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中华肾病研究电子杂志

中华肾病研究电子杂志 ›› 2016, Vol. 05 ›› Issue (04) : 182 -185. doi: 10.3877/cma.j.issn.2095-3216.2016.04.009

所属专题: 文献

综述

核辐射对肾脏致癌作用的机制
郑新明1, 那宇1,()   
  1. 1. 100101 安徽医科大学解放军306临床学院、解放军306医院
  • 收稿日期:2016-06-07 出版日期:2016-08-28
  • 通信作者: 那宇
  • 基金资助:
    "十二五"国家科技支撑计划(核辐射医院救治信息系统与应用示范)(2013BAHO2B05)

Mechanism of renal cell carcinoma induced by nuclear radiation

Xinming Zheng1, Yu Na1,()   

  1. 1. Chinese PLA 306 Hospital Affiliated to Chinese PLA 306 Clinical School, Anhui Medical University, Beijing 100101, China
  • Received:2016-06-07 Published:2016-08-28
  • Corresponding author: Yu Na
  • About author:
    Corresponding author: Na Yu, Email:
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引用本文:

郑新明, 那宇. 核辐射对肾脏致癌作用的机制[J]. 中华肾病研究电子杂志, 2016, 05(04): 182-185.

Xinming Zheng, Yu Na. Mechanism of renal cell carcinoma induced by nuclear radiation[J]. Chinese Journal of Kidney Disease Investigation(Electronic Edition), 2016, 05(04): 182-185.

核能(nuclear energy ),又称原子能,是原子核中的核子重新分配时释放出来的能量,是当今世界上污染少、成本低、运输方便的新型能源。但是核泄漏所引起的放射性污染对人类的健康危害巨大,其中肾脏是对辐射敏感的器官之一,长期慢性的核辐射可能导致肾细胞癌的发病率增加。本文对核辐射所致肾细胞癌的发生机制进行了综述。

关键词: 核辐射, 肾细胞癌, 机制

Nuclear energy, also known as atomic energy, is the nuclear power released when nucleons redistribute. It is a new type of energy in the world with the characteristics of less pollution, lower cost, and easier transportation. But the radioactive pollution caused by nuclear leakage is harmful to the human health. The kidney is one of the most sensitive organs to nuclear radiation. Long-term chronic radiation may increase the incidence of renal cell carcinomas. Here, the mechanism of renal cell carcinoma induced by nuclear radiation was reviewed.

Key words: Nuclear radiation, Renal cell carcinoma, Mechanism
[1]
Oumeish OY. Nuclear terrorism: health and environmental hazards and threats from ionizing and nuclear radiation[J]. Clin Dermatol, 2002, 20(4): 330-335.
[2]
Pollock NJ. Health transitions, fast and nasty: the case of Marshallese exposure to nuclear radiation[J]. Pac Health Dialog, 2002, 9(2): 275-282.
[3]
Vozianov AF,Pasechnicov SP,Pavlova LP, et al. The state of urologic assistance for the population of Ukraine and the ways to improve it[J]. Urology Kiev Ukraine, 1998, 1: 3-9.
[4]
Blanco Espinosa A,Leva Vallejo M,Merlo de la Peña F, et al. Association of renal carcinoma and the exposure to ionizing radiation after the Chernobyl accident[J]. Actas Urol Esp, 2003, 27(2): 164-167.
[5]
Romanenko A,Morell-Quadreny L,Nepomnyaschy V, et al. Pathology and proliferative activity of renal-cell carcinomas (RCCs) and renal oncocytomas in patients with different radiation exposure after the Chernobyl accident in Ukraine[J]. Int J Cancer, 2000, 87(6): 880-883.
[6]
Richardson DB,Hamra G. Ionizing radiation and kidney cancer among Japanese atomic bomb survivors[J]. Radiat Res, 2010, 173(6): 837-842.
[7]
Robbins BA,de la Vega D,Ogata K, et al. Immunohistochemical detection of proliferating cell nuclear antigen in solid human malignancies[J]. Arch Pathol Lab Med, 1987, 111(9): 841-845.
[8]
Kawamura K,Kobayashi Y,Tanaka T, et al. Intranuclear localization of proliferating cell nuclear antigen during the cell cycle in renal cell carcinoma[J]. Anal Quant Cytol Histol, 2000, 22(2): 107-113.
[9]
Cares C,Hancock JF,Marshall CJ, et al. The cytoplasmic protein GAP is implicated as the target for regulation by the ras gene product[J]. Nature, 1988, 332(6164): 548-551.
[10]
Kamai T,Arai K,Koga F, et al. Higher expression of K-ras is associated with parathyroid hormone-related protein-induced hypercalcaemia in renal cell carcinoma[J]. BJU Int, 2001, 88(9): 960-966.
[11]
King S,Bray S,Galbraith S, et al. Evidence for aldosterone-dependent growth of renal cell carcinoma[J]. Int J Exp Pathol, 2014, 95(4): 244-250.
[12]
Romanenko A,Morell-Quadreny L,Nepomnyaschy V, et al. Radiation sclerosing proliferative atypical nephropathy of peritumoral tissue of renal-cell carcinomas after the Chernobyl accident in Ukraine[J]. Virchows Arch, 2001, 438(2): 146-153.
[13]
Romanenko A,Morell-Quadreny L,Lopez-Guerrero JA, et al. P16INK4A and p15INK4B gene alteration associated with oxidative stress in renal cell carcinomas after the Chernobyl accident (pilot study)[J]. Diagn Mol Pathol, 2002, 11(3): 163-169.
[14]
Romanenko A,Morell-Quadreny L,Lopez-Guerrero JA, et al. The INK4a/ARF locus: role in cell cycle control for renal cell epithelial tumor growth after the Chernobyl accident[J]. Virchows Arch, 2004, 445(3): 298-304.
[15]
Barcellos-Hoff MH. Integrative radiation carcinogenesis: interactions between cell and tissue responses to DNA damage[J]. Semin Cancer Biol, 2005, 15(2): 138-148.
[16]
Romanenko A,Morell-Quadreny L,Ramos D, et al. Extracellular matrix alterations in conventional renal cell carcinomas by tissue microarray profiling influenced by the persistent, long-term, low-dose ionizing radiation exposure in humans[J]. Virchows Arch, 2006, 448(5): 584-590.
[17]
Ehrhart EJ,Segarini P,Tsang ML, et al. Latent transforming growth factor-beta1 activation in situ: quantitative and functional evidence after low-dose gamma-irradiation[J]. FASEB J, 1997, 11(12): 991-1002.
[18]
Boguslawska J,Kedzierska H,Poplawski P, et al. Expression of genes involved in cellular adhesion and extracellular matrix remodeling correlates with poor survival of patients with renal cancer[J]. J Urol, 2016, 195(6): 1892-1902.
[19]
Vainionpää N,Lehto VP,Tryggvason K, et al. Alpha4 chain laminins are widely expressed in renal cell carcinomas and have a de-adhesive function[J]. Lab Invest, 2007, 87(8): 780-791.
[20]
Okuma E,Ohishi Y,Oda Y, et al. Cytoplasmic and stromal expression of laminin γ 2 chain correlates with infiltrative invasion in ovarian mucinous neoplasms of gastro-intestinal type[J]. Oncol Rep, 2010, 24(6): 1569-1576.
[21]
Bajpai S,Feng Y,Wirtz D, et al.β-Catenin serves as a clutch between low and high intercellular E-cadherin bond strengths[J]. Biophys J, 2013, 105(10): 2289-2300.
[22]
Voronkov A,Krauss S. Wnt/beta-catenin signaling and small molecule inhibitors[J]. Curr Pharm Des, 2013, 19(4): 634-664.
[23]
Gumbiner BM. Regulation of cadherin adhesive activity[J]. J Cell Biol, 2000, 148(3): 399-404.
[24]
Pecina-Šlaus N,Kafka A,Vladušic T, et al. Loss of p53 expression is accompanied by upregulation of beta-catenin in meningiomas: a concomitant reciprocal expression[J]. Int J Exp Pathol, 2016, 97(2): 159-169.
[25]
McBride WH,Iwamoto KS,Syljuasen R, et al. The role of the ubiquitin/proteasome system in cellular responses to radiation[J]. Oncogene, 2003, 22(37): 5755-5763.
[26]
Dianov GL,Meisenberg C,Parsons JL. Regulation of DNA repair by ubiquitination[J]. Biochemistry (Mosc), 2011, 76(1): 69-79.
[27]
Bartek J,Hodny Z. SUMO boosts the DNA damage response barrier against cancer[J]. Cancer Cell, 2010, 17(1): 9-11.
[28]
Morell-Quadreny L,Romanenko A,Lopez-Guerrero JA, et al. Alterations of ubiquitylation and sumoylation in conventional renal cell carcinomas after the Chernobyl accident: a comparison with Spanish cases[J]. Virchows Arch, 2011, 459(3): 307-313.
[29]
Kavantzas N,Paraskevakou H,Tseleni-Balafouta S, et al. Association between microvessel density and histologic grade in renal cell carcinomas[J]. Pathol Oncol Res, 2007, 13(2): 145-148.
[30]
Romanenko AM,Ruiz-Saurí A,Morell-Quadreny L, et al. Microvessel density is high in clear-cell renal cell carcinomas of Ukrainian patients exposed to chronic persistent low-dose ionizing radiation after the Chernobyl accident[J]. Virchows Arch, 2012, 460(6): 611-619.
[31]
North S,Moenner M,Bikfalvi A. Recent developments in the regulation of the angiogenic switch by cellular stress factors in tumors[J]. Cancer Lett, 2005, 218(1): 1-14.
[32]
Jargin SV. Over-estimation of radiation-induced malignancy after the Chernobyl accident[J]. Virchows Arch, 2007, 451(1): 105-106.
[33]
Jargin SV. Renal cell carcinoma after Chernobyl: on the role of radiation vs. late detection[J]. Pathol Oncol Res, 2015, 21(3): 845-846.
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