{"title":"暴露于欧杰电子发射体碘-125、β-发射体氚和铯-137 γ 射线后的染色体畸变诱导。","authors":"M Unverricht-Yeboah, M Von Ameln, R Kriehuber","doi":"10.1667/RADE-23-00158.1","DOIUrl":null,"url":null,"abstract":"<p><p>High-LET-type cell survival curves have been observed in cells that were allowed to incorporate 125I-UdR into their DNA. Incorporation of tritiated thymidine into the DNA of cells has also been shown to result in an increase in relative biological effectiveness in cell survival experiments, but the increase is smaller than observed after incorporation of 125I-UdR. These findings are explained in the literature by the overall complexity of the induced DNA damage resulting from energies of the ejected electron(s) during the decay of 3H and 125I. Chromosomal aberrations (CA) are defined as morphological or structural changes of one or more chromosomes, and can be induced by ionizing radiation. Whether the number of CA is associated with the linear energy transfer (LET) of the radiation and/or the actual complexity of the induced DNA double-strand breaks (DSB) remains elusive. In this study, we investigated whether DNA lesions induced at different cell cycle stages and by different radiation types [Auger-electrons (125I), β- particles (3H), or γ radiation (137Cs)] have an impact on the number of CA induced after induction of the same number of DSB as determined by the γ-H2AX foci assay. Cells were synchronized and pulse-labeled in S phase with low activities of 125I-UdR or tritiated thymidine. For decay accumulation, cells were cryopreserved either after pulse-labeling in S phase or after progression to G2/M or G1 phase. Experiments with γ irradiation (137Cs) were performed with synchronized and cryopreserved cells in S, G2/M or G1 phase. After thawing, a CA assay was performed. All experiments were performed after a similar number of DSB were induced. CA induction after 125I-UdR was incorporated was 2.9-fold and 1.7-fold greater compared to exposure to γ radiation and radiation from incorporated tritiated thymidine, respectively, when measured in G2/M cells. In addition, measurement of CA in G2/M cells after incorporation of 125I-UdR was 2.5-fold greater when compared to cells in G1 phase. In contrast, no differences were observed between the three radiation qualities with respect to exposure after cryopreservation in S or G1 phase. The data indicate that the 3D organization of replicated DNA in G2/M cells seems to be more sensitive to induction of more complex DNA lesions compared to the DNA architecture in S or G1 cells. 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Incorporation of tritiated thymidine into the DNA of cells has also been shown to result in an increase in relative biological effectiveness in cell survival experiments, but the increase is smaller than observed after incorporation of 125I-UdR. These findings are explained in the literature by the overall complexity of the induced DNA damage resulting from energies of the ejected electron(s) during the decay of 3H and 125I. Chromosomal aberrations (CA) are defined as morphological or structural changes of one or more chromosomes, and can be induced by ionizing radiation. Whether the number of CA is associated with the linear energy transfer (LET) of the radiation and/or the actual complexity of the induced DNA double-strand breaks (DSB) remains elusive. In this study, we investigated whether DNA lesions induced at different cell cycle stages and by different radiation types [Auger-electrons (125I), β- particles (3H), or γ radiation (137Cs)] have an impact on the number of CA induced after induction of the same number of DSB as determined by the γ-H2AX foci assay. Cells were synchronized and pulse-labeled in S phase with low activities of 125I-UdR or tritiated thymidine. For decay accumulation, cells were cryopreserved either after pulse-labeling in S phase or after progression to G2/M or G1 phase. Experiments with γ irradiation (137Cs) were performed with synchronized and cryopreserved cells in S, G2/M or G1 phase. After thawing, a CA assay was performed. All experiments were performed after a similar number of DSB were induced. CA induction after 125I-UdR was incorporated was 2.9-fold and 1.7-fold greater compared to exposure to γ radiation and radiation from incorporated tritiated thymidine, respectively, when measured in G2/M cells. In addition, measurement of CA in G2/M cells after incorporation of 125I-UdR was 2.5-fold greater when compared to cells in G1 phase. In contrast, no differences were observed between the three radiation qualities with respect to exposure after cryopreservation in S or G1 phase. The data indicate that the 3D organization of replicated DNA in G2/M cells seems to be more sensitive to induction of more complex DNA lesions compared to the DNA architecture in S or G1 cells. 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引用次数: 0
摘要
在允许将 125I-UdR 植入 DNA 的细胞中观察到了高 LET 型细胞存活曲线。在细胞存活实验中,将三价胸腺嘧啶掺入细胞的 DNA 中也会导致相对生物效应的增加,但增加的幅度比掺入 125I-UdR 后观察到的要小。文献中对这些发现的解释是,在 3H 和 125I 的衰变过程中,射出电子的能量导致诱导 DNA 损伤的整体复杂性。染色体畸变(CA)是指一条或多条染色体的形态或结构变化,可由电离辐射诱发。CA的数量是否与辐射的线性能量转移(LET)和/或诱导的DNA双链断裂(DSB)的实际复杂性有关,目前尚不清楚。在这项研究中,我们研究了在不同细胞周期阶段和不同辐射类型(奥奇电子(125I)、β粒子(3H)或γ辐射(137Cs))诱导的DNA病变是否会影响γ-H2AX病灶检测法确定的诱导相同数量DSB后诱导的CA数量。细胞同步化后,在 S 期用低活度的 125I-UdR 或三尖杉烷进行脉冲标记。为了进行衰变积累,细胞在S期脉冲标记后或进入G2/M期或G1期后进行冷冻保存。对处于 S、G2/M 或 G1 期的同步细胞和冷冻保存的细胞进行γ辐照(137Cs)实验。解冻后,进行 CA 检测。所有实验都是在诱导了相似数量的 DSB 后进行的。在G2/M细胞中测量,与暴露于γ辐射和掺入三价胸苷的辐射相比,掺入125I-UdR后诱导的CA分别高出2.9倍和1.7倍。此外,与 G1 期细胞相比,掺入 125I-UdR 后 G2/M 期细胞的 CA 测量值增加了 2.5 倍。相比之下,在 S 期或 G1 期冷冻保存后,三种辐射质量之间的照射量没有差异。数据表明,与 S 期或 G1 期细胞的 DNA 结构相比,G2/M 期细胞中复制 DNA 的三维组织似乎对诱导更复杂的 DNA 病变更敏感。这究竟是由于DNA组织本身还是DNA修复能力的差异造成的,目前还不清楚。
Induction of Chromosomal Aberrations after Exposure to the Auger Electron Emitter Iodine-125, the β--emitter Tritium and Cesium-137 γ rays.
High-LET-type cell survival curves have been observed in cells that were allowed to incorporate 125I-UdR into their DNA. Incorporation of tritiated thymidine into the DNA of cells has also been shown to result in an increase in relative biological effectiveness in cell survival experiments, but the increase is smaller than observed after incorporation of 125I-UdR. These findings are explained in the literature by the overall complexity of the induced DNA damage resulting from energies of the ejected electron(s) during the decay of 3H and 125I. Chromosomal aberrations (CA) are defined as morphological or structural changes of one or more chromosomes, and can be induced by ionizing radiation. Whether the number of CA is associated with the linear energy transfer (LET) of the radiation and/or the actual complexity of the induced DNA double-strand breaks (DSB) remains elusive. In this study, we investigated whether DNA lesions induced at different cell cycle stages and by different radiation types [Auger-electrons (125I), β- particles (3H), or γ radiation (137Cs)] have an impact on the number of CA induced after induction of the same number of DSB as determined by the γ-H2AX foci assay. Cells were synchronized and pulse-labeled in S phase with low activities of 125I-UdR or tritiated thymidine. For decay accumulation, cells were cryopreserved either after pulse-labeling in S phase or after progression to G2/M or G1 phase. Experiments with γ irradiation (137Cs) were performed with synchronized and cryopreserved cells in S, G2/M or G1 phase. After thawing, a CA assay was performed. All experiments were performed after a similar number of DSB were induced. CA induction after 125I-UdR was incorporated was 2.9-fold and 1.7-fold greater compared to exposure to γ radiation and radiation from incorporated tritiated thymidine, respectively, when measured in G2/M cells. In addition, measurement of CA in G2/M cells after incorporation of 125I-UdR was 2.5-fold greater when compared to cells in G1 phase. In contrast, no differences were observed between the three radiation qualities with respect to exposure after cryopreservation in S or G1 phase. The data indicate that the 3D organization of replicated DNA in G2/M cells seems to be more sensitive to induction of more complex DNA lesions compared to the DNA architecture in S or G1 cells. Whether this is due to the DNA organization itself or differences in DNA repair capability remains unclear.
期刊介绍:
Radiation Research publishes original articles dealing with radiation effects and related subjects in the areas of physics, chemistry, biology
and medicine, including epidemiology and translational research. The term radiation is used in its broadest sense and includes specifically
ionizing radiation and ultraviolet, visible and infrared light as well as microwaves, ultrasound and heat. Effects may be physical, chemical or
biological. Related subjects include (but are not limited to) dosimetry methods and instrumentation, isotope techniques and studies with
chemical agents contributing to the understanding of radiation effects.