Abstract
Moraxella catarrhalis is a major cause of infectious exacerbations of chronic obstructive lung disease. In pulmonary epithelial cells, M. catarrhalis induces release of the pro-inflammatory cytokine interleukin (IL)-8, which plays a pivotal role in orchestrating airway inflammation.
The present study demonstrated that protein kinase (PK)C was activated by Moraxella infection and positively regulated M. catarrhalis-triggered nuclear factor (NF)-κB activation and subsequent IL-8 release. Activation of the PKC/NF-κB signalling pathway was found to be dependent on expression of the Moraxella-specific ubiquitous surface protein A2. In addition, it was shown that specific isoforms of PKC play differential roles in the fine-tuning of the M. catarrhalis-induced NF-κB-dependent gene expression through controlling il8 promoter activity. Inhibition of PKCα and ϵ with chemical inhibitors or using short interfering RNA-mediated gene silencing significantly suppressed, whereas inhibition of PKCθ increased, the M. catarrhalis-induced IL-8 transcription and cytokine release.
In conclusion, it was shown that Moraxella catarrhalis infection activates protein kinase C and its isoforms α, ϵ and θ, which differentially regulate interleukin-8 transcription in human pulmonary epithelial cells.
- Cytokine response
- Moraxella catarrhalis
- protein kinase C isoforms
- pulmonary epithelial cells
- ubiquitous surface protein A2
Chronic obstructive pulmonary disease (COPD) is one of the most common causes of morbidity and mortality worldwide with increasing prevalence 1. In COPD patients, Moraxella catarrhalis continues to emerge as a leading human mucosal pathogen 2. This Gram-negative diplococcus colonises the lower respiratory tract of up to 32% of adults with COPD and is associated with recurrent and persistent lower respiratory tract infections that cause ∼10% of all COPD exacerbations 3. Among the various putative virulence factors of this pathogen that have been identified to date, several proteinaceous antigens have been shown to protrude from the outer membrane of M. catarrhalis, including the ubiquitous surface protein (Usp)A1 and UspA2 proteins, which are expressed in most clinical isolates 2, 4, 5. In vitro mutant analysis indicates that UspA1 is involved in adherence to epithelial cells, whereas UspA2 is essential for serum resistance 6. However, little is known about the role of these proteins in the inflammatory immune responses of pulmonary epithelial cells. Inflammation in COPD is characterised by increased infiltration of neutrophils, lymphocytes and macrophages into the airways 7. In addition, bronchial epithelium also directly contributes to immune responses by secreting bioactive substances when exposed to pathogens or stimulation by inflammatory mediators 8. Among them, interleukin (IL)-8, a member of the CXC chemokine family, plays a pivotal role in regulating neutrophil and monocyte chemotaxis toward sites of infection, and in inducing airway inflammation 9, 10. The presence of microorganisms such as M. catarrhalis in the lower respiratory tract of COPD patients has been found to increase IL-8 release in bronchoalveolar lavage of COPD patients, which is associated with disease progression 11–13. Transcriptional regulation of IL-8 is controlled by a tight regulatory signalling network, most importantly involving the nuclear factor (NF)-κB. NF-κB comprises a family of Rel proteins that are normally retained in the cytoplasm by binding to NF-κB inhibitors (IκBs) 9, 14. Following cellular activation, phosphorylation of IκBα results in its ubiquitination and proteolysis, which lead to nuclear translocation and binding to the IL-8 κB-binding site within the il8 promoter 14. Subsequently, binding of the RNA polymerase II to the promoter determines the start of the IL-8 gene transcription 15, 16. Recently, the current authors demonstrated that M. catarrhalis-induced NF-κB activation results in IL-8 release by pulmonary epithelial cells 17. There are, however, considerable data to suggest that a number of additional signal transduction pathways are required for fine-tuning the NF-κB-dependent cytokine transcription 18. Protein kinase (PK)C has been recently implicated in the control of IL-8 release by IL-1β or tumour necrosis factor (TNF)-α 19, 20. Members of the PKC family are serine/threonine kinases that play ubiquitous roles in intracellular signal transduction 18. The PKCs comprise 12 closely related isoforms (isozymes), which are classified into three subfamilies on the basis of their domain structure and their ability to respond to Ca2+ and diacylglycerol (DAG). Classical PKC isoforms (α, βI, βII and γ) require calcium, DAG and phosphatidylserine for activation. Novel PKC isoforms, including PKCδ, ϵ and θ, require DAG and phosphatidylserine. Atypical PKC isoforms (ζ, ι and λ) and PKCμ require phosphatidylserine only and, in contrast to conventional and novel PKCs, do not respond to phorbol esters 21. The classical PKCs, PKCα and PKCβ, the novel PKCs, PKCδ, PKCϵ and PKCθ, and the atypical PKCζ have been shown to be expressed in the pulmonary epithelium 22–24. Individual PKC isozymes are activated by diverse stimuli and have been implicated to play distinct and, in some cases, opposing roles in the transduction of intracellular signals, often being overexpressed in disease states 19. However, the role of PKC and its isoforms in regulating epithelial NF-κB activation and IL-8 expression following M. catarrhalis infection has not yet been investigated. Therefore, the present work studied the involvement of Moraxella UspA1 and UspA2 and different PKC isoforms expressed in pulmonary epithelial cells in M. catarrhalis-induced IL-8 production. The present data demonstrate that expression of the Moraxella UspA2 was important for activating the PKC/NF-κB signalling pathway leading to IL-8 release. Moreover, it was found that the PKC isoforms PKCα, PKCϵ and PKCθ are involved in the M. catarrhalis-induced IL-8 release by differentially regulating the transcription at the il8 promoter.
MATERIAL AND METHODS
Bacterial strains
The M. catarrhalis strain 25238 (serotype A) was purchased from the American Type Culture Collection (ATCC; Manassas, VA, USA). M. catarrhalis wild-type strain O35E (Serotype A) and the UspA1- and UspA2-deficient mutant strains O35E.1 and O35E.2 were kindly provided by E. Hansen (University of Texas Southwestern Medical Center, Dallas, TX, USA). Antimicrobial supplementation for the M. catarrhalis mutant O35E.1 and O35E.2 involved kanamycin (15 μg·mL−1). M. catarrhalis was grown overnight at 37°C on brain–heart infusion (BHI) agar (Dibco Laboratories, BD, Heidelberg, Germany) supplemented with 5% heated sheep blood as previously described 17, 25, 26. For infection experiments, single colonies of bacterial overnight cultures were expanded by resuspension in BHI broth and incubation at 37°C for 2–3 h to mid-log phase (absorbance at 405 nm 0.4–0.6). Subsequently, bacteria were harvested by centrifugation, resuspended in cell culture medium without antibiotics and adjusted to an optical density (OD) of 0.3 (equivalent 1×106 colony-forming units (cfu)·mL−1) at 405 nm and used for infecting epithelial cells at the indicated doses. Cells were infected with M. catarrhalis at doses 0.1–10 cfu·mL−1. To investigate inactivated M. catarrhalis, bacterial suspension were treated by heat (95°C, 30 min) and subsequent viability was ruled out by plating the suspension on BHI agar for 12 h.
Cell lines
Human primary bronchial epithelial cells (PBECs) were obtained by endobronchial brushing during bronchoscopy of normal human volunteers. The study was approved by the local ethics committee (Charité – Universitätsmedizin Berlin, Berlin, Germany). PBECs were plated in bronchial epithelial cell basal medium supplemented with human epidermal growth factor (0.5 ng·mL−1), insulin (5 μg·mL−1), transferrin (10 μg·mL−1), epinephrine (0.5 μg·mL−1), triiodothyronine (6.5 ng·mL−1), gentamicin (50 μg·mL−1), amphotericin B (50 ng·mL−1), bovine pituitary extract (52 μg·mL−1), retinoic acid (0.1 ng·mL−1) and cultured on tissue culture plates coated with human collagen (Vitrogen 100; Cohesion Technologies, Palo Alto, CA, USA). All experiments were performed with cells in passage 2. The bronchial epithelial cell line BEAS-2B was a kind gift from C. Harris (National Institutes of Health, Bethesda, MD, USA). BEAS-2B cells were grown in Keratinocyte-SFM (Gibco BRL Life Technologies, Paisley, UK) supplemented with 2 mM l-glutamine, penicillin (100 U·mL−1) and streptomycin (100 μg·mL−1), as previously described 17. The cells were used between passages 10–35. A549 epithelial cells (type-II alveolar cells) were obtained from the ATCC and cultured in Dulbecco’s modified Eagle medium (DMEM; Gibco BRL Life Technologies) supplemented with 10% foetal calf serum (FCS), 200 mM l-glutamine and streptomycin (100 μg·mL−1), as previously described. The NF-κB-dependent reporter cell line, A549 6Btkluc, was a kind gift of R. Newton (University of Warwick, Coventry, UK). These cells contain a stably integrated plasmid with three tandem repeats of the sequence 5′-AGCTTACAAGGGATTTCCGCTGGGGACTTTCCAGGGA-3′, which contains two copies of the decameric NF-κB binding site upstream of a minimal thymidine kinase promoter (-105–51) driving a luciferase gene 27. Cells were grown in medium without antibiotic supplements 12 h prior to the experiment. To assess the multiplicity of infection (MOI) per epithelial cell infected with M. catarrhalis, cell counts of confluent BEAS-2B layers per well of a 24-well plate were performed after trypsination in a Neubauer cytometer (Hecht Assistant, Sondheim, Germany). Cell counts were ∼5×105 cells·well−1. Counting of PBEC and A549 cells·well−1 gave similar results. Experiments were performed in 500 μL volume per well. Therefore, the infection doses of 106 cfu·mL−1 M. catarrhalis corresponded with an MOI of 1.
Materials
DMEM, FCS, trypsin-EDTA-solution, CA-650 and antibiotics were obtained from Life Technologies (Karlsruhe, Germany). Protease inhibitors, Triton X-100 and Tween-20 were purchased from Sigma (Munich, Germany), and calphostin C, Gö6976, PKC inhibitor 20-28, PKCβ inhibitor, Rottlerin, PKCϵ inhibitor peptide, PKCθ myristoylated pseudosubstrate inhibitor and PKCζ pseudosubstrate inhibitor were purchased from Calbiochem-Merck (Darmstadt, Germany) and dissolved in dimethylsulphoxide. Phorbol-12-myristate-13-acetate (PMA) was obtained from Calbiochem-Merck (Darmstadt, Germany). All other chemicals used were of analytical grade and obtained from commercial sources.
IL-8 ELISA
IL-8 secreted by PBECs, BEAS-B and A549 cells was measured using a commercially available sandwich-ELISA kit, according to the manufacturer's protocol (R&D Systems, Wiesbaden, Germany), as described previously 17.
RT-PCR analysis
RNA was extracted using RNeasy Mini kit (Qiagen, Hilden, Germany), according to the manufacturer's instructions. All primers were purchased from TIB MOLBIOL (Berlin, Germany). PCR products were analysed on 1.5% agarose gels, stained with ethidium bromide and subsequently visualised. To confirm equal loading, PCR for glyceraldehyde-3-phoshate dehydrogenase was performed in parallel.
PKC assay
The PKC assay StressXpress (Stressgen Bioreagents Corp., Victoria, BC, Canada) was used to detect PKC activity, as described previously 28. BEAS-2B and A549 cells were stimulated with M. catarrhalis. A cell extract containing activated PKC was collected and processed for PKC activity by ELISA according to manufacturer’s instructions.
Western blot
Transfection efficiency of short interfering (si)RNA for PKCα, PKCϵ and PKCθ, the phosphorylation of myristoylated, alanine-rich C-kinase substrate (MARCKS), and PKC isotype translocation to membranes was assessed by Western blot analysis. Briefly, BEAS-2B cells were infected as indicated and lysed in buffer containing Triton X-100, subjected to SDS-PAGE and blotted on Hybond-ECL membrane (Amersham Biosciences, Freiburg, Germany). Immunodetection of target proteins was carried out with specific antibodies. In all experiments, actin or extracellular signal-regulated kinase 2 was determined simultaneously on the same membrane by using Odyssey Infrared Imaging System (LI-COR Biosciences GmbH, Bad Homburg, Germany) to confirm equal protein load as described previously 17, 28.
RNA interference in A549 cells and bacterial infection
Control nonsilencing siRNA (sense UUCUCCGAACGUGUCACGUtt, antisense ACGUGACACGUUCGGAGAAtt), siRNA targeting PKCα (sense UAGUUGAUCUCGCGGACGAtt, antisense UCGUCCGCGAGAUCAACUAtt), siRNA targeting PKCϵ (sense CGAUUCCAUCACUAUCCAUtt, antisense AUGGAUAGUGAUGGAAUCGtt) and PKCθ-siRNA (sense AAACCACCGTGGAGCTCTACTtt, antisense AAGAGCCCGACCTTCTGTGAAtt) were purchased from MWG (Ebersberg, Germany). A549 cells were transfected by using Amaxa NucleofectorTM (Amaxa, Köln, Germany) according to the manufacturer's protocol, (NucleofectorTM Solution V, NucleofectorTM program G-16) with 2 μg siRNA per 106 cells.
Chromatin immunoprecipitation
BEAS-2B cells were stimulated, culture medium was removed, and 1% formaldehyde was added as previously described 17. After 1 min, the cells were washed in ice-cold 0.125 M glycin in PBS, then rapidly collected in ice-cold PBS, centrifuged and washed twice with ice-cold PBS. The cells were lysed in chromatin immunoprecipitation (ChIP) radioimmunoprecipitation assay (RIPA) buffer (10 mM Tris, pH 7.5, 150 mM NaCl, 1% Nonidet P-40, 1% desoxycholic acid, 0.1% SDS, 1 mM EDTA, 1% aprotinin), and chromatin was sheared by sonication. The samples were cleared by centrifugation and the supernatants were stored in aliquots at -80°C until further use. NF-κB p65 (C-20) antibodies and polymerase II (N-20) antibodies were purchased from Santa Cruz Biotechnology Inc. (Heidelberg, Germany). Immunoprecipitations from soluble chromatin were carried out overnight at 4°C. Immune complexes were collected with protein A/G-agarose (Santa Cruz Biotechnology Inc.) for 60 min and washed thoroughly with RIPA buffer and high salt buffer (2 M NaCl, 10 mM Tris, pH 7.5, 1% Nonidet P-40, 0.5% desoxycholic acid, 1 mM EDTA). Immune complexes were extracted in elution buffer by shaking the samples for 15 min at 180×g at 30°C. They were then digested with RNase for 30 min at 37°C. After proteinase K digestion for 6 h at 37°C and 6 h at 65°C, DNA was extracted using a PCR purification kit (Qiagen). il8 promoter DNA was amplified by PCR using Hot Star Taq (Qiagen) DNA polymerase. PCR products were separated by agarose gel electrophoresis and detected by ethidium bromide staining. Equal amounts of input DNA was controlled by gel electrophoresis. The following promoter-specific primers for il8 were used: sense, 5′-AAG AAA ACT TTC GTC ATA CTC CG-3′; antisense, 5′-TGG CTT TTT ATA TCA TCA CCC TAC-3′.
Statistical analysis
Data in figures 1⇓–⇓⇓⇓⇓⇓7⇓ are shown as mean±sem of at least three independent experiments, as indicated. Main effects were then compared via Newman–Keul’s post-test. Stimulatory effects of M. catarrhalis as well as inhibitory effects of siRNA used were statistically evaluated employing a paired t-test.
RESULTS
M. catarrhalis-induced IL-8 transcription and release in bronchial epithelial cells
To study the host–pathogen interaction between M. catarrhalis and pulmonary epithelium in vitro, the present study used the SV-40 T-antigen-transformed bronchial epithelial cell line BEAS-2B as cell culture model, as well as PBECs closely resembling their in vivo state and thus offering an important tool for the study of PBEC activation in vitro. Moreover, BEAS-2B cells have been shown to behave similarly to the primary culture of PBEC cells in many aspects of their cellular functions 17, 26, 29. Incubation of BEAS-2B cells and PBECs with M. catarrhalis strain O35E (107 cfu·mL−1 for 60, 120 and 240 min) produced a time-dependent increase in IL-8 transcription (fig. 1a⇑ and b). Infection of BEAS-2B cells with M. catarrhalis strain ATCC 25238 induced an equally strong IL-8 protein release when compared with strain O35E (fig. 1c⇑). A dose-dependent IL-8 release could also be demonstrated by PBECs infected with Moraxella strain O35E (fig. 1d⇑). In order to investigate the influence of bacterial viability on IL-8 release, M. catarrhalis strain O35E (1×107 cfu·mL−1) was heat-inactivated prior to infection of BEAS-2B cells. No significant difference was found in the IL-8 release of BEAS-2B cells induced by inactivated bacteria when compared with infection with viable Moraxella at the same doses (fig. 1e⇑).
M. catarrhalis increased PKC activity in bronchial epithelial cells
To further explore whether activation of PKC might play a crucial role in M. catarrhalis-induced cell activation, BEAS-2B cells were infected for 60, 120 and 240 min with M. catarrhalis (107 cfu·mL−1) and a two- to four-fold increase in PKC activity was found (fig. 2a⇑). A 2-h stimulation of the cells with strain O35E resulted in an increase of PKC activity that was comparable to that observed after infection with strain ATCC 25238 or a 1-h stimulation of the cells with PMA (160 nM), a strong inducer of PKC activity (fig. 2a⇑). M. catarrhalis-induced PKC activation was confirmed by immunoblot showing a time-dependent increase of phophorylation of MARCKS, one major substrate of PKC in strain O35E-infected cells (fig. 2b⇑) 30.
M. catarrhalis-induced IL-8 release and PKC activation in bronchial epithelium is dependent on UspA2 but not on UspA1 expression
In order to investigate the role of M. catarrhalis proteins UspA1 and UspA2 for the IL-8 release of pulmonary epithelial cells, BEAS-2B cells were infected with either the M. catarrhalis wild-type strain O35E, the UspA1-deficient mutant strain O35E.1 or the UspA2 deficient mutant strain O35E.2 for 16 h. As shown in figure 3a⇑, IL-8 protein release induced by the strain O35E.1 did not differ from IL-8 secretion induced by the wild-type strain O35E. In contrast, strain O35E.2 induced significantly lower IL-8 secretion suggesting that UspA2-epithelial cell interaction is important for the M. catarrhalis-induced IL-8 release. Next, the impact of UspA1 and UspA2 expression on the activation of PKC was investigated by incubating the cells with either the O35E wild-type strain, the UspA1-deficient mutant strain O35E.1 or the UspA2-deficient mutant strain O35E.2. It was found that Moraxella expression of UspA1 was not involved in PKC activation of BEAS-2B cells, whereas PKC activity seemed to be dependent on UspA2 (fig. 3b⇑). To exclude possible discrepancies in growth rates of the used Moraxella strains, the growth of the wild-type and mutant strains of M. catarrhalis was compared by incubating the bacterial suspensions at an initial OD of 0.01 (at 405 nm) in BHI broth and at 37°C with shaking. Growth was followed by means of OD measurements. Data were verified by different cfu countings at different OD of M. catarrhalis suspensions. Analogous to the results of Aebi et al. 31 no differences were found between the strains tested (data not shown). Therefore, these data suggest that UspA2 but not UspA1 is important for M. catarrhalis-induced PKC activation and IL-8 release in pulmonary epithelial cells.
M. catarrhalis-induced IL-8 release is differentially regulated by the PKC isoforms PKCα, PKCϵ and PKCθ
To further investigate the contribution of PKC and its different isoforms to M. catarrhalis-induced IL-8 release, BEAS-2B cells were pre-incubated with the pan-PKC inhibitors calphostin C or staurosporin for 1 h, and subsequently infected with Moraxella strain O35E. Induction of IL-8 release was assessed by ELISA. As shown in figure 4a⇑, both inhibitors lead to a reduction of IL-8 release, suggesting an involvement of PKC in the IL-8 production in response to Moraxella infection. Next, the role of different PKC isoforms known to be expressed in pulmonary epithelium was studied. Therefore, confluent BEAS-2B cells were pre-incubated with chemical PKC isoform inhibitors blocking PKCαβ (Gö6976, PKC 20/28), PKCβ (PKCβ inhibitor), PKCδ (rottlerin), PKCϵ (PKCϵ-translocation inhibitor peptide), PKCθ (PKCθ pseudosubstrate inhibitor, myristoylated) or PKCζ (PKCζ pseudosubstrate inhibitor, myristoylated) before infecting the cells with M. catarrhalis for 16 h. As shown in figure 4b⇑, blocking of PKCα and PKCϵ reduced M. catarrhalis-induced IL-8 production. In contrast, inhibiton of PKCθ led to a significant increase of the IL-8 response. Inhibition of other PKC isotypes did not affect IL-8 release as exemplarily shown for PKCβ and PKCζ (fig. 4b⇑ and data not shown). The chemical inhibitors used in these experiments did not reduce epithelial cell numbers, induce morphological signs of cytotoxicity, or alter bacterial growth within the time-frame tested (data not shown).
Next, the relevance of PKCα, PKCϵ and PKCθ for IL-8 expression was analysed in more detail using siRNA-mediated gene silencing. However, viability of BEAS-2B cells was significantly affected during the gene knock-out procedure (data not shown). Therefore, the pulmonary epithelial cell line A549 was used, which the current authors utilised previously with success for efficient target gene silencing 26, 32. At first, involvement of the PKC isoforms PKCα, PKCϵ and PKCθ in Moraxella-induced IL-8 release was confirmed in this cell line by making use of the chemical inhibitors described previously in this article (fig. 5a⇑). Next, siRNA was tested for ability to reduce expression of the target proteins and found that the PKCα-, PKCϵ- and PKCθ-specific siRNA substantially reduced protein levels of the corresponding kinase isotypes (fig. 5b–d⇑). Moreover, knock-down of PKCα and PKCϵ by siRNA decreased the IL-8 production induced by O35E compared with cells transfected with control siRNA (fig. 5e⇑ and f). In contrast, transfection of PKCθ siRNA increased the Moraxella-induced IL-8 response in A549 cells (fig. 5g⇑). Therefore, the results confirm the different regulatory functions of these PKC isoforms for the M. catarrhalis-induced IL-8 release.
M. catarrhalis activates PKCα, PKCϵ and PKCθ activation in pulmonary epithelial cells
The translocation of kinases from cytosol to the cellular membrane is known to be an indicator for activation of these PKC isoforms 33, 34. In order to confirm activation of the PKC isotypes PKCα, PKCϵ and PKCθ, translocated PKC isotypes were detected in the cell membrane following M. catarrhalis infection by Western blotting. As shown in figure 5a⇑, by using a pan-specific PKC antibody, PKC strongly translocated from the cytosol to the cell membrane of infected cells. Similarly, translocation to the cell membrane could also be shown for PKCα, PKCϵ and PKCθ isoforms indicating activation of these isoforms by following Moraxella infection in pulmonary epithelium (fig. 5b–d⇑).
PKC and UspA2 participate in M. catarrhalis-induced NF-κB activation
Recently, the current authors have demonstrated that M. catarrhalis-induced IL-8 release is dependent on the activation and translocation of NF-κB and its binding to the il8 promoter 17. Previous studies have demonstrated that activation of PKC by PMA and TNF-α were required for NF-κB activation in various cell types 35. To assess the importance of PKC for M. catarrhalis-induced NF-κB activation, the NF-κB-dependent reporter cell line, A549 6Btkluc, was infected with M. catarrhalis for different time periods. Prior to the infection, cells were incubated with the pan-PKC inhibitor calphostin C. As shown in figure 7a⇑, inhibition of PKC significantly reduced NF-κB activation measured by NF-κB luciferase activity. Moreover, infection of the cells with the UspA2-deficient mutant strain O35E.2 also resulted in a decreased NF-κB activation when compared with the wild-type strain (fig. 7a⇑) and to the UspA1-deficient mutant strain O35E.1 (data not shown).
The PKC isoforms PKCα, PKCϵ and PKCθ differentially control IL-8 expression in M. catarrhalis-infected pulmonary epithelial cells
Following activation, NF-κB translocates from the cytosol to the nucleus, to bind the IL-8/κB-binding site of the il8 promoter and induce transcription 14. To characterise the role of the different PKC isoforms for the M. catarrhalis-induced transcription at the il8 promoter, ChIP studies were employed. It was investigated whether M. catarrhalis-induced NF-κB activation in pulmonary epithelial cells led to an increased binding of RNA polymerase II (Pol II) at the il8 promoter to indicate start of gene transcription 36. As shown in figure 7b⇑, infection of the BEAS-2B cells with M. catarrhalis resulted in an increased binding of Pol II to the il8 promoter, confirming previous results of an increased IL-8 transcription induced by this pathogen (fig. 7b⇑) 17. To investigate the role of PKCα, PKCϵ and PKCθ in this process, BEAS-2B cells were pre-incubated for 60 min with the specific inhibitors of PKCα (Gö6976), PKCϵ (PKCϵ-translocation inhibitor peptide) or PKCθ (PKCθ pseudosubstrate inhibitor) before infection with M. catarrhalis (107 cfu·mL−1) for an additional 120 min. Pre-incubation of the cells with PKCζ inhibitor did not influence the M. catarrhalis-induced IL-8 release, and was used as internal control. The present results clearly show that the M. catarrhalis-induced recruitment of the Pol II to the il8 promoter was significantly reduced after inhibition of PKCα and PKCϵ (fig. 7b⇑). In contrast, inhibition of PKCθ resulted in an increased binding of Pol II to the promoter in response to Moraxella infection, suggesting that M. catarrhalis-induced IL-8 transcription is negatively regulated by this PKC isoform (fig. 7b⇑). Inhibition of PKCζ did not change the binding pattern of Pol II when compared with the untreated but Moraxella-infected cells.
DISCUSSION
M. catarrhalis plays a pathological role in COPD exacerbations by stimulating the secretion of pro-inflammatory mediators, such as IL-8 17, 26. In the present study, it was demonstrated that the M. catarrhalis-induced NF-κB-dependent IL-8 release is controlled, at least in part, by activation of PKC. In addition, it was found that several PKC isoforms expressed in pulmonary epithelium were differentially involved in M. catarrhalis-induced IL-8 secretion 24. Chemical inhibition, as well as siRNA-mediated gene silencing of PKCα and ϵ, significantly suppressed the M. catarrhalis-induced IL-8 release, whereas inhibition of PKCθ increased this release, suggesting an opposing effect of these isoforms. The activating effect of PKCα and ϵ on M. catarrhalis-induced IL-8 release, as well as the inhibiting effect of PKCθ, was accompanied by a translocation of these PKC isoforms from the cytosol to the cell membrane fraction. Other PKC isoforms expressed in pulmonary epithelium revealed no effects on M. catarrhalis-induced IL-8 production. Furthermore, it was demonstrated that the differential regulation of the PKC isoforms α, ϵ and θ was mediated through controlling the binding of the polymerase II to the il8 promoter of respiratory epithelial cells. PKC activation was found to be dependent on the expression of the M. catarrhalis-specific outer membrane protein UspA2. Cells infected with the UspA2-deficient M. catarrhalis mutant strain O35E.2 showed a decreased PKC activity resulting in a decreased NF-κB activation and IL-8 release when compared with infection with the wild-type strain or with the UspA1-deficient mutant strain O35E.1. The UspA2 protein is a putative autotransporter macromolecule that forms relatively short, filamentous projections on the surface of M. catarrhalis cells and is a target for biologically active antibodies 6, 37. In contrast to UspA1, it is not functioning as adhesin but is directly involved in the expression of serum resistance found in UspA2-positive Moraxella strains 5, 38, 39. In addition, the results of the present study suggest that the UspA2-mediated activation of PKC controlling the NF-κB-dependent IL-8 release may represent a new virulence mechanism of Moraxella UspA2 in respiratory epithelial cells. The main limitation of the present investigation is that it is an in vitro study making use of human bronchial epithelial cells. However, studying the mechanisms of the pathogenesis of this strictly human-specific pathogen is difficult because of the lack of simple animal models that mimic the pathogen–host interactions seen in humans. Therefore, as documented in several publications, in vitro cell culture methods provide a useful alternative for the investigation of the interactions between Moraxella, or other potentially pathogenic microorganisms, and the host pulmonary epithelium that occur during infection 13, 26, 29.
Recent reports support a role for PKC in the regulation of pro-inflammatory gene expression in airway epithelial cells. PKC activation by PMA has been shown to stimulate NF-κB activation and to induce granulocyte-macrophage colony-stimulating factor (GM-CSF) expression in A549 cells and human bronchial epithelial cells 40, 41. In addition, several studies have demonstrated airway epithelial cell TNF-α responses to be at least partially sensitive to PKC inhibitors. In human bronchial epithelial cells, cigarette smoke-induced, as well as C5a-mediated, IL-8 expression 42 and TNF-α-induced intercellular adhesion molecule-1 expression 43 were blocked by calphostin C, and TNF-α-induced GM-CSF expression was inhibited by the pan-PKC blocker staurosporine 44. In addition, Hewson et al. 45 reported that PMA-induced expression of the airway mucins MUC5B and MUC5AC by airway epithelial cells were attenuated after treatment of the cells with the pan-PKC inhibitor calphostin C. Although these studies did not determine the PKC isoenzymes responsible for phorbol ester-induced responses, they are consistent with the findings of the present study, that PKC isoforms may regulate airway epithelial cell gene expression in an NF-κB-dependent manner. The PKC family has long been known to play pivotal roles in controlling inflammation, cell growth, differentiation and apoptosis by regulating the activity of transcription factors such as NF-κB 19, 46. However, their biological effects exerted by the activation of PKC may be stimulus- as well as cell- or tissue-specific. In epithelial cells, little is known concerning pathogen-induced specific regulation of PKC, and in particular PKC isoforms, and with regard to NF-κB-dependent pro-inflammatory cytokine transcription. Candida albicans was found to upregulate cyclooxygenase (COX)-2 through activation of PKC in epithelial cells 47. Moreover, pathogen-related expression of COX-2 in Helicobacter pylori- or Staphylococcus aureus-infected epithelial cells was shown to be mediated by PKC activation 48, 49. The current authors recently demonstrated that COX-2 expression and subsequent PGE2-synthesis induced by Legionella neumophila infection of the alveolar epithelial cell line A549 was reliant on PKCα and NF-κB activation in lung epithelial cells 28. As shown in the present study, infection of pulmonary epithelial cells with M. catarrhalis activated PKC, which triggered NF-κB activation resulting in IL-8 transcription and release. Moreover, the current authors found that the PKC isoforms PKCα, PKCϵ and PKCθ were involved in the M. catarrhalis-induced IL-8 release by differentially regulating IL-8 transcription. Therefore, the results suggest a specific regulation of PKC isoforms with regard to IL-8 induction in Moraxella-infected pulmonary epithelial cells.
The levels and different compositions of the protein kinase C isoforms represent a tissue-dependent balance between expression and degradation, which may be altered in settings of cellular stress, such as acute or chronic inflammation or smoking 50. Changes in the expression of protein kinase C isoforms may further influence the inflammatory immune response following Moraxella catarrhalis infection. However, limited information exists about protein kinase C in human pulmonary epithelial cells and further studies are needed to analyse the composition of protein kinase C isoforms in normal and diseased pulmonary epithelium. A better understanding of the mechanisms of how individual protein kinase C isozymes contribute to the pathogenesis of bacterial infections in chronic obstructive pulmonary disease patients may provide a new therapeutic target to combat this chronic inflammatory disease.
Support statement
The study received financial support from the University Hospitals of Leicester NHS Trust.
Statement of interest
None declared.
Acknowledgments
We greatly appreciate the excellent technical assistance of J. Hellwig, F. Schreiber and D. Stoll (Charité – Universitätsmedizin Berlin). Part of this work will be included in the doctoral thesis of L. Maqami (Charité – Universitätsmedizin Berlin).
- Received August 9, 2007.
- Accepted December 11, 2007.
- © ERS Journals Ltd