EPCO-12. IN VIVO PERTURB-SEQ DEFINES BIOLOGICAL DRIVERS AND THERAPEUTIC VULNERABILITIES UNDERLYING RADIOTHERAPY RESISTANCE IN GLIOBLASTOMA

Abstract

Abstract Glioblastomas are comprised of dynamic malignant cell states and microenvironment cell types. Mechanistic and functional studies of glioblastoma resistance to therapy have been limited by a lack of in vivo approaches for multiplexed interrogation of single cells. Here we use genome-wide and targeted CRISPR interference (CRISPRi) to identify therapeutic vulnerabilities in glioblastomas in vivo by coupling convection enhanced delivery (CED) with functional genomics and single-cell transcriptomics (perturb-seq). Human (GBM43, LN18) or mouse (GL261, SB28) glioblastomas expressing CRISPRi machinery were established intracranially in mice, and unmodified mouse glioblastomas were established intracranially in immunocompetent mice expressing CRISPRi machinery in the tumor microenvironment. Perturb-seq gene prioritization was performed using genome-wide CRISPRi screens ± radiotherapy in cell cultures. Dual-sgRNA Perturb-seq lentivirus libraries were transduced in vivo using CED, and single-cell RNA sequencing with sgRNA capture was performed ± radiotherapy. RESULTS: were validated using RNA sequencing of 254,288 single nuclei from 43 pairs of primary and recurrent patient-matched human glioblastomas. Perturb-seq ± radiotherapy of 98 genes underlying glioblastoma radiotherapy responses was performed across 414,092 single cells in vivo. Genetic perturbations reprogrammed tumor and microenvironment cell states in response to radiotherapy, and high dimensional manifolds revealed genetic dependencies in metabolic and DNA damage response pathways. The DNA-dependent protein kinase (DNA-PK) component PRKDC was identified as a driver of glioblastoma radiotherapy resistance through regulation of malignant cell-intrinsic growth and stress pathways, and regulation of malignant cell-extrinsic interferon pathways that controlled cell-cell interactions with the tumor microenvironment. PRKDC inhibition with nedisertib sensitized glioblastomas to radiotherapy and extended survival in vivo, and single-cell RNA sequencing revealed hyperactivation of cell stress and cytokine signatures with combination treatment. In summary, we report in vivo perturb-seq as a platform for simultaneous discovery and functional interrogation of therapeutic vulnerabilities in glioblastoma, and show DNA-PK inhibition sensitizes glioblastomas to radiotherapy in vivo.