One-electron oxidation of DNA: mechanism and consequences.

Gary B Schuster
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引用次数: 6

Abstract

All living organisms store the information necessary to maintain life in their DNA. Any process that damages DNA and causes loss or corruption of that information threatens the viability of the organism. One-electron oxidation is such a process. Loss of an electron from DNA generates a radical cation that is located primarily on its nucleobases. The radical cation migrates reversibly through duplex DNA by hopping until it is eventually trapped in an irreversible chemical reaction. The particular sequence of nucleobases in a DNA oligomer determines both the efficiency of hopping and the specific location and nature of the damaging chemical reaction. In its normal aqueous solutions, DNA is a polyanion because of the negative charge carried by its phosphate groups. Counter ions (typically Na(+)) to the phosphate groups play an important role in facilitating both the migration of the radical cation and in its eventual reaction with H(2)O. Irreversible reaction of a radical cation with H(2)O in duplex DNA occurs preferentially at the most reactive site. In normal DNA that is comprised of the four common DNA nucleobases, reaction occurs most commonly at a guanine and results in its conversion primarily to 8-oxo-7,8-dihydroguanine (8-OxoG). Both electronic and steric effects control the outcome of this process. If the DNA oligomer does not contain a suitable guanine, then reaction of the radical cation occurs at the thymine of a TT step primarily by a tandem process. The general outcomes revealed in the one-electron oxidation of DNA oligomers in solution appear to be generally valid also for more complex DNA structures and for the cellular DNA of living organisms.

DNA的单电子氧化:机制和后果。
所有生物体都将维持生命所需的信息储存在DNA中。任何破坏DNA并导致信息丢失或损坏的过程都会威胁到生物体的生存能力。单电子氧化就是这样一个过程。从DNA中失去一个电子会产生一个主要位于其核碱基上的自由基阳离子。自由基阳离子通过跳跃可逆地通过双链DNA迁移,直到它最终被困在一个不可逆的化学反应中。DNA寡聚物中特定的核碱基序列既决定了跳跃的效率,也决定了破坏性化学反应的特定位置和性质。在正常的水溶液中,DNA是一个多阴离子,因为它的磷酸基团带负电荷。反离子(通常是Na(+))在促进自由基阳离子的迁移和最终与H(2)O的反应中起着重要作用。在双链DNA中,自由基阳离子与H(2)O的不可逆反应优先发生在最活跃的位点。在由四个常见DNA核碱基组成的正常DNA中,反应最常发生在鸟嘌呤上,并导致其主要转化为8-氧-7,8-二氢鸟嘌呤(8-OxoG)。电子效应和空间效应控制着这一过程的结果。如果DNA低聚物不含合适的鸟嘌呤,则自由基阳离子的反应主要通过串联过程发生在TT步骤的胸腺嘧啶上。在溶液中DNA低聚物的单电子氧化中揭示的一般结果似乎也普遍适用于更复杂的DNA结构和活生物体的细胞DNA。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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