Ascorbate promotes the cellular accumulation of doxorubicin and reverses the multidrug resistance in breast cancer cells by inducing ROS-dependent ATP depletion.

Chemotherapy is the most effective strategy for the treatment of metastatic breast cancer. However, P-glycoprotein (P-gp)-mediated multidrug resistance severely limits the efficacy of chemotherapy and is a major cause of the failure during chemotherapeutic treatment. In this study, we investigated the anticancer effects of combining chemotherapeutic drugs with ascorbate (AA) in human breast cancer cells. We found that combined administration of AA can improve the sensitivity of both MCF-7 and doxorubicin (Dox)-resistant MCF-7/Adr cells to Dox in vitro and in vivo by a reactive oxygen species (ROS)-dependent mechanism. Further studies proved that AA can promote the accumulation of Dox in MCF-7/Adr cells when combined with doxorubicin. AA had no effect on the expression of P-gp at the mRNA and protein levels, but could decrease its activity as demonstrated by an obvious inhibition of efflux of P-gp substrate Rh 123. AA reduced ATP levels in both MCF-7 and MCF-7/Adr cells, and pretreating AA-stimulating cells with catalase completely rescued ATP levels. With ATP reduction, we observed an increased cellular calcium and the appearance of vacuoles and micropores on the cell surface, indicating the increased cell membrane permeability in AA-treated MCF-7/Adr cells. The above results suggest that AA could promote the cellular accumulation of doxorubicin by inducing ROS-dependent ATP depletion. Clinically, a combination of AA with doxorubicin would be a novel strategy for reversal of the multidrug resistance in human breast cancer cells during chemotherapy.

Metabolism of nitroxide spin labels in subcellular fractions of rat liver. II. Reduction in the cytosol.

As part of an ongoing study of the role of subcellular fractions on the metabolism of nitroxides, we studied the metabolism of a set of five nitroxides in cytosol derived from rat hepatocytes. The nitroxides were chosen to provide information on the effects of the type of charge and the ring on which the nitroxyl group is located. The rates of reduction were fastest for a six-membered positively charged nitroxide ('CAT-1') and slowest for an anionic five-membered ring nitroxide ('PCA'). Changing levels of glutathione, sulphydryl groups in general, NADPH or NADH had little or no effect on the rates of reduction, while the addition of ascorbate oxidase essentially abolished reduction of the nitroxides. The products of reduction by the cytosol were the corresponding hydroxylamines. The overall rates of reduction of neutral or anionic nitroxides were much slower than those observed with intact cells. We conclude that the primary source of metabolism of nitroxides by cytosol is reduction by ascorbate and that under most conditions reduction of nitroxides in the cytosol is not a major factor in the metabolism of nitroxides by cells.

NO2 reactive absorption substrates in rat pulmonary surface lining fluids.

Inhaled 'NO2 is absorbed by a free radical-dependent reaction mechanism that localizes the initial oxidative events to the extracellular space of the pulmonary surface lining layer (SLL). Because 'NO2 per se is eliminated upon absorption, most likely the SLL-derived reaction products are critical to the genesis of 'NO2-induced lung injury. We utilized analysis of the rate of 'NO2 disappearance from the gas phase to determine the preferential absorption substrates within rat SLL. SLL was obtained via bronchoalveolar lavage and was used either as the cell-free composite or after constituent manipulation [(i) dialysis, treatment with (ii) N-ethylmaleimide, (iii) ascorbate oxidase, (iv) uricase, or (v) combined ii + iii]. Specific SLL constituents were studied in pure chemical systems. Exposures were conducted under conditions where 'NO2 is the limiting reagent and disappears with first-order kinetics ([NO2]0 < or = 10 ppm). Reduced glutathione and ascorbate were the principle rat SLL absorption substrates. Nonsulfhydryl amino acids and dipalmitoyl phosphatidylcholine exhibited negligible absorption activity. Whereas uric acid and vitamins A and E displayed rapid absorption kinetics, their low SLL concentrations preclude appreciable direct interaction. Unsaturated fatty acids may account for < or = 20% of absorption. The results suggest that water soluble, low molecular weight antioxidants are the preferential substrates driving 'NO2 absorption. Consequently, their free radicals, produced as a consequence of 'NO2 exposure, may participate in initiating the 'NO2-induced cascade, which results in epithelial injury.

Ascorbate does not act as a pro-oxidant towards lipids and proteins in human plasma exposed to redox-active transition metal ions and hydrogen peroxide.

The combination of ascorbate, transition metal ions, and hydrogen peroxide (H(2)O(2)) is an efficient hydroxyl radical generating system called "the Udenfriend system." Although the pro-oxidant role of ascorbate in this system has been well characterized in vitro, it is uncertain whether ascorbate also acts as a pro-oxidant under physiological conditions. To address this question, human plasma, used as a representative biological fluid, was either depleted of endogenous ascorbate with ascorbate oxidase, left untreated, or supplemented with 25 microM-1 mM ascorbate. Subsequently, the plasma samples were incubated at 37 degrees C with 50 microM-1 mM iron (from ferrous ammonium sulfate), 60 or 100 microM copper (from cupric sulfate), and/or 200 microM or 1 mM H(2)O(2). Although endogenous and added ascorbate was depleted rapidly in the presence of transition metal ions and H(2)O(2), no cholesterol ester hydroperoxides or malondialdehyde were formed, i.e., ascorbate protected against, rather than promoted, lipid peroxidation. Conversely, depletion of endogenous ascorbate was sufficient to cause lipid peroxidation, the rate and extent of which were enhanced by the addition of metal ions but not H(2)O(2). Ascorbate also did not enhance protein oxidation in plasma exposed to metal ions and H(2)O(2), as assessed by protein carbonyl formation and depletion of reduced thiols. Interestingly, neither the rate nor the extent of endogenous alpha-tocopherol oxidation in plasma was affected by any of the treatments. Our data show that even in the presence of redox-active iron or copper and H(2)O(2), ascorbate acts as an antioxidant that prevents lipid peroxidation and does not promote protein oxidation in human plasma in vitro.

The physiologically induced release of ascorbate in rat brain is dependent on impulse traffic, calcium influx and glutamate uptake.

Extracellular brain ascorbate fluctuates with neuronal activity. There is previous evidence that the release of ascorbate is triggered by the re-uptake of neuronally released glutamate. This hypothesis predicts that drugs which block the release and re-uptake of glutamate will also block the release of ascorbate. In the present experiments we have used a novel dialysis electrode which allows continuous monitoring of physiologically induced ascorbate release from the striatum in freely moving rats. An infusion of the enzyme ascorbic acid oxidase abolished the increase in oxidation current in response to tail-pinch, which identified it as an ascorbate current. Perfusion with tetrodotoxin reduced the response to 25% and with CdCl2 to 4% of control. Perfusion with the uptake blocker L-trans-pyrrolidine-2,4-di-carboxylate reduced the response to 24% of control. A neuroprotective function for this coupling of ascorbate and glutamate release is discussed.

Rapid changes in striatal ascorbate in response to tail-pinch monitored by constant potential voltammetry.

The first peak in the voltammogram recorded with linear sweep and a carbon paste electrode implanted in the rat striatum is due to the oxidation of ascorbic acid. When the potential is held at a level slightly positive to this peak a current is recorded which is abolished by the microinjection of ascorbic acid oxidase in the vicinity of the electrode; this suggests that it is due to the oxidation of ascorbate. This current shows the same diurnal variation as the size of the ascorbate peak and its rise and fall coincides with the onset and offset of motor activity. A tail-pinch applied through a paper clip causes an immediate rise in the ascorbate current which begins to fall as soon as the paper clip is removed. Measurement of the ascorbate current at constant potential provides a technique for monitoring rapid changes in extracellular brain ascorbate in response to physiological stimuli.

Differential effects of ascorbate on endothelium-derived hyperpolarizing factor (EDHF)-mediated vasodilatation in the bovine ciliary vascular bed and coronary artery.

1. The ability of ascorbate to inhibit endothelium-derived hyperpolarizing factor (EDHF)-mediated vasodilatation was compared in the bovine perfused ciliary vascular bed and isolated rings of coronary artery. 2. Acetylcholine-induced, EDHF-mediated vasodilatation of the ciliary circulation was blocked following inclusion of ascorbate (50 micro M, 120 min) in the perfusion fluid. The blockade was highly selective since ascorbate had no effect on the vasodilator actions of the K(ATP) channel opener, levcromakalim, nor on the tonic vasodepressor action of basally released nitric oxide. 3. The possibility that concentration of ascorbate by the ciliary body was a prerequisite for blockade to occur was ruled out, since EDHF was still blocked when the anterior and posterior chambers were continuously flushed with Krebs solution or when both the aqueous and vitreous humour were drained. 4. Ascorbate at 50 micro M failed to affect bradykinin- or acetylcholine-induced, EDHF-mediated vasodilatation in rings of bovine coronary artery. Raising the concentration to 3 mM did produce blockade of EDHF, but this was nonselective, since vasodilator responses to endothelium-derived nitric oxide were also inhibited. 5. Thus, ascorbate (50 micro M) is not a universal blocker of EDHF. Whether its ability to block in the bovine ciliary circulation, but not in the coronary artery, is due to differences in the nature of EDHF at the two sites, differences in vessel size (resistance arterioles versus conduit artery), the presence or absence of flow, or to some other factor remains to be determined.

Reduction and uptake of methylene blue from rat air spaces.

The use of methylene blue (MB) to estimate dilution of epithelial lining fluid, which occurs during bronchoalveolar lavage (BAL), is complicated by loss of this redox dye from the air spaces. The rate of MB uptake from the air spaces of isolated rat lungs and the effects of oxidation and reduction on this process were investigated in this study. Movement of MB from the air spaces to perfusate was compared with the corresponding transport of 125I-labeled albumin, [14C]-dextran, 99mTc-labeled diethylenetriaminepentaacetate, [3H]-sucrose, and 3H2O. By the end of 2 min, MB concentrations in the BAL had fallen by 58 +/- 4% (SE; n = 11) and 3H2O by 78 +/- 2% (n = 13), whereas concentrations of the other indicators decreased by approximately 6%. All but 10% of the 3H2O lost from the air spaces was found in the perfusate, whereas 19% of the lost MB was not recovered in the perfusate, suggesting retention of MB in the pulmonary tissues. Absorption of MB from the air spaces was slowed by 20% when the lungs were left unperfused, and absorption was accelerated threefold by reduction of MB to leukomethylene blue with Na2S2O4. In contrast, MB losses from the air space were slowed by the oxidizing agent K3Fe(CN)6 and by addition of superoxide dismutase or ascorbic oxidase. It is therefore possible that ascorbic acid and O2- entering the air spaces reduce MB to the uncharged leuko form. Lowering the pH of the BAL fluid to 3.5 also slowed MB reabsorption. This suggests that acid aspiration may stimulate release of oxidants into the air spaces.

Nonenzymatic elimination of ascorbic acid in clinical samples.

OBJECTIVES: Ascorbic acid interferes significantly in the oxidative reaction of chromogenic reagents by peroxidase and hydrogen peroxide. Currently, ascorbate oxidase is commonly utilized for eliminating the interference of ascorbic acid in the oxidative colorimetric reaction. This enzyme, however, displays several disadvantages, such as high cost, variation from lot to lot, and low stability. We applied a series of commercially available and stable radicals (ascorbic acid quenchers [AAQs]) for nonenzymatic quenching of ascorbic acid in the uricase-based uric acid determination in serum and urine. DESIGN AND METHODS: In order to evaluate the quenching activity of AAQs, a commercially available uric acid detection kit was used. TBA-80FR.NEO biochemical analyzer was utilized for the assay. RESULTS: 4-Hydroxy-2,2,6,6-tetramethyl-1-piperidinyloxy free radical (AAQ-2) was the most effective ascorbic acid quencher among the four stable radicals, and the uric acid assay suffered no interference by AAQ-2. The ascorbic acid quenching ability of 2 mmol/L of AAQ-2 in reagent solution (reagent-I) was > or = 2 U/ml ascorbate oxidase in reagent solution. CONCLUSIONS: AAQ-2 was proven to be a suitable quencher of ascorbic acid in clinical samples.

Lucigenin chemiluminescence in human seminal plasma.

Seminal plasma protects spermatozoa from the detrimental effects of reactive oxygen species such as hydrogen peroxide. We investigated the lucigenin-dependent chemiluminescence in cell-free seminal plasma from andrological patients. The seminal plasma was separated from cells by centrifugation. In all seminal plasmas studied lucigenin-dependent chemiluminescence (LCL) was detected. The LCL showed a strong pH-dependence. The signal was stable if samples were stored at +4 degrees C for up to 4 days or up to 8 days at -80 degrees C. Filtration of the samples (0.45 and 0.22 microm pore size) did not lower their luminescence. The addition of superoxide dismutase (SOD) and ascorbic acid oxidase (AAO) lowered LCL nearly to baseline values while trolox and desferal showed moderate effect, whereas allopurinol had no effect. Electron paramagnetic resonance spectroscopy demonstrated ascorbyl radicals in seminal plasma. Physiological concentrations of ascorbic acid yielded SOD-inhibitable lucigenin-chemiluminescence. The nitroblue-tetrazolium assay showed that ascorbic acid in buffer solution produced formazan. Superoxide-anion radicals were not detected in seminal plasma by the spin-trap DEPMPO due to their low steady state concentration. It is concluded that in seminal plasma ascorbate reacts with molecular oxygen yielding ascorbyl radicals and superoxide anion. If lucigenin is added to seminal plasma, reducing substances present, such as ascorbate, reduce lucigenin to the corresponding radical; this radical reacts with molecular oxygen and also forms O2-. So LCL in human seminal plasma results from the autoxidation of ascorbate and the oxidation of the reduced lucigenin. While the physiological relevance of the former mechanism is unknown, the latter is an artifact.

Differential effects and transport kinetics of ascorbate derivatives in leukemic cell lines.

In order to investigate the differential effects of ascorbate derivatives on leukemic cell growth, we examined their stabilities and transmembrane transport efficiencies. The growth of HL-60 and U937 cells was dose-dependently inhibited by ascorbic acid and sodium ascorbate, but not by dehydroascorbic acid and magnesium ascorbyl 2-phosphate up to 200 microM. The growth-suppression by ascorbic acid was dependent on its redox state, showing a complete or partial reversion by ascorbate oxidase or FeCl3 addition, respectively. Three different patterns of intracellular ascorbic acid accumulation were observed by HPLC according to the species of ascorbate derivative applied for the incubation. Compared with the reduced form of ascorbic acid, the oxidized forms (dehydroascorbic acid, ascorbic acid plus ascorbate oxidase or FeCl3) were rapidly transported into cells and readily degraded, while magnesium ascorbyl 2-phosphate, a stable derivative of ascorbic acid, slowly elevated the intracellular level of ascorbic acid, reaching a plateau at 24 hours. We also measured the differential kinetics of ascorbic acid levels In culture supernatants following the addition of ascorbate derivatives. Ascorbic acid at 40, 10, or 1 microM was observed 3 hours following treatment with 100 microM of ascorbic acid, ascorbic acid plus FeCl3, or magnesium ascorbyl 2-phosphate, respectively. No ascorbic acid was found in the culture supernatant treated with dehydroascorbic acid. This order of ascorbic acid concentrations in culture supernatant reflects their growth-inhibitory effects. Thus the growth inhibitory effect of ascorbic acid appears to be dependent on its concentration in culture medium rather than its intracellular concentration. In conclusion, the results in this study indicate that the differential effects of ascorbate derivatives appear to be due to the actual concentration differences of the reduced form of ascorbic acid in culture medium following their addition, which is determined by their stability and efficiency of cellular uptake.

The gel state of the vitreous and ascorbate-dependent oxygen consumption: relationship to the etiology of nuclear cataracts.

OBJECTIVE: To investigate the rate and mechanism of oxygen consumption by the vitreous. METHODS: Oxygen consumption was measured with a microrespirometer. Vitreous ascorbate was measured spectrophotometrically and by gas chromatography-mass spectrometry. Vitreous degeneration was related to the rate of oxygen consumption and ascorbate concentration in samples obtained during vitrectomy. RESULTS: Prolonged exposure to oxygen or treatment with ascorbate oxidase eliminated oxygen consumption by the vitreous. Adding ascorbate restored oxygen consumption. Oxygen consumption persisted after boiling or treating the vitreous with the chelating agents EDTA and deferoxamine. In patients undergoing retinal surgery, liquefaction of the vitreous and previous vitrectomy were associated with decreased ascorbate concentration and lower oxygen consumption. CONCLUSIONS: Ascorbate in the vitreous decreases exposure of the lens to oxygen. The catalyst for this reaction is not known, although free iron may contribute. The gel state of the vitreous preserves ascorbate levels, thereby sustaining oxygen consumption. Vitrectomy or advanced vitreous degeneration may increase exposure of the lens to oxygen, promoting the progression of nuclear cataracts. CLINICAL RELEVANCE: Determining how the eye is protected from nuclear cataracts should suggest treatments to reduce their incidence.

Involvement of extracellular ascorbate and iron in hydroxyl radical generation in rat striatum in carbon monoxide poisoning.

Carbon monoxide (CO) poisoning stimulated generation in rat striatum of toxic hydroxyl radicals (*OH), which might participate in the CO-induced neuronal injury. Since an increase in extracellular ascorbate (AA) stimulated *OH generation in the presence of endogenous metals, including iron, in rat striatum in vivo, we examined the role of extracellular AA in *OH generation due to CO poisoning in the present study. The CO-induced *OH generation in the striatum was strongly suppressed by intrastriatal administration of active, but not inactivated, AA oxidase, which degrades extracellular AA. In addition, CO poisoning caused a significant increase in extracellular AA in rat striatum, suggesting a role of extracellular AA in the CO-induced *OH generation. However, the time-course of changes in extracellular AA could not be completely superimposed on that of the CO-induced *OH generation. On the other hand, the CO-induced *OH generation was completely suppressed by an iron chelator, deferoxamine. These findings suggest that *OH generation in rat striatum due to CO poisoning may involve both extracellular AA and chelatable iron.

Evaluation of the hepatic reduction of a nitroxide radical in rats receiving ascorbic acid, glutathione or ascorbic acid oxidase by in vivo electron spin resonance study.

BACKGROUND: A nitroxide radical, 4-hydroxyl-2,2,6,6-tetramethylpiperidin-1-oxyl (TEMPOL), is directly reduced to hydroxylamine by ascorbic acid (AsA). Ascorbic acid is oxidized to dehydroascorbic acid (DHA) by ascorbic acid oxidase (AAOx), and DHA is reduced to AsA by glutathione (GSH). In the present study, in vivo and ex vivo reduction of TEMPOL in the rat liver under various conditions of AsA supply was investigated using an electron spin resonance (ESR) spectrometer equipped with a surface coil-type resonator. METHODS: To investigate in vivo hepatic reduction of TEMPOL, an ESR study of the liver of living rats which orally received AsA or intravenously received GSH or AAOx was made. To investigate direct interactions between TEMPOL and GSH or AAOx, an in vitro ESR study was conducted. To investigate TEMPOL reduction in the hepatic homogenate, an ex vivo ESR study was performed. RESULTS: Ascorbic acid and GSH administration increased the in vivo hepatic reducing ability of TEMPOL. In contrast, AAOx administration decreased the reducing ability. In vitro TEMPOL was not reduced by GSH and hydroxylamine was not oxidized by AAOx. Reducing ability in the hepatic homogenate of AAOx-treated rats decreased, but that for GSH-treated rats was unchanged. CONCLUSION: Ascorbic acid administration directly increases hepatic reducing ability. Ascorbic acid, which increased in the plasma due to GSH administration, entered the liver and enhanced the hepatic reducing ability. Administration of AAOx impaired the hepatic reducing ability by oxidizing AsA in the plasma and/or the liver.

Kinetics of bilirubin oxidation with peroxidase, as applied to studies of bilirubin-albumin binding.

In the determination of unbound bilirubin by rate of oxidation with peroxidase, errors may be caused by (1) phenol, propylparaben, and phenothiazines (free radical acceleration), (2) haemoglobin (peroxidase effect), and (3) ascorbate (inhibition). Such errors may be diminished by dilution 1:40, or with an anti-oxidant, tert-butyl-p-hydroxyanisole, and ascorbate oxidase.

Nonenzymatic bioreduction in rat liver and kidney of nitroxyl spin labels, potential contrast agents in magnetic resonance imaging.

Paramagnetic nitroxyl spin labels have potential clinical utility as contrast agents in proton magnetic resonance imaging. Reduction of the nitroxyl moiety in vivo results in the formation of the diamagnetic hydroxylamine, which lacks contrast-enhancing activity. Bioreduction is therefore an important determinant of the imaging behavior of these agents. Both enzymatic and nonenzymatic reduction mechanisms have been suggested for nitroxyl spin labels. This study examines the nonenzymatic mechanisms in rat liver and kidney, mammalian tissues that demonstrate high reducing activity. Protein-free preparations, obtained by heat precipitation or ultrafiltration of rat liver and kidney homogenates, were used to test piperidine and pyrrolidine nitroxyl spin-label derivatives, for which imaging properties and bioreduction had previously been examined. For the piperidine derivative, the initial reduction rates in ultrafiltrates and supernatant fluids were 25-60% of those in whole liver and kidney homogenates. However, the pyrrolidine derivative was reduced at rates much slower than those in whole tissue homogenates. The reduction in whole tissue homogenates was NADPH-dependent, while reduction in ultrafiltrates was unaffected by the addition of NADPH. Preincubation of the ultrafiltrates and supernatant fluids with ascorbic acid oxidase caused almost complete inhibition of the reduction. The reduction rates of these nitroxyl derivatives were determined in ascorbic acid solution; second order rate constants were 0.45 +/- 0.04 and 0.0042 +/- 0.001 mM-1 min-1 for the piperidine and pyrrolidine derivatives, respectively. The concentrations of ascorbic acid in the supernatant fluids and ultrafiltrates of rat liver and kidney were then predicted from the observed reduction rates and found to be virtually identical with those from spectrophotometric determinations.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of ascorbate in plant tissues by high-performance capillary zone electrophoresis.

We describe here a simple and rapid capillary electrophoresis method for the determination of ascorbic acid (L-AA) and isoascorbic acid (D-AA) in vegetative tissues. For optimal yields and stabilization, samples are extracted with cold 3% metaphosphoric acid. Hydrophobic contaminants are then removed by passage through a C18 solid-phase extraction cartridge. The analysis itself is performed on a fused silica capillary with 200 mM borate, pH 9, as the carrier electrolyte, using on-line diode array detection over the range 190-350 nm. Quantitation was performed at 260 nm, the uv-absorption maximum for ascorbate at this pH. This method has a minimum detection limit of 84 fmol/injection and linearity of detector response was observed up to at least 12 pmol/injection. We also describe the influence of electrolyte concentration, pH, and the presence of detergent on separations of L-AA, D-AA, and L-galacturonic acid-1,4-lactone. The protocol has been demonstrated to be suitable for the analysis of L-AA in Arabidopsis, parsley, and mushroom. The method has superior resolution to comparable HPLC separations, a comparable analysis time, but lower sensitivity because of the concentration limitations of the detection system.

Studies on the antioxidant activity of milk caseins.

The antioxidant properties of milk casein subunits (alpha-casein, beta-casein and kappa-casein) were evaluated in liposomal models. All the subunits of casein are able to inhibit Fe-induced peroxidation of arachidonic acid inserted into multilamellar liposomes of dipalmitoylphosphatidylcholine (0.2 mM and 0.8 mM, respectively). The peroxidation was monitored as thiobarbituric acid reactive substances, and the strongest inhibitory effect occurred when 500 micrograms of alpha-casein were added to 0.5 ml of liposomal suspension. At this concentration, peroxidation was completely inhibited in our experimental conditions (incubation for 2 h at room temperature, with a mixture of ferrous sulfate and ascorbate, 50 and 500 microM final concentration, respectively). The mechanisms of antioxidant action are complex, but the strongest effect is achieved by modifying the Fe2+/Fe3+ equilibrium; in fact, caseins seem to favour the autoxidation of iron, and thus inhibit lipid peroxidation.