Abstract
The phage surface display technology is a useful tool to screen and to extend the spectrum of metal-binding protein structures provided by nature. The directed evolution approach allows identifying specific peptide ligands for metals that are less abundant in the biosphere. Such peptides are attractive molecules in resource technology. For example, gallium-binding peptides could be applied to recover gallium from low concentrated industrial wastewater. In this study, we investigated the affinity and selectivity of five bacteriophage clones displaying different gallium-binding peptides towards gallium and arsenic in independent biosorption experiments. The displayed peptides were highly selective towards Ga3+ whereby long linear peptides showed a lower affinity and specificity than those with a more rigid structure. Cysteine scanning was performed to determine the relationship between secondary peptide structure and gallium sorption. By site-directed mutagenesis, the amino acids of a preselected peptide sequence are systematically replaced by cysteines. The resulting disulphide bridge considerably reduces the flexibility of linear peptides. Subsequent biosorption experiments carried out with the mutants obtained from cysteine scanning demonstrated, depending on the position of the cysteines in the peptide, either a considerable increase in the affinity of gallium compared to arsenic or an increase in the affinity for arsenic compared to gallium. This study shows the impressive effect on peptide–target interaction based on peptide structure and amino acid position and composition via the newly established systematic cysteine scanning approach.
Highlights
The interaction of biomolecules with metals is one of the most fascinating mechanisms in nature.The implementation of such mechanisms in technical applications is promising and has been controversially debated in biomedicine [1], biotechnological production [2,3,4], and nanotechnology [5,6,7,8].Their use for biotechnological applications in the resource technology [9] is considered to be innovative
Inspired by natural evolution, which resulted in highly specialized biomolecules, the phage surface display technique systematically selects randomized peptide sequences for a certain target
We reported the identification of binding motifs of gallium binding bacteriophage clones obtained from a commercial random peptide library
Summary
The interaction of biomolecules with metals is one of the most fascinating mechanisms in nature. Inspired by natural evolution, which resulted in highly specialized biomolecules, the phage surface display technique systematically selects randomized peptide sequences for a certain target. This method has already been used to identify several peptides that interact with metal-containing particles, surfaces, or metal ions. This process is well established and highly efficient but entails a high energy and water consumption [16] For these reasons, a rising awareness of the finiteness of primary raw materials sources and the use of secondary resources is recently discussed. Cysteine scanning is very suitable for reducing the entropy of the peptides presented on the bacteriophage and systematically validating the position of the disulphide bridge in order to identify optimized metal-binding peptide sequences
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