Katherine Morelli, Sandro M Meier, Angela Zhao, Madhurima Choudhury, M Willis, Yves Barral, Jackie Vogel
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引用次数: 0
摘要
微管耗能的动态不稳定性会产生巨大的力,人们认为可以利用这些力来移动细胞中的大型载荷。然而,能够捕捉微管解聚过程中释放的力以移动大型载荷的机制一直难以确定。在这项工作中,我们发现生物分子凝聚物为这一问题提供了一个优雅的解决方案。利用活细胞超分辨率显微镜,我们直接观察到芽殖酵母 +TIP 体是具有典型流体行为的纳米级液滴,其表面聚集了 V 型肌球蛋白(Myo2)。我们发现,蛋白质 Kar9 中保守的自聚界面调整了粘弹性 +TIP 体的生物物理特性及其有效移动有丝分裂纺锤体的能力。我们的发现为如何利用微管动力学在细胞中产生的力量引入了一个范例,并为纳米级生物分子凝聚体在其原生环境中的研究开辟了一个前沿领域。
A fluid droplet harvests the force generated by shrinking microtubules in living cells
The energy-consuming dynamic instability of microtubules generates significant forces which are thought to be harnessed to move large cargos in cells. However, identification of mechanisms which can capture the force released during microtubule depolymerization to move large loads has been elusive. In this work we show that a biomolecular condensate provides an elegant solution to this problem. Using live cell super-resolution microscopy, we directly observe that budding yeast +TIP bodies are nanoscale droplets with classic fluid-like behaviors which accumulate type V myosin (Myo2) at their surfaces. We find that conserved self-oligomerization interfaces in the protein Kar9 tune the biophysical properties of the viscoelastic +TIP body and its ability to efficiently move the mitotic spindle. Our findings introduce a paradigm for how forces generated by microtubule dynamics are harnessed in cells and open a frontier of research on nanoscale biomolecular condensates in their native environment.
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