Abstract
Pseudomonas aeruginosa often colonizes immunocompromised patients, causing acute and chronic infections. This bacterium can reside transiently inside cultured macrophages, but the contribution of the intramacrophic stage during infection remains unclear. MgtC and OprF have been identified as important bacterial factors when P. aeruginosa resides inside cultured macrophages. In this study, we showed that P. aeruginosa mgtC and oprF mutants, particular the latter one, had attenuated virulence in both mouse and zebrafish animal models of acute infection. To further investigate P. aeruginosa pathogenesis in zebrafish at a stage different from acute infection, we monitored bacterial load and visualized fluorescent bacteria in live larvae up to 4 days after infection. Whereas the attenuated phenotype of the oprF mutant was associated with a rapid elimination of bacteria, the mgtC mutant was able to persist at low level, a feature also observed with the wild-type strain in surviving larvae. Interestingly, these persistent bacteria can be visualized in macrophages of zebrafish. In a short-time infection model using a macrophage cell line, electron microscopy revealed that internalized P. aeruginosa wild-type bacteria were either released after macrophage lysis or remained intracellularly, where they were localized in vacuoles or in the cytoplasm. The mgtC mutant could also be detected inside macrophages, but without causing cell damage, whereas the oprF mutant was almost completely eliminated after phagocytosis, or localized in phagolysosomes. Taken together, our results show that the main role of OprF for intramacrophage survival impacts both acute and persistent infection by this bacterium. On the other hand, MgtC plays a clear role in acute infection but is not essential for bacterial persistence, in relation with the finding that the mgtC mutant is not completely eliminated by macrophages.
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Introduction
Pseudomonas aeruginosa, a gram-negative bacterium found in soil and water, is one of the most common nosocomial pathogens responsible for acute infections, especially in immunocompromised patients1. In patients with Cystic Fibrosis (CF), the viscous mucus layer adhering to the epithelial cells of airway allows P. aeruginosa to colonize the CF lungs, where it causes chronic infection that is very difficult to eradicate, increasing the risk of death1. Furthermore, increasing antibiotic resistance of P. aeruginosa has led the World Health Organization (WHO) to identify this bacterium as a priority in searching for alternative and novel therapeutic strategies2. To this aim, appropriate models are required to better understand host–pathogen interactions at the molecular and cellular level, and direct interaction of P. aeruginosa with the host immune system.
The zebrafish (Danio rerio) is a vertebrate that has demonstrated its importance as a biomedical model to study host–pathogen interaction, particularly with host innate immune cells in the embryo3, and it is increasingly used to model human infections4,5. The transparency of the embryo offers a unique opportunity to visualize in real time both bacteria and macrophages, which are highly migratory cells capable of the phagocytosis of pathogens, using transgenic zebrafish lines with fluorescent macrophages6,7. Zebrafish embryos have been successfully used as a model for P. aeruginosa infection to address the role of several bacterial factors, including the type 3 secretion system (T3SS)8,9,10. Different routes of infection have been used, for instance, microinjection of P. aeruginosa in a closed compartment causes a localized infection that is particularly suitable to follow in real time the interaction between bacteria and host innate immune cells11. Indeed, injection of P. aeruginosa in muscle or the hindbrain ventricle has been applied to investigate a role of macrophages in bacterial clearance in vivo during the early phase of acute infection12. The failure in clearing P. aeruginosa by innate immune cells causes a lethal acute infection in embryos within 24–30 h8,9.
Despite being described as an extracellular pathogen, recent data showed that P. aeruginosa can reside, at least transiently, inside cultured epithelial cells and macrophages13,14,15,16. Macrophages play a key role in the immunity of CF lungs17. Recent findings have highlighted the pivotal role of P. aeruginosa MgtC and OprF in the ability of this bacterium to survive inside host macrophages12,18,19. MgtC is an inner membrane protein known to promote intramacrophage growth of several classical intracellular bacteria, including Salmonella typhimurium, as well as various non-classical intracellular pathogens20,21,22. OprF is an outer membrane porin that can modulate the production of various virulence factors of P. aeruginosa23,24. In P. aeruginosa, MgtC and OprF are also involved in bacterial escape from the phagosome and cell lysis caused by intracellular bacteria16. Upon acute infection in the zebrafish embryo model, both mgtC and oprF mutant strains of P. aeruginosa were significantly attenuated in comparison to the wild-type strain12,18. Interestingly, these attenuated phenotypes are dependent on the presence of macrophages, supporting a contribution of both factors in the pathogen-macrophage interaction in vivo12,18.
In the present study, we first performed a comparative analysis of the virulence of the wild-type P. aeruginosa strain PAO1, as well as mgtC and oprF mutants, in mouse and zebrafish acute infection models. Then, we investigated for the first time the behavior of these strains at a stage different from acute infection in zebrafish embryo to address bacterial persistence and interaction with host macrophages. To extend our in vivo findings, we investigated in detail the intracellular localization of these three strains in infected cultured rodent macrophages using electron microscopy.
Material and methods
Bacterial strains and growth conditions
Bacterial strains and plasmids used in this study are described in Table 1. P. aeruginosa strain PAO1, and PAO1-derived oprF and mgtC mutants express GFP constitutively by the introduction of plasmid pMF230 (Addgene).
In vivo experiments in mice
Adult C57BL/6J were purchased from Charles River Laboratories (France) and housed in the Institut Pasteur animal facilities. All experiments were performed in compliance with the French and European regulations on care and protection of laboratory animals (EU Directive 2010/63, French Law 2013-118, February 6th, 2013). The studies were approved by the Ethics Committee of Institut Pasteur (reference 2014-0014) with the infection protocol 04.146. Mice were infected intranasally as described previously25. In brief, mice were anesthetized by intraperitoneal injection of ketamine (Imalgene 1000®, 40 mg/kg)/xylazine (Rompun®, 8 mg/kg) suspended in PBS. The intranasal infection was conducted in the anesthetized animals (6 mice per group) with P. aeruginosa PAO1, PAO1∆mgtC or PAO1∆oprF (1.5 × 107 CFU) suspended in 50 μl of PBS. The animal mortality was monitored twice daily up to 60 h.
Ethics statement for zebrafish
Animal experimentation procedures were conducted at the University of Montpellier by following the 3Rs—Replacement, Reduction and Refinement principles according to the European Union guidelines for handling of laboratory animals (http://ec.europa.eu/environment/chemicals/lab_animals/home_en.htm) and were approved by the Direction Sanitaire et Vétérinaire de l'Hérault and Comité d’Ethique pour l’Expérimentation Animale under reference CEEA-LR-B4-172-37 and APAFIS #36309-2022040114222432 V2. Larvae were treated with the anesthetic Tricaine (400 µg/ml) before bleaching. The study is reported in accordance with ARRIVE guidelines.
Zebrafish lines, husbandry and maintenance
Wild-type AB zebrafish (ZIRC Cat# ZL1, RRID:ZIRC_ZL1) or tg(mfap4: mCherry-F) transgenic fish with macrophages displaying red fluorescence26 were maintained at 28 °C under standard conditions27. Adult fish were reared in accordance with international guidelines set out in EU Animal Protection Directive 2010/63/EU. Eggs were obtained by natural spawning, collected in petri dishes and incubated at 28 °C in water with 60 μg/ml ocean salts supplemented with 0.1% methylene blue. For experiments, larvae were staged at 1-day post-fertilization (dpf) and used from 2 to 6 dpf.
Microinjection of P. aeruginosa into zebrafish embryos
The bacteria were freshly streaked out on LB-Agar plates from glycerol stocks kept at − 80 °C. Bacterial strains were grown in LB medium to mid-log phase (OD600 = 0.7 to 0.8), recovered by centrifugation and washed twice in Phosphate-Buffered Saline (PBS). A 26-gauge needle was used to homogenize suspensions that were diluted in PBS at about 109 bacteria/ml. Phenol red (0.1% final) was added to facilitate visualization of the injection process.
Infection was carried out by the direct microinjection of 1.5 nl of bacterial suspension, containing 2000–2500 Colony Forming Unit (CFU), into the hindbrain ventricle of previously dechorionated embryos anesthetized with 400 µg/ml Tricaine (from 4 mg/ml stock, Sigma, France) at 50 h post-fertilization (hpf). To follow infection kinetics, larvae were individually transferred into a multi-well plate and incubated using a light/dark cycle at 28 °C with the melanization inhibitor Phenylthiourea (PTU) 1X. The number of dead embryos was counted based on the absence of heartbeat after visual inspection to determine survival curves.
Bacterial loads (CFU) in infected embryos
Groups of five infected larvae were collected at 24, 48, 72 and 96 h post-infection (hpi). The experiments were performed in triplicate. The larvae were lysed individually using a pestle in 100 µl of PBS. Then 100 µl of Triton X-100 was added to rinse off all residual bacteria from the pestle (PBS-Triton 1%). After a period of 10 min to allow Triton to fully lyse cells and to release intracellular bacteria, 100 µl was plated on LB plates containing 100 μg/ml ampicillin. Several dilutions were plated when needed, usually for the 24 hpi time-point. Only fluorescent colonies were considered for CFU counts and are represented as individual values in scatter dot plots, prepared with GraphPad Prism 8.0.2 Software (https://www.graphpad.com/updates/prism-802-release-notes). A black horizontal line indicates the mean. An aliquot (20 µl) of the well medium was also plated and fluorescent colonies were counted to assess the presence of P. aeruginosa in the medium. At 48, 72 and 96 hpi, if 20 or more fluorescent colonies were found, which occurred at low frequency (< 10%) and only with PAO1 and ΔmgtC strains, the corresponding zebrafish was not included in the analysis. Plasmid pMF230 is stable for all strains in non-selective medium in vitro upon serial dilution passages. We can, however, not exclude a low percentage of plasmid loss within the host, which might result in an underestimation of CFU numbers at later infection times.
Live imaging of zebrafish larvae
After anesthesia with tricaine (400 µg/ml), larvae were mounted in 1% low melting point agarose (Sigma, france) in 35 mm glass-bottom dishes (FluoroDish, World Precision Instruments, UK). Alive zebrafish larvae were imaged using the ANDOR CSU-W1 confocal spinning disk on an inverted NIKON microscope (Ti Eclipse) with ANDOR Neo sCMOS camera (20× air/NA 0.75 objective) at different time-points post injection, up to 96 hpi. The excitation wavelength of the green laser (for the bacteria expressing GFP) was 488 nm, the emission wavelength 525 and the exposure time was 0.15 s. The excitation wavelength of the red laser (for the macrophages expressing mCherry) was 561 nm, the emission wavelength 607 and the exposure time was 0.5 s. The exposure time for the white light (DIC) was 0.1 s. Z-stack images of approximately 100 planes with 1 µm intervals were acquired at 28 °C to study the localization of bacteria (inside or outside the host macrophages) and the presence of bacterial clusters. 3D files were generated from z-stack image acquisition with the iQ3 .6.5 software (Andor; https://andor.oxinst.cn/products/iq-live-cell-imaging-software/andor-iq3). Images in the manuscript were prepared using Imaris 9.6 (Andor Technology, https://imaris.oxinst.com/versions/9-6), after conversion of the files using Imaris file converter. Image properties were set at x = 0.319, y = 0.319, z = 1 to set the scale and channels set to the correct colour. Stacks, individual planes and orthogonal views are shown as indicated in the figure legends. Image intensities were only adapted for Fig. 3B green (reduced), Fig. 4A red (increased) and 4B (reduced green and red background). Additional artistic 3D representations are shown for some of the images (settings: Surfaces, background subtraction, diameter of largest sphere: 20 µm for macrophages, 1 µm for bacteria).
Transmission electron microscopy (TEM)
J774A.1 cells were kept at 37 °C in 5% CO2 in Dulbecco’s modified Eagle medium (DMEM) (Gibco) supplemented with 10% fetal bovine serum (FBS) (Gibco). P. aeruginosa infection of J774 macrophages on glass coverslips was completed as previously described18. For preparation of samples for TEM analysis, infected cells that have been treated after phagocytosis for 2.5 h with gentamicin (to eliminate extracellular bacteria) were fixed with 2.5% glutaraldehyde. Acetonitrile series were used for dehydration. Epon 118: acetonitrile 50:50, followed by two times for 1 h in 100% epon impregnated samples as described previously16. A Leica UC7 ultramicrotome (Leica microsystems) was utilized to cut ultrathin sections of 70 nm. Those sections were then counterstained with uranyl acetate and lead citrate and imaged with a Jeol 1200 EXII transmission electron microscope. All chemicals were from Electron Microscopy Sciences (USA) and solvents were from Sigma. Images were treated using Fiji software (https://imagej.net/software/fiji/).
Statistical analysis
Graphs and data analysis were done using GraphPad Prism 8.0.2 (https://www.graphpad.com/updates/prism-802-release-notes) software. The specific statistical tests used to evaluate the significant differences between groups is indicated in the figure legends. Kaplan–Meier survival analysis and log-rank (Mantel-Cox) test were utilized for survival curves whereas ordinary One-way-ANOVA followed by Sidak’s test was used for CFU. Statistically significant included p-values are lower than 0.05. *P < 0.01, **P < 0.001, ***P < 0.0001. The p-values and the number of independent experiments (biological replicates) are indicated in the figure legends.
Results
MgtC and OprF are key virulence factors of P. aeruginosa in mammalian and non-mammalian animal models
Since the virulence of mgtC and oprF mutant strains, both in a PAO1 background, has never been tested in a mammalian model, our first objective here was to analyze virulence of both mutants in mice using intranasal administration of bacteria to induce an acute pulmonary infection. Both mgtC and oprF mutants exhibited significantly attenuated virulence compared to the PAO1 WT strain as established by survival curves, with the oprF mutant unable to cause death until 5 days of infection (Fig. 1A). These data are consistent with previous results obtained after intravenous (iv) injection in a zebrafish embryo infection model12,18, confirming that MgtC and OprF are key virulence factor of P. aeruginosa, and that the virulence profiles of the three P. aeruginosa strains are similar in mice and zebrafish models.
In order to study bacterial behavior at the cellular level in vivo, we chose to inject bacteria in a localized compartment, the hindbrain ventricle (HBV) of 2 dpf zebrafish embryos, which is very suitable for analysis of the interaction of bacteria with macrophages12. Therefore, we first analyzed the infection pattern of the wild-type and the two mutants in this localized infection model. The mgtC and oprF mutants showed attenuated virulence compared to the PAO1 WT strain (Fig. 1B), with the oprF mutant being the least virulent, validating the use of the zebrafish embryo to address P. aeruginosa pathogenesis using the HBV infection model.
Analysis of bacterial load in zebrafish larvae up to 4 days post-infection
In zebrafish, about 50% of embryos injected with the wild-type PAO1 strain died within the first 24 h after infection, which is considered as an acute infection, while embryos that survived 2 days after infection did not die within the time frame of the experiment (Fig. 1B). To assess whether embryos that were able to survive infection with PAO1 for 4 days had cleared the bacteria or not, we determined bacterial CFUs in live zebrafish larvae at different time-points post-infection (24, 48, 72 and 96 hpi). Clearly, at 24 hpi most live larvae contained fewer bacteria than the initial inoculum of 2000 CFU, indicating host killing of bacteria after injection. Larvae, surviving up to the end point of the assay (96 hpi, Fig. 2), had stable low bacterial burden after 48 hpi, indicating bacterial persistence in surviving embryos. Although more larvae died after injection with wild-type PAO1 than with the mgtC mutant, unexpectedly, both strains exhibited similar CFU profiles with between 15 and 30 CFU (median values) in surviving larvae between 2 and 4 dpi (Fig. 2). The few larvae that contained large numbers of PAO1 or the mgtC mutant bacteria at 24 hpi (> 1000) most likely are larvae that would have died from acute infection. In contrast, surviving larvae infected with the oprF mutant had mostly cleared the bacteria, and only some had very few bacteria (mean of 2–5 bacteria per embryo) (Fig. 2).
Taken together, PAO1 causes an acute lethal infection in about 50% of the larvae, while surviving larvae develop a persistent infection with relatively low bacterial burden, with reproducible variation in CFU between larvae. The results demonstrate that OprF plays an important role in bacterial persistence and induction of acute infection, while MgtC seems not essential for persistence, yet has an important contribution to acute fatal infection.
Real time imaging of persistent P. aeruginosa WT and mgtC mutant in zebrafish larvae
We then aimed to visualize persisting bacteria in embryos between 2 to 4 dpi, specifically the interaction of these bacteria with host macrophages. Therefore, bacterial strains carrying a reporter plasmid that constitutively expresses GFP were injected into the HBV of 2 dpf embryos from the transgenic fish line tg(mfap4:mCherry-F) in which macrophages are labelled with a red fluorescent protein. Real-time, non-invasive live imaging was conducted using a confocal spinning disk microscope. Imaging of embryos that had been injected with the wild-type strain confirmed the initial high bacterial load and presence in macrophages at 2 hpi (Fig. 3A), as reported earlier12. We then imaged the HBV area of individual live embryos injected with the wild-type strain at 2, 3 or 4 dpi and assessed the maximal projection of z-stacks and 3D reconstruction (Fig. 3B–D). In agreement with CFU data, fluorescent bacteria could be seen up to 4 dpi in surviving larvae. Such persisting bacteria sometimes appeared as small clusters (Fig. 3B). Importantly, persisting P. aeruginosa PAO1 WT bacteria were detected inside macrophages, as visualized in orthogonal view (Fig. 3B) and by 3D reconstruction (Fig. 3B–D). Small bacterial clusters were also seen outside macrophages, although we could not determine whether these were present in other cell types (Fig. 3C), or in potential vesicles issued from macrophages (Fig. 3D).
Real time imaging of zebrafish larvae injected with the mgtC mutant from 2 dpi until 4 dpi showed, similar to the wild-type strain and consistent with CFU data (Fig. 2), that bacteria can be visualized at later time points in infection, either individually or clustered (Fig. 4). Clustered bacteria could be detected inside macrophages, as shown by 3D reconstruction (Fig. 4A,B). In embryos infected with the oprF mutant, bacteria were difficult to detect, which is in line with the low CFU count per larvae (Fig. 2). Occasionally, persisting bacterial clusters were visualized inside macrophages, as shown by 3D reconstruction, some of which had diffuse fluorescence, suggesting that bacteria had been degraded in macrophages (Fig. 5).
Taken together, real time imaging of infected embryos supports the ability of P. aeruginosa wild-type and mgtC mutant bacteria, but not the oprF mutant, to persist at low level in zebrafish embryos up to at least 3–4 dpi, which agrees with the CFU quantification. Moreover, the imaging showed that the wild-type strain and mgtC mutant were able to reside inside macrophages at late time points. Due to low numbers of bacteria, it was however not feasible to quantitate precise numbers of intra/extramacrophage bacteria based on live imaging, which is a limitation to determine the contribution of intracellular bacteria in persistence.
Fate of P. aeruginosa strains upon infection of cultured macrophages
We have previously used macrophage cell line J774 to investigate the fate of intracellular P. aeruginosa after phagocytosis and gentamicin treatment to remove extracellular bacteria, and demonstrated cell lysis caused by intracellular bacteria16. A quantitative analysis using fluorescent wild-type strain, mgtC or oprF mutants showed that both MgtC and OprF were involved in the ability of intracellular P. aeruginosa to escape from the phagosome and lyse macrophages in culture16. Using transmission electron microscopy (TEM), we have previously shown that P. aeruginosa PAO1 WT first resided in phagosomal vacuoles at early time point after phagocytosis (25 min) and subsequently could be detected in the cytoplasm at 2.5 h after phagocytosis16. In the present study, we extended the qualitative TEM analysis of J774 macrophages infected with the wild-type strain, mgtC or oprF mutants at 2.5 h after phagocytosis. Imaging of PAO1-infected cells showed different outcomes upon internalization by macrophages. We could visualize lysed macrophages that released intracellular bacteria (Fig. 6A). Bacteria could also be found in the cytoplasm of damaged macrophages (Fig. 6B) or in blebs (Fig. 6C). On the other hand, bacteria were also detected to reside in seemingly healthy macrophages, either in the cytoplasm (Fig. 6D) or in vacuoles (Fig. 6E). Non-damaged infected cells with bacteria found in vacuoles filled with heterogeneous electron dense material were also rarely observed (Fig. 6F), suggesting bacterial degradation by phago-lysosomal fusion. Infection with wild-type PAO1 thus showed diverse patterns, from bacterial release by lysed macrophages to bacterial elimination by macrophages.
A similar TEM analysis was conducted with P. aeruginosa mgtC and oprF mutants. In contrast to the wild-type strain, macrophage lysis driven by intracellular bacteria was not observed with the mgtC or oprF mutants, which is consistent with our previous results using fluorescence microscopy16. In addition, we previously quantified higher bacterial number per macrophage with the wild-type strain compared to the mgtC mutant 2.5 h post-phagocytosis and CFU counting confirmed a higher rate of viable surviving bacteria with the wild-type strain18. Interestingly, mgtC mutant bacteria can be found in macrophages, sometimes with several bacteria residing in a single vacuole (Fig. 7A). In other cases, isolated bacteria could also be found in the cytoplasm or associated with dense material (Fig. 7B), suggesting a fusion of the vacuole with lysosomes. For macrophages infected with the oprF mutant, it was more difficult to find evidence of surviving intracellular bacteria, and occasionally, isolated bacteria were found in vacuoles (Fig. 8A) where they were frequently associated with dense material (Fig. 8B), thus also supporting elimination of oprF mutant bacteria upon fusion with lysosomes.
In conclusion, TEM analysis showed that the wild-type strain exhibited a lytic phenotype, which was not found with mgtC or oprF mutant strains, in addition to intracellular survival for at least 2.5 h. Importantly, TEM analysis confirmed a different pattern between mgtC and oprF mutants in cultured macrophages: mgtC mutant could be found in vacuoles at 2.5 h, while at this time point the oprF mutant was mostly located in phagolysosomes or already eliminated.
Discussion
There is an increasing interest in the zebrafish embryo model to monitor P. aeruginosa pathogenesis11. Here, we further confirmed the pertinence of this model by performing for the first time a comparative analysis of three P. aeruginosa strains (PAO1, and mgtC and oprF mutants) in both mouse and zebrafish models of acute infection. Similar virulence patterns were observed in both models, with an attenuated phenotype for both mutants, and the strongest attenuation for the oprF mutant. We then investigated the fate of the three different strains in zebrafish larvae that did not develop an acute fatal infection after 2 dpi, a feature not considered in earlier studies, and demonstrated the relevance of this non-mammalian vertebrate model for tracking P. aeruginosa persistence.
Injection of P. aeruginosa in closed compartments of zebrafish embryos has been used by several groups to visualize bacteria and their interaction with host innate immune cells12,28,29,30. These studies were done during the acute phase of infection (within 30 hpi). Localized microinjection of zebrafish embryos with P. aeruginosa PAO1 and the oprF mutant allowed real-time visualisation of macrophages migrating to the injection site to phagocytize bacteria at early time points after infection12. In the present study, we conducted real time microscopy analysis of embryos locally injected in the HBV, combined with CFU counting, over a longer time period (up to 4 dpi). Our results indicated that PAO1 has the ability to persist at low bacterial numbers in some larvae that overcome or do not develop acute infection. Injection in the HBV, which is a small compartment, may restrict the number of persisting P. aeruginosa and it will be of interest to investigate P. aeruginosa persistence using a different infection mode. Real time imaging revealed persisting individual bacteria and bacteria in small clusters, either within or outside macrophages. This finding is consistent with a previous study that visualized bacterial clusters, referred as microcolonies, of P. aeruginosa PAO1 at 1 dpi in embryos injected in HBV28. In this former study, the analysis was carried out on fixed embryos subjected to immunofluorescence imaging and the intracellular location of bacteria was not investigated. Microcolonies were of smaller size with a psl mutant, making the authors suggest that bacterial aggregates may have features of biofilms28, although this hypothesis remains to be experimentally validated by other approaches.
Despite its attenuated phenotype, the mgtC mutant also exhibited the capacity to persist at low bacterial numbers, with characteristics similar to those of the wild-type PAO1 strain, namely the ability to reside within macrophages with visible small bacterial clusters up to 3 dpi. On the other hand, the attenuation of the oprF mutant was associated with a clear elimination of most bacteria 1 day after infection. Interestingly, the elimination of the oprF mutant is consistent with the TEM analysis of infected cultured macrophages, in which the oprF mutant was also largely eliminated or found as single bacteria in phagolysosomes at 2.5 h. This finding is in agreement with the higher incidence of localization of the oprF mutant with acidified compartments 2 h after phagocytosis12. In contrast, TEM analysis of cultured macrophages infected with the mgtC mutant showed internalized bacteria, often localized in vacuoles, residing in healthy macrophages at 2.5 h. This is consistent with our previous findings that implicated MgtC in the ability of the bacteria to escape the phagosome16. The TEM analysis of wild-type bacteria in infected cultured macrophages showed a more complex picture. First, in contrast to the mutant strains, but in agreement with our previous quantitative analysis using fluorescent microscopy16, internalized wild-type bacteria can induce lysis of macrophages and are then released extracellularly. Second, intracellular wild-type bacteria can reside in damaged or healthy macrophages, in vacuoles or in the cytoplasm. Interestingly, vesicles issued from macrophages can harbor P. aeruginosa, as observed by TEM and in vivo with the PAO1 strain. Further studies will be required to better characterize these vesicles. Taken together, in vivo infection combined with a cellular infection model with three different strains allowed us to propose a mechanism that links bacterial factors, intramacrophage fate and the outcome of infection (acute infection, persistent infection or bacterial eradication) (Fig. 9). OprF is essential for both acute and persistent infection by P. aeruginosa. In contrast, MgtC is required for acute infection in zebrafish larvae and macrophage lysis in cell culture, yet does not seem to be essential for persistent infection in vivo. Of note, the intramacrophage fate of mgtC mutant imaged by TEM differs from the one of wild-type PAO1 and further studies are required to fully determine the contribution of MgtC during intramacrophage stages and prolonged infection.
Zebrafish larvae have also been helpful to distinguish Burkholderia cepacia complex strains that cause either persistent or acute fatal infection, and to establish a key role for macrophages in bacterial survival and replication during acute infection31,32. The importance of an intracellular phase for extracellular respiratory tract bacterial pathogens has gained interest over the past years33. Besides P. aeruginosa, Staphylococcus aureus is another bacterial pathogen classically considered as an extracellular pathogen of the respiratory airway where the intracellular survival and proliferation has been well documented in recent years33. Here, our TEM analysis suggests that bacterial persistence may be associated with vacuolar location of the bacteria, at least transiently. This result find echoes in a recent study that identified a subpopulation of P. aeruginosa in vacuoles of epithelial cells, which displays persistence features as slow growth and expression of biofilm-associated factors34. In our analysis, we only considered the interaction of infecting bacteria with macrophages, but internalization in non-phagocytic cells is likely to also play a role during P. aeruginosa long-term infection in animal models. Further studies are needed to explore the localization of intracellular P. aeruginosa in the zebrafish embryo model, as well as complementary analysis in an appropriate mammalian model34, to better characterize the contribution of intracellular life during chronic infection.
Data availability
The datasets used and/or analysed during the current study available from the corresponding author on reasonable request.
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Acknowledgements
We thank Sylvie Chevalier (Rouen) for providing H636 strain. We thank the imaging facility MRI, member of the national infrastructure France-BioImaging infrastructure supported by the French National Research Agency (ANR-10-INBS-04, «Investments for the future») for photonic Microscopy at the MRI-DBS-UM platform and training by Vicky Diakou and Elodie Jublanc, as well as the Electron Microscopy facility of the University of Montpellier (MEA) for sample preparation and transmission electron microscopy. This work is supported by Vaincre La Mucoviscidose (RF20160501619, RF20200502703, RIF20210502864) and Association Gregory Lemarchal. HH is supported by Méditerranée Infection foundation.
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H.H., A.C.V. and A-B.B-P. conceived and designed experiments. H.H. performed zebrafish experiments and A.C.V. contributed to image analysis. L.B. performed TEM. Y.W. and L.T. performed mice experiments. All authors contributed in formal analysis. H.H., A.C.V. and A-B.B-P. wrote the manuscript. All authors edited the manuscript and approved the submitted version.
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Hajjar, H., Berry, L., Wu, Y. et al. Contribution of intramacrophage stages to Pseudomonas aeruginosa infection outcome in zebrafish embryos: insights from mgtC and oprF mutants. Sci Rep 14, 6297 (2024). https://doi.org/10.1038/s41598-024-56725-8
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DOI: https://doi.org/10.1038/s41598-024-56725-8
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