微管崩溃及其调控的理论。

A theory of microtubule catastrophes and their regulation.

机构信息

Cell Biology Unit, European Molecular Biology Laboratory, 69117 Heidelberg, Germany.

出版信息

Proc Natl Acad Sci U S A. 2009 Dec 15;106(50):21173-8. doi: 10.1073/pnas.0910774106. Epub 2009 Nov 30.

DOI:10.1073/pnas.0910774106

PMID:19948965

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2795527/

Abstract

Dynamic instability, in which abrupt transitions occur between growing and shrinking states, is an intrinsic property of microtubules that is regulated by both mechanics and specialized proteins. We discuss a model of dynamic instability based on the popular idea that growth is maintained by a cap at the tip of the fiber. The loss of this cap is thought to trigger the transition from growth to shrinkage, called a catastrophe. The model includes longitudinal interactions between the terminal tubulins of each protofilament and "gating rescues" between neighboring protofilaments. These interactions allow individual protofilaments to transiently shorten during a phase of overall microtubule growth. The model reproduces the reported dependency of the catastrophe rate on tubulin concentration, the time between tubulin dilution and catastrophe, and the induction of microtubule catastrophes by walking depolymerases. The model also reproduces the comet tail distribution that is characteristic of proteins that bind to the tips of growing microtubules.

摘要

动态不稳定性是微管的固有性质，其中会在生长和收缩状态之间发生突然转变，这种不稳定性受到力学和专门蛋白质的调节。我们讨论了一个基于微管尖端存在帽状结构来维持生长的流行观点的动态不稳定性模型。这种帽状结构的丢失被认为会引发从生长到收缩的转变，称为灾难。该模型包括每个原纤维末端微管蛋白之间的纵向相互作用，以及相邻原纤维之间的“门控救援”。这些相互作用允许单个原纤维在微管整体生长的一个阶段中短暂缩短。该模型再现了报告的灾难率与微管蛋白浓度、微管蛋白稀释和灾难之间的时间以及行走解聚酶诱导微管灾难之间的依赖性。该模型还再现了与结合到生长微管尖端的蛋白质特征性相关的彗星尾分布。

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