Decreased expression of miR-551b predicts poor prognosis and promotes tumorigenesis by targeting PTP4A3 in human colorectal cancer.

OBJECTIVE: MiR-551b has been reported to display tumor-suppressive and oncogenic potential in several cancers, but there has been no study on the roles of miR-551b in colorectal cancer (CRC). In this work, we aimed to explore the potential functions and mechanisms of miR-551b in the modulation of the CRC progression. PATIENTS AND METHODS: The expressions of miR-551b were examined in 122 pairs of CRC cancer tissues and adjacent non-tumor samples by Real Time-Polymerase Chain Reaction (RT-PCR). The clinical significance of miR-551b in CRC patients was explored using a Chi-square test, Kaplan-Meier assays, and multivariate analysis. MiR-551b mimics and inhibitors were used to establish miR-551b upregulation and downregulation models in CRC cells to examine the functions of miR-551b on cells proliferation, migration, invasion, and apoptosis. Dual-luciferase reporter assays were conducted for the validation of the possible modulation of a putative target of miR-551b. RESULTS: We showed that miR-551b was significantly down-regulated in CRC tissues and cell lines. It was observed that miR-551b expressions were correlated with lymph nodes metastasis, TNM stage, and poor prognosis. Multivariate analysis identifies low level of miR-551b expressions as an independent predictor for a shorter overall survival. The functional assessment suggested that forced miR-551b expression distinctly suppressed CRC cells growth, invasion, and migration, while the suppression of miR-551b displayed the opposite trend. Mechanistic studies confirmed that PTP4A3 was identified as a direct target of miR-551b in CRC. Interesting observations revealed that the cells capacities were higher in miR-551b +PTP4A3 group, when compared with those in miR-551b group, indicating that up-regulation of PTP4A3 rescued the repressive functions of miR-551b overexpression on CRC cells growth and migration. CONCLUSIONS: The findings of our study first showed that miR-551b, a potential tumor suppressor, may be used as a promising prognostic predictor and therapeutic target for CRC.

Selection of phage-display peptides that bind specifically to the outer coat protein of Rice black streaked dwarf virus.

Several peptides that could bind specifically to the outer coat protein encoded by the S10 gene of Rice black streaked virus (RBSDV) were isolated from a phage-display random 12-mer peptide library. The sequence analysis showed that the amino acid motif (K)K**(*)P, the asterisk denoting any amino acid, might be the core sequence by which the peptides bind to the target protein. The peptide 1 that had a high affinity to RBSDV outer coat protein was synthesized by a chemical method and its fusion protein with glutathione-S-transferase (GST) was produced in an Escherichia coli expression system. The dot and Western blot analyses indicated that RBSDV could be detected with a high sensitivity in crude extracts of diseased plant leaves using a purified GST fusion protein. The circular dichroism (CD) spectroscopy revealed that the synthesized binding peptide but not a nonbinding peptide could bring about a marked change in the conformation of outer coat RBSDV protein. Since the protein functions only when it has correct conformation, the peptides binding specifically to it could possibly disturb the function of the virus outer coat protein and might be used to block the transmission pathway of the virus. Summing up, as these peptides showed a high specificity and sensitivity and diagnostic potential for RBSDV, they may represent the basis of a novel strategy for development of resistance to RBSDV.

Selection and expression of peptides which can change the conformation of p20 protein of rice stripe virus.

Phages with high affinity to the P20 protein of rice stripe virus (RSV) were enriched from phage-displayed random 12-mer peptide library after three rounds of phage display screening. Nine different peptides from the enriched library were selected by enzyme-linked immunosorbent assay (ELISA). The P20 protein from raw extracts of rice leaves infected with RSV could be detected by those 9 peptides displayed on the phage, which suggested that a peptide could be an effective tool for diagnosis of RSV in rice and planthopper. Circular dichroism (CD) spectra of P20 fusion proteins with the binding phages and non-binding phages showed that the conformation of P20 protein was changed after binding to each of the 9 selected 12-mer peptides, which suggested that these peptides might disrupt the function of the P20 protein. Thereafter, those peptides might be used to develop plant resistance and disrupt virus transmission. Three of the 12-mer peptide genes were fused with the glutathione-S-transferase (GST) gene in the vector pGEX 3X. The fusion proteins were obtained from an Escherichia coli expression system and purified. The fusion proteins might have a potential to develop a plant peptide-based resistance to its pathogens and virus diagnosis. It also provided a tool (i) to confirm the inhibition of the function of P20 protein by the fusion peptides in vivo, and (ii) to detect the function of P20 protein and the interaction between the virus and its vector.

Identification of rice black streaked dwarf virus in different cereal crops with dwarfing symptoms in China.

This report describes isolation of virus particles from plants of rice, maize, wheat and sorghum with symptoms of dwarfing collected from two provinces of China, purification of double-stranded RNA (dsRNA) from the virus particles, and synthesis of full-length cDNAs of genome segments 9 (S9) and 10 (S10) by reverse transcription-polymerase chain reaction (RT-PCR). Sequence analysis showed that the S9 sequences of the Chinese isolates and a Japanese rice black-streaked disease virus (RBSDV) isolate were very similar (89.1-89.6% homology at nucleotide level and 92.3-92.9% and 95.8-98.6% homology at amino acid level for ORF1 and ORF2, respectively). Analogical similarity was found also for the S10 sequences of the isolates under comparison: 93.0-95.4% homology at nucleotide level and 96.2-97.0% homology at amino acid level. However, there was a relatively lower similarity for S9 and S10 segments ofthe Chinese isolates and an Italian maize rough dwarf virus (MRDV) isolate. The phylogenetic analysis indicated that the Chinese isolates that infect rice, maize, wheat and sorghum and cause similar symptoms could represent the same virus species, RBSDV.

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.

Nitrite uptake and metabolism and oxidant stress in human erythrocytes.

Nitric oxide, when released into the bloodstream, is quickly scavenged by Hb in erythrocytes or oxidized to nitrite. Nitrite can also enter erythrocytes and oxidize Hb. The goals of this work were to determine the mechanism of erythrocyte nitrite uptake and whether this uptake causes oxidant stress in these cells. Erythrocytes took up 0.8 mM nitrite with a half-time of 11 min. Nitrite uptake was sensitive to temperature and to the pH and ionic composition of the medium but was not inhibited by the specific anion-exchange inhibitor DIDS. About 25% of nitrite uptake occurred on the sodium-dependent phosphate transporter and the rest as diffusion of nitrous acid or other species across the plasma membrane. Methemoglobin formation increased in proportion to the intracellular nitrite concentration. Nitrite reacted with erythrocyte ascorbate, but ascorbate loading of cells decreased nitrite-induced methemoglobin formation only at high nitrite concentrations. In conclusion, nitrite rapidly enters erythrocytes and reacts with oxyhemoglobin but does not exert a strong oxidant stress on these cells.

Extracellular reduction of the ascorbate free radical by human erythrocytes.

We investigated the possibility that human erythrocytes can reduce extracellular ascorbate free radical (AFR). When the AFR was generated from ascorbate by ascorbate oxidase, intact cells slowed the loss of extracellular ascorbate, an effect that could not be explained by changes in enzyme activity or by release of ascorbate from the cells. If cells preserve extracellular ascorbate by regenerating it from the AFR, then they should decrease the steady-state concentration of the AFR. This was confirmed directly by electron paramagnetic resonance spectroscopy, in which the steady-state extracellular AFR signal varied inversely with the cell concentration and was a saturable function of the absolute AFR concentration. Treatment of cells N-ethylmaleimide (2 mM) impaired their ability both to preserve extracellular ascorbate, and to decrease the extracellular AFR concentration. These results suggest that erythrocytes spare extracellular ascorbate by enhancing recycling of the AFR, which could help to maintain extracellular concentrations of the vitamin.

Troglitazone protects human erythrocytes from oxidant damage.

The antidiabetic drug troglitazone contains the active chromanol ring of alpha-tocopherol, which should give it antioxidant properties within cells. In these studies, the antioxidant effects of troglitazone were tested in human erythrocytes and in their ghosts. Troglitazone bound to erythrocyte ghosts in a linear manner and was retained even after centrifugation washes. In response to an oxidant stress generated by a water-soluble free radical initiator, troglitazone that was bound to erythrocyte ghosts was oxidized, but induced a lag-phase in the disappearance of endogenous alpha-tocopherol and in the appearance of lipid hydroperoxides. Troglitazone also delayed loss of endogenous alpha-tocopherol and hemolysis in washed intact erythrocytes in response to free radical-induced extracellular oxidant stress. To mimic exposure of erythrocytes to lipid hydroperoxides in vivo, erythrocytes were incubated with phospholipid liposomes that contained small amounts of preformed lipid hydroperoxides. This induced an oxidant stress in both the liposomes and cells. Troglitazone in concentrations above 4 microM almost completely prevented further appearance of lipid hydroperoxides in the liposomes, and also completely preserved alpha-tocopherol in the erythrocytes. The present results suggest that troglitazone will help to prevent peroxidative damage to erythrocytes in areas of excessive oxidant stress in the vascular bed.

Ascorbate-dependent electron transfer across the human erythrocyte membrane.

Reduction of extracellular ferricyanide by intact cells reflects the activity of an as yet unidentified trans-plasma membrane oxidoreductase. In human erythrocytes, this activity was found to be limited by the ability of the cells to recycle intracellular ascorbic acid, its primary trans-membrane electron donor. Ascorbate-dependent ferricyanide reduction by erythrocytes was partially inhibited by reaction of one or more cell-surface sulfhydryls with p-chloromercuribenzene sulfonic acid, an effect that persisted in resealed ghosts prepared from such treated cells. However, treatment of intact cells with the sulfhydryl reagent had no effect on NADH-dependent ferricyanide or ferricytochrome c reductase activities of open ghosts prepared from treated cells. When cytosol-free ghosts were resealed to contain trypsin or pronase, ascorbate-dependent reduction of extravesicular ferricyanide was doubled, whereas NADH-dependent ferricyanide and ferricytochrome c reduction were decreased by proteolytic digestion. The trans-membrane ascorbate-dependent activity was also found to be inhibited by reaction of sulfhydryls on its cytoplasmic face. These results show that the trans-membrane ferricyanide oxidoreductase is limited by the ability of erythrocytes to recycle intracellular ascorbate, that it does not involve the endofacial NADH-dependent cytochrome b(5) reductase system, and that it is a trans-membrane protein that contains sensitive sulfhydryl groups on both membrane faces.

Vitamin C recycling and function in human monocytic U-937 cells.

The uptake, recycling, and function of ascorbic acid was evaluated in cultured U-937 monocytic cells. Dehydroascorbic acid, the two-electron oxidized form of the vitamin, was taken up on the glucose transporter and reduced to ascorbate to a much greater extent than ascorbate itself was accumulated by the cells. In contrast to dehydroascorbic acid, ascorbate entered the cells on a sodium- and energy-dependent transporter. Intracellular ascorbate enhanced the transfer of electrons across the cell membrane to extracellular ferricyanide. Rates of ascorbate-dependent ferricyanide reduction were saturable, fivefold greater than basal rates, and facilitated by intracellular recycling of ascorbate. Whereas reduction of dehydroascorbic acid concentrations above 400 microM consumed reduced glutathione (GSH), even severe GSH depletion by 1-chloro-2,4-dinitrobenzene was without effect on the ability of the cells to reduce concentrations of dehydroascorbic acid likely to be in the physiologic range (< 200 microM). Dialyzed cytosolic fractions from U-937 cells reduced dehydroascorbic acid to ascorbate in an NADPH-dependent manner that appeared due to thioredoxin reductase. However, thioredoxin reductase did not account for the bulk of dehydroascorbic acid reduction, since its activity was also decreased by treatment of intact cells with 1-chloro-2,4-dinitrobenzene. Thus, U-937 cells loaded with dehydroascorbic acid accumulate ascorbate against a concentration gradient via a mechanism that is not dependent on GSH or NADPH, and this ascorbate can serve as the major source of electrons for transfer across the plasma membrane to extracellular ferricyanide.

Role of ascorbic acid in transferrin-independent reduction and uptake of iron by U-937 cells.

The role of ascorbic acid in transferrin-independent ferric iron reduction and uptake was evaluated in cultured U-937 monocytic cells. Uptake of 55Fe by U-937 cells was doubled by 100 microM extracellular ascorbate, and by pre-incubation of cells with 100 microM dehydroascorbic acid, the two-electron-oxidized form of ascorbate. Reduction of extracellular ferric citrate also was enhanced by loading the cells with dehydroascorbic acid. Dehydroascorbic acid was taken up rapidly by the cells and reduced to ascorbate, such that the latter reached intracellular concentrations as high as 6 mM. However, some ascorbate did escape the cells and could be detected at concentrations of up to 1 microM in the incubation medium. Further, addition of ascorbate oxidase almost reversed the effects of dehydroascorbic acid on both 55Fe uptake and ferric citrate reduction. Thus, it is likely that extracellular ascorbate reduced ferric to ferrous iron, which was then taken up by the cells. This hypothesis also was supported by the finding that during loading with ferric citrate, only extracellular ascorbate increased the pool of intracellular ferrous iron that could be chelated with cell-penetrant ferrous iron chelators. In contrast to its inhibition of ascorbate-dependent ferric iron reduction, ascorbate oxidase was without effect on ascorbate-dependent reduction of extracellular ferricyanide. This indicates that the cells use different mechanisms for reduction of ferric iron and ferricyanide. Therefore, extracellular ascorbate derived from cells can enhance transferrin-independent iron uptake by reducing ferric to ferrous iron, but intracellular ascorbate neither contributes to this reduction nor modifies the redox status of intracellular free iron.

Ascorbate 6-palmitate protects human erythrocytes from oxidative damage.

Lipid-soluble antioxidants, such as alpha-tocopherol, protect cell membranes from oxidant damage. In this work we sought to determine whether the amphipathic derivative of ascorbate, ascorbate 6-palmitate, is retained in the cell membrane of intact erythrocytes, and whether it helps to protect the cells against peroxidative damage. We found that ascorbate 6-palmitate binding to erythrocytes was dose-dependent, and that the derivative was retained during the multiple wash steps required for preparation of ghost membranes. Ascorbate 6-palmitate remained on the extracellular surface of the cells, because it was susceptible to oxidation or removal by several cell-impermeant agents. When bound to the surface of erythrocytes, ascorbate 6-palmitate reduced ferricyanide, an effect that was associated with generation of an ascorbyl free radical signal on EPR spectroscopy. Erythrocyte-bound ascorbate 6-palmitate protected membrane alpha-tocopherol from oxidation by both ferricyanide and a water-soluble free radical initiator, suggesting that the derivative either reacted directly with the exogenously added oxidant, or that it was able to recycle the alpha-tocopheroxyl radical to alpha-tocopherol in the cell membrane. Ascorbate 6-palmitate also partially protected cis-parinaric acid from oxidation when this fluorescent fatty acid was intercalated into the membrane of intact cells. These results show that an amphipathic ascorbate derivative is retained on the exterior cell surface of human erythrocytes, where it helps to protect the membrane from oxidant damage originating outside the cells.

[Western blotting of RStV gene products in rice and insects].

The NS3 and NC protein genes encoded by RNA3 of RStV, the NCP and NSvc4 protein genes encoded by RNA4 were subcloned into the E. coli expression vector pGEX3X to express four groups of fusion protein under IPTG induction. These fusion proteins were used to immunize rabbits to raise antisera. The antisera against the E. coli-expressed proteins were available for probing the presence of the viral gene products in both rice plant and insect hosts. The expected gene products can be probed only in diseased rice plant with NCP antiserum and the corresponding products detected in both plant and RStV particle preparation with NC antiserum. The viral gene products probed by NS3 and NSvc4 antisera were different from the expected ones in size.

Enzyme-dependent ascorbate recycling in human erythrocytes: role of thioredoxin reductase.

Human erythrocytes efficiently reduce dehydroascorbic acid (DHA) to ascorbate, which helps to maintain the ascorbate content of blood. Whereas erythrocyte DHA reduction is thought to occur primarily through a direct chemical reaction with GSH, this work addresses the role of enzyme-mediated DHA reduction by these cells. The ability of intact erythrocytes to recycle DHA to ascorbate, estimated as DHA-dependent ferricyanide reduction, was decreased in parallel with GSH depletion by glutathione-S-transferase substrates. In contrast, the sulfhydryl reagent phenylarsine oxide inhibited DHA reduction to a much greater extent than it decreased GSH in intact cells. DHA reduction in excess of that due to a direct chemical reaction with GSH was also observed in freshly prepared hemolysates. Hemolysates likewise showed NADPH-dependent reduction of DHA that appeared due to thioredoxin reductase, because this activity was inhibited 68% by 10 microM aurothioglucose, doubled by 5 microM E. coli thioredoxin, and had an apparent Km for DHA (1.5 mM) similar to that of purified thioredoxin reductase. Additionally, aurothioglucose-sensitive, NADPH-dependent DHA reductase activity was decreased 80% in hemolysates prepared from phenylarsine oxide-treated cells. GSH-dependent DHA reduction in hemolysates was more than 10-fold that of NADPH-dependent reduction. Nonetheless, the ability of phenylarsine oxide to decrease DHA reduction in intact cells with little effect on GSH suggests that enzymes, such as thioredoxin reductase, may contribute more to this activity than previously considered.

Erythrocyte ascorbate recycling: antioxidant effects in blood.

Ascorbic acid is an important antioxidant in human plasma, but requires efficient recycling from its oxidized forms to avoid irreversible loss. Human erythrocytes prevented oxidation of ascorbate in autologous plasma, an effect that required recycling of ascorbate within the cells. Erythrocytes had a high capacity to take up dehydroascorbate, the two-electron oxidized product of ascorbate, and to reduce it to ascorbate. Uptake and conversion of dehydroascorbate to ascorbate was saturable, was half-maximal at 400 microM dehydroascorbate, and achieved a maximal intracellular ascorbate concentration of 1.5 mM. In the presence of 100 microM dehydroascorbate, erythrocytes had the capacity to regenerate a 35 microM ascorbate concentration in blood every 3 min. Ascorbate recycling from DHA required intracellular GSH. Depletion of erythrocyte GSH by more than 50% with diamide did not acutely affect the cellular ascorbate content, but did impair the subsequent ability of GSH-depleted cells to recycle dehydroascorbate to ascorbate. Whereas erythrocyte ascorbate recycling was coupled to GSH, an overwhelming extracellular oxidant stress depleted both ascorbate and alpha-tocopherol before the GSH content of cells fell appreciably. Recycled ascorbate was released from cells into plasma, but at a rate less than one tenth that of dehydroascorbate uptake and conversion to ascorbate. Nonetheless, ascorbate released from cells protected endogenous alpha-tocopherol in human LDL from oxidation by a water soluble free radical initiator. These results suggests that recycling of ascorbate in erythrocytes helps to maintain the antioxidant reserve of whole blood.

Protection and recycling of alpha-tocopherol in human erythrocytes by intracellular ascorbic acid.

Ascorbic acid can recycle alpha-tocopherol from the tocopheroxyl free radical in lipid bilayers and in micelles, but such recycling has not been demonstrated to occur across cell membranes. In this work the ability of intracellular ascorbate to protect and to recycle alpha-tocopherol in intact human erythrocytes and erythrocyte ghosts was investigated. In erythrocytes that were 80% depleted of intracellular ascorbate by treatment with the nitroxide Tempol, both 2,2'-azobis(2-amidinopropane) dihydrochloride (AAPH) and ferricyanide oxidized alpha-tocopherol to a greater extent than in cells not depleted of ascorbate. In contrast, in erythrocytes in which the intracellular ascorbate concentration had been increased by loading with dehydroascorbate, loss of alpha-tocopherol was less with both oxidants than in control cells. Protection against AAPH-induced oxidation of alpha-tocopherol was not prevented by extracellular ascorbate oxidase, indicating that the protection was due to intracellular and not to extracellular ascorbate. Incubation of erythrocytes with lecithin liposomes also generated an oxidant stress, which caused lipid peroxidation in the liposomes and depleted erythrocyte alpha-tocopherol, leading to hemolysis. Ascorbate loading of the erythrocytes delayed liposome oxidation and decreased loss of alpha-tocopherol from both cells and from alpha-tocopherol-loaded liposomes. When erythrocyte ghosts were resealed to contain ascorbate and challenged with free radicals generated by AAPH outside the ghosts, intravesicular ascorbate was totally depleted over 1 h of incubation, whereas alpha-tocopherol decreased only after ascorbate was substantially oxidized. These results suggest that ascorbate within the erythrocyte protects alpha-tocopherol in the cell membrane by a direct recycling mechanism.

Interaction of ascorbate and alpha-tocopherol in resealed human erythrocyte ghosts. Transmembrane electron transfer and protection from lipid peroxidation.

A role for ascorbate-derived electrons in protection against oxidative damage to membrane lipids was investigated in resealed human erythrocyte ghosts. Incubation of resealed ghosts with the membrane-impermeant oxidant ferricyanide doubled the ghost membrane concentration of F2-isoprostanes, a sensitive marker of lipid peroxidation. Incorporation of ascorbate into ghosts during resealing largely prevented F2-isoprostane formation due to extravesicular ferricyanide. This protection was associated with a rapid transmembrane oxidation of intravesicular ascorbate by extravesicular ferricyanide. Transmembrane electron transfer, which was measured indirectly as ascorbate-dependent ferricyanide reduction, correlated with the content of alpha-tocopherol in the ghost membrane in several respects. First, ascorbate resealed within ghosts protected against ferricyanide-induced oxidation of endogenous alpha-tocopherol in the ghost membrane. Second, when exogenous alpha-tocopherol was incorporated into the ghost membrane during the resealing step, subsequent ferricyanide reduction was enhanced. Last, incubation of intact erythrocytes with soybean phospholipid liposomes, followed by resealed ghost preparation, caused a proportional decrease in both the membrane content of alpha-tocopherol and in ferricyanide reduction. Incorporation of exogenous alpha-tocopherol during resealing of ghosts prepared from liposome-treated cells completely restored the ferricyanide-reducing capacity of the ghosts. These results suggest that the transmembrane transfer of ascorbate-derived electrons in erythrocyte ghosts is dependent in part on alpha-tocopherol and that such transfer may help to protect the erythrocyte membrane against oxidant stress originating outside the cell.

Accessibility and reactivity of ascorbate 6-palmitate bound to erythrocyte membranes.

Lipophilic derivatives of ascorbic acid may protect lipid bilayers and micelles against lipid peroxidation. In this work the binding, accessibility, and reducing capacity of ascorbate 6-palmitate (A6P) were studied in human erythrocyte membranes. In contrast to less lipophilic carbon-6-modified ascorbate derivatives, A6P bound to erythrocyte membranes in a concentration-dependent manner. This binding was preserved following centrifugation washes, but was largely reversed by extraction with bovine serum albumin. Most of the ascorbyl groups of membrane-bound A6P were readily accessible to oxidation by water-soluble oxidants. Ferricyanide quantitatively oxidized membrane-bound A6P, but the latter spared endogenous tocopherols from destruction. In EPR studies, A6P was much more effective than ascorbate in reducing nitroxide spin labels positioned at either carbon-5 or carbon-16 of membrane-bound stearic acid in both intact cells and in membranes. A6P, thus, appears to intercalate into the erythrocyte membrane with the ascorbyl group located superficially, but with access to the hydrophobic membrane interior, and with the ability to recycle endogenous alpha-tocopherol during oxidant stress.

Ascorbate recycling in human erythrocytes: role of GSH in reducing dehydroascorbate.

Human erythrocytes regenerate ascorbate from its oxidized product, dehydroascorbate. The extent to which such ascorbate recycling occurs by a GSH-dependent mechanism was investigated. In the presence of glucose, erythrocytes took up over 90% of extracellular [14C]dehydroascorbate and rapidly converted it to [14C]ascorbate, which was trapped within the cells. Dehydroascorbate uptake and reduction was not associated with generation of a monoascorbyl free radical intermediate. Uptake and reduction of dehydroascorbate by glucose-depleted erythrocytes coordinately decreased GSH and raised GSSG concentrations in erythrocytes. This effect was reversed by D-glucose, but not by L-lactate. Conversely, depletion of cellular GSH decreased the ability of cells to recycle dehydroascorbate to ascorbate, as reflected in the extent to which cells were able to reduce extracellular ferricyanide. Monoascorbyl free radical was formed during the reduction of extracellular ferricyanide, indicating that one electron transfer steps were involved in this process. In GSH-depleted cells, addition of L-lactate as an energy source for glycolysis-dependent NADH regeneration did cause a partial recovery of the ability of cells to reduce ferricyanide. However, in resealed erythrocyte ghosts containing either 4 mM GSH or 400 mu M NADH, only the GSH-containing ghosts supported regeneration of ascorbate from added dehydroascorbate. These results suggest that in human erythrocytes ascorbate regeneration from dehydroascorbate is largely GSH dependent, and that it occurs through either enzymatic or nonenzymatic reactions not involving the monoascorbyl free radical.

Ascorbic acid recycling enhances the antioxidant reserve of human erythrocytes.

The role of ascorbate transport and metabolism in the response of human erythrocytes to an extracellular oxidant stress was investigated. Rates of entry and exit of [14C]dehydroascorbate from erythrocytes were more than 10-fold greater than those of [14C]ascorbate. Both the reduced and oxidized forms of the vitamin were transported largely by the glucose transporter. Inside erythrocytes, dehydroascorbate was converted to ascorbate, increasing intracellular ascorbate concentrations 2-3-fold over those in the medium. In such ascorbate-loaded cells, the membrane-impermeant oxidant ferricyanide induced a transmembrane oxidation of intracellular ascorbate to dehydroascorbate. The latter escaped the cells on the glucose transporter, which resulted in a halving of the net entry of [14C]dehydroascorbate in the presence of ferricyanide. Treatment of ascorbate-loaded cells with H2O2 and Cu2+ also oxidized ascorbate and induced efflux of [14C]dehydroascorbate. Ferricyanide-dependent intracellular oxidation of ascorbate resulted in a corresponding reduction of extracellular ferricyanide, which served as an integrated measure of ascorbate recycling. Ferricyanide reduction was proportional to the loading concentration of dehydroascorbate and was enhanced when loss of dehydroascorbate from cells was decreased, either by blockade of the glucose transporter or by concentrating the cells. Selective depletion of cellular ascorbate lowered rates of ferricyanide reduction by two-thirds, suggesting that ascorbate rather than NADH is the major donor for the transmembrane ferricyanide oxidoreductase activity. On the basis of the ascorbate-dependent rate of ferricyanide reduction, erythrocytes at a 45% hematocrit can regenerate the ascorbic acid present in whole blood every 3 min. Erythrocyte ascorbate recycling may thus contribute more to the antioxidant reserve of blood than is evident from plasma ascorbate concentrations alone.