共抑制RAD18和REV1基因显著增加顺铂对肺癌细胞的毒性

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摘要目的: 探讨采用基因敲减技术抑制跨损伤合成（translesion synthesis,TLS）通路和范可尼贫血（Fanconi anemia,FA)通路上游的RAD18基因与TLS通路的REV1基因后增加顺铂对人肺腺癌耐药细胞株（A549/DDP）细胞毒性的可行性及其机制。方法: 蛋白质印迹法测定顺铂诱导的A549和A549/DDP细胞RAD18和REV1蛋白表达；应用脂质体转染试剂转染针对RAD18基因的siRNAs (RAD18siRNA)，检测A549/DDP细胞转染前后顺铂诱导的FANCD2和PCNA蛋白单泛素化水平；CCK8法检测分别转染RAD18siRNA、REV1siRNA以及两者共转染前后经顺铂处理的A549/DDP细胞的增殖率；流式细胞术检测转染前后A549/DDP细胞凋亡率和细胞周期。结果： A549/DDP细胞转染RAD18siRNA和REV1siRNA后，RAD18和REV1蛋白表达明显降低，表明转染有效，基因敲减成功。转染RAD18siRNA后顺铂诱导的FANCD2和PCNA蛋白的单泛素化水平明显下降，提示FA通路和TLS通路的激活受到抑制。分别转染RAD18siRNA或REV1siRNA均可增强顺铂对A549/DDP的细胞毒性，增加顺铂诱导的细胞凋亡率，并增强细胞周期S/G2期的阻滞效应。共转染RAD18siRNA和REV1siRNA后，顺铂对A549/DDP细胞的毒性增强作用较单转染更为显著，顺铂诱导的细胞凋亡进一步增加。结论：敲减A549/DDP细胞的RAD18和REV1基因可通过抑制FA通路和TLS通路的DNA损伤修复功能，增加A549/DDP细胞对顺铂的敏感性；RAD18和REV1基因共敲减对顺铂的这一增敏作用更加明显，显示出A549/DDP细胞对顺铂耐药的逆转效应。

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关键词 ：肺癌细胞, 顺铂, 耐药, RAD18, REV1, siRNA

Abstract：Objective: To explore the effects of RAD18 and REV1 gene knockdowns on cisplatin cytotoxicity in cisplatinresistant A549/DDP cell line. Methods: The expression of RAD18 and REV1 protein, and the FANCD2 and PCNA monoubiquitination level were detected by Western blotting. The siRNAs against RAD18 and REV1 genes(RAD18siRNA and REV1siRNA) were transfected into A549/DDP cells using Lipofectamine. The CCK8 assay was used to detect the changes of cell proliferation rate following treatment with cisplatin before and after transfection of RAD18siRNA and REV1siRNA in A549/DDP cells. Cisplatininduced cell apoptosis and cell cycle were detected by flow cytometry in A549/DDP cells pre and posttransfection of RAD18siRNA and REV1siRNA. Results: The expressions of RAD18 and REV1 proteins were significantly decreased after transfection of RAD18siRNA or REV1siRNA, indicating that the transfections were successful. Cisplatininduced monoubiquitinations of FANCD2 and PCNA were significantly decreased after transfection with RAD18siRNA, suggesting that the activation of the FA pathway and the TLS pathway was suppressed. Individual knockdown of RAD18 or REV1 by siRNAs transfection enhanced the cytotoxicity of cisplatin to A549/DDP cells, promoted cell apoptosis induced by cisplatin, and resulted in the arrest of S/G2 phase. Coknockdown of RAD18 and REV1 genes further enhanced the cytotoxicity of cisplatin to A549/DDP cells compared to RAD18 or REV1 knockdown alone. Conclusion: Knockdowns of RAD18 gene of the TLS pathway and the Fanconi anemia（FA） pathway upstream and REV1 gene of the TLS pathway could increase the sensitivity of cisplatinresistant A549/DDP cells to cisplatin by inhibiting the DNA damage repair capacity,and the sensitization can be further potentiated by coknockdown of RAD18 and REV1.

收稿日期: 2017-12-27

通讯作者: 李坚(通讯作者)，教授，主任医师，博士生导师，E-mail: lijian541226@163.com

作者简介: 金君(1992—)，女，硕士研究生

引用本文:

金君，李坚，袁荣霞. 共抑制RAD18和REV1基因显著增加顺铂对肺癌细胞的毒性[J]. 江苏大学学报:医学版, 2018, 28(02): 109-116. JIN Jun, LI Jian, YUAN Rong-xia. Co-inhibition of RAD18 and REV1 gene markedly enhance the cytotoxicity of cisplatin to lung cancer A549 /DDP cell line. Journal of Jiangsu University(Medicine Edition), 2018, 28(02): 109-116.

链接本文:

http://zzs.ujs.edu.cn/xbyxb/CN/ 或 http://zzs.ujs.edu.cn/xbyxb/CN/Y2018/V28/I02/109

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