Zhao Yurong, Deng Li, Yang Wei, Wang Dong, Pambou Elias, Lu Zhiming, Li Zongyi, Wang Jiqian, King Stephen, Rogers Sarah, Xu Hai, Lu Jian R
Centre for Bioengineering and Biotechnology, China University of Petroleum (East China), Changjiang West Road, Qingdao, 266580, P. R. China.
School of Physics and Astronomy, The University of Manchester, Oxford Road, Manchester, M13 9PL, UK.
Chemistry. 2016 Aug 1;22(32):11394-404. doi: 10.1002/chem.201601309. Epub 2016 Jun 30.
By combining experimental measurements and computer simulations, we here show that for the bola-like peptide amphiphiles XI4 X, where X=K, R, and H, the hydrophilic amino acid substitutions have little effect on the β-sheet hydrogen-bonding between peptide backbones. Whereas all of the peptides self-assemble into one dimensional (1D) nanostructures with completely different morphologies, that is, nanotubes and helical nanoribbons for KI4 K, flat and multilayered nanoribbons for HI4 H, and twisted and bilayered nanoribbons for RI4 R. These different 1D morphologies can be explained by the distinct stacking degrees and modes of the three peptide β-sheets along the x-direction (width) and the z-direction (height), which microscopically originate from the hydrogen-bonding ability of the sheets to solvent molecules and the pairing of hydrophilic amino acid side chains between β-sheet monolayers through stacking interactions and hydrogen bonding. These different 1D nanostructures have distinct surface chemistry and functions, with great potential in various applications exploiting the respective properties of these hydrophilic amino acids.
通过结合实验测量和计算机模拟,我们在此表明,对于bola型肽两亲物XI4 X(其中X = K、R和H),亲水性氨基酸取代对肽主链之间的β-折叠氢键影响很小。尽管所有肽都自组装成具有完全不同形态的一维(1D)纳米结构,即KI4 K形成纳米管和螺旋纳米带,HI4 H形成扁平且多层的纳米带,RI4 R形成扭曲且双层的纳米带。这些不同的1D形态可以通过三种肽β-折叠沿x方向(宽度)和z方向(高度)的不同堆积程度和模式来解释,这在微观上源于β-折叠与溶剂分子的氢键结合能力以及β-折叠单层之间通过堆积相互作用和亲水氨基酸侧链之间的氢键形成的配对。这些不同的1D纳米结构具有独特的表面化学性质和功能,在利用这些亲水性氨基酸各自特性的各种应用中具有巨大潜力。
