Department of Molecular and Cellular Pharmacology, University of Miami Miller School of Medicine, Miami, FL 33101, USA.
Traffic. 2012 Apr;13(4):511-9. doi: 10.1111/j.1600-0854.2011.01321.x. Epub 2012 Jan 13.
The N-terminal domain (TD) of the clathrin heavy chain is folded into a seven-bladed β-propeller that projects inward from the polyhedral outer clathrin coat. As the most membrane-proximal portion of assembled clathrin, the TD is a major protein-protein interaction node. Contact with the TD β-propeller occurs through short peptide sequences typically located within intrinsically disordered segments of coat components that usually are elements of the membrane-apposed, inner 'adaptor' coat layer. A huge variation in TD-binding motifs is known and now four spatially discrete interaction surfaces upon the β-propeller have been delineated. An important operational feature of the TD interaction sites in vivo is functional redundancy. The recent discovery that 'pitstop' chemical inhibitors apparently occupy only one of the four TD interaction surfaces, but potently block clathrin-mediated endocytosis, warrants careful consideration of the underlying molecular basis for this inhibition.
网格蛋白重链的 N 端结构域(TD)折叠成一个七叶β-螺旋桨,从多面的外网格蛋白衣向内突出。作为组装好的网格蛋白最接近膜的部分,TD 是一个主要的蛋白质-蛋白质相互作用节点。与 TD β-螺旋桨的接触是通过短肽序列发生的,这些序列通常位于衣壳成分的固有无序片段内,这些成分通常是膜贴附的、内部“衔接”衣壳层的元件。已知 TD 结合基序有很大的变异性,现在已经描绘了β-螺旋桨上四个空间离散的相互作用表面。TD 相互作用位点在体内的一个重要操作特征是功能冗余。最近的发现表明,“停车”化学抑制剂显然只占据四个 TD 相互作用表面中的一个,但能有效地阻断网格蛋白介导的胞吞作用,这需要仔细考虑这种抑制的潜在分子基础。