, 1997) This polyP accumulation is due to the inhibition of poly

, 1997). This polyP accumulation is due to the inhibition of polyP degradation by ppGpp rather than the loss of PhoU function (Kuroda & Ohtake, selleck products 2000; Kuroda, 2006). To determine whether YjbB reduces the levels of polyP under conditions of amino acid starvation, we introduced pMWyjbB into the wild-type strain and then subjected the transformant to amino acid starvation. The levels of polyP in the transformant were lower than those of the strain carrying a control vector plasmid (Fig. 2a). Escherichia coli also accumulates polyP when its growth is blocked by antibiotics that inhibit nucleic acid synthesis

(Kuroda & Ohtake, 2000; Kuroda, 2006). When treated with rifampicin, the levels of polyP in the transformant were also lower than those in the strain carrying a control vector plasmid (Fig. 2b). These results also supported the hypothesis that the reduction of polyP was not due to the suppression of the expression of Pho regulon genes including pstSCAB. As noted above, the N-terminal half of YjbB shows homology with Na+/Pi selleck chemicals cotransporters, indicating the possible involvement of YjbB in the Pi flux. Escherichia coli possesses four Pi transporters (PitA, PitB, PhnCDE, and PstSCAB). Here, we constructed a mutant strain, MT2006, which lacks all four Pi transporters (Table 1). This mutant lost the ability to grow on a medium containing

Pi as the sole source of phosphorus (Pi medium) (Fig. 3a). To test whether YjbB is involved in Pi import, we introduced pMWyjbB into MT2006. However, this transformant still failed to grow on the Pi medium (Fig. 3a). Escherichia coli can utilize glycerol-3-phosphate as the sole source of Pi (Hayashi et al., 1964; Schweizer et al., 1982). The transformant could grow on a medium containing glycerol-3-phosphate as the sole source of phosphorus (GP medium) (Fig. 3b), indicating that YjbB has no or little Pi-uptake activity. On the other

hand, the transformant released approximately 1 mM Pi into the supernatant Methane monooxygenase when it grew for 8 h on the GP medium. To exclude the possibility that Pi was due to the degradation of glycerol-3-phosphate by an elevated alkaline phosphatase activity in the phoU mutant, we constructed MT2013 (phoA, yjbB, pitA, pitB, phnC, pstSCAB-phoU). Similar to MT2006, MT2013 and its transformant harboring pMWyjbB lost the ability to grow on Pi medium, but could grow on GP medium (Fig. 3). MT2013 carrying pMWyjbB still released a large amount of Pi into the GP medium, while MT2013 carrying a control vector plasmid only released a small amount of Pi during the lag phase (Fig. 4a and b). Escherichia coli can take up glycerol-3-phosphate via glycerol-3-phosphate transport systems (Ugp and GlpT) (Hayashi et al., 1964; Schweizer et al., 1982). The GlpT transport system can function in the exchange mode, so that glycerol-3-phosphate is taken up in exchange with internal Pi, while the Ugp system does not release Pi.

Leave a Reply

Your email address will not be published. Required fields are marked *

*

You may use these HTML tags and attributes: <a href="" title=""> <abbr title=""> <acronym title=""> <b> <blockquote cite=""> <cite> <code> <del datetime=""> <em> <i> <q cite=""> <strike> <strong>