Fujimori Hiroaki, Sato Akira, Kikuhara Sota, Wang Junhui, Hirai Takahisa, Sasaki Yuka, Murakami Yasufumi, Okayasu Ryuichi, Masutani Mitsuko
Division of Genome Stability Research, National Cancer Center Research Institute, 5-1-1 Tsukiji, Chuo-ku, Tokyo 104-0045, Japan.
Division of Chemotherapy and Translational Research, National Cancer Center Research Institute, 5-1-1 Tsukiji, Chuo-ku, Tokyo 104-0045, Japan.
Sci Rep. 2015 Dec 15;5:18231. doi: 10.1038/srep18231.
A comprehensive genome-wide screen of radiosensitization targets in HeLa cells was performed using a shRNA-library/functional cluster analysis and DNMT3B was identified as a candidate target. DNMT3B RNAi increased the sensitivity of HeLa, A549 and HCT116 cells to both γ-irradiation and carbon-ion beam irradiation. DNMT3B RNAi reduced the activation of DNA damage responses induced by γ-irradiation, including HP1β-, γH2AX- and Rad51-foci formation. DNMT3B RNAi impaired damage-dependent H2AX accumulation and showed a reduced level of γH2AX induction after γ-irradiation. DNMT3B interacted with HP1β in non-irradiated conditions, whereas irradiation abrogated the DNMT3B/HP1β complex but induced interaction between DNMT3B and H2AX. Consistent with radiosensitization, TP63, BAX, PUMA and NOXA expression was induced after γ-irradiation in DNMT3B knockdown cells. Together with the observation that H2AX overexpression canceled radiosensitization by DNMT3B RNAi, these results suggest that DNMT3B RNAi induced radiosensitization through impairment of damage-dependent HP1β foci formation and efficient γH2AX-induction mechanisms including H2AX accumulation. Enhanced radiosensitivity by DNMT3B RNAi was also observed in a tumor xenograft model. Taken together, the current study implies that comprehensive screening accompanied by a cluster analysis enabled the identification of radiosensitization targets. Downregulation of DNMT3B, one of the targets identified using this method, radiosensitizes cancer cells by disturbing multiple DNA damage responses.
利用shRNA文库/功能聚类分析对HeLa细胞中的放射增敏靶点进行了全基因组综合筛选,并确定DNMT3B为候选靶点。DNMT3B RNA干扰增加了HeLa、A549和HCT116细胞对γ射线和碳离子束照射的敏感性。DNMT3B RNA干扰降低了γ射线诱导的DNA损伤反应的激活,包括HP1β、γH2AX和Rad51灶的形成。DNMT3B RNA干扰损害了损伤依赖性H2AX的积累,并显示γ射线照射后γH2AX诱导水平降低。在未照射条件下,DNMT3B与HP1β相互作用,而照射消除了DNMT3B/HP1β复合物,但诱导了DNMT3B与H2AX之间的相互作用。与放射增敏一致,γ射线照射后,DNMT3B敲低细胞中TP63、BAX、PUMA和NOXA的表达被诱导。连同H2AX过表达消除了DNMT3B RNA干扰引起的放射增敏这一观察结果,这些结果表明,DNMT3B RNA干扰通过损害损伤依赖性HP1β灶的形成和包括H2AX积累在内的有效的γH2AX诱导机制诱导放射增敏。在肿瘤异种移植模型中也观察到DNMT3B RNA干扰增强了放射敏感性。综上所述,目前的研究表明,综合筛选和聚类分析能够识别放射增敏靶点。使用该方法鉴定出的靶点之一DNMT3B的下调通过干扰多种DNA损伤反应使癌细胞对放疗敏感。