Ice-binding mechanism of winter flounder antifreeze proteins.

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Ice-binding mechanism of winter flounder antifreeze proteins.

A Cheng and K M Merz, Jr

Department of Chemistry, The Pennsylvania State University, University Park 16802-2801, USA.

ABSTRACT

We have studied the winter flounder antifreeze protein (AFP)and two of its mutants using molecular dynamics simulation techniques.The simulations were performed under four conditions: in thegas phase, solvated by water, adsorbed on the ice (2021) crystalplane in the gas phase and in aqueous solution. This study provideddetails of the ice-binding pattern of the winter flounder AFP.Simulation results indicated that the Asp, Asn, and Thr residuesin the AFP are important in ice binding and that Asn and Thras a group bind cooperatively to the ice surface. These ice-bindingresidues can be collected into four distinct ice-binding regions:Asp-1/Thr-2/Asp-5, Thr-13/Asn-16, Thr-24/Asn-27, and Thr-35/Arg-37.These four regions are 11 residues apart and the repeat distancebetween them matches the ice lattice constant along the (1102)direction. This match is crucial to ensure that all four groupscan interact with the ice surface simultaneously, thereby, enhancingice binding. These Asx (x = p or n)/Thr regions each form 5-6hydrogen bonds with the ice surface: Asn forms about three hydrogenbonds with ice molecules located in the step region while Thrforms one to two hydrogen bonds with the ice molecules in theridge of the (2021) crystal plane. Both the distance betweenThr and Asn and the ordering of the two residues are crucialfor effective ice binding. The proper sequence is necessaryto generate a binding surface that is compatible with the icesurface topology, thus providing a perfect "host/guest" interactionthat simultaneously satisfies both hydrogen bonding and vander Waals interactions. The results also show the relation amongbinding energy, the number of hydrogen bonds, and the activity.The activity is correlated to the binding energy, and in thecase of the mutants we have studied the number of hydrogen bonds.The greater the number of the hydrogen bonds the greater theantifreeze activity. The roles van der Waals interactions andthe hydrophobic effect play in ice binding are also highlighted.For the latter it is demonstrated that the surface of ice hasa clathratelike structure which favors the partitioning of hydrophobicgroups to the surface of ice. It is suggested that mutationsthat involve the deletion of hydrophobic residues (e.g., theLeu residues) will provide insight into the role the hydrophobiceffect plays in partitioning these peptides to the surface ofice.

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