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:The diagnosis of ependymoma has moved from a purely histopathological review with limited prognostic value to an integrated diagnosis, relying heavily on molecular information. However, as the integrated approach is still novel and some molecular ependymoma subtypes are quite rare, few studies have correlated integrated pathology and clinical outcome, often focusing on small series of single molecular types. We collected data from 2023 ependymomas as classified by DNA methylation profiling, consisting of 1736 previously published and 287 unpublished methylation profiles. Methylation data and clinical information were correlated, and an integrated model was developed to predict progression-free survival. Patients with EPN-PFA, EPN-ZFTA, and EPN-MYCN tumors showed the worst outcome with 10-year overall survival rates of 56%, 62%, and 32%, respectively. EPN-PFA harbored chromosome 1q gains and/or 6q losses as markers for worse survival. In supratentorial EPN-ZFTA, a combined loss of CDKN2A and B indicated worse survival, whereas a single loss did not. Twelve out of 200 EPN-ZFTA (6%) were located in the posterior fossa, and these tumors relapsed or progressed even earlier than supratentorial tumors with a combined loss of CDKN2A/B. Patients with MPE and PF-SE, generally regarded as non-aggressive tumors, only had a 10-year progression-free survival of 59% and 65%, respectively. For the prediction of the 5-year progression-free survival, Kaplan-Meier estimators based on the molecular subtype, a Support Vector Machine based on methylation, and an integrated model based on clinical factors, CNV data, and predicted methylation scores achieved balanced accuracies of 66%, 68%, and 73%, respectively. Excluding samples with low prediction scores resulted in balanced accuracies of over 80%.

Project description:Background: A methylation-based classification of ependymoma has recently found broad application. However, the diagnostic advantage and implications for treatment decisions remain unclear. Here, we retrospectively evaluate the impact of surgery and radiotherapy on outcome after molecular reclassification of adult intracranial ependymomas. Methods: Tumors diagnosed as intracranial ependymomas from 170 adult patients collected from eight diagnostic institutions were subjected to DNA methylation profiling. Molecular classes, patient characteristics, and treatment were retrospectively correlated with progression-free survival (PFS). Results: The classifier indicated an ependymal tumor in 73.5%, a different tumor entity in 10.6% and non-classifiable tumors in 15.9% of cases, respectively. The most prevalent molecular classes were posterior fossa ependymoma group B (EPN-PFB, 32.9%), posterior fossa subependymoma (PF-SE, 25.9%), and supratentorial ZFTA fusion-positive ependymoma (EPN-ZFTA, 11.2%). With a median follow-up of 60.0 months, the 5- and 10-year-PFS rates were 64.5% and 41.8% for EPN-PFB, 67.4% and 45.2% for PF-SE and 60.3% and 60.3% for EPN-ZFTA. In EPN-PFB, but not in other molecular classes, gross total resection (p=0.009) and postoperative radiotherapy (p=0.007) were significantly associated with improved PFS in multivariable analysis. Histological tumor grading (WHO 2 vs. 3) was not a predictor of prognosis within molecularly defined ependymoma classes. Conclusions: DNA methylation profiling improves diagnostic accuracy and risk stratification in adult intracranial ependymoma. The molecular class of PF-SE is unexpectedly prevalent among adult tumors with ependymoma histology and relapsed as frequently as EPN-PFB, despite the supposed benign nature. Gross total resection and radiotherapy may represent key factors in determining the outcome of EPN-PFB patients.

Project description:Ependymomas (EPN) are central nervous system tumors arising from ependymal cells, primarily affecting young children and accounting for 10% of intracranial tumors in children and 4% in adults. Current treatments are limited to surgery and radiotherapy, with chemotherapy providing minimal benefit. Over 70% of supratentorial ependymomas (ST-EPNs) are driven by ZFTARELA fusions (ZFTA-RELAfus), which are associated with poor prognosis. Recent molecular classifications have identified two distinct ST-EPN clusters, E1 and E2, with the E1 cluster predominantly composed of ZFTA-RELAfus tumors. However, effective targeted therapies for these tumors remain lacking. Here, we show that the ZFTA-RELAfus mouse model closely mirrors the human E1 cluster, validating its use for therapeutic discovery. Using this model and a systems polypharmacology approach called Kinome Regularization, we identified mer tyrosine kinase (Mertk) as a key regulator of ZFTA-RELAfus cell viability and proliferation. Genetic depletion or pharmacological inhibition of Mertk reduced cell growth ex vivo and treatment with the clinical-grade Mertk inhibitor significantly suppressed tumor proliferation in vivo. Mechanistically, both human E1 tumors and mouse ZFTA-RELAfus tumors showed elevated Mertk expression, with Mertk inhibition leading to decreased activity of pro-survival pathways. Further, substantial overlap (>80%) between genes upregulated in ZFTA-RELAfus tumors and those downregulated following Mertk inhibition treatment suggest a dependency on Mertkmediated signaling for tumor growth. These findings highlight Mertk as a promising therapeutic target and support the clinical development of Mertk inhibitors for treating human E1 subtype and ZFTA-RELAfus -driven ependymomas.

Project description:Over 95% of ependymomas (EPNs) that arise in the cortex are driven by a gene fusion involving the zinc finger translocation associated (ZFTA) protein. Using super-resolution and lattice light sheet microscopy, we demonstrate that the most frequent fusion variant, ZFTA-RELA (ZR), forms dynamic nuclear condensates that are required for oncogene expression and tumorigenesis. Mutagenesis of ZR reveals a key intrinsically disordered region (IDR) that governs condensate formation. Condensate-modulating ZR IDR mutations impaired genomic occupancy at oncogenic loci, and inhibited the recruitment of transcriptional effector proteins, such as MED1, BRD4 and RNA polymerase II. Using nuclear magnetic resonance spectroscopy, we examined the protein structure of the critical zinc finger found in ZR, and characterized its significance for condensate formation, genomic binding, and oncogene activation. Our data leverages microscopy, genomics, cell biology, animal modeling, structural biology, and machine learning approaches to provide mechanistic insights into the processes that govern oncogene expression in ZFTA FO-driven tumors.

Project description:We report an infantile case of midline ‘supratentorial ependymoma ZFTA fusion-positive’ involving both the infra- and the supra-tentorial compartments (i.e., cerebellar vermis, pons and midbrain). The radiological features, i.e., the upward displacement and compression of the supratentorial anatomical structures and the infiltrative margins of the tumour towards the cerebellar vermis, suggested an infratentorial origin of the lesion with secondary involvement of the supratentorial compartment. This case adds to the limited literature of non-hemispheric ‘supratentorial ependymoma ZFTA fusion-positive’ occurring in midline structures, both supratentorial (pineal region, thalamus) and infratentorial (cervico-medullary region and spinal cord), and in the cerebellum. These cases highlight the need to consider this entity in the differential diagnosis of paediatric non-hemispheric lesions and raise the question of whether the inclusion of the location within the WHO definition of this tumour type may be too restrictive

Project description:Ependymoma (EPN) is a brain tumor commonly presenting in childhood that remains fatal in the majority of children. Intra-tumoral cellular heterogeneity in bulk tumor samples significantly confounds our understanding of EPN biology, impeding development of effective therapy. We used single-cell RNA sequencing to identify four neoplastic cell subpopulations in posterior fossa EPN patient samples that underlie traditional subgroup classification and harbor divergent lineage trajectories and clinical outcomes. Neoplastic subpopulations expressed gene signatures associated with normal ependyma, ependymoma, and mesenchymal phenotypes, consequently named ciliated (CEC), transportive (TEC), undifferentiated (UEC), and mesenchymal ependymoma cells (MEC). The abundance of EPN subpopulations as estimated by deconvolution of EPN bulk tumor transcriptomes showed that the ratio of MEC and CEC cell fractions dictated assignment to the two main classification subgroups in PFA. Longitudinal analysis revealed evolution of subpopulation fractions, notably MEC and CEC, which changed between presentation and recurrence. Outcome analyses demonstrated that a higher proportion of UEC or MEC subpopulations was associated with shorter survival, whereas CEC was associated with longer survival. Unsupervised pseudotime analysis revealed divergent subpopulation lineages. The first lineage conformed to a classic cancer stem cell trajectory where UEC progenitors differentiate sequentially to TECs and then CECs. In the second trajectory MECs arise from UECs via TECs, potentially in response to hypoxia-mediated cellular stress, a process that we recreated in vitro in a hypoxia treated EPN cell line. Our study reveals the existence of significant, unappreciated cellular heterogeneity in EPN and provides important resolution of EPN tumor biology.

Project description:ZFTA-RELA is the most recurrent genetic alteration seen in ependymoma, and sufficient to initiate tumors when expressed during mouse brain development. Despite ZFTA-RELA’s potent oncogenic potential, ZFTA-RELA gene fusions are observed exclusively in ependymoma and have never been documented in any other adult or pediatric malignancy. We hypothesized that specific chromatin modules accessible during brain development would render specific cells-of-origin at increased risk of transformation by ZFTA fusion proteins. To this end we performed integrated single cell ATAC and RNA-seq analysis (referred to as scMultimome) in mouse and human ependymoma tumors driven by the ZFTA-RELA fusion. We demonstrate that specific epi-developmental programs present in radial glia and regulated by Plagl1 are at direct risk of transformation. Oncoprotein engagement of this chromatin module leads to persistent oncogene expression, a failure to halt cellular proliferation, and initiate terminal cellular differentiation. Surprisingly, ependymomas exhibit significant heterogeneity across lineage differentiation programs, and continued activation of Plagl1 networks in differentiated cell types such as tumor neuronal-like cells contribute to tumor progression. These findings implicate specific chromatin modules in cells of origin as critical mediators of ependymoma initiation. Persistent activation and erosion of developmetn lineage programs serve as drivers of tumor development and contribute to the cellular heterogeneity of the tumor microenvironment.

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.