DNA核碱基和沃森-克里克碱基对特征振动耦合的局域模式分析

IF 2.9 Q3 CHEMISTRY, PHYSICAL Electronic Structure Pub Date : 2022-12-09 DOI:10.1088/2516-1075/acaa7a
Mateus M. Quintano, A. A. A. Delgado, Renaldo T. Moura Jr., M. Freindorf, E. Kraka
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引用次数: 6

摘要

二维红外光谱已经报道了核苷酸单磷酸盐指纹区中高度离域的平面内碱基振动,表明碱基对C=O和C=C环键的参与以及C=O键伸展之间的相当大的相互作用。高离域导致拥挤的振动光谱,这使峰的分配复杂化。这种拥塞也延伸到Watson–Crick碱基对。我们在这项工作中应用了正态模式过程的表征,这是我们局部模式分析的一个特殊特征,并且可以首次识别参与碱基对耦合的C=O和C=C键,并量化它们对每个离域指纹振动的贡献。此外,还对Watson–Crick碱基对中涉及的氢键进行了详细和定量的描述。基于这项研究的结果,我们开发了一种新的方案,通过探测碱基配对之前和之后官能团之间的特定相互作用的振动空间,来阐明核酸振动光谱中谱带的分配。该方案将有助于填补脱氧核糖核酸结构信息和振动光谱实验之间的空白,促进光谱的定量解释。
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Local mode analysis of characteristic vibrational coupling in nucleobases and Watson–Crick base pairs of DNA
Two-dimensional infrared spectroscopy has reported highly delocalized in-plane base vibrations in the fingerprint region of nucleotide monophosphates, suggesting the involvement of base pair C=O and C=C ring bonds and considerable interaction between C=O bond stretches. The high delocalization results in congested vibrational spectra, which complicates the assignment of the peaks. This congestion also extends to Watson–Crick base pairs. We applied in this work the characterization of normal mode procedure, a special feature of our local mode analysis, and could for the first time identify the C=O and C=C bonds being engaged in base pair coupling and quantify their contribution to each of the delocalized fingerprint vibration. In addition, a detailed and quantitative description of the hydrogen bonds involved in the Watson–Crick base pairs was provided. Based on the results of this study, we developed a new protocol to elucidate on the assignment of bands in the vibrational spectra of nucleic acids by probing the vibrational space for specific interactions between functional groups prior to and upon base pairing. This protocol will aid to fill the gap between deoxyribonucleic acid structural information and vibrational spectroscopy experiments by facilitating the interpretation of spectra on a quantitative basis.
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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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