Department of Chemical and Biomolecular Engineering, University of Illinois at Urbana-Champaign, Urbana, Illinois, USA.
Center for the Physics of Living Cells, University of Illinois at Urbana-Champaign, Urbana, Illinois, USA.
Nanoscale. 2022 Sep 2;14(34):12463-12475. doi: 10.1039/d2nr01701f.
Molecular motors often work in teams to move a cellular cargo. Yet measuring the forces exerted by each motor is challenging. Using a sensor made with denatured ssDNA and multi-color fluorescence, we measured picoNewtons of forces and nanometer distances exerted by individual constrained kinesin-1 motors acting together while driving a common microtubule . We find that kinesins primarily exerted less than 1 pN force, even while the microtubule is bypassing artificial obstacles of 20-100 nanometer size. Occasionally, individual forces increase upon encountering obstacles, although at other times they do not, with the cargo continuing in a directional manner. Our high-throughput technique, which can measure forces by many motors simultaneously, is expected to be useful for many different types of molecular motors.
分子马达通常协同工作以移动细胞货物。然而,测量每个马达施加的力是具有挑战性的。使用由变性 ssDNA 和多色荧光制成的传感器,我们测量了单个约束驱动蛋白-1 马达在共同驱动一个常见微管时施加的皮牛顿力和纳米距离。我们发现,即使在微管绕过大小为 20-100 纳米的人工障碍物时,驱动蛋白主要施加的力也小于 1 pN。偶尔,在遇到障碍物时,个别力会增加,尽管在其他时候它们不会增加,货物会继续以定向方式前进。我们的高通量技术可以同时测量多个马达施加的力,预计对许多不同类型的分子马达都很有用。