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经合理设计的整合素β3突变体稳定于高亲和力构象。

Rationally designed integrin beta3 mutants stabilized in the high affinity conformation.

作者信息

Luo Bing-Hao, Karanicolas John, Harmacek Laura D, Baker David, Springer Timothy A

机构信息

Immune Disease Institute and Department of Pathology, Harvard Medical School, Boston, Massachusetts 02115, USA.

出版信息

J Biol Chem. 2009 Feb 6;284(6):3917-24. doi: 10.1074/jbc.M806312200. Epub 2008 Nov 19.

DOI:10.1074/jbc.M806312200
PMID:19019827
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2635054/
Abstract

Integrins are important cell surface receptors that transmit bidirectional signals across the membrane. It has been shown that a conformational change of the integrin beta-subunit headpiece (i.e. the beta I domain and the hybrid domain) plays a critical role in regulating integrin ligand binding affinity and function. Previous studies have used coarse methods (a glycan wedge, mutations in transmembrane contacts) to force the beta-subunit into either the open or closed conformation. Here, we demonstrate a detailed understanding of this conformational change by applying computational design techniques to select five amino acid side chains that play an important role in the energetic balance between the open and closed conformations of alphaIIbbeta3. Eight single-point mutants were designed at these sites, of which five bound ligands much better than wild type. Further, these mutants were found to be in a more extended conformation than wild type, suggesting that the conformational change at the ligand binding headpiece was propagated to the legs of the integrin. This detailed understanding of the conformational change will assist in the development of allosteric drugs that either stabilize or destabilize specific integrin conformations without occluding the ligand-binding site.

摘要

整合素是重要的细胞表面受体,可跨膜传递双向信号。研究表明,整合素β亚基头部(即βI结构域和杂合结构域)的构象变化在调节整合素配体结合亲和力和功能方面起着关键作用。先前的研究使用了粗略的方法(聚糖楔、跨膜接触处的突变)来迫使β亚基进入开放或关闭构象。在这里,我们通过应用计算设计技术来选择五个在αIIbβ3开放和关闭构象之间的能量平衡中起重要作用的氨基酸侧链,从而详细了解这种构象变化。在这些位点设计了八个单点突变体,其中五个与配体的结合比野生型好得多。此外,发现这些突变体比野生型具有更伸展的构象,这表明配体结合头部的构象变化传播到了整合素的腿部。对这种构象变化的详细了解将有助于开发变构药物,这些药物可以稳定或破坏特定的整合素构象,而不会封闭配体结合位点。

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