Pyridomycin

Pyridomycin is an antimycobacterial cyclodepsipeptide assembled by a nonribosomal peptide synthetase/polyketide synthase hybrid system. Analysis of its cluster revealed a nonribosomal peptide synthetase (NRPS) module, PyrG, that contains two tandem adenylation domains and a PKS-type ketoreductase domain. In this study, we biochemically validated that the second A domain recognizes and activates α-keto-β-methylvaleric acid (2-KVC) as the native substrate; the first A domain was not functional but might play a structural role. The KR domain catalyzed the reduction of the 2-KVC tethered to the peptidyl carrier protein of PyrG in the presence of the MbtH family protein, PyrH. PyrG was demonstrated to recognize many amino acids. This substrate promiscuity provides the potential to generate pyridomycin analogues with various enolic acids moiety; this is important for binding InhA, a critical enzyme for cell-wall biosynthesis in Mycobacterium tuberculosis.

Pyridomycin is a structurally unique antimycobacterial cyclodepsipeptide containing rare 3-(3-pyridyl)-l-alanine and 2-hydroxy-3-methylpent-2-enoic acid moieties. The biosynthetic gene cluster for pyridomycin has been cloned and identified from Streptomyces pyridomyceticus NRRL B-2517. Sequence analysis of a 42.5-kb DNA region revealed 26 putative open reading frames, including two nonribosomal peptide synthetase (NRPS) genes and a polyketide synthase gene. A special feature is the presence of a polyketide synthase-type ketoreductase domain embedded in an NRPS. Furthermore, we showed that PyrA functioned as an NRPS adenylation domain that activates 3-hydroxypicolinic acid and transfers it to a discrete peptidyl carrier protein, PyrU, which functions as a loading module that initiates pyridomycin biosynthesis in vivo and in vitro. PyrA could also activate other aromatic acids, generating three pyridomycin analogues in vivo.

Pyridomycin, a cyclodepsipeptide with potent antimycobacterial activity, specifically inhibits the InhA enoyl reductase of Mycobacterium tuberculosis. Structure-activity relationship studies indicated that the enolic acid moiety in the pyridomycin core system is an important pharmacophoric group, and the natural configuration of the C-10 hydroxyl contributes to the bioactivity of pyridomycin. The ring structure of pyridomycin was generated by the nonribosomal peptide synthetase (NRPS) and polyketide synthase (PKS) hybrid system (PyrE-PyrF-PyrG). Bioinformatics analysis reveals that short-chain dehydrogenase/reductase (SDR) family protein Pyr2 functions as a 3-oxoacyl acyl carrier protein (ACP) reductase in the pyridomycin pathway. Inactivation ofpyr2resulted in accumulation of pyridomycin B, a new pyridomycin analogue featured with enol moiety in pyridyl alanine moiety and a saturated 3-methylvaleric acid group. The elucidated structure of pyridomycin B suggests that rather than functioning as a post-tailoring enzyme, Pyr2 catalyzes ketoreduction to form the C-10 hydroxyl group in pyridyl alanine moiety and the double bond formation of the enolic acid moiety derived from isoleucine when the intermediate assembled by PKS-NRPS machinery is still tethered to the last NRPS module in a special energy-saving manner. Ser-His-Lys residues constitute the active site of Pyr2, which is different from the typically conserved Tyr-based catalytic triad in the majority of SDRs. Site-directed mutation identified that His154 in the active site is a critical residue for pyridomycin B production. These findings will improve our understanding of pyridomycin biosynthetic logic, identify the missing link for the double bound formation of enol ester in pyridomycin, and enable the creation of chemical diversity of pyridomycin derivatives.IMPORTANCETuberculosis (TB) is one of the world's leading causes of death by infection. Recently, pyridomycin, the antituberculous natural product fromStreptomyceshas garnered considerable attention for being determined as a target inhibitor of InhA enoyl reductase of Mycobacterium tuberculosis. In this study, we report a new pyridomycin analogue from mutant HTT12, demonstrate the essential role of a previously ignored genepyr2in pyridomycin biosynthetic pathway, and imply that Pyr2 functions as atransketoreductase (KR) contributing to the formation of functional groups of pyridomycin utilizing a distinct catalytic mechanism. As enol moiety are important for pharmaceutical activities of pyridomycin, our work would expand our understanding of the mechanism of SDR family proteins and set the stage for future bioengineering of new pyridomycin derivatives.