WestCHEM/Department of Pure and Applied Chemistry, University of Strathclyde , Thomas Graham Building, 295 Cathedral Street, Glasgow G1 1XL, United Kingdom.
Departament de Química Inorgànica i Orgànica, Universitat Jaume I , Avda. Sos Baynat s/n, 12071 Castelló, Spain.
ACS Appl Mater Interfaces. 2015 Nov 25;7(46):25946-54. doi: 10.1021/acsami.5b08968. Epub 2015 Nov 16.
Coupling of peptide self-assembly to dynamic sequence exchange provides a useful approach for the discovery of self-assembling materials. In here, we demonstrate the discovery and optimization of aqueous, gel-phase nanostructures based on dynamically exchanging peptide sequences that self-select to maximize charge transfer of n-type semiconducting naphthalenediimide (NDI)-dipeptide bioconjugates with various π-electron-rich donors (dialkoxy/hydroxy/amino-naphthalene or pyrene derivatives). These gel-phase peptide libraries are characterized by spectroscopy (UV-vis and fluorescence), microscopy (TEM), HPLC, and oscillatory rheology and it is found that, of the various peptide sequences explored (tyrosine Y-NDI with tyrosine Y, phenylalanine F, leucine L, valine V, alanine A or glycine G-NH2), the optimum sequence is tyrosine-phenylalanine in each case; however, both its absolute and relative yield amplification is dictated by the properties of the donor component, indicating cooperativity of peptide sequence and donor/acceptor pairs in assembly. The methodology provides an in situ discovery tool for nanostructures that enable dynamic interfacing of supramolecular electronics with aqueous (biological) systems.
肽自组装与动态序列交换的偶联为发现自组装材料提供了一种有用的方法。在这里,我们展示了基于动态交换肽序列的水相、凝胶相纳米结构的发现和优化,这些肽序列可以自我选择,以最大化 n 型半导体萘二酰亚胺 (NDI)-二肽生物缀合物与各种π-富电子供体(二烷氧基/羟基/氨基-萘或芘衍生物)之间的电荷转移。这些凝胶相肽库通过光谱学(UV-vis 和荧光)、显微镜(TEM)、HPLC 和振荡流变学进行了表征,结果发现,在所探索的各种肽序列(带有酪氨酸 Y 的 NDI-酪氨酸 Y、苯丙氨酸 F、亮氨酸 L、缬氨酸 V、丙氨酸 A 或甘氨酸 G-NH2)中,酪氨酸-苯丙氨酸在每种情况下都是最佳序列;然而,其绝对和相对产量的放大都取决于供体成分的性质,这表明在组装中肽序列和供体/受体对之间存在协同作用。该方法为纳米结构提供了一种原位发现工具,使超分子电子学能够与水相(生物)系统进行动态接口。
