Download MendeleyIndel-driven evolution of the canavanine tRNA-editing deacetylase enzyme CtdA.
Tabagari, N., Hauth, F., Fleming, J.R., Hartig, J.S., Mayans, O.(2025) J Struct Biol X 12: 100132-100132
- PubMed: 40687620
- DOI: https://doi.org/10.1016/j.yjsbx.2025.100132
- Primary Citation of Related Structures:
9F7E - PubMed Abstract:
Proteins are heteropolymers composed of twenty standard amino acids, but over 500 non-proteogenic amino acids exist in nature that can be misincorporated into proteins. Canavanine is an antimetabolite of the chemically similar L-arginine. It can be utilized by bacteria such as Pseudomonas canavaninivorans in the legume rhizome as a sole source of carbon and nitrogen. However, canavanine misincorporates in proteins of this bacterium as its arginyl-tRNA synthetase loads tRNA Arg with both canavanine and arginine. Canavanyl-tRNA Arg deacetylase (CtdA) removes canavanine from misloaded tRNA Arg , preventing its protein toxicity, being the first enzyme known to edit tRNA mischarged with a non-proteinogenic amino acid. We have elucidated CtdA's crystal structure and studied its active site using site-directed mutagenesis. We found that CtdA is a small monomeric enzyme with a central, deep cavity that predictably is the canavanine binding site and a positively charged surface area that likely coordinates the CCA-3' tRNA attachment sequence. CtdA is distantly related to the B3/B4 cis -editing domains of the multi-subunit enzyme Phenylalanine-tRNA-Synthetase (PheRS). CdtA and B3/B4 domains from bacterial and archaeal/eukaryotic origin are three subclasses of a conserved 3D-fold that differ in type-specific indels, which shape the substrate binding site. We propose a class-unifying nomenclature of secondary structure for this fold. In CtdA, residues Y104, N105, E118 and E191 are relevant for catalysis, of which N105 is conserved in bacterial B3/B4 domains. Residue N105 is in proximity of the canavanyl-ribose junction and might coordinate the nucleophilic water molecule that attacks the substrate, possibly sharing a mechanistic role in CtdA and bacterial B3/B4 editing enzymes.
- Department of Biology, University of Konstanz, Universitätsstraße 10, 78457 Konstanz, Germany.
Organizational Affiliation:
