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KIF3A/B的两个运动结构域协同实现连续运动,并以不同速度移动。

The two motor domains of KIF3A/B coordinate for processive motility and move at different speeds.

作者信息

Zhang Yangrong, Hancock William O

机构信息

Department of Bioengineering, The Pennsylvania State University, University Park, Pennsylvania 16802, USA.

出版信息

Biophys J. 2004 Sep;87(3):1795-804. doi: 10.1529/biophysj.104.039842.

DOI:10.1529/biophysj.104.039842
PMID:15345558
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1304584/
Abstract

KIF3A/B, a kinesin involved in intraflagellar transport and Golgi trafficking, is distinctive because it contains two nonidentical motor domains. Our hypothesis is that the two heads have distinct functional properties, which are tuned to maximize the performance of the wild-type heterodimer. To test this, we investigated the motility of wild-type KIF3A/B heterodimer and chimaeric KIF3A/A and KIF3B/B homodimers made by splicing the head of one subunit to the rod and tail of the other. The first result is that KIF3A/B is processive, consistent with its transport function in cells. Secondly, the KIF3B/B homodimer moves at twice the speed of the wild-type motor but has reduced processivity, suggesting a trade-off between speed and processivity. Third, the KIF3A/A homodimer moves fivefold slower than wild-type, demonstrating distinct functional differences between the two heads. The heterodimer speed cannot be accounted for by a sequential head model in which the two heads alternate along the microtubule with identical speeds as in the homodimers. Instead, the data are consistent with a coordinated head model in which detachment of the slow KIF3A head from the microtubule is accelerated roughly threefold by the KIF3B head.

摘要

驱动蛋白KIF3A/B参与鞭毛内运输和高尔基体运输,其独特之处在于它包含两个不同的运动结构域。我们的假设是,这两个头部具有不同的功能特性,这些特性经过调整以最大化野生型异二聚体的性能。为了验证这一点,我们研究了野生型KIF3A/B异二聚体以及通过将一个亚基的头部与另一个亚基的杆部和尾部拼接而成的嵌合KIF3A/A和KIF3B/B同二聚体的运动性。第一个结果是,KIF3A/B具有持续性,这与其在细胞中的运输功能一致。其次,KIF3B/B同二聚体的移动速度是野生型驱动蛋白的两倍,但持续性降低,这表明速度和持续性之间存在权衡。第三,KIF3A/A同二聚体的移动速度比野生型慢五倍,这表明两个头部之间存在明显的功能差异。异二聚体的速度不能用顺序头部模型来解释,在该模型中,两个头部沿着微管交替移动,速度与同二聚体相同。相反,数据与协调头部模型一致,在该模型中,KIF3B头部使较慢的KIF3A头部从微管上脱离的速度加快了约三倍。

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