Add to ORKGWe performed classical molecular dynamics simulations using both fixed-charge and polarizable water and protein force fields to contrast the hydration dynamics near hydrophilic and amphiphilic peptides as a function of temperature. The high peptide concentrations we use serve as a model for the surface of folded proteins where hydration layers around each residue overlap significantly. Through simulation we determine that there are notable differences in the water dynamics analyzed from the outer and inner hydration layer regions of the amphiphilic peptide solution that explains the experimentally observed presence of two translational relaxations, while the hydrophilic peptide solution shows only a single non-Arrhenius translational proces...
International audienceHydration shell dynamics plays a critical role in protein folding and biochemi...
Based on molecular dynamics simulations of four globular proteins in dilute aqueous solution, with t...
Water is fundamental to the biochemistry of enzymes. It is well known that without a minimum amount ...
We report quasi-elastic neutron scattering experiments to contrast the water dynamics as a function ...
Hydration water on the surface of a protein is thought to mediate the thermodynamics of protein–liga...
Most proteins have evolved to function optimally in aqueous environments, and the interactions betwe...
Water 2H and 17O spin relaxation is used to study water dynamics in the hydration layers of two smal...
Thermally driven rotational and translational diffusion of proteins and other biomolecules is govern...
Water molecules in the hydration layer of a bio-molecule (proteins and DNA) and of a self-assembled ...
Water is fundamental to the biochemistry of enzymes. It is well known that without a minimum amount ...
We study the dynamics of hydration water/protein association in folded proteins using lysozyme and m...
AbstractThe evolution of water dynamics from dilute to very high concentration solutions of a protot...
ABSTRACT: Protein hydration shell dynamics play an important role in biochemical processes including...
Hydration water is necessary for protein function. It was long thought that the hydration water was ...
The evolution of water dynamics from dilute to very high concentration solutions of a prototypical h...
International audienceHydration shell dynamics plays a critical role in protein folding and biochemi...
Based on molecular dynamics simulations of four globular proteins in dilute aqueous solution, with t...
Water is fundamental to the biochemistry of enzymes. It is well known that without a minimum amount ...
We report quasi-elastic neutron scattering experiments to contrast the water dynamics as a function ...
Hydration water on the surface of a protein is thought to mediate the thermodynamics of protein–liga...
Most proteins have evolved to function optimally in aqueous environments, and the interactions betwe...
Water 2H and 17O spin relaxation is used to study water dynamics in the hydration layers of two smal...
Thermally driven rotational and translational diffusion of proteins and other biomolecules is govern...
Water molecules in the hydration layer of a bio-molecule (proteins and DNA) and of a self-assembled ...
Water is fundamental to the biochemistry of enzymes. It is well known that without a minimum amount ...
We study the dynamics of hydration water/protein association in folded proteins using lysozyme and m...
AbstractThe evolution of water dynamics from dilute to very high concentration solutions of a protot...
ABSTRACT: Protein hydration shell dynamics play an important role in biochemical processes including...
Hydration water is necessary for protein function. It was long thought that the hydration water was ...
The evolution of water dynamics from dilute to very high concentration solutions of a prototypical h...
International audienceHydration shell dynamics plays a critical role in protein folding and biochemi...
Based on molecular dynamics simulations of four globular proteins in dilute aqueous solution, with t...
Water is fundamental to the biochemistry of enzymes. It is well known that without a minimum amount ...