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Literature DB >> 24128764

Comparing a simple theoretical model for protein folding with all-atom molecular dynamics simulations.

Eric R Henry¹, Robert B Best, William A Eaton.

Abstract

Advances in computing have enabled microsecond all-atom molecular dynamics trajectories of protein folding that can be used to compare with and test critical assumptions of theoretical models. We show that recent simulations by the Shaw group (10, 11, 14, 15) are consistent with a key assumption of an Ising-like theoretical model that native structure grows in only a few regions of the amino acid sequence as folding progresses. The distribution of mechanisms predicted by simulating the master equation of this native-centric model for the benchmark villin subdomain, with only two adjustable thermodynamic parameters and one temperature-dependent kinetic parameter, is remarkably similar to the distribution in the molecular dynamics trajectories.

Keywords: Ising-like model; funneled energy landscape; statistical mechanics; stochastic kinetics

Mesh：

Year: 2013 PMID： 24128764 PMCID： PMC3816406 DOI： 10.1073/pnas.1317105110

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

54 in total

Comparing a simple theoretical model for protein folding with all-atom molecular dynamics simulations.

1. A simple model for calculating the kinetics of protein folding from three-dimensional structures.

2. A theoretical search for folding/unfolding nuclei in three-dimensional protein structures.

3. Prediction of protein-folding mechanisms from free-energy landscapes derived from native structures.

4. Absolute comparison of simulated and experimental protein-folding dynamics.

5. From transition paths to transition states and rate coefficients.

6. Folding-based molecular simulations reveal mechanisms of the rotary motor F1-ATPase.

7. Levinthal's paradox.

Review 8. Theory of protein folding: the energy landscape perspective.

9. Funnels, pathways, and the energy landscape of protein folding: a synthesis.

10. Spin glasses and the statistical mechanics of protein folding.

1. Fold and flexibility: what can proteins' mechanical properties tell us about their folding nucleus?

2. Sequence, structure, and cooperativity in folding of elementary protein structural motifs.

3. Disordered proteins follow diverse transition paths as they fold and bind to a partner.

4. Native contacts determine protein folding mechanisms in atomistic simulations.

Review 5. Protein folding transition path times from single molecule FRET.

6. Folding pathway of a multidomain protein depends on its topology of domain connectivity.

7. A simple theoretical model goes a long way in explaining complex behavior in protein folding.

8. Measuring the average shape of transition paths during the folding of a single biological molecule.

9. Heterogeneity in the Folding of Villin Headpiece Subdomain HP36.

10. Peptide and Protein Structure Prediction with a Simplified Continuum Solvent Model.