Project description:Mutations of SMAD family member 4 (Smad4) gene caused Hereditary Hemorrhagic Telangiectasia (HHT). It was believed that bleeding disorders were caused by arteriovenous malformation in this syndrome. Although several studies indicated dysfunction of platelets from HHT patient, the role(s) of smad4 in platelet function has not been examined. In this study, using megakaryocyte/platelet-specific Smad4-deficient mice, we investigated the physiological function of Smad4 in platelet activation and the underlying mechanism. Microarray data demonstrated that the level of mRNA for multiple genes changed in Smad4 deficient platelet.

Project description:Mutations of SMAD family member 4 (Smad4) gene caused Hereditary Hemorrhagic Telangiectasia (HHT). It was believed that bleeding disorders were caused by arteriovenous malformation in this syndrome. Although several studies indicated dysfunction of platelets from HHT patient, the role(s) of smad4 in platelet function has not been examined. In this study, using megakaryocyte/platelet-specific Smad4-deficient mice, we investigated the physiological function of Smad4 in platelet activation and the underlying mechanism. Microarray data demonstrated that the level of mRNA for multiple genes changed in Smad4 deficient platelet. For microarray analysis, total mRNA was extracted from washed platelets from Smad4f/f or Smad4M-bM-^HM-^R/M-bM-^HM-^R mice (for each group, n=6). mRNA was labeled and hybridized to Affymetrix Mouse Genome 430 2.0 chips according to manufacturer's instructions (Affymetrix).

Project description:Chronic inflammatory and immune dysregulation are critical drivers in the development and progression of chronic obstructive pulmonary disease (COPD). Posttranslational modifications, such as glycosylation of Immunoglobulin G (IgG), modulates systemic inflammatory homeostasis. This study aims to profile plasma IgG glycopeptides (IgGPs) in COPD patients to uncover new insights into its pathogenesis and to identify novel biomarkers. Plasma IgG N-glycopeptides from 90 COPD patients, 45 clinical defined early COPD (CECOPD) patients and 90 healthy individuals were analyzed using an integrated platform that combines Fe3O4@PDA@DETA nanospheres enrichment with high-resolution mass spectrometry measurement. Correlations between IgG N-glycoforms and clinical parameters were assessed to explore underlying mechanisms of COPD progression. Disease-specific IgGPs were identified in both ECOPD and COPD cohorts. Notably, IgG glyco-pattern, rather than IgG levels, changed with disease progression. Early COPD patients showed decreased bisection and increased site-specific afucosylated galactosylation and fucosylation of IgG, indicating an anti-inflammatory state. In contrast, COPD patients gave increased inflammation, characterized by reduced galactosylation and sialylation. Interestingly, a subset of healthy controls displayed IgGPs patterns similar to early COPD, possibly reflecting the impact of substantial smoking exposure and associated immune responses. These findings suggest that plasma IgG glycosylation could serve as a potential biomarker for early COPD diagnosis, providing valuable insights into immune system changes during disease progression.

Project description:The role of eosinophilic inflammation in chronic obstructive pulmonary disease (COPD) pathogenesis is unknown and is probably different than in asthma. The molecular processes underlying the differences between eosinophils from asthma and COPD have not been studied. The study group included 5 patients with asthma and 4 patients with COPD. The RNA-Seq data analysis identified 26 differentially expressed genes between COPD and asthma (according to adjusted p-value). In total, 6 genes were up-regulated (CCL3L1, CCL4L2, SERPINB2, PRSS21, GPR82) and 20 were down-regulated (e.g. JUN, IFITM3, DUSP1, GNG7, ZNF107, BCL6) in peripheral eosinophils of COPD patients compared to asthma. Biological processes associated with down-regulated genes were cell differentiation, positive regulation of RNA metabolic process. The genes associated with signaling of IL-4 and IL-13 pathway were down-regulated in COPD eosinophils compared to asthma. Peripheral eosinophils from COPD and asthma patients present different transcriptomic profiles suggesting their different function in pathobiology of both obstructive airway diseases.

Project description:Cigarette smoking is the leading cause of the respiratory diseases collectively known as chronic obstructive pulmonary disease (COPD). While the pathogenesis of COPD is complex, there is abundant evidence that alveolar macrophages (AM) play an important role. Based on the concept that COPD is a slow-progressing disorder likely involving multiple mediators released by AM activated by cigarette smoke, the present study focuses on the identification of previously unrecognized genes that may be linked to early events in the molecular pathogenesis of COPD, as opposed to factors associated with the presence of disease. To accomplish this, microarray analysis using Affymetrix microarrays was used to carry out an unbiased survey of the differences in gene expression profiles in the AM of phenotypically normal, ~20 pack-yr smokers compared to healthy non-smokers. Although smoking did not alter the global gene expression pattern of AM, 75 genes were modulated by smoking, with 40 genes up-regulated and 35 down-regulated in the AM of smokers compared to non-smokers. Most of these genes belong to the functional categories of immune/inflammatory response, cell adhesion and extracellular matrix, proteolysis and antiproteolysis, lysosomal function, antioxidant-related, signal transduction and regulation of transcription. Of these 75 genes, 69 have not been previously recognized to be up- or down-regulated in alveolar macrophages in association with smoking or COPD, including genes coding for proteins belonging to all of the above categories, and others belonging to various functional categories or of unknown function. These observations suggest that gene expression responses of alveolar macrophages associated with the stress of cigarette smoking are more complex than previously thought, and offer a variety of new insights into the complex pathogenesis of smoking-induced lung diseases. Experiment Overall Design: 5 non smokers and 5 smokers Experiment Overall Design: Alveolar macrophages were obtained from bronchoalveolar lavage

Project description:Background: When exposed to specific stimuli, macrophages exhibit distinct activation programs, M1 and M2 polarization, that define macrophage function as inflammatory/immune effectors or anti-inflammatory/tissue remodeling cells, respectively. Due to their position on the lung epithelial surface, alveolar macrophages (AM) directly interact with environmental stimuli such as cigarette smoke, the major risk factor for the development of chronic obstructive pulmonary disease (COPD). Based on the current paradigm that, in response to smoking, AM contribute to both inflammatory and tissue remodeling processes in the lung relevant to the pathogenesis of COPD, we hypothesized that chronic exposure to cigarette smoking activates both the M1 and M2 polarization programs in AM. Methods and Findings: To assess this hypothesis, global transcriptional profiling with TaqMan confirmation and flow cytometry analysis was carried out on AM obtained by bronchoalveolar lavage of 24 healthy nonsmokers, 34 healthy smokers and 12 smokers with COPD to assess the expression of 41 M1 genes and 32 M2 genes in each group. Contrary to our expectations, while there was up-regulation of some genes typical for M2-related phenotypes, AM of healthy smokers exhibited substantial suppression of M1-related inflammatory/immune genes. These M1- and M2-related changes progressed with the development of smoking-induced lung disease, with AM of smokers with COPD exhibiting further down-regulation of M1-related genes accompanied with further up-regulation of some M2-related genes. Conclusion: The data demonstrates that the modifications of the AM transcriptome associated with smoking result in a unique phenotype characterized by reprogramming of AM towards M1-deactivated partially M2-polarized macrophages and suggests that, while AM likely contribute to smoking-induced tissue remodeling, the role of AM in the early pathogenesis of smoking-induced COPD in humans is not inflammatory. This concept is a departure from the conventional concept that AM-mediated inflammation participates in the early derangements of the lung induced by smoking, and suggests a novel paradigm for conceptualizing COPD and developing new approaches to prevent the development of smoking-induced lung disease. Comparison of gene expression in alveolar macrophages of normal non-smokers and normal smokers and smokers with COPD

Project description:Cigarette smoking is the leading cause of the respiratory diseases collectively known as chronic obstructive pulmonary disease (COPD). While the pathogenesis of COPD is complex, there is abundant evidence that alveolar macrophages (AM) play an important role. Based on the concept that COPD is a slow-progressing disorder likely involving multiple mediators released by AM activated by cigarette smoke, the present study focuses on the identification of previously unrecognized genes that may be linked to early events in the molecular pathogenesis of COPD, as opposed to factors associated with the presence of disease. To accomplish this, microarray analysis using Affymetrix microarrays was used to carry out an unbiased survey of the differences in gene expression profiles in the AM of phenotypically normal, ~20 pack-yr smokers compared to healthy non-smokers. Although smoking did not alter the global gene expression pattern of AM, 75 genes were modulated by smoking, with 40 genes up-regulated and 35 down-regulated in the AM of smokers compared to non-smokers. Most of these genes belong to the functional categories of immune/inflammatory response, cell adhesion and extracellular matrix, proteolysis and antiproteolysis, lysosomal function, antioxidant-related, signal transduction and regulation of transcription. Of these 75 genes, 69 have not been previously recognized to be up- or down-regulated in alveolar macrophages in association with smoking or COPD, including genes coding for proteins belonging to all of the above categories, and others belonging to various functional categories or of unknown function. These observations suggest that gene expression responses of alveolar macrophages associated with the stress of cigarette smoking are more complex than previously thought, and offer a variety of new insights into the complex pathogenesis of smoking-induced lung diseases. Keywords: Comparison of gene expression profile in smokers vs non-smokers

Project description:Emphysema is a major pathological phenotype of chronic obstructive pulmonary disease (COPD) that is characterized by progressive and irreversible alveolar tissue destruction caused by several stressors, such as tobacco smoke and air pollution. It remains incurable in part due to an incomplete understanding of cellular and molecular mechanisms underlying the failure of tissue repair. Here, we have generated a single cell RNA sequencing dataset of enriched epithelial cells from emphysematous parenchymal lung tissue of COPD patients and from healthy controls.Using this dataset, we performed high resolution analysis of 78,699 ATII cells and reveal novel ATII cell subsets in severe emphysema and health. These include two ATII sub-clusters expressing various secretoglobin mRNAs (SCGBpos) in COPD that present distinct transcriptomic profiles compared to healthy sub-clusters. These ATII sub-clusters that are present in human COPD are also found in a mouse emphysema model. Importantly, the COPD specific ATII cells from both species demonstrate airway origins and fail to undergo alveolar differentiation in organoid cultures, thereby suggesting that a common mechanism in emphysema pathogenesis.

Project description:Emphysema is a major pathological phenotype of chronic obstructive pulmonary disease (COPD) that is characterized by progressive and irreversible alveolar tissue destruction caused by several stressors, such as tobacco smoke and air pollution. It remains incurable in part due to an incomplete understanding of cellular and molecular mechanisms underlying the failure of tissue repair. Here, we have generated a single cell RNA sequencing dataset of enriched epithelial cells from emphysematous parenchymal lung tissue of COPD patients and from healthy controls. Using this dataset, we performed high resolution analysis of 78,699 ATII cells and reveal novel ATII cell subsets in severe emphysema and health. These include two ATII sub-clusters expressing various secretoglobin mRNAs (SCGBpos) in COPD that present distinct transcriptomic profiles compared to healthy sub-clusters. These ATII sub-clusters that are present in human COPD are also found in a mouse emphysema model. Importantly, the COPD specific ATII cells from both species demonstrate airway origins and fail to undergo alveolar differentiation in organoid cultures, thereby suggesting that a common mechanism in emphysema pathogenesis.

Project description:Chronic obstructive pulmonary disease (COPD) is one of the most prevalent lung diseases, and involves persistent airflow limitation and incorporates both emphysema and chronic bronchitis. Cigarette smoking has been identified as the main risk factor for disease development and progression. In a basic model of COPD, the disease is initiated when the physiologic response mechanisms to cigarette smoke exposure are overwhelmed; for example, because of long-term exposure effects or other aging-related changes. In this parallel-group case-controlled clinical study we asked to what extent the different transitions in a chronic-exposure-to-disease model are reflected in the proteome and cellular transcriptome of induced sputum samples from the lung. For this, we selected 60 age- and gender-matched individuals for each of four study groups: current healthy smokers, current-smoker COPD patients, former smokers, and never smokers (a total of 240 individuals). Induced sputum was collected, the cell-free supernatant was analyzed by quantitative proteomics (isobaric-tag based), and the cellular mRNA fraction was analyzed by microarray-based expression profiling. The sputum proteome of current smokers (healthy or COPD patients) clearly reflected the common physiological responses to smoke exposure, including alterations in mucin/trefoil proteins (e.g., MUC5AC and TFF1/3up-regulation), peptidase regulators (e.g., TIMP1 up-regulation), and a prominent xenobiotic/oxidative stress response (e.g., NQO1 and ALDH3A1 up-regulation). The latter response also was observed in the sputum transcriptome, which additionally demonstrated an immune-related polarization change (toward a M2 signature). The (long-term) former smoker group showed nearly complete reversal of the observable biological effects. Thirteen differentially abundant proteins between the COPD and healthy smoker groups were identified. These abundant proteins included previously reported COPD-associated proteins (e.g., TIMP1 (up-regulation) and APOA1 (down-regulation)) and novel proteins such as C6orf58 and BPIFB1 (LPLUNC1) (both up-regulated in the COPD group compared with the healthy smokers). In summary, our study demonstrates that sputum proteomics/transcriptomics can capture the complex and reversible physiological response to cigarette smoke exposure, which appears to be only slightly modulated in early-stage COPD patients. The study has been registered on ClinicalTrials.gov with identifier NCT01780298.