Park Jai Il, Nguyen Trung Dac, de Queirós Silveira Gleiciani, Bahng Joong Hwan, Srivastava Sudhanshu, Zhao Gongpu, Sun Kai, Zhang Peijun, Glotzer Sharon C, Kotov Nicholas A
1] Departments of Chemical Engineering, University of Michigan, Ann Arbor, Michigan 48109, USA [2] [3].
1] Departments of Chemical Engineering, University of Michigan, Ann Arbor, Michigan 48109, USA [2].
Nat Commun. 2014 May 20;5:3593. doi: 10.1038/ncomms4593.
Self-assembly of proteins and inorganic nanoparticles into terminal assemblies makes possible a large family of uniformly sized hybrid colloids. These particles can be compared in terms of utility, versatility and multifunctionality to other known types of terminal assemblies. They are simple to make and offer theoretical tools for designing their structure and function. To demonstrate such assemblies, we combine cadmium telluride nanoparticles with cytochrome C protein and observe spontaneous formation of spherical supraparticles with a narrow size distribution. Such self-limiting behaviour originates from the competition between electrostatic repulsion and non-covalent attractive interactions. Experimental variation of supraparticle diameters for several assembly conditions matches predictions obtained in simulations. Similar to micelles, supraparticles can incorporate other biological components as exemplified by incorporation of nitrate reductase. Tight packing of nanoscale components enables effective charge and exciton transport in supraparticles and bionic combination of properties as demonstrated by enzymatic nitrate reduction initiated by light absorption in the nanoparticle.
蛋白质与无机纳米粒子自组装成终端组装体,使得一大类尺寸均匀的混合胶体成为可能。就实用性、多功能性和多用途性而言,这些粒子可与其他已知类型的终端组装体相媲美。它们制作简单,并为设计其结构和功能提供了理论工具。为了展示此类组装体,我们将碲化镉纳米粒子与细胞色素C蛋白相结合,并观察到具有窄尺寸分布的球形超粒子的自发形成。这种自限行为源于静电排斥与非共价吸引相互作用之间的竞争。在几种组装条件下超粒子直径的实验变化与模拟中获得的预测结果相符。与胶束类似,超粒子可以纳入其他生物成分,以硝酸还原酶的纳入为例。纳米级组件的紧密堆积能够在超粒子中实现有效的电荷和激子传输,并实现如纳米粒子中光吸收引发的酶促硝酸盐还原所证明的特性的仿生组合。