Project description:Late lung development is a period of alveolar and microvascular formation, which is pivotal in ensuring sufficient and effective gas exchange. Defects in late lung development manifest in premature infants as a chronic lung disease named bronchopulmonary dysplasia (BPD). Numerous studies demonstrated the therapeutic properties of exogenous bone marrow and umbilical cord-derived mesenchymal stromal cells (MSCs) in experimental BPD. However, very little is known regarding the regenerative capacity of resident lung MSCs (L-MSCs) during normal development and in BPD. In this study we aimed to characterize the L-MSC population in homeostasis and upon injury. We used single-cell RNA sequencing (scRNA-seq) to profile in situ Ly6a+ L-MSCs in the lungs of normal and O2-exposed neonatal mice (a well-established model to mimic BPD) at three developmental timepoints (postnatal days 3, 7 and 14). Hyperoxia exposure increased the number, and altered the expression profile of L-MSCs, particularly by increasing the expression of multiple pro-inflammatory, pro-fibrotic, and anti-angiogenic genes. In order to identify potential changes induced in the L-MSCs transcriptome by storage and culture, we profiled 15,000 Ly6a+ L-MSCs after in vitroculture. We observed great differences in expression profiles of in situ and cultured L-MSCs, particularly those derived from healthy lungs. Additionally, we have identified the location of Ly6a+/Col14a1+ L-MSCs in the developing lung and propose Serpinf1 as a novel, culture-stable marker of L-MSCs. Finally, cell communication analysis suggests inflammatory signals from immune and endothelial cells as main drivers of hyperoxia-induced changes in L-MSCs transcriptome.

Project description:Neonatal hyperoxia exposure causes alveolar simplification in mice and has been employed as a model to study bronchopulomonary dysplasia, or chronic lung disease of prematurity. Loss of epithelial TGF-beta signaling has also been shown to cause alveolar simplification in mouse models of lung development. We used single cell RNA sequencing (scRNA-seq) to analyze both of these models of lung injury to identify shared molecular and cellular mechanisms that contribute to pathogenic alveolar simplification.

Project description:Background: Nrf2 is an essential cytoprotective transcription factor. However, association of Nrf2 in organ development and neonatal disease is rarely examined. Hyperoxia exposure to newborn rodents generates pulmonary phenotypes which resemble bronchopulmonary dysplasia (BPD) of prematurity. Methods: To investigate the role of Nrf2 in lung maturation and BPD pathogenesis, Nrf2-deficient (Nrf2-/-) and wild-type (Nrf2+/+) neonates were exposed to air or hyperoxia (O2). Transcriptome analysis determined Nrf2-directed mechanisms in premature lung. Lung injury was assessed by bronchoalveolar lavage analysis and histopathology. Results: In Nrf2-/- neonates, basal expression of cell cycle machinery, redox balance, and lipid/carbohydrate metabolism genes were suppressed while immunity genes were overexpressed compared to Nrf2+/+ pups. O2-induced mortality and pulmonary inflammation/injury were significantly higher in Nrf2-/- than in Nrf2+/+. Lung DNA lesion and oxidation were greater in Nrf2-/- than in Nrf2+/+, constitutively and after O2. Nrf2-dependent genes modulated cellular growth/proliferation, defense, immunity, and lipid metabolism against hyperoxia. Bioinformatic elucidation of Nrf2 binding motifs and augmented O2-induced inflammation in genetically deficient neonates validated Gpx2 and Marco as Nrf2 effectors. Conclusion: Overall, Nrf2 in underdeveloped lungs orchestrated cell cycle, morphogenesis, and immunity as well as cellular defense constitutively and under oxidant stress. Results provide putative molecular mechanisms of Nrf2-directed lung alveolarization and BPD of prematurity. PARALLEL study design with 42 samples comparing 14 groups of age (P1 to P4 corresponding to day 0 to day 3 animals), gene, and exposure: (4 groups Nrf+/+ wild type P1-P4 air exposure) (4 groups Nrf -/- knockout P1-P4 air exposure), (3 groups Nrf+/+ wild type P2-P4 with 100 percent O2 (hyperoxia exposure) and 3 groupsNrf -/- knockout P2-P4 with 100 percent O2 (hyperoxia exposure)) Biological replicates: 3 per group

Project description:Bronchopulmonary dysplasia (BPD) is characterized by an arrest in alveolarization, abnormal vascular development and variable interstitial fibroproliferation in the premature lung. Endothelial to mesenchymal transition (Endo-MT) may be a source of pathologic fibrosis in many organ systems. Whether Endo-MT contributes to the pathogenesis of BPD is not known. We tested the hypothesis that pulmonary endothelial cells will show increased expression of Endo-MT markers upon exposure to hyperoxia and that sex as a biological variable will modulate differences in expression. WT and Cdh5-PAC CreERT2 (endothelial reporter) neonatal male and female mice (C57BL6) were exposed to hyperoxia (0.95 FiO2) either during the saccular stage of lung development (95% FiO2; PND1-5) or through the saccular and early alveolar stages of lung development (75% FiO2; PND1-14). Expression of Endo-MT markers were measured in whole lung and endothelial cell mRNA. Sorted lung endothelial cells were subjected to bulk RNA-Seq. We show that exposure of the neonatal lung to hyperoxia leads to upregulation of key markers of EndoMT Neonatal male mice show higher expression of genes related to EndoMT. Furthermore, using lung sc-RNAseq data from neonatal lung we were able to show that xxx. Markers related to Endo-MT are upregulated in the neonatal lung upon exposure to hyperoxia and show sex-specific differences. Mechanisms mediating EndoMT in the injured neonatal lung can modulate the response of the neonatal lung to hyperoxic injury and need further investigation.

Project description:Oxidative stress (OS), inflammation, and endoplasmic reticulum (ER) stress sequentially occur in the rat model of hyperoxia (HOX) induced bronchopulmonary dysplasia (BPD), and they all increase DNA damage. Tumor suppressors increase after DNA damage, followed by apoptosis or cellular senescence when the damage becomes irreparable. Although cellular senescence contributes to wound healing, its persistence will inhibit growth potential. Therefore, we hypothesized that the persistence of cellular senescence plays a role in BPD progression. We detected evidence of increased cellular senescence in rat and human BPD lungs. Foxo4-p53 binding was increased in BPD rat lungs, and inhibition of this binding attenuated BPD severity, indicating that such binding contributes to BPD's cellular senescence. Treatment with tauroursodeoxycholic acid (TUDCA) decreases ER stress. N-Acetyl-lysyltyrosylcysteine-amide (KYC) reduced toxic oxidant production by myeloperoxidase (MPO) and subsequent OS and inflammation. Both agents effectively decreased cellular senescence. Concomitantly, alveolar complexity and the number of type 2 alveolar cells increased, indicating that MPO-mediated OS and ER stress preceded cellular senescence in BPD rat pup lungs. These data suggest that cellular senescence plays an essential role in BPD progression. Reducing MPO toxic oxidant production, ER stress, and attenuating cellular senescence are potential therapeutic strategies for halting BPD progression. Using multiomic data to investigate the role of cellular senescence in the development of BPD in rat model.

Project description:Background: Bronchopulmonary dysplasia (BPD), the most common complication of extreme preterm birth, can be caused by oxygen-related lung injury and is characterized by impaired alveolar and vascular development. Mesenchymal stromal cells (MSCs) have lung protective effects. Conversely, BPD is associated with increased MSCs in tracheal aspirates. Objective: To determine whether endogenous lung (L-)MSCs are perturbed in a well-established oxygen-induced rat model mimicking BPD features. Methods: Rat pups were exposed to room air or 95% oxygen from birth to postnatal day 10. On day 12, CD146+ L-MSCs were isolated and characterized according to the International Society for Cellular Therapy criteria. Epithelial and vascular repair potential were tested by scratch assay and endothelial network formation respectively, immune function by mixed lymphocyte reaction assay. Microarray analysis was performed using the Affymetrix GeneChip and gene set enrichment analysis (GSEA) software. Results: CD146+ L-MSCs isolated from rat pups exposed to hyperoxia had decreased CD73 expression and inhibited lung endothelial network formation. CD146+ L-MSCs indiscriminately promoted epithelial wound healing and limited T-cell proliferation. Expression of potent anti-angiogenic genes of the axonal guidance cue and CDC42 pathways was increased after in vivo hyperoxia, whereas genes of the anti-inflammatory JAK/STAT and lung/vascular growth promoting Fibroblast Growth Factor (FGF) pathways were decreased. Conclusions: In vivo hyperoxia exposure alters the pro-angiogenic effects and FGF expression of L-MSCs. Additionally, decreased CD73 and JAK/STAT expression suggest decreased immune function. L-MSC function may be perturbed and contribute to BPD pathogenesis. These findings may lead to improvements in manufacturing exogenous MSCs with superior repair capabilities.

Project description:Background: Nrf2 is an essential cytoprotective transcription factor. However, association of Nrf2 in organ development and neonatal disease is rarely examined. Hyperoxia exposure to newborn rodents generates pulmonary phenotypes which resemble bronchopulmonary dysplasia (BPD) of prematurity. Methods: To investigate the role of Nrf2 in lung maturation and BPD pathogenesis, Nrf2-deficient (Nrf2-/-) and wild-type (Nrf2+/+) neonates were exposed to air or hyperoxia (O2). Transcriptome analysis determined Nrf2-directed mechanisms in premature lung. Lung injury was assessed by bronchoalveolar lavage analysis and histopathology. Results: In Nrf2-/- neonates, basal expression of cell cycle machinery, redox balance, and lipid/carbohydrate metabolism genes were suppressed while immunity genes were overexpressed compared to Nrf2+/+ pups. O2-induced mortality and pulmonary inflammation/injury were significantly higher in Nrf2-/- than in Nrf2+/+. Lung DNA lesion and oxidation were greater in Nrf2-/- than in Nrf2+/+, constitutively and after O2. Nrf2-dependent genes modulated cellular growth/proliferation, defense, immunity, and lipid metabolism against hyperoxia. Bioinformatic elucidation of Nrf2 binding motifs and augmented O2-induced inflammation in genetically deficient neonates validated Gpx2 and Marco as Nrf2 effectors. Conclusion: Overall, Nrf2 in underdeveloped lungs orchestrated cell cycle, morphogenesis, and immunity as well as cellular defense constitutively and under oxidant stress. Results provide putative molecular mechanisms of Nrf2-directed lung alveolarization and BPD of prematurity.

Project description:To explore the key molecules and mechanisms involved in the occurrence and development of BPD by using a hyperoxia-based BPD model in neonatal mice, providing new ideas for discovering new therapeutic target to approach the clinical prevention and treatment for BPD. We performed whole transcriptome sequencing (RNA-seq) profiling analysis of lung endothelial cells from mouse normoxic or hyperoxic mice

Project description:Bronchopulmonary dysplasia (BPD), a chronic pulmonary sequela of preterm birth, increases susceptibility to respiratory viral infection. Exposure to hyperoxia of neontal mice (a model of BPD) increases the number of activated, IL-12 producing lung CD103+ dendritic cells (DCs) and augments the inflammatory response to rhinovirus infection. We used microarray analysis to detail the effect of hyperoxia on the gene expression of the two main subsets of lung cDC, including CD103+ DCs and CD11bhi DC. We identified distinct up- and down-regulated genes in response to hyperoxia in both cDC subclasses.

Project description:Preterm infants are delivered during vulnerable stages of lung development at late canalicular, saccular, or early alveolar phases according to their degree of prematurity. Consequently, they often require medical interventions, especially to support their respiratory system. Preterm birth and post-natal oxygen and mechanical ventilation support can alter programmed patterns of fetal lung development, leading to the instauration of chronic lung diseases. The most significant pulmonary complication of preterm birth is bronchopulmonary dysplasia (BPD). The aim of this study is to delve into the translational power of rabbits as a suitable model of neonatal chronic lung diseases, characterizing the physiological rabbit lung development through the application of histological, transcriptomic, and proteomic analyses on perinatal rabbit lung samples, investigating the impact of preterm birth and its relevance on BPD modeling.