Project description:Patients with severe uncontrolled asthma represent a distinct endotype with persistent airway inflammation and remodeling refractory to corticosteroid treatment. CD4+ T cells and their canonical effector molecules, like type 2 cytokines, play a central role in orchestrating asthma pathogenesis, and biologic therapies targeting these cytokine pathways have had promising outcomes. However, not all patients respond well to such treatment, and their effects are not always durable nor reverse airway remodeling. This observation raises the possibility that other CD4+ T cell subsets and their effector molecules may drive airway inflammation and remodeling. To address this issue in a hypothesis-free manner, we performed single-cell transcriptome analysis of >50,000 airway CD4+ T cells isolated from bronchoalveolar lavage (BAL) samples from 30 patients with mild and severe asthma. We observed striking heterogeneity in the nature of CD4+ T cells present in asthmatics' airways with tissue-resident memory (TRM) cells making a dominant contribution. Notably, a subset of CD4+ TRM cells (CD103-expressing) was significantly increased, comprising nearly 65% of all CD4+ T cells in the airways of male patients with severe asthma when compared to mild asthma. This subset was enriched for transcripts linked to T cell receptor (TCR) activation (HLA-DRB1, HLA-DPA1, CD40LG) and cytotoxicity (GZMB, GZMH), and following stimulation expressed high levels of transcripts encoding for pro-inflammatory non-TH2 cytokines (CCL3, CCL4, CCL5, TNF, IL-17A, CSF2, LIGHT) that could fuel persistent airway inflammation and remodeling. Furthermore, we found that CD4+ T cells isolated ex vivo from airways of severe asthmatics displayed signatures linked to corticosteroid resistance (FKBP5, DDIT4), as well as reduced expression of transcripts encoding for molecules that dampen TCR signaling and T cell effector functions (CREM, DUSP1, TNFAIP3). Overall, our single-cell transcriptomic analysis highlights the pathogenic properties and clinical associations of airway CD4+ T cell subsets in severe asthmatics, features that can potentially trigger their unrestrained activation, and that these findings were more pronounced in males. These pathways may therefore be crucial for driving disease severity in adult male severe asthmatics.

Project description:Sputum airway cells transcriptome from 19 asthmatics from the Severe Asthma Research Program at baseline and 6-8 weeks follow-up after a 40mg dose of intramuscular corticosteroid triamcinolone acetonide.

Project description:Asthma is a heterogeneous disease. Exercise-induced bronchoconstriction (EIB) is a distinct syndrome that occurs in 30-50% of asthmatics and is characterized by high levels of pro-inflammatory eicosanoids. We identified genes differentially expressed in the airways of asthmatics with EIB relative to asthmatics without EIB. Genes related to epithelial repair and mast cell infiltration including beta-tryptase and carboxypeptidase A3 were upregulated by exercise challenge in the asthma group with EIB. We confirmed that two novel mediators trefoil factor 3 (TFF3) and transglutaminase 2 (TGM2) have increased expression in airways cells and secreted product in the airways. In vitro studies indicate that 1) TFF3 induces nitric oxide synthase in airway epithelial cells from asthmatics and 2) TGM2 augments the enzymatic activity of secreted phospholipase A2 (sPLA2) group X, an enzyme recently been implicated in asthma pathogenesis. Since PLA2 serves as the first rate-limiting step leading to eicosanoid generation, these results suggest that TGM2 may be a key initiator of the airway inflammatory cascade in asthma. EIB positive and EIB negative subjects sampled pre- and post-exercise

Project description:Inhaled corticosteroids (ICS) control airway inflammation in mild to moderate asthma by reducing inflammatory gene expression. However, incomplete understanding of the molecular mechanisms underpinning corticosteroid action hinders development of improved therapies for more severe disease. Microarray analysis was performed on RNA from biopsies taken from healthy individuals after receiving single dose of ICS to characterize corticosteroid-induced modulation of gene expression in the human airways.

Project description:Asthma is a heterogeneous disease. Exercise-induced bronchoconstriction (EIB) is a distinct syndrome that occurs in 30-50% of asthmatics and is characterized by high levels of pro-inflammatory eicosanoids. We identified genes differentially expressed in the airways of asthmatics with EIB relative to asthmatics without EIB. Genes related to epithelial repair and mast cell infiltration including beta-tryptase and carboxypeptidase A3 were upregulated by exercise challenge in the asthma group with EIB. We confirmed that two novel mediators trefoil factor 3 (TFF3) and transglutaminase 2 (TGM2) have increased expression in airways cells and secreted product in the airways. In vitro studies indicate that 1) TFF3 induces nitric oxide synthase in airway epithelial cells from asthmatics and 2) TGM2 augments the enzymatic activity of secreted phospholipase A2 (sPLA2) group X, an enzyme recently been implicated in asthma pathogenesis. Since PLA2 serves as the first rate-limiting step leading to eicosanoid generation, these results suggest that TGM2 may be a key initiator of the airway inflammatory cascade in asthma.

Project description:Using a human model of asthma exacerbation, we compared the airway mucosa in allergic asthmatics and allergic non-asthmatic controls using single-cell RNA-sequencing frameworks. In response to allergen challenge, the airway epithelium in asthmatics was highly dynamic and upregulated genes involved in matrix degradation, mucus metaplasia, and glycolysis while failing to induce injury-repair and antioxidant pathways observed in controls. Asthmatics also had a unique mucosal immune profile, characterized by IL9-expressing pathogenic TH2 cells and enrichment of DC2 (CD1C) and CCR2-expressing monocyte-derived cells (MC) after allergen, with upregulation of genes that promote pathologic airway remodeling. In contrast, controls were enriched for macrophage-like MC that upregulated tissue repair programs after allergen challenge, suggesting these populations may protect against asthmatic airway remodeling. These findings reveal a novel TH2-mononuclear phagocyte-epithelial interactome unique to asthmatics, suggesting that pathogenic effector circuits and the absence of pro-resolution programs drive structural airway disease in response to type 2 inflammation.

Project description:Background: Tissue remodeling induced by airway inflammation is a main trigger of pathogenesis in various chronic lung diseases like asthma, COPD, IPF, and pulmonary hypertension. The role of human airway smooth muscle cells (HASMCs) in this context is unclear. Hypothesis: HASMCs participate in linking inflammation with remodeling. Methods: The inflammatory responses of ex vivo-cultivated HASMCs to TNFα were investigated by whole-genome-microarray analyses. Diferrential regulation of genes associated with airway inflammation and remodeling were verified by qRT-PCR and ELISA. Results: TNFa induced the expression of 18 cytokines/chemokines and five tissue remodeling genes involved in (severe/corticosteroid-insensitive) asthma, COPD, IPF and/or pulmonary hypertension. Conclusion: HASMCs participate in the interaction of inflammation and tissue remodeling. HASMCs might be considered as targets in therapies of chronic inflammatory lung diseases with regard to attenuating inflammation-induced remodeling processes leading to the development of emphysema or fibrosis. HASMCs of eight donors were left untreated of were stimulated with TNFa at 20 ng/ml. Total RNA was subjected after eight hours of stimulation to whole-human-genome oligo microarray analysis.

Project description:Asthma is a progressive inflammatory airways disease that leads to structural airway changes and debilitating symptoms in many severely affected adults. We need novel therapeutic agents that are affordable, can decrease the reliance on steroids, and can improve quality of life. This clinical and mechanistic study has the potential to impact treatment of a subset of adult severe asthmatics and to further our understanding of the mechanisms of L-arginine metabolism and NO biology in the airways of asthmatics. We will pursue a clinical trial in subjects not well controlled on standard drug therapy; this strategy will address whether L-arginine is efficacious in patients receiving standard of care medications. In studies using animal models, we and others have shown that interventions that augment NO levels, through either supplementation of L-arginine or inhibition of arginase, decrease allergic airway inflammation and hyperresponsiveness-the two hallmarks of asthma. Overall, we hypothesize that a responder subset of adult severe asthma patients will derive clinical benefit from supplemental L-arginine therapy and that these patients will have a lower exhaled NO concentrations (<20 ppb) and a higher NOS2/Arg1 mRNA and protein ratio in their airway epithelial cells than non-responders. We aim to: 1) test the hypothesis that uncontrolled, adult severe asthma patients with exhaled breath NO concentrations <20 ppb will have fewer asthma exacerbations over 3 months when treated with L-arginine compared to patients with FeNO > 25, 2) determine the mechanisms by which L-arginine affects the regulation of NOS and arginase enzymes in primary airway epithelial cell cultures from severe asthmatic subjects, and 3) test the hypothesis that inhaled nanoparticle carrier formulations of L-arginine will decrease airway inflammation, airway hyperresponsiveness, and airway fibrosis at lower doses than systemically administered L-arginine. The major impact of our study will be to identify the adult severe asthma cohort that will benefit from supplemental L-arginine therapy. Our ultimate goal is to develop novel therapeutic agents to treat adult severe asthma patients better. PUBLIC HEALTH RELEVANCE: Asthma is a progressive inflammatory airways disease that leads to structural airway changes and debilitating symptoms in many severely affected adults. This clinical study has the potential to improve the care of adult severe asthmatics and to further our understanding of the mechanisms of L-arginine metabolism and nitric oxide biology in the lung. If we demonstrate that L-arginine supplementation can decrease asthma attacks in a subset of severe asthmatics, it will have great implications for future research as well as for the daily lives of patients with asthma.

Project description:Asthma is a progressive inflammatory airways disease that leads to structural airway changes and debilitating symptoms in many severely affected adults. We need novel therapeutic agents that are affordable, can decrease the reliance on steroids, and can improve quality of life. This clinical and mechanistic study has the potential to impact treatment of a subset of adult severe asthmatics and to further our understanding of the mechanisms of L-arginine metabolism and NO biology in the airways of asthmatics. We will pursue a clinical trial in subjects not well controlled on standard drug therapy; this strategy will address whether L-arginine is efficacious in patients receiving standard of care medications. In studies using animal models, we and others have shown that interventions that augment NO levels, through either supplementation of L-arginine or inhibition of arginase, decrease allergic airway inflammation and hyperresponsiveness-the two hallmarks of asthma. Overall, we hypothesize that a responder subset of adult severe asthma patients will derive clinical benefit from supplemental L-arginine therapy and that these patients will have a lower exhaled NO concentrations (<20 ppb) and a higher NOS2/Arg1 mRNA and protein ratio in their airway epithelial cells than non-responders. We aim to: 1) test the hypothesis that uncontrolled, adult severe asthma patients with exhaled breath NO concentrations <20 ppb will have fewer asthma exacerbations over 3 months when treated with L-arginine compared to patients with FeNO > 25, 2) determine the mechanisms by which L-arginine affects the regulation of NOS and arginase enzymes in primary airway epithelial cell cultures from severe asthmatic subjects, and 3) test the hypothesis that inhaled nanoparticle carrier formulations of L-arginine will decrease airway inflammation, airway hyperresponsiveness, and airway fibrosis at lower doses than systemically administered L-arginine. The major impact of our study will be to identify the adult severe asthma cohort that will benefit from supplemental L-arginine therapy. Our ultimate goal is to develop novel therapeutic agents to treat adult severe asthma patients better. PUBLIC HEALTH RELEVANCE: Asthma is a progressive inflammatory airways disease that leads to structural airway changes and debilitating symptoms in many severely affected adults. This clinical study has the potential to improve the care of adult severe asthmatics and to further our understanding of the mechanisms of L-arginine metabolism and nitric oxide biology in the lung. If we demonstrate that L-arginine supplementation can decrease asthma attacks in a subset of severe asthmatics, it will have great implications for future research as well as for the daily lives of patients with asthma.

Project description:Via extensive comparative analysis of 3D human bronchial epithelial model (MucilAirTM) exposed to air or CuO-based aerosols, we show that existence of asthma enhances sensitivity of the airways to nanoparticles, possibly as a combined result of a hyperactive airway and inefficient mucociliary clearance mechanisms in asthmatics.