Ascorbate-mediated electron transfer in protein thiol oxidation in the endoplasmic reticulum

Addition of, or gulonolactone oxidase-dependent in situ generation of, ascorbate provoked the oxidation of protein thiols, which was accompanied by ascorbate consumption in liver microsomal vesicles. The maximal rate of protein thiol oxidation was similar upon gulonolactone, ascorbate or dehydroascorbate addition. Cytochrome P450 inhibitors (econazole, proadifen, quercetin) decreased ascorbate consumption and the gulonolactone or ascorbate-stimulated thiol oxidation. The results demonstrate that the ascorbate/dehydroascorbate redox couple plays an important role in electron transfer from protein thiols to oxygen in the hepatic endoplasmic reticulum, even in gulonolactone oxidase deficient species.     

Induction and peroxisomal appearance of gulonolactone oxidase upon clofibrate treatment in mouse liver

Various antihyperlipemic peroxisome proliferators are known to be carcinogenic in rodents but not in human, other primates and guinea pig, which species lost their ability to synthesize ascorbate due to mutations in the gulonolactone oxidase gene. Ascorbate synthesis is accompanied by H2O2 production, consequently its induction can be potentially harmful; therefore, the in vivo effect of the peroxisome proliferator clofibrate was investigated on gulonolactone oxidase expression in mouse liver. Liver weights and peroxisomal protein contents were increased upon clofibrate treatment. Elevated plasma ascorbate concentrations were found in clofibrate-treated mice due to the higher microsomal gulonolactone oxidase activities. Remarkable gulonolactone oxidase activity appeared in the peroxisomal fraction upon the treatment. Increased activity of the enzyme was associated with an elevation of its mRNA level. According to the present results the evolutionary loss of gulonolactone oxidase may contribute to the explanation of the missing carcinogenic effect of peroxisome proliferators in humans.     

Biosynthesis of ascorbic acid by extant actinopterygians

Polypterus senegalus , the longnose gar Lepisosteus osseus and the bowfin Amia calva had gulonolactone oxidase activity in the kidney and thus can synthesize ascorbic acid de novo . The enzyme activity was associated with the microsomal fraction. The common carp Cyprinus carpio and the goldfish Carassius auratus had no gulonolactone oxidase activity. Antibodies directed against white sturgeon gulonolactone oxidase showed cross-reactivity with lake sturgeon, bowfin and longnose gar kidney enzymes, but not with enzymes from Polypterus , sea lamprey, and tadpole kidney or pig liver. Given cross-reactivity, gulonolactone oxidase relatedness matched actinopterygian phylogeny, and suggested homology of the character throughout fishes. Modern teleosts may have lost the ability to synthesize ascorbic acid since the late Triassic as a result of a single reversal in the founding population. Wild bowfin and longnose gar exhibited high ascorbate concentrations in liver and spleen when compared with the teleosts rainbow trout Oncorhynchus mykiss and common carp fed vitamin C-supplemented diets.     

Role of ascorbate in oxidative protein folding

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

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

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

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 suggest that reductant other than ascorbate can at least partially satisfy the requirement for a reductant in the prolyl hydroxylase reaction in vivo.     

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

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

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.     

Iron-dependent uptake of ascorbate into isolated microsomes

A preliminary study (J.M. Mata, R. Assad, and B. Peterkofsky (1981) Arch. Biochem. Biophys. 206, 93-104) suggested that chick embryo limb bone microsomes took up and concentrated [14C]ascorbate in the presence of cofactors for prolyl hydroxylase. In the present study, we found that the apparent Km for ascorbate in the hydroxylation of intracisternal unhydroxylated procollagen by endogenous prolyl hydroxylase was approximately an order of magnitude less than the value obtained when enzyme solubilized from microsomes was used with an exogenous substrate. These results are compatible with a concentrative uptake of ascorbate into microsomes. The uptake of [14C]ascorbate into microsomes was confirmed and it required only iron, in either the ferrous or ferric form, and was time and temperature dependent, proportional to microsome concentration, and substrate saturable at 2-3 mM ascorbate. Iron-dependent ascorbate uptake also was observed with L-929 cell microsomes. [14C]Ascorbate seemed to be taken up without prior oxidation, since only unlabeled ascorbate, and not dehydroascorbate, competed for uptake into limb bone microsomes. A functional requirement for Fe2+ in ascorbate transport was demonstrated using the intracisternal proline hydroxylating system. L-929 cell microsomes were preincubated with ascorbate with or without the metal and then external ascorbate was oxidized to inactive dehydroascorbate using ascorbic acid oxidase, which cannot penetrate the microsomal membrane. Samples which did not receive iron during the preincubation received it, along with other requirements for prolyl hydroxylase, in a final incubation to measure hydroxylation. Significant hydroxylation was obtained only in samples incubated with iron prior to oxidase treatment, consistent with the conclusion that an iron-dependent process was required to translocate ascorbate and protect it from the oxidase.     

Scurvy-prone animals, including man, monkey, and guinea pig, do not express the gene for gulonolactone oxidase

Man, monkeys, and guinea pigs cannot synthesize ascorbic acid due to a lack of gulonolactone oxidase activity. Recently, using two immunological methods, immunoprecipitation and microcomplement fixation, we reported that guinea pigs do not contain antigenic material related to gulonolactone oxidase. Now, using such immunologie techniques as double immunodiffusion, microcomplement fixation, antibody affinity chromatography, and a more sensitive radioimmunoassay, we have found that all three of these species do not contain immunologically cross-reacting material to gulonolactone oxidase. On the other hand, comparable extracts from tissues of all other species that were investigated and that do possess gulonolactone oxidase did cross-react with antiserum to enzyme from two widely differing species, rat and goat. We conclude that the gene for gulonolactone oxidase is not expressed in these scurvy-prone animals.     

Tomato vesicles as a model system for studying in situ activity of 1-aminocyclopropane-1-carboxylic acid oxidase

A model system is described which could be used for the studyof ACC oxidase in vivo. The enzyme is localized within sedimentablevesicles isolated from the locular tissue of ripening tomatofruit. These vesicles display linear ACC oxidase activity overa period of at least 3 h and this activity is not dependenton the essential cofactors (Fe²⁺ and ascorbate) needed for theenzyme in vitro. This system has been used to demonstrate thepresence of an inhibitors) of ACC oxidase activity in the locularjuice and also to study the effects of ionophores and uncouplerson the in vivo enzyme activity. Key words: ACC oxidase, tomato, Lycopersicon esculentum     

Electron transfer in chromaffin-vesicle ghosts containing peroxidase.

In chromaffin vesicles, the enzyme dopamine beta-monooxygenase converts dopamine to norepinephrine. It is believed that reducing equivalents for this reaction are supplied by intravesicular ascorbic acid and that the ascorbate is regenerated by importing electrons from the cytosol with cytochrome b-561 functioning as the transmembrane electron carrier. If this is true, then the ascorbate-regenerating system should be capable of providing reducing equivalents to any ascorbate-requiring enzyme, not just dopamine beta-monooxygenase. This may be tested using chromaffin-vesicle ghosts in which an exogenous enzyme, horseradish peroxidase, has been trapped. If ascorbate and peroxidase are trapped together within chromaffin-vesicle ghosts, cytochrome b-561 in the vesicle membrane is found in the reduced form. Subsequent addition of H2O2 causes the cytochrome to become partially oxidized. H2O2 does not cause this oxidation if either peroxidase or ascorbate are absent. This argues that the cytochrome is oxidized by semidehydroascorbate, the oxidation product of ascorbate, rather than by H2O2 or peroxidase directly. The semidehydroascorbate must be internal because the ascorbate from which it is formed is sequestered and inaccessible to external ascorbate oxidase. This shows that cytochrome b-561 can transfer electrons to semidehydroascorbate within the vesicles and that the semidehydroascorbate may be generated by any enzyme, not just dopamine beta-monooxygenase.     

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.     

Studies on the transmembrane orientation of cytochrome c oxidase in phospholipid vesicles

We report investigations into the direction of orientation of cytochrome c oxidase in reconstituted vesicles and the factors determining this. Measurement of the enzyme orientation employed two independent techniques: monitoring of the level of haem reduction by membrane-permeant and membrane-impermeant reagents and a kinetic analysis of the reduction of a spin label covalently bound to the oxidase surface. The method of preparation of the oxidase vesicles had a pronounced effect on the enzyme orientation and the two measurement techniques agreed in indicating that the proportion of mitochondrially oriented enzyme was approximately 85% and 50% for vesicles prepared by cholate dialysis and sonication respectively. Our results show that the membrane orientation of the oxidase is determined by interactions between the phospholipid bilayer and the portion of the enzyme embedded therein, as opposed to gross physical constraints. In particular, we demonstrate that the orientation of the oxidase is affected by the fluidity and surface charge of the membrane.     

Preparation of reconstituted cytochrome oxidase vesicles with defined trans-membrane protein orientations employing a cytochrome c affinity column

Reconstituted cytochrome oxidase systems in which the majority of the vesicles contain a single oxidase dimer can be prepared. It is shown that, when these are passed through a cytochrome c affinity column, only those vesicles oriented outwards (such that the active site is available to external cytochrome c) are bound to the support matrix. Protein-free vesicles and vesicles containing an inwardly oriented enzyme are eluted in the void volume. Subsequently, vesicles containing an outwardly oriented enzyme can be eluted from the column at high salt concentrations. This protocol has been used successfully to resolve vesicles of either oxidase orientation when the enzyme is reconstituted with a variety of lipid mixtures. The recovery of oxidase activity from the column ranged between 75 and 94%.     

Measurements of the proton motive force generated by cytochrome c oxidase from Bacillus subtilis in proteoliposomes and membrane vesicles

Cytochrome c oxidase from Bacillus subtilis was reconstituted in liposomes and its energy-transducing properties were studied. The reconstitution procedure used included Ca2+-induced fusion of pre-formed membranes. The orientation of the enzyme in liposomes is influenced by the phospholipid composition of the membrane. Negatively charged phospholipids are essential for high oxidase activity and respiratory control. Analyses of the proteoliposomes by gel filtration, density gradient centrifugation and electron microscopy indicated a heterogeneity of the proteoliposomes with respect to size and respiratory control. Cytochrome c oxidase activity in the proteoliposomes resulted in the generation of a proton motive force, internally negative and alkaline. In the presence of the electron donor, ascorbate/N,N,N',N'-tetramethyl-p-phenylenediamine/cytochrome c or ascorbate/phenazine methosulphate, the reconstituted enzyme generated an electrical potential of 84 mV which was increased by the addition of nigericin to 95 mV and a pH gradient of 32 mV which was increased by the addition of valinomycin to 39 mV. Similar results were obtained with beef-heart cytochrome c oxidase reconstituted in liposomes. The maximal proton motive force which could be generated, assuming no endogenous ion leakage, varied over 110-140 mV. From this the efficiency of energy transduction by cytochrome c oxidase was calculated to be 18-23%, indicating that the oxidase is an efficient proton-motive-force-generating system.     

The terminal step in vitamin C biosynthesis in Trypanosoma cruzi is mediated by a FMN-dependent galactonolactone oxidase

Humans lack the ability to synthesize vitamin C (ascorbate) due to the absence of gulonolactone oxidase, the last enzyme in the biosynthetic pathway in most other mammals. The corresponding oxidoreductase in trypanosomes therefore represents a target that may be therapeutically exploitable. This is reinforced by our observation that Trypanosoma cruzi, the causative agent of Chagas' disease, lacks the capacity to scavenge ascorbate from its environment and is therefore dependent on biosynthesis to maintain intracellular levels of this vitamin. Here, we show that T. cruzi galactonolactone oxidase (TcGAL) can utilize both L-galactono-gamma-lactone and D-arabinono-gamma-lactone as substrates for synthesis of vitamin C, in reactions that obey Michaelis-Menten kinetics. It is >20-fold more active than the analogous enzyme from the African trypanosome Trypanosoma brucei. FMN is an essential cofactor for enzyme activity and binds to TcGAL non-covalently. In other flavoproteins, a histidine residue located within the N-terminal flavin-binding motif has been shown to be crucial for cofactor binding. Using site-directed mutagenesis, we show that the corresponding residue in TcGAL (Lys-55) is not essential for this interaction. In contrast, we find that histidine and tryptophan residues (His-447 and Trp-448), localized within a C-terminal motif (HWXK) that is a feature of ascorbate-synthesizing enzymes, are necessary for the FMN association. The conserved lysine residue within this motif (Lys-450) is not required for cofactor binding, but its replacement by glycine renders the protein completely inactive.     

The ascorbic acid-dependent oxidation of reduced nicotinamide–adenine dinucleotide by ciliary and retinal microsomes: The effect of some pharmacologically active compounds on this reaction

1. The presence of an ascorbic acid-dependent NADH oxidation in ocular tissues has been established. Subcellular fractionation revealed that the enzyme is localized in the microsomes. The distribution of the enzyme in some ocular tissues has been determined; microsomes from the ciliary processes and the retina have comparable activities, which are much higher than those from the cornea or lens. 2. NADPH cannot replace NADH, and cysteine, reduced glutathione, ergothioneine and dehydroascorbic acid cannot be substituted for ascorbic acid in the reaction. The rate of NADH oxidation was greatly increased in the presence of cucumber ascorbate oxidase, and the enzyme appears to be NADH–monodehydroascorbate transhydrogenase. 3. Cytochrome b₅ is present in retinal microsomes. 4. The enzyme is inhibited by p-chloromercuribenzoate and iodoacetate, but not by cyanide, Amytal or malonate. 5. High concentrations of chloroquine cause a partial inhibition of the reaction, probably owing to interaction of this compound with the enzyme thiol groups. Low concentrations of Diamox, comparable with those attained in tissues during therapy with this drug, bring about partial inhibition of the reaction. Eserine, cortisone, hydrocortisone, 11-deoxycorticosterone and dexamethasone have no effect on the rate of oxidation. 6. The possible role of ascorbic acid and NADH–monodehydroascorbate transhydrogenase in the formation of aqueous humour and secretory mechanisms is discussed.     

Fusion of phospholipid vesicles reconstituted with cytochrome c oxidase and mitochondrial hydrophobic protein.

Reconstituted cytochrome oxidase liposomes were fused with liposomes reconstituted with mitochondrial hydrophobic protein, which acts as a membrane-bound uncoupler of cytochrome oxidase. Fusion was assayed by the loss of respiratory control of cytochrome oxidase as measured by the increased rate of ascorbate oxidation induced by hydrophobic protein when both proteins shared the same vesicles. Fusion was dependent on the presence of phosphatidylserine in the liposomes Ca++ in the aqueous medium. Phosphatidylcholine-phosphatidylserine liposomes required higher concentrations of phosphatidylserine and Ca++ than did phosphatidylethanolamine-phosphatidylserine liposomes. Cytochrome oxidase vesicles containing high concentrations of phosphatidylserine showed little or no respiratory control, while those with lower concentrations showed high respiratory control; respiratory control could be induced by fusing cytochrome oxidase vesicles containing high phosphatidylserine with protein-free liposomes containing low phosphatidylserine concentration. If cytochrome oxidase vesicles and hydrophobic protein vesicles were prefused separately for 15 min, they lost the ability to fuse upon being subsequently mixed together. The reconstituted vesicles had diameters of about 200 A; fusion yielded vesicles with diameters in excess of 1000 A.