The MexGHI-OpmD multidrug efflux pump controls growth, antibiotic susceptibility and virulence in Pseudomonas aeruginosa via 4-quinolone-dependent cell-to-cell communication

Séverine Aendekerk1,2, Stephen P. Diggle2, Zhijun Song3, Niels Høiby3, Pierre Cornelis1, Paul Williams2 and Miguel Cámara2

1 Laboratory of Microbial Interactions, Department of Molecular and Cellular Interactions, Flanders Interuniversity Institute for Biotechnology, Vrije Universiteit Brussel, Building E, Room 6.6, Pleinlaan 2, B-1050 Brussels, Belgium
2 Institute of Infection, Immunity and Inflammation, Centre for Biomolecular Sciences, University of Nottingham, Nottingham NG7 2RD, UK
3 Dept Clinical Microbiology 9301, University Hospital of Copenhagen, Rigshospitalet, DK-2100 Copenhagen, Denmark

Correspondence
Miguel Cámara
miguel.camara{at}nottingham.ac.uk


   ABSTRACT
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
In Pseudomonas aeruginosa the production of multiple virulence factors depends on cell-to-cell communication through the integration of N-acylhomoserine lactone (AHL)- and 2-heptyl-3-hydroxy-4(1H)-quinolone (PQS)- dependent signalling. Mutation of genes encoding the efflux protein MexI and the porin OpmD from the MexGHI-OpmD pump resulted in the inability to produce N-(3-oxododecanoyl)-L-homoserine lactone (3-oxo-c12-hsl) and pqs and a marked reduction in n-butanoyl-L-homoserine lactone levels. Both pump mutants were impaired in growth and exhibited enhanced rather than reduced antibiotic resistance. Provision of exogenous PQS improved growth and restored AHL and virulence factor production as well as antibiotic susceptibility, indicating that the pump mutants retained their capacity to respond to PQS. RT-PCR analysis indicated that expression of the PQS biosynthetic genes, phnA and pqsA, was inhibited when the mutants reached stationary phase, suggesting that the pleiotropic phenotype observed may be due to intracellular accumulation of a toxic PQS precursor. To explore this hypothesis, double mexI phnA (unable to produce anthranilate, the precursor of PQS) and mexI pqsA mutants were constructed; the improved growth of the former suggested that the toxic compound is likely to be anthranilate or a metabolite of it. Mutations in mexI and opmD also resulted in the attenuation of virulence in rat and plant infection models. In plants, addition of PQS restored the virulence of mexI and opmD mutants. Collectively, these results demonstrate an essential function for the MexGHI-OpmD pump in facilitating cell-to-cell communication, antibiotic susceptibility and promoting virulence and growth in P. aeruginosa.


Abbreviations: AHL, N-acylhomoserine lactone; C4-HSL, N-butanoyl-L-homoserine lactone; 3-oxo-C12-HSL, N-(3-oxododecanoyl)-L-homoserine lactone; PQS, 2-heptyl-3-hydroxy-4(1H)-quinolone


   INTRODUCTION
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
Pseudomonas aeruginosa is an ubiquitous Gram-negative {gamma}-proteobacterium capable of causing disease in humans, animals and plants (Cao et al., 2001a; Lyczak et al., 2002). P. aeruginosa produces a vast array of extracellular virulence factors, the majority of which are regulated both in a cell population density-dependent manner, via cell-to-cell communication or ‘quorum sensing’ (Swift et al., 2001; Withers et al., 2001; Bassler, 2002; Smith & Iglewski, 2003), and in a growth phase-dependent manner (Diggle et al., 2002, 2003). P. aeruginosa possesses two N-acylhomoserine lactone (AHL)- dependent quorum sensing systems (reviewed by Winzer & Williams, 2001; Cámara et al., 2002). The las system comprises the N-(3-oxododecanoyl)-L-homoserine lactone (3-oxo-C12-HSL) synthase, LasI and its cognate response regulator LasR, whilst the rhl system involves the N-butanoyl-L-homoserine lactone (C4-HSL) synthase and the response regulator RhlR (Winzer & Williams, 2001; Cámara et al., 2002). The las system regulates the production of extracellular virulence determinants such as elastase, the LasA protease, alkaline protease and exotoxin A (Winzer & Williams, 2001; Cámara et al., 2002). It also plays a role in controlling the expression of the xcpP and xcpR genes involved in the regulation of the Type II general secretion pathway (Chapon-Hervé et al., 1997) and has been implicated in the maturation of P. aeruginosa biofilms (Davies et al., 1998). The rhl system controls the production of rhamnolipids, elastase, LasA protease, hydrogen cyanide, pyocyanin, siderophores and the cytotoxic lectins PA-IL and PA-IIL (Diggle et al., 2002; Latifi et al., 1995, 1996; Winson et al., 1995). The las and the rhl systems are hierarchically organized such that the las system exerts transcriptional control over the rhl system (Latifi et al., 1996). However, the rhl system can also function independently of the las system (Diggle et al., 2003). Three independent transcriptome analyses have revealed that the las and the rhl systems influence the expression of more than 5 % of the P. aeruginosa PAO1 genome (Schuster et al., 2003; Wagner et al., 2003; Hentzer et al., 2003). Recently, an additional LuxR homologue, VqsR (virulence and quorum sensing regulation) has been shown to control the expression of a subset of quorum sensing regulated genes and to be needed for the full expression of siderophore biosynthesis and uptake genes (Juhas et al., 2004; Cornelis & Aendekerk, 2004).

P. aeruginosa also releases into the extracellular milieu 2-heptyl-3-hydroxy-4(1H)-quinolone, the pseudomonas quinolone signal (PQS), a molecule which closely resembles the 4-quinolone family of synthetic antimicrobials. The synthesis and action of PQS are modulated by the las and rhl systems respectively (Pesci et al., 1999). LasR regulates the production of PQS, and the addition of exogenous PQS to P. aeruginosa cultures enhances the expression of the elastase gene lasB, rhlI and rhlR as well as the alternative sigma factor, RpoS (Diggle et al., 2003; Pesci et al., 1999; McKnight et al., 2000). These findings suggest that PQS functions as a regulatory link between the las and rhl AHL-dependent quorum sensing systems and the stationary phase (via RpoS). The overlap between the quorum sensing and the RpoS regulons has been confirmed by a recent transcriptome analysis of the genes controlled by RpoS in P. aeruginosa (Schuster et al., 2004). Although the rhl system is active in the absence of PQS, production of certain rhl-dependent phenotypes such as PA-IL lectin and pyocyanin strictly depends on the presence of PQS at the onset of stationary phase (Diggle et al., 2003).

PQS is derived from anthranilate (Calfee et al., 2001), and the structural genes required for PQS biosynthesis have recently been identified (pqsABCD, pqsH plus the anthranilate synthase genes phnAB) together with the transcriptional regulator MvfR (PqsR) and a proposed effector, PqsE (Gallagher et al., 2002; Déziel et al., 2004). The transcription of pqsH is regulated by the las quorum sensing system, linking AHL-dependent quorum sensing with PQS regulation (Gallagher et al., 2002). Evidence that PQS is produced during human infections has been obtained by the direct detection of PQS in P. aeruginosa strains from cystic fibrosis (CF) patients (Collier et al., 2002) and by data indicating that PQS synthesis is increased in P. aeruginosa isolates from CF airways (Guina et al., 2003).

We have previously described a genetic locus (mexGHI-opmD), conferring resistance to vanadium in P. aeruginosa (Aendekerk et al., 2002), of which the gene products MexH, MexI and OpmD are highly conserved in relation to other components of P. aeruginosa antibiotic efflux pumps (Poole, 2002). Recently, it was shown that a plasmid expressing mexH, mexI and opmD conferred elevated resistance to norfloxacin, ethidium bromide, acriflavine and rhodamine 6G, confirming that MexHI-OpmD functions as a multi-drug efflux pump (Sekiya et al., 2003). We knew from our previous work that mutants in the non-coding region, upstream of mexGHI-opmD, in mexI and opmD were severely affected in the production of AHL-regulated exoproducts including elastase, rhamnolipids and pyocyanin (Aendekerk et al., 2002). In addition, the expression of lecA, which encodes the cytotoxic, galactophilic lectin PA-IL of P. aeruginosa, was markedly reduced by a Tn5 insertion into the mexGHI-opmD operon (Diggle et al., 2002). Here we demonstrate that the MexI efflux protein and the OpmD porin play a key role in controlling P. aeruginosa growth, antibiotic susceptibility and virulence via 4-quinolone-dependent cell-to-cell communication. We also show that loss of the pump by mutation may result in the accumulation of a toxic PQS precursor which could be responsible for the severely attenuated phenotype observed.


   METHODS
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
Growth conditions and strains.
All the bacterial strains and plasmids used in this study are listed in Table 1. The P. aeruginosa strain PA14 mexI and opmD mutants and the PAO1 strain mexI phnA and mexI pqsA double mutants were constructed by allelic exchange as described for the corresponding single mexI PAO1 mutants by Aendekerk et al. (2002). P. aeruginosa strains were grown in Luria broth (LB), Casamino acids medium (CAA) or ox broth (Statens Serum Institut, Copenhagen, Denmark) at 37 °C. When required, synthetic PQS was added to a final concentration of 60 µM, the synthetic AHLs 3-oxo-C12-HSL and C4-HSL at concentrations of 10 or 100 µM, and anthranilate at concentrations of 100 nM to 100 µM. Growth was continuously monitored in the Bioscreen apparatus (Life Technologies), using the following parameters: culture volume 300 µl, temperature 37 °C, shaking for 10 s every 3 min, and reading every 20 min. As inoculum, an overnight culture of PAO1 in CAA was diluted in order to achieve a final OD600 of 0·001. Each culture was inoculated in triplicate and each experiment was repeated three times.


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Table 1. Bacterial strains and plasmids

 
Synthesis of AHLs and PQS analogues.
C4-HSL and 3-oxo-C12-HSL were synthesized as described previously (Chhabra et al., 1993, 2003), and PQS was synthesized as described by Diggle et al. (2003) using the procedures of Pesci et al. (1999).

TLC assays for C4-HSL and 3-oxo-C12-HSL detection.
Acidified supernatants from 18 h cultures (OD600 2) in LB at 37 °C were extracted with dichloromethane as described previously (Diggle et al., 2002; Yates et al., 2002) and analysed by TLC. Ten-microlitre samples were spotted onto reverse-phase silica RP-18 F254S (Merck) and separated using a methanol/H2O (60 : 40) system. C4-HSL was assayed using an Escherichia coli strain harbouring the AHL reporter plasmid pSB536 (Swift et al., 1997). For the detection of 3-oxo-C12-HSL, samples were spotted onto RP-2 plates and the TLC was resolved using a mixture of methanol/H2O (45 : 55, v/v). In this case 3-oxo-C12-HSL was detected using the AHL biosensor E. coli(pSB1075) (Winson et al., 1998). For both biosensors, AHLs were visualized as bright spots on a dark background when viewed with a Luminograph LB980 (Berthold) photon video camera.

TLC analysis of PQS production.
For the detection of extracellular PQS, cell-free spent supernatants were prepared from 18 h cultures (10 ml at OD600 2) and extracted with 10 ml acidified ethyl acetate. The organic phase was dried and resuspended in 50 µl methanol. Intracellular PQS was detected after disruption by sonication of a cell pellet prepared from a 40 ml overnight culture resuspended in 20 ml LB. PQS was then extracted from the supernatant of the cell lysate using equal volume of acidified ethyl acetate. The solvent was evaporated and resuspended in 100 µl methanol. Ten-microlitre samples of each extracellular and intracellular extract were spotted onto normal-phase silica 60F254 (Merck) TLC plates, pretreated by soaking in 5 % K2HPO4 for 30 min and activated at 100 °C for 1 h. Extracts were separated using a dichloromethane/methanol (95 : 5, v/v) system until the solvent front reached the top of the plate. PQS was visualized under UV light and identified by comparison with a synthetic standard (5 µl of a 10 mM stock).

Antibiotic resistance test.
Antibiotic resistance was measured by the filter-disk assay method using commercially available disks (Fluka). The following antibiotics were tested: spectinomycin (15 µg per disk), tetracycline (30 µg), nalidixic acid (30 µg), chloramphenicol (30 µg), kanamycin (30 µg), rifampicin (15 µg) and carbenicillin (30 µg). Three millilitres of a cell suspension (5x106 c.f.u. ml–1) was added to a LB plate and left for 30 min, after which the cell suspension was removed and the plate dried under laminar flow. The disks were applied to the plates (four per plate) and the plates incubated for 18 h at 37 °C. The diameter of the inhibition ring was then measured. Each experiment was done in triplicate.

Quantification of pyocyanin.
For pyocyanin analysis bacteria were spread onto PAB agar (Difco) in numbers that enabled confluent growth and incubated at 37 °C for 48 h. Pyocyanin was extracted from the agar medium and quantified according to Mavrodi et al. (2001).

Measurement of bioluminescence.
Bioluminescence was measured as a function of cell density using a combined automated luminometer–spectrophotometer (LUCYI, Anthos Labtech). Overnight cultures of the P. aeruginosa lecA' : : luxCDABE reporter gene fusion were diluted to OD600 0·01 in LB and 200 µl of this dilution was added to each well of a LUCY plate. Where required, PQS (60 µM) or C4-HSL (100 µM) or both were added. Bioluminescence and optical density were determined. Luminescence is given, in relative light units (RLU) divided by OD495, indicating the approximate light output per cell.

RT-PCR.
RNA was extracted from P. aeruginosa PAO1, mexI and opmD grown in LB using the High Pure RNA Isolation Kit (Roche Diagnostics). cDNA was synthesized using the First-Strand cDNA Synthesis Kit (Amersham Pharmacia). For PQS biosynthesis gene expression, RT-PCR was done using two sets of primers: pqsA1 and pqsA2 or phnA1 and phnA2 (Table 2). The primers used for lasI and rhlI transcript detection are also shown in Table 2. As a control, RT-PCR was done using primers oprL-1 and oprL-2 for the amplification of the housekeeping gene oprL (Lim et al., 1997). The complete list of primers used in this study is shown in Table 2.


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Table 2. Primers used for RT-PCR

 
Construction of the PAO1 pqsA, mexI pqsA and mexI phnA mutants.
A pqsA chromosomal deletion mutant in PAO1 lacking 1172 internal nucleotides was constructed as follows. Using PAO1 DNA as a template, a 2600 bp fragment containing the intact pqsA gene (1554 bp) was amplified using the primer pair pqsAUF containing a SalI restriction site (5'-TAGGTGTCGACTTCGGCAGGCTCGCC-3') and pqsADR containing a HindIII restriction site (5'-GCGTAAAGCTTCGGGCAATCCAGGTT-3'). The resulting PCR product was digested with SalI and HindIII and cloned into similarly digested pUC18, resulting in the plasmid pUCpqsA. To introduce a deletion of the recombinant pqsA gene, the primer pair DpqsAUP (5'-TCGGGACGTAATCGAGGCGGAACAG-3') and DpqsADR (5'-TTCCGTACGTACGGGCATGTTGATTC-3') was used in conjunction with inverse PCR using pUCpqsA DNA as a template. The resulting blunt-ended PCR product containing a 1172 bp deletion in pqsA was self-ligated, resulting in the plasmid pUC{Delta}pqsA. The PCR product was excised from the vector using SalI and XbaI, and cloned into the suicide vector pDM4 (Milton et al., 1996) digested with SalI and XbaI, resulting in the plasmid pDM4{Delta}pqsA. Allelic exchange using pDM4{Delta}pqsA contained in E. coli S17-1 {lambda}pir with PAO1 resulted in a P. aeruginosa strain (PAO1 pqsA) containing an in-frame deletion of the pqsA gene. This deletion was confirmed by PCR analysis (data not shown). The phnA deletion mutant is a transposon mutant from PAO1 obtained from the University of Washington Genome Center. The mexI pqsA and mexI phnA double mutants were made by inserting a GmR cassette in the mexI gene of the pqsA and phnA mutants as previously described (Aendekerk et al., 2002).

Virulence assays in plants and animals
Animals.
Lung infection in rats was performed as previously reported (Song et al., 1998). PAO1 and mexI strains were first cultured on agar plates, and then one colony of each strain was inoculated into ox broth and cultured at 37 °C with shaking for 24 h. Bacteria were harvested by centrifugation and embedded in alginate beads. Alginate beads (100 µl) containing either PAO1 or the mexI mutant were instilled intratracheally to the deep left bronchus for each rat (female, 7-week-old Lewis rats with a body weight of between 150 and 200 g). The challenge concentration for PAO1 strain was 1x108 c.f.u. ml–1, and for the mexI mutant 1·5x109 c.f.u. ml–1. Challenge concentrations were determined from a series of pilot studies. The mortality rate was followed up to 7 days post-challenge, after which all animals were sacrificed. Lung pathology was expressed as lung index of macroscopic pathology (LIMP) and pathological scoring. LIMP represents the lung area with pathological changes versus the area of the whole lung. Lung scores can be divided into four grades: score 1, normal; score 2, only lung atelectasis <10 mm2; score 3, lung atelectasis <40 mm2; score 4, lung abscess or lung atelectasis >40 mm2.

Plants.
P. aeruginosa strain PA14 and the isogenic mexI and opmD mutants were grown overnight in LB medium or until they reached the stationary phase at 37 °C, and washed in 10 mM MgSO4. Cells were then diluted to 107 and 108 c.f.u. ml–1. Ten microlitres of diluted cells was inoculated with a micropipette into the stems of Romaine lettuce plants. The stems were washed with 0·1 % bleach and placed on 15 cm diameter Petri dishes containing a Whatman filter impregnated with 10 mM MgSO4. The midrib of each lettuce leaf was inoculated with each of the three P. aeruginosa strains to be tested. For some experiments, PQS (60 µM) was either co-injected with the bacteria or injected on its own. The plates were kept in a growth chamber at 28 °C and symptoms monitored daily for 5 days.


   RESULTS
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
MexI and OpmD are required for AHL and PQS production
We have previously shown that mutations in the P. aeruginosa genes mexI and opmD from the MexGHI-OpmD efflux system result in the inability to produce detectable levels of C6-HSL and C4-HSL using the AHL biosensor strain Chromobacterium violaceum CV026 (Aendekerk et al., 2002). However, CV026 has a relatively low sensitivity for C4-HSL (McClean et al., 1997) and is not activated by 3-oxo-C12-HSL. To gain better insights into the production of AHLs by the mexI and opmD mutants, two alternative and more sensitive AHL biosensor strains were used in conjunction with TLC (Diggle et al., 2002; Yates et al., 2002). These were the lux-based E. coli(pSB536) for the detection of C4-HSL and E. coli(pSB1075) for 3-oxo-C12-HSL (Swift et al., 1997; Winson et al., 1998). We also investigated the effect of the mexI and opmD mutations on PQS production using the TLC-based method described by Calfee et al. (2001). Fig. 1 shows that the mexI and opmD mutants produced no detectable 3-oxo-C12-HSL or PQS and markedly reduced levels of C4-HSL in spent-culture supernatants. However, the addition of 60 µM synthetic PQS to cultures of mexI and opmD mutants resulted in the restoration of both 3-oxo-C12-HSL (Fig. 1a) and C4-HSL production (Fig. 1b), although in the mexI mutant, 3-oxo-C12-HSL levels did not return to wild-type (Fig. 1a, lane 5). In contrast, exogenous provision of 3-oxo-C12-HSL did not restore PQS synthesis in these mutants (data not shown), demonstrating that the PQS-negative phenotype was not simply due to a non-functioning las system. This is believed to be the first time that 3-oxo-C12-HSL synthesis has been shown to be PQS-dependent. Furthermore, no intracellular PQS (Fig. 1c) or AHLs (data not shown) could be detected in either the mexI or opmD mutants, indicating that the loss of the AHLs was not a consequence of the inability to export 3-oxo-C12-HSL or PQS.



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Fig. 1. (a) Detection of 3-oxo-C12-HSL by TLC using the AHL biosensor strain E. coli(pSB1075). Lanes 1 to 7 contain synthetic 3-oxo-C12-HSL (1), extracts from spent medium of P. aeruginosa PAO1 (2), PAO1 grown in the presence of 60 µM PQS (3), mexI mutant (4), mexI mutant grown in the presence of 60 µM PQS (5), opmD mutant (6) and opmD mutant grown in the presence of 60 µM PQS (7). (b) Detection of C4-HSL by TLC using the AHL biosensor strain E. coli(pSB536). Lane 1 contains synthetic C4-HSL, and lanes 2 to 7 are as for (a). (c) Detection of PQS by TLC and UV light. Lanes 1 to 7 contain synthetic PQS (1), extracts from spent medium of PAO1 (2), mexI mutant (4) and opmD mutant (6), and intracellular extracts from PAO1 (3), mexI mutant (5) and opmD mutant (7). All extractions were from cells grown for 18 h (OD600 2).

 
Expression of quorum sensing regulated virulence determinants in the mexI and ompD mutants can be restored by exogenously supplied PQS
The fact that mutations in mexI and opmD abolish or drastically reduce the production of quorum sensing signal molecules suggests that this may also result in a decreased production of quorum sensing regulated virulence determinants in these mutants. If this is the case, since PQS has a central role in quorum sensing-mediated gene expression (Diggle et al., 2003) and can restore AHL production in the mexI and opmD mutants, addition of PQS to these mutants should restore the production of virulence determinants. In our previous work, we showed that the production of elastase and pyocyanin was drastically reduced in the mexI and opmD mutants.

We have also shown before that expression of lecA (encoding the cytotoxic PA-IL lectin) is strictly under the control of the rhl quorum sensing system (Winzer et al., 2000). In addition, lecA expression has an absolute requirement for PQS (Diggle et al., 2003). In both mexI and opmD mutants, the loss of PQS and reduced level of C4-HSL suggested that expression of lecA should be severely down-regulated. To test this hypothesis we first introduced mexI and opmD mutations into a PAO1 strain harbouring a lecA' : : lux chromosomal fusion (Winzer et al., 2000). Interestingly, mutations in mexI resulted in the abolition of lecA expression, which could only partially be restored upon addition of high concentration of C4-HSL (Fig. 2). In contrast, the provision of exogenous PQS to the mexI mutant restored lecA' : : lux expression to wild-type levels (Fig. 2). Similar results were obtained with the ompD mutant in the lecA' : : lux strain (data not shown). This is consistent with our recent work (Diggle et al., 2003), in which we showed that inhibition of PQS biosynthesis, in the presence of a functional rhl system, abolished PA-IL production. Addition of a combination of PQS and C4-HSL to these mutants further enhanced lecA' : : lux expression (data not shown). In contrast, 3-oxo-C12-HSL had no effect on lecA transcriptional levels (data not shown), as shown previously (Winzer et al., 2000).



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Fig. 2. Expression of the lecA' : : luxCDABE transcriptional fusion in P. aeruginosa PAO1 and mexI mutant. Strains were grown at 37 °C for 22 h in LUCYI (Anthos Labtech). {blacklozenge}, No addition (PAO1); {blacksquare}, no addition (mexI); {triangleup}, 100 µM C4-HSL (mexI); x, 60 µM PQS (mexI). In all experiments, RLU and OD495 were determined as described in Methods. The graphs represent single experiments although each one was repeated three times with similar results.

 
mexI and opmD mutants show enhanced antibiotic resistance which can be reversed upon addition of exogenous PQS
We have previously described the role of the mexGHI-opmD locus in resistance to vanadium in P. aeruginosa (Aendekerk et al., 2002). Also, a mutant (ncr, with an insertion in the non-coding upstream region) unable to express mexGHI-opmD was shown to be more resistant to tetracycline and to the combination of ticarcillin and clavulanic acid (Aendekerk et al., 2002). To investigate whether mutations in mexI and opmD confer altered susceptibility to other antibiotics, we tested a range of these against the two mutants. Confirming and extending our previous results, we observed that the mexI and opmD mutants became resistant to kanamycin and spectinomycin, while they displayed a decreased sensitivity to carbenicillin, nalidixic acid, tetracycline, chloramphenicol and rifampicin (Table 3). Furthermore, the sensitivity towards all antibiotics was partially or totally restored upon provision of exogenous PQS to the mutants, in a way similar to complementation by the mexGHI-opmD genes in trans (Aendekerk et al., 2002). Interestingly, antibiotic sensitivity also increased in the wild-type strain upon supplementation of the medium with PQS (Table 3). Hence the increased resistance to several antibiotics in the P. aeruginosa mexI and opmD mutants is governed by the absence of PQS in these mutants.


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Table 3. Antibiotic sensitivity of wild-type, mexI and opmD mutants in the absence and presence of PQS

Numbers represent the diameter of inhibition (cm) around the point of addition of the antibiotic. PQS concentration in the medium was 60 µM. Results are means±SD of 3 replicates.

 
PQS biosynthetic gene expression is switched off during the growth of the mexI and opmD mutants
To understand the mechanism leading to the reduction in the production of virulence determinants in the MexGHI-OpmD mutants, and as the mexI and opmD mutations exert a profound effect on cell-to-cell communication, we investigated whether this was due to a reduction in the expression of lasI, rhlI (encoding the 3-oxo-C12-HSL and the C4-HSL synthases, respectively) or pqsA and phnA, which are two key genes in the biosynthesis of PQS (Gallagher et al., 2002; Déziel et al., 2004). Detection of transcripts for these genes was carried out using RT-PCR. After 18 h growth (OD600 2), the cDNAs corresponding to all four genes were present in the parent PAO1 strain while in both the mexI and opmD mutants, only the lasI and rhlI transcripts were present (Fig. 3a). A more detailed analysis of pqsA and phnA expression as a function of growth revealed that the corresponding transcripts could be detected at OD600 0·6 and 1·2, but not at OD600 1·6. We conclude that, the absence of PQS production in the mexI and opmD mutants is a result of the inhibition of the expression of PQS biosynthetic genes during growth. The fact that the absence of 3-oxo-C12-HSL did not correlate with the inhibition of lasI transcription suggested the presence of an alternative, post-transcriptional mechanism preventing the biosynthesis of this quorum sensing signal molecule.



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Fig. 3. RT-PCR analysis of transcripts. (a) Transcripts for oprL (house-keeping control gene), lasI, rhlI, pqsA and phnA, in wild-type, mexI mutant and opmD mutant strains (left to right). The cultures were grown in LB medium until they reached an OD600 of 2. (b)Transcripts for pqsA in wild-type, mexI and opmD mutants as a function of the OD600 in LB medium (indicated on the right). Identical results were obtained for the phnA transcripts (results not shown).

 
Mutation of mexI and opmD results in growth deficiency which is restored upon addition of exogenous PQS
To investigate whether mutations in mexI and opmD affected the growth of P. aeruginosa, which could also account for the increase in antibiotic resistance observed, the growth of both mutants was monitored. As shown in Fig. 4, in LB liquid medium at 37 °C, an extended lag phase was observed for both mutants (20–40 h) compared with the wild-type (8 h), although the growth rate was similar between the mutants and the wild-type. Interestingly, whilst addition of 10 µM 3-oxo-C12 to the medium had no effect, the presence of 60 µM PQS considerably shortened the lag phase (Fig. 4). This suggests that only exogenously supplied PQS can overcome the growth defect in the P. aeruginosa pump mutants. Although these experiments were done in the Bioscreen apparatus, where the cultures are under lower oxygen tension, similar results (extended lag phases for mexI and opmD mutants and growth stimulation by addition of PQS) were obtained when the cultures were incubated in flasks and shaken at 150 r.p.m. (results data not shown).



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Fig. 4. Growth of wild-type ({bullet}), mexI ({circ}) and opmD ({triangleup}) mutants in LB medium in the absence (no additions) and in the presence of exogenously added 100 µM 3-oxo-C12-HSL (+3-oxo-C12-HSL) or 60 µM PQS (+PQS). The graphs represent the mean of three independent measurements using the Bioscreen growth monitoring apparatus as described in Methods. Each OD600 value is the mean of three wells using an identical inoculum. For clarity, the variation between wells is not indicated, but it never exceeded 10 %. The growth experiments were repeated three times in different experiments and the trend was similar.

 
The extended lag phase of mexI and opmD mutants is probably due to the accumulation of a toxic PQS precursor
It has recently been shown that anthranilate, the product of the anthranilate synthase PhnAB, is a biosynthetic precursor of PQS, thought to be modified by PqsA during the initial steps in the biosynthesis of this 4-quinolone signal molecule (Essar et al., 1990; Gallagher et al., 2002; Déziel et al., 2004). In addition, it has been demonstrated that a pqsA mutant accumulates and excretes anthranilate into the growth medium (Déziel et al., 2004), suggesting the existence of an efflux mechanism for this PQS precursor. Hence the inhibition of pqsA transcription in the pump mutants may result in the accumulation of anthranilate or a metabolic derivative which may exert a toxic effect on the cells and hence affect growth. This would suggest that mexGHI-opmD is involved in the excretion of these toxic metabolites. To investigate this hypothesis we first constructed a P. aeruginosa mexI phnA double mutant (which does not produce anthranilate, from the PhnAB pathway, and therefore does not produce PQS via the pqsA-E operon) and observed improved growth compared with the single mexI mutant (Fig. 5). Conversely, the growth of a mexI pqsA mutant (which accumulates anthranilate and does not produce PQS) was characterized by a very long lag phase and a diminished growth rate (Fig. 5), in contrast to the single phnA or pqsA mutants, which did not present any growth alterations (Fig. 5). Interestingly, although exogenous PQS reduced the lag phase of the mexI mutant (Fig. 4) it had no effect on the mexI phnA or mexI pqsA double mutants (data not shown). Taken together, these data indicate that the delayed growth observed in the pump mutants is caused by the accumulation of anthranilate or a metabolic derivative and that the mexGHI-opmD pump might be involved in the detoxification of these compounds.



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Fig. 5. Growth of wild-type (PAO1), phnA, pqsA, mexI, mexI phnA and mexI pqsA mutants in LB medium. The graphs represent the mean of three independent measurements. Each OD600 value is the mean of three wells using an identical inoculum. For clarity, the variation between wells is not indicated, but it never exceeded 10 %. The growth experiments were repeated three times in different experiments and the trend was similar.

 
Mutation of mexI and opmD severely compromises virulence in P. aeruginosa
The fact that a mutation in the MexGHI-OpmD pump affected the production of some quorum sensing regulated virulence determinants suggested that it could also have significant implications in the ability of this organism to cause disease. Consequently, we tested the effect that mutations in mexI and ompD had on the virulence of P. aeruginosa using both an animal and a plant model of infection. As the animal model we used a rat lung infection model (Song et al., 1998) in which rats were infected intratracheally in the left lung with either the wild-type PAO1 (40 animals) or the mexI mutant (20 animals). Whilst 32 (80 %) animals infected with the wild-type died, only 1 rat infected with the mexI did (Fig. 6a). Analysis of bacterial numbers present in the lung at the end of the experiments revealed large differences between the mexI mutant (4x106 c.f.u. per lung) and the wild-type (2x108 c.f.u. per lung) even though 15 times more cells from the mexI mutant were used for the infection. Pathological examination of the lungs from the infected rats (Fig. 6a) showed the presence of multiple abscesses in the animals infected with the wild-type PAO1 while only a single abscess was detected in the lungs from the rats infected with the mexI mutant.



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Fig. 6. (a) Lungs from rats infected with the wild-type P. aeruginosa PAO1 (right) and the mexI mutant (left). Multiple abscesses are present in the wild-type-infected lung while only one is visible for the mexI-infected lung (shown by arrows). The table shows a summary of the results from these virulence studies. (b) Plant (lettuce) infection assay with P. aeruginosa PA14 wild-type and its corresponding mexI and opmD mutants (1), wild-type PA14, mexI and mexI co-inoculated with 60 µM PQS (2) and wild-type PA14, opmD and opmD co-inoculated with PQS (3).

 
The mexI and opmD mutations were then transferred by allelic exchange to the highly plant- and animal-virulent P. aeruginosa PA14 strain, and the virulence of the mutants was tested in a lettuce infection assay where PA14, in contrast to PAO1, is known to induce necrotic lesions (Rahme et al., 1995). Fig. 6(b) shows that the mexI and opmD mutants did not cause any necrosis of the leaves whilst typical disease signs (necrosis and maceration) were clearly observed for the wild-type. The fact that PQS can restore the quorum sensing regulated phenotypes tested suggests that one of the reasons for the reduced virulence of the P. aeruginosa mexI and opmD mutants is the absence of this signal molecule. To investigate whether this is the case we tested whether co-inoculation of the PA14 mexI and opmD mutants with PQS could restore their ability to cause necrotic lesions in the lettuce infection assay. Fig. 6(b) shows that the addition of PQS indeed restored virulence in both of the mutants. However for the mexI mutant this restoration was only partial. Inoculation of PQS alone did not cause any necrosis (results not shown).


   DISCUSSION
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
 
In this work, we have demonstrated a key role for the MexI and OpmD proteins, two components of a newly discovered efflux system in P. aeruginosa (Aendekerk et al., 2002; Sekiya et al., 2003), in the production of 4-quinolone and AHL quorum sensing signal molecules in this organism, and in promoting cell growth and in virulence. Furthermore, we have shown that loss by mutation of the pump enhances rather than reduces resistance to several different classes of antibiotics, a process which can be reversed by the provision of the PQS signal molecule. We believe that this is the first example of mutants in an efflux system displaying such strong phenotypes, including obvious growth defects.

Previous studies have suggested a role for P. aeruginosa efflux pumps in the transport of quorum sensing signal molecules to the extracellular milieu. The MexAB-OprM efflux system of P. aeruginosa has been proposed to be involved in the efflux of 3-oxo-C12-HSL while C4-HSL appears to diffuse freely out of the cells (Pearson et al., 1999). In addition this efflux pump has been shown to play an important role in the invasiveness of P. aeruginosa and it has been suggested to be involved in the export of virulence determinants (Hirakata et al., 2002). However the mechanism involved was not elucidated. Köhler et al. (2001) have also proposed that the inducible MexEF-OprN system might be responsible for the efflux of PQS. These authors found that overexpression of this pump, achieved via the nfxC mutation, restored the activity of the MexT activator and resulted in the decreased transcription of rhlI and a reduction of PQS and C4-HSL production (Köhler et al., 1999, 2001). They suggested that either PQS or a precursor might be the substrate of the MexEF-OprN pump. It is remarkable that the phenotypes described by Köhler and co-workers for the nfxC mutant overexpressing mexEF-oprN are similar to those we describe here and in our previous work (Aendekerk et al., 2002), including decreased production of virulence factors and signal molecules, and lack of virulence in a model of acute pneumonia in mice (Cosson et al., 2002). Recently, Ramsey & Whiteley (2004) described a genetic locus, dad6 (dynamic attachment deficient), corresponding to the PA2491 gene and encoding an oxidoreductase; mutants in this gene showed a defect in the establishment of biofilms. This gene is located upstream of the mexT regulator gene and the mexEF-oprN genes and its inactivation results in increased expression of the mexEF-oprN genes and decreased expression of the PQS biosynthesis genes (Ramsey & Whiteley, 2004). In contrast, our data presented here are believed to be the first to conclusively show that the absence of an efflux pump dramatically affects the production of quorum sensing signal molecules via the repression of PQS biosynthesis genes in P. aeruginosa while the data of Köhler et al. (2001) and Ramsey & Whiteley (2004) suggest that overproduction of MexEF-OprN results in the same phenotype. Microarray analysis of the expression of different efflux porin genes showed that, from the genes encoding members of the Opm porin family (Hancock & Brinkman, 2002; Jo et al., 2003) only oprM, oprJ, opmA, opmD and opmL are highly transcribed (Jo et al., 2003). However, that study was done in the PAK strain of P. aeruginosa, which does not produce PQS (Lépine et al., 2003). Using P. aeruginosa PAO1, Murata et al. (2002) detected the production of OpmB and OpmD by Western blot analysis, with OpmD increasing at the onset of the stationary phase, corresponding to the time of PQS appearance.

Our studies also demonstrate that the absence of the main components of the MexGHI-OpmD pump does not affect the response to exogenous PQS as demonstrated by the restoration of pyocyanin production (data not shown) and the expression of a lecA' : : lux fusion, both traits known to be controlled by PQS and the Rhl system (Diggle et al., 2003; Gallagher et al., 2002; Déziel et al., 2004; D'Argenio et al., 2002).

An unexpected finding was the growth-phase-dependent shut-down of transcription of the PQS biosynthetic genes pqsA and phnA in the mexI and opmD mutants. This result may suggest the involvement of the pump in the efflux of a toxic compound (explaining the reduced growth rate) linked to the production of PQS. As already noted, no PQS could be detected inside the cells of the mexI and opmD mutants. The precursor of PQS is anthranilate (Calfee et al., 2001). The phnA and phnB genes encode the two components of an anthranilate synthase and were first described as being important for the production of phenazines, including pyocyanin (Essar et al., 1990, Anjaiah et al., 1998). Subsequently it was demonstrated that phnAB are necessary for PQS biosynthesis, providing an explanation as to why mutants in these genes failed to produce phenazines (Gallagher et al., 2002).

In a previous report we described that a trpC mutant failed to produce phenazines and excreted anthranilate into the medium (Anjaiah et al., 1998). Addition of increasing amounts of tryptophan to the trpC mutant restored the production of phenazines while decreasing the concentration of anthranilate in the spent medium, due to feedback inhibition of the TrpEG anthranilate synthase (Essar et al., 1990). These results suggest that (i) anthranilate synthesized by the TrpEG anthranilate synthase cannot be channelled into the synthesis of PQS, (ii) high anthranilate concentrations inhibit the production of phenazines, eventually by repressing phnA transcription and (iii) anthranilate is excreted from the cells. One possibility is that, in the absence of efflux mediated by MexI-OpmD, accumulation of intracellular anthranilate leads to the progressive transcriptional shutdown of the PQS biosynthesis genes. Our physiological studies of the double mexI phnA and mexI pqsA mutants indicate that the accumulation of anthranilate in the cell may be responsible for the growth defect in the absence of the pump, since the mexI pqsA mutant is almost non-viable, in contrast to a pqsA mutant which grows in a manner similar to the parent strain. Anthranilate is also a direct precursor of catechol biosynthesis. Catechols have been shown to exert toxic effects in cells such as generation of reactive oxygen species by redox reactions, oxidative DNA damage and protein damage by thiol arylation or oxidation, and they can also interfere with electron transport (Schweigert et al., 2001). Catechols can also complex metals, such as iron (Schweigert et al., 2001). Accumulation of catechols inside the cells in the absence of the MexGHI-OpmD pump could also explain the observed increased sensitivity to vanadium in a mutant affected in this pump (Aendekerk et al., 2002), which could be due to the accumulation of catechol–vanadium complexes. The incomplete restoration of growth in the case of the mexI phnA double mutant could be explained by the fact that a second route exists in pseudomonads for the production of anthranilate via the degradation of tryptophan by the enzyme tryptophan 2,3-dioxygenase (TDO, encoded by PA 2579) into N-formylkynurenine, followed by the conversion of this molecule into N-kynurenine by a formamidase (PA2081), and finally the degradation of N-kynurenine into anthranilate by a kynureninase (PA2080) (Kurnasov et al., 2003; Matthijs et al., 2004). Supporting this proposition, it has been shown that a transposon insertion in the TDO gene suppresses the autolysis phenotype caused by an overproduction of PQS in P. aeruginosa (D'Argenio et al., 2002). It is also worth noting a recently published report showing the presence of an efflux system in E. coli that acts as a ‘metabolic relief valve’ by pumping out p-hydroxybenzoic acid, which is a precursor of ubiquinones (Van Dyk et al., 2004).

Despite the loss of AHL production in the mexI and opmD mutants, both the lasI and rhlI transcripts were present in both the exponential and the stationary phase. Previously, it has been shown that the absence of MvfR (PqsR), which is a positive regulator of PQS biosynthesis, does not affect the transcription of lasR or rhlR (Cao et al., 2001b). These data suggest that the restoration of AHL production in the pump mutants by exogenous PQS must therefore be occurring at the post-transcriptional level. It is possible that this involves the post-transcriptional regulatory protein RsmA, which influences the expression of both lasI and rhlI (Pessi et al., 2001), since PQS is capable of overcoming the RsmA-dependent repression of lecA, a gene which is known to be positively regulated by both C4-HSL and PQS (Diggle et al., 2003). Clearly, addition of PQS to the opmD mutant results in the complete restoration of production of 3-oxo-C12, while the effect is less pronounced in the case of the mexI mutant. One possibility is that MexI is the most important component of the pump and that PQS stimulates the transcription of the pump. Indeed, as opmD is the last gene of the operon, mexI should be transcribed in the opmD mutant (Aendekerk et al., 2002).

Analysis of the P. aeruginosa PAO1 genome sequence suggests that this opportunistic human pathogen, which exhibits innate resistance to multiple antibiotic classes, possesses at least ten different RND (Resistance-Nodulation-Cell Division) type multi-drug efflux pumps (Stover et al., 2000). For those pumps that have been extensively characterized, genetic disruption generally leads to increased susceptibility to antimicrobial agents. Paradoxically, here we show that disruption of the MexGHI-OpmD efflux pump enhances the resistance of P. aeruginosa to a variety of antibiotics including {beta}-lactams, aminoglyclosides and quinolones (Table 3).

Interestingly, Maseda et al. (2004) showed that overproduction of the MexEF-OprN pump results in increased resistance to quinolones, but hypersusceptibility to most {beta}-lactams. The same authors demonstrated that C4-HSL is needed for maximal expression of mexAB-oprM in stationary phase and that this is antagonized by the MexT regulator. For both the mexI and opmD mutants, the provision of exogenous PQS restored susceptibility to for example kanamycin and spectinomycin. These data indicate that PQS-dependent cell-to-cell communication in P. aeruginosa is also involved in controlling susceptibility to antimicrobial agents. This is further highlighted by the increase in susceptibility of the parent PAO1 strain cultured in the presence of PQS. The mechanism involved is not known but may be a consequence of the PQS-dependent repression of other multi-drug efflux pumps. Although there is no published information on the regulation of any of the RND efflux pumps by PQS, both the mexGHI-opmD gene cluster (qsc133; Whiteley et al., 1999) and the mexAB-oprM cluster (Maseda et al., 2004) are positively regulated by AHL-dependent quorum sensing. Alternatively, PQS may directly regulate genes involved in controlling cell envelope permeability. Further work will clearly be required to determine the mechanism by which PQS modulates antibiotic susceptibility.

Mutation of both mexI and opmD rendered P. aeruginosa unable to cause necrosis and macerate plant tissues. Likewise, the mexI mutant was found to be avirulent in an acute rat lung infection model. This is in agreement with a previous study which showed that biosynthetic mutants unable to produce PQS are avirulent in a pathogenicity assay employing the nematode Caenorhabditis elegans (Gallagher & Manoil, 2001). Interestingly, in the plant infection model, the virulence of both mexI and opmD mutants could be restored to different levels by the provision of exogenous PQS. The fact that PQS only partially restored virulence in the mexI mutant could be explained by the inability of PQS to fully restore 3-oxo-C12-HSL production in this mutant. The restoration of virulence confirms that PQS uptake occurs via an alternative pathway to export and that PQS uptake is not dependent on the presence of a functional MexGHI-OpmD pump or the quorum sensing circuitry. These results clearly reveal the central role played by PQS as the primary quorum sensing signal molecule required for the healthy growth and full virulence of P. aeruginosa. As such 4-quinolone-dependent cell-to-cell communication, as well as the MexGHI-OpmD pump, make attractive targets for the development of novel anti-pseudomonal drugs.


   ACKNOWLEDGEMENTS
 
This work was supported in part by an IWT fellowship and a Marie Curie training fellowship (to S. A.), and by a grant (QLK3-2000-01759) from the European Union (Vth Framework Programme) and a grant from the Biotechnology and Biological Sciences Research Council (UK). We would like to thank Ram Chhabra, Chris Harty and Alex Truman for synthesizing the AHLs and PQS, and Mavis Daykin for technical support.


   REFERENCES
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DISCUSSION
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Received 20 September 2004; revised 20 December 2004; accepted 10 January 2005.



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