经典钙黏蛋白的两步黏附结合。
Two-step adhesive binding by classical cadherins.
机构信息
Department of Biochemistry and Molecular Biophysics, Columbia University, New York, New York, USA.
出版信息
Nat Struct Mol Biol. 2010 Mar;17(3):348-57. doi: 10.1038/nsmb.1784. Epub 2010 Feb 28.
Abstract
Crystal structures of classical cadherins have revealed two dimeric configurations. In the first, N-terminal beta-strands of EC1 domains 'swap' between partner molecules. The second configuration (the 'X dimer'), also observed for T-cadherin, is mediated by residues near the EC1-EC2 calcium binding sites, and N-terminal beta-strands of partner EC1 domains, though held adjacent, do not swap. Here we show that strand-swapping mutants of type I and II classical cadherins form X dimers. Mutant cadherins impaired for X-dimer formation show no binding in short-time frame surface plasmon resonance assays, but in long-time frame experiments, they have homophilic binding affinities close to that of wild type. Further experiments show that exchange between monomers and dimers is slowed in these mutants. These results reconcile apparently disparate results from prior structural studies and suggest that X dimers are binding intermediates that facilitate the formation of strand-swapped dimers.
摘要
经典钙黏蛋白的晶体结构揭示了两种二聚体构象。在第一种构象中,EC1 结构域的 N 端β-链在配对分子之间“交换”。第二种构象(“X 二聚体”)也在 T-钙黏蛋白中观察到,由 EC1-EC2 钙结合位点附近的残基以及配对 EC1 结构域的 N 端β-链介导,尽管相邻,但不交换。在这里,我们表明 I 型和 II 型经典钙黏蛋白的链交换突变体形成 X 二聚体。X 二聚体形成缺陷的突变钙黏蛋白在短时间框架表面等离子体共振测定中没有结合,但在长时间框架实验中,它们具有接近野生型的同种亲合力结合亲和力。进一步的实验表明,这些突变体中单体和二聚体之间的交换速度减慢。这些结果调和了先前结构研究中明显不同的结果,并表明 X 二聚体是结合中间体,可促进链交换二聚体的形成。
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