The formation of hydroxyproline in collagen by cells grown in the absence of serum.

L-929 and 3T6 cells were conditioned to grow in a chemically defined medium lacking serum and ascorbate. Serum, when added, had a small stimulatory effect on the growth rate of the cells, but ascorbate had no effect either on the growth rate or on the rate of protein synthesis. These cells were also shown to lack gulonolactone oxidase activity and therefore could not synthesize their own ascorbate. Nevertheless, in the absence of serum and ascorbate both cell types were able to hydroxylate peptidyl proline to an appreciable extent. This suggests that reductants other than ascorbate can at least partially satisfy the requirement for a reductant in the prolyl hydroxylase reaction in vivo.     

A substance in L-929 cell extracts which replaces the ascorbate requirement for prolyl hydroxylase in a tritium release assay for reducing cofactor; correlation of its concentration with the extent of ascorbate-independent proline hydroxylation and the level of prolyl hydroxylase activity in these cells

Reductant used as cofactor for the prolyl hydroxylase reaction, was measured by a tritium release assay modified from an enzyme assay by making all components of the assay system saturating except for the reductant, but including prolyl hydroxylase. Reduced glutathione (6 mm), which had little activity as a cofactor, and thymol (0.1 mm), an antioxidant which exhibited no cofactor activity at all, were required for optimal proline hydroxylation dependent on reducing cofactor, with thymol fulfilling the previously described requirement for catalase. Ascorbate, cysteine and 6,7-dimethyltetrahydropterin were active as cofactors, in descending order of activity at equimolar concentrations, and activity was concentration dependent for all of these compounds. Sonicates of stationary phase L-929 cells which exhibit ascorbate-independent proline hydroxylation in culture contained reducing cofactor which could replace ascorbate in the cofactor assay, while sonicates of log phase cells which exhibit an ascorbate requirement in culture contained about one-third or less of that amount. NADH and NADPH, which themselves have little or no activity as cofactor, increased the cofactor activity of log phase cell sonicates but had relatively little effect on the activity of stationary cell sonicates suggesting that the cofactor is in a more reduced state in stationary phase. Within 24 h after replating dense, stationary phase cell cultures at low density, conditions where cells return to ascorbate dependence, prolyl hydroxylase activity had decreased to one-fifth the original activity while the concentration of functional reducing cofactor had decreased to less than 1% of its original concentration, largely as a result of oxidation. Ascorbate was not present in L-929 cells sonicates and the levels of tetrahydropterin and cysteine in sonicates could not account for the amount of cofactor activity exhibited by the sonicates in the assay system. Treatment of L-929 cultures with aminopterin did not decrease ascorbate independence, suggesting that tetrahydrofolate did not contribute significantly to cellular proline hydroxylation. These results suggest that an unidentified reductant present in L-929 cells can account for ascorbate-independent proline hydroxylation and also regulate prolyl hydroxylase activity in these cells and that cellular levels of reduced pyridine nucleotides may regulate the reduction state of this substance.     

Effect of ascorbate on oxygen uptake and growth of Escherichia coli B

The addition of ascorbate to aerobically growing cultures of Escherichia coli B caused only a short pause in growth and no subsequent change in the rate or extent of growth. The effect of ascorbate on oxygen uptake varied from inhibition in minimal medium to stimulation in rich medium. Cyanide-resistant growth and oxygen uptake were stimulated by ascorbate. Both the rate and extent of anaerobic growth were stimulated in proportion to the amount of ascorbate added when fumarate was the terminal electron acceptor. Ascorbate had no effect on any aspect of anaerobic growth in the absence of a terminal electron acceptor or in the presence of nitrate.     

Chromosaponin I stimulates the growth of lettuce roots

A γ-pyronyl triterpenoid saponin termed chromosaponin 1 (CSI), a conjugate of soyasaponin I and γ-pyrone, was found at 3 mM to stimulate the growth of lettuce root ( Lactuca sativa L. ev. Grand Rapids) to about 190% of the control. Since CSI is an amphipathic reductant, the stimulating effect of this saponin was compared with other reductants and other surface-active compounds. Trolox (2-carboxy-2.5.7.8-tetraamethyl-6-chromanol). another amphipathic reductant, also stimulated root growth, while other hydrophilic reductants including ascorbate. NADPH, NADH and glutathione did not. Some surfactants promoted root growth but their stimulating effects were smaller than the optimum effect of CSI. These results suggest a possible Function of CSI as an amphipathic reductant in root growth regulation.     

An intramembranous reductant which participates in the proline hydroxylation reaction with intracisternal prolyl hydroxylase and unhydroxylated procollagen in isolated microsomes from L-929 cells

We previously have described a substance present in crude sonicates of L-929 cells which replaced ascorbate in vitro as a reductant for prolyl hydroxylase (B. Peterkofsky, D. Kalwinksy and R. Assad, 1980, Arch. Biochem. Biophys.199, 362–373). In the present study we found that almost 90% of the substance was particulate after differential centrifugation of stationary phase L-929 cell homogenates. The substance was not localized in nuclei or mitochondria and was found in the same fractions as microsomes, but these fractions also contained lysosomes and cell membranes. The reductant could not be solubilized from particles by Brij-35, indicating that it is an intrinsic component of a membrane rather than intracisternally located. The intramembranous cofactor, in the absence of ascorbate, participated in the in vitro hydroxylation of [4-³H]proline in radio-actively labeled, intracisternal unhydroxylated procollagen in isolated microsomes which also contained prolyl hydroxylase. Hydroxylation was determined by measuring tritiated water formed from release of the 4-trans tritium atom. Since it is unlikely that such participation could occur if the cofactor were located within the membrane of another subcellular organelle, we have concluded that it is in the same particle as prolyl hydroxylase and unhydroxylated procollagen, that is, the microsome. With the endogenous reductant the reaction was slower than with saturating ascorbate and was increased by NADH. Maximum hydroxylation with the endogenous reductant was close to that which could be achieved with ascorbate. These results provide strong evidence that the endogenous reductant alone can account for the phenomenon of ascorbate-independent proline hydroxylation in L-929 cells. As in the case of ascorbate, the microsomal reductant functioned only in the presence of α-ketoglutarate and Fe²⁺ and served as reductant for lysyl hydroxylase. It also was detected in the particulate fraction of virally transformed BALB 3T3 cells and in purified microsomes from bones of intact chick embryos. Since ascorbate could be taken up and concentrated in bone microsomes, it is unlikely that the endogenous reductant serves as an intermediary between ascorbate and intracisternal prolyl hydroxylase.     

Deleterious synergistic effects of ascorbate and copper on the development of Plasmodium falciparum: an in vitro study in normal and in G6PD-deficient erythrocytes

The effects of ascorbate and copper on the development of Plasmodium falciparum were studied in two modes: pretreatment of uninfected erythrocytes followed by infection by P. falciparum and treatment of parasitized erythrocytes. Pretreatment of G6PD(+) cells with ascorbate caused a slight enhancement in parasite development, while in G6PD(-) cells a suppressive effect on the plasmodia was demonstrated. Copper alone interfered with parasite growth in both cell types. The combination of copper and ascorbate arrested parasite maturation, an effect which was more pronounced in G6PD(-) cells. Synergism between copper and ascorbate was better demonstrated following the treatment of infected erythrocytes: while ascorbate alone supported parasite development and copper alone had only a marginal suppressive effect, the combination of copper and ascorbate yielded a marked inhibition of parasite growth. Ascorbate proved destructive to the parasites in the presence of adventitious copper, or on the second day of the parasite life cycle. In these cases it acted as a pro-oxidant, while in other systems, in particular in the presence of a chelator, ascorbate acted as an antioxidant and promoted parasite growth. The understanding of the role of transition metals and free radicals in parasite development and injury could shed light on novel approaches to fight malaria.     

Ascorbate free radical and its role in growth control

Summary Ascorbate and its free radical potentiates proliferation of HL-60 cells in serum-limiting media. Dehydroascorbate does not affect growth. This stimulation of growth is due to a general shortening of the cell cycle. The incubation of HL-60 cells with ascorbate free radical produces a significant change of the redox potential of cells. The presence of cells in culture media avoids the total oxidation of ascorbate, and also HL-60 cells induce the short-term stabilization of ascorbate. Ascorbate free radical potentiates also the onset of DNA synthesis in CCL39 cells induced by fetal calf serum, although itself does not affect quiescense to proliferation transition. This transition induced by fetal calf serum also potentiates the capacity of CCL39 cells to stabilize ascorbate. We discuss here the role of ascorbate free radical on growth control by its reduction by the plasma membrane redox system and its meaning for cell physioslogy.     

The effect of aging and increasing ascorbate concentrations on respiratory chain activity in cultured human fibroblasts

The specific activities of Complexes I‐III, II‐III, and IV of the respiratory chain, and citrate synthase, were determined in mitochondrial sonicates of six control passage 5 fibroblast cultures, cultivated in growth medium containing fetal calf serum as the only source of ascorbate. The enzymes were also assayed in serially subcultured fibroblasts which were characterized as aged at passage 20 and beyond. Results indicated a significant loss of all enzyme activities in aged cells at passage 20, 25, and 30. Further studies involved maintenance of serially subcultured cells in serum free media to which increasing ascorbate concentrations (100, 200, and 300 µmol 1^?1) were added. Results indicated that ascorbate at 100 µmol 1^?1 was not sufficient to restore any of the enzyme activities in aged cells. An ascorbate concentration of 200 µmol 1^?1 however, could totally restore Complex IV and citrate synthase activities, but had no effect on complexes I‐III and II‐III activities which required 300 µmol 1^?1 ascorbate to be partially or totally restored respectively. In conclusion, this study demonstrates an age related drop in mitochondrial respiratory chain activity in cultured human fibroblasts. Enzyme activities could be completely or partially restored in the presence of double or triple normal human plasma ascorbate concentrations. Copyright © 2010 John Wiley & Sons, Ltd.     

Activation of dopamine beta-monooxygenase by external and internal electron donors in resealed chromaffin granule ghosts

Membrane ghosts derived from chromaffin vesicles of bovine adrenal medullas have been used to examine the mechanism of reduction of dopamine beta-monooxygenase in its compartmentalized state. The rate of the dopamine beta-monooxygenase-catalyzed conversion of dopamine to norepinephrine is greatly stimulated by the presence of ATP, reflecting substrate hydroxylation on the ghost interior subsequent to the active transport of dopamine. We demonstrate a 2-3-fold increase in the turnover rate for ghosts resealed with 0.2-2 mM potassium ferrocyanide, conditions leading to a slight decrease in the rate of dopamine transport. These data provide the first evidence that an intravesicular pool of reductant can activate dopamine beta-monooxygenase, as required by models in which vesicular ascorbate behaves as enzyme reductant. Although there is sufficient catecholamine (endogenous plus substrate) to keep internal ferrocyanide reduced in these experiments, an additional 2-3-fold increase in turnover occurs in the presence of 0.2-2 mM ascorbate on the ghost exterior. The magnitude of this activation is found to be constant at all concentrations of internal ferrocyanide (both below and above saturation), implying that reductants on opposite sides of the membrane behave independently. Replacement of ascorbate by potassium ferrocyanide as external reductant leads to almost identical results, and we are able to rule out an inward transport of dehydroascorbate as the source of activation by external ascorbate. We conclude that external reductants are capable of reducing membrane-bound dopamine beta-monooxygenase from the exterior face of the vesicle, either by direct reduction or through a membrane-bound mediator. It appears that two viable modes for reduction of dopamine beta-monooxygenase may exist in vivo, involving the reduction of membrane-bound enzyme by cytosolic ascorbate as well as the reduction of soluble enzyme by the pool of intravesicular ascorbate present in chromaffin vesicles.     

Mechanism of the insect enzyme, tyramine beta-monooxygenase, reveals differences from the mammalian enzyme, dopamine beta-monooxygenase

Tyramine beta-monooxygenase (TbetaM) catalyzes the synthesis of the neurotransmitter, octopamine, in insects. Kinetic and isotope effect studies have been carried out to determine the kinetic mechanism of TbetaM for comparison with the homologous mammalian enzymes, dopamine beta-monooxygenase and peptidylglycine alpha-hydroxylating monooxygenase. A new and distinctive feature of TbetaM is very strong substrate inhibition that is dependent on the level of the co-substrate, O(2), and reductant as well as substrate deuteration. This has led to a model in which tyramine can bind to either the Cu(I) or Cu(II) forms of TbetaM, with substrate inhibition ameliorated at very high ascorbate levels. The rate of ascorbate reduction of the E-Cu(II) form of TbetaM is also reduced at high tyramine, leading us to propose the existence of a binding site for ascorbate to this class of enzymes. These findings may be relevant to the control of octopamine production in insect cells.     

Superoxide ion as a primary reductant in ascorbate-mediated ferritin iron release

The mechanism of ascorbate-promoted ferritin iron reduction under aerobic conditions was studied. The initial rate of ferritin iron release was determined by spectrophotometric measurement of the Fe(ferrozine)3(2+) complex which absorbs at 562 nm. Variation of the initial ferrozine concentration had no influence on the rate of iron release suggesting that ferrozine does not participate in the rate-determining step. Experimental measurements of the initial rate of iron release as a function of ascorbate concentration resulted in saturation kinetics with Vmax = 2.0 X 10(-7) M.min-1 and KM = 1.3 X 10(-3) M. The effect of pH was quite pronounced with a maximal rate of iron release at pH 7.0. Stoichiometric measurements on the reaction mixture, with added catalase, resulted in a ratio of 2 Fe(II) released per ascorbate. Ascorbate-mediated iron release was inhibited 85% by superoxide dismutase, but 0% inhibition was noted with aposuperoxide dismutase. It is proposed that superoxide ion, generated during the iron-promoted oxidation of ascorbate, acts as a reductant of ferritin iron. A mechanism of ferritin iron release consistent with these experimental observations is discussed.     

The effect of intracellular ascorbate on the susceptibility of HL60 and Jurkat cells to chemotherapy agents

Chemotherapy agents initiate tumour cell apoptosis and this is thought to involve oxidative stress. In this study we have investigated the effect of the important antioxidant Vitamin C (ascorbate) on the response of HL60 and Jurkat cells to three chemotherapy drugs, namely etoposide, melphalan and arsenic trioxide (As₂O₃). Cells grown in routine culture media are deficient in ascorbate and to determine its effect on chemotherapy drug-induced apoptosis we supplemented the cells prior to drug exposure. We found that ascorbate had a varied effect on apoptosis and cell cycle progression. Etoposide-induced apoptosis in HL60 cells was significantly increased in ascorbate-loaded cells as measured by caspase-3 activation and DNA degradation, and this appeared to reflect a decrease in the number of necrotic cells rather than increased cytotoxicity. In contrast, ascorbate had no effect on etoposide-induced apoptosis in Jurkat cells. In both cell types melphalan-induced apoptosis was unaffected by intracellular ascorbate, whereas both apoptosis and growth arrest with low concentrations of As₂O₃ were diminished. These results indicate that intracellular ascorbate can affect cell responses to chemotherapy drugs in a complex and somewhat unpredictable manner and that it may play an important role in the responsiveness of tumour cells to chemotherapy regimes. This study was supported by the Health Research Council of New Zealand.     

Copper catalyzed oxidation of ascorbate (vitamin C). Inhibitory effect of catalase, superoxide dismutase, serum proteins (ceruloplasmin, albumin, apotransferrin) and amino acids

The inhibitory effect of catalase and superoxide dismutase on copper catalyzed oxidation of ascorbate is probably due to a binding of copper ions. Scavengers of hydroxyl ions and singlet oxygen had no effect on the ascorbate oxidation rate. Copper binding serum proteins reduced the oxidation rate; the order of effectiveness being: Ceruloplasmin greater than human albumin = bovine albumin greater than apotransferrin. The excellent protection obtained with catalase and ceruloplasmin is possibly due to a strong affinity for cuprous ions generated during the reaction. Cupric ion binding amino acids (His, Thr, Glu, Gln, Tyr) had considerably weaker protective effect than the proteins studied. Apparently they do not compete favorably with ascorbate for cupric ions.     

Characterization of alternate reductant binding and electron transfer in the dopamine beta-monooxygenase reaction

The steady-state limiting kinetic parameters Vmax, V/KDA, and V/KO2, together with deuterium isotope effects on these parameters, have been determined for the dopamine beta-monooxygenase (D beta M) reaction in the presence of structurally distinct reductants. The results show the one-electron reductant ferrocyanide to be nearly as kinetically competent as the presumed in vivo reductant ascorbate. Further, a reductant system of ferricyanide plus substrate dopamine yields steady-state kinetic parameters and isotope effects very similar to those measured solely in the presence of ferrocyanide, indicating a role for catecholamine in the rapid recycling of oxidized ferrocyanide. Use of substrate dopamine as the sole reductant is found to lead to a highly unusual kinetic independence of oxygen concentration, as well as significantly reduced values of Vmax and V/KDA, and we conclude that dopamine reduces enzymic copper in a rate-limiting step that is 40-fold slower than with ascorbate. The near-identical kinetic parameters measured in the presence of either ascorbate or ferrocyanide, together with markedly reduced rates with dopamine, are interpreted in terms of a binding site for reductant that is physically distinct from the substrate binding site. This view is supported by molecular modeling, which reveals ascorbate and ferrocyanide to possess an unexpected similarity in potential sites for interaction with enzymic residues. With regard to electron flux, identical values of V/KO2 have been measured with [2,2-2H2]dopamine as substrate both in the presence and in the absence of added ascorbate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Properties of two distinct heme centers of cytochrome b561 from bovine chromaffin vesicles studied by EPR, resonance Raman, and ascorbate reduction assay

Cytochrome b(561) from bovine adrenal chromaffin vesicles contains two hemes b with different midpoint potentials (+150 and +60 mV) and participates in transmembrane electron transport from extravesicular ascorbate to an intravesicular monooxygenase, dopamine beta-hydroxylase. Treatment of oxidized cytochrome b(561) with diethylpyrocarbonate caused a downshift of midpoint potential for the lower component, and this shift was prevented by the presence of ascorbate during the treatment. Present EPR analyses showed that, upon the treatment, the g(z) = 3.69 heme species was converted to a non-ascorbate-reducible form, although its g(z)-value showed no appreciable change. The treatment had no effect on the other heme (the g(z) = 3.13 species). Raman data indicated that the two heme b centers adopt a six-coordinated low-spin state, in both the reduced and oxidized forms. There was no significant effect of diethylpyrocarbonate-treatment on the Raman spectra of either form, but the reducibility by ascorbate differed significantly between the two hemes upon the treatment. The addition of ferrocyanide enhanced both the reduction rate and final reduction level of the diethylpyrocarbonate-treated cytochrome b(561) when ascorbate was used as a reductant. This observation suggests that ferrocyanide scavenges monodehydroascorbate radicals produced by the univalent oxidation of ascorbate and, thereby, increases both the reduction rate and the final reduction level of the heme center on the intravesicular side of the diethylpyrocarbonate-treated cytochrome. These results further clarify the physiological role of this heme center as the electron donor to the monodehydroascorbate radical.     

Use of alternate substrates to probe the order of substrate addition to dopamine beta-hydroxylase

In order to determine the order of substrate binding to dopamine beta-hydroxylase during catalysis, the effect of alternate substrates upon kinetic parameters was examined. The V/K value for ascorbate was unchanged when tyramine, phenylpropylamine, p-Cl-phenethylamine, p-CH3O-phenethylamine, or phenethylamine was the hydroxylated substrate. The V/K values for tyramine and oxygen were similarly unchanged when ferrocyanide was used as the reductant in place of ascorbate. In order to use ferrocyanide as reductant it was necessary to include copper to alleviate the substrate inhibition seen with this substrate. The pattern of substrate inhibition observed with ferrocyanide was consistent with a small amount of free cyanide present in the ferrocyanide. With ferrocyanide as reductant and [2,2-2H2]tyramine as substrate, there was a measurable isotope effect on the V/K value for oxygen, but none on the values of Vmax or V/K for tyramine. These results are consistent with a ping-pong mechanism in which tyramine binds to the enzyme after the release of oxidized ascorbate. Subsequently, oxygen binds to form a ternary complex.     

Ascorbate- and dehydroascorbic acid-mediated reduction of free radicals in the human erythrocyte

Nitroxides were used as models of persistent free radicals to study the antioxidant function of ascorbic acid in the human erythrocyte. It was concluded that: 1) ascorbate and other reductant(s) derived from dehydroascorbic acid (DHA) in the presence of thiols are the only significant reducing agents for nitroxides, 2) glutathione and DHA reduce nitroxides by a process that cannot be inhibited by ascorbic acid oxidase, 3) erythrocytes can be depleted of ascorbic acid by exhaustive washing in the presence of membrane-permeable cationic nitroxides such as N,N-dimethylamino-Tempo, 4) ascorbate-depleted cells do not reduce nitroxides; however, nitroxide reduction is restored when the cells are incubated with DHA, 5) reduction of nitroxides in ascorbate-depleted, DHA-treated cells is significantly faster than in buffered solutions of DHA and glutathione, 6) several equivalents of nitroxide are reduced relative to the intracellular ascorbate pool, 7) sustained nitroxide reduction is observed even when most of the intracellular ascorbate is oxidized, 8) spin trapping of oxyradicals in tert-butyl hydroperoxide-treated cells is accelerated with ascorbate depletion and inhibited with ascorbate loading, 9) ascorbate can be quantified within intact cells by analyzing the initial reduction rates of membrane-permeable cationic nitroxides, and 10) DHA-stimulated reduction of cationic nitroxides is slower and less extensive in erythrocytes deficient in glucose-6-phosphate dehydrogenase than in normal erythrocytes.     

Activity of membranous dopamine beta-monooxygenase within chromaffin granule ghosts. Interaction with ascorbate

The role of intra- and extravesicular ascorbate has been investigated in dopamine beta-monooxygenase (D beta M) turnover using adrenal medulla chromaffin granule ghosts. Resealing of vesicle ghosts with high levels of intravesicular ascorbate leads to viable vesicles, as evidenced from the high rates of the ATP-dependent accumulation of tyramine, Vmax = 14 +/- 1 nmol/min.mg and Km = 20 +/- 6 microM. However, the D beta M-catalyzed conversion of tyramine to octopamine occurs slowly, Vmax = 0.50 +/- 0.13 nmol/min.mg and Km = 29 +/- 18 mM. When ascorbate is present instead in the external buffer, the D beta M rate increases 3.6-fold for a final Vmax = 1.8 +/- 0.2 and Km = 1.2 +/- 0.3 mM. This relatively high rate of enzyme turnover is retained in ghosts resealed with a large excess of ascorbate oxidase, ruling out contamination by intravesicular ascorbate as the source of enzyme activity. The synergistic effect of intravesicular ascorbate was examined under conditions of 2 mM external ascorbate, showing that the enzymatic rate increases 2.7-fold, from 1.2 (0 internal ascorbate) to 3.2 +/- 0.4 nmol/min.mg (saturating internal ascorbate). This result confirms that high levels of internal ascorbate are not damaging to intravesicular D beta M. These studies demonstrate very clearly that external ascorbate is the preferred reductant for the membranous form of D beta M in chromaffin granule ghosts.     

Ascorbate enhances the toxicity of the photodynamic action of Verteporfin in HL-60 cells

As a reducing agent, ascorbate serves as an antioxidant. However, its reducing function can in some settings initiate an oxidation cascade, i.e., seem to be a "pro-oxidant." This dichotomy also seems to hold when ascorbate is present during photosensitization. Ascorbate can react with singlet oxygen, producing hydrogen peroxide. Thus, if ascorbate is present during photosensitization the formation of highly diffusible hydrogen peroxide could enhance the toxicity of the photodynamic action. On the other hand, ascorbate could decrease toxicity by converting highly reactive singlet oxygen to less reactive hydrogen peroxide, which can be removed via peroxide-removing systems such as glutathione and catalase. To test the influence of ascorbate on photodynamic treatment we incubated leukemia cells (HL-60 and U937) with ascorbate and a photosensitizer (Verteporfin; VP) and examined ascorbic acid monoanion uptake, levels of glutathione, changes in membrane permeability, cell growth, and toxicity. Accumulation of VP was similar in each cell line. Under our experimental conditions, HL-60 cells were found to accumulate less ascorbate and have lower levels of intracellular GSH compared to U937 cells. Without added ascorbate, HL-60 cells were more sensitive to VP and light treatment than U937 cells. When cells were exposed to VP and light, ascorbate acted as an antioxidant in U937 cells, whereas it was a pro-oxidant for HL-60 cells. One possible mechanism to explain these observations is that HL-60 cells express myeloperoxidase activity, whereas in U937 cells it is below the detection limit. Inhibition of myeloperoxidase activity with 4-aminobenzoic acid hydrazide (4-ABAH) had minimal influence on the phototoxicity of VP in HL-60 cells in the absence of ascorbate. However, 4-ABAH decreased the toxicity of ascorbate on HL-60 cells during VP photosensitization, but had no affect on ascorbate toxicity in U937 cells. These data demonstrate that ascorbate increases hydrogen peroxide production by VP and light. This hydrogen peroxide activates myeloperoxidase, producing toxic oxidants. These observations suggest that in some settings, ascorbate may enhance the toxicity of photodynamic action.