Vigna sp. (mung)管蛋白 GTP 水解速率差异对微管丝组装的集体影响。

Jashaswi Basu, Chaitanya A Athale
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摘要

微管(MT)是一种动态细胞骨架细丝,其序列在进化过程中高度保守,通过依赖 GTP 的微管蛋白亚基组装而聚合。尽管序列保守,但脊椎动物大脑、模式植物拟南芥和原生动物疟原虫的MT聚合动力学在数量上存在差异。在此之前,通过温度循环从植物Vigna sp.(绿豆)幼苗中纯化的微管蛋白被发现临界浓度非常低。然而,MT 的长度为亚微米级,比脑微管蛋白丝短得多。这在模拟中被解释为高成核率和 GTP 水解率共同作用的结果。在这里,我们测试了亲和纯化的木犀草小管蛋白的 GTPase 速率对微管聚合和伸长的影响。亲和纯化的孟小管蛋白具有活性,临界浓度为 0.37 μM。GTP 依赖性聚合动力学是瞬时的,与之前的结果一致。在 GTP 类似物 GMPPNP(不可水解)或 GMPCPP(可缓慢水解)存在的情况下,聚合会趋于稳定。通过干涉反射显微镜(IRM),我们发现使用不可水解类似物进行聚合会显著增加细丝数量,而两种 GTP 类似物的长度均不受影响。然而,长时间与可缓慢水解的 GMPCPP 培养会产生长丝,这表明 GTP 的水解是决定 MT 长度的关键因素。我们发现蒙氏管蛋白的 GTPase 平均周转次数为 22.8 分钟-1,而山羊脑管蛋白的周转次数为 2.04 分钟-1。因此,调节 GTPase 的速率会影响成核和伸长。尽管α和β-微管蛋白的GTPase结构域序列高度保守,但这种动力学上的定量差异有助于更好地理解选择压力和功能在不同生物体中的作用。
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Collective effect of Vigna sp. (mung) tubulin GTP hydrolysis rate divergence on microtubule filament assembly.

Microtubules (MTs) are dynamic cytoskeletal filaments with highly conserved sequences across evolution, polymerizing by the GTP-dependent assembly of tubulin subunits. Despite the sequence conservation, MT polymerization kinetics diverge quantitatively between vertebrate brain, the model plant Arabidopsis and the protozoan Plasmodium. Previously, tubulin purified from seedlings of the plant Vigna sp. (mung) by temperature cycling was found to have a very low critical concentration. However, the lengths of MTs were sub-micron, much shorter than brain tubulin filaments. This was explained in simulations to be the result of the collective effect of high nucleation and GTP hydrolysis rates. Here, we test the effect of GTPase rates of affinity-purified Vigna sp. tubulin on microtubule polymerization and elongation. Affinity-purified mung tubulin is active and has a critical concentration of .37 μM. The GTP-dependent polymerization kinetics are transient, consistent with previous results. Polymerization is stabilized in the presence of either GTP analog GMPPNP (non-hydrolyzable) or GMPCPP (slow-hydrolyzable). Using interference reflection microscopy (IRM) we find polymerization with the non-hydrolysable analog significantly increases filament numbers, while lengths are unaffected for both GTP analogs. However, prolonged incubation with slow-hydrolyzable GMPCPP results in long filaments, pointing to GTP hydrolysis as a key factor determining MT length. We find the average GTPase turnover number of mung tubulin is 22.8 min-1, compared to 2.04 min-1 for goat brain tubulin. Thus modulating GTPase rates affects both nucleation and elongation. This quantitative divergence in kinetics despite high sequence conservation in the GTPase domains of α- and β-tubulin could help better understand the roles of selective pressure and function in the diverse organisms.

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