX3-FOXO1 epigenetic mechanisms, including interactions with, and dependence on, other chromatin and transcription factors, are incompletely understood. We previously identified a novel disease-promoting epigenetic axis in RMS, involving the histone demethylase KDM3A and the ETS1 transcription factor, and demonstrated that this epigenetic axis interfaces with PAX3-FOXO1 both phenotypically and transcriptomically, including co-regulation of biological processes and genes important to FP-RMS progression. In this study, we demonstrate that KDM3A and ETS1 colocalize with PAX3-FOXO1 to enhancers of important disease-promoting genes in FP-RMS, including FGF8, IL4R, and MEST, as well as PODXL, which we define herein as a new FP-RMS-promoting gene. We show that ETS1, which is induced by both PAX3-FOXO1 and KDM3A, exists in complex with PAX3-FOXO1, and augments PAX3-FOXO1 chromatin occupancy. We further show that the PAX3-FOXO1/ETS1 complex can be disrupted by the clinically relevant small molecule inhibitor YK-4-279. YK-4-279 displaces PAX3-FOXO1 from chromatin and interferes with PAX3-FOXO1-dependent gene regulation, resulting in potent inhibition of growth and invasive properties in FP-RMS, along with downregulation of FGF8, IL4R, MEST and PODXL expression. We additionally show that, in some FP-RMS, KDM3A also increases PAX3-FOXO1 levels. Together, our studies illuminate mechanisms of action of the KDM3A/ETS1 regulatory module, and reveal novel targetable mechanisms of PAX3-FOXO1 chromatin complex regulation, in FP-RMS.

Project description:Rhabdomyosarcoma (RMS), a malignancy of impaired myogenic differentiation, is the most common soft tissue pediatric cancer. PAX3-FOXO1 oncofusions drive the majority of the clinically more aggressive fusion-positive rhabdomyosarcoma (FP-RMS). Recent studies have established an epigenetic basis for PAX3-FOXO1-driven oncogenic processes. However, details of PAX3-FOXO1 epigenetic mechanisms, including interactions with, and dependence on, other chromatin and transcription factors, are incompletely understood. We previously identified a novel disease-promoting epigenetic axis in RMS, involving the histone demethylase KDM3A and the ETS1 transcription factor, and demonstrated that this epigenetic axis interfaces with PAX3-FOXO1 both phenotypically and transcriptomically, including co-regulation of biological processes and genes important to FP-RMS progression. In this study, we demonstrate that KDM3A and ETS1 colocalize with PAX3-FOXO1 to enhancers of important disease-promoting genes in FP-RMS, including FGF8, IL4R, and MEST, as well as PODXL, which we define herein as a new FP-RMS-promoting gene. We show that ETS1, which is induced by both PAX3-FOXO1 and KDM3A, exists in complex with PAX3-FOXO1, and augments PAX3-FOXO1 chromatin occupancy. We further show that the PAX3-FOXO1/ETS1 complex can be disrupted by the clinically relevant small molecule inhibitor YK-4-279. YK-4-279 displaces PAX3-FOXO1 from chromatin and interferes with PAX3-FOXO1-dependent gene regulation, resulting in potent inhibition of growth and invasive properties in FP-RMS, along with downregulation of FGF8, IL4R, MEST and PODXL expression. We additionally show that, in some FP-RMS, KDM3A also increases PAX3-FOXO1 levels. Together, our studies illuminate mechanisms of action of the KDM3A/ETS1 regulatory module, and reveal novel targetable mechanisms of PAX3-FOXO1 chromatin complex regulation, in FP-RMS.

Project description:Hallmarks of the alveolar subclass of Rhabdomyosarcoma are chromosomal translocations that generate PAX3-FOXO1 or PAX7-FOXO1 chimeric transcription factors. Both PAX-FOXO1s drive related cell transformation in animal models, yet the two mutations are associated with distinct pathological manifestations in patients. To evaluate the mechanisms underlying these differences, we generated isogenic fibroblast lines expressing either PAX-FOXO1 paralog. Mapping their genome recruitment using CUT&Tag revealed that the two chimeric proteins have distinct DNA binding preferences. Furthermore, PAX7-FOXO1 causes stronger de novo transactivation of its bound regions than PAX3-FOXO1, resulting in greater transcriptomic dynamics involving genes regulating cell shape and cycle. Consistently, PAX3-FOXO1 accentuates fibroblast cellular traits associated with contractility and surface adhesion and limits entry to M phase. Instead, PAX7-FOXO1 pushes cells to adopt an amoeboid-like shape, reduce S phase entry and provokes more genome instabilities. Altogether, our results demonstrate that PAX7-FOXO1 has a greater chromatin remodelling and transactivating abilities and is more deleterious to cells than PAX3-FOXO1. Altogether our results argue that the diversity in rhabdomyosarcoma manifestation stems, in part, from the diverging transcriptional activity of PAX3-FOXO1 and PAX7-FOXO1. Furthermore, PAX7-FOXO1 pronounced deleterious effects provides an explanation for the low frequency of the translocation generating this factor in Rhabdomyosarcoma patients.

Project description:The goal of this study was to explore in detail how the chromatin remodeler and NuRD subunit CHD4 controls the oncogenic signature of the tumor driver and fusion protein PAX3-FOXO1 in fusion-positive rhabdomyosarcoma. To this aim, we defined the interactome of CHD4 by LC-MS, identified its location in the genome by ChIP-seq, assessed its influence on DNA accessibility by DNase I hypersensitivity assays, and determined its target genes by RNA-seq.

Project description:We developed a new method for ChIP-seq with per-cell normalization (pc-ChIP-seq) to define PAX3-FOXO1 localization in rhabdomyosarcoma (RMS). We report novel pioneer function for the major driver oncogene in RMS, with nucleosome-motif targeting and kinetic displacement of nucleosomes in human cells.