Diffusion dynamics, moments, and distribution of first-passage time on the protein-folding energy landscape, with applications to single molecules
- 17 April 2003
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review E
- Vol. 67 (4), 041905
- https://doi.org/10.1103/physreve.67.041905
Abstract
We study the dynamics of protein folding via statistical energy-landscape theory. In particular, we concentrate on the local-connectivity case with the folding progress described by the fraction of native conformations. We found that the first passage-time (FPT) distribution undergoes a dynamic transition at a temperature below which the FPT distribution develops a power-law tail, a signature of the intermittent nonexponential kinetic phenomena for the folding dynamics. Possible applications to single-molecule dynamics experiments are discussed.Keywords
All Related Versions
This publication has 25 references indexed in Scilit:
- First-passage time distribution and non-Markovian diffusion dynamics of protein foldingThe Journal of Chemical Physics, 2003
- Analyzing single molecule trajectories on complex energy landscapes using replica correlation functionsChemical Physics, 1999
- Intermittency of activated events in single molecules: The reaction diffusion descriptionThe Journal of Chemical Physics, 1999
- High-Resolution Optical Spectroscopy of Single Molecules in SolidsAccounts of Chemical Research, 1996
- Statistics of Kinetic Pathways on Biased Rough Energy Landscapes with Applications to Protein FoldingPhysical Review Letters, 1996
- Intermittency of Single Molecule Reaction Dynamics in Fluctuating EnvironmentsPhysical Review Letters, 1995
- Funnels, pathways, and the energy landscape of protein folding: A synthesisProteins-Structure Function and Bioinformatics, 1995
- Free energy landscape for protein folding kinetics: Intermediates, traps, and multiple pathways in theory and lattice model simulationsThe Journal of Chemical Physics, 1994
- Transition states and folding dynamics of proteins and heteropolymersThe Journal of Chemical Physics, 1994
- Intermediates and barrier crossing in a random energy model (with applications to protein folding)The Journal of Physical Chemistry, 1989