Abstract
Abstract Current standard of care therapy for glioblastoma (GB) includes cytoreduction followed by ablative therapies that target rapidly dividing cell types. However, non-cycling, quiescent-like states (G0 phase cells) are present in both normal tissue and tumors and play important roles in maintaining heterogeneity and cellular hierarchies. The presence of quiescent-like/G0 states therefore represents a natural reservoir of tumor cells that are resistant to current treatments. Quiescence or G0 phase is a reversible state of “stasis” cells enter in response to developmental or environmental cues. However, it remains largely unclear to what degree or by what mechanisms tumor cells enter into or exit from quiescent-like states. To gain insight into how GB cells might regulate G0-like states, we performed a genome-wide CRISPR-Cas9 screen in patient-derived GB stem-like cells (GSCs) harboring a G0 reporter construct, which is stabilized when cells enter a G0-like state. Among the top screen hits were members of the Tip60/KAT5 histone acetyltransferase complex, including KAT5 itself. Remarkably, we show that knockout of KAT5 in vitro and in vivo dramatically increases G0 subpopulations in GSC cultures and GSC-induced tumors. Using genetically engineered GSC harboring KAT5 under the control of a Doxycyclin-titratable promoter, we establish that incrementally down regulating KAT5 activity is sufficient to slow cell cycle dynamics causing a build-up G0-like cells; and that partial inhibition of KAT5 leads to extended (mouse) patient survival. Further, in primary tumors, cell-based KAT5 activity assays revealed that high grade tumors harbor larger cell subpopulations with higher KAT5 activity than lower grade tumors. In summary, our results suggest that Tip60/KAT5 activity plays key roles in G0 ingress/egress for GBM tumors, may contribute to tumor progression, and may provide novel therapeutic opportunities.
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