Abstract
Asthmatics have elevated levels of IL-17A compared to healthy controls. IL-17A is likely to contribute to reduced corticosteroid sensitivity of human airway epithelium. Here, we aimed to investigate the mechanistic underpinnings of this reduced sensitivity in more detail. Differentiated primary human airway epithelial cells (hAECs) were exposed to IL-17A in the absence or presence of dexamethasone. Cells were then collected for RNA sequencing analysis or used for barrier function experiments. Mucus was collected for volume measurement and basal medium for cytokine analysis. 2861 genes were differentially expressed by IL-17A (Padj < 0.05), of which the majority was not sensitive to dexamethasone (< 50% inhibition). IL-17A did inhibit canonical corticosteroid genes, such as HSD11B2 and FKBP5 (p < 0.05). Inflammatory and goblet cell metaplasia markers, cytokine secretion and mucus production were all induced by IL-17A, and these effects were not prevented by dexamethasone. Dexamethasone did reverse IL-17A-stimulated epithelial barrier disruption, and this was associated with gene expression changes related to cilia function and development. We conclude that IL-17A induces function-specific corticosteroid-insensitivity. Whereas inflammatory response genes and mucus production in primary hAECs in response to IL-17A were corticosteroid-insensitive, corticosteroids were able to reverse IL-17A-induced epithelial barrier disruption.
Similar content being viewed by others
Introduction
IL-17 is a pro-inflammatory cytokine that is central in physiological responses such as host defense regulation and tissue repair. However, it also plays a role in the pathogenesis of several diseases. For example, IL-17A plays an important role in aggravating the inflammatory processes in airway diseases such as asthma and chronic obstructive pulmonary disease (COPD)1. The levels of IL-17A in sputum, nasal and bronchial biopsies and serum have been reported to be higher in asthma and COPD patients than healthy controls2,3,4,5,6. Moreover, asthma severity has been linked with more elevated levels of IL-17A in these sputum, nasal and bronchial biopsies and serum3,4,7,8,9. In COPD patients, the presence of an IL-17A gene signature in airway epithelial cells was associated with increased airway obstruction and functional small airways disease, as well as reduced sensitivity to corticosteroids10.
The main anti-inflammatory drugs used clinically in asthma and COPD are corticosteroids11,12. Problematically, the effects of corticosteroids are limited in patients with severe asthma and in patients with COPD13. Several stimuli, such as pathogens, allergens, and cigarette smoke, as well as cytokines (IFN-γ, IL-17A, IL33, TSLP, TNFα, TGFβ) have been shown to promote corticosteroid insensitivity in severe asthma and COPD13. Indeed, there is a growing body of evidence for reduced corticosteroid sensitivity in response to IL-17A driven inflammation. Such corticosteroid insensitivity in response to IL-17A has been reported in immune cells, such as T helper cells and PBMCs, as well as structural cells, such as airway smooth muscle and epithelial cells14.
Epithelial cells have a major role in the airways by acting as barrier in the airway and by regulating immune responses15. In asthma and in COPD, there is a shift in epithelial differentiation leading to higher goblet cell number and exaggerated mucus production16. IL-17A exerts its effect on epithelial cells through binding to its receptor (IL-17R) and stimulates granulocyte-colony stimulating factor (G-CSF) and neutrophil recruiting chemokines, such as C-X-C ligand 1 (CXCL1), CXCL2, and CXCL5, causing neutrophilic inflammation17. Neutrophilic inflammation is known to be poorly sensitive to corticosteroids18,19,20. Moreover, in human airway epithelial cells, IL-17A pre-treatment reduced the effect of budesonide in preventing TNF-α-induced IL-8 production in vitro21. This indicates that IL-17A-induced insensitivity to corticosteroids might be the result of a direct effect on airway epithelial cells and might not necessarily be neutrophil-dependent. However, the functional responses via which IL-17A represses glucocorticosteroid signaling in airway epithelial cells, as well as the functional responses sensitive to this mechanism, are not yet fully clarified. Therefore, in this study, we investigated the functional and molecular interactions of IL-17A and dexamethasone, a potent corticosteroid, on primary human airway epithelial cells. We demonstrate that IL-17A induces function-specific corticosteroid insensitivity, which was evident for inflammatory responses and mucus production, whereas the effects of dexamethasone on epithelial barrier were maintained.
Results
Effect of IL-17A and dexamethasone on primary human airway epithelial cells
To validate the effect of IL-17A on primary human airway epithelial cells (hAECs), we stimulated the cells with three concentrations of IL-17A: 1, 10, and 100 ng/ml. To study corticosteroid insensitivity, cells were exposed to 10 nM dexamethasone. Markers previously described characteristic for IL-17A sensitivity (IL6, CXCL8, CXCL3, CSF3, CXCL5, and SAA2) were assessed10. All were indeed induced by IL-17A in dose dependent manners (Fig. 1a–f). The expression of these genes was not altered by the presence of dexamethasone. Furthermore, addition of dexamethasone tended to further induce expression of these genes in response to IL-17A 100 ng/ml stimulation. This validates the IL-17A-gene-signature sensitivity in hAECs as well as its corticosteroid insensitive nature (Fig. 1a–f). Based on these data, we chose IL-17A at a concentration of 10 ng/ml for further experiments.
Effect of IL-17A on differentiated hAECs grown at an air liquid interface (ALI)
Next, we characterized the effect of 10 ng/ml IL-17A and 10 nM dexamethasone in hAECs grown and differentiated at an air liquid interface (ALI) for 14 days. We exposed the cells to IL-17A, dexamethasone, or the combination during the 14 day differentiation period. The top 10 genes regulated by IL-17A were SLC26A4, IL-19, CBS, PDZK1IP1, ZC3H12A, B3GNT6, CYP2F1, NFKBIZ, SAMHD1, and LCN2, the expression of which was not inhibited by the presence of dexamethasone (Fig. 2a). 2861 genes were significantly differentially expressed by IL-17A (Padj < 0.05), of which 1439 were significantly upregulated and 1422 genes were significantly downregulated (Fig. 2b). Importantly, we found the same genes to be regulated by IL-17 in the air liquid interface design that we independently observed in the submerged design (Fig. 1). These genes were previously reported to be part of the IL-17A gene signature by others10, further supporting the findings.
We further analysed the IL-17A differentially expressed genes by gene set enrichment analysis (GSEA) using three pathway definitions: Kyoto Encyclopedia of Genes and Genomes (KEGG), reactome, and wikipathways (http://www.gsea-msigdb.org). Genes induced by IL-17A clustered into more than 100 pathways, the top 10 pathways are presented in Fig. 2c. The significantly enriched pathways in response to IL-17A included Cilia function and development, Neutrophil degranulation, and Extracellular matrix organization (FDR q-value < 0.05), which are known to be regulated by IL-17A22. For the top 10 genes (Fig. 2a), an IL-17A gene signature Z-score was calculated for each group. There was no difference between IL-17A with and without dexamethasone. This analysis confirmed that dexamethasone had no effect on the top 10 IL-17A gene signature (Fig. 2d).
Effect of dexamethasone on differentiated hAECs grown at an air liquid interface (ALI)
The top 10 genes regulated by dexamethasone were ALOX15B, TP53I3, ARRDC2, KCKNK5, PROM1, HSD11B2, MUC21, CAPS2, ZBTB16, and AC009061.1 (Fig. 3a). Interestingly, the presence of IL-17A prevented the regulation of these genes. 64 genes were significantly differentially expressed, of which 38 genes were significantly upregulated and 27 genes were significantly downregulated (Padj < 0.05) (Fig. 3b). Only two pathways were significantly regulated by dexamethasone, including cilia function and development, which were driven by CEP41, TMEM67, ARL6, NME7, DNAL1 gene expression (FDR q-value < 0.05) (Fig. 3c). Interestingly, these genes were also significantly regulated by IL-17A alone, as previously shown in Fig. 2c. Moreover, the calculated dexamethasone signature gene Z-score was also inhibited by IL-17A (Fig. 3d). This indicates a dexamethasone effect in ciliated cell differentiation and its interaction with IL-17A in regulating this pathway.
In addition, we analyzed two canonical corticosteroid genes that were reported in literature, HSD11B2 and FKBP5. HSD11B2 and FKBP5 gene expression was induced by dexamethasone, which was prevented almost completely by IL-17A (Fig. 3e,f)23,24. Together, the results indicate that IL-17A inhibits dexamethasone signaling.
Interactions between IL-17A and dexamethasone
Since IL-17A regulated genes seemed to be insensitive to dexamethasone in the stimulated hAECs, we examined the IL-17A and dexamethasone interaction in differentiated hAECs in more detail and focused on genes for which there was a significant interaction effect between IL-17A and dexamethasone. There were nine genes that demonstrated significant interaction: ARRDC2, ALOX15B, PROM1, CAPS2, KCNK5, TP53I3, C14orf142, HSD11B2, and MUC21 (Padj < 0.05) (Fig. 4a,b). Interestingly, these genes were also significantly regulated by dexamethasone alone, suggesting that the interaction is mainly affecting dexamethasone related genes (Padj < 0.05).
Surprised by the very strong repressive effects of IL-17A on dexamethasone signaling and the general lack of effect of dexamethasone on IL-17A signaling, we analyzed the effect of dexamethasone on IL-17A-related-genes in further detail. For the genes that were up/down-regulated by at least 1.5-fold in response to IL-17A stimulation the ability of dexamethasone to reverse this gene expression was assessed. The resulting score was normalized to 100%, yielding genes with a score of 100% as being completely dexamethasone resistant and genes with a score of 0% as being completely dexamethasone sensitive. Out of 2354 of these genes, only 170 (7.22%) genes showed strong inhibition by dexamethasone (≥ 50%), and the vast majority of 2184 genes (92.78%) were inhibited less than 50%) (Fig. 4c). This indicates that most of IL-17A-stimulated genes are less sensitive to dexamethasone, although dexamethasone sensitive genes do exist.
Effect of IL-17A and dexamethasone on IL-17-induced inflammation
To elucidate the functional significance of dexamethasone sensitive and resistant IL-17A signaling in differentiated hAECs, we first examined their interactive effect on IL-17A inflammatory markers as well as neutrophilic inflammatory marker expressions, a known type of inflammation caused by high IL-17A stimulation in the airway10,25,26.
IL-17A significantly induced CXCL8 and CCL20 protein expression in basolateral medium (p < 0.0001 and p = 0.0003, respectively) (Fig. 5a,b). Both effects were completely resistant to dexamethasone (p < 0.05). Similarly, IL-17A effected gene expression of CXCL8 (p = 0.0804), CCL20 (p = 0.0053), SLC26A4 (p = 0.0018), SAA1 (p = 0.0271), SAA2 (p = 0.0405), IL1β (p = 0.0690), CXCL3 (p = 0.0038), CXCL6 (p = 0.0196), CXCL1 (p = 0.0004), CXCL2 (p = 0.0015), and ALPL (p = 0.0650), and this effect was completely resistant to dexamethasone for all cytokines (Fig. 5c–m). This indicates that the IL-17A inflammatory pathway in hAECs is insensitive to corticosteroids.
Effect of IL-17A and dexamethasone on epithelial mucus production
Next, we investigated IL-17 functional interactions on epithelial mucus production. Mucus was collected and weighed every 2 days during the second week of differentiation. On day-11, IL-17A significantly increased mucus production and this was not inhibited by dexamethasone (Fig. 6a). Similar patterns of mucus production were also observed on day-8, day-13, and day-15 of differentiation period (data not shown). Consistent with this finding, epithelial goblet cell marker, MUC5AC, that was measured by immunofluorescence, were higher in IL-17A with and without dexamethasone groups (Fig. 6b). Other epithelial goblet cell markers MUC5B and SPDEF were also significantly increased at the gene expression level (p = 0.0064 and p = 0.0198, respectively), suggesting a shift towards goblet cell differentiation (Fig. 6c,d). In contrast, the ciliated cell marker FOXJ1 was downregulated (p = 0.0236) (Fig. 6e). These effects were not prevented by dexamethasone. Together these results suggests that IL-17A stimulation leads to a shift towards mucus hypersecretory phenotype that is not prevented by dexamethasone.
Effect of IL-17A and dexamethasone on airway epithelial integrity
Next, we evaluated the epithelial integrity by FITC-dextran membrane permeability assay. Epithelial membrane integrity was measured after 2 weeks of differentiation. IL-17A stimulation caused epithelial membrane disruption, and the presence of dexamethasone significantly reversed this effect (Fig. 7a). To elucidate the corresponding genes that might be responsible for the effects on epithelial integrity, we reanalyzed the RNAseq data, with the inclusion of the FITC-dextran membrane permeability results into the analysis, to discover genes with a matching expression pattern. We found 749 genes that were significantly correlated with epithelial membrane integrity (Padj < 0.05), of which 337 and 412 genes were up- and down-regulated by IL-17A, respectively. Pathway analysis (GSEA) showed that 97 pathways were significantly regulated, with Cilia function and development as the most regulated pathway (FDR < 0.05) (Fig. 7b). This indicates that IL-17A-induced disruption of epithelial integrity and the reversal effect by dexamethasone are associated with cilia function and development regulation.
Furthermore, genes related with Cilia function and development pathway were analyzed with string analysis (Fig. 7c). There were 2 main clusters that were significantly involved: cluster 1 and cluster 2 (both with enrichment p-value < 1.0e − 16). Cluster 1 includes 16 genes (LZTFL1, XPNPEP3, TMEM231, NPHP1, IFT172, C5orf42, CSPP1, RPGRIP1L, TTC21B, IFT122, CC2D2A, WDR19, TTC26, ARL3, IFT57, DYNCH21) and cluster 2 includes 14 genes (DNAH6, DNAAF3, ZMYND10, RSPH1, CCDC40, CCDC114, LRRC6, RSPH4A, CCDC11, EFHC1, NME7, TUBA1A, AK7, HAUS1) (Fig. 7c; cluster 1 in red, cluster 2 in green). Previously, we showed that dexamethasone significantly regulated the ciliopathies pathway. This might explain the reversal effect of dexamethasone in IL-17A-induced barrier disruption here.
Discussion
IL-17A regulates several airway epithelial functions in asthma and COPD, including stimulation of immune responses, airway remodeling, and mucus production. These effects have been reported as insensitive to corticosteroids21,27,28,29,30,31,32. In this study, we demonstrate that IL-17A induces function-specific corticosteroid insensitivity in differentiated primary human airway epithelial cells (hAECs) cultured at an air liquid interface (ALI). We demonstrate that IL-17A-induced inflammation and mucus production were not prevented by dexamethasone. Furthermore, we provide evidence that genes transactivated by dexamethasone, including HSD11B2 and FKBP5, were dampened by the presence of IL-17A. In contrast, dexamethasone reversed IL17A induced hAEC epithelial barrier disruption, which was associated with gene expression changes related to cilia function and development.
Data from this study clearly indicates that IL-17A-induced inflammation is dexamethasone insensitive in primary hAECs. This is in line with previous studies showing that IL-17A-stimulated gene and cytokine expressions in primary hAECs were not inhibited by the presence of corticosteroids21,32. Furthermore, our data show that the expression of the IL-17A gene signature previously identified by Christenson et al.10 was not affected by the presence of dexamethasone. In contrast, the dexamethasone gene signature and corticosteroid transactivation genes that have been reported in literature, such as HSD11B2 and FKBP523,24, were downregulated by the addition of IL-17A. These data indicate that IL-17A might alter dexamethasone mechanisms of action and resulted in the lack of dexamethasone effect in primary hAECs.
Studies have indicated that corticosteroid insensitivity in airway epithelial is related to enhanced phosphoinositide-3-kinase (PI3K) pathway activity and a subsequent reduced HDAC2 activity, as well as elevated levels of GRβ expression, an inactive splice variant of the corticosteroid receptor, in response to IL-17A exposure21,32. Both mechanisms have been linked to corticosteroid insensitivity in asthma and COPD33,34. Moreover, IL-17-induced GRβ upregulation and subsequent corticosteroid insensitivity were also observed in peripheral blood mononuclear cells (PBMCs)35. Other IL-17A-related corticosteroid insensitivity mechanisms have also been reported in other cell types, such as increased MAP-ERK kinase 1 (MEK1) signaling in immune cells obtained from human bronchoalveolar lavage (BAL)36 and elevated colony stimulating factor 3 (CSF3), a key neutrophil survival cytokine, in human ASM cells37. In line with these findings, clinical data showed that COPD patients with a higher IL-17A gene signature have a lower response to ICS therapy with respect to the change in FEV1%-predicted-over-30-months10.
The notion that IL-17 is not only related to neutrophilic infiltration, but also a paracrine signaling cytokine in airway epithelial cells, has widened the perspective of the role of IL-17 in airway pathophysiology. It has been proposed that this direct role of IL-17 on airway epithelial cells might play a role in asthma and COPD pathophysiology. However, the mechanisms are still ill-defined14. In this study, ALI-cultured primary hAECs were used as a model to observe the direct role of IL-17A in airway epithelial cells. Moreover, since an ALI-cultured cells represent a pseudostratified mucociliary cell culture with various epithelial cells present, it is a more accurate comparison to the in vivo situation. Indeed, we observed that IL-17A stimulation upregulated the IL-17A gene signature, including SLC26A4, SAA1, SAA2, CCL20, CXCL3, CXCL6, CXCL1, and CXCL2, as was reported in a clinical study of patients with COPD10. Furthermore, our data showed that the Neutrophil degranulation pathway and neutrophil-activating chemokines, such as CXCL8, CXCL3, CXCL6, CXCL1, and CXCL2, IL1β, and ALPL, were upregulated upon stimulation with IL-17A in primary hAECs. Interestingly, IL-17A had direct effects on Cilia function and development as well as Extracellular matrix (ECM) organization pathways which were markedly regulated. Therefore, we propose that IL-17A effects on airway pathology might not only via inducing neutrophilic inflammation but also directly by altering airway epithelial cells.
Cilia function and development has a pivotal role in cell proliferation and differentiation38,39,40. More specifically, cilia loss is known to be related to aberrant cell differentiation39. Although studies on the role of IL-17A in cilia function and development of airway epithelial cells are limited, it was reported that IL-17A modulates ciliogenesis in keratinocytes, which is likely to driven by intraflagellar transport protein 88 (IFT88)22. Our data showed that IFT88 was significantly upregulated (Padj = 0.0033) by IL-17A stimulation. Moreover, pathways related to Cilia function and development, such as Primary cilium development, Cilium assembly, and Ciliopathies, were the most regulated pathways by IL-17A, involving 105 cilia-related-genes. Interestingly, the most regulated pathway by dexamethasone is also Ciliopathies that was contributed by 5 cilia-related-genes. We need to emphasize that our study did not include a detailed analysis of cilia function, or of ciliogenesis; this hypothesis was based on gene expression patterns only. Thus, it would be of interest to further investigate functional interaction of IL-17A and dexamethasone on ciliated cell development.
Another IL-17A-induced hAECs response that we observed is related to Extracellular matrix organization, including Collagen formation, Degradation of extracellular matrix, and Collagen biosynthesis and modifying enzyme pathways, involving 55 ECM-related-genes. In murine parenchymal epithelium, the expansion of Th17 cells through overactivation of STAT3 in T lymphocytes caused upregulation of matrix metalloproteinase-9 (MMP9) and ECM degradation that leads to airway epithelial remodeling31. This was shown to be an indirect consequence of neutrophil infiltration via CXCL5 and MIP-2 upregulation31. Although we did not observe significant regulation of MMP9 (Padj = 0.544) in our model, the gene expressions of other MMPs, such as MMP7, MMP13, MMP14, MMP15, and MMP17 were significantly regulated and contribute to Extracellular matrix organization pathway modulation. Our finding highlight IL-17A effects on airway epithelial ECM regulation which are independent from systemic inflammation. In fibroblasts, the direct effect of IL-17A on stimulating ECM production is via TGF-β activation in murine29 and human cells41. The involvement of NF-κB signaling and inhibition of JAK2, but not JAK1/3, in driving out this effect was also reported in human fibroblasts in vitro42. Therefore, elucidation of IL-17A molecular dynamics in regulating ECM in airway epithelium is an interesting topic to be studied further.
IL-17A is known to induce goblet cell hyperplasia and mucus production, which are prominent features of airway diseases, such as COPD, asthma, and cystic fibrosis28,29,30,43. Moreover, IL-17A is known to stimulate upregulation of SLC26A4, an anion exchange protein which is known to induce goblet cell hyperplasia in human lung mucoepidermoid carcinoma cells and murine airway epithelial cells44,45,46,47. Interestingly, SLC26A4 was found to be elevated in serum48, endobronchial biopsies49, and lung tissues of asthmatics45, and inversely associated with percentage of forced expiratory volume in 1 s (FEV1%), suggesting its role in airway disease48. Our data shows that SLC26A4 is the most differentially expressed gene in response to IL-17A, suggesting its significant role in driving goblet cell hyperplasia in our model. Furthermore, stimulation with IL-17A increased mucus production and the epithelial goblet cell gene markers, MUC5B and SPDEF, which were not inhibited by dexamethasone.
An important feature of airway remodeling in airway diseases is a change in epithelial barrier function. We observed reduced epithelial barrier integrity in IL-17A-stimulated hAECs as seen as increased FITC-dextran transmembrane permeability. An in vitro study in primary human nasal epithelial of chronic rhinosinusitis patients also reported similar results; a substantial epithelial barrier disruption, which was shown as elevated FITC-dextran permeability, loss of TEER, and reduced ZO-1 expression50. However, it is of great interest to investigate the underlying mechanism of IL-17A-induced airway epithelial barrier disruption, as it is yet to be unraveled. Studies that have been done in epidermal keratinocytes in vitro indicated that IL-17A impairs tight junction and epidermal barrier via downregulation of filaggrin and via genes involved in cell adhesion51,52. Thus, evaluation of changes in protein expressions related to airway epithelial tight junction and cellular adhesion that might resulted in barrier disruption, is the next interesting step forward in the future.
In conclusion, we demonstrated that IL-17A induces corticosteroid insensitivity in IL-17A-driven airway epithelial cell inflammatory cytokine responses and mucus production. In contrast, dexamethasone reverses IL-17A-stimulated epithelial barrier disruption. This indicates that IL-17A drives function-specific corticosteroid insensitivity.
Methods
Culture of human airway epithelial cells
Primary human airway epithelial cells (hAECs) were obtained from healthy lung transplant donors post-mortem, from residual tracheal and main stem bronchial tissue, within 1-8 h after a lung donation. Selection criteria for transplant donors are listed in the Eurotransplant guidelines and include the absence of primary lung disease, such as asthma and COPD, and no more than 20 pack years of smoking history. The material was collected in carbogenated Krebs–Henseleit-buffer (composition in mM: 117.5 NaCl, 5.6 KCl, 1.18 MgSO4, 2.5 CaCl2, 1.28 NaH2PO4, 25 NaHCO3 and 5.5 glucose). Epithelial cells were isolated by enzymatic digestion and cultured as described previously53,54. Cells were cultured in Keratinocyte Serum Free Medium (KSFM) medium with Bovine Pituitary Extract and EGF (Invitrogen, 17005042), supplemented with isoproterenol 1 µM (Sigma-aldrich, I6504). Experiments in submerged cells were conducted by exposing cells to 10 nM of Dexamethasone (Sigma-aldrich D4902), recombinant human IL-17A (R&D 7955-IL-025/CF) in three different concentrations (1, 10, and 100 ng/ml), or to combinations of IL-17A and Dexamethasone for 24 h.
For experiments in ALI cultured cells, cells from passage 1–2 were grown submerged on collagen-coated Transwell inserts until confluence, after which they were cultured at an air–liquid interface (ALI) and differentiated for 2 weeks in B/D medium (1:1), which is a mixture of DMEM [Gibco] and bronchial epithelial growth medium (BEGM) [Lonza], supplemented with 0.4% [w/v] bovine pituitary extract [BPE], 0.5 ng/ml epidermal growth factor [EGF], 5 µg/ml insulin, 10 µg/ml transferrin, 1 µM hydrocortisone, 6.5 ng/ml T3, 0.5 µg/ml epinephrine [all from Lonza], 15 ng/ml retinoic acid [Sigma chemical] 1.5 µg/ml bovine serum albumin [Sigma chemical] 0.5 mM sodium pyruvate [Gibco], 20 U/ml penicillin and 20 µg/ml streptomycin [Gibco]53. Cells were exposed to 10 nM of Dexamethasone (Sigma-aldrich D4902), 10 ng/ml of recombinant human IL-17A (R&D 7955-IL-025/CF), or the combination of IL-17A and Dexamethasone that was added to the basal medium during two weeks of differentiation. ALI cultures were maintained for 14 days at 37 °C in a humidified atmosphere of 5% CO2. Medium and stimuli were refreshed three times per week. The apical side of the epithelial cells was washed with phosphate buffer saline (PBS) at the same time. After 2 weeks, cells were collected for RNA analysis or used for barrier function experiments, mucus was collected for volume measurement, and basal medium was collected for cytokine analysis.
RNA analysis
Total RNA was isolated using the RNA purification kit NucleoSpin RNA (Macherey–Nagel 740955, Germany) according to the manufacturer’s guide. Cells were lysed by adding a mixture of buffer RA1 and dithiothreitol (Sigma-Aldrich, 3483-12-3). The yield of the isolated RNA was then measured using the NanoDrop 1000 spectrophotometer. Samples were analyzed by RT-PCR or RNA sequencing (RNA-seq).
For RT-PCR analysis, equal amounts of total RNA were reverse transcribed into cDNA. cDNA was generated with cDNA synthesis kit (Promega) using M-MLV reverse transcriptase (Promega M1701) in Doppio thermal cycler (VWR, 732-2551). RT-PCR analysis were performed in Quantstudio 7 flex Real-Time PCR system (Thermo Fisher Scientific, 4485701). RT-PCR was performed with denaturation at 94 °C for 30 s, annealing at 59 °C for 30 s and extension at 72 °C for 30 s for 45 cycles followed by 10 min at 72 °C. RT-PCR data were analyzed using the comparative cycle threshold (Ct: amplification cycle number) method. The amount of target gene was normalized to the endogenous reference gene RPL13a and SDHA.
RNA-seq was conducted using the Illumina NovaSeq 6000 sequencer by GenomeScan (https://www.genomescan.nl/). The procedure included data quality control, adapter trimming, alignment of short reads and feature counting. Library preparation was checked by calculating ribosomal (and globin) content. Checks for possible sample and barcode contamination were performed and a set of standard quality metrics for the raw dataset was determined using quality control tools (FstQC v0.34 and FastQA). Prior to alignment, the reads were trimmed for adapter sequences using Trimmomatic v0.30. To align the reads of each sample, the human reference GRCh37.75 was used. Data was analyzed with DESEQ2 in R studio v1.4.1106.
Z-scores were calculated as follows:
where: x is the data point, µ is the mean, σ is the standard deviation.
FDR q-values were assessed using the Gene Set Enrichment Analysis webtool, Broad Institute, UC San Diego (https://www.gsea-msigdb.org/gsea/index.jsp).
ELISA
Basal media were used for ELISA quantification of human CCL20 and CXCL8 following the instructions of the commercial kit (DM3A00 and D8000C, respectively, R&D systems).
Barrier function
Barrier function was assessed by permeability to 4000 Da fluorescein isothiocyanate-dextran (FITC-dextran, Sigma-Aldrich). Cells were washed once with HBSS (Thermo Fisher) and 500 µl of 1 mg/ml FITC-dextran in HBSS was added to the apical chamber. Cells were incubated for 6 h at 37 °C in a humidified atmosphere of 5% CO2, after which 100 µl HBSS with tracer was collected from the basolateral chamber in duplicate. Permeability to FITC-dextran was evaluated through measuring the fluorescence intensity at 490/520 nm using a fluorescence plate reader (Synergy H1, Biotek).
Mucus analysis
Mucus was collected from the apical side of the ALI-cultured cells and weighed every 2 days during the second week of differentiation.
Immunofluorescence
For mucin 5AC (MUC5AC) protein visualization, ALI-cultured hAECs cells on top of the insert’s membranes were fixed in acetone:methanol 1:1 (volume/volume) for 15 min at − 20 °C. After fixation, the inserts were washed with 1X phosphate buffer saline (PBS) 3 times and blocked with 3% H2O2 for 30 min in room temperature. The inserts were further washed and incubated with the primary antibody mouse anti-MUC5AC (1:100; Fisher Scientific Epredia MS145P) in 1% BSA and 2% donkey serum for 1 h in room temperature. Next, the inserts were washed and incubated with the secondary antibody donkey anti-mouse Alexa Fluor 488 (1:200, Invitrogen A21202) for 30 min in the dark in room temperature. The inserts then were cut, inverted, and transferred to glass slides with 2 drops of the mounting medium containing DAPI (Abcam 104139). The slides were kept at 4 °C. Confocal images were acquired using Leica SP8 microscope at 20× magnificantion.
Statistical analysis
All data were presented as mean ± SEM unless indicated otherwise. Data was analyzed for statistical significance using one-way or two-way ANOVA. The padj-value indicating statistically significant differences between the mean values are defined as follows: *p < 0.05, **p < 0.01, ***p < 0.001, ****p < 0.0001. Statistical analyses were performed with Graphpad Prism 9.2.0 software.
Data availability
The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
References
Li, X., Bechara, R., Zhao, J., McGeachy, M. J. & Gaffen, S. L. IL-17 receptor-based signaling and implications for disease. Nat. Immunol. 20, 1594–1602 (2019).
Molet, S. et al. IL-17 is increased in asthmatic airways and induces human bronchial fibroblasts to produce cytokines. J. Allergy Clin. Immunol. 108, 430–438 (2001).
Chakir, J. et al. Airway remodeling-associated mediators in moderate to severe asthma: Effect of steroids on TGF-β, IL-11, IL-17, and type I and type III collagen expression. J. Allergy Clin. Immunol. 111, 1293–1298 (2003).
Bullens, D. M. A. et al. IL-17 mRNA in sputum of asthmatic patients: Linking T cell driven inflammation and granulocytic influx?. Respir. Res. 7, 135 (2006).
Zheng, R. et al. Elevated Th17 cell frequencies and Th17/Treg ratio are associated with airway hyperresponsiveness in asthmatic children. J. Asthma 58, 707–716 (2021).
Doe, C. et al. Expression of the T helper 17-associated cytokines IL-17A and IL-17F in asthma and COPD. Chest 138, 1140–1147 (2010).
Agache, I., Ciobanu, C., Agache, C. & Anghel, M. Increased serum IL-17 is an independent risk factor for severe asthma. Respir. Med. 104, 1131–1137 (2010).
Ricciardolo, F. L. M. et al. Identification of IL-17F/frequent exacerbator endotype in asthma. J. Allergy Clin. Immunol. 140, 395–406 (2017).
Al-Ramli, W. et al. TH17-associated cytokines (IL-17A and IL-17F) in severe asthma. J. Allergy Clin. Immunol. 123, 1185–1187 (2009).
Christenson, S. A. et al. An airway epithelial IL-17A response signature identifies a steroid-unresponsive COPD patient subgroup. J. Clin. Invest. 129, 169–181 (2019).
Global Initiative for Asthma. Global Strategy for Asthma Management and Prevention Updated 2020. Global Initiative for Asthma (2020).
Agusti, A. & Vogelmeier, C. Global Initiative for Chronic Obstructive Lung Disease: GOLD Report 2020. Global Initiative for Chronic Obstructive Lung Disease (2020).
Mei, D., Tan, W. S. D. & Wong, W. S. F. Pharmacological strategies to regain steroid sensitivity in severe asthma and COPD. Curr. Opin. Pharmacol. 46, 73–81 (2019).
Rahmawati, S. F. et al. Pharmacological rationale for targeting IL-17 in asthma. Front. Allergy 2, 694514 (2021).
Mertens, T. C. J., Karmouty-Quintana, H., Taube, C. & Hiemstra, P. S. Use of airway epithelial cell culture to unravel the pathogenesis and study treatment in obstructive airway diseases. Pulmonary Pharmacol. Therap. 45 (2017).
Lambrecht, B. N. & Hammad, H. The airway epithelium in asthma. Nat. Med. 18, 684–692 (2012).
Willis, C. R. et al. IL-17RA signaling in airway inflammation and bronchial hyperreactivity in allergic asthma. Am. J. Respir. Cell Mol. Biol. 53, 810–821 (2015).
Pelletier, M. et al. Evidence for a cross-talk between human neutrophils and Th17 cells. Blood 115, 335–343 (2010).
Essilfie, A. T. et al. Combined Haemophilus influenzae respiratory infection and allergic airways disease drives chronic infection and features of neutrophilic asthma. Thorax 67, 588–599 (2012).
Ito, K. et al. Steroid-resistant neutrophilic inflammation in a mouse model of an acute exacerbation of asthma. Am. J. Respir. Cell Mol. Biol. 39, 543–550 (2008).
Zijlstra, G. J., Ten Hacken, N. H. T., Hoffmann, R. F., Van Oosterhout, A. J. M. & Heijink, I. H. Interleukin-17A induces glucocorticoid insensitivity in human bronchial epithelial cells. Eur. Respir. J. 39, 439–445 (2012).
Rizaldy, D. et al. Increase in primary cilia in the epidermis of patients with atopic dermatitis and psoriasis. Exp. Dermatol. 30, (2021).
Orsida, B. E., Krozowski, Z. S. & Haydn Walters, E. Clinical relevance of airway 11β-hydroxysteroid dehydrogenase type II enzyme in asthma. Am. J. Respir. Crit. Care Med. 165, (2002).
Woodruff, P. G. et al. Genome-wide profiling identifies epithelial cell genes associated with asthma and with treatment response to corticosteroids. Proc. Natl. Acad. Sci. USA 104, 15858–15863 (2007).
Kuo, C. H. S. et al. T-helper cell type 2 (Th2) and non-Th2 molecular phenotypes of asthma using sputum transcriptomics in U-BIOPRED. Eur. Respir. J. 49, 1602135 (2017).
Fricker, M. et al. A sputum 6-gene signature predicts future exacerbations of poorly controlled asthma. J. Allergy Clin. Immunol. 144, 51-60.e11 (2019).
Ma, L. et al. Cigarette and IL-17A synergistically induce bronchial epithelial-mesenchymal transition via activating IL-17R/NF-κB signaling. BMC Pulm. Med. 20, 26 (2020).
Hall, S. L. et al. IL-17A enhances IL-13 activity by enhancing IL-13–induced signal transducer and activator of transcription 6 activation. J. Allergy Clin. Immunol. 139, 462-471.e14 (2017).
Peters, M., Köhler-Bachmann, S., Lenz-Habijan, T. & Bufe, A. Influence of an allergen-specific Th17 response on remodeling of the airways. Am. J. Respir. Cell Mol. Biol. 54, 350–358 (2016).
Fujisawa, T. et al. Regulation of airway MUC5AC expression by IL-1β and IL-17A; the NF-κB paradigm. J. Immunol. 183, 6236–6243 (2009).
Fogli, L. K. et al. T cell-derived IL-17 mediates epithelial changes in the airway and drives pulmonary neutrophilia. J. Immunol. 191, 3100–3111 (2013).
Vazquez-Tello, A. et al. Induction of glucocorticoid receptor-β expression in epithelial cells of asthmatic airways by T-helper type 17 cytokines. Clin. Exp. Allergy 40, 1312–1322 (2010).
Barnes, P. J. Corticosteroid resistance in patients with asthma and chronic obstructive pulmonary disease. J. Allergy Clin. Immunol. 131, 636–645 (2013).
Wadhwa, R. et al. Cellular mechanisms underlying steroid-resistant asthma. Eur. Respir. Rev. 28, 190096 (2019).
Vazquez-Tello, A., Halwani, R., Hamid, Q. & Al-Muhsen, S. Glucocorticoid receptor-beta up-regulation and steroid resistance induction by IL-17 and IL-23 cytokine stimulation in peripheral mononuclear cells. J. Clin. Immunol. 33, 466–478 (2013).
Irvin, C. et al. Increased frequency of dual-positive TH2/TH17 cells in bronchoalveolar lavage fluid characterizes a population of patients with severe asthma. J. Allergy Clin. Immunol. 134, 1175-1186.e7 (2014).
Ouyang, S. et al. Targeting IL-17A/glucocorticoid synergy to CSF3 expression in neutrophilic airway diseases. JCI Insight 5, e132836 (2020).
Wheway, G., Nazlamova, L. & Hancock, J. T. Signaling through the primary cilium. Front. Cell Developmental Biol. 6 (2018).
Croyle, M. J. et al. Role of epidermal primary cilia in the homeostasis of skin and hair follicles. Development. 138, (2011).
Irigoin, F. & L. Badano, J. Keeping the balance between proliferation and differentiation: The primary cilium. Curr. Genom. 12, (2011).
Lai, T. et al. HDAC2 suppresses IL17A-mediated airway remodeling in human and experimental modeling of COPD. Chest 153, 863–875 (2018).
Zhang, J. et al. Profibrotic effect of IL-17A and elevated IL-17RA in idiopathic pulmonary fibrosis and rheumatoid arthritis-associated lung disease support a direct role for IL-17A/IL-17RA in human fibrotic interstitial lung disease. Am. J. Physiol. Lung Cell. Mol. Physiol. 316, L487–L497 (2019).
Roger, D. F. Physiology of airway mucus secretion and pathophysiology of hypersecretion. Respiratory Care. 52 (2007).
Nakao, I. et al. Identification of pendrin as a common mediator for mucus production in bronchial asthma and chronic obstructive pulmonary disease. J. Immunol. 180, (2008).
Lee, J. U. et al. Effects of ammonium chloride on ozone-induced airway inflammation: The role of Slc26a4 in the lungs of mice. J. Korean Med. Sci. 35, (2020).
Park, J. et al. Novel pendrin inhibitor attenuates airway hyperresponsiveness and mucin expression in experimental murine asthma. J. Allergy Clin. Immunol. 144, (2019).
Adams, K. M. et al. IL-17A induces Pendrin expression and chloride-bicarbonate exchange in human bronchial epithelial cells. PLoS One 9, (2014).
Do, D. C. et al. Type II alveolar epithelial cell–specific loss of RhoA exacerbates allergic airway inflammation through SLC26A4. JCI Insight 6, (2021).
Yick, C. Y. et al. Transcriptome sequencing (RNA-Seq) of human endobronchial biopsies: Asthma versus controls. Eur. Respir. J. 42, (2013).
Ramezanpour, M., Moraitis, S., Smith, J. L. P., Wormald, P. J. & Vreugde, S. Th17 cytokines disrupt the airway mucosal barrier in chronic rhinosinusitis. Mediators Inflamm. 2016, (2016).
Yuki, T., Tobiishi, M., Kusaka-Kikushima, A., Ota, Y. & Tokura, Y. Impaired tight junctions in atopic dermatitis skin and in a skin-equivalent model treated with interleukin-17. PLoS One 11, (2016).
Gutowska-Owsiak, D. et al. IL-17 downregulates filaggrin and affects keratinocyte expression of genes associated with cellular adhesion. Exp. Dermatol. 21, (2012).
Zuyderduyn, S. et al. IL-4 and IL-13 exposure during mucociliary differentiation of bronchial epithelial cells increases antimicrobial activity and expression of antimicrobial peptides. Respir. Res. https://doi.org/10.1186/1465-9921-12-59 (2011).
Kistemaker, L. E. M. et al. Tiotropium attenuates IL-13-induced goblet cell metaplasia of human airway epithelial cells. Thorax 70, (2015).
Acknowledgements
We thank Lembaga pengelola dana pendidikan (LPDP) Indonesia for providing the scholarship to SFR.
Author information
Authors and Affiliations
Contributions
S.F.R., R.G., L.K., and H.K. conceived and designed the study. S.F.R. performed all the experiments. S.F.R., I.S.T.B., R.V., and R.G. analyzed the data. S.F.R. wrote the main manuscript text and prepared all figures. All authors reviewed the manuscript.
Corresponding author
Ethics declarations
Competing interests
SFR received a scholarship from lembaga pengelola dana pendidikan (LPDP) Indonesia. SFR and RG received research funding, to the institution, from Sanofi-Genzyme for the development of novel drugs targeting the IL-17 pathway. In addition, RG received research funding from Aquilo and Boehringer Ingelheim, to the institution, outside the scope of the present study. STB declares no competing interest. RV declares no competing interest. LK is an employee of Aquilo BV. HK reports no competing interests in relation to the topic of this manuscript. His institution has received funding from Boehringer for investigator-initiated studies as well as for consultancies, all outside the scope of the work presented here.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Rahmawati, S.F., Vos, R., Bos, I.S.T. et al. Function-specific IL-17A and dexamethasone interactions in primary human airway epithelial cells. Sci Rep 12, 11110 (2022). https://doi.org/10.1038/s41598-022-15393-2
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-022-15393-2
This article is cited by
-
An integrated study fusing systems biology and machine learning algorithms for genome-based discrimination of IPF and NSIP diseases: a new approach to the diagnostic challenge
Soft Computing (2024)
-
Characterization of immunomodulatory factors and cells in bronchoalveolar lavage fluid for immune checkpoint inhibitor-related pneumonitis
Journal of Cancer Research and Clinical Oncology (2023)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.