A protease from ribosomal peptide biosynthesis macrocyclizes diverse substrates, including those resembling nonribosomal peptide and hybrid polyketide-peptide products. The proposed mechanism is analogous to thioesterase-catalyzed chemistry, but the substrates are amide bonds rather than thioesters.Macrocyclization is a common strategy to improve the rigidity and stability of bioactive metabolites. 1,2 In polyketide and nonribosomal peptide biosynthesis, macrocyclization via lactones or lactams is typically catalyzed by thioesterase (TE) domains, which contain a serine protease-like Asp-His-Ser catalytic triad (Figure 1). 1 The TE domain transfers the peptide/polyketide chain from a carrier protein to the active site serine, which is then displaced by a nucleophile, generating either a linear product, or more commonly a macrocycle, as in tyrocidine A (1).Quite interestingly, one of the major groups of macrocyclic ribosomal peptides, the cyanobactins, 3 is cyclized in a similar way: a subtilisin-like serine protease catalyzes cleavage of a C-terminal peptide sequence in tandem with N-C macrolactamization, leading to compounds such as patellamide C (2). 4-6 Among ribosomal peptides, both the cyanobactins and cyclotides are N-C cyclic, while other ribosomal peptides, such as capistruin, 7 microcin J25, 8 and the microviridins, 9 are cyclized via side-chain residues using ATP via wholly different biochemical mechanisms. There is indirect evidence that cyclotides are circularized in a similar fashion to cyanobactins, 10 and circular ribosomal peptides are common in diverse organisms. However, no definitive enzymatic or genetic studies of N-C macrocyclization have been performed on any ribosomal peptide system other than the cyanobactins. Previously, we have shown that the subtilisin-like protease, PatG, is solely responsible for catalyzing macrocyclization in the patellamide pathway. 6 Metagenomic and biochemical analyses of the patellamide pathway showed that PatG is a broad-substrate enzyme, processing 29 known precursor peptide sequences encoding macrocycles of 7-8 amino acids. 4,5 Every natural product residue is mutated at least once in this series, and PatG could also produce the unnatural compound eptidemnamide (3) both in vivo and in vitro ( Figure 2). Consequently, the cyanobactin macrocyclases exhibit exceptionally relaxed substrate specificity. Furthermore, unlike other ribosomal peptide natural product pathways, 11,12 the cyanobactin macrocyclases require only a C-terminal 4-5 amino acid recognition sequence, AYDG(E), which allowed us to employ short synthetic peptides as substrates.We proposed that PatG performs macrocyclization in a manner that is mechanistically analogous to TE domains, although the proteins and the substrates are quite different. In particular, while as their name implies TEs require activated thioesters (or esters) 13 to catalyze circularization, the PatG substrates are simple amides readily accessible through standard solid phase peptide synthesis. Based on this mechanistic...
