JPCB Abstract
Abstract
Ramachandran surfaces for the alanine di- and tripeptides in gas
phase and solution are mapped out using the recently introduced
adiabatic free energy dynamics (AFED) approach introduced by
Rosso, et al. [J. Chem. Phys. 116, 4389 (2002)]
as applied to the CHARMM22 force field.
It is shown that complete surfaces can be mapped out with an
order of magnitude greater
efficiency with the AFED approach than they can using the popular
umbrella sampling method. In the alanine dipeptide, it is found,
in agreement with numerous other studies using the CHARMM22
force field, that the lowest free energy structure is the
extended beta conformation, (phi,psi) = (-81,81), while in solution, the extended beta, (phi,psi) = (-81,153)
and right-handed alpha-helical, (phi,psi)=(-81,63) conformations are
nearly isoenergetic. In solution, a secondary minimum
at (phi,psi) = (63,-81), corresponding to a
C7ax conformation, occurs approximately 2.3 kcal/mol
above the global free energy minimum.
The alanine tripeptide, a system that has received considerably
less attention in the literature, is found to exhibit a similar
structure to the alanine dipeptide with the extended beta
conformation being the free energy minimum in the gas phase and
the $\beta$ and right-handed alpha-helical conformations being isoenergetic
in solution. These studies indicate that the AFED method can be a powerful
tool for studying multidimensional free energy surfaces in
complex systems.