Escherichia coli pgsA mutations, which cause acidic phospholipid deficiency, repress transcription of the flagellar master operon flhDC, and thus impair flagellar formation and motility. The molecular mechanism of the strong repression of flhDC transcription in the mutant cells, however, has not yet been clarified. In order to shed light on this mechanism we isolated genes which, when supplied in multicopy, suppress the repression of flhD, and found that three genes, gadW, metE and yeaB, were capable of suppression. Taking into account a previous report that gadW represses s S production, the level of s S in the pgsA3 mutant was examined. We found that pgsA3 cells had a high level of s S and that introduction of a gadW plasmid into pgsA3 cells did reduce the s S level. The pgsA3 cells exhibited a sharp increase in s S levels that can only be partially attributed to the slight increase in rpoS transcription; the largest part of the effect is due to a post-transcriptional accumulation of s S . GadW in multicopy exerts its effect by posttranscriptionally downregulating s S . YeaB and MetE in multicopy also exert their effect via s S .Disruption of rpoS caused an increase of the flhD mRNA level, and induction from P trc -rpoS repressed the flhD mRNA level. The strong repression of flhD transcription in pgsA3 mutant cells is thus suggested to be caused by the accumulated s S .
INTRODUCTIONEscherichia coli membranes contain only three major phospholipids. Molecular genetic approaches to correlate mutationally modified lipid compositions with altered membrane functions have been successfully used to understand the biological roles of the individual phospholipids (for reviews, see Shibuya, 1992;Cronan, 2003;Dowhan et al., 2004). Lack of phosphatidylethanolamine, a zwitterionic phospholipid, which accounts for about 70 % of total phospholipids, is lethal, but the lethality is suppressed by supplementation with high concentrations of divalent cations (DeChavigny et al., 1991;Saha et al., 1996). The lack of phosphatidylethanolamine causes a defect in motility (Shi et al., 1993), an activation of the Cpx two-component signal transduction pathway (Mileykovskaya & Dowhan, 1997), a defect in division site selection, probably due to the concomitant increase in cardiolipin content that affects the localization of MinD (Mileykovskaya & Dowhan, 2005), and a defect in the native folding of lactose permease LacY, which causes the loss of active transport of the substrate (Dowhan et al., 2004).Lack of, or deficiency in, the major acidic phospholipid phosphatidylglycerol, brought about by the mutations pgsA30 : : kan or pgsA3, respectively, is lethal, due to the absence of, or the missense defect in, phosphatidylglycerophosphate synthase, which catalyses the committed step in the biosynthetic pathway for this acidic phospholipid (Shibuya, 1992;Usui et al., 1994). However, simultaneous lack of the major outer membrane lipoprotein (Braun's lipoprotein), the most abundant protein, encoded by lpp, suppresses the lethality (Shibuya, 1992;K...
