One of challenges for using microtubules (MTs) driven by kinesin motors in microfluidic environments is to control their direction of movement. Although applying physical biases to rectify MTs is prevalent, it has not been established as a design methodology in conjunction with microfluidic devices. In the future, the methodology is expected to achieve functional motor-driven nanosystems. Here, we propose a method to guide kinesin-propelled MTs in multiple directions under an electric field by designing a charged surface of MT minus ends labeled with dsDNA via a streptavidin-biotin interaction. MTs labeled with 20-bp or 50-bp dsDNA molecules showed significantly different trajectories according to the DNA length, which were in good agreement with values predicted from electrophoretic mobilities measured for their minus ends. Since the effective charge of labeled DNA molecules was equal to that of freely dispersed DNA molecules in a buffer solution, MT trajectory could be estimated by selecting labeling molecules with known charges. Moreover, the estimated trajectory enables to define geometrical sizes of a microfluidic device. This rational molecular design and prediction methodology allows MTs to be guided in multiple directions, demonstrating the feasibility of using molecular sorters driven by motor proteins.
展开▼
机译:在微流体环境中使用由驱动蛋白驱动的微管(MT)的挑战之一是控制其运动方向。尽管普遍施加物理偏差来校正MT,但尚未将其建立为与微流体装置结合的设计方法。将来,该方法有望实现功能性的电机驱动纳米系统。在这里,我们提出了一种方法,通过设计链霉亲和素-生物素相互作用,设计带有dsDNA标记的MT负端的带电表面,从而在电场下沿多个方向引导驱动蛋白的MT。标记有20 bp或50 bp dsDNA分子的MTs根据DNA长度显示出明显不同的轨迹,这与根据电泳迁移率的负端预测的值非常吻合。由于标记的DNA分子的有效电荷等于缓冲溶液中自由分散的DNA分子的有效电荷,因此可以通过选择带有已知电荷的标记分子来估计MT轨迹。此外,估计的轨迹使得能够定义微流体装置的几何尺寸。这种合理的分子设计和预测方法使MT可以在多个方向上被引导,这证明了使用由运动蛋白驱动的分子分选仪的可行性。
展开▼
