Protein Folding Funnels: A Kinetic Approach to the Sequence-Structure Relationship

A lattice model of protein folding is developed to distinguish between amino acid sequences that do and do not fold into unique conformations. Although Monte Carlo simulations provide insights into the long-time processes involved in protein folding, these simulations cannot systematically chart the...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 1992-09, Vol.89 (18), p.8721-8725
Main Authors: Leopold, Peter E., Montal, Mauricio, Onuchic, Jose Nelson
Format: Article
Language:English
Subjects:
Algorithms
Amino Acid Sequence
Amino acids
Biological and medical sciences
Biology
Conformational dynamics in molecular biology
Cubes
Energy
Fundamental and applied biological sciences. Psychology
funnels
Geometric funnels
Grants
Kinetics
Molecular biophysics
Molecular Sequence Data
Peptides - chemistry
Physics
Protein Conformation
Protein folding
Proteins
Proteins - chemistry
Reactants
Solubility
Structure-Activity Relationship
Thermodynamics
Trajectories
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Summary:A lattice model of protein folding is developed to distinguish between amino acid sequences that do and do not fold into unique conformations. Although Monte Carlo simulations provide insights into the long-time processes involved in protein folding, these simulations cannot systematically chart the conformational energy surface that enables folding. By assuming that protein folding occurs after chain collapse, a kinetic map of important pathways on this surface is constructed through the use of an analytical theory of probability flow. Convergent kinetic pathways, or "folding funnels," guide folding to a unique, stable, native conformation. Solution of the probability flow equations is facilitated by limiting treatment to diffusion between geometrically similar collapsed conformers. Similarity is measured in terms of a reconfigurational distance. Two specific amino acid sequences are deemed foldable and nonfoldable because one gives rise to a single, large folding funnel leading to a native conformation and the other has multiple pathways leading to several stable conformers. Monte Carlo simulations demonstrate that folding funnel calculations accurately predict the fact of and the pathways involved in folding-specific sequences. The existence of folding funnels for specific sequences suggests that geometrically related families of stable, collapsed conformers fulfill kinetic and thermodynamic requirements of protein folding.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.89.18.8721