Identification of regB, a gene required for optimal exotoxin A yields in Pseudomonas aeruginosa

Regulation of toxA by PtxR in Pseudomonas aeruginosa PA103

Exotoxin A (ETA) production in Pseudomonas aeruginosa requires the regulatory locus regAB. Pseudomonas aeruginosa PA103 produces significantly higher levels of ETA than the prototypic strain PAO1 does, partly because of differences in the regAB locus. Other factors that contribute to this variation are not known. We previously described the P. aeruginosa gene ptxR that positively regulates production of ETA through regAB. ETA production was enhanced but still iron regulated in the PAO1 strain PAO1-XR that carries two copies of ptxR on its chromosome. Here we determine whether ptxR regulation of ETA is different in PA103. In contrast to PAO1-XR, ETA activity produced by PA103-2R, a PA103 strain carrying two copies of ptxR, is enhanced tenfold and partially deregulated in the presence of iron. Real-time PCR transcriptional analysis showed that the copy number of toxA mRNA in PA103-2R is significantly higher than in PA103 in both the presence and absence of iron, yet no similar increase in either regAB or ptxR mRNA copy number was detected. The integrated plasmid together with adjoining DNA was retrieved from the PA103-2R chromosome to determine whether integration-induced DNA changes played a role in this phenotype. Introduction of the retrieved plasmid in PA103 produced a phenotype similar to that of PA103-2R. Sequence analysis of the plasmid revealed the loss of 322 bp within the region 3' of ptxR. A plasmid construct carrying a 4-bp insertion in this same region produced in PA103 a phenotype similar to that of PA103-2R. Our results suggest that the effect of ptxR on toxA expression is different in PA103 than in PAO1 and that this variation in PA103-2R does not occur solely through regAB. Changes within the region 3' of ptxR are critical for the production of the unique PA103-2R phenotype, which occurs in trans and requires intact ptxR, but is not caused by ptxR overexpression.

The Pseudomonas aeruginosa alternative sigma factor PvdS controls exotoxin A expression and is expressed in lung infections associated with cystic fibrosis

PvdS is an alternative sigma factor regulated by the global iron regulator Fur. It has been demonstrated that PvdS plays a role in the iron-dependent regulation of exotoxin A (ETA) in Pseudomonas aeruginosa strain PAO1. The goals of this research were to determine if pvdS was transcribed by the bacteria in the chronic lung infections associated with cystic fibrosis (CF) and to determine how PvdS interacts with the regAB promoters of the hyper-toxigenic strain PA103. It was found that pvdS is transcribed in the lungs of patients with CF and that it appears to be involved with the regulation of toxA in this environment. This correlated with the finding that in strain PA103, a mutation in pvdS reduced ETA activity while the same mutation in strain PAO1 abrogated ETA production. It was also shown that in strain PA103, pvdS was absolutely required for activation of the regAB P2 promoter. The effect of PvdS on the P2 promoter may be direct or indirect; however, in support of a direct role, an eight-out-of-nine base-pair match to the consensus sequence for PvdS binding was identified at the transcriptional start site for the P2 promoter. The effect of PvdS on the PA103 regAB P1 promoter under aerobic growth conditions was also examined. The results show that PvdS does modulate the expression from this promoter but that both the regAB operon and PvdS are required for optimal P1 promoter activity. These studies demonstrate that the alternative sigma factor PvdS acts as a regulator of ETA expression in P. aeruginosa strain PA103 through the regAB operon and that PvdS is expressed in lung infections associated with CF.

Expression ofptxRand its effect ontoxAandregAexpression during the growth cycle ofPseudomonas aeruginosastrain PAO1

The expression of the toxA and regA genes in Pseudomonas aeruginosa is negatively regulated by iron at the transcriptional level. We have previously described ptxR, an exotoxin A regulatory gene which appears to enhance toxA expression through regA. In this study, we have tried to determine if ptxR expression correlates with its effect on toxA and regA expression throughout the growth cycle of P. aeruginosa strain PAO1. This was done using Northern blot hybridization experiments (with toxA, regA, and ptxR probes), and ptxR transcriptional fusion studies. To avoid problems related to the presence of multiple copies of ptxR in PAO1, we have constructed a PAO1 strain (PAO1-XR) that carries only two ptxR genes in its chromosome. Our results showed that when PAO1-XR was grown in iron-limited conditions, the increase in exotoxin A activity and the accumulation of toxA mRNA appeared at about mid- to late-exponential phase. A similar increase in the accumulation of regA mRNA was detected. Both regA transcripts, T1 and T2, were enhanced in PAO1-XR. In iron-sufficient medium, neither toxA nor regA mRNA was detected at any time point in the growth cycle of PAO1-XR. In contrast, the accumulation of ptxR mRNA was detected throughout the growth cycle of PAO1-XR under both iron-deficient and iron-sufficient conditions. The presence of iron in the growth medium also had no effect on the level of β-galactosidase activity produced by a ptxR-lacZ fusion in PAO1. These results suggest that (i) the enhancement in toxA expression by ptxR correlates with the enhancement in regA expression; (ii) ptxR affects the expression of the regA P1 and P2 promoters; (iii) ptxR expression precedes its effect on toxA and regA expression; and (iv) unlike toxA and regA, the overall expression of ptxR throughout the growth cycle of PAO1 is not negatively regulated by iron.Key words: ptxR, differential expression, transcriptional regulation, regA, toxA.

The response of Pseudomonas aeruginosa to iron: genetics, biochemistry and virulence

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.

Characterisation of a chloramphenicol acetyltransferase determinant found in the chromosome of Pseudomonas aeruginosa

The open reading frame (ORF) in the Pseudomonas aeruginosa chromosome, whose product resembles the chloramphenicol acetyltransferases (CAT) belonging to the CATB family, was cloned and shown to confer resistance to chloramphenicol (Cm) in Escherichia coli. The determinant was therefore named catB7 and the corresponding protein CATB7. When the copy number and expression signals were identical, the catB7 gene conferred resistance to Cm at a level slightly lower than those of three other catB genes. CATB7 resembles other CATBs in that it acetylates Cm but not 1-acetoxy-Cm. For CATB7, the K(m) values for acetyl-CoA and Cm were 5.0-5.4-fold higher than the corresponding values for each of the three other CATB proteins (CATB1, CATB3 and CATB5) examined and the Vmax was 5-6 fold lower. Using PCR, the catB7 gene was found in all six P. aeruginosa strains examined but not in any other species of pseudomonad tested. Weak CAT activity was detected in crude cell extracts from five of the six P. aeruginosa strains. However, this activity did not correlate with the Cm susceptibility of the strains, indicating that catB7 is not likely to be the major determinant of intrinsic Cm resistance in P. aeruginosa.

Analysis of Pseudomonas aeruginosa clinical isolates for possible variations within the virulence genes exotoxin A and exoenzyme S

We have previously characterized several Pseudomonas aeruginosa isolates that were obtained from patients with tracheal, urinary tract, or wound infections (A. H. Hamood, J. A. Griswold, and C. M. Duhan, 1996, J. Surg. Res. 61: 425). Analysis of additional isolates showed that regardless of the isolation site, some isolates produced significantly higher or significantly lower levels of either exotoxin A or exoenzyme S proteins. These variations did not correlate with the mucoid phenotype of the isolates. One aim of this study was to determine if the variations in the level of exotoxin A or exoenzyme S are due to DNA rearrangements within either the toxA or the exoS gene. This was accomplished by Southern blot hybridization experiments using a toxA internal probe, a toxA upstream probe, or an exoS internal probe. Hybridization with the toxA internal probe produced a 0.8-kb hybridizing fragment, whereas hybridization with the exoS internal probe produced either a 2.0- or a 2.3-kb hybridizing fragment. Hybridization with the toxA upstream probe, however, produced hybridizing fragments of varying sizes, regardless of their isolation site. Isolates that showed a similar hybridization fragment with either the toxA upstream probe or the exoS internal probe produced variable levels of exotoxin A or exoenzyme S. These results suggest that: [1] specific location within the host has no effect on either the mucoid phenotype of the isolate or the level of exotoxin A or exoenzyme S produced by the isolates; [2] although restriction polymorphism exists within the toxA upstream region, both the toxA and the exoS structural genes are relatively conserved; and [3] variations in the level of exoenzyme S and exotoxin A produced by different isolates do not correlate with either the observed heterogeneity within the toxA upstream region or the mucoid phenotype of the isolates.

Characterization of elastase-deficient clinical isolates of Pseudomonas aeruginosa

Elastase production in Pseudomonas aeruginosa is regulated by the lasR, lasI, rhlR, and rhlI genes. Recently, we have analyzed several clinical isolates of P. aeruginosa for the production of elastase and other extracellular virulence factors. Four of these isolates (CIT1, CIW5, CIW7, and CIW8) produced no elastolytic activity. We have characterized these isolates with respect to their elastase-deficient phenotype. Elastase was detected by immunoblotting experiments using elastase-specific antiserum. We also determined the presence of IasB and IasR mRNAs by Northern (RNA) blot hybridization experiments using lasB and lasR internal probes, respectively. None of the four elastase-deficient strains produced either the elastase protein or the lasB mRNA. Complementation experiments (using plasmids carrying either the lasB or the lasR gene) were conducted to determine if the isolates carry defective lasB or lasR genes. The presence of either a lasB or a lasR plasmid in CIW7 and CIW8 resulted in the production of very low levels of elastase and lasB mRNA. Neither elastase nor lasB mRNA was detected in CIT1 and CIW5 carrying the lasB plasmid. The presence of the lasR plasmid in CIT1 and CIW5 resulted in the production of lasB mRNA and elastase protein in CIW5 only. All elastase-deficient strains produced detectable levels of lasR mRNA which were enhanced in the presence of the lasR plasmid. The Pseudomonas autoinducer (which is encoded by lasI) was also produced by all strains. CIT1 produced both hemolysin and alkaline protease but was defective in pyocyanin production. These results suggest that (i) CIT1 may contain a defect in a lasB-regulatory gene, (ii) CIW5 carries a defect within lasR, and (iii) the defect in isolates CIW7 and CIW8 affects the efficiency of lasB transcription.

Role of the ferric uptake regulator of Pseudomonas aeruginosa in the regulation of siderophores and exotoxin A expression: purification and activity on iron-regulated promoters

The cloned Pseudomonas aeruginosa fur (ferric uptake regulator) gene was overexpressed in P. aeruginosa by using a T7 expression system, and the Fur protein (PA-Fur) was purified by using a combination of ion-exchange chromatography and metal affinity chromatography. The DNA binding activity of the PA-Fur protein was confirmed by gel mobility shift assays and DNase I footprints of the synthetic DNA fragment GATAAT GATAATCATTATC, representing a perfect "Fur box". In addition, it was shown that PA-Fur is capable of binding to promoter and operator determinants of the tightly iron-regulated Escherichia coli fepA-fes enterobactin gene system. The activity of PA-Fur on the promoters of iron-regulated genes involved in the production of two siderophores, pyochelin and pyoverdin, and in the expression of exotoxin A was investigated. Data indicating that the promoters of the pchR gene, encoding a transcriptional activator for pyochelin synthesis, and of the pvdS gene, encoding a positive regulator for pyoverdin production, are specifically recognized by Fur-Fe(II) are presented, suggesting that PA-Fur represses expression of pchR and pvdS during growth in an iron-replete environment. However, neither the promoter region of the gene encoding exotoxin A (toxA) nor the promoters of the regAB operon, required for toxA expression, interacted with high concentrations of purified PA-Fur. These data indicate that iron regulation of exotoxin A production involves additional factors which may ultimately be under the control of PA-Fur.

New mobile gene cassettes containing an aminoglycoside resistance gene, aacA7, and a chloramphenicol resistance gene, catB3, in an integron in pBWH301

The multidrug resistance plasmid pBWH301 was shown to contain a sull-associated integron with five inserted gene cassettes, aacA7-catB3-aadB-oxa2-orfD, all of which can be mobilized by the integron-encoded DNA integrase. The aadB, oxa2, and orfD cassettes are identical to known cassettes. The aacA7 gene encodes a protein that is a member of one of the three known families of aminoglycoside acetyltransferases classified as AAC(6')-I. The chloramphenicol acetyltransferase encoded by the catB3 gene is closely related to members of a recently identified family of chloramphenicol acetyltransferases. The catB3 gene displays a relatively high degree of sequence identity to a chromosomally located open reading frame in Pseudomonas aeruginosa, and this may represent evidence for the acquisition by a cassette of a chromosomal gene.

ToxR (RegA) activates Escherichia coli RNA polymerase to initiate transcription of Pseudomonas aeruginosa toxA

The Pseudomonas aeruginosa (Pa) structural gene (toxA), which encodes the exotoxin A protein has been shown to be regulated at the transcriptional level by a protein designated ToxR (also known as RegA). We have previously reported that ToxR directly enhances toxA transcription in vitro; however, in the absence of ToxR, Pa RNA polymerase (RNAP) transcribes toxA with low efficiency. In the present study, we have examined the ability of ToxR to initiate toxA transcription using the heterologous Escherichia coli (Ec) RNAP and found that ToxR can function with Ec RNAP to efficiently transcribe toxA both in vitro and in vivo. Antibodies produced against the sigma 70 subunit of Ec RNAP inhibit ToxR-mediated enhancement of toxA transcription, suggesting that the RNAP holoenzyme (E sigma 70) is required for transcriptional activation of toxA. We further demonstrate that ToxR is required for open-complex formation at the toxA promoter. By selectively deleting toxA upstream sequences, we have localized at 214-bp region containing both the toxA promoter and a putative ToxR-binding site sufficient for ToxR-mediated transcription of toxA.

ToxR (RegA)-mediated in vitro transcription of Pseudomonas aeruginosa toxA

Exotoxin A (ETA) has been described as a major virulence factor produced by the opportunistic pathogen Pseudomonas aeruginosa. The transcription of the ETA structural gene (toxA) has been shown to be positively regulated by the product of the toxR gene (also called regA). However, the mechanism by which ToxR regulates toxA transcription is still under investigation. We have expressed toxR in Escherichia coli under the control of the T7 promoter and purified the wild-type ToxR protein. We have also produced ToxR as a fusion protein consisting of the first 12 amino acids of the T7 capsid protein attached to the N terminus of the intact ToxR protein. In the present study we have developed and used an in vitro transcription assay in order to investigate the mechanism of ToxR-mediated transcriptional regulation of toxA. Under the conditions of this in vitro assay toxA transcription requires the toxR product in addition to P. aeruginosa RNA polymerase (RNAP). Both the native and the T7::ToxR fusion proteins facilitate initiation of toxA transcription in vitro in the presence of Pseudomonas RNAP. Additional studies using (i) specific enzyme-linked immunosorbent assay; (ii) indirect immunoprecipitation; and (iii) gel-filtration chromatography, indicate that ToxR binds to the purified Pseudomonas RNAP and strengthens the possibility that ToxR may be an alternative sigma factor. Furthermore, the ToxR-mediated transcription of toxA is increased approx. threefold in the presence of crude cytoplasmic extracts from P. aeruginosa ToxR+ or ToxR-RegB- strains, indicating that additional factors play a role in the efficient and optimal transcription of toxA.

The vfr gene product, required for Pseudomonas aeruginosa exotoxin A and protease production, belongs to the cyclic AMP receptor protein family

The synthesis of exotoxin A (ETA) by Pseudomonas aeruginosa is a complex, regulated event. Several ETA putative regulatory mutants of P. aeruginosa PA103 have previously been characterized (S. E. H. West, S. A. Kaye, A. N. Hamood, and B. H. Iglewski, Infect. Immun. 62:897-903, 1994). In addition to ETA production, these mutants, PA103-15, PA103-16, and PA103-19, were also deficient in the production of protease and in regA P1 promoter activity. RegA is a positive regulator of ETA transcription. We cloned a gene, designated vfr for virulence factor regulator, that restored ETA and protease production to parental levels in these mutants. In addition, transcription from the regA P1 promoter was restored. In Escherichia coli, when vfr was overexpressed from a phage T7 promoter, a protein with an apparent molecular mass of 28.5 kDa was produced. Analysis of the deduced amino acid sequence of vfr revealed that the expected protein is 67% identical and 91% similar over a 202-amino-acid overlap to the E. coli cyclic AMP receptor protein (CAP or Crp). The cloned vfr gene complemented the beta-galactosidase- and tryptophanase-deficient phenotypes of E. coli RZ1331, a crp deletion mutant. However, the E. coli crp gene under the control of the tac promoter did not complement the ETA-deficient or protease-deficient phenotype of PA103-15 or PA103-16. The ability of vfr to restore both ETA and protease production to these mutants suggests that vfr is a global regulator of virulence factor expression in P. aeruginosa.

Association between transcript levels of the Pseudomonas aeruginosa regA, regB, and toxA genes in sputa of cystic fibrosis patients

In this study, we examined the regulation of exotoxin A (ETA) production by Pseudomonas aeruginosa during chronic lung infections of cystic fibrosis (CF) patients. We used a recently developed technique termed population transcript accumulation in hybridization studies with RNA extracted from sputa. With this technique, we demonstrated that the structural gene for ETA, toxA, as well as two genes encoding positive regulators of ETA synthesis, regA and regB, were expressed in the lungs of CF patients infected with P. aeruginosa. These genes were always expressed together, never alone or in pairs, suggesting coincident expression and a possible regulatory role for regA and regB in this environment. Fluctuations in the levels of the three gene products were observed among samples, consistent with a regulatory phenomenon. The level of regB RNA detected never exceeded that of regA, although the ratio of regA RNA to regB RNA detected did change between samples. These observations are in agreement with in vitro observations which have shown that regB is located 3' to regA in an operon which is expressed from two independently regulated promoters located upstream of regA. The presence of high levels of toxA, regA, and regB RNAs in some sputum samples prompted us to look for hyperproducing-toxin strains in the sputa of CF patients. In vitro, one such strain, 4384, had a transcript accumulation pattern for toxA, regA, and regB similar to that of a laboratory hyperproducer of ETA, strain PA103. These observations suggest that regA and regB are involved in the regulation of ETA production in strains of P. aeruginosa infecting the lungs of CF patients and that some of these strains may regulate ETA production in a manner similar to that of the hyperproducing-ETA strain PA103.

Characterization of Pseudomonas aeruginosa mutants that are deficient in exotoxin A synthesis and are altered in expression of regA, a positive regulator of exotoxin A

In Pseudomonas aeruginosa, production of exotoxin A, an ADP-ribosyltransferase, is a complex and highly regulated process. Two positively acting regulatory genes, regA and regB, have been cloned and characterized. To identify additional exotoxin A regulatory genes, we have characterized four N-methyl-N'-nitro-N-nitrosoguanidine-generated mutants of P. aeruginosa PA103 which are deficient in exotoxin A production. These mutants (PA103-8, PA103-15, PA103-16, and PA103-19) do not accumulate intracellular exotoxin A and are not complemented by the cloned toxA or regAB genes. This observation indicates that the lesion(s) in the mutants is probably in an exotoxin A regulatory gene(s) and is not in the genes for secretion of exotoxin A or in the toxA or regAB genes. To assess the effect of the putative regulatory mutations on the toxA and regAB genes, we compared the activity of the toxA and regAB promoters in the mutant and parental strains using plasmids containing the genes for beta-galactosidase or chloramphenicol acetyltransferase under the control of either the toxA or the regAB promoter. The toxA promoter-beta-galactosidase fusion plasmid could not be maintained in PA103-8. beta-Galactosidase expression driven by the toxA promoter was absent in the mutant PA103-19 and occurred at a low level, which was not repressed by iron in mutants PA103-15 and PA103-16. The regAB genes are temporally controlled by two promoters, P1 and P2. In all four mutants, regAB P1 promoter activity was reduced; however, expression under the control of the regAB P2 promoter was normal. These observations suggest the existence of one or more regulatory genes which directly affect expression of both the toxA and the regAB P1 promoters.

Construction and characterization of chromosomal insertional mutations of the Pseudomonas aeruginosa exoenzyme S trans-regulatory locus

Exoenzyme S is an ADP-ribosyltransferase produced by Pseudomonas aeruginosa. Synthesis of exoenzyme S depends on an intact trans-regulatory locus encoding three protein products, ExsC, ExsB, and ExsA. To identify the phenotype of ExsC, -B, and -A mutants in exoenzyme S production, specific insertional mutations with the streptomycin resistance-encoding omega interposon were introduced into cloned DNA and returned to the chromosomes of P. aeruginosa PA103, PAO1, and PAK. Southern blot analysis was used to confirm insertion of omega and resolution of vector sequences. Exoenzyme S expression was measured in parental and mutant derivatives by Western blot (immunoblot) analysis and ADP-ribosyltransferase activity measurement. A complete set of mutations were obtained in strains PAK and PAO1, but in strain PA103, only an insertion in the exsA coding region was identified. Southern blot analysis demonstrated that extensive duplication and rearrangement of the PA103 chromosomal trans-regulatory locus occurred when exsC::omega or exsB::omega recombination events were attempted. Exoenzyme S antigen was not detectable in the supernatant or lysate fractions of mutant strains by Western blot analysis. ADP-ribosyltransferase activity was detected in the lysate but not in the supernatant fractions of mutant derivatives. The general secretion pathway appeared to function normally in mutant strains, as elastase, exotoxin A, and phospholipase C were measured in the supernatants of parental and mutant strains. Several differences were noted when the extracellular protein profiles of parental strains were compared with similar samples from the insertional mutant strains. Some of these differences appeared to be unrelated to exoenzyme S. These data suggest that insertional inactivation of the exoenzyme S trans-regulatory locus may affect a subset of other extracellular proteins.

Identification of the satA gene encoding a streptogramin A acetyltransferase in Enterococcus faecium BM4145

Enterococcus faecium BM4145, a clinical isolate from urine, was resistant to streptogramin group A antibiotics by inactivation. The strain harbored a plasmid containing a gene, satA, responsible for this resistance; this gene was cloned and sequenced. It encoded SatA, a protein deduced to be 23,634 Da in mass and homologous with a new family of chloramphenicol acetyltransferases described in Agrobacterium tumefaciens, Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureus. The similarity of SatA to other acetyltransferases, LacA (thiogalactoside acetyltransferase) and CysE (serine acetyltransferase) from E. coli, and to two putative acetyltransferases, NodL from Rhizobium leguminosarum and Urf1 from E. coli, was also observed in a region considered to be the enzyme's active site. Acetylation experiments indicated that acetyl coenzyme A was necessary for SatA activity and that a single acetylated derivative of pristinamycin IIA was produced. Other members of the streptogramin A group such as virginiamycin M and RP54476 were also substrates for the enzyme. We conclude that resistance to the streptogramin A group of antibiotics in E. faecium BM4145 is due to acetylation by an enzyme related to the novel chloramphenicol acetyltransferase family.

LasR of Pseudomonas aeruginosa is a transcriptional activator of the alkaline protease gene (apr) and an enhancer of exotoxin A expression

The lasR gene of Pseudomonas aeruginosa is required for transcription of the genes for elastase (lasB) and LasA protease (lasA), two proteases associated with virulence. We report here that the alkaline protease gene (apr) also requires the lasR gene for transcription. Alkaline protease mRNA was absent in the lasR mutant PAO-R1 and present when an intact lasR gene was supplied in trans as determined by Northern (RNA) analysis. The lasR gene also enhances exotoxin A production. Exotoxin A activity in supernatants of PAO-R1 were 30% less than in supernatants of the parental strain, PAO-SR. Multiple copies of lasR in trans in PAO-R1 in increased toxin A activity to twice the parental levels. Analysis of PAO-R1 containing the toxA promoter fused to beta-galactosidase suggests that LasR acts at the toxA promoter or at upstream toxA mRNA sequences. beta-Galactosidase activity was approximately 40% lower in PAO-R1 than in the parental strain, PAO-SR. Furthermore, the effect of LasR on the toxA promoter is not due to the stimulation of transcription of regA, a transcriptional activator of toxA. No difference in chloramphenicol acetyltransferase (CAT) activity was noted between PAO-SR and PAO-R1 containing transcriptional regA promoter-CAT gene fusions. These results broaden the regulatory dominion of lasR and suggest that the lasR gene plays a global role in P. aeruginosa pathogenesis.

The chloramphenicol acetyltransferase gene of Tn2424: a new breed of cat

We have sequenced the gene coding for the chloramphenicol acetyltransferase of Tn2424 of plasmid NR79. This gene codes for a protein of 23,500 Da, and the derived protein sequence is similar to those of the chromosomal chloramphenicol acetyltransferases of Agrobacterium tumefaciens and Pseudomonas aeruginosa and of unidentified open reading frames, which may encode chloramphenicol acetyltransferases, adjacent to the ermG macrolide-lincosamide-streptogramin resistance gene of Bacillus sphaericus and the vgb virginiamycin resistance gene of Staphylococcus aureus. Weaker similarity to the LacA (thiogalactoside acetyltransferase) and CysE (serine acetyltransferase) proteins of Escherichia coli and the NodL protein of Rhizobium leguminosarum is also observed. There is no significant similarity to any other chloramphenicol acetyltransferase genes, such as that of Tn9. The Tn2424 cat gene is part of a 4.5-kb region which also contains the aacA1a aminoglycoside-6'-N-acetyltransferase gene; Tn2424 is similar to Tn21 except for the presence of this region. Sequences flanking the cat gene are typical of those flanking other genes inserted into pVS1-derived "integrons" by a site-specific recombinational mechanism.

Regulation of toxA and regA by the Escherichia coli fur gene and identification of a Fur homologue in Pseudomonas aeruginosa PA103 and PA01

A multicopy plasmid containing the Escherichia coli fur gene was introduced into Pseudomonas aeruginosa strain PA103C. This strain contains a toxA-lacZ fusion integrated into its chromosome at the toxA locus. Beta-galactosidase synthesis in this strain is regulated by iron, as is seen for exotoxin A production. Beta-galactosidase synthesis and exotoxin A production in PA103C containing multiple copies of E. coli fur was still repressed in low iron conditions. The transcription of regA, a positive regulator of toxA, was also found to be inhibited by multiple copies of the E. coli fur gene. In addition, the ability of PA103C containing multiple copies of E. coli fur to produce protease was greatly reduced relative to PA103C containing a vector control. A polyclonal rabbit serum containing antibodies that recognize E. coli Fur was used to screen whole-cell extracts from Vibrio cholerae, Shigella flexneri, Salmonella typhimurium and Pseudomonas aeruginosa. All strains tested expressed a protein that was specifically recognized by the anti-Fur serum. These results and those described above suggest that Fur structure and function are conserved in a variety of distinct bacterial genera and that at least some of these different genera use this regulatory protein to control genes encoding virulence factors.

Effect of regB on expression from the P1 and P2 promoters of the Pseudomonas aeruginosa regAB operon

Exotoxin A production in Pseudomonas aeruginosa is dependent on two regulatory genes, regA and regB, which are located in tandem on the chromosome. Expression of regA and regB is controlled by two promoters (P1 and P2) situated upstream of the regAB locus. We have studied the effect of the regA and regB gene products on transcription from the regAB promoters. Transcriptional and translational fusions, under the control of the P. aeruginosa regA promoters, were used to analyze the regulation of these promoters in a variety of genetic backgrounds. When the regA P1 promoter was supplied in trans to strains lacking expression of regB (PAO1) or lacking transcription of the regAB operon (PA103-29), little activity from the P1 promoter was detected. In contrast, activity from the P2 promoter was not affected in either PAO1 or PA103-29. Sequence analysis of the regAB operon of PA103-29 detected two mutations. One of the mutations is predicted to result in a premature stop codon in the regA open reading frame. We complemented PA103-29 with a construction containing regA and an inactive regB or a construction containing both regA and regB to directly analyze the effect of regB on transcription of the regAB operon. When PA103-29 was complemented with regA but not regB, we could not detect any transcription from the P1 promoter. Complementation of PA103-29 with both regA and regB resulted in a high level of transcription from the P1 promoter and a corresponding early transcriptional activation of toxA. Our results indicated that induction of transcription from the P1 promoter requires the regB open reading frame and thus the regAB operon is autogenously regulated in P. aeruginosa.

Identification of a gene that positively regulates expression of listeriolysin, the major virulence factor of listeria monocytogenes

We have isolated, by molecular cloning and genetic complementation of a listeriolysin-negative mutant, a gene required for the expression of this virulence factor in Listeria monocytogenes. The mutant strain SLCC53, which was nonhemolytic and avirulent, harbored a deletion of 450 base pairs located approximately 1500 base pairs upstream of the listeriolysin gene. No transcripts corresponding to the listeriolysin gene were detected in the mutant. DNA sequencing of this region from the hemolytic strain EGD revealed that the region deleted in the mutant would abrogate expression of a 27-kDa polypeptide. Introduction of a recombinant plasmid expressing this 27-kDa polypeptide restored hemolytic activity to the mutant and increased the hemolytic activity of the wild-type L. monocytogenes strain EGD. We have designated the gene encoding the 27-kDa polypeptide prfA, for positive regulatory factor of listeriolysin (lisA) expression. The prfA gene regulates transcription of the lisA gene positively.

Analysis of the structure-function relationship of Pseudomonas aeruginosa exotoxin A

Biochemical and genetic techniques have provided considerable insight into the structure-function relationship of one of the ADP-ribosyl transferases produced by Pseudomonas aeruginosa, exotoxin A. Exotoxin A contains a typical prokaryotic signal sequence which, in combination with the first 30 amino-terminal amino acids of the mature protein, is sufficient for exotoxin A secretion from P. aeruginosa. Determination of the nucleotide sequence and crystalline structure of this prokaryotic toxin allowed a molecular model to be constructed. The model reveals three structural domains of exotoxin A. Analysis of the identified domains shows that the amino-terminal domain (domain I) is involved in recognition of eukaryotic target cells. Furthermore, the central domain (domain II) is involved in secretion of exotoxin A into the periplasm of Escherichia coli. Evidence also implicates the role of domain II in translocation of exotoxin A from the eukaryotic vesicle which contains the toxin after it becomes internalized into susceptible eukaryotic cells via receptor-mediated endocytosis. The carboxy-terminal portion of exotoxin A (domain III) encodes the enzymatic activity of the molecule. The structure of this domain includes a cleft which is hypothesized to be the catalytic site of the enzyme. Several residues within domain III have been identified as having a direct role in catalysis, while others are hypothesized to play an important structural role.