Construction of Protein Probe with a His-tag and an Electron-transfer Peptide for a Target Protein Sensing

A protein probe with an electron-transfer peptide and a His-tag was designed to electrochemically sense a target protein. We selected tyrosine-rich (Y₄C) and tryptophan-rich (W₄C) peptides for use as electron-transfer agents. The peak for oxidation was based on the oxidations of the phenolic hydroxy groups in Y₄C and on the indole rings in W₄C. Asialofetuin (ASF) with galactose residues was the protein probe, and a galactose recognition protein, soybean agglutinin (SBA), was the target protein. A protein probe composed of an amino acid and carbohydrate residue was expected to be biocompatible. When voltammetric measurements were performed using a glassy carbon electrode, the oxidation peaks of H₆Y₄C and ASF-H₆Y₄C appeared at the same potential. The peak current of ASF-H₆Y₄C was 4-fold that of H₆Y₄C because of the stronger adsorption of ASF-H₆Y₄C onto the electrode. The electrode response of ASF-H₆Y₄C with SBA was half that of ASF-H₆Y₄C alone. By contrast, the peak current of ASF-Y₄CH₆ was higher than that of ASF-H₆Y₄C, which was the result of a greater degree of contact between the Y₄C moieties and an electrode. On the other hand, the voltammetric behaviors of ASF with W₄C and a His-tag were similar to those with Y₄C and a His-tag. The sensitivity of SBA using ASF-Y₄CH₆ was at the 10⁻¹³ M level. To confirm the function of the sensing system, measurements were performed in human serum with SBA and ASF-Y₄CH₆. When SBA was added, the serum had a concentration that ranged between 5.0×10⁻¹³ and 4.0×10⁻¹² M, and the amount of SBA that could be recovered ranged from 97 to 101%. Consequently, this system could be applied to the detection of SBA in serum.