Dynamic thiolation–thioesterase structure of a non-ribosomal peptide synthetase

Abstract

Non-ribosomal peptide synthetases (NRPS) and polyketide synthases (PKS) are found in bacteria, fungi, and plants, in the main, producing antibiotics. They are macromolecular machines that rely on the activity of thioesterases to produce biologically active small molecules. They are of particular interest as an assembly system that might be adapted for the production of novel bioactive compounds with possible therapeutic activity. Frueh et al. have solved the structure of a carrier protein — part of the EntF NRPS subunit of enterobactin synthetase — bound to a type I thioesterase. (Type I thioesterases catalyse the final 'release' step of the small molecule from the NRPS or PKS machinery.) The structure reveals that part of the thioesterase can flip open to reveal the carrier-protein binding site of the enzyme; this movement allows the tether of the carrier protein to access the active site. Koglin et al. determined the structure of conformational sub-states of a thioesterase II enzyme. Type II thioesterases are required to regenerate a functional 4'-phosphopantetheine cofactor when it gets mis-primed by reacting with acetyl- and short chain acyl-residues. Comparison with the structures of type I thioesterases reveals the basis for substrate selectivity and the different modes of interaction of the two types of thioesterases with thiolation domains. The structure of the apo thiolation-thioesterase di-domain fragment of the EntF non-ribosomal peptide synthetase subunit of enterobactin synthetase is solved. Extensive inter- and intra-domain motions are observed, and these are modulated by interactions with other proteins that participate in the biosynthesis of enterobactin. Non-ribosomal peptide synthetases (NRPS) and polyketide synthases (PKS) produce numerous secondary metabolites with various therapeutic/antibiotic properties1. Like fatty acid synthases (FAS), these enzymes are organized in modular assembly lines in which each module, made of conserved domains, incorporates a given monomer unit into the growing chain. Knowledge about domain or module interactions may enable reengineering of this assembly line enzymatic organization and open avenues for the design of new bioactive compounds with improved therapeutic properties. So far, little structural information has been available on how the domains interact and communicate. This may be because of inherent interdomain mobility hindering crystallization, or because crystallized molecules may not represent the active domain orientations2. In solution, the large size and internal dynamics of multidomain fragments (>35 kilodaltons) make structure determination by nuclear magnetic resonance a challenge and require advanced technologies. Here we present the solution structure of the apo-thiolation–thioesterase (T–TE) di-domain fragment of the Escherichia coli enterobactin synthetase EntF NRPS subunit. In the holoenzyme, the T domain carries the growing chain tethered to a 4′-phosphopantetheine whereas the TE domain catalyses hydrolysis and cyclization of the iron chelator enterobactin. The T–TE di-domain forms a compact but dynamic structure with a well-defined domain interface; the two active sites are at a suitable distance for substrate transfer from T to TE. We observe extensive interdomain and intradomain motions for well-defined regions and show that these are modulated by interactions with proteins that participate in the biosynthesis. The T–TE interaction described here provides a model for NRPS, PKS and FAS function in general as T–TE-like di-domains typically catalyse the last step in numerous assembly-line chain-termination machineries.