Project description:Pulmonary fibrosis (PF) is a form of chronic lung disease characterized by progressive destruction of normal alveolar gas-exchange surfaces and accumulation of extracellular matrix (ECM). In order to comprehensively define the cell types, mechanisms and mediators driving ECM deposition and fibrotic remodeling in lungs with pulmonary fibrosis, we performed single-cell RNA-sequencing (scRNA-seq) of single-cell suspensions generated from non-fibrotic control and PF lungs. Analysis of over 114,000 cells from 20 PF and 10 control lungs identified 31 distinct cell types. We identified multiple distinct lineages directly contribute to ECM expansion, including a novel HAS1hi fibroblast subtype and a previously undescribed KRT5-/KRT17+, collagen and ECM-producing epithelial cell population that was highly enriched in PF lungs. Together these data provide high-resolution insights into the basic mechanisms of pulmonary fibrosis, and indicate a direct profibrotic role of the lung epithelium in PF pathogenesis.

Project description:Pulmonary fibrosis (PF) is a serious chronic pulmonary disease, and lung transplantation is currently the only treatment option that can prolong patient survival. A greater understanding of the transcriptomes of cells related to the pathogenesis of PF can elucidate the impact of different cell types on its occurrence and development. To this end, we performed single cell RNA sequencing (scRNA-seq) to identify key cells and their biological processes in PF. We analyzed the transcriptomes of a total of 36400 cells isolated from the lungs of control and bleomycin-stimulated mice, and observed significant changes in the macrophages, fibroblasts and epithelial cells in the PF model. The macrophages were divided into alveolar macrophages (AMs) and interstitial macrophages (IMs). Based on the anatomical location, the fibroblasts were classified as alveolar fibroblasts, adventitial fibroblasts and peribronchial fibroblasts. Finally, the epithelial cells were divided into the type I alveolar epithelial cells, transitional type II alveolar epithelial cells, and Scgb3a2+ epithelial cells. The subgroups were further classified into key cell clusters to identify the signaling pathways involved in fibrotic progression. Finally, we identified several ligand-receptor complexes that mediate the communication between microphages, fibroblasts and epithelial cells during PF development. Our findings provide new insights into the mechanisms underlying PF, along with potential therapeutic targets.

Project description:Pulmonary fibrosis (PF) is a chronic, progressive condition that represents the end-stage of many interstitial lung diseases (ILDs). Single-cell transcriptomic studies have revealed disease-emergent epithelial, fibroblast, and macrophage cell types/states in PF lungs, but the spatial contexts wherein these cells contribute to disease pathogenesis has remained uncertain. Using image-based spatial transcriptomics to profile gene expression changes in-situ across 28 lung samples from control and PF lungs, we characterized the expression of 343 genes in over 1 million nuclei at subcellular resolution. Using both cell-based and cell-agnostic approaches, we observed a diversity of distinct molecularly-defined spatial niches in control and PF lungs. Overlaying these computationally-defined niches with disease-associated histopathologic features, we identified novel patterns of dysregulation in alveoli informed by spatial context. We computationally segmented individual air spaces and using cell composition, we ordered airspaces from homeostatic to most dysregulated. Using this ordering we identified a series of stepwise molecular changes associated with progressive distal lung remodeling. Together, these results advance our understanding of the molecular programs underlying progressive PF.

Project description:Pulmonary fibrosis (PF) is a chronic, progressive condition that represents the end-stage of many interstitial lung diseases (ILDs). Single-cell transcriptomic studies have revealed disease-emergent epithelial, fibroblast, and macrophage cell types/states in PF lungs, but the spatial contexts wherein these cells contribute to disease pathogenesis has remained uncertain. Using image-based spatial transcriptomics to profile gene expression changes in-situ across 28 lung samples from control and PF lungs, we characterized the expression of 343 genes in over 1 million nuclei at subcellular resolution. Using both cell-based and cell-agnostic approaches, we observed a diversity of distinct molecularly-defined spatial niches in control and PF lungs. Overlaying these computationally-defined niches with disease-associated histopathologic features, we identified novel patterns of dysregulation in alveoli informed by spatial context. We computationally segmented individual air spaces and using cell composition, we ordered airspaces from homeostatic to most dysregulated. Using this ordering we identified a series of stepwise molecular changes associated with progressive distal lung remodeling. Together, these results advance our understanding of the molecular programs underlying progressive PF.

Project description:Pulmonary fibrosis (PF) is an intractable disorder with a poor prognosis. Although macrophages are known to promote both the initiation and resolution of lung injury in reversible PF, it remains unclear how macrophages contribute to the progression of chronic PF. The object of this study was to investigate the role of inflammatory monocyte-derived macrophages (MMs) in the transcriptomic signatures of the lung tissue cells from murine progressive PF. We collected CD45-negative lung tissue cells from silica-treated CCR2 knockout and WT mice on days 28, 40 and untreated mice on day 0 post-aspiration and performed global transcriptome analyses using microarray. Data were analyzed by fuzzy c-means or CLICK clustering, gene set enrichment analysis, and network analyses. Global transcriptome analyses revealed that MM deficiency potentiated changes in gene-expression in tissue cells, closely matching trends seen in human chronic PF. Regulatory network analysis of transcriptome data suggested that MM-derived factors, such as tumor necrosis factor-α, were involved in the suppression of tissue remodeling-related gene expression. Overall, these results demonstrate that MMs suppress tissue cell responses and associated pathology in progressive PF.

Project description:Pulmonary fibrosis (PF) is a chronic interstitial lung disease that causes irreversible and progressive lung scarring and respiratory failure. Activation of fibroblasts (FBs) play a central role in progression of PF. Here we report that platelet endothelial aggregation receptor 1 (Pear1) in FBs is a new molecular target for PF therapy. Pear1 deficiency spontaneously caused respiratory function decline and alveolar collagens accumulation in old mice. The degree of PF and mortality induced by bleomycin were significantly enhanced in Pear1 deficient mice. FB Mesenchyme-specific Pear1 deficiency aggravated bleomycin-induced PF, confirming that Pear1 modulates PF progression probably byvia regulation of FBs function. Single cell RNA-seq analysis of pulmonary FB and functional enrichment analysis revealed drastic expansion of Aactivated- FB clusters and enrichment of activated FB marker genes in extracellular matrix (ECM) development and pulmonary fibrosis in Pear1-/- fibrotic lungs. CD140+ bulk tissue RNA-seq analysis further confirmed that multiple mesenchyme development pathways especially epithelial mesenchymal transition (EMT) are enriched with up-regulated genes involving FB mediated ECM organization and development in in Pear1-/- fibrotic lungs. We further found that Pear1 associated with Protein Phosphatase 1 to suppress fibrotic factors such as TGFß, FGF or PDGF-induced intracellular signalling and FB activation. Intratracheal aerosolization of monoclonal antibody activating Pear1 greatly ameliorates PF in both wild-type mice and Pear1-humanized mice, suggesting that targeting Pear1 may serve as a new therapeutic strategy for PF.

Project description:Comparison between cell lines from 9 different cancer tissue of origin types (Breast, Central Nervous System, Colon, Leukemia, Melanoma, Non-Small Cell Lung, Ovarian, Prostate, Renal) from NCI-60 panel Keywords: cell_type_comparison_design; disease state; cell line; tissue type

Project description:Comparison between cell lines from 9 different cancer tissue of origin types (Breast, Central Nervous System, Colon, Leukemia, Melanoma, Non-Small Cell Lung, Ovarian, Prostate, Renal) from NCI-60 panel Keywords: cell_type_comparison_design; disease state; cell line; tissue type

Project description:TCGA Analysis of RNA Expression for Non Small Cell Lung Cancer, Squamous Cell Carcinoma Using Affymetrix HT_HG-U133A EXP-592 Assay Type: Gene Expression Provider: Affymetrix Array Designs: HT_HG-U133A Organism: Homo sapiens (ncbitax) Tissue Sites: Lung Material Types: organism_part, Primary solid_tumor Disease States: Lung Squamous Cell Carcinoma, NOT SPECIFIED

Project description:Pulmonary fibrosis (PF) is both an independent disease and a pathologic basis for fibroproliferative lung diseases. Understanding of underlying mechanisms of PF is critical for developing effective therapeutics. Fibroblasts activation and extracellular matrix deposition are critical in pathogenesis of PF. Stimulation of certain factors can induce profibrotic changes in fibroblasts. Evaluation of associated genes in treated fibroblasts is helpfu to analyze the profibrotic changes of this critical effector cell for PF. We used microarrays to detail the global programme of gene expression following TGFβ and CCL1 stimulation of primary lung fibroblasts.