Ascorbate uptake and antioxidant function in peritoneal macrophages

Since activated macrophages generate potentially deleterious reactive oxygen species, we studied whether ascorbic acid might function as an antioxidant in these cells. Thioglycollate-elicited murine peritoneal macrophages contained about 3 mM ascorbate that was halved by culture in ascorbate-free medium. However, the cells took up added ascorbate to concentrations of 6-8 mM by a high-affinity sodium-dependent transport mechanism. This likely reflected the activity of the SVCT2 ascorbate transporter, since its message and protein were present in the cells. Activation of the cells by phagocytosis of latex particles depleted intracellular ascorbate, although not below the basal levels present in the cells in culture. Glutathione (GSH) was unaffected by phagocytosis, suggesting that ascorbate was more sensitive to the oxidant stress of phagocytosis than GSH. Phagocytosis induced a modest increase in reactive oxygen species as well as a progressive loss of alpha-tocopherol, both of which were prevented in cells loaded with ascorbate. These results suggest that activated macrophages can use ascorbate to lessen self-generated oxidant stress and spare alpha-tocopherol, which may protect these long-lived cells from necrosis or apoptosis.

Catalase-dependent measurement of H2O2 in intact mitochondria

Mitochondria generate potentially damaging amounts of superoxide and H2O2 during oxidative metabolism. Although many assays are available to measure mitochondrial H2O2 generation, most detect H2O2 that has escaped the organelle. To measure H2O2 within mitochondria that contain catalase, we have developed an assay based on the ability of H2O2 to inhibit catalase in the presence of 3-amino-1,2,4-triazole. The assay is simple to perform, does not require expensive instrumentation, and is specific for H2O2. Results from this assay show that H2O2 generation in rat heart mitochondria reflects the activity of the electron transport chain. Further, liver mitochondria prepared from selenium-deficient rats have increased succinate-stimulated rates of H2O2 generation. This indicates that mitochondrial selenoenzymes are important for H2O2 removal. It also demonstrates the utility of this assay in measuring H2O2 release from mitochondria that do not contain catalase. The assay should be useful for study of both superoxide-dependent H2O2 generation in situ, and the role of endogenous mitochondrial catalase in H2O2 removal.

Transport and intracellular accumulation of vitamin C in endothelial cells: relevance to collagen synthesis

Endothelial cells preserve vascular integrity in part by synthesizing type IV collagen for the basement membrane of blood vessels. Vitamin C, which at physiologic pH is largely the ascorbate mono-anion, both protects these cells from oxidant stress and is required for collagen synthesis. Therefore, cultured endothelial cells were used to correlate intracellular concentrations of ascorbate with its uptake and ability to stimulate collagen release into the culture medium. The kinetics and inhibitor specificity of ascorbate transport into EA.hy926 endothelial cells were similar to those observed in other cell types, indicative of a specific high affinity transport process. Further, transport of the vitamin generated intracellular ascorbate concentrations that were 80-100-fold higher than concentrations in the medium following overnight culture, and transport inhibition with sulfinpyrazone and phloretin partially prevented such ascorbate accumulation. On the other hand, low millimolar intracellular concentrations of ascorbate impaired its transport measured after overnight culture. Synthesis and release of type IV collagen into the culture medium was markedly stimulated by ascorbate in a time-dependent manner, and was saturable with increasing medium concentrations of the vitamin. Optimal rates of collagen synthesis required intracellular concentrations of the vitamin up to 2 mM. Since such concentrations can only be generated by the ascorbate transporter, these results show the necessity of transport for this crucial function of the vitamin in endothelium.

Antioxidant effects of dihydrocaffeic acid in human EA.hy926 endothelial cells

Dihydrocaffeic acid (DHCA) is a metabolite of caffeic acid with potent antioxidant properties. Since DHCA has been detected in human plasma following coffee ingestion, we tested the hypothesis that DHCA protects the endothelium from oxidative stress in a model in human-derived EA.hy926 endothelial cells. During culture for 16-24 hours, the cells accumulated DHCA against a concentration gradient to low millimolar concentrations. In alpha-tocopherol-loaded cells, DHCA spared alpha-tocopherol during overnight culture in a dose-dependent manner. In response to oxidant stress induced by a water-soluble free radical initiator, both alpha-tocopherol and DHCA diminished oxidation of cis-parinaric acid that had been incorporated into the cells, although their antioxidant activities were not additive. DHCA also decreased intracellular oxidation of dihydrofluorescein due to redox cycling by menadione. This suggests that the protective effects of DHCA were caused by scavenging of intracellular reactive oxygen species. DHCA also increased nitric oxide synthase activity in a dose-dependent manner in cultured cells, which was associated with a comparable increase in endothelial nitric oxide synthase protein. Although the DHCA concentrations required for these effects are higher than those likely to be present in plasma or the interstitium, these results indicate that DHCA can function as an intracellular antioxidant.

Ascorbic acid recycling by cultured beta cells: effects of increased glucose metabolism

Ascorbic acid is necessary for optimal insulin secretion from pancreatic islets. We evaluated ascorbate recycling and whether it is impaired by increased glucose metabolism in the rat beta-cell line INS-1. INS-1 cells, engineered with the potential for overexpression of glucokinase under the control of a tetracycline-inducible gene expression system, took up and reduced dehydroascorbic acid to ascorbate in a concentration-dependent manner that was optimal in the presence of physiologic D-glucose concentrations. Ascorbate uptake did not affect intracellular GSH concentrations. Whereas depletion of GSH in culture to levels about 25% of normal also did not affect the ability of the cells to reduce dehydroascorbic acid, more severe acute GSH depletion to less than 10% of normal levels did impair dehydroascorbic acid reduction. Culture of inducible cells in 11.8 mM D-glucose and doxycycline for 48 h enhanced glucokinase activity, increased glucose utilization, abolished D-glucose-dependent insulin secretion, and increased generation of reactive oxygen species. The latter may have contributed to subsequent decreases in the ability of the cells both to maintain intracellular ascorbate and to recycle it from dehydroascorbic acid. Cultured beta cells have a high capacity to recycle ascorbate, but this is sensitive to oxidant stress generated by increased glucose metabolism due to culture in high glucose concentrations and increased glucokinase expression. Impaired ascorbate recycling as a result of increased glucose metabolism may have implications for the role of ascorbate in insulin secretion in diabetes mellitus and may partially explain glucose toxicity in beta cells.

Nitric oxide-induced oxidant stress in endothelial cells: amelioration by ascorbic acid

Nitric oxide has multiple beneficial effects in the blood vessel wall. However, high concentrations of nitric oxide in the presence of hydroperoxides have been shown to damage cultured cells. In this work, the effect of relatively high concentrations of nitric oxide alone on the function and antioxidant status of a human endothelial cell line (EA.hy926) was tested. Nitric oxide generated from 0.1 to 0.5mM spermine NONOate generated reactive species in the cells detected by triazole formation from diaminofluorescein and by oxidation of dihydrofluorescein. Intracellular ascorbic acid decreased this oxidant stress. Spermine NONOate also decreased intracellular ascorbate concentrations, although reduced glutathione was not affected unless cells had also been caused to reduce dehydroascorbic acid to ascorbate. Nitric oxide predictably inhibited both endothelial nitric oxide synthase and glyceraldehyde 3-phosphate dehydrogenase, and ascorbate partially prevented inhibition of the latter enzyme. These results suggest that relatively high concentrations of nitric oxide can cause oxidant stress in endothelial cells that is ameliorated by ascorbic acid.

Reduction and uptake of methylene blue by human erythrocytes

A thiazine dye reductase has been described in endothelial cells that reduces methylene blue (MB), allowing its uptake into cells. Because a different mechanism of MB uptake in human erythrocytes has been proposed, we measured MB uptake and reduction in this cell type. Oxidized MB (MB(+)) stimulated reduction of extracellular ferricyanide in a time- and concentration-dependent manner, reflecting extracellular reduction of the dye. Reduced MB was then taken up by the cells and partially oxidized to MB(+). Both forms were retained against a concentration gradient, and their redox cycling induced an oxidant stress in the cells. Whereas concentrations of MB(+) <5 microM selectively oxidized NAD(P)H, higher concentrations also oxidized both glutathione (GSH) and ascorbate, especially in the absence of d-glucose. MB(+)-stimulated ferricyanide reduction was inhibited by thiol reagents with different mechanisms of action. Phenylarsine oxide, which is selective for vicinal dithiols in proteins, inhibited MB(+)-dependent ferricyanide reduction more strongly than it decreased cell GSH and pentose phosphate cycle activity, and it did not affect cellular NADPH. Open erythrocyte ghost membranes facilitated saturable NAD(P)H oxidation by MB(+), which was abolished by pretreating ghosts with low concentrations of trypsin and phenylarsine oxide. These results show that erythrocytes sequentially reduce and take up MB(+), that both reduced and oxidized forms of the dye are concentrated in cells, and that the thiazine dye reductase activity initially responsible for MB(+) reduction may correspond to MB(+)-dependent NAD(P)H reductase activity in erythrocyte ghosts.

Human erythrocyte recycling of ascorbic acid: relative contributions from the ascorbate free radical and dehydroascorbic acid

Recycling of ascorbic acid from its oxidized forms helps to maintain the vitamin in human erythrocytes. To determine the relative contributions of recycling from the ascorbate radical and dehydroascorbic acid, we studied erythrocytes exposed to a trans-membrane oxidant stress from ferricyanide. Ferricyanide was used both to induce oxidant stress across the cell membrane and to quantify ascorbate recycling. Erythrocytes reduced ferricyanide with generation of intracellular ascorbate radical, the concentrations of which saturated with increasing intracellular ascorbate and which were sustained over time in cells incubated with glucose. Ferricyanide also generated dehydroascorbic acid that accumulated in the cells and incubation medium to concentrations much higher than those of the radical, especially in the absence of glucose. Ferricyanide-stimulated ascorbate recycling from dehydroascorbic acid depended on intracellular GSH but was well maintained at the expense of intracellular ascorbate when GSH was severely depleted by diethylmaleate. This likely reflects continued radical reduction, which is not dependent on GSH. Erythrocyte hemolysates showed both NAD- and NADPH-dependent ascorbate radical reduction. The latter was partially due to thioredoxin reductase. GSH-dependent dehydroascorbate reduction in hemolysates, which was both direct and enzyme-dependent, was greater than that of the radical reductase activity but of lower apparent affinity. Together, these results suggest an efficient two-tiered system in which high affinity reduction of the ascorbate radical is sufficient to remove low concentrations of the radical that might be encountered by cells not under oxidant stress, with back-up by a high capacity system for reducing dehydroascorbate under conditions of more severe oxidant stress.

Oxidative stress is a mediator of glucose toxicity in insulin-secreting pancreatic islet cell lines

Pancreatic beta cells secrete insulin in response to changes in the extracellular glucose. However, prolonged exposure to elevated glucose exerts toxic effects on beta cells and results in beta cell dysfunction and ultimately beta cell death (glucose toxicity). To investigate the mechanism of how increased extracellular glucose is toxic to beta cells, we used two model systems where glucose metabolism was increased in beta cell lines by enhancing glucokinase (GK) activity and exposing cells to physiologically relevant increases in extracellular glucose (3.3-20 mm). Exposure of cells with enhanced GK activity to 20 mm glucose accelerated glycolysis, but reduced cellular NAD(P)H and ATP, caused accumulation of intracellular reactive oxygen species (ROS) and oxidative damage to mitochondria and DNA, and promoted apoptotic cell death. These changes required both enhanced GK activity and exposure to elevated extracellular glucose. A ROS scavenger partially prevented the toxic effects of increased glucose metabolism. These results indicate that increased glucose metabolism in beta cells generates oxidative stress and impairs cell function and survival; this may be a mechanism of glucose toxicity in beta cells. The level of beta cell GK may also be critical in this process.

Generation of oxidant stress in cultured endothelial cells by methylene blue: protective effects of glucose and ascorbic acid

The thiazine dye methylene blue has long been used to stimulate cellular redox metabolism. To determine the extent to which it also generates oxidant stress in cells, its effects in cultured human-derived endothelial cells were studied. As expected, low concentrations of the dye (2-20 microM) activated the pentose phosphate pathway and oxidized both NADPH and NADH. Methylene blue enhanced extracellular ferricyanide reduction, indicating that the reduced form of the dye was present outside the cells. This reduction was greater when ferricyanide was added just before rather than 15 min after methylene blue, confirming that the dye is at least initially reduced at the cell surface. In the absence of glucose, methylene blue at concentrations above 5 microM increased intracellular oxidant stress, as manifest by oxidation of dihydrofluorescein and cellular GSH. Inclusion of glucose protected against these effects. In cells that had been loaded with ascorbate, the dye caused progressive oxidation of ascorbate, even in the presence of D-glucose. Loading cells with ascorbate also partially prevented oxidation of dihydrofluorescein by methylene blue. These results suggest that concentrations of the dye above 5 microM generated intracellular reactive oxygen species that were scavenged by ascorbate and GSH. Further, although D-glucose enhanced reduction of methylene blue, it ameliorated the oxidant stress generated by the dye.

Location and recycling of mitochondrial α-tocopherol

Vitamin E in the form of alpha-tocopherol is crucial for mitochondrial integrity. We studied the distribution of alpha-tocopherol in rat muscle mitochondria in relation to the capacity of the electron transport chain to recycle the vitamin. Fractionation studies showed that almost 90% of the alpha-tocopherol in mitochondria is located in the outer membrane. This distribution was confirmed with the finding that ferricytochrome c, which does not penetrate the outer membrane, oxidized 70-80% of mitochondrial alpha-tocopherol in a time- and concentration-dependent manner. Despite the predominant outer membrane distribution of alpha-tocopherol, succinate and other mitochondrial respiratory substrates spared alpha-tocopherol from oxidative loss by both agents. Sparing of alpha-tocopherol by succinate was prevented by 2-thenoyltrifluoroacetone, but not by myxothiazol, which suggests that ubiquinol is the electron donor. Ferricytochrome c significantly increased total F2-isoprostanes, an effect that was prevented by succinate. Most alpha-tocopherol in muscle mitochondria is located in the outer membrane, where it is susceptible to oxidative loss. Nonetheless, alpha-tocopherol is partially spared by ubiquinol in the electron transport chain.

Ascorbic acid spares alpha-tocopherol and decreases lipid peroxidation in neuronal cells

Ascorbic acid is considered an antioxidant in the central nervous system, but direct evidence that ascorbate protects neuronal cells from oxidant stress is lacking. Differentiated SH-SY5Y cells in culture took up ascorbic acid on the sodium-dependent vitamin C transporter Type 2 and retained it much more effectively than dehydroascorbic acid. Intracellular ascorbate spared alpha-tocopherol, both in cells loaded with alpha-tocopherol in culture and in cells under oxidant stress due to extracellular ferricyanide. Sparing of alpha-tocopherol in response to ferricyanide was associated with protection against lipid peroxidation in cell membranes. These results show that neuronal cells concentrate ascorbate, and that intracellular ascorbate, either directly or through sparing of alpha-tocopherol, protects them against oxidant stress.

Combined deficiency of vitamins E and C causes paralysis and death in guinea pigs

BACKGROUND

On the basis of in vitro studies, the antioxidant nutrients vitamins E and C are postulated to interact in vivo.

OBJECTIVE

We developed a guinea pig model to evaluate the combined deficiency of vitamins E and C in vivo.

DESIGN

Weanling guinea pigs were fed a control diet or a vitamin E-deficient diet for 14 d, after which one-half of each group had vitamin C removed from their diet, thus creating 4 diet groups. Some animals were observed for clinical signs. Others were killed for evaluation.

RESULTS

Of 21 guinea pigs that were observed after being fed the diet deficient in both vitamins, 8 died 9 +/- 2 d (x +/- SD) after starting the diet. Eight additional guinea pigs developed a characteristic syndrome at 11 +/- 3 d. First, they became paralyzed in the hind limbs. Within a few hours, the paralysis progressed to include all 4 limbs and caused difficulty in breathing, which would have caused death had the animals not been euthanized. Histopathologic evaluation did not identify a lesion in the muscles or nervous system that could account for the paralysis. Biochemical measurements confirmed the deficiencies and indicated that the double deficiency caused lipid peroxidation in the central nervous system.

CONCLUSIONS

A distinct clinical syndrome of combined vitamin E and vitamin C deficiency occurs in guinea pigs. This syndrome indicates that these antioxidant vitamins are related in vivo. We speculate that acute oxidative injury in the central nervous system underlies the clinical syndrome.

Recycling of vitamin C from its oxidized forms by human endothelial cells

Endothelial cells encounter oxidant stress due to their location in the vascular wall, and because they generate reactive nitrogen species. Because ascorbic acid is likely involved in the antioxidant defenses of these cells, we studied the mechanisms by which cultures of EA.hy926 endothelial cells recycle the vitamin from its oxidized forms. Cell lysates reduced the ascorbate free radical (AFR) by both NADH- and NADPH-dependent mechanisms. Most NADH-dependent AFR reduction occurred in the particulate fraction of the cells. NADPH-dependent reduction resembled that due to NADH in having a high affinity for the AFR, but was mediated largely by thioredoxin reductase. Reduction of dehydroascorbic acid (DHA) required GSH and was both direct and enzyme dependent. The latter was saturable, half-maximal at 100 microM DHA, and comparable to rates of AFR reduction. Loading cells to ascorbate concentrations of 0.3-1.6 mM generated intracellular DHA concentrations of 20-30 microM, indicative of oxidant stress in culture. Whereas high-affinity AFR reduction is the initial and likely the preferred mechanism of ascorbate recycling, any DHA that accumulates during oxidant stress will be reduced by GSH-dependent mechanisms.

Ascorbic acid spares alpha-tocopherol and prevents lipid peroxidation in cultured H4IIE liver cells

Ascorbic acid, or vitamin C, can recycle alpha-tocopherol in lipid bilayers, but even sparing of alpha-tocopherol has not been a consistent finding in intact cells. Therefore, we tested the ability of ascorbate loading to spare alpha-tocopherol and to prevent lipid peroxidation of cultured H4IIE rat liver cells. Although alpha-tocopherol was undetectable in H4IIE cells, its cell content was increased by overnight incubation with alpha-tocopherol in culture. Cells incubated with ascorbate 2-phosphate accumulated ascorbate to concentrations as high as 0.6 mM after overnight loading, but also released ascorbate into the medium. Ascorbate loading of alpha-tocopherol-treated cells spared alpha-tocopherol in a concentration-dependent manner during overnight incubation. Lipid peroxidative damage, measured as a decrease in fluorescence of cell-bound cis-parinaric acid, was decreased in cells loaded with either alpha-tocopherol or ascorbate 2-phosphate, and showed an additive effect. These results suggest that ascorbate loading of H4IIE cells spares cellular alpha-tocopherol and either directly or through recycling of alpha-tocopherol prevents lipid peroxidative damage due to oxidant stress in culture.

Ascorbic acid blunts oxidant stress due to menadione in endothelial cells

Endothelial cells are exposed to potentially damaging reactive oxygen species generated both within the cells and in the bloodstream and underlying vessel wall. In this work, we studied the ability of ascorbic acid to protect cultured human-derived endothelial cells (EA.hy926) from oxidant stress generated by the redox cycling agent menadione. Menadione caused intracellular oxidation of dihydrofluorescein, which required the presence of D-glucose in the incubation medium, and was inhibited by intracellular ascorbate and desferrioxamine. At concentrations of 100 microM and higher, menadione depleted the cells of both GSH and ascorbate, and ascorbate loading partially prevented the decrease in GSH due to menadione. Menadione increased L-arginine uptake by the cells, but inhibited endothelial nitric oxide synthase, an effect that was prevented by acute loading with ascorbate. Ascorbate blunts menadione-induced oxidant stress in EA.hy926 cells, which may help to preserve nitric oxide synthase activity under conditions of excessive oxidant stress.

Control of glucose phosphorylation in L6 myotubes by compartmentalization, hexokinase, and glucose transport

In muscle, insulin enhances influx of glucose and its conversion to glucose 6-phosphate (G6P) by hexokinase (HK). While effects of insulin on glucose transport have been demonstrated, its effect on the activity of HK of cells has not. In L6 myotubes treated for 24 h with insulin there was increased expression of the HK isoform, HKII, and increased glucose phosphorylation without a concomitant increase in glucose transport, indirectly suggesting that phosphorylation of glucose was a target of insulin action [Osawa, Printz, Whitesell and Granner (1995) Diabetes 44, 1426-1432]. In the present work the same treatment led to a 2-fold rise in G6P, suggesting that transport and/or HK were important targets of insulin action. We used a method to identify the site of rate control involving the specificity of phosphorylation towards 2-deoxy-[1-14C]glucose and D-[2-3H]glucose. Glucose transport does not greatly discriminate between these two tracers while HK shows increased specificity for glucose. Specificity of the glucose phosphorylation of the cells increased with addition of insulin and when extracellular glucose was raised. Specificity was reduced at low glucose concentrations or when the inhibitor of transport, cytochalasin B, was added. We conclude that transport and HK share nearly equal control over glucose phosphorylation in these cells. A computer program was used to test models for compatibility with the different types of experiments. The predicted intracellular glucose and transport rates associated with phosphorylation activity were lower than their measured values for the whole cell. In the most likely model, 15+/-4% of the glucose transporters serve a proportionate volume of the cytoplasm. Insulin activation of glucose phosphorylation might then result from stimulation of these transporters together with HK recruitment or relief from inhibition by G6P.

Mitochondrial recycling of ascorbic acid from dehydroascorbic acid: dependence on the electron transport chain

Mitochondria can regenerate ascorbic acid from its oxidized forms, which may help to maintain the vitamin both in mitochondria and in the cytoplasm. In this work, we sought to determine the site and mechanism of mitochondrial ascorbate recycling from dehydroascorbic acid. Rat skeletal muscle mitochondria incubated for 3 h at 37 degrees C with 500 microM dehydroascorbic acid and energy substrates maintained ascorbate concentrations more than twice those observed in the absence of substrate. Succinate-dependent mitochondrial reduction of dehydroascorbic acid was blocked by inhibitors of mitochondrial Complexes II and III. Neither cytochrome c nor the outer mitochondrial membrane were necessary for the effect. The ascorbate radical was generated by mitochondria during treatment with dehydroascorbic acid and was abolished by ferricyanide, which does not penetrate the mitochondrial inner membrane. Together, these results show that energy substrate-dependent ascorbate recycling from dehydroascorbic acid involves an externally exposed portion of mitochondrial complex III.

Uptake, recycling, and antioxidant actions of alpha-lipoic acid in endothelial cells

Alpha-lipoic acid, which becomes a powerful antioxidant in its reduced form, has been suggested as a dietary supplement to treat diseases associated with excessive oxidant stress. Because the vascular endothelium is dysfunctional in many of these conditions, we studied the uptake, reduction, and antioxidant effects of alpha-lipoic acid in cultured human endothelial cells (EA.hy926). Using a new assay for dihydrolipoic acid, we found that EA.hy926 cells rapidly take up and reduce alpha-lipoic acid to dihydrolipoic acid, most of which is released into the incubation medium. Nonetheless, the cells maintain dihydrolipoic acid following overnight culture, probably by recycling it from alpha-lipoic acid. Acute reduction of alpha-lipoic acid activates the pentose phosphate cycle and consumes nicotinamide adenine dinucleotide phosphate (NADPH). Lysates of EA.hy926 cells reduce alpha-lipoic acid using both NADPH and nicotinamide adenine dinucleotide (NADH) as electron donors, although NADPH-dependent reduction is about twice that due to NADH. NADPH-dependent alpha-lipoic acid reduction is mostly due to thioredoxin reductase. Pre-incubation of cells with alpha-lipoic acid increases their capacity to reduce extracellular ferricyanide, to recycle intracellular dehydroascorbic acid to ascorbate, to decrease reactive oxygen species generated by redox cycling of menadione, and to generate nitric oxide. These results show that alpha-lipoic acid enhances both the antioxidant defenses and the function of endothelial cells.

Thioredoxin reductase reduces lipid hydroperoxides and spares alpha-tocopherol

We investigated whether and how rat liver thioredoxin reductase spares alpha-tocopherol in biomembranes. Purified hydroperoxides of beta-linoleoyl-gamma-palmitoylphosphatidylcholine were decreased 35% by treatment with thioredoxin reductase and 54% by thioredoxin reductase plus E. coli thioredoxin. Thioredoxin reductase also halved the amount of hydroperoxides that had been formed during photoperoxidation of liposomes composed of beta-linoleoyl-gamma-palmitoylphosphatidylcholine, and of emulsions of both cholesterol and cholesteryl linolenate. In erythrocyte ghosts, thioredoxin reductase spared alpha-tocopherol from oxidation by both soybean lipoxygenase and ferricyanide. Thioredoxin reductase also decreased F(2)-isoprostanes in ghosts oxidized by ferricyanide, suggesting that its ability to spare alpha-tocopherol relates to reduction of lipid hydroperoxides.

Coordinate regulation of L-arginine uptake and nitric oxide synthase activity in cultured endothelial cells

Despite intracellular L-arginine concentrations that should saturate endothelial nitric oxide synthase (eNOS), nitric oxide production depends on extracellular L-arginine. We addressed this 'arginine paradox' in bovine aortic endothelial cells by simultaneously comparing the substrate dependence of L-arginine uptake and intracellular eNOS activity, the latter measured as L-[3H]arginine conversion to L-[3H]citrulline. Whereas the Km of eNOS for L-arginine was 2 microM in cell extracts, the L-arginine concentration of half-maximal eNOS stimulation was increased to 29 microM in intact cells. This increase likely reflects limitation by L-arginine uptake, which had a Km of 108 microM. The effects of inhibitors of endothelial nitric oxide synthesis also suggested that extracellular L-arginine availability limits intracellular eNOS activity. Treatment of intact cells with the calcium ionophore A23187 reduced the L-arginine concentration of half-maximal eNOS activity, which is consistent with a measured increase in L-arginine uptake. Increases in eNOS activity induced by several agents were closely correlated with enhanced L-arginine uptake into cells (r = 0.89). The 'arginine paradox' may be explained in part by regulated L-arginine uptake into a compartment, probably represented by caveolae, that contains eNOS and that is distinct from the bulk cytosolic L-arginine.

GSH is required to recycle ascorbic acid in cultured liver cell lines

Liver is the site of ascorbic acid synthesis in most mammals. As human liver cannot synthesize ascorbate de novo, it may differ from liver of other species in the capacity or mechanism for ascorbate recycling from its oxidized forms. Therefore, we compared the ability of cultured liver-derived cells from humans (HepG2 cells) and rats (H4IIE cells) to take up and reduce dehydroascorbic acid (DHA) to ascorbate. Neither cell type contained appreciable amounts of ascorbate in culture, but both rapidly took up and reduced DHA to ascorbate. Intracellular ascorbate accumulated to concentrations of 10-20 mM following loading with DHA. The capacity of HepG2 cells to take up and reduce DHA to ascorbate was more than twice that of H4IIE cells. In both cell types, DHA reduction lowered glutathione (GSH) concentrations and was inhibited by prior depletion of GSH with diethyl maleate, buthionine sulfoximine, and phenylarsine oxide. NADPH-dependent DHA reduction due to thioredoxin reductase occurred in overnight-dialyzed extracts of both cell types. These results show that cells derived from rat liver synthesize little ascorbate in culture, that cultured human-derived liver cells have a greater capacity for DHA reduction than do rat-derived liver cells, but that both cell types rely largely on GSH- or NADPH-dependent mechanisms for ascorbate recycling from DHA.

Selenium spares ascorbate and alpha-tocopherol in cultured liver cell lines under oxidant stress

The selenoenzyme thioredoxin reductase (TR) can recycle ascorbic acid, which in turn can recycle alpha-tocopherol. Therefore, we evaluated the role of selenium in ascorbic acid recycling and in protection against oxidant-induced loss of alpha-tocopherol in cultured liver cells. Treatment of HepG2 or H4IIE cultured liver cells for 48 h with sodium selenite (0-116 nmol/l) tripled the activity of the selenoenzyme TR, measured as aurothioglucose-sensitive dehydroascorbic acid (DHA) reduction. However, selenium did not increase the ability of H4IIE cells to take up and reduce 2 mM DHA, despite a 25% increase in ascorbate-dependent ferricyanide reduction (which reflects cellular ascorbate recycling). Nonetheless, selenium supplements both spared ascorbate in overnight cultures of H4IIE cells, and prevented loss of cellular alpha-tocopherol in response to an oxidant stress induced by either ferricyanide or diazobenzene sulfonate. Whereas TR contributes little to ascorbate recycling in H4IIE cells, selenium spares ascorbate in culture and alpha-tocopherol in response to an oxidant stress.

Mechanisms of ascorbic acid recycling in human erythrocytes

Vitamin C, or ascorbic acid, is efficiently recycled from its oxidized forms by human erythrocytes. In this work the dependence of this recycling on reduced glutathione (GSH) was evaluated with regard to activation of the pentose cycle and to changes in pyridine nucleotide concentrations. The two-electron-oxidized form of ascorbic acid, dehydroascorbic acid (DHA) was rapidly taken up by erythrocytes and reduced to ascorbate, which reached intracellular concentrations as high as 2 mM. In the absence of D-glucose, DHA caused dose-dependent decreases in erythrocyte GSH, NADPH, and NADH concentrations. In the presence of 5 mM D-glucose, GSH and NADH concentrations were maintained, but those of NADPH decreased. Reduction of extracellular ferricyanide by erythrocytes, which reflects intracellular ascorbate recycling, was also enhanced by D-glucose, and ferricyanide activated the pentose cycle. Diethylmaleate at concentrations up to 1 mM was found to specifically deplete erythrocyte GSH by 75-90% without causing oxidant stress in the cells. Such GSH-depleted erythrocytes showed parallel decreases in their ability to take up and reduce DHA to ascorbate, and to reduce extracellular ferricyanide. These results show that DHA reduction involves GSH-dependent activation of D-glucose metabolism in the pentose cycle, but that in the absence of D-glucose DHA reduction can also utilize NADH.