关于酶促反应动力学的注释：强调热力学效应的分解。

A note on the kinetics of enzyme action: a decomposition that highlights thermodynamic effects.

机构信息

Department of Plant Sciences, The Weizmann Institute of Science, Rehovot 76100, Israel.

出版信息

FEBS Lett. 2013 Sep 2;587(17):2772-7. doi: 10.1016/j.febslet.2013.07.028. Epub 2013 Jul 23.

DOI:10.1016/j.febslet.2013.07.028

PMID:23892083

Abstract

Michaelis and Menten's mechanism for enzymatic catalysis is remarkable both in its simplicity and its wide applicability. The extension for reversible processes, as done by Haldane, makes it even more relevant as most enzymes catalyze reactions that are reversible in nature and carry in vivo flux in both directions. Here, we decompose the reversible Michaelis-Menten equation into three terms, each with a clear physical meaning: catalytic capacity, substrate saturation and thermodynamic driving force. This decomposition facilitates a better understanding of enzyme kinetics and highlights the relationship between thermodynamics and kinetics, a relationship which is often neglected. We further demonstrate how our separable rate law can be understood from different points of view, shedding light on factors shaping enzyme catalysis.

摘要

米氏酶催化机制以其简单性和广泛适用性而著称。Haldane 对可逆过程的扩展使其更具相关性，因为大多数酶催化的反应本质上是可逆的，并且在两个方向上都有体内通量。在这里，我们将可逆的米氏方程分解为三个具有明确物理意义的项：催化能力、底物饱和度和热力学驱动力。这种分解有助于更好地理解酶动力学，并强调了热力学和动力学之间的关系，而这种关系经常被忽视。我们进一步展示了我们可分离的速率定律如何从不同的角度来理解，揭示了影响酶催化的因素。

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关于酶促反应动力学的注释：强调热力学效应的分解。

A note on the kinetics of enzyme action: a decomposition that highlights thermodynamic effects.

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