Lee Ho-Jin, Park Hyun-Mee, Lee Kang-Bong
Advanced Analysis Center, Korea Institute of Science and Technology, P.O. Box 131 Cheongryangri, Seoul 130-650, Korea.
Biophys Chem. 2007 Jan;125(1):117-26. doi: 10.1016/j.bpc.2006.05.028. Epub 2006 Aug 4.
The conformational preferences of azaphenylalanine-containing peptide were investigated using a model compound, Ac-azaPhe-NHMe with ab initio method at the HF/3-21G and HF/6-31G() levels, and the seven minimum energy conformations with trans orientation of acetyl group and the 4 minimum energy conformations with cis orientation of acetyl group were found at the HF/6-31G() level if their mirror images were not considered. An average backbone dihedral angle of the 11 minimum energy conformations is phi=+/-91 degrees +/-24 degrees , psi =+/-18 degrees +/-10 degrees (or +/-169 degrees +/-8 degrees ), corresponding to the i+2 position of beta-turn (delta(R)) or polyproline II (beta(P)) structure, respectively. The chi(1) angle in the aromatic side chain of azaPhe residue adopts preferentially between +/-60 degrees and +/-130 degrees, which reflect a steric hindrance between the N-terminal carbonyl group or the C-terminal amide group and the aromatic side chain with respect to the configuration of the acetyl group. These conformational preferences of Ac-azaPhe-NHMe predicted theoretically were compared with those of For-Phe-NHMe to characterize the structural role of azaPhe residue. Four tripeptides containing azaPhe residue, Boc-Xaa-azaPhe-Ala-OMe [Xaa=Gly(1), Ala(2), Phe(3), Asn(4)] were designed and synthesized to verify whether the backbone torsion angles of azaPhe reside are still the same as compared with theoretical conformations and how the preceding amino acids of azaPhe residue perturb the beta-turn skeleton in solution. The solution conformations of these tripeptide models containing azaPhe residue were determined in CDCl(3) and DMSO solvents using NMR and molecular modeling techniques. The characteristic NOE patterns, the temperature coefficients of amide protons and small solvent accessibility for the azapeptides 1-4 reveal to adopt the beta-turn structure. The structures of azapeptides containing azaPhe residue from a restrained molecular dynamics simulation indicated that average dihedral angles [(phi(1), psi(1)), (phi(2), psi(2))] of Xaa-azaPhe fragment in azapeptide, Boc-Xaa-azaPhe-Ala-OMe were [(-68 degrees, 135 degrees ), (116 degrees, -1 degrees )], and this implies that the intercalation of an azaPhe residue in tripeptide induces the betaII-turn conformation, and the volume change of a preceding amino acid of azaPhe residue in tripeptides would not perturb seriously the backbone dihedral angle of beta-turn conformation. We believe such information could be critical in designing useful molecules containing azaPhe residue for drug discovery and peptide engineering.
使用模型化合物Ac-azaPhe-NHMe,采用从头算方法在HF/3-21G和HF/6-31G()水平上研究了含氮杂苯丙氨酸肽的构象偏好。如果不考虑镜像,在HF/6-31G()水平上发现了7种乙酰基呈反式取向的最低能量构象和4种乙酰基呈顺式取向的最低能量构象。11种最低能量构象的平均主链二面角为phi=+/-91度+/-24度,psi =+/-18度+/-10度(或+/-169度+/-8度),分别对应于β-转角(delta(R))或多聚脯氨酸II(beta(P))结构的i+2位置。氮杂苯丙氨酸残基芳香侧链中的chi(1)角优先在+/-60度和+/-130度之间,这反映了N-末端羰基或C-末端酰胺基与芳香侧链之间相对于乙酰基构型的空间位阻。将理论预测的Ac-azaPhe-NHMe的这些构象偏好与For-Phe-NHMe的构象偏好进行比较,以表征氮杂苯丙氨酸残基的结构作用。设计并合成了四种含氮杂苯丙氨酸残基的三肽,Boc-Xaa-azaPhe-Ala-OMe [Xaa=Gly(1)、Ala(2)、Phe(3)、Asn(4)],以验证氮杂苯丙氨酸残基的主链扭转角与理论构象相比是否仍然相同,以及氮杂苯丙氨酸残基之前的氨基酸如何在溶液中扰动β-转角骨架。使用NMR和分子建模技术在CDCl(3)和DMSO溶剂中测定了这些含氮杂苯丙氨酸残基的三肽模型的溶液构象。氮杂肽1-4的特征性NOE模式、酰胺质子的温度系数和小的溶剂可及性表明其采用β-转角结构。来自受限分子动力学模拟的含氮杂苯丙氨酸残基的氮杂肽结构表明,氮杂肽Boc-Xaa-azaPhe-Ala-OMe中Xaa-azaPhe片段的平均二面角[(phi(1), psi(1)), (phi(2), psi(2))]为[(-68度, 135度), (116度, -1度)],这意味着三肽中氮杂苯丙氨酸残基的插入诱导了βII-转角构象,并且三肽中氮杂苯丙氨酸残基之前的氨基酸的体积变化不会严重扰动β-转角构象的主链二面角。我们相信这些信息对于设计用于药物发现和肽工程的含氮杂苯丙氨酸残基的有用分子可能至关重要。
