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Crosslinking intermodular condensation in non-ribosomal peptide biosynthesis

Graham W. Heberlig, James J. Clair and Michael D. Burkart ()
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Graham W. Heberlig: University of California San Diego
James J. Clair: University of California San Diego
Michael D. Burkart: University of California San Diego

Nature, 2025, vol. 638, issue 8049, 261-269

Abstract: Abstract Non-ribosomal peptide synthetases are assembly line biosynthetic pathways that are used to produce critical therapeutic drugs and are typically arranged as large multi-domain proteins called megasynthetases1. They synthesize polypeptides using peptidyl carrier proteins that shuttle each amino acid through modular loading, modification and elongation2 steps, and remain challenging to structurally characterize, owing in part to the inherent dynamics of their multi-domain and multi-modular architectures3. Here we have developed site-selective crosslinking probes to conformationally constrain and resolve the interactions between carrier proteins and their partner enzymatic domains4,5. We apply tetrazine click chemistry to trap the condensation of two carrier protein substrates within the active site of the condensation domain that unites the first two modules of tyrocidine biosynthesis and report the high-resolution cryo-EM structure of this complex. Together with the X-ray crystal structure of the first carrier protein crosslinked to its epimerization domain, these structures highlight captured intermodular recognition events and define the processive movement of a carrier protein from one catalytic step to the next. Characterization of these structural relationships remains central to understanding the molecular details of these unique synthetases and critically informs future synthetic biology design of these pathways.

Date: 2025
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DOI: 10.1038/s41586-024-08306-y

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