Quantum chemical calculations of tryptophan → heme electron and excitation energy transfer rates in myoglobin.

Christian J Suess,Jonathan D Hirst,Nicholas A Besley

doi:10.1002/jcc.24793

Christian J Suess, Jonathan D Hirst + Show 1 more

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https://doi.org/10.1002/jcc.24793

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Journal: Journal of computational chemistry	Publication Date: Apr 1, 2017
Citations: 16	License type: CC BY 4.0

Affiliation: University of Nottingham

Abstract

The development of optical multidimensional spectroscopic techniques has opened up new possibilities for the study of biological processes. Recently, ultrafast two‐dimensional ultraviolet spectroscopy experiments have determined the rates of tryptophan → heme electron transfer and excitation energy transfer for the two tryptophan residues in myoglobin (Consani et al., Science, 2013, 339, 1586). Here, we show that accurate prediction of these rates can be achieved using Marcus theory in conjunction with time‐dependent density functional theory. Key intermediate residues between the donor and acceptor are identified, and in particular the residues Val68 and Ile75 play a critical role in calculations of the electron coupling matrix elements. Our calculations demonstrate how small changes in structure can have a large effect on the rates, and show that the different rates of electron transfer are dictated by the distance between the heme and tryptophan residues, while for excitation energy transfer the orientation of the tryptophan residues relative to the heme is important. © 2017 The Authors. Journal of Computational Chemistry Published by Wiley Periodicals, Inc.

Highlights

Electron transfer (ET) and the transfer of excitation energy are fundamental processes in biological systems
Ultrafast two-dimensional ultraviolet spectroscopy experiments have determined the rates of tryptophan ! heme electron transfer and excitation energy transfer for the two tryptophan residues in myoglobin (Consani et al, Science, 2013, 339, 1586)
Our calculations demonstrate how small changes in structure can have a large effect on the rates, and show that the different rates of electron transfer are dictated by the distance between the heme and tryptophan residues, while for excitation energy transfer the orientation of the tryptophan residues relative to the heme is important

Summary

Introduction

Electron transfer (ET) and the transfer of excitation energy are fundamental processes in biological systems. The efficient and controlled movement of electrons is one of the primary regulation mechanisms in biology and critical for the existence of living organisms,[1,2] and excitation energy transfer (EET) is important in light harvesting systems.[3] This has motivated the development of experimental and computational approaches to characterize the mechanisms of ET and EET processes. These studies are challenging due to the fast time-scale of ET and EET and the complexity of biological systems. An oxygen carrier in muscle tissue, comprises a single polypeptide chain of 153 amino acids arranged in eight a-helices with an iron porphyrin active site and has been described as the hydrogen atom of biology and a paradigm of complexity.[6]

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