植物细胞皮层微管重定向机制的研究。

C L Wymer, D D Fisher, R C Moore, R J Cyr
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引用次数: 41

摘要

皮层微管阵列的重新定向是植物细胞发育的重要组成部分。然而,这一过程的机制细节尚不清楚。新鲜分离的原生质体(从烟草BY-2悬浮培养中获得)的皮层微管阵列相对随机,但在培养后细胞壁再生,微管开始重组。由于皮质微管是高度动态的,我们假设它们的重组完全是通过无序微管的解聚,然后再聚合成有序阵列来完成的。这一假设在新鲜分离的原生质体上进行了测试,使用药物通过过度稳定聚合物(紫杉醇)来改变微管的动态状态;或者阻止亚基加入微管(氨丙磷甲基;APM)。用10微米紫杉醇超稳定的微管阵列不仅重新排序,而且比未处理的细胞更快。此外,紫杉醇和20微米APM处理的原生质体也表现出加速的重组。在体内和体外进行的对照实验证实,亚基添加受到APM的阻碍。因此,微管似乎能够作为相对完整的单位重新定向。叠氮化钠(1mm)和氰化钠(1mm)可以阻止重定向,表明这一事件需要细胞能量,但这种能量不被肌动蛋白-肌球蛋白系统使用,因为微丝破坏药物细胞松弛素D(50微米)不影响重定向。这些结果表明,皮层微管阵列重组是一个复杂的过程,可能涉及聚合物的运动。
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Elucidating the mechanism of cortical microtubule reorientation in plant cells.

Reorientation of the cortical microtubule array is an essential component of cellular development in plants. However, mechanistic details of this process are unknown. The cortical microtubule array of freshly isolated protoplasts (obtained from Nicotiana tabacum BY-2 suspension culture) is relatively random, but upon culturing the cell wall regenerates and the microtubules begin to reorganize. Because cortical microtubules are highly dynamic, we postulated that their reorganization is accomplished solely by the depolymerization of disordered microtubules, followed by repolymerization into an ordered array. This hypothesis was tested on freshly isolated protoplasts using drugs that alter the dynamic status of microtubules by either hyperstabilizing the polymer (taxol); or preventing the addition of subunits to the microtubules (amiprophosmethyl; APM). Microtubule arrays that were hyperstabilized with 10 microM taxol not only reordered, but did so more quickly than untreated cells. Moreover, protoplasts treated with taxol and 20 microM APM also showed accelerated reorganization. Control experiments, performed in vivo and in vitro, confirmed that subunit addition was hindered by APM. Thus, microtubules appear capable of reorienting as relatively intact units. Sodium azide (1 mM) and sodium cyanide (1 mM) can prevent reorientation, indicating that cellular energy is required for this event but this energy is not used by the actin-myosin system because the microfilament-disrupting drug cytochalasin D (50 microM) did not affect reorientation. These results indicate that cortical microtubule array reorganization is a complex process that can involve polymer movement.

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