Driving Forces for Adsorption of Amphiphilic Peptides to the Air−Water Interface

We have studied the partitioning of amphiphilic peptides at the air−water interface. The free energy of adsorption from bulk to interface was calculated by determining the potential of mean force via atomistic molecular dynamics simulations. To this end a method is introduced to restrain or constrai...

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Bibliographic Details
Published in:The journal of physical chemistry. B 2010-09, Vol.114 (34), p.11093-11101
Main Authors: Engin, Ozge, Villa, Alessandra, Sayar, Mehmet, Hess, Berk
Format: Article
Language:English
Subjects:
Adsorption
Air
B: Statistical Mechanics, Thermodynamics, Medium Effects
Hydrophobic and Hydrophilic Interactions
Medicin och hälsovetenskap
Molecular Dynamics Simulation
NATURAL SCIENCES
NATURVETENSKAP
Peptides - chemistry
Surface Tension
Thermodynamics
Water - chemistry
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Summary:We have studied the partitioning of amphiphilic peptides at the air−water interface. The free energy of adsorption from bulk to interface was calculated by determining the potential of mean force via atomistic molecular dynamics simulations. To this end a method is introduced to restrain or constrain the center of mass of a group of molecules in a periodic system. The model amphiphilic peptides are composed of alternating valine and asparagine residues. The decomposition of the free energy difference between the bulk and interface is studied for different peptide block lengths. Our analysis revealed that for short amphiphilic peptides the surface driving force dominantly stems from the dehydration of hydrophobic side chains. The only opposing force is associated with the loss of orientational freedom of the peptide at the interface. For the peptides studied, the free energy difference scales linearly with the size of the molecule, since the peptides mainly adopt extended conformations both in bulk and at the interface. The free energy difference depends strongly on the water model, which can be rationalized through the hydration thermodynamics of hydrophobic solutes. Finally, we measured the reduction of the surface tension associated with complete coverage of the interface with peptides.
ISSN:1520-6106
1520-5207
1520-5207
DOI:10.1021/jp1024922