A high-level quantum chemical study of the thermodynamics associated with chlorine transfer between N-chlorinated nucleobases

IF 2.9 Q3 CHEMISTRY, PHYSICAL Electronic Structure Pub Date : 2023-05-03 DOI:10.1088/2516-1075/acd234
Robert J. O’Reilly, A. Karton
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引用次数: 1

Abstract

The relative free energies of the isomers formed upon N-chlorination of each nitrogen atom within the DNA nucleobases (adenine, guanine, and thymine) have been obtained using the high-level G4(MP2) composite ab initio method (the free energies of the N-chlorinated isomers of cytosine have been reported at the same level of theory previously). Having identified the lowest energy N-chlorinated derivatives for each nucleobase, we have computed the free energies associated with chlorine transfer from N-chlorinated nucleobases to other unsubstituted bases. Our results provide quantitative support pertaining to the results of previous experimental studies, which demonstrated that rapid chlorine transfer occurs from N-chlorothymidine to cytidine or adenosine. The results of our calculations in the gas-phase reveal that chlorine transfer from N-chlorothymine to either cytosine, adenine, or guanine proceed via exergonic processes with ΔG o values of −50.3 (cytosine), −28.0 (guanine), and −6.7 (adenine) kJ mol–1. Additionally, we consider the effect of aqueous solvation by augmenting our gas-phase G4(MP2) energies with solvation corrections obtained using the conductor-like polarizable continuum model. In aqueous solution, we obtain the following G4(MP2) free energies associated with chlorine transfer from N-chlorothymine to the three other nucleobases: −58.4 (cytosine), −26.4 (adenine), and −18.7 (guanine) kJ mol–1. Therefore, our calculations, whether in the gas phase or in aqueous solution, clearly indicate that chlorine transfer from any of the N-chlorinated nucleobases to cytosine provides a thermodynamic sink for the active chlorine. This thermodynamic preference for chlorine transfer to cytidine may be particularly deleterious since previous experimental studies have shown that nitrogen-centered radical formation (via N–Cl bond homolysis) is more easily achieved in N-chlorinated cytidine than in other N-chlorinated nucleosides.
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与n -氯化核碱基之间氯转移相关的热力学的高级量子化学研究
DNA核碱基(腺嘌呤、鸟嘌呤和胸腺嘧啶)中每个氮原子N-氯化形成的异构体的相对自由能已使用高级G4(MP2)复合从头算方法获得(胞嘧啶的N-氯化异构体的自由能已在先前的相同理论水平上报道)。在确定了每个核碱基的最低能量N-氯化衍生物后,我们计算了氯从N-氯化核碱基转移到其他未取代碱基的自由能。我们的结果为先前的实验研究结果提供了定量支持,这些实验研究表明,氯从N-氯胸苷快速转移到胞苷或腺苷。我们在气相中的计算结果表明,氯从N-氯胸腺嘧啶转移到胞嘧啶、腺嘌呤或鸟嘌呤是通过外泌过程进行的,ΔG o值为−50.3(胞嘧啶)、−28.0(鸟嘌呤)和−6.7(腺嘌呤)kJ mol–1。此外,我们通过使用类导体极化连续体模型获得的溶剂化校正来增加气相G4(MP2)能量,从而考虑了水溶剂化的影响。在水溶液中,我们获得了以下与氯从N-氯胸腺嘧啶转移到其他三个核碱基相关的G4(MP2)自由能:−58.4(胞嘧啶)、−26.4(腺嘌呤)和−18.7(鸟嘌呤)kJ mol–1。因此,我们的计算,无论是在气相还是在水溶液中,都清楚地表明氯从任何N-氯化核碱基转移到胞嘧啶,为活性氯提供了热力学汇。氯转移到胞苷的热力学偏好可能特别有害,因为先前的实验研究表明,N-氯化胞苷中的氮中心自由基形成(通过N–Cl键均聚)比其他N-氯化核苷更容易实现。
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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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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