P12.08.A CELL-EXTRINSIC D-2-HYDROXYGLUTARATE PROMOTES HYPERMETHYLATION AT LINEAGE-SPECIFIC REGULATORY REGIONS TO PREVENT MICROGLIAL ACTIVATION IN IDH-MUTANT GLIOMAS

Abstract

Abstract BACKGROUND Tumor-associated macrophages and microglia (TAMs) are highly abundant myeloid cells in diffuse gliomas. Their composition and transcriptional programs differ according to the IDH mutation status of glioma cells. The underlying mechanisms remain until now little known. MATERIAL AND METHODS We compared bulk DNA methylome (Methylation EPIC array) and transcriptome of TAMs (CD11b+ purified by magnetic-activated cell sorting) from 25 IDH-mutant and 11 IDH-wildtype gliomas. The contamination of the CD11b+ fraction by tumor cells was determined by the detection of IDH and/or TERT mutations using droplet digital PCR. Only samples with a purity of at least 95% were used for analyses. To determine experimentally direct effects of D-2-hydroxyglutarate (D-2-HG), which is the oncometabolite produced and realeased into the microenvironment by IDH-mutated glioma cells, we used primary cultures of human microglial cells obtained from glioma surgery or epilepsy surgery. We exposed microglia or not to (D-2-HG) during 14 days, and analyzed their DNA methylome and transcriptome. RESULTS TAMs from IDH-mutant gliomas compared with TAMs from IDH-wildtype gliomas exhibit decreased expression of pro-inflammatory pathways (mainly IFN-γ, IFN-α, and TNF-α signaling) and genes related to G2-M checkpoint, glycolysis and Epithelial-Mesenchymal Transition (EMT). We uncovered that TAMs from IDH-mutant gliomas exhibit significant hypermethylation at promoters and enhancers linked to decreased expression of genes involved in inflammatory responses. Notably, these hypermethylated regions were enriched for binding motifs of transcription factors controlling an environment-dependent transcriptional network in microglial cells (such as PU.1, AP-1, C/EBP and RUNX). These findings were confirmed by comparing methylome data of TAMs from IDH-mutant gliomas and methylome of microglia from normal brains available in the literature. A 14 days exposition to D-2-HG of human microglial cells in vitro partially recapitulates the observed methylation changes. Transcriptome analyses of these cells show that this oncometabolite dampens the IFN-α/γ pathways and attenuates the response to LPS while inducing a metabolic shift toward oxidative phosphorylation. CONCLUSION Our findings establish a link between an extrinsic cell-effect of D-2-HG and the hypermethylation of DNA of microglial cells at regulatory regions in IDH-mutant gliomas. Our observations support the concept that oncometabolites may disrupt directly the function of immune cells of the tumor microenvironment.