Yap A S, Brieher W M, Pruschy M, Gumbiner B M
Cellular Biochemistry and Biophysics Program, Memorial Sloan-Kettering Cancer Center, 1275 York Avenue, New York 10021, USA.
Curr Biol. 1997 May 1;7(5):308-15. doi: 10.1016/s0960-9822(06)00154-0.
Classical cadherin-based cellular adhesion is mediated by a multicomponent protein complex that links the adhesive binding activity of the cadherin ectodomain to the actin cytoskeleton. Despite the importance of cadherins in morphogenesis and development, we know very little about how cells determine and alter cadherin adhesive strength. In this study, we sought to identify specific cellular mechanisms that modulate cadherin function by studying adhesion between cells transfected with Xenopus C-cadherin mutant molecules and substrata coated with the purified ectodomain of C-cadherin.
Using the FKBP-FK1012 protein oligomerization system, we found that forced clustering, in cells, of cadherin mutants lacking the cytoplasmic tail significantly increased cellular adhesive strength. Therefore, redistribution of the adhesive binding sites of cells into clusters can influence adhesion independently of other protein interactions mediated by the cadherin cytoplasmic tail. Furthermore, cells transfected with full-length C-cadherin demonstrated dynamic changes in adhesion over time that correlated with clustering but not with changes in the surface expression of C-cadherin or in the composition of the cadherin-catenin complex. The cytoplasmic tail was, however, necessary for clustering of wild-type cadherin.
These studies directly demonstrate a fundamental role for lateral clustering in cadherin function. The distribution of cadherin binding sites presented at the cell surface, a cellular property which is regulated by the cadherin cytoplasmic tail, is an important mechanism which modulates cellular adhesion independently of cytoskeletal activity or signalling.
基于经典钙黏蛋白的细胞黏附由一种多组分蛋白质复合物介导,该复合物将钙黏蛋白胞外域的黏附结合活性与肌动蛋白细胞骨架相连。尽管钙黏蛋白在形态发生和发育中很重要,但我们对细胞如何确定和改变钙黏蛋白黏附强度知之甚少。在本研究中,我们试图通过研究用非洲爪蟾C-钙黏蛋白突变分子转染的细胞与包被有纯化的C-钙黏蛋白胞外域的基质之间的黏附,来确定调节钙黏蛋白功能的特定细胞机制。
使用FKBP-FK1012蛋白质寡聚化系统,我们发现,在细胞中,缺乏胞质尾的钙黏蛋白突变体的强制聚集显著增加了细胞黏附强度。因此,细胞黏附结合位点重新分布成簇可独立于由钙黏蛋白胞质尾介导的其他蛋白质相互作用来影响黏附。此外,用全长C-钙黏蛋白转染的细胞表现出随时间的黏附动态变化,这与成簇相关,但与C-钙黏蛋白的表面表达变化或钙黏蛋白-连环蛋白复合物的组成变化无关。然而,胞质尾对于野生型钙黏蛋白的成簇是必需的。
这些研究直接证明了侧向成簇在钙黏蛋白功能中的基本作用。细胞表面呈现的钙黏蛋白结合位点的分布是一种由钙黏蛋白胞质尾调节的细胞特性,是一种独立于细胞骨架活性或信号传导来调节细胞黏附的重要机制。
