Browsing by Subject "Ischemic Preconditioning"

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    The macrophage mediates the renoprotective effects of endotoxin preconditioning
    (American Society of Nephrology (ASN), 2015-06) Hato, Takashi; Winfree, Seth; Kalakeche, Rabih; Dube, Shataakshi; Kumar, Rakesh; Yoshimoto, Momoko; Plotkin, Zoya; Dagher, Pierre C.; Department of Medicine, IU School of Medicine
    Preconditioning is a preventative approach, whereby minimized insults generate protection against subsequent larger exposures to the same or even different insults. In immune cells, endotoxin preconditioning downregulates the inflammatory response and yet, preserves the ability to contain infections. However, the protective mechanisms of preconditioning at the tissue level in organs such as the kidney remain poorly understood. Here, we show that endotoxin preconditioning confers renal epithelial protection in various models of sepsis in vivo. We also tested the hypothesis that this protection results from direct interactions between the preconditioning dose of endotoxin and the renal tubules. This hypothesis is on the basis of our previous findings that endotoxin toxicity to nonpreconditioned renal tubules was direct and independent of immune cells. Notably, we found that tubular protection after preconditioning has an absolute requirement for CD14-expressing myeloid cells and particularly, macrophages. Additionally, an intact macrophage CD14-TRIF signaling pathway was essential for tubular protection. The preconditioned state was characterized by increased macrophage number and trafficking within the kidney as well as clustering of macrophages around S1 proximal tubules. These macrophages exhibited increased M2 polarization and upregulation of redox and iron-handling molecules. In renal tubules, preconditioning prevented peroxisomal damage and abolished oxidative stress and injury to S2 and S3 tubules. In summary, these data suggest that macrophages are essential mediators of endotoxin preconditioning and required for renal tissue protection. Preconditioning is, therefore, an attractive model to investigate novel protective pathways for the prevention and treatment of sepsis.
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    Studies on hydrodynamic delivery as a treatment for acute kidney injury
    (2017) Kolb, Alexander; Atkinson, Simon; Bacallao, Robert; Basile, David; Dai, Guoli; Szymanski, Daniel
    Hydrodynamic delivery is a powerful tool that allows delivery of macromolecules to the kidney culminating in gene expression. This finding is important in the fight against kidney disease. Current therapy for kidney injury, specifically acute kidney injury, is lacking. Supportive care in the form of IV fluids and medications aimed at restoring Glomerular Filtration Rate (GFR) and urine output are currently used. However, even with these treatments, prognoses of patients diagnosed with this disease remains poor. We believe that hydrodynamic delivery provides a mechanism that can be used to reverse and prevent AKI. Hydrodynamic delivery following ischemic injuries leads to reductions in serum creatinine and infiltrating mononuclear cells, as well as increased renal blood flow and survival. These changes are due to reductions in vascular congestion and inflammation typically seen following injury. To determine the underlying mechanisms of gene delivery preventing AKI, we used candidate genes identified in a proteomic screen on kidneys that recovered from AKI. We selected Isocitrate Dehydrogenase II (IDH2) and Sulfotransferase 1C2 (SULT1C2) for study and found that delivery prior to injury prevents serum creatinine increase and reduces cell death. We found that gene delivery of IDH2 prevents a glycolytic shift typically seen following ischemic injuries. The mechanism underlying the prevention of this shift are seen in increased ATP stores and spare respiratory capacity allowing the cell to remain in an oxidative state. Additionally, we show that SULT1C2 post-translationally modifies the mitochondria membrane, increasing oxidative phosphorylation providing the cell with additional energy needed in times of oxidative stress. These candidate genes allow cells to remain in an oxidative state preventing the activation of cell death pathways typically activated following injury, thereby preserving normal kidney function.