Abstract 2497: Glioma-induced neuronal remodeling promotes regional immunosuppression

Abstract Recent studies have elucidated that gliomas remodel neuronal circuits, and distinct intratumoral regions maintain functional connectivity through a subpopulation of synaptogenic malignant cells expressing Thrombospondin-1 (TSP-1, encoded by the THBS1 gene). Single-cell RNA sequencing analyses of our primary glioblastoma patient samples identified a significant downregulation of immune response signatures in myeloid cells and lymphoid cells in functionally connected intratumoral regions characterized by upregulated THBS1. Understanding the biological significance of immunosuppression within functionally connected intratumoral regions may uncover therapeutic vulnerabilities. Here, we investigate glioma-neuronal-immune crosstalk across clinical tumor specimens and preclinical syngeneic models through bulk and single-cell RNA sequencing (13,670 cells), flow cytometry, and spatial transcriptomics. Using an SB28 murine glioma cell line that endogenously expresses Thbs1 at high levels, we generated a CRISPR Thbs1-knock-out (KO) cell line. In bulk RNA-sequencing data performed on orthotopic tumor models, Thbs1-KO tumors were characterized by the downregulated expression of synapse-associated genes and synaptogenic factors and the recovered expression of genes related to immune response. It highlighted the important role of Thrombospondin-1 in synaptogenesis and immunosuppression consistent with the observation from our primary patient tumor samples. Flow cytometry revealed that tumor-associated macrophages isolated from Thbs1-KO tumors were more polarized toward the pro-inflammatory “M1-like” phenotype (median M1/M2 ratio = 0.6 [WT] vs. 1.34 [KO], p < 0.006). Unbiased gene expression program analysis using spatial transcriptomics for in vivo tumor-harboring mouse brains demonstrated a significant negative correlation between signatures of synaptogenesis (represented by Ntng1 and Nlgn3 genes) and those of immune response (represented by Nfkb1 and Cd83 genes). SB28-Thbs1-KO syngeneic models demonstrated slower tumor growth and significantly longer survival compared to Thbs1-WT counterparts (19 days [WT] vs. 25 days [KO], p < 4.5E-5). The survival difference was abrogated in B6-SCID immunodeficient mice, indicating the critical role of adaptive immunity in the survival advantage associated with Thrombospondin-1 downregulation. Our results identify previously unknown immunosuppression mechanisms in the context of glioma-induced intratumoral connectivity via Thrombospondin-1. Future therapeutic strategies targeting this glioma-neuronal-immune crosstalk may open up new avenues for glioblastoma immunotherapy. Citation Format: Takahide Nejo, Saritha Krishna, Christian Jimenez, Akane Yamamichi, Jacob S. Young, Tiffany Chen, Senthilnath Lakshmanachetty, Payal Watchmaker, Abrar Choudhury, Hirokazu Ogino, David R. Raleigh, Shawn L. Hervey-Jumper, Hideho Okada. Glioma-induced neuronal remodeling promotes regional immunosuppression [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 2497.