Complete Inhibition of a Polyol Nucleation by a Micromolar Biopolymer Additive

Overview

Journal Cell Rep Phys Sci

Publisher Cell Press

Date 2022 Mar 10

PMID 35265868

Authors

Xin Wen

Sen Wang

Robert Ramji

Luke O Butler

Yelena Bagdagulyan

Audrey Kishishita

James A Golen

Arnold L Rheingold

Soo-Kyung Kim

William A Goddard 3rd

Tod A Pascal

Affiliations

Soon will be listed here.

Abstract

Preventing spontaneous crystallization of supersaturated solutions by additives is of critical interest to successful process design and implementation, with numerous applications in chemical, pharmaceutical, medical, pigment, and food industries, but challenges remain in laboratory and industry settings and fundamental understanding is lacking. When copresented with antifreeze proteins (AFPs), otherwise spontaneously crystallizing osmolytes are maintained at high supersaturations for months in over-wintering organisms. Thus, we here explore the inhibition phenomenon by AFPs, using persistent crystallization of a common sugar alcohol, D-mannitol, as a case study. We report experimentally that DAFP1, an insect AFP, completely inhibits D-mannitol nucleation. Computer simulations reveal a new mechanism for crystallization inhibition where the population of the crystal-forming conformers are selectively bound and randomized in solution by hydrogen bonding to the protein surface. These results highlight the advantages of using natural polymers to address crystallization inhibition challenges and suggest new strategies in controlling the nucleation processes.

Citing Articles

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