In the present study, we found that EZH1 depletion in MYCN-amplified neuroblastoma cells resulted in significant cell death as well as xenograft inhibition. EZH1 depletion decreased the level of H3K27me1; the interaction and protein stabilization of MYCN and EZH1 appear to play roles in epigenetic transcriptional regulation. Transcriptome analysis of EZH1-depleted cells resulted in down-regulation of the cell cycle progression-related pathway. In particular, GSEA revealed down-regulation of reactome E2F-mediated regulation of DNA replication along with key genes of this process, TYMS, POLA2, and CCNA1. TYMS and POLA2 were transcriptionally activated by MYCN and EZH1-related epigenetic modification. Treatment with the EZH1/2 inhibitor UNC1999 also induced cell death, decreased H3K27 methylation, and reduced the levels of TYMS in NB cells. Previous reports indicated neuroblastoma cells are resistant to 5-fluorouracil (5-FU) and TYMS (encoding thymidylate synthetase) has been considered the primary site of action for folate analogues. Intriguingly, UNC1999 treatment significantly sensitized MYCN-amplified neuroblastoma cells to 5-FU treatment, suggesting that EZH inhibition may be an effective strategy for development of a new epigenetic treatment for neuroblastoma. Overall design: RNA was extracted at 2 days after shEZH1-expressing lentiviral infection, and a microarray analysis was performed using the Agilent platform of 8x60 K design ID G4851B (Agilent Single Color. 39494, Agilent Technologies). Two hundred nanograms of total RNA was labeled with Cyanine3 using a Low Input Quick-Amp Labeling Kit (one color, Agilent Technologies) according to the manufacturer’s instructions. Purified labeled total RNA was hybridized to the expression microarray. Hybridization, the scanning of microarrays, and data extraction from scanned images were conducted according to Agilent protocol version 6.9.