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Multi-omic approach identifies hypoxic tumor-associated myeloid cells that drive immunobiology of high-risk pediatric ependymoma

Andrea M. Griesinger, Kent Riemondy, Nithyashri Eswaran, Andrew M. Donson, Nicholas Willard, Eric Prince, Simon Paine, Georgia Bowes, John Rheaume, Rebecca Chapman, Judith M. Ramage, Andrew M. Jackson, Richard G. Grundy, Nicholas K. Foreman, Timothy Ritzmann

2023iScience16 citationsDOIOpen Access PDF

Abstract

Ependymoma (EPN) is a devastating childhood brain tumor. Single-cell analyses have illustrated the cellular heterogeneity of EPN tumors, identifying multiple neoplastic cell states including a mesenchymal-differentiated subpopulation which characterizes the PFA1 subtype. Here, we characterize the EPN immune environment, in the context of both tumor subtypes and tumor cell subpopulations using single-cell sequencing (scRNAseq, n = 27), deconvolution of bulk tumor gene expression (n = 299), spatial proteomics (n = 54), and single-cell cytokine release assays (n = 12). We identify eight distinct myeloid-derived subpopulations from which a group of cells, termed hypoxia myeloid cells, demonstrate features of myeloid-derived suppressor cells, including IL6/STAT3 pathway activation and wound healing ontologies. In PFA tumors, hypoxia myeloid cells colocalize with mesenchymal-differentiated cells in necrotic and perivascular niches and secrete IL-8, which we hypothesize amplifies the EPN immunosuppressive microenvironment. This myeloid cell-driven immunosuppression will need to be targeted for immunotherapy to be effective in this difficult-to-cure childhood brain tumor.

Topics & Concepts

MyeloidEpendymomaTumor microenvironmentImmunotherapyBiologyMesenchymal stem cellCancer researchImmune systemImmunologyMedicinePathologyCell biologySingle-cell and spatial transcriptomicsImmune cells in cancerExtracellular vesicles in disease