构象选择是配体结合的主要机制。

Conformational selection is a dominant mechanism of ligand binding.

机构信息

Edward A. Doisy Department of Biochemistry and Molecular Biology, Saint Louis University School of Medicine, Missouri 63104, United States.

出版信息

Biochemistry. 2013 Aug 27;52(34):5723-9. doi: 10.1021/bi400929b. Epub 2013 Aug 15.

DOI:10.1021/bi400929b

PMID:23947609

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3791601/

Abstract

Molecular recognition in biological macromolecules is achieved by binding interactions coupled to conformational transitions that precede or follow the binding step, two limiting mechanisms known as conformational selection and induced fit, respectively. Sorting out the contribution of these mechanisms to any binding interaction remains a challenging task of general interest in biochemistry. Here we show that conformational selection is associated with a vast repertoire of kinetic behaviors, can never be disproved a priori as a mechanism of ligand binding, and is sufficient to explain the relaxation kinetics documented experimentally for a large number of systems. On the other hand, induced fit features a narrow spectrum of kinetic behaviors and can be disproved in many cases in which conformational selection offers the only possible explanation. This conclusion offers a paradigm shift in the analysis of relaxation kinetics, with conformational selection acquiring preeminence as a mechanism of ligand binding. The dominant role of conformational selection supports the emerging structural view of the macromolecule as a conformational ensemble from which the ligand selects the initial optimal fit to produce a biological response.

摘要

生物大分子中的分子识别是通过结合相互作用来实现的，这些结合相互作用与结合步骤之前或之后的构象转变相关联，这两种限制机制分别称为构象选择和诱导契合。区分这些机制对任何结合相互作用的贡献仍然是生物化学中一个具有普遍意义的挑战性任务。在这里，我们表明构象选择与广泛的动力学行为相关联，作为配体结合的机制，不能先验地被否定，并且足以解释大量系统中实验记录的弛豫动力学。另一方面，诱导契合具有狭窄的动力学行为谱，在构象选择提供唯一可能的解释的许多情况下，可以被否定。这一结论在弛豫动力学分析中带来了范式转变，构象选择作为配体结合的机制获得了优势。构象选择的主导作用支持了大分子作为构象集合的新兴结构观点，配体从该集合中选择初始最佳契合以产生生物学响应。

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