Artificial Gold Enzymes Using a Genetically Encoded Thiophenol‐Based Noble‐Metal‐Binding Ligand

Abstract

Incorporating noble metals in artificial metalloenzymes (ArMs) is challenging due to the lack of suitable soft coordinating ligands among natural amino acids. We present a new class of ArMs featuring a genetically encoded noble‐metal‐binding site based on a non‐canonical thiophenol‐based amino acid, 4‐mercaptophenylalanine (pSHF), incorporated in the transcriptional regulator LmrR via stop codon suppression. We demonstrate that pSHF is an excellent ligand for noble metals in their low oxidation states. The corresponding gold(I) enzyme was characterised by mass spectrometry, UV‐vis spectroscopy and X‐ray crystallography and successfully catalysed hydroamination reactions of 2‐ethynyl anilines with over 50 turnover numbers. Interestingly, two equivalents of gold(I) per protein dimer proved to be required for activity. Up to 98% regioselectivity in the hydroamination of an ethynylphenylurea substrate was obtained, yielding the corresponding phenyl‐dihydroquinazolinone product, consistent with a π‐activation mechanism by single gold centres. The ArM was optimized by site saturation mutagenesis, using an on‐bead screening protocol. This resulted in a single mutant that showed higher activity on one class of substrates. This work brings the power of noble‐metal catalysis into the realm of enzyme engineering and establishes thiophenols as alternative ligands for noble metals, providing new opportunities in coordination chemistry and catalysis.