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- Title
Polymorph Selectivity of Coccolith‐Associated Polysaccharides from Gephyrocapsa Oceanica on Calcium Carbonate Formation In Vitro.
- Authors
Walker, Jessica M.; Marzec, Bartosz; Lee, Renee B. Y.; Vodrazkova, Kristyna; Day, Sarah J.; Tang, Chiu C.; Rickaby, Rosalind E. M.; Nudelman, Fabio
- Abstract
Coccolith‐associated polysaccharides (CAPs) are thought to be a key part of the biomineralization process in coccolithophores; however, their role is not fully understood. Two different systems that promote different polymorphs of calcium carbonate are used to show the effect of CAPs on nucleation and polymorph selection in vitro. Using a combination of time‐resolved cryo‐transmission electron microscopy and scanning electron microscopy, the mechanisms of calcite nucleation and growth in the presence of the intracrystalline fraction are examined containing CAPs extracted from coccoliths from Gephyrocapsa oceanica and Emiliania huxleyi, two closely related coccolithophore species. The CAPs extracted from G. oceanica are shown to promote calcite nucleation in vitro, even under conditions favoring the kinetic products of calcium carbonate, vaterite, and aragonite. This is not the case with CAPs extracted from E. huxleyi, suggesting that the functional role of CAPs in vivo may be different between the two species. Additionally, high‐resolution synchrotron powder X‐ray diffraction has revealed that the polysaccharide is located between grain boundaries of both calcite produced in the presence of the CAPs in vitro and biogenic calcite, rather than within the crystal lattice. Coccolith‐associated polysaccharides from Gephyrocapsa oceanica are shown to have the ability to directly nucleate calcite even when this is no longer the thermodynamically favored polymorph. This property is not shared by coccolith‐associated polysaccharides (CAPs) extracted from its "sister species" Emiliania huxleyi, suggesting that CAPs may have different functions in different species.
- Subjects
POLYSACCHARIDES; CALCIUM carbonate; BIOMINERALIZATION; CRYSTAL lattices; NUCLEATION; THERMODYNAMICS
- Publication
Advanced Functional Materials, 2019, Vol 29, Issue 1, pN.PAG
- ISSN
1616-301X
- Publication type
Article
- DOI
10.1002/adfm.201807168