Abstract
The antifreeze protein (AFP) activity is explained using two models. The first model is using ice binding and the second is using antiice structuralization of water molecules. The description of AFP function using anti-ice structuralization of water molecules is less explored. Therefore, it is of interest to explain AFP function using this model. Protein folding is often described using models where hydrophobic residues move away from water getting buried and hydrophilic residues are exposed to the surface. Thus, the 3D Gauss function stretched on the protein molecule describes the hydrophobicity distribution in a protein molecule. Small antifreeze proteins (less than 150 residues) are often represented by structures with hydrophobic core. Large antifreeze proteins (above 200 residues) contain solenoid (modular repeats). The hydrophobic field of solenoid show different distribution with linear propagation of the bands of different hydrophobicity level having high and low hydrophobicity that is propagated parallel to the long axis of solenoid. This specific ordering of hydrophobicity implies water molecules ordering different from ice. We illustrate this phenomenon using two antifreeze proteins to describe the hypothesis.
Highlights
Structuralization of water molecules in close neighbourhood of antifreeze proteins: The activity of antifreeze proteins is interpreted as the interaction with water in form of ice similar to protein-ligand docking [1], where the structure of ice appears compatible to the docking areas in antifreeze proteins [2]
The fuzzy oil drop model assuming Gaussian distribution of hydrophobicity in protein molecules treats the surface of molecule as covered by polar groups [3]
The high mobility of water molecules is observed on the surface of antifreeze proteins what is accordant with our interpretation of the action of these proteins [7]
Summary
Structuralization of water molecules in close neighbourhood of antifreeze proteins: The activity of antifreeze proteins is interpreted as the interaction with water in form of ice similar to protein-ligand docking [1], where the structure of ice appears compatible to the docking areas in antifreeze proteins [2]. These polar groups influence the order of water molecules in a close neighbourhood ( not limited to one layer). In consequence the water dipoles orientations follow the charge distribution on the protein surface.
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