Microarray analysis of global gene expression in mucoid Pseudomonas aeruginosa

Pseudomonas aeruginosa is the dominant pathogen causing chronic respiratory infections in cystic fibrosis (CF). After an initial phase characterized by intermittent infections, a chronic colonization is established in CF upon the conversion of P. aeruginosa to the mucoid, exopolysaccharide alginate-overproducing phenotype. The emergence of mucoid P. aeruginosa in CF is associated with respiratory decline and poor prognosis. The switch to mucoidy in most CF isolates is caused by mutations in the mucA gene encoding an anti-sigma factor. The mutations in mucA result in the activation of the alternative sigma factor AlgU, the P. aeruginosa ortholog of Escherichia coli extreme stress sigma factor sigma(E). Because of the global nature of the regulators of mucoidy, we have hypothesized that other genes, in addition to those specific for alginate production, must be induced upon conversion to mucoidy, and their production may contribute to the pathogenesis in CF. Here we applied microarray analysis to identify on the whole-genome scale those genes that are coinduced with the AlgU sigmulon upon conversion to mucoidy. Gene expression profiles of AlgU-dependent conversion to mucoidy revealed coinduction of a specific subset of known virulence determinants (the major protease elastase gene, alkaline metalloproteinase gene aprA, and the protease secretion factor genes aprE and aprF) or toxic factors (cyanide synthase) that may have implications for disease in CF. Analysis of promoter regions of the most highly induced genes (>40-fold, P < or = 10(-4)) revealed a previously unrecognized, putative AlgU promoter upstream of the osmotically inducible gene osmE. This newly identified AlgU-dependent promoter of osmE was confirmed by mapping the mRNA 5' end by primer extension. The recognition of genes induced in mucoid P. aeruginosa, other than those associated with alginate biosynthesis, reported here revealed the identity of previously unappreciated factors potentially contributing to the morbidity and mortality caused by mucoid P. aeruginosa in CF.     

Overexpression of CupB5 activates alginate overproduction in Pseudomonas aeruginosa by a novel AlgW‐dependent mechanism

In Pseudomonas aeruginosa, alginate overproduction, also known as mucoidy, is negatively regulated by the transmembrane protein MucA, which sequesters the alternative sigma factor AlgU. MucA is degraded via a proteolysis pathway that frees AlgU from sequestration, activating alginate biosynthesis. Initiation of this pathway normally requires two signals: peptide sequences in unassembled outer‐membrane proteins (OMPs) activate the AlgW protease, and unassembled lipopolysaccharides bind periplasmic MucB, releasing MucA and facilitating its proteolysis by activated AlgW. To search for novel alginate regulators, we screened a transposon library in the non‐mucoid reference strain PAO1, and identified a mutant that confers mucoidy through overexpression of a protein encoded by the c haperone‐u sher p athway gene cupB5. CupB5‐dependent mucoidy occurs through the AlgU pathway and can be reversed by overexpression of MucA or MucB. In the presence of activating OMP peptides, peptides corresponding to a region of CupB5 needed for mucoidy further stimulated AlgW cleavage of MucA in vitro. Moreover, the CupB5 peptide allowed OMP‐activated AlgW cleavage of MucA in the presence of the MucB inhibitor. These results support a novel mechanism for conversion to mucoidy in which the proteolytic activity of AlgW and its ability to compete with MucB for MucA is mediated by independent peptide signals.     

Control of AlgU, a member of the sigma E-like family of stress sigma factors, by the negative regulators MucA and MucB and Pseudomonas aeruginosa conversion to mucoidy in cystic fibrosis.

The alternative sigma factor AlgU (Pseudomonas aeruginosa sigma E) is required for full resistance of P. aeruginosa to oxidative stress and extreme temperatures. AlgU also controls conversion of P. aeruginosa to the mucoid, alginate-overproducing phenotype associated with lethal infections in cystic fibrosis patients. Mutations that cause conversion to mucoidy in cystic fibrosis isolates occur frequently in mucA, the second gene within the algU mucABCD gene cluster. Here we analyze the biochemical basis of conversion to mucoidy. MucA was shown to act as an anti-sigma factor by binding to AlgU and inhibiting its activity. MucB, another negative regulator of AlgU, was localized in the periplasm. MucB exerts its function from this compartment, since deletion of the leader peptide and the cytoplasmic location of MucB abrogated its ability to inhibit mucoidy. These data support a model in which a multicomponent system, encompassing an anti-delta factor and elements in the periplasmic compartment, modulates activity of AlgU. Since factors controlling AlgU are conserved in other gram-negative bacteria, the processes controlling conversion to mucoidy in P. aeruginosa may be applicable to the regulation of AlgU (sigma E) equivalents in other organisms.     

Synthesis of lipopolysaccharide O side chains by Pseudomonas aeruginosa PAO1 requires the enzyme phosphomannomutase.

We have cloned a lipopolysaccharide (LPS) biosynthetic gene from Pseudomonas aeruginosa PAO1 that complements the defect in the production and incorporation of LPS O side chains in the LPS-rough strain AK1012. This gene was characterized by pulsed-field gel electrophoresis, deletion and restriction mapping of the cloned DNA, and biochemical analysis of the protein product. The cloned DNA was found to map to the 7-to-11-min region of the P. aeruginosa chromosome, and the gene needed for complementation of the LPS-rough phenotype was contained on a 2.6-kb HindIII-SacI fragment. This same size restriction fragment contains the alginate gene algC, which encodes the enzyme phosphomannomutase (PMM) and also maps to this region of the P. aeruginosa chromosome. The LPS-rough strain AK1012 was deficient in PMM activity, and this activity was restored to parental levels when the cloned gene was transferred to strain AK1012. In addition, the cloned gene could complement the PMM deficiency in the algC mutant strain 8858, and the cloned algC gene could restore the LPS-smooth phenotype to strain AK1012. These results indicate that the gene we have cloned is equivalent to the alginate gene algC. We designate this gene pmm to emphasize that it encodes the enzyme PMM, which has been shown to be essential for alginate production, and we demonstrate that PMM activity is required for the LPS-smooth phenotype in P. aeruginosa PAO1.     

Membrane-to-cytosol redistribution of ECF sigma factor AlgU and conversion to mucoidy in Pseudomonas aeruginosa isolates from cystic fibrosis patients

The conversion to mucoid phenotype in Pseudomonas aeruginosa during chronic infections in cystic fibrosis (CF) is due to mutations in the algU mucABCD gene cluster. This cluster encodes an extreme stress response system conserved in Gram-negative bacteria. The system includes an ECF sigma factor, AlgU (sigmaE), an inner membrane protein, MucA, which inhibits AlgU activity, and MucB, a periplasmic protein that negatively controls AlgU. In this work, we investigated whether and how these factor interact to transduce signals between different cellular compartments. The mutation mucADeltaG440, which renders a large fraction of P. aeruginosa CF isolates mucoid, did not abrogate AlgU-MucA interactions, although it eliminated MucA-MucB interactions in the yeast two-hybrid system. The mucADeltaG440 truncation of the periplasmic C-terminal tail of MucA destabilized the molecule resulting in low or undetectable steady-state levels in P. aeruginosa. Somewhat reduced levels of MucA were also seen in cells with inactivated mucB or with the mucACF53 allele carrying the missense P184S mutation, which mildly affected interactions with MucB. The events downstream from MucA destabilization were also investigated. AlgU was found to associate with inner membranes in mucA+ cells. In mutants destabilizing MucA, a limited redistribution of AlgU from the membrane to the cytosol was observed. The redistribution was spontaneous in mucADeltaG440 cells, while in mucB and mucACF53 mutants it required additional signals. Despite a large reduction in MucA levels in mucADeltaG440 cells, only a small fraction of AlgU was redistributed to the cytosol and a significant portion of this sigma factor remained membrane bound and behaved as a peripheral inner membrane protein. The fraction of AlgU that depended on MucA for association with the membrane also brought RNA polymerase into this compartment. These results are consistent with a model in which MucB-MucA-AlgU-RNA polymerase interactions at the membrane allow transduction of potentially lethal stress signals with both rapid reaction times of the preassembled complexes and efficient resupply at the membrane from the prebound components.     

Analysis of the Pseudomonas aeruginosa regulon controlled by the sensor kinase KinB and sigma factor RpoN

Alginate overproduction by Pseudomonas aeruginosa, also known as mucoidy, is associated with chronic endobronchial infections in cystic fibrosis. Alginate biosynthesis is initiated by the extracytoplasmic function sigma factor (σ(22); AlgU/AlgT). In the wild-type (wt) nonmucoid strains, such as PAO1, AlgU is sequestered to the cytoplasmic membrane by the anti-sigma factor MucA that inhibits alginate production. One mechanism underlying the conversion to mucoidy is mutation of mucA. However, the mucoid conversion can occur in wt mucA strains via the degradation of MucA by activated intramembrane proteases AlgW and/or MucP. Previously, we reported that the deletion of the sensor kinase KinB in PAO1 induces an AlgW-dependent proteolysis of MucA, resulting in alginate overproduction. This type of mucoid induction requires the alternate sigma factor RpoN (σ(54)). To determine the RpoN-dependent KinB regulon, microarray and proteomic analyses were performed on a mucoid kinB mutant and an isogenic nonmucoid kinB rpoN double mutant. In the kinB mutant of PAO1, RpoN controlled the expression of approximately 20% of the genome. In addition to alginate biosynthetic and regulatory genes, KinB and RpoN also control a large number of genes including those involved in carbohydrate metabolism, quorum sensing, iron regulation, rhamnolipid production, and motility. In an acute pneumonia murine infection model, BALB/c mice exhibited increased survival when challenged with the kinB mutant relative to survival with PAO1 challenge. Together, these data strongly suggest that KinB regulates virulence factors important for the development of acute pneumonia and conversion to mucoidy.     

Exopolysaccharide production in biofilms: substratum activation of alginate gene expression by Pseudomonas aeruginosa.

Reporter gene technology was employed to detect the activity of an alginate promoter of Pseudomonas aeruginosa when the organism was grown as a biofilm on a Teflon mesh substratum and as planktonic cells in liquid medium. Alginate biosynthetic activity was determined with a mucoid cell line derived from a cystic fibrosis isolate and containing an alginate algC promoter fused to a lacZ reporter gene. Reporter activity was demonstrated with chromogenic and fluorogenic substrates for beta-galactosidase. Expression of algC was shown to be upregulated in biofilm cells compared with planktonic cells in liquid medium. Gene up-expression correlated with alginate biosynthesis as measured by Fourier transform infrared spectroscopy, uronic acid accumulation, and alginate-specific enzyme-linked immunosorbent assay. The algC promoter was shown to have maximum activity in planktonic cultures during the late lag and early log phases of the cell growth cycle. During a time course experiment, biofilm algC activity exceeded planktonic activity except during the period immediately following inoculation into fresh medium. In continuous-culture experiments, conversion of lacZ substrate was demonstrated microscopically in individual cells by epifluorescence microscopy.     

Azotobacter vinelandii aldehyde dehydrogenase regulated by sigma(54): role in alcohol catabolism and encystment

Encystment in Azotobacter vinelandii is induced by n-butanol or beta-hydroxybutyrate (BHB). We identified a gene, encoding an aldehyde dehydrogenase, that was named aldA. An aldA mutation impaired bacterial growth on n-butanol, ethanol, or hexanol as the sole carbon source. Expression of aldA increased in cells shifted from sucrose to n-butanol and was shown to be dependent on the alternative sigma(54) factor. A mutation in rpoN encoding the sigma(54) factor also impaired growth on alcohols. Encystment on n-butanol, but not on BHB, was impaired in aldA or rpoN mutants, indicating that n-butanol is not an inducer of encystment by itself but must be catabolized in order to induce encystment.