Project description:Aberrant expansion of KRT5+ basal cells in the distal lung accompanies progressive alveolar epithelial cell loss and tissue remodelling during fibrogenesis in idiopathic pulmonary fibrosis (IPF). The mechanisms determining activity of KRT5+ cells in IPF have not been delineated. Here, we show an association between KRT5+ cells in human fibrotic lung and regional differences in collagen topography. In vitro, KRT5+ cell migratory characteristics and expression of remodelling genes are modulated by extracellular matrix (ECM) composition and organisation. Mass spectrometry-based proteomics revealed compositional differences in the matrisome secreted by primary human lung fibroblasts (HLF) from IPF patients compared to controls. Over-expression of ECM glycoprotein, Secreted Protein Acidic and Cysteine Rich (SPARC) in the IPF HLF matrisome restricts KRT5+ cell migration in vitro. Together, our findings demonstrate that changes to the ECM in IPF directly influence KRT5+ cell behaviour and function contributing to remodelling events in the fibrotic niche.

Project description:Idiopathic pulmonary fibrosis (IPF) is a disease related to AT2 cell. We used flow cytometry to analyze the epithelial component of donor and IPF lungs. From the live cells, we first excluded the CD31PosCD45Pos and then selected the EPCAMPos cells for further analysis using the human AT2 cell marker HTll-280 and the surface marker PD-L1. Our data indicate that, the bona fide differentiated AT2 cells (HTll-280High PD-L1Neg), were drastically reduced in the context of IPF. More interestingly, the number of HTll-280Low/Neg PD-L1High was drastically increased, suggesting that HTll-280Low PD-L1High epithelial cells could represent a pool of progenitors linked to the deficient AT2 lineage. The aim of this experiment is further characterization of AT2 and PDL1+ cells in donor and IPF.

Project description:In the present study, we report a bleomycin-induced ferret PF model characterized by an irreversible decrease in pulmonary compliance and increase of opacification, accompanied by “honeycomb cyst-like” structures, “proximalization” of distal lung epithelium. Cellular and molecular analysis by single-nucleus RNA sequencing analysis revealed a significant shift in distal lung epithelium towards proximal epithelial phenotype. Importantly, a histopathological pattern of bronchiolization encompassing divergent atypical epithelial cells, and KRT17+/TP63+/KRT5low “basaloid-like” cells, were present in the distal fibrotic lung lesions. Trajectory analysis revealed AT2 cells transition through multiple cell-states in bleomycin injured ferret lungs, particularly AT2 to KRT8high/KRT7low/SOX4+ to eventual KRT8high/KRT7high/SFN+/TP63+/KRT5low “basaloid-like” cells. Further, immunofluorescence analyses demonstrated KRT7 and KRT8 populations reside in close proximity to the ACTA2 positive myofibroblasts in fibrotic foci thereby driving fibrogenic phenotype in bleomycin injured ferret lungs. Collectively, our results provide evidence that the bleomycin ferrets can reproduce pathophysiological, cellular, and molecular features of human IPF disease, suggesting that they may be a reliable model for understanding mechanisms of IPF pathogenesis and for testing therapeutic strategies for treatment of IPF.

Project description:Idiopathic Pulmonary Fibrosis (IPF) is a devastating and life-threatening lung disease characterized by epithelial reprogramming and increased extracellular matrix deposition leading to loss of lung function. A prominent histopathological structure in the IPF lung are aberrant bronchioles filled with mucus, referred to as honeycomb cysts. These heterogeneous bronchiolized areas feature clusters of simple epithelium with Keratin (KRT)5+ basal-like cells interspersed with pseudostratified epithelium containing differentiated, hyperplastic epithelial cells as well as aberrant ciliated cells. Recent single-cell RNA sequencing studies of the lung epithelium shed further light into cellular subtypes unique to IPF, including basaloid KRT5-/KRT17+ cells present in the distal lung. However, IPF distal bronchiole cell subtypes still remain poorly characterized and their disease contribution remains underinvestigated. Using single-cell RNA sequencing of enriched EpCAM+ lung cells of the distal IPF lung, we identified G-protein coupled receptor (GPR) 87, as a marker of distal bronchioles and KRT5+ IPF basal cells contributing to impaired airway differentiation and honeycombing.

Project description:Following lung injury, alveolar regeneration is characterized by the transformation of alveolar type 2 (AT2) cells, via a transitional KRT8+ state, into alveolar type 1 (AT1) cells. In lung disease, dysfunctional intermediate cells accumulate, AT2 and AT1 cells are diminished and fibrosis occurs. Using single cell RNA sequencing (scRNA-seq) datasets of human interstitial lung disease, we found that Interleukin-11 (IL11) is specifically expressed in aberrant KRT8 expressing KRT5-/KRT17+ epithelial cells and basaloid cells. Stimulation of AT2 cells and distal airway epithelial cells with IL11 or TGFβ1 caused epithelial-to-mesenchymal transition (EMT), induced extracellular matrix (ECM) production, increased KRT8 expression and stalled AT2-to-AT1 differentiation, with TGFβ1 effects being partially IL11 dependent. In bleomycin injured mouse lung, IL11 was increased in AT2-derived Krt8+ transitional cells and deletion of Il11ra1 in AT2 lineage cells prevented the accumulation of Krt8+ transitional cells, enhanced AT1 differentiation and promoted alveolar regeneration, which was replicated in therapeutic studies using anti-IL11 antibodies. scRNA-seq analysis of lung epithelial cells from mice with deletion of Il11ra1 in AT2 lineage cells further identified the importance of IL11 signaling for the potentiation and polarization of a disease-causing, ECM producing KRT8+ transitional cells that contributes to pathological lung remodeling. Overall, our data show that IL11 maintains damaged AT2 cells in a transitional state, impairs reparative AT1 differentiation and impairs endogenous alveolar regeneration to cause fibrotic lung disease.

Project description:The epithelium lining airspaces of the human lung is maintained by regional stem cells including basal cells of pseudostratified airways and alveolar type 2 pneumocytes (AT2) of the gas-exchange region. Despite effective techniques for long-term preservation of airway basal cells, procedures for efficient preservation of functional epithelial cell types of the distal gas-exchange region are lacking. Here we detail a method for cryobanking of epithelial cells from either mouse or human lung tissue for preservation of their phenotypic and functional characteristics. Flow cytometric profiling, epithelial organoid-forming efficiency, and single cell transcriptomic analysis, were used to compare cells recovered from cryobanked tissue with those of freshly dissociated tissue. Alveolar type 2 cells within single cell suspensions of enzymatically digested cryobanked distal lung tissue retained expression of the pan-epithelial marker CD326 and the AT2 cell surface antigen recognized by monoclonal antibody HTII-280, allowing antibody-mediated enrichment and downstream analysis. Isolated AT2 cells from cryobanked tissue were comparable with those of freshly dissociated tissue both in their single cell transcriptome and their capacity for in vitro organoid formation in 3D cultures. We conclude that the cryobanking method described herein allows long-term preservation of distal human lung tissue for downstream analysis of lung cell function and molecular phenotype, and is ideally suited for creation of an easily accessible tissue resource for the research community.

Project description:Cellular Heterogeneity of HTII-280–Labeled Epithelial Cells in Healthy and Fibrotic Human Lungs

Project description:Mechanisms of epithelial renewal in the alveolar compartment remain incompletely understood. To this end, we aimed to characterize alveolar progenitors. Single-cell RNA-seq (scRNA-seq) analysis of the HTII-280 positive and HTII-280+ /EpCAM+populations from total 6 donors from periferal tissue was performed, and analysis revealed subclusters enriched for stem cell signature genes. We found that these alveolar progenitors in organoid culture in vitro show phenotypic lineage plasticity as they can yield alveolar or bronchial cell type progeny. The direction of the differentiation is dependent on the presence of the GSK-3β inhibitor, CHIR99021. By RNA-seq analysis of GSK-3 βknockdown organoids, we identify additional functional candidate target genes and pathways which contribute to alveolar differentiation independent of Wnt signaling

Project description:The distal lung contains terminal bronchioles and alveoli that facilitate gas exchange. Three-dimensional in vitro human distal lung culture systems would strongly facilitate investigation of pathologies including interstitial lung disease, cancer, and SARS-CoV-2-associated COVID-19 pneumonia. We generated long-term feeder-free, chemically-defined culture of distal lung progenitors as organoids derived from single adult human alveolar epithelial type II (AT2) or KRT5+ basal cells. AT2 organoids exhibited AT1 transdifferentiation potential while basal cell organoids developed lumens lined by differentiated club and ciliated cells. Single cell analysis of basal organoid KRT5+ cells revealed a distinct ITGA6+ITGB4+ mitotic population whose proliferation further segregated to a TNFRSF12Ahi subfraction comprising ~10% of KRT5+ basal cells, residing in clusters within terminal bronchioles and exhibiting enriched clonogenic organoid growth activity. Distal lung organoids were created with apical-out polarity to display ACE2 on the exposed external surface, facilitating SARS-CoV-2 infection of AT2 and basal cultures and identifying club cells as a novel target population. This long-term, feeder-free organoid culture of human distal lung, coupled with single cell analysis, identifies unsuspected basal cell functional heterogeneity and establishes a facile in vitro organoid model for human distal lung infections including COVID-19-associated pneumonia.

Project description:Idiopathic pulmonary fibrosis (IPF) is a lethal progressive lung disease urgently needing new therapies. Current treatments only delay disease progression, leaving lung transplant as the sole remaining option. Recent studies support a model whereby IPF arises because alveolar epithelial type II (AT2) cells, which normally mediate distal lung regeneration, acquire airway and/or mesenchymal characteristics, preventing proper repair. Mechanisms driving this abnormal differentiation remain unclear. We performed integrated transcriptomic and epigenomic analysis of purified AT2 cells which revealed genome-wide alterations in IPF lungs. The most prominent epigenetic alteration was activation of an enhancer in thyroid receptor interactor 13 (TRIP13), coinciding with TRIP13 upregulation. TRIP13 is broadly implicated in epithelial-mesenchymal plasticity and transforming growth factor-beta signaling. In cultured human AT2 cells and lung slices, small molecule TRIP inhibitor DCZ0415 prevented acquisition of the mesenchymal gene signature characteristic of IPF, suggesting TRIP13 inhibition as a potential therapeutic approach to fibrotic disease.