意想不到的膜动力学由膜纳米管挤出揭示。
Unexpected membrane dynamics unveiled by membrane nanotube extrusion.
机构信息
Institut Curie, Centre de Recherche, Laboratoire Physico-Chimie, Paris, France.
出版信息
Biophys J. 2013 Mar 19;104(6):1248-56. doi: 10.1016/j.bpj.2013.01.051.
Abstract
In cell mechanics, distinguishing the respective roles of the plasma membrane and of the cytoskeleton is a challenge. The difference in the behavior of cellular and pure lipid membranes is usually attributed to the presence of the cytoskeleton as explored by membrane nanotube extrusion. Here we revisit this prevalent picture by unveiling unexpected force responses of plasma membrane spheres devoid of cytoskeleton and synthetic liposomes. We show that a tiny variation in the content of synthetic membranes does not affect their static mechanical properties, but is enough to reproduce the dynamic behavior of their cellular counterparts. This effect is attributed to an amplified intramembrane friction. Reconstituted actin cortices inside liposomes induce an additional, but not dominant, contribution to the effective membrane friction. Our work underlines the necessity of a careful consideration of the role of membrane proteins on cell membrane rheology in addition to the role of the cytoskeleton.
摘要
在细胞力学中,区分质膜和细胞骨架的各自作用是一个挑战。细胞膜和纯脂质膜的行为差异通常归因于细胞骨架的存在,这一点可以通过膜纳米管挤出实验来探究。在这里,我们通过揭示没有细胞骨架的质膜球体和合成脂质体出人意料的力响应,重新审视了这一普遍观点。我们表明,合成膜含量的微小变化不会影响其静态机械性能,但足以重现其细胞对应物的动态行为。这种效应归因于增强的膜内摩擦力。在脂质体内部重新组装的肌动蛋白皮层会引起额外的、但不是主要的贡献,从而增加有效膜摩擦力。我们的工作强调了在考虑细胞细胞膜流变性时,除了细胞骨架的作用外,还必须仔细考虑膜蛋白的作用。
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