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Multivalent Display of Antifreeze Proteins by Fusion to Self-Assembling Protein Cages Enhances Ice-Binding Activities

抗冻蛋白 冰晶 防冻剂 化学 再结晶(地质) 生物物理学 单体 冰点 纳米颗粒 蛋白质亚单位 生物化学 结晶学 聚合物 生物 纳米技术 基因 材料科学 有机化学 物理 光学 古生物学 热力学
作者
Sean Phippen,Corey A. Stevens,Tyler D. R. Vance,Neil P. King,David Baker,Peter L. Davies
出处
期刊:Biochemistry [American Chemical Society]
卷期号:55 (49): 6811-6820 被引量:29
标识
DOI:10.1021/acs.biochem.6b00864
摘要

Antifreeze proteins (AFPs) are small monomeric proteins that adsorb to the surface of ice to inhibit ice crystal growth and impart freeze resistance to the organisms producing them. Previously, monomeric AFPs have been conjugated to the termini of branched polymers to increase their activity through the simultaneous binding of more than one AFP to ice. Here, we describe a superior approach to increasing AFP activity through oligomerization that eliminates the need for conjugation reactions with varying levels of efficiency. A moderately active AFP from a fish and a hyperactive AFP from an Antarctic bacterium were genetically fused to the C-termini of one component of the 24-subunit protein cage T33-21, resulting in protein nanoparticles that multivalently display exactly 12 AFPs. The resulting nanoparticles exhibited freezing point depression >50-fold greater than that seen with the same concentration of monomeric AFP and a similar increase in the level of ice-recrystallization inhibition. These results support the anchored clathrate mechanism of binding of AFP to ice. The enhanced freezing point depression could be due to the difficulty of overgrowing a larger AFP on the ice surface and the improved ice-recrystallization inhibition to the ability of the nanoparticle to simultaneously bind multiple ice grains. Oligomerization of these proteins using self-assembling protein cages will be useful in a variety of biotechnology and cryobiology applications.

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