柔性红细胞膜纳米结构域在膜纳米管生长和稳定性中的可能作用。

Possible role of flexible red blood cell membrane nanodomains in the growth and stability of membrane nanotubes.

作者信息

Iglic Ales, Lokar Marusa, Babnik Blaz, Slivnik Tomaz, Veranic Peter, Hägerstrand Henry, Kralj-Iglic Veronika

机构信息

Laboratory of Physics, University of Ljubljana, Ljubljana, Slovenia.

出版信息

Blood Cells Mol Dis. 2007 Jul-Aug;39(1):14-23. doi: 10.1016/j.bcmd.2007.02.013. Epub 2007 May 1.

DOI:10.1016/j.bcmd.2007.02.013

PMID:17475520

Abstract

Tubular budding of the erythrocyte membrane may be induced by exogenously added substances. It is shown that tubular budding may be explained by self-assembly of anisotropic membrane nanodomains into larger domains forming nanotubular membrane protrusions. In contrast to some previously reported theories, no direct external mechanical force is needed to explain the observed tubular budding of the bilayer membrane. The mechanism that explains tubular budding may also be responsible for stabilization of the thin tubes that connect cells or cell organelles and which might be important for the transport of matter and information in cellular systems. It is shown that small carrier vesicles (gondolas), transporting enclosed material or the molecules composing their membrane, may travel over long distances along the nanotubes connecting two cells.

摘要

红细胞膜的管状出芽可由外源性添加物质诱导。结果表明，管状出芽可以通过各向异性膜纳米结构域自组装成更大的结构域形成纳米管膜突起加以解释。与一些先前报道的理论不同，解释双层膜观察到的管状出芽现象无需直接的外部机械力。解释管状出芽的机制也可能负责连接细胞或细胞器的细管的稳定，这可能对细胞系统中的物质和信息运输很重要。结果表明，运输封闭物质或构成其膜的分子的小载体囊泡（吊篮）可以沿着连接两个细胞的纳米管长距离移动。

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柔性红细胞膜纳米结构域在膜纳米管生长和稳定性中的可能作用。

Possible role of flexible red blood cell membrane nanodomains in the growth and stability of membrane nanotubes.

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