Abstract
Next generation sequencing (NGS) in combination with phage surface display (PSD) are powerful tools in the newly equipped molecular biology toolbox for the identification of specific target binding biomolecules. Application of PSD led to the discovery of manifold ligands in clinical and material research. However, limitations of traditional phage display hinder the identification process. Growth-based library biases and target-unrelated peptides often result in the dominance of parasitic sequences and the collapse of library diversity. This study describes the effective enrichment of specific peptide motifs potentially binding to arsenic as proof-of-concept using the combination of PSD and NGS. Arsenic is an environmental toxin, which is applied in various semiconductors as gallium arsenide and selective recovery of this element is crucial for recycling and remediation. The development of biomolecules as specific arsenic-binding sorbents is a new approach for its recovery. Usage of NGS for all biopanning fractions allowed for evaluation of motif enrichment, in-depth insight into the selection process and the discrimination of biopanning artefacts, e.g., the amplification-induced library-wide reduction in hydrophobic amino acid proportion. Application of bioinformatics tools led to the identification of an SxHS and a carboxy-terminal QxQ motif, which are potentially involved in the binding of arsenic. To the best of our knowledge, this is the first report of PSD combined with NGS of all relevant biopanning fractions.
Highlights
Arsenic is a toxic metalloid often used in semiconductor elements as gallium arsenide (GaAs) compound
Three biopanning rounds against arsenic oxyanions immobilized on quaternary amines were conducted in a chromatographic setup
Three rounds of biopanning against on-column immobilized arsenic on a cationic ion exchange material were performed
Summary
Arsenic is a toxic metalloid often used in semiconductor elements as gallium arsenide (GaAs) compound. It naturally occurs as a trace element at average concentrations of ~5 ppm, but is concentrated as part of many minerals. Human population in many countries are exposed to high levels of arsenic from water, including Taiwan, Argentina, Chile, Mexico, India, Bangladesh and Chile [2]. The United States Agency for Toxic Substances and Disease Registry (ATSDR) classifies arsenic as most important, No 1 ranked priority hazardous substance (https://www.atsdr.cdc.gov/SPL/index.html, 2020/08/05). Its main toxicity results from inorganic arsenate (HAsO4 2− ) mimicking phosphate (HPO4 2− ) and competition for and inhibition
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