Paul V. Phibbs

The Global Carbon Metabolism Regulator Crc Is a Component of a Signal Transduction Pathway Required for Biofilm Development by Pseudomonas aeruginosa

The transition from a planktonic (free-swimming) existence to growth attached to a surface in a biofilm occurs in response to environmental factors, including the availability of nutrients. We show that the catabolite repression control (Crc) protein, which plays a role in the regulation of carbon metabolism, is necessary for biofilm formation in Pseudomonas aeruginosa. Using phase-contrast microscopy, we found that a crc mutant only makes a dispersed monolayer of cells on a plastic surface but does not develop the dense monolayer punctuated by microcolonies typical of the wild-type strain. This is a phenotype identical to that observed in mutants defective in type IV pilus biogenesis. Consistent with this observation, crc mutants are defective in type IV pilus-mediated twitching motility. We show that this defect in type IV pilus function is due (at least in part) to a decrease in pilA (pilin) transcription. We propose that nutritional cues are integrated by Crc as part of a signal transduction pathway that regulates biofilm development.

Crc Is Involved in Catabolite Repression Control of the bkd Operons of Pseudomonas putida and Pseudomonas aeruginosa

Crc (catabolite repression control) protein of Pseudomonas aeruginosa has shown to be involved in carbon regulation of several pathways. In this study, the role of Crc in catabolite repression control has been studied in Pseudomonas putida. The bkd operons of P. putida and P. aeruginosa encode the inducible multienzyme complex branched-chain keto acid dehydrogenase, which is regulated in both species by catabolite repression. We report here that this effect is mediated in both species by Crc. A 13-kb cloned DNA fragment containing the P. putida crc gene region was sequenced. Crc regulates the expression of branched-chain keto acid dehydrogenase, glucose-6-phosphate dehydrogenase, and amidase in both species but not urocanase, although the carbon sources responsible for catabolite repression in the two species differ. Transposon mutants affected in their expression of BkdR, the transcriptional activator of the bkd operon, were isolated and identified as crc and vacB (rnr) mutants. These mutants suggested that catabolite repression in pseudomonads might, in part, involve control of BkdR levels.

Effect of vfr mutation on global gene expression and catabolite repression control of Pseudomonas aeruginosa

Vfr of Pseudomonas aeruginosa is 91% similar to the cAMP receptor protein (CRP) of Escherichia coli. Based on the high degree of sequence homology between the two proteins, the question arose whether Vfr had a global regulatory effect on gene expression for P. aeruginosa as CRP did for E. coli. This report provides two-dimensional polyacrylamide gel electrophoretic evidence that Vfr is a global regulator of gene expression in P. aeruginosa. In a vfr101::aacC1 null mutant, at least 43 protein spots were absent or decreased when compared to the proteome pattern of the parent strain. In contrast, 17 protein spots were absent or decreased in the parent strain when compared to the vfr101::aacC1 mutant. Thus, a mutation in vfr affected production of at least 60 proteins in P. aeruginosa. In addition, the question whether Vfr and CRP shared similar mechanistic characteristics was addressed. To ascertain whether Vfr, like CRP, can bind cAMP, Vfr and CRP were purified to homogeneity and their apparent dissociation constants (K(d)) for binding to cAMP were determined. The K(d) values were 1.6 microM for Vfr and 0.4 microM for CRP, suggesting that these proteins have a similar affinity for cAMP. Previously the authors had demonstrated that Vfr could complement a crp mutation and modulate catabolite repression in E. coli. This study presents evidence that Vfr binds to the E. coli lac promoter and that this binding requires the presence of cAMP. Finally, the possible involvement of Vfr in catabolite repression control in P. aeruginosa was investigated. It was found that succinate repressed production of mannitol dehydrogenase, glucose-6-phosphate dehydrogenase, amidase and urocanase both in the parent and in two vfr null mutants. This implied that catabolite repression control was not affected by the vfr null mutation. In support of this, the cloned vfr gene failed to complement a mutation in the P. aeruginosa crc gene. Thus, although Vfr is structurally similar to CRP, and is a global regulator of gene expression in P. aeruginosa, Vfr is not required for catabolite repression control in this bacterium.

Adaptations of Pseudomonas aeruginosa to the Cystic Fibrosis Lung Environment Can Include Deregulation of zwf, Encoding Glucose-6-Phosphate Dehydrogenase

Cystic fibrosis (CF) patients are highly susceptible to chronic pulmonary disease caused by mucoid Pseudomonas aeruginosa strains that overproduce the exopolysaccharide alginate. We showed here that a mutation in zwf, encoding glucose-6-phosphate dehydrogenase (G6PDH), leads to a approximately 90% reduction in alginate production in the mucoid, CF isolate, P. aeruginosa FRD1. The main regulator of alginate, sigma-22 encoded by algT (algU), plays a small but demonstrable role in the induction of zwf expression in P. aeruginosa. However, G6PDH activity and zwf expression were higher in FRD1 strains than in PAO1 strains. In PAO1, zwf expression and G6PDH activity are known to be subject to catabolite repression by succinate. In contrast, FRD1 zwf expression and G6PDH activity were shown to be refractory to such catabolite repression. This was apparently not due to a defect in the catabolite repression control (Crc) protein. Such relaxed control of zwf was found to be common among several examined CF isolates but was not seen in other strains of clinical and environmental origin. Two sets of clonal isolates from individual CF patient indicated that the resident P. aeruginosa strain underwent an adaptive change that deregulated zwf expression. We hypothesized that high-level, unregulated G6PDH activity provided a survival advantage to P. aeruginosa within the lung environment. Interestingly, zwf expression in P. aeruginosa was shown to be required for its resistance to human sputum. This study illustrates that adaptation to the CF pulmonary environment by P. aeruginosa can include altered regulation of basic metabolic activities, including carbon catabolism.

Characterization of the 2-ketogluconate utilization operon in Pseudomonas aeruginosa PAO1

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.

Carbohydrate Catabolism in Pseudomonas aeruginosa

The goal of this review is to update the reader on recent data elucidating the physiology and genetics of glycolytic pathways in P. aeruginosa, the most thoroughly investigated member of the pseudomonads. Glycolytic pathways in this organism have several unique features. Lacking phosphofructokinase, P. aeruginosa metabolizes three- and six-carbon sugars via a central cycle which includes the Entner-Doudoroff pathway (EDP) enzymes, rather than utilizing the fermentation pathway of Embden-Meyerhoff-Parnas (EMP) (Entner and Doudoroff, 1952; Kersters and DeLey, 1968). Another unique physiological feature is that a product of the EDP, glyceraldehyde 3-phosphate, is largely recycled through the central cycle, rather than continuing to pyuvate via the lower EMP pathway (Banerjee, 1989; Phibbs, 1988). Thus, the latter enzymes in P. aeruginosa seem to serve gluconeogenic rather than the more usual catabolic functions in other organisms. Whereas the metabolism of glucose is preferred by Escherichia coli, P. aeruginosa utilizes succinate and other tricarboxylic acid cycle intermediates before glucose (Anderson and Wood, 1969; Belvins et al., 1975; Hylemon and Phibbs, 1972; Midgley and Dawes, 1973; and Tiwari and Campbell, 1969). In addition, this organism lacks an oxidative hexose monophosphate pathway (Phibbs, 1988).

Characterization of fructose-1,6-diphosphate-insensitive catabolic glycerol kinase ofPseudomonas aeruginosa

Glycerol kinase is induced in cells ofPseudomonas aeruginosa strain PAO when grown in the presence of glycerol or glycerol-3-phosphate. The enzyme was isolated from the soluble cytoplasmic fraction of cell extracts and purified 500-fold by ammonium sulfate precipitation and chromatography on columns of Sephadex G-25, DEAE-Sephadex, hydroxyapatite, and Sephadex G-200. A molecular weight of 120,000 was estimated by gel filtration of the catalytically active enzyme. In polyacrylamide gel electrophoresis the purified product contained one major band of Coomassie Blue staining material. The enzyme exhibited an apparent Km of 40 μM for glycerol and 23 μM for ATP. Of the nucleotide triphosphates tested, only ATP served as a phosphoryl group donor. Mg++ or Mn++ was required for activity, although a threefold greater concentration of Mn++ was required when Mn++ substituted for Mg++. In contrast to most other catabolic glycerol kinases in bacteria, the enzyme was not inhibited by fructose-1,6-diphosphate nor by other tested metabolites.

Characterization and Genetic Mapping of Phosphoglucoisomerase Mutations in Mannitol-Negative Mutants of Pseudomonas aeruginosa

Abstract. Phosphoglucoisomerase (pgi) mutations in a number of independently isolated mannitol-negative mutants of Pseudomonas aeruginosa PAO1 were mapped on the chromosome by plasmid FP5-mediated conjugation and by cotransduction with the generalized transducing phages G101 and F116L. Mutant allele pgi-9001 exhibited linkage to ilvB, C-9059 (46–85%), car-9003 (93–100%), and pur-9047 (70%), but not with met-9011, in FP5-mediated conjugational crosses. All known pgi mutations and several previously uncharacterized mannitol-negative mutations exhibited transductional linkage to two independent car mutations at frequencies ranging from 13% to 42% and 53% to 99%, in transductional crosses mediated by phages G101 and F116L respectively. These pgi and mannitol-negative mutations also were cotransducible at very low frequencies (<1%) with two independent ilv mutations. Cotransduction of the car and ilv loci could not be detected. These data suggest the location of pgi within the first minute of the P. aeruginosa chromosome closely linked to the car marker and probably between the ilv and car loci. All of the mannitol-negative mutations that exhibited linkage to the car and ilv loci were characterized as pgi mutations by enzyme assays. A phenotypically similar, mannitol-negative mutatant was shown to contain a mutation in glucose-6-phosphate dehydrogenase (zwf-9012) that maps to a different region on the chromosome.