posted on 2015-06-10, 00:00authored byAnna Jean Wirth, Yanxin Liu, Maxim B. Prigozhin, Klaus Schulten, Martin Gruebele
The
unimolecular folding reaction of small proteins is now amenable
to a very direct mechanistic comparison between experiment and simulation.
We present such a comparison of microsecond pressure and temperature
jump refolding kinetics of the engineered WW domain FiP35, a model
system for β-sheet folding. Both perturbations produce experimentally
a faster and a slower kinetic phase, and the “slow”
microsecond phase is activated. The fast phase shows differences between
perturbation methods and is closer to the downhill limit by temperature
jump, but closer to the transiently populated intermediate limit by
pressure jump. These observations make more demands on simulations
of the folding process than just a rough comparison of time scales.
To complement experiments, we carried out several pressure jump and
temperature jump all-atom molecular dynamics trajectories in explicit
solvent, where FiP35 folded in five of the six simulations. We analyzed
our pressure jump simulations by kinetic modeling and found that the
pressure jump experiments and MD simulations are most consistent with
a 4-state kinetic mechanism. Together, our experimental and computational
data highlight FiP35’s position at the boundary where activated
intermediates and downhill folding meet, and we show that this model
protein is an excellent candidate for further pressure jump molecular
dynamics studies to compare experiment and modeling at the folding
mechanism level.