Abstract
Multi-potent stem-like cells (i.e. cancer stem cells, CSCs) are critical determinants of tumor propagation, therapeutic resistance, and recurrence in glioblastoma (GBM). Modifications in chromatin architecture play a fundamental role in the tumor cell phenotype of GBM. The polycomb repressor complex 2 (PRC2) is a key histone modifier that supports multi-potency and oncogenesis via H3K27 trimethylation (H3K27me3). Understanding how these epigenetic modifications cooperatively drive cancer cell stemness should unveil new targets for therapeutic development in GBM. Using a combination of next-generation sequencing, bioinformatics, and molecular approaches we identified EZH2, the catalytic domain of the PRC2 complex, as a critical mediator of reprograming events in GBM cells. We found that EZH2 is highly induced in response to transgenic Oct4/Sox2 with global increases in H3K27me3. Pharmacological inhibition of EZH2 diminishes self-renewal capacity of GBM neurospheres concurrent with a reduction in gene expression levels of markers and drivers of stemness. Furthermore, we identified and validated a set of 6 putative tumor suppressor genes repressed by Oct4 and Sox2 in a PRC2-dependent manner. We identified miR-217 as an EZH2 regulator in GBM cells and miR-217 reconstitution using advanced nanoparticle formulations re-activates the PRC2-repressed tumor suppressors, inhibited tumor growth and enhanced the effects of ionizing radiation in an orthotopic model of GBM. Taken together, these data show that PRC2-mediated chromatin changes in H3K27me3 help regulate the stem-cell phenotype induced by Oct4 and Sox2 in GBM cells and predict that targeting EZH2 could have therapeutic benefit in GBM.