Figure 3 Characterization of P. syringae 1448a pyoverdine NRPS knockouts. A. Wild type (WT) and pyoverdine NRPS knockouts (Δ1911, Δ1923-1926) on iron-limiting KB agar viewed under UV light. Only the wild type is able to synthesize fluorescent pyoverdine. Pyoverdine gene knockout strains are named according to the gene deleted, based on the Pspph gene numbering scheme in the published genome database [27]. B. Wild type and pyoverdine null strain (Δ1925) inoculated into KB agar containing CAS dye and incubated for 24 h at 28°C. Only the wild type strain took
up discernible levels of iron as evidenced by the orange halo surrounding this inoculum. All pyoverdine NRPS knockouts exhibited indistinguishable iron transport deficient phenotypes. C. Wild type, Δ1925 p38 MAPK activity and Δ1925 complemented by pSX:1925 on iron-restricted KB agar containing 200 μg/ml EDDHA. Complementation by a functional gene copy in trans restored pyoverdine synthesis to near wild type levels in each of the NRPS knockout strains. To confirm the pyoverdine NRPS substrate specificity assigned by in silico analysis, and also to investigate click here the possibility that relaxed substrate specificity for one of the NRPS modules might explain the presence of a variant pyoverdine species, we
sought to express and purify each side chain module as a heterologous His6-tagged protein from Escherichia coli for biochemical characterization. However we were unable to recover any AP26113 molecular weight proteins that were functional in substrate specificity assays, despite managing to obtain soluble protein for full modules as well as isolated A-domains by several different methods (including low temperature growth in the presence of 2.5 mM glycine betaine and 1 M D-sorbitol, a strategy that previously enabled us to isolate functional recombinant PvdD from P. aeruginosa PAO1 [19]; and over-expression and purification of recombinant proteins in the native P. syringae 1448a host). In contrast, we were able to express and purify two functional single-module NRPS control proteins, EntF from E. Gefitinib mouse coli and BpsA from Streptomyces lavendulae [40]. Characterization
of achromobactin as a secondary siderophore of P. syringae 1448a Although the pyoverdine deficient (pvd-) strains were unable to discernibly alter the color of the CAS dye during 24 h growth on agar at 28°C (Figure 3B), i.e. no active iron sequestration was apparent within this timeframe, some color change was observed when these plates were subsequently left at room temperature or maintained at 28°C for an extended duration. These observations suggested that the pvd- strains were secreting at least one alternative siderophore. Production of the secondary siderophore(s) appeared to be temperature dependent, with the pvd- strains exhibiting greater iron uptake at 22°C than at 28°C (the latter being the optimal laboratory temperature for growth of P.