Embryonal Tumor With Multilayered Rosettes Research Articles

IMMU-16. TARGETING GLYPICAN 2 (GPC2) ON PEDIATRIC MALIGNANT BRAIN TUMORS WITH MRNA CAR T CELLS

Glypican 2 (GPC2) is a cell-surface oncoprotein initially identified in neuroblastoma, retinoblastoma, and medulloblastoma as an ideal target for immunotherapy (Cancer Cell, 2017). Here we evaluated GPC2 expression across the spectrum of pediatric brain tumors using RNA sequencing from specimens in the Children’s Brain Tumor Network (CBTN). High GPC2 expression, defined as >10 FPKM, was found in 100% of embryonal tumors with multilayered rosettes (ETMRs) (n=6), 95% of medulloblastomas (n=122), 86% of other embryonal tumors (n=21), 50% of choroid plexus carcinomas (n=4), 42% of high grade gliomas (HGG) (n=117), and 37% of diffuse midline gliomas (DMG) (n=65). Within medulloblastoma subtypes, group 4 tumors had the highest expression, and within the HGG tumor cohort H3.3 G34 mutated gliomas had the highest GPC2 expression. High GPC2 protein expression was validated with medulloblastoma and HGG/DMG primary tumors and cell lines using IHC, Western blot, and flow cytometry. We next developed two potent CAR T cell constructs using the D3 specific scFv directed against GPC2 for testing in brain tumor models. GPC2-directed CAR T cells were tested in vitro against medulloblastoma and HGG cells lines, and in vivo using two patient-derived medulloblastoma xenograft models: Rcmb28 (group 3) and 7316-4509 (group 4). GPC2-directed mRNA CAR T cells induced significant GPC2-specific cell death in medulloblastoma and HGG cellular models with concomitant T cell degranulation compared to CD19-directed mRNA CAR T cells. In vivo, GPC2-directed mRNA CAR T cells delivered locoregionally induced significant tumor regression measured by bioluminescence after 4–6 intratumoral infusions of 4 x 106 CAR T cells (p<0.0001 for Rcmb28, p<0.05 for 7316-4509). No GPC2-directed CAR T cell related toxicity was observed. GPC2 is a highly differentially expressed cell surface protein on multiple malignant pediatric brain tumors that can be targeted safely with local delivery of mRNA CAR T cells.

MiRNAs in early brain development and pediatric cancer

The size and organization of the brain are determined by the activity of progenitor cells early in development. Key mechanisms regulating progenitor cell biology involve miRNAs. These small noncoding RNA molecules bind mRNAs with high specificity, controlling their abundance and expression. The role of miRNAs in brain development has been studied extensively, but their involvement at early stages remained unknown until recently. Here, recent findings showing the important role of miRNAs in the earliest phases of brain development are reviewed, and it is discussed how loss of specific miRNAs leads to pathological conditions, particularly adult and pediatric brain tumors. Let-7 miRNA downregulation and the initiation of embryonal tumors with multilayered rosettes (ETMR), a novel link recently discovered by the laboratory, are focused upon. Finally, it is discussed how miRNAs may be used for the diagnosis and therapeutic treatment of pediatric brain tumors, with the hope of improving the prognosis of these devastating diseases.

Potential Importance of Early Focal Radiotherapy Following Gross Total Resection for Long-Term Survival in Children With Embryonal Tumors With Multilayered Rosettes.

Embryonal tumor with multilayered rosettes (ETMR) is a rare, aggressive embryonal central nervous system tumor characterized by LIN28A expression and alterations in the C19MC locus. ETMRs predominantly occur in young children, have a dismal prognosis, and no definitive treatment guidelines have been established. We report on nine consecutive patients and review the role of initiation/timing of radiotherapy on survival. Between 2006 and 2018, nine patients were diagnosed with ETMR. Diagnosis was confirmed histopathologically, immunohistochemically and molecularly. Median age was 25 months (5–38). Location was supratentorial in five, pineal in three, and brainstem in one. Seven patients had a gross total resection, one a partial resection and one a biopsy at initial diagnosis. Chemotherapy augmented with intrathecal therapy started a median of 10 days (7–20) after surgery. Only two patients who after gross total resection received radiotherapy very early on (six weeks after diagnosis) are alive and in complete remission 56 and 50 months after diagnosis. All remaining patients for whom radiotherapy was deferred until the end of chemotherapy recurred, albeit none with leptomeningeal disease. A literature research identified 228 patients with ETMR. Including our patients only 26 (11%) of 237 patients survived >36 months with no evidence of disease at last follow-up. All but two long-term (>36 months) survivors received radiotherapy, ten of whom early on following gross total resection (GTR). GTR followed by early focal radiotherapy and intrathecal therapy to prevent leptomeningeal disease are potentially important to improve survival of ETMR in the absence of effective targeted therapies.

ETMR-17. SINGLE-CELL TRANSCRIPTOME ANALYSIS OF ETMR PATIENT SAMPLES

Brain tumors are comprised of cells with heterogeneous genetic and transcriptional states, resulting in substantial phenotypic diversity. This diversity is particularly evident in embryonal tumor with multilayered rosettes (ETMR), which shows a striking bi-phasic pattern for which it is named. A better understanding of its underlying molecular makeup is urgently needed to develop more effective therapeutic strategies that eliminate all malignant cell types underlying ETMR initiation, maintenance, progression, and relapse. Furthermore, the cellular origin of ETMR is currently poorly understood. We used plate-based single-cell RNA sequencing to assess the intratumoral heterogeneity in 6 fresh and 4 snap-frozen surgical biopsies, following a workflow that we have previously established to study pediatric high grade gliomas, medulloblastomas, and ependymomas. Computational analyses conducted on >4,000 single cells identified cellular hierarchies ranging from a proliferative, undifferentiated cell population to more differentiated, predominantly neural-like progeny in all samples. Patient-derived cell line and xenograft models partially recapitulated this hierarchy. We further integrated transcriptional programs identified in single cells with available datasets of the developing normal brain, as well as with programs identified in other pediatric brain tumor entities, to inform both putative cellular origins and ETMR-specific oncogenic pathways. These timely results provide unparalleled insights into the molecular underpinnings of the phenotypic heterogeneity observed in ETMR. Analyses aimed at further integrating malignant cell type abundances with genetic alterations and clinical annotations, and therapeutical targeting of malignant cell populations using in-vitro models are currently ongoing.

ETMR-20. IMPACT OF HIGH DOSE CHEMOTHERAPY WITH AND WITHOUT METHOTREXATE (MTX) ON OUTCOME OF PATIENTS WITH EMBRYONAL TUMORS WITH MULTI-LAYERED ROSETTES (ETMRs): A REPORT FROM CHILDREN’S ONCOLOGY GROUP PHASE III TRIAL ACNS0334

Infant embryonal brain tumors comprise a spectrum of histologic and molecular entities including medulloblastoma (MB) and tumors collectively called CNS PNET’s, including supratentorial PNET (sPNET), pineoblastoma and other less common histologic entities. Non-MB embryonal tumors, historically considered high risk disease, were included in ACNS0334, A Children’s Oncology Group prospective phase III trial which compared efficacy of an induction regimen with and without methotrexate combined with high dose chemotherapy and stem cell rescue; no radiation was mandated. Molecular testing performed after ACNS0334 closure identified 14 patients with embryonal tumors with multi-layered rosettes (ETMRs), a new molecular entity previously classified under various diagnostic categories. ETMR patients made up 20% of the molecularly analyzed ACNS0334 cohort and were predominantly females. Tumors were largely non-metastatic (10/14 M0, 1 M1, 3 M2/M3) and originated in the cerebrum (8), cerebellum (3) and pineal gland (3). Gross total tumor resection was achieved in 5/11 patients with M0/M1 disease; 9/14 patients completed full treatment with 5 randomized to MTX induction and 9 to no-MTX. Five of 14 patients progressed on treatment, one had a toxic death. Disease progression was primarily local (88 %). No difference by methotrexate randomization was observed. Four patients are alive without progression 5–10+ years off therapy, none received radiation. No patients received radiation prior to progression. Four were irradiated after progression and died from disease within 3 to 13 months. Our study, a first report on ETMRs prospectively treated on a clinical trial, suggests high dose chemotherapy benefits a portion of ETMR patients.

C19MC amplification and expression of Lin28A and Olig2 in the classification of embryonal tumors of the central nervous system: A 14-year retrospective study from a tertiary care center.

CNS embryonal tumors (CET) other than medulloblastomas (MB) and atypical teratoid/rhabdoid tumors (AT/RTs), previously designated as 'central nervous system primitive neuroectodermal tumors' ('CNS PNETs'), are a heterogenous subset of tumors with poorly defined diagnostic criteria. Other than the subset of embryonal tumor with multilayered rosettes (ETMR) defined by C19MC amplification, most CETs are diagnosed by exclusion of other molecularly defined entities and histological mimics including MB, AT/RTs, and high-grade gliomas, and termed as CET, not otherwise specified (NOS) in the 2016 WHO classification. To reclassify 'CNS PNETs' as per WHO 2016, and estimate the true proportion of CET, NOS in a tertiary healthcare setting, and to evaluate the diagnostic utility of C19MC amplification, Lin28A and Olig2 expression in the subclassification of CETs. Previously diagnosed cases of 'CNS PNETs' (2002-2016) were first evaluated by immunohistochemistry (IHC) for MIC2, RelaA, L1CAM, IDH1R132H, H3K27M, H3G34R, H3G34V, INI1, and BRG1 proteins and by fluorescence in-situ hybridization (FISH) for EWSR1 translocation to exclude histological mimics. The selected CETs (case cohort) and 79 histological mimics (comparison cohort) comprising of MB, AT/RT, pineal parenchymal tumors, Ewing sarcoma, esthesioneuroblastoma, intraocular medulloepithelioma, and H3G34R mutant high-grade glioma were subject to IHC for Olig2 and Lin28A, and FISH for C19MC amplification. Twenty-two cases of 'CNS PNETs' were retrieved, all of which were negative for the first panel of markers and showed retained INI-1/BRG1 expression. Three of them (3/22, 13.6%) showed C19MC amplification (ETMR, C19MC-altered) with ETMR histology, Lin28A positivity, and Olig2 negativity. Among the remaining 19 CETs, one showed medulloepithelioma histology (Medulloepithelioma, NOS) and remaining were non-descript small round cell tumors (CET, NOS), all negative for Lin28A. Olig2 was positive in only 3 CETs (13.6%), all being CET, NOS. All tumors in the comparison cohort were negative for C19MC amplification, Lin28A and Olig2 except for 27% of ATRTs that were Lin28A positive. ETMR, C19MC-altered constitute less than 14% of CETs, with majority remaining uncharacterized as CET, NOS. Lin28A is 100% sensitive for the detection of C19MC amplification; however, its specificity is limited by its expression in ATRTs. Olig2 expression is seen only in a small subset of CET, NOS and is of limited diagnostic utility.

Transcriptomic Analysis Revealed an Emerging Role of Alternative Splicing in Embryonal Tumor with Multilayered Rosettes.

Embryonal tumor with multilayered rosettes (ETMR) is an aggressive and rare pediatric embryonal brain tumor. Amplification of C19MC microRNA cluster and expression of LIN28 are distinctive features of ETMR. Despite the increasing efforts to decipher ETMR, the biology remains poorly understood. To date, the role of aberrant alternative splicing in ETMR has not been thoroughly investigated. In the current study, a comprehensive analysis was performed on published unprocessed RNA-seq reads of tissue-matched ETMR and fetal controls datasets. Gene expression was quantified in samples using Kallisto/sleuth pipeline. For the alternative splicing analysis, STAR, SplAdder and rMATS were used. Functional enrichment analysis was subsequently performed using Metascape. The expression analysis identified a total of 3622 differentially expressed genes (DEGs) between ETMR and fetal controls while 1627 genes showed differential alternative splicing patterns. Interestingly, genes with significant alternative splicing events in ETMR were identified to be involved in signaling pathways such as ErbB, mTOR and MAPK pathways as well as ubiquitin-mediated proteolysis, cell cycle and autophagy. Moreover, up-regulated DEGs with alternative splicing events were involved in important biological processes including nuclear transport, regulation of cell cycle and regulation of Wnt signaling pathway. These findings highlight the role of aberrant alternative splicing in shaping the ETMR tumor landscape, and the identified pathways constitute potential therapeutic targets.

Abstract 6144: St. Jude Pediatric Brain Tumor Portal: Cloud-based resource for patient-derived orthotopic xenograft (PDOX) models of pediatric high-grade glioma, ependymoma, and CNS embryonal tumors

Abstract Pediatric brain tumors comprise a distinct spectrum of diseases compared to adult brain tumors and are distinguished by their unique clinical and histopathological features, developmental context, mutation burden, and genomic, epigenomic, and transcriptomic alterations. Access to in vivo models that recapitulate pediatric brain tumors has been limited and inadequate to represent these heterogeneous diseases. Here we introduce the Pediatric Brain Tumor Portal (PBTP, pbtp.stjude.cloud), an open resource to access molecular characterization, including whole-genome sequencing, whole-exome sequencing, RNA-seq, and DNA methylome profiling, of patient-derived orthotopic xenograft (PDOX) models of pediatric brain tumors. The portal will host more than 70 models, which currently include pediatric High-Grade Glioma (pHGG), Medulloblastoma, Atypical Teratoid/Rhabdoid Tumors (AT/RT), Ependymoma, and Embryonal Tumors with Multilayered Rosettes (ETMR), and reflects close to ten years of effort to generate and extensively characterize in vivo models that recapitulate primary pediatric brain tumors. PBTP is a database-driven and user-friendly platform that enables multi-omics views of PDOX and matched patient tumor and germline samples at multiple levels to help identify appropriate lines for studies of tumorigenesis or preclinical testing. To evaluate the representation of different molecular features within a disease subgroup, we implemented various visualization tools for searching and comparing somatic mutations, gene expression profiles, and methylation groups of our models and matched patient tumors. Details for each tumor including de-identified clinical data, histology, growth characteristics, DNA methylation classification, mutation status, and copy number variations are also readily available for side-by-side comparison. Furthermore, in vitro chemical sensitivity profiling is presented for selected models with matched cell lines. Users can investigate genes of interest for single nucleotide variants, small insertions and deletions, copy number variations, gene fusions, and mRNA expression in PDOX and matched patient tumors. This portal has been integrated into the St. Jude Cloud platform, through which users can explore patient and PDOX sequencing data in the context of larger cohort data sets and download raw genomics data files. PBTP provides a platform to share PDOX models with in-depth genome/epigenome-wide characterization to support advances in basic and translational research in pediatric brain tumors. *co-first, #co-corresponding Citation Format: Paige S. Dunphy, Ke Xu, Darrell T. Gentry, Chen He, Kimberly Mercer, Xiaoyan Zhu, Kyle Smith, Brian Gudenas, Sarah Robinson, Junyuan Zhang, Lawryn H. Kasper, Chang-Hyuk Kwon, Laura D. Hover, Jon D. Larson, Nathaniel Twarog, Aksana Vasilyeva, Nedra Robison, Daniel Alford, Cynthia Williams, Anthony Woodard, Xin Zhou, Edgar Sioson, J. Robert Michael, Austyn Trull, Irina McGuire, Brandon McMahan, Swapnali Mohite, Ashok Boddu, Kirby Birch, Clay McLeod, Michael A. Dyer, Paul Klimo, Frederick A. Boop, Amar Gajjar, Christopher L. Tinkle, Giles Robinson, Brent A. Orr, Jason Chiang, Paul A. Northcott, Jinghui Zhang, Keith Perry, Gang Wu, Anang A. Shelat, Ed Suh, Martine F. Roussel, Suzanne J. Baker. St. Jude Pediatric Brain Tumor Portal: Cloud-based resource for patient-derived orthotopic xenograft (PDOX) models of pediatric high-grade glioma, ependymoma, and CNS embryonal tumors [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 6144.

Abstract A39: Molecular characterization of ETMRs reveals role for R-loop mediated genomic instability and new treatment options

Abstract Introduction: Embryonal tumors with multilayered rosettes (ETMRs) are aggressive brain tumors that occur mainly in infants. Patients face a very poor prognosis with a median overall survival of ~12 months after diagnosis. The tumors harbor in ~90% of all cases amplification of a miRNA cluster on chromosome 19 (C19MC) that is thought to be the driver of the disease. However, current treatment options are lacking as (a) the mechanisms downstream of C19MC are poorly understood and (b) the drivers in cases lacking the C19MC aberration are unknown. To develop better treatment protocols for ETMR patients, more insight is needed in what is driving these tumors and how that can be targeted. Materials and Methods: To investigate the genomic and epigenomic landscape of ETMR in depth, we collected 193 ETMR samples and 23 matched relapses and performed DNA methylation profiling on all and DNA (whole genome, whole exome, and panel) sequencing and mRNA and miRNA transcriptome analysis on a subset of them. The BT183 ETMR cell line was used for drug treatments. Results: Among the 22 tumors without C19MC amplification, we identified 8 cases with truncating DICER1 germline mutations in one allele and somatic missense mutations in the RNASE III domain in the other allele. No DICER1 mutations were identified in C19MC amplified cases. In addition, structural variations (SVs) affecting C19MC were found in 3 other C19MC nonamplified cases and amplification of another miRNA cluster, miR-17-92, in 2 other cases. However, despite the presence of different genetic aberrations, based on DNA methylation and transcriptome profiling no molecular subgrouping was observed within our cohort. Whole-genome sequencing revealed an overall low recurrence and conservation of SNVs but strong conservation of SVs from primary tumors to relapses, especially surrounding C19MC. Moreover, many newly acquired SNVs in the relapses are associated to a new cisplatin treatment-related mutational signature. SVs detected in ETMRs significantly colocalized with R-loops, structures that form upon a collision of replication and transcription and are associated to increased levels of chromosomal instability, which is frequently observed in ETMRs. Using a DICER1 KO model, we found that global deregulation of miRNAs led to increased levels of R-loops and R-loop associated chromosomal instability. Finally, we show that a combination of topoisomerase and PARP inhibitors is highly synergistic and strongly increased the levels of both R-loops and DNA damage in ETMR cells and effectively killed the cells. Conclusions: Our results show that genomically instable ETMR cells are vulnerable to further increases in chromosomal instability, knowledge that may lead to new treatment strategies for ETMR patients and possibly other cancers with high levels of R-loops. Citation Format: Sander Lambo, Susanne Grübner, Tobias Rausch, Sebastian Waszak, Christin Schmidt, Sonja Krausert, Loreen Weichert, Aparna Gorthi, Carolina Romero, Annie Huang, Julia Schueler, Jan Korbel, Alexander Bishop, Stefan Pfister, Andrey Korshunov, Marcel Kool. Molecular characterization of ETMRs reveals role for R-loop mediated genomic instability and new treatment options [abstract]. In: Proceedings of the AACR Special Conference on the Advances in Pediatric Cancer Research; 2019 Sep 17-20; Montreal, QC, Canada. Philadelphia (PA): AACR; Cancer Res 2020;80(14 Suppl):Abstract nr A39.

Abstract PR06: The immunogenomic landscape of pediatric primary solid tumors

Abstract Introduction: Immune checkpoint inhibition is a novel approach of restimulating immune cells to overcome immunosuppressive microenvironment in tumors and has shown significant clinical benefit in 20-40% of adult patients. Although this success in adult cancers has resulted in a plethora of immunogenomic efforts to delineate mechanisms of response, such studies in pediatric cancers are lacking. The main objective of this study is to uncover the overall characteristics of immune microenvironment in pediatric solid tumors. Methods: We leveraged transcriptomes of 1,268 pediatric primary solid tumors acquired from multiple international initiatives, including Therapeutically Applicable Research to Generate Effective Treatments (TARGET, n = 269), International Cancer Genome Consortium (ICGC, n = 216) and Children Brain Tumor Tissue Consortium (CBTTC, n = 803). We compared our results with those of 7 adult cancer types from The Cancer Genome Atlas (TCGA, n = 2720). We applied methods of immune deconvolution, repurposed RNAseq data to recover infiltrating T- and B-cell clonotypes and studied checkpoint gene expression in pediatric tumors. In collaboration with Gabriela Miller’s Kids First Data Resource Centre, all analyses were performed and shared on CAVATICA computational platform (cavatica.sbgenomics.com). Results: Embryonal tumors with multilayered rosettes (ETMR) and medulloblastomas (MB) harbored the lowest levels of immune infiltration in our pediatric cohort. Immune deconvolution analysis revealed that neuroblastomas (NBL) had the highest T-cell infiltration amongst pediatric cancers. We found atypical teratoid/rhabdoid tumors (ATRT) had highest levels of CD8+ T cells among pediatric CNS tumors. While tumor mutational burden (TMB) was associated with immune cell infiltration in adult lung cancers and melanomas, we found no significant association in pediatric cancers. We found specific genetic alterations such as BRAF, H3F3A, and CTNNB1 had significant impact on the composition of the immune microenvironment. Analysis of T-cell repertoire revealed an inverse correlation between clonal diversity and TMB, suggesting a T-cell clonal expansion in high TMB samples. Finally, while the majority of NBL samples expressed LAG3, ~10% of samples had elevated levels of TIM3 gene, suggesting a distinct mode of immunosuppression in this subset. 2% of pediatric CNS tumors, mostly consisted of ATRTs, harbored high expression of PRF1 and GZMA genes suggestive of functionally capable immune cells in these cases. Conclusions: We report characteristics of the tumor microenvironment in pediatric tumors at primary diagnosis. We found that specific gene mutations, rather than mutational load, shape the composition of immune cell types. Furthermore, hypermutant samples exhibit evidence of clonal T-cell expansion. Our results suggest immune activity in 2% of CNS tumors and uncover a subtype of NBL expressing TIM3 checkpoint gene, calling for investigations to evaluate the effectiveness of immunotherapy. This abstract is also being presented as Poster A74. Citation Format: Arash Nabbi, Pengbo Sun, Sudhaman Sumedha, Kelsey Zhu, S.Y. Cindy Yang, Joseph N. Paulson, Marcel Kool, Komal Rathi, Karthik Kalletla, Pichai Raman, Yuankun Zhu, Adam C. Resnick, David T.W. Jones, Natalie Jäger, Stefan M. Pfister, Trevor J. Pugh. The immunogenomic landscape of pediatric primary solid tumors [abstract]. In: Proceedings of the AACR Special Conference on the Advances in Pediatric Cancer Research; 2019 Sep 17-20; Montreal, QC, Canada. Philadelphia (PA): AACR; Cancer Res 2020;80(14 Suppl):Abstract nr PR06.

Inside the USCAP Journals

Inside the USCAP Journals

Inside the USCAP Journals

Inside the USCAP Journals

A C19MC-LIN28A-MYCN Oncogenic Circuit Driven by Hijacked Super-enhancers Is a Distinct Therapeutic Vulnerability in ETMRs: A Lethal Brain Tumor

Embryonal tumors with multilayered rosettes (ETMRs) are highly lethal infant brain cancers with characteristic amplification of Chr19q13.41 miRNA cluster (C19MC) and enrichment of pluripotency factor LIN28A. Here we investigated C19MC oncogenic mechanisms and discovered a C19MC-LIN28A-MYCN circuit fueled by multiple complex regulatory loops including an MYCN core transcriptional network and super-enhancers resulting from long-range MYCN DNA interactions and C19MC gene fusions. Our data show that this powerful oncogenic circuit, which entraps an early neural lineage network, is potently abrogated by bromodomain inhibitor JQ1, leading to ETMR cell death.

New stratification for early childhood medulloblastoma

Radiotherapy (RT) remains the mainstay of medulloblastoma treatment but its impact on neurocognitive outcome of young children is massive. In this age group, the main challenge is to limit the cost of cure by deferring, completely avoiding or at least reducing RT (field or dose) without jeopardizing survival. In the past, survival of young children with medulloblastoma was somewhat lower than in older children treated with standard craniospinal RT. Apart from the decrease of RT other causes can be discussed: differences in tumor biology, higher frequency of metastases, inclusion of others embryonal tumors such as atypical teratoid/rhabdoid tumor (ATRT) or embryonal tumor with multilayered rosettes (ETMR) with known worse prognosis.

Embryonal Tumors of the Central Nervous System in Children: The Era of Targeted Therapeutics

Embryonal tumors (ET) of the central nervous system (CNS) in children encompass a wide clinical spectrum of aggressive malignancies. Until recently, the overlapping morphological features of these lesions posed a diagnostic challenge and undermined discovery of optimal treatment strategies. However, with the advances in genomic technology and the outpouring of biological data over the last decade, clear insights into the molecular heterogeneity of these tumors are now well delineated. The major subtypes of ETs of the CNS in children include medulloblastoma, atypical teratoid rhabdoid tumor (ATRT), and embryonal tumors with multilayered rosettes (ETMR), which are now biologically and clinically characterized as different entities. These important developments have paved the way for treatments guided by risk stratification as well as novel targeted therapies in efforts to improve survival and reduce treatment burden.

Abstract 3172: Targeting genomic instability in embryonal tumors with multilayered rosettes (ETMR)

Abstract Embryonal Tumors with Multilayered Rosettes (ETMRs) are pediatric brain tumors mainly occurring in infants. Characteristic to ETMRs is the highly recurrent (~90%) amplification of the C19MC miRNA cluster fused to TTYH1 that drives the expression of this cluster. As the overall survival of these patients is very poor, there is an urgent need for a better understanding of these tumors that may lead to other treatment strategies. Whole genome and panel sequencing data have been generated for 60 ETMRs and matching germline when available. Data have been complemented with DNA methylation profiling and m(i)RNA sequencing data. Our results show that ETMR is a single disease entity without molecular subgroups. ETMRs lacking the C19MC amplification (~10%) are highly similar to tumors with C19MC amplification, based on methylation and m(i)RNA profiling, indicating that they do not represent a distinct subgroup. Germline sequencing revealed mutations in genes involved in DNA repair or miRNA processing, while tumor specific mutations included genes involved in the TP53-, SHH-, WNT-, or miRNA processing pathways. These pathways are also highly upregulated compared to other pediatric brain tumors. Mutations in DNA repair, miRNA processing, structural variations (SVs) and mutations in close proximity of SVs occur at high allele frequencies and are conserved in recurrent tumors while many other SNVs are lost. These data suggest that C19MC amplification/fusion, miRNA processing and DNA repair defects are the early (driving) events in tumor formation while aberrations involving for instance the SHH and WNT pathways are later (passenger) events. Aside from frequent and recurrent copy number changes, ETMRs show pluriploidy, complex rearrangements and strong presence of R-loops suggesting that ETMR genomes are highly unstable. We identified a high number of R-loops in the region forming the C19MC aberration and an enrichment of breakpoints in other R-loop forming regions. This may suggest a role for R-loops in both tumor progression and initiation. Finally, we tested whether further inducing the number of R-loops in these tumors may increase replication stress and cell death. Indeed, topoisomerase inhibition coupled to PARP inhibition increased the amount of R-loops and acted synergistically in killing ETMR cells. These data show that targeting the genomic instability in ETMRs could be a viable treatment option for treating ETMR patients. Citation Format: Sander Lambo, Andrey Korshunov, Christin Schmidt, Carolina Romero, Aparna Gorthi, Sonja Krausert, Tobias Rausch, Susanne Gröbner, Sebastian Brabetz, Sebastian Waszak, Alexander J. Bishop, Stefan Pfister, Marcel Kool. Targeting genomic instability in embryonal tumors with multilayered rosettes (ETMR) [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 3172.

Embryonal Tumor with Multilayered Rosettes, C19MC-Altered: Clinical, Pathological, and Neuroimaging Findings.

Embryonal tumor with multilayered rosettes (ETMR), C19MC-altered, is a recently described, rare central nervous system tumor. To our knowledge, the imaging findings of this tumor have not been systematically evaluated in the neuroradiology literature. We present here the clinical, radiological, and pathological correlation of a case series of this very rare tumor, including the full range of anatomic compartment presentations (supratentorial, infratentorial, and spinal). We retrospectively analyzed 7 (4M, 3F) pathologically-proven cases of ETMR referred to our institution between 2007 and 2017. We demonstrate the imaging characteristics of this tumor on CT and MRI with advanced imaging. All of the patients are children (ages 1-12). On MR imaging of ETMR, contrast enhancement is often heterogeneous and minimal if any, and there is no significant surrounding T2 fluid-attenuated inversion recovery (FLAIR) hyperintensity to suggest edema. The lesions were often expansile with no evidence of infiltration of the fiber tracks that were displaced by the tumor mass. Diffusion-weighted imaging often demonstrated restricted diffusion within ETMRs. On magnetic resonance spectroscopy (MRS), the choline/creatine (Cho/Cr) ratio is increased, with low N-acetylaspartate (NAA) or NAA/Cho ratio, typical of high-grade tumors. We demonstrate the conventional and advanced imaging characteristics of ETMR, including MRS and diffusion tensor imaging, which, to our knowledge, have not been systematically evaluated in the radiology literature. The knowledge gained may potentially impact patient management, especially in inoperable cases and in locations where it is risky to perform a biopsy.

Incorporating Advances in Molecular Pathology Into Brain Tumor Diagnostics.

Recent advances in molecular pathology have reshaped the practice of brain tumor diagnostics. The classification of gliomas has been restructured with the discovery of isocitrate dehydrogenase (IDH) 1/2 mutations in the vast majority of lower grade infiltrating gliomas and secondary glioblastomas (GBM), with IDH-mutant astrocytomas further characterized by TP53 and ATRX mutations. Whole-arm 1p/19q codeletion in conjunction with IDH mutations now define oligodendrogliomas, which are also enriched for CIC, FUBP1, PI3K, NOTCH1, and TERT-p mutations. IDH-wild-type (wt) infiltrating astrocytomas are mostly primary GBMs and are characterized by EGFR, PTEN, TP53, NF1, RB1, PDGFRA, and CDKN2A/B alterations, TERT-p mutations, and characteristic copy number alterations including gains of chromosome 7 and losses of 10. Other clinically and genetically distinct infiltrating astrocytomas include the aggressive H3K27M-mutant midline gliomas, and smaller subsets that occur in the setting of NF1 or have BRAF V600E mutations. Low-grade pediatric gliomas are both genetically and biologically distinct from their adult counterparts and often harbor a single driver event often involving BRAF, FGFR1, or MYB/MYBL1 genes. Large scale genomic and epigenomic analyses have identified distinct subgroups of ependymomas tightly linked to tumor location and clinical behavior. The diagnosis of embryonal neoplasms also integrates molecular testing: (I) 4 molecularly defined, biologically distinct subtypes of medulloblastomas are now recognized; (II) 3 histologic entities have now been reclassified under a diagnosis of "embryonal tumor with multilayered rosettes (ETMR), C19MC-altered"; and (III) atypical teratoid/rhabdoid tumors (AT/RT) now require SMARCB1 (INI1) or SMARCA4 (BRG1) alterations for their diagnosis. We discuss the practical use of contemporary biomarkers for an integrative diagnosis of central nervous system neoplasia.

Extracranial extra-CNS spread of embryonal tumor with multilayered rosettes (ETMR): case series and systematic review

Embryonal tumors with multilayered rosettes (ETMR) is a rare variant of embryonal tumor of infancy with nearly 200 cases reported in the literature. Leptomeningeal spread of this tumor is well known; however, extracranial metastasis has been sparsely reported in the literature. Our study was divided into two sections: (1) We conducted a retrospective review of our patient series of ETMR and screened for patients with evidence of ETMR over the last 10years 2007-2017 at a single tertiary referral pediatric hospital, and (2) we conducted a systematic review according to PRISMA guidelines of all reported cases of ETMR to determine the incidence of extracranial metastasis and treatment paradigms. Here we report three cases of extracranial non-CNS spread of ETMR and conduct a systematic review of ETMR to improve our understanding of ETMR metastases and treatment paradigms. In our systematic review (n = 204), median overall survival was less than 1year with 44.1% children surviving over 1year. Previously, only five cases of extracranial metastasis of ETMR have been reported. Our case series (n = 3) and review demonstrate that these tumors may behave like soft tissue sarcomas and may be susceptible to tumor seeding through surgical manipulation or by CSF (ventriculoperitoneal shunt). Surgery for tumor recurrence may offer an improved local disease control, but preventative measures such as meticulous surgical resection may be necessary to reduce intraoperative contamination.

A mouse model for embryonal tumors with multilayered rosettes uncovers the therapeutic potential of Sonic-hedgehog inhibitors.

Embryonal tumors with multilayered rosettes (ETMRs) have recently been described as a new entity of rare pediatric brain tumors with a fatal outcome. We show here that ETMRs are characterized by a parallel activation of Shh and Wnt signaling. Co-activation of these pathways in mouse neural precursors is sufficient to induce ETMR-like tumors in vivo that resemble their human counterparts on the basis of histology and global gene-expression analyses, and that point to apical radial glia cells as the possible tumor cell of origin. Overexpression of LIN28A, which is a hallmark of human ETMRs, augments Sonic-hedgehog (Shh) and Wnt signaling in these precursor cells through the downregulation of let7-miRNA, and LIN28A/let7a interaction with the Shh pathway was detected at the level of Gli mRNA. Finally, human ETMR cells that were transplanted into immunocompromised host mice were responsive to the SHH inhibitor arsenic trioxide (ATO). Our work provides a novel mouse model in which to study this tumor type, demonstrates the driving role of Wnt and Shh activation in the growth of ETMRs and proposes downstream inhibition of Shh signaling as a therapeutic option for patients with ETMRs.