Abstract
The ensemble folding of two 21-residue alpha-helical peptides has been studied using all-atom simulations under several variants of the AMBER potential in explicit solvent using a global distributed computing network. Our extensive sampling, orders of magnitude greater than the experimental folding time, results in complete convergence to ensemble equilibrium. This allows for a quantitative assessment of these potentials, including a new variant of the AMBER-99 force field, denoted AMBER-99 phi, which shows improved agreement with experimental kinetic and thermodynamic measurements. From bulk analysis of the simulated AMBER-99 phi equilibrium, we find that the folding landscape is pseudo-two-state, with complexity arising from the broad, shallow character of the "native" and "unfolded" regions of the phase space. Each of these macrostates allows for configurational diffusion among a diverse ensemble of conformational microstates with greatly varying helical content and molecular size. Indeed, the observed structural dynamics are better represented as a conformational diffusion than as a simple exponential process, and equilibrium transition rates spanning several orders of magnitude are reported. After multiple nucleation steps, on average, helix formation proceeds via a kinetic "alignment" phase in which two or more short, low-entropy helical segments form a more ideal, single-helix structure.
Keywords
ChemistryMolecular dynamicsKinetic energyProtein foldingForce field (fiction)ThermodynamicsPhase transitionNucleationStatistical physicsChemical physicsReaction coordinateConformational entropyCrystallographyMoleculeComputational chemistryPhysicsClassical mechanics
MeSH Terms
AlgorithmsBiophysicsCluster AnalysisComputer SimulationDiffusionHot TemperatureKineticsMarkov ChainsModelsMolecularModelsStatisticalMolecular ConformationPeptidesPolymersProtein FoldingProtein StructureSecondarySoftwareTemperatureThermodynamicsTime Factors
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Publication Info
- Year
- 2005
- Type
- article
- Volume
- 88
- Issue
- 4
- Pages
- 2472-2493
- Citations
- 643
- Access
- Closed
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Cite This
Eric J. Sorin,
Vijay S. Pande
(2005).
Exploring the Helix-Coil Transition via All-Atom Equilibrium Ensemble Simulations.
Biophysical Journal
, 88
(4)
, 2472-2493.
https://doi.org/10.1529/biophysj.104.051938
Identifiers
- DOI
- 10.1529/biophysj.104.051938
- PMID
- 15665128
- PMCID
- PMC1305346