Changing the initiation unit of nonribosomal peptide synthetases to access underexplored biosynthetic potential

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Changing the initiation unit of nonribosomal peptide synthetases to access underexplored biosynthetic potential

Authors

Bai, X.; Zhong, L.; Chen, H.; Liu, Y.; Shi, X.; Wang, X.; Yang, Q.; Diao, X.; Wu, D.; Zhang, Y.; Bian, X.

Abstract

Nonribosomal peptide synthases (NRPSs) are large multimodular enzymes, capable of synthesizing nonribosomal peptides (NRPs) with diverse structures and bioactivities. Genome sequencing revealed a large number of uncharacterized NRPS biosynthetic gene clusters (BGCs) and their products are underexplored. The majority of NRPSs remain silent potentially attributed to factors such as the low activity of the initiation unit or insufficient precursor supply. Exchanging the starter condensation (Cs) domains within initiation unit can change the length of acyl chains of NRPs, hinting at a promising strategy through swapping of a well-studied Cs domain to activate the initiation unit and harness primary metabolites as precursors, which may offer a new option to access silent BGCs. Here, we first pinpointed two highly efficient fusion sites for initiation unit exchanges. Subsequently, they were validated by replacing the initiation region of endopyrrole pathway with a Cs-containing initiation unit for generation of a lipo-endopyrrole derivate. We promptly leveraged this strategy of changing initiation unit to target six previously silent NRPS BGCs, three BGCs were successfully activated and five novel lipopeptides were identified, demonstrating its application to recover silent BGCs. Furthermore, we extended this strategy in more BGCs from different bacteria. Utilizing a heterologous Cs-containing unit to replace the initiation region of chitinimide biosynthetic pathway led to successful incorporation of N-terminal fatty acid chains into chitinimide to create artificial lipo-chitinimides. This study provides a feasible strategy to rationally recover silent BGCs and add fatty acid chains to NRPs, enriching the genome mining and combinatorial biosynthesis approach for bacterial natural products.

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