The Induction of IL-33 in the Sinus Epithelium and Its Influence on T-Helper Cell Responses

Michael B. Soyka; David Holzmann; Tomasz M. Basinski; Marcin Wawrzyniak; Christina Bannert; Simone Bürgler; Tunc Akkoc; Angela Treis; Beate Rückert; Mübeccel Akdis; Cezmi A. Akdis; Thomas Eiwegger

doi:10.1371/journal.pone.0123163

Abstract

Background

Chronic rhinosinusitis (CRS) is characterized by epithelial activation and chronic T-cell infiltration in sinonasal mucosa and nasal polyps. IL-33 is a new cytokine of the IL-1 cytokine family that has a pro-inflammatory and Th2 type cytokine induction property. The role of IL-33 in the pathomechanisms of CRS and its interaction with other T cell subsets remain to be fully understood.

Methods

The main trigger for IL-33 mRNA expression in primary human sinonasal epithelial cells was determined in multiple cytokine and T-cell stimulated cultures. The effects of IL-33 on naïve, Th0 and memory T-cells was studied by PCR, ELISA and flow cytometry. Biopsies from sinus tissue were analyzed by PCR and immunofluorescence for the presence of different cytokines and receptors with a special focus on IL-33.

Results

IL-33 was mainly induced by IFN-γ in primary sinonasal epithelial cells, and induced a typical CRSwNP Th2 favoring cytokine profile upon co-culture with T-helper cell subsets. IL-33 and its receptor ST2 were highly expressed in the inflamed epithelial tissue of CRS patients. While IL-33 was significantly up-regulated in the epithelium for CRSsNP, its receptor was higher expressed in sinus tissue from CRSwNP.

Conclusions

The present study delineates the influence of IL-33 in upper airway epithelium and a potential role of IL-33 in chronic inflammation of CRSwNP by enhancing Th2 type cytokine production, which could both contribute to a further increase of an established Th2 profile in CRSwNP.

Citation: Soyka MB, Holzmann D, Basinski TM, Wawrzyniak M, Bannert C, Bürgler S, et al. (2015) The Induction of IL-33 in the Sinus Epithelium and Its Influence on T-Helper Cell Responses. PLoS ONE 10(5): e0123163. https://doi.org/10.1371/journal.pone.0123163

Academic Editor: Derya Unutmaz, Jackson Laboratory, UNITED STATES

Received: January 21, 2015; Accepted: February 20, 2015; Published: May 1, 2015

Copyright: © 2015 Soyka et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited

Data Availability: All relevant data are within the paper.

Funding: This work was supported by grants from: Swiss National Science Foundation Grants No. 320030_140772, 320030_132899; Müller-Gierok Foundation, Bern; funds from the Oesterreichische Nationalbank (Anniversary Fund, project number 13846ONB); Christine Kühne-Center for Allergy Research and Education, Davos; and Austrian Science Fund Project, grant numbers F4615-B19, F4605-B19. Tomasz M. Basinski was the recipient of European Respiratory Society Fellowship (Number 312). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: This work was supported by grants from: Swiss National Science Foundation Grants No. 320030_140772, 320030_132899, Müller-Gierok Foundation, Bern, funds from the Oesterreichische Nationalbank (Anniversary Fund, project number 13846ONB, Christine Kühne-Center for Allergy Research and Education, Davos. Tomasz M. Basinski was the recipient of European Respiratory Society Fellowship (Number 312). This does not alter the authors' adherence to PLOS ONE policies on sharing data and materials.

Introduction

Chronic rhinosinusitis (CRS) is defined as an inflammation of the nose and the paranasal sinuses and is estimated to affect more than 200 million patients worldwide [1]. The inflammatory response represents an essential mechanism of defense of the mucosa against viral, fungal and bacterial infections [2–4]. All of them lead to an overwhelming inflammatory response resulting in tissue damage, healing and remodeling [5–7]. However, the key players in this process remain to be defined in detail[8]. Based on current knowledge on CRS, several T-cell subsets are involved in the chronic phase that succeeds over counter-regulatory and anti-inflammatory mechanisms controlling these subsets [9].

Th2 cytokines and T-regulatory (Treg) cell-associated transcription factors (FOXP3) and cytokines (IL-10, TGF-β) have been shown to be altered in sinus tissue from CRS patients [10–12]. The recently described alarmin, IL-33 is an interesting target, since it is considered to act as an endogenous danger signal that is upregulated upon tissue damage or inflammation [13,14]. IL-33 is considered to be among the most potent inducers of Th2 type inflammation on mucosal tissues and signals via its receptor ST2. [15] It has been reported to induce IL-13 and IL-5 and thereby may counteract Th1 and also Th17 inflammatory responses. IL-33 has recently come into focus of research in CRS, as its receptor ST2 has been shown to be elevated in CRSwNP and IL-33 responsive innate lymphoid cells were found in nasal polyps [16,17]. Furthermore, constitutive IL-33 expression is present in epithelial cell cultures of recalcitrant CRSwNP patients [18]. These facts point to the idea of IL-33 as a contributor to the pathogenesis of CRS with its link to a Th2 predominant inflammation as it does in allergic disease[19].

The present study focused on the IL-33 mediated induction via T-cell and T-cell-related cytokines and the interrelationship between IL-33 and T-helper subsets. We demonstrate that IL-33 expressing cells are present in CRS tissues and identified IFN-γ as a potent IL-33 inducing factor. In addition, IL-33 skews inflammation towards a Th2 predominance and thus may contribute to the pathogenesis and chronic nature of CRS.

Methods

Subjects

Seventy patients referred to sinus surgery with clinical and radiologic evidence for chronic rhinosinusitis, according to the definition in the European Position Paper on Rhinosinusitis and Nasal Polyps,[20] were included in the study. The control group consisted of 19 patients operated on the paranasal sinuses for reasons unrelated to CRS. Patients with immune deficiency or under systemic immunosuppressive therapy were excluded. Both systemic and local corticosteroid treatment was stopped 6 weeks prior to biopsies. All operations were performed in exacerbation free intervals. Patient history related to allergy was recorded and allergy testing was performed by measurement of the total serum IgE level and the ImmunoCAP (Thermo Fisher, Reinach, Switzerland) SX1 test for a panel of allergens (for further details please refer to the online supplementary).

Tissue samples were obtained during endoscopic, endonasal approaches under general anaesthesia. In detail, the chosen procedure was adapted to the underlying disease and has been carried out in a standardized manner [21]. Sinonasal biopsies were collected in the region of affected mucosa in the anterior ethmoid, in particular the ethmoid bulla or uncinate process. In CRSwNP patients, samples were taken directly from polypoid tissue in the region of the infundibulum ethmoidale. In control patients, who did not need paranasal sinus surgery either the lateral portion of the middle turbinate or mucosa from the middle meatus was harvested, always as far away as possible from the potential pathology.

In parallel, peripheral blood was taken into lithium heparine tubes by venopuncture. Written informed consents were obtained from all patients. The study protocols, including patient information forms, have been approved by the ethical committee of the canton of Zurich (#528).

Real time PCR

Sinus biopsies were stored in RNA-later (Quiagen, Hilden, Germany) immediately after removal, and total RNA was isolated from the homogenate within 24 h after homogenization with RNase-free beads using a Precellys 24 (Bertin Technologies, Montigny-le-Bretonneux, France). 6.5 ng cDNA or standardized cell numbers were applied for real time RT-PCR. The details and primer sequences are found in the online repository.

Immunofluorescence

Biopsies were immediately embedded in Optimal Cutting Temperature (OCT) compound (Sacura Seiki, Tokyo, Japan) and stored at -80°. Samples were cut (7 μm), mounted, air-dried and fixed in 4% paraformaldehyde (PFA), permeabilized and blocked.

IL-33 staining was performed with a primary antibody against IL-33 (1:100; clone Nessy-1 ALEXIS Biochemicals, San Diego, CA, USA) and a secondary Alexa Fluor® 488 labeled goat anti mouse antibody (1:4000 Biolegend, San Diego, CA, US). Slides were mounted with Vectashield Mounting Medium containing 4‘, 6-diamino-2-phenylindole (DAPI) for nuclear staining (Vector Labolatories, Burlingame, CA, USA) and examined by confocal laser scanning microscope Leica TCS SP5 (Leica Microsystems, Glattbrugg, Switzerland).

ELISA, flowctometry and Wetern blot

Multiplex-ELISA (Bioplex, Bio-Rad Laboratories, Hercules, CA, USA) was performed according to the manufacturers´ instructions. IL-33 ELISA was performed using the human IL-33 ELISA development kit 900-K398 (PeproTech, Rocky Hill, NJ, USA) according to the manufacturer’s instructions.

The number of INF-γ-, IL-13-, IL-4- and IL17A-producing CD3^pos CD4^pos cells was assessed in naïve and memory subsets. Intracellular and surface staining of T-cells as well as procedures are described elsewhere [22–25].

Western blots were performed as described previously using the same primary antibody against IL-33 as described above (clone Nessy-1 ALEXIS Biochemicals, San Diego, CA, USA) [26].

Isolation and culture of primary HSEC

Primary HSEC were isolated and purity was checked as described [9] and subjected to different stimuli at 80% confluence. Cells between passages 1 and 3 were used in all experiments. HSEC cells for functional experiments were cultured in serum-free bronchial epithelial cell medium in humidified atmosphere containing 5% CO₂ at 37°C and grown until 80% confluence and subjected to cytokines (for details we refer to the online repository). Messenger RNA induction was monitored after 8h and protein induction was measured in cell free supernatant after 72h. Depending on the respective experiment cells were cultured in 48 or 6 well plates flat bottom plates.

The cytokines and its concentrations used throughout the study are found in the online repository.

T-cell experiments

Naive CD4⁺ T-cells (CD45 RA⁺) and CD4⁺ CD45 RO⁺ T-cells were purified from peripheral blood mononuclear cells (PBMC) from buffy coats via magnetic cell sorting [27,28]. In brief, initially CD4+ RA+ cells were isolated via negative selection (naïve T-cell isolation kit, Miltenyi Biotech Bergisch Gladbach, Germany). Thereafter residual CD45RA+RO+ double positive cells were removed by an additional CD45RO depletion step.

Direct impact of IL-33 on CD3+CD4+CD45RA+ cytokine polarization was monitored. To asses direct impact of IL-33 on naïve T-cells in the absence of initial TCR stimulation, naïve T-cells were stimulated for 7 days with IL-33 (10ng/ml) in the presence of IL-2 (100 IU/ml).

For T-cell differentiation, naïve T-cells were stimulated with a combination of soluble anti-CD2 (0.25 μg/mL; CLB Amsterdam Netherlands), anti-CD3 (0.25 μg/mL, clone OKT3, ATCC, Maryland, USA), and anti-CD28 (0.25 μg/mL clone 15E8, CLB Amsterdam Netherlands) in the presence of IL-33 (10 ng/ml) and of different cytokine cocktails that drive differentiation direction Th0, Th1, Th2, Th9, Th17 and Treg as described in detail by Burgler et al.[27] Polarization was confirmed after TCR re-stimulated via PCR analysis.

Memory T-cells were isolated via positive isolation of the CD45RO-positive fraction CD3+CD4+ (T-helper isolation kit II, Miltenyi Biotec, Bergisch Gladbach, Germany) subset. The memory subset was co cultured with IL-33 (10 ng/ml) in the presence of IL-2 (100 IU/ml) for 7 days and cytokines were measured in cell free supernatant via bead-based ELISA.

Statistical analysis

Statistical comparison between the groups was performed by nonparametric Mann-Whitney U-test, Wilcoxon Rank Sum test or unpaired Student‘s t-test according to statistical standards based on the number of samples and homogeneity/heterogenity of the datasets. For frequency analysis Fisher’s exact test was applied. A p-value < 0.05 was considered significant.

Results

IL-33 is up-regulated in primary human sinus epithelial cells upon IFN-γ stimulation

In order to investigate the most potent inducers of IL-33 in human primary sinonasal epithelial cells, a large panel of cytokines and combinations of such were used to stimulate epithelial cell cultures. The Th1 prototype cytokine IFN-γ turned out to be the most effective inducer of IL-33 mRNA (Fig 1A). This IFN-γ -related effect was found unrelated to the clinical features of the donor (Fig 1B). Both IL-33 mRNA and IL-33 protein expression were increased by IFN-γ in a dose dependent manner (Fig 1C). The biologically active, non-cleaved version of IL-33, was confirmed by Western Blot (Fig 1D). Thereafter, we confirmed the Th1 dependence of our findings by adding different T-cells subsets, differentiated from naïve T-cells, to the epithelial cells. Only Th1 cells significantly upregulated IL-33 mRNA expression in primary human sinonasal epithelial cell cultures (Fig 1E). Th2, Th17, Th9 and Treg cells did not exert any influence on IL-33 expression.

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Fig 1. IFN-γ is a strong inducer of IL-33 in sinonasal epithelial cells.

Primary sinus epithelial cells (CRS patient) were subjected to T-cell lineage specific or T-cell related cytokines or their combinations. mRNA expression of IL-33 was measured via real time RT-PCR. IFN-γ induced a relevant increase in IL-33 (A). The observed effects are independent of the source of HSEC cells (B; n = 5; mRNA levels are expressed as fold expression of the unstimulated control). The induction of IL-33 via IFNγ was dose dependent (C). The presence of the uncleaved form of IL-33 after co-culture of HSEC with 50 μg/ml IFNγ was confirmed by western blot (D). Only Th1 cells, but not Th2, Th9, Th17 or Treg were significantly up-regulated IL-33 mRNA expression in HSECS (E).

https://doi.org/10.1371/journal.pone.0123163.g001

Modulation of naïve, memory and Th0 responses by IL-33

Potential interactions between IL-33 and Th-cell subsets were investigated in naïve and effector/memory T-cells. First, we investigated the impact of IL-33 on purified naïve T-cells. A Th2 favoring effect of naïve T-cells in the presence of IL-2 was observed at mRNA levels without significantly affecting IFN-γ and IL-17 mRNA production (Fig 2A). IL-33 seems to be more effective on memory and effector T-cell subsets, which actually play the key role in tissue inflammation. Consequently, CD45RO⁺ CD4⁺ T-cells were isolated from healthy donors and cultured with IL-33, which led to a significant up-regulation of the Th2 type cytokines IL-4 and IL-5 (Fig 2B).

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Fig 2. IL-33 favors Th2 cell development.

Naïve T-cells were isolated from PBMCs of and purified via magnetic cell sorting. CD45RA+CD45RO- CD4+ T-cells were stimulated with IL-33 in the presence of IL-2 for 5 days and thereafter subjected to TCR stimulation. mRNA expression was assessed after 8 hours (A, n = 5). Th2-type cytokine production of purified memory T-cells (CD45RO+CD45RA- CD4+ T-cells) was significantly increased by IL-33. (B, n = 8) Mean +/- SEM.

https://doi.org/10.1371/journal.pone.0123163.g002

Thereafter, the impact of IL-33 during the course of T-cell maturation from naïve cells towards Th0 was investigated. The frequency of IL-13-producing cells was up-regulated, whereas IFN-γ-producing cells decreased in 4 out of five experiments. There was no evidence for the induction of IL-17A under these conditions (Fig 3).

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Fig 3. Impact of IL-33 on Th0 cell differentiation from naïve T cells.

Naïve T-cells from buffy coats were differentiated into Th0 (n = 5) in the presence or absence of IL-33 (10 ng/ml) and thereafter subjected to intracellular cytokine staining. IL-33 promoted an increase in Th2-producing cells in four out of five experiments. There was no evidence of an IL-17 induction.

https://doi.org/10.1371/journal.pone.0123163.g003

Sinus tissue from chronic rhinosinusitis patients shows a mixed pro-inflammatory cytokine profile and an upregulation of IL-33

Whole sinus tissue mRNA analysis of a broad panel of cytokines, cytokine receptors and transcription factors was performed to investigate the general proinflammatory cytokine profile and also in relationship with Th1, Th2, Th17 and Treg-cell-subsets. The inflammatory character of CRSwNP is represented with significantly elevated IL-1β, IL-6, IL-8, IL-13 and ST2 compared to controls samples (Fig 4). In line with previous publications CRSwNP represent a more Th2 type inflammation as reflected in significantly augmented IL13 and ST2 expression and and a trendwise increased IL5 expression. In CRSsNP IL-8, IL-33, and ST2 were significantly elevated compared to controls. The upregulation of IL-33 in CRSsNP and of its receptor ST2 in both types of CRS led to an investigation of protein expression in the tissue. An enhanced expression of IL-33 in CRS patients compared to control tissue was visualized in epithelial cells by immuno-fluorescent staining (Fig 5).

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Fig 4. Sinus tissue from chronic rhinosinusitis patients shows a mixed pro-inflammatory cytokine profile.

Whole sinus tissue mRNA from CRS patients (CRSsNP n = 16; CRSwNP n = 8) and controls (n = 8) of an array of cytokines and transcription factors was quantified by real time PCR (Mann Whitney U-Test; mean +/- SEM).

https://doi.org/10.1371/journal.pone.0123163.g004

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Fig 5. IL-33 expression in CRS tissue.

IL-33 is expressed in the sinus epithelium of CRS patients in vivo (A; one out of three independent experiments; CRSwNP shown). Nuclear staining with DAPI in blue, IL-33 in green.

https://doi.org/10.1371/journal.pone.0123163.g005

Discussion

Chronic rhinosinusitis (CRS) is defined as a chronic inflammation of the nose and the paranasal sinuses. Both T-cells and epithelial cells contribute to this state. To date, counter regulatory mechanisms of inflammation that are generated from the tissues as a result of the inflammatory processes and in turn favor chronic inflammation have been poorly understood. Particularly, in the context of rhinitis/rhinosinusitis and T-cell inflammation, there is scant data for a role of IL-33. In the present study we demonstrate the interrelationship between the epithelium, the influence of IL-33 and T-cells as important players in inflammation.

IL-33 possesses several functions that fit to the picture of CRS as a member of the IL-1 cytokine family [29,30]. Polarized Th2 cells, mast cells and basophils produce enhanced amounts of Th2 type cytokines in response to IL-33. Eosinophils are among the major responder cells [31]. A potential role in nasal polyposis due to a linkage of IL-33 polymorphisms to clinical disease and on type2 innate lymphoid cells has been suggested [32]. In this study an enrichment of IL-33 responsive CRTH2⁺ ILC2s is shown in nasal polyps providing a source of TH2 cytokines. Our findings were in line with previous reports, where ST2 expression was elevated in CRSwNP/eosinophilic CRS [16,17]. The reports on the levels of IL-33 itself are heterogeneous. Elevated IL-33 levels were observed in recalcitrant CRS [18]. However, no information about the site of inflammation has been provided in these studies and the inducers for IL-33 remained to be elucidated. In our study, IL-33 was higher in CRSsNP, whereas its receptor ST2 was higher in the CRSwNP group. This may relate to types of inflammation described for CRSsNP and CRSwNP with a higher frequency of ST2-bearing cells (i.e. Th2 cells and Th2-related cells). We suggest that the overexpression of ST2 in CRSwNP represents a more accurate marker of chronic IL-33 driven inflammation. As IL-33 itself is only released upon epithelial cell destruction as a potential counter-regulator of the initial Th1-caused injury it may result in a collateral Th2 inflammation as a result of the Th2 skewed local milieu with a high ST2 receptor and Th2 density in CRSwNP.

It is still unclear what the main factors for the induction of IL33 at mucosal sides are. Here, we provide the first data on induction of IL-33 and its high expression confirmed at a protein level in human upper airway epithelium. We demonstrate in the present study an important role for IFN-that is released e.g. via viral infections in the induction of epithelial cell-mediated inflammation and, in a second step, the induction of apoptosis of sinus epithelial cells [9]. Recently, an important role of IL-33 in anti-viral defense has been reported [33]. The linkage of viral infection IL33 and Th2 inflammation in the context of asthma has been fostered by a recent publication that described the induction of IL33 in a human experimental model of rhinovirus infection [34,35]. In line with our study, the induction of IL-33 by IFN-γhas been shown in keratinocytes [36] and gastric epithelial cells [37]. In clinically stable cystic fibrosis, IL-33 has been correlated with IL-8 and IL-13 levels in broncho-alveolar lavage fluid.[38] Especially, the importance of apoptosis in the termination of the pro-inflammatory feedback loop seems to be an important anti-inflammatory mechanism [29]. This could be an additional so far undefined, mechanism to limit inflammation if necrosis occurs, whereas the process of apoptosis itself limits IL-33- mediated effects via cleavage and inactivation. In addition, the Th2 inducing role of IL-33 may act as an important mediator in the skew to a Th2 microenvironment. In line with our data, an association between the polymorphisms of the receptor for IL-33 and surgery unresponsive CRS has been reported [39]. The loci rs13431828 of the interleukin-1 receptor-like gene showed the highest association with CRS.

Nasal polyps are one of the major phenotypes in the context of CRS and differential cytokine patterns and have been described [40]. Although general patterns like elevated Th2 type cytokines, such as elevated IL-5 and IL-13 expression with concomitant ST2 up-regulation were detected in CRSwNP, some differences as compared to recently published datasets were observed. We could not detect GATA3 and Tbet up-regulation with FOXP3 down-regulation in CRSwNP as observed by others [11,41]. This may reflect a more pronounced heterogeneity within our population. The herein described patient group seems to represent a more inflammatory phenotype that is closer to the so called “Chinese phenotype” in terms of IL-1β, IL-6 up-regulation and IL-17A linkage, but also shows strong Th2 type phenomena as observed in other Caucasian populations [12,41].

Our findings provide important data for multi-faceted types of inflammation in CRS both with or without NP. There is definitely a possibility that different endotypes and cytokine profiles in a farm and mountain dominated environment, such as Switzerland with different living circumstances harbor the possibility to show different inflammatory patterns. There is a high likelihood that there will be new endotypes of CRS that will be more and more defined as currently happening for asthma [5,42] and the mixed cytokine profiles demonstrated here will be better explained and gain more attention.

In the present study, IL-33 induces Th2 type cytokines in naïve and memory T-cells. IL-33/ST-2 driven induction of Th2 cytokine secreting cells from naïve T-cells was observed in an IL-4 independent way [43,44]. Although we detected IFN-γin these conditions, we cannot know whether the observed values reflect the level that is already suppressed by IL-33 or by other IFN-γ-suppressing conditions such as Th2 cytokines. We consider local inflammation in CRS tissue of dynamic nature and the co-occurrence of several T-cell types is a pre-requisite to make chronicity of the disease possible.

In conclusion, the present study suggests novel mechanisms due to the mixed T cell cytokine profile and their interaction with IL-33. IL-33 that is up-regulated by IFN-γcontributes to the Th2 arm, which may enhance chronicity in CRSwNP. With the results from our single-cytokine experiments a tissue model is suggested, where IFN-γdriven tissue damage leads to the expression of IL-33 as an alarmin, which in turn favors the switch from a Th1/Th17 to a rather Th2 type inflammation (Fig 6).

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Fig 6. The interaction of IL-33 with Th1, Th2 and Th17 responses in chronic rhinosinusitis.

IL-33 may act as an “alarmin” that is released by HSECS via a Th1 dependent mechanism. IL-33 itself induces IL-13 and IL-5 and thereby contributes to the limitation of both Th17- and Th1-related arms of the inflammation.

https://doi.org/10.1371/journal.pone.0123163.g006

Author Contributions

Conceived and designed the experiments: TE CAA. Performed the experiments: TE DH TB MW CB TA SB AT BR. Analyzed the data: TE MS MA CAA. Contributed reagents/materials/analysis tools: TE MA CAA. Wrote the paper: TE MS CAA.

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Figures

Abstract

Background

Methods

Results

Conclusions

Introduction

Methods

Subjects

Real time PCR

Immunofluorescence

ELISA, flowctometry and Wetern blot

Isolation and culture of primary HSEC

T-cell experiments

Statistical analysis

Results

IL-33 is up-regulated in primary human sinus epithelial cells upon IFN-γ stimulation

Modulation of naïve, memory and Th0 responses by IL-33

Sinus tissue from chronic rhinosinusitis patients shows a mixed pro-inflammatory cytokine profile and an upregulation of IL-33

Discussion

Author Contributions

References