Introduction
Asthma is one of the most common chronic diseases and more than 300 million individuals worldwide currently suffer from asthma (1). It was estimated that the number will reach 400 million by 2025 (2). Asthma has been considered a heterogeneous disease that comprises different phenotypes and shares similar clinical manifestations and typical features of airway inflammation, airway hyperresponsiveness (AHR) and airway remodeling (3,4). Although corticosteroids and bronchodilators can control disease symptoms (5,6), asthma is not readily preventable or curable (7,8). Therefore, it is necessary to identify early effective primary prevention and intervention strategies.
Interleukin 27 (IL-27) is a novel cytokine composed of the subunit p28 (IL-27p28) and Epstein Barr virus-induced gene 3 (9). This molecule is primarily produced by activated antigen-presenting cells and exhibits pleiotropic effects on T-helper cell responses (9,10). For example, it induces T-helper 1 (Th1) cell differentiation (11,12) and directly suppresses T-helper 2 (Th2) production and T-helper 17 (Th17) differentiation (13,14). Th2-type cytokines play a pivotal role in airway inflammation and AHR, which are the hallmarks of asthma (15,16). Therefore, IL-27 may play an important role in the pathogenesis of asthma.
Several studies have found that high levels of IL-27 combined with activation of the type-2 signature are associated with increasing severity of asthma (17-19). IL-27 may be stimulated as a counter-regulatory cytokine to suppress Th2 inflammation (17-19). In addition, Miyazaki et al (20) reported that IL-27R (-/-) mice challenged with ovalbumin (OVA) exhibited increased asthmatic phenotypes, suggesting that IL-27 plays a pivotal role in the inhibition of lung inflammation and AHR. Jirmo et al (21) demonstrated that IL-27 is critical for the control of allergic asthma. Therefore, IL-27 is a novel, promising preventative agent for alleviating asthma development and exacerbation. A series of studies based on the OVA-induced mouse model have shown that preventative intranasal administration of IL-27 reduced airway inflammation and improved pathological changes, whereas IL-27 does not reduce airway inflammation and improve pathological changes when administered in a therapeutic mode following OVA challenge (22,23). However, Yoshimoto et al (17) reported that intranasal administration of IL-27 could inhibit OVA-induced airway hyperresponsiveness and inflammation in OVA-immunized mice. The biological impact of IL-27 on asthma remains elusive and previous studies have shown contradictory pro-inflammatory and anti-inflammatory effects (24,25). Furthermore, it has not been examined whether IL-27 plays a role in airway remodeling of chronic asthma.
In the present study, the effects of intranasal administration of IL-27 on airway inflammation and AHR were investigated in OVA-immunized mouse models of acute asthma. In addition, the effects of IL-27 on airway remodeling in mouse models of chronic asthma were explored. Finally, the effects of IL-27 stimulation on the expression levels of signal transducer and activator of transcription (STAT)1, STAT3, T-box transcription factor (T-bet), and GATA binding protein-3 GATA3) were studied. The data revealed that the effect of IL-27 was dependent on STAT1 and STAT3 pathways
Materials and methods
Mice
A total of 24 healthy female BALB/c mice were purchased from the Experimental Animal Center of Shandong University and used between 6-8 weeks of age. The animals were kept under specific pathogen-free and standard conditions including 12 h light/dark cycle, room temperature of 22°C, relative humidity of 60% and free access to food and water. The health and wellbeing of animals were monitored via daily observations of behaviour and condition. The mice were randomly assigned to three study groups: PBS group (PBS, n=8), OVA group (OVA, n=8) and IL-27 group (OVA + IL-27, n=8). All procedures on mice were performed in accordance with the National Institutes of Health Guide for the Care and Use of Laboratory Animals (26). In addition, all protocols were approved by the Ethics Committee for Laboratory Animals Care and Use in Shandong Qianfoshan Hospital, Shandong University (Shandong, China).
Experimental model for OVA-induced acute asthma
OVA sensitization and challenge were accomplished using a modified protocol as previously described by Reddy et al (27) and Venkayya et al (16). Briefly, in the OVA and OVA + IL-27 groups, the mice received intraperitoneal (i.p.) injections containing 100 µg OVA (Sigma-Aldrich; Merck KGaA), 2 mg Alum (Thermo Fisher Scientific, Inc.) and 100 µl PBS (Invitrogen; Thermo Fisher Scientific, Inc.) on days 0 and 7. The mice received aerosol challenge with 50 µl PBS and 100 µg OVA intranasally (i.n.) on days 14-18 under light isoflurane anesthesia, which was performed for 1 min with a concentration of 3% isoflurane (28). The mice were sensitized with sterile endotoxin-free PBS/Alum and challenged with PBS i.n. on the same days in the PBS group. In the OVA + IL-27 group, the mice were treated i.n. with 50 µl PBS and 50 ng IL-27 twice a day on days 6 and 7. On days 0, 7 and 14-18, the mice received i.n. 50 µl PBS and 1 µg IL-27 1 h prior to OVA sensitization and the subsequent challenge. The mice were treated with 50 µl PBS alone in the OVA and PBS groups (see the protocol scheme in Fig. 1A). Each group included eight mice.
Experimental model of OVA-induced chronic asthma
The mice were sensitized and challenged with OVA using a modified protocol described by Kirstein et al (29). In brief, a mixture containing 20 µg OVA/1 mg Alum/200 µl PBS was delivered subcutaneously to mice on days 0, 7, 14 and 21 to the OVA and OVA + IL-27 groups, while 1 mg Alum/200 µl PBS was administered to the PBS group. On days 26 and 28 and on the following 4 weeks, the mice received i.n challenge of 20 mg either OVA in PBS (50 µl; OVA and OVA + IL-27 groups) or 50 µl PBS alone (PBS group) following induction of anesthesia. The administration of OVA and IL-27 from day 28 was performed twice every week. In the OVA + IL-27 group, the mice were treated i.n. with 50 µl PBS and 50 ng IL-27 twice a day on days 6 and 7. On days 0, 7, 26-28, 35, 38, 42, 49, 52, 56 and 59 the mice received i.n. 50 µl PBS and 20 ng IL-27 1 h prior to OVA sensitization and prior to the subsequent challenge. The mice were treated with 50 µl PBS alone in the OVA and PBS groups (Fig. 2A). Each group included eight mice.
Measurement of airway responsiveness
Airway responses and dynamic lung compliance to methacholine challenge were assessed 24 h following the last OVA challenge, as previously reported (30). Briefly, the mice were anesthetized with pentobarbital sodium (50 mg/kg, i.p. injection) and the depth of anesthesia was determined by mice's responses to nociceptive stimulation and movement (31). No side effects of anesthesia were observed in 3 mice groups. After the mice were fully anaesthetized (immobility and absence of the withdrawal reflex of the right paw), a cannula was subsequently inserted into the trachea, and the mice were connected to the flexiVent system (Scireq). The mice were mechanically ventilated with a tidal volume of 5 ml/kg at a rate of 150 breaths/min with a positive end-expiratory pressure of 3 cm H2O (32). In the plethysmograph chamber, a thermostat-controlled warming pad was built to retain the temperature at 37°C. The mice were initially challenged with aerosol saline followed by challenge with increasing concentrations of acetyl-β-methylcholine chloride (methacholine; 0, 5, 10, and 20 mg/ml; Sigma-Aldrich; Merck KGaA) for 10 sec at each dose. Airway resistance and lung compliance were calculated as percentage increase over baseline (saline challenge).
Bronchoalveolar lavage (BAL)
At 24 h following the final OVA challenge and immediately after the measurement of airway responsiveness, mice were euthanized by cervical dislocation and death was confirmed according to lack of breathing, pulse, corneal reflex and response to firm toe pinch (33). BAL fluid (BALF) was collected and processed as previously described (34). In brief, the trachea was cannulated and 4×1 ml PBS-EDTA (0.05 M; Merck KGaA) was instilled in the right lung and recovered by gentle manual aspiration. Subsequently, the BALF was centrifuged (80 × g for 10 min at 4°C) and the cell pellets were resuspended in 1 ml PBS-EDTA. Total and differential cell counts were determined on cytospin slide preparations and stained with Wright-Giemsa at room temperature for 8 min. A total of 200 cells per slide were counted per sample using a light microscope at ×400 magnification (DP73; Olympus Corporation) (35).
Enzyme-linked immunosorbent assay (ELISA)
The expression levels of IL-4 (cat. no. M4000B), IL-5 (cat. no. M5000), IL-13 (cat. no. DY413), IL-17 (cat. no. M1700) and interferon (IFN)-γ (cat. no. DY485) in the serum and supernatant of BALF were determined using ELISA kits (R&D Systems, Inc.) as previously described, according to the manufacturer's protocol (36).
Reverse transcription-quantitative PCR (RT-qPCR)
The left lungs of mice were removed immediately after collection of BALF and total RNA was extracted from the lung tissues using TRIzol® reagent (Invitrogen; Thermo Fisher Scientific, Inc.), according to the manufacturer's protocol. The concentration of RNA was assessed by a Nanodrop™ ND-1000 spectrophotometer (Thermo Fisher Scientific, Inc.). cDNA synthesis was performed using a Superscript III First-Strand Synthesis kit (Invitrogen; Thermo Fisher Scientific, Inc.), according to the manufacturer's protocols at 50°C for 50 min. qPCR for mRNA detection was conducted using an ABI 7000 PCR instrument (Thermo Fisher Scientific, Inc.) according to the manufacturer's instructions. The PCR reaction system consisted of 1 µl cDNA, 0.5 µl of each forward and reverse primer, 10 µl SYBR Green Mix (Beijing Solarbio Science & Technology Co., Ltd.) and 8 µl ddH2O. The following thermocycling conditions were used for the qPCR: Initial denaturation at 94°C for 5 min, followed by 40 cycles of 10 sec at 94°C and 20 sec at 60°C and a final extension of 30 sec at 72°C. β-actin was used as the reference control gene. The primer sequences used for this analysis and the expected size of the PCR products are listed in Table I. The relative abundance of the mRNA transcripts was calculated using the 2−∆∆Cq method (37). Each sample was tested in triplicate and at least three wells were used for each group.
Western blot analysis
Western blot analysis was performed as described previously (38). Briefly, the proteins were extracted from mouse lung tissues and loaded on 5% SDS polyacrylamide gels. A bicinchoninic acid protein assay kit (cat. no. 23225; Pierce; Thermo Fisher Scientific, Inc.) was used to determine protein concentration. Following electrophoresis, the proteins were transferred to PVDF membranes (EMD Millipore). The membranes were blocked in 5% (w/v) nonfat dry milk in TBS-Tween-20 (0.15%) at 37°C for 1 h. Subsequently, membranes were incubated with primary antibodies against STAT1 (cat. no. sc-464), phosphorylated (p)-STAT1 (cat. no. sc-8394), STAT3 (cat. no. sc-482), p-STAT3 (cat. no. sc-8059), GATA3 (cat. no. sc-9009), T-bet (cat. no. sc-21003) and β-actin (cat. no. sc-47778; all from Santa Cruz Biotechnology, Inc.) separately. The dilutions of the primary antibodies were 1:500 and the incubations were performed overnight at 4°C. Subsequently, the membranes were incubated with goat anti-rabbit immunoglobulin G-horseradish peroxidase secondary antibody (cat. no. sc-2004; 1:5,000; Santa Cruz Biotechnology, Inc.) at 37°C for 45 min. β-actin was used as the internal control. The protein bands were visualized using an ECL detection reagent kit (GE Healthcare) according to the manufacturer's instructions. Densitometry was performed using Gel-Pro analyzer software (version 4.0; Media Cybernetics, Inc.).
Lung histology
The lung tissues (5-µm thick) were subsequently formalin-fixed and paraffin-embedded, as described previously (39). The lung sections were prepared and stained with hematoxylin and eosin (H&E), Masson's trichrome and periodic acid-Schiff (PAS) stain according to a standard protocol (39,40). Two pathologists who were blinded to the group assignment of mice independently evaluated and scored three differently stained tissue sections and the average scores were calculated. H&E-stained lung sections were used mainly for the assessment of basal membrane thickening and hyperplasia of airway smooth muscle cells. Three bronchioles with 150–200 µm inner diameter were selected in each slide. The perimeter of basement membrane (Pbm), total area of airway wall (Wat) and area of smooth muscle (Wam) were measured by morphometric analysis (Image-Pro Plus 6.0; Media Cybernetics, Inc.) and the ratios of Wat to Pbm (Wat/Pbm) and Wam to Pbm (Wam/Pbm) were calculated (40). Masson's trichrome-stained sections were used to identify subepithelial fibrosis. The epithelial basement membranes with diameters of >250 µm were selected and both the collagen fiber area (stained in blue) beneath the basement membrane and Pbm were measured using Image-Pro Plus 6.0. The mean score of the fibrotic area divided by Pbm was calculated (41). PAS-stained sections were used for evaluating goblet cell hyperplasia. The bronchioles with 1.0–2.5 mm-long epithelial basement membranes were selected, and the area of goblet cells was measured as the area of PAS-positive staining using Image-Pro Plus 6.0. Subsequently, the ratio of the area of PAS-positive staining to Pbm was calculated (42). In addition, myofibroblast activation and angiogenesis were assessed by immunohistochemical analysis for α-smooth muscle actin (α-SMA) (1:200; cat. no. sc-15320; Santa Cruz Biotechnology, Inc.) and CD31(1:100; cat. no. sc-28188; Santa Cruz Biotechnology, Inc.). The areas of peribronchial a-SMA-positive immunostaining and CD31-positive immunostaining in the submucosa were outlined and determined by Image-Pro Plus 6.0 and the expression levels of these markers were quantified by the area of α-SMA and CD31-positive staining relative to Pbm (43).
Statistical analysis
The data are expressed as the mean ± SEM. Statistical analysis was performed using GraphPad Prism 5 software (GraphPad Software, Inc.). One-way ANOVA with Bonferroni's multiple comparisons test was used to determine statistical significance between experimental groups. P<0.05 was considered to indicate a statistically significant difference.
Discussion
In the current study, the data indicated that intranasal administration of IL-27 significantly inhibited airway inflammation and AHR in the acute mouse models of experimental asthma. This finding is consistent with a study reported by Su et al (22) highlighting that preventative administration of IL-27 could reduce airway inflammation and improve AHR in asthmatic mice. In addition, the present study demonstrated that intranasal administration of IL-27 attenuated significant airway remodeling in chronic mouse models of experimental asthma. To the best of our knowledge, this is the only study which examined the effects of IL-27 on airway remodeling using a chronic asthma model. The data indicated that phosphorylation of STAT1 and STAT3 was impaired in the lung tissues of asthmatic mice and could be reversed by IL-27 administration.
As a pleiotropic cytokine, IL-27 is involved in the regulation of immune responses of certain inflammatory cells, such as Th cells, dendritic cells and macrophages (44). Therefore, IL-27 may be implicated in the pathogenesis of autoimmune and inflammatory diseases including asthma (45). Chronic airway inflammation is one of the main characteristics of asthma and plays a critical role in the pathogenesis of this disorder (46). Various types of cells, such as eosinophils, T cells, mast cells and neutrophils, are involved in the inflammatory response to allergens during asthma progression (20). AHR is one of the key features characteristic of asthma and one of the main factors responsible for the pathogenesis of this disease (47). AHR is characterized by increased airway resistance and decreased airway compliance (48). The results of the present study highlighted that intranasal administration of IL-27 could reduce inflammatory cell numbers in BALF samples and reverse methacholine-induced AHR. This indicated that IL-27 could effectively attenuate airway inflammation and AHR in experimental asthma. Furthermore, the serum and BALF concentration levels of the Th1 cytokines (IFN-γ) increased, whereas levels of Th2 cytokines (IL-4, IL-5, and IL-13) decreased in the OVA+IL-27 group compared with the OVA group, which suggested that enhanced production of Th2 cytokines and/or decreased production of Th1 cytokines may contribute to the effects of IL-27 on allergic asthma in this experimental model. These findings concur with a previous study, which demonstrated that preventative administration of IL-27 diminished BALF concentration levels of Th2 cytokines, such as IL-5 and IL-13 (22). IL-27 activates naive CD4+ T cells and natural killer (NK) cells to stimulate production of IFN-γ (49). Moreover, it can upregulate the expression levels of IL-12Rb2 and T-bet to promote Th1-effector function (49). Both IFN-γ and T-bet play a role in the suppression of AHR and eosinophil lung infiltration, indicating that IL-27 may have regulatory effects on asthmatic immune responses and promote the development of Th1 (50). In addition, IL-27 can directly suppress Th2 cell differentiation and conversely induce these cells to develop into Th1 cells that produce IFN-γ (17). Under Th2 polarization conditions, naive IL-27 receptor WSX-1-/- CD4 T cells increased production of Th2 cytokines (14). Previous studies showed that certain cytokines, such as IL-4, IL-5 and IL-13, play important roles in the initiation of airway inflammation, AHR and in variable airflow obstruction (15,51). Administration of IL-27 attenuated allergen-induced AHR and airway inflammation, which are hallmarks of allergic asthma (17,22,23). These studies are in concordance with the present work and demonstrated that IL-27 significantly suppresses Th2 cytokine production.
IL-17 is secreted by multiple cell types, such as Th17, NK cells, mast cells, neutrophils and γδ T cells (52). IL-17 cytokines are also key players in several immune responses (52). Serum and BALF IL-17 levels were significantly downregulated in the OVA+IL-27 group compared with those noted in the OVA group. These findings suggested that IL-17 plays a role in allergic asthma and that IL-27 acts in a manner antagonistic to IL-17, which is in accordance with previously reported data (21,53). Moreover, a previous study revealed that high levels of IL-17 were found in induced sputum and bronchial biopsies obtained from severe asthmatics and were associated with poor patient response to steroids (54). IL-27 inhibited the differentiation of Th17 cells by suppressing the expression of retinoic acid-related orphan receptor (ROR)γ and RORα (55). In addition, IL-27 has a direct effect on effector T cells and inhibited the development of IL-17-producing Th cells (56). Furthermore, IL-27 inhibited the expression of granulocyte-macrophage colony-stimulating factor, which is a regulator of Th17 cells (57).
Airway remodeling is a central feature of asthma (42). This condition includes epithelial changes, thickening of basement membrane, hypertrophy and hyperplasia of airway smooth muscle, angiogenesis, increased deposition of collagen proteins and subepithelial fibrosis (58). Airway remodeling is the main etiological factor of airflow limitation, bronchial hyperreactivity and mucus production (51). In the present study, it was initially shown that IL-27 could reduce the number of mucus-containing airway goblet cells (PAS-positive), the thickening of the basal membrane and the hyperplasia of airway smooth muscle cells. Previous studies have shown that in airway epithelial cells, both goblet cell hyperplasia and mucus overproduction can be induced by IL-13 (59,60). In addition, certain Th2 cytokines exhibit a negative effect on epithelial hypertrophy in a murine model of asthma (41,61). Therefore, IL-27 may modulate goblet cell proliferation, mucus production, and thickening of airway wall via a pathway including IL-13 and other cytokines.
Subsequently, subepithelial fibrosis was examined, which is an important feature of airway remodeling in asthma (62). The data indicated that OVA induced the activation of myofibroblasts (those expressing α-SMA) in the experimental model of chronic asthma, whereas IL-27 inhibited this process. Furthermore, IL-27 decreased the area of Masson's-stained sections, which reflected reduced deposition of collagen, which is an ingredient of the extracellular matrix (ECM) (62). It was reported that higher numbers of fibroblasts are associated with severe asthma. The accumulation of peribronchial myofibroblasts was detected in a mouse model of chronic asthma (63,64). Myofibroblasts and fibroblasts are the major sources of ECM proteins and deposition of the ECM, along with other components, such as fibronectin and glycoproteins, contributed to subepithelial fibrosis (62). IL-27 was found to suppress differentiation of myofibroblasts and fibroblasts and thereby alleviated the process of pulmonary fibrosis (65). Therefore, IL-27 may play a pivotal role in subepithelial fibrosis in the experimental model of chronic asthma.
Finally, the level of angiogenesis was assessed, and the vascular surface area was quantified by immunohistochemical staining of CD31. Therefore, the extent of airway vascularity was increased in OVA-induced asthmatic mice compared with PBS-induced subjects. These data are consistent with previous reports (66,67). Notably, the degree of angiogenesis was reduced in the OVA+IL-27 group. Lung inflammation may contribute to neovascularization and inflammation stimulated by effector cells, such as eosinophils, mast cells and macrophages, which are the major sources of various angiogenic and lymphangiogenic factors (66). Vascular endothelial growth factor (VEGF) may be an important player in the development of angiogenesis in asthma, whereas IL-27 can suppress both VEGFA mRNA expression and protein secretion (68). This suggested that IL-27 may control vascular remodeling. It was shown that IL-27 can inhibit angiogenesis in the tumor microenvironment in various malignancies such as prostate and lung cancer, which is a known anti-tumor mechanism (69). Taken together, the findings suggested that IL-27 can attenuate airway remodeling in a chronic mouse model of asthma.
It was that IL-27 can activate multiple signaling cascades, including Janus kinase (JAK) 1, JAK2 and tyrosine kinase-2 (70). STAT enzymes are the downstream proteins of JAKs (70). A previous in vitro study revealed that the effects of IL-27 on epithelial cells are dependent on STAT1 and STAT3 signaling pathways (71). IL-27 can exert its effects on T cells by inducing the phosphorylation of STAT1/STAT3/STAT5. In the current study, it was shown that both the STAT1 and STAT3 pathways were suppressed in the OVA group, whereas the opposite effects were noted in the OVA+IL-27 group, which indicated that the STAT1 and STAT3 pathways were impaired in the OVA-induced mice model of asthma. This impairment was reversed following IL-27 treatment. The STAT1 pathway is critically important for IL-27 signaling, which results in the induction of Th1 differentiation and the inhibition of Th2 differentiation (44). Following IL-27-stimulated activation of STAT1 signaling, the expression of T-bet was induced. T-bet serves as the main regulator of Th1 differentiation and of the expression of intercellular adhesion molecule 1 (ICAM-1)/lymphocyte function-associated antigen 1 (LFA-1) (12). The latter molecules interact and induce extracellular signal-regulated kinase activation (ERK) (67). ERK is located downstream of ICAM-1/LFA-1 and plays an important role in modulating the polarizing of naive T-helper cells toward Th1 subsets (12). Accordingly, IL-27 promotes early Th1 commitment by enhanced expression of IL-12Rβ2 and production of IFN-γ (12,72). Formation of the IL-12 receptor complex with IL-12 Rβ1 and IL-12 Rβ2 leads to the cells response to IL-12, which is indispensable for Th1 initiation (72). In addition, IL-27 was reported to activate T-bet and lead to IFN-γ secretion via the p38/mitogen-activated protein kinase signaling pathway, which is independent of JAK/STAT (11). Moreover, STAT1 is required for the suppression of the Th2-specific transcription factor, GATA-3 (73). In the presence of IL-2 and IL-4, naïve Th cells express GATA-3 at a high level and develop into Th2 cells (16). By suppressing GATA-3, IL-27 represses Th2 lineage commitment, which is dependent on STAT1 (73). Moreover, T-bet can directly interact with GATA-3, which interferes with the binding of GATA-3 to its target DNA, and causes inhibition of Th2 differentiation (74). In the present study, IL-27 upregulated T-bet expression and downregulated GATA-3 expression. These findings are in concordance with previous reports (12,23).
In addition to STAT1 activation, IL-27 can increase STAT3 activation in naive CD4+T cells. Augmented activation of STAT3 is found to serve as a counterbalance to activation of STAT1 (18). The activation of STAT3 and STAT1 are reciprocally regulated and their balance in phosphorylation levels is key to maintaining appropriate immune responses (75). IL-27-induced activation of the STAT3 signaling pathway is important for proliferation and differentiation of T-cells (45,70). The expression levels of T-bet and GATA-3 can be modulated by STAT3 along with STAT1, leading to the positive or negative regulation of Th1 and Th2 differentiation (73). By activation of the STAT1 and STAT3 pathways, IL-27 also inhibited γδ T cells from producing Th2-related cytokines, such as IL-5 and IL-13 (76) in the immune response against tumors. STAT3 activation further plays an important role in Th17 cell differentiation (77). Activated STAT3 directly binds to IL-17A and IL-17F promoters and increased IL-17 gene transcription (77). In addition to the activation of STAT3, the induction of RORγt, a master regulator of Th17 cell differentiation, is required for the expression of genes encoding IL-17 in naïve CD4+ Th cells (78). IL-27 can modulate the activity of RORγt and plays an important role in the development of Th17 cell differentiation (78). These findings are in alignment with the evidence of the present study, which indicated that the STAT1 and STAT3 pathways were suppressed in the OVA group and activated in the OVA+IL-27 group. This evidence demonstrated that IL-27 upregulated the phosphorylation of STAT1 and STAT3 proteins and restored the STAT1 and STAT3 signaling pathways in the asthma mouse model used.
In summary, the present study demonstrated that intranasal administration of IL-27 could alleviate airway inflammation and AHR by restored both the STAT1 and STAT3 pathways in an experimental mouse model. The present study provided additional evidence that IL-27 could ameliorate airway remodeling in mice with chronic allergen exposure in vivo. These findings will add insight into the multifaceted role of IL-27 in asthma. Additional studies are required to ensure the potential therapeutic applications of IL-27 in asthma. The exact mechanism of IL-27 in therapeutic action requires further investigation.