Fluorescence tracking of motor proteins in vitro.

Q2 Medicine Experientia supplementum (2012) Pub Date : 2014-01-01 DOI:10.1007/978-3-0348-0856-9_10

Mark DeWitt, Thomas Schenkel, Ahmet Yildiz

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引用次数: 3

Abstract

Motor proteins convert the chemical energy of adenosine triphosphate (ATP) hydrolysis into directed movement along filamentous tracks, such as DNA, microtubule, and actin. The motile properties of motors are essential to their wide variety of cellular functions, including cargo transport, mitosis, cell motility, nuclear positioning, and ciliogenesis. Detailed understanding of the biophysical mechanisms of motor motility is therefore essential to understanding the physical basis of these processes. In which direction is the motor going? How fast and how far can a single motor walk down its track? How is ATP hydrolysis coupled to directed motion? How do multiple subunits of a motor coordinate with each other during motility? These questions can be addressed directly by tracking motors at a single-molecule level. This chapter will focus on high-resolution fluorescence tracking techniques of the processive cytoskeletal motors: myosins, kinesins, and cytoplasmic dynein. We outline the theoretical and practical considerations for studying these motors in vitro using fluorescence tracking at nanometer precision.

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体外运动蛋白的荧光跟踪。

运动蛋白将三磷酸腺苷(ATP)水解的化学能转化为沿丝状轨迹定向运动，如DNA、微管和肌动蛋白。马达的运动特性对其多种细胞功能至关重要，包括货物运输、有丝分裂、细胞运动、核定位和纤毛发生。因此，详细了解运动的生物物理机制对于理解这些过程的物理基础至关重要。马达朝哪个方向转动?一个马达在轨道上能走多快多远?ATP水解如何与定向运动耦合?在运动过程中，一个运动的多个亚单位是如何相互协调的?这些问题可以通过在单分子水平上跟踪马达来直接解决。本章将重点介绍过程细胞骨架马达的高分辨率荧光跟踪技术:肌凝蛋白、运动蛋白和细胞质动力蛋白。我们概述了在纳米精度下使用荧光跟踪在体外研究这些马达的理论和实践考虑。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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