Corey A. Stevens scite author profile

By binding to ice, antifreeze proteins (AFPs) depress the freezing point of a solution and inhibit ice recrystallization if freezing does occur. Previous work showed that the activity of an AFP was incrementally increased by fusing it to another protein. Even larger increases in activity were achieved by doubling the number of ice-binding sites by dimerization. Here, we have combined the two strategies by linking multiple outward-facing AFPs to a dendrimer to significantly increase both the size of the molecule and the number of ice-binding sites. Using a heterobifunctional cross-linker, we attached between 6 and 11 type III AFPs to a second-generation polyamidoamine (G2-PAMAM) dendrimer with 16 reactive termini. This heterogeneous sample of dendrimer-linked type III constructs showed a greater than 4-fold increase in freezing point depression over that of monomeric type III AFP. This multimerized AFP was particularly effective at ice recrystallization inhibition activity, likely because it can simultaneously bind multiple ice surfaces. Additionally, attachment to the dendrimer has afforded the AFP superior recovery from heat denaturation. Linking AFPs together via polymers can generate novel reagents for controlling ice growth and recrystallization.

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Self-assembly of protein-polymer conjugates for drug delivery

Stevens

Kaur

Klok

2021

Advanced Drug Delivery Reviews

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A minimalistic cyclic ice-binding peptide from phage display

et al. 2021

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Developing molecules that emulate the properties of naturally occurring ice-binding proteins (IBPs) is a daunting challenge. Rather than relying on the (limited) existing structure–property relationships that have been established for IBPs, here we report the use of phage display for the identification of short peptide mimics of IBPs. To this end, an ice-affinity selection protocol is developed, which enables the selection of a cyclic ice-binding peptide containing just 14 amino acids. Mutational analysis identifies three residues, Asp8, Thr10 and Thr14, which are found to be essential for ice binding. Molecular dynamics simulations reveal that the side chain of Thr10 hydrophobically binds to ice revealing a potential mechanism. To demonstrate the biotechnological potential of this peptide, it is expressed as a fusion (‘Ice-Tag’) with mCherry and used to purify proteins directly from cell lysate.

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RTX Adhesins are Key Bacterial Surface Megaproteins in the Formation of Biofilms

Guo¹,

Vance²,

Stevens³

et al. 2019

Trends in Microbiology

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Corey A. Stevens

Structure of a 1.5-MDa adhesin that binds its Antarctic bacterium to diatoms and ice

Dendrimer-Linked Antifreeze Proteins Have Superior Activity and Thermal Recovery

Self-assembly of protein-polymer conjugates for drug delivery

A minimalistic cyclic ice-binding peptide from phage display

RTX Adhesins are Key Bacterial Surface Megaproteins in the Formation of Biofilms

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