Abstract

Abstract In solid tumors, G0-like states are likely critical for maintaining developmental hierarchies and cellular heterogeneity and promoting tumor growth/recurrence, yet little is known about tumor G0 states or regulation of their ingress/egress. To discover G0-like states and their regulators for glioblastoma (GBM), we previously performed a genome-wide CRISPR-Cas9 screen in patient-derived GBM stem-like cells (GSCs) for genes that trap cells in G0 when inhibited. We identify the protein acetyltransferase KAT5 as a key regulator of GBM G0 ingress/egress. Here, we show in an in vivo GSC-derived orthotopic xenograft model that KAT5 regulates transcriptional, epigenetic, and proliferative heterogeneity impacting transitions into G0-like states. We show that KAT5 activity suppresses the emergence of non-dividing subpopulations with oligodendrocyte progenitor and radial glial cell characteristics. With regard to chromatin regulation, we show that loss of KAT5 activity alters sites of mixed epigenetic valency (which have both activating and repressive marks in bulk tumor populations) to promote emergence of OPC/RG G0-like populations in tumors. Our data reveal KAT5-associated transcriptional and epigenetic changes in tumors, which indicate that KAT5 activity biases cell state distribution away from OPC and RG-like subpopulations. In addition, loss of KAT5 resulted in a less invasive phenotype and prolonged survival of mice harboring orthotopic xenografts.

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