2009 APS March Meeting
Volume 54, Number 1
Monday–Friday, March 16–20, 2009;
Pittsburgh, Pennsylvania
Session V6: Recent Advances in Biomolecular Simulations
8:00 AM–11:00 AM,
Thursday, March 19, 2009
Room: 406
Sponsoring
Unit:
DCOMP
Chair: Jerry Bernholc, North Carolina State University
Abstract ID: BAPS.2009.MAR.V6.3
Abstract: V6.00003 : Urea's action on the hydrophobic interaction in physical and biophysical systems
9:12 AM–9:48 AM
Preview Abstract
Abstract
Author:
B.J. Berne
(Columbia University)
For more than a century, urea has been commonly used as an agent for
denaturing proteins. However, the mechanism behind its denaturing
power
is still not well understood. The mechanism of denaturation of
proteins
by urea is explored using
all-atom microseconds molecular dynamics simulations of hen lysozyme
generated on BlueGene/L. Accumulation of urea around lysozyme
shows that
water molecules are expelled from the first hydration shell of the
protein. We observe a two stage penetration of the protein, with
urea
penetrating the hydrophobic core before water, forming a ``dry
globule." The direct dispersion interaction between urea and the
protein backbone and sidechains is stronger than for water, which
gives
rise to the intrusion of urea into the protein interior and also to
urea's preferential binding to all regions of the protein. This is
augmented by preferential hydrogen bond formation between the urea
carbonyl and the backbone amides which contributes to the
breaking of
intra-backbone hydrogen bonds. Our study supports the ``direct
interaction mechanism" whereby urea has a stronger dispersion
interaction with protein than water. We also show by molecular
dynamics
simulations that a 7 M aqueous urea solution unfolds a chain of
purely
hydrophobic groups which otherwise adopts a compact structure in
pure
water. The unfolding process arises due to a weakening of
hydrophobic
interactions between the polymer groups. Again the action of urea is
found to be direct, through its preferential binding to the
polymer or
plates. It is, therefore, acting like a surfactant capable of
forming
hydrogen bonds with the solvent. The preferential binding and the
consequent weakened hydrophobic interactions are driven by
enthalpy and
are related to the difference in the strength of the attractive
dispersion interactions of urea and water with the polymer chain or
plate. We also show that the indirect mechanism, in which urea
acts as a
chaotrope, is not a likely cause of urea's action as a denaturant.
These findings suggest that, in denaturing proteins, urea (and
perhaps
other denaturants) forms stronger attractive dispersion interactions
with the protein side chains and backbone than
does water and, therefore, is able to dissolve the core
hydrophobic region.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2009.MAR.V6.3