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Notes: Phospholipases D (PLDs) are virtually ubiquitous in eukaryotic organisms; however, they are relatively uncommon in prokaryotes. In this report, we demonstrate that the environmentally acquired, opportunistic pathogen Pseudomonas aeruginosa expresses PLD activity. A gene designated pldA was identified in the genomic database of P. aeruginosa PAO1 encoding a protein with significant homology to eukaryotic PLDs, but not to any prokaryotic PLDs. PldA is most homologous to PLDs from mammals and yeast. The pldA gene was cloned and shown to express an ≈ 116 kDa protein with calcium-regulated PLD activity that is localized to the periplasm. Interestingly, not all strains of P. aeruginosa carry pldA. When present, pldA is always linked to an open reading frame (ORF), ORF4, and a gene (vgrA1) encoding a protein homologous to Vgr from Escherichia coli. Vgr proteins contain regularly repeated dipeptide motifs (valine-glycine repeats). In E. coli, genes encoding Vgr are associated with multicopy genetic elements designated Rhs (rearrangement hot-spots). P. aeruginosa PAO1 has 10 vgr homologues dispersed throughout its genome, but the copy number of these genetic elements varies considerably in different strains. Neither vgrA1 nor ORF4 is present in strains lacking pldA. Furthermore, sequences flanking vgrA1, pldA and ORF4 in the P. aeruginosa strains examined are highly conserved, suggesting a specific site of insertion. These and other data suggest that vgrA1, pldA and ORF4 constitute an ≈ 7 kb mobile genetic element and that pldA was acquired horizontally, perhaps from a eukaryotic organism. Competition studies between a PldA knock-out mutant and the parental wild-type strain indicate that PldA contributes to the ability of P. aeruginosa PAO1 to persist in a chronic pulmonary infection model in rats.

Notes: The Pseudomonas aeruginosa protein PtxS negatively regulates its own synthesis by binding to the upstream region of its gene. We have recently identified a 14 bp palindromic sequence within the ptxS upstream region as the PtxS operator site (OP1). In this study, we searched the P. aeruginosa genomic sequence to determine whether this 14 bp sequence exists in other regions of the P. aeruginosa chromosome. Another PtxS operator site (OP2) was located 47 bp downstream of ptxS. DNA gel shift experiments confirmed that PtxS specifically binds to a 520 bp fragment that carries OP2. The DNA segment 3′ of OP2 contains four open reading frames (ORF1–ORF4), which code for 29, 32, 48 and 35 kDa proteins respectively. The molecular weight of the products of ORFs 2 and 3 were confirmed by T7 expression experiments. Computer analyses suggest that ORF2 encodes an ATP-dependent kinase; ORF3, a transporter; and ORF4, a dehydrogenase. The predicted product of ORF1 showed no homology to previously identified proteins and contains all the conserved amino acids within the aldose 1-epimerase protein motif. Examination of the ptxs–ORF1 intergenic region (using promoter fusion experiments) showed that no potential promoter exists. An isogenic mutant defective in ORF1 was constructed in the P. aeruginosa strain PAO1. In contrast to its parent strain, the mutant failed to grow on a minimal medium in which 2-ketogluconate was the sole carbon source. Similarly, a previously constructed ptxS isogenic mutant of PAO1 did not grow in a minimal medium containing 2-ketogluconate as the sole carbon source. Furthermore, a plasmid carrying a fragment that contains ptxS and ORFs 1–4 complemented the defect of the previously described P. aeruginosa 2-ketogluconate-negative mutant. In the presence of 10 mM 2-ketogluconate, the in vitro binding of PtxS to a DNA fragment that carries either OP1 or OP2 was inhibited. These results suggest that: (i) ptxS together with the other four ORFs constitute the 2-ketogluconate utilization operon (kgu) in P. aeruginosa. Therefore, ORFs 1–4 were designated kguE, kguK, kguT and kguD respectively. (ii) PtxS regulates the expression of the kgu operon by binding to two operators (OP1 and OP2) within the operon; and (iii) 2-ketogluconate is the molecular inducer of the kgu operon or the molecular effector of PtxS.

Notes: In this report we describe the 1500-fold purification and characterization of the haemolytic phospholipase C (PLC) of Pseudomonas aeruginosa, the paradigm member of a novel PLC/phosphatase superfamily. Members include proteins from Mycobacterium tuberculosis, Bordetella spp., Francisella tularensis and Burkholderia pseudomallei. Purification involved overexpression of the plcHR1,2 operon, ion exchange chromatography and native preparative polyacrylamide gel electrophoresis. Matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry confirmed the presence of two proteins in the purified sample with sizes of 17 117.2 Da (PlcR2) and 78 417 Da (PlcH). Additionally, liquid chromatography electrospray mass spectrometry (LCMS) revealed that PlcH and PlcR2 are at a stoichiometry of 1 : 1. Western blot analysis demonstrated that the enzyme purifies as a heterodimeric complex, PlcHR2. PlcHR2 is only active on choline-containing phospholipids. It is equally active on phosphatidylcholine (PC) and sphingomyelin (SM) and is able to hydrolyse plasmenylcholine phospholipids (plasmalogens). Neither PlcHR2 nor the M. tuberculosis homologues are inhibited by D609 a widely used, competitive inhibitor of the Bacillus cereus PLC. PlcH, PlcR2, and the PlcHR2 complex bind calcium. While calcium has no detectable effect on enzymatic activity, it inhibits the haemolytic activity of PlcHR2. In addition to being required for the secretion of PlcH, the chaperone PlcR2 affects both the enzymatic and haemolytic properties of PlcH. Inclusive in these data is the con-clusion that the members of this PC-PLC and phosphatase family possess a novel mechanism for the recognition and hydrolysis of their respective substrates.

Notes: Upon iron restriction, the opportunistic pathogen Pseudomonas aeruginosa produces various virulence factors, including siderophores, exotoxin, proteases and haemolysin. The ferric uptake regulator (Fur) plays a central role in this response and also controls other regulatory genes, such as pvdS, which encodes an alternative sigma factor. This circuit leads to a hierarchical cascade of direct and indirect iron regulation. We used the GeneChip® to analyse the global gene expression profiles in response to iron. In iron-starved cells, the expression of 118 genes was increased at least fivefold compared with that in iron-replete cells, whereas the expression of 87 genes was decreased at least fivefold. The GeneChip® data correlated well with results obtained using individual lacZ gene fusions. Strong iron regulation was observed for previously identified genes involved in biosynthesis or uptake of the siderophores pyoverdine and pyochelin, utilization of heterologous siderophores and haem and ferrous iron transport. A low-iron milieu led to increased expression of the genes encoding TonB, alkaline protease, PrpL protease, exotoxin A, as well as fumarase C, Mn-dependent superoxide dismutase SodA, a ferredoxin and ferredoxin reductase and several oxidoreductases and dehydrogenases. Iron-controlled regulatory genes included seven alternative sigma factors and five other transcriptional regulators. Roughly 20% of the iron-regulated genes encoded proteins of unknown function and lacked any conclusive homologies. Under low-iron conditions, expression of 26 genes or operons was reduced in a ΔpvdS mutant compared with wild type, including numerous novel pyoverdine biosynthetic genes. The GeneChip® proved to be a very useful tool for rapid gene expression analysis and identification of novel genes controlled by Fur or PvdS.

Notes: Exotoxin A (ETA) is secreted by Pseudomonas aeruginosa under iron-limiting growth conditions. The ETA structural gene, toxA, is regulated at the transcriptional level by the gene products of the regAB operon. The expression of both toxA and regAB is repressed under iron-replete conditions, suggesting a role for the ferric uptake regulator (Fur) in regulation of ETA synthesis; however, the Fur protein does not interact directly with the toxA or the regAB promoters. Evidence is presented that the iron control of ETA synthesis is mediated by a Fur-regulated alternative sigma factor, PvdS, which had initially been identified as a positive activator for the production of the siderophore pyoverdin. In a ΔpvdS deletion mutant, ETA was produced at low levels of less than 5% compared to wild type, but still in response to iron starvation, and introduction of a functional pvdS gene on a plasmid fully restored wild-type levels and normal iron regulation of ETA synthesis. Therefore, a functional pvdS locus is essential for ETA production. Neither toxA nor regAB mRNA was detectable in a ΔpvdS mutant. Overexpression of pvdS from the tac promoter on a plasmid resulted in a high-level and iron-independent production of ETA in wild-type PAO1, in the ΔpvdS strain, but not in a ΔregA strain as a host. These findings suggest that PvdS is required for the activation of the regAB promoters. The transcription of regAB and toxA after induction of the Ptac–pvdS gene was monitored in cells grown in high-iron medium. While both regAB and toxA were highly expressed during all growth phases under microaerobic conditions, toxA transcripts were detected only during the exponential but not the early stationary phase of growth under aerobic conditions. These results suggest that a second regulatory mechanism besides the Fur–PvdS system is involved in iron regulation of ETA production.

Notes: Exotoxin A production in Pseudomonas aeruginosa is a complicated and highly regulated process that involves several genes. In this report, we describe the isolation of a new toxA regulatory gene (ptxR) which affects exotoxin A production in P. aeruginosa. In an iron-deficient medium, the presence of a plasmid carrying ptxR in P. aeruginosa PAO1 resulted in a four- to fivefold increase in exotoxin A synthesis. No effect was observed on the levels of elastase, phospholipase C, exoenzyme S, and alkaline protease. Using subcloning and complementation experiments, ptxR was localized to a 2.1 kb KpnI–BglII fragment. Nucleotide sequence analysis revealed the presence of an open reading frame which encodes a 34.97 kDa protein (PtxR). The size of the predicted PtxR compares closely with the 34 kDa PtxR that was synthesized in Escherichia coli using the T7 expression system. The deduced amino acid sequence of PtxR is homologous to that of several members of the LysR family of transcriptional activators. The amino-terminus region of PtxR contains a putative helix-turn-helix DNA-binding motif. Specific ptxR-deletion mutants in P. aeruginosa strains PAO1 and PA103 were constructed. In comparison with their parent strains, both mutants showed a significant reduction in the level of exotoxin A activity. However, upon extensive subculturing, the level of exotoxin A produced by the PAO1::ptxR mutant was similar to that of PAO1. Transcriptional studies, using both toxA–lacZ fusion and RNA analysis, confirmed that ptxR increases toxA and regA transcription. These results suggest that ptxR regulates (through regA) exotoxin A production at the transcriptional level.

Notes: RegA is a transcriptional activator that controls exotoxin A (ETA) production in Pseudomonas aeruginosa. To date, functional assays performed with the purified protein have not clearly defined the molecular mechanism of action of RegA. In this study, we sought to identify important coding regions of regA by analysing the sequences around linker insertion mutations in regA that affected toxA transcription. First, we constructed a strain with the regAB locus deleted from the chromosome, PA103ΔregAB::Gm. toxA transcription was obliterated in strain PA103ΔregAB::Gm, demonstrating that the regAB locus is essential for ETA production. Next, we constructed a series of 6 bp linker insertion mutations distributed throughout regA. These regA linker insertion mutants were sequenced and screened in PA103ΔregAB::Gm for their effects on regulation of ETA production. Six linker insertion mutations occurring between amino acids (aa) 53 and 163 of RegA were isolated that resulted in depression of toxA transcription to varying levels relative to the parental regAB locus. One of these linker insertion mutations (pTR53), resulted in a lack of iron-regulated ETA production and occurred directly upstream from a predicted transmembrane α-helix. The other five linker mutations (pTR88, pTR124, pTR132, pTR132-2 and pTR163) occurred within or flanked a region of RegA between aa 87–142 with similarity to the transcriptional activation domains of ToxR, VirG and OmpR. These data suggest the presence of a previously unidentified transcriptional activation domain in RegA between aa 87–142 and implicate the predicted transmembrane α-helix in the N-terminus as being involved in sensory transduction.

Notes: Production of the two phospholipases C (PLCs) in Pseudomonas aeruginosa PAO1 is induced under conditions of phosphate limitation, or by the osmoprotectants choline or glycine betaine. Tn5 mutagenesis was performed on strain PAO1 to isolate mutants deficient in choline-dependent induction of PLC. Two mutants, Tn5T1 and Tn5G19, were identified which produce decreased levels of PLC in phosphate-replete media supplemented with choline. A total of 136 and 496 bp of flanking DNA from Tn5G19 and Tn5T1 was cloned by an inverse polymerase chain reaction (PCR) and sequenced. The DNA flanking the Tn5T1 insertion contains an open reading frame predicted to encode a peptide that is approx. 60% identical to the N-terminus of a previously identified protein (P35) of unknown function from Escherichia coli. The P35 gene, which is located in the nusA–infB operon in E. coli, was designated orp (osmoprotectant regulator of PLC). Haemolytic titres, total PlcH protein and β-galactosidase activity expressed from a chromosomally inserted plcH–lacZ operon fusion werereduced in strain Tn5T1 in comparison with the parental strain (PAO1) carrying the same fusion. However, this mutant expressed several-fold higher levels of plcH message than strain PAO1 in the presence of choline, while the phosphate-starvation-dependent transcript of plcH could not be detected in this mutant. The defects in Tn5T1 are complemented by a DNA fragment, isolated from a genomic library of PAO1, that carries the orp gene. The deduced amino acid sequence of the DNA fragment cloned from Tn5G19 exhibits 84% identity with the betB gene product of E. coli that has betaine aldehyde dehydrogenase activity. This enzyme catalyses the conversion of betaine aldehyde to glycine–betaine. Unlike the parental strain, the Tn5G19 mutant could not utilize choline as a sole carbon, nitrogen and energy source, and it was deficient in betaine aldehyde dehydrogenase activity. Also, consistent with a disruption of betB in Tn5G19, choline inhibited growth of this strain in media containing 0.7 M NaCl, while glycine–betaine restores growth to wild-type levels. The defects in Tn5G19 are complemented by a DNA fragment from PAO1 that carries the betB gene. The orp gene is located between 0.6 to 6.6 min while betB is located between 10.5 to 12.5 min on the chromosome of PAO1.

Notes: Phospholipase C has been increasingly recognized as a significant virulence determinant in the pathogenesis of Gram-negative and Gram-positive infections. Pseudomonas aeruginosa carries two, non-tandem genes encoding phospholipase C (PLC) activity. One PLC (PLC-H) haemolyses human and sheep erythrocytes while the other is not haemolytic for these kinds of red blood cells. It was previously determined that the synthesis of both PLCs is regulated by inorganic phosphate (Pi), but little else was known regarding the regulation of these potentially important virulence determinants of P. aeruginosa. In this report, data are presented demonstrating that both PLC genes are regulated at the transcriptional level by Pi and by a P. aeruginosa homologue of the positive regulator of genes in the Pi regulon of Escherichia coli, i.e. PhoB. In addition to Pi, it is also shown in this report that the synthesis of both PLC-H and PLC-N is induced by compounds which are not only derived from the substrate product of both enzymes, i.e. phosphorylcholine, but are also known osmoprotectants in eukaryotic and prokaryotic cells. The osmoprotective derivatives of phosphorylcholine which induce the synthesis of PLC in P. aeruginosa include choline, glycine betaine, and dimethylglycine, but not sarcosine (monomethylglycine) or glycine. By constructing mutants which are deficient in the production of each separate PLC and in the production of PhoB it was determined that induction of PLC-H by the osmoprotective compounds is independent of Pi concentration and PhoB, while induction of PLC-N by these compounds requires Pi-deficient conditions and PhoB. It was further demonstrated that while an ionic osmolyte, such as NaCl, inhibited production of both enzymes in Pi-deficient conditions, the presence of osmoprotective compounds, such as choline, restored synthesis of PLC when P. aeruginosa was grown in 0.5 M NaCl. In contrast to the inhibition of PLC production in 0.5 M NaCl in Pi-deficient conditions, PLC production in an equivalent osmotic pressure generated by the neutral osmolyte sucrose was not inhibited, and choline markediy induced production of PLC in this ionically neutral, high osmotic environment. These observations are especially relevant to the pathogenic potential of PLC in the dehydrating (hence high osmotic) conditions of the lungs of cystic fibrosis patients.

Notes: During the past decade significant progress has been made towards identifying some of the schemes that Pseudomonas aeruginosa uses to obtain iron and towards cataloguing and characterizing many of the genes and gene products that are likely to play a role in these processes. This review will largely recount what we have learned in the past few years about how P. aeruginosa regulates its acquisition, intake and, to some extent, trafficking of iron, and the role of iron acquisition systems in the virulence of this remarkable opportunistic pathogen. More specifically, the genetics, biochemistry and biology of an essential regulator (Ferric uptake regulator — Fur) and a Fur-regulated alternative sigma factor (PvdS), which are central to these processes, will be discussed. These regulatory proteins directly or indirectly regulate a substantial number of other genes encoding proteins with remarkably diverse functions. These genes include: (i) other regulatory genes, (ii) genes involved in basic metabolic processes (e.g. Krebs cycle), (iii) genes required to survive oxidative stress (e.g. superoxide dismutase), (iv) genes necessary for scavenging iron (e.g. siderophores and their cognate receptors) or genes that contribute to the virulence (e.g. exotoxin A) of this opportunistic pathogen. Despite this recent expansion of knowledge about the response of P. aeruginosa to iron, many significant biological issues surrounding iron acquisition still need to be addressed. Virtually nothing is known about which of the distinct iron acquisition mechanisms P. aeruginosa brings to bear on these questions outside the laboratory, whether it be in soil, in a pipeline, on plants or in the lungs of cystic fibrosis patients.