Structure of a Promiscuous Thioesterase Domain Responsible for Branching Acylation in Polyketide Biosynthesis

Thioesterases (TEs) are fundamentally important enzymes present in all bacteria and eukaryotes, where they have conserved functions in fatty acid biosynthesis and secondary metabolism. This work provides the first structural insights into a functionally distinct group of TEs that perform diverse acylations in polyketide and peptide biosynthesis (TE(B)s). Structural analysis of the oocydin (OocS) TEB domain facilitated identification and engineering of the active site to modulate acyl-group acceptance. In this way, we achieved higher reactivity using a structure-based approach, building a foundation for biocatalytic development of TEB-mediated O-acylation, a modification known to improve the bioactivity of oocydin-type polyketides. Lastly, the promiscuity of the OocS TEB motivated us to investigate, and ultimately provide evidence for, the production of longer chain branched oocydins in the native host Serratia plymuthica 4Rx13. This work frames the OocS TEB and homologs as invaluable synthetic biology tools for polyketide drug development.

Automated summary

This study provides the first structural insights into a distinct group of TEs (TE(B)s) that have diverse acylation roles in polyketide and peptide biosynthesis. By analyzing and engineering the active site, the acyl-group acceptance can be modulated. Moreover, the production of longer chain branched oocydins was discovered, positioning this enzyme as a valuable synthetic biology tool for polyketide drug development.