Abstract
Proteins regulate diverse biological processes by the specific interaction with, e.g., nucleic acids, proteins and inorganic molecules. The generation of inorganic hybrid materials, such as shell formation in mollusks, is a protein-controlled mineralization process. Moreover, inorganic-binding peptides are attractive for the bioinspired mineralization of non-natural inorganic functional materials for technical applications. However, it is still challenging to identify mineral-binding peptide motifs from biological systems as well as for technical systems. Here, three complementary approaches were combined to analyze protein motifs consisting of alternating positively and negatively charged amino acids: (i) the screening of natural biomineralization proteins; (ii) the selection of inorganic-binding peptides derived from phage display; and (iii) the mineralization of tobacco mosaic virus (TMV)-based templates. A respective peptide motif displayed on the TMV surface had a major impact on the SiO2 mineralization. In addition, similar motifs were found in zinc oxide- and zirconia-binding peptides indicating a general binding feature. The comparative analysis presented here raises new questions regarding whether or not there is a common design principle based on acidic and basic amino acids for peptides interacting with minerals.
Highlights
Peptides which interact with inorganic materials are attractive tools for materials design and various fields of application
Do we find oppositely charged amino acids in other natural biomineralization proteins, and is this a characteristic feature of species- and/or mineral-specific biomineralization processes, especially with respect to CaCO3 ?
Common binding principles and motifs are hard to identify since biomineralization proteins interact with a range of different materials, at different environmental conditions and at various levels of regulation [7,8]
Summary
Peptides which interact with inorganic materials are attractive tools for materials design and various fields of application. Peptides bear an excellent degree of accuracy for positioning distinct functionalities at sub-nanometer level for nanoscale interaction with materials interfaces. Materials 2017, 10, 119 are hydrophilicity and hydrophobicity, and even features related to aromatic or ionic bonds can be very implemented based on the most common set of 20 natural amino acids. One reason is that the functionality of the common amino acids is about an order of magnitude above that of distances of ions in a crystal. There is a spatial discrepancy so that not each functional group of consecutive amino acid residues in a protein may contribute to the binding of the inorganic phase and a straightforward matching of the functional groups of the organic and inorganic phase is not possible
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