An analysis of reaction pathways for proton tunnelling in methylamine dehydrogenase

Sara Nuñez; Gary Tresadern; Ian H. Hillier; Neil A. Burton

doi:10.1098/rstb.2006.1867

An analysis of reaction pathways for proton tunnelling in methylamine dehydrogenase

Sara Nuñez, Gary Tresadern, Ian H. Hillier, Neil A. Burton

Research output: Contribution to journal › Article › peer-review

Abstract

Computational methods have now become a valuable tool to understand the way in which enzymes catalyse chemical reactions and to aid the interpretation of a diverse set of experimental data. This study focuses on the influence of the condensed-phase environment structure on proton transfer mechanisms, with an aim to understand how C-H bond cleavage is mediated in enzymatic reactions. We shall use a combination of molecular simulation, ab initio or semi-empirical quantum chemistry and semi-classical multidimensional tunnelling methods to consider the primary kinetic isotope effects of the enzyme methylamine dehydrogenase (MADH), with reference to an analogous application to triosephosphate isomerase. Analysis of potentially reactive conformations of the system, and correlation with experimental isotope effects, have highlighted that a quantum tunnelling mechanism in MADH may be modulated by specific amino acid residues, such as Asp428, Thr474 and Asp384. © 2006 The Royal Society.

Original language	English
Pages (from-to)	1387-1398
Number of pages	11
Journal	Philosophical Transactions of the Royal Society B: Biological Sciences
Volume	361
Issue number	1472
DOIs	https://doi.org/10.1098/rstb.2006.1867
Publication status	Published - 29 Aug 2006

Keywords

Enzyme catalysis
Kinetic isotope effects
Methylamine dehydrogenase
Proton tunnelling
Quantum mechanical and molecular mechanical computational methods
Triosephosphate isomerase

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10.1098/rstb.2006.1867

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title = "An analysis of reaction pathways for proton tunnelling in methylamine dehydrogenase",

abstract = "Computational methods have now become a valuable tool to understand the way in which enzymes catalyse chemical reactions and to aid the interpretation of a diverse set of experimental data. This study focuses on the influence of the condensed-phase environment structure on proton transfer mechanisms, with an aim to understand how C-H bond cleavage is mediated in enzymatic reactions. We shall use a combination of molecular simulation, ab initio or semi-empirical quantum chemistry and semi-classical multidimensional tunnelling methods to consider the primary kinetic isotope effects of the enzyme methylamine dehydrogenase (MADH), with reference to an analogous application to triosephosphate isomerase. Analysis of potentially reactive conformations of the system, and correlation with experimental isotope effects, have highlighted that a quantum tunnelling mechanism in MADH may be modulated by specific amino acid residues, such as Asp428, Thr474 and Asp384. {\textcopyright} 2006 The Royal Society.",

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T1 - An analysis of reaction pathways for proton tunnelling in methylamine dehydrogenase

AU - Nuñez, Sara

AU - Tresadern, Gary

AU - Hillier, Ian H.

AU - Burton, Neil A.

PY - 2006/8/29

Y1 - 2006/8/29

N2 - Computational methods have now become a valuable tool to understand the way in which enzymes catalyse chemical reactions and to aid the interpretation of a diverse set of experimental data. This study focuses on the influence of the condensed-phase environment structure on proton transfer mechanisms, with an aim to understand how C-H bond cleavage is mediated in enzymatic reactions. We shall use a combination of molecular simulation, ab initio or semi-empirical quantum chemistry and semi-classical multidimensional tunnelling methods to consider the primary kinetic isotope effects of the enzyme methylamine dehydrogenase (MADH), with reference to an analogous application to triosephosphate isomerase. Analysis of potentially reactive conformations of the system, and correlation with experimental isotope effects, have highlighted that a quantum tunnelling mechanism in MADH may be modulated by specific amino acid residues, such as Asp428, Thr474 and Asp384. © 2006 The Royal Society.

AB - Computational methods have now become a valuable tool to understand the way in which enzymes catalyse chemical reactions and to aid the interpretation of a diverse set of experimental data. This study focuses on the influence of the condensed-phase environment structure on proton transfer mechanisms, with an aim to understand how C-H bond cleavage is mediated in enzymatic reactions. We shall use a combination of molecular simulation, ab initio or semi-empirical quantum chemistry and semi-classical multidimensional tunnelling methods to consider the primary kinetic isotope effects of the enzyme methylamine dehydrogenase (MADH), with reference to an analogous application to triosephosphate isomerase. Analysis of potentially reactive conformations of the system, and correlation with experimental isotope effects, have highlighted that a quantum tunnelling mechanism in MADH may be modulated by specific amino acid residues, such as Asp428, Thr474 and Asp384. © 2006 The Royal Society.

KW - Enzyme catalysis

KW - Kinetic isotope effects

KW - Methylamine dehydrogenase

KW - Proton tunnelling

KW - Quantum mechanical and molecular mechanical computational methods

KW - Triosephosphate isomerase

U2 - 10.1098/rstb.2006.1867

DO - 10.1098/rstb.2006.1867

M3 - Article

SN - 0962-8436

VL - 361

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JO - Philosophical Transactions of the Royal Society B: Biological Sciences

JF - Philosophical Transactions of the Royal Society B: Biological Sciences

IS - 1472

ER -

An analysis of reaction pathways for proton tunnelling in methylamine dehydrogenase

Abstract

Keywords

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