Involvement of ascorbic acid and ab-type cytochrome in plant plasma membrane redox reactions

Summary Higher plant plasma membranes contain ab-type cytochrome that is rapidly reduced by ascorbic acid. The affinity towards ascorbate is 0.37 mM and is very similar to that of the chromaffin granule cytochromeb ₅₆₁. High levels of cytochromeb reduction are reached when ascorbic acid is added either on the cytoplasmic or cell wall side of purified plasma membrane vesicles. This result points to a transmembrane organisation of the heme protein or alternatively indicates the presence of an effective ascorbate transport system. Plasma membrane vesicles loaded by ascorbic acid are capable of reducing extravesicular ferricyanide. Addition of ascorbate oxidase or washing of the vesicles does not eliminate this reaction, indicating the involvement of the intravesicular electron donor. Absorbance changes of the cytochromeb -band suggest the electron transfer is mediated by this redox component. Electron transport to ferricyanide also results in the generation of a membrane potential gradient as was demonstrated by using the charge-sensitive optical probe oxonol VI. Addition of ascorbate oxidase and ascorbate to the vesicles loaded with ascorbate results in the oxidation and subsequent re-reduction of the cytochromeb. It is therefore suggested that ascorbate free radical (AFR) could potentially act as an electron acceptor to the cytochrome-mediated electron transport reaction. A working model on the action of the cytochrome as an electron carrier between cytoplasmic and apoplastic ascorbate is discussed.Abbreviations AFR ascorbate free radical - AO ascorbate oxidase - DTT dithiothreitol - FCCP carbonylcyanidep-trifluorome-thoxyphenylhydrazon - Hepes N-(2-hydroxyethyl)-piperazine-N-(2-ethanesulfonic acid) - Oxonol VI bis(3-propyl-5-oxoisoxazol-4-yl) penthamethine oxonol - PMSF phenylmethylsulfluoride     

Reduction of ascorbate free radical by the plasma membrane of synaptic terminals from rat brain

Synaptic plasma membranes (SPMV) decrease the steady state ascorbate free radical (AFR) concentration of 1 mM ascorbate in phosphate/EDTA buffer (pH 7), due to AFR recycling by redox coupling between ascorbate and the ubiquinone content of these membranes. In the presence of NADH, but not NADPH, SPMV catalyse a rapid recycling of AFR which further lower the AFR concentration below 0.05 μM. These results correlate with the nearly 10-fold higher NADH oxidase over NADPH oxidase activity of SPMV. SPMV has NADH-dependent coenzyme Q reductase activity. In the presence of ascorbate the stimulation of the NADH oxidase activity of SPMV by coenzyme Q₁ and cytochrome c can be accounted for by the increase of the AFR concentration generated by the redox pairs ascorbate/coenzyme Q₁ and ascorbate/cytochrome c. The NADH:AFR reductase activity makes a major contribution to the NADH oxidase activity of SPMV and decreases the steady-state AFR concentration well below the micromolar concentration range.     

Recycling of the ascorbate free radical by human erythrocyte membranes.

Reduction of the ascorbate free radical (AFR) at the plasma membrane provides an efficient mechanism to preserve the vitamin in a location where it can recycle alpha-tocopherol and thus prevent lipid peroxidation. Erythrocyte ghost membranes have been shown to oxidize NADH in the presence of the AFR. We report that this activity derives from an AFR reductase because it spares ascorbate from oxidation by ascorbate oxidase, and because ghost membranes decrease steady-state concentrations of the AFR in a protein- and NADH-dependent manner. The AFR reductase has a high apparent affinity for both NADH and the AFR (< 2 microM). When measured in open ghosts, the reductase is comprised of an inner membrane activity (both substrate sites on the cytosolic membrane face) and a trans-membrane activity that mediates extracellular AFR reduction using intracellular NADH. However, the trans-membrane activity constitutes only about 12% of the total measured in ghosts. Ghost AFR reductase activity can also be differentiated from NADH-dependent ferricyanide reductase(s) by its sensitivity to the detergent Triton X-100 and insensitivity to enzymatic digestion with cathepsin D. This NADH-dependent AFR reductase could serve to recycle ascorbic acid at a crucial site on the inner face of the plasma membrane.     

Ascorbate system in plant development

By using lycorine, a specific inhibitor of ascorbate biosynthesis, it was possible to demonstrate that plant cells consume a high quantity of ascorbate (AA). Thein vivo metabolic reactions utilizing ascorbate are the elimination of H₂O₂ by ascorbate peroxidase and the hydroxylation of proline residues present in the polypeptide chains by means of peptidyl-proline hydroxylase.Ascorbate acts in the cell metabolism as an electron donor, and consequently ascorbate free radical (AFR) is continuously produced. AFR can be reconverted to AA by means of AFR reductase or can undergo spontaneous disproportion, thus generating dehydroascorbic acid (DHA).During cell division and cell expansion ascorbate consumption is more or less the same; however, the AA/DHA ratio is 6–10 during cell division and 1–3 during cell expansion. This ratio depends essentially on the different AFR reductase activity in these cells. In meristematic cells AFR reductase is very high, and consequently a large amount of AFR is reduced to AA and a small amount of AFR undergoes disproportionation; in expanding cells the AFR reductase activity is lower, and therefore AFR is massively disproportionated, thus generating a large quantity of DHA. Since the transition from cell division to cell expansion is marked by a large drop of AFR reductase activity in the ER, it is suggested here that AFR formed in this compartment may be involved in the enlargement of the ER membranes and provacuole acidification.DHA is a toxic compound for the cell metabolism and as such the cell has various strategies to counteract its effects: (i) meristematic cells, having an elevated AFR reductase, prevent large DHA production, limiting the quantity of AFR undergoing disproportionation. (ii) Expanding cells, which contain a lower AFR reductase, are, however, provided with a developed vacuolar system and segregate the toxic DHA in the vacuole. (iii) Chloroplast strategy against DHA toxicity is efficient DHA reduction to AA using GSH as electron donor. This strategy is usually poorly utilized by the surrounding cytoplasm.DHA reduction does play an important role at one point in the life of the plant, that is, during the early stage of seed germination. The dry seed does not store ascorbate, but contains DHA, and several DHA-reducing proteins are detectable. In this condition, DHA reduction is necessary to form a limited AA pool in the seed for the metabolic requirements of the beginning of germination. After 30–40h ascorbateex novo synthesis starts, DHA reduction declines until a single isoform remains, as is typical in the roots, stem, and leaves of seedlings. Finally, DHA recycling also appears to be important under adverse environmental conditions and ascorbate deficiency.     

The NADH oxidase activity of the plasma membrane of synaptosomes is a major source of superoxide anion and is inhibited by peroxynitrite

Plasma membrane vesicles from adult rat brain synaptosomes (PMV) have an ascorbate-dependent NADH oxidase activity of 35-40 nmol/min/(mg protein) at saturation by NADH. NADPH is a much less efficient substrate of this oxidase activity, with a Vmax 10-fold lower than that measured for NADH. Ascorbate-dependent NADH oxidase activity accounts for more than 90% of the total NADH oxidase activity of PMV and, in the absence of NADH and in the presence of 1 mm ascorbate, PMV produce ascorbate free radical (AFR) at a rate of 4.0 +/- 0.5 nmol AFR/min/(mg protein). NADH-dependent *O2- production by PMV occurs with a rate of 35 +/- 3 nmol/min/(mg protein), and is a coreaction product of the NADH oxidase activity, because: (i) it is inhibited by more than 90% by addition of ascorbate oxidase, (ii) it is inhibited by 1 micro g/mL wheat germ agglutinin (a potent inhibitor of the plasma membrane AFR reductase activity), and (iii) the KM(NADH) of the plasma membrane NADH oxidase activity and of NADH-dependent *O2- production are identical. Treatment of PMV with repetitive micromolar ONOO- pulses produced almost complete inhibition of the ascorbate-dependent NADH oxidase and *O2- production, and at 50% inhibition addition of coenzyme Q10 almost completely reverts this inhibition. Cytochrome c stimulated 2.5-fold the plasma membrane NADH oxidase, and pretreatment of PMV with repetitive 10 microm ONOO- pulses lowers the K0.5 for cytochrome c stimulation from 6 +/- 1 (control) to 1.5 +/- 0.5 microm. Thus, the ascorbate-dependent plasma membrane NADH oxidase activity can act as a source of neuronal.O2-, which is up-regulated by cytosolic cytochrome c and down-regulated under chronic oxidative stress conditions producing ONOO-.     

Recycling of vitamin C from its oxidized forms by human endothelial cells

Endothelial cells encounter oxidant stress due to their location in the vascular wall, and because they generate reactive nitrogen species. Because ascorbic acid is likely involved in the antioxidant defenses of these cells, we studied the mechanisms by which cultures of EA.hy926 endothelial cells recycle the vitamin from its oxidized forms. Cell lysates reduced the ascorbate free radical (AFR) by both NADH- and NADPH-dependent mechanisms. Most NADH-dependent AFR reduction occurred in the particulate fraction of the cells. NADPH-dependent reduction resembled that due to NADH in having a high affinity for the AFR, but was mediated largely by thioredoxin reductase. Reduction of dehydroascorbic acid (DHA) required GSH and was both direct and enzyme dependent. The latter was saturable, half-maximal at 100 microM DHA, and comparable to rates of AFR reduction. Loading cells to ascorbate concentrations of 0.3-1.6 mM generated intracellular DHA concentrations of 20-30 microM, indicative of oxidant stress in culture. Whereas high-affinity AFR reduction is the initial and likely the preferred mechanism of ascorbate recycling, any DHA that accumulates during oxidant stress will be reduced by GSH-dependent mechanisms.     

Reaction of ascorbic acid with cytochrome b561. Concerted electron and proton transfer.

Rate constants for reduction of cytochrome b561 by internal ascorbate (k0A) and oxidation by external ferricyanide (k1F) were determined as a function of pH from rates of steady-state electron transfer across chromaffin-vesicle membranes. The pH dependence of electron transfer from cytochrome b561 to ferricyanide (k1F) may be attributed to the pH dependence of the membrane surface potential. The rate constant for reduction by internal ascorbate (k0A), like the previously measured rate constant for reduction by external ascorbate (k-1A), is not very pH-dependent and is not consistent with reduction of cytochrome b561 by the ascorbate dianion. The rate at which ascorbate reduces cytochrome b561 is orders of magnitude faster than the rate at which it reduces cytochrome c, despite the fact that midpoint reduction potentials favor reduction of cytochrome c. Moreover, the rate constant for oxidation of cytochrome b561 by ferricyanide (k1F) is smaller than the previously measured rate constant for oxidation by semidehydroascorbate, despite the fact that ferricyanide has a higher midpoint reduction potential. These results may be reconciled by a mechanism in which electron transfer between cytochrome b561 and ascorbate/semidehydroascorbate is accelerated by concerted transfer of a proton. This may be a general property of biologically significant electron transfer reactions of ascorbic acid.     

Extracellular reduction of the ascorbate free radical by human erythrocytes

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

Hierarchy of ozone scavenging reactions in the plant cell wall

To estimate protection of the plasmalemma against ozone by the cell apoplast, the decomposition network of ozone in the mesophyll cell wall is analysed in consideration of data on published bimolecular reaction rate constants and concentrations of the reactants involved. The effect of dimerization of ascorbate free radicals (AFR) on the stoichiometric ratio of ozone reduction by ascorbate is quantified over the range of cell wall acidity, pH = 5.0‐6.5. As the disproportionation of AFR decreases sharply towards higher pH, the flow of AFR through dimerization is low over the pH range 5.5‐6.5, allowing abstraction of the second electron from AFR and formation of dehydroascorbate with a nearly 1:1 stoichiometric ratio in relation to ozone. The direct reaction between ozone and ascorbate (AA) in cell walls 0.3‐0.5 µm thick and at an AA concentration of 0.5 m M is able to detoxify 50‐70% of the O₃ that impinges on the wall surface. Generation of singlet oxygen and the hydroxyl radical, which are more reactive to AA than O₃, decreases markedly the O₃ flow to the plasmalemma. The question is raised whether cell wall alkalinization under ozone may hasten the decomposition of the pollutant due to the more rapid generation of hydroxyl radical by phenolic compounds.     

Ascorbate free radical reductase mRNA levels are induced by wounding.

A cDNA clone encoding ascorbate free radical (AFR) reductase (EC 1.6.5.4) was isolated from tomato (Lycopersicon esculentum Mill.) and its mRNA levels were analyzed. The cDNA encoded a deduced protein of 433 amino acids and possessed amino acid domains characteristic of flavin adenine dinucleotide- and NAD(P)H-binding proteins but did not possess typical eukaryotic targeting sequences, suggesting that it encodes a cytosolic form of AFR reductase. Low-stringency genomic DNA gel blot analysis indicated that a single nuclear gene encoded this enzyme. Total ascorbate contents were greatest in leaves, with decreasing amounts in stems and roots and relatively constant levels in all stages of fruit. AFR reductase activity was inversely correlated with total ascorbate content, whereas the relative abundance of AFR reductase mRNA was directly correlated with enzyme activity in tissues examined. AFR reductase mRNA abundance increased dramatically in response to wounding, a treatment that is known to also induce ascorbate-dependent prolyl hydroxylation required for the accumulation of hydroxyproline-rich glycoproteins. In addition, AFR reductase may contribute to maintaining levels of ascorbic acid for protection against wound-induced free radical-mediated damage. Collectively, the results suggest that AFR reductase activity is regulated at the level of mRNA abundance by low ascorbate contents or by factors that promote ascorbate utilization.     

Catalytic activity of cytochrome oxidase and cytochrome c in apolar solvents containing phospholipids and low amounts of water

Cytochrome c and cytochrome oxidase, in bovine heart submitochondrial particles and in their purified forms, were transferred to a ternary system that contained phospholipids (10 mg/ml toluene), the apolar solvent toluene, and water at concentrations of 13-15 microliters (high water) and 3 microliters (low water) per milliliter of toluene. When the enzymes were transferred back to an all water system, they exhibited full catalytic capacity. In the low water ternary system, cytochrome c could be reduced by ascorbate introduced via inverted micelles. Also in this system, cytochrome oxidase was reduced by ascorbate and cytochrome c but its oxidation was highly impaired. Data on the kinetics of reduction by ascorbate of cytochrome c and cytochrome oxidase under these conditions are presented. Cytochrome oxidase reduced in the organic solvent by ascorbate failed to form a complex with CO, but formed a complex with cyanide introduced via inverted micelles. The oxidized and the ascorbate-reduced cytochrome oxidase-cyanide complex exhibited a trough at 415 nm and a peak at 433 nm. The extent and rate of formation of the cyanide complex were higher with the reduced form of cytochrome oxidase. To achieve protein-protein interactions (cytochrome c-cytochrome oxidase) in the ternary system, it was necessary to extract the two proteins together. There was no functional interaction when they were extracted separately and mixed. In the high water ternary system reduced cytochrome oxidase was not detected, and it oxidized ascorbate at a higher rate than in the low water system; however, this rate was several orders of magnitude lower than in aqueous media.     

Cytochrome b561 catalyzes transmembrane electron transfer

Purified cytochrome b561 from bovine adrenal medulla chromaffin vesicles has been reconstituted into phosphatidylcholine vesicles by a detergent-dialysis method. When the reconstituted cytochrome-containing vesicles were preloaded with ascorbic acid and cytochrome c was added to the external medium, the internal ascorbic acid was able to reduce the external cytochrome c. This reduction of cytochrome c was dependent on the presence of cytochrome b561 in the membrane and was not due to leakage of ascorbate from the vesicles. These results demonstrate that cytochrome b561 catalyzes a transmembrane electron transfer.     

Synthesis of a cytochrome c derivative with prolonged in vivo half-life and determination of ascorbyl radicals in the circulation of the rat.

Since cytochrome c and acetylated cytochrome c disappear from the circulation with a half-life of 4 min, these proteins cannot be used for in vivo detection of superoxide radicals and related metabolites. To determine superoxide and other radicals in vivo, a cytochrome c derivative (SMAC) was synthesized by linking 1 mol of poly(styrene-co-maleic acid) butyl ester (SM) to cytochrome c, followed by acetylation of its lysyl amino groups. SMAC retained 8 and 80% of cytochrome c activity to react with ascorbyl and superoxide radicals, respectively. However, SMAC did not serve as a substrate for cytochrome c reductase and cytochrome c oxidase. When injected intravenously to the rat, SMAC circulated bound to albumin with a half-life of 130 min. SMAC was rapidly reduced in the circulation of intact animals. Treatment of animals with paraquat markedly enhanced the reduction of the circulating SMAC. We have synthesized an SM-conjugated superoxide dismutase (SOD) derivative (SM-SOD) that circulates bound to albumin with a half-life of 6 h. Kinetic analysis revealed that SM-SOD effectively inhibited the superoxide-dependent reduction of SMAC either in the presence or absence of 0.5 mM albumin. However, the reduction of the circulating SMAC was not inhibited by SM-SOD both in normal and paraquat-treated animals. Plasma samples from both animal groups also reduced cytochrome c and SMAC by an SOD-insensitive mechanism. However, after treatment with ascorbate oxidase, both plasma samples lost their activity to reduce cytochrome c and SMAC. These and other results suggest that ascorbyl radical might principally be responsible for the reduction of circulating SMAC and that plasma levels of ascorbyl radical might increase in paraquat-treated animals.     

The action of ascorbate in vesicular systems

Many effects of ascorbate center on its interactions with membranes from plant and animal cells. These actions can be studied using vesicles produced from phospholipid components (liposomes), by isolating naturally occurring vesicles, or by purifying particular membranes that form vesicles during the extraction process. Liposomes have provided information concerning the anti- and prooxidant properties of ascorbate and about how the water-soluble vitamin can have effects within the phospholipid bilayer. The involvement of ascorbate in transmembrane electron transport has been characterized in vesicles normally found in certain cells, such as, chromaffin granules, synaptosomes, glyoxisomes, peroxisomes, and clathrincoated vesicles. Redox activity using reducing power associated with ascorbate/ascorbate free radical (AFR) has been characterized in some of these vesicles and it appears to be mediated by ab-type cytochrome. Ascorbate also participates in the reduction of iron within clathrin-coated vesicles. Vesicles appearing during purification of plasma membranes have transmembrane electron transport, oxidoreductase activity with ascorbate/AFR as redox agents, and an ascorbate-reducibleb-type cytochrome. It is also possible that ascorbate-related redox activity exists at the tonoplast of plant cells.     

The orientation of cytochrome c oxidase in coupled phospholipid membrane vesicles--a spin-label study.

Cytochrome oxidase, an enzyme containing six different subunits, has been shown to span the inner mitochrondrial membrane. The arrangement of the subunits within the membrane is unknown. Wh have specifically labeled the 25 000 molecular weight subunit with a spin-label derivative of N-ethylmaleimide, 3-maleimido-2,2,5,5-tetramethyl-1-pyrrolidinyloxyl (NEM-SL(5)). NEM-SL(5)-lebeled cytochrome oxidase can be incorporated into phospholipid membranes to form coupled vesicles of the Hinkle, Kim & Racker ((1972) Jriol. Chem; 247, 1338-1399) type. The resonance spectrum of NEM-SL(5) is similar in both soluble and vesicular cytochrome oxidase. Since ascorbate has been shown to reduce only spin label that is exposed to the exterior surface of a closed vesicle, we have used ascorbate to determine the NEM-SL(5)-binding site in the coupled vesicles; NEM-SL(5)-labeled cytochrome oxidase vesicles are reduced by 10 mM ascorbate with tau 1/2 of 1 min at 22 degrees C; The rate of reduction is relatively independent of temperature. We conclude that (1) cytochrome oxidase is unidirectionally or preferentially oriented in the vesicle membrane, and (2) the NEM-SL(5)-binding site on the 25 000 molecular weight subunit is exposed to the external aqueous medium.     

Pathways of cytochrome c oxidation by soluble and membrane-bound cytochrome aa3

In media of low ionic strength, membraneous cytochrome c oxidase, isolated cytochrome c oxidase, and proteoliposomal cytochrome c oxidase each bind cytochrome c at two sites, one of low affinity (1 microM greater than Kd' greater than 0.2 microM) and readily reversible and the other of high affinity (0.01 microM greater than Kd) and weakly reversible. When cytochrome c occupies both sites, including the low affinity site, the maximal turnover measured polarographically with ascorbate and N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) is independent of TMPD concentration, and lies between 250 and 400 s-1 (30 degrees C, pH 7.4) for fully activated systems. The apparent affinity of the enzyme for cytochrome c is, however, TMPD dependent. When cytochrome c occupies only the high-affinity site, the maximal turnover is closely dependent upon the concentration of TMPD, which, unlike ascorbate, can reduce bound cytochrome c. As TMPD concentration is increased, the maximal turnover approaches that seen when both sites as occupied. The lower activity of isolated cytochrome aa3 is due to the presence of inactive or inaccessible enzyme molecules. Incorporation of isolated enzyme into phospholipid vesicles restores full activity to all the subsequently accessible cytochrome aa3 molecules. Negatively charged (asolectin) vesicles show a higher cytochrome c affinity at the low-affinity sites than do the other enzyme preparations. A model for the cytochrome c-cytochrome aa3 complexes is put forward in which both sites, when occupied, are fully catalytically competent, but in which occupation of the "tight" site by a catalytically functional cytochrome c molecule is required for overall oxidation of cytochrome c via the "loose" site.     

Oxidation and reduction of cytochrome c bound to the phosphoprotein phosvitin

The oxidation-reduction reactions and structural characteristics of phosvitin-bound cytochrome c were examined at various ratios of cytochrome c to phosvitin. At binding ratios below half the maximum, the rate constants for the oxidation reactions with cytochrome c oxidase and ferricyanide and the rate constants for the reduction reactions with cytochrome b2 and ascorbate were low, but at higher ratios these rate constants gradually increased to that of free cytochrome c and, in particular, the rate constant for oxidation by cytochrome c oxidase was raised to two to three times that of the free form. This binding-ratio dependence of the rate constants for the oxidation and reduction reactions was different from that of the net charge of the cytochrome c-phosvitin complex, implying that the negative charges of phosvitin are unlikely to modulate the rates. In contrast, the broadening of the NMR signals for the heme and methionine-80 methyl groups and the conformational transition in the vicinity of the heme moiety on change from the native to the cyanide-bound or urea-denatured form of cytochrome c showed a similar binding-ratio dependence to the rate constants for the oxidation and reduction reactions. Since the conformation and electronic structure in the heme environment of ferric and ferrous cytochromes c were not changed significantly by binding to phosvitin, and since the binding strength of cytochrome c to phosvitin at binding ratios below half the maximum is different from that at higher ratios, these findings suggest that a difference in the movement of cytochrome c in its complex with phosvitin may modulate its oxidation-reduction reactions.     

Rate of electron transfer between cytochrome b561 and extravesicular ascorbic acid

Cytochrome b561 transfers electrons across secretory vesicle membranes in order to regenerate intravesicular ascorbic acid. To show that cytosolic ascorbic acid is kinetically competent to function as the external electron donor for this process, electron transfer rates between cytochrome b561 in adrenal medullary chromaffin vesicle membranes and external ascorbate/semidehydroascorbate were measured. The reduction of cytochrome b561 by external ascorbate may be measured by a stopped-flow method. The rate constant is 450 (+/- 190) M-1 s-1 at pH 7.0 and increases slightly with pH. The rate of oxidation of cytochrome b561 by external semidehydroascorbate may be deduced from rates of steady-state electron flow. The rate constant is 1.2 (+/- 0.5) x 10(6) M-1 s-1 at pH 7.0 and decreases strongly with pH. The ratio of the rate constants is consistent with the relative midpoint reduction potentials of cytochrome b561 and ascorbate/semidehydroascorbate. These results suggest that cytosolic ascorbate will reduce cytochrome b561 rapidly enough to keep the cytochrome in a mostly reduced state and maintain the necessary electron flux into vesicles. This supports the concept that cytochrome b561 shuttles electrons from cytosolic ascorbate to intravesicular semidehydroascorbate, thereby ensuring a constant source of reducing equivalents for intravesicular monooxygenases.     

Respiratory electron transfer activity in an asolectin-isooctane reverse micellar system.

Bovine heart submitochondrial particles (SMP) were solubilized in an asolectin isooctane reverse micellar system and the functionality of the respiratory chain was tested by spectroscopic and amperometric techniques. Electron transfer rate supported by NADH was very slow as evidenced by the low cytochrome reduction levels attained over long incubation periods. In the presence of KCN, NADH caused 34% and 12.5% reduction of the cytochromes aa3 and c, respectively, and negligible reduction of cytochrome b. Supplementation of the system with menadione rose the NADH-dependent reduction of all the cytochromes to levels that were close to the total content. However, no measurable O2 uptake activity took place in the presence of NADH plus menadione, or with ascorbate (or NADH) plus TMPD reducing systems. Therefore, it is suggested that in the organic medium, electron transfer from NADH to O2 is arrested at the terminal oxidase step. Cytochrome oxidase reduced by ascorbate (or NADH) plus TMPD seems to be trapped in its half reduced state (ie, a2+ a3(3+)). Although it is poorly reactive with O2, it can transfer electrons back to cytochrome c and TMPD. The electron transfer block to O2 was overcome when PMS was used instead of TMPD. This seems to be due to the recognized capacity of PMSH2 to carry out simultaneous reduction of both a CuA and a3 CuB redox centers of cytochrome oxidase. The cytochrome oxidase reaction in the organic solvent was highly sensitive to KCN (Ki 1.9 microM) and showed bell-shaped kinetics towards the PMS concentration and a sigmoidal response to water concentration, reaching its maximal turnover number (18 s-1) at 4 mM PMS and 1.1% (v/v) water.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of presence of ascorbic acid and the appearance of ascorbate peroxidase activity in embryos of Avena sativa L

Avena sativa L. grains are devoid of ascorbic acid (AA) and of oxidative enzymes (AA oxidase and AA peroxidase), while both reducing enzymes (AFR reductase and DHA reductase) are present. AA biosynthesis in the embryos starts after 12-14 hours of germination and at the same time AA peroxidase activity is detectable. During the following 14 hours the AA peroxidase activity rises up to 28 nmoles/AA oxidated/min/mg/prot. Incubation of Avena embryos with GL (the last precursor of AA according to the Isherwood biosynthetic pathway), results in both earlier AA biosynthesis and enhanced AA peroxidase activity. A 4 hour treatment is enough to induce AA synthesis and AA peroxidase elicitation. These data suggest that the development of AA peroxidase activity is controlled by AA, but they are not sufficient to clarify how that happens. Probably AA induces the synthesis of specific m-RNAs or activates enzymic precursors present in the embryos but still not working.