Coarse Master Equations for Peptide Folding Dynamics

We construct coarse master equations for peptide folding dynamics from atomistic molecular dynamics simulations. A maximum-likelihood propagator-based method allows us to extract accurate rates for the transitions between the different conformational states of the small helix-forming peptide Ala5. A...

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Bibliographic Details
Published in:The journal of physical chemistry. B 2008-05, Vol.112 (19), p.6057-6069
Main Authors: Buchete, Nicolae-Viorel, Hummer, Gerhard
Format: Article
Language:English
Subjects:
Computer Simulation
Models, Molecular
Peptides - chemistry
Protein Folding
Protein Structure, Tertiary
Temperature
Time Factors
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Summary:We construct coarse master equations for peptide folding dynamics from atomistic molecular dynamics simulations. A maximum-likelihood propagator-based method allows us to extract accurate rates for the transitions between the different conformational states of the small helix-forming peptide Ala5. Assigning the conformational states by using transition paths instead of instantaneous molecular coordinates suppresses the effects of fast non-Markovian dynamics. The resulting master equations are validated by comparing their analytical correlation functions with those obtained directly from the molecular dynamics simulations. We find that the master equations properly capture the character and relaxation times of the entire spectrum of conformational relaxation processes. By using the eigenvectors of the transition rate matrix, we are able to systematically coarse-grain the system. We find that a two-state description, with a folded and an unfolded state, roughly captures the slow conformational dynamics. A four-state model, with two folded and two unfolded states, accurately recovers the three slowest relaxation process with time scales between 1.5 and 7 ns. The master equation models not only give access to the slow conformational dynamics but also shed light on the molecular mechanisms of the helix−coil transition.
ISSN:1520-6106
1520-5207
DOI:10.1021/jp0761665