Influence of the Pseudomonas Quinolone Signal on Denitrification in Pseudomonas aeruginosa

Denitrification is a well-studied respiratory system that isalso important in the biogeochemical nitrogen cycle. Environmentalsignals such as oxygen and N-oxides have been demonstrated toregulate denitrification, though how denitrification is regulatedin a bacterial community remains obscure. Pseudomonas aeruginosais a ubiquitous bacterium that controls numerous genes throughcell-to-cell signals. The bacterium possesses at least two N-acyl-L-homoserinelactone (AHL) signals. In our previous study, these quorum-sensingsignals controlled denitrification in P. aeruginosa. In additionto the AHL signals, a third cell-to-cell communication signal,2-heptyl-3-hydroxy-4-quinolone, referred to as the Pseudomonasquinolone signal (PQS), has been characterized. In this study,we examined the effect of PQS on denitrification to obtain moreinsight into the respiratory regulation in a bacterial community.Denitrification in P. aeruginosa was repressed by PQS, whichwas partially mediated by PqsR and PqsE. Measuring the denitrifyingenzyme activities indicated that nitrite reductase activitywas increased by PQS, whereas PQS inhibited nitric oxide reductaseand the nitrate-respiratory chain activities. This is the firstreport to demonstrate that PQS influences enzyme activities,suggesting this effect is not specific to P. aeruginosa. Furthermore,when iron was supplied to the PQS-added medium, denitrifyingactivity was almost restored, indicating that the iron chelatingproperty of PQS affected denitrification. Thus, our data indicatethat PQS regulates denitrification primarily through iron chelation.The PQS effect on denitrification was relevant in a conditionwhere oxygen was limited and denitrification was induced, suggestingits role in controlling denitrification where oxygen is present.

INTRODUCTION

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INTRODUCTION

Bacteria regulate their metabolism by sensing environmentalsignals in order to adapt to various environmental conditions.In the environment, a number of bacteria are capable of usingN-oxides as alternative electron acceptors of oxygen. Denitrificationis a mode of anaerobic respiration in which nitrate (NO₃^–)or nitrite (NO₂^–) is reduced to gaseous N-oxides, suchas nitric oxide (NO), nitrous oxide (N₂O), and nitrogen (N₂),concomitant with energy generation (61). The switch from aerobicrespiration to denitrification is usually known to be regulatedby a response to N-oxides and oxygen levels (2, 28, 31). TheseN-oxides and oxygen levels are sensed through the CRP/FNR (cAMPreceptor protein/fumarate and nitrate reductase regulator) family,the members of which are global regulators that activate transcriptionof denitrifying genes (49). In Pseudomonas aeruginosa, a ubiquitousgram-negative environmental bacterium, denitrifying genes arealso regulated by N-oxides and oxygen levels through a regulatorynetwork requiring ANR, DNR regulatory proteins, and a nitrate-respondingtwo-component regulator, NarXL (45).

Although how respiration is regulated by physicochemical factorssuch as oxygen and N-oxide concentrations is well studied, howrespiration is regulated in a bacterial community remains obscure.The availability of electron acceptors will change due to thebacterial population or community. For instance, when a bacteriumforms a biofilm, the cells outside of the biofilm can utilizeoxygen, whereas inside the biofilm, the oxygen is depleted andbacterial metabolism changes (5). Where bacteria exist in highdensity, they can interact with each other through cell-to-cellcommunication signaling molecules, enabling the bacteria tocoordinate diverse biological functions. These signal moleculesin gram-negative bacteria are typically N-acyl-L-homoserinelactones (AHLs). P. aeruginosa possesses at least two of theseAHL-dependent quorum-sensing systems, the LasR-LasI (las) andRhlR-RhlI (rhl) systems (42). In order to investigate how bacterialrespiration is regulated as a community develops, we have previouslyexamined denitrification regulation by the AHL quorum-sensingsystems (52). The results demonstrated that the las and rhlquorum-sensing systems repress denitrification, and the regulationby the las quorum-sensing system is dependent on the rhl quorum-sensingsystem.

In addition to the AHL quorum-sensing signals, a non-AHL quorum-sensingsignal, 2-heptyl-3-hydroxy-4-quinolone, referred to as the Pseudomonasquinolone signal (PQS), has been characterized in P. aeruginosa(41). PQS regulates the production of itself and virulence factorssuch as elastase, rhamnolipids, and pyocyanin mediated by aLysR-type regulator PqsR (MvfR) and PqsE (19, 22, 54). The functionof PqsE is not known. The direct precursor of PQS is 2-heptyl-4-quinolone(HHQ), which is converted to PQS by a putative monooxygenase,PqsH, that is regulated by the LasR quorum-sensing system (16).HHQ has also been reported to act as a ligand of PqsR, indicatingits role in cell-cell communication as well as PQS (58). Inaddition, HHQ is produced in other pathogenic bacteria besidesP. aeruginosa, suggesting a role in interspecies communication(17).

To obtain more insight into how energy production is regulatedin a bacterial community, we examined the effect of PQS on denitrification.Based on our results, PQS affects denitrifying enzyme activitiesprimarily due to the chelating activity of PQS. These resultssuggest that PQS not only affects respiration in P. aeruginosabut may also affect respiration in other species of bacteria.The low production of PQS in anaerobic conditions points outthat this effect is relevant in interfaces of oxygen respirationand denitrification.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Bacterial strains, plasmids, and growth conditions. The strains and plasmids used in this study are listed in Table1. Bacterial strains were routinely grown at 37°C in Luria-Bertani(LB) medium or on LB agar plates. When necessary, gentamicinwas added at the concentration of 10 µg/ml for Escherichiacoli and 80 µg/ml for P. aeruginosa. PQS and N-(3-oxododecanoyl)-L-homoserinelactone (3-oxo-C₁₂-HSL) were synthesized and purchased fromNARD institute, Ltd. (Hyogo, Japan). A total of 20 mM PQS and400 µM 3-oxo-C₁₂-HSL stock solution in dimethyl sulfoxidewas prepared and added to the culture as a final concentrationof 50 µM or 1 µM, respectively. An equivalent amountof dimethyl sulfoxide was added to control cultures. Beforebeginning experimental cultures, P. aeruginosa was grown aerobicallyin 24-ml test tubes containing 4 ml of LB medium and was usedto inoculate cultures at a starting optical density at 600 nm(OD₆₀₀) of 0.01. The culture that examined the effect of 3-oxo-C₁₂-HSLon denitrification was inoculated at a starting OD₆₀₀ of 0.1.For anaerobic cultures, the air of butyl-rubber-sealed Hungatetubes or Erlenmeyer flasks was replaced with argon by flushinggas through a needle. Anaerobic growth, denitrification activity,and transcriptional activity were measured using 17-ml Hungatetubes containing 5 ml LBN medium (LB medium supplemented with100 mM KNO₃) incubated at 37°C with shaking at 200 rpm.Oxygen-limiting experiments were carried out by using butyl-rubber-sealed17-ml Hungate tubes containing 2 ml LBN medium incubated at37°C with shaking at 170 rpm. Cells used to determine denitrifyingenzyme activities were anaerobically cultured in a 500-ml Erlenmeyerflask containing 80 ml LBN at 37°C and 200 rpm. The pqsAtranscriptional fusion plasmid was constructed by cloning thepromoter region of pqsA (59), using pmpqsAF3 and pmpqsAR PCRprimers (Table 1), into the multicloning site of pMEX9 reporterplasmid. Plasmids were transformed into P. aeruginosa strainPAO1 by electroporation (20). Complementation plasmids carryingpqsR or pqsE were constructed by cloning each gene into themulticloning site of pUCP24. cpqsRF/cpqsRR or cpqsEF/cpqsERprimer pairs (Table 1) were used to amplify pqsR and pqsE, respectively.

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TABLE 1. Bacterial strains, plasmids, and primers

Construction of P. aeruginosa mutants. The primers used in this study are listed in Table 1. pG19pqsA,pG19pqsH, pG19pqsR, and pG19pqsE plasmids carrying deletioncassettes of pqsA, pqsH, pqsR, and pqsE were constructed withthe same procedure described previously (36). The PAO1 chromosomewas amplified with pqsAF1/pqsAR2, pqsHF1/pqsHR2, pqsRF1/pqsRR2,or pqsEF1/pqsER2 primer pairs and then ligated into the XbaI/HindIII-treatedmulticloning site of a cloning vector, pHSG398. The DNA flankingfragments of pqsA, pqsH, pqsE, and pqsR on pHSG398 were amplifiedusing inverse PCR with pqsAF2/pqsAR1, pqsHF2/pqsHR1, pqsRF2/pqsRR1,or pqsEF2/pqsER1 PCR primers. The amplified pqsA flanking fragmentwas digested with SpeI, and the amplified pqsH, pqsR, and pqsEflanking fragment was digested with BglII, as restriction siteshad been attached to the primers. The pqsA-, pqsH-, pqsR-, andpqsE-deleted DNA fragments were subcloned into the XbaI-HindIIIsite in the multicloning site of pG19II, generating pG19pqsA,pG19pqsH, pG19pqsR, and pG19pqsE. The pG19II-derived plasmidswere transferred into PAO1, ${Delta}$ pqsA, ${Delta}$ lasI, and ${Delta}$ rhlI strains byconjugating with E. coli S17-1 (48), followed by homologousrecombination previously described elsewhere (36). The mutantswere analyzed by PCR.

Preparation of cell fractions. Cells grown in LBN medium were collected in the mid-logarithmicphase (6-h incubation time), centrifuged at 7,000 x g at 4°C,and washed twice with 100 mM potassium phosphate buffer, pH7.5, containing 10% glycerol. The cells were suspended in thesame buffer and sonicated. The sonicated cells were centrifugedfor 10 min at 2,000 x g at 4°C to remove unbroken cellsand then centrifuged at 104,000 x g at 4°C for 60 min. Thesupernatants were collected as soluble fractions of the cells,and the pellets were resuspended in the same buffer and collectedas membrane fractions.

Enzyme activity assays. NAR activity was assayed by determining its NO₂^– productcolorimetrically as described by Nicholas and Nason (39).

Benzylviologen-dithionite-related NAR activity was assayed accordingto a method previously described elsewhere (30) by using benzylviologeninstead of methylviologen. One hundred microliters of Na₂S₂O₄was added at a final concentration of 10 mM into a 400 µl100 mM potassium phosphate buffer (pH 7.5) containing 10 mMNaNO₃, 0.2 mM benzylviologen, and an appropriate concentrationof the cell membrane fraction of anaerobically cultured P. aeruginosa.The air in the reaction mixtures was replaced with N₂ beforeadding Na₂S₂O₄. The reaction mixture was incubated at 30°Cfor 5 min and was vortexed until the color of the mixture becameclear, indicating methylviologen oxidation.

NAR activity associated with the respiratory chain was measuredusing NADH as an electron donor (43). Five-hundred-microliterreaction mixtures for NADH-derived NAR activity assays contained10 mM NaNO₃ and the membrane fraction of anaerobically culturedP. aeruginosa. The air in the reaction mixture was replacedwith N₂. The reaction was started by the addition of NADH ata final concentration of 1 mM at 30°C and was stopped bybeing boiled at 100°C for 15 min.

NIR activity was assayed by measuring NO₂^– consumption(32). The reaction was started by the addition of 100 µlNADH at a final concentration of 1 mM into a 400-µl mixturecontaining 200 µM NaNO₂, 200 µM phenazine methosulfate,and the soluble fraction of anaerobically cultured P. aeruginosa.The air in the reaction mixtures was replaced with N₂ beforeadding NADH, and the reactions were carried out at 30°Cfor 10 min.

NOR activity was assayed by a modified method measuring itsproduct, N₂O, with a gas chromatograph (50). One hundred microlitersof 20 mM NO donor sodium nitroprusside was injected into 900-µlreaction mixtures in which the air had been replaced with N₂and which contained 4 mM NADH, 0.2 mM phenazine methosulfate,and the membrane fraction of anaerobically cultured P. aeruginosa.The reactions were carried out at 30°C for 6 min.

Catechol 2,3-dioxygenase (C23O) specific activity (the xylEgene product) was determined by the method described previously(36, 44) by monitoring A₃₇₅.

Analytical methods. Bacterial growth in liquid cultures was monitored based on theOD₆₀₀. The protein amount was quantified using the method ofBradford (6). NO₃^– concentrations were determined usingthe Brucine method described in reference 39. N₂O, N₂, and O₂concentrations were measured with a gas chromatograph (GC-8AIT;Shimadzu) equipped with a gas thermal conductivity detector.Helium was used as the carrier gas. A Shincarbon ST column wasused for N₂O detection, and a Molecular Sieve 5A column wasused for the detection of N₂ and O₂.

PQS production assays. PQS was collected from the supernatant and detected by thin-layerchromatography (TLC) analysis, following the method previouslydescribed (37). Stationary-phase samples cultured for 16 h werecentrifuged for 1 min at 13,000 x g to collect the supernatants.PQS was extracted from 1 ml of supernatants twice with 600 µlacidified ethyl acetate. The ethyl acetate portion was collectedinto a new tube and dried. Extracts were resuspended in 20 µlof 1:1 acidified ethyl acetate/acetonitrile. Aliquots of extractswere loaded on TLC plates (silica gel 60 F254; Merck) whichhad been soaked in 5% KH₂PO₄ for 30 min and activated at 100°Cfor 1 h. The extracts were separated using 17:2:1 methylenechloride/acetonitrile/1,4-dioxane as the solvent. SyntheticPQS was used as a control. Photographs were taken under long-waveUV light by using a digital camera. The spot intensity was evaluatedby using ImageMaster 1D Elite version 4.2 software (AmershamPharmacia Biotech), following the method previously published(37).

RESULTS

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RESULTS

Anaerobic growth is repressed by PQS. First, we examined the effect of PQS on the growth of P. aeruginosa.When grown aerobically in LB medium or anaerobically in LBNmedium, no change in growth was observed between the wild-type(WT) strain and the ${Delta}$ pqsA or ${Delta}$ pqsH mutants (Fig. 1). However,when PQS was added to the medium, a longer lag phase was observedin the aerobic culture, as had been observed previously (19)(Fig. 1A). This may be due to the prooxidant effect of PQS,as it was demonstrated in a recent paper (24). When PQS wasadded to anaerobic cultures (Fig. 1B), it resulted in a lowerstationary-phase OD than that of the growth in LBN medium alone.To investigate the mechanism of PQS suppression of anaerobicgrowth, we further examined the effect of PQS on denitrification.

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FIG. 1. PQS effect on aerobic growth and anaerobic growth. Aerobic growth (A) and anaerobic growth (B) of P. aeruginosa with or without exogenous PQS. PQS was added at a final concentration of 50 µM in all experiments. Three independent experiments were carried out, and representative data are shown.

PQS affects denitrifying enzyme activities. Denitrification is a process known to reduce NO₃^– to N₂Oor N₂ gases and is physiologically important for acquiring energyunder anaerobic conditions (61). During the denitrificationprocess, NO₃^– reductase (NAR), NO₂^– reductase (NIR),NO reductase (NOR), and N₂O reductase (NOS) are involved (61).Each denitrifying enzyme is encoded by genes that are organizedinto distinct operons (2, 3, 29, 47). In order to examine theeffect of PQS on transcription of each denitrifying enzyme,promoter fusion plasmids (52) with the xylE gene fused withpromoter regions of narK1, nirS, norC, and nosR denitrifyinggenes were each transferred to a ${Delta}$ pqsA mutant. As a control,the basal C23O activity was measured in a ${Delta}$ pqsA mutant transformedwith a pMEX9 plasmid with or without added PQS. C23O activitywas measured during the mid-logarithmic phase (a 6-h incubation).The promoter-dependent C23O activity was determined by dividingits C23O activity by the basal C23O activity. When PQS was addedto the culture of each strain at a final concentration of 50µM, no significant effect on the promoter activity couldbe observed (Fig. 2). This result indicates that the denitrificationregulation by PQS is not due to transcriptional regulation butis caused by other posttranscriptional mechanisms. To examinewhether denitrification is regulated in posttranscriptionallevels, denitrifying enzyme activities were measured duringthe mid-logarithmic phase. A ${Delta}$ pqsA mutant was cultured with orwithout added PQS, and then NAR, NIR, and NOR denitrifying enzymeactivities were measured. As a result, NAR activity was suppressed(66% activity compared to the NAR activity of a ${Delta}$ pqsA mutantcultured without added PQS) in the culture incubated with PQS(Fig. 3A). Interestingly, NIR activity increased 1.8-fold inthe culture incubated with PQS (Fig. 3B). NOR activity was suppressedto 64% when PQS was added to the culture (Fig. 3C). The changesin these denitrifying enzyme activities may be due to posttranscriptionalregulation, or PQS may have affected enzyme activities. To furtherexamine whether PQS affects denitrifying enzyme activities,an assay was carried out by adding PQS to each enzyme assayreaction mixture with ${Delta}$ pqsA mutant cell fractions collected fromcells cultured without PQS. As shown in Fig. 3C, NOR activitywas inhibited by the PQS addition in vitro. On the other hand,NAR and NIR activity was not affected by the addition of PQSin vitro (Fig. 3A and B). Taken with the result that transcriptionof denitrifying genes was not regulated by PQS, our resultsindicate that NAR and NIR activities are regulated posttranscriptionally,requiring growth with PQS, and NOR activity is inhibited byPQS.

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FIG. 2. PQS effect on denitrifying gene expression. C23O activity was measured in cells cultured for 6 h (mid-logarithmic phase). C23O activity (nanomoles of product/minute/milligram of protein) of denitrifying gene promoters was measured and was normalized by the C23O activity of promoterless control plasmids. +PQS, cultured with exogenous PQS; –PQS, cultured without exogenous PQS. The data displayed are the means ± standard deviations of more than three independent experiments.

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FIG. 3. PQS effect on denitrifying enzyme activities and NO₃^– respiratory chain. NAR (A), NIR (B), NOR (C), and NADH-dependent NAR (D) activities were measured in cells cultured for 6 h (mid-logarithmic phase). PQS was added at a final concentration of 50 µM for the culture medium or the reaction mixture. Bar 1, PAO1; bar 2, ${Delta}$ pqsA mutant cultured without added PQS; bar 3, ${Delta}$ pqsA mutant cultured with PQS; bar 4, PQS added to the reaction mixture with cell fractions collected from a ${Delta}$ pqsA mutant cultured without added PQS. More than three independent experiments were carried out, and the data represented are means ± standard deviations of triplicate assays.

PQS inhibits the NO₃^– respiratory chain. Denitrifying enzymes are associated with the respiratory chainin which energy is generated. During NO₃^– respiration,the electron donated from NADH is transferred through the respiratorychain and finally accepted by NO₃^–. The final step ismediated by NAR (61). In the NAR activity assay (Fig. 3A), anelectron donor (benzylviologen) that donates electrons directlyto NAR was used, and the activity of the NO₃^– respiratorychain was not taken into account. In order to examine whetherthe NO₃^– respiratory chain is affected by PQS, a NADH-derivedNAR activity assay was carried out. When NADH was used as anelectron donor, NADH-NAR activity was repressed in the culturewith added PQS and was also inhibited in vitro when PQS wasadded to the reaction mixture (Fig. 3D). These results indicatethat NO₃^– respiration is inhibited by PQS. The fact thatPQS inhibited NADH-derived NAR activity (Fig. 3D), but not benzylviologen-derivedNAR activity (Fig. 3A), indicates that PQS's inhibition occurssomewhere in the electron transfer from NADH to NO₃^–.

Iron-chelating property of PQS affects denitrification. In this study, our results addressed that PQS influences denitrificationby affecting the denitrifying enzyme activities without regulatingtheir transcription. PQS has been reported not only to regulatetranscription in P. aeruginosa but also to chelate iron (7,18). We considered that this chelating effect on iron may affectthe denitrification activity. To test this hypothesis, FeCl₃was added to the medium in addition to PQS. The iron additionfully restored suppression of NO₃^– reduction and N₂O productionin the culture with exogenous PQS (Fig. 4A and B) and indicatedthat the PQS regulation of denitrification is due to iron chelation.To confirm that iron chelation affects denitrification, an ironchelator, 2,2'-bipyridyl, was added to the culture, and denitrificationactivity was measured. NO₃^– reduction and N₂O productionwere suppressed (as is the case of PQS); NO₃^– reductionand N₂O production were then restored by supplementing FeCl₃(Fig. 4A and B). Interestingly, N₂ production was restored onlypartially by FeCl₃ in the PQS-added culture, and 2,2'-bipyridyldid not repress N₂ production (Fig. 4C). These results suggestthat N₂O reduction to N₂, which is catalyzed by NOS, is regulatedby mechanisms other than iron chelation by PQS.

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FIG. 4. Effect of iron chelation on denitrification. NO₃^– reduction (A), N₂O production (B), and N₂ production (C) of ${Delta}$ pqsA mutant. PQS, 2,2'-bipyridyl, and FeCl₃ were added at final concentrations of 50 µM, 120 µM, and 100 µM, respectively. Data displayed are means ± standard deviations of three independent experiments.

PQS regulates N₂ production through PqsR and PqsE. A number of PQS-regulated genes require the cognate responseregulator PqsR (11, 15, 54) or a functionally unknown PqsE,which is known to facilitate the response to PQS (19, 22). Tofurther examine if the N₂O reduction to N₂ is regulated by thispathway, ${Delta}$ pqsA ${Delta}$ pqsR and ${Delta}$ pqsA ${Delta}$ pqsE double mutants were constructed.PQS was added to the mutants, and the amounts of NO₃^–that was reduced and N₂O and N₂ that were produced during a12-h incubation were measured. The denitrifying activities of ${Delta}$ pqsA ${Delta}$ pqsR and ${Delta}$ pqsA ${Delta}$ pqsE mutants (Fig. 5) were identical to thatof ${Delta}$ pqsA (Fig. 4). As shown in Fig. 5C, the repression of N₂production by PQS was not observed in either the ${Delta}$ pqsA ${Delta}$ pqsR orthe ${Delta}$ pqsA ${Delta}$ pqsE mutants, while PQS repressed N₂ production in ${Delta}$ pqsA (Fig. 4C), indicating that N₂ production is regulated byPQS through PqsE and the PqsR transcriptional regulator. Togetherwith the result that N₂ production was not affected by an ironchelator (Fig. 4), our data indicate that PQS regulates N₂ productionby a pathway that mediates PqsR and PqsE and does not dependon the iron chelation property of PQS. This regulation is likelyto be involved in the transcriptional regulation of factorsinvolved in N₂ production other than the nos operon, since PQSdid not regulate nosR transcription (Fig. 2). The NO₃^–reduction and N₂O production were repressed by PQS even in theabsence of PqsE or PqsR (Fig. 5A and B), as had been observedfor ${Delta}$ pqsA (Fig. 4A and B), supporting our suggestion that NO₃^–reduction to N₂O is regulated by PQS iron chelation. To confirmthat the results observed for ${Delta}$ pqsA ${Delta}$ pqsR and ${Delta}$ pqsA ${Delta}$ pqsE strainsare not due to polar effects, an experiment complementing eachmutant with its appropriate WT copy ( ${Delta}$ pqsA ${Delta}$ pqsR/pUCP-pqsR, ${Delta}$ pqsA ${Delta}$ pqsE/pUCP-pqsE) was carried out. Surprisingly, NO₃^– reductionand N₂O and N₂ production were all strongly repressed when pqsRand pqsE were expressed on a plasmid, even in the absence ofPQS (data not shown).

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FIG. 5. PqsR and PqsE involvement in N₂ production regulation by PQS. NO₃^– reduction (A), N₂O production (B), and N₂ production (C) of ${Delta}$ pqsA ${Delta}$ pqsR and ${Delta}$ pqsA ${Delta}$ pqsE mutants with or without exogenous PQS, represented as black bars or white bars, respectively. pUCP24 plasmid was transferred into each strain as a control for the complementation experiments. The data displayed are the means ± standard deviations from three independent experiments. PQS was added at a final concentration of 50 µM in all experiments.

Relation of AHLs and PQS in denitrification regulation. In our previous study, AHLs regulated transcriptions of denitrifyinggenes (52). PQS is known to be incorporated in the AHL signalingpathway where the las quorum-sensing system regulates the PQSsystem and the PQS system regulates the rhl quorum-sensing system(38). To further investigate the relationship between AHL andPQS signaling systems in denitrification regulation, we firstexamined whether the las quorum-sensing requires PQS for denitrificationregulation. When 3-oxo-C₁₂-HSL was added to the culture, 3-oxo-C₁₂-HSLregulated denitrifying activity at the same extent in a ${Delta}$ lasImutant and a ${Delta}$ pqsA ${Delta}$ lasI double mutant (Fig. 6A to C), indicatingthat PQS is not required for the 3-oxo-C₁₂-HSL denitrificationregulations. This result correlates with the fact that PQS islacking under anaerobic conditions (later discussed in Fig.7), suggesting that PQS has less effect on las quorum-sensingregulated phenotypes under anaerobic conditions. The N₂O accumulationinduced by 3-oxo-C₁₂-HSL may be due to the imbalance of NORand NOS activity, in which NOS activity may have been repressedby 3-oxo-C₁₂-HSL to a greater extent than NOR activity, as isthe case of NO accumulation caused by rhlR deletion (23). Furthermore,it was examined whether the rhl quorum-sensing system is incorporatedin the effect of PQS on denitrification. When PQS was addedto a ${Delta}$ pqsA ${Delta}$ rhlI double mutant, NO₃^– reduction to N₂O wasrepressed, as had been observed in a ${Delta}$ pqsA mutant (Fig. 6D and E).However, N₂ production was repressed only partially by the PQSaddition in the ${Delta}$ pqsA ${Delta}$ rhlI double mutant compared to the ${Delta}$ pqsAmutant (Fig. 6F), indicating that the rhl quorum-sensing systemis partially required for the repression of N₂ production byPQS. Since N₂ production was not fully repressed by the PQSaddition to a ${Delta}$ pqsA ${Delta}$ pqsR mutant, these data suggest that a transcriptionalregulation mediated by PqsR and the rhl quorum-sensing systemis involved in N₂ production. According to our previous study(52), the rhl quorum-sensing system repressed nosR transcription;therefore, it may simply be considered that PQS induced therhl quorum-sensing system through PqsR, leading to the repressionof nosR transcription. However, repression of nosR transcriptionby PQS was not observed in this study (Fig. 2). The effect ofPQS on nosR transcription may have been too little to be detectedby the transcriptional assay; otherwise, there may be a complicatedregulatory system in N₂ production. The result that the N₂ productionin the ${Delta}$ pqsA ${Delta}$ pqsR strain was not repressed by PQS, while N₂ productionin the ${Delta}$ pqsA ${Delta}$ rhlI strain was partially repressed by PQS, indicatesthat there are other factors regulated by PqsR that are involvedin the N₂ production in addition to the rhl quorum-sensing system.

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FIG. 6. Relation between AHLs and PQS in denitrification regulation. NO₃^– reduction (A), N₂O production (B), and N₂ production (C) of ${Delta}$ lasI and ${Delta}$ pqsA ${Delta}$ lasI mutants with (+3oC₁₂) or without (–) exogenous 3-oxo-C₁₂HSL. 3-Oxo-C₁₂HSL was added at a final concentration of 1 µM in all experiments. NO₃^– reduction (D), N₂O production (E), and N₂ production (F) of ${Delta}$ pqsA and ${Delta}$ pqsA ${Delta}$ rhlI mutants with (+PQS) or without (–) exogenous PQS are shown. PQS was added at a final concentration of 50 µM in all experiments. The data displayed are the means ± standard deviations from three independent experiments.

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FIG. 7. PQS signaling under anaerobic conditions. (A) PQS production in the supernatant of aerobic, anaerobic, or oxygen-limited cultures. PQS was detected by TLC analysis. Lane 1, synthetic PQS; lane 2, aerobic culture; lane 3, anaerobic culture; lane 4, oxygen-limited culture with LBN medium; lane 5, synthetic PQS. (B) Comparison of PQS production between aerobic, anaerobic, and oxygen-limited cultures. Bar 1, aerobic culture; bar 2, anaerobic culture; bar 3, oxygen-limited culture with LBN medium. PQS production was compared by measuring the band intensity of the TLC plates with an image analyzer. ND, not detected. (C) pqsA expression in PAO1 and a ${Delta}$ pqsR mutant under anaerobic conditions. pMEXpqsA or pMEX9 was introduced in each cells. C23O activity (nanomoles of product/minute/milligram of protein) was measured in cells cultured for 12 h (stationary phase). C23O activity of pMEXpqsA-introduced cells was measured and was normalized by the C23O activity of pMEX9-introduced cells. Data displayed are means ± standard deviations of three independent experiments.

PQS signaling under anaerobic conditions. In order to reveal the PQS effect on denitrification, our experimentswere carried out under anaerobic conditions. Interestingly,although PQS suppressed denitrification, no changes in growthbetween the WT and the ${Delta}$ pqsA ${Delta}$ pqsH mutants were observed (Fig.1), and no differences in denitrification activity were observedbetween WT and non-PQS-producing strains (data not shown). Toexamine whether PQS is produced under anaerobic conditions,PQS was extracted from culture supernatants and was detectedby TLC. When grown aerobically, PQS was detected but it couldnot be detected under anaerobic conditions (Fig. 7A and B).Although PQS was not produced under anaerobic conditions, theresult that the addition of PQS to a ${Delta}$ pqsR mutant did not repressN₂ production (Fig. 5C) suggests that PQS can regulate genetranscriptions in a PqsR-dependent manner under anaerobic conditions.To examine whether the PQS signaling system mediated by PqsRcould be activated under anaerobic conditions, pqsA expression,which is known to be regulated by PQS through PqsR under aerobicconditions (37), was measured in the WT P. aeruginosa stainPAO1 and a ${Delta}$ pqsR mutant. When PQS was added to PAO1, pqsA wasinduced, while it was not induced in the absence of PqsR (Fig.7C). These results, along with results demonstrating the lackof PQS under anaerobic conditions (Fig. 7), indicate that cellsunder anaerobic conditions can respond to PQS through PqsR butcannot produce PQS. The reason why PQS is lacking under anaerobicconditions could be due to the final step of PQS synthesis,which is predicted to require diatomic oxygen (22).

Effect of PQS on denitrification is relevant under oxygen-limiting conditions. When considering the environment, oxygen concentration is notalways constant and changes according to several factors, includingcell population. The PQS effect on denitrification may be relevantunder such conditions. To examine whether PQS affects denitrificationunder conditions where oxygen is gradually depleted and denitrificationis induced, we cultured P. aeruginosa in a Hungate tube witha rubber cap. The oxygen concentration was 7.5 ppm at the startof the culture and became less than 1.7 ppm at the end of theculture (16 h). Under these conditions, PQS was detected inthe supernatant (Fig. 7A and B), and the ${Delta}$ pqsA, ${Delta}$ pqsH, and ${Delta}$ pqsRmutants reduced more NO₃^– and produced more N₂O than PAO1(Fig. 8). These results indicate that denitrification is repressedby PQS when PQS is produced. Interestingly, the PQS productionwas lower compared to the aerobic conditions (Fig. 7A and B),suggesting that oxygen or N-oxides related to denitrificationregulate PQS production. When PQS was added to the medium, PQSrepressed NO₃^– production and N₂O production in PAO1 andthe ${Delta}$ pqsH mutant to a greater extent than in the ${Delta}$ pqsA and ${Delta}$ pqsRmutants (Fig. 8). The transcriptional regulator PqsR is knownto regulate the pqsABCDE operon (54). Therefore, under oxygen-limitingconditions, other 2-alkyl-4-quinolones (AHQs), such as 2-heptyl-4-quinoloneN-oxide (HQNO) or HHQ, which are produced as a result of thetranscription of the pqsABCDE operon (16), may be involved indenitrification regulation. The denitrification repression byPQS in the ${Delta}$ pqsR mutant indicates that PQS represses denitrificationwithout mediating PqsR, as had been observed under anaerobicconditions. To confirm if this denitrification suppression byPQS was a result of the iron-chelating activity, FeCl₃ was addedto the medium. FeCl₃ addition increased denitrifying activityin PAO1 to the level of the non-PQS-producing mutants and restoreddenitrifying activity in the PQS-added ${Delta}$ pqsA and ${Delta}$ pqsH mutants(Fig. 8). Taken together, PQS affects denitrification by chelatingiron under oxygen-limiting environments where denitrificationis induced and a sufficient amount of PQS is produced to influencedenitrification.

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FIG. 8. PQS effect on denitrification under oxygen-limited conditions. NO₃^– reduction (A) and N₂O production (B) of PAO1, ${Delta}$ pqsA, ${Delta}$ pqsH, and ${Delta}$ pqsR mutants in LBN medium in the presence of oxygen. PQS and FeCl₃ were added at final concentrations of 50 µM and 100 µM, respectively. Data displayed are means ± standard deviations of three independent experiments.

DISCUSSION

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DISCUSSION

Bacterial energy production is well known to be regulated bythe environment. On the other hand, the environment surroundingthe bacteria changes due to the bacterial population or community.However, the impact of cell-to-cell communication on regulatingenergy production has not been well documented. This researchwas carried out to gain more insight into respiration regulationin a bacterial population. Some studies in Rhizobium specieshave reported that cell-to-cell communication affects the growthrate, although the mechanisms remain obscure (14, 25, 46, 56).Another study demonstrated that butanediol fermentation in Serratiaspecies is affected by quorum-sensing as a result of changesin acidic end products (53). We have demonstrated previouslythat AHL signal molecules (C₄-HSL and 3-oxo-C₁₂HSL) repressdenitrification in P. aeruginosa, which was mediated by regulatoryproteins RhlR or LasR exerting denitrifying gene expression(52). In contrast to the AHL regulation of denitrification inP. aeruginosa, the PQS effect on denitrification does not necessarilyrequire the regulatory protein PqsR but depends primarily onits iron-chelating property and has a potential to inhibit denitrificationin other species. PQS may have depleted iron from the medium,and besides, results from our in vitro assay adding PQS to thecell lysates (Fig. 3) suggest that PQS can affect enzyme activities,presumably by chelating iron. According to our knowledge, thisis the first report to demonstrate that PQS affects enzyme activities.Thus, PQS is the third cell-cell communication molecule to bereported to control denitrification in P. aeruginosa, and thisreceptor-independent effect on denitrification by PQS may havean impact on P. aeruginosa interactions with other bacteriaspecies.

Another fact suggesting the role of PQS in interspecies interactionsis the presence of HHQ producers, which could induce PQS production.HHQ has been reported to be produced in the supernatant of somehuman pathogens (17). Once HHQ is produced in the supernatant,it can be converted to PQS by P. aeruginosa (16). The fact thatPQS can affect denitrification by chelating iron, and that PQSproduction could be induced by other HHQ-producing bacteria,leads us to postulate that PQS may have an impact on a bacterialcommunity of HHQ producers, and further studies in this areaare expected.

The biosynthetic pathway that produces PQS also generates diverseAHQs besides HHQ (16). HQNO is one of the AHQs, known as a classicalrespiratory inhibitor that suppresses growth in gram-positivebacteria but not in gram-negative bacteria (34). The spectrumof HQNO is broader in vitro, where it was demonstrated to bindto a nitrate reductase subunit (NarI) of Escherichia coli (35).Although PQS and HQNO inhibit respiration, their mechanismsseem to differ. HQNO inhibits respiration by binding to quinone-reactingcytochromes and inhibits respiratory electron transfer fromquinone to cytochromes (35), while PQS depends on iron chelating.According to the mechanism, PQS may inhibit respiration in otherspecies, and it will be interesting to examine the differencein spectrum of HQNO in future research.

In this study, PQS did not decrease aerobic growth, but it diddecrease anaerobic growth (Fig. 1). The amount of iron requiredfor denitrification may be greater than that for aerobic respiration.Supporting this hypothesis, Diggle et al. (18) have demonstratedthat PQS would decrease aerobic growth under iron-deficientconditions. In P. aeruginosa, the aerobic respiratory chainis predicted to be well branched, possessing five putative terminaloxidases (13), which may be another reason why PQS had lesseffect on aerobic growth than on anaerobic growth. Still, theregulation and the role of these terminal oxidases are poorlyunderstood, and it will be interesting to examine whether theseterminal oxidases are affected by PQS and to investigate therole of PQS in the aerobic respiratory chain.

The suppression of NO₃^– reduction and N₂O production byPQS iron chelation (Fig. 4), along with PQS's inhibition ofNO₃^– respiration and NOR activities (Fig. 3), suggeststhat PQS inhibits NO₃^– respiration and NOR activity bychelating iron. Iron is related to the NO₃^– respiratorychain during the transfer of electrons from NADH to NO₃^–(21, 61). The NOR enzyme in P. aeruginosa is a cytochrome bc-typeenzyme consisting of cytochrome c and cytochrome b (1, 61).Therefore, it will be reasonable to consider that PQS inhibitstheir activities by chelating iron. Conversely, it was surprisingto us that NIR activity was not inhibited by PQS (Fig. 3B),because the P. aeruginosa NIR enzyme is a cytochrome cd₁-typeenzyme (60) that requires iron for its activity. There is aconsiderable difference in the hydrophobicity between the enzymesinhibited by PQS and the noninhibited enzymes. The PQS-affectedNO₃^– respiration and NOR enzyme are associated with thecell membrane, while the NIR enzyme is soluble and located inthe periplasm (61). Together with the fact that PQS is a highlyhydrophobic molecule (10), it can be assumed that the proteinhydrophobicity is one of the factors that determine whetherPQS affects the activity or not. The result that PQS is associatedwith the cell membrane (33) could also support our study thatPQS inhibits NO₃^– respiration and NOR enzyme activities.It will be interesting to further investigate whether the PQSeffect on NO₃^– respiration and the NOR enzyme activitiesis due to direct interactions of PQS with the enzymes.

Denitrification regulation by PQS was due not only to the iron-chelatingproperty of PQS but was also partially regulated through PqsEand PqsR regulatory proteins. The result that an iron chelator,2,2'-bipyridyl, did not suppress N₂ production, while NO₃^–reduction and N₂O were suppressed (Fig. 4), suggests that N₂production is regulated by PQS but by mechanisms other thaniron chelation. This suggestion was confirmed by the resultthat PqsE and PqsR were required for PQS regulation of N₂ suppression(Fig. 5C). Results from the experiment in which PQS was addedto a ${Delta}$ pqsA ${Delta}$ rhlI mutant indicate that several factors, includingthe rhl quorum-sensing system, are incorporated in this regulation(Fig. 6D to F). Collectively, our study demonstrates that denitrificationis regulated by PQS by at least two pathways; one pathway isdependent on the iron-chelating property of PQS, and the otheris dependent on transcriptional regulation by PQS mediated throughPqsE and PqsR (Fig. 9). The fact that iron chelators inhibitN₂O production without inhibiting N₂ production may serve asa basis for development of a more efficient water treatmentsystem, since N₂O emission during wastewater treatment is knownto contribute to global warming and has become a problem. Previously,microarray data by Déziel et al. (15) comparing transcriptionalprofiles of WT with a ${Delta}$ mvfR (pqsR) mutant suggested that denitrifyinggenes are controlled by PqsR. When pqsR was expressed on a plasmidin our experiment, denitrification activity was repressed ina ${Delta}$ pqsA ${Delta}$ pqsR mutant background that does not produce AHQs, includingPQS (data not shown). Along with the result that PQS did notaffect transcription of denitrifying genes (Fig. 2), these resultssuggest that PqsR regulates denitrifying genes alone withoutPQS when it is expressed in a sufficient amount. Still, theexperiments of Déziel et al. (15) were carried out underaerobic conditions without NO₃^– added, and it will notbe that simple to compare their results with ours using anaerobicconditions.

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FIG. 9. Proposed model for PQS regulation of NO₃^– respiration and denitrifying enzymes. The NO₃^– respiratory chain and NOR enzyme activities are inhibited by PQS through iron chelation. NAR activity is repressed, and NIR activity is increased by PQS indirectly, presumably through iron chelation. PqsE and PqsR are involved in the NOS activity repression. DH, NADH dehydrogenase; OM, outer membrane; PP, periplasmic space; IN, inner membrane; e^–, electron flow.

Our data indicate that the effect of PQS on denitrificationis relevant where oxygen is present or was present and denitrificationis induced. The regulation may be important in the transitionfrom aerobic respiration to denitrification. Also, the regulationmay be important in an environment where oxygen is localized,such as in biofilms, where oxygen is consumed at the surfaceand conditions become anaerobic inside (5). Our in vitro results(Fig. 3) suggest that PQS promotes NO accumulation, since NIRactivity (which reduces NO₂^– to NO) was elevated, whileNOR activity (which further reduces NO to N₂O) was suppressedafter the addition of PQS into the medium. These results mayexplain the mechanism of NO accumulation in biofilms, whichin turn regulates biofilm formation by upregulating bacterialmotility (4). PQS has also been detected in the lungs of P.aeruginosa-infected individuals with cystic fibrosis, conditionswhich are considered to be O₂ limited (57) and where NO₃^–levels are sufficient for anaerobic growth (40). In addition,P. aeruginosa is known to denitrify even in the presence ofoxygen (12, 51). Although the ecological role of aerobic denitrificationis still uncertain, PQS denitrification regulation may be involved.

Regarding the significance of respiratory regulation by cell-to-cellcommunication molecules, a number of studies have demonstratedthat respiratory chains are not only coupled to energy generationbut also serve other functions. Considering the advantage ofrepressing growth, there are studies reporting that inhibitingrespiration results in increased aminoglycoside resistance (9,26). A study in P. aeruginosa has suggested that NAR-relatedfunctions are involved in this resistance, since resistanceto aminoglycosides was increased in a NAR activity-deficientmutant and the susceptibility was increased in a strain withincreased NAR activity (8). The denitrification regulation byPQS may not be restricted to the regulation of energy generationbut may have significance for bacterial physiology. The biologicalroles of denitrification regulation by cell-to-cell communicationsignaling molecules, such as AHL and PQS, remain elusive, andit is reasonable to assume that there are biological functionsyet to be uncovered.

ACKNOWLEDGMENTS

We thank Michael A. Kertesz for providing us with the pME4510plasmid and Herbert P. Schweizer for providing us with the pUCP24plasmid.

This study was partially supported by a grant to N.N. from theIndustrial Technology Research Grant Program 2003-2005 of theNew Energy and Industrial Technology Development Organization(NEDO) of Japan.

FOOTNOTES

* Corresponding author. Mailing address: Graduate School of Life and Environmental Sciences, University of Tsukuba, Tsukuba, Ibaraki 305-8572, Japan. Phone and fax: 81-29-853-6627. E-mail: nomunobu{at}sakura.cc.tsukuba.ac.jp

Published ahead of print on 17 October 2008.

Both authors contributed equally to this study.

REFERENCES

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