U1006 INSERM, Université Aix-Marseille, Parc Scientifique et Technologique de Luminy , 163 Avenue de Luminy , 13009 Marseille , France.
Department of Anesthesiology , Weill Cornell Medicine , 1300 York Avenue , New York , New York 10065 , United States.
ACS Nano. 2018 Mar 27;12(3):2719-2727. doi: 10.1021/acsnano.7b08973. Epub 2018 Feb 6.
Spectrins are cytoskeletal proteins located at the inner face of the plasma membrane, making connections between membrane anchors and the actin cortex, and between actin filaments. Spectrins share a common structure forming a bundle of 3 α-helices and play a major role during cell deformation. Here, we used high-speed force spectroscopy and steered molecular dynamics simulations to understand the mechanical stability of spectrin, revealing a molecular force buffering function. We find that spectrin acts as a soft spring at short extensions (70-100 Å). Under continuous external stretching, its α-helices unwind, leading to a viscous mechanical response over larger extensions (100-300 Å), represented by a constant-force plateau in force/extension curves. This viscous force buffering emerges from a quasi-equilibrium competition between disruption and re-formation of α-helical hydrogen bonds. Our results suggest that, in contrast to β-sheet proteins, which unfold in a catastrophic event, α-helical spectrins dominantly unwind, providing a viscous force buffer over extensions about 5 times their folded length.
收缩蛋白是位于质膜内表面的细胞骨架蛋白,将膜锚定物与肌动蛋白皮质以及肌动蛋白丝连接起来。收缩蛋白具有共同的结构,形成一束 3 个α-螺旋,在细胞变形过程中发挥主要作用。在这里,我们使用高速力谱和导向分子动力学模拟来了解收缩蛋白的机械稳定性,揭示了其分子力缓冲功能。我们发现,在短延伸(70-100Å)时,收缩蛋白表现为软弹簧。在持续的外部拉伸下,其α-螺旋展开,导致在较大的延伸(100-300Å)下出现粘性力学响应,表现为力/延伸曲线中的恒力平台。这种粘性力缓冲来自于α-螺旋氢键破坏和再形成之间的准平衡竞争。我们的结果表明,与β-折叠蛋白在灾难性事件中展开不同,α-螺旋收缩蛋白主要展开,在其折叠长度的约 5 倍延伸范围内提供粘性力缓冲。
