电离辐射簇损伤的修饰：生理条件下通过鸟嘌呤自由基穿过DNA的空穴迁移距离的估计

Milligan J R, Aguilera J A, Paglinawan R A, Nguyen K J, Ward J F

Department of Radiology, University of California at San Diego, La Jolla, CA 92093-0610, USA.

Int J Radiat Biol. 2002 Aug;78(8):733-41. doi: 10.1080/09553000210140109.

PURPOSE

Guanyl radicals are produced in DNA when it is subjected to oxidation or ionizing radiation. The sites at which stable products can be identified can be located dozens of base pairs away from the initial site of the electron loss. This migration will modify the spatial distribution of damage and tends to mitigate the clustering of initial damage generally associated with ionizing radiation. The migration distance is presumably a function of the lifetime of the intermediate guanyl radical, and we wished to quantify the relationship between them.

MATERIALS AND METHODS

Aqueous solutions containing plasmid DNA and thiocyanate ions were treated with gamma-irradiation. These conditions result in the very efficient production of guanyl radicals in the plasmid. We quantified the formation of stable guanine oxidation products in the plasmid as strand breaks by using the E. coli base excision repair endonuclease formamidopyrimidine-DNA N-glycosylase (FPG). The effect of two additives on the yield of guanine oxidation, nitrite ions and the DNA binding ligand doxorubicin (adriamycin), were examined.

RESULTS

The presence during irradiation of the DNA-binding ligand doxorubicin attenuated the yields of stable oxidized guanine products formed. The additional presence of nitrite decreased this effect of doxorubicin.

CONCLUSION

Because doxorubicin binds strongly to DNA, its ability to attenuate guanine oxidation can be interpreted in terms of the migration distance of the intermediate guanyl radical. Because nitrite repairs these intermediate guanyl radicals by electron transfer, its presence during irradiation decreases their lifetime. Therefore, we derived an estimate of the migration distance of guanyl radicals as a function of their lifetime. The presence in cells of antioxidants such as glutathione sets an upper limit to the likely lifetime and, therefore, the migration distance of guanyl radicals. It was concluded that the migration of guanyl radicals may not decrease the clustering of DNA damage in vivo to a great extent.

目的

当DNA受到氧化或电离辐射时会产生鸟嘌呤自由基。能够鉴定出稳定产物的位点可能位于离最初电子丢失位点数十个碱基对的位置。这种迁移会改变损伤的空间分布，并倾向于减轻通常与电离辐射相关的初始损伤的聚集。迁移距离大概是中间鸟嘌呤自由基寿命的函数，我们希望量化它们之间的关系。

材料与方法

含有质粒DNA和硫氰酸根离子的水溶液用γ射线辐照。这些条件能在质粒中非常有效地产生鸟嘌呤自由基。我们通过使用大肠杆菌碱基切除修复内切酶甲酰胺嘧啶-DNA N-糖基化酶（FPG），将质粒中稳定的鸟嘌呤氧化产物的形成量化为链断裂。研究了两种添加剂亚硝酸根离子和DNA结合配体阿霉素（多柔比星）对鸟嘌呤氧化产率的影响。

结果

在辐照过程中DNA结合配体阿霉素的存在减弱了形成的稳定氧化鸟嘌呤产物的产率。亚硝酸根的额外存在降低了阿霉素的这种作用。

结论

由于阿霉素与DNA强烈结合，其减弱鸟嘌呤氧化的能力可以根据中间鸟嘌呤自由基的迁移距离来解释。由于亚硝酸根通过电子转移修复这些中间鸟嘌呤自由基，其在辐照过程中的存在缩短了它们的寿命。因此，我们得出了鸟嘌呤自由基迁移距离作为其寿命函数的估计值。细胞中抗氧化剂如谷胱甘肽的存在为鸟嘌呤自由基可能的寿命以及因此的迁移距离设定了上限。得出的结论是，鸟嘌呤自由基的迁移在体内可能不会在很大程度上减少DNA损伤的聚集。