Figures
Abstract
The opportunistic pathogen Pseudomonas aeruginosa is able to thrive in diverse ecological niches and to cause serious human infection. P. aeruginosa environmental strains are producing various virulence factors that are required for establishing acute infections in several host organisms; however, the P. aeruginosa phenotypic variants favour long-term persistence in the cystic fibrosis (CF) airways. Whether P. aeruginosa strains, which have adapted to the CF-niche, have lost their competitive fitness in the other environment remains to be investigated. In this paper, three P. aeruginosa clonal lineages, including early strains isolated at the onset of infection, and late strains, isolated after several years of chronic lung infection from patients with CF, were analysed in multi-host model systems of acute infection. P. aeruginosa early isolates caused lethality in the three non-mammalian hosts, namely Caenorhabditis elegans, Galleria mellonella, and Drosophila melanogaster, while late adapted clonal isolates were attenuated in acute virulence. When two different mouse genetic background strains, namely C57Bl/6NCrl and Balb/cAnNCrl, were used as acute infection models, early P. aeruginosa CF isolates were lethal, while late isolates exhibited reduced or abolished acute virulence. Severe histopathological lesions, including high leukocytes recruitment and bacterial load, were detected in the lungs of mice infected with P. aeruginosa CF early isolates, while late isolates were progressively cleared. In addition, systemic bacterial spread and invasion of epithelial cells, which were detected for P. aeruginosa CF early strains, were not observed with late strains. Our findings indicate that niche-specific selection in P. aeruginosa reduced its ability to cause acute infections across a broad range of hosts while maintaining the capacity for chronic infection in the CF host.
Citation: Lorè NI, Cigana C, De Fino I, Riva C, Juhas M, Schwager S, et al. (2012) Cystic Fibrosis-Niche Adaptation of Pseudomonas aeruginosa Reduces Virulence in Multiple Infection Hosts. PLoS ONE 7(4): e35648. https://doi.org/10.1371/journal.pone.0035648
Editor: Pierre Cornelis, Vrije Universiteit Brussel, Belgium
Received: December 13, 2011; Accepted: March 19, 2012; Published: April 25, 2012
Copyright: © 2012 Lorè 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: The study was supported by the European Commission (http://cordis.europa.eu/fp7/dc/index.cfm) (Grant NABATIVI, EU-FP7-HEALTH-2007-B, contract number 223670) and Italian Cystic Fibrosis Research Foundation (FFC#20/2011) (http://www.fibrosicisticaricerca.it/) with the contribution of the Delegazione FFC di Bergamo Villa d'Almè, Amici della Ricerca di Milano, Latteria Montello 70° compleanno nonno Armando. 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 declared that no competing interests exist.
Introduction
Pseudomonas aeruginosa is a common bacterium found in a wide range of environments; it infects nematodes, insects, plants, and ameba in the laboratory and probably encounters a similar range of potential hosts in the wild [1]. In humans, P. aeruginosa causes a wide range of infections, including deadly pneumonia when infecting immuno-compromised or cystic fibrosis (CF) patients. The clinical outcome of P. aeruginosa infection ranges from acute to chronic infections. Individuals in intensive care units can develop ventilator-associated pneumonia and/or sepsis as a result of P. aeruginosa infection. Patients with CF develop life-long chronic lung P. aeruginosa infection which leads to death.
Genomes of different P. aeruginosa isolates share a remarkable amount of sequence similarity when isolated from the environment or from different clinical origins [2], [3]. A considerable conservation of genes including nearly all known virulence factors, such as pyocyanin, a type III secretion system (T3SS), several proteases, lipases and phospholipases and rhamnolipids was observed in P. aeruginosa strains isolated from the environment, immuno-compromised patients and CF patients at the onset of infection [3]. Despite the overall genome similarity among diverse P. aeruginosa strains, point mutations accumulate in bacterial lineages persisting in CF airways. Mutations commonly acquired by P. aeruginosa strains during CF chronic infection are those in the regulators of alginate biosynthesis [4] and virulence genes involved in the LPS modification [5], motility [6], in the quorum-sensing regulation [7], [8], in biosynthesis of the T3SS [9] and multidrug-efflux pumps, and in mutator genes [10]. Changes in metabolic functions have also been described [11]. In addition, whole genome sequence analysis of P. aeruginosa longitudinal strains from the same CF patient revealed that a surprisingly large number of genes in the genome can be targets for mutation during adaptation to CF airways, although only a few of these genes were found to be affected in many of the late isolates [11]. Recent work demonstrated that the greatest contribution to the extremely high levels of genetic diversity is within an individual patient rather than between patients [12].
Pathogenicity of P. aeruginosa isolates from different habitats and clinical origin, including complex phenotypes from CF patients, can be strikingly different. Previous studies in the P. aeruginosa reference strains PA14 and PAO1, and additional strains from various sources, showed that the genes required for pathogenicity in one strain are neither required for nor predictive of virulence in other strains [2]. When comparing P. aeruginosa strains derived from the same type of infection, there was no consistent clustering with respect to their phenotype in C. elegans [2]. For example, urinary tract infection strains exhibited a wide range of virulent and avirulent phenotypes in acute infection models. In the same vein, both the most and the least virulent strains tested were isolates from CF infections. Taken together, these results suggest that virulence and in particular pathogenicity-related genes in different organisms are both multifactorial and combinatorial, and that the outcome of a specific host-pathogen interaction depends on the bacterial origin as well as on the host genetic background. Recent whole genome sequence analyses of P. aeruginosa strains isolated from CF patients described loss-of-function mutations in virulence genes, suggesting attenuation of virulence for CF-adapted strains [13]. In the case of CF infections, P. aeruginosa clonal populations remain isolated in a defined environment over a long period of time and normally do not spread to other patients. Whether P. aeruginosa phenotypes that have adapted to the CF-niches, have lost their competitive fitness in other environment is not known.
To expand our knowledge on P. aeruginosa virulence and how this bacterium interacts with its host, we tested the hypothesis that CF-niche adaptation and specialization reduces the bacterial pathogenic potential of the organism in acute infection models. We selected well characterized P. aeruginosa clonal lineages of strains isolated from three CF patients at the onset of infections and after several years of chronic colonization; the samples included late adapted strains carrying several phenotypic changes in virulence factor production, structural modification in the Pathogen-Associated Molecular Patterns (PAMPs) [14], [5], and patho-adaptive mutations within the genome temporally associated with CF lung infection [15]. These P. aeruginosa clonal lineages were tested in a multiple infection hosts, including Caenorhabditis elegans, Galleria mellonella, Drosophila melanogaster and mice with two different genetic backgrounds, C57bl/6NCrl and Balb/cAnNCrl, described previously as susceptible and resistant [16]. We showed that P. aeruginosa early strains were lethal in the multi-host models included in this study while late strains reduced or abolished acute virulence. Our findings suggest that the adaptation of different P. aeruginosa lineages within CF lungs selects populations with reduced pathogenic potential in acute infections which is maintained across a broad range of hosts.
Results
Pathogenic potential of P. aeruginosa sequential strains from CF patients in C. elegans, D. melanogaster and G. mellonella
P. aeruginosa longitudinal strains isolated from three CF patients at the onset of infection (early) and after several years of chronic colonization (late) and carrying several phenotypic differences (Figure 1 and Table S1) were tested for their virulence potential in three non-mammalian hosts, namely C. elegans, D. melanogaster and G. mellonella. In these experiments early P. aeruginosa strains, AA2, KK1, KK2 and MF1, and late strains, AA43, AA44, KK71, KK72 and MF51 were administered to non-mammalian hosts and mortality was monitored. P. aeruginosa early strain AA2 was significantly more lethal than the clonal late isolates AA43 and AA44 in C. elegans (AA2: 100% vs AA43: 21% and AA44: 41%, Mantel-Cox test: p<0.001) (Fig. 2A). Similar results were also obtained in D. melanogaster (AA2: 100% vs AA43: 82% and AA44: 97% p<0.001)(Fig. 2D). Although the late strains AA43 and AA44 were more pathogenic in this model in comparison to C. elegans, they killed the fruit flies later in comparison to the early strain AA2. Likewise, early P. aeruginosa isolates from patients KK and MF were significantly more lethal than their clonal late isolates in both models. However, lethality in C. elegans (KK1: 25% and KK2: 36% vs KK71: 11% and KK72: 7%, p<0.01; MF1: 69% vs MF51: 35%, p<0.001) (Fig. 2B, C) was generally less severe than in D. melanogaster (KK1: 100% and KK2: 100% vs KK71: 16% and KK72: 35%, p<0.01; MF1: 99% vs MF51: 11%, p<0.001) (Fig. 2E, F). We also evaluated lethality in a G. mellonella infection model. As in the previous models, the LD50 of the early isolate AA2 was found to be more than 20-folds reduced when compared to the clonal late isolates AA43 and AA44 (Table 1). Similar trends were also seen with the sets of early and late isolates (KK and MF isolates). The LD50 of the early isolates KK1 and KK2 were found to be more than 20-folds reduced when compared to the clonal late isolates KK71 and KK72. The early isolate MF1 showed a LD50 of 1500-folds reduced when compared to the clonal late isolate MF51, confirming the higher acute virulence of early strains.
Three clonal lineages (AA, KK and MF) of P. aeruginosa strains were isolated at the onset of chronic colonization (early: AA2, KK1, KK2, MF1) or several years after acquisition and before patient's death (late: AA43, AA44, KK71, KK72, MF51). Clonality of strains was assessed by Pulsed Field Gel Electrophoresis and was reported previously [4]. Multiple phenotypic traits changed during genetic adaptation to the CF lung and included [14]: (a) motility defect, (b) mucoid phenotype, (c) protease reduction, (d) siderophore reduction, (e) hemolysis reduction, (f) LasR phenotype, (g) growth rate reduction. In addition, lipopolysaccharide (LPS) lipid A (h) and peptidoglycan (PGN) muropeptides (i) were analysed exclusively in the lineage AA showing specific structural modifications temporally associated with CF lung infection as described previously [5]. Additional data were reported in the online data supplement (Table S1).
Pathogenicity of lineages of early and late P. aeruginosa isolates in C. elegans: AA, (A); KK, (B); MF, (C); Pathogenicity of different lineages of early and late P. aeruginosa isolates in D. melanogaster: AA lineage, (D); KK lineage, (E); MF lineage, (F). Three independent experiments were pooled. Statistical analysis was calculated for pair wise comparisons between early and late strains (** p<0.01, *** p<0.001, Mantel-Cox test).
Response of different C57Bl/6NCrl and Balb/cAnNCrl inbred mouse strains to infection with P. aeruginosa sequential strains
To test whether the differences in lethality between early and late clonal P. aeruginosa strains are maintained in the mammalian host, we analyzed the host response in murine models of acute pneumonia. Lethality and changes in body weight in C57Bl/6NCrl and Balb/cAnCrl inbred mouse strains were assessed. First, escalating doses ranging from 105 to 109 cfu of P. aeruginosa were applied to C57Bl/6NCrl mice to determine the relative range of susceptibility. As shown in Fig. 3 and Table S2, C57Bl/6NCrl died starting from 5×106 cfu/lung of early AA2 strain and 1×107 cfu/lung of early KK1 and KK2 strains, indicating differences in virulence between P. aeruginosa early strains of different lineages. When mice were inoculated at the same doses, late AA43, AA44, KK71 and KK72 strains were not lethal, indicating that their virulence was attenuated in comparison to the early strains (AA2 vs AA43 and AA44, p<0.001; KK1 and KK2 vs KK71 and KK72, Mantel-Cox, p<0.001) (Fig. 4A and B). In the AA lineage, all mice died at doses of 108 cfu/lung of AA43 and AA44 strains (Fig. 3A), while in the KK lineage doses of 109 cfu/lung of KK71 and 108 cfu/lung of KK72 were fully lethal (Fig. 3B). Differences between early and late strains were also observed in BALB/cAnNCrl mice (AA2 vs AA43 and AA44, p<0.05; KK1 and KK2 vs KK71 and KK72, p<0.01) (Fig. 4C and D), which showed similar susceptibility as C57Bl/6NCrl. Bacterial cells were recovered from blood and other organs of moribund mice indicating that death was caused by sepsis (data not shown).
C57Bl/6NCrl mice were infected with different doses of P. aeruginosa strains from AA (A) and KK (B) clonal lineages. Survival of infected mice was followed over a period of 4 days and is indicated as a cumulative percent. Higher doses of late P. aeruginosa strains (AA43, AA44, KK71, KK72) are required for mortality when compared to early strains (AA2, KK1 and KK2). Two to three independent experiments were pooled (nr of mice: 5–18 as detailed in table S2). Statistical analysis of pair wise comparisons for early and late strains are indicated *** p<0.001 (Mantel-Cox test).
C57Bl/6NCrl (A, B) and BALB/cAnNCrl (C, D) mice were infected with 5×106 cfu/lung of P. aeruginosa strains from AA (A, C) and 1×107 cfu/lung KK (B, D) clonal lineages. Survival of infected mice was followed over a period of 4 days. Early strains (AA2, KK1 and KK2) were lethal while late strains (AA43, AA44, KK71, KK72) were attenuated in acute virulence. Two to three independent experiments were pooled (nr of mice: 5–18 as detailed in table S3). Statistical analysis was calculated for pair wise comparisons between early and late strains (* p<0.05; ** p<0.01; *** p<0.001, Mantel-Cox test).
In accordance with these results, a major decrease in body weight was observed in mice infected with the early P. aeruginosa strains AA2, KK1 and KK2 when compared with the late clonal strains AA43, AA44 and KK71 both in C57Bl/6NCrl and Balb/cAnCrl (Fig. S1). Infections with KK72 strain appeared to be an exception.
Histopathological lesions, localization and quantification of P. aeruginosa strains in the murine airways
To assess clinical strain-specific traits of acute pneumonia, lung histopathology was performed on mice challenged with strains of the P. aeruginosa AA clonal lineage for 24 hours. This analysis revealed that acute infection with early AA2 strain caused more severe lesions and leukocytes recruitment in the airways than infection with late AA43 and AA44 (Fig. 5 A–C, E–G). The area infiltrated with inflammatory cells was significantly increased in the AA2 strain compared to AA43 and AA44 infected mice (cell infiltration mean±SEM: 63.99±5.42% of AA2 vs 43.15±0.91% of AA43 and 44.51±0.44% of AA44, Mann Whitney test, p<0.05) (Fig. 5O). Accordingly, the percentage of tissue preservation was significantly higher for AA43 and AA44 compared to AA2 (36.01±5.42% of AA2 vs 56.85±0.91% of AA43 and 55.49±0.44% of AA44, p<0.05).
C57Bl/6NCrl were infected with 5×106 cfu/lung of P. aeruginosa strains from AA lineage for 24 hours. Control mice were not infected. Lungs were stained with H&E and in immunofluorescence with specific antibody against P. aeruginosa (red) (A, E, I: AA2; B, F, L: AA43; C, G, M: AA44; D, H, N: not infected). Counterstaining was performed with 4′,6-Diamidino-2-phenylindole dihydrochloride (DAPI) (blue). I–N) Bacterial cells of P. aeruginosa are visible in the bronchia and pulmonary parenchyma. O) Severity of lesions and lung involvement is heterogeneous in different lobes of the same mice. Quantification of infiltrated and preserved areas as percentage of total tissue area with mean ± SEM is shown (n = 3 mice each/strain). Statistical analysis was calculated for pair wise comparisons between early and late strains (* p<0.05; ** p<0.01; *** p<0.001, Mann–Whitney). P) Dots represent individual measurements of the no. of cfu per lung, and horizontal lines represent median values after 12, 24 and 48 h. Two independent experiments were pooled. Statistical analysis was calculated for pair wise comparisons between early and late strains (* p<0.05, Student's t-test).
Immunofluorescence staining showed that the early strain AA2 was localized both within the bronchial lumen and within alveolar space (Fig. 5I), supporting its spreading to other organs during sepsis. In contrast, the late strains AA43 and AA44 were localized exclusively within the bronchia (Fig. 5L, M). Next, we quantified the bacterial load in the lungs of mice up to 48 h post infection. Given a starting dose of 5×106, early AA2 strain replicated in the airways reaching a high load (2.3×108 median CFU) and causing death of the animal (Fig. 5P). Late AA43 and AA44 decreased significantly bacterial numbers soon after infection and were completely cleared by the host immune system after 48 h, indicating a low pathogenic potential (AA2 vs AA43 and AA44, Student's t-test, p<0.05).
Invasion of P. aeruginosa sequential strains in epithelial cells
Bacterial invasion of host cells is a process common to many pathogens, including the CF-related pathogen, to evade extracellular immune factors [17] or to favour systemic spread [18]. We tested the ability of the P. aeruginosa clinical strains to invade CF respiratory cells (IB3-1) and isogenic corrected cells (C38). As shown in Fig. 6, early AA2 strain was found to be significantly more invasive than the P. aeruginosa clonal late strains AA43 and AA44 in both IB3-1 and C38 cells (IB3-1: AA2 vs AA43 p<0.05, AA2 vs AA44 p<0.001; C38: AA2 vs AA43 p<0.001, AA2 vs AA44, Student's t-test: p<0.001). In particular, AA44 strain was completely non-invasive in these experiments. Similar results were obtained with strains of the KK lineage. Early KK1 was significantly more invasive when compared to late KK71 and KK72 strains (IB3-1: KK1 vs KK71 and KK72, p<0.01 and p<0.001, respectively; C38: KK1 vs KK71 and KK72, p<0.01 and p<0.001, respectively). Early KK2 strain was more invasive than late clonal strains KK71 and KK72 both in IB3-1 and C38 cells, although significance was found only in IB3-1 cells (KK2 vs KK71, p<0.01).
A) Fold of invasion relative to AA2 after 1 h of stimulation with AA clonal lineage. B) Fold of invasion relative to KK1 after 1 h of stimulation with KK clonal lineage. Measurements were performed in triplicate. Statistical analysis was calculated for pair wise comparisons between early and late strains (* p<0.05, ** p<0.01, *** p<0.001, Student's t-test).
Discussion
Previous studies that were based on whole genome sequence analyses of longitudinal P. aeruginosa isolate from CF patients suggested that bacterial invasive functions are selected against during the course of chronic infection [5], [11]. Examples include motility, type III secretion system, O antigen biosynthesis, exotoxin, protease, and phenazine production, among others. Historically, many of these functions are considered to be virulence factors, as they provoke acute infection or dissemination within the host. Consequently, a major question that derived from previous reports and which requires further investigation was whether adaptation of P. aeruginosa strains to the CF-niche changes the fitness in other environments.
In this paper, we tested this hypothesis by evaluating acute pathogenicity of P. aeruginosa clonal variants from CF patients, in multiple infection hosts. The P. aeruginosa clonal strains included in this panel were isolated at different time points during CF chronic lung infection and were genetically characterized for genome rearrangements, mutations, and variations in pathogenic islands, and phenotypically for the loss of motility, acquisition of mucoidy, and a number of changes in the production of distinct virulence factors [14], [15]. Furthermore, the P. aeruginosa late strains, which were selected for this study, clustered with respect to their ability to persist in CF airways as well as in murine models of chronic infection that mimic the anaerobic conditions found the CF sputum [19], [14]. When P. aeruginosa longitudinal strains were tested in non-mammalian infection models, including C. elegans, G. mellonella and D. melanogaster, a reduction in acute virulence was observed in late strains relative to the respective early isolates. Most notably, there was a general agreement between the three models. When the panel of hosts was expanded to C57bl/6NCrl and Balb/cAnNCrl inbred mouse strains of different genetic backgrounds, we confirmed that early strains were lethal while late adapted P. aeruginosa strains were attenuated in acute virulence.
Based on previous reports on P. aeruginosa and other CF-related pathogens, this result was not obvious. In fact, the ability of bacteria to survive in a particular environment depends on virulence factors that are often specific for a particular host. Recent studies of Burkholderia cenocepacia infection in C. elegans, G. mellonella, alfalfa plant, mice and rats reported that most virulence factors are specific for one infection model only, and virulence factors are only rarely essential for full pathogenicity in multiple hosts. Only three factors were found to be essential for full pathogenicity in several host. Burkholderia cenocepacia mutants defective in quorum sensing, siderophore production and LPS biosynthesis were found to be attenuated in at least three of the infection models [20]. In P. aeruginosa PA14 strain only few host-specific virulence factors could be identified, and many of the mutants were attenuated in virulence in different hosts including C. elegans, G. melonella and mice [21]. However, when the virulence factors discovered in reference strains PA14 and PAO1 were tested in other clinical strains, no correlation between the absence and presence of these genes with virulence was observed [21]. Comparison of various clinical P. aeruginosa strains revealed that virulence is both multifactorial and combinatorial, the result of a pool of pathogenicity-related genes that interact in various combinations in different genetic background. P. aeruginosa clinical strains from the same type of infection exhibited a wide range of virulence in C. elegans [2]. For example, both the most and the least virulent strains tested were isolates from CF infections. Examination of specific genes among the several P. aeruginosa isolates did not reveal a consistent clustering of their genomic content with their pathogenic potential.
However, distinction between early and late P. aeruginosa strains from patients with CF had not been taken into account in previous works. Here, we directly compared P. aeruginosa early and late strains adapted to the CF-niche, which included strain exhibiting diverse phenotypes and belong to different genotypes, in several hosts. Although the genomes of P. aeruginosa isolates used in this work were not fully sequenced and only few phenotypic differences were identified, it is likely that late strains have accumulated several mutations during chronic persistence which account for the reduced pathogenicity across a broad range of hosts [14], [15]. Thus, the genetic adaptation process that leads to CF-niche specialization restricts the overall virulence of late strains to other environmental niche. Regarding the P. aeruginosa strains selected in this study, this process is not strain-dependent but is consistent for all the late isolates.
We were unable to correlate the observed differences in virulence of early and late P. aeruginosa strains with a specific phenotype, but it is most likely that multiple mutations are responsible for the attenuation of late strain in acute virulence. Notably, a single phenotypic difference of the early KK1 and KK2 strains, including a LasR phenotype and a motility defect, did not change virulence in several hosts; major pathogenic differences are evident in KK71 and KK72, in which multiple phenotypic changes were observed. The mucoid AA43 and the non-mucoid AA44 strains did not differ in their virulence potential. In addition, AA43 and AA44 were similarly attenuated despite their differences in LPS lipid A, as has been reported previously [5].
Although rodents are the first choice for understanding infectious diseases in human, non-mammalian models can be useful surrogate hosts. Drosophila response to pathogens and mammalian innate immune defenses are characterized by pathways conserved in vertebrates [22]. C. elegans has been largely used to identify virulence factors [23], allowing the study of responses to infection as well as comparison of the virulence of clinical and environmental isolates [24]. More recently both model organisms, C. elegans and Drosophila, have been also used to study host tolerance in addition to resistance mechanisms [25]. Their innate immune system employs evolutionary conserved signalling pathways [26], [21]. In reference to G. mellonella, it has been shown to correlate with mice models, when used to test P. aeruginosa virulence [27]. The use of non-mammalian infection models has several downsides, such as the specific temperature for the cultivation of the nematode may inhibit expression of certain virulence factors, the absence of the target organ and the lack of specific receptors or pathways. However, our results demonstrate the usefulness of these models for evaluating differences in acute virulence of P. aeruginosa.
Regarding the mammalian host, several studies have demonstrated that the host resistant/susceptibility response relies not only on the animal species but also on its genetic background [28], [29], [30], [16]. In particular, different susceptibility to P. aeruginosa chronic bronchopulmonary infection has been reported among genetically well-defined inbred mouse strains when mice were exposed to clinical strains embedded in the agar beads. Based on the bacterial load detected in the lung after three days and two weeks, Balb/cAnCrl mice were found to be resistant and C57Bl/6NCrl mice were identified as susceptible in two different studies [31], [28]. So far, direct comparison of the susceptibility of murine inbred strains to P. aeruginosa early and late strains from CF patients has not been performed. In our study, C57Bl/6NCrl and Balb/cAnCrl showed similar susceptibility to P. aeruginosa acute infection in terms of mortality but differences in pathogenicity among clonal early and late P. aeruginosa isolates observed in non-mammalian hosts. The genetic diversity of the mice in addition to the differences among type of infection (e.g. acute, reported in this work, and chronic, reported in previous works) and challenge, and bacterial origin may account for the different results [28], [29], [30], [16], [32]. Separate breeding colonies of C57Bl/6 mice maintained at the Charles River (“NCrl”), used in this study, or Jackson (J), used in previous studies, have led to the emergence of distinct substrains of C57Bl/6 mice that may explain the different susceptibility.
However, the findings that P. aeruginosa early strains were more lethal when compared to late strains in two different mouse genetic backgrounds strongly support the results in non-mammalian hosts that CF-niche adaptation of P. aeruginosa selects populations with reduced pathogenic potential in the acute infections. In addition, it has been argued that a high burden of infection but low virulence should account for host tolerance [33], [34], [25]. Consequently, our results indicated an increased host tolerance against P. aeruginosa CF adapted strains, as suggested by the high bacterial load sustained by the host. Our previous study showed that PAMPs of these P. aeruginosa strains, which were isolated at the late stage of CF chronic infection, drastically impair the host immune detection system suggesting a role of adaptation in increasing host tolerance [5], [35], [25]. Histopathological analysis carried out in this work supports the previous findings that detection of P. aeruginosa adaptive strains is impaired compared to early strains. The mechanism(s) that permits P. aeruginosa to cause invasive infections with bacteremia or tolerance is not known. Some bacterial pathogens can induce their own uptake into host cells (invasion), allowing the pathogen to enter a protected niche and, in some cases, to pass through cellular barriers including the respiratory epithelium and/or the blood barrier [17], [18]. Although further studies are needed to determine the exact mechanisms of P. aeruginosa/host interaction, it is tempting to speculate that the invasiveness of P. aeruginosa early strains may facilitate spreading from the lung to other tissues, while P. aeruginosa late strains, which are not able to protect themselves, may be finally eliminated.
Taken together, our results demonstrate that P. aeruginosa adaptation in CF airways selects pathoadaptive variants with a strongly reduced ability to cause acute infection processes in a host-independent way. These results have important implications for our understanding of the pathogenesis of P. aeruginosa-host interaction.
Materials and Methods
Ethics Statement
Animal studies were conducted according to protocols approved by the San Raffaele Scientific Institute (Milan, Italy) Institutional Animal Care and Use Committee (IACUC) and adhered strictly to the Italian Ministry of Health guidelines for the use and care of experimental animals.
Research on the bacterial isolates from the individuals with CF has been approved by the responsible physician at the CF center at Hannover Medical School, Germany. All patients gave informed consent before the sample collection. Approval for storing of biological materials was obtained by the Hannover Medical School, Germany.
Bacterial strains and CF patient
Nine sequential P. aeruginosa isolates from three CF patient carrying ΔF508/ΔF508 or ΔF508/R553X cftr mutation were chosen from the strains collection of the CF clinic Medizinische Hochschule of Hannover, Germany. Genotypic and phenotypic data of P. aeruginosa strains were published previously and summarized in Figure 1 and Table S1 [4], [14], [5]. P. aeruginosa was cultured in Pseudomonas isolation agar (PIA) or Trypticase Soy Broth (TSB) at 37°C.
Investigation of pathogenicity in the C. elegans model
For the investigation of pathogenicity C. elegans strain DH26 has been used. Worms were synchronized into L4 larval stage by egg preparation, which was followed by incubation of isolated eggs on E. coli OP50 feeding plates at 20°C for around 76 hours. Subsequently, L4 larvae were transferred on the lawns of examined bacterial strains grown in the 6-well plates (approximately 30 worms per well) and incubated at 25°C. The surviving worms were counted after 24, 48 and 72 hours with the aid of a Stemi SV 6 microscope (Zeiss, Goettingen). The pathogenicity of the investigated bacterial strains was determined from the survival rates of C. elegans in three independent replicates.
G. mellonella killing assays
Infection of G. mellonella larvae was performed as described previously [27], with some modifications. Caterpillars in the final larval stage (Brumann, Zurich, Switzerland) were stored in wooden shavings at 15°C and used within 2 to 3 weeks. Bacterial overnight cultures grown in LB broth were diluted 1∶100 in 30 ml fresh medium and grown to an OD600 of 0.4 to 0.7. Cultures were centrifuged and the cellswere resuspended in 10 mM MgSO4 (E. Merck, Dietikon, Switzerland). 10-µl aliquots of three dilutions were injected into G. mellonella via the hindmost proleg using a 1-ml syringe (BD Plastipak, Madrid, Spain) with a 27-gauge needle (Rose GmbH, Trier, Germany).. Six healthy, randomly chosen larvae were injected and incubated at 30°C in the dark. As a control larvae were injected with 10 µl MgSO4. The number of dead larvae was scored 24 h after infection and the LD50 dosage was determined. Data are mean values for at least three independent experiments.
Fly pathogenicity assay
Fly pricking assays were performed essentially as described by Apidianianakis et al [36]. 1 ml of an overnight culture was pelleted by centrifugation (10 min by 5000 rpm) and re-suspended in 1 ml of 10 mM MgSO4 solution. A Tungsten stainless steel needle, with approximate diameters of 0.01 mm at the tip and 0.2 mm across the main needle body, was dipped into the bacterial solution and pricked into the middle dorsolateral thorax of anesthetized flies. For each strain 15 flies were used. As a control, the flies were pricked with MgSO4 buffer. The infected flies were kept in glass vials, which were incubated at 26°C. Survival of the flies was monitored over time.
Mouse model of acute P. aeruginosa infection
C57Bl/6 mice (20–22 gr) were purchased by Charles River. Mice were housed in filtered cages under specific-pathogen conditions and permitted unlimited access to food and water. Prior to animal experiments, the clinical P. aeruginosa strains were grown for 3 h to reach exponential phase. Next, the bacteria were pelleted by centrifugation (2700 g, 15 min), washed twice with sterile PBS and the OD of the bacterial suspension was adjusted by spectrophotometry at 600 nm. The intended number of cfu was extrapolated from a standard growth curve. Appropriate dilutions with sterile PBS were made to prepare the inoculum of 2×106 up to 2×1010 cfu/ml. Mice were anesthetized and the trachea directly visualized by a ventral midline incision, exposed and intubated with a sterile, flexible 22-g cannula attached to a 1 ml syringe according to established procedures [14] [37]. A 50 µl inoculum of 1×105 up to 1×109 cfu were implanted via the cannula into the lung, with both lobes inoculated. After infection, mortality and body weight were monitored in one group of mice over one week. In another group of mice, the lungs were excised, used for histopathology, homogenized and plated onto TSB-agar plates for cfu counting.
Histological examination and immunofluorescence
Mice were sacrificed by CO2 administration after 12, 24, 48 h of infection, lungs were removed en bloc and fixed in 10% buffered formalin at 4°C for 24 h, and processed for paraffin embedding. Longitudinal sections of 5 µm from the proximal, medial and distal lung regions were obtained at regular intervals using a microtome. Sections were stained with H&E according to standard procedures. Areas of inflammatory cell infiltration and tissue preservation (normal histology) were quantified using Image J software (National Institutes of Health) and reported as a percentage of total area [38]. Localization of P. aeruginosa was performed in de-paraffinized lung sections by employing a rabbit antiserum specific for P. aeruginosa and Texas Red-labeled goat anti-rabbit IgG as described [14]. The slides were examined using an Axioplan fluorescence microscope (Zeiss), and images were taken with a KS 300 imaging system (Kontron).
Cell cultures and invasion assay
IB3-1 cells, an adeno-associated virus-transformed human bronchial epithelial cell line derived from a CF patient (ΔF508/W1282X) and C38 cells, the rescued cell line which expresses a plasmid encoding a copy of functional CFTR, were obtained from LGC Promochem [39]. Cells were grown in LHC-8 media (Biosource) supplemented with 5% fetal bovine serum (FBS) (Cambrex Bio Science). All culture flasks and plates were coated with a solution of LHC-basal medium (Biosource) containing 35 µg/mL bovine collagen (BD Biosciences), 1 µg/mL bovine serum albumin (BSA, Sigma) and 10 µg/mL human fibronectin (BD Bio Science) as described [40].
Bacteria invasion assay was performed using Polymyxins B (100 µg/ml) (Sigma) protection assay with minor modifications [41]. P. aeruginosa strains, grown to the mid-exponential phase, were used to infect cell monolayers at a 100∶1 multiplicity of infection for 1 h. The monolayers were washed with PBS, treated with antibiotic for 1 h, washed, lysed with H2O and plated on TSB-agar plates (Difco).
Supporting Information
Figure S1.
Weight change after infection with clonal pair of early/late P. aeruginosa isolates in C57Bl/6NCrl and BALB/cAnNCrl inbred mouse strains. (A) C57Bl/6NCrl weights after infection with P. aeruginosa AA clonal lineage; (B) C57Bl/6NCrl weights after infection with P. aeruginosa KK clonal lineage; (C) BALB/cAnNCrl weights after infection with P. aeruginosa AA clonal lineage; (D) BALB/cAnNCrl weights after infection with P. aeruginosa KK clonal lineage. Data are expressed as mean ± SEM. Two to three independent experiments were pooled (nr of mice: 5–18 as detailed in table S3).
https://doi.org/10.1371/journal.pone.0035648.s001
(TIF)
Table S1.
Genotypic and phenotypic characteristics of P. aeruginosa strains used in this work.
https://doi.org/10.1371/journal.pone.0035648.s002
(DOC)
Table S2.
Dose response in C57Bl/6NCrl infected with P. aeruginosa clonal lineages.
https://doi.org/10.1371/journal.pone.0035648.s003
(DOC)
Table S3.
Comparison between C57Bl/6NCrl and BALB/cAnCrl infected with P. aeruginosa clonal lineages.
https://doi.org/10.1371/journal.pone.0035648.s004
(DOC)
Acknowledgments
The authors would like to thank M. Rocchi and F. Sanvito (Department of Pathology, San Raffaele Scientific Institute, Milano, Italy) for the mouse histopathology, B. Tümmler (Klinische Forschergruppe, OE 6710, Medizinische Hochschule Hannover, Hannover, Germany) for the P. aeruginosa clinical strains.
Author Contributions
Conceived and designed the experiments: NIL CC LE AB. Performed the experiments: NIL CC IDF CR MJ SS. Analyzed the data: NIL CC MJ SS. Contributed reagents/materials/analysis tools: LE AB. Wrote the paper: NIL CC LE AB.
References
- 1.
Bernd Rehm HA (2008) Pseudomonas: model organism, pathogen, cell factory. Wiley & Sons Ltd.
- 2. Lee D, Urbach JM, Wu G, Liberati NT, Feinbaum RL, et al. (2006) Genomic analysis reveals that Pseudomonas aeruginosa virulence is combinatorial. Genome Biology 7: R90.
- 3. Wiehlmann L, Wagner G, Cramer N, Siebert B, Gudowius P, et al. (2007) Population structure of Pseudomonas aeruginosa. PNAS 104: 8101–8106.
- 4. Bragonzi A, Wiehlmann L, Klockgether J, Cramer N, Worlitzsch D, et al. (2006) Sequence diversity of the mucABD locus in Pseudomonas aeruginosa isolates from patients with cystic fibrosis. Microbiology 152: 3261–3269.
- 5. Cigana C, Curcurù L, Leone MR, Ieranò T, Lorè NI, et al. (2009) Pseudomonas aeruginosa exploits lipid A and muropeptides modification as a strategy to lower innate immunity during cystic fibrosis lung infection. PLoS One 4: e8439.
- 6. Mahenthiralingam E, Campbell ME, Speert DP (1994) Nonmotility and phagocytic resistance of Pseudomonas aeruginosa isolates from chronically colonized patients with cystic fibrosis. Infect Immun 62: 596–605.
- 7. D'Argenio DA, Wu M, Hoffman LR, Kulasekara HD, Déziel E, et al. (2007) Growth phenotypes of Pseudomonas aeruginosa lasR mutants adapted to the airways of cystic fibrosis patients. Mol Microbiol 64: 512–533.
- 8. Hoffmann L, Kulasekara HD, Emerson J, Houston LS, Burns JL, et al. (2009) Pseudomonas aeruginosa lasR mutants are associated with cystic fibrosis lung disease progression. J Cyst Fibros 8: 66–70.
- 9. Jain M, Ramirez D, Seshadri R, Cullina JF, Powers CA, et al. (2004) Type III secretion phenotypes of Pseudomonas aeruginosa strains change during infection of individuals with cystic fibrosis. J Clin Microbiol 42: 5229–5237.
- 10. Oliver A, Cantón R, Campo P, Baquero F, Blázquez J (2000) High frequency of hypermutable Pseudomonas aeruginosa in cystic fibrosis lung infection. Science 288: 1251–1254.
- 11. Smith EE, Buckley DG, Wu Z, Saenphimmachak C, Hoffman LR, et al. (2006) Genetic adaptation by Pseudomonas aeruginosa to the airways of cystic fibrosis patients. Proc Natl Acad Sci U S A 30: 8487–8492.
- 12. Mowat E, Paterson S, Fothergill JL, Wright EA, Ledson MJ, et al. (2011) Pseudomonas aeruginosa population diversity and turnover in cystic fibrosis chronic infections. Am J Respir Crit Care Med 183: 1674–1679.
- 13. Nguyen D, Singh PK (2006) Evolving stealth: genetic adaptation of Pseudomonas aeruginosa during cystic fibrosis infections. Proc Natl Acad Sci U S A 30: 8305–8306.
- 14. Bragonzi A, Paroni M, Nonis A, Cramer N, Montanari S, et al. (2009) Pseudomonas aeruginosa microevolution during cystic fibrosis lung infection establishes clones with adapted virulence. AJRCCM 180: 138–145.
- 15. Bianconi I, Milani A, Paroni M, Cigana C, Levesque RC, et al. (2011) Positive signature-tagged mutagenesis in Pseudomonas aeruginosa: tracking patho-adaptive mutations promoting long-term airways chronic infection. Plos Pathogen 7: e1001270.
- 16. Tam M, Snipes GJ, Stevenson MM (1999) Characterization of chronic bronchopulmonary Pseudomonas aeruginosa infection in resistant and susceptible inbred mouse strains. Am J Respir Cell Mol Biol 20: 710–719.
- 17. Foster T (2005) Immune evasion by staphylococci. Nat Rev Microbiol 3: 948–958.
- 18. Schwab U, Leigh M, Ribeiro C, Yankaskas J, Burns K, et al. (2002) Patterns of epithelial cell invasion by different species of the Burkholderia cepacia complex in well-differentiated human airway epithelia. Infect Immun 70: 4547–4555.
- 19. Bragonzi A, Worlitzsch D, Pier GB, Timpert P, Ulrich M, et al. (2005) Nonmucoid Pseudomonas aeruginosa expresses alginate in the lungs of patients with cystic fibrosis and in a mouse model. J Infect Dis 192: 410–419.
- 20. Uehlinger S, Schwager S, Bernier SP, Riedel K, Nguyen DT, et al. (2009) Identification of specific and universal virulence factors in Burkholderia cenocepacia strains by using multiple infection hosts. Infect Immun 77: 4102–4110.
- 21. Mahajan-Miklos S, Rahme LG, Ausubel FM (2000) Elucidating the molecular mechanisms of bacterial virulence using non-mammalian hosts. Mol Microbiol 37: 981–988.
- 22. Ferrandon D, Imler JL, Hetru C, Hoffmann JA (2007) The Drosophila systemic immune response: sensing and signalling during bacterial and fungal infections. Nat Rev Immunol 11: 862–874.
- 23. Garvis S, Munder A, Ball G, de Bentzmann S, Wiehlmann L, et al. (2009) Caenorhabditis elegans semi-automated liquid screen reveals a specialized role for the chemotaxis gene cheB2 in Pseudomonas aeruginosa virulence. PLoS Pathog e1000540:
- 24. Monk A, Boundy S, Chu VH, Bettinger JC, Robles JR, et al. (2008) Analysis of the genotype and virulence of Staphylococcus epidermidis isolates from patients with infective endocarditis. Infect Immun 76: 5127–5132.
- 25. Medzhitov R, Schneider DS, Soares MP (2012) Disease tolerance as a defense strategy. Science 335: 936–941.
- 26. Engelmann I, Pujol N (2010) Innate immunity in C. elegans. Adv Exp Med Biol 708: 105–121.
- 27. Jander G, Rahme LG, Ausubel FM (2000) Positive correlation between virulence of Pseudomonas aeruginosa mutants in mice and insects. J Bacteriol 182: 3843–3845.
- 28. Morissette C, Skamene E, Gervais F (1995) Endobronchial inflammation following Pseudomonas aeruginosa infection in resistant and susceptible strains of mice. Infect Immun 63: 1718–1724.
- 29. Morissette C, Francoeur C, Darmond-Zwaig C, Gervais F (1996) Lung phagocyte bactericidal function in strains of mice resistant and susceptible to Pseudomonas aeruginosa. Infection and Immunity 64: 4984–4992.
- 30. Sapru K, Stotland PK, Stevenson MM (1999) Quantitative and qualitative differences in bronchoalveolar inflammatory cells in Pseudomonas aeruginosa-resistant and -susceptible mice. Clin Exp Immunol 115: 103–109.
- 31. Tam M, Snipes GJ, Stevenson MM (1999) Characterization of chronic bronchopulmonary Pseudomonas aeruginosa infection in resistant and susceptible inbred mouse strains. Am J Respir Cell Mol Biol 20: 710–719.
- 32. Furukawa S, Kuchma SL, O'Toole GA (2006) Keeping their options open: acute versus persistent infections. J Bacteriol 188: 1211–1217.
- 33. Read A, Graham AL, Råberg L (2008) Animal defenses against infectious agents: is damage control more important than pathogen control. PLoS Biol 6: e4.
- 34. Råberg L, Graham AL, Read AF (2009) Decomposing health: tolerance and resistance to parasites in animals. Philos Trans R Soc Lond B Biol Sci 364: 37–49.
- 35. Cigana C, Lorè NI, Bernardini ML, Bragonzi A (2011) Dampening host sensing and avoiding recognition in Pseudomonas aeruginosa pneumonia. J Biomed Biotechnol 852513:
- 36. Apidianakis Y, Rahme LG (2009) Drosophila melanogaster as a model host for studying Pseudomonas aeruginosa infection. Nature Protocols 4: 1285–1293.
- 37. Bragonzi A (2010) Murine models of acute and chronic lung infection with cystic fibrosis pathogens. IJMM 300: 584–593.
- 38. Sarkar K, Fox-Talbot K, Steenbergen C, Bosch-Marcé M, Semenza GL (2009) Adenoviral transfer of HIF-1alpha enhances vascular responses to critical limb ischemia in diabetic mice. Proc Natl Acad Sci U S A 106: 18769–18774.
- 39. Egan M, Flotte T, Afione S, Solow R, Zeitlin PL, et al. (1992) Defective regulation of outwardly rectifying Cl- channels by protein kinase A corrected by insertion of CFTR. Nature 358: 581–584.
- 40. Zeitlin P, Lu L, Rhim J, Cutting G, Stetten G, et al. (1991) A cystic fibrosis bronchial epithelial cell line: immortalization by adeno-12-SV40 infection. Am J Respir Cell Mol Biol 4: 313–319.
- 41. Pirone L, Bragonzi A, Farcomeni A, Paroni M, Auriche C, et al. (2008) Burkholderia cenocepacia strains isolated from cystic fibrosis patients are apparently more invasive and more virulent than rhizosphere strains. Environ Microbiol 10: 2773–2784.