Biofilm formation by Pseudomonas aeruginosa: role of the C4-HSL cell-to-cell signal and inhibition by azithromycin

Sabine Favre-Bonté*, Thilo Köhler and Christian Van Delden§

Department of Genetics and Microbiology, University of Geneva, CMU, 1, rue Michel-Servet, CH-1211 Geneva 4, Switzerland

Received 6 February 2003; returned 6 April 2003; revised 19 June 2003; accepted 30 June 2003


    Abstract
 Top
 Abstract
 Introduction
 Materials and methods
 Results and discussion
 References
 
Objectives: In Pseudomonas aeruginosa, biofilm formation is controlled by a cell-to-cell signalling circuit relying on the secretion of 3-oxo-C12-HSL and C4-HSL. Previous studies suggested that C4-HSL plays no significant role in biofilm formation. However the wild-type PAO1 strain PAO-BI, used as a control in these studies is itself impaired in the production of C4-HSL. We wondered therefore whether the role of C4-HSL in biofilm formation might have been underestimated, and whether azithromycin inhibits biofilm formation by interfering with cell-to-cell signalling.

Methods: We used isogenic mutants of wild-type PAO1 strains PAO-BI and PT5 in a static biofilm model. Biofilm formation was quantified using Crystal Violet staining and exopolysaccharide measurements.

Results: Wild-type strain PAO-BI, as a result of its reduced C4-HSL secretion, produced 40% less biofilm compared with the wild-type PAO1 strain PT5. Using isogenic mutants of strain PT5 we have shown that whereas a lasI mutant (deficient in 3-oxo-C12-HSL) produced similar amounts of biofilm to the wild-type, a rhlI mutant (deficient in C4-HSL) produced 70% less biofilm. In the latter strain, biofilm formation could be restored by addition of exogenous C4-HSL. Azithromycin, known to reduce the production of both 3-oxo-C12-HSL and C4-HSL, inhibited biofilm formation of wild-type PT5 by 45%. This inhibition could be reversed by the addition of both cell-to-cell signals.

Conclusions: Our results indicate that C4-HSL also plays a significant role in biofilm formation. Furthermore, we demonstrate the potential of using cell-to-cell signalling blocking agents such as azithromycin to interfere with biofilm formation.

Keywords: quorum sensing, autoinducers, homoserine-lactones, 3-oxo-C12-HSL


    Introduction
 Top
 Abstract
 Introduction
 Materials and methods
 Results and discussion
 References
 
The opportunistic pathogen Pseudomonas aeruginosa is responsible for severe ventilator-associated pneumonia (VAP) in intubated patients. In these patients, colonization of the upper respiratory tract by P. aeruginosa, which almost always precedes pneumonia, is related to the presence and duration of an endotracheal intubation. The colonization of inert surfaces by P. aeruginosa requires a sessile bacterial growth pattern, called a biofilm.1 The acyl homoserine lactone based cell-to-cell signals (autoinducers, AHLs) 3-oxo-C12-HSL and C4-HSL participate in a cell-to-cell signalling (quorum-sensing) regulatory network that controls the production of several extracellular virulence factors and are important for biofilm formation.2 Synthesis of these molecules depends on two autoinducer-synthase genes, lasI and rhlI, respectively.2 Both AHLs are produced in vitro by P. aeruginosa isolates from chronically infected cystic fibrosis (CF) patients,3 ex vivo in sputum from CF patients infected by P. aeruginosa,4 as well as in lungs of mice chronically infected by P. aeruginosa.5 AHLs have been detected in situ on urethral catheters and in vitro using a P. aeruginosa biofilm model,6 as well as in lung secretions of CF patients.7,8 Based on studies using the wild-type PAO1 strain PAO-BI and its derived lasI mutant PAO-JP1, it has been shown that 3-oxo-C12-HSL is required for biofilm different-iation.9 Using the same strain PAO-BI, it was observed that the autoinducer synthase gene lasI, required for 3-oxo-C12-HSL pro-duction, is expressed in a large number of cells during the initial phase of biofilm development and that this number decreases progressively over time.10 In contrast, rhlI, the autoinducer synthase gene required for C4-HSL production, was expressed in fewer cells but remained constant over time. Based on these observations, it has been suggested that C4-HSL might be of little importance in biofilm formation.10 This is surprising as it has recently been shown that ex vivo, P. aeruginosa isolates from CF patients grown in biofilm produce higher amounts of C4-HSL compared with 3-oxo-C12-HSL.4 It has also been suggested that this AHL production pattern could be used as a marker for P. aeruginosa growing in biofilm in CF patients.4 We have detected AHLs in situ directly in the lung tissue of CF patients infected by P. aeruginosa and found a similar elevated C4-HSL/3-oxo-C12-HSL ratio.11 Moreover, the rhl cell-to-cell signalling system (dependent on the production of C4-HSL) has been suggested to be important for survival of bacteria during the anaerobic biofilm mode of growth encountered in CF lung disease,12 and rhamnolipids whose production is controlled by C4-HSL2 has been shown to be required for the maintenance of biofilm architecture.13 Together, these observations suggest that C4-HSL might be more important for biofilm formation than previously thought.

It has been recently understood that wild-type PAO1 strains from various laboratories might differ in cell-to-cell signal production.14 In particular, strain PAO-BI produces less C4-HSL than other PAO1 strains.14 We have recently described that the macrolide antibiotic azithromycin inhibits virulence factor production of P. aeruginosa by interfering with the cell-to-cell signalling circuit.15 We wondered whether the reduced production of C4-HSL by strain PAO-BI might have affected previous biofilm studies using this strain as a control strain, and whether azithromycin affects biofilm formation by interfering with AHL production.


    Materials and methods
 Top
 Abstract
 Introduction
 Materials and methods
 Results and discussion
 References
 
Media, antibiotics and strains

Unless otherwise stated, bacteria were freshly streaked from frozen stocks onto LB-agar medium supplemented with antibiotics when appropriate. Liquid LB cultures, containing antibiotics when appropriate, were grown overnight at 37°C with agitation (250 rpm). Minimal AP medium supplemented with 0.3 M NaCl was used for biofilm growth experiments.16 Antimicrobials were supplied at the following concentrations: gentamicin (15 mg/L), tetracycline (50 mg/L), mercury chloride (12.5 mg/L). All chemicals and antimicrobials were purchased from Sigma, except azithromycin which was kindly provided by Pfizer. The bacterial strains and their genetic linkage are presented in Table 1. To construct strain PT918 (PAO-BI mexE::{Omega}Hg), the mexE::{Omega}Hg mutation from strain PT12117 was transferred by transduction using phage E79tv218 into strain PAO-BI.


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Table 1. Bacterial strains and plasmids used in this study 
 
Autoinducer measurements

For extraction of autoinducers from liquid cultures, bacterial strains were grown in LB medium until they reached stationary phase (6 h). Aliquots of filtered culture supernatants were subjected to two extractions by add-ition of one volume of acidified ethyl acetate (0.01% acetic acid). For extraction of autoinducers from biofilms, polyvinyl chloride (PVC) fragments on which biofilms had been formed were rinsed three times and immersed into 1 mL of 0.9% NaCl. One volume of acidified ethyl acetate was added and the mixture incubated in closed tubes at 4°C overnight. A second extraction was carried out for 1 h, and the two extracts were pooled. The extracted autoinducers were quantified using specific bioassays using E. coli MG4{lambda}I14 (pPCS1) for 3-oxo-C12-HSL and P. aeruginosa PAO-JP2 (pECP61.5) for C4-HSL as reporter strains.19 ß-Galactosidase (ß-gal) activity was determined as previously described.20

Static biofilm formation assay

Sterile PVC strips of approximately 1 cm2 were cut from original endotracheal devices (Mallinckrodt Inc., St Louis, MO, USA) and biofilm was allowed to develop under static conditions for 3 days as previously described.21 All PVC strips were weighed and experiments were standardized by weight. Bacterial strains were grown in LB medium for 6 h with agitation at 37°C. PVC strips were immersed in the bacterial culture medium for 1 h without agitation to allow bacteria to adhere. PVC strips were then transferred into AP medium and incubated for 3 days without agitation at 37°C. Azithromycin (2 mg/L) and/or autoinducers (10 µM each, once a day) were added as indicated. After the 3 day incubation period, the PVC strips were individually washed twice in 0.9% NaCl and subjected to biofilm measurements (see below). We had previously observed that initial growth of wild-type PT5 was slightly retarded in the presence of 2 mg/L azithromycin when grown under agitation in liquid media.15 This effect was restricted to early and mid-exponential growth phases, when quorum sensing is not yet active. In order to determine whether this small delay could affect final growth in our 3 day static biofilm assay, we measured colony forming units (cfu) of strain PT5 grown without agitation after 3 days in the biofilm medium in the presence and absence of 2 mg/L azithromycin. Azithromycin did not affect the number of viable counts of wild-type strain PT5.

Crystal Violet staining and exopolysaccharide determinations

PVC strips, on which biofilm had developed, were incubated for 15 min in a Crystal Violet staining solution (0.1% in distilled water),22 and washed three times in distilled water. The stain was then dissolved in ethanol and absorbance was measured at 570 nm as previously described.22

Exopolysaccharide determinations were carried out by total carbohydrate assays.23 PVC strips were washed in 0.9% NaCl, and incubated in an equal volume of 5% phenol to which 5 volumes of H2SO4 containing hydrazine sulphate was added. The mixture was incubated for 1 h in the dark and absorbance was measured at 490 nm.


    Results and discussion
 Top
 Abstract
 Introduction
 Materials and methods
 Results and discussion
 References
 
Role of C4-HSL and 3-oxo-C12-HSL in total biofilm formation

Most in vitro studies have investigated the potential role of cell-to-cell signals in the formation of P. aeruginosa biofilm using a continuous flow system.9,10,24,25 In such bioreactors a constant medium flux brings new nutrients and eliminates metabolic products. These experimental conditions are therefore very different from in vivo situations such as biofilm formation on endotracheal intubation devices. Indeed the bacteria growing inside the secretions that accumulate above the cuff of intubation devices are in static growth conditions without regular change of their growth medium. We therefore decided to adopt a static in vitro biofilm model21 using sterile PVC strips derived from original intubation devices. Previous experiments, using continuous flow systems, have shown that the total amount of biofilm formed by the lasI mutant PAO-JP1 is not reduced compared with its parent strain.9,25 As experimental conditions greatly influence biofilm formation,25 we first compared biofilm formation by mutant PAO-JP1 and its parent strain the PAO1 wild-type strain PAO-BI in our static biofilm assay. Biofilm measurements using Crystal Violet staining gave similar results for both strains (Figure 1a), confirming that the lasI mutation does not affect total biofilm for-mation in our biofilm model.



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Figure 1. (a) Biofilm formation in wild-type Pseudomonas aeruginosa and AHL-deficient mutants. (b) Effects of AHLs on biofilm formation.

 
In previous studies, strain PAO-BI and its derived lasI mutant PAO-JP1, as well as the non-nfxC rhlI mutant PDO100, have been used to determine the respective roles of autoinducers in biofilm formation.9,10,24,25 Such studies have suggested that C4-HSL does not play a significant role in biofilm formation.9,10 However, we have recently shown that strain PAO-BI bears the nfxC mutation.14 This mutation leads to overexpression of the MexEF-OprN multidrug efflux system, and to resistance towards quinolones, chloramphenicol, trimethoprim and tetracycline. More importantly, this mutation also leads to a reduction in rhlI expression, responsible for lower C4-HSL production, compared with the non-nfxC wild-type PAO1 strain PT5.14 Therefore, we wondered whether the reduced expression of rhlI by strains PAO-BI and PAO-JP1 might have led to an underestimation of the role of C4-HSL in biofilm formation. In accordance with a recent report,24 we have shown that the rhlI mutant PDO100 formed slightly less biofilm compared with strain PAO-BI (Figure 1a). More importantly, strain PAO-BI only produced 60% of the total biofilm compared with wild-type PT5 (Figure 1a), suggesting that overexpression of the MexEF-OprN multidrug efflux system reduces the biofilm production of strain PAO-BI. In order to confirm this result we deleted the mexE gene that encodes the membrane fusion protein of the MexEF-OprN efflux pump17 in strain PAO-BI to obtain mutant PT918. Such a deletion leads to complete inactivation of the MexEF-OprN efflux system, therefore suppressing the phenotype associated with pump overexpression.14 When tested in our static biofilm model, mutant PT918 was completely restored in biofilm formation to wild-type PT5 levels (Figure 1a). We also measured C4-HSL production in culture supernatants of strains PT5, PAO-BI and PT918 by a specific bioassay. C4-HSL production, reduced by 50% in strain PAO-BI, was restored to strain PT5 levels by the inactivation of the MexEF-OprN efflux system in strain PAO-BI (Table 2). These results confirm that the nfxC mutation is responsible for a reduction in biofilm formation by strain PAO-BI resulting from decreased C4-HSL production.


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Table 2. Concentration of C4-HSL in culture supernatants of P. aeruginosa cell-to-cell signalling mutants after 6 h of growth in LB medium
 
In order to determine the role of C4-HSL during biofilm formation, we decided to compare the total biofilm formed by wild-type PT5 and its derived lasI (PT466), rhlI (PT454), and lasI/rhlI (PT502) mutants. First, the production of C4-HSL was measured in the culture super-natants of these mutants. Some reduction in C4-HSL production can be expected in a lasI mutant as the las quorum-sensing system controls the transcription of rhlR, itself required for optimal C4-HSL production.26 Indeed the C4-HSL production of the lasI mutant PT466 was reduced by 55% compared with its parent strain, probably as a result of the las/rhl hierarchy. The lasI mutant PAO-JP1 was even more severely affected and produced only 2.5% compared with its parent strain and 1.5% compared with strain PT5 (Table 2). As expected, culture supernatants of mutants PT454, PT502 and PDO100 contained no detectable C4-HSL (Table 2).

When biofilm production was assessed, the lasI mutant PT466 produced slightly more biofilm than strain PT5 (Figure 1b). In contrast, the biofilm formed by the rhlI mutant PT454 was reduced by 70% compared with its parent strain (Figure 1b), correlating with the reduction in biofilm formed by the rhlI mutant PDO100 (Figure 1a). Furthermore, the double lasI/rhlI mutant PT502 formed a similar amount of biofilm as the rhlI mutant PT454 (Figure 1b). These results indicate that C4-HSL is required for full biofilm formation. To confirm this hypothesis, we complemented mutant PT454 by adding exogenous C4-HSL during the biofilm formation assay. As shown in Figure 1(b), addition of exogenous C4-HSL partially restored the biofilm formation of rhlI mutant PT454 from 30% to 65% of the wild-type PT5 level. Similarly, in the presence of both exogenous AHLs, the biofilm formed by mutant PT502 increased from 30% to 75% of the PT5 level (Figure 1b). The lack of complete complementation of both mutants through addition of a constant concentration of exogenous autoinducers to the biofilm assay is likely to result from suboptimal AHL concentrations as these vary both in time and space during biofilm formation.10 We do not believe that secondary mutations in vfr and algC in our cell-to-cell signalling mutants could be responsible for the lack of complete complementation. Mutations in these genes affect twitching motility, which is cell-to-cell signalling in-dependent.27,28 As twitching motility did not differ between parent strain PT5 and its derived cell-to-cell signalling mutants PT466, PT454 and PT502 (data not shown), such secondary mutations are unlikely to have occurred in our strains.

These results clearly demonstrate that, at least under our experimental conditions, C4-HSL is required for optimal biofilm formation by P. aeruginosa. Indeed it appears that a previously undiscovered reduced expression of rhlI, leading to lower C4-HSL production, in the wild-type strain PAO-BI, is responsible for an underestimation of the role of this autoinducer in biofilm formation. The importance of C4-HSL is indeed not visible when PAO-BI is used as the control strain,9 or when carrying an rhlI reporter fusion.10 In contrast, the importance of this autoinducer becomes apparent when both the parent and the rhlI mutant do not overexpress the MexEF-OprN efflux system. These results correlate well with the recent observation that the rhl system is activated during the maturation stage of biofilm development.29 It appears that while the las system (LasR/ 3-oxo-C12-HSL) is essential for biofilm differentiation,9 and plays a role during the irreversible attachment stage,29 the rhl system (RhlR/C4-HSL) also plays an important role.

The finding that P. aeruginosa strains overexpressing the MexEF-OprN multidrug efflux system are impaired in biofilm formation is interesting. Such strains can be selected during quinolone treatment in an animal model,30 and are less virulent in a rat model of acute pneumonia.31 Whether such multidrug-resistant isolates could be selected during antimicrobial treatment of CF patients, and affect the evolution of the disease deserves further investigation.

Azithromycin inhibits biofilm formation by reducing cell-to-cell signalling

The potential clinical value of antibacterials that would control and/or prevent P. aeruginosa infections by interfering with cell- to-cell signalling has recently been underlined.2,32 The macrolide antibiotic azithromycin is neither bactericidal nor bacteriostatic against P. aeruginosa (MIC 64–128 mg/L) at achievable tissue concentrations (1–4 mg/L).33,34 However, even at low concentrations (1–2 mg/L) azithromycin reduced the adherence of P. aeruginosa to polystyrene,35 as well as the production of exopolysaccharides by P. aeruginosa, and has therefore been suggested to inhibit biofilm formation.36 We have recently shown that 2 mg/L azithromycin inhibits the production of both 3-oxo-C12-HSL and C4-HSL by P. aeruginosa.15 In view of the above presented results we wondered whether azithromycin inhibits biofilm formation by interfering with autoinducer synthesis. In the presence of 2 mg/L azithromycin, the biofilm formed by strain PT5 was reduced by 45% as quantified by Crystal Violet staining (Figure 2a). This decrease was associated with a 50% reduction in exopolysaccharide production as measured by the total carbohydrate assay. In contrast 2 mg/L azithromycin did not affect biofilm production by mutant PT502 (27% of wild-type in the absence versus 25% in the presence of 2 mg/L azithromycin), suggesting that azithromycin exerts its effect on biofilm formation via inhibition of cell-to-cell signalling.



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Figure 2. Effect of azithromycin on (a) biofilm formation, determined by Crystal Violet staining (diagonally striped bars) and exopolysaccharide production (white bars) and (b) AHL production.

 
In order to confirm that azithromycin reduced the production of both AHLs in the biofilm, we directly extracted and measured both AHLs from strain PT5 biofilms grown on PVC strips in the absence and presence of 2 mg/L azithromycin. As expected, both 3-oxo-C12-HSL and C4-HSL were severely reduced in the presence of the macrolide (Figure 2b). Addition of both AHLs in the presence of azithromycin restored the amount of biofilm formed to 85% of the initial levels observed in the absence of azithromycin as measured by Crystal Violet staining, and to 80% as measured by exopolysaccharide production (Figure 2a). Taken together, these results indicate that 2 mg/L azithromycin inhibits the production of biofilm by wild-type PT5 in our biofilm model at least partially by interfering with the production of the two autoinducers. As 3-oxo-C12-HSL is required for biofilm differentiation,9 it is likely that azithromycin, by reducing both C4-HSL and 3-oxo-C12-HSL formation, leads not only to a reduction in the total amount of biofilm formed, but also affects its differentiation. It has been recently described that rhamnolipid surfactant is important for the maintenance of biofilm architecture by maintaining open channels within the biofilm structure.13 Moreover the rhl cell-to-cell signalling system has been suggested to protect P. aeruginosa strains growing inside biofilms by controlling the production of nitrite reductase essential for the detoxification from NO produced during growth in anaerobic conditions.12 Both these functions are dependent on the adequate production of C4-HSL.2 It appears therefore that azithromycin by reducing cell-to-cell signal production not only reduces the production of extracellular virulence factors such as elastase,15 but also interferes with biofilm formation at different levels. This could be particularly useful in clinical situations, such as cystic fibrosis,4,11 and colonization of intubation devices in which growth in biofilm might play an important role. The recent encouraging results obtained in CF patients treated with azithromycin3739 might therefore not only be the result of the suggested anti-inflammatory effect of this macrolide, but also because of its cell-to-cell signalling blocking activity. These results support the need for active research to develop more efficient cell-to-cell signalling blockers that could, according to the results presented here, reduce P. aeruginosa biofilm formation on medical devices such as endotracheal intubation devices.


    Acknowledgements
 
Synthetic 3-oxo-C12-HSL and C4-HSL were kindly provided by U. Burger, Department of Chemistry, University of Geneva. We would like to thank R. Comte for outstanding technical assistance and P. Wood for carefully reviewing the manuscript prior to submission. This work was supported by a grant from the Programme Commun de Recherche en Génie Biomédical Genève Lausanne 1999–2002 (to C.V.D.), and grants 3231-051940.97 and 3200-052189.97 from the Swiss National Research Foundation (to C.V.D.).


    Footnotes
 
* Present address. UMR CNRS 5557-Ecologie Microbienne, Université Claude Bernard, Lyon 1, France. Back

§ Corresponding author. Tel: +41-22-702-56-39; Fax: +41-22-702-57-02; E-mail: Christian.VanDelden{at}medecine.unige.ch Back


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 Abstract
 Introduction
 Materials and methods
 Results and discussion
 References
 
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