Project description:Rationale: Aryl hydrocarbon receptor (AhR), a ligand-activated transcription factor, has been considered as an important regulator for immune diseases. We have previously shown that AhR protects against allergic airway inflammation. The underlying mechanism, however, remains undetermined. Objectives: We sought to determine whether AhR specifically in Type II alveolar epithelial cells (AT2) modulates allergic airway inflammation and its underlying mechanisms. Methods: The role of AhR in AT2 cells in airway inflammation was investigated in a mouse model of asthma with AhR conditional knock out mice in AT2 cells (Sftpc-Cre;AhRflox/flox). The effect of AhR on allergen-induced autophagy was examined by both in vivo and in vitro analyses. The involvement of autophagy in airway inflammation was analyzed by using autophagy inhibitor chloroquine. The AhR-regulated gene profiling in AT2 cells was also investigated by RNA-seq analysis. Results: Sftpc-Cre; AhRflox/flox mice showed exacerbation of allergen-induced airway hyperresponsiveness and airway inflammation with elevated Th2 and airway epithelial-derived cytokines in bronchoalveolar lavage fluid (BALF). Notably, an increased allergen-induced autophagy was observed in the lung tissues of Sftpc-Cre; AhRflox/flox mice when compared with wild-type mice. Further analyses suggested a functional axis of AhR-TGF-β1 that is critical in driving allergic airway inflammation through regulating allergen-induced cellular autophagy. Furthermore, inhibition of autophagy suppressed allergic airway inflammation with decreased Th2 and epithelial cell-derived cytokines in BALFs. Additionally, RNA-seq analysis suggests that autophagy is one of the major pathways and CALCOCO2/NDP52 and S1009 are major autophagy-associated genes in AT2 cells that contribute to the AhR-mediated allergic airway inflammation. Conclusion: These results suggest that AhR in AT2 cells functions as a protective mechanism against allergic airway inflammation through controlling cell autophagy.

Project description:Analysis of gene expression during differentiation of alveolar epithelial type 2 (AT2) cells into AT1 cells. Timepoints taken at Day 0 (AT2 cell), Days 2, 4, and 6 in culture (differentiating) and Day 8 in culture (AT1-like cells). 1ug of RNA was subjected to cRNA conversion using Illumina TotalPrep RNA kit and hybridized to the HT12v4 array Analysis of gene expression during differentiation of alveolar epithelial type 2 (AT2) cells into AT1 cells

Project description:Analysis of gene expression during differentiation of alveolar epithelial type 2 (AT2) cells into AT1 cells. Timepoints taken at Day 0 (AT2 cell), Days 2, 4, and 6 in culture (differentiating) and Day 8 in culture (AT1-like cells). 1ug of RNA was subjected to cRNA conversion using Illumina TotalPrep RNA kit and hybridized to the HT12v4 array Analysis of gene expression during differentiation of alveolar epithelial type 2 (AT2) cells into AT1 cells

Project description:Idiopathic pulmonary fibrosis (IPF) is a lethal interstitial lung disease causing alveolar remodeling, inflammation, and fibrosis. We utilized single cell RNA-sequencing (scRNA-Seq) to identify epithelial cell types and associated biological processes involved in the pathogenesis of IPF. Transcriptomic analysis of epithelial cells from normal human lung defined gene expression patterns associated with highly differentiated alveolar type 2 (AT2) cells, indicated by enrichment of RNAs critical for surfactant homeostasis. In contrast, scRNA-seq of IPF cells identified three distinct subsets of epithelial cell types with characteristics of conducting airway basal and goblet cells and, an additional atypical "transitional" cell that contribute to pathological processes in IPF. Individual IPF cells frequently co-expressed alveolar AT1, AT2, and conducting airway selective markers, demonstrating "indeterminate" states of differentiation not seen in normal lung development. Pathway analysis predicted aberrant activation of canonical signaling via TGF-ß, HIPPO/YAP, P53, and AKT-PI3 Kinase. Immunofluorescence confocal microscopy identified the disruption of alveolar structure and loss of the normal proximal-peripheral differentiation of pulmonary epithelial cells. Single cell transcriptomic analyses of respiratory epithelial cells identified loss of normal epithelial cell identities and unique contributions of epithelial cells to the pathogenesis of IPF. Present scRNA-seq transcriptomic analysis of normal and IPF respiratory epithelial cells provides a rich data source to further explore lung health and disease.

Project description:Idiopathic pulmonary fibrosis (IPF) is a lethal interstitial lung disease causing alveolar remodeling, inflammation, and fibrosis. We utilized single cell RNA-sequencing (scRNA-Seq) to identify epithelial cell types and associated biological processes involved in the pathogenesis of IPF. Transcriptomic analysis of epithelial cells from normal human lung defined gene expression patterns associated with highly differentiated alveolar type 2 (AT2) cells, indicated by enrichment of RNAs critical for surfactant homeostasis. In contrast, scRNA-seq of IPF cells identified three distinct subsets of epithelial cell types with characteristics of conducting airway basal and goblet cells and, an additional atypical "transitional" cell that contribute to pathological processes in IPF. Individual IPF cells frequently co-expressed alveolar AT1, AT2, and conducting airway selective markers, demonstrating "indeterminate" states of differentiation not seen in normal lung development. Pathway analysis predicted aberrant activation of canonical signaling via TGF-ß, HIPPO/YAP, P53, and AKT-PI3 Kinase. Immunofluorescence confocal microscopy identified the disruption of alveolar structure and loss of the normal proximal-peripheral differentiation of pulmonary epithelial cells. Single cell transcriptomic analyses of respiratory epithelial cells identified loss of normal epithelial cell identities and unique contributions of epithelial cells to the pathogenesis of IPF. Present scRNA-seq transcriptomic analysis of normal and IPF respiratory epithelial cells provides a rich data source to further explore lung health and disease.

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 airways and the alveoli of the human respiratory tract are lined by two distinct types of epithelium. We previously established long-term expanding human lung epithelial organoids from lung tissues and developed a ‘proximal’ differentiation protocol to generate mucociliary airway organoids, yet the derivation of alveolar organoids from adult lung has remained a challenge. Here we defined a ‘distal’ differentiation approach to generate alveolar organoids from the same source that allows the establishment of airway organoids. Alveolar organoids are enriched for AT1 and AT2 cells and functionally simulate the alveolar epithelium. AT2 cells in lung organoids act as the progenitor cells from which alveolar organoids emerge. Moreover, we demonstrate productive SARS-CoV-2 infection of alveolar organoids. We further optimize 2-dimensional (2D) airway organoids. When differentiated under a slightly acidic pH, these 2D airway organoids sustain enhanced viral replication and better recapitulate the high infectivity of SARS-CoV-2. Moreover, the optimized 2D airway organoids can model IgG transcytosis across the airway epithelium. Collectively, we establish a bipotential organoid culture system that can reproducibly expand the entire human respiratory epithelium in vitro for modeling respiratory diseases, including COVID-19.

Project description:A hallmark of idiopathic pulmonary fibrosis (IPF) and other interstitial lung diseases is dysregulated repair of the alveolar epithelium. The Hippo pathway effector transcription factors YAP and TAZ are implicated as essential for type 1 and type 2 alveolar epithelial cell (AT1 and AT2) differentiation in the developing lung, yet aberrant activation of YAP/TAZ is a prominent feature of the dysregulated alveolar epithelium in IPF. In these studies, we sought to define the functional role of YAP/TAZ activity during alveolar regeneration. We demonstrated that Yap and Taz are normally activated in AT2 cells shortly after injury, and deletion of Yap/Taz in AT2 cells led to pathologic alveolar remodeling, failure of AT2 to AT1 cell differentiation, increased collagen deposition, exaggerated neutrophilic inflammation, and increased mortality following injury induced by a single dose of bleomycin. Loss of Yap/Taz activity prior to a LPS injury prevented AT1 cell regeneration, led to intra-alveolar collagen deposition, and resulted in persistent innate inflammation. Together these findings established that AT2 cell Yap/Taz activity is essential for functional alveolar epithelial repair and prevention of fibrotic remodeling.

Project description:The cytokine interleukin-33 (IL-33) is an epithelial alarmin with critical roles in allergic inflammation and type 2 immunity. The project aims at the characterization of the direct cleavage of IL-33 by allergen proteases, resulting in its activation, and in the subsequent induction of type 2 cytokine production in group 2 innate lymphoid cells. The present dataset contains mass spectrometry analyses to map the cleavage sites for 9 distinct allergens proteases in the human IL-33 sequence.

Project description:During influenza pneumonia, the alveolar epithelial cells of the lungs are targeted by influenza virus. The distal airway stem cells (DASCs) and proliferating alveolar type II (AT2) cells are reported to be putative lung repair cells. However, their relative spatial and temporal distribution is still unknown during influenza-induced acute lung injury. Here, we investigated the distribution of these cells, and concurrently performed global proteomic analysis of the infected lungs to elucidate and link the cellular and molecular events during influenza pneumonia recovery. BALB/c mice were infected with a sub-lethal dose of influenza H1N1 virus. From 5 to 25 days post-infection (dpi), mouse lungs were subjected to histopathologic and immunofluorescence analysis to probe for global distribution of lung repair cells (using P63 and KRT5 markers for DASCs; PCNA and SPC markers for AT2 cells). At 7 and 15 dpi, infected mouse lungs were also subjected to protein mass spectrometry for relative protein quantification. DASCs appeared only in the damaged area of the lung from 7 dpi onwards, reaching a peak at 21 dpi, and persisted at 25 dpi. However, no differentiation of DASCs to AT2 cells was observed by 25 dpi. In contrast, AT2 cells began proliferating from 7 dpi to replenish its population. Mass spectrometry and gene ontology analysis revealed prominent innate immune response at 7 dpi, which shifted towards adaptive immune responses by 15 dpi. Hence, proliferating AT2 cells but not DASCs contribute to AT2 cell regeneration following transition from innate to adaptive immune responses during the early phase of recovery from influenza pneumonia up to 25 dpi.