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:During late lung development, alveolar and microvascular development is finalized to enable sufficient gas exchange. Impaired late lung development manifests as bronchopulmonary dysplasia (BPD) in preterm infants. Single-cell RNA sequencing (scRNA-seq) allows for assessment of complex cellular dynamics during biological processes, such as development. Here, we use MULTI-seq to generate scRNA-seq profiles of over 66,000 cells from 36 mice during normal or impaired lung development secondary to hyperoxia. We observed dynamic populations of cells, including several rare cell types and putative progenitors. Hyperoxia exposure, which mimics the BPD phenotype, alters the composition of all cellular compartments, particularly alveolar epithelium, capillary endothelium and macrophage populations. Pathway analysis and predicted dynamic cellular crosstalk suggests inflammatory signalling as the main driver of hyperoxia-induced changes. Our data provides a novel single-cell view of cellular changes associated with late lung development in health and in disease.

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:Myeloperoxidase (MPO), oxidative stress (OS), and endoplasmic reticulum (ER) stress are all increased in the lungs of neonatal rat pups raised in hyperoxia (HOX, >90% O2), an established model of bronchopulmonary dysplasia (BPD). However, the relationship between OS, MPO, and ER stress has not been examined in HOX rat pups. To determine the relationship between OS, MPO, and ER stress in BPD we treated Sprague-Dawley neonatal rat pups with Tunicamycin (Tun) or with HOX. Tun directly induces ER stress and simplifies neonatal lung alveolarization. Previously, we showed that HOX induces a cycle of destruction that we hypothesize through increased OS, MPO, and ER stress to induce BPD. To inhibit ER stress specifically, we used tauroursodeoxycholic acid (TUDCA), a molecular chaperone. To break the cycle of destruction and reduce OS and MPO we used N-acetyl-lysyltyrosylcysteine-amide (KYC), a systems pharmacology agent. Lung structure was studied morphometrically. ER stress was detected using immunofluorescence (IF), transcriptomic, proteomic, and electron microscopic analyses. Increased ER stress was observed in the lungs of HOX rat pups and also in human BPD lungs by IF. Morphometric and proteomic studies of rat lungs showed that Tun treatment decreased lung complexity and increased ER stress and BPD severity. The fact that TUDCA improved lung complexity in Tun-treated neonatal rat pups, and decreased BPD induced by HOX provides strong support for the idea that ER stress plays a causal role in BPD. Additional support comes from data showing TUDCA decreased lung myeloid cells and MPO levels in the lungs of both Tun- and HOX-treated neonatal rat pups. These data link OS and MPO to ER stress in the mechanisms mediating BPD. KYC's effective inhibition of ER stress in the lungs of Tun-treated rat pups provides additional support for the idea that MPO-induced ER stress plays a direct causal role in BPD. Thus, ER stress appears to expand our proposed cycle of destruction. Our results suggest ER stress evolves from OS and MPO to increase neonatal lung injury and impaired neonatal lung growth and development. The encouraging effect of TUDCA indicates chemical chaperone has the potential in treating BPD. Using multiomic data to investigate the role of endoplasmic reticulum stress in the development of BPD in rat model.

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: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: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:Growth Differentiation Factor 15 (GDF15) is a divergent member of the TGF-β superfamily, and its expression increases under various stress conditions, including inflammation, hyperoxia, and senescence. GDF15 expression is increased in neonatal murine BPD models, and GDF15 loss exacerbates oxidative stress and decreases viability in vitro in pulmonary epithelial and endothelial cells. Our overall hypothesis is that the loss of GDF15 will exacerbate hyperoxic lung injury in the neonatal lung in vivo. We exposed neonatal Gdf15-/- mice and wild-type (WT) controls on a similar background to room air or hyperoxia (95% O2) for 5 days after birth. The mice were euthanized on PND 21. Gdf15 -/- mice had higher mortality and lower body weight than WT mice after exposure to hyperoxia. Upon exposure to hyperoxia, female mice had higher alveolar simplification in the Gdf15-/- group than the female WT group. Gdf15-/- and WT mice showed no difference in the degree of the arrest in angiogenesis upon exposure to hyperoxia. Gdf15-/- mice showed lower macrophage count in the lungs compared to WT mice. Our results suggest that Gdf15 deficiency decreases the tolerance to hyperoxic lung injury with evidence of sex-specific differences.

Project description:Previously, we have shown that a synthesized peptide originated from high mobility group box-1 protein (HMGB1) induces a regenerative cascade via activating endogenous mesenchymal stem cells in the body. Here, we have tested whether the HMGB1 peptide can ameliorate BPD related manifestations. In a mouse BPD model established by hyperoxia exposure, three shots of the HMGB1 peptide significantly improved the survival and lung function. Single-cell RNA-seq analysis on the lung showed that an inflammatory signature in macrophages and a fibrotic signature in fibroblasts induced by hyperoxia exposure were significantly suppressed by the HMGB1 peptide. These changes in transcriptome were also confirmed at the protein level. Together, the HMGB1 peptide treatment prevented the progression of BPD by suppressing inflammation and fibrosis. Our data serve as a foundation to develop new effective therapies for BPD.

Project description:The goal of the project was to delineate sex-specific differences in the neonatal lung exposed to postnatal hyperoxia to model the pathophysiologic mechanisms in the human disease; bronchopulmonary dysplasia (BPD).