Abstract
Quinones and quinoproteins are essential redox components and enzymes in biological systems. Here, we report the de novo design, synthesis, and properties of model four‐α‐helix bundle quinoproteins. The proteins were designed and constructed from three different helices with 21 or 22 amino acid residues by chemoselective ligation to a cyclic decapeptide template. A free cysteine unit is placed at the hydrophobic core of the protein for binding of ubiquinone‐0 and menaquinone‐0 through a thioether bond. The quinoproteins with molecular weights of 11–12 kDa were characterized by electrospray ionization mass spectrometry, UV/Vis spectroscopy, size‐exclusion chromatography, circular dichroism measurements, ^1^H NMR spectroscopy, cyclic voltammetry, and redox‐induced FTIR difference spectroscopy. The midpoint redox potentials at pH 8 in aqueous solution E~m,8~ of thioether conjugates with N‐acetyl cysteine methyl ester were 89 mV and −63 mV and with a synthetic protein 229 mV and 249 mV versus standard hydrogen electrode (SHE) for ubiquinone‐0 and menaquinone‐0, respectively. Detailed redox‐induced FTIR difference spectroscopic studies of the model compounds and quinoproteins show the special resonance features for CO bands at 1656–1660 and 1655–1665 cm^−1^ due to the sulfur substitution to ubiquinone‐0 and menaquinone‐0, respectively. The construction of model quinoproteins represents a significant step toward more complex artificial redox systems.