Mitochondrial damage and metabolic compensatory mechanisms induced by hyperoxia in the U-937 cell line (original) (raw)
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Mitochondrial thiol status in the liver is altered by exposure to hyperoxia
Toxicology Letters, 2001
Patients with poorly functioning lungs often require treatment with high concentrations of supplemental oxygen, which, although often necessary to sustain life, can cause lung injury. The mechanisms responsible for hyperoxic lung injury have been investigated intensely and most probably involve oxidant stress responses, but the details are not well understood. In the present studies, we exposed adult male C57/Bl6 mice to \ 95% O 2 for up to 72 h and obtained lung and liver samples for assessment of lung injury, measurements of tissue concentrations of coenzyme A (CoASH) and the corresponding mixed disulfide with glutathione (CoASSG), as possible biomarkers of intramitochondrial thiol redox status. Subcellular fractions were prepared from both tissues for determination of glutathione reductase (GR) activities. Lung injury in the hyperoxic mice was demonstrated by increases in lung weight to body weight ratios at 48 h and by increases in bronchoalveolar lavage protein concentrations at 72 h. Lung CoASH concentrations declined in the hyperoxic mice, but CoASSG concentrations were not increased nor were CoASH/CoASSG ratios decreased, as would be expected for an oxidant shift in mitochondrial thiol-disulfide status. Interestingly, CoASSG concentrations increased (from 6.72 90.54 to 14.10 9 1.10 nmol/g of liver in air-breathing controls and 72 h of hyperoxia, respectively, PB0.05), and CoASH/CoASSG ratios decreased in the livers of mice exposed to hyperoxia. Some apparent effects of duration of hyperoxia on GR activities in lung or liver cytosolic, mitochondrial, or nuclear fractions were observed, but the changes were not consistent or progressive. Yields of isolated hepatic nuclear protein were decreased in the hyperoxic mice within 24 h of exposure, and by 72 h of hyperoxia, protein recoveries in purified nuclear fractions had declined from 41.8 to 14.8 mg of protein/g animal body weight. Concentrations of 10-formyltetrahydrafolate dehydrogenase were diminished in hepatic mitochondria of hyperoxic mice. A second protein in hepatic mitochondria of : 25 kDa showed apparent decreases in thiol content, as determined by fluorescence intensities of monobromobimane derivatives separated by SDS-PAGE. The mechanisms responsible for the observed effects and the possible implications for the adverse effects of hyperoxic therapies are not known and need to be investigated.
FEBS Letters, 1989
Cells require molecular oxygen for the generation of energy through mitochondrial oxidative phosphorylation; however, high concentrations of oxygen are toxic and can cause cell death. A number of different mechanisms have been proposed to cause cellular oxygen toxicity. One hypothesis is that reactive oxygen free radicals may be generated; however free radical generation in hyperoxic cells has never been directly measured and the mechanism of this radical generation is unknown. In order to determine if cellular oxygen toxicity is free radical mediated, we applied electron paramagnetic resonance, EPR, spectroscopy using the spin trap 5,5'-dimethyl-1-pyrroline-N-oxide, DMPO, to measure free radical generation in hyperoxic pulmonary endothelial cells. Cells in air did not give rise to any detectable signal. However, cells exposed to 100% 0, for 30 min exhibited a prominent signal of trapped hydroxyl radical, DMPO-OH, while cell free buffer did not give rise to any detectable radical generation. This cellular radical generation was demonstrated to be derived from the superoxide radical since the observed signal was totally quenched by superoxide dismutase, but not by equal concentrations of the denatured enzyme. It was confirmed that the hydroxyl radical was generated since in the presence of ethanol the CH,CH(OH) radical was formed. Loss of cell viability as measured by uptake of trypan blue dye was observed paralleling the measured free radical generation. Thus, superoxide and hydroxyl radicals are generated in hyperoxic pulmonary endothelial cells and this appears to be an important mechanism of cellular oxygen toxicity. Oxygen toxicity; Free radical; Cell injury; Superoxide
Biochimica et Biophysica Acta (BBA) - Bioenergetics, 2006
HIFα prolyl hydroxylases (PHDs) are a family of enzymes that regulate protein levels of the α subunit of the hypoxia inducible transcription factor (HIF) under different oxygen levels. PHDs catalyse the conversion of a prolyl residue, molecular oxygen and α-ketoglutarate to hydroxyprolyl, carbon dioxide and succinate in a reaction dependent on ferrous iron and ascorbate as cofactors. Recently it was shown that pseudohypoxia, HIF induction under normoxic conditions, is an important feature of tumours generated as a consequence of inactivation of the mitochondrial tumour suppressor 'succinate dehydrogenase' (SDH). Two models have been proposed to describe the link between SDH inhibition and HIF activation. Both models suggest that a mitochondrial-generated signal leads to the inhibition of PHDs in the cytosol, however, the models differ in the nature of the proposed messenger. The first model postulates that mitochondrial-generated hydrogen peroxide mediates signal transduction while the second model implicates succinate as the molecular messenger which leaves the mitochondrion and inhibits PHDs in the cytosol. Here we show that pseudo-hypoxia can be observed in SDH-suppressed cells in the absence of oxidative stress and in the presence of effective antioxidant treatment.
Hypoxia and mitochondrial oxidative metabolism
Biochimica et Biophysica Acta (BBA) - Bioenergetics, 2010
It is now clear that mitochondrial defects are associated with a large variety of clinical phenotypes. This is the result of the mitochondria's central role in energy production, reactive oxygen species homeostasis, and cell death. These processes are interdependent and may occur under various stressing conditions, among which low oxygen levels (hypoxia) are certainly prominent. Cells exposed to hypoxia respond acutely with endogenous metabolites and proteins promptly regulating metabolic pathways, but if low oxygen levels are prolonged, cells activate adapting mechanisms, the master switch being the hypoxia-inducible factor 1 (HIF-1). Activation of this factor is strictly bound to the mitochondrial function, which in turn is related with the oxygen level. Therefore in hypoxia, mitochondria act as [O 2 ] sensors, convey signals to HIF-1directly or indirectly, and contribute to the cell redox potential, ion homeostasis, and energy production. Although over the last two decades cellular responses to low oxygen tension have been studied extensively, mechanisms underlying these functions are still indefinite. Here we review current knowledge of the mitochondrial role in hypoxia, focusing mainly on their role in cellular energy and reactive oxygen species homeostasis in relation with HIF-1 stabilization. In addition, we address the involvement of HIF-1 and the inhibitor protein of F 1 F 0 ATPase in the hypoxia-induced mitochondrial autophagy.
Hyperoxia-Induced Oxidative Stress
2015
Prolonged hyperoxia exposure generates excessive reactive oxygen species (ROS) and potentially leads to oxi-dative injury in every organ. We have previously generated Drosophila melanogaster flies that tolerate extreme oxidative stress (90%–95 % O2), a lethal condition to naive flies, through a long-term laboratory selection. We found that hyperoxia-selected (SO2A) flies had a significantly longer lifespan in hyperoxia and paraquat-induced oxidative stress. Prolonged hyperoxia exposure induced a significant ROS accumulation and an increased ex-pression of oxidative stress markers, including lipid peroxidation and protein carbonyl contents in control flies, but not in SO2A flies. Enzymatic assays revealed that antioxidant enzyme activity in SO2A flies was similar to that in control flies. However, in isolated mitochondria and using electron paramagnetic resonance, we observed that SO2A flies displayed a decreased superoxide yield during state 3 respiration as compared to control flie...
Methods and Protocols
Mitochondrial dysfunction and cytosolic oxidative stress are pathological biomarkers interlinked in several chronic diseases and cellular toxicity promoted by high-energy radiation or xenobiotics. Thus, assessing the activities of the mitochondrial redox chain complexes and the cytosolic antioxidant enzymes in the same cell culture system is a valuable approach to addressing the challenge of chronic diseases or unveiling the molecular mechanisms underlying the toxicity of physical and chemical stress agents. The present article gathers the experimental procedures to obtain, from isolated cells, a mitochondria-free cytosolic fraction and a mitochondria-rich fraction. Furthermore, we describe the methodologies to evaluate the activity of the main antioxidant enzymes in the mitochondria-free cytosolic fraction (superoxide dismutase, catalase, glutathione reductase and glutathione peroxidase), and the activity of the individual mitochondrial complexes I, II and IV, as well as the conjug...
BioFactors, 2004
Dichlorophenol indophenol (DCIP) reduction by intracellualr pyridine nucleotides was investigated in two different lines of cultured cells characterized by enhanced production of reacive oxygen species (ROS) with respect to suitable controls. The first line denominated XTC-UC1 was derived from a metastasis of an oxyphilic thyroid tumor characterized by mitochondrial hyperplasia and compared with a line (B-CPAP) derived from a papillary thyroid carcinoma with normal mitochondrial mass. The second line (170 MN) was a cybrid line derived from ρ 0 cells from an osteosarcoma line (143B) fused with platelets from a patient with a nucleotide 9957 mutation in mitochondrial DNA (encoding for cytochrome c oxidase subunit III) in comparison with the parent 143B line. The experimental lines had no major decreases of electron transfer activities with respect to the controls; both of them, however, exhibited an increased peroxide production. The XTC-UC1 cell line exhibited enhanced activity with respect to control of dicoumarol-sensitive DCIP reduction, identified with membrane bound DT-diaphorase, whereas dicoumarol insensitive DCIP reduction was not significantly changed. On the other hand the mtDNA mutated cybrids exhibited a strong increase of both dicoumarol sensitive and insensitive DCIP reduction. The results suggest that enhanced oxidative stress and not deficient respiratory activity per se is the stimulus triggering over-expression of plasma membrane oxidative enzymes.
Mutation Research/Fundamental and Molecular Mechanisms of Mutagenesis, 1989
Cell death by oxidative stress has been proposed to be based on suicidal NAD depletion, typically followed by ATP depletion, caused by the NAD-consuming enzyme poly(ADP)ribose polymerase, which becomes activated by the presence of excessive DNA-strand breaks. In this study NAD+, NADH and ATP levels as well as DNA-strand breaks (assayed by alkaline elution) were determined in Chinese hamster ovary (CHO) cells treated with either H2O2 or hyperoxia to a level of more than 80% clonogenic cell killing. With H2O2 extensive DNA damage and NAD depletion were observed, while at a higher H2O2 dosage ATP also became depleted. In agreement with results of others, the poly(ADP)ribose polymerase inhibitor 3-aminobenzamide completely prevented NAD depletion. However, both H2O2-induced ATP depletion and cell killing were unaffected by the inhibitor, suggesting that ATP depletion may be a more critical factor than NAD depletion in H2O2-induced killing of CHO cells. With hyperoxia, only moderate DNA damage (2 X background) and no NAD depletion were observed, whereas ATP became largely (70%) depleted. We conclude that (1) there is no direct relation between ATP and NAD depletion in CHO cells subjected to toxic doses of H2O2 or hyperoxia; (2) H2O2-induced NAD depletion is not by itself sufficient to kill CHO cells; (3) killing of CHO cells by hyperoxia is not due to NAD depletion, but may be due to depletion of ATP.