oligomycins and Ischemia

The alteration in energy metabolic products was analyzed in cultured retinal cells submitted to oxidative stress, hypoxia, glucopenia, or ischemia-like conditions. Ischemia highly reduced cellular ATP and increased AMP formation, without significant changes in ADP. Ischemia induced a significant increase in extracellular adenosine (ADO) and hypoxanthine (HYP), and to a lesser extent inosine (INO). Glucopenia reduced cellular ATP by about two- to threefold, which was not compensated for by AMP formation. Under glucopenia, extracellular ADO and HYP were significantly increased, although a major increase in extracellular INO was observed. 5-(4-Nitrobenzyl)-6-thioinosine (10 microM) reduced extracellular ADO during glucopenia or ischemia by approximately 80%, indicating that ADO accumulation occurs mainly via the transporter. Intracellular ATP, ADP, or AMP and extracellular ADO, INO, or HYP were not apparently changed after oxidative stress or hypoxia. Nevertheless, in the presence of 10 microM erythro-9-(2-hydroxy-3-nonyl)adenosine, oxidative stress was shown to increase significantly the accumulation of ADO, which was reduced in the presence of 200 microM alpha,beta-methyleneadenosine 5'-diphosphate, suggesting that ADO accumulation after oxidative stress may result from extracellular degradation of adenine nucleotides. The increase in ADO accumulation resulting from the depletion of cellular ATP was directly related to the release of endogenous glutamate occurring through a Ca2+-independent pathway after ischemia. Increased metabolic products derived from ATP are suggested to exert a modulating effect against excitotoxic neuronal death.

Topics: Adenine; Adenosine; Adenosine Diphosphate; Adenosine Monophosphate; Adenosine Triphosphate; Animals; Calcium; Cell Hypoxia; Cells, Cultured; Chick Embryo; Enzyme Inhibitors; Glucose; Hypoxanthine; Inosine; Iodoacetates; Iodoacetic Acid; Ischemia; Kinetics; Oligomycins; Oxidative Stress; Retina; Thioinosine

Topics: Adenosine Diphosphate; Animals; In Vitro Techniques; Ischemia; Kidney; Kinetics; Mitochondria; Oligomycins; Oxidative Phosphorylation; Oxygen Consumption; Rabbits; Reperfusion Injury; Time Factors; Uncoupling Agents

Intestinal ischemia is characterized by rapid early inhibition of absorptive function and the appearance of net secretion, although why active secretion persists in the setting of a mucosal energy deficit is unknown. The cryptlike epithelial line T84, a well-characterized model of intestinal Cl- secretion, develops a prominent increase in short-circuit current (Isc, indicative of active Cl- transport) in response to "hypoxia" induced by metabolic inhibitors. The increased Isc is associated with the initial decrease in monolayer ATP content. The Isc is transient and disappears with progressive energy depletion, although graded degrees of ATP depletion induce a more sustained Isc response. Chromatographic analysis and secretory bioassays show that the Isc response to metabolic inhibitors is related to the endogenous release of adenosine into the extracellular space in quantities sufficient to interact locally with stimulatory adenosine receptors. Unlike its classical role as a metabolic feedback inhibitor, adenosine appears to function as an autocrine "feed-forward" activator of active intestinal Cl- secretion. These studies suggest a novel role for adenosine in the conversion of the gut from an absorptive to a secretory organ during ischemic stress, thus contributing to the initial diarrheal manifestation of intestinal ischemia.

Topics: Adenosine; Adenosine Triphosphate; Biological Transport; Cells, Cultured; Chlorides; Deoxyglucose; Epithelium; Humans; Intestinal Mucosa; Intestines; Ischemia; Oligomycins

In an attempt to search for neuronal models to investigate the molecular pharmacology of central nervous system ischemia, we have focused on PC12 pheochromocytoma cultures which are now popular in neuroscience research. These chromaffinergic transformed cells, originary from the adrenal medulla, synthesize and release catecholamines and, upon treatment with nerve growth factor (NGF), differentiate to a sympathetic phenotype expressing neurites and excitability. To measure eicosanoid production, undifferentiated or NGF-treated PC12 cultures have been exposed for 1 h to a mixture of N2/CO2 (95:5%), resulting in hypoxia (5 +/- 1% O2), followed by 1 h reoxygenation (21% O2) using a special ischemic device. Hypoxia, up to 2 h, was not followed by significant cytotoxicity or significant production of prostaglandin PGE2. However, upon reoxygenation, a specific release of PGE2 (2-3 fold over control) was measured. A similar PGE2-enhanced release could be induced by 'chemical hypoxia' using 2-deoxyglucose and oligomycin to reduce cellular adenosine triphosphate (ATP). Anoxia (0.1-1% O2, 1 h) achieved by a reduction of culture incubation volume and the reduction in ATP level have been found as critical parameters leading to PC12 cells cytotoxicity. These results emphasize the simplicity and applicability of the tissue culture ischemic device proposed to investigate hypoxia and ischemia at a cellular level.

Topics: Adrenal Gland Neoplasms; Animals; Cell Differentiation; Cell Hypoxia; Culture Techniques; Eicosanoids; Ischemia; Models, Neurological; Nerve Growth Factors; Neurites; Neurons; Oligomycins; Oxygen; PC12 Cells; Pheochromocytoma; Rats

Toxic oxygen species have been implicated as important mediators of injury after reperfusion of an ischemic organ. The aim of this study was to determine if prior metabolic inhibition, such as that which occurs during ischemia, potentiates oxidant injury in vitro. Bovine pulmonary artery endothelial cells were metabolically inhibited for various periods of time with or without the mitochondrial inhibitor oligomycin (650 nM). The cells were rescued from metabolic inhibition by a wash step and subsequent addition of 5.5 mM glucose. At the same time that metabolic inhibition was relieved the cells were subjected to doses of H2O2 ranging from 0 to 100 microM. ATP levels were monitored over a 2-hr time course after rescue from metabolic inhibition by the luciferin-luciferase assay. Cell viability at 2 hr after relief of metabolic inhibition was assessed by trypan blue exclusion. Intracellular pH during metabolic inhibition was determined with the fluorescent dye 2',7'-bis-(2-carboxyethyl)-5(and-6) carboxyfluorescein tetraacetomethoxymethyl ester. H2O2 consumption, a measure of H2O2 scavenging capability, was determined by a fluorescent assay. The viability and ATP levels of cells not subjected to metabolic inhibition were unaffected by these low concentrations of H2O2. Cells metabolically inhibited with glucose depletion and oligomycin were exquisitely sensitive to H2O2. Cells that were only deprived of glucose demonstrated no potentiation of injury, while cells subjected to mitochondrial inhibition with oligomycin alone also showed significant potentiation of oxidant injury. H2O2 consumption was not affected by metabolic inhibition. Conditions associated with mitochondrial inhibition consistently resulted in a decrease in intracellular pH. These experiments suggest that a synergism exists between metabolic inhibition and subsequent oxidant exposure.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Adenosine Triphosphate; Animals; Cattle; Cell Survival; Endothelium, Vascular; Glucose; Hydrogen Peroxide; Hydrogen-Ion Concentration; In Vitro Techniques; Ischemia; Models, Biological; Oligomycins; Potassium Cyanide; Reperfusion Injury

The ATP synthase capacity of rat heart myocytes can be measured in sonicated cell suspensions and in sonicated preparations of cultured cardiomyocytes. This procedure allows the rapid measurement of mitochondrial function in response to changes in the metabolic status of the cell. In cultured myocytes, transitions in ATP synthase capacity (with no detectable change in cellular ATP concentration) accompany a change to anoxia or electrically stimulated contraction (rise of 70%). These changes are reversed on returning to the original conditions. Exposure of myocytes to low pH has little effect on basal ATP synthase capacity (down to values less than pH 6), but markedly affects cellular ATP levels and the response of the cells to anoxia and reoxygenation, possibly mimicking changes seen in ischaemic heart. Similar effects are seen in suspensions of freshly prepared myocytes, but these preparations are less stable and more pH-sensitive than are cells in culture. It is proposed that mitochondria in vivo are directly regulated at the level of the ATP synthase, and that a regulator protein, the naturally occurring inhibitor protein from mitochondria, may be responsible for this regulation.

Topics: Adenosine Triphosphate; Animals; Atractyloside; Cells, Cultured; Cold Temperature; Electric Stimulation; Energy Metabolism; Hydrogen-Ion Concentration; Hypoxia; In Vitro Techniques; Intracellular Membranes; Ischemia; Male; Mitochondria, Heart; Oligomycins; Ouabain; Proton-Translocating ATPases; Rats; Rats, Inbred Strains; Vanadium

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.

Topics: Animals; ATP Synthetase Complexes; Calcium; Dibucaine; Free Radicals; Ischemia; Kidney; Malates; Male; Mitochondria; Models, Biological; Multienzyme Complexes; Oligomycins; Oxygen; Oxygen Consumption; Phosphotransferases; Proton-Translocating ATPases; Pyruvates; Pyruvic Acid; Quinone Reductases; Rats; Rats, Inbred Strains

Topics: Animals; Antimetabolites; Creatinine; Cyanides; Ethacrynic Acid; Furosemide; Ischemia; Kidney; Magnesium Sulfate; Male; Oligomycins; Ouabain; Quinones; Rats; Rats, Inbred Strains; Sodium; Tissue Preservation; Tissue Survival