IMMU-30. IDENTIFICATION OF COORDINATELY REGULATED IMMUNO-MODULATORY GENES USING SINGLE-CELL RNA SEQUENCING OF DECITABINE TREATED GLIOMA CELLS

Abstract

Abstract INTRODUCTION The immunotherapeutic targeting of New York-esophageal squamous cell carcinoma (NY-ESO-1) and other cancer/testis antigens (CTA) is an appealing strategy for the treatment of malignant gliomas because CTA are not expressed in most normal adult tissues and their expression can be induced in tumors for targeting by T-cells. Basally, NY-ESO-1 is often poorly expressed in glioblastoma (GBM), presumably through promoter methylation. Our previous data has shown that the hypomethylating agent decitabine (DAC) is a strong sensitizer of GBM to NY-ESO-1 specific adoptive T-cell induced cytotoxicity. However, we hypothesized that DAC alters expression of other immuno-modulatory genes in addition to NY-ESO-1 that may also increase T-cell mediated killing in GBM. The extent of regulation of other immuno-modulatory genes to DAC demethylation has not yet been thoroughly investigated. METHODS We performed single-cell RNA sequencing on DAC and non-DAC treated glioma cells. We confirmed DAC treatment induced NY-ESO-1 expression with quantitative real-time PCR and demethylation using bisulfite sequencing. We analyzed our single-cell RNA sequencing data with Seurat and our customized R-based pipelines to identify coordinate differential expression of immuno-modulatory genes and their tumor subpopulations. RESULTS Using our single-cell data, we identified tumor subpopulations with coordinate differentially expressed immuno-modulatory genes including cancer testes antigens, antigen presentation proteins, and apoptosis regulators. Amongst these candidate genes, we validated their expression with qPCR and promoter demethylation with bisulfite sequencing and TA bisulfite cloning. CONCLUSION Exposure of glioma cells to DAC results in promoter demethylation of NY-ESO-1, with increased expression of CTA and other immunomodulatory genes. DAC treatment may therefore sensitize GBM to the immunotherapeutic targeting of these antigens and reveals a feasible strategy for clinical translation.