The primary localization of free radical generation after anoxia/reoxygenation in isolated endothelial cells

While free radical-mediated reperfusion injury is clearly important in a variety of disparate organs, the particular cellular source of these radicals is unclear. To address this question, we subjected relatively pure (92% +/- 3% by factor VIII immunoassay) cultures of rat pulmonary artery endothelial cells to 0 to 45 minutes of anoxia (95% N2, 5% CO2), followed by reoxygenation (95% air, 5% CO2), to simulate ischemia/reperfusion. Cell injury was assayed after reoxygenation by the release of previously incorporated 51chromium and/or lactate dehydrogenase, and viability was determined by means of trypan blue exclusion. These three end points correlated closely. Without anoxia, the cells remained viable, with minimal evidence of injury for the entire experimental period, while 45 minutes of hypoxia followed by 30 minutes of reoxygenation produced substantial evidence of cell injury in 71% +/- 6% of the cells. This injury was reduced to 21% +/- 2% by treatment with the highly specific free radical scavengers superoxide dismutase and catalase together, either before anoxia or after anoxia, but just before reoxygenation. Similar protection was provided by xanthine oxidase inhibition with allopurinol. The injury was mimicked (without anoxia) by the exogenous generation of superoxide radicals with xanthine and xanthine oxidase. These experiments establish the essential components of free radical generation at reperfusion to be localized within the isolated endothelial cell in the absence of neutrophils or parenchymal cells.     

Evidence against increased hydroxyl radical production during oxygen deprivation-reoxygenation proximal tubular injury.

The purpose of this study was to assess whether proximal renal tubules generate excess hydroxyl radical (.OH) during hypoxia/reoxygenation or ischemia/reperfusion injury, thereby supporting the hypothesis that reactive oxygen species contribute to the pathogenesis of postischemic acute renal failure. In the first phase of the study, rat isolated proximal tubular segments (PTS) were subjected to hypoxia (95% N2- 5% CO2) for 15, 30, or 45 min, followed by 15 to 30 min of reoxygenation in the presence of sodium salicylate, a stable .OH trap. Cellular injury after hypoxia and reoxygenation was assessed by lactate dehydrogenase release; .OH production was gauged by hydroxylated salicylate by-product generation (2,3-, 2,5-dihydroxybenzoic acids (DHBA); quantified by HPLC/electrochemical detection). Continuously oxygenated PTS served as controls. Despite substantial lactate dehydrogenase release during hypoxia (8 to 46%) and reoxygenation (8 to 11%), DHBA production did not exceed that of the coincubated, continuously oxygenated control PTS. In the second phase of the study, salicylate-treated rats were subjected to 25 or 40 min of renal arterial occlusion +/- 15 min of reperfusion. No increase in renal DHBA concentrations occurred during ischemia or reperfusion, compared with that in sham-operated controls. To validate the salicylate trap method, PTS were incubated with a known .OH-generating system (Fe2+/Fe3+); in addition, rats were treated with antioxidant interventions (oxypurinol plus dimethylthiourea). Fe caused marked DHBA production, and the antioxidants halved in vivo DHBA generation. In conclusion, these results suggest that exaggerated .OH production is not a consequence of O2 deprivation/reoxygenation tubular injury.     

Protective effects of glutathione, glycine, or alanine in an in vitro model of renal anoxia.

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.     

Immature tubules are tolerant of oxygen deprivation

The tolerance of immature tissues to injury has been noted over the past several decades. Traditional teaching relates this tolerance to energy derived from anaerobic glycolysis. This mini-review describes investigations of the hypothesis that the immature kidney is less susceptible to oxygen deprivation than the mature kidney. Utilizing proximal tubule suspensions from immature and mature rats, studies assessing ATP levels as an index of cellular energy and lactate dehydrogenase (LDH) release as a determinant of plasma membrane damage demonstrate the developing kidney is resistant to prolonged anoxia. ATP is maintained at twofold higher levels during anoxia in the immature tubule compared with the mature tubule. The contribution of anaerobic glycolysis to the tolerance of the immature renal tubules is investigated by two inhibitors of the glycolytic pathway, L-glucose and iodoacetate. Following 70% – 90% inhibition of glycolysis, ATP is decreased to similar levels in immature and mature tubules. However, immature tubules remain resistant to anoxic damage with no significant change in LDH release. Therefore, enhanced glycolytic activity does not play a dominant role in the tolerance of the developing kidney to anoxia, and this tolerance is not primarily dependent on preservation of cellular ATP. Received July 12, 1996; received in revised form and accepted August 8, 1996     

Role of caspases in hypoxia-induced necrosis of rat renal proximal tubules.

The role of the caspases, a newly discovered group of cysteine proteases, was investigated in a model of hypoxia-induced necrotic injury of rat renal proximal tubules. An assay for caspases in freshly isolated rat proximal tubules was developed. There was a 40% increase in tubular caspase activity after 15 min of hypoxia in association with increased cell membrane damage as indicated by a threefold increase in lactate dehydrogenase release. The specific caspase inhibitor Z-Asp-2,6-dichlorobenzoyloxymethylketone (Z-D-DCB) attenuated the increase in caspase activity during 15 min of hypoxia and markedly decreased lactate dehydrogenase release in a dose-dependent manner. In the proximal tubules, Z-D-DCB also inhibited the hypoxia-induced increase in calpain activity, another cysteine protease. In contrast, when Z-D-DCB was added to purified calpain in vitro, there was no inhibition of calpain activity. The calpain inhibitor (2)-3-(4-iodophenyl)-2-mercapto-2-propenoic acid (PD150606) also inhibited the hypoxia-induced increase in caspase activity in proximal tubules, but did not inhibit the activity of purified caspase 1 in vitro. In these experiments, caspase activity was detected with the fluorescence substrate Ac-Tyr-Val-Ala-Asp-7-amido-4-methyl coumarin (Ac-YVAD-AMC), which is preferentially cleaved by caspase 1. However, minimal caspase activity was detected with the fluorescence substrate Ac-Asp-Glu-Val-Asp-7-amido-4-methyl coumarin (Ac-DEVD-AMC), which is cleaved by caspases 2, 3, and 7. The present study in proximal tubules demonstrates that (1) caspase inhibition protects against necrotic injury by inhibition of hypoxia-induced caspase activity; and (2) caspase 1 may be the caspase involved. Thus, although the role of caspases in apoptotic cell death is well established, this study provides new evidence that caspases contribute to necrotic cell death as well.     

Reactive oxygen species and rat renal epithelial cells during hypoxia and reoxygenation.

To study the importance of oxygen free radical production by and injury to proximal tubule epithelial cells, an in vitro model was established. Rat renal proximal tubule epithelial cells in primary culture were subjected to normoxic conditions or 60 minutes of hypoxia and 30 minutes of reoxygenation. Under normoxic conditions, these cells produced superoxide radical, hydrogen peroxide, and hydroxyl radical. During hypoxia and reoxygenation, there was an increase in the production of these reactive oxygen species, detected in the extracellular medium, of 252, 226, and 45 percent, respectively. The production rate of superoxide radical was most markedly increased in the first five minutes of reoxygenation. Studies employing 2,7-dichlorofluorescein which fluoresces when oxidized by peroxides revealed a seven-fold increase in cellular fluorescence in cells studied after hypoxia and reoxygenation compared with control cells. That increased production of reactive oxygen species played a role in cellular injury was demonstrated by an increase in lipid peroxidation during hypoxia and reoxygenation, as well as substantial injury during hypoxia and reoxygenation which could be largely prevented by the addition of superoxide dismutase, catalase, dimethylthiourea, or deferoxamine to the cells. These studies demonstrate that proximal tubule epithelial cells produce reactive oxygen species in increased amounts during hypoxia and reoxygenation, and that these reactive oxygen species are injurious to the cells under these conditions.     

Nitric oxide—mediated renal epithelial cell injury during hypoxia and reoxygenation

The potent endothelial-derived vasodilator nitric oxide (NO) has been identified as a protective agent in acute renal failure. However, some recent studies have suggested a detrimental effect of NO on rat proximal tubules exposed to hypoxia and reoxygenation. We determined whether NO metabolites cause intracellular oxidation during hypoxia and reoxygenation and whether this oxidative stress is linked to irreversible cell injury. Primary cultures of rat proximal tubular epithelial cells were studied in a subconfluent stage and subjected to 60 min hypoxia and 30 min reoxygenation. Intracellular oxidation was assessed by monitoring the conversion of nonfluorescent dihydrorhodamine 123 (DHR) to fluorescent rhodamine 123 as a probe for the long-lived oxidant peroxvnitrite. Hypoxia and reoxygenation produced a marked increase in cellular generation of oxidant species. Intracellular oxidation of DHR was reduced by approsimately 40% when cells were also exposed to the NO svnthase inhibitor L-NAME. Oxidation of DHR following hypoxia and reoxygenation was not affected by SOD or DATTU. A combination of SOD and L-NAME was no more effective than L-NAME alone. Hypoxia and reoxygenation produced substantial injury (as LDH release). There was a 40% reduction in LDH release when cells were pretreated with a NO synthase inhibitor. In summary, increased generation of NO capable of inducing intracellular oxidizing reactions and cell death occurred during renal hypoxia and reoxygenation.     

Changes in xanthine oxidase in ischemic rat brain

Xanthine oxidase activity in the rat brain was measured by means of high-performance liquid chromatography with electrochemical detection of uric acid. Cerebral ischemia was produced by a four-vessel occlusion method. In the control rat, the enzyme activity was 0.87 +/- 0.13 nmol/gm wet weight/min at 25 degrees C (mean +/- standard deviation), of which 92.4% was associated with the nicotinamide adenine dinucleotide (NAD)-dependent dehydrogenase form and only 7.6% with the oxygen-dependent superoxide-producing oxidase form. However, the ratio of the latter form increased to 43.7% after 30 minutes of global ischemia, despite the total xanthine oxidase activity remaining the same. Thus, it was revealed that uric acid can be synthesized in the rat brain and that cerebral ischemia induced the conversion of xanthine oxidase from an NAD-dependent dehydrogenase to an oxygen-dependent superoxide-producing oxidase. Although the xanthine oxidase pathway has been proposed as a source of oxygen-derived free radicals in various ischemic organs other than brain, the results of the present study suggest the involvement of the oxygen free radicals generated from this pathway in the pathogenesis of the ischemic injury of the rat brain.     

Xanthine:acceptor oxidoreductase activities in ischemic rat skin flaps

Xanthine:acceptor oxidoreductase activities were assayed in free skin flaps following prolonged preservation. In normal rat skin, xanthine dehydrogenase transfers electrons to NAD+ and accounts for 73% of total oxidoreductase activity, and xanthine oxidase transfers electrons to molecular oxygen and accounts for the remaining 27%. Xanthine oxidase activity increased significantly in skin flaps during ischemia: approximately 30 and 100% increases after 6 and 24 hr of ischemia, respectively. Allopurinol inhibited xanthine oxidoreductase activity: free skin flaps obtained from allopurinol-treated animals exhibited a low level of xanthine oxidoreductase activity throughout the period of preservation. Systemic allopurinol significantly improved the survival rate from 32 to 75% of free flaps transferred after 24 hr of preservation at room temperature. These observations suggest that the xanthine oxidase system is a major source of oxygen free radicals following ischemia/reperfusion in skin. The increase in xanthine oxidase is attributable to the conversion of xanthine dehydrogenase to oxidase, a conversion which involves sulfhydryl oxidation in skin flaps.     

A novel method of inducing and assuring total anoxia during in vitro studies of O2 deprivation injury

Oxyrase is an enzyme mixture coveted by microbiologists for its unique ability to remove O2 from media in which anaerobic bacteria are grown. The study reported here examined the potential usefulness of Oxyrase as an adjunct to gassing freshly isolated rat proximal tubules (RPT) with 95% N2-5% CO2 in an attempt to achieve totally O2-free conditions (anoxia) before initiating studies on the mechanism of O2 deprivation injury in vitro. RPT, in 6 ml of Krebs-Henseleit buffer (KHB), were initially gassed with 95% N2-5% CO2 at 1.5 liters/min for 5 min and incubated for 15 to 30 min at 37 degrees C in a shaking water bath, pO2 decreased from approximately 400 to 80 mm Hg. If RPT were present in the KHB, pO2 was even lower, i.e., approximately 50 mm Hg. Addition of increasing concentrations of Oxyrase (300 to 1,500 mU) to KHB alone, that is, without RPT, reduced pO2 from 80 mm Hg to less than 5 mm Hg; increasing the gas rate from 1.5 to 3.0 liter/min of 95% N2-5% CO2, the concentration of Oxyrase to 1,800 mU, and adding RPT reduced pO2 to zero. In this latter condition, pO2 remained unmeasurable during the 20 min of study and neither pH nor pCO2 changed compared with control values. Oxyrase (1,800 mU) had no effect on lactate dehydrogenase release, a sign of membrane injury, in normoxic RPT in KHB. We conclude that anoxia can easily be achieved by the addition of Oxyrase to KHB in which RPT are suspended, if the appropriate concentration of Oxyrase is added and if the RPT are gassed with 95% N2-5% CO2. This concentration of Oxyrase exerts no detrimental effects on RPT gassed with 95% O2-5% CO2.     

Reoxygenation injury following anoxic perfusion preferentially impairs bile acid-independent bile flow.

We perfused isolated rat livers with Krebs-Ringer buffer, with no recirculation. Bile flow virtually stopped during 30 min of anoxia and resumed following reoxygenation to reach a plateau of 44% of the control level. When taurodehydrocholic acid (TDHC, 50 nmol/min/g liver) was administered during reoxygenation, bile flow increased three-fold (16.1 +/- 1.3 to 45.3 +/- 6.3 microliters/g liver). The increase in bile output with TDHC was 27.8 microliters/g liver, which was 89% of the control output. Bile acid output during this period was 1.4 mumol/g liver, which was 93% of the control level. Addition of allopurinol (50 nmol/min/g liver) without TDHC increased bile flow significantly (16.1 +/- 1.3 to 21.3 +/- 1.2 microliters/g liver), but the change was not significant when allopurinol and TDHC were given. The addition of allopurinol also reduced the cumulative release of lactate dehydrogenase from the liver during the reoxygenation period, but had no effect on hepatic adenosine triphosphate levels. Our data suggest that the bile acid-independent bile flow is sensitive to reoxygenation injury following anoxia whereas bile acid output and bile acid-dependent bile flow are resistant.     

A synergistic effect of extracellular hypocalcemic condition for hyperoxic reoxygenation injury in rat hepatocytes

BACKGROUND: Calcium accumulation of cells and mitochondria during reperfusion or reoxygenation has been implicated as a potential factor in cell injury as the result of mitochondrial damage. The objective of this study was to disclose whether or not low extracellular calcium ion concentration ([Ca2+]ex) in the medium at the time of reoxygenation might prevent calcium accumulation and attenuate hepatocytes injury after severe hypoxia. METHODS: Isolated rat hepatocytes were incubated under a hyperoxic or hypoxic atmosphere for 60 min. During the ensuing 60-min hyperoxic reoxygenation, medium [Ca2+]ex was varied from 0.6 microM to 2.0 mM by altering total calcium and addition of chelators. RESULTS: Incubation in low [Ca2+]ex reduced total cellular calcium and mitochondrial calcium in both the hyperoxic and hypoxic group. Under hyperoxic/hyperoxic incubation (control), hepatocytes were able to maintain potassium balance when [Ca2+]ex was >3.0 microM (pCa=5.5) and cellular viability (% lactate dehydrogenase release) at all levels of extracellular calcium. Under hypoxic/hyperoxic incubation (reoxygenation), however, loss of the ability to restore potassium balance as well as apparent increase in lactate dehydrogenase release were observed at severely low [Ca2+]ex (<30 microM; pCa=4.5). This low [Ca2+]ex-induced exacerbation of hepatocytes viability could not be generated under mild reoxygenation such as normoxia. CONCLUSIONS: In normal isolated hepatocytes, very low [Ca2+]ex levels produce only very subtle changes in membrane permeability of isolated hepatocytes. After hypoxia, however, hypocalcemia acts synergistically with hyperoxic reoxygenation to produce more severe damage. These results suggested that [Ca2+]ex should be maintained on the physiological level to attenuate hepatocytes injury after severe hypoxia.     

Elemental microanalysis of organelles in proximal tubules. II. Effects of oxygen deprivation

This communication describes the effects of anoxia on rabbit proximal renal tubule element (ion) content by using high-resolution electron probe x-ray microanalytical imaging to obtain quantitative elemental data from subcellular compartments not previously resolvable with low-resolution imaging. These organelles and regions include the heterochromatin and euchromatin of the nucleus and the microvilli of the apical brush border, in addition to mitochondria, lysosomes, and cytoplasm. Anoxia of 40-min duration caused the expected decrease in K and increase in Na and Cl concentrations in the tubules with the cytoplasmic K:Na ratio declining to 0.13:1. These changes were accompanied by decreases in ATP and total K contents, and an increase in lactate dehydrogenase release. Swelling occurred in some cells as evidenced by ultrastructural changes. No alterations were evident after oxygen deprivation in Ca content of cytoplasm (control, 6.7 +/- 0.6 versus anoxia, 7.6 +/- 0.7 nmol/mg dry wt) or mitochondria (control, 4.0 +/- 0.4 versus anoxia, 4.9 +/- 0.6 nmol/mg dry wt) or in S content of recognizable lysosomes (control, 314 +/- 11 versus anoxia, 325 +/- 12 nmol/mg dry wt). Brush border (microvillus) Ca content was higher than cytoplasmic Ca content during normoxia (10.7 +/- 0.9 nmol/mg dry wt) and increased further during anoxia (17.0 +/- 1.0 nmol of Ca/mg dry wt). The finding of higher Ca content within the brush border region during normoxia is unexpected and novel, because such results suggest that Ca homeostasis in the apical elaboration of the proximal cell may be different from that in the cytoplasm. The results also raise the possibility that an increase in Ca content in the brush border membrane region may be involved in the pathogenesis of renal cell injury.     

Stress initiated during isolation of rat renal proximal tubules limits in vitro survival

The effects of oxidative damage were assessed in rat proximal tubule fragments (isolated by collagenase perfusion) by monitoring lactate dehydrogenase release (LDH-R) to measure cell viability and thiobarbituric acid (TBA) reactive material to follow oxidative damage. Increasing the oxygen content in the incubation atmosphere from 10 to 95% significantly increased LDH-R and TBA reactants. Addition of butylated hydroxytoluene or deferoxamine (DF) to the medium prevented these changes, but ascorbic acid or mannitol had no positive effect. Lima bean trypsin inhibitor also reduced LDH leakage significantly when added to the medium, but not when added to the perfusion buffers. In contrast, adding DF to the perfusate during tubule isolation produced the most pronounced benefit; net LDH-R after 4 hr was about 10% in tubules prepared this way compared to 20% when DF was omitted. Basal oxygen consumption declined to approximately the same extent as LDH-R increased. Maintenance of nystatin-stimulated respiration, ATP/ADP, GSH content and total adenine nucleotides indicated good cell function. These results suggest that oxidative damage initiated during the tubule isolation procedure limits cell survival but this effect can be counteracted substantially by the addition of DF to the perfusion buffer.     

Stress Initiated During Isolation of Rat Renal Proximal Tubules Limits in Vitro Survival

The effects of oxidative damage were assessed in rat proximal tubule fragments (isolated by collagenase perfusion) by monitoring lactate dehydrogenase release (LDH-R) to measure cell viability and thiobarbituric acid (TBA) reactive material to follow oxidative damage. Increasing the oxygen content in the incubation atmosphere from 10 to 95% significantly increased LDH-R and TBA reactants. Addition of butylated hydroxytoluene or deferoxamine (DF) to the medium prevented these changes, but ascorbic acid or mannitol had no positive effect. Lima bean trypsin inhibitor also reduced LDH leakage significantly when added to the medium, but not when added to the perfusion buffers. In contrast, adding DF to the perfusate during tubule isolation produced the most pronounced benefit; net LDH-R after 4 hr was about 10% in tubules prepared this way compared to 20% when DF was omitted. Basal oxygen consumption declined to approximately the same extent as LDH-R increased. Maintenance of nystatin-stimulated respiration, ATP/ADP, GSH content and total adenine nucleotides indicated good cell function. These results suggest that oxidative damage initiated during the tubule isolation procedure limits cell survival but this effect can be counteracted substantially by the addition of DF to the perfusion buffer.     

Propofol displays no protective effect against hypoxia/reoxygenation injury in rat liver slices

Using precision-cut liver slices (20-25 mg wet weight) from male Wistar rats, we examined whether clinically relevant propofol concentrations have hepatoprotective or -toxic effects during hypoxia/reoxygenation. Slices were preincubated for 2 h in sealed roller vials (three slices per vial) containing Waymouth's medium (37 degrees C; 95% oxygen/5% CO(2)). Then, propofol or Intralipid was added to create four different groups (control, Intralipid, small-concentration propofol [0.5-1.5 micro g/mL], and large-concentration propofol [2.0-6.0 micro g/mL]). Thereafter, each group was incubated for 4 h under 95% oxygen/5% CO(2) (no hypoxia) or for 2 h under 100% nitrogen plus 2 h under 95% oxygen/5% CO(2) (hypoxia/reoxygenation). Slice viability and hypoxia/reoxygenation injury were assessed at 2, 3, and 4 h after incubation began by using the slice intracellular K(+) concentration, energy status (adenosine triphosphate content, total adenine nucleotides content, and energy charge), and liver enzyme leakage (aspartate aminotransferase, alanine aminotransferase, and lactate dehydrogenase). Propofol and Intralipid caused a significant delay in energy charge recovery in comparison with the control. There were no significant differences between the propofol groups and the other two groups in intracellular K(+) content or liver enzyme leakage. Propofol had no hepatotoxic effect under no-hypoxia conditions in rat liver slices, nor did it have a protective effect against hypoxia/reoxygenation-induced hepatic injury. IMPLICATIONS: Propofol had no hepatotoxic effect under no-hypoxia conditions in rat liver slices, nor did it have a protective effect against hypoxia/reoxygenation-induced hepatic injury.     

Protective effect of anisodamine on cultured bovine pulmonary endothelial cell injury induced by oxygen-free radicals.

Anisodamine, a Chinese traditional medicine herb, has been used for treatment of adult respiratory distress syndrome effectively, but little is known about its mechanism. We attempted to investigate if anisodamine could protect bovine pulmonary endothelial cell injury induced by exogenous oxygen-free radicals that were generated by xanthine/xanthine oxidase or opsonized zymosan-stimulated polymorphonuclear leukocytes. Results showed that with the addition of xanthine/xanthine oxidase into cultured bovine pulmonary endothelial cells, production of malondialdehyde and release of lactate dehydrogenase in supernatant increased, and synthesis of prostacyclin decreased. Damaged cellular membranes were revealed by scanning electron microscopy. The same was true for the addition of opsonized zymosan-stimulated polymorphonuclear leukocytes. While treatment with anisodamine greatly attenuated all of the above-mentioned parameters, results showed that (1) cultured bovine pulmonary endothelial cells could be damaged by oxygen-free radicals, (2) anisodamine had a protective effect on this injury as effective as that of superoxide dismutase and catalase, and (3) the membrane-stable action might contribute to the mechanism of protective effect against this injury.     

Increased proximal tubular cholesterol content: implications for cell injury and "acquired cytoresistance"

BACKGROUND: Acute renal failure (ARF) leads to secondary adaptive changes that serve to protect proximal tubules from subsequent ischemic or toxic damage [so-called "acquired cytoresistance" (CR)]. A characteristic of CR is increased plasma membrane resistance to attack. Therefore, this study sought to identify potential changes in plasma membrane lipid composition in CR tubules/renal cortex and, if present, to test whether they might mechanistically contribute to the CR state. METHODS: Renal cortices/isolated tubules were obtained from CR mouse kidneys (18-hr postinduction of ischemia reperfusion, myoglobinuria, or ureteral obstruction). Their plasma membrane phospholipid/cholesterol profiles were compared with those observed in either control tissues or tissues obtained one to two hours post-renal damage (that is, prior to emergence of CR). RESULTS: Either no changes or inconsistent changes in phospholipid profiles were observed in CR tissues. Conversely, CR (vs. control) tissues demonstrated a consistent 25 to 50% increase in membrane cholesterol content. To ascertain whether cholesterol impacts tubule susceptibility to injury, its levels were reduced in proximal tubule (HK-2) cells with either (a) mevastatin, (b) a cholesterol "stripping" agent, (c) cholesterol oxidase, or (d) cholesterol esterase. Then cell susceptibility to injury [adenosine 5'-triphosphate (ATP) depletion; Fe-mediated oxidant stress] was assessed. In each instance, cholesterol reductions dramatically sensitized to superimposed injury (for example, a 2 to 3 times increase in the % of lactate dehydrogenase release). When cholesterol levels were restored to normal in CR tubules (with a "stripping" agent), an increased tubule susceptibility to injury resulted. Because cholesterol decreases membrane fluidity, the impact of a membrane-fluidizing agent (A2C) on cell injury was assessed. A2C dramatically sensitized HK-2 cells to superimposed attack. CONCLUSIONS: ARF leads to an up-regulation of proximal tubule cholesterol content. The latter may then contribute to acquired CR, possibly by stabilizing the plasma membrane via its antifluidizing effect.     

Sevoflurane Protects Rat Mixed Cerebrocortical Neuronal-Glial Cell Cultures against Transient Oxygen-Glucose Deprivation: Involvement of Glutamate Uptake and Reactive Oxygen Species

Background: The purpose of this study was to clarify the role of glutamate and reactive oxygen species in sevoflurane-mediated neuroprotection on an in vitro model of ischemia-reoxygenation.

Methods: Mature mixed cerebrocortical neuronal-glial cell cultures, treated or not with increasing concentrations of sevoflurane, were exposed to 90 min combined oxygen-glucose deprivation (OGD) in an anaerobic chamber followed by reoxygenation. Cell death was quantified by lactate dehydrogenase release into the media and cell viability by reduction of 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium by mitochondrial succinate dehydrogenase. Extracellular concentrations of glutamate and glutamate uptake were assessed at the end of the ischemic injury by high-performance liquid chromatography and incorporation of L-[3H]glutamate into cells, respectively. Free radical generation in cells was assessed 6 h after OGD during the reoxygenation period using 2',7'-dichlorofluorescin diacetate, which reacts with intracellular radicals to be converted to its fluorescent product, 2',7'-dichlorofluorescin, in cell cytosol.

Results: Twenty-four hours after OGD, sevoflurane, in a concentration-dependent manner, significantly reduced lactate dehydrogenase release and increased cell viability. At the end of OGD, sevoflurane was able to reduce the OGD-induced decrease in glutamate uptake. This effect was impaired in the presence of threo-3-methyl glutamate, a specific inhibitor of the glial transporter GLT1. Sevoflurane counteracted the increase in extracellular level of glutamate during OGD and the generation of reactive oxygen species during reoxygenation.     

The role of calcium ions and calcium channel entry blockers in experimental ischemia-reperfusion-induced liver injury.

Verapamil administered before treatment, but not after treatment, had a beneficial effect on a 90-minute warm ischemia-reperfusion rat liver injury model. The possible activation of proteases converting the xanthine dehydrogenase to xanthine oxidase, the significant mitochondrial calcium loading during the ischemic period, and the potentiation of calcium and oxygen-derived free radicals to promote injury to mitochondria are mechanisms supported by this study, based on both histologic observations and on the pattern of enzyme leak after the acute ischemic event.