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

Elad Noor; Avi Flamholz; Wolfram Liebermeister; Arren Bar-Even; Ron Milo

doi:10.1016/j.febslet.2013.07.028

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

Elad Noor, Avi Flamholz, Wolfram Liebermeister, Arren Bar-Even, Ron Milo

Department of Plant and Environmental Sciences

Weizmann Institute of Science

Research output: Contribution to journal › Review article › peer-review

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.

Original language	English
Pages (from-to)	2772-2777
Number of pages	6
Journal	FEBS Letters
Volume	587
Issue number	17
DOIs	https://doi.org/10.1016/j.febslet.2013.07.028
State	Published - 2 Sep 2013

Keywords

Enzyme kinetics
Michaelis-Menten
Reversible reaction
Thermodynamics

All Science Journal Classification (ASJC) codes

Genetics
Molecular Biology
Biophysics
Structural Biology
Biochemistry
Cell Biology

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title = "A note on the kinetics of enzyme action: A decomposition that highlights thermodynamic effects",

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.",

keywords = "Enzyme kinetics, Michaelis-Menten, Reversible reaction, Thermodynamics",

author = "Elad Noor and Avi Flamholz and Wolfram Liebermeister and Arren Bar-Even and Ron Milo",

note = "European Research Council [260392]; Israel Science Foundation [750/09]; Helmsley Charitable Foundation; Larson Charitable Foundation; Estate of David Arthur Barton; Anthony Stalbow Charitable Trust; Stella Gelerman (Canada); German Research Foundation [Ll 1676/2-1]; Azrieli FoundationThis work was funded by the European Research Council (260392 - Project SYMPAC); Israel Science Foundation (Grant 750/09); Helmsley Charitable Foundation; the Larson Charitable Foundation; Estate of David Arthur Barton; Anthony Stalbow Charitable Trust, and Stella Gelerman (Canada); and the German Research Foundation (Ll 1676/2-1). E.N. is grateful to the Azrieli Foundation for the award of an Azrieli Fellowship. R. M. is the incumbent of the Anna and Maurice Boukstein Career Development Chair.",

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doi = "10.1016/j.febslet.2013.07.028",

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AU - Noor, Elad

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AU - Bar-Even, Arren

AU - Milo, Ron

N1 - European Research Council [260392]; Israel Science Foundation [750/09]; Helmsley Charitable Foundation; Larson Charitable Foundation; Estate of David Arthur Barton; Anthony Stalbow Charitable Trust; Stella Gelerman (Canada); German Research Foundation [Ll 1676/2-1]; Azrieli FoundationThis work was funded by the European Research Council (260392 - Project SYMPAC); Israel Science Foundation (Grant 750/09); Helmsley Charitable Foundation; the Larson Charitable Foundation; Estate of David Arthur Barton; Anthony Stalbow Charitable Trust, and Stella Gelerman (Canada); and the German Research Foundation (Ll 1676/2-1). E.N. is grateful to the Azrieli Foundation for the award of an Azrieli Fellowship. R. M. is the incumbent of the Anna and Maurice Boukstein Career Development Chair.

PY - 2013/9/2

Y1 - 2013/9/2

N2 - 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.

AB - 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.

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KW - Michaelis-Menten

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

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Keywords

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