细胞间通讯中膜状纳米结构形成的机制。
Mechanisms for the formation of membranous nanostructures in cell-to-cell communication.
作者信息
Schara Karin, Jansa Vid, Sustar Vid, Dolinar Drago, Pavlic Janez Ivan, Lokar Marusa, Kralj-Iglic Veronika, Veranic Peter, Iglic Ales
机构信息
Laboratory of Clinical Biophysics, Institute of Biophysics, Faculty of Medicine, University of Ljubljana, Lipiceva 2, SI-1000, Ljubljana, Slovenia.
出版信息
Cell Mol Biol Lett. 2009;14(4):636-56. doi: 10.2478/s11658-009-0018-0. Epub 2009 Jun 25.
Abstract
Cells interact by exchanging material and information. Two methods of cell-to-cell communication are by means of microvesicles and by means of nanotubes. Both microvesicles and nanotubes derive from the cell membrane and are able to transport the contents of the inner solution. In this review, we describe two physical mechanisms involved in the formation of microvesicles and nanotubes: curvature-mediated lateral redistribution of membrane components with the formation of membrane nanodomains; and plasmamediated attractive forces between membranes. These mechanisms are clinically relevant since they can be affected by drugs. In particular, the underlying mechanism of heparin's role as an anticoagulant and tumor suppressor is the suppression of microvesicluation due to plasma-mediated attractive interaction between membranes.
摘要
细胞通过交换物质和信息进行相互作用。细胞间通讯的两种方式是通过微囊泡和纳米管。微囊泡和纳米管均源自细胞膜,并且能够运输内部溶液的成分。在本综述中,我们描述了微囊泡和纳米管形成过程中涉及的两种物理机制:膜成分的曲率介导的横向重新分布与膜纳米域的形成;以及血浆介导的膜间吸引力。这些机制具有临床相关性,因为它们会受到药物的影响。特别是,肝素作为抗凝剂和肿瘤抑制剂作用的潜在机制是由于血浆介导的膜间吸引相互作用而抑制微囊泡化。
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