Daggett V, Kollman P A, Kuntz I D
Department of Pharmaceutical Chemistry, University of California, San Francisco 94143-0446.
Biopolymers. 1991 Feb 15;31(3):285-304. doi: 10.1002/bip.360310304.
There has been much interest recently in the structure of small peptides in solution. A recent study by Bradley and co-workers [(1989) in Techniques of Protein Chemistry, Hugli, T.E., Ed., Academic Press, Orlando, FL, pp. 531-546; (1990) Journal of Molecular Biology, 215, pp. 607-622] describes a 17-residue peptide that is stable as a monomeric helix in aqueous solution at low pH, as determined by two-dimensional nmr and CD spectroscopy. They also have determined the helix content of the peptide as a function of pH using CD. We performed molecular dynamics simulations, with an empirical force field, of this peptide at low pH, with three different dielectric models: a linear distance-dependent dielectric function (epsilon = R); a modified form [J. Ramstein and R. Lavery (1988) Proceedings of the National Academy of Science, USA, Vol. 85, pp. 7231-7235] of the sigmoidal distance-dependent dielectric function of Hingerty and co-workers [(1985) Biopolymers, Vol. 24, pp. 427-439]; and epsilon = 1 with the peptide immersed in a bath of water molecules. We found that simulations with the sigmoidal dielectric function and the model with explicit water molecules resulted in average distances for particular interactions that were consistent with the experimental nmr results, with the sigmoidal function best representing the data. However, these models exhibited very different helix-stabilizing interactions. We also performed simulations using the sigmoidal function at moderate and high pH to compare to experimental determinations of the pH dependence of helix content. Helix content did not decrease with increases in pH, as shown experimentally. We did, however, observe changes in a specific side chain-helix dipole interaction that was implicated in determining the pH-dependent behavior of this peptide. Overall, the sigmoidal dielectric function was a reasonable alternative to adding explicit water molecules. In comparing 100 ps molecular dynamics simulations, the sigmoidal function was much less computer intensive and sampled more of conformational space than the treatment using explicit water molecules. Sampling is especially important for this system since the peptide has been shown experimentally to populate both helical and nonhelical conformations.
最近,人们对溶液中小肽的结构颇感兴趣。布拉德利及其同事近期的一项研究[(1989年)发表于《蛋白质化学技术》,休格利编著,学术出版社,佛罗里达州奥兰多,第531 - 546页;(1990年)《分子生物学杂志》,第215卷,第607 - 622页]描述了一种17个残基的肽,通过二维核磁共振和圆二色光谱法测定,该肽在低pH值的水溶液中以单体螺旋形式稳定存在。他们还利用圆二色光谱法测定了该肽的螺旋含量随pH值的变化。我们使用经验力场,对该肽在低pH值下进行了分子动力学模拟,采用了三种不同的介电模型:线性距离依赖介电函数(ε = R);欣格蒂及其同事[(1985年)《生物聚合物》,第24卷,第427 - 439页]的S形距离依赖介电函数的一种改进形式[J. 拉姆斯坦和R. 拉弗里(1988年)《美国国家科学院院刊》,第85卷,第7231 - 7235页];以及将肽浸入水分子浴中的ε = 1模型。我们发现,使用S形介电函数和含有明确水分子的模型进行模拟时,特定相互作用的平均距离与实验核磁共振结果一致,其中S形函数最能代表数据。然而,这些模型表现出非常不同的螺旋稳定相互作用。我们还使用S形函数在中等和高pH值下进行了模拟,以与螺旋含量pH依赖性的实验测定结果进行比较。螺旋含量并未如实验所示随pH值升高而降低。不过,我们确实观察到了一种特定的侧链 - 螺旋偶极相互作用的变化,这种相互作用与该肽的pH依赖性行为的确定有关。总体而言,S形介电函数是添加明确水分子的一种合理替代方案。在比较100皮秒的分子动力学模拟时,S形函数的计算强度要小得多,并且比使用明确水分子的处理方式能对更多的构象空间进行采样。由于实验表明该肽存在螺旋和非螺旋构象,所以采样对这个系统尤为重要。
