Abstract
The ability to compute from first principles the infrared spectrum of a protein in solution phase representing a biological system would provide a useful connection to atomistic models of protein structure and dynamics. Indeed, such calculations are a vital complement to 2DIR experimental measurements, allowing the observed signals to be interpreted in terms of detailed structural and dynamical information. In this article, we have studied nine structurally and spectroscopically well‐characterized proteins, representing a range of structural types. We have simulated the equilibrium conformational dynamics in an explicit point charge water model. Using the resulting trajectories based on MD simulations, we have computed the one and two dimensional infrared spectra in the Amide I region, using an exciton approach, in which a local mode basis of carbonyl stretches is considered. The role of solvent in shifting the Amide I band (by 30 to 50 cm−1) is clearly evident. Similarly, the conformational dynamics contribute to the broadening of peaks in the spectrum. The inhomogeneous broadening in both the 1D and 2D spectra reflects the significant conformational diversity observed in the simulations. Through the computed 2D cross‐peak spectra, we show how different pulse schemes can provide additional information on the coupled vibrations. © 2016 The Authors. Journal of Computational Chemistry Published by Wiley Periodicals, Inc.
Highlights
Understanding the three-dimensional structure of a protein is often a challenging task but is an undertaking that can yield deep insights into biological functions, ranging from membrane signaling to catalysis to charge transfer as well as dynamic scaffolding, mechanical and electrical transduction
The Hamiltonian matrix consists of three types of element: the diagonal elements which correspond to the harmonic frequency, the off-diagonal nearest neighbor coupling (NNC) constants, and the other off-diagonal elements which describe the through-space interaction between local mode vibrations
We have investigated the sensitivity of the Amide I peaks to conformational dynamics
Summary
Understanding the three-dimensional structure of a protein is often a challenging task but is an undertaking that can yield deep insights into biological functions, ranging from membrane signaling to catalysis to charge transfer as well as dynamic scaffolding, mechanical and electrical transduction. Approaches such as X-ray crystallography and nuclear magnetic resonance can provide atomistic detail, while optical spectroscopy in the ultra-violet and infrared (IR) regions can provide useful qualitative information. Bands near 1663 cm have been associated with 310 helices,[3,7,8] while b-sheets exhibit bands between 1620 and 1640 cm as well as 1690 and 1695 cm21.[3,4,5,6,7]
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