The Intrinsically Disordered C-RING Biomineralization Protein, AP7, Creates Protein Phases That Introduce Nanopatterning and Nanoporosities into Mineral Crystals | Zendy

Eric P. Chang | Zendy; Jennie A. Russ | Zendy; Andreas Verch | Zendy; Roland Kröger | Zendy; Lara A. Estroff | Zendy; John Spencer Evans | Zendy

Open Access

The Intrinsically Disordered C-RING Biomineralization Protein, AP7, Creates Protein Phases That Introduce Nanopatterning and Nanoporosities into Mineral Crystals

Author(s) -

Eric P. Chang,

Jennie A. Russ,

Andreas Verch,

Roland Kröger,

Lara A. Estroff,

John Spencer Evans

Publication year - 2014

Publication title -

biochemistry

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.43

H-Index - 253

eISSN - 1520-4995

pISSN - 0006-2960

DOI - 10.1021/bi500664w

Subject(s) - biomineralization , calcite , nucleation , nanoparticle , protein crystallization , crystallography , materials science , mineralization (soil science) , chemistry , phase (matter) , nanotechnology , chemical engineering , crystallization , mineralogy , organic chemistry , nitrogen , engineering

We report an interesting process whereby the formation of nanoparticle assemblies on and nanoporosities within calcite crystals is directed by an intrinsically disordered C-RING mollusk shell nacre protein, AP7. Under mineralization conditions, AP7 forms protein phases that direct the nucleation of ordered calcite nanoparticles via a repetitive protein phase deposition process onto calcite crystals. These organized nanoparticles are separated by gaps or spaces that become incorporated into the forming bulk crystal as nanoporosities. This is an unusual example of organized nanoparticle biosynthesis and mineral modification directed by a C-RING protein phase.

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