Astumian R Dean
Department of Physics, University of Maine, Orono, ME 04469-5709, USA.
J Phys Condens Matter. 2005 Nov 30;17(47):S3753-66. doi: 10.1088/0953-8984/17/47/008. Epub 2005 Nov 4.
Biomolecular motors are often described in mechanical terms, with analogy to cars, turbines, judo throws, levers, etc. It is important to remember however that because of their small size, and because of the aqueous environment in which molecular motors move, viscous drag and thermal noise dominate the inertial forces that drive macroscopic machines. The sequence of motions-conformational changes-by which a motor protein moves can best be described as a random walk, with transitions from one state to another occurring by thermal activation over energy barriers. In this paper I will address the question of how this random walk is biased by a non-equilibrium chemical reaction (ATP hydrolysis) so that the motor molecule moves preferentially (with almost unit certainty) in one direction, even when an external force is applied to drive it in the opposite direction. I will also discuss how these 'soft matter' motors can achieve thermodynamic efficiencies of nearly 100%.
生物分子马达通常用机械术语来描述,可类比为汽车、涡轮机、柔道投掷动作、杠杆等。然而,重要的是要记住,由于它们尺寸小,且分子马达运动所处的水环境中,粘性阻力和热噪声主导着驱动宏观机器的惯性力。运动蛋白移动所经历的一系列运动——构象变化——最好描述为随机游走,从一个状态到另一个状态的转变是通过跨越能量势垒的热激活发生的。在本文中,我将探讨这样一个问题:这种随机游走如何受到非平衡化学反应(ATP水解)的偏向,从而使马达分子即使在受到外力驱使向相反方向移动时,仍能优先(几乎确定无疑地)向一个方向移动。我还将讨论这些“软物质”马达如何能实现接近100%的热力学效率。