细胞长度依赖性微管在极化过程中的积累。

Cell-length-dependent microtubule accumulation during polarization.

机构信息

Department of Biomedical Engineering, University of Minnesota, Minneapolis, MN 55455, USA.

出版信息

Curr Biol. 2010 Jun 8;20(11):979-88. doi: 10.1016/j.cub.2010.04.040. Epub 2010 May 20.

DOI:10.1016/j.cub.2010.04.040

PMID:20493705

Abstract

BACKGROUND

Breaking cell symmetry, known as polarization, requires dynamic reorganization of microtubules (MTs) and is essential to many cellular processes, including axon formation in neurons. A critical step in polarization is believed to be the "selective stabilization" of MTs, which hypothesizes a spatial and/or temporal shift toward net MT assembly in a preferred direction of growth.

RESULTS

We now find that a simpler "length-dependent" model, in which MT assembly parameters are spatially and temporally constant, predicts MT accumulation in the direction of growth because of longer mean first passage times in the longer direction. We experimentally tested both models by tracking MT assembly dynamics in polarizing embryonic chick forebrain neurons, and we confirmed that assembly is spatially and temporally constant during axon formation.

CONCLUSION

Cell polarization occurs most simply through cell-length-dependent accumulation of MTs without MT stabilization or capture. In this way, F-actin-mediated cell shape and size changes can be read out by dynamic MTs undergoing simple dynamic instability to ultimately break cell symmetry.

摘要

背景

细胞对称性的破坏，即极化，需要微管（MTs）的动态重组，这对许多细胞过程至关重要，包括神经元中的轴突形成。极化的一个关键步骤被认为是 MT 的“选择性稳定”，这假设了在生长的首选方向上，MT 组装的空间和/或时间向净 MT 组装的转移。

结果

我们现在发现，一个更简单的“长度依赖性”模型，其中 MT 组装参数在空间和时间上是恒定的，由于较长方向上的平均首次通过时间较长，预测 MT 在生长方向上的积累。我们通过跟踪极化的胚胎鸡前脑神经元中 MT 组装动力学来实验测试这两个模型，并证实了在轴突形成过程中，组装在空间和时间上是恒定的。

结论

细胞极化最容易通过 MT 的细胞长度依赖性积累而发生，而不需要 MT 的稳定或捕获。通过这种方式，F-肌动蛋白介导的细胞形状和大小的变化可以通过经历简单动态不稳定性的动态 MT 读出，最终打破细胞对称性。

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细胞长度依赖性微管在极化过程中的积累。

Cell-length-dependent microtubule accumulation during polarization.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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