能量考量表明,低势垒氢键相较于普通氢键并无催化优势。
Energy considerations show that low-barrier hydrogen bonds do not offer a catalytic advantage over ordinary hydrogen bonds.
作者信息
Warshel A, Papazyan A
机构信息
Department of Chemistry, University of Southern California, Los Angeles 90089-1062, USA.
出版信息
Proc Natl Acad Sci U S A. 1996 Nov 26;93(24):13665-70. doi: 10.1073/pnas.93.24.13665.
Abstract
Low-barrier hydrogen bonds have recently been proposed as a major factor in enzyme catalysis. Here we evaluate the feasibility of transition state (TS) stabilization by low-barrier hydrogen bonds in enzymes. Our analysis focuses on the facts that (i) a low-barrier hydrogen bond is less stable than a regular hydrogen bond in water, (ii) TSs are more stable in the enzyme active sites than in water, and (iii) a nonpolar active site would destabilize the TS relative to its energy in water. Combining these points and other experimental and theoretical facts in a physically consistent frame-work shows that a low-barrier hydrogen bond cannot stabilize the TS more than an ordinary hydrogen bond. The reason for the large catalytic effect of active site hydrogen bonds is that their formation entails a lower reorganization energy than their solution counterparts, due to the preorganized enzyme environment.
摘要
低势垒氢键最近被认为是酶催化的一个主要因素。在此,我们评估酶中低势垒氢键对过渡态(TS)稳定作用的可行性。我们的分析聚焦于以下事实:(i)在水中,低势垒氢键比普通氢键更不稳定;(ii)与水中相比,过渡态在酶活性位点更稳定;(iii)相对于其在水中的能量,非极性活性位点会使过渡态不稳定。在一个物理上一致的框架中综合这些要点以及其他实验和理论事实表明,低势垒氢键对过渡态的稳定作用不会超过普通氢键。活性位点氢键具有巨大催化作用的原因是,由于酶环境的预先组织,其形成所需的重组能比在溶液中的对应物更低。
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