理解芳香环与碱基在水溶液中的堆积相互作用：实验和理论研究。

Understanding Stacking Interactions between an Aromatic Ring and Nucleobases in Aqueous Solution: Experimental and Theoretical Study.

机构信息

Institute of Chemistry, Faculty of Natural Sciences, Technische Universität Chemnitz , 09107 Chemnitz, Germany.

出版信息

J Org Chem. 2016 Aug 5;81(15):6505-14. doi: 10.1021/acs.joc.6b01130. Epub 2016 Jul 8.

DOI:10.1021/acs.joc.6b01130

Abstract

Stacking interactions between aromatic compounds and nucleobases are crucial in recognition of nucleotides and nucleic acids, but a comprehensive understanding of the strength and selectivity of these interactions in aqueous solution has been elusive. To this end, model complexes have been designed and analyzed by experiment and theory. For the first time, stacking free energies between five nucleobases and anthracene were determined experimentally from thermodynamic double mutant cycles. Three different experimental methods were proposed and evaluated. The dye prefers to bind nucleobases in the order (kcal/mol): G (1.3) > T (0.9) > U (0.8) > C (0.5) > A (0.3). The respective trend of interaction free energies extracted from DFT calculations correlates to that obtained experimentally. Analysis of the data suggests that stacking interactions dominate over hydrophobic effects in an aqueous solution and can be predicted with DFT calculations.

摘要

芳环化合物与碱基之间的堆积相互作用对核苷酸和核酸的识别至关重要，但在水溶液中全面了解这些相互作用的强度和选择性一直难以捉摸。为此，已经通过实验和理论设计和分析了模型配合物。首次通过热力学双突变体循环实验确定了五个碱基与蒽之间的堆积自由能。提出并评估了三种不同的实验方法。该染料优先按以下顺序与碱基结合（千卡/摩尔）：G（1.3）>T（0.9）>U（0.8）>C（0.5）>A（0.3）。从 DFT 计算中提取的相互作用自由能的相应趋势与实验获得的趋势相关。数据分析表明，堆积相互作用在水溶液中超过疏水性影响，可以通过 DFT 计算进行预测。

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理解芳香环与碱基在水溶液中的堆积相互作用：实验和理论研究。

Understanding Stacking Interactions between an Aromatic Ring and Nucleobases in Aqueous Solution: Experimental and Theoretical Study.

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