The influence of lactate,pyruvate and glucose as exogenous substrates on free radical defense mechanisms in isolated rat hearts during ischaemia and reperfusion

Previous studies have shown that exogenous lactate impairs mechanical function of reperfused ischaemic hearts, while pyruvate improves post-ischaemic recovery. The aim of this study was to investigate whether the diverging influence of exogenous lactate and pyruvate on functional recovery can be explained by an effect of the exogenous substrates on endogenous protecting mechanisms against oxygen-derived free radicals. Isolated working rat hearts were perfused by a Krebs-Henseleit bicarbonate buffer containing glucose (5 mM) as basal substrate and either lactate (5 mM) or pyruvate (5 mM) as cosubstrate. In hearts perfused with glucose as sole substrate the activity of glutathione reductase was decreased by 32% during 30 min of ischaemia (p<0.10 versus control value), while the activity of superoxide dismutase and catalase was reduced by 27 and 35%, respectively, during 5 min of reperfusion (p<0.10 versus control value). The GSH level in the glucose group was reduced by 29% following 30 min of ischaemia and 35 min of reperfusion (p<0.10). In lactate- and pyruvateperfused hearts there were no significant decreases of superoxide dismutase, catalase, glutathione peroxidase and glutathione reductase activity during 30 min of ischaemia, 5 min of reperfusion or 35 min of reperfusion. In pyruvate-perfused hearts the glutathione peroxidase activity was even increased by 43% during 30 min of ischaemia (p<0.05). Glutathione levels (reduced and oxidized) did not markedly change in the lactate and pyruvate groups. Thus, the endogenous defense mechanism against oxygen-derived free radicals is compromised at the onset of reperfusion when glucose as sole substrate is present, while addition of lactate or pyruvate prevents reduction of the endogenous capacity to scavenge oxygen-derived free radicals. The equivocal relationship between endogenous scavenging enzyme activity and haemodynamic recovery indicates that involvement of the endogenous antioxidants, if any, in functional recovery of the post-ischaemic heart is complex. Pyruvate may exert protective effects on mechanical function after mild ischaemia by functioning as exogenous scavenger in itself, as pyruvate is able to react with hydrogen peroxide.     

Role of xanthine oxidase inhibitor as free radical scavenger: a novel mechanism of action of allopurinol and oxypurinol in myocardial salvage

Xanthine oxidase (XO) has been hypothesized to be a potential source of oxygen-derived free radicals during reperfusion of ischemic myocardium based on the fact that allopurinol, a XO-inhibitor, can reduce reperfusion injury. In this communication we report that both allopurinol and oxypurinol, the principle metabolite of allopurinol, prevent the reperfusion injury in isolated pig heart. However, we found that neither pig heart nor pig blood contain any XO activity. Our study showed a direct free radical scavenging action of these XO-inhibitors during ischemia and reperfusion, as judged by the reduction of free radical signals when compared using an Electron Paramagnetic Resonance Spectrometer. Using a Luminometer, we also confirmed that both allopurinol and oxypurinol can scavenge ClO2, HOCl, and significantly inhibit free radical signals generated by activated neutrophils. These XO-inhibitors, however, failed to scavenge O2. and OH. radicals. Our results suggest that these XO-inhibitors salvaged the ischemic-reperfused myocardium by scavenging free radicals, and not by inhibiting XO in the pig heart.     

Enzyme release and mitochondrial activity in reoxygenated cardiac muscle: relationship with oxygen-induced lipid peroxidation

The aim of this work was to precisely determine the sites of the peroxidative action on unsatured lipids by oxygen-derived free radicals and the lytic cell damage on reoxygenated perfused hearts. The cellular load of lipid peroxidation products (malondialdehyde) during the reoxygenation was dependent on PO2. This unfavorable biochemical response was linked to creatine kinase leakage, alteration of coronary flow and mitochondrial injury. When an enzymatic (superoxide dismutase, 290 IU/minute) or tripeptide scavenger of oxygen radicals (reduced glutathione, 0.5 mmol/l) was administered at the end of hypoxia and during reoxygenation, the abnormal intolerance of hypoxic heart to molecular oxygen was significantly weakened; the load of lipid peroxides load, enzyme release, and vascular alteration were all reduced. Moreover, mitochondrial activity was enhanced and the oxygen-induced uncoupling of mitochondrial remained limited: both the respiratory control ratio (RCR) and the ADP/O ratio were higher than in control reoxygenated hearts. The inhibition by rotenone (100 mumol/l) of reoxidation of electron chain transfer during oxygen readmission also reduced the unfavorable cardiac accumulation of lipid peroxidation products and the release of creatine kinase. These data demonstrate that in the oxygen paradox, the peroxidative attack on lipids plays an important role in inducing alterations of sarcolemmal permeability and mitochondrial activity. An uncontrolled reactivation of oxidative function of mitochondria during reoxygenation enhances the synthesis of oxygen-derived free radicals and triggers the peroxidation of cardiac lipids resulting in irreversible injury to cellular and intracellular membranes.     

Effect of ischemia/reperfusion sequence on cytosolic iron status and its release in the coronary effluent in isolated rat hearts

The hypothesis that oxygen-derived free radicals play an important role in myocardial ischemic and reperfusion injury has received a lot of support. In the presence of catalytic amounts of transition metals such as iron, superoxide anions, and hydrogen peroxide can be transformed into a highly reactive hydroxyl radical °OH (Haber-Weiss reaction). In view of this, we have undertaken this study to investigate whether iron is involved in the reperfusion syndrome and therefore could aggravate free radicals injury. Coronary effluent iron concentrations and cardiac cytosolic iron levels were evaluated in rat hearts subjected to an ischemia/reperfusion sequences. In the case of total ischemia, iron concentration in coronary effluents peaked immediately in the first sample collected upon reperfusion. However, in the case of partial ischemia, iron concentration in coronary effluents peaked rather exclusively during ischemia period. Cardiac cytosolic iron level augmented significantly after 30 min of total ischemia and non significantly in the other ischemia protocols compared to perfused control hearts. It also appears that the iron released is not protein-bound, and could therefore have a marked catalytic activity. The results of the present study suggest that in the oxygen paradox, iron plays an important role in inducing alterations during reoxygenation.     

血管内皮舒张因子在氧自由基所致慢性缺氧大鼠肺内动...

The role of endothelium-derived relaxing factor (EDRF) on the effect of oxygen-derived free radicals (generated by xanthine-xanthine oxidase system) on intrapulmonary arterial in chronic hypoxic rats was studied by a microbioassay method. Intrapulmonary artery rings with intact or denuded endothelium of hypoxic (5,000 m, 10 days) and normoxic rats were prepared for observation of oxygen-derived free radicals induced contraction. It was shown that oxygen-derived free radicals induced contractions of intrapulmonary arterial rings with intact endothelium were obviously augmented in hypoxic rats than in normoxic controls. The augmented responses could be further potentiated by the addition of EDRF inactivator reduced hemoglobin (RHb), but diminished or even abolished by applying superoxide dismutase (Cu-Zn SOD). However, no effect on denuded rings was observed when RHb or SOD was added. It is concluded that chronic hypoxia may attenuate the action of EDRF in the enhancement of the reactivity of intrapulmonary artery to oxygen-derived free radicals.     

Myocardial Tissue Preparation for ESR Spectroscopy: Some Methods May Cause Artifactual Generation of Signals

It has been suggested that some techniques of tissue preparation for esr spectroscopy may artifactually generate radicals. We have investigated this, together with the possibility that the susceptibility of the tissue to preparation artifacts may be altered by ischaemia and reperfusion. Three different methods of tissue processing have been assessed: (i) freeze-clamping (- 196 °C), using grooved, aluminium tongs which produce frozen cylinders of tissue (3 mm diameter) which fit directly into esr tubes; (ii) grinding of freeze-clamped tissue with a porcelain pestle and mortar; (iii) lyophilisation of ground, freeze-clamped, tissue. Isolated rat hearts (n = 7 or n = 5/group) were subjected to aerobic perfusion (10 min, 37 °C), total, global ischaemia (15 min) and reperfusion (30 sec). Hearts were freeze-clamped at the end of each period. Tissue was prepared by each of the three methods and esr spectra recorded at - 100 °C. In spectra from tissue which had been freeze-clamped only, broad high- and low-spin iron III signals (g = 1.9, g = 2.2-2.9 and g = 4.6) were seen together with a narrow, well-defined signal (g = 2.005), possibly from a semiquinone radical. In spectra from ground samples, an anisotropic signal (g_∥ = 2.040 and g_⊥ = 2.008), probably from a peroxyl radical, was observed in addition to the iron III signals. The intensity of the anisotropic signal varied with perfusion conditions; in ischaemic tissue it was decreased to 33 ± 10% of the control value and in reperfused tissue it was decreased to 76 ± 26%. In spectra from lyophilised samples, a narrow signal (g = 2.009), probably from a protein radical, was observed in addition to the iron III signals. The intensity of the signal at g = 2.009 was increased in ischaemic tissue to 170 ± 57% of the control value and in reperfused tissue to 241 ± 85%. In conclusion, artifactual generation of radicals can occur upon grinding (peroxyl radical) and lyophilisation (protein radical). Ischaemia and reperfusion may alter not only radical content per se but may also modify the susceptibility of the tissue to the artifactual production of radicals.     

Oxygen-derived free radicals and 'stunned myocardium'

A brief, transient period of coronary artery occlusion (less than 20 minutes in duration) followed by reperfusion does not result in irreversible myocyte injury or death, yet the regional contractile function and high energy phosphate content of the previously ischemic tissue remains depressed or 'stunned' for hours to days following reperfusion. It has been suggested that this prolonged postischemic dysfunction of viable, previously ischemic myocardium may be a consequence of oxygen-derived free radicals generated during occlusion or at the time of reperfusion. Recent evidence demonstrates that free radical scavenging agents such as superoxide dismutase (SOD) + catalase, N-2-mercaptopropionylglycine, and allopurinol, administered prior to coronary artery occlusion, significantly enhance recovery of regional contractile function of the stunned, previously ischemic tissue. This improved contractile function was not, however, accompanied by improvements in high energy phosphate metabolism: infusion of SOD + catalase did not preserve ATP stores in the previously ischemic tissue. These data support the hypothesis that oxygen-derived free radicals contribute, at least in part, to the phenomenon of the stunned myocardium. The source or mechanisms of free radical production in the setting of brief, transient ischemia, however, remains to be elucidated.     

Time window of nitroxide effect on myocardial ischemic-reperfusion injury potentiated by iron

Transition metals such as iron and copper potentiate the postischemic reperfusion (I/R) injury induced by oxygen-derived radical and nonradical toxic species (ROS). Various natural and synthetic antioxidants have been previously tested to ameliorate such injury, yet the limitations of the common antioxidants are well known. An alternative strategy for combating oxidative damage is presented wherein cell-permeable, nitroxide stable radicals, which act as SOD-mimics and oxidize reduced metals thus prompting the Fenton-like chemistry, are investigated for utility in ameliorating I/R injury. Our study concentrates on the early effect of nitroxide on the myocardial I/R injury. Isolated rat hearts in the Langendorff configuration were equilibrated with Krebs-Henseleit buffer and then subjected to 18 min of normothermic global ischemia followed by 20 min reperfusion. Iron administered as Fe(III)-citrate (10 microM) did not affect the cardiac function under normoxia but did potentiate I/R injury and decreased the recovery during reperfusion. The iron-induced damage was manifested by further deterioration of the cardiac hemodynamic function and the energy status as reflected by decreased tissue level of phosphorylated nucleotides. Nitroxide at 200 microM protected against the iron-potentiated I/R injury by improving the recovery of the hemodynamic function and the cardiac energy status. Exogenously added iron requires bioreduction to form deleterious Fe(II) bound to critical cellular sites. The nitroxide, which enters the cell and oxidizes the reduced metal instantaneously, provided protection even when administered 2 or 3.5, but not 5 min, after the onset of reperfusion. Thus, its narrow therapeutic time window provides insight into the schedule of the I/R injurious process.     

Identification of free radicals in myocardial ischemia/reperfusion by spin trapping with nitrone DMPO

The spin trapping ESR technique was applied to investigate oxygen-derived radicals in ischemic and post-ischemic rat hearts. Using 5,5'-dimethyl-l-pyrroline-N-oxide, carbon-centered radicals were identified during ischemia and oxy-radical adducts (superoxide anion radical, O.-2 and hydroxyl radicals, .OH) in post-ischemic rat heart. The formation of these spin adducts was inhibited by superoxide dismutase, suggesting that superoxide plays a role in the adducts' formation. The results demonstrate that oxygen derived free radicals are important byproducts of abnormal oxidative metabolism during myocardial ischemic and reperfusion injuries.     

Magnesium-deficiency potentiates free radical production associated with postischemic injury to rat hearts: Vitamin E affords protection

Preexisting magnesium deficiency may alter the susceptibility of rat hearts to postischemic oxidative injury (free radicals). This was examined in rats maintained for 3 weeks on a magnesium-deficient (Mg-D) diet with or without concurrent vitamin E treatment (1.2 mg/day, SC). Magnesium-sufficient (Mg-S) rats received the same diet supplemented with 100 mmol Mg/kg feed. Following sacrifice, isolated working hearts were subjected to 30-, 40-, or 60-min global ischemia and 30-min reperfusion. Postischemic production of free radicals was monitored using electron spin resonance (ESR) spectroscopy and spin trapping with -phenyl-N-tert butylnitrone (PBN, 3 mM final); preischemic and postischemic effluent samples were collected and then extracted with toluene. PBN/alkoxyl adduct(s) (PBN/RO·; _H = 1.93 G,_N = 13.63 G) were the dominant signals detected in untreated Mg-S and Mg-D postischemic hearts, with comparably higher signal intensities observed for the Mg-D group following any ischemic duration. Time courses of postischemic PBN/RO· detection were biphasic for both groups (maxima: 2–4 and 8.5–12.5 min), and linear relationships between the extent of PBN/RO· production and the severity of both mechanical dysfunction and tissue injury were determined. Following each duration of ischemia, Mg-D hearts displayed greater levels of total PBN adduct production (1.7 –2.0 times higher) and lower recovery of cardiac function (42–48% less) than Mg-S hearts. Pretreating Mg-D rats with vitamin E prior to imposing 40-min ischemia/reperfusion, led to a 49% reduction in total PBN/RO· production, a 55% lower LDH release and a 2.2-fold improvement in functional recovery, compared to untreated Mg-D hearts. These data suggest that magnesium deficiency predisposes postischemic hearts to enhanced oxidative injury and functional loss, and that antioxidants may offer significant protection against pro-oxidant influence(s) of magnesium deficiency.     

Reperfusion-induced arrhythmias are not prevented by uric acid in the isolated rat heart

Oxygen-derived free radicals have been implicated in ventricular arrhythmogenesis during coronary reperfusion following an acute ischemic event. We have investigated the possibility that uric acid, a potentially important physiological antioxidant (inhibits lipid peroxidation and scavenges various radical species during oxidation to allantoin), or oxonic acid (inhibitor of uricase enzyme), are able to prevent reperfusion-induced ventricular dysrhythmias in isolated buffer-perfused rat hearts. Rat hearts (n = 12/group) underwent 15 minutes occlusion; arrhythmias were monitored during ischemia and for 10 minutes of reperfusion. There was no difference in the incidence of ventricular fibrillation or ventricular tachycardia in either uric acid or oxonic acid treated hearts compared to untreated controls. Mean duration of ventricular fibrillation appeared to be reduced in hearts treated with 10(-3) and 10(-4) M oxonic acid compared to controls but these data did not achieve a level of statistical significance. These results demonstrate that uric acid and oxonic acid failed to prevent reperfusion-mediated ventricular dysrhythmias in this experimental preparation. Although oxygen-derived free radicals may contribute to the initiation of either ischemia- or reperfusion-induced arrhythmogenesis, our findings provide little support for this hypothesis.     

Ischemic preconditioning preserves proton leakage from mitochondrial membranes but not oxidative phosphorylation during heart reperfusion

The aim of this study was to evaluate the role of mitochondria in the recovery of cardiac energetics induced by ischaemic preconditioning at reperfusion. Isolated rat hearts were aerobically perfused (control), subjected to global ischaemia and reperfusion (reperfusion), or subjected to 3 brief cycles of ischaemia/reperfusion and then to the protocol of reperfusion (preconditioning). At the end of the perfusion, antimycin A was delivered to the heart for 25 min, to inhibit mitochondrial respiration and stimulate glycolysis. The increased amount of lactate released in the coronary effluent was correlated with the number of viable cells producing this end-product of glycolysis. Preconditioned hearts released 18% more lactate than reperfused hearts (p < 0.05). This result indicates that preconditioning partially preserved cell viability, as was also evidenced by the MTT assay performed on cardiac biopsies. The difference between antimycin A-stimulated and basal lactate concentration, representing the contribution of mitochondria to the overall energetics of cardiac tissue, was also 18% more elevated in the preconditioned hearts than in the reperfused hearts (p < 0.01). The study of the respiratory function of mitochondria isolated at the end of perfusion, showed that preconditioning did not improve the oxygen-dependent production of ATP (state 3 respiration, ADP/O). On the contrary, state 4 respiration, which is related to proton leakage, was 35.0% lower in the preconditioned group than reperfusion group (p < 0.05). Thus, preconditioning ameliorates cardiac energetics by preserving cell death, but without affecting mitochondrial oxidative phosphorylation. Mitochondria can contribute to cell survival by the attenuation of proton leak from inner membrane.     

血管内皮舒张因子在氧自由基所致慢性缺氧大鼠肺内动脉收缩中的作用

以黄嘌岭(X)-黄嘌呤氧化酶(XO)系统产生氧自由基,应用微量生物测定法观察慢性缺氧(5000m,10d)对大鼠氧自由基所致肺内动脉收缩的影响及内皮舒张因子(EDRF)在其中的作用。慢性缺氧大鼠有内皮的肺内动脉环对氧自由基的收缩反应较正常环境中的对照动物明显增强,加入EDRF灭活剂还原型血红蛋白(RHb)后更加显著;而加入超氧化物歧化酶(铜锌SOD)后则减弱,甚至消除。反之,不论加入RHb或SOD对氧自由基所致去内皮肺内动脉环的收缩反应均无明显影响。上述结果表明慢性缺氧引起肺内动脉收缩增强与EDRF有密切关系:慢性缺氧可能使EDRF的作用减弱,肺内动脉对氧自由基的反应性增强。表示EDRF及其与氧自由基的关系在慢性缺氧性肺动脉高压的形成中可能具有十分重要的意义。     

Tumor necrosis factor-alpha pretreatment is protective in a rat model of myocardial ischemia-reperfusion injury.

We have demonstrated that tumor necrosis factor-alpha (TNF-alpha) pretreatment protected the rat heart from ischemia-reperfusion injury. This effect was monitored by assaying for lactate dehydrogenase (LDH), an enzyme whose release correlates with loss of cell membrane integrity. Intact hearts removed from rats pretreated with TNF-released significantly lower amounts of LDH compared to control hearts after 20 min. of total global ischemia followed by reperfusion. Hearts from TNF-alpha-pretreated animals contained higher levels of manganous superoxide dismutase (MnSOD) mRNA than hearts from untreated rats. Because oxygen free radicals have been implicated as a major cause of reperfusion damage and the function of MnSOD is to detoxify superoxide anions in the mitochondria, a possible protective mechanism for TNF-alpha may be to induce expression of MnSOD in the heart and thus confer resistance to oxygen free radicals generated during reperfusion.     

Oxygen-derived free radicals and hemolysis during open heart surgery

Reperfusion injury occurs during open-heart surgery after prolonged cardioplegic arrest. Cardiopulmonary bypass also is known to cause hemolysis. Since reperfusion of ischemic myocardium is associated with the generation of oxygen free radicals, and since free radicals can attack a protein molecule, it seems reasonable to assume that hemolysis might be the consequence of free radical attack on hemoglobin protein. The results of this study demonstrated that reperfusion following ischemic arrest caused an increase in free hemoglobin and free heme concentrations, simultaneously releasing free iron and generating hydroxyl radicals. In vitro studies using pure hemoglobin indicated that superoxide anion generated by the action of xanthine oxidase on xanthine could release iron from the heme ring and cause deoxygenation of oxyhemoglobin into ferrihemoglobin. This study further demonstrated that before the release of iron from the heme nucleus, oxyhemoglobin underwent deoxygenation to ferrihemoglobin. The released iron can catalyze the Fenton reaction, leading to the formation of cytotoxic hydroxyl radical (OH·). In fact, the formation of OH. in conjunction with hemolysis occurs during cardiac surgery, and when viewed in the light of the in vitro results, it seems likely that oxygen-derived free radicals may cause hemolysis during cardiopulmonary bypass and simultaneously release iron from the heme ring, which can catalyze the formation of OH·.     

Lipid peroxidation and alterations to oxidative metabolism in mitochondria isolated from rat heart subjected to ischemia and reperfusion.

Ischemia-reperfusion injury to cardiac myocytes involves membrane damage mediated by oxygen free radicals. Lipid peroxidation is considered a major mechanism of oxygen free radical toxicity in reperfused heart. Mitochondrial respiration is an important source of these reactive oxygen species and hence a potential contributor to reperfusion injury. We have examined the effects of ischemia (30 min) and ischemia followed by reperfusion (15 min) of rat hearts, on the kinetic parameters of cytochrome c oxidase, on the respiratory activities and on the phospholipid composition in isolated mitochondria. Mitochondrial content of malonyldialdheyde (MDA), an index of lipid peroxidation, was also measured. Reperfusion was accompanied by a significant increase in MDA production. Mitochondrial preparations from control, ischemic and reperfused rat heart had equivalent Km values for cytochrome c, although the maximal activity of the oxidase was 25 and 51% less in ischemic and reperfused mitochondria than that of controls. These changes in the cytochrome c oxidase activity were associated to parallel changes in state 3 mitochondrial respiration. The cytochrome aa3 content was practically the same in these three types of mitochondria. Alterations were found in the mitochondrial content of the major phospholipid classes, the most pronounced change occurring in the cardiolipin, the level that decreased by 28 and by 50% as function of ischemia and reperfusion, respectively. The lower cytochrome c oxidase activity in mitochondria from reperfused rat hearts could be almost completely restored to the level of control hearts by exogenously added cardiolipin, but not by other phospholipids nor by peroxidized cardiolipin. It is proposed that the reperfusion-induced decline in the mitochondrial cytochrome c oxidase activity can be ascribed, at least in part, to a loss of cardiolipin content, due to peroxidative attack of its unsaturated fatty acids by oxygen free radicals. These findings may provide an explanation for some of the factors that lead to myocardial reperfusion injury.     

EPR study of flavo- and ubisemiquinones in liver tissue

Several types of flavins and quinones having different parameters of magnetic relaxation have been detected in the mouse liver tissue by means EPR technique. The values of these parameters depend on the redox state of the respiratory chain meal-containing centres. This means that there is an interaction between the free radicals and the metal-containing paramagnetic centres.     

Evidence of direct toxic effects of free radicals on the myocardium

The hypothesis that oxygen-derived free radicals do indeed play a role in myocardial ischemic and reperfusion injury has received a lot of support. Experimental results have shown that free radical scavengers can protect against certain aspects of myocardial ischemic injury and that on reperfusion the heart approaches a level that is more normal than those hearts not receiving additional scavenging agents. Superoxide dismutase, catalase, glutathione peroxidase, hydroxyl radical scavengers and iron chelators such as desferrioxamine have proven successful in providing an increased level of recovery. These results indicate, as would be expected, that superoxide, hydrogen peroxide and hydroxyl radicals may all, at some point, either contribute to the injury or be important in generating a subsequent radical which causes damage. In addition, solutions capable of generating free radicals have been shown to cause damage to myocardial cells and the vascular endothelium that is similar to the damage observed during myocardial ischemic and reperfusion injury. Alterations in function, structure, flow, and membrane biochemistry have been documented and compared to ischemic injury. The continued investigation of the role of free radicals in ischemic injury is warranted in the hope of further elucidating the mechanisms involved in free radical injury, the sources of their generation, and in defining a treatment that will provide significant protection against this particular aspect of ischemic damage.     

Mechanism of calcium potentiation of oxygen free radical injury to renal mitochondria. A model for post-ischemic and toxic mitochondrial damage

With a variety of forms of ischemic and toxic tissue injury, cellular accumulation of Ca2+ and generation of oxygen free radicals may have adverse effects upon cellular and, in particular, mitochondrial membranes. Damage to mitochondria, resulting in impaired ATP synthesis and diminished activity of cellular energy-dependent processes, could contribute to cell death. In order to model, in vitro, conditions present post-ischemia or during toxin exposure, the interactions between Ca2+ and oxygen free radicals on isolated renal mitochondria were characterized. The oxygen free radicals were generated by hypoxanthine and xanthine oxidase to simulate in vitro one of the sources of oxygen free radicals in the early post-ischemic period in vivo. With site I substrates, pyruvate and malate, Ca2+ pretreatment, followed by exposure to oxygen free radicals, resulted in an inhibition of electron transport chain function and complete uncoupling of oxidative phosphorylation. These effects were partially mitigated by dibucaine, a phospholipase A2 inhibitor. With the site II substrate, succinate, the electron transport chain defect was not manifest and respiration remained partially coupled. The electron transport chain defect produced by Ca2+ and oxygen free radicals was localized to NADH CoQ reductase. Calcium and oxygen free radicals reduced mitochondrial ATPase activity by 55% and adenine nucleotide translocase activity by 65%. By contrast oxygen free radicals alone reduced ATPase activity by 32% and had no deleterious effects on translocase activity. Dibucaine partially prevented the Ca2+-dependent reduction in ATPase activity and totally prevented the Ca2+-dependent translocase damage observed in the presence of oxygen free radicals. These findings indicate that calcium potentiates oxygen free radical injury to mitochondria. The Ca2+-induced potentiation of oxygen free radical injury likely is due in part to activation of phospholipase A2. This detrimental interaction associated with Ca2+ uptake by mitochondria and exposure of the mitochondria to oxygen free radicals may explain the enhanced cellular injury observed during post-ischemic reperfusion.     

Increased susceptibility to lipid peroxidation in rabbit kidneys: a consequence of warm ischaemia and subsequent reperfusion

Rabbit kidneys were clamped and rendered warm ischaemic (WI) in situ for 60 and 120 min. They were then either removed immediately after the ischaemic insult or after reperfusion with blood for 60 min or 24 hr. Homogenates were assayed for phospholipid-Schiff base fluorescence (Ex. 360 nm, Em. 435 nm) and for diene conjugate formation by u.v. spectrophotometry (240 nm) as indices of lipid peroxidation. No alteration in tissue levels of Schiff base was evident immediately after WI but when the homogenates were incubated at 37 degrees C for 90 min, the rate of peroxidation was significantly elevated compared to controls (P less than 0.02 after WI of 60 min and P less than 0.001 after 120 min of WI). These values were still further elevated after reperfusion with blood for 60 min and 24 hr (P less than 0.001). Diene conjugates were raised after WI alone and further still after reperfusion. Thus an early index of lipid peroxidation (diene conjugation) suggested peroxidative damage during the warm ischaemic period itself, whilst detection of Schiff bases was only possible after in vitro incubation of the tissue. Both indices of oxygen-derived free radical damage were increased after reperfusion in vivo with blood and may relate to the degree of tissue damage sustained during ischaemia and reflow.