Abstract
Pseudomonas aeruginosa is a ubiquitous environmental organism and an opportunistic pathogen that causes chronic lung infections in the airways of cystic fibrosis (CF) patients as well as other immune-compromised individuals. During infection, P. aeruginosa enters the terminal bronchioles and alveoli and comes into contact with alveolar lining fluid (ALF), which contains homeostatic and antimicrobial hydrolytic activities, termed hydrolases. These hydrolases comprise an array of lipases, glycosidases, and proteases and thus, they have the potential to modify lipids, carbohydrates and proteins on the surface of invading microbes. Here we show that hydrolase levels between human ALF from healthy and CF patients differ. CF-ALF influences the P. aeruginosa cell wall by reducing the content of one of its major polysaccharides, Psl. This CF-ALF induced Psl reduction does not alter initial bacterial attachment to surfaces but reduces biofilm formation. Importantly, exposure of P. aeruginosa to CF-ALF drives the activation of neutrophils and triggers their oxidative response; thus, defining human CF-ALF as a new innate defense mechanism to control P. aeruginosa infection, but at the same time potentially adding to the chronic inflammatory state of the lung in CF patients.
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Introduction
Pseudomonas aeruginosa is ubiquitous and especially common in humid environments and in the endogenous flora of hospitalized individuals1, 2. P. aeruginosa causes devastating infections in individuals with the genetic disease cystic fibrosis (CF) resulting in significant morbidity and mortality3, 4. A critical aspect of this infection involves the formation of microbial communities called biofilms5. P. aeruginosa biofilm growth within the lungs of individuals with CF complicates this disease by adding to the chronic inflammatory state of the lung. In contrast to planktonic cells, bacterial biofilms are characterized by their antimicrobial recalcitrance as well as by conferring resistance against the host immune response.
P. aeruginosa synthesizes special cell wall properties that allow the formations of biofilms, which can be visualized in individuals with CF6, 7. P. aeruginosa biofilms are characterized by the presence of an extracellular matrix8,9,10 containing polysaccharides, proteins, and extracellular DNA. These polysaccharides are important in biofilm initiation, development and maintenance11. P. aeruginosa produces three major polysaccharides: alginate, Pel, and Psl. P. aeruginosa variants expressing alginate are mucoid12, which is a hallmark of an established, biofilm-mode of infection. Non-mucoid variants of P. aeruginosa may contain two additional polysaccharides, Psl and Pel13. Pel is critical to biofilm architecture by maintaining interactions among cells14. Psl is instrumental in biofilm initiation, developing the structure of the biofilm and participating in the evasion of the innate immune response by blocking complement deposition and reducing the neutrophil oxidative response15. The two most common P. aeruginosa non-mucoid laboratory strains studied are PAO1 and PA114. PAO1 expresses Psl on its cell surface, along with minimal amounts of Pel, while strains such as PA14 express Pel but are devoid of Psl14, 16,17,18.
In individuals with CF, P. aeruginosa establishes chronic infections throughout different regions of the lung, i.e. upper, middle and lower lung regions19. Additionally, P. aeruginosa isolates differ phenotypically and evolve independently within the CF lung based on their regional location19. This suggests that regional environmental pressures, such as the alveolar mucosa surrounding the alveolar space of the lungs9, 20 may impact P. aeruginosa in individuals with CF. The alveolar mucosa is obtained by bronchoalveolar lavage upon deposition of the bronchoscope close to the entry of the bronchi, allowing for washing of the bronchioles and alveoli. Alveoli contain the majority of the washed surface area [75 (116,250 sq. inches) to 100 (155,000 sq. inches square) meters squared]21; therefore, the recovered fluid (alveolar mucosa) contains mainly alveolar components22. Alveolar mucosa can be separated into two distinct components, the alveolar lining fluid or ALF (hypophase) and the surfactant (lipidic phase)22. Surfactant and ALF are produced and secreted by type II alveolar epithelial cells22, 23. ALF contains numerous hydrolytic activities (called hydrolases), which play a regulatory role in antimicrobial pathways and maintenance of alveolar homeostasis24. These hydrolases are hypothesized to alter key properties of microbial cell surfaces and modify specific host-pathogen interactions25. Our studies with Mycobacterium tuberculosis (M.tb) demonstrate that these hydrolases modify the M.tb cell wall properties significantly reducing the surface exposure of two of the major cell wall factors involved in M.tb intracellular survival, mannose-capped lipoarabinomannan and trehalose dimycolate26. M.tb exposure to human ALF also altered its interaction with and infection outcome in host phagocytes26,27,28,29.
The role of ALF hydrolases play in acute and chronic CF airway infection and inflammation is poorly understood. We hypothesize that upon microbial deposition in the alveolar space, ALF hydrolases have the potential to remodel the P. aeruginosa cell envelope prior to its interaction with host alveolar compartment cells. Our results show that the most bioactive CF-ALF hydrolases are acid phosphatase and α-mannosidase. These hydrolases can alter P. aeruginosa cell wall properties. We observed that these cell wall alterations are predominant in P. aeruginosa strains expressing Psl exopolysaccharide on their cell surface. In addition to its role in biofilms30, planktonic P. aeruginosa also produces Psl which promotes surface attachment by acting as ‘molecular glue’31. After this event, individual surface-attached bacteria self-organize into microcolonies which is the first step in communal biofilm organization (the mechanism behind this process is described elsewhere)32. Thus, we further determined that CF-ALF hydrolases alter the surface expression of Psl in planktonic P. aeruginosa and diminish biofilm formation capability. Importantly, P. aeruginosa exposure to CF-ALF also reduces the ability of P. aeruginosa to be opsonized, as well as alters the neutrophils immune response by increasing their activation status and oxidative response, which could contribute to the successful establishment of the infection by inducing tissue damage. Here we define ALF hydrolases in individuals with CF that may influence the successful establishment of the P. aeruginosa infection.
Results
Enzymatic activities of hydrolases present in human ALF from CF patients
To determine which hydrolases with the potential to alter the P. aeruginosa cell envelope are present in the human alveolar space, we obtained ALF in 0.9% NaCl from healthy donors (n = 14) and CF individuals (n = 10) at their in vivo relevant concentrations of 1.0–1.5 mg/phospholipids as determined by a phosphate assay23, 33 as we previously described26. A colorimetric assay based on the cleavage of p-nitrophenol from a specific substrate was performed to measure hydrolase activities that could alter the P. aeruginosa cell wall26. The activities of 17 hydrolases from ALF are summarized in Fig. 1. Our results (normalized to negative controls) show evidence of hydrolase activities present in human ALF. Specifically, a significant increase of the enzymatic activities of acid phosphatase, α-mannosidase, α- and β-galactosidase, α-glucosidase, phospholipase C, and fatty acid esterase-I and -II was observed in ALF from CF individuals (CF-ALF), when compared to ALF from healthy donors (H-ALF). Compared with H-ALF, there was a decrease, although not statistically significant, of α-fucosidase, arylsulfatase, and both alkaline phosphatase and alkaline phosphodiesterase in the CF-ALF.
Effect of hydrolase activities derived from CF-ALF on live P. aeruginosa
We reasoned that upon deposition into the alveolar space, P. aeruginosa will be exposed to the basal levels of these hydrolytic enzymes, and thus, potentially these could alter the P. aeruginosa cell wall prior encountering host alveolar compartment cells. To assess if hydrolases in CF-ALF were capable of modifying the P. aeruginosa cell envelope in vivo, bacteria were harvested and exposed to CF-ALF normalized at physiological concentration in vivo [1 mg of phospholipid/ml]26 from 3 different donors, commercial acid phosphatase and α-mannosidase (at the levels determined in Fig. 1), or 0.9% NaCl as control.
Since the exopolysaccharide Psl is one of the major exopolysaccharide on the cell surface of non-mucoid P. aeruginosa 13, we focused our attention on assessing if hydrolases present in CF-ALF impact its levels. Dot blot of the surface extracted Psl in Fig. 2a followed by densitometry analysis indicates that P. aeruginosa exposure to CF-ALF significantly reduces the amount of bacterial surface associated Psl by ∼82.0%; in contrast, exposure to H-ALF reduced the Psl on the P. aeruginosa surface by only 22.5%. ELISA further confirmed these results, where we observed a similar trend, a 71.2% % cell surface reduction of Psl after P. aeruginosa exposure to CF-ALF (Fig. 2b) and only 10.9% reduction when exposed to H-ALF. This reduction was also observed in bacteria exposed to α–mannosidase (90.7% by densitometry and 83% by ELISA) but not when exposed to acid phosphatase (1 and 4% by ELISA and densitometry, respectively), indicating that the significant high levels of α–mannosidase observed in CF-ALF may directly contribute to the loss of Psl immunoreactive motifs observed on the bacterial cell surface.
The Psl structure was identified as repeating units of a neutral, branched pentasaccharide consisting of D-glucose (Glc), D-mannose (Man) and L-rhamnose (Rha) monosaccharides34. The biochemical alteration of the P. aeruginosa cell wall and effects on Psl were thus further corroborated by our sugar analysis on whole bacteria exposed to CF-ALF, demonstrating a reduction in the overall content of Rha and Man in CF-ALF exposed bacteria compared to our control 0.9% NaCl-exposed bacteria, as well as when compared to bacteria exposed to H-ALF (Fig. 2c). Unexpectedly, the overall cell wall content of Glc remained unaffected. Importantly, these differences in total carbohydrate content were only observed in CF-ALF exposed P. aeruginosa, as bacteria exposed to H-ALF did not have alterations in their overall cell wall sugar content when compared to control (0.9% NaCl-exposed bacteria) (Fig. 2c).
As P. aeruginosa exposure to CF-ALF results in bacterial cell wall alterations, we further assessed if P. aeruginosa exposure to CF-ALF impaired bacterial growth. Results in Fig. 2d indicate that CF-ALF exposed P. aeruginosa grew at similar rate to our control (0.9% NaCl exposed) bacteria. These results indicate that P. aeruginosa exposure to CF-ALF does not kill P. aeruginosa and does not significantly impair growth.
Effects of CF-ALF on P. aeruginosa adhesion and biofilm formation
Our above results indicate that exposure of P. aeruginosa to CF-ALF has two consequences: modifications on the P. aeruginosa cell wall surface and release of cell wall fragments into the milieu. We next determined if exposure to CF-ALF alters the capacity of P. aeruginosa to attach to surfaces, and thus, establish a biofilm. In this assay we used P. aeruginosa PAO1, characterized for having abundant Psl on its cell surface, and as a control P. aeruginosa WFPA800, which lacks Psl. We assessed both, if the induced cell wall modifications alone (washed, white bars) or together with the released material (unwashed, black bars) affected P. aeruginosa capacity to attach (2 hours assay) or form a biofilm (overnight assay).
Results in Fig. 2e indicate that PAO1 strain similarly attach to plastic surfaces independently of both, being exposed to 0.9% NaCl, H-ALF or CF-ALF and the presence of the released cell wall material (white vs. black bars). Interestingly, we found that under the unwashed conditions (black bars); H-ALF exposed P. aeruginosa was more efficient in forming biofilms. However, under the washed conditions (white bars), H-ALF and CF-ALF exposed P. aeruginosa had reduced ability to form biofilms compared to 0.9% NaCl exposed bacteria. Under all conditions studied, our WFPA800 control strain lacking Psl presented deficient attachment and biofilm formation (data not shown).
Impacts of CF-ALF on P. aeruginosa opsonization and subsequent interactions with neutrophils
To determine if P. aeruginosa exposure to CF-ALF affects the innate immune response, we first determined if exposure to H-ALF or CF-ALF affects opsonization of P. aeruginosa. This was evaluated by directly measuring serum complement component 3 (C3) deposition on the bacterial surface by flow cytometry. Compared with exposure to H-ALF, P. aeruginosa exposure to CF-ALF resulted in a reduction in serum C3 bacterial opsonization (observed in 4 out of 5 CF-ALF samples studied) (Fig. 3a). Next we determined if H-ALF or CF-ALF altered the activation status of resting neutrophils. Our results indicate that P. aeruginosa exposed to CF-ALF significantly increased the activation status of neutrophils (increased expression of CD63 on the surface of resting neutrophils indicative of primary degranulation and neutrophil activation) when compared to P. aeruginosa exposed to H-ALF (Fig. 3b). However, significant changes of CD66b (marker of secondary degranulation) or CD11b (CR3) were not observed (data not shown). We further assessed the oxidative response of neutrophils infected with non-mucoid (PAO1 strain) and mucoid (PDO300 strain) P. aeruginosa variants pre-exposed to CF-ALF and H-ALF. Results in Fig. 3c indicate that P. aeruginosa exposed to CF-ALF induces a significantly stronger production and release of neutrophil’s radical oxygen species (ROS). This phenotype was further corroborated with CF-ALF from multiple donors (Fig. 3d). Interestingly, this phenotype was only observed in the non-mucoid P. aeruginosa variant (PAO1) known to express Psl on its cell wall surface, as CF-ALF exposed mucoid P. aeruginosa variant expressing alginate (PDO300) did not further increase the release of ROS by neutrophils (Fig. 3e).
Discussion
P. aeruginosa is the causative agent for one of the most prevalent microbial infections in CF patients3, 4. Upon deposition in the lung, P. aeruginosa isolates are capable of establishing infection in different regions of the lung19. Differential evolution and functionality of these isolates suggest that the existing multiple microenvironments in the lung may impact P. aeruginosa infection. In this regard, P. aeruginosa deposited into the alveolar space is in close contact with ALF and its hydrolytic enzymes. The main function of ALF hydrolases is to assist in the recycling and degradation of the alveolar mucosa35. These ALF hydrolases may be altered due to the inflammation caused by CF and/or by microbial infection36. Our current results suggest that the lung airways in CF patients may harbor hydrolases that benefit a chronic P. aeruginosa infection, directing the robust neutrophil-dominant airway inflammation37.
Based on the biochemical composition of the P. aeruginosa cell wall, we assessed the bioactivity of a series of hydrolases present in the lung. Our results indicate a significant increase of acid phosphatase (∼4.6-fold increase) in the lung milieu of CF patients. This high level of acid phosphatase has been also measured in patients with pulmonary sarcoidosis and cryptogenic fibrosing alveolitis (also known as idiopathic pulmonary fibrosis)38. The role of acid phosphatase in microbial infections is not clear, although it is likely that this lipid phosphohydrolase has critical roles in lung morphogenesis and in acute lung injury and repair39. The presence of acid phosphatase has been previously described in mammalian ALF40, where this enzyme contains characteristics of the microsomal enzyme, and it is quite specific for the hydrolysis of phosphatidic acid and 1-acyl-2-lysophosphatidic acid. An increase of acid phosphatase in CF-ALF may correspond to the homeostatic necessity to quickly degrade accumulation of lysophospholipids, which are related to surfactant dysfunction and lung inflammation41. The second most bioactive enzymatic activity found in CF-ALF is α-mannosidase. Although the exact function of this hydrolase in the alveolar mucosa is not clear, studies showed that the lung α-mannosidase originates in epithelial cell type II lamellar bodies and is a lysosomal-type hydrolase with optimum activity at acidic pH42. In this regard, CF-ALF is acidic43. What implication this may have in P. aeruginosa infection is not clear, however, ALF with acidic pH also has impaired antibacterial killing capacity43.
Importantly, our results indicate that CF-ALF also contains significant amounts of phospholipase C and fatty acid esterases. Dipalmitoylphosphatidylcholine (DPPC), the major phospholipid of human ALF surfactant, is degraded by P. aeruginosa phospholipase C44 and extracellular lipases and fatty acid esterases to produce glycerol and free fatty acids. DPPC can be used by P. aeruginosa as a sole source of carbon, nitrogen, and phosphorous for growth44, 45, and P. aeruginosa growth in the presence of DPPC leads to the emergence of mucoid variants with elevated levels of alginate46. Thus, the increase of fatty acid esterases in CF-ALF may facilitate DPPC degradation for use as a P. aeruginosa nutrient source within the CF lung. Furthermore, DPPC-derived glycerol (by the action of CF-ALF fatty acid esterases) could be a particular good source of carbon for alginate biosynthesis within the CF lung, as it has been shown that P. aeruginosa growth in medium containing high-concentrations of glycerol promotes the appearance of mucoid variants from non-mucoid bacteria45.
The effects of CF-ALF on the P. aeruginosa cell wall were obvious in the PAO1 strain, which is well known to expose Psl on its cell surface. Our results indicate that modifications of Psl or potential release of Psl into the milieu may occur after P. aeruginosa is exposed to CF-ALF, and at lesser extend to H-ALF. Based on the Psl structure and the hydrolases detected in CF-ALF, a decrease in mannose and rhamnose was observed, but not in glucose. As Psl is formed by these three monosaccharides, a plausible explanation for this observation is that the majority of the enzymatic activity detected in ALF that could alter Psl have exoglycosidase activity, i.e. α-mannosidase, α-rhamnosidase, α-glucosidase and β-glucosidase; which imply the release of terminal residues or short oligosaccharides from Psl. Psl is formed by a penta-saccharide repeating unit which consist of a lineal core β-Glcp(1-3)-β-Manp(1-3)-β-Manp-(1-3)-α-Rhap with a single terminal α-Manp branching from the C2 position of the first 3-β-Manp 34. Thus, the high content of α-mannosidase present in CF-ALF could remove Psl single branched terminal 2-α-Manp residues (highly present in Psl). Additionally, the levels of α-rhamnosidase detected in CF-ALF could also remove the Psl terminal 3-α-Rhap, as well as, remove rhamnose from the P. aeruginosa LPS47 and rhamnolipid48. However, our sugar analysis also showed no variation in glucose residues, indicating that the β-glucosidase present in H-ALF and CF-ALF has limited or no access to the Psl terminal 1-β-Glcp. Endoglycanase activities that could internally cleave Psl and other P. aeruginosa polysaccharides such as alginate, Pel, rhamnolipid and two types of lipopolysaccharide (LPS), were not detected in ALF (data not shown). To which extent these P. aeruginosa components are altered by P. aeruginosa exposed to CF-ALF or H-ALF, and its implications in host cell recognition is currently being studied in the lab.
Unexpectedly, changes on Psl on the ALF exposed P. aeruginosa did not translate in differences in PAO1 adhesion to cell surfaces but influenced the capacity to form biofilms (observed for both cases, H-ALF and CF-ALF exposure). This result is consistent with the literature, which shows lack of Psl (using a P. aeruginosa mutant completely devoid of Psl) is directly related to decrease in biofilm formation49,50,51. The fact that biofilm formation is reduced but not completely eliminated could be a consequence that CF-ALF exposure only partially reduces Psl (by ∼82%) on P. aeruginosa; thus, the remaining Psl present after exposure to CF-ALF (∼18%) might be sufficient for P. aeruginosa to maintain its adhesion/biofilm properties.
Neutrophil activation and subsequent production of ROS were also enhanced by CF-ALF induced modifications on the P. aeruginosa cell envelope, which may contribute to the pathology of CF by impairing ALF clearance, interfering with innate immune functions, and overall driving neutrophilic inflammation. Because we found that so many hydrolases are upregulated in CF-ALF, the excessive neutrophil oxidative response to P. aeruginosa exposed to CF-ALF could be due to several factors, including the observed modifications on Psl cell surface expression, P. aeruginosa cell surface opsonization by CF-ALF components, and exposure of other components of the P. aeruginosa cell wall due to the actions of CF-ALF hydrolases. In this study we focused on Psl, as this, together with Pel and LPS, are major cell wall components of P. aeruginosa, and Psl is critical for biofilm formation and pathogenesis. In this context, the link between CF-ALF affecting the overall surface exposure of Psl and the increased production of ROS observed is in accordance with our previous studies showing that the presence of Psl in non-mucoid P. aeruginosa reduces the neutrophil production of ROS15. The complete absence of Psl in P. aeruginosa enhances serum complement opsonization of bacteria, thus favoring P. aeruginosa killing15. But this is not what we observed after P. aeruginosa is exposed to CF-ALF, where partial reduction of Psl from the cell surface resulted in a decrease of C3 opsonization but still triggered neutrophil ROS production. Therefore, this scenario defines CF-ALF as acting to eliminate Psl from the P. aeruginosa cell surface driving the immune response against the bacterium, but at the same time, originating an increase in ROS production that at the end may be detrimental for both, P. aeruginosa and the host due to tissue damage.
In summary, this study demonstrates that using a colorimetric approach we can identify the basal activity of several hydrolases in human CF-ALF, where we identified higher activity levels of several ALF hydrolases in CF patients compared to healthy individuals. Hydrolases with the most abundant catalytic activity in these samples were acid phosphatase, α-mannosidase, and some glycosidases, phospholipase C, and fatty acid esterases. These will be the focus of future studies to determine how these hydrolases may impact the outcome of microbial infections observed in CF patients. In the case of P. aeruginosa, these CF-ALF hydrolases reduce the cell surface exposure of Psl, which results in increase in ROS production by neutrophils upon contact with CF-ALF exposed P. aeruginosa. The dynamics of the lung environment in chronic diseases may dictate the establishment of a given infection in a determined time, where the P. aeruginosa encounter with ALF and the subsequent biological consequences in the establishment of the infections may provide answers to targeting specific ALF hydrolases to improve the quality of life for CF patients colonized with P. aeruginosa.
Methods
Patient Population
Bronchoalveolar lavage fluid (BALF) from CF individuals (n = 10) was obtained following the approved Nationwide Children’s Hospital (NCH) IRB for human subjects. There were 50:50 male/female with mean age of 17 years (range 7–30). The BALF was neutrophilic in nature with mean cell differential of 77% neutrophils, 18% macrophages, 3% lymphocytes, and 2% eosinophils. Control BALF from healthy human donors (n = 14, 50:50 male/female with mean age of 23, range 18–30 years of age) was performed as we previously described under a The Ohio State University (OSU) approved protocol for human subjects. All experiments were performed in accordance with the relevant guidelines and regulations. All BALF donors agreed to participate in this study and publication of this study by informed written consent.
P. aeruginosa strains and growth conditions
P. aeruginosa strains were grown on Luria-Bertani (LBNS; tryptone 10 g per liter and yeast extract 5 g per liter without NaCl) at 37 °C for broth cultures. Solid medium (LANS) was prepared with the addition of 1.5% agar and also grown at 37 °C. The strains used in this study were P. aeruginosa PAO1, WFPA800 and PDO30052,53,54.
Hydrolase activity determination in alveolar lining fluid (ALF)
ALF was obtained as we previously described26. Briefly, BALF was obtained by bronchoalveolar lavage from healthy and CF donors in 80 ml sterile 0.9% NaCl, 0.22-µM filtered to remove cells, depleted of lipids, concentrated 20-fold to achieve the ALF volume present within the human lungs23, and frozen at −80 °C until use for subsequent studies. A total of 14 different healthy ALF donors and 10 different CF ALF donors were used in these studies. A colorimetric method based on the cleavage of p-nitrophenol from a specific substrate upon enzymatic activity was used to measure the hydrolase activities present in the samples as we previously described26.
Measuring growth rates with Biolog™
Biolog growth medium was prepared using LBNS and 1.2% of Biolog Dye A (Biolog, Hayward, CA). Fresh cultures of P. aeruginosa were grown to an O.D. A600 of 0.3. Up to 150 μl of this culture was combined with 750 μl of Biolog growth medium per sample and 100 μl, in triplicate, was placed into the Biolog plate wells (catalog #30311). The plate was incubated in the OmniLog® PM System (S/N #93171) at 37 °C for 24 hours using OmniLog® software analysis (vr. 1.2). The OmniLog® PM System generates a kinetic response curve for the growth or inhibition assays by monitoring and detecting changes in cellular respiration through measurement of spectroscopic change resulting from the reduction of the Biolog indicator dye. The changes in respiration reflected in “Biolog Units” correlate to growth of the particular organism. After 24 hours, data were compiled and exported from the OmniLog software using Microsoft Excel and graphically displayed using GraphPad Prism (vr. 5.03). In all cases, the mean signal values are presented.
Polysaccharide immunoblotting and ELISA
Crude polysaccharide extracts were obtained by suspending either saline-, hydrolase- or CF-ALF-exposed bacteria in 250 μl of 500 mM EDTA and boiling for 5 min at 100 °C55. The suspension was then centrifuged at 20,800- × g for 3 min. Supernatants were then transferred to new tubes and treated with proteinase K stock solution (Qiagen, Valencia, CA) at a final concentration of 0.5 mg/ml for 60 min at 60 °C. The proteinase K was inactivated by heating at 80 °C for 30 min. Samples were stored at 4 °C prior to immunoblotting and ELISA.
For immunoblotting, 5 μl of crude polysaccharide extract was spotted onto Amersham Hybond-ECL nitrocellulose membrane (GE Healthcare Bio-Sciences, Pittsburgh, PA) and allowed to air dry. The membrane was blocked with 5% non-fat dry milk in TBST (20 mM Tris, 137 mM NaCl, 0.1% Tween 20, pH 7.6) for one hour at room temperature with agitation followed by probing with α-Psl polyclonal antibody (diluted 1:25,000 in TBST) as previously describe34. For quantification of the Psl in the polysaccharide extracts, ELISA was performed as previously described34 using a α-Psl polyclonal antibody (diluted 1:25,000 in PBS).
Monosaccharide Analysis
Samples were hydrolyzed with 2 M trifluoroacetic acid and converted to alditol acetates by reducing with NaBD4 in NH4OH followed by acetylation using acetic anhydride56. Alditols were analyzed on a Thermo Scientific gas chromatography-mass spectrometer model DSQ-II (Bruker-Daltonics, Billerica, MA), using scyllo-inositol as an internal standard, as previously described26.
Microtiter dish attachment assay
Attachment of P. aeruginosa to an abiotic surface was performed as previously described (39). Briefly, bacteria were grown to mid-log (O.D. A600 of 0.5) and treated with CF ALF for one hour at 37 °C. After treatment, the bacteria were pelleted by centrifugation and washed three times in 0.9% NaCl. After the final wash the bacteria were suspend in LBNS and 100 μL of the pellet was added to wells of a 96-well PVC microtiter plate (Costar Inc., Corning, NY) for 30 minutes at room temperature. Non-adherent bacteria were removed by washing thoroughly in water. Adherent bacteria were stained with 125 μL of 0.1% crystal violet per well and incubated at room temperature for fifteen minutes. The plate was washed in water and the bound crystal violet was solubilized in 150 μL of 95% ethanol for fifteen minutes at room temperature. The solubilized stain was transferred to a 96-well microtiter plate and the absorbance measured at O.D. A540.
P. aeruginosa C3 opsonization
C3 deposition in P. aeruginosa was determined as previously described15. Briefly, P. aeruginosa (1.7 × 108 bacteria per mL) was opsonized with 20% pooled human serum at 37 °C for 15 minutes with gentle rocking. Bacteria were centrifuged at 21,000- × g for 5 minutes at 4 °C, washed twice with cold PBS on ice, and fixed with cold 2% paraformaldehyde for 10 minutes on ice. Bacteria were then stained with a mouse anti-human activated C3 antibody (Santa Cruz Biotechnology Inc., #sc47687, Dallas, Texas) or a PE-conjugated mouse IgG1 k isotype control isotype (BD, #555749, San Jose, CA) on ice in the dark for 20 minutes. C3-stained cells were subsequently stained with a PE-conjugated goat anti-mouse antibody (Abcam, #ab7002, Cambridge, MA) on ice in the dark for 20 minutes. Samples were analyzed using BD FACS CANTO II flow cytometer (BD Biosciences, San Jose, CA) by reading >10,000 events per sample, and data analyzed using FlowJo Vr. 9.7.6 Software.
Neutrophil isolation, activation status and oxidative burst studies
Human neutrophils were obtained from healthy adult donors as we previously described27 using an approved IRB protocol (2009H0314) at The Ohio State University. Surface expression of activation and degranulation markers on human neutrophils was assessed by flow cytometry as we previously described27. Briefly, neutrophils were infected with healthy ALF-exposed P. aeruginosa or CF-ALF-exposed P. aeruginosa at 37 °C, 5% CO2 for 30 min. After infection, neutrophils were stained with antibodies specific for cell-surface markers (BD PE-mouse anti-human CD63-Ab, BD PerCP/Cy5.5-mouse anti-human CD66b-Ab, and BD FITC-mouse anti-human CD11b-Ab; BD Biosciences, Franklin Lakes, NJ) for 30 min on ice in dark conditions. Neutrophil surface expression of CD63 and CD66b, markers of primary and secondary granules, respectively, and CD11b expression were assessed by flow cytometry (≥10,000 events). All appropriate isotype controls were included (BD PE-mouse IgG1 ĸ isotype control-Ab, BD PerCP/Cy5.5-mouse IgM ĸ isotype control-Ab and BD FITC-mouse IgG1 ĸ isotype control-Ab). Samples were read on a BD FACS CANTO II flow cytometer (BD Biosciences, San Jose, CA) and data were analyzed using BD FACS Diva and FlowJo vr. 9.7.6 Software.
The luminol chemiluminescence assay was used to detect intracellular and extracellular reactive oxygen species (total ROS) generated by neutrophils upon interaction with P. aeruginosa 57. Actively growing P. aeruginosa (non-mucoid P. aeruginosa PAO1 and mucoid P. aeruginosa PDO300) were diluted to a final concentration of 3 × 107/ml, washed three times with sterile HBSS and exposed with either sterile 0.9% NaCl, CF-ALF or H-ALF for 1 h at 37 °C, 5% CO2. Bacteria were then washed three times and further opsonized with 20% pooled fresh normal human serum for 30 min at 37 °C. Following opsonization, bacteria were washed and used for infections. ROS production was determined via a luminescent assay. Phorphol 12-myristate 13-acetate (PMA) was used at 10 ng/ml as a positive control for the generation of ROS, while non-opsonized P. aeruginosa was used as a negative control. Neutrophils were diluted to a final concentration of 4 × 106/ml in HBSS containing 50 mM luminol and seeded onto a 96-well microtiter plate. The prepared bacteria were added to the neutrophils at an MOI of 50:1. ROS generation was measured at regular intervals over one hour by luminescence using a SpectraMax M5 plate reader (Molecular Devices LLC, Sunnyvale, CA) Relative light units (RLU) were plotted as a function of time to evaluate chemiluminescence (CL) rate58.
Statistics
Statistical analyses were performed using GraphPad 4.0/5.0 Prism software to determine the statistical significance between the means for 2 experimental groups using an unpaired, 2-tailed Student’s t test. Differences were considered statistically significant at a *,§ p < 0.05; **,§§ p < 0.005; ***,§§§ p < 0.0005.
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Acknowledgements
We thank the Campus Chemical Instrument Center at OSU for their technical support. This work was supported by the National Institutes of Health/National Institute of Allergy and Infectious Diseases (NIH/NIAID) AI097511 to D.J.W. and AI093570 to J.B.T. J.M.S. was sponsored by NIH/NIAID award #1-T32-AI-112542, a NRSA training grant administered by the Center for Microbial Interface Biology (CMIB) at The Ohio State University. Inquiries after August 2017 for Jordi B. Torrelles should be sent to the e-mail address jtorrell@txbiomed.org.
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P.J.H., J.M.S., J.A., S.E.K., M.D.W., D.J.W., J.B.T. had substantial contributions to the conception or design of the work; or the acquisition, analysis, and/or interpretation of data for the studies. P.J.H., J.M.S., D.J.W. and J.B.T. drafted the work and/or revised it critically for important intellectual content.
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Hill, P.J., Scordo, J.M., Arcos, J. et al. Modifications of Pseudomonas aeruginosa cell envelope in the cystic fibrosis airway alters interactions with immune cells. Sci Rep 7, 4761 (2017). https://doi.org/10.1038/s41598-017-05253-9
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DOI: https://doi.org/10.1038/s41598-017-05253-9
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