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DNA 双链稳定性:预组织静电的作用。

DNA duplex stability: the role of preorganized electrostatics.

机构信息

National Institute of Chemistry, Hajdrihova 19, 1001 Ljubljana, Slovenia.

出版信息

J Phys Chem B. 2010 Mar 4;114(8):2876-85. doi: 10.1021/jp9064246.

DOI:10.1021/jp9064246
PMID:20131770
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2841231/
Abstract

The insertion of a DNA base moiety at the end of a DNA duplex to form a Watson-Crick or wobble pair during DNA annealing or replication is a step of fundamental biological importance. Therefore, we investigated the energetics of a formation of the terminal G x C, G x T, and G x A base pairs in DNA containing a 5'-dangling G adjacent to the base insertion point using differential scanning calorimetry and computer simulations. The energies calculated along classical molecular dynamics trajectories in aqueous solution were analyzed in the framework of linear-response approximation (LRA) to obtain relative free energies for the base insertion and their electrostatic, van der Waals, and preorganization components. Using the generic set of LRA parameters, the calculated free energies disfavored the mispair formation by 2.5 (G x C --> G x T) and 1.7 (G x C --> G x A) kcal/mol, in reasonable agreement with the experimental free energy differences of 1.8 and 1.4 kcal/mol, respectively. The calculated preorganization components of these free energies of 0.6 (G x C --> G x T) and -0.1 (G x C --> G x A) kcal/mol show that electrostatic preorganization, which is an important source of DNA replication fidelity, plays a lesser role in the mispair destabilization in the absence of DNA polymerase.

摘要

在 DNA 退火或复制过程中,将 DNA 双链体末端的一个碱基插入形成 Watson-Crick 或摆动配对,这是一个具有基本生物学重要性的步骤。因此,我们使用差示扫描量热法和计算机模拟研究了在含有 5'-悬垂 G 的 DNA 中形成末端 G x C、G x T 和 G x A 碱基对的热力学。在水溶液中沿着经典分子动力学轨迹计算的能量在线性响应近似 (LRA) 的框架内进行了分析,以获得碱基插入及其静电、范德华和预组织成分的相对自由能。使用通用的 LRA 参数集,计算出的自由能使错配形成的自由能分别降低了 2.5(G x C --> G x T)和 1.7(G x C --> G x A)kcal/mol,与实验自由能差异分别为 1.8 和 1.4 kcal/mol 相吻合。这些自由能的预组织成分分别为 0.6(G x C --> G x T)和 -0.1(G x C --> G x A)kcal/mol,表明在没有 DNA 聚合酶的情况下,静电预组织作为 DNA 复制保真度的重要来源,在错配失稳中作用较小。

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