David Ricardo Figueroa Blanco, Pietro Vidossich and Marco De Vivo*,
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引用次数: 0
Abstract
DNA polymerases (Pols) add incoming nucleotides (deoxyribonucleoside triphosphate (dNTPs)) to growing DNA strands, a crucial step for DNA synthesis. The insertion of correct (vs incorrect) nucleotides relates to Pols’ fidelity, which defines Pols’ ability to faithfully replicate DNA strands in a template-dependent manner. We and others have demonstrated that reactant alignment and correct base pairing at the Pols catalytic site are crucial structural features to fidelity. Here, we first used equilibrium molecular simulations to demonstrate that the local dynamics at the protein–DNA interface in the proximity of the catalytic site is different when correct vs incorrect dNTPs are bound to polymerase β (Pol β). Formation and dynamic stability of specific interatomic interactions around the incoming nucleotide influence the overall binding site architecture. This explains why certain Pols’ mutants can affect the local catalytic environment and influence the selection of correct vs incorrect nucleotides. In particular, this is here demonstrated by analyzing the interaction network formed by the residue R283, whose mutant R283A has an experimentally measured lower capacity of differentiating correct (G:dCTP) vs incorrect (G:dATP) base pairing in Pol β. We also used alchemical free-energy calculations to quantify the G:dCTP →G:dATP transformation in Pol β wild-type and mutant R283A. These results correlate well with the experimental trend, thus corroborating our mechanistic insights. Sequence and structural comparisons with other Pols from the same family suggest that these findings may also be valid in similar enzymes.
DNA 聚合酶(Pols)将输入的核苷酸(三磷酸脱氧核苷(dNTPs))添加到生长的 DNA 链中,这是 DNA 合成的关键步骤。正确(与不正确)核苷酸的插入与 Pols 的保真度有关,它决定了 Pols 以依赖模板的方式忠实复制 DNA 链的能力。我们和其他人已经证明,Pols 催化位点的反应物排列和正确的碱基配对是保真度的关键结构特征。在这里,我们首次利用平衡分子模拟证明,当正确与不正确的 dNTP 与聚合酶 β(Pol β)结合时,催化位点附近蛋白质-DNA 界面的局部动力学是不同的。输入核苷酸周围特定原子间相互作用的形成和动态稳定性会影响整个结合位点的结构。这就解释了为什么某些 Pols 突变体会影响局部催化环境,并影响正确与错误核苷酸的选择。我们还利用炼金术自由能计算来量化 Pol β 野生型和突变体 R283A 中 G:dCTP →G:dATP 的转化。这些结果与实验趋势密切相关,从而证实了我们的机理见解。与同族其他 Pols 的序列和结构比较表明,这些发现可能也适用于类似的酶。
期刊介绍:
The Journal of Chemical Information and Modeling publishes papers reporting new methodology and/or important applications in the fields of chemical informatics and molecular modeling. Specific topics include the representation and computer-based searching of chemical databases, molecular modeling, computer-aided molecular design of new materials, catalysts, or ligands, development of new computational methods or efficient algorithms for chemical software, and biopharmaceutical chemistry including analyses of biological activity and other issues related to drug discovery.
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