带电粒子和伽马射线在人类细胞中诱导产生的DNA双链断裂：实验结果与理论方法

DNA DSB induced in human cells by charged particles and gamma rays: experimental results and theoretical approaches.

作者信息

Campa A, Ballarini F, Belli M, Cherubini R, Dini V, Esposito G, Friedland W, Gerardi S, Molinelli S, Ottolenghi A, Paretzke H, Simone G, Tabocchini M A

机构信息

Health and Technology Department, Istituto Superiore di Sanità, INFN Sezione di Roma1, Gruppo Collegato Sanità, Roma, Italy.

出版信息

Int J Radiat Biol. 2005 Nov;81(11):841-54. doi: 10.1080/09553000500530888.

DOI:10.1080/09553000500530888

PMID:16484153

Abstract

PURPOSE

To quantify the role played by radiation track structure and background fragments in modulating DNA fragmentation in human cells exposed to gamma-rays and light ions.

MATERIALS AND METHODS

Human fibroblasts were exposed in vitro to different doses (in the range from 40 - 200 Gy) of (60)Co gamma-rays and 0.84 MeV protons (Linear Energy Transfer, LET, in tissue 28.5 keV/microm). The resulting DNA fragments were scored under two electrophoretic conditions, in order to optimize separation in the size ranges 0.023 - 1.0 Mbp and 1.0 - 5.7 Mbp. In parallel, DNA fragmentation was simulated both with a phenomenological approach based on the "generalized broken-stick" model, and with a mechanistic approach based on the PARTRAC (acronym of PARticle TRACk) Monte Carlo code (1.32 MeV photons were used for the simulation of (60)Co gamma-rays).

RESULTS

For both gamma-rays and protons, the experimental dose response in the range 0.023 - 5.7 Mbp could be approximated as a straight line, the slope of which provided a yield of (5.3 +/- 0.4) x 10(-9) Gy(-1) bp(-1) for gamma-rays and (7.1 +/- 0.6) x 10(-9) Gy(-1) bp(-1) for protons, leading to a Relative Biological Effectiveness (RBE) of 1.3 +/- 0.2. From both theoretical analyses it appeared that, while gamma-ray data were consistent with double-strand breaks (DSB) random induction, protons at low doses showed significant deviation from randomness, implying enhanced production of small fragments in the low molecular weight part of the experimental range. The theoretical analysis of fragment production was then extended to ranges where data were not available, i.e. to fragments larger than 5.7 Mbp and smaller than 23 kbp. The main outcome was that small fragments (<23 kbp) are produced almost exclusively via non-random processes, since their number is considerably higher than that produced by a random insertion of DSB. Furthermore, for protons the number of these small fragments is a significant fraction (about 20%) of the total number of fragments; these fragments remain undetected in these experiments. Calculations for 3.3 MeV alpha particle irradiation (for which no experimental data were available) were performed to further investigate the role of fragments smaller than 23 kbp; in this case, besides the non-random character of their production, their number resulted to be at least as much as half of the total number of fragments.

CONCLUSION

Comparison between experimental data and two different theoretical approaches provided further support to the hypothesis of an important role of track structure in modulating DNA damage. According to the theoretical approaches, non-randomness of fragment production was found for proton irradiation for the smaller fragments in the experimental size range and, in a significantly larger extent, for fragments of size less than 23 kbp, both for protons and alpha particles.

摘要

目的

量化辐射径迹结构和背景碎片在调节暴露于γ射线和轻离子的人类细胞中DNA片段化过程中所起的作用。

材料与方法

将人类成纤维细胞在体外暴露于不同剂量（40 - 200 Gy范围）的⁶⁰Co γ射线和0.84 MeV质子（组织中的线能量转移，LET，为28.5 keV/μm）。在两种电泳条件下对产生的DNA片段进行评分，以优化在0.023 - 1.0 Mbp和1.0 - 5.7 Mbp大小范围内的分离。同时，采用基于“广义断棒”模型的唯象方法和基于PARTRAC（粒子径迹的首字母缩写）蒙特卡罗代码的机理方法对DNA片段化进行模拟（使用1.32 MeV光子模拟⁶⁰Co γ射线）。

结果

对于γ射线和质子，在0.023 - 5.7 Mbp范围内的实验剂量响应都可近似为一条直线，其斜率对于γ射线为(5.3 ± 0.4) × 10⁻⁹ Gy⁻¹ bp⁻¹，对于质子为(7.1 ± 0.6) × 10⁻⁹ Gy⁻¹ bp⁻¹，导致相对生物效应（RBE）为1.3 ± 0.2。从两种理论分析来看，虽然γ射线数据与双链断裂（DSB）的随机诱导一致，但低剂量质子显示出与随机性有显著偏差，这意味着在实验范围的低分子量部分小片段的产生有所增加。然后将片段产生的理论分析扩展到没有数据的范围，即大于5.7 Mbp和小于23 kbp的片段。主要结果是小片段（<23 kbp）几乎完全通过非随机过程产生，因为它们的数量远高于由DSB随机插入产生的数量。此外，对于质子，这些小片段的数量占片段总数的很大一部分（约20%）；在这些实验中这些片段未被检测到。对3.3 MeV α粒子辐照进行了计算（没有可用的实验数据）以进一步研究小于23 kbp的片段的作用；在这种情况下，除了其产生的非随机特性外，它们的数量至少占片段总数的一半。