Joy Abraham, Ghosh Avik K, Schuster Gary B
School of Chemistry and Biochemistry, Georgia Institute of Technology, Atlanta, Georgia 30332, USA.
J Am Chem Soc. 2006 Apr 26;128(16):5346-7. doi: 10.1021/ja058758b.
The anthraquinone (AQ) photosensitized one-electron oxidation of DNA introduces a radical cation (electron "hole") that migrates through the duplex by hopping. The radical cation normally is trapped irreversibly by reaction at guanine. We constructed AQ-linked DNA oligomers composed exclusively of A/T base pairs. Their irradiation led to reaction and strand cleavage primarily at thymines. Long-distance radical cation hopping to distant thymines was demonstrated by the distance dependence of the process and by experiments with DNA oligomers that contain a single remote GG step. The reaction of the radical cation at thymine was shown to involve its 5-methyl group by the replacement of selected thymines with uracils. These findings show that the reactivity of radical cations in DNA cannot be explained simply by exclusive reliance on the relative oxidation potential of the nucleobases. Instead, the site of reaction is determined in accord with the Curtin-Hammett principle for reactive species in rapid equilibrium.
蒽醌(AQ)对DNA的光敏单电子氧化会引入一个自由基阳离子(电子“空穴”),该自由基阳离子通过跳跃在双链体中迁移。自由基阳离子通常会因与鸟嘌呤发生反应而被不可逆地捕获。我们构建了仅由A/T碱基对组成的AQ连接的DNA寡聚物。对它们的照射主要导致胸腺嘧啶处发生反应和链断裂。通过该过程的距离依赖性以及对含有单个远程GG步骤的DNA寡聚物进行的实验,证明了自由基阳离子向远处胸腺嘧啶的长距离跳跃。用尿嘧啶取代选定的胸腺嘧啶表明,自由基阳离子在胸腺嘧啶处的反应涉及其5-甲基。这些发现表明,DNA中自由基阳离子的反应性不能简单地通过仅依赖于核碱基的相对氧化电位来解释。相反,反应位点是根据快速平衡中反应物种的柯廷-哈米特原理确定的。