Project description:For the clinical treatment of chronic obstructive pulmonary disease (COPD), it is important not only to improve the airflow limitation by bronchodilation but also to suppress emphysema by controlling inflammation. In this study, we have screened for compounds that prevent elastase-induced airspace enlargement in mice from medicines already used clinically. Mepenzolate bromide, a muscarinic antagonist used to treat gastrointestinal disorders was selected. Intratracheal administration or inhalation of mepenzolate bromide decreased the severity of elastase-induced airspace enlargement, alteration of lung mechanics and respiratory dysfunction. While mepenzolate bromide showed bronchodilatory activity, most of other muscarinic antagonists tested did not improve the elastase-induced pulmonary disorders. Mepenzolate bromide suppressed elastase-induced pulmonary inflammatory responses and production of superoxide anions, and reduced the level of cigarette smoke-induced airspace enlargement and alteration of lung mechanics. Based on these results, we propose that this drug is therapeutically effective for COPD as a consequence of both its anti-inflammatory and bronchodilatory activities. In order to understand the mechanism governing mepenzolate-dependent decrease in inflammatory responses and oxidative stress, we performed DNA microarray analysis at the lung of mepenzolate-administered (or control) mice. We then analyzed gene sets that were differently expressed at 25 hours after administration of mepenzolate using Gene Set Enrichment Analysis (GSEA).

Project description:For the clinical treatment of chronic obstructive pulmonary disease (COPD), it is important not only to improve the airflow limitation by bronchodilation but also to suppress emphysema by controlling inflammation. In this study, we have screened for compounds that prevent elastase-induced airspace enlargement in mice from medicines already used clinically. Mepenzolate bromide, a muscarinic antagonist used to treat gastrointestinal disorders was selected. Intratracheal administration or inhalation of mepenzolate bromide decreased the severity of elastase-induced airspace enlargement, alteration of lung mechanics and respiratory dysfunction. While mepenzolate bromide showed bronchodilatory activity, most of other muscarinic antagonists tested did not improve the elastase-induced pulmonary disorders. Mepenzolate bromide suppressed elastase-induced pulmonary inflammatory responses and production of superoxide anions, and reduced the level of cigarette smoke-induced airspace enlargement and alteration of lung mechanics. Based on these results, we propose that this drug is therapeutically effective for COPD as a consequence of both its anti-inflammatory and bronchodilatory activities.

Project description:Patients with chronic obstructive pulmonary disease (COPD) having higher blood eosinophil levels exhibit worse lung function and more severe emphysema, implying the potential role of eosinophils in emphysema development. However, the specific mechanism underlying eosinophil-mediated emphysema development is not fully elucidated. In this study, single-cell RNA sequencing was used to identify eosinophil subgroups in mouse models of asthma and emphysema and analyze their functions. Analysis of the accumulated eosinophils revealed differential transcriptomes between the mouse lungs of elastase-induced emphysema and ovalbumin-induced asthma., Eosinophil depletion alleviated elastase-induced emphysema. Notably, eosinophil-derived cathepsin L (CTSL) degraded the extracellular matrix (ECM), causing emphysema in the pulmonary tissue. Eosinophils were positively correlated with serum CTSL levels, which were increased in patients with emphysema than in those without emphysema. Collectively, these results suggest that CTSL expression in eosinophils plays an important role in ECM degradation and remodeling and is related to emphysema in patients with COPD. Therefore, eosinophil-derived CTSL may serve as a potential therapeutic target for patients with emphysema.

Project description:Chronic obstructive pulmonary disease (COPD) is a highly prevalent disease leading to irreversible airflow limitation and is characterized by chronic pulmonary inflammation，obstructive bronchiolitis and emphysema. Etiologically, COPD is mediated by toxic gases and particles, e.g. cigarette smoke, while the pathogenesis of the disease is largely unknown. Several lines of evidence indicate a link between COPD and autoimmunity but comprehensive studies are lacking. By using a protein microarray assaying more than 19,000 human proteins we determined in this study the autoantibody profiles of COPD and non-COPD smokers.

Project description:Chronic obstructive pulmonary disease (COPD) is a complex pulmonary disorder primarily induced by cigarette smoking, and characterized by persistent airflow limitation. The mouse represents an important model for studying COPD pathologies such as lung emphysema. In this respect, a number of mechanistic studies have been performed, however the approaches were mostly focused on single gene analysis or characterization of cellular, inflammatory or histopathological changes without attempting a more comprehensive interpretation. In the present study we aimed at applying systems biology approach to identify genome-wide molecular mechanisms indicative of cigarette smoke (CS)-induced lung emphysema. The lung transcriptomes of five mouse models (C57BL/6, ApoE-/-, A/J, CD1, and Nrf2-/-), that are known to be susceptible to CS-induced emphysema development, were analyzed following prolonged (5-6 months) CS exposure. The investigation resulted in the confirmation of many existing mechanistic explanations underlying smoke-induced lung emphysema, including increased transcriptional activity of NF-?B, and increased levels of TNF-a, IFN-g, and IL-1b. More importantly, we predicted mechanisms without currently well-documented roles, including increased transcriptional activity of PU.1, STAT1, C/EBP, FOXM1, YY1 and N-cor, and increased IL-17 cytokine expression, and reduced protein expression of ITGB6 and CFTR. We also corroborated, by using targeted proteomic approaches, several predictions such as reduced expression of ITGB6 and increased expression of BRCA1, C/EBPs, PU.1, TNF-a, IL-1b or CSF2. We believe this study will provide more insights into better understanding of CS-induced molecular processes underlying emphysema development in mice that may eventually be relevant in humans.

Project description:Whole lung tissue transcriptomic profiling studies in chronic obstructive pulmonary disease (COPD) have led to the identification of several genes associated with the severity of airflow limitation and/or the presence of emphysema, however, the cell types driving these gene expression signatures remain unidentified. T-distributed stochastic neighbor embedding and clustering of scRNA seq data revealed a total of 17 distinct populations. Among them, the populations with more differentially expressed genes in cases vs. controls (log fold change >|0.4| and FDR=0.05) were monocytes (n=1499); macrophages (n=868) and ciliated epithelial cells (n= 590), respectively. Using GSEA, we found that only ciliated and cytotoxic T cells manifested a trend towards enrichment of the previously reported 127 regional emphysema gene signatures (normalized enrichment score [NES] = 1.28 and =1.33, FDR= 0.085 and =0.092 respectively). Among the significantly altered genes present in ciliated epithelial cells of the COPD lungs, QKI and IGFBP5 protein levels were also found to be altered in the COPD lungs.

Project description:Comparison of severely emphysematous tissue removed at lung volume reduction surgery to that of normal or mildly emphysematous lung tissue resected from smokers with nodules suspicious for lung cancer. Data obtained from the 18 patients with severe emphysema and 12 patients with mild/no emphysema. Research may provide insights into the pathogenetic mechanisms involved in chronic obstructive pulmonary disease (COPD).

Project description:Fibroblast growth factor (FGF) 10 is essential for lung morphogenesis and polymorphisms in the Fgf10 region are linked with higher susceptibility towards COPD in human patients. We found that FGF10 signaling is impaired in lung septal wall compartment from COPD patients. Mice with impaired FGF10 signaling (Fgf10+/-) were more prone to develop cigarette smoke (CS)-induced emphysema and pulmonary hypertension (PH). Furthermore, FGF10 overexpression could successfully reverse cigarette smoke-induced emphysema and PH in mice.

Project description:Comparison of severely emphysematous tissue removed at lung volume reduction surgery to that of normal or mildly emphysematous lung tissue resected from smokers with nodules suspicious for lung cancer. Data obtained from the 18 patients with severe emphysema and 12 patients with mild/no emphysema. Research may provide insights into the pathogenetic mechanisms involved in chronic obstructive pulmonary disease (COPD). Keywords: other

Project description:Chronic obstructive pulmonary disease (COPD) is a heterogeneous disease typified by not fully reversible and often progressive airflow obstruction, along with persistent respiratory symptoms. This gap is due to lack of animal models that more closely mimic human COPD are needed to bridge translational gaps. Commonly used mice model produces primarily emphysematous disease and do not develop features pathognomonic for chronic bronchitis. Suggesting the potential for additional molecular insights to be obtained from animal models that exhibit COPD with features of chronic bronchitis and emphysema, as in humans. We sought to identify whether our ferret model of COPD captures unique genetic signatures in comparison to mouse models that can help improve understanding of the molecular pathogenesis of COPD and promote the development of new and effective therapies.