Project description:Ischemia/reperfusion injury (IRI) occurs in liver transplantations and major resections and can lead to liver dysfunction. HMGB1 locates in nucleus of normal hepatocytes, but translocates to cytoplasm and the extracellular space during IRI. Although the functions of nuclear and extracellular HMGB1 are well explored, the role cytoplasmic HMGB1 plays in hepatic IRI is still unknown. We hypothesize cytoplasmic HMGB1 interacts with binding proteins involved in the hepatocellular response to IRI. In this study binding proteins of cytoplasmic HMGB1 during hepatic IRI were identified. Normal and warm ischemia reperfusion (WI/R) liver tissues were used for cytoplasmic protein extraction. The protein extracts were subjected to co-immunoprecipitation to enrich HMGB1-protein complexes. To identify the immunoprecipitated proteins in eluates, 2DE and subsequent MS detection were performed. Three identified proteins were verified using western blotting: betaine--homocysteine S-methyltransferase 1 (BHMT), cystathionine gamma-lyase (CTH) and ATP synthase beta subunit (ATP5B). All three identified proteins have a role in metabolic pathways and autophagy. Our results demonstrate cytoplasmic HMGB1 binds to BHMT, CTH and ATP5B during hepatic WI/R. Since both, cytoplasmic HMGB1 and binding proteins, are involved in autophagy, we speculate this protein complex may be involved in the hepatocellular response to IRI via the autophagy pathway.

Project description:Because exosomes have gained attention as a source of biomarkers, we investigated if miRNAs in exosomes (exo-miRs) can report the disease progression of organ injury. Using renal ischemia-reperfusion injury (IRI) as a model of acute kidney injury (AKI), we determined temporally-released exo-miRs in urine during IRI and found that these exo-miRs could reliably mirror the progression of AKI. From the longitudinal measurements of miRNA expression in kidney and urine, we found that release of exo-miRs was regulated sorting process, rather than simply representing their intracellular biosynthesis. In the injury state, miR-16, miR-24, and miR-200c were increased in the urine. Interestingly, expression of target mRNAs of these exo-miRs was significantly altered in renal medulla. Next, in the early recovery state, urinary exo-miRs (miR-9a, miR-141, miR-200a, miR-200c, miR-429), which shares Zeb1/2 as a common target mRNA, were upregulated, indicating that they reflect TGF--associated renal fibrosis. Finally, release of exo-miRs (miR-125a, miR-351) was regulated by TGF-1 and was able to differentiate the sham and IRI even after the injured kidneys were functionally recovered. Altogether, these data indicate that exo-miRs released in renal IRI are largely associated with TGF- signaling. Temporal release of exo-miRs which share targets might be a regulatory mechanism to control the disease progression of AKI.

Project description:Background Extracellular vesicles (EVs) secreted by mesenchymal stromal cells (MSCs) provide significant protection against renal ischemia-reperfusion injury (IRI). Hypoxia is considered an important method for enhancing the tissue repair capabilities of MSCs. However, the specific effects of hypoxia on MSCs and MSC-EVs, as well as their therapeutic potential for renal IRI, remain unclear. In this study, we investigated the alterations in MSCs and the production of MSC-EVs following hypoxia pre-treatment, and further explored the key intrinsic mechanisms by which hypoxic MSC-EVs treat renal IRI. Methods Human umbilical cord MSCs were cultured under normoxic and hypoxic conditions. Proliferation and related pathways were measured, and RNA sequencing was used to detect changes in the transcription profile. MSC-EVs from both normoxic and hypoxic conditions were isolated and characterized. In vivo, the localization and therapeutic effects of MSC-EVs were assessed in a rat renal IRI model. Histological examinations were employed to assess the structure, proliferation, and apoptosis of IRI kidney tissue respectively. Renal function was measured by analyzing serum creatinine and blood urea nitrogen levels. In vitro, the therapeutic potential of MSC-EVs were measured in renal tubular epithelial cells injured by antimycin A. Protein sequencing analysis of hypoxic MSC-EVs was conducted, and the depletion of Glutathione S-Transferase Omega 1 (GSTO1) in hypoxic MSC-EVs was performed to verify its key role in alleviating renal injury. Results Hypoxia alters MSCs transcription, promotes their proliferation, and increases the production of EVs. Hypoxia-pretreated MSC-EVs exhibited a superior ability to mitigate renal IRI, enhancing proliferation and reducing apoptosis of renal tubular epithelial cells both in vivo and in vitro. Protein profiling of the EVs revealed an accumulation of numerous anti-oxidative stress proteins, with GSTO1 being particularly prominent. GSTO1 knock down was significantly reduced the antioxidant and therapeutic effects in renal IRI of hypoxic MSC-EVs. Conclusions Hypoxia significantly promotes MSC-EVs generation and enhances the therapeutic effect of EVs on renal IRI. The effect of antioxidant stress induced by GSTO1 is one of the most important underlying mechanisms. Our findings underscore that hypoxia-pretreated MSC-EVs represent a novel and promising therapeutic intervention for renal IRI.

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:Endothelial cell (EC) injury plays a critical part in the occurrence and progression of renal ischemia-reperfusion injury (IRI). PGC-1α, as a master regulator of mitochondrial function, has been identified as a potential therapeutic target for treating injured ECs. Here, fucoidan-plasmid PGC-1α-gas vesicles (Fuc-pPGC-1α-GVs) are synthesized to identify damaged renal ECs at the early stage of renal IRI through the high affinity of fucoidan to P-selectin, and significantly enhance gene transfection efficiency by ultrasound-mediated controlled cavitation, resulting in specific overexpression of PGC-1α in injured renal ECs. In vitro and in vivo evidence reveals that ultrasound-mediated gene transfection with Fuc-pPGC-1α-GVs could ameliorate renal IRI by rescuing the function of ECs, decreasing immune cells infiltration, and alleviating renal tubular injury. Mechanistically, overexpressed PGC-1α in injured renal ECs promotes mitophagy and inhibits ROS production by upregulating BNIP3, BNIP3L and SOD2. This study provides a promising strategy for early and efficient treatment of renal IRI.

Project description:Chemotherapy-induced peripheral neuropathy (CIPN) is a serious adverse reaction of chemotherapy with limited treatment. Previous research indicates neutrophil extracellular traps (NETs) is a critical pathogenesis of CIPN. LPS/HMGB1 serve as important inducers of NETs. Here, we aim to target inhibiting NETs formation (NETosis) to alleviate CIPN. Clinically we found the content of LPS, HMGB1 and NETs in the plasma of CIPN patients was significantly increased and positively correlated with VAS scores. Fucoidan decreased LPS/HMGB1/NETs content and relieved CIPN in mice. Mechanistically, fucoidan upregulated the scavenger receptor A1 (SR-A1) expression and promoted bone marrow derived macrophage (BMDM) to phagocytize LPS/HMGB1. Fucoidan also facilitated BMDM to engulf NETs via the recognition and localization of SR-A1 and HMGB1. The therapeutic effects of fucoidan were abolished by SR-A1 knockout. RNA-seq analysis showed that fucoidan significantly increased sqstm1 (p62) gene expression. Fucoidan promoted the competitive binding of sqstm1 and Nrf2 to Keap1, increasing Nrf2 nuclear translocation and SR-A1 transcription. Additionally, microbial diversity sequencing analysis (16S) showed that fucoidan increased gut microbiota diversity and abundance, and upregulated the Bacteroides/Firmicutes ratio. In conclusion, fucoidan promotes SR-A1-mediated phagocytosis of LPS/HMGB1/NETs and maintains gut microbial homeostasis, providing a potential therapeutic strategy for CIPN.

Project description:Pulmonary endothelial cells endocytosis of HMGB1 promotes lung injury after renal ischemia-reperfusion injury

Project description:ROS once released from myeloid cells is quickly converted into H2O2 in lungs. We performed RNAseq of cultured pulmonary primary endothelial cells treated with or without H2O2. Pathway enrichment analysis revealed that some of the signaling pathways that are altered by H2O2 are related to AKT signaling. AKT signaling has a protective role in a murine model of ALI by preventing capillary leakage. Moreover, H2O2 stimulates AKT activation in endothelial cells to strengthen vessel barrier integrity

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: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.