Shemyakin-Ovchinnikov Institute of Bioorganic Chemistry, Russian Academy of Sciences, 16/10 Miklukho-Maklaya Street, Moscow 117997, Russia.
Proc Natl Acad Sci U S A. 2010 Mar 30;107(13):5827-32. doi: 10.1073/pnas.1001142107. Epub 2010 Mar 15.
A bioengineering method for self-assembly of multifunctional superstructures with in-advance programmable properties has been proposed. The method employs two unique proteins, barnase and barstar, to rapidly join the structural components together directly in water solutions. The properties of the superstructures can be designed on demand by linking different agents of various sizes and chemical nature, designated for specific goals. As a proof of concept, colloidally stable trifunctional structures have been assembled by binding together magnetic particles, quantum dots, and antibodies using barnase and barstar. The assembly has demonstrated that the bonds between these proteins are strong enough to hold macroscopic (5 nm-3 microm) particles together. Specific interaction of such superstructures with cancer cells resulted in fluorescent labeling of the cells and their responsiveness to magnetic field. The method can be used to join inorganic moieties, organic particles, and single biomolecules for synergistic use in different applications such as biosensors, photonics, and nanomedicine.
提出了一种具有预先可编程特性的多功能超结构的自组装生物工程方法。该方法采用两种独特的蛋白质, barnase 和 barstar,在水溶液中直接快速地将结构组件连接在一起。通过连接不同大小和化学性质的各种试剂,可以按需设计超结构的性能,指定用于特定的目的。作为概念验证,使用 barnase 和 barstar 结合磁性颗粒、量子点和抗体组装了胶体稳定的 trifunctional 结构。该组装证明了这些蛋白质之间的键足够强,可以将宏观(5nm-3μm)颗粒结合在一起。这些超结构与癌细胞的特异性相互作用导致了细胞的荧光标记及其对磁场的响应。该方法可用于连接无机部分、有机颗粒和单个生物分子,以协同应用于生物传感器、光子学和纳米医学等不同领域。