X射线对人淋巴母细胞基因表达谱的影响

doi:10.13491/j.issn.1004-714x.2019.04.006

中国辐射卫生

2019, Vol. 28

Issue (4): 371-375 DOI: 10.13491/j.issn.1004-714x.2019.04.006

放射生物学/论著

本期目录 | 过刊浏览 | 高级检索

X射线对人淋巴母细胞基因表达谱的影响

方连英, 李卫国, 马娅, 毛雪松, 侯殿俊, 朱伟, 贾喜明, 乔建维, 李洁清

山东省医学科学院放射医学研究所, 山东济南 250062

Alterations of gene transcriptional profiles in human lymphoblastoid cells by X-ray exposure

FANG Lianying, LI Weiguo, MA Ya, MAO Xuesong, HOU Dianjun, ZHU Wei, JIA Ximing, QIAO Jianwei, LI Jieqing

Institute of Radiation Medicine, Shangdong Academy of Medical Sciences, Jinan 250062 China

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (949 KB) HTML ( )
输出: BibTeX | EndNote (RIS)

摘要目的应用基因芯片分析X射线对人淋巴母细胞基因表达的影响，为阐明辐射生物效应的作用机制提供理论依据。方法应用基因芯片分析人淋巴细胞经0.5和2 Gy X射线照射后的基因表达情况，通过Real-time PCR对部分差异表达基因进行验证。结果人淋巴母细胞经0.5和2 Gy X射线照射后6h差异表达基因分别有1 250和1 773个，照射后20 h差异表达基因分别有1 076和690个。通过Real-time PCR验证差异表达的基因PERP与基因芯片结果一致，与对照组相比表达下调。结论电离辐射诱导差异表达的基因与照射剂量和照后时间相关，本研究为寻找新型辐射生物剂量计和研究辐射生物效应机制提供了新的理论依据。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	方连英
	李卫国
	马娅
	毛雪松
	侯殿俊
	朱伟
	贾喜明
	乔建维
	李洁清

关键词 ：电离辐射, 人淋巴母细胞, 基因表达谱, PERP

收稿日期: 2019-03-01

PACS:

Q691.5

基金资助:山东省自然基金（ZR2017YL007）；山东省医药卫生科技发展计划（2016WS0520）

通讯作者: 李洁清,E-mail:stx90@163.com E-mail: stx90@163.com

作者简介: 方连英(1990-),女,山东德州人,博士,主要研究放射生物学。E-mail:flianying@126.com

引用本文:

方连英, 李卫国, 马娅, 毛雪松, 侯殿俊, 朱伟, 贾喜明, 乔建维, 李洁清. X射线对人淋巴母细胞基因表达谱的影响[J]. 中国辐射卫生, 2019, 28(4): 371-375.
FANG Lianying, LI Weiguo, MA Ya, MAO Xuesong, HOU Dianjun, ZHU Wei, JIA Ximing, QIAO Jianwei, LI Jieqing. Alterations of gene transcriptional profiles in human lymphoblastoid cells by X-ray exposure. , 2019, 28(4): 371-375.

链接本文:

http://www.zgfsws.com/CN/10.13491/j.issn.1004-714x.2019.04.006 或 http://www.zgfsws.com/CN/Y2019/V28/I4/371

[1] Tubbs A, Nussenzweig A. Endogenous DNA damage as a source of genomic instability in cancer[J]. Cell, 2017, 168(4):644-656.
[2] Smirnov D A, Morley M, Shin E, et al. Genetic analysis of radiation-induced changes in human gene expression[J]. Nature, 2009, 459(7246):587-591.
[3] 尹晶晶,秦秀军,张伟,等. 大鼠外周血淋巴细胞2 Gy γ射线照射后12 h差异基因表达谱的研究[J].中国辐射卫生, 2013, 22(3):267-269.
[4] Cash H, Dean D. The effects of low-dose radiation on articular cartilage:a review[J]. J Biol Eng, 2019, 13:1.
[5] Balog R P, Bacher R, Chang P, et al. Development of a biodosimeter for radiation triage using novel blood protein biomarker panels in humans and non-human primates[J]. International Journal of Radiation Biology, 2019:1-13.
[6] 李洁清,李坤,封丽,等.X射线照射AHH-1细胞基因表达转录谱变化研究[J].中国职业医学, 2013, 40(5):420-426.
[7] 陈忠民,刘波,南新中,等.低剂量电离辐射损伤检测技术及其研究进展[J].中国辐射卫生, 2017,26(2):254-256.
[8] 王畅,黎金荣,莫素芳,等.放射工作人员淋巴细胞微核异常影响因素的病例对照研究[J].中国辐射卫生,2018,27(3):209-212.
[9] Long XH, Zhao ZQ, He XP, et al. Dose-dependent expression changes of early response genes to ionizing radiation in human lymphoblastoid cells[J]. Int J Mol Med, 2007, 19(4):607-15.
[10] Premkumar K, Shankar B S. Involvement of MAPK signalling in radioadaptive response in BALB/c mice exposed to low dose ionizing radiation[J]. International Journal of Radiation Biology, 2016, 92(5):249-262.
[11] Kita K, Sugita K, Sato C, et al. Extracellular release of annexin A2 is enhanced upon oxidative stress response via the p38 MAPK pathway after low-dose X-ray irradiation[J]. Radiation Research, 2016, 186(1):79-91.
[12] Jazayeri A, Falck J, Lukas C, et al. ATM-and cell cycle-dependent regulation of ATR in response to DNA double-strand breaks[J]. Nat Cell Biol, 2006, 8(1):37-45.
[13] Balmus G, Pilger D, Coates J, et al. ATM orchestrates the DNA-damage response to counter toxic non-homologous end-joining at broken replication forks[J]. Nat Commun, 2019, 10:87.
[14] Fischer M, Quaas M, Steiner L, et al. The p53-p21-DREAM-CDE/CHR pathway regulates G2/M cell cycle genes[J]. Nucleic Acids Res, 2016, 44(1):164-174.
[15] Nukina K, Hayashi A, Shiomi Y, et al. Mutations at multiple CDK phosphorylation consensus sites on Cdt2 increase the affinity of CRL4Cdt2 for PCNA and its ubiquitination activity in S phase[J]. Genes Cells, 2018, 23(3):200-213.
[16] Budworth H, Snijders AM, Marchetti F, et al. DNA repair and cell cycle biomarkers of radiation exposure and inflammation stress in human blood[J]. PLoS One, 2012, 7(11):e48619.
[17] Cazzalini O, Perucca P, Mocchi R, et al. DDB2 association with PCNA is required for its degradation after UV-induced DNA damage[J]. Cell Cycle, 2014, 13(2):240-248.
[18] Zou N, Xie G Z, Cui T T, et al. DDB2 increases radioresistance of NSCLC cells by enhancing DNA damage responses[J]. Tumor Biol, 2016, 37(10):14183-14191.
[19] Xue B. Coordination between p21 and DDB2 in the cellular response to UV radiation[J]. PLoS One, 2013, 8(11):e80111.
[20] Singaravelu K, Devalaraja-Narashimha K, Lastovica B, et al. PERP, a p53 proapoptotic target, mediates apoptotic cell death in renal ischemia[J]. American Journal of Physiology-Renal Physiology, 2009, 296(4):F847-F858.