Inhibition of DT-diaphorase potentiates the in vivo neurotoxic effect of intranigral injection of salsolinol in rats

The present study shows that intranigral injection of dicoumarol, a DT-diaphorase inhibitor, potentiates the neurotoxic effect of salsolinol (salsolinol 1.25 nmoles plus dicoumarol 2 nmoles; in 2 microl). Rats treated with dicoumarol plus salsolinol presented a characteristic contralateral rotational behaviour when they were stimulated with apomorphine (0.5 mg/kg, s.c.), similar to rats injected unilaterally with 6-hydroxydopamine (6-OHDA). These rats also exhibited impairment of motor and cognitive behaviours. The results support the hypothesis that DT-diaphorase plays a protective role in the nigrostriatal dopaminergic systems.

MPP+-induced degeneration is potentiated by dicoumarol in cultures of the RCSN-3 dopaminergic cell line. Implications of neuromelanin in oxidative metabolism of dopamine neurotoxicity

We have tested the idea that oxidative metabolism of dopamine may be involved in MPTP toxicity using the RCSN-3 cell line derived from the substantia nigra of an adult rat. Treatment with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) (10 microM), MPTP combined with 40 microM dicoumarol (an inhibitor of DT-diaphorase) and dicoumarol alone, did not induce toxicity in RCSN-3 cells after 72 h incubation. The lack of toxicity in MPTP-treated RCSN-3 cells may be explained by the fact that they are unable to metabolize MPTP to 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridinium ion (MPP+ as determined by HPLC. Incubation for 72 h with 100 microM MPP+ induced a 6.6 +/- 1.4% cell death of RCSN-3 cells compared to 3.5 +/- 0.4 observed in control cells. However, when the cells were treated with 100 microM MPP+ and 40 microM dicoumarol, cell death increased 4-fold compared to that of cells treated solely with MPP+ (27 +/- 2%; P<0.001). Under these conditions, a significant increase in DNA fragmentation (3-fold compared to MPP+ alone; P<0.01) and in calpain activation (P<0.05 compared to control) was evident. The inhibition of DT-diaphorase by dicoumarol supports the idea that oxidative metabolism of dopamine is involved in MPP+ toxicity in RCSN-3 cells.

Behavioral effects of aminochrome and dopachrome injected in the rat substantia nigra

The exact mechanism of cell death in neurodegenerative diseases remains obscure, although there is evidence that their pathogenesis may involve the formation of free radicals originating from the oxidative metabolism of catecholamines. The purpose of this study was to evaluate the degree of neurodegenerative changes and behavioral impairments induced by unilateral injection into the rat substantia nigra of cyclized o-quinones, aminochrome and dopachrome, derived from oxidizing dopamine and L-DOPA, respectively, with Mn(3+)-pyrophosphate complex. The behavioral changes were compared with those induced after selective lesions of dopaminergic neurons with 6-hydroxydopamine (6-OHDA). Intranigral injection of aminochrome and dopachrome produced impairment in motor and cognitive behaviors. The behavioral impairment was also revealed by apomorphine-induced rotational asymmetry. Apomorphine (0.5 mg/kg sc) significantly increased rotational behavior in rats injected with aminochrome and dopachrome. These rats presented a clear motor bias showing a significant contralateral rotation activity, similar but less vigorous that in rats injected with 6-OHDA. The avoidance conditioning was seriously impaired in rats injected with aminochrome and dopachrome although only dopachrome-injected rats showed a similar hypomotility to 6-OHDA-injected rats. The behavioral effects were correlated to the extent of striatal tyrosine hydroxylase (TH)-positive fiber loss. Rats receiving unilateral intranigral aminochrome and dopachrome injections exhibited a 47.9+/-5.1% and a 39.7+/-4.4% reduction in nigrostriatal TH-positive fiber density. In conclusion, this study provided evidence that oxidizing DA and L-DOPA to cytotoxic quinones, aminochrome and dopachrome appears to be an important mediator of oxidative damage in vivo.

Neurotoxicity of some MAO inhibitors in adult rat hypothalamic cell culture

Monoamine oxidase-A (MAO-A) [amiflamine (AMF) and 4-methylthioamphetamine (MTA)] and MAO-B (L-deprenyl) inhibitors were found to be cytotoxic in a concentration-dependent manner for RCHT cells derived from adult rat hypothalamus. The cytotoxic effects were increased when the inhibitors were co-incubated with dicoumarol and especially with 25 micro M AMF+100 micro M dicoumarol (2.5-fold; P <0.001). The treatment of RCHT cells solely with AMF induced a marked decrease in the expression of DT-diaphorase mRNA.

Inhibition of DT-diaphorase is a requirement for Mn(III) to produce a 6-OH-dopamine like rotational behaviour

Intracerebral manganese administration together with the DT-diaphorase inhibitor dicoumarol [Mn(III) 40 nmol + -dicoumarol 2 nmol; in 4 micro l] into the left medial forebrain bundle (MFB) produced a behavioural pattern characterized by contralateral behaviour when the rats were stimulated with apomorphine (0.5 mg/kg s.c.), in a manner similar to that when administered to unilaterally 6-hydroxy-dopamine-lesioned animals. The same animals rotated towards the opposite side (ipsilaterally) when stimulated with d-amphetamine (2 mg/kg s.c.). These results support the idea that DT-diaphorase plays a protective role in the dopaminergic systems.

Possible role of salsolinol quinone methide in the decrease of RCSN-3 cell survival

The endogenous dopamine-derived neurotoxin salsolinol was found to decrease survival in the dopaminergic neuronal cell line RCSN-3, derived from adult rat substantia nigra in a concentration-dependent manner (208 microM salsolinol induced a 50% survival decrease). Incubation of RCSN-3 cells with 100 micro;M dicoumarol and salsolinol significantly decreased cell survival by 2.5-fold (P < 0.001), contrasting with a negligible effect on RCHT cells, which exhibited nearly a 5-fold lower nomifensine-insensitive dopamine uptake. The levels of catalase and glutathione peroxidase mRNA were decreased when RCSN-3 cells were treated with 100 microM salsolinol alone or in the presence of 100 microM dicoumarol. In vitro oxidation of salsolinol to o-quinone catalyzed by lactoperoxidase gave the quinone methide and 1,2-dihydro-1-methyl-6,7-isoquinoline diol as final products of salsolinol oxidation as determined by NMR analysis. Evidence of the formation of salsolinol o-semiquinone radical has been provided by ESR studies during one-electron oxidation of salsolinol catalyzed by lactoperoxidase.

Copper neurotoxicity is dependent on dopamine-mediated copper uptake and one-electron reduction of aminochrome in a rat substantia nigra neuronal cell line

The mechanism of copper (Cu) neurotoxicity was studied in the RCSN-3 neuronal dopaminergic cell line, derived from substantia nigra of an adult rat. The formation of a Cu-dopamine complex was accompanied by oxidation of dopamine to aminochrome. We found that the Cu-dopamine complex mediates the uptake of (64)CuSO(4) into the Raúl Caviedes substantia nigra-clone 3 (RCSN3) cells, and it is inhibited by the addition of excess dopamine (2 m M) (63%, p < 0.001) and nomifensine (2 microM) (77%, p < 0.001). Copper sulfate (1 m M) alone was not toxic to RCSN-3 cells, but was when combined with dopamine or with dicoumarol (95% toxicity; p < 0.001) which inhibits DPNH and TPNH (DT)-diaphorase. Electron spin resonance (ESR) spectrum of the 5,5-dimethylpyrroline-N-oxide (DMPO) spin trap adducts showed the presence of a C-centered radical when incubating cells with dopamine, CuSO(4) and dicoumarol. A decrease in the expression of CuZn-superoxide dismutase and glutathione peroxidase mRNA was observed when RCSN-3 cells were treated with CuSO(4), dopamine, or CuSO(4) and dopamine. However, the mRNA expression of glutathione peroxidase remained at control levels when the cells were treated with CuSO(4), dopamine and dicoumarol. The regulation of catalase was different since all the treatments with CuSO(4) increased the expression of catalase mRNA. Our results suggest that copper neurotoxicity is dependent on: (i) the formation of Cu-dopamine complexes with concomitant dopamine oxidation to aminochrome; (ii) dopamine-dependent Cu uptake; and (iii) one-electron reduction of aminochrome.

The possible role of one-electron reduction of aminochrome in the neurodegenerative process of the dopaminergic system

We present for discussion a possible molecular mechanism explaining the formation of reactive oxygen species involved in the neurodegenerative process of dopaminergic system in Parkinson's disease. This new hypothesis involves one-electron reduction of aminochrome to o-semiquinone radical, which seems to be the reaction responsible for neurodegenerative process of dopaminergic system. Leukoaminochrome o-semiquinone is extremely reactive with oxygen, which reoxidizes by reducing oxygen to superoxide radicals. Superoxide radicals enzymatically or spontaneously dismutate to dioxygen and hydrogen peroxide which is a precursor of hydroxyl radicals. ESR-experiments have showed that aminochrome o-semiquinone is extremely reactive in the presence of oxygen compared to dopamine o-semiquinone. In addition, the antioxidant enzymes superoxide dismutase and catalase play a prooxidant role by increasing the autoxidation rate and formation of superoxide radicals. One electron reduction of aminochrome to o-semiquinone can be performed by flavoenzymes which use NADPH and NADH as electron donator. The ability of aminochrome o-semiquinone to autoxidize in the presence of oxygen gives rise to a redox cycling process which will continue until oxygen, NADH and/or NADPH are depleted. Depletion of NADPH will prevent glutathione reductase from reducing glutathione, which is one of the main antioxidants in the cell. In addition depletion of NADH will prevent the formation of ATP in the electron transport chain in the mitochondria. Two antioxidants, probably, neuroprotective reactions are also discussed.

Studies of aminochrome toxicity in a mouse derived neuronal cell line: is this toxicity mediated via glutamate transmission?

Aminochrome was found to be toxic in a mouse-derived neuronal cell line (CNh). The effect was concentration dependent (10-150microM). The issue whether aminochrome toxicity involves glutamate transmission was studied with several glutamate receptors antagonists. Incubation of the cells with aminochrome (150microM) in the presence of 100microM of the AMPA antagonist, NBQX resulted in an increase of cell survival, from 52 to 73%. However, this protective effect did not seem to be related to activation of ionotropic glutamate receptors since incubation of CNh cells with 200microM of glutamate resulted in only 10% decrease of cell survival. However, NBQX was found to inhibit in vitro the autoxidation process. One hundred microM AP-5 did not have any effect on aminochrome toxicity. The toxic effect of aminochrome on CNh cells seems to be dependent of extracellular activation since addition of dicoumarol, a specific inhibitor of DT-diaphorase, did not affect that toxicity, which can be explained perhaps by a lack of a transport system for aminochrome into the CNh cells.

Angiotensin receptor II is present in dopaminergic cell line of rat substantia nigra and it is down regulated by aminochrome

Angiotensin receptor II mRNA was found to be expressed in dopaminergic neuronal cell line RCSN3 of rat substantia nigra using RT-PCR reaction. Aminochrome (150 microM), a metabolite of the dopamine oxidative pathway, was found to down regulate the expression of angiotensin receptor mRNA in RCSN3 cells by 83% (p < 0.05).

Glutathione transferase M2-2 catalyzes conjugation of dopamine and dopa o-quinones

Human glutathione transferase M2-2 prevents the formation of neurotoxic aminochrome and dopachrome by catalyzing the conjugation of dopamine and dopa o-quinone with glutathione. NMR analysis of dopamine and dopa o-quinone-glutathione conjugates revealed that the addition of glutathione was at C-5 to form 5-S-glutathionyl-dopamine and 5-S-glutathionyl-dopa, respectively. Both conjugates were found to be resistant to oxidation by biological oxidizing agents such as O(2), H(2)O(2), and O(*-)(2), and the glutathione transferase-catalyzed reaction can therefore serve a neuroprotective antioxidant function.

Reduction of brain antioxidant defense upon treatment with butylated hydroxyanisole (BHA) and Sudan III in Syrian golden hamster

Treatment with the antioxidant butylated hydroxyanisole (BHA) or the azo dye Sudan III during two weeks led to changes in the brain enzymatic antioxidant defense of Syrian golden hamsters. BHA was able to induce liver superoxide dismutase (SOD) 2-fold but had no effect on the brain SOD activity, whereas SOD activity was reduced to 50% in brain and remained unchanged in liver with Sudan III. These two substances are known inducers of DT-diaphorase and in fact this enzymatic activity was induced 4- and 6-fold in liver with BHA and Sudan III, respectively. However, BHA promoted a significant 40% reduction, whereas no change was observed with Sudan III in brain DT-diaphorase activity. Glutathione(GSH)-related enzymatic activities were also assayed in brain and liver. No induction was observed with BHA or Sudan III for any of the activities tested in hamster brain: GSH S-transferase (GST), GSH peroxidase (GSH-Px) and glutathione disulfide (GSSG) reductase (GR). Only 1.3- and 1.4-fold increases of GST and GR activities were observed in liver and no change in any of these enzymatic activities in brain with BHA; a partial limitation of permeability to BHA of the blood-brain barrier may explain this results. Furthermore, Sudan III promoted reductions in all these GSH-related enzymatic activities in brain and liver. The possible explanations for these results are discussed.

Regioselectivity and reversibility of the glutathione conjugation of quercetin quinone methide

The chemical reactivity, isomerization, and glutathione conjugation of quercetin o-quinone were investigated. Tyrosinase was used to generate the unstable quercetin o-quinone derivative which could be observed upon its subsequent scavenging by glutathione. Identification of the products revealed formation of 6-glutathionyl-quercetin and 8-glutathionyl-quercetin adducts. Thus, in particular, glutathione adducts in the A ring of quercetin were formed, a result which was not expected a priori. Quantum mechanical calculations support the possibility that the formation of these glutathione adducts can be explained by an isomerization of quercetin o-quinone to p-quinone methides. Surprisingly, additional experiments of this study reveal the adduct formation to be reversible, leading to interconversion between the two quercetin glutathione adducts and possibilities for release and further electrophilic reactions of the quercetin quinone methide at cellular sites different from those of its generation.

Role of redox cycling and activation by DT-diaphorase in the cytotoxicity of 5-(aziridin-1-yl)-2,4-dinitrobenzamide (CB-1954) and its analogs

In tumor cell lines with high content of DT-diaphorase (EC 1.6.99.2), the cytotoxicity of 5-(aziridin-1-yl)-2,4-dinitrobenzamide (CB-1954) and its derivatives is exerted through DT-diaphorase-catalyzed formation of crosslinking species. However, little is known about other possible mechanisms of CB-1954 action. We have examined the toxicity of CB-1954 and its derivatives to bovine leukemia virus-transformed lamb fibroblasts (line FLK), which possessed moderate DT-diaphorase activity, 260 units/mg protein. The action of these compounds was accompanied by lipid peroxidation, their toxicity was decreased by desferrioxamine and antioxidant N,N'-diphenyl-p-phenylene diamine (DPPD), but, in most cases, not by dicumarol, an inhibitor of DT-diaphorase. Using multiparameter regression analysis, we have found that the toxicity of CB-1954 derivatives as well as that of several non-alkylating nitroaromatics, increased upon the increase in their single-electron reduction potential (E(1)7) and octanol/water partition coefficient (P), and almost did not depend on their reactivity towards DT-diaphorase. It seems that in cell lines with a moderate amount of DT-diaphorase, the toxicity of CB- 1954 and its analogs is exerted through their redox cycling.

Interplay between CYP3A-mediated metabolism and polarized efflux of terfenadine and its metabolites in intestinal epithelial Caco-2 (TC7) cell monolayers

PURPOSE

To further characterize cytochrome P450 (CYP) and P-glycoprotein (Pgp) expression in monolayers of the Caco-2 cell clone TC7, a cell culture model of the human intestinal epithelium. To study the interplay between CYP3A and Pgp as barriers to intestinal drug absorption in TC7 cells using terfenadine and its metabolites as substrates.

METHODS

mRNA expression of eight CYPs and Pgp was investigated in TC7 and parental Caco-2 (Caco-2p) cell monolayers using RT-PCR. The CYP3A kinetics was determined in microsomes from both cell lines. The transport, metabolism and efflux of terfenadine and its metabolites were investigated in TC7 monolayers.

RESULTS

Both TC7 and Caco-2p cells expressed mRNA for Pgp and several important CYPs. However, mRNA for CYP3A4 was detectable anly from TC7 cells. The relative affinity of CYP3A for terfenadine metabolism in the two cell lines was comparable, but the maximum reaction rate in the TC7 cells was 8-fold higher. The rate of transport of terfenadine and its metabolites hydroxy-terfenadine (HO-T) and azacyclonol across TC7 monolayers was 7.1-, 3.5- and 2.1-fold higher, respectively, in the basolateral to apical direction than it was in the apical to basolateral (AP-BL) direction. Inhibition studies indicated that the efflux was mediated by Pgp. Ketoconazole increased the AP-BL transport terfenadine dramatically by inhibiting both terfenadine metabolism and Pgp efflux.

CONCLUSIONS

Cell culture models such as TC7 provide qualitative information on drug interactions involving intestinal CYP3A and Pgp.

Quercetin may act as a cytotoxic prooxidant after its metabolic activation to semiquinone and quinoidal product

In the last ten years, there has been an important increase in interest in quercetin action as a unique antioxidant, but its putative role in numerous prooxidant effects is also being continually updated. The mechanism underlying this undesirable ability seems to involve its metabolic oxidoreductive activation. Based on the structural properties of quercetin, we have investigated whether its catechol moiety may be the potential tool for revealed toxicity. We demonstrated, with an ESR spin-stabilization technique coupled to conventional spectrophotometry, that o-semiquinone and o-quinone are indeed the products of enzymatically catalyzed oxidative degradation of quercetin. The former radical might serve to facilitate the formation of superoxide and depletion of GSH, which could confer a specificity of its prooxidative action in situ. The observed one-electron reduction of o-quinone may enrich the semiquinone pool, thereby magnifying its effect. The two-electron reduction of quinone can result in constant resupply of quercetin in situ, thereby also modulating another pathway of its known biological activities. We have also tried to see whether the intracellular oxidative degradation of quercetin can be confirmed under the controlled conditions of model monolayer cell cultures. The results are indicative of the intracellular metabolic activation of quercetin to o-quinone, the process which can be partially associated with the observed concentration-dependent cytotoxic effect of quercetin.

DT-diaphorase catalyzes N-denitration and redox cycling of tetryl

Rat liver DT-diaphorase (EC 1.6.99.2) catalyzed reductive N-denitration of tetryl (2,4,6-tri-nitrophenyl-N-methylnitramine) and 2,4-dinitrophenyl-N-methylnitramine, oxidizing the excess of NADPH. The reactions were accompanied by oxygen consumption and superoxide dismutase-sensitive reduction of added cytochrome c and reductive release of Fe2+ from ferritin. Quantitatively, the reactions of DT-diaphorase proceeded like single-electron reductive N-denitration of tetryl by ferredoxin:NADP+ reductase (EC 1.18.1.2) (Shah, M.M. and Spain, J.C. (1996) Biochem. Biophys. Res. Commun. 220, 563-568), which was additionally checked up in this work. Thus, although reductive N-denitration of nitrophenyl-N-nitramines is a net two-electron (hydride) transfer process, DT-diaphorase catalyzed the reaction in a single-electron way. These data point out the possibility of single-electron transfer steps during obligatory two-electron (hydride) reduction of quinones and nitroaromatics by DT-diaphorase.

Metabolic activation of dopamine o-quinones to o-semiquinones by NADPH cytochrome P450 reductase may play an important role in oxidative stress and apoptotic effects

In this study, it is shown that considerable evidence for the possible pathway by which dopamine o-quinone, o-quinone and aminochrome can be activated metabolically by NADPH cytochrome P450 reductase to high reactive semiquinones. These findings were discussed from a mechanistic standpoint as well as in terms of potential physiological implications of dopamine o-quinones and o-semiquinones' concerted action in oxidative stress and apoptotic events.

Quantitative structure activity relationships for the conversion of nitrobenzimidazolones and nitrobenzimidazoles by DT-diaphorase: implications for the kinetic mechanism

Quantitative structure activity relationships (QSARs) for the conversion of nitrobenzimidazolones and nitrobenzimidazoles by rat liver DT-diaphorase (EC 1.6.99.2) are described. The parameter used for description of the QSARs is the energy of the lowest unoccupied molecular orbital (E(LUMO)) of the nitroaromatic compounds. Interestingly, correlations with E(LUMO) were observed for both the natural logarithm of kcat, but also for the natural logarithm of kcat/Km. The minimal kinetic model in line with these QSARs is a ping-pong mechanism that includes a substrate binding equilibrium in the second half reaction.

Nitrobenzimidazoles as substrates for DT-diaphorase and redox cycling compounds: their enzymatic reactions and cytotoxicity

We have synthesized a number of nitrobenzimidazoles containing nitro groups in the benzene ring and found that they acted as relatively efficient substrates for rat liver DT-diaphorase (EC 1.6.99.2), their reactivity exceeding reactivities of nitrofurans and nitrobenzenes. Nitrobenzimidazoles were competitive with NADPH inhibitors of DT-diaphorase in menadione reductase reactions, their inhibition constant being unchanged in the presence of dicumarol and being increased in the presence of 2',5'-ADP. These data indicate that the poor reactivity of nitrobenzimidazoles and other nitroaromatics in comparison to quinones could be determined by their binding in the adenosine-phosphate binding region of the NADPH-binding site, whereas quinones bind at the nicotinamide-binding pocket at the vicinity of FAD of DT-diaphorase. The reduction of 4,5,6-trinitrobenzimidazol-2-one by DT-diaphorase most probably involves reduction of 5-nitro group to 5-nitroso or 5-hydroxylamine derivative at the initial step. A certain parallelism existed between reactivities of nitrobenzimidazoles toward DT-diaphorase and their reactivities in single-electron reduction by Anabaena ferredoxin:NADP+ reductase (EC 1.18.1.2) and Saccharomyces cerevisiae flavocytochrome b2 (EC 1.1.2.3), the latter being determined by electronic factors. However, we suppose that the relatively high reactivity of polinitrobenzimidazoles toward DT-diaphorase was due not only to electronic effects, but also to a sterical crowding of nitrogroups by each other. The toxicity of nitrobenzimidazoles to bovine leukemia virus-transformed lamb kidney fibroblasts (line FLK) with a moderate amount of DT-diaphorase (260 U/mg protein) is partly prevented by dicumarol. That points out to partial determination of nitrobenzimidazole cytotoxicity by their reduction by DT-diaphorase. Another important factor of nitrobenzimidazole toxicity to this cell line was oxidative stress, catalyzed by single-electron transferring enzymes.

Glutathione transferases catalyse the detoxication of oxidized metabolites (o-quinones) of catecholamines and may serve as an antioxidant system preventing degenerative cellular processes

o-Quinones are physiological oxidation products of catecholamines that contribute to redox cycling, toxicity and apoptosis, i.e. the neurodegenerative processes underlying Parkinson's disease and schizophrenia. The present study shows that the cyclized o-quinones aminochrome, dopachrome, adrenochrome and noradrenochrome, derived from dopamine, dopa, adrenaline and noradrenaline respectively, are efficiently conjugated with glutathione in the presence of human glutathione transferase (GST) M2-2. The oxidation product of adrenaline, adrenochrome, is less active as a substrate for GST M2-2, and more efficiently conjugated by GST M1-1. Evidence for expression of GST M2-2 in substantia nigra of human brain was obtained by identification of the corresponding PCR product in a cDNA library. Glutathione conjugation of these quinones is a detoxication reaction that prevents redox cycling, thus indicating that GSTs have a cytoprotective role involving elimination of reactive chemical species originating from the oxidative metabolism of catecholamines. In particular, GST M2-2 has the capacity to provide protection relevant to the prevention of neurodegenerative diseases.

Effects of four organohalogen environmental contaminants on cytochrome P450 forms that catalyze 4- and 2-hydroxylation of estradiol in the rat liver

The four environmental pollutants studied (3,3',4,4',5-pentachlorobiphenyl, 2,2',4,4'-tetrabromodiphenyl ether, Tris-(p-chlorophenyl)methanol, and 3,4,5-trichloroguaiacol) were all found to induce a significant increase in 4-hydroxylation of estradiol activity in male rat liver microsomes. However, only 3,3',4,4',5-pentachlorobiphenyl was found to significantly increase 4- and 2-hydroxylation of estradiol in female rat liver microsomes. 4-Hydroxylation has been suggested to be responsible for the development of estrogen-dependent tumors and, therefore, it cannot be excluded that these pollutants can be a risk for the development of estrogen-dependent tumors in humans and wildlife.

Human class Mu glutathione transferases, in particular isoenzyme M2-2, catalyze detoxication of the dopamine metabolite aminochrome

Human glutathione transferases (GSTs) were shown to catalyze the reductive glutathione conjugation of aminochrome (2, 3-dihydroindole-5,6-dione). The class Mu enzyme GST M2-2 displayed the highest specific activity (148 micromol/min/mg), whereas GSTs A1-1, A2-2, M1-1, M3-3, and P1-1 had markedly lower activities (<1 micromol/min/mg). The product of the conjugation, with a UV spectrum exhibiting absorption peaks at 277 and 295 nm, was 4-S-glutathionyl-5,6-dihydroxyindoline as determined by NMR spectroscopy. In contrast to reduced forms of aminochrome (leucoaminochrome and o-semiquinone), 4-S-glutathionyl-5, 6-dihydroxyindoline was stable in the presence of molecular oxygen, superoxide radicals, and hydrogen peroxide. However, the strongly oxidizing complex of Mn3+ and pyrophosphate oxidizes 4-S-glutathionyl-5,6-dihydroxyindoline to 4-S-glutathionylaminochrome, a new quinone derivative with an absorption peak at 620 nm. GST M2-2 (and to a lower degree, GST M1-1) prevents the formation of reactive oxygen species linked to one-electron reduction of aminochrome catalyzed by NADPH-cytochrome P450 reductase. The results suggest that the reductive conjugation of aminochrome catalyzed by GSTs, in particular GST M2-2, is an important cellular antioxidant activity preventing the formation of o-semiquinone and thereby the generation of reactive oxygen species.

The two-electron quinone reductase DT-diaphorase generates and maintains the antioxidant (reduced) form of coenzyme Q in membranes

The experiments reported here were undertaken to test the hypothesis that the antioxidative, reduced form of hydrophobic phase coenzyme Q (CoQ) may be generated and maintained by the two-electron quinone reductase, DT-diaphorase [NAD(P)H:(quinone-acceptor) oxidoreductase, EC 1.6.99.2] by catalyzing formation of the hydroquinone form of CoQ. This enzyme was isolated and purified from rat liver cytosol and its reduction of several CoQ homologs incorporated into large unilamellar vesicles (LUVETs) was demonstrated. The addition of NADH and DT-diaphorase to LUVETs and to multilamellar vesicles (MLVs) containing CoQ homologs, including CoQ9 and CoQ10, resulted in essentially complete reduction of the CoQ. Incorporation of either CoQ9H2 or CoQ10H2 and the lipophylic radical generator 2,2'-azobis(2,4-dimethylvaleronitrile) (AMVN) into MLVs in the presence of DT-diaphorase and NADH maintained the reduced state of CoQ and inhibited lipid peroxidation. The reaction between DT-diaphorase and CoQ was also demonstrated in isolated rat liver hepatocytes in which incorporation of CoQ10 provided protection from adriamycin (adr)-induced mitochondrial membrane damage. The role of DT-diaphorase in the antioxidant activity of CoQ was demonstrated by the co-incorporation of dicoumarol (dic), a potent inhibitor of DT-diaphorase, resulting in a loss of protection by incorporated CoQ10. These results support the antioxidant function of DT-diaphorase in both artificial and natural membrane systems by acting as a two-electron CoQ reductase which forms and maintains CoQ in the reduced state.

DT-Diaphorase maintains the reduced state of ubiquinones in lipid vesicles thereby promoting their antioxidant function

The activity of purified DT-diaphorase in the reduction of ubiquinone homologues of different side-chain length incorporated in uni- and multilamellar vesicles was determined. The direct relationship between the reduced state of ubiquinones and the inhibition of lipid autoxidation induced by thermolabile azocompounds was also demonstrated. Results demonstrate that DT-diaphorase is able to generate and to maintain the reduced, antioxidant form of ubiquinones in both types of vesicles. Furthermore, the results reported herein show that, in the presence of nicotinamide adenine dinucleotide (NADH) and DT-diaphorase, ubiquinol-containing multilamellar vesicles exposed to a lipophilic azocompound did not undergo lipid peroxidation, whereas in vesicles lacking either NADH or DT-diaphorase, thiobarbituric acid reactive substances (TBARS) formation occurred. It is suggested that DT-diaphorase may be responsible for maintaining the reduced state of ubiquinones in various nonmitochondrial cellular membranes.

Peroxidase activity of liver microsomal vitamin D 25-hydroxylase and cytochrome P450 1A2 catalyzes 25-hydroxylation of vitamin D3 and oxidation of dopamine to aminochrome

Purified liver microsomal vitamin D 25-hydroxylase, a cytochrome P450, catalyzes 25-hydroxylation of vitamin D3 in the absence of NADPH and NADPH-cytochrome P450 reductase by using t-butyl hydroperoxide as electron donors. The rate of 25-hydroxylation was approximately the same when NADPH/ NADPH-cytochrome P450 reductase or t-butyl hydroperoxide was used as electron donor. The Km value for vitamin D3 in the presence of t-butyl hydroperoxide was found to be 30 microM. The rates of 25-hydroxylation of 1 alpha-hydroxyvitamin D3 and 5 beta-cholestane-3 alpha, 7 alpha-diol catalyzed by 25-hydroxylase were significantly higher when the reaction proceeded in the presence of NADPH/NADPH-cytochrome P450 reductase than in the presence of t-butyl hydroperoxide. Other liver microsomal cytochrome P450 forms such as taurochenodeoxycholic acid 6 alpha-hydroxylase and cytochromes P450 1A2 and 2B4 did not catalyze 25-hydroxylation of vitamin D3 in the presence of NADPH/NADPH-cytochrome P450 reductase or t-butyl hydroperoxide. The peroxidase activity of the 25-hydroxylase also catalyzed oxidation of dopamine to aminochrome. A linear correlation between increase in aminochrome formation and increase in the amount of 25-hydroxylase was observed in the oxidation of dopamine. The Km values for dopamine and t-butyl hydroperoxide were 8.6 microM and 1 mM when 25-hydroxylase catalyzes the formation of aminochrome in the presence of t-butyl hydroperoxide. Oxidation of dopamine to aminochrome catalyzed by the peroxidase activity of cytochrome P-450 1A2 was observed in the presence of t-butyl hydroperoxide. A linear correlation between formation of aminochrome and the amount of cytochrome P450 1A2 was found.

The role of DT-diaphorase in the maintenance of the reduced antioxidant form of coenzyme Q in membrane systems

The experiments reported here were designed to test the hypothesis that the two-electron quinone reductase DT-diaphorase [NAD(P)H:(quinone-acceptor) oxidoreductase, EC 1.6.99.2] functions to maintain membrane-bound coenzyme Q (CoQ) in its reduced antioxidant state, thereby providing protection from free radical damage. DT-diaphorase was isolated and purified from rat liver cytosol, and its ability to reduce several CoQ homologs incorporated into large unilamellar vesicles was demonstrated. Addition of NADH and DT-diaphorase to either large unilamellar or multilamellar vesicles containing homologs of CoQ, including CoQ9 and CoQ10, resulted in the essentially complete reduction of the CoQ. The ability of DT-diaphorase to maintain the reduced state of CoQ and protect membrane components from free radical damage as lipid peroxidation was tested by incorporating either reduced CoQ9 or CoQ10 and the lipophylic azoinitiator 2,2'-azobis(2,4-dimethylvaleronitrile) into multilamellar vesicles in the presence of NADH and DT-diaphorase. The presence of DT-diaphorase prevented the oxidation of reduced CoQ and inhibited lipid peroxidation. The interaction between DT-diaphorase and CoQ was also demonstrated in an isolated rat liver hepatocyte system. Incubation with adriamycin resulted in mitochondrial membrane damage as measured by membrane potential and the release of hydrogen peroxide. Incorporation of CoQ10 provided protection from adriamycin-induced mitochondrial membrane damage. The incorporation of dicoumarol, a potent inhibitor of DT-diaphorase, interfered with the protection provided by CoQ. The results of these experiments provide support for the hypothesis that DT-diaphorase functions as an antioxidant in both artificial membrane and natural membrane systems by acting as a two-electron CoQ reductase that forms and maintains the antioxidant form of CoQ. The suggestion is offered that DT-diaphorase was selected during evolution to perform this role and that its conversion of xenobiotics and other synthetic molecules is secondary and coincidental.

Effects of superoxide dismutase and catalase during reduction of adrenochrome by DT-diaphorase and NADPH-cytochrome P450 reductase

NADPH-cytochrome1 P450 reductase and DT-diaphorase catalyze and one- and two-electron reduction of adrenochrome to its o-semiquinone and o-hydroquinone, respectively. Under aerobic conditions both adrenochrome o-semiquinone and o-hydroquinone proved to be unstable, undergoing autoxidation with concomitant oxygen consumption and continuous NADPH and NADH oxidation. Molecular oxygen was found to play a predominant role in autoxidation of o-semiquinone during reduction of adrenochrome catalyzed by NADPH-cytochrome P450 reductase. In addition, molecular oxygen, in the presence of manganese, was found to be responsible for the majority of autoxidation of o-semiquinone. However, the role of superoxide radicals in the autoxidation of leucoadrenochrome during the reduction of adrenochrome by DT-diaphorase was found to be predominant. Catalase different significantly with respect to NADPH and NADH oxidation during reduction of adrenochrome catalyzed by NADPH-cytochrome P450 reductase and DT-diaphorase. Catalase increased NADPH oxidation slightly, while NADH oxidation was inhibited during reduction of adrenochrome by NADPH cytochrome P450 reductase and DT-diaphorase, respectively. The presence of manganese in the incubation mixture was found to increase the prooxidant role of catalase on autoxidation during one-electron reduction of aminochrome catalyzed by NADPH cytochrome P450 reductase. A marked difference in the inhibitory effect of superoxide dismutase on oxygen consumption during adrenochrome reduction catalyzed by NADPH-cytochrome P450 reductase and DT-diaphorase was also observed. A possible mechanism for reduction of adrenochrome by NADPH-cytochrome P450 reductase and DT-diaphorase and a role for superoxide dismutase and catalase are proposed.

Superoxide dismutase and catalase enhance autoxidation during one-electron reduction of aminochrome by NADPH-cytochrome P-450 reductase

NADPH-cytochrome P-450 reductase catalyzes one-electron reduction of aminochrome to the corresponding ortho-semiquinone, which was found to be unstable as indicated by the occurrence of NADPH oxidation and oxygen consumption. The addition of superoxide dismutase and catalase, alone or together, to the incubation mixture, during reduction of aminochrome catalyzed by NADPH-cytochrome P-450 reductase, did not prevent the autoxidation of ortho-semiquinone, but instead they increased NADPH oxidation. These results contrast with the almost complete inhibition of autoxidation (NADH oxidation) of ortho-hydroquinone during reduction of aminochrome catalyzed by DT-diaphorase in the presence of both superoxide dismutase and catalase. However, the effect of superoxide dismutase and catalase on oxygen consumption was found to differ from the effect on NADH or NADPH oxidation, since these enzymes, alone or together, inhibited the oxygen consumption during the reduction of aminochrome catalyzed by both NADPH-cytochrome P-450 reductase and DT-diaphorase. These results support the proposed role of NADPH-cytochrome P-450 reductase in neurodegeneration as a consequence of activation of aminochrome to reactive oxygen species. In addition, they also support the protective and antioxidant role of DT-diaphorase, together with superoxide dismutase and catalase, by competing with NADPH-cytochrome P-450 reductase to reduce aminochrome to ortho-hydroquinone and prevent the formation of reactive oxygen species. A possible mechanism is proposed.

Superoxide dismutase and catalase prevent the formation of reactive oxygen species during reduction of cyclized dopa ortho-quinone by DT-diaphorase

Dopa was oxidized by Mn(3+)-pyrophosphate complex to the corresponding o-quinone, accompanied by the cyclization of the amino chain to form cyclized dopa ortho-quinone (cDoQ) with absorption maxima at wavelengths of 305 and 475 nm. The cyclization was found to proceed in a single step from DoQ to cDoQ without formation of cDoQH2 and oxygen consumption. DT-diaphorase catalyzes the reduction of cDoQ to the corresponding hydroquinone (cDoQH2), which was found to be unstable in the presence of oxygen. The autoxidation of the cDoQH2 was followed by recording the constant oxidation of NADH and oxygen consumption and reduction of cDoQ at a wavelength of 475 nm. It was found that three different oxidizing agents were involved in autoxidation of cDoQH2. The addition of DETAPAC resulted in a strong inhibition of NADH oxidation (65% inhibition) during the reduction of cDoQ by DT-diaphorase, suggesting that manganese was responsible for 65% of the autoxidation of cDoQH2. The addition of SOD to the incubation mixture resulted in the inhibition of NADH oxidation (79%) during the reduction of cDoQ by DT-diaphorase. In the presence of DETAPAC, the addition of SOD inhibited NADH oxidation during cDoQH2 autoxidation 75%, suggesting that superoxide radicals are responsible for 75% of the oxygen-dependent autoxidation. The remaining NADH oxidation, which was not inhibited by DETAPAC and SOD, was accompanied by a constant oxygen consumption, suggesting that this autoxidation of cDoQH2 proceeds by reducing oxygen to superoxide radical. The effect of SOD and catalase in the presence of DETAPAC was also studied. A nearly complete inhibition (90%) of oxygen consumption during the reduction of cDoQ by DT-diaphorase was observed when SOD alone or SOD and catalase were added to the incubation mixture containing DETAPAC. We conclude that SOD and catalase constitute a protective cellular system against formation of reactive oxygen species during reduction of cDoQ by DT-diaphorase.

Activity and immunohistochemistry of DT-diaphorase in hamster and human kidney tumours

We have studied the biochemical and immunohistochemical changes of DT-diaphorase in diethylstilbestrol (DES)-induced hamster kidney tumours and human biopsies from normal kidneys and renal clear cell carcinoma. The activities of primary and secondary antioxidants in these hamster and human tissues are also reported. DT-diaphorase is decreased in the different subcellular fractions of hamster and human tissues. In hamster kidney the activities of the one-electron quinone reductases show a nearly two-fold increase. Immunohistochemical findings confirm the decrease in DT-diaphorase in hamster and human tissues. This image is of special interest in the case of nephroblastoma (Wilms' tumour), since it has been proposed that the DES-induced tumour is a 'nephroblastoma-like' one. Primary anti oxidant enzymatic activities, i.e. superoxide dismutase and glutathione peroxidase, are increased in hamster kidney bearing DES-induced tumours and decreased in human renal clear cell carcinoma. Glutathione disulphide reductase is decreased in hamster and human tumours. The role of these enzymatic activities in the carcinogenic process is also discussed.

The protective effect of superoxide dismutase and catalase against formation of reactive oxygen species during reduction of cyclized norepinephrine ortho-quinone by DT-diaphorase

Norepinephrine was oxidized by the Mn(3+)-pyrophosphate complex to the corresponding o-quinone at pH 6.5. Cyclized norepinephrine ortho-quinone showed an absorption maximum at 289 and 483 nm. No oxygen consumption was observed during oxidation of norepinephrine to o-quinone by Mn3+ and subsequent cyclization. The reduction of cyclized norepinephrine ortho-quinone to the corresponding hydroquinone was catalyzed by DT-diaphorase. However, the hydroquinone formed proved to be unstable in the presence of oxygen, since reduction of cyclized norepinephrine o-quinone by DT-diaphorase was accompanied by continuous oxidation of NADH and oxygen consumption. Addition of the chelator DETAPAC or SOD to the incubation mixture during reduction of cyclized norepinephrine ortho-quinone by DT-diaphorase strongly inhibited NADPH oxidation and oxygen consumption, suggesting that manganese and superoxide radicals were involved in hydroquinone autoxidation. Elimination of the effects of superoxide radicals, manganese and H2O2 on autoxidation of hydroquinone by addition of SOD, catalase and DETAPAC to the incubation mixture resulted in a 79% inhibition of NADH oxidation, suggesting that 21% of the autoxidation is oxygen-dependent. However, the effect of these additions on oxygen consumption was even more pronounced (93% inhibition).

A new direct method for determining superoxide dismutase activity by measuring hydrogen peroxide formation

A new, direct method for determining superoxide dismutase activity is presented in this study. This method is based on measurement of one of the products of the superoxide dismutase reaction, hydrogen peroxide. Hydrogen peroxide is quantitated using a coupled reaction where horseradish peroxidase catalyzes the formation of a fluorescent product, 6,6'-diOH-(1,1'-biphenyl)-3,3'-diacetic acid, from 4-OH-phenylacetic acid and hydrogen peroxide. Substrate for superoxide dismutase is provided by reduction of oxygen during the autoxidation of riboflavin in the presence of UV light. A linear correlation between the amount of superoxide dismutase (200 ng-6 micrograms) and of hydrogen peroxide was found with this method.

The Effect of 5OH-1,4-Naphthoquinone on Norway Spruce Seeds during Germination

The effect of 5-OH-1,4-naphthoquinone (5OH-NQ), a known inhibitor of germination and growth and an inducer of oxidative stress, on seeds from Norway spruce (Picea abies) during germination was studied. 5OH-NQ was activated by homogenate from seeds to reactive species that reduce oxygen to superoxide radicals in vitro. Increasing concentrations of 5OH-NQ increased lipid peroxidation during this activation. Small effects of 5OH-NQ on germination of seeds were observed at concentrations up to 200 mum. However, higher concentrations, e.g. 500 and 1000 mum, exerted more pronounced effects on seeds. These results suggest that the effect of 5OH-NQ was a delay rather than an inhibition of germination. However, the effect of 5OH-NQ on postgerminative growth was more potent than that on germination, and higher concentrations inhibited growth >97%. These results suggest that the seeds have a very effective defense system against quinone and reactive oxygen species, since the small effects of 5OH-NQ on germination and postgermination at concentrations up to 200 mum can be explained by the formation of a metabolite of 5OH-NQ that is not as reactive with oxygen as the original quinone. The 5OH-NQ metabolite collected during germination experiments showed differences in its absorption spectrum in comparison with 5OH-NQ, which suggest changes in structure. This metabolite was reduced by quinone reductase, but reduction of oxygen to superoxide radicals was not detected during its activation with homogenate from seeds. This metabolite may arise via a conjugation reaction, since the addition of 500 mum uridine 5'-diphosphoglucuronic acid or 3'-phosphoadenosine-5'-phosphosulfate to the incubation mixture during activation of this metabolite by homogenate from seeds in vitro inhibited reduction of oxygen to superoxide radicals by 50 and 64%, respectively. The constitutive levels of superoxide dismutase and catalase were sufficient to prevent oxygen toxicity during activation of 5OH-NQ, since these enzymes were not induced when the seeds were treated with 200 mum 5OH-NQ.

The cytotoxic effects of 5-OH-1,4-naphthoquinone and 5,8-diOH-1,4-naphthoquinone on doxorubicin-resistant human leukemia cells (HL-60)

The effect of 5-OH-1,4-naphthoquinone and 5,8-diOH-1,4-naphthoquinone, two quinones highly reactive with oxygen, was studied on HL-60 and HL-60R cells. The multidrug resistance developed by the doxorubicin-resistant HL-60 cell line did not prevent the cytotoxic effect of these compounds, at clinically relevant concentrations. An increase in cellular defenses against oxygen radicals seemed to be one of the features developed by HL-60R, since the homogenate from this cell line had only 65% of the ability of the original cell line to form oxygen radicals during doxorubicin reduction. This result may be explained in part by the slight increase in superoxide dismutase and DT-diaphorase enzymatic activities.

Separation and characterization of isoforms of DT-diaphorase from rat liver cytosol

Rats were treated with 3-methylcholanthrene (MC) and DT-diaphorase from liver was partially purified on an azodicoumarol-Sepharose 6B column and applied to an FPLC-chromatofocusing column in order to resolve isoforms. Six peaks showing significant DT-diaphorase activity were eluted from this column with a pH gradient between 7.30 to 4.80. The amino acid compositions of the two major peaks (II and VIb) were found to be nearly identical, suggesting existence of isoforms rather than isozymes of DT-diaphorase. The isoforms of DT-diaphorase showed broad substrate specificities towards four different quinones (menadione, vitamin K-1, benzo(a)pyrene 3,6-quinone and cyclized-dopamine ortho-quinone), although quantitative differences in the specific activities were also found. All isoforms are glycoproteins but contain different carbohydrates. Thus isoform II reacts with biotinylated lectins which are specific for N-acetylgalactosamine, mannose, fucose and galactosyl(beta-1,3)N-acetylgalactosamine, while isoform VIb reacts only with biotinylated lectins specific for mannose and N-acetylgalactosamine. Separation of DT-diaphorase isoforms from control rat liver cytosol using FPLC-chromatofocusing revealed that the induction of the isoforms is not uniform, since isform II was not found and the major isoform was composed of three peaks, whereas the major isoform of DT-diaphorase from liver cytosol of rats treated with 3-methylcholanthrene was composed of only two peaks.

Oxygen toxicity in the nervous tissue: comparison of the antioxidant defense of rat brain and sciatic nerve

Nervous tissue, central and peripheral, is, as any other, subject to variations in oxygen tension, and to the attack of different xenobiotics; these situations may promote the generation of activated oxygen species of free radical character. Results are presented showing that the content of total glutathione (GSH) in brain is 10-fold that found in the sciatic nerve of the rat (2620 vs. 261 nmol/g wet weight, respectively). The existence of a relatively high superoxide dismutase activity in peripheral nervous tissue, when compared with brain or liver, in combination with the DT-diaphorase activity detected in the sciatic nerve might represent an effective defense mechanism against quinone toxicity, as is also discussed. Nervous tissue, both central and peripheral lack Se-independent GSH peroxidase activity. Finally, the activities of other glutathione-related enzymes studied in the sciatic nerve are very low, when compared with the central nervous tissue, thus suggesting a higher susceptibility of peripheral tissue to oxidative stress damage, since GSH concentration and/or any GSH-related enzymatic activities, e.g. GSH peroxidase or glutathione disulfide reductase, might become limiting.

Antioxidant and glutathione-related enzymatic activities in rat sciatic nerve

The present work tries to establish the antioxidant capacity of the peripheral nervous tissue of the rat, in terms of the enzymatic activities present in this tissue that either prevent the formation of activated species as the semiquinone radical (DT-diaphorase), protect against activated oxygen species (superoxide dismutase, glutathione peroxidase), conjugate natural toxic products or xenobiotics (glutathione S-transferase, especially the activity conjugating 4-hydroxy-nonenal), or complete the glutathione system metabolism (glutathione disulfide reductase, gamma-glutamyl transpeptidase). All the activities studied are lower in this tissue than they are in liver, except for gamma-glutamyl transpeptidase. The relevance of the results obtained and its possible relationship with different neuropathies is discussed. It is concluded that the peripheral nervous tissue is by far less protected than the liver against oxidative damage.

The levels of quinone reductases, superoxide dismutase and glutathione-related enzymatic activities in diethylstilbestrol-induced carcinogenesis in the kidney of male Syrian golden hamsters

The level of quinone oxidoreductases (microsomal and cytosolic DT-diaphorase, NADPH-cytochrome P450 reductase and NADH-cytochrome b5 reductase), superoxide dismutase and glutathione-related enzymatic activities in diethylstilbestrol (DES)-induced carcinogenesis in kidney from Syrian golden hamsters are presented. Animals that exhibited two different stages of DES-induced carcinogenesis in kidney--pre- and neoplastic lesions and tumorous lesions (after 6 and 8 months of continuous exposure to DES respectively)--were studied in comparison to kidneys from control animals. A dramatic decrease in microsomal and cytosolic DT-diaphorase activities (13.6 and 37.8% of controls), as well as in glutathione disulphide reductase (39.5%), and less marked in superoxide dismutase (45.6%), NADH cytochrome b5 reductase (61.9%) glutathione transferase (GST) towards 1-chloro-2,4-dinitrobenzene (CDNB) (66.2%) and glutathione peroxidase (GSH-Px) (80%) activities, were observed in kidneys with pre- and neoplastic lesions. NADPH-cytochrome P450 reductase and GST activity towards 4-hydroxy-2,3-trans-nonenal (4-HNE) showed no statistically significant variation at this stage of carcinogenesis. In kidney from animals with tumorous lesions, all the enzymatic activities mentioned above decreased, except for superoxide dismutase, which was increased to 186% of the control activity. GST activity towards 4-HNE again showed no statistically significant variation. These results suggest that if one-electron reduction of diethylstilbestrol-4',4''-quinone (DESQ) occurs, it may play a very important role in the development of DES carcinogenesis (pre- and neoplastic lesions), since at this stage of carcinogenesis the primary defense mechanisms against the oxygen free radicals generated in this way, i.e. SOD activity, is reduced to less than a half of control values. Both cytosolic and microsomal DT-diaphorase activities are unable at this stage of carcinogenesis to promote effectively the two-electron reduction of DESQ, which would avoid the initial formation of superoxide anion. The consequences of these decreases may be an increased steady-state concentration of superoxide anion and hydrogen peroxide, which in the presence of iron might lead to lipid peroxidation. GST activity towards 4-HNE could be responsible for the possible higher steady-state concentration of this lipid peroxidation product during DES treatment. The induction of DT-diaphorase and its protective role in the prevention of the development of pre- and neoplastic lesions in kidney from Syrian golden hamster during DES treatment is also discussed.

On the mechanism of the Mn3(+)-induced neurotoxicity of dopamine:prevention of quinone-derived oxygen toxicity by DT diaphorase and superoxide dismutase

Dopamine (DA) is rapidly oxidized by Mn3(+)-pyrophosphate to its cyclized o-quinone (cDAoQ), a reaction which can be prevented by NADH, reduced glutathione (GSH) or ascorbic acid. The oxidation of DA by Mn3+, which appears to be irreversible, results in a decrease in the level of DA, but not in a formation of reactive oxygen species, since oxygen is neither consumed nor required in this reaction. The formation of cDAoQ can initiate the generation of superoxide radicals (O2-.) by reduction-oxidation cycling, i.e. one-electron reduction of the quinone by various NADH- or NADPH-dependent flavoproteins to the semiquinone (QH.), which is readily reoxidized by O2 with the concomitant formation of O2-.. This mechanism is believed to underly the cytotoxicity of many quinones. Two-electron reduction of cDAoQ to the hydroquinone can be catalyzed by the flavoprotein DT diaphorase (NAD(P)H:quinone oxidoreductase). This enzyme efficiently maintains DA quinone in its fully reduced state, although some reoxidation of the hydroquinone (QH2) is observed (QH2 + O2----QH. + O2-. + H+; QH. + O2----Q + O2-.). In the presence of Mn3+, generated from Mn2+ by O2-. (Mn2+ + 2H+ + O2-.----Mn3+ + H2O2) formed during the autoxidation of DA hydroquinone, the rate of autoxidation is increased dramatically as is the formation of H2O2. Furthermore, cDAoQ is no longer fully reduced and the steady-state ratio between the hydroquinone and the quinone is dependent on the amount of DT diaphorase present. The generation of Mn3+ is inhibited by superoxide dismutase (SOD), which catalyzes the disproportionation of O2-. to H2O2 and O2. It is noteworthy that addition of SOD does not only result in a decrease in the amount of H2O2 formed during the regeneration of Mn3+, but, in fact, prevents H2O2 formation. Furthermore, in the presence of this enzyme the consumption of O2 is low, as is the oxidation of NADH, due to autoxidation of the hydroquinone, and the cyclized DA o-quinone is found to be fully reduced. These observations can be explained by the newly-discovered role of SOD as a superoxide:semiquinone (QH.) oxidoreductase catalyzing the following reaction: O2-. + QH. + 2H+----QH2 + O2. Thus, the combination of DT diaphorase and SOD is an efficient system for maintaining cDAoQ in its fully reduced state, a prerequisite for detoxication of the quinone by conjugation with sulfate or glucuronic acid. In addition, only minute amounts of reactive oxygen species will be formed, i.e. by the generation of O2-., which through disproportionation to H2O2 and further reduction by ferrous ions can be converted to the hydroxyl radical (OH.). Absence or low levels of these enzymes may create an oxidative stress on the cell and thereby initiate events leading to cell death.

Distribution of DT diaphorase in the rat brain: biochemical and immunohistochemical studies

DT diaphorase [NAD(P)H:quinone oxidoreductase] activity was measured in subcellular fractions from homogenates of striatum, frontal cortex, hippocampus, cerebellum, hypothalamus and substantia nigra. This flavoprotein, which by definition oxidizes dihydronicotinamide adenine dinucleotide and dihydronicotinamide adenine dinucleotide phosphate at equal rates and is completely inhibited by 10(-5) M dicoumarol, was found to constitute 80-90% of the total dihydronicotinamide adenine dinucleotide- and dihydronicotinamide adenine dinucleotide phosphate-reductase activities in all brain regions studied. Antibodies raised against purified cytosolic DT diaphorase from the rat liver cross-reacted with the brain enzyme and inhibited soluble DT diaphorase from striatum and cerebellum to 80-90%. Immunohistochemical studies with the same antibodies demonstrated the occurrence of DT diaphorase immunoreactivity in a population of neurons in the substantia nigra and ventral tegmental area. In some neurons there was a colocalization of DT diaphorase and tyrosine hydroxylase-like immunoreactivity. The dense network of DT diaphorase-immunoreactive fibres in the striatum disappeared along with the dopaminergic innervation after 6-hydroxydopamine lesion. DT diaphorase immunoreactivity was also found in Bergmann glia, astrocytes and tanycytes. No correlation appeared to exist between the localization of neuronal DT diaphorase immunoreactivity and the dihydronicotinamide adenine dinucleotide phosphate-diaphorase-like activity, as defined by tetrazolium salt staining, used as a marker for certain peptidergic and cholinergic neurons. However, in, for example, glial cells in the cerebellum, DT diaphorase might contribute or be responsible for the histochemical dihydronicotinamide adenine dinucleotide phosphate-diaphorase activity.

Effect of superoxide dismutase on the autoxidation of various hydroquinones--a possible role of superoxide dismutase as a superoxide:semiquinone oxidoreductase

The autoxidation of DT-diaphorase-reduced 1,4-naphthoquinone, 2-OH-1,4-naphthoquinone, and 2-OH-p-benzoquinone is efficiently prevented by superoxide dismutase. This effect was assessed in terms of an inhibition of NADPH oxidation (over the amount required to reduce the available quinone), O2 consumption, and H2O2 formation. Superoxide dismutase also affects the distribution of molecular products -hydroquinone/quinone-involved in autoxidation, by favoring the accumulation of the reduced form of the above quinones. In contrast, the rate of autoxidation of DT-diaphorase-reduced 1,2-naphthoquinone is enhanced by superoxide dismutase, as shown by increased rates of NADPH oxidation, O2 consumption, and H2O2 formation and by an enhanced accumulation of the oxidized product, 1,2-naphthoquinone. These findings suggest that superoxide dismutase can either prevent or enhance hydroquinone autoxidation. The former process would imply a possible new activity displayed by superoxide dismutase involving the reduction of a semiquinone by O2-.. This activity is probably restricted to the redox properties of the semiquinones under study, as indicated by the failure of superoxide dismutase to prevent autoxidation of 1,2-naphthohydroquinone.

DT-diaphorase-catalyzed two-electron reduction of various p-benzoquinone- and 1,4-naphthoquinone epoxides

The oxidation of various quinones by H2O2 results in quinone epoxide formation. The yield of epoxidation is inversely related to the degree of methyl substitution of the quinone and seems not to be dependent on the redox potential of the quinones studied. The following order of H2O2-mediated epoxidation of quinones was found: p-benzoquinone greater than or equal to 1,4-naphthoquinone greater than 2-methyl-p-benzoquinone greater than 2,6-dimethyl-p-benzoquinone greater than or equal to 2-methyl-1,4-naphthoquinone greater than 2,3-dimethyl-1,4-naphthoquinone. DT-Diaphorase reduces several quinone epoxides at different rates. The rate of quinone epoxide reduction cannot be related to either the redox potential of the quinone epoxide (as reflected by the half-wave potential calculated from the corresponding hydrodynamic voltamograms) or the degree of substitution of the quinone epoxide. It appears, however, that a quinone epoxide redox potential more negative than -0.5 to -0.6 volts settles a threshold for the electron transfer reaction. This does not exclude that specificity requirements, i.e. the formation of the quinone epoxide substrate-enzyme complex may chiefly determine the rate of reduction of quinone epoxides by DT-diaphorase. DT-diaphorase-catalyzed two-electron transfer to quinone epoxides--resulting in epoxide ring opening--yields 2-OH-p-benzohydroquinone or 2-OH-1,4-naphthohydroquinone products. These hydroxy-derivatives show a higher rate of autoxidation than do the parent hydroquinones lacking the OH substituent.

DT-diaphorase-catalyzed two-electron reduction of quinone epoxides

DT-diaphorase catalyzes the two-electron reduction of the unsubstituted quinone epoxide, 2,3-epoxy-p-benzoquinone, at expense of NAD(P)H with formation of 2-OH-p-benzohydroquinone as the reaction product. The further conversion reactions of 2-OH-p-benzohydroquinone are influenced by the presence of O2 in the medium. Under aerobic conditions, 2-OH-p-benzohydroquinone undergoes autoxidation--probably with formation of 2-OH-semiquinone intermediates--to 2-OH-p-benzoquinone. The latter product is rapidly reduced by DT-diaphorase and, thus, its accumulation can be only observed upon exhaustion of NADPH. Under anaerobic conditions, 2-OH-p-benzohydroquinone does not undergo autoxidation and its accumulation is stoichiometrically (1:1) related to the amount of NADPH oxidized and epoxide substrate reduced. DT-diaphorase also catalyzes the reduction of the disubstituted quinone epoxide, 2,3-dimethyl-2,3-epoxy-1,4-naphthoquinone. Neither the aliphatic epoxide, trans-stilbene oxide, nor the aromatic epoxide, 4,5-epoxy-benzo[a]pyrene are substrates for DT-diaphorase. The reduction of 2,3-epoxy-p-benzoquinone is also catalyzed by the one-electron transfer enzyme, NADPH-cytochrome P450 reductase at a rate similar to that found with DT-diaphorase. However, this reaction differs from that catalyzed by DT-diaphorase in the distribution of molecular products as well as in the relative contribution of nonenzymatic reactions, i.e. semiquinone disproportionation and autoxidation.