植物细胞分裂的微管网络。

Systems and Synthetic Biology Pub Date : 2014-09-01 Epub Date: 2014-04-02 DOI:10.1007/s11693-014-9142-x
Jeroen de Keijzer, Bela M Mulder, Marcel E Janson
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引用次数: 22

摘要

在细胞质分裂过程中,细胞的细胞质分裂形成两个子细胞。在动物细胞中,现有的质膜首先收缩,然后脱落,形成两个单独的质膜。另一方面,植物细胞通过形成内部分裂壁进行分裂,即所谓的细胞板,它是由膜和细胞壁材料的局部沉积构成的。结构开始于细胞中心有丝分裂纺锤体的位置,并沿径向向现有的质膜继续进行。最后,细胞膜与细胞质膜融合形成两个独立的细胞质膜。两个基于微管的细胞骨架网络——片质体和前期带(PPB)共同控制着植物的细胞分裂。phragmoplast的双极微管阵列调节细胞板沉积到皮质位置,该位置由PPB的环状微管阵列模板化。与大多数动物细胞相比,植物不使用中心体作为微管生长起始的焦点。相反,植物微管网络是自组织系统的显著例子,它是由分散的微管的物理约束相互作用产生的。在这里,我们将讨论基于微管的活动,包括生长、收缩、切断、滑动、成核和捆绑如何相互关联,共同产生所需的有序结构。越来越多的证据表明,适配蛋白感知微管的局部几何形状,从而局部调节参与微管生长调节和切断的蛋白质的活性。许多涉及的蛋白质和机制在其他微管组装中也有作用,赋予从植物中获得的见解更广泛的相关性。
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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Microtubule networks for plant cell division.

During cytokinesis the cytoplasm of a cell is divided to form two daughter cells. In animal cells, the existing plasma membrane is first constricted and then abscised to generate two individual plasma membranes. Plant cells on the other hand divide by forming an interior dividing wall, the so-called cell plate, which is constructed by localized deposition of membrane and cell wall material. Construction starts in the centre of the cell at the locus of the mitotic spindle and continues radially towards the existing plasma membrane. Finally the membrane of the cell plate and plasma membrane fuse to form two individual plasma membranes. Two microtubule-based cytoskeletal networks, the phragmoplast and the pre-prophase band (PPB), jointly control cytokinesis in plants. The bipolar microtubule array of the phragmoplast regulates cell plate deposition towards a cortical position that is templated by the ring-shaped microtubule array of the PPB. In contrast to most animal cells, plants do not use centrosomes as foci of microtubule growth initiation. Instead, plant microtubule networks are striking examples of self-organizing systems that emerge from physically constrained interactions of dispersed microtubules. Here we will discuss how microtubule-based activities including growth, shrinkage, severing, sliding, nucleation and bundling interrelate to jointly generate the required ordered structures. Evidence mounts that adapter proteins sense the local geometry of microtubules to locally modulate the activity of proteins involved in microtubule growth regulation and severing. Many of the proteins and mechanisms involved have roles in other microtubule assemblies as well, bestowing broader relevance to insights gained from plants.

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