EPCO-11. SINGLE-NUCLEI TRANSCRIPTOMICS RELATES GLIOBLASTOMA INFILTRATION TO DISTINCT GLIAL PROGENITOR STATES

Our understanding of glioblastoma (GBM) intratumoral heterogeneity, particularly in the context of neurodevelopment, has thus far been primarily focused on the more surgically accessible tumor core niche. In contrast, the biology of GBM cells at the infiltrative edge, which evade surgical resection and drive tumor recurrence, remains poorly characterized. To this end, we microdissected and performed single-nuclei RNA sequencing (snRNA-seq) on approximately 62,000 nuclei taken from the tumor core and from the infiltrative edge of six GBM tumors with diverse genomic drivers, including IDH1, EGFR, PDGFRA, FGFR3, and NF1. Unbiased clustering reveals distinct neoplastic and non-neoplastic populations, further distinguished using copy number variation analysis. After projecting previously defined signatures taken from snRNA-seq analysis of human adult neocortex/subventricular zone and prenatal germinal matrix, we find that approximately 90% of tumor cells recapitulate a neurodevelopment-like molecular phenotype, reprising gene expression signatures of prenatal astrocytes and of a distinct glial intermediate progenitor cell population (g-IPC) that precedes both astrocyte and oligodendrocyte lineage differentiation. Examining the infiltrative edge of samples with the most confident microdissection (n=4), we see that while distinct populations of tumor cells in this niche express proneural and classical signatures, these cells are overall enriched for a g-IPC-like phenotype, relative to the tumor core, irrespective of the tumors’ genomic alterations. A subset of cells at the infiltrative edge, in particular, recapitulates the signature of an uncommitted g-IPC subtype, expressing both astroglial and oligodendroglial markers. Trajectory analyses also reveal distinct branches of core and edge tumor cells, which are predominantly astrocyte- and g-IPC-like, respectively. Differential gene expression analysis of GBM cells at the infiltrative edge vs. tumor core reveals a migration signature, dominated by EGFR, ERBB4, PCDH9, and PCDH15. Ultimately, this high resolution analysis of heterogeneity at the infiltrative edge allows us to uncover potentially targetable drivers of invasion in GBM.

STAU2 binds a Complex RNA Cargo that changes temporally with production of diverse intermediate progenitor cells during mouse corticogenesis

STAU2 is a double-stranded RNA-binding protein enriched in the nervous system. During asymmetric divisions in the developing mouse cortex, STAU2 preferentially distributes into the intermediate progenitor cell (IPC), delivering RNA molecules that can impact IPC behavior. Corticogenesis occurs on a precise time-schedule, raising the hypothesis that the cargo STAU2 delivers into IPCs changes over time. To test this, we combine RNA-immunoprecipitation with sequencing (RIP-seq) over four stages of mouse cortical development, generating a comprehensive cargo profile for STAU2. A subset of the cargo was ‘stable’, present at all stages, and involved in chromosome organization, macromolecule localization, translation, and DNA repair. Another subset was ‘dynamic’, changing with cortical stage, and involved in neurogenesis, cell projection organization, neurite outgrowth, and included cortical layer markers. Notably, the dynamic STAU2 cargo included determinants of IPC versus neuronal fates and genes contributing to abnormal corticogenesis. Knockdown of one STAU2 target, Taf13, previously linked to microcephaly and impaired myelination, reduced oligodendrogenesis in vitro. We conclude that STAU2 contributes to the timing of corticogenesis by binding and delivering complex and temporally-regulated RNA cargo into IPCs.