Project description:Ewing sarcomas are driven by chromosomal translocations that fuse a FET RNA‑binding protein to an ETS transcription factor, most commonly generating the EWS-FLI1 fusion oncoprotein. EWS-FLI1 engages GGAA microsatellite repeats to create de novo enhancers and activate oncogenic transcriptional programs—a neomorphic gain-of-function essential for Ewing sarcoma pathogenesis. In addition to the truncal fusion, recurrent loss‑of‑function alterations in the cohesin subunit STAG2 occur in approximately 10–15% of Ewing sarcomas and are associated with adverse clinical outcomes. Yet, how STAG2-cohesin deficiency remodels EWS-FLI1 chromatin occupancy and gene regulatory network remains incompletely understood. Here, using genetic STAG2 loss‑of‑function models combined with functional multi-omic profiling, we show that STAG2-cohesin loss in Ewing sarcoma cells reprograms the EWS-FLI1 cistrome by shifting its binding preference at GGAA microsatellite repeats. Despite increased EWS–FLI1 protein abundance, disruption of STAG2 eliminates more than 40% of EWS-FLI1 binding sites. The lost sites are enriched for elements harboring 1–4 GGAA repeat motifs, with a simultaneous gain in EWS-FLI1 binding at multimeric enhancers containing ≥5 GGAA repeat sequences. Notably, reprogrammed EWS-FLI1 sites show concomitant changes in chromatin accessibility and H3K27ac abundance, which preferentially amplify EWS-FLI1 activity at multimeric enhancers and drive marked up‑regulation of canonical microsatellite‑regulated target genes in STAG2‑null cells. By integrating Hi‑C–derived chromatin interaction maps with altered EWS-FLI1 occupancy, we derive distinct monomeric (1xGGAA) and multimeric (≥10xGGAA) EWS-FLI1 transcriptional signatures and show that STAG2 inactivation selectively augments the multimeric signature while attenuating monomeric activity. We further define a prognostic signature of GGAA-repeat enhancers that is significantly upregulated in patient tumors with aggressive clinical features and deleterious STAG2 alterations. Together, these findings reveal that loss of STAG2–cohesin does not simply attenuate EWS-FLI1 function but reprograms its cistrome toward microsatellite multimeric GGAA neo‑enhancers, thereby amplifying a high‑risk EWS–FLI1 transcriptional state in Ewing sarcoma.

Project description:Ewing sarcomas are driven by chromosomal translocations that fuse a FET RNA‑binding protein to an ETS transcription factor, most commonly generating the EWS-FLI1 fusion oncoprotein. EWS-FLI1 engages GGAA microsatellite repeats to create de novo enhancers and activate oncogenic transcriptional programs—a neomorphic gain-of-function essential for Ewing sarcoma pathogenesis. In addition to the truncal fusion, recurrent loss‑of‑function alterations in the cohesin subunit STAG2 occur in approximately 10–15% of Ewing sarcomas and are associated with adverse clinical outcomes. Yet, how STAG2-cohesin deficiency remodels EWS-FLI1 chromatin occupancy and gene regulatory network remains incompletely understood. Here, using genetic STAG2 loss‑of‑function models combined with functional multi-omic profiling, we show that STAG2-cohesin loss in Ewing sarcoma cells reprograms the EWS-FLI1 cistrome by shifting its binding preference at GGAA microsatellite repeats. Despite increased EWS–FLI1 protein abundance, disruption of STAG2 eliminates more than 40% of EWS-FLI1 binding sites. The lost sites are enriched for elements harboring 1–4 GGAA repeat motifs, with a simultaneous gain in EWS-FLI1 binding at multimeric enhancers containing ≥5 GGAA repeat sequences. Notably, reprogrammed EWS-FLI1 sites show concomitant changes in chromatin accessibility and H3K27ac abundance, which preferentially amplify EWS-FLI1 activity at multimeric enhancers and drive marked up‑regulation of canonical microsatellite‑regulated target genes in STAG2‑null cells. By integrating Hi‑C–derived chromatin interaction maps with altered EWS-FLI1 occupancy, we derive distinct monomeric (1xGGAA) and multimeric (≥10xGGAA) EWS-FLI1 transcriptional signatures and show that STAG2 inactivation selectively augments the multimeric signature while attenuating monomeric activity. We further define a prognostic signature of GGAA-repeat enhancers that is significantly upregulated in patient tumors with aggressive clinical features and deleterious STAG2 alterations. Together, these findings reveal that loss of STAG2–cohesin does not simply attenuate EWS-FLI1 function but reprograms its cistrome toward microsatellite multimeric GGAA neo‑enhancers, thereby amplifying a high‑risk EWS–FLI1 transcriptional state in Ewing sarcoma.

Project description:Ewing sarcomas are driven by chromosomal translocations that fuse a FET RNA‑binding protein to an ETS transcription factor, most commonly generating the EWS-FLI1 fusion oncoprotein. EWS-FLI1 engages GGAA microsatellite repeats to create de novo enhancers and activate oncogenic transcriptional programs—a neomorphic gain-of-function essential for Ewing sarcoma pathogenesis. In addition to the truncal fusion, recurrent loss‑of‑function alterations in the cohesin subunit STAG2 occur in approximately 10–15% of Ewing sarcomas and are associated with adverse clinical outcomes. Yet, how STAG2-cohesin deficiency remodels EWS-FLI1 chromatin occupancy and gene regulatory network remains incompletely understood. Here, using genetic STAG2 loss‑of‑function models combined with functional multi-omic profiling, we show that STAG2-cohesin loss in Ewing sarcoma cells reprograms the EWS-FLI1 cistrome by shifting its binding preference at GGAA microsatellite repeats. Despite increased EWS–FLI1 protein abundance, disruption of STAG2 eliminates more than 40% of EWS-FLI1 binding sites. The lost sites are enriched for elements harboring 1–4 GGAA repeat motifs, with a simultaneous gain in EWS-FLI1 binding at multimeric enhancers containing ≥5 GGAA repeat sequences. Notably, reprogrammed EWS-FLI1 sites show concomitant changes in chromatin accessibility and H3K27ac abundance, which preferentially amplify EWS-FLI1 activity at multimeric enhancers and drive marked up‑regulation of canonical microsatellite‑regulated target genes in STAG2‑null cells. By integrating Hi‑C–derived chromatin interaction maps with altered EWS-FLI1 occupancy, we derive distinct monomeric (1xGGAA) and multimeric (≥10xGGAA) EWS-FLI1 transcriptional signatures and show that STAG2 inactivation selectively augments the multimeric signature while attenuating monomeric activity. We further define a prognostic signature of GGAA-repeat enhancers that is significantly upregulated in patient tumors with aggressive clinical features and deleterious STAG2 alterations. Together, these findings reveal that loss of STAG2–cohesin does not simply attenuate EWS-FLI1 function but reprograms its cistrome toward microsatellite multimeric GGAA neo‑enhancers, thereby amplifying a high‑risk EWS–FLI1 transcriptional state in Ewing sarcoma.

Project description:Megakaryocytes and platelets arise from hematopoietic stem and progenitor cells through a tightly regulated process involving various transcription factors, including ETS family member FLI1. Pathogenic variants in FLI1, particularly those affecting the ETS DNA-binding domain, have been implicated in inherited thrombocytopenia and are associated with abnormal giant alpha granules, as seen in Paris-Trousseau Syndrome. However, the precise pathophysiological mechanisms remain unclear. Here, we describe a patient with a de novo heterozygous nonsense mutation, FLI1Met100* (c.297del), and investigate its effects on megakaryopoiesis using the Meg01 megakaryoblast cell line as a model. We hypothesized that this variant generates a truncated protein that exerts a dominant-negative effect on megakaryocyte maturation. Western blot analysis confirmed the presence of the truncated protein following FLI1Met100* overexpression in Meg01 cells. To further examine its impact, we overexpressed both wild-type FLI1 (FLI1WT) and FLI1Met100* in Meg01 cells, followed by bulk RNA sequencing and proteomics analysis. Gene set enrichment analysis revealed that FLI1WT enhanced megakaryocytic phenotypes while suppressing erythroid phenotypes, whereas FLI1Met100* upregulated both. Flow cytometry further confirmed that erythroid markers CD235a, CD36, and KLF1 were downregulated by FLI1WT but elevated by FLI1Met100*. Additionally, FLI1WT promoted megakaryocyte maturation and adhesion, as evidenced by increased expression of the megakaryocyte marker CD61 and adhesion markers CD34 and CD44. Moreover, we demonstrated through immunoprecipitation that both FLI1WT and FLI1Met100* interact with shared cofactors. Collectively, our findings suggest that FLI1Met100* impairs megakaryocyte maturation through a dominant-negative manner, potentially contributing to thrombocytopenia by promoting erythroid features at the expense of proper megakaryocytic development.

Project description:Nuclear receptor binding SET domain protein 1 (NSD1) is recurrently mutated in human cancers including acute leukemia. We found that NSD1 knockdown altered erythroid clonogenic growth of human CD34+ hematopoietic cells. Ablation of Nsd1 in the hematopoietic system induced a transplantable erythroleukemia in mice. Despite abundant expression of the transcriptional master regulator GATA1, in vitro differentiation of Nsd1-/- erythroblasts was majorly impaired associated with reduced activation of GATA1-induced targets, while GATA1-repressed target genes were less affected. Retroviral expression of wildtype Nsd1, but not a catalytically-inactive Nsd1N1918Q SET-domain mutant induced terminal maturation of Nsd1-/- erythroblasts. Despite similar GATA1 levels, exogenous Nsd1 but not Nsd1N1918Q significantly increased GATA1 chromatin occupancy and target gene activation. Notably, Nsd1 expression reduced the association of GATA1 with the co-repressor SKI, and knockdown of SKI induced differentiation of Nsd1-/- erythroblasts. Collectively, we identified the NSD1 methyltransferase as a novel regulator of GATA1-controlled erythroid differentiation and leukemogenesis.

Project description:Cohesin complexes carrying STAG1 or STAG2 organize the genome into chromatin loops. STAG2 loss-of-function mutations promote metastasis in Ewing sarcoma, a pediatric cancer that is driven by the fusion transcription factor EWS-FLI1. We have integrated transcriptomic data from patients and cellular models to identify a STAG2-dependent gene signature associated with worse prognosis. Subsequent genomic profiling and high-resolution chromatin interaction data from Capture Hi-C indicate that cohesin-STAG2 facilitates the communication between EWS-FLI1-bound long GGAA repeats acting as neoenhancers and their target promoters. Changes in CTCF-dependent chromatin contacts, unrelated to EWS-FLI1 binding, also contribute to the aggressive phenotype. STAG1 is unable to compensate for STAG2 loss and chromatin-bound cohesin is severely decreased, while levels of the processivity factor NIPBL remain unchanged, resulting in altered DNA looping dynamics. These results illuminate how STAG2 loss rewires the Ewing sarcoma chromatin interactome to promote metastasis and provide a list of potential biomarkers and therapeutic targets.

Project description:Cohesin complexes carrying STAG1 or STAG2 organize the genome into chromatin loops. STAG2 loss-of-function mutations promote metastasis in Ewing sarcoma, a pediatric cancer that is driven by the fusion transcription factor EWS-FLI1. We have integrated transcriptomic data from patients and cellular models to identify a STAG2-dependent gene signature associated with worse prognosis. Subsequent genomic profiling and high-resolution chromatin interaction data from Capture Hi-C indicate that cohesin-STAG2 facilitates the communication between EWS-FLI1-bound long GGAA repeats acting as neoenhancers and their target promoters. Changes in CTCF-dependent chromatin contacts, unrelated to EWS-FLI1 binding, also contribute to the aggressive phenotype. STAG1 is unable to compensate for STAG2 loss and chromatin-bound cohesin is severely decreased, while levels of the processivity factor NIPBL remain unchanged, resulting in altered DNA looping dynamics. These results illuminate how STAG2 loss rewires the Ewing sarcoma chromatin interactome to promote metastasis and provide a list of potential biomarkers and therapeutic targets.

Project description:Cohesin complexes carrying STAG1 or STAG2 organize the genome into chromatin loops. STAG2 loss-of-function mutations promote metastasis in Ewing sarcoma, a pediatric cancer that is driven by the fusion transcription factor EWS-FLI1. We have integrated transcriptomic data from patients and cellular models to identify a STAG2-dependent gene signature associated with worse prognosis. Subsequent genomic profiling and high-resolution chromatin interaction data from Capture Hi-C indicate that cohesin-STAG2 facilitates the communication between EWS-FLI1-bound long GGAA repeats acting as neoenhancers and their target promoters. Changes in CTCF-dependent chromatin contacts, unrelated to EWS-FLI1 binding, also contribute to the aggressive phenotype. STAG1 is unable to compensate for STAG2 loss and chromatin-bound cohesin is severely decreased, while levels of the processivity factor NIPBL remain unchanged, resulting in altered DNA looping dynamics. These results illuminate how STAG2 loss rewires the Ewing sarcoma chromatin interactome to promote metastasis and provide a list of potential biomarkers and therapeutic targets.

Project description:Adane B, Alexe G, Seong BKA, Lu D, Hwang E, Hnisz D, Lareau CA, Ross L, Lin S, Dela Cruz FS, Richardson M, Weintraub AS, Wang S, Balboni-Iniguez A, Dharia NV, Conway AS, Robichaud AL, Tanenbaum B, Krill-Burger JM, Vazquez F, Schenone M, Berman JN, Kung A, Carr SA, Aryee MJ, Young RA, Crompton BD, Stegmaier K. 2021 Cancer Cell. The core cohesin subunit STAG2 is recurrently mutated in Ewing sarcoma but its biological role is less clear. Herein, we demonstrate that cohesin complexes containing STAG2 occupy enhancer and polycomb repressive complex (PRC2) marked regulatory regions. Genetic suppression of STAG2 leads to a compensatory increase in cohesin-STAG1 complexes, but not in enhancer rich regions, and results in reprogramming of cis-chromatin interactions. Strikingly, in STAG2 knockout cells, the oncogenic genetic program driven by the fusion transcription factor EWS/FLI1 was highly perturbed, in part due to altered enhancer-promoter contacts. Moreover, loss of STAG2 also disrupted PRC2-mediated regulation of gene expression. Combined, these transcriptional changes converged to modulate EWS/FLI1, migratory and neurodevelopmental programs. Finally, consistent with clinical observations, functional studies revealed that loss of STAG2 enhances the metastatic potential of Ewing sarcoma xenografts. Our findings demonstrate that STAG2 mutations can alter chromatin architecture and transcriptional programs to promote an aggressive cancer phenotype.

Project description:This SuperSeries is composed of the SubSeries listed below. Germline GATA1 mutations resulting in the production of an amino-truncated protein termed GATA1s (for M-bM-^@M-^\shortM-bM-^@M-^]) cause congenital hypoplastic anemia. Similar somatic mutations promote transient myeloproliferative disease and acute megakaryoblastic leukemia in trisomy 21 patients. Here we show that induced pluripotent stem cells (iPSCs) from patients with GATA1-truncating mutations exhibit impaired erythroid potential but enhanced megakaryopoiesis and myelopoiesis, faithfully recapitulating the major phenotypes of associated diseases. Similarly, GATA1s promotes megakaryopoiesis but not erythropoiesis in developmentally arrested Gata1- murine megakaryocyte-erythroid progenitors derived from murine embryonic stem cells (ESCs). Transcriptome studies demonstrate a selective deficiency in the ability of GATA1s to activate erythroid-expressed genes within populations of hematopoietic progenitors. Although its DNA binding domain is intact, chromatin immunoprecipitation studies show that GATA1s binding at specific erythroid regulatory regions is impaired, while binding at many non-erythroid sites, including megakaryocytic and myeloid target genes, is normal. These observations point to lineage specific GATA1 co-factor associations essential for normal chromatin occupancy and provide mechanistic insights into how GATA1s mutations cause human disease. More broadly, our studies underscore the value of ESCs and iPSCs to recapitulate and study disease phenotypes. Refer to individual Series