Individual, culture-specific alterations in the human endothelial glutathione system: relationships to oxidant toxicity

Mitochondrial Uptake and Accumulation of Vitamin C: What Can We Learn from Cell Culture Studies?

SIGNIFICANCE

The mitochondrial fraction of l-ascorbic acid (AA) is of critical importance for the regulation of the redox status of these organelles and for cell survival. Recent Advances: Most cell types take up AA by the high-affinity sodium-dependent vitamin C transporter 2 (SVCT2) sensitive to inhibition by dehydroascorbic acid (DHA). DHA can also be taken up by glucose transporters (GLUTs) and then reduced back to AA. DHA concentrations, normally very low in biological fluids, may only become significant next to superoxide-releasing cells. Very little is known about the mechanisms mediating the mitochondrial transport of the vitamin.

CRITICAL ISSUES

Information on AA transport is largely derived from studies using cultured cells and is therefore conditioned by possible cell culture effects as overexpression of SVCT2 in the plasma membrane and mitochondria. Mitochondrial SVCT2 is susceptible to inhibition by DHA and transports AA with a low affinity as a consequence of the restrictive ionic conditions. In some cells, however, high-affinity mitochondrial transport of AA is observed. Mitochondrial uptake of DHA may take place through GLUTs, an event followed by its prompt reduction to AA in the matrix. Intracellular levels of DHA are, however, normally very low.

FUTURE DIRECTIONS

We need to establish, or rule out, the role and significance of mitochondrial SVCT2 in vivo. The key question for mitochondrial DHA transport is instead related to its very low intracellular concentrations.

Oxidative stress in cell culture: an under-appreciated problem?

Cell culture studies have given much valuable information about mechanisms of metabolism and signal transduction and of regulation of gene expression, proliferation, senescence, and death. However, cells in culture may behave differently from cells in vivo in many ways. One of these is that cell culture imposes a state of oxidative stress on cells. I argue that cells that survive and grow in culture might use ROS-dependent signal transduction pathways that rarely or never operate in vivo. A further problem is that cell culture media can catalyse the oxidation of compounds added to them, resulting in apparent cellular effects that are in fact due to oxidation products such as ROS. Such artefacts may have affected many studies on the effects of ascorbate, thiols, flavonoids and other polyphenolic compounds on cells in culture.

Selenoprotein expression in endothelial cells from different human vasculature and species

Selenium (Se) can protect endothelial cells (EC) from oxidative damage by altering the expression of selenoproteins with antioxidant function such as cytoplasmic glutathione peroxidase (cyGPX), phospholipid hydroperoxide glutathione peroxidase (PHGPX) and thioredoxin reductase (TR). If the role of Se on EC function is to be studied, it is essential that a model system be chosen which reflects selenoprotein expression in human EC derived from vessels prone to developing atheroma. We have used [75Se]-selenite labelling and selenoenzyme measurements to compare the selenoproteins expressed by cultures of EC isolated from different human vasculature with EC bovine and porcine aorta. Only small differences were observed in selenoprotein expression and activity in EC originating from human coronary artery, human umbilical vein (HUVEC), human umbilical artery and the human EC line EAhy926. The selenoprotein profile in HUVEC was consistent over eight passages and HUVEC isolated from four cords also showed little variability. In contrast, EC isolated from pig and bovine aorta showed marked differences in selenoprotein expression when compared to human cells. This study firmly establishes the suitability and consistency of using HUVEC (and possibly the human cell line EAhy926) as a model to study the effects of Se on EC function in relation to atheroma development in the coronary artery. Bovine or porcine EC appear to be an inappropriate model.

Ascorbate and glutathione homeostasis in vascular smooth muscle cells: cooperation with endothelial cells

Human umbilical vein smooth muscle cells (HUVSMCs) utilize extracellular cystine, glutathione (GSH), and N-acetylcysteine (NAC) to synthesize cellular GSH. Extracellular cystine was effective from 5 microM, whereas GSH and NAC were required at 100 microM for comparable effects. The efficacy of extracellular GSH was dependent on de novo GSH synthesis, indicating a dependence on cellular gamma-glutamyltransferase (glutamyl transpeptidase). Coculture of syngenetic HUVSMCs and corresponding human umbilical vein endothelial cells (HUVECs) on porous supports restricted cystine- or GSH-stimulated synthesis of HUVSMC GSH when supplied on the "luminal" endothelial side. Thus HUVSMC GSH rapidly attained a steady-state level below that achieved in the absence of interposed HUVECs. HUVSMCs also readily utilize both reduced ascorbate (AA) and oxidized dehydroascorbate (DHAA) over the range 50-500 microM. Phloretin effectively blocked both AA- and DHAA-stimulated assimilation of intracellular AA, indicating a role for a glucose transporter in their transport. Uptake of extracellular AA was also sensitive to extracellular, but not intracellular, thiol depletion. When AA was applied to the endothelial side of the coculture model, assimilation of intracellular AA in HUVSMCs was restricted to a steady-state level below that achieved by free access.

Fructus corni enhances endothelial cell antioxidant defenses

1. The present study determined the effects of Fructus corni extract (FCE) on the levels of hydrogen peroxide (H2O2) and superoxide anion (O2-), on the glutathione (GSH) redox cycle and on the activities of antioxidant enzymes in bovine pulmonary artery endothelial cells (PAECs). 2. Confluent monolayers of PAECs were incubated with FCE, and oxidative stress was triggered by hypoxanthine and xanthine oxidase (to induce H2O2) or H2O2 (to induce O2-). 3. FCE exhibited a concentration-dependent suppression of H2O2 and O2-. 4. It modulated the GSH redox cycle by increasing the intracellular GSH content, the activities of GSH peroxidase and GSH disulfide reductase, and by decreasing the intracellular level of GSH disulfide. 5. It also increased the activities of superoxide dismutase and catalase. 6. These results demonstrate that FCE can promote a protective antioxidant defense state by affecting some important enzymatic and nonenzymatic oxidant-scavenging systems and may thus be useful for the prevention or treatment of disorders associated with oxidative damage.

The uptake of ascorbic acid into human umbilical vein endothelial cells and its effect on oxidant insult

Intracellular reduced ascorbate (AA) levels in confluent cultures of human umbilical vein endothelial (HUVE) cells, grown under conventional conditions, were shown to be very low, ranging between undetectable, < 0.1 nmol/mg protein, and 0.3 nmol/mg protein. Reduced ascorbate was accumulated into the endothelial cells from M199 culture medium in time- and concentration-dependent manners, and was saturated at medium concentrations related to the normal plasma concentrations of the antioxidant (i.e. between 50 microM and 100 microM). Cells derived from different individuals demonstrated considerable inter-individual variation in these AA uptake parameters. The uptake of AA was sensitive to temperature and the presence of the structural analogue isoascorbate in the medium, indicating the involvement of an active transport mechanism. A role for the glucose transporter is, however, not indicated, as AA uptake was not sensitive to phloretin, an inhibitor of the cellular glucose transporter, nor greatly enhanced by depletion of glucose from the medium. Incubation of HUVE cells with dehydroascorbate (DHAA) caused a dose-dependent, but transient increase in intracellular AA. This indicates that HUVE cells are both competent in the uptake and intracellular reduction of oxidised ascorbate, and may resecrete AA into the medium. Indeed, reduced ascorbate in the medium was shown to be preferentially maintained in the presence of cells. The uptake of AA was not sensitive to the presence of DHAA in the medium, perhaps indicating different transporters for reduced and oxidised forms of ascorbate in these human cells. Pre-loading HUVE cells with AA was shown to protect control cells only weakly from the acute, sub-lethal toxicity of H2O2 generated by xanthine oxidase (1 U/mL or 10 U/mL). Protection was optimal at intracellular levels of 3-4 nmol AA/mg protein, with higher concentrations lacking a protective effect. Additionally, the presence of the iron chelator, desferoxamine, significantly protected GSH-depleted HUVE cells only in response to the peroxide, but did not potentiate the protective action of intracellular AA in either control or GSH-depleted cells. This indicates that ascorbate-driven redox-cycling of the Fe2+/Fe3+ does not hamper the intracellular protective function of ascorbate during hydrogen peroxide-derived oxidative stress. These results are discussed in terms of the central role of endothelial cells in the distribution of AA to the tissues of the body, the use of the HUVE cell system for model studies of the toxicity of oxidants in the human endothelium, and the balance between the antioxidant and pro-oxidant actions of AA.