Intermittent Anoxia Reduces Oxygen Free Radicals Formation During Reoxygenation in Rat Hepatocytes

The sensitivity of liver cells to anoxia is a major problem afflicting liver preservation and transplantation. Intermittent ischemia has been proposed to reduce reperfusion injury. The aim of the study was to assess oxygen free radical formation and cell injury during continuous or intermittent anoxia/reoxygenation in rat hepatocytes. Anion superoxide was measured by lucigenin-enhanced chemiluminescence and cell damage by LDH release and trypan blue uptake. During anoxia, superoxide generation dropped to background level in both groups; trypan blue uptake and LDH release, which increased progressively, were significantly greater in hepatocytes exposed to continuous compared to intermittent anoxia. During reoxygenation, a massive generation of superoxide anion formation, followed by a sharp increase in LDH release, was observed in both groups. However, both oxyradical generation and cell injury were significantly greater in cells exposed to continuous compared to intermittent anoxia. The data, showing that intermittent oxygen deprivation reduce liver cell injury and oxygen free radical formation determined by anoxia/reoxygenation, suggest a novel possible approach to the reduction of reperfusion injury.     

Sediment Core Sectioning and Extraction of Pore Waters under Anoxic Conditions

We demonstrate a method for sectioning sediment cores and extracting pore waters while maintaining oxygen-free conditions. A simple, inexpensive system is built and can be transported to a temporary work space close to field sampling site(s) to facilitate rapid analysis. Cores are extruded into a portable glove bag, where they are sectioned and each 1-3 cm thick section (depending on core diameter) is sealed into 50 ml centrifuge tubes. Pore waters are separated with centrifugation outside of the glove bag and then returned to the glove bag for separation from the sediment. These extracted pore water samples can be analyzed immediately. Immediate analyses of redox sensitive species, such as sulfide, iron speciation, and arsenic speciation indicate that oxidation of pore waters is minimal; some samples show approximately 100% of the reduced species, e.g. 100% Fe(II) with no detectable Fe(III). Both sediment and pore water samples can be preserved to maintain chemical species for further analysis upon return to the laboratory.     

Effects of flooding under hydrostatic pressure on the respiratory metabolism of germinated wheat seeds

Germinated wheat seeds ( Triticum aestivum L. cv. Barqai) that had been subjected to short hydrostatic pressure treatments (0.3–1.2 MPa) changed their normal metabolism into one which is characterized by a high ethanol production, a low O₂ consumption and a low CO₂ evolution. Alcoholic fermentation could account for ca half of the CO₂ evolved from the pressurized seeds. The level of acetaldehyde was low, though significantly higher in the pressurized seeds than in the controls. Subjection of wheat seeds to osmotic stress under aerobic conditions lowered their O₂ uptake and CO₂ evolution but did not induce ethanol production. Exposure of pressurized seeds to NaCl stress did not alter their ethanol production beyond that which had been induced by pressure. Ethanol production by pressurized seeds increased following either the addition of sucrose or by excision of the embryos from the endosperms. More electrolytes leaked into the embedding solution from pressurized seeds than from control seeds. Exogenous ethanol was toxic to wheat seeds at concentrations as low as 343 m M . The effects of hydrostatic pressure and of the consequently induced ethanol production on the mortality of flooded seeds is discussed.     

Expression of alcohol dehydrogenase in rice embryos under anoxia

Summary Alcohol dehydrogenase (ADH) activity was present in roots and shoots of 48-h rice embryos and rose in response to anoxia. The increase was accompanied by changes in the ADH isozyme pattern. Translatable levels of mRNA for two ADH peptides increases as early as 1 h after the beginning of anoxic treatment. Adh mRNA was detected in aerobically grown rice embryos by hybridization to maize Adh1 cDNA: its level increased significantly after 3 h of anoxia.     

The distribution and abundance of benthic cyclopoid copepods in Esthwaite Water,Cumbria

The spatial and temporal distribution of the benthic cyclopoid copepods, Acanthocyclops viridis, Acanthocyclops bicuspidatus, Eucyclops agilis, Paracyclops fimbriatus and Macrocyclops albidus in a small eutrophic lake Esthwaite Water, Cumbria was investigated in 1982 and 1983. The behavioural and physiological mechanisms by which these organisms cope with the conditions of hypoxia and anoxia prevalent during seasonal stratification of the lake waters was considered. During stratification all of these species, with the exception of resting stage A. bicuspidatus, disappeared from the profundal zone and were limited to the shallower margins of the lake. None of these copepod species entered the plankton and established planktonic populations, none appeared capable of sustained anaerobic respiration, although all can withstand some degree of hypoxia, and only A. bicuspidatus appeared capable of entering resting stages. The data suggest that in eutrophic lakes species normally found in the profundus deal with anoxia by lateral migration to shallow waters where oxygen is available.     

CHO cell responses to low oxygen: regulation of oxygen consumption and sensitization to oxidative stress

We have investigated the regulation of oxygen consumption and modulation of glutathione levels in CHO-K1 cells under oxygen-limiting conditions. We report here suppression of oxygen consumption and alteration of the supply-dependent relationship as a consequence of prolonged hypoxic or anoxic exposure. The suppression is characterized by an increase in the value of P(o(2)/50) (the oxygen tension at which oxygen consumption is half maximal). Under prolonged anoxia there is also a decrease in the cells' potential to use oxygen. Elevated glucose consumption under low oxygen conditions may contribute to the suppression in respiration. The glutathione concentration remains constant throughout hypoxic exposure but may decrease by as much as 40% under anoxia. The glutathione level in hypoxic and anoxic cells increases by two- and four-fold, respectively, over that of the control cells when exposed to a cytotoxic level of oxygen (93%). This suggests that anoxic and hypoxic exposure sensitizes CHO cells to oxidative stress. (c) 1992 John Wiley & Sons, Inc.     

Chroman amide and nicotinyl amide derivatives: Inhibition of lipid peroxidation and protection against head trauma

A series of chroman amide and nicotinyl amide derivatives was designed and synthesized for the treatment of traumatic and ischemic CNS injury. Five compounds were significantly more potent inhibitors of lipid peroxidation in vitro than the reference antioxidant, trolox (p < 0.01). Quantitative structure activity studies demonstrated that the inhibitory action was related to the ability to donate electrons, charge on hydroxy group and E_LUMO, to scavenging radicals and to the lipophilicity log P, which determines penetration of membrane lipids. ESR study indicated the ability of 12 to scavenge the hydroxyl radicals. The most promising compound, [(3,4-dihydro-6-hydroxy-2,5,7,8-tetramethyl-2H-1-benzopyran-2yl)carbonyl]-3′-(aminoethyl) indole (12), inhibited ex vivo lipid peroxidation in a head injury model and showed potent in vivo neuroprotective efficacy. Improvement of neurological recovery within 1 h of injury (grip test score) by as much as 200% was observed together with significant anti-anoxia activity. Compound 12 was a potent antagonist of methamphetamine-induced hypermotility resulting from dopamine release in the mouse brain. These results support the importance of cerebroprotective radical-scavenging agents for the treatment of traumatic injury and anoxia as well as provide additional evidence for the role of oxygen radicals and dopamine in brain damage.     

Near anoxia and sulfide as possible factors influencing the spatial distribution of Acartia tonsa and Acartia clausi: Comparative evaluation of egg tolerance

In many coastal and estuarine areas the planktonic copepods Acartia tonsa and Acartia clausi show a spatial separation with A. tonsa restricted to brackish waters and confined environments and A. clausi inhabiting areas more influenced by sea water. The hatching and viability of A. tonsa and A. clausi eggs exposed to anoxia and anoxia/sulfide (conditions that are frequent in bottom waters of the most confined areas) was evaluated to determine if these stress factors play a role in the distribution of these species. Subitaneous eggs, spawned by laboratory reared organisms, were incubated in near anoxia (< 7.59 × 10^− 3 mmol O₂ L^− 1) or anoxia/sulfide (∼ 1 mmol L^− 1) for different periods (1, 4, 8 and 15 days), then transferred to normoxic conditions. The exposure of the eggs to near anoxia and sulfide appears to induce the same response (quiescence) in both species. Exposure times ≤ 8 days to near anoxia or anoxia/sulfide did not affect egg viability, while 15 day exposure caused significant declines in hatching success of both species. A significant difference between the effects of near anoxia and anoxia/sulfide was observed when incubation lasted 15 days; hatching of eggs exposed to sulfide being higher than that of eggs exposed to near anoxia for both species. No significant differences were observed between the two species in hatching success of eggs exposed to both near anoxia and anoxia/sulfide (with the exception of eggs incubated in near anoxia for 4 days). The results indicate that the impact of anoxia and sulfide on the eggs of the two Acartia species cannot be a factor explaining the spatial distribution in coastal and brackish environments of these copepods.Feeding experiments on A. clausi were also performed. Suitability of different algal species to rear this copepod was evaluated and the results were compared with data previously obtained for A. tonsa. Differences in feeding needs between A. clausi and A. tonsa are discussed.     

Brief antecedent anoxia preserves mitochondrial function after sustained undersupply: A subcellular correlate to ischemic preconditioning?

Background: There is increasing evidence that mitochondria – owning a high degree of autonomy within the cell – might represent the target organelles of the myocardial protection afforded by ischemic preconditioning. It was the aim of the study to investigate a possible subcellular correlate to ischemic preconditioning at the mitochondrial level. In addition, we tested whether this protection depends on mitochondrial ATP-dependent potassium channels (K _ATP) and an might involve an attenuation of mitochondrial ATP hydrolysis during sustained anoxia.Methods and Results: Sustained anoxia (A, 14 min) and reoxygenation (R) completely inhibited state 3 and state 4 respiration of isolated ventricular mitochondria from Wistar rats. An antecedent brief anoxic incubation (4 min) followed by reoxygenation (2 min) prevented this loss of mitochondrial function. The protection afforded by anoxic preconditioning could be mimicked by the K _ATP opener diazoxide (30 μmol/l) and was completely inhibited by the K _ATP blocker 5-hydroxydecanoic acid (300 μmol/l). Structural mitochondrial integrity, as estimated from externalization of the mitochondrial enzymes creatine kinase and glutamateoxalacetate transaminase, remained unchanged between the groups, as did mitochondrial ATP loss during anoxia.Conclusion: For the first time, we provide direct evidence for a subcellular preconditioning-like functional mitochondrial adaptation to sustained anoxia. This effect apparently depends on opening of K_ATP but is independent of ATP preservation.