Project description:Background: Artemisia argyi is a traditional medicinal herb with established anti-inflammatory and immunomodulatory properties. Its aqueous extract (AEAA), enriched in water-soluble bioactive constituents, exhibits favorable safety and bioavailability; however, its potential protective effects against acute lung injury (ALI) and its associations with systemic immunometabolic regulation remain incompletely understood. Methods: An LPS-induced ALI mouse model was established following 28 days of AEAA pretreatment. Lung histopathology, pulmonary edema, and inflammatory cytokines were evaluated. Integrated multi-omics analyses—including gut microbiota profiling, untargeted metabolomics of colonic contents and serum, and lung transcriptomics—were performed to characterize treatment-associated microbial, metabolic, and transcriptional alterations. Results: AEAA pretreatment dose-dependently alleviated lung injury, reduced pulmonary edema, and suppressed pro-inflammatory cytokines while restoring anti-inflammatory IL-10 levels. AEAA treatment was associated with partial reversal of LPS-induced gut dysbiosis, characterized by reduced abundance of inflammation-associated taxa and enrichment of beneficial genera, particularly Akkermansia and Lactobacillus. Metabolomic analyses revealed treatment-associated normalization of intestinal and systemic metabolic disturbances, including increased homeostasis-related metabolites and reduced inflammation-associated metabolites. Lung transcriptomic profiling suggested attenuation of LPS-associated transcriptional signatures related to NF-κB, MAPK, Toll-like receptor, and PI3K–AKT signaling pathways. Cross-omics integration further revealed coordinated associations among microbial shifts, metabolic remodeling, and pulmonary inflammatory gene expression. Conclusion: These findings suggest that aqueous Artemisia argyi extract is associated with mitigation of LPS-induced acute lung injury, accompanied by coordinated alterations in gut microbiota composition, host metabolic profiles, and pulmonary inflammatory gene expression. Although causal relationships were not established, this integrated multi-omics analysis provides a systems-level, hypothesis-generating framework supporting the potential of AEAA as a multi-target botanical candidate for ALI.

Project description:his study investigated the metabolic alterations in colonic contents associated with aqueous extract of Artemisia argyi (AEAA) intervention in a lipopolysaccharide (LPS)-induced acute lung injury (ALI) mouse model. Male C57BL/6 mice were randomly divided into control, LPS, and AEAA treatment groups with low-, medium-, and high-dose administration.</p><p>AEAA was administered by oral gavage for 28 consecutive days. On day 29, ALI was induced by intratracheal instillation of LPS (5 mg/kg) in the LPS and treatment groups, while control mice received sterile saline. Colonic content samples were collected 8 hours after LPS administration.</p><p>Untargeted metabolomics analysis was performed using liquid chromatography¨Cmass spectrometry (LC-MS). Quality control (QC) samples were included to ensure analytical stability. The metabolomic profiles of colonic contents were analyzed to explore gut metabolic alterations and potential mechanisms underlying the protective effects of AEAA in acute lung injury.</p><p>This dataset provides raw LC-MS data of colonic content metabolomics and can be used to investigate gut-related metabolic pathways involved in inflammation and natural product intervention.

Project description:Acute lung injury (ALI) refers to a clinical syndrome characterized by bilateral lung injury, severe lung diffuse failure and hypoxemia caused by non-cardiogenic pulmonary edema.Sepsis is the leading etiology of ALI and a common admission to the intensive care unit, which induces pulmonary inflammation leading disruption of endothelial-epithelial barriers by surge release of pro-inflammatory cytokines that increases the permeability of the alveolar-capillary membrane, pulmonary infiltration, and edema.Ultimately, gas exchange across the alveolar-capillary membrane is severely impaired and acute respiratory failure and hypoxia occur. ALI patients may suffer from pulmonary inflammation and hypoxia simultaneously or sequentially, those two pathophysiological processes may interact mutually and contribute together to the development of ALI. LPS is the most important biological mediator of sepsis induce secretion of inflammatory cytokines including TNF-α, IL-1, and IL-6 from many cell types in response to bacterial toxins. Thus LPS has been commonly used to establish inflammatory ALI models of rats and mice. Clinically, hypoxia commonly coexists with sepsis; however, the role of hypoxia on the development of inflammatory ALI is unclear. The understanding of interaction of hypoxia and inflammation in ALI is of the importance for the treatment of ALI.

Project description:Purpose: Acute lung injury (ALI) is a severe clinical disorder characterized by diffused capillary-alveolar barrier damage and noncardiogenic lung edema induced by excessive inflammation reactions. Nogo-B, a member of the reticulon 4 protein family, plays a critical role in modulating macrophages and neutrophils’ function in inflammation. Its role in ALI remains unclear. Methods: Pulmonary expression of Nogo-B was investigated in a LPS-induced ALI mice model. The effects and the underline mechanisms of Nogo-B expression on the severity of lung injury was assessed using histological examination, Bronchoalveolar lavage fluid (BALF) protein and inflammatory cells and cytokines measurement, and microarray analysis. Results: Nogo-B was normally highly expressed in the lungs of naïve C57BL/6 mice. Intra-tracheal instillation of LPS significantly repressed the Nogo-B expression in lung tissues and BALF cells of ALI mice. In addition, over-expression of pulmonary Nogo-B using an adenovirus vector which expresses a Nogo-B-RFP-3-flag fusion protein (Ad-Nogo-B) significantly prolonged the survival time of mice challenged with lethal dose of LPS. Histological results and BALF protein measurement convinced that Ad-Nogo-B treated mice had less severity of lung injury and alveolar protein exudation, as compared with control adenovirus treated mice (Ad-RFP). They also had higher MCP-1 secretion and alveolar macrophages infiltration, but lower neutrophils infiltration. Finally, using microarray analysis, we identified a protective gene, PTX3, was highly elevated in Ad-Nogo-B treated mice. Conclusions: Nogo-B played a protective role in LPS-induced ALI, which might exert its role through modulation of inflammatory response and PTX3 secretion. A total of 12 samples from mice treated with or without LPS in the presence of Ad-Nogo-B or Ad-RFP transfection (n=3 for each group)

Project description:Acute lung injury (ALI) accompanied by an inflammatory response is an important complication after drowning. Macrophage activation and polarization are implicated in the inflammatory process of lipopolysaccharide (LPS)-induced ALI (LPS-ALI), but little is known about drowning-induced ALI (drowning-ALI). SH3GLB1 is a member of the endophilin family and has been shown to be involved in mitochondrial morphological changes and autophagy. However, its role in ALI remains unclear. Here,we performed single-cell profiling of lung immune cells isolated from the lungs of drowning-ALI mouse models. We found that the regulation of macrophages in drowning-ALI was similar to that in LPS-ALI. Specifically, SH3GLB1 was highly expressed in macrophages of drowning-ALI mouse models and was related to inflammation. Furthermore, SH3GLB1 deletion ameliorated LPS-ALI or drowning-ALI. In contrast, the restoration of SH3GLB1 expression provoked LPS-ALI and drowning-ALI. Mechanistically, SH3GLB1 was shown to interact with Rab7 to contribute to mitophagy, which resulted in mitochondrial dysfunction. Overall, these findings indicated that SH3GLB1 is required for Rab7-mediated mitophagy in inflammation during ALI and could be a novel target for lung protection.

Project description:Multipotent stromal cells (MSCs) are currently in clinical trials for a number of inflammatory diseases. Recent studies have demonstrated the ability of MSCs to attenuate inflammation in rodent models of acute lung injury (ALI) suggesting that MSCs may also be beneficial in treating ALI. To better understand how human MSCs (hMSCs) may act in ALI, the lungs of immunocompetent mice were exposed to lipopolysaccharide (LPS) and 4 hr later bone marrow derived hMSCS were delivered by oropharyngeal aspiration (OA). Administration of hMSCs significantly reduced the expression of pro-inflammatory cytokines, neutrophil counts and total protein in bronchoalveolar lavage. There was a concomitant reduction in pulmonary edema as indicated by a decrease in lung wet/dry weight ratio. The anti-inflammatory effects of hMSCs were not dependent on localization to the lung, as intraperitoneal administration of hMSCs also attenuated LPS-induced inflammation in the lung. Microarray analysis revealed significant induction of TNF-α-induced protein 6 (TSG-6) expression by hMSCs 12 hr after OA delivery to LPS-exposed lungs. Knockdown of TSG-6 expression in hMSCs by RNA interference abrogated most of their anti-inflammatory effects. In addition, intra-pulmonary delivery of recombinant human TSG-6 reduced LPS-induced inflammation in the lung. These results show that hMSCs recapitulate the observed beneficial effects of rodent MSCs in animal models of ALI and suggest that the anti-inflammatory properties of hMSCs in the lung are explained, at least in part, by activation of hMSCs to secrete TSG-6.

Project description:Multipotent stromal cells (MSCs) are currently in clinical trials for a number of inflammatory diseases. Recent studies have demonstrated the ability of MSCs to attenuate inflammation in rodent models of acute lung injury (ALI) suggesting that MSCs may also be beneficial in treating ALI. To better understand how human MSCs (hMSCs) may act in ALI, the lungs of immunocompetent mice were exposed to lipopolysaccharide (LPS) and 4 hr later bone marrow derived hMSCS were delivered by oropharyngeal aspiration (OA). Administration of hMSCs significantly reduced the expression of pro-inflammatory cytokines, neutrophil counts and total protein in bronchoalveolar lavage. There was a concomitant reduction in pulmonary edema as indicated by a decrease in lung wet/dry weight ratio. The anti-inflammatory effects of hMSCs were not dependent on localization to the lung, as intraperitoneal administration of hMSCs also attenuated LPS-induced inflammation in the lung. Microarray analysis revealed significant induction of TNF-α-induced protein 6 (TSG-6) expression by hMSCs 12 hr after OA delivery to LPS-exposed lungs. Knockdown of TSG-6 expression in hMSCs by RNA interference abrogated most of their anti-inflammatory effects. In addition, intra-pulmonary delivery of recombinant human TSG-6 reduced LPS-induced inflammation in the lung. These results show that hMSCs recapitulate the observed beneficial effects of rodent MSCs in animal models of ALI and suggest that the anti-inflammatory properties of hMSCs in the lung are explained, at least in part, by activation of hMSCs to secrete TSG-6. Eight- to 10-week-old female BALB/C mice were treated with either 1 mg/kg lipopolysaccharide (LPS) in 100 μl PBS or an equal volume of PBS, as vehicle control, by oropharyngeal aspiration (OA). Four hours after LPS exposure, 250,000 human multipotent stromal cells in 100 μl of PBS were given by OA and 30 min later a second dose of equal concentration was administered, for a total of 500,000 hMSC. As a control, 200 μl PBS was delivered as described above. After 12 h, total RNA was isolated from (A) lungs of LPS-exposed mice treated with either hMSCs (LPS+MSC) or PBS (LPS+PBS), and (B) lungs of PBS-exposed mice treated with hMSCs (PBS+MSC). To obtain additional controls, hMSCs were mixed in vitro with either LPS- (LPS+MSC in vitro mix) or PBS-exposed (PBS+MSC in vitro mix) mouse lungs just before RNA isolation. RNA samples containing mouse and human RNA were first analyzed for amount of human RNA based on human GAPDH signal from real-time RT PCR. Samples with similar human RNA content were used for both mouse and human microarrays

Project description:Acute lung injury (ALI)/acute respiratory distress syndrome (ARDS) is an inflammatory process of the lungs characterized by increased permeability of the alveolar-capillary membrane with subsequent interstitial/alveolar edema and diffuse alveolar damage. ALI/ARDS can be the results of either direct or indirect lung injury, with pneumonia being the most common direct pulmonary insult and sepsis the most common extra-pulmonary cause. In this study, we employed the murine lipopolysaccharide (LPS)-induced direct and indirect lung injury model to explore the pathogenic mechanisms of pulmonary and extra-pulmonary ARDS, using an unbiased, discovery and quantitative proteomic approach. A total of 1,017 proteins were both identified and quantified in bronchoalveolar lavage fluid (BALF) from control, intratracheal LPS (I.T. LPS, 0.1 mg/kg) and intraperitoneal LPS (I.P. LPS, 5 mg/kg) treated mice. The two LPS groups shared 13 up-regulated and 22 down-regulated proteins compared to the control group. Among them, molecules related to bronchial and type II alveolar epithelial cell functions including cell adhesion molecule 1 and surfactant protein B were reduced, whereas lactotransferrin and resistin like alpha involved in lung innate immunity were upregulated in both LPS groups. Proteomic profiling also identified significant differences in BALF proteins between I.T. and I.P. LPS groups. Ingenuity pathway analysis revealed that acute-phase response signaling was activated by both I.T. and I.P. LPS, however, the magnitude of activation is much greater in I.T. LPS group compared to I.P. LPS group. Intriguingly, two canonical signaling pathways, liver X receptor/retinoid X receptor activation and the production of nitric oxide and reactive oxygen species in macrophages, were activated by I.T. LPS but suppressed by I.P. LPS. In addition, CXCL15 (also known as lungkine) was also up-regulated by I.T LPS but down-regulated by I.P. LPS. In conclusion, our quantitative discovery-based proteomic approach identified commonalities as well as significant differences in BALF protein expression profiles in LPS-induced direct and indirect lung injury, and importantly, LPS-induced indirect lung injury results in suppression of select components of lung innate immunity, which could contribute to the so-called “immunoparalysis” in sepsis patients.

Project description:Chronic inflammation plays a central role in the pathogenesis of many lung diseases including asthma, SARS-COVID19, obstructive pulmonary disease (COPD), and lung cancer. Lipopolysaccharide (LPS) is an inflammatory agent produced by most Gram-negative bacteria and found in cigarette smoke. In a mouse model of inflammation, inhalation exposure to LPS induced COPD and increased the size and the multiplicity of lung tumors induced by tobacco-specific nitrosamines. In the present work, we employed a comprehensive multi-omics approach that monitored changes in DNA methylation/hydroxymethylation, gene expression, and global protein abundances in Type II pneumocytes of A/J mice following sub-chronic exposure to LPS.

Project description:Purpose: Acute lung injury (ALI) is a severe clinical disorder characterized by diffused capillary-alveolar barrier damage and noncardiogenic lung edema induced by excessive inflammation reactions. Nogo-B, a member of the reticulon 4 protein family, plays a critical role in modulating macrophages and neutrophils’ function in inflammation. Its role in ALI remains unclear. Methods: Pulmonary expression of Nogo-B was investigated in a LPS-induced ALI mice model. The effects and the underline mechanisms of Nogo-B expression on the severity of lung injury was assessed using histological examination, Bronchoalveolar lavage fluid (BALF) protein and inflammatory cells and cytokines measurement, and microarray analysis. Results: Nogo-B was normally highly expressed in the lungs of naïve C57BL/6 mice. Intra-tracheal instillation of LPS significantly repressed the Nogo-B expression in lung tissues and BALF cells of ALI mice. In addition, over-expression of pulmonary Nogo-B using an adenovirus vector which expresses a Nogo-B-RFP-3-flag fusion protein (Ad-Nogo-B) significantly prolonged the survival time of mice challenged with lethal dose of LPS. Histological results and BALF protein measurement convinced that Ad-Nogo-B treated mice had less severity of lung injury and alveolar protein exudation, as compared with control adenovirus treated mice (Ad-RFP). They also had higher MCP-1 secretion and alveolar macrophages infiltration, but lower neutrophils infiltration. Finally, using microarray analysis, we identified a protective gene, PTX3, was highly elevated in Ad-Nogo-B treated mice. Conclusions: Nogo-B played a protective role in LPS-induced ALI, which might exert its role through modulation of inflammatory response and PTX3 secretion.