Project description:Heart disease remains the leading cause of death globally. Although reperfusion following myocardial ischemia can prevent death by restoring nutrient flow, ischemia/reperfusion injury can cause significant heart damage. The mechanisms that drive ischemia/reperfusion injury are not well understood; currently, few methods can predict the state of the cardiac muscle cell and its metabolic conditions during ischemia. Here, we explored the energetic sustainability of cardiomyocytes, using a model for cellular metabolism to predict the levels of ATP following hypoxia. We modeled glycolytic metabolism with a system of coupled ordinary differential equations describing the individual metabolic reactions within the cardiomyocyte over time. Reduced oxygen levels and ATP consumption rates were simulated to characterize metabolite responses to ischemia. By tracking biochemical species within the cell, our model enables prediction of the cell’s condition up to the moment of reperfusion. The simulations revealed a distinct transition between energetically sustainable and unsustainable ATP concentrations for various energetic demands. Our model illustrates how even low oxygen concentrations allow the cell to perform essential functions. We found that the oxygen level required for a sustainable level of ATP increases roughly linearly with the ATP consumption rate. An extracellular O2 concentration of ~0.007 mM could supply basic energy needs in non-beating cardiomyocytes, suggesting that increased collateral circulation may provide an important source of oxygen to sustain the cardiomyocyte during extended ischemia. Our model provides a time-dependent framework for studying various intervention strategies to change the outcome of reperfusion.

Project description:Long noncoding RNA profile in the mouse plasma after ischemia-reperfusion injury (IRI). In the study presented here, we mixed the plasma from three mouse after IRI and identified the genome-wide expression level of lncRNAs.

Project description:This study aims to determine changes in transcriptomic profiles in lymphatic vessels in response to ischemia-reperfusion injury, which mimics conditions in liver transplantation. This experiment will determine the potential role of lymphatic vessels during the ischemia-reperfusion injury in the liver.

Project description:LIF is a pleotropic cytokine and its role in liver ischemia-reperfusion injury (IRI) remains unexplored. Utilizing wildtype (WT) and myeloid cell-specific knockout (KO) mice, we demonstrate that the transcription of LIF is activated in myeloid cells and promotes LIFR-induced STAT3 activation in hepatocytes during liver IRI. To understand the downstream targets of STAT3, we performed ChIP-seq analysis.

Project description:Long noncoding RNA profile in the mouse plasma after ischemia-reperfusion injury (IRI).

Project description:schemic preconditioning (IPC) has been developed for protection of liver from ischemia reperfusion injury, which results in tolerance to subsequent insults of ischemia. But little is known about the underlying biological pathophysiology of long non-coding RNAs (lncRNAs) in the liver ischemia-reperfusion (I/R) injury. Our study aims to provide a mechanism for the function of IPC against liver I/R injury and to giving rise to new research perspectives of lncRNAs. In this study, 18 mice (C57BL/6) were involved and randomly divided into the following groups (6 mice per group): the Sham group, the I/R group, and I/R+IPC group. Serum and liver tissue samples were collected for analysis from a mouse liver model of I/R injury and I/R+IPC. Then we randomly selected 5 mice per group and extracted their liver samples for microarray analysis and subsequent bioinformatics analysis.

Project description:Liver ischemia reperfusion mice

Project description:Background & Aims: Liver ischemia-reperfusion (IR) injury is a common and serious complication in liver transplantation surgery. Disturbances of mitochondrial function, altered lipid metabolism, and insulin resistance are pathways shown to participate in acute and chronic liver diseases. NcoR1 was previously shown to integrate in all these damage pathways in liver, adipose tissue, and muscle, whereby its mechanistic role is not fully understood. Here, we delineated hepatocytic NcoR1 in liver ischemia-reperfusion injury. Methods: We established an IR model in mice, measured liver function related enzymes in serum, SOD, and combined these data with HE staining and PCR assays from liver sections and lysates, respectively to determine the extent of liver injury. We used mice with albumin-Cre/LoxP system mediated hepatocyte-specific NcoR1 depletion (NcoR1△Hep) to investigate the role of NcoR1 in the etiopathogenesis of liver IR and to delineate potential related mechanisms. We also analysed the impact of NcoR1 on oxidative stress mediated cell damage, including activation of NFB signaling activation in hepatocytes in gain and loss of function studies, using immunoblotting and immunofluorescence. Results: Upon ischemia and reperfusion injury (IR), as evidenced by increased levels of liver enzymes (ALT, AST), and inflammatory cytokines (Tnf, Mcp1 et al), NcoR1 expression levels decreased at both, mRNA and protein levels in total liver lysates. To discriminate cell type specific effects, we successfully established NcoR1△Hep mice, and found that depletion of Ncor1 in hepacotytes exhibited more severe liver injury from IR, as compared to NcoR1fl/fl control mice, as evidenced by the aforementioned parameters. Silencing NcoR1 or Ncor1 deficiency promoted both, parameters of inflammatory and oxidative stress such as Gclc, Gclm, Hmox1, and Ccl2, et, al. in AML12 cells and primary mouse hepatocytes, while NcoR1 over-expression shows the opposite results. Further, IR treated NcoR1△Hep mice displayed increased phosphorylation of p65, an essential parameter of the NFB signaling pathway, a critical mediator of stress signals in hepatocytes. Gene silencing of p65 in primary hepatocytes increased NcoR1 expression, suggesting that NFkB/p65 signaling is a negative regulator of NcoR1 expression. Conclusion: Our results indicate that damage mediated activation of NFB/p65 signaling decreases NcoR1 expression in hepatocytes, which is required for IR aggravation.

Project description:Background & Aims: Liver ischemia-reperfusion (IR) injury is a common and serious complication in liver transplantation surgery. Disturbances of mitochondrial function, altered lipid metabolism, and insulin resistance are pathways shown to participate in acute and chronic liver diseases. NcoR1 was previously shown to integrate in all these damage pathways in liver, adipose tissue, and muscle, whereby its mechanistic role is not fully understood. Here, we delineated hepatocytic NcoR1 in liver ischemia-reperfusion injury. Methods: We established an IR model in mice, measured liver function related enzymes in serum, SOD, and combined these data with HE staining and PCR assays from liver sections and lysates, respectively to determine the extent of liver injury. We used mice with albumin-Cre/LoxP system mediated hepatocyte-specific NcoR1 depletion (NcoR1△Hep) to investigate the role of NcoR1 in the etiopathogenesis of liver IR and to delineate potential related mechanisms. We also analysed the impact of NcoR1 on oxidative stress mediated cell damage, including activation of NFB signaling activation in hepatocytes in gain and loss of function studies, using immunoblotting and immunofluorescence. Results: Upon ischemia and reperfusion injury (IR), as evidenced by increased levels of liver enzymes (ALT, AST), and inflammatory cytokines (Tnf, Mcp1 et al), NcoR1 expression levels decreased at both, mRNA and protein levels in total liver lysates. To discriminate cell type specific effects, we successfully established NcoR1△Hep mice, and found that depletion of Ncor1 in hepacotytes exhibited more severe liver injury from IR, as compared to NcoR1fl/fl control mice, as evidenced by the aforementioned parameters. Silencing NcoR1 or Ncor1 deficiency promoted both, parameters of inflammatory and oxidative stress such as Gclc, Gclm, Hmox1, and Ccl2, et, al. in AML12 cells and primary mouse hepatocytes, while NcoR1 over-expression shows the opposite results. Further, IR treated NcoR1△Hep mice displayed increased phosphorylation of p65, an essential parameter of the NFB signaling pathway, a critical mediator of stress signals in hepatocytes. Gene silencing of p65 in primary hepatocytes increased NcoR1 expression, suggesting that NFkB/p65 signaling is a negative regulator of NcoR1 expression. Conclusion: Our results indicate that damage mediated activation of NFB/p65 signaling decreases NcoR1 expression in hepatocytes, which is required for IR aggravation.

Project description:Purpose：Detection of differentially expressed lncRNA in the infarct zone and the control group in myocardial ischemia-reperfusion injury model tissue. Method: Use 8 weeks of C57BL/6 mice to establish a myocardial ischemia-reperfusion injury model, 45 minutes of ischemia, and 24 hours after reperfusion, the mice were sacrificed to obtain materials. Result: The expression of lncRNAs in the infarct area of myocardial ischemia-reperfusion injury model mice was detected, and it was found that a total of 43 lncRNAs related to myocardial ischemia-reperfusion injury changed in expression, of which 17 were up-regulated (fold change >1.5). 26 expressions are down-regulated (fold change <0.8)