生物系统中的远程机械信号传导。
Long-range mechanical signaling in biological systems.
作者信息
Alisafaei Farid, Chen Xingyu, Leahy Thomas, Janmey Paul A, Shenoy Vivek B
机构信息
Center for Engineering Mechanobiology, University of Pennsylvania, Philadelphia, PA 19104, USA.
出版信息
Soft Matter. 2021 Jan 22;17(2):241-253. doi: 10.1039/d0sm01442g.
Abstract
Cells can respond to signals generated by other cells that are remarkably far away. Studies from at least the 1920's showed that cells move toward each other when the distance between them is on the order of a millimeter, which is many times the cell diameter. Chemical signals generated by molecules diffusing from the cell surface would move too slowly and dissipate too fast to account for these effects, suggesting that they might be physical rather than biochemical. The non-linear elastic responses of sparsely connected networks of stiff or semiflexible filament such as those that form the extracellular matrix (ECM) and the cytoskeleton have unusual properties that suggest multiple mechanisms for long-range signaling in biological tissues. These include not only direct force transmission, but also highly non-uniform local deformations, and force-generated changes in fiber alignment and density. Defining how fibrous networks respond to cell-generated forces can help design new methods to characterize abnormal tissues and can guide development of improved biomimetic materials.
摘要
细胞能够对来自非常远处的其他细胞产生的信号作出反应。至少从20世纪20年代起的研究表明,当细胞间距离在毫米量级时,它们会相互靠近,这是细胞直径的许多倍。从细胞表面扩散的分子产生的化学信号移动太慢且消散太快,无法解释这些效应,这表明它们可能是物理信号而非生化信号。诸如构成细胞外基质(ECM)和细胞骨架的那些刚性或半柔性细丝的稀疏连接网络的非线性弹性响应具有不同寻常的特性,这表明生物组织中存在多种长程信号传导机制。这些机制不仅包括直接的力传递,还包括高度不均匀的局部变形,以及力引起的纤维排列和密度变化。确定纤维网络如何响应细胞产生的力有助于设计表征异常组织的新方法,并能指导改进的仿生材料的开发。
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