Project description:Acute Lung Injury (ALI) can cause Acute Respiratory Distress Syndrome (ARDS), a lethal condition with limited treatment options and currently a common global cause of death due to COVID-19-induced ALI. ARDS secondary to Transfusion-Related Acute Lung Injury (TRALI) has been recapitulated pre-clinically by anti-MHC-I antibody administration to LPS-primed mice. In this model, we demonstrated that inhibitors of PTP1B, a protein tyrosine phosphatase that regulates signaling pathways of fundamental importance to homeostasis and inflammation, prevented lung injury and increased survival. Treatment with PTP1B inhibitors attenuated the aberrant neutrophil function that drives ALI, and was associated with release of myeloperoxidase, suppression of Neutrophil Extracellular Trap (NET) formation, and inhibition of neutrophil migration. Mechanistically, reduced signaling through the CXCR4 chemokine receptor, particularly to the activation of mTOR, was essential for these effects, linking PTP1B in hibition to promoting an aged neutrophil phenotype. Considering dysregulated activation of neutrophils is implicated in sepsis and can cause collateral tissue damage, we demonstrated also that PTP1B inhibitors improved survival and ameliorated lung injury in the LPS-induced sepsis model. Our data highlight PTP1B inhibition for prevention of TRALI and ARDS from multiple etiologies.

Project description:Acute lung injury (ALI)/acute respiratory distress syndrome (ARDS) is a common life-threatening critical syndrome with no effective pharmacotherapy. Extracellular vesicles (EVs) are considered as a new way of long-distance communication between cells. Our previous research using an ex vivo perfused human ALI model suggested that endothelial cell-derived EVs (EC-EVs) mediate the development of ALI/ARDS. However, how EC-EVs aggravate lung injury remains largely unknown. Here we demonstrated that EC-EVs released under inflammatory stimulation are preferentially taken up by monocytes and reprogram the differentiation of monocytes towards M1 type macrophage. These findings demonstrate a previously unidentified mechanism by which distant infections could lead to ALI/ARDS, providing novel targets and strategies for the prevention and treatment of sepsis-related ALI/ARDS.

Project description:To investigate neutrophil adaptation to the lung during ARDS and COVID-induced ARDS.

Project description:To investigate the contribution of type I interferon to neutrophil adaptation to the lung during ARDS and COVID-induced ARDS.

Project description:Acute respiratory distress syndrome (ARDS) is a severe critical condition with a high mortality that is currently in focus given that it is associated with mortality caused by coronavirus induced disease 2019 (COVID-19). Neutrophils play a key role in the lung injury characteristic of non-COVID-19 ARDS and there is also accumulating evidence of neutrophil mediated lung injury in patients who succumb to infection with SARS-CoV-2. We undertook a functional proteomic and metabolomic survey of circulating neutrophil populations, comparing patients with COVID-19 ARDS and non-COVID-19 ARDS to understand the molecular basis of neutrophil dysregulation. Expansion of the circulating neutrophil compartment and the presence of activated low and normal density mature and immature neutrophil populations occurs in ARDS, irrespective of cause. Release of neutrophil granule proteins, neutrophil activation of the clotting cascade and upregulation of the Mac-1 platelet binding complex with formation of neutrophil platelet aggregates is exaggerated in COVID-19 ARDS. Importantly, activation of components of the neutrophil type I interferon responses is seen in ARDS following infection with SARS-CoV-2, with associated rewiring of neutrophil metabolism to promote glutamine utilisation, and the upregulation of antigen processing and presentation. Whilst dexamethasone treatment constricts the immature low density neutrophil population it does not impact upon prothrombotic hyperinflammatory neutrophil signatures.

Project description:Background: Acute Respiratory Distress Syndrome (ARDS) or its earlier stage Acute lung injury (ALI), is a worldwide health concern that jeopardizes human well-being. Currently, the treatment strategies to mitigate the incidence and mortality of ARDS are severely restricted. This limitation can be attributed, at least in part, to the substantial variations in immunity observed in individuals with this syndrome. Methods: Bulk and single cell RNA sequencing from ALI mice and single cell RNA sequencing from ARDS patients were analyzed. We utilized the Seurat program package in R and cellmarker 2.0 to cluster and annotate the data. The differential, enrichment, protein interaction, and cell-cell communication analysis were conducted. Results: The mice with ALI caused by pulmonary and extrapulmonary factors demonstrated differential expression including Clec4e, Retnlg, S100a9, Coro1a, and Lars2. We have determined that inflammatory factors have a greater significance in extrapulmonary ALI, while multiple pathways collaborate in the development of pulmonary ALI. Clustering analysis revealed significant heterogeneity in the relative abundance of immune cells in different ALI models. The autocrine action of neutrophils plays a crucial role in pulmonary ALI. Additionally, there was a significant increase in signaling intensity between B cells and M1 macrophages, NKT cells and M1 macrophages in extrapulmonary ALI. The CXCL, CSF3 and MIF, TGFb signaling pathways play a vital role in pulmonary and extrapulmonary ALI, respectively. Moreover, the analysis of human single-cell revealed DCs signaling to monocytes and neutrophils in COVID-19-associated ARDS is stronger compared to sepsis-related ARDS. In sepsis-related ARDS, CD8+ T and Th cells exhibit more prominent signaling to B cell nucleated DCs. Meanwhile, both MIF and CXCL signaling pathways are specific to sepsis-related ARDS. Conclusion: This study has identified specific gene signatures and signaling pathways in animal models and human samples that facilitate the interaction between immune cells, which could be targeted therapeutically in ARDS patients of various etiologies.

Project description:Background: Acute Respiratory Distress Syndrome (ARDS) or its earlier stage Acute lung injury (ALI), is a worldwide health concern that jeopardizes human well-being. Currently, the treatment strategies to mitigate the incidence and mortality of ARDS are severely restricted. This limitation can be attributed, at least in part, to the substantial variations in immunity observed in individuals with this syndrome. Methods: Bulk and single cell RNA sequencing from ALI mice and single cell RNA sequencing from ARDS patients were analyzed. We utilized the Seurat program package in R and cellmarker 2.0 to cluster and annotate the data. The differential, enrichment, protein interaction, and cell-cell communication analysis were conducted. Results: The mice with ALI caused by pulmonary and extrapulmonary factors demonstrated differential expression including Clec4e, Retnlg, S100a9, Coro1a, and Lars2. We have determined that inflammatory factors have a greater significance in extrapulmonary ALI, while multiple pathways collaborate in the development of pulmonary ALI. Clustering analysis revealed significant heterogeneity in the relative abundance of immune cells in different ALI models. The autocrine action of neutrophils plays a crucial role in pulmonary ALI. Additionally, there was a significant increase in signaling intensity between B cells and M1 macrophages, NKT cells and M1 macrophages in extrapulmonary ALI. The CXCL, CSF3 and MIF, TGFβ signaling pathways play a vital role in pulmonary and extrapulmonary ALI, respectively. Moreover, the analysis of human single-cell revealed DCs signaling to monocytes and neutrophils in COVID-19-related ARDS is stronger compared to sepsis-associated ARDS. In sepsis-associated ARDS, CD8+ T and Th cells exhibit more prominent signaling to B-cell nucleated DCs. Meanwhile, both MIF and CXCL signaling pathways are specific to sepsis-associated ARDS. Conclusions: This study has identified specific gene signatures and signaling pathways in animal models and human samples that facilitate the interaction between immune cells, which could be targeted therapeutically in ARDS patients of various etiologies.

Project description:Recent studies reported the inhibitory properties of LAIR-1 in different inflammatory diseases, including allergic and viral airway inflammation. However, the implication of LAIR-1 in ALI/ARDS remains unknown. Poly(I:C), a synthetic analog of (ds)RNA was administrated intranasally to mimic acute inflammation in viral infections and therefore induce experimental ALI/ARDS. RNA sequencing approach was used to explore and compare lung macrophage transcriptomic profiles in wild-type and LAIR-1 knock-out mice.

Project description:Acute lung injury (ALI) is characterized by acute respiratory failure in the setting of non-cardiogenic pulmonary edema, causing acute respiratory distress syndrome (ARDS) in patients and contributes significantly to mortality of critically illness. The main goal of our study is to elucidate the role of miRNAs in neutrophil-epithelial communication during pulmonary inflammation and thereby identifying novel targets for therapy of acute lung injury (ALI). In our studies we identified a miR-223-dependent neutrophil-epithelial crosstalk during ALI. Activated neutrophils (PMN) and pulmonary epithelial cells come into a close spatial relationship during ALI. And, since previous studies had indicated the possibility that inflammatory cell-dependent release of miRNA-containing microvesicles could function as a means of exchanging genetic information from a donor to a target cell, we assessed PMN-elicited alterations of pulmonary epithelial miRNA expression in an experimental co-culture setup. This approach provided a selective and extremely robust readout: While other miRNAs were not or only moderately altered in their expression, pulmonary-epithelial-expressed miR-223 was significantly induced after 4 or 6h of co-incubation. Additional in vitro and in vivo studies clearly demonstrate that this increase of epithelial miR-223 is not due to miR-223 transcriptional induction, but instead PMN-dependent and caused by shuttling miR-223 from PMN into pulmonary epithelial cells. To address the functional role of miR-223-dependent neutrophil-epithelial crosstalk during ALI, we exposed mice to ventilator-induced ALI and observed robust induction of pulmonary miR-223 during ALI, while increases of miR-223 were completely abolished after antibody-depletion of PMN. Moreover, studies of alveolar epithelial cells isolated from mice with ALI showed robust increases of miR-223, indicating that miR-223 is shuttled from PMN towards alveolar epithelia during ALI in vivo. Functional studies revealed that gene-targeted mice for miR-223 experience a more severe phenotype during ALI as compared to controls, while their phenotype could be resuscitated by nanoparticle-mediated overexpression of miR-223 in the lungs. In summary, these studies reveal a novel role of miR-223-dependent neutrophil-epithelial crosstalk representing an anti-inflammatory pathway that can be targeted for ALI treatment.

Project description:Endothelial cells (ECs) serve as a semipermeable barrier and play a key role in acute lung injury (ALI)/acute respiratory distress syndrome (ARDS). It is well known that fibroblast growth factor receptor 1 (FGFR1) is a requirement for maintaining vascular integrity. However, how endothelial FGFR1 exerts its function remains obscure in ALI/ARDS. Here, we performed RNA-seq analysis to investigate transcriptional changes of ECs between saline and LPS group, WT (Fgfr1loxp/loxp) and endothelial Fgfr1-conditional knock out mice (Fgfr1iΔEC/iΔEC mice).