Background
Chronic obstructive pulmonary disease (COPD) is characterized by progressive alveolar destruction and inflammation of the airways caused by noxious particles or gases. The precise mechanisms behind these pathological changes remain unclear, although oxidative stress, elastinolytic activity, and apoptosis of lung parenchymal cells are believed to contribute to the pathogenesis of the disease [
1]. Current anti-inflammatory therapies are poorly effective in maintaining lung function and symptoms in COPD [
2], therefore, new anti-inflammatory therapeutic strategies are needed.
It has been reported that there are increased numbers of tertiary lymphoid follicles in the lungs of patients with COPD [
3,
4], and that these follicles are organized structures with a B-cell core, T cells in the periphery, and dendritic cells capable of antigen presentation [
5‐
7]. Such observations have led to the hypothesis that COPD has an autoimmune component [
8‐
10].
IL-17 is produced by inflammatory cells and targets structural cells such as epithelial cells, fibroblasts, and smooth muscle cells. The IL-17 family comprises six members (IL-17A to IL-17 F). IL-17A and IL-17 F display high sequence homology and can be secreted as homodimers, as well as IL-17A/F heterodimers, by both mouse and human cells [
11]. These cytokines are produced by a subset of CD4+ lymphocytes known as T-helper (Th) 17 cells [
12] and contribute to the development of autoimmune disease [
13,
14]. IL-17A has been shown to induce the production of chemokines and inflammatory cytokines such as keratinocyte-derived chemokine (KC), macrophage inflammatory protein 2 (MIP-2), and IL-1β, that promote neutrophilic inflammation [
15‐
17].
Recently, IL-17 has been shown to be associated with the development of lung inflammatory diseases such as COPD [
16,
18,
19]. Production of IL-17A was increased in the bronchial submucosa and subepithelium of COPD patients [
18,
19]. Airway smooth muscle strips from COPD patients expressed IL-17RA and responded to IL-17 by inducing IL-8 production [
16]. However, other studies failed to show any involvement of IL-17 in the development of COPD. Numbers of IL-17A+ cells in the airways of COPD patients were increased compared to healthy control subjects, but were not increased compared to smoking control subjects, and were not associated with increased neutrophilic inflammation [
20]. Expression of IL-17 receptors in COPD was not different compared to non-COPD lung disease [
21].
Nonetheless, the role of IL-17A in the pathogenesis of COPD remains controversial and often has been based on indirect evidence. To address this question, we instilled porcine pancreatic elastase (PPE) in the trachea which first induces lung inflammation and subsequently results in alveolar wall destruction [
22,
23]. These pathological changes closely mimic those seen in human emphysema. Here, we investigated the role of IL-17 in the development of elastase-inducible emphysema using IL-17A-deficient (IL-17A−/−) mice.
Methods
Animals and treatment
C57BL/6 wild-type (WT) mice were obtained from Charles River Japan. IL-17A−/− mice were generated and backcrossed to C57BL/6 mice for 10 generations [
24]. Ten week-old female WT and female IL-17A−/− mice were used in experiments.
WT and IL-17A−/− mice received 3.5u of PPE (Sigma-Aldrich, St. Louis, MO, USA) in 30 μl of saline by intratracheal instillation on day 0 after being anesthetized with isoflurane. As control groups, WT and IL-17A−/− mice received 30 μl of saline on day 0. To evaluate emphysematous changes in the lungs, lung function was measured, and lung histology and morphometric measurements of air space size were assessed 21 days after PPE administration. On days 2, 4, and 21 after PPE administration, lungs were lavaged for analysis of cellular composition in bronchoalveolar lavage (BAL) fluid.
To determine the timing of production of IL-17A in the airways, WT mice received PPE, and then lung tissue was taken at different time points (12 hours, 1 day, 2 day, 4 day, and 21 days) after PPE administration, and the levels of IL-17A in lung homogenates were measured.
To assess the numbers of IL-17A and IFN-γ producing cells, WT mice received PPE or saline on day 0, and lung cells were isolated and IL-17A-producing cells were assessed by flow cytometry on day 2 after PPE administration.
All experiments were performed in accordance with the National Institutes of Health guidelines. All protocols were approved by the Institutional Animal Care and Use Committees of Okayama University (Okayama, Japan).
Determination of static lung compliance (Cst)
21 days after PPE administration, lung function was measured in tracheostomized mice using a computer-controlled small-animal ventilator (flexiVent; SCIREQ, Montreal, Canada) as described previously [
25‐
27]. In brief, the mice were anesthetized with sodium pentobarbital (Kyoritsu Seiyaku, Tokyo, Japan) by intraperitoneal injection (12.5 mg/kg = 250 μl/mouse). The mice were tracheostomized with a 5 mm section of metallic tubing (= 18 G cannula), ventilated at 180 breaths/min with a tidal volume of 4 ml/kg and positive end-expiratory pressure of 3 cm H
2O, and Cst was assessed. All data points were determined by flexiVent software (version 5.0).
Lung histology and morphometric measurements of air space size
On day 21 after PPE administration, mice were killed by intraperitoneal injection of pentobarbital sodium and lungs were inflated and fixed by intratracheal instillation of 10% formalin at a constant pressure of 25 cmH
2O. The tissue was then embedded in paraffin and 2-μm thick sections were stained with hematoxylin and eosin (H&E). Air space enlargement was quantified by mean linear intercept (Lm) calculations in 20 randomly selected fields [
28].
BAL
On days 2, 4, and 21 after PPE administration, lungs were lavaged via the tracheal tube with Hanks’ balanced salt solution (2 × 1 ml, 37°C). The volume of the collected BAL fluid was measured in each sample, and the number of cells in the BAL fluid was counted. Cytospin slides were stained and differentiated in a blinded fashion by counting at least 200 cells under light microscopy [
29].
Measurement of cytokines and chemokines
KC, MIP-2 and IL-1β levels in the BAL fluid, and IL-17A levels in the supernatants of homogenized lungs were measured by ELISA as previously described [
30]. For preparation of lung homogenates, lung tissue was frozen at −70°C immediately after euthanasia. Lung tissue was mixed with a PBS-0.1% Triton-X100 solution containing proteinase inhibitors at a 1:2.5 ratio of weight per volume (BD Biosciences, San Diego, CA, USA). The specimens were homogenized and then centrifuged at 15,000 rpm for 15 min. The supernatants were frozen at −70°C until analysis [
30]. All cytokine and chemokine ELISAs were performed according to the manufacturer’s directions (R&D Systems, Minneapolis, MN, USA). The limits of detection were 5 pg/ml for IL-17A, 2 pg/ml for KC, 1.5 pg/ml for MIP-2, and 3 pg/ml for IL-1β.
Flow cytometry
Lung cells were isolated as previously described following collagenase digestion [
30]. Intracytoplasmic cytokine staining was performed as previously described [
31,
32]. Briefly, after purification, cells were stimulated in vitro with phorbol myristate acetate (Sigma-Aldrich) and ionomycin (Sigma-Aldrich). Cells were stained for cell surface markers with PerCP-conjugated anti-CD4 (BD Biosciences). Then, cells were stained with PE-conjugated anti-IL-17A (BD Biosciences) or FITC-conjugated anti-IFN-γ (BD Biosciences), and analyzed on MACS Quant flow cytometer (Miltenyi Biotec, Auburn, CA, USA) with FlowJo software (TreeStar, Ashland, OR, USA). The numbers of cytokine-producing CD4 T cells per lung were calculated from the percentages of cytokine-producing cells and the numbers of CD4 T cells isolated from the lung.
Statistical analysis
All results were expressed as the means ± standard error of the means (SEM). Statistical significance was detected by using 1-way ANOVA, followed by post-hoc analysis with the Tukey-Kramer test for comparisons between multiple groups. As measured values may not be normally distributed due to the small sample sizes, nonparametric analysis, Mann–Whitney U-test, was used for comparison of the numbers of cytokine-producing cells. Significance was assumed at p values of < 0.05.
Discussion
It has been reported that Th17 cells are a critical component of the adaptive immune response and IL-17 has been implicated in chronic inflammatory and autoimmune diseases [
13,
14]. There has been much interest in the role of the adaptive immune response in COPD since COPD in humans is associated with the development of lymphoid follicles in the lung [
3,
4]. Moreover, patients with COPD have evidence of anti-elastin antibodies and Th1 responses, suggesting an autoimmune component [
8,
9]. Recently, numbers of IL-17A+ cells in the airways [
18‐
20,
36] and peripheral blood [
37] of COPD patients have been reported to be increased. These studies suggested an association between Th17 and COPD, however, the role for IL-17A in disease development is not defined.
In the present study, to elucidate the role of IL-17A in the development of emphysema, we investigated PPE-induced initial inflammation and subsequent late phase emphysematous change in IL-17A−/− and WT mice. We demonstrated that both the PPE-induced acute phase inflammation and the late phase emphysematous changes seen in WT mice were attenuated in IL-17A−/− mice. Increased levels of neutrophil-related chemokines such as KC, MIP-2 and IL-1β seen in the BAL fluid of WT mice were also significantly reduced in IL-17A−/− mice following PPE administration. These data, for the first time, indicated that IL-17A may play a role in the elastase-induced pulmonary pathology.
We observed that levels of IL-17A in the lungs were increased in the acute phase following PPE treatment. The numbers of IL-17A producing cells in the lung were also increased following PPE treatment. Thus, elastase administration leads to increases in both IL-17-producing cells and levels of IL-17A. These results were consistent with the observations showing that IL-17A expressing cells were increased in the airways of COPD patients. For example, numbers of IL-17A+ cells in the bronchial submucosa were increased in COPD compared to smokers without COPD and nonsmoking control subjects [
19]. The sputum concentrations of IL-17A in COPD were increased compared to patients with asthma [
19]. It has also been reported that cigarette smoke extract had an adjuvant effect on CD4 T cell activation and differentiation to Th17 cells in vitro [
38]. These data suggest that smoking induces both IL-17A secretion in the airways and increases differentiation of Th17 cells.
IL-17A has been shown to accumulate [
39] and activate neutrophils [
40], and enhance epithelial production of IL-8 [
41]. It has also been reported that IL-17A acts directly on epithelial cells, airway fibroblasts and smooth muscle cells to induce the secretion of neutrophil-recruiting chemokines [
42]. Airway smooth muscle strips from COPD patients expressed IL-17RA and responded to IL-17A by inducing IL-8 production [
16]. Rodents lack a direct homologue of IL-8, but the chemokines KC and MIP-2 are regarded as functional homologues and have been found to contribute to the pathology of a number of neutrophil-dependent animal models of disease [
43]. In the present study, levels of KC and MIP-2 were increased in WT mice following PPE treatment, and these levels were lower in IL-17A−/− mice. Thus IL-17A may induce neutrophil chemotactic factor production, KC and MIP-2, and contribute to neutrophilic airway inflammation following PPE treatment.
Th17 cells have been shown to produce more inflammatory cytokines, such as IL-1β, compared with regulatory T cells and other T-helper cells [
44]. In the present study, the levels of IL-1β in WT mice were increased 4 days after intratracheal PPE instillation and levels were significantly lower in IL-17A−/− mice. Although the link between acute inflammatory changes and the subsequent development of emphysematous changes requires further investigation, it is likely that in addition to KC and MIP-2, increased levels of proinflammatory cytokines such as IL-1β prolong and enhance acute inflammation and contribute to later emphysema. In this way, IL-17A-mediated pathways might play a central role in the pathophysiological events.
Chen et al. recently reported that IL-17RA-deficient mice failed to develop emphysema after 6 months of cigarette smoke exposure in contrast to wild-type mice [
38]. In their study, the wild-type mice which received 6 months smoking exposure showed higher levels of IL-17 in BAL fluid compared to sham-exposed mice. IL-17RA−/− mice showed lower levels of monocyte chemotactic protein-1 (MCP-1) in BAL fluid and lower expression of the matrix metalloproteinase (MMP)-9 and MMP-12 in the lung, compared to wild-type mice, suggesting an important role for IL-17RA in macrophage recruitment to the inflamed lung and for development of emphysema. They saw no differences in KC levels in BAL fluid between IL-17RA−/− mice and wild-type mice when emphysema was established, similar to our study. In the present study, however, we have shown that neutrophil-related chemokines such as KC and MIP-2 were increased at a relatively early stage following elastase treatment, which was associated with increased levels of IL-17A, and increased numbers of neutrophils in the airways, suggesting an important role for IL-17A in the recruitment of neutrophils at a relatively early stage. IL-17RA has at least three ligands including IL-17A, IL-17 F, and IL-25. In the present study, we demonstrated the importance of IL-17A for emphysema using IL-17A−/− mice. Shan et al. have also shown that cigarette smoke-induced emphysema is mediated by IL-17A in mice [
45]. Regarding other ligands for IL17RA, IL-25 has been reported to be associated with both Th2 and Th17 immune responses [
46], however, little is known about the role of this cytokine in emphysema development. Expression of both IL-17A and IL-17 F were increased in the airways of COPD subjects in both inflammatory cells as well as in the airway epithelium [
18,
19]. In contrast, numbers of IL-17 F+ cells were not increased in COPD compared to control subjects [
20].
In the present study, elastase-induced emphysematous changes of the lung in IL-17A−/− mice were reduced, but not completely attenuated compared to WT mice, suggesting that IL-17A may be essential but not sufficient for the full development of elastase-induced emphysema. Previous studies have shown that Th1 cells contribute largely to the inflammatory cascade of events related to the pathogenesis of COPD [
34,
35]. It has also been reported that Th2 cells may be important in the inflammatory response of the disease [
47‐
49]. Using IL-18 transgenic mice with disruption of the IL-13 gene, Hoshino et al. have shown that IL-18 and IL-13 might have important roles in the pathogenesis of emphysema [
50]. Recently, it has also been reported that overexpression of IL-18 induced emphysema via IFN-γ and IL-17A, and induced mucus metaplasia via IL-13 [
51]. Chronic cigarette smoke has been shown to induce both Th1 and Th17 cells in mice [
52]. Thus, although Th17 cells may play an important role in the pathogenesis of emphysema, their role is not exclusive and Th1 and Th2 cells may also have contributory roles. Further understanding of how these helper T cell subsets interact and orchestrate a pathological response to smoking will be essential if we are to successfully intervene in the development and progression of COPD and emphysema.
Competing interests
None of the authors have any conflicts of interest, financial or non-financial, to disclose.
Authors’ contributions
EK, KW, AT, GI, HK, and YI carried out the animal experiments. EK and HN carried out the flow cytometory. EK and AK performed the statistical analysis. NM, AK, HN, YT, MK, YI, EWG, and MT helped to draft the manuscript. NM conceived of the study, and participated in its design and coordination. All authors read and approved the final manuscript.