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基于糖苷扭转轮廓的参考量子化学计算对康奈尔等人核酸力场的优化。

Refinement of the Cornell et al. Nucleic Acids Force Field Based on Reference Quantum Chemical Calculations of Glycosidic Torsion Profiles.

作者信息

Zgarbová Marie, Otyepka Michal, Sponer Jiří, Mládek Arnošt, Banáš Pavel, Cheatham Thomas E, Jurečka Petr

出版信息

J Chem Theory Comput. 2011 Sep 13;7(9):2886-2902. doi: 10.1021/ct200162x. Epub 2011 Aug 2.

DOI:10.1021/ct200162x
PMID:21921995
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3171997/
Abstract

We report a reparameterization of the glycosidic torsion χ of the Cornell et al. AMBER force field for RNA, χ(OL). The parameters remove destabilization of the anti region found in the ff99 force field and thus prevent formation of spurious ladder-like structural distortions in RNA simulations. They also improve the description of the syn region and the syn-anti balance as well as enhance MD simulations of various RNA structures. Although χ(OL) can be combined with both ff99 and ff99bsc0, we recommend the latter. We do not recommend using χ(OL) for B-DNA because it does not improve upon ff99bsc0 for canonical structures. However, it might be useful in simulations of DNA molecules containing syn nucleotides. Our parametrization is based on high-level QM calculations and differs from conventional parametrization approaches in that it incorporates some previously neglected solvation-related effects (which appear to be essential for obtaining correct anti/high-anti balance). Our χ(OL) force field is compared with several previous glycosidic torsion parametrizations.

摘要

我们报告了康奈尔等人的RNA AMBER力场糖苷扭转角χ(χ(OL))的重新参数化。这些参数消除了ff99力场中反式区域的不稳定因素,从而防止在RNA模拟中形成虚假的梯状结构扭曲。它们还改善了顺式区域和顺-反平衡的描述,并增强了各种RNA结构的分子动力学模拟。虽然χ(OL)可以与ff99和ff99bsc0结合使用,但我们推荐后者。我们不建议将χ(OL)用于B-DNA,因为对于经典结构,它并没有比ff99bsc0有改进。然而,它可能在含有顺式核苷酸的DNA分子模拟中有用。我们的参数化基于高水平的量子力学计算,与传统的参数化方法不同,它纳入了一些以前被忽视的与溶剂化相关的效应(这似乎对于获得正确的反式/高反式平衡至关重要)。我们将χ(OL)力场与之前的几种糖苷扭转角参数化进行了比较。

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