Regulation of rpoS Gene Expression in Pseudomonas: Involvement of a TetR Family Regulator

doi:10.1128/JB.183.12.3712-3720.2001

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Journal of Bacteriology, June 2001, p. 3712-3720, Vol. 183, No. 12
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.12.3712-3720.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Regulation of rpoS Gene Expression in Pseudomonas: Involvement of a TetR Family Regulator

Milan Kojic and Vittorio Venturi^*

Bacteriology Group, International Centre for Genetic Engineering and Biotechnology, 34012 Trieste, Italy

Received 5 September 2000/Accepted 20 March 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The rpoS gene encodes the sigma factor which was identified in several gram-negative bacteria as a central regulator duringstationary phase. rpoS gene regulation is known to respond tocell density, showing higher expression in stationary phase. ForPseudomonas aeruginosa, it has been demonstrated that the cell-density-dependentregulation response known as quorum sensing interacts with thisregulatory response. Using the rpoS promoter of P. putida, weidentified a genomic Tn5 insertion mutant of P. putida which showeda 90% decrease in rpoS promoter activity, resulting in less RpoSbeing present in a cell at stationary phase. Molecular analysisrevealed that this mutant carried a Tn5 insertion in a gene, designatedpsrA (Pseudomonas sigma regulator), which codes for a protein(PsrA) of 26.3 kDa. PsrA contains a helix-turn-helix motif typicalof DNA binding proteins and belongs to the TetR family of bacterialregulators. The homolog of the psrA gene was identified in P.aeruginosa; the protein showed 90% identity to PsrA of P. putida.A psrA::Tn5 insertion mutant of P. aeruginosa was constructed.In both Pseudomonas species, psrA was genetically linked to theSOS lexA repressor gene. Similar to what was observed for P. putida,a psrA null mutant of P. aeruginosa also showed a 90% reductionin rpoS promoter activity; both mutants could be complementedfor rpoS promoter activity when the psrA gene was provided intrans. psrA mutants of both Pseudomonas species lost the abilityto induce rpoS expression at stationary phase, but they retainedthe ability to produce quorum-sensing autoinducer molecules. PsrAwas demonstrated to negatively regulate psrA gene expression inPseudomonas and in Escherichia coli as well as to be capable ofactivating the rpoS promoter in E. coli. Our data suggest thatPsrA is an important regulatory protein of Pseudomonas spp. involvedin the regulatory cascade controlling rpoS gene regulation inresponse to celldensity.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The rpoS gene codes for sigma factor RpoS (also called $sigma$ ^s and $sigma$ ³⁸) (12, 18), which was identified as a central regulator duringstationary phase in Escherichia coli; this factor is involvedin the survival of famine conditions and in cross-protection againstosmotic, acidic, oxidative, and heat stresses (19, 22). Sincethen, it has been identified in various gram-negative bacteria,including several species belonging to the fluorescent pseudomonads;these findings demonstrate that in these bacteria as well thisfactor has an important regulatory role, including adaptationto nutrient-limiting conditions, survival in the presence of severalenvironmental stresses, and the production of virulence factors(16, 17, 34, 37, 42, 43).

RpoS is an alternative sigma factor, resulting in the alteration of RNA polymerase core specificity and thereby switchinggene expression at stationary phase. The levels of RpoS withina bacterial cell are carefully controlled, since perturbationsin the relative amounts can have severe consequences. Thus, theregulation of RpoS levels is of crucial importance (8). InE. coli, the levels of RpoS are extremely low in exponential growthphase but increase markedly upon entry into stationary phase (15).The regulation of RpoS in E. coli remains a subject of extensiveinvestigation, since regulation occurs at the transcriptional,posttranscriptional, and protein levels (6, 13, 20). Atthe transcriptional level, it has been observed that in rich mediathere is a considerable increase in transcription at the transitionto stationary phase and that the cyclic AMP-cyclic AMP receptorprotein complex is involved either directly or indirectly in thisregulation. However, RpoS levels in E. coli appear to be regulatedmainly at the posttranscriptional level through susceptibilityto proteolysis. RpoS is rapidly degraded by the ClpXP protease(29, 38); this degradation absolutely requires the phosphorylatedform of a two-component response regulator called SprE or RssB(33), which in turn is modulated by a LysR regulatory familyprotein called LrhA (13). It is still unclear which signalsand effector molecules trigger the regulators responsible forthe regulation of this RpoSproteolysis.

The regulation of rpoS in Pseudomonas has also been addressed recently. The cell-cell communication device, called quorumsensing (10), used by gram-negative bacteria to regulate severalphysiological processes has been demonstrated to be involved inthe control of rpoS transcription in Pseudomonas aeruginosa (21).There are at least two chemically and genetically independentquorum-sensing systems in P. aeruginosa, designated the LasR-LasIand the RhlR-RhlI systems, each having a cognate N-acylhomoserinelactone (AHL) (21); these systems are involved in the regulationof a large number of exoproducts in response to cell density.It has been reported that the LasR-LasI elements regulate theactivation at the transcriptional level of the RhlR-RhlI system,which then directs the regulation of rpoS transcription, resultingin RpoS accumulation in response to cell density (21). A recentstudy, however, reports that RpoS regulates rhlI transcription(45); thus, RpoS and the quorum-sensing system in P. aeruginosaare part of the same regulatory network. Future work is requiredto precisely define the molecular events leading to rpoS regulation.In P. fluorescens Pf-5, the GacS-GacA two-component regulatorysystem positively influences rpoS expression (44). This two-componentsystem is well conserved in Pseudomonas spp. and regulates theproduction of several secondarymetabolites.

The rpoS gene of P. putida WCS358 has been identified (17). In this study, we used rpoS-reporter gene transcriptional fusionsto identify a Tn5 mutant of strain WCS358 that had considerablyreduced rpoS expression. This mutant had a Tn5 insertion in aregulatory gene (designated psrA) coding for a protein (designatedPsrA) belonging to the TetR regulatory family. A homolog of thisgene in P. aeruginosa encodes a protein having 90% identity withPsrA of P. putida. This gene was inactivated by transposon mutagenesisand homologous recombination; the resulting mutant also showeda 90% reduction in rpoS promoter activity. Our data suggest thatin Pseudomonas spp., psrA plays an important role in rpoSexpression.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Strains, plasmids, media, and chemicals. The strains used in this study included E. coli HB101 (35), DH5 $alpha$ (14), and XL1-Blue (4); P. putida WCS358, a plant-growth-promotingstrain isolated from the rhizosphere of potato roots (11); P.aeruginosa PAO1 (Holloway collection); and Chromobacterium violaceumCVO26, a double mini-Tn5 mutant derived from ATCC 31532. Thismutant is nonpigmented, and production of the purple pigment canbe induced by providing exogenous AHL inducer molecules (27).E. coli and P. aeruginosa PAO1 were grown in LB medium (28)at 37°C, whereas P. putida WCS358 was cultured in LB medium orin M9 minimal medium (35) at 30°C. The following antibioticconcentrations were used: tetracycline, 10 µg/ml (E. coli), 40µg/ml (strain WCS358), and 300 µg/ml (PAO1); kanamycin, 100 and300 µg/ml (PAO1); ampicillin, 100 µg/ml; nalidixic acid, 25 µg/ml;chloramphenicol, 25 µg/ml (E. coli), 250 µg/ml (strain WCS358),and 500 µg/ml (PAO1); and gentamicin, 10 µg/ml (E. coli), 40 µg/ml(strain WCS358), and 60 µg/ml (PAO1). The plasmids used in thisstudy are listed in Table 1.

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TABLE 1. Plasmids used

The rpoS promoter transcriptional fusions were constructed as follows. First, a 135-bp fragment consisting of the $-$ 9 to $-$ 144DNA region, where position 0 is the ATG codon of the rpoS geneof P. putida WCS358 (17), was cloned into promoter probe vectorpMP220 by making use of two synthetic oligonucleotides (5'-CCTTTGCTGCAGTTCGAACTCAGA-3'and 5-'CCCGTGGATCCACTCCAGTTCCTG-3'). One oligonucleotide had aPstI restriction site inserted and the other had a BamHI site,and they were cloned into the BglII and PstI sites in pMP220 toyield pRPO220A. Second, a HindIII-AatII DNA fragment of 962 bpobtained from plasmid pH3.5 and containing 920 bp of DNA upstreamof the ATG of the rpoS gene of strain WCS358 (17) was end filledand cloned into the SmaI site of pUC18 to yield pMK962. pMK962was then digested with BamHI and KpnI, and the 974-bp fragmentwas cloned into pMP220 and pMP77, both digested with BglII andKpnI, to yield pRPO220B and pRPO77,respectively.

Plasmid pPSRPAO1 harbors a 2.2-kb fragment of PAO1 genomic DNA. It was constructed by amplifying by PCR, using the PAO1 genomeas a template and two oligonucleotides (5'-ACCTTGCTGAATTCGCGCTTGAAGCG-3'and 5'-CGCCACATGGGAATTCGGCCTCGGCC-3'), a 2.2-kb fragment locatedat positions 3368363 to 3370563 in the PAO1 genome (www.pseudomonas.com).This fragment was cloned as an EcoRI (the two oligonucleotidesused harbored EcoRI restriction sites) fragment of pBluescriptto yieldpPSRPAO1.

The psrA promoter was cloned into promoter probe vector pMP220 as follows. An XmnI-SacII fragment of 435 bp (Fig. 1) containingthe psrA promoter was blunted by end filling and cloned into theSmaI site of pUC18 to generate pPPSR18. The promoter was thenremoved as a BamHI-KpnI fragment and cloned into BglII-KpnI-digestedpMP220 to yield pPPSR220. The psrA gene was cloned into expressionvector pQE30 as follows. The gene was amplified by PCR using twooligonucleotides (psrA-BamHI-start, 5'-GGAATAATCGGATCCCAATCGGAAACCG-3',and psrA-HindIII-end, 5'-GCGCAAGCTTAGCCGAAGCGCCCTGCCCC-3') andcloned as a BamHI-HindIII fragment into the corresponding sitesof pQE30, yielding pQEPSRA and resulting in psrA being in framewith the six histidines. The P. putida WCS358 rpoS gene was clonedinto expression vector pQE31 as follows. The gene was amplifiedby PCR using two oligonucleotides (rpoS-BamHI-start, 5'-CTATAACAATGGATCCCAATAAAGAAGCGCC-3'and rpoS-HindIII-end, 5'-GTCTTAAGCTTGCGAACAGCGTATTACTGG-3') andcloned as a BamHI-HindIII fragment into the corresponding sitesof pQE31, yielding pQERPOS.

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FIG. 1. Strategy for construction of rpoS-lacZ and rpoS-xylE transcriptional fusions. The genetic map shows the location of rpoS in the P. putida WCS358 genome, as described by Kojic et al. (17). Plasmid constructs pRPO220A and pRPO220B are derivatives of promoter probe vector pMP220. pRPO77 is derived from pMP77 (see the text for details). Also shown is whether the transcriptional fusion had promoter activity, as detected using the reporter gene. Plasmid construct pRPO220A contains the rpoS-nlpD intergenic region cloned upstream of a promoterless lacZ gene. Plasmid constructs pRPO220B and pRPO77 contain the indicated 962-bp fragment cloned upstream of promoterless lacZ and xylE genes, respectively (see the text for details).

Recombinant DNA techniques. Digestion with restriction enzymes, agarose gel electrophoresis, purification of DNA fragments, ligation with T4 DNA ligase,end filling with the Klenow fragment of DNA polymerase, Southernhybridization, transformation of E. coli, and sodium dodecyl sulfate-polyacrylamidegel electrophoresis analysis were performed as described by Sambrooket al. (35). Analytical amounts of plasmids were isolated asdescribed by Birnboim (3), whereas preparative amounts werepurified with Qiagen columns. Total DNA from Pseudomonas was isolatedby Sarkosyl-pronase lysis as described by Better et al. (2).Triparental matings from E. coli to Pseudomonas were performedwith an E. coli(pRK2013) helper strain (9). The DNA sequenceflanking transposon mutant P. putida MT17 was determined usingarbitrary PCR. In this procedure, the DNA flanking the Tn5 insertionsite was enriched in two rounds of amplification using primersspecific to the ends of the Tn5 element and primers of randomsequence which annealed to chromosomal sequences flanking thetransposon as described by O' Toole and Kolter (31).

Protein expression, analysis, and purification and antibodies against PsrA and RpoS. Expression and purification of His₆-PsrA (pQEPSRA) and His₆-RpoS (pQERPOS) were carried out with E. coli M15(pREP-4) accordingto the instructions of the supplier (Qiagen, Hilden, Germany).Proteins were transferred to a polyvinylidene difluoride (PVDF)membrane (Immobilon-P; Millipore Corp.) using a tank system accordingto the manufacturer's instructions. The membrane was subjectedto Western blot analysis using polyclonal antibodies against eitherRpoS or PsrA. After incubation with the secondary horseradishperoxidase-labeled antibody, the proteins were detected with 3-3'-diaminobenzidinetetrahydrochloride tablets (Sigma, St. Louis, Mo.). Antibodiesagainst PsrA and RpoS were produced in rabbits by injecting thepurified protein. No significant cross-reaction was observed inthisstudy.

Reporter gene fusion assays; purification, detection, and visualization of autoinducer molecules; pyocyanin quantification; and stress response assays. $beta$ -Galactosidase activity was determined essentially as described by Miller (28) with the modifications of Stachel et al.(40). The purification, detection, and visualization of AHLinducer molecules from culture supernatants were performed essentiallyas described by McClean et al. (27) and Kojic et al. (17).C. violaceum CVO26 and E. coli(pSB1075) were used as the indicatorstrains for C₄-homoserine lactone (HSL) and 3-oxo-C₁₂-HSL, respectively,on thin-layer chromatography plates to detect the presence ofAHL molecules (27, 46). As controls, chemically synthesizedC₄-HSL and 3-oxo-C₁₂-HSL (kindly donated by P. Williams) wereused. Pyocyanin production was measured as described by Essaret al. (7) The measurement of cell viability to survive heatstress and osmotic stress and sensitivity to hydrogen peroxidewere determined as described by Kojic et al. (17).

Identification of rpoS regulatory mutants and their complementation with a WCS358 gene bank. About 200 cells per plate of a Tn5 mutant bank of strain WCS358 (26), harboring promoter fusion pRPO77, were spread on LBplates containing kanamycin (100 µg/ml) and chloramphenicol (250µg/ml). These plates were incubated for 2 days at 30°C beforebeing sprayed with a 0.1 M catechol solution. Colonies with adecrease in yellow color were purified and further studied. Tn5mutants which had reduced promoter activity were complementedfor promoter activity as follows. About 4 × 10⁹ cells each of E. coli HB101 harboring the P. putida WCS358 genebank in pLAFR3 and E. coli(pRK2013) and 2 × 10⁸ cells of mutant MT17(pRPO77) were mixed, and the suspension wasapplied to a 0.45-µm-pore-size membrane filter (Millipore) onan LB plate. The plate was incubated overnight at 30°C beforethe cells were resuspended and plated on LB plates containingnalidixic acid (25 µg/ml), ampicillin (100 µg/ml), kanamycin (100µg/ml), chloramphenicol (250 µg/ml), and tetracycline (40 µg/ml).These plates were incubated for 2 days at 30°C, and the cellswere resuspended and pooled. About 100 cells were spread on LBplates containing chloramphenicol (250 µg/ml), kanamycin (100µg/ml), and tetracycline (40 µg/ml). These plates were incubatedat 30°C for 2 days before being sprayed with a 0.1 M catecholsolution. Transconjugants that turned yellow were purified andfurtherassayed.

Construction of a psrA mutant of P. putida WCS358. Transposon Tn5 insertions within recombinant plasmid pBS25 were obtained as described by Magazin et al. (25) with E. coliHB101::Tn5 as the source of the transposon. E. coli HB101 cellscontaining Tn5 insertions within plasmid pBS25 were identifiedby purifying plasmid DNA from HB101::Tn5(pBS25), using it to transformE. coli DH5 $alpha$ , and selecting for plasmids having ampicillin andkanamycin resistance. Transposon insertions in the psrA gene ofP. putida were then mapped by restriction and Southern analysesand DNA sequencing using a Tn5-based primer (5'-GAACGTTACCATGTTAGGAGGTC-3').One Tn5 insertion in the psrA gene in pBS25 was identified (theplasmid was designated pBS25::Tn5R) and was located 428 bp downstreamof the putative ATG codon of the P. putida psrA gene (see Fig.3A). This Tn5 insertion in pBS25 was transferred to the psrA geneharbored in pCOS17 by homologous recombination in the followingway. pBS25::Tn5 was used to transform HB101(pCOS17), and the resultingconstruct, HB101(pCOS17)(pBS25::Tn5), was grown overnight. Theculture was used for a triparental conjugation into P. putidaWCS358 with E. coli(pRK2013) as a helper. After appropriate selection,pCOS17::Tn5R was selected. It was verified that Tn5 had been transferredby double-crossover homologous recombination from pBS25::Tn5 topCOS17. Plasmid pCOS17::Tn5 was then used in a marker exchangetechnique (5) in order to introduce insertion mutations sitespecifically with the psrA gene of P. putida; in this experiment,pPH1JI was used as the incoming incompatible plasmid as previouslydescribed (1). The fidelity of the marker exchange event inthe P. putida psrA::Tn5 mutant was confirmed by Southern analysis(data not shown). This mutant was designated P. putidaM17R.

Construction of a psrA::Tn5 mutant of P. aeruginosa PAO1. Transposon Tn5 insertions within recombinant plasmid pPSRPAO1 were obtained as described by Magazin et al. (25) with E.coli HB101::Tn5 as the source of the transposon as described above.One Tn5 insertion in the psrA gene in pPSRPAO1 was identified(the plasmid was designated pPSRPAO::Tn5) and was located 478bp downstream of the putative ATG codon of the PAO1 psrA gene.Plasmid pPSRPAO1::Tn5 was digested with EcoRI, and the 8-kb fragmentharboring the 2.2-kb EcoRI fragment of PAO1 DNA with a Tn5 insertionwas cloned into the corresponding site of pLAFR3 to yield pPSRE8.This plasmid was conjugated into P. aeruginosa PAO1 and used ina marker exchange technique (5) in order to introduce insertionmutations site specifically with the psrA gene of P. aeruginosaPAO1 (1). The fidelity of the marker exchange event in thePAO1 psrA::Tn5 mutant was confirmed by Southern analysis (datanotshown).

DNA sequence determination and analysis. DNA segments of various sizes were created from plasmid pBS25 using a nested deletion kit (Amersham-Pharmacia). These constructswere either encapsidated as single-stranded DNA upon infectionwith helper phage VCSM13 (Stratagene Co.) or used directly forDNA sequencing. Nucleotide sequences were determined by the dideoxychain termination method (36) using [ $alpha$ -³⁵S]dATP for labeling and 7-deaza-dGTP (Amersham-Pharmacia) insteadof dGTP. The DNA fragments were separated with a Bio-Rad electrophoresiskit. The nucleotide sequences presented here were determined inboth orientations and across all restrictionsites.

Nucleotide sequence accession number. The GenBank/EMBL/DDBJ accession number for the sequence reported in this paper is AJ293485.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Isolation and characterization of P. putida WCS358 regulatory mutants affected in rpoS expression. Two transcriptional fusions were constructed using the P. putida WCS358 rpoS promoter and a promoterless lacZ gene as describedin Materials and Methods (Fig. 1). The first fusion (pRPO220A)contained a 135-bp fragment of the rpoS promoter starting from9 bp upstream of the ATG and reaching 17 bp away from the stopcodon of the nlpD gene, which is located upstream and transcribedin the same orientation as the rpoS gene (Fig. 1). The secondfusion (pRPO220B) contained 920 bp upstream of the ATG codon,as depicted in Fig. 1. The first fusion did not show any $beta$ -galactosidaseactivity; thus, there was no promoter element in the nlpD-rpoSintergenic region. However, the second, larger construct displayedsignificant promoter activity, demonstrating that the rpoS promoterwas contained in this fragment within the nlpD gene (Fig. 1).This same fragment was cloned in promoter probe vector pMP77,yielding pRPO77 (Fig. 1), which contained a promoterless xylEgene. This procedure provided a convenient plate assay for detectingpromoter activity compared to the more sensitive detection of $beta$ -galactosidaseactivity.

A transposon Tn5 insertion mutant bank of P. putida strain WCS358 harboring promoter fusion pRPO77 was assayed for promoteractivity. With this construct, promoter activity can be convenientlydetected on plates by assaying for the xylE gene product, catechol2,3-dioxygenase (XylE), which converts catechol to a yellow product.Bacterial colonies exhibiting promoter activity become yellowwhen sprayed with a catechol solution. Ten thousand mutants werescreened, and 1 mutant, designated MT17, showed very little yellowcoloration after being sprayed with a catechol solution. In orderto confirm the reduced rpoS promoter activity, plasmid pRPO77was cured from mutant MT17 by growth for several generations inthe absence of antibiotics and then selection for a chloramphenicol-sensitivecolony. pRPO77 was then conjugated into the mutants, and it wasreconfirmed that MT17(pRPO77) displayed less yellow color thanwild-type WCS358(pRPO77) when sprayed with a catecholsolution.

The activity of the rpoS promoter was quantified in mutant MT17 after the introduction of plasmid pRPO220B. This plasmid containsthe same promoter as pRPO77 but cloned upstream of a promoterlesslacZ gene, providing a more convenient way to quantify promoteractivity through assaying for $beta$ -galactosidase activity. The rpoSpromoter showed strong activity in parent strain WCS358, whereasin mutant strain MT17 it displayed only 10% the activity shownin parent strain WCS358 (Fig. 2). It was concluded that mutantMT17 had a Tn5 insertion in a locus affecting rpoS gene expression.

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FIG. 2. $beta$ -Galactosidase activities. (A) $beta$ -Galactosidase activities driven by the rpoS-lacZ fusion pRPO220B. All measurements were done in triplicate; the mean and standard error are shown. Cells harboring plasmids were grown for 16 h in LB medium in the presence of appropriate antibiotics. P. putida MT17 is a psrA null mutant of parent strain WCS358, P. putida MT17R is also a psrA null mutant, and P. aeruginosa MKV8 is a psrA null mutant of parent strain PAO1. Plasmid pRPO220B (IncP; Tc^r) is an rpoS-pacZ transcriptional fusion, whereas pMKP25 (IncQ; Cm^r) harbors a 2.5-kb PstI insert of P. putida WCS358 DNA carrying the complete psrA gene. (B) $beta$ -Galactosidase activities driven by the psrA-lacZ fusion pPPSR220. Cells harboring plasmids were grown for 16 h in LB medium in the presence of appropriate antibiotics. See the text for details. Columns: a, P. putida WCS358(pRPO220B); b, P. putida MT17(pRPO220B); c, P. putida MT17(pRPO220B)(pMKP25); d, P. aeruginosa PAO1(pRPO220B); e, P. aeruginosa MKV8(pRPO220B); f, P. aeruginosa MKV8(pRPO220B)(pMKP25); g, P. putida MT17R(pRPO220B); h, P. putida MT17R(pRPO220B)(pMKP25); i, P. putida WCS358(pMP220); j, P. putida WCS358(pPPSR220); k, P. putida rpoS::Tn5 WCS358(pPPSR220); l, P. putida MT17(pPPSR220); m, P. putida MT17R(pPPSR220); n, P. putida WCS358(pMP220).

Complementation of P. putida MT17 Tn5 regulatory mutants. A gene bank containing partially digested HindIII chromosomal DNA fragments of strain WCS358 cloned in the corresponding sitein cosmid vector pLAFR3 was introduced into the regulatory mutants.The transconjugants were complemented for the restoration of thepromoter activity of plasmid pRPO77 as described in Materialsand Methods. Two cosmids, pCOS17 and pCOS18, were isolated thatcomplemented mutant MT17 for promoter activity. Restriction analysisrevealed that pCOS17 and pCOS18 shared a 10-kb HindIIIfragment.

A portion of the DNA sequence flanking Tn5 was cloned using an arbitrary PCR method as described in Materials and Methods.This allowed the cloning into pUC18 of a 680-bp fragment (pAPC17)flanking Tn5 in mutant MT17. This fragment was sequenced and usedas a probe in Southern analysis, which allowed the localizationof the complementing region within the 10-kb HindIII fragmentof pCOS17 and pCOS18. This 10-kb HindIII fragment was cloned intothe corresponding site in pBluescript to yield pBSH10. Furthermapping using the 680-bp PCR fragment from pAPC17 as a probe revealedthat within the 10-kb HindIII fragment, a 5-kb EcoRI fragmentand a 2.5-kb PstI fragment contained the DNA flanking the Tn5transposon in mutant MT17. Both of these fragments were clonedinto the corresponding site in vector pLAFR3, yielding pLM17Eand pLM17P, respectively, and were conjugated into P. putida MT17(pRPO77).Both of these subclones restored rpoS promoter activity (datanot shown). The 2.5-kb PstI fragment was also cloned into theIncQ plasmid pMP77 to yield pMKP25, which was transferred to P.putida MT17(pRPO220B); this procedure restored wild-type levelsof rpoS promoter activity, as detected by $beta$ -galactosidase activity(Fig. 2). It was concluded that the 2.5-kb PstI fragment couldcomplement the mutant and contained all the necessary informationto restore rpoS promoter activity in mutantMT17.

Characterization of the complementing DNA. The 2.5-kb PstI fragment from pCOS17 and pCOS18 (i.e., construct pBS25) was sequenced in both directions (GenBank accessionnumber AJ293485). The genetic map of the region is presentedin Fig. 3A. Tn5 in mutant MT17 was inserted within an open readingframe (ORF) of 714 bp and coding for a putative protein of 237amino acids and having a predicted molecular mass of 26,359 Da(Fig. 3B). The precise position of the Tn5 insertion in P. putidaMT17 was 178 bp downstream of the putative ATG of this ORF. Thegene representing this ORF was designated psrA (Pseudomonas sigmaregulator). Western analysis using anti-PsrA antibodies revealedthat mutant MT17 no longer produced PsrA (Fig. 4). This ORF waspreceded by a potential Shine-Dalgarno sequence and was located216 bp upstream of and in the orientation opposite that of thefirst codon of the lexA gene (GenBank accession number AJ293485).The LexA repressor protein identified here displayed a high levelof identity to the characterized LexA proteins of other gram-negativebacteria (data not shown).

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FIG. 3. Gene map and protein sequence alignments. (A) Genetic organization of the region (PstI fragment; see text for details) containing the psrA regulatory gene in P. putida WCS358. Shown is the Tn5 insertion position located in mutant MT17. Also shown is the Tn5 insertion (shown as Tn5-R) located in the regenerated psrA mutant, designated MT17R. The DNA sequence of this 2.5-kb fragment can be found in GenBank accession number AJ293485. (B) (i) Protein sequence alignment, using the one-letter code, of the first 60 amino acids of PsrA, a TetR regulator of V. parahaemolyticus (V.para) (GenBank accession number Q56726), and IfeR of A. tumefaciens (GenBank accession number O68442). (ii) Protein sequence alignment, using the one-letter code, of the PsrA proteins from P. putida (PsrA) and P. aeruginosa (PsrA*) (this study). In bold are shown the amino acids which constitute the TetR family signature pattern (Prosite accession number PS01081). A star indicates conservation of identical amino acids, a colon indicates a conserved substitution, and a period indicates a semiconserved substitution.

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FIG. 4. $beta$ -Galactosidase activities and Western analyses. (A) Growth and $beta$ -galactosidase ( $beta$ -Gal.) activities of P. putida WCS358(pRPO220B), psrA null mutant MT17(pRPO220B), and MT17(pRPO220B)(pMKP25). The values were determined with LB medium, and the means of triplicate experiments are shown. OD₆₀₀, OD at 600 nm. (B) Cellular RpoS levels of overnight cultures (OD, 2.3) of P. putida WCS358 (lane 1), P. putida MT17 (lane 2), P. putida MT17(pMKP25) (lane 3), rpoS:: Tn5 P. putida (lane 4), purified His₆-RpoS (lane 5), and prestained molecular mass markers (lane 6). Immunoblot analysis was performed with 30 µg of total cellular protein per lane, 20 ng of purified His₆-RpoS (lane 5), and anti-RpoS antibodies. (C) Cellular PsrA levels of overnight cultures (OD, 2.4) of P. putida MT17 (lane 1), P. putida MT17(pMKP25) (lane 2), P. putida WCS358 (lane 3), and purified His₆-PsrA (lane 4). Immunoblot analysis was performed with 30 µg of total cellular protein per lane, 20 ng of purified His₆-PsrA (lane 4), prestained molecular mass markers (lane 5), and anti-PsrA antibodies.

Regeneration of the psrA::Tn5 mutant of P. putida WCS358. In order to unequivocally confirm that the psrA gene alone was responsible for the phenotype in mutant MT17, this gene wasinsertionally inactivated in P. putida WCS358 as described inMaterials and Methods. In the regenerated psrA null mutant, rpoSpromoter activity was reduced by 90%, just as in P. putida MT17,as identified by genetic selection. It was concluded that theORF coding for the PsrA protein was responsible for the phenotypeof reduced rpoS geneexpression.

PsrA belongs to the TetR family of bacterial regulators. A computer-assisted homology search between PsrA and proteins deposited in data banks revealed significant homology to bacterialregulators belonging to the TetR family (Prosite accession numberPS01081). Many of the proteins of this family appear to be repressors,and their targets are often genes encoding proteins involved incell envelope permeability. They have similar molecular masses(from 21 to 27 kDa). As a signature pattern, there is a conservedregion that starts four residues before the helix-turn-helix motifand ends six residues after it and that is located near the Nterminus. For PsrA, the signature is between amino acids 10 and56, as depicted in Fig. 3B. The two proteins which displayed thehighest level of identity to PsrA were a 175-amino-acid TetR regulatorof Vibrio parahaemolyticus (30), showing 40% identity, and aregulator called IfeR (207 amino acids) of Agrobacterium tumefaciens(32), showing 34% identity. Both of these regulators are geneticallylinked to operons encoding efflux pumps. An alignment of the first60 amino acids of PsrA with these two proteins is depicted inFig. 3B. Apart from these proteins, PsrA displayed significantidentity in the first 60 amino acids (approximately 30%) to 18putative TetR family regulators (data not shown). We have founda similar gene upstream of the lexA gene in P. aeruginosa (www.pseudomonas.com);the genetic organization is like that in P. putida. This putativegene codes for a protein which is 90% identical to PsrA (Fig.3B); it has not been characterized but has been identified throughsequencing of the P. aeruginosa genome (seebelow).

Growth phase dependence of rpoS expression in P. putida The growth phase dependence of rpoS expression was assessed using the pRPO220B rpoS-lacZ fusion (Fig. 4). Expression was relativelyconstant during early and exponential growth and then increasedapproximately fivefold in late exponential and early stationaryphases. In psrA::Tn5 mutant MT17, rpoS expression was low throughoutgrowth. The induction observed in the parent strain was not detected;rpoS expression was approximately 10% that seen in strain WCS358(Fig. 4). P. putida MT17 harboring psrA in plasmid pMKP25 regainedpromoter activity and inducibility in response to celldensity.

The psrA gene of P. aeruginosa is also involved in rpoS gene expression. To investigate the role of the putative psrA gene of P. aeruginosa PAO1, we insertionally inactivated this locus in P. aeruginosa.A psrA null mutant was constructed and designated P. aeruginosaMKV8. Similar to what was observed for P. putida WCC358, a 90%reduction in rpoS promoter activity was observed in the mutantstrain relative to the wild-type strain (Fig. 2). This reductionin promoter activity was restored when the P. putida psrA geneharbored in pMKP25 was introduced in trans into P. aeruginosaMKV8(pRPO220B) (Fig. 2). It was concluded that this gene alsoplays a role in rpoS gene expression in P. aeruginosa.

Phenotype of the Pseudomonas psrA::Tn5 mutants. RpoS is known to confer cross-protection against heat and osmotic shock as well as hydrogen peroxide. It was reported thatP. putida WCS358 containing rpoS::Tn5 was more sensitive to thesethree environmental stresses (17). When stationary-phase culturesof mutant MT17 were exposed to a sudden shift in temperature from30 to 50°C, it was found to be twofold more sensitive at 50°Cthan the parent strain (data not shown). Similarly, when mutantMT17 was subjected to an increase in osmotic pressure caused bythe addition of a high concentration of salt, the mutant was almosttwofold more sensitive than strain WCS358 (data not shown). Wealso tested protection against hydrogen peroxide. In exponentiallygrowing cells, there was no difference in sensitivity betweenthe psrA mutant and the parent strain; however, in stationary-phasecells, the zone of inhibition was approximately 10% larger (datanot shown), most probably due to a decrease in catalase activity(42).

It was reported that in P. aeruginosa, RpoS negatively regulates the production and secretion of pyocyanin pigment (42),the rpoS mutants showing a clear dark-blue coloration comparedto the wild type. The psrA mutants of P. aeruginosa PAO1 alsodisplayed a dark-blue coloration compared to the wild type. Therefore,we determined pyocyanin production in P. aeruginosa MKV8 and inPAO1 and found that the psrA mutant produces 2.5-fold more pyocyaninthan the wild type (data notshown).

Finally, we examined levels of RpoS proteins in 24-h-old stationary-phase cultures of P. putida WCS358 and the psrA knockoutP. putida MT17 using anti-RpoS antibodies. As depicted in Fig.4, RpoS levels in P. putida MT17 were significantly lower thanthose in the wild type and the complemented mutant. Using a densitometer(Pharmacia LKB Ultroscan), we determined that RpoS levels in overnightcultures of the psrA mutant were approximately 50% those in parentstrain WCS358 or the complemented mutant (Fig. 4).

Pseudomonas psrA mutants produce autoinducer molecules. In P. aeruginosa, quorum sensing was implicated in rpoS gene expression and/or vice versa (21, 45). We tested the productionof autoinducer (AHL) molecules in the psrA null mutant of P. aeruginosa.P. aeruginosa PAO1 synthesized the two identified and characterizedAHLs, namely, N-3-oxododecanoyl-L-homoserine lactone, encodedby the lasI gene, and N-butanoyl-L-homoserine lactone, encodedby the rhlI gene, as detected by violacein production with thebiosensor C. violaceum CVO26 and by light production with E. coli(pSB1075),respectively. AHL molecules were purified in a volume correspondingto 5 × 10⁸ CFU at optical densities (ODs) of 0.1, 0.2, 0.4, 0.8, 1.2, 1.6,2, and 2.5 from culture supernatants of P. aeruginosa PAO1 andthe psrA mutant P. aeruginosa MKV8 grown on LB plates. The purifiedextracts were placed on thin-layer chromatography plates and overlaidwith the bacterial sensor. No significant differences were observedfor the psrA mutant P. aeruginosa MKV8 (data not shown). It waspreviously reported that P. putida WCS358 produces at least threedifferent autoinducer molecules, as detected using the biosensorCVO26 (17). Purifying autoinducer molecules from spent supernatantsof P. putida WCS358 and P. putida MT17R revealed that in the psrAnull mutant, there was no difference in the production of thesemolecules. It was concluded that PsrA of P. aeruginosa and P.putida does not play a major role in the regulation of autoinducerbiosynthesis.

psrA is autoregulated. In order to establish whether PsrA regulated its own synthesis, the promoter of psrA fused to a promoterless $beta$ -galactosidasegene in construct pPPSR220 was introduced into wild-type strainWCS358, psrA mutant MT17, and WCS358 containing rpoS::Tn5 (rpoSmutant) (17). As depicted in Fig. 2, in mutant MT17 psrA geneexpression was considerably increased (approximately fourfold),indicating that PsrA had a negative effect on its own synthesis.No difference was observed between the rpoS mutant and the wildtype.

Effect of PsrA on rpoS and psrA promoters in E. coli. We determined whether PsrA had an effect on psrA and rpoS expression in a heterologous background (E. coli). The psrA genewas cloned into expression vector pQE30 (construct designatedpQEPSRA), resulting in His₆-PsrA production in E. coli, as observedby sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis(data not shown). For E. coli(pQEPSRA), the psrA-lacZ fusion (pPPSR220)and the rpoS-lacZ fusion (pRPO220B) were introduced in independentexperiments, and $beta$ -galactosidase activity was determined. As shownin Fig. 5, the psrA promoter in E. coli was active, giving approximately2,445 Miller units; this activity was repressed in the presenceof pQEPSRA. On the other hand, the rpoS promoter in E. coli producedonly 60 Miller units; this activity was increased by approximately10-fold to 550 Miller units in the presence of pQEPSRA. As expectedfrom the results obtained with Pseudomonas, PsrA appeared to actas a repressor of psrA expression and as an activator of rpoSexpression.

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FIG. 5. $beta$ -Galactosidase activities in E. coli DH5 $alpha$ driven by the rpoS-lacZ (pRPO220B) and psrA-lacZ (pPPSRA220) fusions. Plasmid pQEPSRA contains the psrA gene and expresses the PsrA protein, whereas plasmid pQE30 is the vector (see text for details). All measurements were done in triplicate; the mean and standard error are shown. Cells harboring plasmids were grown for 16 h in LB medium in the presence of appropriate antibiotics. Columns: A, E. coli(pQE30)(pPPSR220); B, E. coli(pQEPSRA)(pPPSR220); C, E. coli(pQE30)(pRPO220B); D, E. coli(pQEPSRA)(pRPO220B).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The regulation of rpoS expression in P. putida WCS358 was investigated. Using an rpoS transcriptional fusion, we identifieda Tn5 genomic mutant, MT17, which showed a 90% decrease in rpoSpromoter activity. This mutant had a Tn5 insertion in an ORF of714 bp and coding for a protein (PsrA) of 26.3 kDa. The PsrA proteincontains, near its N terminus, a helix-turn-helix motif and belongsto the TetR family of bacterial regulators (Fig. 3B). Many ofthe regulators belonging to the TetR regulatory family act asrepressors of transcription, their targets very often being geneswhich encode proteins involved in membrane permeability (23,24). PsrA likely acts as a positive regulator of rpoS gene expression,since a null mutant resulted in a considerable decrease in rpoSgene expression and in less RpoS protein being present in thecell (Fig. 4). It is not known whether this regulatory actionis direct or indirect, through another regulatory component(s).PsrA acts as a repressor of its own synthesis, since psrA wasexpressed at a much higher level in P. putida MT17 than in wild-typeWCS358, indicating that PsrA regulates its own synthesis in anegative way. The observation that PsrA represses psrA and activatesrpoS in E. coli is an indication that it might do so directly.The repression was strong and clear, whereas the activation ofrpoS was rather weak compared to promoter activities in Pseudomonas.Thus, it is likely that some other factors are missing in E. coli.

To our knowledge, this study represents the first genetic screen of Pseudomonas spp. using an rpoS transcriptional fusionand selecting for down-regulated mutants. Our selection led tothe identification of only one mutant having Tn5 in the psrA gene.The screen made use of the xylE reporter gene, which is less sensitivethan other reporter systems (e.g., lacZ). However, mutants notshowing a strong decrease in promoter activity cannot be detectedin plate assays. The fact that the P. putida rpoS promoter exhibitedstrong promoter activity made the selection even more difficult.It is therefore possible that other mutants which showed lowerlevels of rpoS expression were not detected. The fact that a mutantexhibiting no rpoS promoter activity was not isolated could indicatethat the regulation of RpoS occurs at different levels, as inE. coli, or that more transcriptional activators are involved.Our data showed that in Pseudomonas, there is an important regulatorcontrolling rpoS transcription. However, additional control couldtake place in response to various stresses or to the stringentresponse. At present we do not know to which effector molecule(s)or environmental stimuli PsrAresponds.

Previous studies have indicated that two other regulatory systems are involved in the regulation of rpoS expression in P.aeruginosa, namely, the LasR-LasI and RhlI-RhlR quorum-sensingsystems and the GacA-GacS two-component regulatory system (seeabove) (21, 45). Surprisingly, no mutations in either of thesesystems were isolated in the genetic selection. We have demonstratedthat the rpoS regulatory gene psrA is also present in P. aeruginosaPAO1 and that, as in P. putida, it plays a role in rpoS expression,since a psrA null mutant of PAO1 displayed a 90% reduction inrpoS promoter activity. By analysis of the production of quorum-sensingautoinducer molecules, it was verified that psrA mutants of bothP. putida and P. aeruginosa still produced autoinducer molecules.Thus, it does not appear that PsrA influences rpoS gene expressionthrough the biosynthesis of these molecules. Similarly, a reductionof rpoS expression in the psrA mutants did not result in any alterationin the production of autoinducer molecules. Following the contradictoryreports of Latifi et al. (21) and Whiteley et al. (45), inwhich RpoS was linked to autoinducer production, we did not concludein this study that PsrA plays a major role. However, it must bestressed that small quantities of RpoS were still made in psrAmutants.

Experiments thus far have indicated that in Pseudomonas, unlike in E. coli, rpoS appears to be extensively regulated at thetranscriptional level through the use of various regulators. Morework is needed to show whether the regulation of rpoS expressionby PsrA occurs directly or indirectly or through quorum sensingand/or other regulatory components and to determine which effectormolecules act on whichregulators.

	ACKNOWLEDGMENTS

M.K. is a scientist on leave from the Institute of Molecular Genetics and Genetic Engineering, Belgrade, Yugoslavia, and isbenefiting from an ICGEBfellowship.

We are grateful to G. Degrassi and C. Aguilar for interest and support. We thank P. Williams and his coworkers for providingbacterial strains, plasmid constructs, and purifiedautoinducers.

	FOOTNOTES

^* Corresponding author. Mailing address: Bacteriology Group, International Centre for Genetic Engineering and Biotechnology,Area Science Park, Padriciano 99, 34012 Trieste, Italy. Phone:040 3757317. Fax: 040 226555. E-mail: venturi{at}icgeb.trieste.it.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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Bertani, I., Venturi, V. (2004). Regulation of the N-Acyl Homoserine Lactone-Dependent Quorum-Sensing System in Rhizosphere Pseudomonas putida WCS358 and Cross-Talk with the Stationary-Phase RpoS Sigma Factor and the Global Regulator GacA. Appl. Environ. Microbiol. 70: 5493-5502 [Abstract] [Full Text]
Sevo, M., Buratti, E., Venturi, V. (2004). Ribosomal Protein S1 Specifically Binds to the 5' Untranslated Region of the Pseudomonas aeruginosa Stationary-Phase Sigma Factor rpoS mRNA in the Logarithmic Phase of Growth. J. Bacteriol. 186: 4903-4909 [Abstract] [Full Text]
Aguilar, C., Bertani, I., Venturi, V. (2003). Quorum-Sensing System and Stationary-Phase Sigma Factor (rpoS) of the Onion Pathogen Burkholderia cepacia Genomovar I Type Strain, ATCC 25416. Appl. Environ. Microbiol. 69: 1739-1747 [Abstract] [Full Text]
D'Argenio, D. A., Calfee, M. W., Rainey, P. B., Pesci, E. C. (2002). Autolysis and Autoaggregation in Pseudomonas aeruginosa Colony Morphology Mutants. J. Bacteriol. 184: 6481-6489 [Abstract] [Full Text]
Hengge-Aronis, R. (2002). Signal Transduction and Regulatory Mechanisms Involved in Control of the {sigma}S (RpoS) Subunit of RNA Polymerase. Microbiol. Mol. Biol. Rev. 66: 373-395 [Abstract] [Full Text]
Diggle, S. P., Winzer, K., Lazdunski, A., Williams, P., Camara, M. (2002). Advancing the Quorum in Pseudomonas aeruginosa: MvaT and the Regulation of N-Acylhomoserine Lactone Production and Virulence Gene Expression. J. Bacteriol. 184: 2576-2586 [Abstract] [Full Text]
Kojic, M., Aguilar, C., Venturi, V. (2002). TetR Family Member PsrA Directly Binds the Pseudomonas rpoS and psrA Promoters. J. Bacteriol. 184: 2324-2330 [Abstract] [Full Text]

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