MK498-98F14 wild type (WT) and the ΔplyM mutant. C, LC-MS analysis (extracted ion chromatograms of m/z [M + Na]+ 959.5 corresponding to the putative biosynthetic
intermediate of PLYA PS 341 lacking two hydroxyl groups) of Streptomyces sp. MK498-98F14 wild type (WT) and mutants (ΔplyE, ΔplyP, ΔplyR and ΔplyM). B was performed under the conditions: 35-95% B (linear gradient, 0–20 min), 100% B (21–25 min), 35% B (25-40 min) at the flow rate of 0.3 mL/min. Piperazic acid is an attractive building block of many complex secondary metabolites such as Antrimycin [52], Chloptosin [53], Himastatin [39], Luzopeptin [54], Quinoxapeptin [55], Lydiamycin [56], Piperazimycin [57] and Sanglifehrin [58]. The detailed biosynthetic mechanisms by which piperazic acid are formed are not well understood. Recently, Walsh and coworkers demonstrated that KtzI, a homolog of lysine and ornithine N-hydroxylases catalyzes the conversion find more of ornithine into piperazic acid in kutzneride biosynthetic pathway [37]. No such a homolog was found in the ply gene cluster, but two putative homologs are located outside the ply gene cluster (Orf11257 and Orf14738), suggesting that the biosynthesis of piperazic acid may follow the same pathway (Figure 2D). Genes putatively for post-modifications Most modifications in
PLYA biosynthesis take place for the formation of the non-natural building blocks. Recently, Ju and co-workers demonstrated that a cytochrome P450 monooxygenase HtmN catalyzes the hydroxylation of the piperazic acid after peptide formation [59]. There are two cytochrome P450 monooxygenase genes (plyM and plyR) in the ply cluster. PlyR Go6983 in vitro was proposed to hydroxylate leucine that is tethered to a PCP, so we would assume that PlyM may catalyze the hydroxylation of piperazic acid unit as a post-modification although it doesn’t show any homology to HmtN [39]. To test this hypothesis, we constructed the double-crossover mutant by replacement of plyM with the aac(3)IV-oriT gene cassette that is not producing PLYA (Figure 5A, trace v), only accumulating PLYB (Figure 5B). These findings indicate click here that PlyM is responsible for the conversion of PLYB into PLYA
(Figure 2B). To test whether other oxygenases or hydroxylases are involved in the post-modifications, the mass corresponding to the putative intermediate of PLYA lacking two hydroxyl groups was monitored for the mutant strains (Figure 5C). This mass is only detected from the fermentation broth of wide type and ΔplyM strains (Figure 5C, trace v and iv), not from other mutant strains (ΔplyE, ΔplyP and ΔplyR) indicating that the assembly of PLYA and possible intermediates is abolished. These data may support that these genes are involved in the formation of building blocks, not post-modifications. They also indicate that it is very likely to have two steps of post-hydroxylation modifications for maturation of PLYA (Figure 2B).