Exposure of CCRF-CEM cells to acridone derivative 8a triggers tumor death via multiple mechanisms.

A newly synthesized acridone derivative 8a shows potent antitumor activity against CCRF-CEM leukemia cells. Herein, the first proteomic study of 8a effects in CCRF-CEM cells was performed by 2D nano-LC-ESI-MS/MS to better understand the mechanisms of action of 8a. Data analyses based on PLGS, STRING, Cytoscape, and database for annotation, visualization, and integrated discovery identified 55 proteins that were differentially expressed in response to 8a exposure. Multiple cellular pathways were affected, including chromatin organization, energy metabolism, DNA repair, oxidative-stress, and apoptosis. The changes in protein expression were further verified for PKM2. Moreover, 8a lowered down the expression of HEX and PFK-1. Lactate production was decreased in 8a-treated cells, indicating suppression of glycolysis. The elevated XRCC6 and decreased histone expression levels suggested increased DNA damage in 8a-treated cells, which was confirmed by the increased γ-H2AX foci. Molecular docking of 8a with DNA demonstrated direct interactions of 8a with DNA through three hydrogen bonds and four π-π interactions, potentially explaining the mode of action that 8a damaged to DNA. The differential protein profiling and dysfunction of metabolic pathways induced by 8a provide novel insights into the potential action mechanisms of 8a.