Conformational Control of Inorganic Adhesion in a Designer Protein Engineered for Cuprous Oxide Binding

Combinatorial selection of peptides that bind technological materials has emerged as a valuable tool for room-temperature nucleation and assembly of complex nanostructured materials. At present, the parameters that control peptide−solid binding are poorly understood, but such knowledge is needed to...

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Veröffentlicht in:Langmuir 2007-11, Vol.23 (23), p.11347-11350
Hauptverfasser: Choe, Woo-Seok, Sastry, M. S. R, Thai, Corrine K, Dai, Haixia, Schwartz, Daniel T, Baneyx, François
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container_end_page 11350
container_issue 23
container_start_page 11347
container_title Langmuir
container_volume 23
creator Choe, Woo-Seok
Sastry, M. S. R
Thai, Corrine K
Dai, Haixia
Schwartz, Daniel T
Baneyx, François
description Combinatorial selection of peptides that bind technological materials has emerged as a valuable tool for room-temperature nucleation and assembly of complex nanostructured materials. At present, the parameters that control peptide−solid binding are poorly understood, but such knowledge is needed to build the next generation of hybrid materials. Here, we use a derivative of the DNA binding protein TraI engineered with a disulfide-bonded cuprous oxide binding sequence called CN225 to probe the influence of sequence composition and conformation on Cu2O binding affinity. We previously reported a statistically significant enrichment in paired arginines (RR) among a family of cuprous oxide binding peptides and hypothesized that this is a key motif for binding. However, systematic alanine (A) substitutions in the CN225 RR motif (creating RA, AR, and AA pairs) do not support the hypothesis that RR is critical for Cu2O binding by CN225. Instead, we find that the presentation of the peptide in a disulfide-constrained loop (i.e., the conformation present during combinatorial selection) is crucial for binding to the metal oxide. Our results suggest that caution should be exerted when extrapolating from statistical data and that, in some cases, conformation is more important than composition in determining peptide−inorganic adhesion.
doi_str_mv 10.1021/la702414m
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subjects Amino Acid Sequence
Arginine - chemistry
Arginine - metabolism
Base Sequence
Binding Sites
Chemistry
Colloidal state and disperse state
Copper - chemistry
Copper - metabolism
Disulfides - chemistry
Disulfides - metabolism
DNA-Binding Proteins - chemistry
DNA-Binding Proteins - metabolism
Exact sciences and technology
General and physical chemistry
Molecular Sequence Data
Peptides - chemistry
Peptides - metabolism
Plasmids - chemistry
Plasmids - genetics
Protein Conformation
Protein Engineering
Proteins - chemistry
Proteins - metabolism
Surface physical chemistry
Time Factors
title Conformational Control of Inorganic Adhesion in a Designer Protein Engineered for Cuprous Oxide Binding
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