Abstract Fundamentally, cancer arises from genetic and epigenetic alterations that interplay to reprogram gene expression networks, leading to unrestrained proliferation. Glioblastoma (GBM) is the most prevalent and aggressive primary brain cancer, with a median survival of approximately one year and a 5-year survival rate of just 5%. The standard care for GBM patients has remained unchanged for decades, underscoring the need for a better understanding of GBM biology to develop more effective therapies. The relatively low genetic mutation burden in GBM highlights the significant role of epigenetic mechanisms in its pathogenesis. Our recent work shows that chromatin remodeling plays pivotal roles in GBM pathogenesis. The BRD8-driven EP400 chromatin remodeling complex maintains GBM by crippling p53-mediated tumor suppression in an unprecedented way through hijacking the histone variant H2AZ at p53 target loci, enforcing a repressive chromatin state that prevents p53-mediated transactivation. Targeting BRD8 in TP53WT GBM, which makes up ~71% of all GBM cases, enhances chromatin accessibility by evicting H2AZ. This restores p53-mediated transactivation of its targets, reestablishes cell cycle arrest, inhibits gliomagenesis, and prolongs survival in xenograft models of TP53WT GBM. Conversely, the NuRD chromatin remodeling complex driven by CHD5 governs the MYC-mediated oncogenic network to prevent gliomagenesis. Mechanistically, CHD5 forms a CHD3-containing but CHD4-independent NuRD complex that directly binds to the MYC promoter and super enhancers. Chd5 loss triggers the remodeling of chromatin, enhances chromatin accessibility at Myc loci, augments Myc expression, significantly impairs NSCs differentiation while promotes proliferation, transformation, and gliomagenesis in vivo. Furthermore, reactivating CHD5 in human GBM xenograft models significantly extends survival. Thus, our findings reveal previously unappreciated epigenetic mechanisms by which GBM cells reprogram both tumor-suppressive and oncogenic transcription networks to facilitate their outgrowth. This sheds new light on our understanding of GBM malignancy and provides promising therapeutic opportunities for treating patients with this devastating malignancy.
Read full abstract