The Vps/VacJ ABC transporter is required for intercellular spread of Shigella flexneri.

The Vps/VacJ ABC transporter system is proposed to function in maintaining the lipid asymmetry of the outer membrane. Mutations in vps or vacJ in Shigella flexneri resulted in increased sensitivity to lysis by the detergent sodium dodecyl sulfate (SDS), and the vpsC mutant showed minor differences in its phospholipid profile compared to the wild type. vpsC mutants were unable to form plaques in cultured epithelial cells, but this was not due to a failure to invade, to replicate intracellularly, or to polymerize actin via IcsA for movement within epithelial cells. The addition of the outer membrane phospholipase gene pldA on a multicopy plasmid in a vpsC or vacJ mutant restored its resistance to SDS, suggesting a restoration of lipid asymmetry to the outer membrane. However, the pldA plasmid did not restore the mutant's ability to form plaques in tissue culture cells. Increased PldA levels also failed to restore the mutant's phospholipid profile to that of the wild type. We propose a dual function of the Vps/VacJ ABC transporter system in S. flexneri in both the maintenance of lipid asymmetry in the outer membrane and the intercellular spread of the bacteria between adjacent epithelial cells.

Chromosomal context directs high-frequency precise excision of IS492 in Pseudoalteromonas atlantica.

DNA rearrangements, including insertions, deletions, and inversions, control gene expression in numerous prokaryotic and eukaryotic systems, ranging from phase variation of surface antigens in pathogenic bacteria to generation of Ig diversity in human B cells. We report here that precise excision of the mobile element IS492 from one site on the Pseudoalteromonas atlantica chromosome directly correlates with phase variation of peripheral extracellular polysaccharide ((p)EPS) production from OFF (epsG::IS492) to ON (epsG(+)). In a previously undescribed application of quantitative PCR, we determined that the frequency of this transposase-dependent precise excision is remarkably high, ranging from 10(-3) to 10(-2) per cell per generation. High-frequency excision resulting in nonmutagenic repair of donor DNA is extremely unusual for classical transposable elements. Interestingly, high-frequency precise excision of IS492 does not occur at four different insertion sites on the P. atlantica chromosome, despite identity in the IS492 nucleotide sequences and 5- to 7-bp flanking DNA. The genome sequence revealed that epsG-associated IS492 is the only element inserted within a gene. Quantitative RT-PCR assays for externally derived transposase transcripts from each IS492 copy showed that IS492 at epsG has higher levels of host-initiated transcription through the element, suggesting that transcription per se or an increase in transposase (mooV) expression is responsible for the effect of chromosomal position on element excision. MooV levels and excision activity for IS492 inserted in forward and reverse orientations relative to plac and pT7 in Escherichia coli support that external transcription of mooV boosts transposase to a critical level required for detectable excision.