Project description:Congenital diaphragmatic hernia (CDH) is characterized by incomplete closure of the diaphragm and lung hypoplasia. The pathophysiology of lung defects in CDH is poorly understood. To establish a translational model of human airway epithelium in CDH for pathogenic investigation and therapeutic testing, we developed a robust methodology of epithelial progenitor derivation from tracheal aspirates of newborns. Basal stem cells from CDH patients and preterm and term, non-CDH controls were derived and analyzed by bulk RNA-sequencing, ATAC-sequencing, and air-liquid-interface differentiation. Transcriptomic and epigenetic profiling of CDH and non-CDH basal stem cells reveals a disease-specific, proinflammatory signature independent of severity or hernia size. In addition, CDH basal stem cells exhibit defective epithelial differentiation in vitro that recapitulates epithelial phenotypes found in fetal human CDH lung samples and fetal tracheas of the nitrofen rat model of CDH. Furthermore, steroid treatment normalizes epithelial differentiation phenotypes of human CDH basal stem cells in vitro and in nitrofen rat tracheas in vivo. Our findings have identified an interplay between a proinflammatory signature and BSC differentiation as a potential therapeutic target for airway epithelial defects in CDH.

Project description:Congenital diaphragmatic hernia (CDH) is a life-threatening anomaly with high morbidity and mortality. To investigate the pathogenesis of CDH, miRNA sequencing was performed using amniotic fluid-derived extracellular vesicles (AF-EVs) and fetal lung tissue of nitrofen-induced CDH rat model.

Project description:Lung organoids made from pluripotent stem cells have the potential to enhance our understanding of disease mechanisms in pediatric lung disorders. As proof of concept, we have established a reproducible ex vivo model of lung organoid development derived from human induced pluripotent stem cells generated from fetuses and infants with Bockdalek congenital diaphragmatic hernia (CDH), a polygenic disorder associated with fetal lung compression and often lethal pulmonary hypoplasia at birth. We used microarrays to compare transcriptomes among the different cell types focusing on genes associated with lung development and extracellular matrix. We seek to identity anomalous gene expression during lung development, using lung organoids generated from hiPS of patients with congenital diafragmatic hernia.

Project description:Isolation of tissue-specific fetal stem cells and derivation of primary organoids is currently limited to post-termination samples. This hampers the prenatal investigation of fetal development and congenital diseases. Therefore, novel patient-specific in vitro models are needed. To this aim, isolation and expansion of fetal stem cells during pregnancy, without the need for tissue or cellular reprogramming, would be advantageous. The amniotic fluid (AF) is a source of cells originating from multiple developing organs. Using single cell analysis, we characterised the cellular identities present in the human AF. We identified and isolated viable epithelial stem/progenitor cells of fetal gastrointestinal, renal and pulmonary origin. Upon culture, these cells formed clonal epithelial organoids, manifesting small intestine, kidney tubule and lung identity. AF organoids (AFO) exhibit transcriptomic, protein expression and functional features of their tissue of origin. With relevance for prenatal disease modelling, we derived lung organoids from the amniotic and tracheal fluid cells of Congenital Diaphragmatic Hernia (CDH) fetuses. CDH organoids show differences to non-CDH controls recapitulating some features of the disease. AFO are derived in a timeline compatible with prenatal intervention, potentially allowing investigation of therapeutic tools and regenerative medicine strategies personalised to the fetus at clinically relevant developmental stages.

Project description:Microarray data from this study represent the first global transcriptional survey of gene expression during early compared to late diaphragm formation. Based on the assumption that Congenital diaphragmatic hernia (CDH) candidate genes will have similar temporal expression trends and will be part of the same biological pathways as those already implicated in CDH, we used known CDH-associated genes as “baits” to filter expression microarray data sets (GSEA and STEM) to identify a list of novel CDH candidate genes.

Project description:Congenital diaphragmatic hernia (CDH) is a life-threatening anomaly with high morbidity and mortality. To investigate the pathogenesis of CDH, miRNA sequencing was performed using amniotic fluid-derived extracellular vesicles (AF-EVs) of CDH patients.

Project description:A tracheal aspirate-derived airway basal cell model reveals a proinflammatory epithelial defect in congenital diaphragmatic hernia

Project description:In the process of seeking novel lung host defense regulators by analyzing genome-wide RNA sequence data from normal human airway epithelium, we detected expression of POU2AF1, a known transcription co-factor previously thought to be expressed only in lymphocytes. Lymphocyte contamination of human airway epithelial samples obtained by bronchoscopy and brushing was excluded by immunohistochemistry staining, the observation of up-regulation of POU2AF1 in purified airway basal stem/progenitor cells undergoing differentiation and analysis of differentiating single basal cell clones. Lentivirus-mediated up-regulation of POU2AF1 in airway basal cells induced up-regulation of host defense genes, including MX1, IFIT3, IFITM and known POU2AF1 downstream genes HLA-DRA, ID2, ID3, IL6, BCL6. Interestingly, expression of these genes paralleled changes of POU2AF1 expression during airway epithelium differentiation in vitro, suggesting POU2AF1 helps to maintain a "host defense tone" even in pathogen-free condition. Cigarette smoke, a known risk factor for airway infection, suppressed POU2AF1 expression both in vivo in humans and in vitro in human airway epithelial cultures, accompanied by deregulation of POU2AF1 downstream genes. Finally, enhancing POU2AF1 expression in human airway epithelium attenuated the suppression of host defense genes by smoking. Together, these findings suggest a novel function of POU2AF1 as a potential regulator of host defense genes in the human airway epithelium. Methods: Massive parallel RNA sequencing was used to compare the transcriptome of lentivirus mediated POU2AF1 or RFP (control) gene expression in human primary airway epithelial cells (3 samples per group). Uninfected basal cell was used as a further control. Conclusions: The genes up-regulated by POU2AF1 in human airway epithelial cells are mainly related to the intracellular or extracellular anti-pathogen response, suggesting POU2AF1 plays a role in airway epithelial host defense. This Series represents samples complementary to those in GSE60989.

Project description:The derivation of self-renewing tissue-specific stem cells from human induced pluripotent stem cells (iPSCs) would shorten the time needed to engineer mature cell types in vitro and would have broad reaching implications for the field of regenerative medicine. Here we report the directed differentiation of human iPSCs into putative airway basal cells (“iBCs”), a population resembling the epithelial stem cell of lung airways. Using a dual fluorescent reporter system (NKX2-1GFP;TP63tdTomato) we track and purify these cells over time, as they first emerge from iPSC-derived foregut endoderm as developmentally immature NKX2-1GFP+ lung progenitors which then augment a TP63 program during subsequent proximal airway epithelial patterning. These cells clonally proliferate, initially as NKX2-1GFP+/ TP63tdTomato+ immature airway progenitors that lack expression of the adult basal cell surface marker, NGFR. However, in response to primary basal cell media, NKX2-1GFP+/ TP63tdTomato+ cells upregulate NGFR and display the molecular and functional phenotype of airway basal stem cells, including the capacity to clonally self-renew or undergo multilineage ciliated and secretory epithelial differentiation in air-liquid interface cultures. iBCs and their differentiated progeny recapitulate several fundamental physiologic features of normal primary airway epithelial cells and model perturbations that characterize acquired and genetic airway diseases. In an asthma model of mucus metaplasia, the inflammatory cytokine IL-13 induced an increase in MUC5AC+ cells similar to primary cells. CFTR-dependent chloride flux in airway epithelium generated from cystic fibrosis iBCs or their syngeneic CFTR-corrected controls exhibited a pattern consistent with the flux measured in primary diseased and normal human airway epithelium, respectively. Finally, multiciliated cells generated from an individual with primary ciliary dyskinesia recapitulated the ciliary beat and ultrastructural defects observed in the donor. Thus, we demonstrate the successful de novo generation of a tissue-resident stem cell-like population in vitro from iPSCs, an approach which should facilitate disease modeling and future regenerative therapies for a variety of diseases affecting the lung airways.Single-cell RNA-Sequencing profiling of human iPSC-derived basal cells, airway epithelium compared to primary human basal cells and airway epithelium.

Project description:Congenital diaphragmatic hernia (CDH) is a neonatal anomaly that includes pulmonary hypoplasia and hypertension. We hypothesized that differences in microvascular endothelial cell (EC) heterogeneity may be present during CDH lung development and contribute to nderdevelopment and remodeling of the lungs. Time mated rats were gavaged nitrofen to induce CDH. Left lungs were harvested from healthy control (2HC), nitrofen exposed (NC) and nitrofen-exposed with CDH (CDH) fetuses at E21.5. Transcriptomic analysis was performed using single-cell RNA sequencing, and unbiased clustering revealed 3 distinct microvascular EC clusters. The general microvascular EC cluster (mvEC) had a transcriptomic signature suggestive of increased inflammation in CDH. mvEC differential gene expression (DGE) between NC and CDH revealed downregulation of Ca4, Apln and Ednrb, which define a subpopulation of microvascular ECs important to lung development, gas exchange and repair of alveolar injury (mvCa4+). mvCa4+ ECs were significantly reduced between 2HC (22.6%), NC (13.1%) and CDH (5.3%), demonstrating an impact from lung compression. Gene ontology and Ingenuity Pathway Analysis demonstrated that mvCa4+ ECs are primed for vasculogenesis but have DGE suggestive of impaired cell division. These data suggest that inflammation driven by mvECs and absence of mvCa4+ ECs may contribute to CDH pathogenesis.