Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0920646 (renal ischemia)
 2,515 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Rats were anesthetized and their lift kidneys were made ischemic for 1 h by clamping of the aorta just above the left renal artery. Mannitol (2.5 g/kg), Dextran 70 (0.6 g/kg), methylprednisolone (50 and 100 mg/kg), and allopurinol (100 mg/kg body weight) were administered before, during, or after the ischemia period in order to test the effect of each of these drugs upon this model of renal injury. At 24 h after the release of the aortic clamp the left kidneys of the drug treated animals wwere perfusion fixed and processed for light and electron microscopy. Dextran administration to animals with ischemic kidneys gave rise to a pronounced vacuolization ("osmotic nephrosis"), in the entire proximal tubule and especially in the pars recta. This was in contrast to dextran administration to rats with nonischemic kidenys, which showed no or very mild "osmotic nephrosis." This demonstrates that ischemia makes rat kidneys more susceptible to the development of "osmotic nephrosis." In controls (no drug treatment) one hour of renal ischemia gave partial necrosis of pars recta of the proximal tubule, while the pars convoluta tubule survived. Mannitol treatment significantly reduced the amount of necrosis of the pars recta, whereas dextran, methylprednisolone, and allopurinol had no or a negative effect on the survival of the cells of the pars recta segment. It is suggested that mannitol protects against the development of necrosis by increasing medullary blood flow in combination with a counteractive influence on the cellular swelling, which is known to occur in ischemia.
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PMID:Effect of mannitol, dextran (macrodex), allopurinol, and methylprednisolone on the morphology of the proximal tubule of the rat kidney made ischemic in vivo. 40 53

We conducted experiments to determine (1) tissue, blood, and urine levels of adenosine produced by the ischemic kidney under conditions of renal artery occlusion, and (2) the site(s) of production and release of adenosine by the kidney. Concentrations of adenosine, inosine, and hypoxanthine in the dog urine were found to increase after 2 minutes of renal artery occlusion as were concentrations of these metabolites in renal tissue after 10 minutes of renal artery occlusion. Renal venous plasma levels of inosine and hypoxanthine also were elevated after 3 minutes of arterial occlusion. In modified stop-flow experiments, adenosine appeared in the urine in a peak that corresponded most closely with proximal tubule fluid. 5'-Nucleotidase, the enzyme which catalyzes the dephosphorylation of 5'-AMP or 5'-IMP to adenosine or inosine, respectively, was found to be located primarily on the external membranes and mitochondria of proximal tubule cells, but not in distal tubule or collecting duct cells. Since adenosine has been demonstrated to elicit renal vasoconstriction and is produced by the ischemic kidney, it is suggested that adenosine may be involved in the mediation of postocclusion renal ischemia.
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PMID:Adenosine production in the ischemic kidney. 67 22

The hypothesis that posthypoxic renal injury is mediated by xanthine oxidase-derived oxygen free radical production was tested in an in vitro model of rat proximal tubule epithelial cells in primary culture subjected to 60 min of hypoxia and 30 min of reoxygenation. Hypoxia-reoxygenation-induced injury, measured as lactate dehydrogenase (LDH) release, was 54.0 +/- 7.1%. Inhibition of xanthine oxidase by 10(-4) M allopurinol attenuated injury (LDH release = 35.5 +/- 3.7%; P less than 0.01). Oxypurinol was similarly effective. Alternatively, cells were treated with 50 or 100 microM tungsten to inactivate xanthine oxidase. Tungsten prevented hypoxia-reoxygenation-induced superoxide radical production (basal = 97 +/- 8, hypoxia-reoxygenation = 172 +/- 12, and plus tungsten = 73 +/- 8 nmol/micrograms protein) and attenuated hypoxia-reoxygenation-induced injury (LDH release: basal = 18.8 +/- 3.0%, hypoxia-reoxygenation = 62.0 +/- 4.8%, plus 50 microM tungsten = 24.8 +/- 5.0%, and plus 100 microM tungsten = 6.0 +/- 0.7%). In addition, hypoxia and reoxygenation increased the ratio of xanthine oxidase to total activity (xanthine oxidase + xanthine dehydrogenase) from 73 to 100%. Therefore xanthine oxidase was responsible for hypoxia-reoxygenation-induced superoxide radical formation and hypoxia-reoxygenation-induced injury. Xanthine oxidase is likely to be the major source of oxygen free radicals during renal ischemia and reperfusion.
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PMID:Xanthine oxidase produces O2-. in posthypoxic injury of renal epithelial cells. 132 7

To determine whether heat shock proteins (HSPs) might be active in cellular recovery following transient ischemia, we examined rat kidneys for 70-kDa HSP (HSP-70) mRNA expression, protein elaboration, and intracellular localization after 45 min of renal ischemia and reflow of 15 min, 2, 6, and 24 h. Inducible HSP-70 mRNA is present at 15 min of reperfusion, peaks between 2 and 6 h, and falls by 24 h. Inducible 72-kDa HSP (HSP-72) protein accumulates progressively through 24 h and is found in both soluble and microsomal fractions following ischemia. Within proximal tubules, immunofluorescent localization of HSP-72 is restricted to the apical domain at 15 min, is dispersed through the cytoplasm in a vesicular pattern at 2 and 6 h, and has migrated away from the apical domain at 24 h. A portion of the vesicular HSP-72 is associated with lysosomes; no intranuclear HSP-72 is detected. The course of mRNA induction, protein elaboration, and HSP-72 localization coincides with previously described changes in proximal tubule morphology and polarity following sublethal ischemic injury. HSP-72 may be instrumental in cellular remodeling and restitution of epithelial polarity during recovery from ischemic renal injury.
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PMID:Induction and intracellular localization of HSP-72 after renal ischemia. 144 67

The ability of prostaglandins to protect the kidney against ischemic and toxic renal injury was evaluated by in vivo and in vitro models of renal ischemia. The prostaglandin E1 analogue, misoprostol, was found to provide significant protection against ischemia-induced renal dysfunction in rats subjected to 40 minutes of renal artery occlusion. Misoprostol-treated rats had glomerular filtration rates almost threefold greater than control animals, although renal blood flow and renal vascular resistance were not significantly different. Improved tubular function was reflected in a lower fractional excretion of sodium and a higher urine-to-plasma creatinine ratio. Misoprostol also provided similar protection in a model of toxic renal injury produced by mercuric chloride. In an in vitro model employing primary cultures of proximal tubule epithelial cells subjected to hypoxia and reoxygenation, misoprostol limited cell death. Posthypoxic cells had apical membrane disruption and loss of microvilli when examined by transmission electron microscopy. These changes were not seen in misoprostol-treated cells. The "cytoprotective" effect was also produced by prostaglandin E2 and prostacyclin. The ability of prostaglandin E to protect against toxic and ischemic renal injury did not appear to be due to an antioxidant effect because misoprostol did not limit lipid peroxidation in vivo and did not protect against oxidant injury by tert-butyl hydroperoxide in vitro. Although the exact mechanism of prostaglandin protection was not revealed, these studies demonstrate that prostaglandins protect renal tubule epithelial cells from hypoxic injury at the cellular level independent of hemodynamic factors or inflammatory responses. Such a "cytoprotective" effect of prostaglandins may be a generalized phenomenon since it has also been demonstrated in gastrointestinal epithelium.
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PMID:Prostaglandins protect kidneys against ischemic and toxic injury by a cellular effect. 147 66

Both glutathione and glycine provide some protection against ischemic renal injury in a variety of experimental models. However, results have been inconsistent and there may also be model heterogeneity. The effects of glutathione, glycine, and alanine in a cell culture model of renal anoxia/reoxygenation injury were tested. When primary cultures of rat proximal tubule epithelial cells were subjected to 60 min of anoxia and 30 min of reoxygenation, glutathione (2 mM) essentially eliminated lethal cell injury as determined by lactate dehydrogenase release. Glycine or alanine, on the other hand, provided only partial protection. Glutamate did not protect, although cysteine did. The glutathione synthesis inhibitor buthionine sulfoximine blocked the protective effect of exogenous glutathione, and the glutathione transport inhibitor probenecid partially blocked glutathione protection. A combination of glycine, glutamate, plus cysteine also protected against anoxia/reoxygenation injury. The studies suggest that both glutathione degradation with intracellular resynthesis and transport of intact glutathione into the cell are involved in the protection afforded by exogenous glutathione. These results are different from those obtained in other experimental models of renal ischemia, such as freshly isolated proximal tubules, because the protective effects of glutathione were not derived solely from glycine generation. These studies also suggest the need for caution in extrapolating results from one model of renal anoxic injury to another.
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PMID:Protective effects of glutathione, glycine, or alanine in an in vitro model of renal anoxia. 162 58

Although reactive oxygen species are believed to participate in postischemic renal injury, the actual chemical species involved and the role of endogenous scavenging systems in protecting against injury requires additional study. Hydrogen peroxide, which derives from superoxide radical, is toxic and also yields toxic hydroxyl radical. 3-amino-1,2,4-triazole reacts with catalase to form irreversibly inactivated catalase only in the presence of hydrogen peroxide. We made use of this chemical reaction both to determine whether inhibition of the hydrogen peroxide-scavenging enzyme catalase would influence ischemic renal injury and to measure hydrogen peroxide production rates after ischemia. Sprague-Dawley rats were given aminotriazole (100 mg/kg) one hour before 40 min of renal ischemia. Twenty-four h after ischemia GFR had decreased to 300 microL/min in control animals and to 50 microL/min in aminotriazole-treated animals. Histologic evidence of injury was also worse in catalase-inhibited animals. To measure hydrogen peroxide production rates aminotriazole was given 60 min before measurement of renal catalase activity. In control animals, aminotriazole caused a 53.4% decrease in catalase activity. In animals subjected to 40 min of ischemia plus either 10 or 60 min of reflow catalase activity decreased by 33.9 and 49.5% (not significantly different from control). Thus, when measured by this method total renal hydrogen peroxide production was considerable but was not increased by ischemia. However, in isolated proximal tubule segments 60 min of anoxia and 30 min of reoxygenation caused a 42% increase in H2O2 released into the incubation medium. In summary, inhibition of catalase before ischemia led to exacerbation of ischemic injury.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Hydrogen peroxide and ischemic renal injury: effect of catalase inhibition. 164 49

Tandem Scanning Confocal Microscopy (TSCM) allows one to section optically into and record real-time images of living organs and tissues in a noninvasive fashion. In this paper, we will present some initial TSCM observations of subcapsular nephrons in the living, intact kidneys of Munich-Wistar rats and evaluate the nephron's responses to temporary ischemia and to intravenous infusion of mannitol. The rats were anesthetized with Inactin and a laparotomy performed to expose the kidneys. Using a TSCM equipped with a 20 x water-immersion objective, we optically sectioned through the intact kidney capsule and recorded real-time images of living subcapsular glomeruli and uriniferous tubules. The proximal tubule brush border was highly reflective and allowed us to distinguish between the first and second segments of the proximal tubules as well as the distal tubules. Cellular elements of the blood could be seen passing rapidly through peritubular capillaries and individual glomerular capillary loops. With fluorescent filters in place, intravenously injected carboxyfluorescein was seen to pass through the glomerular capillary loops and then progressively through the different segments of the uriniferous tubules. Ligation of the renal artery resulted in rapid swelling of proximal tubule cells into the tubular lumens, loss of reflectiveness of the microvillous brush borders, and closure of the peritubular capillary spaces. Upon release of the ligature, the proximal tubule lumens again became patent, often opening up abruptly and in a zipper-like fashion down the length of the tubules. Increasing the glomerular filtration rate by intravenous infusion of mannitol resulted in increases in tubular luminal and perimeter dimensions. Mannitol also acted as an effective impermeant osmotic agent and prevented most of the cellular swelling which was otherwise seen in response to renal ischemia.
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PMID:Tandem scanning confocal microscopy (TSCM) of normal and ischemic living kidneys. 190 77

Several functional parameters were applied in an experimental model of ischemia to test the ability to localize the distribution of tubular lesions. Canine kidneys were perfused with protective solutions and rendered ischemic for definite periods. Renal function was determined during a subsequent 3-h reperfusion. The pattern and the extent of renal injury were influenced by varying the duration of ischemia and by modifying the protective solution used. The results suggest that by employing an appropriate selection of parameters it is possible to allocate renal injury to definite sections of the tubules. According to such an evaluation, under protection with HTK-solution, the proximal tubule limits the tolerance of renal ischemia. The thick ascending limb shows some vulnerability that is aggravated by disadvantageous modifications of the protective solution and that may become more pronounced in the course of reperfusion. In contrast, more distal parts of the nephron retain a remarkable reserve transport capacity after a tolerable level of ischemia.
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PMID:Postischemic diagnostic localization of tubular lesions. 231 10

Temporary renal ischemia is followed by increased DNA synthesis and cell division as the kidney restores the continuity of the renal epithelium. We sought to characterize some of the changes in proto-oncogene and growth factor expression during this proliferative response. Northern analysis of polyadenylated RNAs of kidney cortical and outer stripe of outer medullary tissue from male Sprague-Dawley rats was performed following release of renal hilar clamping of 50 minutes duration. Ischemia produced an increase in c-fos mRNA that reached a peak at one hour and declined rapidly to control levels by four hours after release of the clamp. A similar rapid increase and decrease in early growth response 1 (Egr 1) mRNA was noted. The response of these immediate early genes was typical of their response to mitogens, suggesting that they served a similar role in renal cell regeneration. Levels of c-Ki-ras and glyceraldehyde phosphate dehydrogenase mRNA were unchanged. Renal preproEGF mRNA decreased at two hours, was virtually absent by 24 hours and remained low for at least four days after ischemia. Urinary excretion of EGF fell immediately after release of ischemia and before the decline in preproEGF mRNA or SNGFR, suggesting post-transcriptional affects of ischemia on renal EGF production. EGF excretion returned to only 50% of control by day 21. Specific 125I-EGF binding increased in membrane fractions of cortex, outer medulla and inner medulla as early as 24 hours after release of the clamp. Cortical 125I-EGF binding increased in the proximal tubule but not in the glomerulus.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Changes in gene expression after temporary renal ischemia. 236 5


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