13 IS Hypothetical protein PvdY Siderophore_Pyoverdine PA4168 fpvB 2.03 Outer membrane ferripyoverdine receptor FpvB, for Type I pyoverdine Siderophore_Pyoverdine PA5150 2.44 IS probable short-chain dehydrogenase PA0471 fluR 2.75 FUR probable transmembrane sensor PA0472 fluI 2.59 FUR probable sigma-70 factor,
ECF subfamily PA0672 hemO 3.61 FUR Heme oxygenase HemO, associated with heme uptake Hemin_transport_system PA2467 foxR 2.08 FUR Fe2+-dicitrate sensor, membrane component PA2468 foxI 2.86 FUR probable sigma-70 factor, ECF subfamily PA4227 pchR 4.73 FUR Transcriptional regulator PchR Siderophore_pyochelin PA4467 7.46 FUR Metal transporter, ZIP family PA4468 sodM #CP-868596 randurls[1|1|,|CHEM1|]# 5.59 FUR
Manganese superoxide dismutase (EC 1.15.1.1) PA4469 10.90 FUR FOG: TPR repeat PA4470 fumC1 7.91 FUR Fumarate hydratase class II (EC 4.2.1.2) TCA_Cycle PA4471 7.01 FUR FagA protein PA4515 2.80 FUR Iron-uptake factor PiuC Transport_of_Iron PA4516 1.87 FUR FOG: TPR repeat, SEL1 subfamily PA4708 phuT 2.00 FUR Heme-transport protein, PhuT Hemin_transport_system PA4709 2.22 FUR probable hemin degrading factor Hemin_transport_system PA4710 phuR 2.00 FUR Haem/Haemoglobin uptake outer Selleckchem NSC 683864 membrane receptor PhuR precursor Ton_and_Tol_transport_systems PA4895 1.47 FUR Iron siderophore sensor protein Iron_siderophore_sensor_&_receptor_system PA4896 3.14 FUR probable sigma-70 factor, ECF subfamily Iron_siderophore_sensor_&_receptor_system PA1911 femR 3.55 sigma factor regulator, FemR PA1912 femI 5.53 ECF sigma factor, FemI While pyoverdin production is considered to be a quorum sensing related exoproduct of P. aeruginosa [19], our microarray results suggest that pH dependent expression Suplatast tosilate of pyoverdin-related genes is not related to quorum sensing. To verify this, we dynamically measured P. aeruginosa PAO1 pyoverdin production during growth in liquid NGM media containing
25 mM [Pi] at pH 7.5 versus pH6.0. Results demonstrated that pyoverdin production was developed at 3 hrs of growth (Figure 3A) at 25 mM Pi, pH 7.5, and was partially suppressed by the addition of 100 μM Fe3+. Most notably, suppression of pyoverdin production at [Pi] 25 mM, pH 6.0 was significantly higher compared to that provided by iron supplementation at [Pi] 25 mM pH 7.5. The concentration of iron in both liquid media NGM Pi25 mM, pH 6.0 and NGM Pi25 mM, pH 7.5 was measured and found to be very low (< 0.1 μg/ml (< 1.78 μM)). Given that the concentration of iron needed to partially attenuate pyoverdin production in NGM Pi25 mM, pH 7.5 is as high as 100 μM (Figure 3A), we are confident that the pH, not the extracellular iron concentration, was a major factor leading to the triggering of pyoverdin production under conditions of similar extracellular iron concentration.