Project description:This study identifies differentially expression genes in the sputum of people with eosinophilic, neutrophilic and paucigranulocytic asthma. A selection of markers identified using this microarray were further validated using qPCR on a wider sample set. Gene expression profiles were generated from induced sputum samples from 47 asthma patients and were grouped by the inflammatory phenotype assigned using sputum cell counts into neutrophilic asthma (n=12), eosinophilic asthma (n=17) and paucigranulocytic asthma (n=18). RNA was extracted, amplified and hybridised to Illumina Sentrix HumanRef-8 Version 2 Expression BeadChips, and genes that were differentially expressed between asthma inflammatory phenotypes were compared.

Project description:Asthma is a complex, chronic respiratory disease with marked clinical and pathophysiological heterogeneity. Distinct inflammatory phenotypes of eosinophilic, mixed, neutrophilic and paucigranulocytic asthma are identified in patients, but most in vivo mouse models, studying asthma mechanisms, mimic only eosinophilic phenotype in humans. The detailed unbiased in vivo studies on molecular responses among different kinds of inflammation in asthma models are lacking. Therefore, we developed mouse models representing three different inflammatory phenotypes of airway inflammation, namely eosinophilic, mixed, and neutrophilic asthma via different methods of house dust mite sensitisation. We used microarrays to determine the global gene expression in the lungs of mice with eosinophilic, mixed and neutrophilic inflammatory phenotypes to uncover underlying differences in clinical presentation and to find novel molecular targets and pathways, which might reflect different molecular mechanisms of the disease. By whole genome transcriptome profiling, we found that airway tight junction (TJ) molecules, mucins and inflammasome-related genes are differentially expressed in distinct phenotypes of allergic airway inflammation. Next, detailed analysis of several molecules from these families by quantitative RT-PCR, western blot and confocal microscopy revealed that (i) Zo-1 and Cldn18 were downregulated in all phenotypes, while Cldn4 upregulation was characteristic for neutrophilic airway inflammation; (ii) mucins Clca1 (Gob5) and Muc5ac were upregulated in eosinophilic and even more in neutrophilic asthma, and (iii) upregulation of inflammasome-related molecules such as Nlrp3, Nlrc4, Casp-1 and IL-1b was characteristic for neutrophilic asthma. Finally, we showed that inflammasome/Th-17/neutrophilic axis cytokines, namely IL-1b and IL-17 impaired epithelial barrier function and increased mucins expressions in primary human bronchial epithelial cells from normal and asthmatic donors. Our findings suggest that differential expression of TJs, mucins and inflammasome-related molecules in distinct asthma phenotypes could be mechanistically linked and might further reflect the differences observed in the clinic.

Project description:Severe asthma is a complex disease with different inflammatory phenotypes. Transcriptomic profiling has contributed to understanding the pathogenesis of asthma, especially type-2 inflammation; however, there is still poor understanding of non-eosinophilic asthma, and consequently there are limited treatment options. The aim of this study was to determine transcriptomic profiles in endobronchial biopsies of adults with severe asthma and different inflammatory phenotypes (neutrophilic, eosinophilic and paucigranulocytic) compared with healthy controls.

Project description:This study identifies differentially expression genes in the sputum of people with eosinophilic, neutrophilic and paucigranulocytic asthma. A selection of markers identified using this microarray were further validated using qPCR on a wider sample set.

Project description:Allergens Abrogate the Anti-inflammatory Property of DNA and Unmasks Macrophage/ILC2-STING-TNFα-driven Neutrophilic Asthma

Project description:Group 3 innate lymphoid cells (ILC3s) have emerged as an important player in the pathogenesis of neutrophilic asthma. However, the regulatory mechanism supporting ILC3 responses in lung remains largely unclear. Here, we demonstrated that stem cell factor (SCF) expression is significantly increased and positively correlated with IL-17A and MPO expression in asthmatic patients. Notably, we identified ILC3 as a major IL-17A-producing responder to SCF in lung. In mice, SCF synergized with IL-1β/IL-23 to enhance pulmonary ILC3 activation and neutrophilic inflammation. Mechanistically, SCF promoted ILC3 proliferation and cytokine production. Transcriptomic analysis revealed that SCF treatment upregulated the genes related to proliferation and Th17 differentiation, associated with increased AKT and STAT3 signaling. In contrast, deficiency of SCF receptor, c-Kit, reduced ILC3 proliferation and IL-17A production, resulting in the amelioration of airway hyperreactivity (AHR) and neutrophilic inflammation in mouse neutrophilic asthma model. Furthermore, genetic deletion of SCF in fibroblasts revealed fibroblasts as the primary source of SCF for ILC3 activation in lung. Moreover, administration of imatinib, a c-Kit inhibitor, alleviated LPS, air pollution or ovalbumin/LPS-induced AHR and neutrophilic inflammation. Our findings elucidated a positive modulatory role of SCF/c-Kit signaling in ILC3 responses during neutrophilic inflammation, offering a potential therapeutic target for neutrophilic asthma.

Project description:Different naïve or memory cell subpopulations (i.e., central memory/CM, effector memory/EM, or terminally differentiated effector memory/EMRA) are involved in asthma development, and they display variable levels of the CD26 (dipeptidyl peptidase 4/DPP4). The phenotype and/or severity of the disease could drive to a phenotypic shift in naïve/memory lymphocyte subsets. Therefore, the aim of our work was to evaluate the association of the phenotype and severity of asthma with the relative frequency of CD26-/lo, CD26int, and CD26hi subsets within CD4+ effector T cells (Teff), total CD4- lymphocytes, γδ-T cells, NK cells, and NKT cells. For that, flow cytometry analyses were performed in peripheral blood samples from healthy donors (N=30) and asthma patients (N=119) with different phenotypes/severities. To avoid a priori bias, we have performed a K-means clustering analysis including clinical and flow cytometry data, resulting in four groups, two of them with opposite inflammatory profiles (eosinophilic vs. neutrophilic). CD4-CD26hi cells were reduced in neutrophilic asthma, and negatively correlated with degree of systemic inflammation. Interestingly, the eosinophilic group displayed a general expansion of CD26-/lo lymphocyte subsets. The expansion of CD4+CD26-/lo Teff cells with a TEM/TEMRA phenotype was confirmed in asthma, especially in atopic patients. Further characterisation of this subset by LC MS/MS revealed upregulated levels of innate (e.g., MPO and RNASE2) and cytoskeleton/extracellular matrix (e.g., MMP9, ACTN1) proteins, which matches its terminally differentiated phenotype. Validation by immunofluorescence confirmed the presence of many of these proteins in CD4+ T cells, as well as an enrichment in “flower-like” nuclei and MMP9/RNASE2 levels in CD4+CD26-/lo Teff compared to CD4+ T lymphocytes. Therefore, there is an association between CD26 levels in different lymphocyte subsets and asthma phenotypes/severities. CD4+CD26-/loTEMRA cells expressing innate proteins specific to eosinophils/neutrophils could be relevant in sustaining long-term inflammation in adult allergic asthma.

Project description:lncRNA expression analysis in patients with eosinophilic and neutrophilic asthma

Project description:This project used a state-of-the-art, multi-omics approach to improve our understanding of the aetiopathogenesis of a highly prevalent, performance-limiting disorder of racehorses; mild to moderate equine asthma (MMEA). This advanced knowledge is a prerequisite to improving prophylactic, management and therapeutic options for this condition. Although a number of risk factors for MMEA have been identified, incomplete understanding of the precise aetiopathogenesis of this syndrome means that options for intervention are currently limited. This study aimed to apply a multi-omic approach, reveal key inflammatory pathways involved in inflammatory cell recruitment to the lower airways and highlight pathways specific to different MMEA inflammatory cell profiles (MMEA endotypes). Thus, we compared BALF cell gene and protein expression data from horses with normal bronchoalveolar lavage fluid (BALF) cytology (n = 8) with those isolated from horses with neutrophilic (n = 4), mastocytic (n = 8), mixed neutrophilic/mastocytic (n=4) and mixed eosinophilic/mastocytic (n=3) inflammation. Analyses on transcriptomic and proteomic data derived from BALF cells from horses with neutrophilic cytology showed enrichment in classical inflammatory pathways, while horses with mastocytic cytology showed enrichment in pathways involved in hypersensitivity reactions related to non-classical inflammation that could mimic a Th2 immune response. The mixed eosinophilic/mastocytic group also presented with a non-classical inflammatory profile while, the mixed neutrophilic/mastocytic group revealed profiles consistent with both neutrophilic inflammation and hypersensitivity. Our adopted multi-omics approach (both gene and protein expression) has enabled a more holistic assessment of the immunological status of the lower airways associated with the different cytological profiles of equine asthma.

Project description:Many neutrophilic asthma patients do not respond to current medications, highlighting the need for novel therapeutic targets. Here, we investigated the role of intraflagellar transport (IFT) complex protein IFT20 in neutrophilic asthma. Mice lacking CD4+ T cell-specific IFT20 displayed reduced protease-induced neutrophilic asthma inflammation. Thus, IFT20 may represent a promising therapeutic target for treatment of patients with neutrophilic asthma.