Department of Genetics, Cell Biology and Development, University of Minnesota, Minneapolis, MN 55455, USA.
Curr Biol. 2013 Jul 22;23(14):1342-8. doi: 10.1016/j.cub.2013.05.059. Epub 2013 Jul 3.
Microtubules are key structural and transport elements in cells. The dynamics at microtubule ends are characterized by periods of slow growth, followed by stochastic switching events termed "catastrophes," in which microtubules suddenly undergo rapid shortening. Growing microtubules are thought to be protected from catastrophe by a GTP-tubulin "cap": GTP-tubulin subunits add to the tips of growing microtubules but are subsequently hydrolyzed to GDP-tubulin subunits once they are incorporated into the microtubule lattice. Loss of the GTP-tubulin cap exposes GDP-tubulin subunits at the microtubule tip, resulting in a catastrophe event. However, the mechanistic basis for sudden loss of the GTP cap, leading to catastrophe, is not known. To investigate microtubule catastrophe events, we performed 3D mechanochemical simulations that account for interactions between neighboring protofilaments. We found that there are two separate factors that contribute to catastrophe events in the 3D simulation: the GTP-tubulin cap size, which settles into a steady-state value that depends on the free tubulin concentration during microtubule growth, and the structure of the microtubule tip. Importantly, 3D simulations predict, and both fluorescence and electron microscopy experiments confirm, that microtubule tips become more tapered as the microtubule grows. This effect destabilizes the tip and ultimately contributes to microtubule catastrophe. Thus, the likelihood of a catastrophe event may be intimately linked to the aging physical structure of the growing microtubule tip. These results have important consequences for catastrophe regulation in cells, as microtubule-associated proteins could promote catastrophe events in part by modifying microtubule tip structures.
微管是细胞中关键的结构和运输元素。微管末端的动力学特征是缓慢生长的时期,随后是随机切换事件,称为“灾难”,在此期间微管突然经历快速缩短。生长中的微管被认为受到 GTP-微管“帽”的保护,以免发生灾难:GTP-微管亚基添加到生长中的微管的尖端,但一旦它们被纳入微管晶格,就会被水解为 GDP-微管亚基。GTP-微管帽的丢失会导致 GDP-微管亚基暴露在微管尖端,从而导致灾难事件。然而,导致灾难的 GTP 帽突然丢失的机制基础尚不清楚。为了研究微管灾难事件,我们进行了 3D 机械化学模拟,该模拟考虑了相邻原丝之间的相互作用。我们发现,有两个独立的因素导致 3D 模拟中的灾难事件:GTP-微管帽的大小,它会稳定在一个取决于微管生长过程中游离微管浓度的稳定值,以及微管尖端的结构。重要的是,3D 模拟预测,荧光和电子显微镜实验均证实,随着微管的生长,微管尖端变得更加锥形。这种效应会使尖端不稳定,并最终导致微管灾难。因此,灾难事件的可能性可能与生长中的微管尖端的老化物理结构密切相关。这些结果对细胞中的灾难调节具有重要意义,因为微管相关蛋白可能通过改变微管尖端结构来促进灾难事件。