Project description:Acute respiratory distress syndrome (ARDS) is a severe clinical condition characterized by widespread inflammation and fluid accumulation in the lungs. Endothelial cell (EC) metabolic changes in acute lung injury (ALI) and their relationship to injury remain unclear. Transcriptomic and lipidomic analyses revealed downregulation of PUFA synthesis pathways, particularly omega-3 PUFAs, in pulmonary ECs during LPS-induced ALI. Activation of the PUFA metabolic pathway, through FADS1/2 overexpression or omega-3 fatty acid supplementation, protected ECs from ferroptosis and restored barrier function. Overexpression of FADS1/2 in a mouse model of ALI, combined with alpha-linolenic acid (ALA) supplementation, significantly mitigated lung injury, reduced inflammatory cytokines, and improved pulmonary edema and barrier integrity. PARK7 was identified as an endogenous regulator of FADS1/2, acting through the BMP-SMAD1/5/9 signaling. Driven by histone H3K14 lactylation, which was also promoted by the downregulation of FADS1/2, PARK7 upregulation restored FADS1/2 expression and counteracted ferroptosis, thereby forming a protective feedback loop. This study elucidates a novel regulatory axis involving the two major metabolic changes—downregulation of PUFA synthesis and upregulation of histone lactylation—in ALI pathogenesis, which are interconnected through the PARK7-BMP signaling pathway. Targeting this axis offers potential therapeutic strategies for mitigating endothelial dysfunction and ferroptosis in ARDS/ALI.

Project description:<p>Acute Respiratory Distress Syndrome (ARDS)/ Acute Lung Injury (ALI) is a syndrome defined by the presence of acute hypoxemic respiratory failure, bilateral pulmonary infiltrates on chest radiograph, a known clinical risk factor (e.g. sepsis, pneumonia, trauma, gastric fluid aspiration, pancreatitis, massive transfusion), and the absence of physiologic or clinical evidence of congestive heart failure.</p> <p>The Identification of SNPs Predisposing to Altered ALI Risk (iSPAAR) study is a multi-institutional cooperative study, funded through the NHLBI Recovery Act, that assembled samples and phenotype information from existing cohorts.</p> <p>The consortium included samples from patients with ARDS from the NIH NHLBI ARDS Clinical Trials Network (ARDSNet). Samples were obtained from 3 interventional treatment trials in patients with ARDS, including the Fluid and Catheter Treatment Trial (FACTT), the Albuterol to Treat Acute Lung Injury (ALTA) trial, and the Omega-3 Fatty Acid/Antioxidant Supplementation for ALI trial (Omega).</p> <p>In addition to ARDSnet samples, samples from the other cohorts included cases of established ARDS but also controls: critically ill patients who were at-risk for ARDS but who did not develop ARDS during their hospital course. These cohorts included the Molecular Epidemiology of Acute Respiratory Distress (MEA) Study enrolled at the Harvard University/Massachusetts General Hospital, the Systemic Inflammatory Immune Response Syndrome (SIRS) Patient Database and ICU Traumatic Injury cohorts from Harborview Medical Center, and cohorts collected from the ALI research programs at the University of Pennsylvania and the University of California, San Francisco.</p> <p><b>The Cohort is utilized in the following dbGaP sub-studies.</b> To view genotypes, other molecular data, and derived variables collected in these sub-studies, please click on the following sub-studies below or in the "Sub-studies" box located on the right hand side of this top-level study page <a href="study.cgi?study_id=phs000631">phs000631</a> ARDSnet iSPAAR Consortium. <ul> <li><a href="study.cgi?study_id=phs000334">phs000334</a> ESP_LungGO_ALI </li> <li><a href="study.cgi?study_id=phs000686">phs000686</a> ALI_GeneticRisk </li> </ul> </p>

Project description:The activation of pulmonary endothelial cells (ECs) triggers the occurrence of lung injury and is a hallmark of sepsis-associated acute respiratory distress syndrome(ARDS). Aberrant metabolism favoring glycolysis plays a pivotal role in the pathogenesis of sepsis-induced EC activation. Herein we demonstrate that glycolysis-related histone lactylation, represented by H3K14 lactylation (H3K14la), drives sepsis-associated EC activation and lung injury. Accordingly, H3K14la level is elevated in injured lung tissue and activated ECs. Inhibition of lactate production suppresses both H3K14la levels and EC activation in response to lipopolysaccharide (LPS). We also show that lactate-dependent H3K14la is enriched at the promoters of ferroptosis-related genes, thereby inducing ferroptosis in ECs, and inhibiting ferroptosis effectively ameliorates EC activation. Taken together, elevated lactate in sepsis modulates EC activation and lung injury via histone lactylation and manipulation of glycolysis/H3K14la/ferroptosis axis may provide novel therapeutic approaches for the treatment of sepsis-associated ARDS.

Project description:Background: Pulmonary endothelial cell (EC) activation is a key factor in acute respiratory distress syndrome (ARDS). In sepsis, increased glycolysis leads to lactate buildup, which induces lysine lactylation (Kla) on histones and other proteins. However, the role of protein lactylation in EC dysfunction during sepsis-induced ARDS remains unclear. Methods: Integrative lactylome and proteome analysis was performed to identify the global lactylome profiling in lung tissues of septic mice. Cut&Tag analysis were used to identify the transcriptional targets of histone H3 lysine 14 lactylation (H3K14la) in ECs. Results: Septic mice exhibited elevated levels of lactate and H3K14la in lung tissues, particularly in pulmonary ECs. Suppressing glycolysis reduced both H3K14la and EC activation, suggesting a link between glycolysis and lactylation. Moreover, H3K14la was found to be enriched at promoter regions of ferroptosis-related genes such as transferrin receptor (TFRC) and solute carrier family 40 member 1 (SLC40A1), which contributed to EC activation and lung injury under septic conditions. Conclusions: We for the first time reported the role of lactate-dependent H3K14 lactylation in regulating EC ferroptosis to promote vascular dysfunction during sepsis-induced lung injury. Our findings suggest that manipulation of glycolysis/H3K14la/ferroptosis axis may provide novel therapeutic approaches for sepsis-associated ARDS.

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:Summary Sodium 4-phenylbutyrate (Na-PBA), a histone deacetylase inhibitor, shows potential in mitigating acute lung injury (ALI) by addressing endothelial cell injury. In a lipopolysaccharide (LPS)-induced ALI mouse model, Na-PBA pretreatment reduced lung damage, pulmonary edema, and inflammatory markers, while decreasing oxidative stress and endothelial pyroptosis via the cytochrome c-caspase9-caspase3-GSDME pathway. In vitro studies with human umbilical vein endothelial cells (HUVECs) confirmed that Na-PBA enhanced PARK7 expression, which is crucial for its protective effects against oxidative damage and pyroptosis. The mechanism involves PARK7 stabilizing mitochondria and inhibiting cytochrome c leakage, leading to reduced caspase activation. Na-PBA's effects are mediated through upregulation of PARK7, potentially within a positive feedback loop involving NRF2. These findings identify a novel therapeutic strategy to alleviate endothelial injury in lung diseases.

Project description:The Acute Respiratory Distress Syndrome (ARDS)/Acute Lung Injury (ALI) was described 30 years ago, yet the interaction between specific sets of genes involved in this syndrome remains incompletely understood. Experiment Overall Design: 13 patients with ALI + sepsis and 21 patients with sepsis alone were recruited from the Medical Intensive Care Unit of the University of Pittsburgh Medical Center between February 2005 and June 2007. Whole blood was obtained from each patient within 48 hours of admission, and RNA was extracted for gene expression profiling, and comparison analysis.

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: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).