Free zinc inhibits transport of vitamin C in differentiated HL-60 cells during respiratory burst

Zinc is an essential trace element for the immune system. It is known to be essential for highly proliferating cells, especially for cells of the immune system. However, zinc and other divalent cations are known to inhibit the human neutrophilic NADPH oxidase. Differentiated HL-60 cells were found to accumulate large quantities of vitamin C (ascorbate) after activation of the NADPH oxidase by phorbol esters (PMA). This increase in vitamin C transport is due to the generation of superoxide and subsequent oxidation of ascorbate to dehydroascorbate (DHA) which is preferentially taken up by the cells. We found that zinc reversibly inhibits both PMA-stimulated ascorbate uptake and superoxide generation with a half-maximal effect at 20 microM of free zinc ions. Higher residual extracellular ascorbate concentrations were measured with increasing zinc concentrations, indicating that less ascorbate was oxidized and taken up by the cells. When the fluorescent dye diSC3(5) was used to monitor shifts in membrane potential, we found that depolarization with PMA was prolonged after preincubation of the cells with zinc. Suppression of the respiratory burst as well as inhibition of the uptake of the antioxidant vitamin C may disturb the balance between oxidative damage of invading particles and antioxidant protection in activated neutrophils.     

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.     

Macrophage uptake and recycling of ascorbic acid: response to activation by lipopolysaccharide

To test whether ascorbic acid might be involved in the antioxidant defenses of inflammatory cells, we studied ascorbate uptake and recycling by quiescent and lipopolysaccharide-activated RAW264.7 murine macrophages. These cells concentrated ascorbate 100-fold in overnight culture, achieving steady-state concentrations of more than 10 mM at extracellular concentrations of 20-100 muM. This steep gradient was generated by high-affinity sodium-dependent ascorbate transport. The latter likely reflects function of the SVCT2 (SLC23A2), since this protein was detected on immunoblots. Dehydroascorbate, the two-electron oxidized form of ascorbate, was also taken up and reduced to ascorbate by the cells. Dehydroascorbate reduction required rapid recycling of GSH from GSSG by glutathione reductase. Activation of ascorbate-containing macrophages with lipopolysaccharide transiently depleted intracellular ascorbate without affecting GSH. Recovery of intracellular ascorbate required function of the SVCT2 transporter, the activity of which was modestly enhanced by lipopolysaccharide. Lipopolysaccharide treatment nearly doubled intracellular GSH concentrations over 2 h. Despite lipopolysaccharide-induced oxidant stress, this GSH increase was associated with a comparable increase in reduction of dehydroascorbate to ascorbate. These results show that macrophages maintain millimolar concentrations of ascorbate through function of the SVCT2 and that activated cells have an enhanced ability to transport and recycle ascorbate, possibly reflecting its role as an intracellular antioxidant.     

Role of ascorbate in oxidative protein folding

Both in prokaryotic and eukaryotic cells, disulfide bond formation (oxidation and isomerization steps) are catalyzed exclusively in extracytoplasmic compartments. In eukaryotes, protein folding and disulfide bond formation are coupled processes that occur both co- and posttranslationally in the endoplasmic reticulum (ER), which is the main site of the synthesis and posttranslational modification of secretory and membrane proteins. The formation of a disulfide bond from the thiol groups of two cysteine residues requires the removal of two electrons, consequently, these bonds cannot form spontaneously; an oxidant is needed to accept the electrons. In aerobic conditions the ultimate electron acceptor is usually oxygen; however, oxygen itself is not effective in protein thiol oxidation. Therefore, a small molecular weight membrane permeable compound should be supposed for the transfer of electrons from the ER lumen. The aim of the present study was the investigation of the role of ascorbate/dehydroascorbate redox couple in oxidative folding of proteins. We demonstrated that ascorbate addition or its in situ synthesis from gulonolactone results in protein thiol (and/or glutathione; GSH) oxidation in rat liver microsomes. Since microsomal membrane is hardly permeable to ascorbate, the existence of a transport metabolon was hypothesized. Three components of the system have been described and partially characterized: (i) A microsomal metalloenzyme is responsible for ascorbate oxidation on the outer surface of the ER. Ascorbate oxidation results in ascorbate free radical and dehydroascorbate production. (ii) Facilitated diffusion of dehydroascorbate is present in microsomal vesicles. The transport is presumably mediated by a GLUT-type transporter. On the contrary, the previously hypothesized glutathione disulfide (GSSG) transport is practically absent, while GSH is transported with a moderate velocity. (iii) Protein disulfide isomerase catalyzes the reduction of dehydroascorbate in the ER lumen. Both GSH and protein thiols can be electron donors in the process. Intraluminal dehydroascorbate reduction and the consequent ascorbate accumulation strictly correlate with protein disulfide isomerase activity and protein thiol concentration. The concerted action of the three components of the system results in the intraluminal accumulation of ascorbate, protein disulfide and GSSG. In fact, intraluminal ascorbate and GSSG accumulation could be observed upon dehydroascorbate and GSH uptake. In conclusion, ascorbate is able to promote protein disulfide formation in an in vitro system. Further work is needed to justify its role in intact cellular and in vivo systems, as well as to explore the participation of other antioxidants (e.g. tocopherol, ubiquinone, and vitamin K) in the electron transfer chain responsible for oxidative protein folding in the ER.     

Vitamin C modulates glutamate transport and NMDA receptor function in the retina

Vitamin C (in the reduced form ascorbate or in the oxidized form dehydroascorbate) is implicated in signaling events throughout the central nervous system (CNS ). In the retina, a high‐affinity transport system for ascorbate has been described and glutamatergic signaling has been reported to control ascorbate release. Here, we investigated the modulatory role played by vitamin C upon glutamate uptake and N ‐methyl‐d ‐aspartate (NMDA ) receptor activation in cultured retinal cells or in intact retinal tissue using biochemical and imaging techniques. We show that both forms of vitamin C, ascorbate or dehydroascorbate, promote an accumulation of extracellular glutamate by a mechanism involving the inhibition of glutamate uptake. This inhibition correlates with the finding that ascorbate promotes a decrease in cell surface levels of the neuronal glutamate transporter excitatory amino acid transporter 3 in retinal neuronal cultures. Interestingly, vitamin C is prone to increase the activity of NMDA receptors but also promotes a decrease in glutamate‐stimulated [³H] MK 801 binding and decreases cell membrane content of NMDA receptor glutamate ionotropic receptor subunit 1 (GluN1) subunits. Both compounds were also able to increase cAMP response element‐binding protein phosphorylation in neuronal nuclei in a glutamate receptor and calcium/calmodulin kinase‐dependent manner. Moreover, the effect of ascorbate is not blocked by sulfinpyrazone and then does not depend on its uptake by retinal cells. Overall, these data indicate a novel molecular and functional target for vitamin C impacting on glutamate signaling in retinal neurons.

     

Glutamate receptors modulate sodium-dependent and calcium-independent vitamin C bidirectional transport in cultured avian retinal cells

Vitamin C is transported in the brain by sodium vitamin C co‐transporter 2 (SVCT‐2) for ascorbate and glucose transporters for dehydroascorbate. Here we have studied the expression of SVCT‐2 and the uptake and release of [¹⁴C] ascorbate in chick retinal cells. SVCT‐2 immunoreactivity was detected in rat and chick retina, specially in amacrine cells and in cells in the ganglion cell layer. Accordingly, SVCT‐2 was expressed in cultured retinal neurons, but not in glial cells. [¹⁴C] ascorbate uptake was saturable and inhibited by sulfinpyrazone or sodium‐free medium, but not by treatments that inhibit dehydroascorbate transport. Glutamate‐stimulated vitamin C release was not inhibited by the glutamate transport inhibitor l ‐β‐threo‐benzylaspartate, indicating that vitamin C release was not mediated by glutamate uptake. Also, ascorbate had no effect on [³H] d ‐aspartate release, ruling out a glutamate/ascorbate exchange mechanism. 2‐Carboxy‐3‐carboxymethyl‐4‐isopropenylpyrrolidine (Kainate) or NMDA stimulated the release, effects blocked by their respective antagonists 6,7‐initroquinoxaline‐2,3‐dione (DNQX) or (5R,2S)‐(1)‐5‐methyl‐10,11‐dihydro‐5H‐dibenzo[a,d]cyclohepten‐5,10‐imine hydrogen maleate (MK‐801). However, DNQX, but not MK‐801 or 2‐amino‐5‐phosphonopentanoic acid (APV), blocked the stimulation by glutamate. Interestingly, DNQX prevented the stimulation by NMDA, suggesting that the effect of NMDA was mediated by glutamate release and stimulation of non‐NMDA receptors. The effect of glutamate was neither dependent on external calcium nor inhibited by 1,2‐bis (2‐aminophenoxy) ethane‐N′,N′,N′,N′,‐tetraacetic acid tetrakis (acetoxy‐methyl ester) (BAPTA‐AM), an internal calcium chelator, but was inhibited by sulfinpyrazone or by the absence of sodium. In conclusion, retinal cells take up and release vitamin C, probably through SVCT‐2, and the release can be stimulated by NMDA or non‐NMDA glutamate receptors.     

Facilitated glucose and dehydroascorbate transport in plant mitochondria

Ascorbate, dehydroascorbate, and glucose transport was investigated in plant mitochondria and mitoplasts prepared from cultured BY2 tobacco cells. Using a rapid filtration method with radiolabeled ligands, we observed a specific glucose and dehydroascorbate transport, which was temperature and time dependent and saturable. Inhibition of mitochondrial respiration by KCN and the uncoupler 2,4-dinitrophenol did not influence the transport of the investigated compounds. Dehydroascorbate transport was inhibited by glucose and genistein, while glucose uptake was decreased upon 3-O-methyl-glucose, D-mannose, cytochalasin B or genistein addition. On the other hand, a low affinity low capacity ascorbate transport was found. Oxidizing agents (potassium ferricyanide or ascorbate oxidase) increased ascorbate uptake. The results demonstrate the presence of dehydroascorbate and glucose transport in plant mitochondria and suggest that it is mediated by the same or closely related transporter(s).     

Characterization of the ascorbic acid transport by 3T6 fibroblasts

Ascorbic acid transport by 3T6 mouse skin fibroblasts has been characterized using radiometric technique with L-[1-14C]ascorbic acid under the conditions in which oxidation of ascorbic acid was prevented by addition of 1 mM thiourea. The ascorbate transport is temperature-dependent with the energy of activation E and Q10 of 13.3 kcal/mol and 2.0, respectively. The transport requires energy and exhibits Michaelis-Menten kinetics with an apparent Km of 112 microM and Vmax of 158 pmol/min per mg protein, when the extracellular Na+ concentration is 150 mM. The ascorbate transport requires presence of extracellular Na+ and can be inhibited by ouabain treatment. At 40 and 200 microM ascorbate concentrations, respectively, 1.4 and 1.0 moles of Na+ bound the transporter molecule per each mole of ascorbate transported. Increased Na+ binding to the transporter at lower ascorbate concentration may signify multiple Na+-binding sites or ascorbate concentration dependent conformational changes in the transporter molecule. Increasing Na+ concentration decreases Km without affecting Vmax, suggesting that Na+ increases affinity of ascorbate for the transporter molecule without affecting translocation process. An increase in ascorbate concentration reduces the number of Na+ bound to the transporter from 1.4 to 1.0. The ascorbate transport is stimulated by Ca2+ and other divalent cations. The mechanism of stimulation by Ca2+ is not clear. Calcium increases both the Km and Vmax. The data presented support the hypothesis that the ascorbate transport by 3T6 fibroblasts is an energy and temperature-dependent active process driven by the Na+ electrochemical gradient. A potent inhibitor of ascorbate transport is also demonstrated in human serum.     

The methanogenic archaeon Methanosarcina thermophila TM-1 possesses a high-affinity glycine betaine transporter involved in osmotic adaptation.

Methanogenic Archaea are found in a wide range of environments and use several strategies to adjust to changes in extracellular solute concentrations. One methanogenic archaeon, Methanosarcina thermophila TM-1, can adapt to various osmotic conditions by synthesis of alpha-glutamate and a newly discovered compatible solute, Ne-acetyl-beta-lysine, or by accumulation of glycine betaine (betaine) and potassium ions from the environment. Since betaine transport has not been characterized for any of the methanogenic Archaea, we examined the uptake of this solute by M. thermophila TM-1. When cells were grown in mineral salts media containing from 0.1 to 0.8 M NaC1, M. thermophila accumulated betaine in concentrations up to 140 times those of a concentration gradient within 10 min of exposure to the solute. The betaine uptake system consisted of a single, high-affinity transporter with an apparent K3 of 10 microM and an apparent maximum transport velocity of 1.15 nmol/min/mg of protein. The transporter appeared to be specific for betaine, since potential substrates, including glycine, sarcosine, dimethyl glycine, choline, and proline, did not significantly inhibit betaine uptake. M. thermophila TM-1 cells can also regulate the capacity for betaine accumulation, since the rate of betaine transport was reduced in cells pregrown in a high-osmolarity medium when 500 microM betaine was present. Betaine transport appears to be H+ and/or Na+ driven, since betaine transport was inhibited by several types of protonophores and sodium ionophores.     

Na+-linked active transport of ascorbate into cultured bovine retinal pigment epithelial cells: heterologous inhibition by glucose

The transport of ascorbate into cultured bovine retinal pigment epithelial (RPE) cells is reported. Primary or subcultured RPE cells were incubated in the presence of 10-500 microM L-[carboxyl-14C]-ascorbate for various periods of time. Accumulation of ascorbate into RPE cells followed a saturable active transport with a Km of 125 microM and a Vmax of 28 pmole/micrograms DNA/min. RPE intracellular water was calculated to be 0.8 pL/cell, and the transported cellular ascorbate concentration was 7.5 +/- 0.8 mM. Replacement of 150 mM NaCl in the incubation media with choline-Cl strongly inhibited (80 +/- 8%) ascorbate uptake into cultured RPE cells. Although the depletion of cellular ATP by 2,4-dinitrophenol and the inhibition of Na+-K+-ATPase by ouabain reduced ascorbate transport into RPE significantly, active transport of ascorbate was not entirely inhibited by these metabolic inhibitors. The ascorbate analogue, D-isoascorbate, competitively inhibited ascorbate transport into cultured RPE with a Ki of 12.5 mM. Cells grown in the presence of 5 to 50 mM alpha-D-glucose in the growth media did not differ in their ability to transport ascorbate. In contrast, the presence of alpha-D-glucose or its nonmetabolizable analogues, 3-0-methyl-glucose, alpha-methyl-glucose, and 2-deoxy-glucose, but not L-glucose or beta-D-fructose, in the incubation media inhibited ascorbate transport. myo-Inositol (10 or 20 mM) also inhibited ascorbate transport into RPE cells. The active uptake of ascorbate into cultured RPE cells was primarily coupled to the movement of sodium ion down its electrochemical gradient. A bifunctional, cotransport carrier possessing an ascorbate-binding site and a sodium-binding site may be involved in the ascorbate uptake system. The inhibition of ascorbate uptake by sugars appeared to be heterologous in nature, occurring between two distinct carrier systems, both of which were dependent on the sodium ions.     

Ascorbate Transport and Recycling by SH-SY5Y Neuroblastoma Cells: Response to Glutamate Toxicity

Neurons maintain relatively high intracellular concentrations of vitamin C, or ascorbic acid. In this work we studied the mechanisms by which neuronal cells in culture transport and maintain ascorbate, as well as how this system responds to oxidant stress induced by glutamate. Cultured SH-SY5Y neuroblastoma cells took up ascorbate, achieving steady-state intracellular concentrations of 6 mM and higher at extracellular concentrations of 200 μM and greater. This gradient was generated by relatively high affinity sodium-dependent ascorbate transport (K _m of 113 μM). Ascorbate was also recycled from dehydroascorbate, the reduction of which was dependent on GSH, but not on d-glucose. Glutamate in concentrations up to 2 mM caused an acute concentration-dependent efflux of ascorbate from the cells, which was prevented by the anion channel blocker 4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid. Intracellular ascorbate did not affect radiolabeled glutamate uptake, showing absence of heteroexchange.     

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.     

Protein-disulfide isomerase- and protein thiol-dependent dehydroascorbate reduction and ascorbate accumulation in the lumen of the endoplasmic reticulum

The transport and intraluminal reduction of dehydroascorbate was investigated in microsomal vesicles from various tissues. The highest rates of transport and intraluminal isotope accumulation (using radiolabeled compound and a rapid filtration technique) were found in hepatic microsomes. These microsomes contain the highest amount of protein-disulfide isomerase, which is known to have a dehydroascorbate reductase activity. The steady-state level of intraluminal isotope accumulation was more than 2-fold higher in hepatic microsomes prepared from spontaneously diabetic BioBreeding/Worcester rats and was very low in fetal hepatic microsomes although the initial rate of transport was not changed. In these microsomes, the amount of protein-disulfide isomerase was similar, but the availability of protein thiols was different and correlated with dehydroascorbate uptake. The increased isotope accumulation was accompanied by a higher rate of dehydroascorbate reduction and increased protein thiol oxidation in microsomes from diabetic animals. The results suggest that both the activity of protein-disulfide isomerase and the availability of protein thiols as reducing equivalents can play a crucial role in the accumulation of ascorbate in the lumen of the endoplasmic reticulum. These findings also support the fact that dehydroascorbate can act as an oxidant in the protein-disulfide isomerase-catalyzed protein disulfide formation.     

Role of vitamin E in ascorbate-dependent protein thiol oxidation in rat liver endoplasmic reticulum

Addition of ascorbate or its generation from gulonolactone causes the oxidation of protein thiols and a simultaneous dehydroascorbate formation in rat liver microsomes. The participation of vitamin E in the phenomenon was studied. We measured ascorbate and protein thiol oxidation and lipid peroxidation in vitamin E deficient liver microsomes. Vitamin E deficiency partly uncoupled the two processes: ascorbate oxidation increased, while protein thiol oxidation decreased. These changes were accompanied with an accelerated lipid peroxidation in the vitamin E-deficient microsomes, which indicates the accumulation of reactive oxygen species. All these effects were reduced by the in vitro addition of vitamin E to the deficient microsomes, supporting its direct role in the process. The results demonstrate that vitamin E is a component of the protein thiol oxidizing machinery in the hepatic endoplasmic reticulum transferring electrons from the thiol groups towards oxygen.     

Stimulation of the pentose phosphate pathway and glutathione levels by dehydroascorbate, the oxidized form of vitamin C.

Ascorbic acid, or vitamin C, generally functions as an antioxidant by directly reacting with reactive oxygen intermediates and has a vital role in defenses against oxidative stress. However, ascorbic acid also has pro-oxidant properties and may cause apoptosis of lymphoid and myeloid cells. The present study shows that dehydroascorbate, the oxidized form of vitamin C, stimulates the antioxidant defenses of cells, preferentially importing dehydroascorbate over ascorbate. While 200-800 microM vitamin C caused apoptosis of Jurkat and H9 human T lymphocytes, pretreatment with 200-1000 microM dehydroascorbate stimulated activity of pentose phosphate pathway enzymes glucose 6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, and transaldolase, elevated intracellular glutathione levels, and inhibited H(2)O(2)-induced changes in mitochondrial transmembrane potential and cell death. A 3. 3-fold maximal glutathione elevation was observed after 48 h stimulation with 800 microM dehydroascorbate. In itself, dehydroascorbate did not affect cytosolic or mitochondrial reactive oxygen intermediate levels as monitored by flow cytometry using oxidation-sensitive fluorescent probes. The data reveal a novel mechanism for increasing glutathione levels through stimulation of the pentose phosphate pathway and identify dehydroascorbate as an antioxidant for cells susceptible to the pro-oxidant and proapoptotic properties of vitamin C.     

Ascorbate uptake in normal and diabetic rat retina and retinal pigment epithelium

Oxidative stress is an important causative factor in the pathogenesis of diabetic retinopathy. Therefore, it becomes important to understand the mechanisms that help maintain appropriate levels of a small molecule antioxidant such as ascorbate in the retina. The outer blood-barrier which results from the tight junctions between the retinal pigment epithelial cells (RPE) restricts the flow of nutrients reaching the retina. In this study, we characterized the transport properties of carboxyl-(14)C ascorbate (AA) in normal rat retina and RPE, and compared them with those in streptozotocin-diabetic rats. Retina and RPE accumulated AA by a temperature-sensitive and energy-dependent kinetic mechanism with an apparent K(M) of 380 and 420 microM, respectively. Accumulation of AA was significantly reduced in a sodium-free medium. Although high glucose concentrations reduced AA uptake by 40%, this was not affected by cytochalasin B. The RPE and retina of diabetic rats presented lower levels of AA accumulation. These findings suggest the presence of the specific vitamin C transporter SVCT in retina and RPE, which may be involved in the manifestation of diabetic retinopathy.     

Ascorbate Transport and Intracellular Concentration in Cerebral Astrocytes

Abstract: Regulation of the initial rate of uptake and steady-state concentration of ascorbate (reduced vitamin C) was investigated in rat cerebral astrocytes. Although these cells did not synthesize vitamin C, they accumulated millimolar concentrations of ascorbate when incubated with medium containing the vitamin at a level (200 µ M ) typical of brain extracellular fluid. Initial rate of [¹⁴C]-ascorbate uptake and intracellular ascorbate concentration were dependent on extracellular Na⁺ and sensitive to the anion transport inhibitor sulfinpyrazone. Comparison of the efflux profiles of ascorbate and 2',7'-bis(carboxyethyl)-5 (or -6)-carboxyfluorescein from astrocytes permeabilized with digitonin localized most intracellular ascorbate to the cytosol. Pretreatment of astrocytes with dibutyryl cyclic AMP (dBcAMP) doubled their initial rate of sulfinpyrazone-sensitive [¹⁴C]ascorbate uptake compared with cells treated with either n -butyric acid or vehicle. dBcAMP also increased steady-state intracellular ascorbate concentration by 39%. The relatively small size of the change in astrocytic ascorbate concentration was explained by the finding that dBcAMP increased the rate of efflux of the vitamin from ascorbate-loaded cells. These results indicate that uptake and efflux pathways are stimulated by cyclic AMP-dependent mechanisms and that they regulate the cytosolic concentration of ascorbate in astrocytes.     

Plasma membrane gamma-glutamyltransferase activity facilitates the uptake of vitamin C in melanoma cells

Adequate cellular transport of ascorbic acid (AA) and its oxidation product dehydroascorbate (DHA) is assured through specific carriers. It was shown that vitamin C is taken up as DHA by most cell types, including cancer cells, via the facilitative GLUT transporters. Thus, AA oxidation to DHA can be considered a mechanism favoring vitamin C uptake and intracellular accumulation. We have investigated whether such an AA-oxidizing action might be provided by plasma membrane gamma-glutamyltransferase (GGT), previously shown to function as an autocrine source of prooxidants. The process was studied using two distinct human metastatic melanoma clones. It was observed that the Me665/2/60 clone, expressing high levels of membrane GGT activity, was capable of effecting the oxidation of extracellular AA, accompanied by a marked increase of intracellular AA levels. The phenomenon was not observed with Me665/2/21 cells, possessing only traces of membrane GGT. On the other hand, AA oxidation and stimulation of cellular uptake were indeed observed after transfection of 2/21 cells with cDNA coding for GGT. The mechanism of GGT-mediated AA oxidation was investigated in acellular systems, including GGT and its substrate glutathione. The process was observed in the presence of redox-active chelated iron(II) and of transferrin or ferritin, i.e., two physiological iron sources. Thus, membrane GGT activity-often expressed at high levels in human malignancies-can oxidize extracellular AA and promote its uptake efficiently.