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A Versatile Enzymatic Pathway for Modification of Peptide C-Termini

Shravan R. Dommaraju, Sanath K. Kandy, Hengqian Ren, Dominic Luciano, Shogo Fujiki, David Šarlah, Huimin Zhao, Jonathan R. Chekan, Douglas A. Mitchell

2025ACS Central Science8 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Advances in bioinformatics have enabled the discovery of unique enzymatic reactions, particularly for ribosomally synthesized and post-translationally modified peptides (RiPPs). The recently discovered daptides, peptides with their C-terminus replaced by an amine, represent one such case, but the diversity, requirements, and engineering potential of daptide biosynthesis remain to be established. Using the daptide biosynthetic gene clusters from Thermobifida fusca and Streptomyces azureus, we reconstituted daptide biosynthesis in vitro, revealing the enzymatic requirements for successive oxidative decarboxylation, transamination, and N, N -dimethylation. In vitro and in vivo studies showed a tailoring family of YcaO enzymes convert a secondary amine intermediate to a C-terminal imidazoline. We further demonstrated enzymatic activity toward shortened, leader peptide-free, and non-native core peptides, highlighting a broad substrate tolerance. Using these insights, we directed the daptide pathway to install new C-termini, including a bioconjugation-compatible aminoacetone, on various peptide and protein substrates.

Topics & Concepts

EnzymeBiochemistryPeptideBiosynthesisChemistryPeptide BiosynthesisSubstrate (aquarium)Peptide synthesisCombinatorial chemistrySubstrate specificityMetabolic pathwayProtein engineeringMetabolic engineeringGeneSynthetic biologyOxidative phosphorylationComputational biologyAmino acidAmine gas treatingPeptide sequenceMicrobial Natural Products and BiosynthesisChemical Synthesis and AnalysisBiochemical and Structural Characterization