APS March Meeting 2015
Volume 60, Number 1
Monday–Friday, March 2–6, 2015;
San Antonio, Texas
Session J46: Invited Session: Physics of Proteins: Integrating Computation with Experiment
2:30 PM–5:30 PM,
Tuesday, March 3, 2015
Room: 217A
Sponsoring
Unit:
DBIO
Chair: Wouter Hoff, Oklahoma State University
Abstract ID: BAPS.2015.MAR.J46.1
Abstract: J46.00001 : Protein Folding Transition Paths: Single Molecule Experiments, Theory and Simulations
2:30 PM–3:06 PM
Preview Abstract
Abstract
Author:
William Eaton
(Laboratory of Chemical Physics, NIDDK, NIH, Bethesda, MD)
The transition-path is the tiny fraction of an equilibrium, single-molecule
trajectory when the transition over a free-energy barrier occurs between two
states. In the case of protein folding, the distribution of transition paths
contains all of the mechanistic information on how a protein folds and
unfolds. Transition path distributions can now be predicted for fast folding
proteins by all-atom molecular dynamics simulations and by an Ising-like
theoretical model [1,2]. Experimental information on transition paths should
provide the most demanding test of both simulations and theoretical models.
However, transition-paths for barrier crossings have never been observed
experimentally for any molecular system in solution. Because it is a single
molecule property, even determining the average transition-path time is
challenging. In this presentation, I will discuss how we use measurements of
Foerster resonance energy transfer in single molecule fluorescence
experiments and a photon-by-photon analysis to measure average transition
path times for proteins of different topology and folding rate coefficients
using the Gopich/Szabo maximum likelihood method [3.4]. These results, which
are surprisingly interesting, are just the first, but important, steps
toward measuring intra-molecular distances during individual transition
paths.
[1] Best, R.B.; Hummer, G.; Eaton. W.A. Native contacts determine protein
folding mechanisms in atomistic simulations.'' Proc. Natl. Acad. Sci. USA
2013, 110, 17874; [2] Henry, E.R.; Best, R.B.; Eaton, W.A. Comparing a
simple theoretical model for protein folding with all-atom molecular
dynamics simulations. Proc. Natl. Acad. Sci. USA 2013,110, 17880; [3] Chung,
H.S.; McHale, K.; Louis, J.M.; Eaton, W.A. Single-molecule fluorescence
experiments determine protein folding transition path times. Science 2012,
335, 981; [4] Chung, H.S.; Eaton, W.A.Single molecule fluorescence probes
dynamics of barrier crossing. Nature 2013, 502, 685.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2015.MAR.J46.1