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酶如何利用极不利的质子转移反应。

How enzymes harness highly unfavorable proton transfer reactions.

机构信息

Chemistry Department, Willamette University, Salem, Oregon, USA.

出版信息

Protein Sci. 2021 Apr;30(4):735-744. doi: 10.1002/pro.4037. Epub 2021 Feb 23.

DOI:10.1002/pro.4037
PMID:33554401
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7980525/
Abstract

Acid-base reactions that are exceedingly unfavorable under standard conditions can be catalytically important at enzyme active sites. For example, in triose phosphate isomerase, a glutamate side chain (nominal pK ≈ 4 in solution) can in fact deprotonate a CH group that is vicinal to a carbonyl (pK ≈ 18 in solution). This is true because of three distinct interactions: (a) ground state pK shifts due to environment polarity and electrostatics; (b) dramatic increases in effective molarity due to optimization of proximity and orientation; and (c) transition state pK shifts due to binding interactions and the formation of strong low barrier hydrogen bonds. In this report, we review the literature showing that the sum of these three effects supplies more than enough free energy to push forward proton transfer reactions that under standard conditions are exceedingly nonspontaneous and slow.

摘要

在标准条件下非常不利的酸碱反应在酶活性部位可能具有催化重要性。例如,在磷酸丙糖异构酶中,谷氨酸侧链(在溶液中的名义 pK ≈ 4)实际上可以使与羰基相邻的 CH 基团去质子化(在溶液中的 pK ≈ 18)。这是因为有三个不同的相互作用:(a)由于环境极性和静电作用,基态 pK 发生变化;(b)由于优化了临近性和取向性,有效摩尔浓度显著增加;(c)由于结合相互作用和形成强低势垒氢键,过渡态 pK 发生变化。在本报告中,我们回顾了文献,表明这三个效应的总和提供了足够的自由能,足以推动质子转移反应向前进行,而在标准条件下,这些反应是非常非自发和缓慢的。

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