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通过控制蛋白质-配体复合物构象来设计相互作用:调整精氨酸-芳烃相互作用几何结构以增强蛋白质-配体静电相互作用。

Designing interactions by control of protein-ligand complex conformation: tuning arginine-arene interaction geometry for enhanced electrostatic protein-ligand interactions.

作者信息

Noresson A-L, Aurelius O, Öberg C T, Engström O, Sundin A P, Håkansson M, Stenström O, Akke M, Logan D T, Leffler H, Nilsson U J

机构信息

Centre for Analysis and Synthesis , Department of Chemistry , Lund University , Box 124 , SE-221 00 Lund , Sweden . Email:

Section for Biochemistry and Structural Biology , Center for Molecular Protein Science , Department of Chemistry , Lund University , Box 124 , SE-221 00 Lund , Sweden.

出版信息

Chem Sci. 2017 Dec 4;9(4):1014-1021. doi: 10.1039/c7sc04749e. eCollection 2018 Jan 28.

DOI:10.1039/c7sc04749e
PMID:29675148
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5883865/
Abstract

We investigated galectin-3 binding to 3-benzamido-2--sulfo-galactoside and -thiodigalactoside ligands using a combination of site-specific mutagenesis, X-ray crystallography, computational approaches, and binding thermodynamics measurements. The results reveal a conformational variability in a surface-exposed arginine (R144) side chain in response to different aromatic C3-substituents of bound galactoside-based ligands. Fluorinated C3-benzamido substituents induced a shift in the side-chain conformation of R144 to allow for an entropically favored electrostatic interaction between its guanidine group and the 2--sulfate of the ligand. By contrast, binding of ligands with non-fluorinated substituents did not trigger a conformational change of R144. Hence, a sulfate-arginine electrostatic interaction can be tuned by the choice of ligand C3-benzamido structures to favor specific interaction modes and geometries. These results have important general implications for ligand design, as the proper choice of arginine-aromatic interacting partners opens up for ligand-controlled protein conformation that in turn may be systematically exploited in ligand design.

摘要

我们结合位点特异性诱变、X射线晶体学、计算方法和结合热力学测量,研究了半乳糖凝集素-3与3-苯甲酰胺基-2-磺酸基半乳糖苷和硫代二半乳糖苷配体的结合情况。结果显示,结合的基于半乳糖苷的配体的不同芳香族C3取代基会使表面暴露的精氨酸(R144)侧链发生构象变化。氟化的C3-苯甲酰胺取代基导致R144侧链构象发生转变,使其胍基与配体的2-硫酸盐之间形成熵有利的静电相互作用。相比之下,具有非氟化取代基的配体的结合不会引发R144的构象变化。因此,可以通过选择配体C3-苯甲酰胺结构来调节硫酸盐-精氨酸静电相互作用,以利于特定的相互作用模式和几何形状。这些结果对配体设计具有重要的普遍意义,因为精氨酸-芳香族相互作用伙伴的恰当选择为配体控制的蛋白质构象开辟了道路,而这反过来又可在配体设计中得到系统利用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/50a9/5883865/c5f0f25486cf/c7sc04749e-f6.jpg
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