Figures
Abstract
Pleural infection/empyema is common and its incidence continues to rise. Streptococcus pneumoniae is the commonest bacterial cause of empyema in children and among the commonest in adults. The mesothelium represents the first line of defense against invading microorganisms, but mesothelial cell responses to common empyema pathogens, including S. pneumoniae, have seldom been studied. We assessed mesothelial cell viability in vitro following exposure to common empyema pathogens. Clinical isolates of S. pneumoniae from 25 patients with invasive pneumococcal disease and three reference strains were tested. All potently induced death of cultured mesothelial cells (MeT-5A) in a dose- and time-dependent manner (>90% at 107 CFU/mL after 24 hours). No significant mesothelial cell killing was observed when cells were co-cultured with Staphylococcus aureus, Streptococcus sanguinis and Streptococcus milleri group bacteria. S. pneumoniae induced mesothelial cell death via secretory product(s) as cytotoxicity could be: i) reproduced using conditioned media derived from S. pneumoniae and ii) in transwell studies when the bacteria and mesothelial cells were separated. No excess cell death was seen when heat-killed S. pneumoniae were used. Pneumolysin, a cytolytic S. pneumoniae toxin, induced cell death in a time- and dose-dependent manner. S. pneumoniae lacking the pneumolysin gene (D39 ΔPLY strain) failed to kill mesothelial cells compared to wild type (D39) controls, confirming the necessity of pneumolysin in D39-induced mesothelial cell death. However, pneumolysin gene mutation in other S. pneumoniae strains (TIGR4, ST3 and ST23F) only partly abolished their cytotoxic effects, suggesting different strains may induce cell death via different mechanisms.
Citation: Rashwan R, Varano della Vergiliana JF, Lansley SM, Cheah HM, Popowicz N, Paton JC, et al. (2018) Streptococcus pneumoniae potently induces cell death in mesothelial cells. PLoS ONE 13(7): e0201530. https://doi.org/10.1371/journal.pone.0201530
Editor: Paulo Lee Ho, Instituto Butantan, BRAZIL
Received: November 21, 2017; Accepted: July 17, 2018; Published: July 30, 2018
Copyright: © 2018 Rashwan 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.
Data Availability: All relevant data are within the paper.
Funding: YCGL has received research funding from the NHMRC, New South Wales Dust Disease Board, Sir Charles Gairdner Research Advisory Committee, Westcare, Cancer Australia and the Cancer Council of Western Australia. JSB receives funding from the UK Department of Health’s NIHR Biomedical Research Centre’s funding scheme. SML has received funding from the NSW Dust Diseases Board. and Sir Charles Gairdner Research Advisory Committee. 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
Bacterial pleural infection is a centuries-old disease and the global incidence continues to rise [1]. Community-acquired pneumonia affects over 5 million people each year in the United States [2, 3]. Of those, 20–40% will be complicated by development of a parapneumonic effusion [4], which can be secondarily infected by bacteria (pleural infection) and may present with frank pleural pus (empyema). Pleural infection is associated with a high (~20%) mortality in adults [5].
Streptococcus pneumoniae is the commonest cause of empyema in pediatric populations [6, 7] and the second most common in adults [1]. The Streptococcus milleri group (S. anginosus, S. intermedius and S. constellatus) is another leading cause of adult empyemas [8–10] whereas Staphylococcus aureus is the most frequent cause of hospital-acquired empyemas [11, 12].
Mesothelial cells line the pleural cavity and are the predominant cell type in the pleura. During infection, the mesothelium represents the first line of defense by acting as a surface barrier to invading pathogens [13]. Our previous animal model data showed that, following aspiration into the lung, S. pneumoniae infects the lung parenchyma and spreads rapidly toward the lung surface where it can disrupt the mesothelial barrier and invade the pleura to produce an empyema [14].
Despite the prevalence and importance of pleural infection, few other studies have investigated the effect of common bacterial pathogens (especially S. pneumoniae) on pleural mesothelial cells. In this study we aimed to characterize the effect of bacterial exposure (especially S. pneumoniae) on pleural mesothelial cell survival in vitro. The role for the secreted cytolytic toxin pneumolysin during mesothelial cell death was also assessed using genetically modified strains and recombinant pneumolysin.
Material and methods
Mesothelial cells
The SV40-transformed human mesothelial MeT-5A cell line was obtained from the American Tissue Culture Collection (Manassas, VA, USA; #CRL-9994). Cells were maintained in Dulbecco’s Modified Eagle Medium (DMEM) supplemented with 4 mM L-glutamine, 0.2 μg/ml streptomycin, 0.2 μg/ml penicillin and 10% (v/v) fetal calf serum (FCS).
Bacterial strains and culture
Bacterial reference strains were obtained from ATCC (Table 1). S. pneumoniae clinical isolates were cultured from patients with invasive disease and included 22 blood and 3 pleural fluid isolates (Table 2). All clinical isolates were collected from Royal Perth Hospital (Perth, Western Australia), except for WCH43, which was provided by Professor James Paton (University of Adelaide, South Australia). Wild type S. pneumoniae D39, TIGR4, ST3 and ST23F strains and their pneumolysin-negative derivatives (referred to as ΔPLY) were kindly provided by Professor Jeremy Brown (University College London, London, UK) [15, 16]. Ethics approval was obtained from the University of Western Australia Institutional Biosafety Committee (Approval number RA/5/1/445).
Streptococcus species were cultured in Todd Hewitt broth containing 0.5% yeast extract (THY), while S. aureus strains were grown in Luria Bertani medium. Bacteria were stored in broth containing 20% (v/v) glycerol at -80°C and directly sub-cultured onto blood agar plates for 18–24 hr at 37°C in 5% (v/v) CO2 before use. For the ΔPLY strains, sub-culturing was performed using blood agar plates supplemented with 0.2 μg/mL erythromycin. For experimentation, bacterial suspensions were prepared in 0.85% (w/v) saline to a turbidity of 0.5 McFarland using a Sensititre Nephelometer (Thermo Scientific; Waltham, MA, USA). Bacteria were also subject to heat-killing at 95°C for 1 hr. Successful heat-killing and viability of the live bacteria was verified by plate counts. Briefly, ten-fold dilutions of each bacteria ranging from 10–1 to 10–6 colony forming units (CFU)/mL were prepared in saline, with 20 μL spotted onto blood agar plates, and incubated overnight at 37°C. The following day, the number of CFU per 20 μL was counted and the CFU/mL calculated.
Preparation of S. pneumoniae conditioned media
S. pneumoniae was directly sub-cultured from blood agar plates into DMEM and incubated overnight in a shaking incubator at 200 rpm at 37°C. The conditioned media was filter-sterilized using a 0.2 μm pore size filter. For each experiment, the sterility of the conditioned media was confirmed by plating onto blood agar.
Recombinant native pneumolysin
Recombinant native pneumolysin was purified and assessed for hemolytic activity as previously described [17]. The preparation contained an activity of 380,000 hemolytic units per mg protein.
Bacterial infection of mesothelial cells
For all experiments, MeT-5A cells were grown to confluence in 24-well plates and deprived of serum and antibiotics 24 hr prior to stimulation. Cells were treated with live or heat-killed bacteria (at 105, 106 and 107 CFU/ml in 500 μL), conditioned media or recombinant pneumolysin for up to 24 hr. Transwell experiments were performed where MeT-5A cells were cultured in 24-well plates and 200 μL of a S. pneumoniae suspension (2 x 107 CFU/mL) was transferred into the upper chamber of Corning® Transwell® polyester membrane cell culture inserts (6.5 mm diameter, 0.4 μm pore size; Sigma-Aldrich). The transwell design did not allow physical contact between the mesothelial cells and bacteria. Viability of the bacteria in the upper chamber and their exclusion within the lower chamber was verified by plating onto blood agar using aliquots of the supernatant from each chamber. At the conclusion of each experiment the cells were analyzed for viability using flow cytometry.
Determination of cell viability
Cell viability was assessed using a LIVE/DEAD® Fixable Dead Cell Stain kit (Invitrogen; Victoria, Australia) according to the manufacturer’s instructions. Briefly, cells were harvested by trypsinization and washed with PBS. Cells were then stained with 1:1000 diluted green fluorescent reactive dye for 30 min, washed with PBS and fixed in 4% (w/v) paraformaldehyde for 15 min. Following this, cells were resuspended in PBS and fluorescence detected by flow cytometry using a 530/30 bandpass filter. Data (each 10,000 events) were acquired and analyzed using a BD FACSCalibur with FACSDiva version 5 software (BD Bioscience; San Jose, CA, USA).
Hemolysis assay
Cytolytic activity of the clinical isolates, reference, wild type and ΔPLY S. pneumoniae strains was determined semi-quantitatively using an erythrocyte hemolysis assay [18]. Bacterial suspensions were made in PBS and pelleted at 10,000 x g for 5 min. The pellet was lysed using 1% (w/v) sodium deoxycholate and stored at -20°C until required. Protein concentrations of the clarified lysates were determined using the DC Protein Assay kit (Bio-Rad: Hercules, CA, USA), according to the manufacturer’s instructions. A 5% (v/v) erythrocyte suspension was prepared from whole human blood and activated for 15 min at room temperature following the addition of 20 mM 2-mercaptoethanol. A 100 μL aliquot of each lysate (50 μg/mL) was serially diluted in PBS and an equal volume of erythrocyte suspension was added. The samples were incubated at 37°C for 30 min and centrifuged at 800 x g for 5 min. The absorbance of the supernatant at 540 nm was then measured. Erythrocytes treated with PBS alone were included as a measure of background absorbance and used to correct absorbance values of samples treated with lysates.
Western blot analysis
Bacterial cell lysis was performed using RIPA buffer containing 1X protease and phosphatase inhibitor cocktail (Thermo Fisher). Lysates were kept on ice for 30 mins with vortexing every 10 mins then centrifuged at 4°C 14,000 x g for 20 minutes before supernatants were transferred to a clean microfuge tube and stored at -20°C. Protein was quantified using Coomassie Plus reagent as per manufacturer’s instructions (BioRad). Ten micrograms of protein was denatured by heating at 95°C for 5 minutes, separated on 4–12% Bis-Tris gels (Invitrogen) and transferred onto nitrocellulose membranes using the iBlot system (Invitrogen). Membranes were blocked for 1 hour at room temperature in 5% skim milk/TBS-T (TBS with 0.05% Tween 20). Membranes were then incubated with anti-pneumolysin (sc-80500; 1:500: Santa Cruz Biotechnology) in TBST containing 5% skim milk powder on a roller overnight at 4°C. After washing a further 3 times with TBST for 5 minutes, blots were incubated with rabbit anti-mouse HRP-conjugated secondary antibody (ab6728: 1:10,000 Abcam) for 1 hour at room temperature. Membranes were visualized using the Pierce™ ECL Western Blotting Substrate (Pierce) and hyperfilm ECL (GE Healthcare, UK).
Statistical analysis
Data are presented as the mean ± standard error of the mean (SEM). Student’s t test with Bonferroni correction was used to compare differences between two treatment groups. A p value <0.05 was considered statistically significant. Analyses were conducted using GraphPad Prism 4.0 (La Jolla, CA, USA).
Results
S. pneumoniae potently induces death of pleural mesothelial cells
To investigate the effect of bacteria on pleural mesothelial cell survival, confluent MeT-5A monolayers were co-cultured with a range of common bacterial pleural empyema pathogens. Twenty five clinical isolates of S. pneumoniae isolated from patients with invasive pneumococcal diseases were tested (Table 2), of which 23 induced significant killing of pleural mesothelial cells (median % dead cells at 107 CFU/mL, 97%; p < 0.0001 compared to vehicle controls). Further, when heat-killed, none of the 25 clinical isolates tested were able to induce mesothelial cell death (Fig 1A).
A) The effect of S. pneumoniae on mesothelial cell death was assessed using 25 clinical isolates obtained from patients with invasive pneumococcal disease. B) MeT-5A cells were treated with increasing doses of live S. pneumoniae reference strains. C) Time course of MeT-5A cell death following S. pneumoniae TIGR4 infection was also assessed. D) Time course of MeT-5A cell death following co-culture with S. pneumoniae TIGR4 following heat-treatment at 95°C for 1 hr and viability determined at various time points up to 24 hr post-infection. * Denotes significantly higher than vehicle control and heat-killed bacteria.
In subsequent experiments 3 reference strains were used (Table 1) to explore the mechanisms of S. pneumoniae-induced cell death. Following infection for 24 hr, S. pneumoniae TIGR4, CIP 104225 and WCH43 strains potently induced death of MeT-5A cells (Fig 1B). Mesothelial cell death was observed at all bacterial doses used and no significant difference in cell death was seen between doses higher than 105 CFU/mL. At 107 CFU/mL, TIGR4, CIP 104225 and WCH43 strains killed 93.7%, 99.2% and 99.9% of MeT-5A cells, respectively (p < 0.0001 compared to vehicle control) (Fig 1B).
In subsequent experiments, a time course response to infection with the S. pneumoniae TIGR4 strain was also determined. As shown in Fig 1C, a significant increase in cell death was seen as early as 2 hr post-infection in cells treated with the highest bacterial dose (107 CFU/mL). This response continued to increase for all subsequent time points measured (2, 4, 6 and 24 hr post-infection: 8.2%, 14.3%, 17.4% and 93% of total; p < 0.05 for all time points). In contrast, cell death was only significantly induced at the 24 hr time point in cells treated with 105 or 106 CFU/mL (p < 0.0001; Fig 1C).
Heat-killing of S. pneumoniae abolished its ability to induced mesothelial cell death
To determine whether S. pneumoniae-induced cell death was dependent on the presence of live bacteria, S. pneumoniae (TIGR4 strain) was heat treated prior to co-culture with mesothelial cells. Compared to live bacteria, heat-killed TIGR4 failed to induce MeT-5A cell death at all concentrations used and at all time points measured (% dead cells 24 hr post-infection at 107 CFU/mL; live, 94%; heat-killed, 4.5%; p < 0.0001) (Fig 1D).
Infection with other empyema-causing bacterial strains did not induce mesothelial cell death
Treatment of MeT-5A cells with S. aureus Smith strain induced a very mild dose-dependent increase in cell death up to 11% at 107 CFU/mL (p < 0.001; Fig 2A). In contrast, S. aureus Seattle 1945 strain, S. milleri bacteria and S. sanguinis had negligible effect on mesothelial cell viability at all concentrations tested (Fig 2A–2C).
A-C) MeT-5A cells were treated with increasing doses of live S. aureus (A), S. milleri group bacteria (B) or S. sanguinis (C) and cell viability was assessed. * Denotes significantly higher than vehicle control.
S. pneumoniae-induced mesothelial cell death is mediated via a secreted bacterial product
In subsequent experiments we assessed the potential role for a secreted product in S. pneumoniae-induced mesothelial cell death. Cell-free conditioned media derived from S. pneumoniae TIGR4, CIP 104225 and WCH43 strains significantly induced death of MeT-5A cells compared to vehicle controls (Fig 3A; p < 0.0001). This effect was similar in potency to treatment with live S. pneumoniae. To further explore this observation, MeT-5A cells were co-cultured with the S. pneumoniae TIGR4 strain using Transwell® inserts. As shown in Fig 3B, culture of TIGR4 in the top chamber of a Transwell® insert still resulted in death of the mesothelial cell layer in the bottom chamber (p < 0.0001). Media obtained from the bottom well was devoid of bacteria.
A) MeT-5A cells were incubated with cell-free bacteria conditioned media. B) S. pneumoniae was loaded into the top chamber of a Transwell® insert and viability of MeT-5A cells was determined in the bottom chamber. Cell viability was assessed 24 hr post-treatment. * Denotes significantly higher than vehicle control.
S. pneumoniae-induced mesothelial cell death is partly mediated by pneumolysin
Pneumolysin is a potent cytolytic toxin produced by all clinically isolated S. pneumoniae strains and represents a major virulence determinant in pneumococcal disease [19]. Given this, the role of pneumolysin in S. pneumoniae-induced mesothelial cell death was investigated. First, cultured mesothelial cells were treated with recombinant pneumolysin to assess for toxin-induced lysis. As shown in Fig 4A, pneumolysin potently induced MeT-5A cell death at 1000 and 3000 ng/mL (p < 0.0001 compared to the vehicle control).
A) MeT-5A cells were treated with a purified, recombinant preparation of pneumolysin and viability determined 24 hr post-treatment. B) Lysates prepared from wild type S. pneumoniae strains and their pneumolysin-negative derivatives (ΔPLY) were assessed for cytolytic activity using an erythrocyte hemolysis assay. C) MeT-5A cells were infected with wild type and ΔPLY S. pneumoniae strains and viability determined 24 hr post-infection. * Denotes significantly higher than vehicle control.
We then employed a variety of wild type and pneumolysin-negative mutant strains to verify the importance of the toxin in this process. All parental wild type strains produced cytolytic toxins, as assessed by an erythrocyte hemolysis assay. In contrast, none of the ΔPLY strains were cytolytic, (Fig 4B). Wild type S. pneumoniae D39 potently killed the mesothelial cells, but the D39 ΔPLY failed to induce mesothelial cell death (Fig 4C), confirming that pneumolysin mediates the D39-induced cell killing. In contrast, TIGR4, ST3 and ST23F and their respective ΔPLY strains were equally potent in killing mesothelial cells, suggesting these strains employed a different mechanism (other than pneumolysin) in inducing cell death.
We extended the dose response of MeT-5A cells to D39 ΔPLY and confirmed that D39 ΔPLY failed to induce cell death even at concentrations up to 5 x 107 CFU/mL (Fig 5A). Lower doses of TIGR4, ST3 and ST23F ΔPLY strains still induced MeT-5A cell death albeit to varying degrees. TIGR4 ΔPLY induced MeT-5A cell death at all doses tested (Fig 5B). In contrast, no cytotoxic effect was observed for concentrations up to 105 CFU/mL and 104 CFU/mL for ST3 and ST23F ΔPLY strains, respectively (Fig 5C and 5D). Heat-killing of TIGR4, ST3 and ST23F ΔPLY strains abolished the cytotoxic activity of the bacteria on MeT-5A cells (Fig 6A). Further, treatment of MeT-5A cells with conditioned media from TIGR4, ST3 and ST23F ΔPLY strains significantly induced cell death (39.9%, 82.65% and 80.8%, respectively compared to vehicle controls; p < 0.01 for all; Fig 6B). Conditioned media from the TIGR4 ΔPLY strain induced cell death to a notably lesser extent than ST3 and ST23.
A-D) MeT-5A cells were treated with various concentrations of D39 (A), TIGR4 (B), ST3 (C) or ST23F (D) wild type and pneumolysin mutant (ΔPLY) strains and viability determined 24 hr post-infection. * Denotes significantly higher than vehicle control. # Denotes significant higher than ΔPLY strain.
A) MeT-5A cells were incubated with either live (open bars) or heat-treated (closed bars) S. pneumoniae pneumolysin mutant strains (ΔPLY). B) MeT-5A cells were treated with conditioned media derived from S. pneumoniae ΔPLY strains. Cell viability was determined 24 hr post-treatment * Denotes significantly higher than vehicle control.
To determine whether a secreted product was also responsible for the mesothelial cell cytotoxicity observed by clinical bacterial isolates, we quantified their hemolytic activity (Fig 7A). Most isolates produced cytolytic proteins, albeit to varying degrees. Combined with the results observed for the reference, wild type and ΔPLY strains, this added further support to a role for pneumolysin in mesothelial cell killing. We therefore assessed pneumolysin protein expression in the S. pneumoniae clinical bacterial isolates by Western blot (Fig 7B). All but one (31337) of the S. pneumoniae clinical isolates were positive for pneumolysin expression. Pneumolysin protein expression was also confirmed in the wild type but not the ΔPLY S. pneumoniae or S. milleri and S. sanguinis strains (Fig 7C).
A) Lysates isolated from clinical S. pneumoniae isolates were assessed for cytolytic activity using an erythrocyte hemolysis assay. Pneumolysin protein expression was assessed by Western blot in lysates obtained from B) clinical and C) wild type and ΔPLY S. pneumoniae isolates strains and S. milleri and S. sanguinis strains.
Discussion
Since first being described over 2000 years ago, pleural infection remains a major respiratory illness [20], and its global incidence is rising [1] despite advances in antibiotics and vaccination [21, 22]. Our understanding of the underlying pathobiology of this disease remains limited and although mesothelial cells are the most abundant cell type within the pleural cavity and S. pneumoniae is one of the most common causative agents of empyema, the host/pathogen interactions between these cells have seldom been studied.
Mesothelial cells can phagocytoze invading bacteria, release a large range of pro-inflammatory cytokines to recruit immune cells to the pleural cavity and induce fibrogenic reactions and septations/loculations to contain unwanted material within the pleural cavity. The ability of bacteria to compromise the mesothelial barrier (by killing mesothelial cells) will aid entry into, and subsequent bacterial proliferation within, the pleural cavity [23–25].
We showed, for the first time, that S. pneumoniae potently induced death of pleural mesothelial cells. These findings were validated using a large number of clinical isolates. This result was consistent across all reference strains tested and could be reproduced in 92% of the clinical isolates tested. Furthermore, mesothelial cell death occurred rapidly (<2 hrs) after exposure to S. pneumoniae, suggesting damage of the mesothelial barrier may be an early event in the onset of pleural infection. This potent cytotoxic effect on mesothelial cells was not observed following treatment with the other strains of common empyema bacteria we tested [8–10, 26].
Using several approaches, we confirmed that mesothelial cell killing was mediated by bacterial product(s) released by live S pneumoniae. The particular product(s) however appeared to vary among different strains of S pneumoniae. In the S. pneumoniae D39 strain, the cytotoxicity to mesothelial cells was mediated by pneumolysin and could be abolished by using S. pneumoniae mutant strains that lacked the pneumolysin gene (ΔPLY strains). Various common empyema pathogens, including S. pneumoniae strains, vary in their degree of pleural cytotoxicity but this study is the first to demonstrate this phenomenon towards mesothelial cells. Our data suggests that this may be due, in part, to the employment of separate pneumolysin-dependent and/or -independent mechanisms in order to mediate mesothelial cell death.
Pleural infection is traditionally viewed as an extension of lung parenchymal infection during pneumonia. In our published murine model of pneumococcal empyema, inhalation of S. pneumoniae induced histologic consolidation of the lung parenchyma and spread rapidly from the peri-bronchial areas to infect the visceral pleural mesothelial cells and enter into the pleural cavity. It is therefore probable that different microbes may employ alternate route(s) of entry to the pleural cavity. S milleri, for example, is a common causative agent for empyema, but rarely causes pneumonia. Computed tomography studies confirmed that a subgroup of empyema patients had no evidence of lung parenchymal infection. Our finding of high lethality of S. pneumoniae against mesothelial cells supports its direct invasion of the pleura through breaching the visceral mesothelium via translocation [14]. Our observation may also lend support to the hypothesis that other common microbes infect the pleura via different mechanisms. Non-cytotoxic bacteria, including S. aureus and viridans streptococci likely employ additional virulence strategies against mesothelial cells during pleura infection. These could include stimulation of cytokine release [24, 27–29], induction of mesothelial permeability [24] and cellular internalization and intracellular survival [14, 23, 30].
Pneumolysin is a cholesterol-dependent cytolysin, which forms large pores in membranes resulting in cell lysis and invasion of S. pneumoniae into host tissues [31]. We demonstrated that mesothelial cells are susceptible to pneumolysin-induced cell death when treated with pneumolysin. This was further confirmed when S. pneumoniae D39 ΔPLY failed to cause death of mesothelial cells. This result is consistent with other studies reporting attenuated cytotoxicity using pneumolysin mutated D39 [32, 33]. However, three other S. pneumoniae strains tested (TIGR4, ST3 and ST23F) were significantly less affected by pneumolysin gene mutation (ΔPLY). These ΔPLY strains produced a significantly weaker cytotoxic effect than the wild type strains, suggesting a role for pneumolysin-independent mechanism(s) in mesothelial cell death. Though the precise nature of these additional mechanisms was outside the scope of our study, this would suggest that both a capsular component/s and a secreted product (other than pneumolysin) may be required. Our results using heat-killed bacteria and conditioned media from the ΔPLY strains also favored the role of additional bacterial secreted product(s), rather than direct toxicity (e.g. via internalisation of S. pneumoniae) [34]. Given the absence of hemolytic activity in the ΔPLY strains, the secreted factor likely mediates cell death independent of direct cell lysis. Recently, S. pneumoniae ClpP protease was shown to induce apoptosis of human neuroblastoma cells [35]. Similarly, pneumococcal cell wall components released as a result of autolysis during growth are cytotoxic to some cell types [32, 36, 37]. These mechanisms warrant exploration.
There are limitations to our study. Although MeT-5A cells are considered the standard for mesothelial cell related studies, due to the considerable challenge of isolating primary cells in sufficient quantitites to establish reproducible in vitro models, the transformed nature of the cells may potentially confound interpretation of results. In addition, we investigated the direct cytotoxic effects of different bacteria on mesothelial cells in vitro, which did not incorporate any interactions of the bacteria that may initiate or augment cytotoxicity from other immune cells in vivo. Also, the precise impact of this lethality and any potential in therapeutic intervention need to be explored in animal models and human studies in future. In addition, intra-strain differences in S. aureus-induced cell death of peritoneal mesothelial cells [25] and a larger number of S. aureus and S. milleri strains need to be studied to make a firm conclusion of differences in their behavior from S. pneumoniae.
In conclusion, our results demonstrate that S pneumoniae is a potent inducer of pleural mesothelial cell death. Pneumolysin, although necessary for some S. pneumoniae strains, is not the sole pneumococcal mediator responsible for mesothelial cytotoxicity. Future studies are required to elaborate the relevance of these findings in vivo.
Acknowledgments
The authors acknowledge the facilities, and the scientific and technical assistance of the Australian Microscopy & Microanalysis Research Facility at the Centre for Microscopy, Characterisation & Analysis of the University of Western Australia, a facility funded by the University, State and Commonwealth Governments.
References
- 1. Lisboa T, Waterer G, and Lee Y. Pleural infection: changing bacteriology and its implications. Respirology. 2011;16:598–603. pmid:21382129
- 2. Anevlavis S, and Bouros D. Community acquired bacterial pneumonia. Expert Opin Pharmacother. 2010;11:361–74. pmid:20085502
- 3. Brar N, and Niederman M. Management of community-acquired pneumonia: a review and update. Ther Ad Respir Dis. 2011;5:61–78.
- 4. Light R. Parapneumonic effusions and empyema. Proc Am Thorac Soc. 2006;3:75–80. pmid:16493154
- 5. Ferguson A, Prescott R, Selkon J, Watson D, Swinburn C. The clinical course and management of thoracic empyema. QJM. 1996;89:285–9. pmid:8733515
- 6. Buckingham S, King M, and Miller M. Incidence and etiologies of complicated parapneumonic effusions in children, 1996 to 2001. Pediatr Infect Dis J. 2003;22:499–504. pmid:12799505
- 7. Grisaru-Soen G, Eisenstadt M, Paret G, Schwartz D, Keller N, Nagar H, et al. Pediatric parapneumonic empyema: rish factors, clinical characteristics, microbiology, and management. Pediatr Emerg Care. 2013;29:425–9. pmid:23528501
- 8. Maskell N, Davies C, Nunn A, Hedley E, Gleeson F, Miller R, et al. U.K. controlled trial of intrapleural streptokinase for pleural infection. N Engl J Med. 2005;352:865–74. pmid:15745977
- 9. Ahmed R, Marrie T, and Huang J. Thoracic empyema in patients with community-acquired pneumoniae. Am J Med. 2006;119:877–83. pmid:17000220
- 10. Lindstrom S, Kolbe J. Community acquired parapneumonic thoracic empyema: predictors of outcome. Respirology. 1999;4:173–9. pmid:10382237
- 11. Chen W, Lin Y, Liang S, Tu C, Chen H, Hang L, et al. Hospital-acquired thoracic empyema in adult: a 5-year study. South Med J. 2009;102:909–14. pmid:19668024
- 12. Maskell N, Batt S, Hedley E, Davies C, Gillespie S, and Davies R. The bacteriology of pleural infection by genetic and standard methods and its mortality significance. Am J Respir Crit Care Med. 2006;174:817–23. pmid:16840746
- 13. Mutsaers S. The mesothelial cell. Int J Biochem Cell Biol. 2004;36:9–16. pmid:14592528
- 14. Wilkosz S, Edwards L, Bielsa S, Hyams C, Taylor A, Davies R, et al. Characterization of a new mouse model of empyema and the mechanisms of pleural invasion by Streptococcus pneumoniae. Am J Respir Cell Mol Biol. 2012;46:180–7. pmid:21885676
- 15. Berry A, Ogunniyi A, Miller D, and Paton J. Comparative virulence of Streptococcus pneumoniae strains with insertion-duplication, point, and deletion mutations in the pneumolysin gene. Infect Immun. 1999;67:981–5. pmid:9916120
- 16. Rubins J, Charboneau D, Fasching C, Berry A, Paton J, Alexander J, et al. Distinct roles for pneumolysin's cytotoxic and complement activities in the pathogenesis of pneumococcal pneumonia. Am J Respir Crit Care Med. 1996;153:1339–46. pmid:8616564
- 17. Lock R, Paton J, and Hansman D. Comparative efficacy of pneumococcal neuraminidase and pneumolysin as immunogens protective against Streptococcus pneumoniae. Microb Pathog. 1988;5:461–7. pmid:3149709
- 18. Paton J, Lock R, and Hansman D. Effect of immunization with pneumolysin on survival time of mice challenged with Streptococcus pneumoniae. Infect Immun. 1983;40:548–52. pmid:6840851
- 19. Paton J, Lock R, Lee C, Li J, Berry A, Mitchell T, et al. Purification and immunogenicity of genetically obtained pneumolysin toxoids and their conjugation to Streptococcus pneumoniae type 19F polysaccharide. Infect Immun. 1991;59:2297–304. pmid:2050399
- 20. Brims F, Lansley S, Waterer G, Lee Y. Empyema thoracis: new insights into an old disease. Eur Respir Rev. 2010;19:220–8. pmid:20956197
- 21. Byington C, Korgenski K, Daly J, Ampofo K, Pavia A, Mason E. Impact of the pneumococcal conjugate vaccine on pneumococcal parapneumonic empyema. Pediatr Infect Dis J. 2006;25:250–4. pmid:16511389
- 22. Fletcher M, Leeming J, Cartwright K, and Finn A. Childhood empyema: limited potential impact of 7-valent pnemococcal conjugate vaccine. Pediatr Infect Dis J. 2006;25:559–60. pmid:16732158
- 23. Mohammed K, Nasreen N, and Antony V. Bacterial induction of early response genes and activation of proapoptotic factors in pleural mesothelial cells. Lung. 2007;185:355–65. pmid:17929089
- 24. Mohammed K, Nasreen N, Hardwick J, Logie C, Patterson C, and Antony V. Bacterial induction of pleural mesothelial monolayer barrier dysfunction. Am J Physiol Lung Cell Mol Physiol. 2001;281:L119–L25. pmid:11404254
- 25. Haslinger-Loffler B, Wagner B, Bruck M, Strangfeld K, Grundmeier M, Fischer U, et al. Staphylococcus aureus induces caspase-independent cell death in human peritoneal mesothelial cells. Kidney Int. 2006;70:1089–98. pmid:16871245
- 26. Meyer C, Rosenlund S, Nielsen J, and Friis-Moller A. Bacteriological aetiology and antimicrobial treatment of pleural empyema. Scand J Infect Dis. 2011;43:165–9. pmid:21108539
- 27. Haslinger-Loffler B, Bruck M, Grundmeier M, Peters G, and Sinha B. Staphylococcal infection impair the mesothelial fibrinolytic system: the role of cell death and cytokine release. Thromb Haemost. 2007;98:813–22. pmid:17938806
- 28. Nasreen N, Mohammed K, Hardwick J, Van Horn R, Sanders K, Doerschuk C, et al. Polar production of interleukin-8 by mesothelial cells promotes the transmesothelial migration of neutrophils: role of intercellular adhesion molecule-1. J Infect Dis. 2001;183:1638–45. pmid:11343213
- 29. Vernier A, Diab M, Soell M, Haan-Archipoff G, Beretz A, Wachsmann D, et al. Cytokine production by human epithelial and endothelial cells following exposure to oral viridans streptococci involves lectin interactions between bacteria and cell surface receptors. Infect Immun. 1996;64:3016–22. pmid:8757828
- 30. Stinson M, Adler S, and Kumar S. Invasion and killing of human endothelial cells by viridans group streptococci. Infect Immun. 2003;71:2365–72. pmid:12704106
- 31. Gilbert R. Cholesterol-dependent cytolysins. Adv Exp Med Biol. 2010;677:56–66. pmid:20687480
- 32. Zysk G, Bejo L, Schneider-Wald B, Nau R, and Heinz H. Induction of necrosis and apoptosis of neutrophil granulocytes by Streptococcus pneumoniae. Clin Exp Immunol. 2000;122:61–6. pmid:11012619
- 33. Zysk G, Schneider-Wald B, Hwang J, Bejo L, Kim K, Mitchell T, et al. Pneumolysin is the main inducer of cytotoxicity to brain microvascular endothelial cell caused by Streptococcus pneumoniae. Infect Immun. 2001;69:845–52. pmid:11159977
- 34. Ali F, Lee M, Iannelli F, Pozzi G, Mitchell T, Read R, et al. Streptococcus pneumoniae-associated human macrophage apoptosis after bacterial internalization via complement and Fcy receptors correlates with intracellular bacterial load. J Infect Dis. 2003;188:1119–31. pmid:14551881
- 35. Lee J, Kim J, Rhee D, and Pyo S. Streptococcus pneumoniae ClpP protease induces apoptosis via caspase-indepedent pathway in human neuroblastoma cells: cytoplasmic relocalization of p53. Toxicon. 2013;70:142–52. pmid:23643883
- 36. Orihuela C, Fillon S, Smith-Sielicki S, El Kasmi K, Gao G, Solulis K, et al. Cell wall-mediated neuronal damage in early sepsis. Infect Immun. 2006;74:3783–9. pmid:16790750
- 37. Geelen S, Bhattacharyya C, and Tuomanen E. The cell wall mediates pneumococcal attachment to and cytopathology in human endothelial cells. Infect Immun. 1993;61:1538–43. pmid:8454360