碳水化合物力场
Carbohydrate force fields.
作者信息
Foley B Lachele, Tessier Matthew B, Woods Robert J
机构信息
Complex Carbohydrate Research Center, University of Georgia, Athens, GA, USA.
Complex Carbohydrate Research Center, University of Georgia, Athens, GA, USA ; School of Chemistry, National University of Ireland, Galway, Ireland.
出版信息
Wiley Interdiscip Rev Comput Mol Sci. 2012 Jul;2(4):652-697. doi: 10.1002/wcms.89.
Abstract
Carbohydrates present a special set of challenges to the generation of force fields. First, the tertiary structures of monosaccharides are complex merely by virtue of their exceptionally high number of chiral centers. In addition, their electronic characteristics lead to molecular geometries and electrostatic landscapes that can be challenging to predict and model. The monosaccharide units can also interconnect in many ways, resulting in a large number of possible oligosaccharides and polysaccharides, both linear and branched. These larger structures contain a number of rotatable bonds, meaning they potentially sample an enormous conformational space. This article briefly reviews the history of carbohydrate force fields, examining and comparing their challenges, forms, philosophies, and development strategies. Then it presents a survey of recent uses of these force fields, noting trends, strengths, deficiencies, and possible directions for future expansion.
摘要
碳水化合物对力场的生成提出了一系列特殊挑战。首先,单糖的三级结构仅因其手性中心数量异常之多而变得复杂。此外,它们的电子特性导致分子几何形状和静电态势难以预测和建模。单糖单元还能以多种方式相互连接,从而产生大量可能的寡糖和多糖,包括线性和分支状的。这些较大的结构包含许多可旋转键,这意味着它们可能会占据巨大的构象空间。本文简要回顾了碳水化合物力场的历史,审视并比较了它们面临的挑战、形式、理念及发展策略。然后概述了这些力场近期的应用情况,指出了发展趋势、优势、不足以及未来扩展的可能方向。
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