Characterization of oxygen-tolerant Chinese hamster ovary cells. II. Energy metabolism and antioxidant status

An in-silico study of the regulation of CHO cells glycolysis

In this work, a kinetic-metabolic model previously developed for CHO cells is used to study glycolysis regulation. The model is assessed for its biological relevance by analyzing its ability to simulate metabolic events induced following a hypoxic perturbation. Feedback and feedforward regulatory mechanisms known to occur to either inhibit or activate fluxes of glycolysis, are implemented in various combined scenarios and their effects on the metabolic response were analyzed. This study aims at characterizing the role of intermediates of glycolysis and of the cell energetic state, described as the AMP-to-ATP ratio, as inhibitors and activators of glycolysis pathway. In addition to the glycolysis pathway, we here describe the transient metabolic response of pathways that are connected to glycolysis, such as the pentose phosphate pathway, TCA cycle, cell bioenergetics system, glutamine and amino acids metabolisms. Taken individually, each regulatory mechanism leads to an oscillatory behavior in response to a hypoxic perturbation, while their combination clearly damps oscillations. However, only the addition of the cell energetic state to the regulatory mechanisms results in a non-oscillating response leading to metabolic flux rate rearrangement corresponding to the anaerobic metabolism expected to prevail under hypoxic conditions. We thus demonstrate in this work, from model simulations, that the robustness of a cell energetic metabolism can be described from a combination of feedback and feedforward inhibition and activation regulatory mechanisms of glycolysis fluxes, involving intermediates of glycolysis and the cell energetic state itself.

Hyperoxia decreases glycolytic capacity, glycolytic reserve and oxidative phosphorylation in MLE-12 cells and inhibits complex I and II function, but not complex IV in isolated mouse lung mitochondria

High levels of oxygen (hyperoxia) are frequently used in critical care units and in conditions of respiratory insufficiencies in adults, as well as in infants. However, hyperoxia has been implicated in a number of pulmonary disorders including bronchopulmonary dysplasia (BPD) and adult respiratory distress syndrome (ARDS). Hyperoxia increases the generation of reactive oxygen species (ROS) in the mitochondria that could impair the function of the mitochondrial electron transport chain. We analyzed lung mitochondrial function in hyperoxia using the XF24 analyzer (extracellular flux) and optimized the assay for lung epithelial cells and mitochondria isolated from lungs of mice. Our data show that hyperoxia decreases basal oxygen consumption rate (OCR), spare respiratory capacity, maximal respiration and ATP turnover in MLE-12 cells. There was significant decrease in glycolytic capacity and glycolytic reserve in MLE-12 cells exposed to hyperoxia. Using mitochondria isolated from lungs of mice exposed to hyperoxia or normoxia we have shown that hyperoxia decreased the basal, state 3 and state3 μ (respiration in an uncoupled state) respirations. Further, using substrate or inhibitor of a specific complex we show that the OCR via complex I and II, but not complex IV was decreased, demonstrating that complexes I and II are specific targets of hyperoxia. Further, the activities of complex I (NADH dehydrogenase, NADH-DH) and complex II (succinate dehydrogenase, SDH) were decreased in hyperoxia, but the activity of complex IV (cytochrome oxidase, COX) remains unchanged. Taken together, our study show that hyperoxia impairs glycolytic and mitochondrial energy metabolism in in tact cells, as well as in lungs of mice by selectively inactivating components of electron transport system.

A kinetic-metabolic model based on cell energetic state: study of CHO cell behavior under Na-butyrate stimulation

A kinetic-metabolic model approach describing and simulating Chinese hamster ovary (CHO) cell behavior is presented. The model includes glycolysis, pentose phosphate pathway, TCA cycle, respiratory chain, redox state and energetic metabolism. Growth kinetic is defined as a function of the major precursors for the synthesis of cell building blocks. Michaelis-Menten type kinetic is used for metabolic intermediates as well as for regulatory functions from energy shuttles (ATP/ADP) and cofactors (NAD/H and NADP/H). Model structure and parameters were first calibrated using results from bioreactor cultures of CHO cells expressing recombinant t-PA. It is shown that the model can simulate experimental data for all available experimental data, such as extracellular glucose, glutamine, lactate and ammonium concentration time profiles, as well as cell energetic state. A sensitivity analysis allowed identifying the most sensitive parameters. The model was then shown to be readily adaptable for studying the effect of sodium butyrate on CHO cells metabolism, where it was applied to the cases with sodium butyrate addition either at mid-exponential growth phase (48 h) or at the early plateau phase (74 h). In both cases, a global optimization routine was used for the simultaneous estimation of the most sensitive parameters, while the insensitive parameters were considered as constants. Finally, confidence intervals for the estimated parameters were calculated. Results presented here further substantiate our previous findings that butyrate treatment at mid-exponential phase may cause a shift in cellular metabolism toward a sustained and increased efficiency of glucose utilization channeled through the TCA cycle.

Oxidation-induced changes in human lens epithelial cells. 1. Phospholipids

Lipid compositional changes in lens epithelial cells (HLE B-3) grown in a hyperoxic atmosphere were studied to determine if oxidation could cause changes in the amount and type of phospholipid similar to those found in vivo with age and cataract. The phosphatidylcholines in HLE B-3 cells were 8 times more unsaturated than the sphingomyelins. Cell viability was the same for cells grown for up to 48 h in a normoxic or hyperoxic atmosphere. Lipid oxidation was about three times higher after growth in a hyperoxic atmosphere compared with cells grown in a normoxic atmosphere. The lack of change in the relative amount of sphingomyelin and the decrease in phosphatidylcholine coupled with the increase in lysophosphatidylcholine support the idea that similar mechanisms may be responsible for the lipid compositional changes in both lens epithelial and fiber cells. It is postulated that lipases eliminate oxidized unsaturated glycerolipids, leaving a membrane increasingly composed of more ordered and more saturated sphingolipids. Oxidative stress leads to changes in membrane composition that are consistent with those seen with age in human epithelial cells. Oxidation-induced epithelial phospholipid change is an area of research that has gone virtually unexplored in the human lens and could be relevant to all cell types and may be important to lens clarity.

Oxidation-induced changes in human lens epithelial cells 2. Mitochondria and the generation of reactive oxygen species

The relationships among reactive oxygen species (ROS) generation, lipid compositional changes, antioxidant power, and mitochondrial membrane potential were determined in a human lens epithelial cell line, HLE-B3. Cells grown in a hyperoxic atmosphere grew linearly for about 3 days, and then progressively died. Total antioxidant power and ROS generation increased by 50 and 43%, respectively, in cells grown in a hyperoxic atmosphere compared to those cultured in a normoxic atmosphere. By specifically uncoupling the mitochondrial proton gradient, we determined that the mitochondria are most likely the major source of ROS generation. ROS generation correlated inversely with mitochondrial membrane potential and the amount of cardiolipin, factors likely to contribute to loss of cell viability. Our results support the idea that hyperoxic damage to HLE-B3 cells derives from enhanced generation of ROS from the mitochondrial electron transport chain resulting in the oxidation of cardiolipin. With extended hyperoxic insult, the oxidants overwhelm the antioxidant defense system and eventually cell death ensues.

Glutamine protects mitochondrial structure and function in oxygen toxicity

Glutamine is an important mitochondrial substrate implicated in the protection of cells from oxidant injury, but the mechanisms of its action are incompletely understood. Human pulmonary epithelial-like (A549) cells were exposed to 95% O2 for 4 days in the absence and presence of glutamine. Cell proliferation in normoxia was dependent on glutamine, and glutamine deprivation markedly accelerated cell death in hyperoxia. Glutamine significantly increased cellular ATP levels in normoxia and prevented the loss of ATP in hyperoxia seen in glutamine-deprived cells. Mitochondrial membrane potential as assessed by flow cytometry with chloromethyltetramethylrosamine was increased by glutamine in hyperoxia-exposed A549 cells, and a glutamine dose-dependent increase in mitochondrial membrane potential was detected. Glutamine-supplemented, hyperoxia-exposed cells had a higher O2 consumption rate and GSH content. Electron and fluorescence microscopy revealed that, in hyperoxia, glutamine protected cellular structures, especially mitochondria, from damage. In hyperoxia, activity of the tricarboxylic acid cycle enzyme alpha-ketoglutarate dehydrogenase was partially protected by its indirect substrate, glutamine, indicating a mechanism of mitochondrial protection.

Hypoxia induces hexokinase II gene expression in human lung cell line A549

During adaptation to hypoxic and hyperoxic conditions, the genes involved in glucose metabolism are upregulated. To probe involvement of the transcription factor hypoxia-induced factor-1 (HIF-1) in hexokinase (HK) II expression in human pulmonary cells, A549 cells and small-airway epithelial cells (SAECs) were exposed to stimuli such as hypoxia, deferoxamine (DFO), and metal ions. The largest increase in HK-II (20-fold for mRNA and 2.5-fold for enzymatic activity) was observed in A549 cells when exposed to DFO. All stimuli selectively increased the 5.5-kb rather than 4-kb transcript in A549 cells. Cycloheximide and actinomycin D inhibited these responses. In addition, cells were transfected with luciferase reporter constructs driven by the full-length HK-II 5'-regulatory region (4.0 kb) or various deletions of that region. A549 cells transfected with the 4.0-kb construct and exposed to hypoxia or DFO increased their luciferase activity 7- and 10-fold, respectively, indicating that HK-II induction is, at least in part, due to increased gene transcription. Sixty percent of the inducible activity of the 4.0-kb construct was shown to reside within the proximal 0.5 kb. Additionally, cotransfection with a stable HIF-1 mutant and the 4.0-kb promoter construct resulted in increased luciferase activity under normoxic conditions. These results strongly suggest that HK-II is selectively regulated in pulmonary cells by a HIF-1-dependent mechanism.

Changes in pulmonary expression of hexokinase and glucose transporter mRNAs in rats adapted to hyperoxia

Impairment of lung aconitase activity, citric acid cycle, and mitochondrial respiration by hyperoxia necessitates the elevation of glycolysis for energy production and of pentose shunt activity for reducing equivalents. The molecular mechanisms that allow increased glucose utilization are unknown. Adult male and female rats were adapted to sublethal hyperoxia, equivalent to 83% oxygen at sea level, or air for 7 days. Lung RNA and protein increased in hyperoxia (197 and 57%, respectively), whereas total DNA was unchanged. In hyperoxia, lung total hexokinase (HK) activity increased threefold, and mRNAs for HK-II and -III were specifically upregulated. HK-I mRNA was unchanged. mRNAs for HK-II and -III gradually increased during the first 72 h in hyperoxia. HK-II mRNA was significantly elevated at 72 h, preceding changes in lung cell populations. Although virtually absent in air, HK-II activity was highly expressed in hyperoxia. Among lung glucose transporters, specific expression of mRNAs for GLUT-4 (insulin dependent) and sodium-glucose cotransporter-1 was decreased, whereas that for GLUT-1 was minimally changed. Adaptation to hyperoxia involves coordinated changes in gene expression for the proteins regulating pulmonary glucose transport.

Modulation of glutathione level in CHO cells. Effects of oxygen concentration and prior exposure to hypoxia

A microtiter-plate assay has been developed for total intracellular glutathione that facilitates multiple-sample analysis and reduces the amount of time and chemicals required. Sonication time, pH, and storage conditions were identified as key parameters that affect the accuracy of the assay. Using this assay, it was found that CHO cells increase their glutathione level under higher oxygen tension. This adaptive response suggests that a rise in glutathione may be used as an indicator of oxidative stress. Based on this criterion, it was found that hypoxic and anoxic cells are sensitized to reoxygenation. This sensitization could not be attributed to a drop in glutathione during low oxygen exposure because the glutathione content reached a basal level at a PO2 of about 40 torr.

Characterization of oxygen-resistant Chinese hamster ovary cells. III. Relative resistance of succinate and alpha-ketoglutarate dehydrogenases to hyperoxic inactivation

We have recently shown that exposure of Chinese hamster ovary (CHO) cells to a toxic dose of normobaric hyperoxia (98% O2 for 3 days) caused a disturbance of cellular energy metabolism, that is, respiratory failure followed by stimulation of glycolytic activity and a net depletion of ATP. Respiratory failure was correlated with a selective inactivation of three mitochondrial enzymes, that is, partial inactivation of NADH dehydrogenase and virtually complete inactivation of succinate and alpha-ketoglutarate dehydrogenase activities (Schoonen et al., 1990). To elucidate the biochemical basis of resistance to hyperoxia in a previously described oxygen-resistant substrain of Chinese hamster ovary (CHO) cells, we compared the resistant cells with wildtype CHO cells with respect to several key parameters of oxidative and glycolytic energy metabolism. The two cell types were critically different in that the succinate and alpha-ketoglutarate dehydrogenases of the oxygen-resistant cells were relatively resistant to inactivation by hyperoxia, which may at least partly explain their enhanced capacity to respire and survive under hyperoxic conditions. Although the biochemical basis for the observed enzyme resistance to hyperoxic inactivation remains to be elucidated, the present data underscore the importance of succinate and alpha-ketoglutarate dehydrogenases as critical targets in hyperoxic killing of wildtype CHO cells.

Oxygen toxicity in control and H2O2-resistant Chinese hamster fibroblast cell lines

Following exposure to 95% oxygen, clonogenic cell survival was assayed and qualitative morphologic changes were observed in a Chinese hamster fibroblast cell line (HA-1). The time in 95% O2 necessary to clonogenically inactivate 90% of the cells was inversely related to the cell density of the cultures at the beginning of hyperoxic exposure (from 1 to 6 X 10(4) cells/cm2). The O2-induced loss in clonogenicity and evidence of morphologic injury were shown to be significantly delayed (17-22 h) in an H2O2-resistant variant of the parental HA-1 cell line. After the delay in onset of clonogenic cell killing or morphologic injury, the process of injury proceeded in a similar fashion in both cell lines. The H2O2-resistant cell line demonstrated significantly greater catalase activity (20-fold), CuZn superoxide dismutase activity (2-fold), and Se-dependent glutathione peroxidase activity (1.5-fold). The greater activities of CuZn superoxide dismutase and catalase were accompanied by similarly greater quantities of immunoreactive protein as determined by immunoblotting. These data demonstrate that the cells adapted and/or selected for growth in a highly peroxidative environment also became refractory to O2-induced toxicity, which may be related to increased expression of antioxidant enzymes. However, the magnitude of this cross-resistance to O2 toxicity was less than the magnitude of the cellular resistance to the toxicity of exogenous H2O2, suggesting that in this system the toxicity of 95% oxygen is not identical to H2O2-mediated cytotoxicity.

Effects of lethal exposure to hyperoxia and to hydrogen peroxide on NAD(H) and ATP pools in Chinese hamster ovary cells

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.

Effect of N-acetylcysteine on the antiproliferative action of X-rays or bleomycin in cultured human lung tumor cells

N-Acetylcysteine is currently being considered as a possible selective protector against pulmonary toxicity resulting from X-rays or chemotherapeutic treatment, but its clinical application awaits evidence that it does not interfere with the efficient killing of tumor cells. The capacity of N-acetylcysteine to protect against the antitumor activity of X-rays and of bleomycin was evaluated in a clonogenic cell-survival assay using SW-1573 human squamous lung carcinoma cells as a tumor model. Using the highest non-toxic dose of N-acetylcysteine (incubation for 2 days in the continuous presence of 10 mM) no effect on clonogenic cell killing by X-rays or bleomycin treatment could be detected, even though a twofold enhancement of endogenous glutathione was effectuated. Our data thus indicate that clinically relevant concentrations of N-acetylcysteine are incapable of protecting tumor cells against clonogenic killing by X-rays and by bleomycin.

Chromosomal instability and progressive loss of chromosomes in HeLa cells during adaptation to hyperoxic growth conditions

By sequential selection for resistance to stepwise increased levels of atmospheric O2, a genetic variant of HeLa cells was obtained capable of stable proliferation under an atmosphere containing 80% O2 (HeLa-80). This cell strain has previously been characterized in terms of growth characteristics, morphology and antioxidant status (Joenje et al., 1985). In an attempt to find cytogenetic clues possibly related to the O2-tolerant character, metaphases of HeLa-80 cells were analyzed and compared to the parental (HeLa-20) strain. Numerical analysis revealed a progressive decrease in the number of chromosomes per cell during selection for O2 resistance, from a modal number of 112 in HeLa-20 cells to 84 in HeLa-80 cells. Cytogenetic endpoints for genetic damage revealed increased frequencies in HeLa-80 cells of both chromosomal aberrations (29.7 versus 6.9% aberrant cells) and sister-chromatid exchanges (0.46 +/- 0.13 versus 0.31 +/- 0.10 SCE/chromosome). G-banded metaphases failed to reveal cytogenetic evidence of gene amplification (homogeneously staining regions, double minutes) in the karyotype of HeLa-80 cells.

Chromosomal instability in an oxygen-tolerant variant of Chinese hamster ovary cells

Background levels of chromosomal aberrations and sister-chromatid exchanges (SCEs) were determined in CHO-99 cells, an oxygen-tolerant variant substrain of Chinese hamster ovary (CHO-20) cells capable of stable proliferation under an atmosphere of 99% O2/1% CO2, a level of hyperoxia at which cultured mammalian cells normally cannot survive. The mean chromosomal aberration frequency in CHO-99 cells was as high as 1 aberration per cell (mainly chromatid and chromosome gaps and breaks) versus 0.05 aberration/cell in CHO-20 cells, while the SCE frequency was 1.7- to 2.1-fold increased. While most aberrations were apparently distributed at random over the chromosomes, up to 31% of the aberrations appeared to be involved in site-specific fragility at a homologous site in chromosomes Z3 and Z4. Immediately upon shifting CHO-99 cells to air-equilibrated conditions their SCE frequency decreased to the control level, whereas the aberration rate persisted at a still elevated level of 0.16-0.31 aberration per cell, even after a culture period of 14 weeks under normoxia. This indicates that at least part of the chromosomal instability is a constitutional property of the variant cells, i.e., not directly dependent upon hyperoxic stress. In CHO-99 X CHO-20 hybrids the occurrence of chromatid-type aberrations and fragile site but not that of chromosome-type aberrations was suppressed under normoxic conditions, suggesting that chromatid-type aberrations and fragile site expression on the one hand and chromosome-type aberrations on the other hand are mediated by different constitutional defects in CHO-99 cells. No gross alterations in (deoxy)ribonucleoside triphosphate pools were detected in CHO-99 cells that could be held responsible for their chromosomal instability. In addition, no increased level of DNA damage was detected by the technique of alkaline elution. The excessive chromosomal instability in CHO-99 cells, as observed under hyperoxic conditions, may originate from reactive intermediates giving rise to DNA double-strand breaks and/or a type of DNA lesion that is resistant to the conditions of the alkaline elution technique. However, alternative mechanisms based upon reactive species interfering with DNA replication/repair processes cannot be excluded.