Inverse Regulation of Biofilm Formation and Swarming Motility by Pseudomonas aeruginosa PA14

We previously reported that SadB, a protein of unknown function,is required for an early step in biofilm formation by the opportunisticpathogen Pseudomonas aeruginosa. Here we report that a mutationin sadB also results in increased swarming compared to the wild-typestrain. Our data are consistent with a model in which SadB inverselyregulates biofilm formation and swarming motility via its abilityboth to modulate flagellar reversals in a viscosity-dependentfashion and to influence the production of the Pel exopolysaccharide.We also show that SadB is required to properly modulate flagellarreversal rates via chemotaxis cluster IV (CheIV cluster). Mutationalanalyses of two components of the CheIV cluster, the methyl-acceptingchemotaxis protein PilJ and the PilJ demethylase ChpB, supporta model wherein this chemotaxis cluster participates in theinverse regulation of biofilm formation and swarming motility.Epistasis analysis indicates that SadB functions upstream ofthe CheIV cluster. We propose that P. aeruginosa utilizes aSadB-dependent, chemotaxis-like regulatory pathway to inverselyregulate two key surface behaviors, biofilm formation and swarmingmotility.

INTRODUCTION

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INTRODUCTION

Pseudomonas aeruginosa is an important model organism for thestudy of gram-negative biofilm development, yet little is knownabout the molecular mechanisms underlying the initial eventsleading to the surface interactions that characterize the earlysteps in bacterial biofilm formation. Microscopic observations(23, 26, 40, 51) and genetic analyses (2) revealed two sequentialevents that lead to stable surface interactions. First, a bacterialcell pole contacts the surface in a process referred to as reversibleattachment. This is a relatively unstable interaction, as reversiblyattached bacteria can readily return to a planktonic existence.The second event is a transition from the polar associationto one that is mediated by the long axis of the cell body, referredto as irreversible attachment. In P. aeruginosa, the only mutationknown to block the transition from reversible to irreversibleattachment is in the sadB gene (2).

Another key aspect of biofilm formation by P. aeruginosa isthe production of an extracellular matrix. In pseudomonads,this matrix is thought to be comprised of exopolysaccharides(EPS), DNA, and protein (19). The biofilm matrix has typicallybeen credited with structuring the mature biofilm (4). Studieshave identified the pel and psl loci as two sets of genes predictedto be involved in the production of the polysaccharide componentof the matrix required for biofilm maturation by P. aeruginosaon abiotic surfaces, although only the pel gene cluster is foundin P. aeruginosa strain PA14 (7, 8, 15, 27), the focus of studyin this report. Interestingly, recent studies suggest that thepel locus also plays a role in early biofilm formation. A pelmutant of P. aeruginosa PAK shows a strong attachment defectin a strain lacking type IV pili (48) and P. aeruginosa PAO1with a mutation in the psl locus has a block in biofilm initiation(24).

Swarming motility, another surface behavior of P. aeruginosa,allows this microbe to move across surfaces (11). Swarming motilityrequires both a functional flagellum and the production of thesurface-wetting agent rhamnolipid surfactant, but the mechanismby which P. aeruginosa propels itself across the surface hasnot been explored. Swarming motility can be distinguished fromswimming motility in that swarming is required to move acrossa hydrated, viscous semisolid surface, while swimming allowsmovement through a relatively low-viscosity liquid environment.We have shown that sadB is also involved in modulating swarmingmotility in response to rhamnolipid surfactants (3).

Here we show that SadB participates in the inverse regulationof biofilm formation and swarming motility and requires chemotaxiscluster IV to mediate these effects. Our data are consistentwith a model in which SadB inversely regulates these behaviorsvia its ability both to modulate flagellar reversals in a viscosity-dependentfashion and to influence the production of the Pel polysaccharide.We propose that P. aeruginosa inversely regulates biofilm formationand swarming motility upon transitioning to a surface lifestyle.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Bacterial strains, plasmids, primers, media, and chemicals. Bacterial strains, plasmids and primers used in this study areshown in Table 1. P. aeruginosa PA14 was cultured on lysogenybroth (LB) medium (1) solidified with 1.5% agar. M63 minimalsalts (35) medium supplemented with MgSO₄ (1 mM), glucose (0.2%),and (where indicated) Casamino Acids (CAA, 0.5%) was used forstatic biofilm assays. Swarm (0.5% and 0.55% agar) and swim(0.3% agar) plates consisted of M8 minimal medium (20) supplementedwith MgSO₄ (1 mM), glucose (0.2%), and CAA (0.5%). Twitch platesconsisted of LB medium solidified with 1.0% agar. Unless notedotherwise, antibiotics were used at the following concentrationsfor P. aeruginosa: carbenicillin, 500 µg/ml; tetracycline,150 µg/ml, gentamicin, 100 µg/ml. All enzymes usedfor DNA manipulation were purchased from Invitrogen (Carlsbad,CA).

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TABLE 1. Strains, plasmids and primers used in this study^a

Molecular techniques. The DNA flanking the transposon carried by the pilG::Tn5B21mutant was mapped to the pilG locus using the published P. aeruginosaPAO1 genome (45) and arbitrarily primed PCR, as previously described(34). In-frame deletions of pilJ and chpB were generated usingpMQ30 (42), constructed as reported elsewhere (13), and theresolved integrants were confirmed by PCR. Single-crossoverinsertion of plasmid pKO3 (30) by homologous recombination wasused to disrupt the PAO178, wspA, and cheR1 genes. The constructswere made using the primers in Table 1 and confirmed by PCR.Plasmids for chpB and pilJ complementation were constructedin pMQ90 by amplifying chpB and pilJ by PCR using the primerslisted in Table 1.

Quantitative reverse transcription PCR (qRT-PCR) was performedas previously reported (21). Bacteria were harvested eitherfrom static planktonic cultures incubated for 8 h (typical biofilmassay growth conditions) or on agar plates used for Congo redassays (see below) but lacking the dyes and solidified with1.0% agar.

Biofilm assays. Ninety-six-well microtiter plate assays and microscopic analysiswere performed as previously described (29, 33). To quantifyreversible versus irreversible attachment, overnight cultureswere normalized by optical density at 600 nm and diluted 1:100in M63 supplemented with glucose, CAA, and MgSO₄. A 500-µlaliquot of this suspension was inoculated into the wells ofa 24-well plate (in duplicate) and incubated for 1 h at 37°C.The medium was removed and gently replaced, and images werecaptured at two frames/second for 30 s. Images were convertedto QuickTime files for analysis.

Determining swim reversals. Swim reversal rate measures the frequency at which a swimmingcell changes its direction. Overnight LB-grown cultures werediluted 1:100 into fresh M63 medium supplemented with glucose.Ficoll was added at 3% for low-viscosity (swimming) conditions;this added Ficoll slowed the swimming cells sufficiently tofacilitate monitoring of reversal rates. High-viscosity conditions,mimicking conditions of swarming motility based on our previousstudies (47), were achieved by adding Ficoll to 15%. Subculturedbacteria were incubated at 37°C for 1 to 2 h, and then 500-µlaliquots were added to the wells of 24-well plates. Phase-contrast,time-lapse images were acquired every 0.3 s at a x1,400 magnificationusing the OpenLab software package. The time-lapse images wereconverted to QuickTime movies for subsequent analysis. QuickTimemovies were advanced frame by frame, and individual cells weremonitored for the number of times they reversed swim directionwhile within the field of view. Approximately 25 cells werecounted in each of six wells ( $~$ 125 cells total) to determinereversal rates, which are expressed as reversals per cell.

Swarm assays. Plate preparation, inoculation, and incubation were performedas previously described (47). To determine the percentage ofswarm plate surface coverage by a given bacterial swarm, animage of the swarm plate was captured using a Nikon 990 digitalcamera (Nikon, Melville, NY) and false colored using Photoshopsoftware (Adobe, Mountain View, CA) to provide ample contrastbetween the bacterial swarm and the agar surface so that thepixels could be counted using Kodak 1D Image Analysis software(Kodak, Rochester, NY). The number of pixels that comprisedthe swarm was expressed as a percentage of the number of pixelsthat comprised an image of the surface of the plate. Alternatively,the captured image was imported into PowerPoint (Microsoft),where the outline of the bacterial swarm was traced in orderto distinguish it from the agar surface. ImageJ software (NationalInstitutes of Health) was used to calculate both the area withinthe swarm and that of the plate surface for comparison.

Polysaccharide assays. Congo red (CR) assays were performed as reported elsewhere,except that the base medium used was M63 medium supplementedwith glucose, MgSO₄, and CAA at the concentrations used forbiofilm assays (7, 8). Scanning electron microscopy (SEM) wasperformed as reported elsewhere (16), except that glutaraldehydewas used at 2.5% and bacteria were grown on the plastic substratefor 38 h in minimal medium plus glucose and CAA.

RESULTS

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RESULTS

Relationship of SadB to biofilm formation and swarming. We postulated that upon encountering a surface, P. aeruginosawould likely coregulate its surface-associated behaviors, includingbiofilm formation and swarming. The fact that SadB appearedto be required for both biofilm formation (2) and swarming motility(3) suggested that this protein might be involved in coregulatingthese processes; therefore, we pursued sadB both as a geneticlink between these phenomena and to gain greater insight intohow P. aeruginosa regulates its surface behaviors.

As part of the published characterization of SadB, we demonstratedthat SadB protein levels were elevated under conditions thatpromote robust biofilm formation. These data suggested thatthere might be a correlation between the levels of SadB andthe extent of biofilm formation. To test this hypothesis, wetook advantage of the observation that expressing sadB in multicopyfrom a plasmid (pSadB⁺) resulted in elevated cytoplasmic levelsof the SadB protein (2). We examined the effects of overexpressingSadB from the pSadB⁺ plasmid on biofilm formation in glucoseminimal medium, a medium that does not promote robust biofilmformation by P. aeruginosa PA14. In a 96-well biofilm assay,biofilm formation was enhanced $~$ 3-fold at 4 h in the wild type(WT) overexpressing SadB (WT/pSadB⁺) in comparison to the vectorcontrol strain (WT/pUCP18) (Fig. 1A). The WT strain overexpressingSadB also showed a 2.5-fold increase in the number of bacteriaattached to the surface in comparison to the vector controlat this early time point, as determined by phase-contrast microscopy(Fig. 1B).

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FIG. 1. Surface-associated behaviors influenced by SadB levels. (A) Biofilm formation phenotypes under static conditions. (Top) Image of crystal violet (CV)-stained biofilms formed by the wild type carrying the vector control (WT/pUCP18) and the wild type overexpressing SadB (WT/pSadB⁺). Cells were grown in minimal medium containing (0.2%) glucose for 4 h at 37°C before staining with CV. (Bottom) Quantification of CV-stained wells. (B) Phase-contrast images of WT/pUCP18 and WT/pSadB⁺ attached to the surface of a 24-well plate after incubation at 37°C for 1 h. For each strain, images were recorded at a magnification of x1,400 over 10 fields of view, and the average number of surface-associated cells for each strain is indicated below the image. (C) The graph shows the average plate surface coverage that results from swarms produced by the WT, sadB, and ${Delta}$ pilJ strains. Below are representative images of WT, sadB, and ${Delta}$ pilJ strains after 16 h of incubation at 37°C. The percent surface coverage of the WT is significantly less than that of the sadB mutant (P = 0.0029) and the ${Delta}$ pilJ mutant (P = 0.000018). (D) Aliquots of the wild type carrying the vector control (WT/pUCP18) and the wild type overexpressing SadB (WT/pSadB⁺) were spotted on 0.5% and 0.55% swarm agar plates and incubated for 16 h at 37°C. (E) Reversal rates of WT and sadB mutant cells under low-viscosity (3% Ficoll) and high-viscosity (15% Ficoll) conditions.

The sadB mutant also shows a hyperswarming phenotype comparedto the WT, resulting in an $~$ 2-fold increase in surface coveragefor the sadB mutant (Fig. 1C). In contrast, overexpression ofSadB leads to suppression of swarming motility on 0.55% agarbut not on 0.5% agar, suggesting a viscosity-dependent rolefor SadB in swarm suppression (Fig. 1D). Together, these datasuggest an inverse relationship between swarming motility andbiofilm formation mediated, at least in part, by SadB.

A sadB mutant has a viscosity-dependent defect in flagellar reversals. Because both swarming motility and biofilm formation are dependenton a functional flagellum, we assayed the sadB mutant for phenotypesrelated to motility, in particular, swim speed and flagellarreversal rate. Directly measuring the speed of swimming underlow-viscosity conditions (using 3% Ficoll [47]) revealed nodifference between the WT (55.3 ± 1.83 µm/s) andthe sadB mutant (53.38 ± 1.52 µm/s; P = 0.37),a result consistent with our previous findings (2). Becauseof the effects of a sadB mutation on swarming motility, we alsomeasured swimming speed under high-viscosity conditions (15%Ficoll), which we have shown previously is a condition analogousto that encountered by the cells when swarming (47). Under high-viscosityconditions, a small but significant difference in swimming speedwas measured between the WT (10.03 ± 0.59 µm/s)and the sadB mutant (12.29 ± 0.40 µm/s; P = 0.003),an increase of $~$ 23% for the sadB mutant. It is formally possiblethat this small increase in swimming motility can also contributeto the enhanced swarming of the sadB mutant; however, thereare no other data to support this conclusion.

Another component of controlling flagellar motility is regulatingthe rate of flagellar reversals; therefore, we also assessedthe flagellar reversal rate of the WT and the sadB mutant (Fig.1E). The rate of reversals under low-viscosity conditions (3%Ficoll) for the sadB mutant is equal to that of WT. Consistentwith a role for SadB in the control of flagellar-mediated reversals,the sadB mutant displayed a >2-fold increase in flagellarreversals compared to WT cells in 15% Ficoll. Also under high-viscosityconditions (15% Ficoll), overexpression of SadB from plasmidpNC5 (pSadB⁺) in the WT reduced reversals per cell to 0.52 ±0.26 compared to 1.36 ± 0.04 for the WT carrying thepUCP18 vector control (P = 0.035). This two- to threefold changein reversal rates is on par with the magnitude of change inreversal rate observed for Escherichia coli in the presenceof attractants and/or for mutants in the Che machinery (31,36).

SadB-mediated effects on biofilm formation and swarming require components of chemotaxis cluster IV. Based on the viscosity-dependent alteration of flagellar reversalsin the sadB mutant and the known role of the chemotaxis systemof E. coli in the regulation of flagellar reversals (25), wehypothesized that one of the five chemotaxis-like clusters ofP. aeruginosa (6) might serve as a link between SadB and flagellarfunction. We found that a Tn5 insertion in pilG, a componentof chemotaxis cluster IV (cheIV) of P. aeruginosa, resultedin a SadB-like swarming phenotype, but mutations in none ofthe other clusters yielded similar phenotypes (Table 2).

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TABLE 2. SadB-dependent biofilm and swarming phenotypes of Che cluster mutants

To confirm a role for the CheIV cluster in SadB-dependent effectson biofilm formation and swarming, in-frame deletions in twogenes of the cheIV cluster (Fig. 2A), pilJ, encoding a predictedmethyl-accepting chemotaxis protein (MCP), and chpB, encodinga predicted MCP demethylase, were constructed. We chose to mutatethese genes based on previous work in E. coli—loss ofthe MCP should block signaling through this chemotaxis-likesystem, while mutating the demethylase should result in hypermethylationof the MCP and thus presumably result in higher basal receptoractivity (25). Therefore, we predicted that mutations in pilJand chpB should have opposite effects on biofilm formation andswarming.

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FIG. 2. The ${Delta}$ pilJ mutant is biofilm defective and a hyperswarmer. (A) CheIV chemotaxis cluster. pil genes are shown in light gray and chp genes in dark gray. Black arrows represent open reading frames, and gene names are given below the arrows. (B) Biofilm formation by the WT, ${Delta}$ pilJ mutant, and complemented strains at 8 h. Cells were grown at 37°C for 8 h in minimal medium containing glucose and CAA. (C) Aliquots of the ${Delta}$ pilJ mutant carrying the vector control ( ${Delta}$ pilJ/pMQ90) or a construct expressing the pilJ gene in trans (pPilJ⁺) were spotted on 0.5% swarm agar plates and incubated at 37°C for 16 h. (D) Aliquots of the ${Delta}$ pilJ mutant carrying the vector control ( ${Delta}$ pilJ/pUCP18) or a construct overexpressing SadB (pSadB⁺) were spotted on 0.5% and 0.55% swarm agar plates and incubated at 37°C for 16 h. (E) The extent of swarming, expressed as percent surface coverage, is shown on 0.5% agar for the strains indicated. *, statistically significant decrease in swarming compared to the other strains (P < 0.001).

The ${Delta}$ pilJ mutant is defective for biofilm formation (Fig. 2B)and displays a hyperswarming phenotype (Fig. 1C), and providingpilJ on a plasmid complements these phenotypes (Fig. 2B and C).The ${Delta}$ pilJ mutant is also defective for twitching motility (Table3). Furthermore, overexpressing SadB in the ${Delta}$ pilJ mutant neitherstimulates biofilm formation (data not shown) nor suppressesswarming motility (Fig. 2D and E), suggesting that PilJ is geneticallydownstream of SadB. Consistent with this hypothesis, expressingPilJ from a high-copy-number plasmid suppresses the swarmingof the sadB mutant (Fig. 2E). In contrast to the ${Delta}$ pilJ mutant,the ${Delta}$ chpB mutant cannot swarm (Fig. 3A) but forms a more robustbiofilm than the WT (Fig. 3B).

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TABLE 3. Swimming, twitching and swarming phenotypes^e

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FIG. 3. The ${Delta}$ chpB mutant is defective for swarming motility and displays increased biofilm formation and CR binding. (A) Aliquots of the ${Delta}$ chpB mutant carrying the vector control ( ${Delta}$ chpB/pMQ90) and a construct expressing the chpB gene in trans (pChpB⁺) were spotted on 0.5% swarm agar plates and incubated at 37°C for 16 h. (B) Biofilm formation by the WT and ${Delta}$ chpB mutant was assessed after 4 h of growth at 37°C in minimal medium containing glucose. Shown are representative wells (top) and quantification of the biofilm assays (bottom). (C) Reversal rates of the WT and the ${Delta}$ pilJ and ${Delta}$ chpB mutants under high-viscosity (15% Ficoll) conditions. (D) CR assays with the WT, the ${Delta}$ chpB mutant, and the ${Delta}$ chpB pelA double mutant. Plates were incubated for 24 h at 37°C and an additional 24 h at room temperature. (E) SEM of WT and the ${Delta}$ chpB and ${Delta}$ pilJ mutants. Images were prepared with ruthenium red to highlight polysaccharides. (F and G) Quantitative RT-PCR analysis of pelA (F) and pelG (G) gene expression in agar-grown cultures of the indicated strains. *, statistically significant difference from the WT (P < 0.05).

If the CheIV cluster is in the same genetic pathway as SadB,we predict that mutations in ${Delta}$ pilJ and/or ${Delta}$ chpB might cause alteredflagellar reversal rates. Consistent with the observation thatthe ${Delta}$ pilJ mutant and the sadB mutant have similar biofilm andswarming phenotypes, the ${Delta}$ pilJ mutant also shows an $~$ 2-fold increasein flagellar reversal rates compared to the WT under high-viscosityconditions; however, the reversal rate of the ${Delta}$ chpB mutant isnot significantly different from that of the WT (Fig. 3C).

Mutating chpB increases production of the pel-encoded matrix. We investigated whether the ${Delta}$ chpB mutant is altered for otherbiofilm-related functions that might explain the hyperbiofilmand nonswarming phenotypes of this mutant. The ${Delta}$ chpB mutant didnot display any defects in swimming or twitching motility (Table3). The ${Delta}$ chpB mutant did show increased binding to CR comparedto the WT (Fig. 3D, compare left and center panels). CR hasbeen shown to bind the pel-encoded polysaccharide of P. aeruginosaPA14 (7, 8). Consistent with the conclusion that mutating chpBalters production of the Pel polysaccharide, introducing a pelAmutation into the ${Delta}$ chpB genetic background completely eliminatedCR binding (Fig. 3D).

The CR data were confirmed by SEM (Fig. 3E) using methods similarto those reported for the analysis of the Pel polysaccharide(7). The WT produced an amorphous material characteristic ofextracellular polysaccharides, and consistent with the CR studies,the ${Delta}$ chpB mutant produced more of this material (Fig. 3E, compareleft and center panels).

To determine whether the ${Delta}$ chpB mutant affected pel gene transcription,we measured the transcript levels of pelA and pelG using qRT-PCR.We chose to assess the expression of pelA and pelG because bothof these genes are predicted to code for enzymes required toproduce the glucose-rich polysaccharide component of the P.aeruginosa matrix (7). The WT and the ${Delta}$ chpB mutant were growneither planktonically under static conditions (identical toconditions used for biofilm assays) or on agar plates underconditions identical to those used for CR assays (minus thedyes). A small ( $~$ 2-fold) but significant increase in pelA transcript,but no difference in pelG transcript level, was observed betweenthe WT and ${Delta}$ chpB mutant grown as a colony (Fig. 3F and G), andno difference was observed when the cultures were grown planktonically(data not shown). These data suggest that mutating chpB haslittle or no effect on the expression of the pelA and pelG genes.

The mutation in pilJ also results in a small decrease in CRstaining and an altered colony morphology, but to a degree identicalto that observed for a mutant lacking type IV pili (data notshown), suggesting that loss of PilJ function plays little orno role in EPS production. However, it may not be possible toobserve subtle changes in EPS production using the CR assay.Consistent with the CR findings, SEM studies indicated thatthe WT and ${Delta}$ pilJ mutant produced similar levels of extracellularmaterial (Fig. 3E, right panel).

Role for sadB in Pel polysaccharide production. We predicted that the sadB mutant might also be altered forpolysaccharide production. Given the lack of biofilm formationand increased swarming of the sadB mutant strain, phenotypesopposite those of the ${Delta}$ chpB mutant, we predicted that the sadBmutant would bind less rather than more CR, and this is whatwe observed (Fig. 4A). Furthermore, SEM analysis revealed thatthe sadB mutant produced noticeably less extracellular matrixmaterial than the WT (Fig. 4B). The ${Delta}$ pelA mutant, defective inproduction of the Pel polysaccharide, served as a control inthis study.

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FIG. 4. A sadB mutant displays decreased Pel polysaccharide production but no decrease in pel gene expression. (A) CR binding assays with the WT and the sadB mutant. Plates were incubated for 24 h at 37°C and an additional 24 h at room temperature. (B) SEM of the indicated strains. Images were prepared with ruthenium red to highlight polysaccharides. (C and D) Quantitative RT-PCR analysis of pelA (C) and pelG (D) gene expression in agar-grown cultures of the indicated strains. *, statistically significant difference from the WT (P < 0.05). (E) Swarming phenotype of the WT and the ${Delta}$ pelA mutant. Shown are a representative swarm plate for each strain and quantification of plate coverage for each strain (five plates).

We determined whether the sadB mutant affected pel gene transcription.A small ( $~$ 2-fold) but significant increase was observed for thepelA or pelG transcript level in the sadB mutant versus theWT grown under colony growth conditions (Fig. 4C and D), andno difference in transcript levels was observed under planktonicconditions (data not shown), indicating that the decrease inCR staining in the sadB mutant cannot be explained by decreasedtranscription of the pel locus.

Role for the pel locus in swarming and early biofilm formation. Given the apparent relationship between swarming and CR bindingdescribed above, we also determined whether a mutation in pelAmight impact swarming motility. A strain mutated in the pelAgene showed a $~$ 2.5-fold increase in swarming motility comparedto the WT strain (Fig. 4E). A mutation in the pelA gene doesnot impact swimming or twitching motility (data not shown).

Several mutations described above impact both biofilm formationand motility, and furthermore, sadB is known to impact biofilmformation at the transition from reversible to irreversibleattachment. If the pel-encoded matrix also plays a role at thisearly step in biofilm formation, we would predict that a straindefective for matrix production would also have a defect inirreversible attachment. Consistent with this prediction, ina static assay, we observed a statistically significant decreasein irreversible attachment of the ${Delta}$ pelA mutant (86.1% ±3.2%) compared to the WT (94.7% ± 4.2%; P = 0.0000583).The decrease in irreversible attachment of the pelA strain isnot as striking as that observed for the sadB mutant (67.8%± 8.1%; P = 0.0001417).

DISCUSSION

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DISCUSSION

Here we show that SadB, originally identified as required forearly biofilm formation, is also a negative effector of swarmingmotility, a result consistent with our previous findings (3).We also showed previously that RpoN and FleR, known regulatorsof flagellum and rhamnolipid production in P. aeruginosa (14,38, 46), also regulate SadB levels (2), suggesting that SadBis coregulated with other functions required for swarming andbiofilm formation. How does SadB contribute to both biofilmformation and swarming behaviors? A model summarizing the findingsfrom this study is shown in Fig. 5. While we have yet to identifythe biochemical function of the SadB protein, our results implicatethis protein in two pathways that impact swarming motility andbiofilm formation.

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FIG. 5. Model for inverse control of biofilm formation and swarming motility. Planktonic bacteria (top) initially interact with the surface, likely via reversible polar attachment, although which end of the cell interacts with the abiotic surface is unclear. A pathway that includes SadB and components of the CheIV chemotaxis cluster (PilJ and ChpB) controls the decision to initiate biofilm formation or move via swarming. Biofilm formation is associated with an increase in the production of Pel-dependent polysaccharide (Pel) and a decrease in flagellar reversal rate (FlaRev). Swarming is associated with decreased production of polysaccharide and an increased rate of flagellar reversals. The substratum is shown as a gradient of gray to represent the fact that variations in surface properties (viscosity, wetness, etc.) might also impact the biofilm-versus-swarming decision.

First, SadB is involved in mediating flagellar reversals, butonly under high-viscosity conditions likely similar to thoseencountered during either biofilm formation or swarming, butnot swimming. A role for the chemotaxis cluster in E. coli incontrolling flagellar reversal rates prompted us to investigatethe potential involvement of the five chemosensory-like clustersof P. aeruginosa as a mechanism for linking SadB to flagellarfunction. An in-frame deletion of pilJ, an MCP homolog, renderedthe strain biofilm defective and a hyperswarmer and resultedin increased flagellar reversals. The biofilm, swarming andflagellar reversal phenotypes of the ${Delta}$ pilJ mutant are identicalto those of a sadB mutant strain. Epistasis analysis indicatesthat SadB is genetically upstream of pilJ, consistent with amodel wherein sadB exerts its effects on flagellar rotationvia the CheIV chemosensory system.

Based on the E. coli paradigm (25), loss of the PilJ MCP shouldblock signaling via this chemosensory system. In contrast, mutatingthe demethylase gene homolog, chpB, should result in a hypermethylatedMCP with higher basal receptor activity. Consistent with thesehypotheses, the ${Delta}$ chpB mutant is defective for swarming but formsa more robust biofilm than the WT, phenotypes opposite thoseobserved for the ${Delta}$ pilJ mutant.

While mutations in sadB and pilJ resulted in increased flagellarreversals, to our surprise the ${Delta}$ chpB mutant did not have thepredicted decrease in reversals and in fact showed no discernibleeffect on this behavior. Perhaps the repression of flagellarreversals is accomplished via another pathway. Alternatively,while the ${Delta}$ chpB mutation alters the basal activity of the MCP,perhaps a second input signal is still required to observe decreasedreversals in this mutant background. We do show here that mutationsin chpB impact another known biofilm-related factor, namely,the production of the putative pel-encoded matrix. A ${Delta}$ chpB mutanthas a CR-hyperbinding phenotype that is pelA dependent and resultsin increased matrix production as judged by SEM, but the ${Delta}$ chpBmutation does not alter pel gene expression, suggesting thatthis mutation increased production of the Pel polysaccharideby a nontranscriptional mechanism. In contrast to the ${Delta}$ chpB mutant,the sadB mutant showed decreased CR binding and matrix production,suggesting that SadB positively impacts production of the Pelpolysaccharide. Despite the decrease in apparent productionof the Pel polysaccharide by the sadB mutant, expression ofthe pelA and pelG mRNAs is slightly up-regulated in the sadBmutant versus the WT. These data indicate that the reductionof Pel polysaccharide production in a sadB mutant occurs viaa nontranscriptional mechanism.

At this point, we do not understand how SadB or components ofthe CheIV cluster impact EPS production. Given the lack of changein pel gene expression in the sadB and chpB mutants, one obviousexplanation for the changes in matrix production in strainsmutated in these functions is that Pel production is controlledby a mechanism other than regulation of pel operon gene expression.To date, the only known means of nontranscriptional regulationof EPS production in pseudomonads is thought to be via the nucleotidesignaling molecule c-di-GMP (10, 12, 17, 22, 44). However, thereare no proteins with known c-di-GMP-related motifs in the CheIVcluster or in the CheI, CheII, or CheV cluster. The WspR protein,a component of the wsp chemosensory system (CheIII cluster)of P. aeruginosa, which plays a role in biofilm formation andEPS production, contains a GGDEF domain, an amino acid motifassociated with the synthesis of c-di-GMP from GTP, and hasbeen shown in vitro to catalyze c-di-GMP synthesis (12), butmutations in wspR do not yield SadB-like phenotypes. Furthermore,SadB lacks the EAL, GGDEF, and HD-GYP domains (39, 44) associatedwith c-di-GMP metabolism, and we have no biochemical evidencethat SadB is involved in c-di-GMP metabolism (data not shown),nor does it appear to alter cellular pools of c-di-GMP (J. Hickman,J. Merritt, C. Harwood, and G. O'Toole, unpublished data). Therefore,the mechanism by which SadB and ChpB modulate Pel polysaccharideproduction remains to be elucidated.

Components of the CheIV cluster, including pilJ and the previouslydescribed chpA (49), also play a role in twitching motility,indicating that this putative chemosensory system participatesin coordinating all three known surface behaviors of this microbe.We also showed that mutations in pilJ and chpB had no effecton swimming motility, further reinforcing a role for the CheIVcluster specifically in surface-associated behaviors of thismicrobe.

Our data suggest that SadB and PilJ modulate flagellar reversalsunder high-viscosity conditions but do not contribute to thecontrol of flagellar reversals under the low-viscosity conditionsthat favor swimming. We hypothesize that SadB-dependent controlof flagellar reversals upon polar, reversible attachment toa solid surface might decrease rotation about the cell poleand thus increase the time of interaction between the bacteriumand its substratum, thereby promoting biofilm formation. Incontrast, increased reversal rates appear to favor swarmingmotility. Wolfe and Berg postulated that for E. coli, increasingflagellar reversals might in some circumstances facilitate theability to move through a semisolid matrix (50). Based on theirmicroscopic observations, they concluded that "cells that donot tumble tend to get trapped in agar" and move less efficientlythrough this matrix (50). While that study was performed inthe context of swimming through 0.3% agar, our data suggestthat this phenomenon might also be extended to swarming conditions.Also consistent with our data is the finding that E. coli strainslocked in the "tumbling" chemotaxis mode by mutation had a reducedability to attach to an abiotic surface compared to the WT ormutants locked in the "running" mode (28). In addition to controllingflagellar function, by coordinating the production of the Pelpolysaccharide, SadB can modulate another facet of biofilm initiationand swarming. Work presented here and recent published studies(24, 48) show that a functional pel locus contributes to earlybiofilm formation, and we show here that mutating the pel locuspromotes swarming motility (Fig. 4D). This inverse relationshipbetween polysaccharide production and motility has been notedin several other studies of P. aeruginosa (5, 9, 18, 43).

Our studies may provide a mechanistic basis for a recent excitingreport by Shrout and colleagues (43). They proposed that earlyin biofilm formation, the extent of swarming motility helpsdictate the final structure of the biofilm. That is, under conditionsthat promote swarming early in biofilm formation, the resultingmature biofilm is flat, while under conditions inhibitory toswarming motility, a biofilm with aggregates (distinct macrocolonies)will result. Based on their experimental work and accompanyingmathematical simulations, they also postulated a role for apolysaccharide-containing matrix in the formation of the aggregatesduring biofilm development (43). One interpretation of the studyof Shrout et al. is that P. aeruginosa must be able to integrateseveral important cell functions early in biofilm formation,namely, swarming motility and matrix production. The data presentedin our report suggest that SadB and the CheIV cluster providea molecular means for coregulating these functions.

We propose that P. aeruginosa inversely regulates the surface-associatedbehaviors of biofilm formation and swarming by controlling bothflagellar reversals and the production of the Pel polysaccharide.Flagellar reversal rates in E. coli are largely regulated nontranscriptionallyvia the Che signal transduction pathway (25), and given thehigh sequence similarity of the cheIV cluster components totheir E. coli counterparts, this is likely also the case inP. aeruginosa. CR binding and SEM data, together with the pelAand pelG transcriptional analysis presented here, indicate thatproduction of the pel-encoded EPS may also be controlled bySadB and the CheIV cluster via a mechanism other than transcriptionalcontrol. Given that PilJ is also involved in twitching motility,the CheIV cluster may coordinate three different surface behaviors:swarming motility, twitching motility and biofilm formation.An appealing aspect of this regulatory strategy for coregulatingsurface behaviors is that in adapting to a surface-associatedlifestyle, P. aeruginosa may be able to seamlessly and rapidlytransition among its surface behaviors as it encounters ever-changingsubstratum properties and environmental conditions.

ACKNOWLEDGMENTS

We thank C. Daghlian and the Ripple Electron Microscopy facilityat Dartmouth College for assistance with the SEM studies.

This work was supported by NIH training grant T32 AI007519 (predoctoralfellowship) to N.C.C., predoctoral fellowship T32 GM08704 toJ.H.M., and grant AI51360-01 to G.A.O.

FOOTNOTES

* Corresponding author. Mailing address: Dept. of Microbiology & Immunology, Rm. 505, Vail Building, Dartmouth Medical School, Hanover, NH 03755. Phone: (603) 650-1248. Fax: (603) 650-1245. E-mail: georgeo{at}Dartmouth.edu

Published ahead of print on 2 March 2007.

Present address: Mascoma Corporation, Dartmouth Regional TechnologyCenter, 16 Cavendish Court, Suite 2A, Lebanon, NH 03766.

REFERENCES

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