Shuli Liu, Ruonan Wang, Xuejing Wang, Lanlan Yu, Chenxuan Wang
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引用次数: 0
摘要
肽组装纳米材料的紧急出现促使人们努力去了解影响肽组装结构的成分效应。在此,我们使用延时原子力显微镜(AFM)表征了富含苯丙氨酸(F)的自组装肽随时间变化的结构转变,并阐明了组成异质性对调节肽聚集的影响。我们合成了四种二元肽(F5Y5、F5A5、F5H5 和 F5D5),将不同类型的氨基酸(包括芳香族酪氨酸(Y)、非极性丙氨酸(A)、阳离子组氨酸(H)和阴离子天冬氨酸(D))排列在富含 F 的分子附近。我们使用原子力显微镜比较了这些多肽组装体随时间变化的结构转变。随着时间的推移,F5Y5 和 F5A5 被观察到形成纤维状的聚集体,而 F5H5 和 F5D5 则在考察的时间过程中聚集成球状颗粒。相邻氨基酸对富含 F 的肽纤维化的影响与氨基酸侧链的疏水性尺度一致。具体来说,Y 和 A 有利于纤丝聚集,而 H 和 D 则阻碍富含 F 的肽的纤丝形成。我们的研究结果表明,F残基近端氨基酸的疏水性对于肽的纤维状聚集非常重要。
Composition effects on the self-aggregation of phenylalanine-rich oligopeptides revealed by atomic force microscopy
The emergency of peptide-assembled nanomaterials motivates the efforts towards understanding the composition effects governing the assembly structure of peptides. Herein, we used time-lapse atomic force microscopy (AFM) to characterize the time-dependent structural transformation of phenylalanine (F)-rich self-assembled peptides and elucidated the impacts of composition heterogeneity on modulating peptide aggregation. Four binary peptides (F5Y5, F5A5, F5H5, and F5D5) were synthesized to arrange distinct types of amino acids, including aromatic tyrosine (Y), nonpolar alanine (A), cationic histidine (H), and anionic aspartic acid (D), in the proximity of an F-rich moiety. We compared the time-dependent structural transitions of these peptide assemblies using AFM. F5Y5 and F5A5 were observed to form fibril-like aggregates over time, whereas F5H5 and F5D5 assembled into globular particles during the time course examined. The impacts of neighboring amino acids on affecting F-rich peptide fibrillation are in line with the hydrophobicity scales of amino acid side chains. Specifically, Y and A facilitate the fibril aggregation, whereas H and D hinder the fibril formation of F-rich peptides. Our results manifest the hydrophobicity of amino acids proximal to the F residues is important for the fibril-like aggregation of peptides.
期刊介绍:
Colloid and Polymer Science - a leading international journal of longstanding tradition - is devoted to colloid and polymer science and its interdisciplinary interactions. As such, it responds to a demand which has lost none of its actuality as revealed in the trends of contemporary materials science.