The extracellular biofilm matrix includes primarily DNA and exopolysaccharides (EPS), which function to maintain aggregate structures and to protect biofilms from antibiotics and the immune response. Both polymers are anionic and have cation binding activity, however the impact of this activity on biofilms is not fully understood. Host cell contact is considered the primary signal for activation of most type III secretion systems (T3SS), although calcium limitation is frequently used as a trigger of contact-independent T3SS expression. We hypothesized that alginate, which is a known calcium binding exopolysaccharide produced in mucoid Pseudomonas aeruginosa isolates, can activate the T3SS in biofilms. The addition of exogenous purified alginate to planktonic, non-mucoid PAO1 cultures induced expression of exoS, exoT and exoY-lux reporters of the T3SS in a concentration-dependent manner. Induction by alginate was comparable to induction by the calcium chelator NTA. We extended our analysis of the T3SS in flow chamber-cultivated biofilms, and showed that hyperproduction of alginate in mucA22 mucoid isolates resulted in induction of the exoS-gfp transcriptional reporter compared to non-mucoid paired isolates. We confirmed the transcriptional effects of alginate on the T3SS expression using a FlAsH fluorescence method and showed high levels of the ExoT-Cys4 protein in mucoid biofilms. Induction of the T3SS could be prevented in planktonic cultures and mucoid biofilms treated with excess calcium, indicating that Ca2+ chelation by the EPS matrix caused contact-independent induction. However, mucoid isolates generally had reduced exoS-lux expression in comparison to paired, non-mucoid isolates when grown as planktonic cultures and agar colonies. In summary, we have shown a mucoid biofilm-specific induction of the type III secretion system and highlight a difference between planktonic and biofilm cultures in the production of virulence factors.
Citation: Horsman SR, Moore RA, Lewenza S (2012) Calcium Chelation by Alginate Activates the Type III Secretion System in Mucoid Pseudomonas aeruginosa Biofilms. PLoS ONE 7(10): e46826. doi:10.1371/journal.pone.0046826
Editor: Stefan Bereswill, Charité-University Medicine Berlin, Germany
Received: June 29, 2012; Accepted: September 5, 2012; Published: October 8, 2012
Copyright: © Horsman et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This research was supported by the Westaim Corporation and the Alberta Science and Research 378 Authority (ASRA) and a grant by Cystic Fibrosis Canada. SH is the recipient of an NSERC 379 Studentship. SL holds the Westaim-ASRA Chair in Biofilm Research. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have the following interests. This research was partly supported by the Westaim Corporation, and SL holds the Westaim-ASRA Chair in Biofilm Research. There are no patents, products in development or marketed products to declare. This does not alter the authors' adherence to all the PLOS ONE policies on sharing data and materials, as detailed online in the guide for authors.
Biofilms are multicellular, surface-associated microbial communities encased in an extracellular matrix largely composed of extracellular DNA and exopolysaccharides (EPS) , . Both DNA and EPS are structural components of the biofilm matrix that are required for attachment, aggregation and the later stage of biofilm maturation , . In mucoid isolates of P. aeruginosa, alginate is hyperproduced and is involved in the formation of biofilms with highly structured architecture . The pel and psl gene clusters code for the production of the primary exopolysaccharides in non-mucoid strains that are required for attachment to plastic surfaces and epithelial cells, as well as aggregation and pellicle formation . Exopolysaccharides also perform capsule functions that include reducing phagocytosis by macrophages , , limiting neutrophil migration, preventing the binding of complement factors and absorbing reactive oxygen species . Another property of the EPS matrix is to provide short-term protection as a diffusion barrier to antibiotics, although not all antibiotics have reduced penetration through biofilms .
Cation chelating activity is a common property of extracellular, anionic polymers present in the biofilm matrix. Alginate is the EPS polymer hyperproduced in mucoid Cystic Fibrosis (CF) isolates of P. aeruginosa and has a cation chelating activity, with a higher binding affinity for Ca2+ than for Mg2+ . Purified alginate from mucoid P. aeruginosa was shown to bind magnesium with weak interactions and preferentially binds calcium leading to cation-induced cross-linking and gelation of alginate . It has been reported that Ca2+ binding activity is a general property of exopolysaccharides isolated from several bacterial species . We recently identified a novel function of extracellular DNA as a chelator of divalent metal cations, including Mg2+, Ca2+, Zn2+ and Mn2+ . The magnesium binding activity of DNA was required for induced expression of the arn antimicrobial peptide resistance genes and increased antimicrobial resistance in biofilms .
The type III secretion system (T3SS) is a conserved virulence mechanism found in Gram-negative bacteria and is required for cytotoxicity and immune evasion , . The T3SS uses a needle-like structure to deliver effector proteins across the two membranes of the Gram-negative envelope and directly into the cytoplasm of host cells, where they are then able to exert their toxic effect. P. aeruginosa encodes four effector proteins translocated by the type III secretion system: ExoS, ExoT, ExoU and ExoY . Contact with the host cell is considered the most relevant cue for triggering T3SS in the context of an infection, however Ca2+ limitation is routinely used in vitro to trigger type III secretion in P. aeruginosa, without host cell contact , . The low Ca2+ response leading to increased T3SS expression is also observed in pathogenic species of Yersinia  and cation levels influence expression of the T3SS in Chlamydia trachomatis  and Salmonella .
P. aeruginosa grows as a biofilm in the lungs of CF patients and mucoid isolates arise in the CF lung to promote long-term survival. Several previous reports have compared the expression of the T3SS in mucoid and non-mucoid isolates and concluded that the T3SS is repressed in mucoid isolates , . These observations support the general view that long-term, chronic isolates have adapted for reduced virulence factor production in order to evade the immune response. In all of these studies, virulence factor production was assessed in planktonic cultures, although it is generally accepted that P. aeruginosa grows as a biofilm in the CF lung. Here we provide evidence that alginate production in mucoid isolates can induce expression and production of type III secreted toxins during growth in flow-chamber biofilms.
Calcium chelation by alginate induces expression of the T3SS
We first examined expression of a transcriptional exoS-lux fusion in wild type PAO1 under conditions with varying cation concentrations and observed that the T3SS was maximally expressed with low levels of Ca2+ (20 µM) and relatively high concentration of Mg2+ (0.1–2 mM) (Fig. 1A,C). The T3SS was repressed with the addition of 2 mM Ca2+, confirming the role of calcium limitation in inducing expression of the T3SS. The T3SS was also repressed under low Ca2+ conditions when Mg2+ levels were also present in low µM levels, indicating that Mg2+ availability also influenced expression of the T3SS (Fig. 1A,C). There was a longer lag and a reduction in growth rate and final growth yield with µM amounts of Mg2+ and Ca2+, which may explain the repression of the T3SS under these conditions (Fig. 1B). The kinetics of gene exoS-lux expression over time are shown in Figure 1C and illustrate that the peak of expression occurred in mid-log phase between 11–13 hours. Similar expression kinetics were seen for exoY-lux and exoT-lux (data not shown).
Figure 1. Calcium limitation induces expression of the type III secretion system in P. aeruginosa PAO1.
(A) P. aeruginosa PAO1 exoS-lux was used as a reporter for activation of the T3SS in BM2 media supplemented with varying amounts of magnesium and calcium. Gene expression was measured every 20 minutes for 18 hours and the maximal gene expression is shown. The values shown are the means from triplicate experiments and the error bars represent the standard deviation. All values differ significantly (p<0.02 by unpaired t-test) from the control (2 mM Mg2+, 2 mM Ca2+). (B) Growth curves in BM2 media with corresponding magnesium and calcium concentrations. (C) Raw CPS illustrating the kinetics of exoS-lux expression in various magnesium and calcium concentrations. Similar curves have been observed for exoT-lux and exoY-lux expression over time (data not shown). Each experiment was performed at least three times and representative curves are shown.doi:10.1371/journal.pone.0046826.g001
DNA and alginate have both been shown to have calcium chelating activity , , but the consequence of this property is unknown in the context of bacterial biofilms. We tested if both matrix polymers could induce expression of the type III secretion system, in a similar manner to the addition of typical Ca2+ chelators (EGTA, NTA) to planktonic cultures , . Exogenous alginate was added in a range of concentrations to planktonic PAO1 cultures expressing transcriptional reporters exoS-lux, exoY-lux and exoT-lux. In this series of experiments, we used BM2 growth media with high Ca2+ (0.2 mM) and Mg2+ (0.5 mM), which resulted in low basal levels of exoS, exoY and exoT, due to the repressing levels of Ca2+ (0.2 mM) (Fig. 2). As a positive control, we added the known calcium chelator NTA and compared the gene expression profiles in all conditions. Exogenous alginate induced expression (up to 17-fold) of the exoS-lux, exoY-lux and exoT-lux reporters in a concentration-dependent manner (Fig. 2A,B). The exoS-lux, exoY-lux and exoT-lux reporters were also strongly induced (up to 23-fold) by exogenous DNA in a concentration-dependent manner (Fig. 2A,C). Of the three chelators, NTA and DNA caused comparable levels of induction, except at high concentrations of NTA, and alginate caused slightly lower levels of induction (Fig. 2). Expression of the T3SS reporter was induced 3-fold when calcium was decreased from 2 mM to 0.02 mM (Fig. 1A) or when alginate was added at concentrations ranging from 0.17–0.25% (Fig. 2). Higher concentrations of alginate caused up to a 17-fold induction in media with a baseline 0.2 mM calcium concentration (Fig. 2A), which illustrates the large capacity for binding and sequestering calcium.
Figure 2. Exogenous alginate and DNA induce expression of the T3SS in P. aeruginosa planktonic cultures.
P. aeruginosa PAO1 exoS-lux, exoT-lux and exoY-lux were used as reporter strains to monitor expression of the T3SS. (A) Bioluminescence gene expression assays were used to measure exoS-lux expression in planktonic cultures of PAO1 grown in BM2 with 0.2 mM Ca2+ and 0.5 mM Mg2+ and supplemented with various concentrations of NTA, exogenous DNA or alginate. (B) Gene expression assays were used to measure exoT-lux and exoY-lux expression in planktonic cultures of PAO1 grown in BM2 with 0.2 mM Ca2+ and 0.5 mM Mg2+ and supplemented with various concentrations of alginate (C) or (D) extracellular DNA. Gene expression was measured every 20 minutes for 18 hours and the maximal gene expression is shown. The values shown are the means from triplicate experiments and the error bars represent the standard deviation. Values that differ significantly (p<0.02 by unpaired t-test) from the controls (BM2 alone) are marked with an asterisk. Each experiment was performed at least three times and representative values are shown.doi:10.1371/journal.pone.0046826.g002
To determine if induction of the T3SS was due to the calcium chelating activity of alginate or DNA, excess cations were added simultaneously with each polymer and the expression of exoS-lux was measured. While the addition of Mg2+ (32 mM) had no effect on DNA-induced T3SS expression, the addition of Ca2+ (8 and 16 mM) significantly reduced expression and the addition of 32 mM Ca2+ completely abrogated the DNA-induced expression (Fig. 3A). Similarly, the addition of Mg2+ (16 mM) had no effect on alginate-induced T3SS expression, but the addition of Ca2+ (8 and 16 mM) completely abrogated the induction by alginate (Fig. 3B). Together, these data suggest that alginate and DNA have a great capacity to sequester calcium, and that calcium chelation was specifically required for induction of the T3SS in this planktonic culture system with exogenous polymer.
Figure 3. Calcium chelation by exogenous DNA and alginate induces expression of the T3SS in P. aeruginosa.
P. aeruginosa PAO1 exoS-lux was used as a reporter for the T3SS. Planktonic cultures were supplemented with (A) exogenous DNA or (B) alginate and various concentrations of calcium and magnesium to BM2 with a baseline concentration of 0.2 mM calcium. Gene expression was measured every 20 minutes for 18 hours and the maximal gene expression is shown. The values shown are the means from experiments done in triplicate and the error bars represent the standard deviation. Values that differ significantly (p<0.02 by unpaired t-test) from the controls (BM2 alone) are marked with an asterisk. Each experiment was performed at least three times and representative values are shown.doi:10.1371/journal.pone.0046826.g003
Comparison of exoS-lux expression in planktonic cultures and colonies in mucoid and non-mucoid strains
To determine if the effects of exogenous alginate could be observed in strains that naturally produced alginate, we compared the expression of exoS-lux in both planktonic cultures and agar-grown colonies in mucoid and non-mucoid isolates of P. aeruginosa. For these experiments we constructed a mucA22 mutant in PAO1, which resulted in the mucoid colony phenotype. In addition, we used the original mucoid isolate FRD1 (mucA22; single base pair mutation) and its non-mucoid derivative FRD2 . When these cultures were grown in planktonic conditions, exoS-lux expression was slightly higher (~2-fold) in non-mucoid isolates PAO1 and FRD2 (Fig. 4A,B). These results are consistent with numerous reports in the literature showing that mucoid isolates have reduced expression of the T3SS when grown in liquid, planktonic cultures , .
Figure 4. ExoS-lux expression in mucoid and non-mucoid isolates grown in planktonic cultures and as agar colonies.
(A) Mucoid (FRD1, PAO1mucA22) and non-mucoid (FRD2, PAO1) P. aeruginosa strains encoding a chromosomal exoS-lux fusion as a reporter for the T3SS were grown in LB and (B) BM2 (0.5 mM Mg2+, 0.2 mM Ca2+) planktonic cultures. Gene expression was measured every 20 minutes for 18 hours and the maximal gene expression is shown. The values shown are the means from experiments done in triplicate and the error bars represent the standard deviation. All values from mucoid strains (FRD1, mucA22) differ significantly (p<0.02 by unpaired t-test) from the corresponding non-mucoid controls (FRD2, PAO1). (C,E) This strain panel was plated on Pseudomonas Isolation Agar (PIA) and (D,F) LB and incubated at 37°C for 2 days. Bioluminescence was detected in Bio-Rad XRS Chemidoc Imaging system. The colonies are depicted using epi white illumination (left panel) and corresponding exoS-lux expression using bioluminescence imaging (lower panel). Each experiment was performed at least three times and representative values and images are shown.doi:10.1371/journal.pone.0046826.g004
Next, all strains were grown on agar plates and exoS-lux gene expression was monitored. Colonies of the non-mucoid strains PAO1 and FRD2 were generally brighter than those of the mucoid isolates FRD1 and PAO1mucA22 on LB or PIA agar (Fig. 4C-F) with the exception of LB agar where exoS-lux expression was comparable and slightly brighter in the mucA22 mucoid isolate of PAO1. This pattern of expression between mucoid and non-mucoid strains was consistent for up to 5 days, and expression levels decreased over time (data not shown).
Mucoid isolates induce exoS-gfp expression in flow chamber biofilms
To determine the influence of the biofilm matrix polymers on expression of the T3SS in P. aeruginosa, we extended our analysis to flow chamber-cultivated biofilms. We constructed a T3SS reporter strain to express a chromosomally encoded exoS-gfp fusion to visualize expression of the T3SS in biofilms. All biofilms were cultivated in flow chamber devices for 2 days at 37°C, which generally resulted in biofilms with a 20–30 µM thickness. As a positive control, the strain PAO1ΔexsE that constitutively expresses the T3SS  was used to demonstrate high levels of exoS-gfp expression in biofilms (Fig. 5A–C). In contrast, exoS-gfp was not expressed in the non-mucoid strain PAO1 (Fig. 5D–F) or PAK (data not shown). Staining the EPS with calcofluor was sufficient to indicate biofilm structure, despite the lack of exoS-gfp expression in PAO1. Although extracellular DNA accumulated in the matrix of PAO1 biofilms (data not shown) and the Pel and Psl exopolysaccharides are produced in this strain , neither of these matrix components were sufficient to induce T3SS expression in non-mucoid PAO1 flow chamber biofilms.
Figure 5. The T3SS expression is induced in flow chamber biofilms of mucoid, alginate producing P. aeruginosa strains.
Flow chamber-grown biofilms of (A–C) constitutive T3SS expressing strain PAO1 ΔexsE, (D–F) non-mucoid PAO1, (G–I) mucoid FRD1, (J–L) mucoid PAO1 mucA22 and (M–O) non-mucoid PAO1 with the exogenous addition of 10 mg/ml alginate, all encoding exoS-gfp were cultivated at 37°C for 2 days. Fluorescence microscopy shows the level of exoS-gfp expression in each strain (A, D, G, J) and the biofilm matrix counterstained with calcofluor for exopolysaccharides (B, E, H, K). The merged images are provided in the right column (C, F, I, L,O). In each case, representative images of x-y (large panel), x-z (bottom panel), and y-z (right panel) slices are displayed. Scale bar, 15 µm. The signal intensity was plotted for the green (exoS-gfp) (P) and purple (EPS) (Q) channels along the line indicated by the white arrow in the x-y plane displayed for FRD1 in panel I. The merged graph is provided (R), with the signal intensities overlapping for the green and purple channels to examine co-localization. Each experiment was performed at least three times and representative images are shown.doi:10.1371/journal.pone.0046826.g005
Next, we introduced the exoS-gfp transcriptional fusion onto the chromosome of FRD1  and a mucA22 mucoid isolate derived from PAO1. In contrast to that seen in non-mucoid strains, exoS-gfp was highly expressed in the mucoid strains FRD1 (Fig. 5G–I) and PAO1 mucA22 (Fig. 5J–L). To determine if exogenous alginate could induce the T3SS in non-mucoid PAO1 biofilms, we examined PAO1 biofilms cultivated in the presence of exogenous alginate for exoS-gfp expression. In agreement with the naturally mucoid strains, the addition of purified alginate was sufficient to induce exoS-gfp expression in the otherwise non-mucoid strain PAO1 (Fig. 5M–O). For the mucoid strain PAO1 mucA22 (Fig. 5J–L) and non-mucoid PAO1 cultivated with exogenous alginate (Fig. 5M–O), there was a clear co-localization of exoS-gfp expression with EPS production. For mucoid strain FRD1, there were regions where exoS-gfp expression was more apparent than EPS production; however the signal intensities shown in Figure 5P–R indicate a co-localization of the highest signals for EPS production with high levels of gene expression.
The T3SS effector ExoT-Cys4 is produced in mucoid biofilms
We wanted to verify that transcription of the T3SS led to production and secretion of T3SS effectors into the biofilm using fluorescence microscopy. Since translational fusions of GFP to the T3SS effectors are not secreted through the needle , we used a novel method to visualize the accumulation of type III effectors in P. aeruginosa biofilms. For this experiment, we examined the production and accumulation of ExoT in biofilms. We constructed a C-terminal tetra-cysteine tagged ExoT-Cys4 and expressed this protein from the chromosome. Biofilms were cultivated for 2 days at 37°C and visualized after injection of the FlAsH reagent. FlAsH is a fluorescein–based dye that binds specifically to CCXXCC amino acid sequences, a motif of four cysteines –. Using FlAsH microscopy, we observed that there was very little FlAsH staining of non-mucoid PAO1 (Fig. 6A–C) and FRD2 (Fig. 6D–F) biofilms expressing ExoT-Cys4. This result was consistent with a lack of exoS-gfp gene expression in non-mucoid strains (Fig. 5D–F). Likewise, there was very little staining of cells in control FRD1 biofilms not expressing the ExoT-Cys4 protein (data not shown), revealing limited background fluorescence in the mucoid strain FRD1 from non-specific FlAsH binding.
Figure 6. The T3SS effector protein ExoT is produced and detected in mucoid P. aeruginosa biofilms.
ExoT was tagged with a C-terminal tetracysteine motif that can be bound by a fluorescein-based biarsenical dye (FlAsH reagent). Biofilms of non-mucoid strains PAO1 and FRD2 and mucoid strain FRD1 encoding this chromosomal ExoT-CCPGCC construct were cultivated at 37°C for 2 days and incubated with the FlAsH reagent. Fluorescence microscopy shows the levels of ExoT production in (A) PAO1, (D) FRD2, (G) FRD1 and (J) FRD1 grown in the presence of 10 mM exogenous calcium as well as the biofilm matrix counterstained for exopolysaccharides (B, E, H, K). The merged images are provided in the right column (C, F, I, L). In each case, representative images of x-y (large panel), x-z (bottom panel), and y-z (right panel) slices are displayed. Scale bar, 15 µm. Mucoid FRD1 biofilms were cultivated then supplemented with excess 10 mM Ca2+ (J–L) to examine the effect on ExoT production. Each experiment was performed at least three times and representative images are shown.doi:10.1371/journal.pone.0046826.g006
In contrast to the non-mucoid PAO1 (Fig. 6A–C) and FRD2 biofilms (Fig. 6D–F), significant levels of ExoT-Cys4 protein were detected in biofilms of mucoid strain FRD1, which hyperproduces alginate  (Fig. 6G–I), with a clear co-localization of ExoT-Cys4 detection with EPS production (data not shown). Since it is known that induced expression of the T3SS is coupled with active secretion in P. aeruginosa , , we propose that detection of T3SS effector ExoT indicates the secretion and accumulation of protein in the matrix of mucoid biofilms.
Increased expression and secretion of the T3SS effectors correlated with the production of alginate and we propose that activation of the T3SS is a consequence of the Ca2+ chelating activity of alginate. To test this hypothesis, mucoid biofilms were cultivated for 7 hours and then 10 mM calcium was added into the media and pumped across the biofilms for the remaining 35 hours, which had no effect on biofilm depth. The addition of 10 mM calcium to pre-formed biofilms was sufficient to repress expression of the T3SS in the mucoid FRD1 isolate (Fig. 6J–L).
To examine the pattern of FlAsH staining of ExoT-Cys4 in greater detail, we used the FlAsH reagent in combination with a membrane-specific stain. Mid-log cultures of mucoid FRD1 were shown to produce large aggregates (Fig. 7B), whereas non-mucoid PAO1 (Fig. 7A) and FRD2 (Fig. 7C) did not aggregate in planktonic cultures. Aggregates of the mucoid strain FRD1 were stained with the membrane-specific lipophilic dye FM4-64 and the FlAsH reagent was added to detect ExoT-Cys4. Green FlAsH fluorescence was observed within certain individual cells and outside of individual cells, which resulted in a diffuse ExoT-Cys4 staining pattern in the aggregate (Fig. 7D–F). This dual staining pattern for ExoT-Cys4 by the FlAsh reagent indicates that extracellular and intracellular protein can be detected under these labeling conditions.
Figure 7. FlAsH detection of ExoT-Cys4 in an aggregate of the mucoid isolate FRD1.
Phase contrast images of (A) PAO1, (B) FRD1 and (C) FRD2 mid-log planktonic cultures. Fluorescence microscopy shows a mid-log culture of mucoid FRD1 stained with (D) FlAsH to detect the production of ExoT-Cys4 and (E) a membrane-specific dye FM 4–64 (red). The merged image is shown in (F). Each experiment was performed at least three times and representative images are shown.doi:10.1371/journal.pone.0046826.g007
Alginate is an anionic polymer consisting of blocks of 1–4 linked D-mannuronate and L-guluronate residues. The negatively charged carboxylate groups are possible sites of calcium binding, which may be a general feature of bacterial exopolysaccharides . Alginate is hyperproduced in mucoid CF isolates and accumulates during biofilm formation. Here we assessed the influence of alginate accumulation on expression of the type III secretion system in planktonic, agar-grown colonies and flow chamber biofilms.
In our initial experiments, we added exogenous purified alginate to planktonic cultures and monitored the effect on expression of the exoS, exoY and exoT type III secreted effectors. Alginate acted as a calcium chelator leading to the induction of all three effectors in a concentration-dependent manner. We then examined the influence of natively produced alginate on expression of the T3SS. Using multiple paired mucoid and non-mucoid isolates, we showed that expression of the type III secretion was slightly reduced in mucoid isolates grown as both planktonic cultures and agar colonies, compared to non-mucoid isolates. This result contrasted our experiments with exogenous polymer, but was consistent with many previous reports comparing the mucoid and non-mucoid isolates , .
Very few studies examine the production of virulence factors during biofilm growth. Therefore, we extended our analysis of the T3SS to flow chamber-cultivated biofilms. We used multiple live-imaging microscopy techniques to demonstrate that the T3SS is indeed highly expressed specifically in mucoid biofilms (Fig. 5), which results in high levels of the ExoT-Cys4 type III secreted-effector in mucoid biofilms (Fig. 6). While both exogenous polymers DNA and alginate induced expression of exoS-lux when added to planktonic cultures (Fig. 1), only alginate production was required for induction of the T3SS in biofilms.
Calcium chelators (EGTA, NTA) are frequently used to induce the T3SS in experiments without host cells. The T3SS was repressed in high Ca2+ (0.2 mM), but was induced when Ca2+ was provided in µM concentrations and with the addition of alginate to media containing repressing levels of Ca2+. Induction of the T3SS by alginate was blocked with the addition of excess calcium but not magnesium, indicating that the calcium chelating activity of alginate is required to induce the T3SS. Similarly, the addition of excess calcium to mucoid biofilms in flow chambers also prevented expression of the T3SS. These observations suggest that alginate in the biofilm matrix binds and sequester Ca2+, which triggers type III secretion in the absence of host cell contact. It has also been shown previously that T3SS is induced in biofilms, leading to the production of T3SS effector proteins in the biofilm effluent , .
In contrast to the expression pattern in mucoid biofilms, planktonic cultures and agar colonies had slightly reduced expression of the T3SS in mucoid isolates under most conditions. This was consistent with multiple studies that also reported reduced gene expression of T3SS effectors in other mucA22 mucoid P. aeruginosa isolates. Thus, we propose that something unique about growth in a mucoid biofilm is required for induction of the T3SS. It may be related to increased EPS production or accumulation of alginate in microcolonies under flow growth conditions, or to the unique structure and organization of mucoid biofilms compared to mucoid isolates grown in liquid or on agar. Alternatively, mucoid cultures aggregate in planktonic conditions (Fig. 7), which may impose nutrient limitation or stress in planktonic cultures. It is known that metabolic stress resulting in an increased demand of certain metabolites represses the T3SS . In contrast, flow chamber biofilms may not experience this stress as the biofilms are exposed to a constant flow of fresh growth media. Since it is widely accepted that P. aeruginosa grows as a biofilm in the CF lung , we propose that studying the expression of virulence genes in cultivated biofilms will yield a new understanding of the virulence traits expressed during chronic CF infections.
The detection of T3SS effector proteins in biofilms suggests that T3SS effectors may function as extracellular toxins, in addition to their functions as injected, intracellular toxins. There are several reports to support the claim that T3SS effectors have biological activity as extracellular toxins. Purified ExoS was added exogenously to immune cells and shown to stimulate monocytes to produce proinflammatory cytokines and chemokines  and activate T cells, resulting in proliferation and apoptosis . There is mounting evidence in other type III secretion systems that extracellular effectors play a role in bacterial pathogenesis. The T3SS effector YopM from Yersinia was purified and shown to promote its own entry into multiple cell types and internalization of YopM resulted in reduced proinflammatory cytokine production . Multiple Yop T3SS effectors of Y. pseudotuberculosis were found on the bacterial surface and it was proposed that translocation of Yop effectors via a T3SS-dependent delivery involves a second step to translocate ‘presecreted’ surface effectors into the host . Taken together, the type III secretion system may not be exclusively required for injection of secreted effectors into host cells.
The biofilm matrix polymers have well-established functions in supporting biofilm structure and immune evasion. Here we show that the calcium binding activity of alginate can induce virulence gene expression. We have previously shown that the magnesium chelating activity of DNA can induce the expression of antimicrobial peptide resistance genes . The expression of these matrix-induced phenotypes may contribute to the long-term survival of biofilms from antibiotic treatment and the immune system, and likely the ability to cause disease in chronic infections.
Materials and Methods
Bacterial strains and media
Strains, plasmids and primers used in the study are listed in Table 1. Unless otherwise indicated, biofilms and planktonic cultures were grown in Basal Minimal Medium (BM2) at 37°C. BM2 contained the following components: 100 mM HEPES, 7 mM (NH4)2SO4, 1.03 mM K2HPO4, 0.57 mM KH2PO4, 500 µM MgSO4, 200 µM CaCl2, 10 µM FeSO4 and ion solution containing 1.6 µM MnSO4·H20, 13.9 µM ZnCl2, 4.7 µM H3BO3 and 0.7 µM CoCl2·6H20.The ion solution and iron sulphate solutions were added to the media after it was autoclaved. The media was supplemented with 20 mM sodium succinate as a carbon source for all bioluminescence assays or 0.4 mM glucose for biofilm cultivation because glucose promotes large aggregate biofilms .
Table 1. Bacterial strains, plasmids and PCR primers used in the study.doi:10.1371/journal.pone.0046826.t001
Real-time gene expression in planktonic cultures
Bioluminescence assays were performed as previously described but with minor modifications . Overnight cultures were grown in LB medium, washed in BM2 medium, diluted 1/1000 into 150 µl culture medium in a 96-well black plate with a transparent bottom (9520 Costar; Corning Inc.) and overlaid with 50 µl of mineral oil to prevent evaporation. Gene expression (luminescence) and growth (optical density) were measured at 37°C every 20 minutes for 18 hours by the Wallac Victor2 luminescence plate reader (Perkin-Elmer) and the maximal expression was retained. Biofilm matrix components, alginate (sodium salt, Sigma) or DNA (sodium salt, USB) were added exogenously to liquid media in the concentrations indicated. To degrade the EPS matrix in retS planktonic cultures, cellulase (from Aspergillus niger, Sigma) was added in the concentrations indicated.
Biofilm cultivation in flow chambers
Biofilms were cultivated for 48 hours at 37°C in flow chambers with channel dimensions of 1×4×40 mm as previously described but with minor modifications . Silicone tubing (VWR, .062 ID×.125 OD×.032 wall) was autoclaved and the system was assembled and sterilized by pumping a 0.5% hypochlorite solution through the system at 6 rpm for 1 hour using a Watson Marlow 205S peristaltic pump. The system was then rinsed at 6 rpm with sterile water and medium for 30 minutes each. Flow chambers were inoculated by injecting 400 µl of mid-log culture diluted to an OD600 of 0.02 with a syringe. After inoculation, chambers were left without flow for two hours after which medium was pumped though the system at a constant rate of 0.75 rpm (3.6 ml/hour).
Construction of P. aeruginosa strains containing gfp transcriptional reporters
The gfpmut3 gene was amplified by PCR from pCS01 using the primer pair BamHI_gfpF/NotI_gfpR, digested with BamHI/NotI and cloned into BamHI/NotI-digested pMS402 . The promoter of exoS was amplified from genomic DNA of P. aeruginosa PAO1 using the primer pair XhoI_exoSF/BamHI_exoSR, digested with XhoI/BamHI and cloned upstream of gfpmut3 in XhoI/BamHI-digested pMS402gfp. The suicide vector used for chromosome integration was constructed by cloning a PacI fragment containing the exoS-gfp construct into a 6 kb PacI fragment from the mini-CTX vector. The mini-CTX-exoSgfp construct was moved into E. coli SM10 and inserted into the chromosomes of P. aeruginosa at the attB site via biparental mating as previously described . We constructed a mucoid mucA22 mutant in the PAO1 background using the pDONRXmucA22 allelic exchange construct, as previously described , .
Construction of P. aeruginosa strains encoding ExoT-Cys4 for FlAsH microscopy
The exoT gene lacking a stop site was amplified by PCR from genomic DNA of P. aeruginosa PAO1 using the primer pair PstI_exoTF/HindIII_exoTR and digested with PstI/HindIII. An optimized, tetracysteine tag (AGSFLNCCPGCCMEPGGR)  with HindIII/KpnI sticky ends was generated by annealing the oligonucleotides HK_Cys4F and HK_Cys4R by incubating in a high salt solution at 95°C for 5 minutes, 70°C for 10 minutes and slowly cooling to 20°C. This tetracysteine tag was ligated to the C-terminus of exoT and then the ExoT-Cys4 construct was inserted into the KpnI/PstI-digested pUC18T-mini-Tn7T-Gm vector by ligation . The mini-Tn7-ExoT-Cys4 construct was confirmed by PCR amplification and sequencing, and then moved into the chromosome of P. aeruginosa at the attTn7 site via electroporation with the helper plasmid pTNS2 .
Fluorescent labeling of effector protein ExoT-Cys4 in a biofilm
Biofilms of Pseudomonas aeruginosa strains expressing the ExoT-Cys4 protein from the chromosome were cultivated as described above. A 400 µl solution of 5 µM FlAsH compound and 10 µM TCEP (reducing agent) was injected into each flow chamber and incubated for 90 minutes before washing once with a 400 µl solution of 250 µM BAL wash buffer and 40 µg/ml calcofluor in a 0.9% NaCl solution. The chambers were removed from the system and imaged using fluorescence microscopy.
Biofilm labeling and microscopy
After biofilm cultivation, the fluorescent dye calcofluor was diluted and 400 µl was injected into the flow chambers. The chambers were removed from the system and imaged using fluorescent microscopy. Calcofluor (Sigma) was used at 40 µg/ml to counterstain the biofilm matrix, binding the β-1,3 and β-1,4 linkages in exopolysaccharides, Sytox red (Invitrogen) was used at 20 nM to counterstain the extracellular DNA in biofilms and FlAsH reagent (Invitrogen) was used at a concentration of 5 µM to stain the tetracysteine-tagged effector protein ExoT. All microscopy was done with a Leica DMI 4000 B widefield fluorescence microscope equipped with filter sets for monitoring of blue (Ex 390/40, Em 455/50), green (Ex 490/20, Em 525/36), red (Ex 555/25, Em 605/52) and far red (Ex 645/30, Em 705/72) fluorescence, using the Quorum Angstrom Optigrid (MetaMorph) acquisition software. Images were obtained with a 63×1.4 objective. Deconvolution was done with Huygens Essential (Scientific Volume Imaging B.V.) and 3D reconstructions were generated using the Imaris software package (Bitplane AG).
The authors acknowledge the support of DE Woods, L Charron-Mazenod and H Mulcahy for technical assistance, and H Mulcahy, EP O'Grady and JB McPhee for critical reading of the manuscript.
Conceived and designed the experiments: SRH SL. Performed the experiments: SRH RAM SL. Analyzed the data: SRH RAM SL. Contributed reagents/materials/analysis tools: SRH SL. Wrote the paper: SRH SL.
- 1. Whitchurch CB, Tolker-Nielsen T, Ragas PC, Mattick JS (2002) Extracellular DNA required for bacterial biofilm formation. Science 295(5559) 1487. doi: 10.1126/science.295.5559.1487
- 2. Sutherland IW (2001) The biofilm matrix–an immobilized but dynamic microbial environment. Trends Microbiol 9(5) 222–227. doi: 10.1016/S0966-842X(01)02012-1
- 3. Ryder C, Byrd M, Wozniak DJ (2007) Role of polysaccharides in Pseudomonas aeruginosa biofilm development. Curr Opin Microbiol 10 (6) 644–648. doi: 10.1016/j.mib.2007.09.010
- 4. Hentzer M, Teitzel GM, Balzer GJ, Heydorn A, Molin S, et al. (2001) Alginate overproduction affects Pseudomonas aeruginosa biofilm structure and function. J Bacteriol 183(18) 5395–5401. doi: 10.1128/JB.183.18.5395-5401.2001
- 5. Leid JG, Willson CJ, Shirtliff ME, Hassett DJ, Parsek MR, et al. (2005) The exopolysaccharide alginate protects Pseudomonas aeruginosa biofilm bacteria from IFN-gamma-mediated macrophage killing. J Immunol 175(11) 7512–7518.
- 6. Kharazmi A (1991) Mechanisms involved in the evasion of the host defence by Pseudomonas aeruginosa.. Immunol Lett 30 (2) 201–205. doi: 10.1016/0165-2478(91)90026-7
- 7. Costerton JW, Stewart PS, Greenberg EP (1999) Bacterial biofilms: A common cause of persistent infections. Science 284 (5418) 1318–1322. doi: 10.1126/science.284.5418.1318
- 8. Lattner D, Flemming HC, Mayer C (2003) 13C-NMR study of the interaction of bacterial alginate with bivalent cations. Int J Biol Macromol 33(1–3) 81–88. doi: 10.1016/S0141-8130(03)00070-9
- 9. Aslam SN, Newman MA, Erbs G, Morrissey KL, Chinchilla D, et al. (2008) Bacterial polysaccharides suppress induced innate immunity by calcium chelation. Curr Biol 18 (14) 1078–1083. doi: 10.1016/j.cub.2008.06.061
- 10. Mulcahy H, Charron-Mazenod L, Lewenza S (2008) Extracellular DNA chelates cations and induces antibiotic resistance in Pseudomonas aeruginosa biofilms. PLoS Pathog 4 (11) e1000213. doi: 10.1371/journal.ppat.1000213
- 11. Hauser AR (2009) The type III secretion system of Pseudomonas aeruginosa: Infection by injection. Nat Rev Microbiol 7 (9) 654–665. doi: 10.1038/nrmicro2199
- 12. Dacheux D, Attree I, Schneider C, Toussaint B (1999) Cell death of human polymorphonuclear neutrophils induced by a Pseudomonas aeruginosa cystic fibrosis isolate requires a functional type III secretion system. Infect Immun 67(11) 6164–6167.
- 13. Yahr TL, Wolfgang MC (2006) Transcriptional regulation of the Pseudomonas aeruginosa type III secretion system. Mol Microbiol 62 (3) 631–640. doi: 10.1111/j.1365-2958.2006.05412.x
- 14. Lee PC, Stopford CM, Svenson AG, Rietsch A (2010) Control of effector export by the Pseudomonas aeruginosa type III secretion proteins PcrG and PcrV. Mol Microbiol 75 (4) 924–941. doi: 10.1111/j.1365-2958.2009.07027.x
- 15. Frank DW (1997) The exoenzyme S regulon of Pseudomonas aeruginosa.. Mol Microbiol 26 (4) 621–629. doi: 10.1046/j.1365-2958.1997.6251991.x
- 16. Michiels T, Wattiau P, Brasseur R, Ruysschaert JM, Cornelis G (1990) Secretion of yop proteins by Yersiniae.. Infect Immun 58 (9) 2840–2849.
- 17. Jamison WP, Hackstadt T (2008) Induction of type III secretion by cell-free Chlamydia trachomatis elementary bodies. Microb Pathog 45 (5–6) 435–440. doi: 10.1016/j.micpath.2008.10.002
- 18. Kim CC, Falkow S (2004) Delineation of upstream signaling events in the Salmonella pathogenicity island 2 transcriptional activation pathway. J Bacteriol 186 (14) 4694–4704. doi: 10.1128/JB.186.14.4694-4704.2004
- 19. Wu W, Badrane H, Arora S, Baker HV, Jin S (2004) MucA-mediated coordination of type III secretion and alginate synthesis in Pseudomonas aeruginosa.. J Bacteriol 186 (22) 7575–7585. doi: 10.1128/JB.186.22.7575-7585.2004
- 20. Jones AK, Fulcher NB, Balzer GJ, Urbanowski ML, Pritchett CL, et al. (2010) Activation of the Pseudomonas aeruginosa AlgU regulon through mucA mutation inhibits cyclic AMP/Vfr signaling. J Bacteriol 192 (21) 5709–5717. doi: 10.1128/JB.00526-10
- 21. DeVries CA, Ohman DE (1994) Mucoid-to-nonmucoid conversion in alginate-producing Pseudomonas aeruginosa often results from spontaneous mutations in algT, encoding a putative alternate sigma factor, and shows evidence for autoregulation. J Bacteriol 176 (21) 6677–6687.
- 22. Cisz M, Lee PC, Rietsch A (2008) ExoS controls the cell contact-mediated switch to effector secretion in Pseudomonas aeruginosa.. J Bacteriol 190 (8) 2726–2738. doi: 10.1128/JB.01553-07
- 23. Akeda Y, Galan JE (2005) Chaperone release and unfolding of substrates in type III secretion. Nature 437 (7060) 911–915. doi: 10.1038/nature03992
- 24. Adams SR, Campbell RE, Gross LA, Martin BR, Walkup GK, et al. (2002) New biarsenical ligands and tetracysteine motifs for protein labeling in vitro and in vivo: Synthesis and biological applications. J Am Chem Soc 124 (21) 6063–6076. doi: 10.1021/ja017687n
- 25. Griffin BA, Adams SR, Jones J, Tsien RY (2000) Fluorescent labeling of recombinant proteins in living cells with FlAsH. Methods Enzymol 327: 565–578. doi: 10.1016/S0076-6879(00)27302-3
- 26. Griffin BA, Adams SR, Tsien RY (1998) Specific covalent labeling of recombinant protein molecules inside live cells. Science 281 (5374) 269–272. doi: 10.1126/science.281.5374.269
- 27. Urbanowski ML, Lykken GL, Yahr TL (2005) A secreted regulatory protein couples transcription to the secretory activity of the Pseudomonas aeruginosa type III secretion system. Proc Natl Acad Sci U S A 102 (28) 9930–9935. doi: 10.1073/pnas.0504405102
- 28. Mikkelsen H, Bond NJ, Skindersoe ME, Givskov M, Lilley KS, et al. (2009) Biofilms and type III secretion are not mutually exclusive in Pseudomonas aeruginosa.. Microbiology 155 (Pt 3) 687–698. doi: 10.1099/mic.0.025551-0
- 29. Manos J, Arthur J, Rose B, Bell S, Tingpej P, et al. (2009) Gene expression characteristics of a cystic fibrosis epidemic strain of Pseudomonas aeruginosa during biofilm and planktonic growth. FEMS Microbiol Lett 292 (1) 107–114. doi: 10.1111/j.1574-6968.2008.01472.x
- 30. Singh PK, Schaefer AL, Parsek MR, Moninger TO, Welsh MJ, et al. (2000) Quorum-sensing signals indicate that cystic fibrosis lungs are infected with bacterial biofilms. Nature 407 (6805) 762–764. doi: 10.1038/35037627
- 31. Epelman S, Neely GG, Ma LL, Gjomarkaj M, Pace E, et al. (2002) Distinct fates of monocytes and T cells directly activated by Pseudomonas aeruginosa exoenzyme S. J Leukoc Biol 71 (3) 458–468.
- 32. Bruno TF, Woods DE, Mody CH (2000) Exoenzyme S from Pseudomonas aeruginosa induces apoptosis in T lymphocytes. J Leukoc Biol 67 (6) 808–816.
- 33. Ruter C, Buss C, Scharnert J, Heusipp G, Schmidt MA (2010) A newly identified bacterial cell-penetrating peptide that reduces the transcription of pro-inflammatory cytokines. J Cell Sci 123 (Pt 13) 2190–2198. doi: 10.1242/jcs.063016
- 34. Akopyan K, Edgren T, Wang-Edgren H, Rosqvist R, Fahlgren A, et al. (2011) Translocation of surface-localized effectors in type III secretion. Proc Natl Acad Sci U S A 108 (4) 1639–44. doi: 10.1073/pnas.1013888108
- 35. Holloway BW (1955) Genetic recombination in Pseudomonas aeruginosa.. J Gen Microbiol 13 (3) 572–581. doi: 10.1099/00221287-13-3-572
- 36. Sibley CD, Duan K, Fischer C, Parkins MD, Storey DG, et al. (2008) Discerning the complexity of community interactions using a drosophila model of polymicrobial infections. PLoS Pathog 4 (10) e1000184. doi: 10.1371/journal.ppat.1000184
- 37. Rietsch A, Wolfgang MC, Mekalanos JJ (2004) Effect of metabolic imbalance on expression of type III secretion genes in Pseudomonas aeruginosa.. Infect Immun 72 (3) 1383–1390. doi: 10.1128/IAI.72.3.1383-1390.2004
- 38. Duan K, Dammel C, Stein J, Rabin H, Surette MG (2003) Modulation of Pseudomonas aeruginosa gene expression by host microflora through interspecies communication. Mol Microbiol 50 (5) 1477–1491. doi: 10.1046/j.1365-2958.2003.03803.x
- 39. Smolke CD, Carrier TA, Keasling JD (2000) Coordinated, differential expression of two genes through directed mRNA cleavage and stabilization by secondary structures. Appl Environ Microbiol 66 (12) 5399–5405. doi: 10.1128/AEM.66.12.5399-5405.2000
- 40. Becher A, Schweizer HP (2000) Integration-proficient Pseudomonas aeruginosa vectors for isolation of single-copy chromosomal lacZ and lux gene fusions. BioTechniques 29 (5) 948–50, 952.
- 41. Choi KH, Gaynor JB, White KG, Lopez C, Bosio CM, et al. (2005) A Tn7-based broad-range bacterial cloning and expression system. Nat Methods 2 (6)443–448. doi: 10.1038/nmeth765
- 42. Klausen M, Heydorn A, Ragas P, Lambertsen L, Aaes-Jorgensen A, et al. (2003) Biofilm formation by Pseudomonas aeruginosa wild type, flagella and type IV pili mutants. Mol Microbiol 48 (6) 1511–1524. doi: 10.1046/j.1365-2958.2003.03525.x
- 43. Yang L, Nilsson M, Gjermansen M, Givskov M, Tolker-Nielsen T (2009) Pyoverdine and PQS mediated subpopulation interactions involved in Pseudomonas aeruginosa biofilm formation. Mol Microbiol 74 (6) 1380–1392. doi: 10.1111/j.1365-2958.2009.06934.x
- 44. Hoang TT, Kutchma AJ, Becher A, Schweizer HP (2000) Integration-proficient plasmids for Pseudomonas aeruginosa: Site-specific integration and use for engineering of reporter and expression strains. Plasmid 43 (1) 59–72. doi: 10.1006/plas.1999.1441
- 45. Simpson N, Audry L, Enninga J (2010) Tracking the secretion of fluorescently labeled type III effectors from single bacteria in real time. Methods Mol Biol 619: 241–256. doi: 10.1007/978-1-60327-412-8_14