Project description:To profile gene expression differences between mouse non-tumor cortex versus ZFTA-RELA ependymoma versus ETV5 overexpressing tumors Furthermore, we also sought to profile gene expression differences between ZFTA-RELA ependymoma versus NPY overexpressing tumor

Project description:To profile H3K4me3Q5Ser (5HT-H3) distribution in mouse ZFTA-RELA ependymoma tumors Furthermore, we also sought to examine H3K27ac and H3K27me3 distribution in mouse ZFTA-RELA ependymoma versus ETV5 overexpressing tumors

Project description:ZFTA-RELA (ZR) is the most recurrent genetic alteration seen in pediatric supratentorial ependymoma (EPN) and is sufficient to initiate tumors in mice. Despite the oncogenic potential of ZR, it is observed nearly exclusively in childhood EPN, with tumors located distinctly in the supratentorial region of the central nervous system (CNS). We hypothesized that specific chromatin modules accessible during brain development would render distinct cell lineage programs at direct risk of transformation by ZR. To this end, we performed combined single nucleus ATAC and RNA (snMultiome) sequencing of the developing mouse forebrain, as compared to ZR-driven mouse and human EPN. We demonstrate that specific developmental lineage programs present in transient progenitor cells and regulated by PLAG/L family transcription factors (TF) are at risk of neoplastic transformation. Binding of this chromatin network by ZR or other PLAG/L family motif targeting fusion oncoproteins lead to persistent chromatin accessibility at oncogenic loci and oncogene expression. Cross-species analysis of mouse and human ZR EPN reveals significant cell type heterogeneity mirroring incomplete neurogenic and gliogenic differentiation, with a small percentage of cycling progenitor-like or radial glial-like cells that establish a putative tumor cell hierarchy. In vivo lineage tracing studies reveal neoplastic clones that aggressively dominate tumor growth and establish the entire EPN cellular hierarchy. These findings unravel developmental epigenomic states critical for fusion oncoprotein-driven transformation and elucidate how these states continue to shape tumor progression.

Project description:ZFTA-RELA (ZR) is the most recurrent genetic alteration seen in pediatric supratentorial ependymoma (EPN) and is sufficient to initiate tumors in mice. Despite the oncogenic potential of ZR, it is observed nearly exclusively in childhood EPN, with tumors located distinctly in the supratentorial region of the central nervous system (CNS). We hypothesized that specific chromatin modules accessible during brain development would render distinct cell lineage programs at direct risk of transformation by ZR. To this end, we performed combined single nucleus ATAC and RNA (snMultiome) sequencing of the developing mouse forebrain, as compared to ZR-driven mouse and human EPN. We demonstrate that specific developmental lineage programs present in transient progenitor cells and regulated by PLAG/L family transcription factors (TF) are at risk of neoplastic transformation. Binding of this chromatin network by ZR or other PLAG/L family motif targeting fusion oncoproteins lead to persistent chromatin accessibility at oncogenic loci and oncogene expression. Cross-species analysis of mouse and human ZR EPN reveals significant cell type heterogeneity mirroring incomplete neurogenic and gliogenic differentiation, with a small percentage of cycling progenitor-like or radial glial-like cells that establish a putative tumor cell hierarchy. In vivo lineage tracing studies reveal neoplastic clones that aggressively dominate tumor growth and establish the entire EPN cellular hierarchy. These findings unravel developmental epigenomic states critical for fusion oncoprotein-driven transformation and elucidate how these states continue to shape tumor progression.

Project description:ZFTA-RELA (ZR) is the most recurrent genetic alteration seen in pediatric supratentorial ependymoma (EPN) and is sufficient to initiate tumors in mice. Despite the oncogenic potential of ZR, it is observed nearly exclusively in childhood EPN, with tumors located distinctly in the supratentorial region of the central nervous system (CNS). We hypothesized that specific chromatin modules accessible during brain development would render distinct cell lineage programs at direct risk of transformation by ZR. To this end, we performed combined single nucleus ATAC and RNA (snMultiome) sequencing of the developing mouse forebrain, as compared to ZR-driven mouse and human EPN. We demonstrate that specific developmental lineage programs present in transient progenitor cells and regulated by PLAG/L family transcription factors (TF) are at risk of neoplastic transformation. Binding of this chromatin network by ZR or other PLAG/L family motif targeting fusion oncoproteins lead to persistent chromatin accessibility at oncogenic loci and oncogene expression. Cross-species analysis of mouse and human ZR EPN reveals significant cell type heterogeneity mirroring incomplete neurogenic and gliogenic differentiation, with a small percentage of cycling progenitor-like or radial glial-like cells that establish a putative tumor cell hierarchy. In vivo lineage tracing studies reveal neoplastic clones that aggressively dominate tumor growth and establish the entire EPN cellular hierarchy. These findings unravel developmental epigenomic states critical for fusion oncoprotein-driven transformation and elucidate how these states continue to shape tumor progression.

Project description:ZFTA-RELA ependymoma poses a formidable challenge due to limited treatment avenues, prompting exploration into immunotherapeutic approaches. Recent investigations have shed light on the calvaria bone marrow as a source of meningeal immune cells crucial for central nervous system (CNS) immunity. Whether or not cues from the tumour microenvironment can instruct local haematopoiesis within the skull is unknown. We used single cell RNA sequencing (snRNAseq + snATAC) to analyze the dynamic transcriptional regulation of skull, peripheral bone marrow from tumour-bearing and non-tumour bearing ZFTA-RELA fusion driven ependymoma mice.

Project description:ZFTA-RELA Dictates Oncogenic Transcriptional Programs to Drive Aggressive Supratentorial Ependymoma

Project description:ZFTA-RELA ependymomas are malignant brain tumors that are frequently lethal. They are defined by fusions formed between the putative chromatin remodeler ZFTA and the NFkB-mediator-RELA. We identified that ZFTA-RELA cells produced itaconate, a key macrophage-associated immunomodulator metabolite. However, itaconate production by tumor cells and its tumor-intrinsic role are not well-established. Itaconate is synthesized by the enzyme Aconitate Decarboxylase-1 (ACOD1) and the ZFTA-RELA fusion upregulated ACOD1 in an NFkB-dependent manner. Additionally, itaconate production enabled a feed-forward system that maintained pathogenic ZFTA-RELA fusion expression through epigenetic activation. To supply the metabolic fuel needed to generate itaconate, these tumors epigenetically activated PI3K/mTOR signaling to enhance glutaminolysis, which provided the carbons necessary for itaconate synthesis. Consequently, antagonizing glutamine metabolism lowered pathogenic ZFTA-RELA levels and was potently therapeutic in multiple in vivo models. Finally, combining glutamine antagonism with PI3K/mTOR inhibition abrogated spinal metastasis. Our data demonstrate that ZFTA-RELA ependymomas subvert a macrophage-like itaconate metabolic pathway to maintain expression of the ZFTA-RELA fusion driver, implicating itaconate as an oncometabolite. Taken together, our results position itaconate upregulation as a previously unappreciated driver of ZFTA-RELA ependymomas. This study therefore has implications for future drug development for children with this devastating brain tumor and will further our understanding of oncometabolites as a novel class of therapeutic dependencies in cancers.

Project description:ZFTA-RELA ependymomas are malignant brain tumors that are frequently lethal. They are defined by fusions formed between the putative chromatin remodeler ZFTA and the NFkB-mediator-RELA. We identified that ZFTA-RELA cells produced itaconate, a key macrophage-associated immunomodulator metabolite. However, itaconate production by tumor cells and its tumor-intrinsic role are not well-established. Itaconate is synthesized by the enzyme Aconitate Decarboxylase-1 (ACOD1) and the ZFTA-RELA fusion upregulated ACOD1 in an NFkB-dependent manner. Additionally, itaconate production enabled a feed-forward system that maintained pathogenic ZFTA-RELA fusion expression through epigenetic activation. To supply the metabolic fuel needed to generate itaconate, these tumors epigenetically activated PI3K/mTOR signaling to enhance glutaminolysis, which provided the carbons necessary for itaconate synthesis. Consequently, antagonizing glutamine metabolism lowered pathogenic ZFTA-RELA levels and was potently therapeutic in multiple in vivo models. Finally, combining glutamine antagonism with PI3K/mTOR inhibition abrogated spinal metastasis. Our data demonstrate that ZFTA-RELA ependymomas subvert a macrophage-like itaconate metabolic pathway to maintain expression of the ZFTA-RELA fusion driver, implicating itaconate as an oncometabolite. Taken together, our results position itaconate upregulation as a previously unappreciated driver of ZFTA-RELA ependymomas. This study therefore has implications for future drug development for children with this devastating brain tumor and will further our understanding of oncometabolites as a novel class of therapeutic dependencies in cancers.

Project description:Over 60% of supratentorial (ST) ependymomas harbor a ZFTA-RELA (ZRfus) gene fusion (formerly C11orf95-RELA). To study the biology of ZRfus, we developed an autochthonous mouse tumor model using in utero electroporation (IUE) of the embryonic mouse brain. Integrative epigenomic and transcriptomic mapping was performed on IUE driven ZRfus tumors by CUT&RUN, ChIP, ATAC, and RNA sequencing and compared to human ZRfus driven ependymoma. In addition to direct canonical NF-kB pathway activation, ZRfus dictates a neoplastic transcriptional program and binds to thousands of unique sites across the genome that are enriched with Plagl family transcription factor (TF) motifs. ZRfus activates gene expression programs through recruitment of transcriptional co-activators (Brd4, Ep300, Cbp, Pol2) that are amenable to pharmacologic inhibition. Downstream ZRfus target genes converge on developmental programs marked by Plagl transcription factor proteins, and activate neoplastic programs enriched in Mapk, focal adhesion, and gene imprinting networks.