硒蛋白TrxR1介导甲萘醌还原：催化特性和抑制作用

硫氧还蛋白还原酶 (Thioredoxin reductase,TrxR) 是一类重要的抗氧化硒蛋白,参与调控肿瘤发生发展。研究表明,萘醌类分子可以靶向抑制TrxR1活性并经由TrxR1介导产生活性氧,导致细胞氧化还原失衡,使其成为潜在的肿瘤化疗药物。本文旨在通过生物化学及质谱分析,探究硒蛋白TrxR1与萘醌化合物甲萘醌的相互作用,进一步揭示TrxR1催化萘醌分子还原的机理和萘醌分子抑制TrxR1活性的机制。通过对TrxR1催化残基的定点突变和突变体的重组表达,我们测定TrxR1突变体介导甲萘醌还原稳态动力学参数,并分析甲萘醌对TrxR1活性抑制,最后通过质谱分析鉴定甲萘醌与TrxR1相互作用。结果表明,硒蛋白TrxR1的Sec498催化甲萘醌还原,但是U498C突变使甲萘醌还原更加高效,表明了甲萘醌还原主要呈现非硒依赖性。突变实验发现C端Cys498发挥主要催化还原作用,而N端Cys64对甲萘醌还原的影响稍强于Cys59。LC-MS结果发现TrxR1存在1分子甲萘醌加合物,推测其不可逆修饰硒蛋白C末端高反应活性的硒代半胱氨酸。本研究揭示了TrxR1可以非硒依赖方式催化甲萘醌还原,同时其活性会受到甲萘醌的不可逆抑制,为靶向TrxR1的萘醌类抗癌药物研发提供有益参考。     

Detection of free radicals as a consequence of rat intestinal cellular drug metabolism

Because the intestine is the first pass organ for orally administered drugs and because some of these drugs are known to undergo oxidative metabolism leading to the formation of free radicals, we investigated the potential for this to occur in cell suspensions of rat enterocytes. As part of our study, the effect of intracellularly produced superoxide on cellular metabolism was investigated. The drugs chosen were the quinone, menadione and the aromatic nitro-containing compound, nitrazepam. On incubation of both drugs with isolated enterocytes and the spin trap, 5,5-dimethyl-1-pyrroline N-oxide (DMPO), rapid appearance of an electron paramagnetic resonance (EPR) spectrum was recorded which was characteristic of hydroxyl radicals being spin trapped by DMPO giving 2,2-dimethyl-5-hydroxy-1-pyrrolidenyloxyl (DMPO-OH). Experiments were conducted which determined that the EPR spectrum of DMPO-OH resulted from the initial spin trapping of superoxide by DMPO to yield the corresponding nitroxide, 2,2-dimethyl-5-hydroxyl-1-pyrrolidenyloxyl (DMPO-OOH). Bioreduction of DMPO-OOH by glutathione peroxidase led to the rapid formation of DMPO-OH. We believe this enzymic pathway accounted for the EPR spectrum noted in incubations with either drug in the presence of the spin trap, DMPO. The incubation of enterocytes with both drugs did not mediate release of 51Cr nor lactate dehydrogenase. However, production of 14CO2 from [14C]glucose was severely inhibited (4-5-fold) in the presence of both drugs, while the incorporation of [14C]leucine into trichloroacetic acid precipitable protein was antagonized by menadione only. We conclude that superoxide can be demonstrated to arise as the result of enterocyte metabolism of menadione or nitrazepam. The consequence of oxidative metabolism of these drugs results in cellular dysfunction.     

Measurement of Menadione-Mediated DNA Damage in Human Lymphocytes Using the Comet Assay

The model quinone compound menadione has been used to study the effects of oxidative stress in mammalian cells, and to investigate the mechanism of action of the quinone nucleus which is present in many anti-cancer drugs. We have used the alkaline single cell gel electrophoresis assay (comet assay) to investigate the effects of low doses of this compound on isolated human lymphocytes. We found that concentrations of menadime as low as 1μM were sufficient to induce strand breaks in these cells. Pre-incubation with the NAD(P)H quinone oxidoreductase inhibitor dicoumarol, enhanced the production of menadione-induced strand breaks. In contrast, the metal ion chelator 1,10-phenanthroline inhibited formation of strand breaks, although prolonged incubation with 1,10-phenanthroline in combination with menadione resulted in an increase in a population of very severely damaged nuclei. A marked variation in the response of lymphocytes from different donors to menadione, and in different samples from the same donor was also observed.     

Quantitative genome-wide analysis of yeast deletion strain sensitivities to oxidative and chemical stress

Understanding the actions of drugs and toxins in a cell is of critical importance to medicine, yet many of the molecular events involved in chemical resistance are relatively uncharacterized. In order to identify the cellular processes and pathways targeted by chemicals, we took advantage of the haploid Saccharomyces cerevisiae deletion strains (Winzeler et al., 1999). Although ~4800 of the strains are viable, the loss of a gene in a pathway affected by a drug can lead to a synthetic lethal effect in which the combination of a deletion and a normally sublethal dose of a chemical results in loss of viability. WE carried out genome-wide screens to determine quantitative sensitivities of the deletion set to four chemicals: hydrogen peroxide, menadione, ibuprofen and mefloquine. Hydrogen peroxide and menadione induce oxidative stress in the cell, whereas ibuprofen and mefloquine are toxic to yeast by unknown mechanisms. Here we report the sensitivities of 659 deletion strains that are sensitive to one or more of these four compounds, including 163 multichemicalsensitive strains, 394 strains specific to hydrogen peroxide and/or menadione, 47 specific to ibuprofen and 55 specific to mefloquine.We correlate these results with data from other large-scale studies to yield novel insights into cellular function.     

Inhibition of biliary taurocholate excretion during menadione metabolism in perfused rat liver

In perfused rat liver menadione elicits substantial oxidation in both the NADPH and GSH redox systems. Biliary excretion of GSSG is increased several-fold. Menadione derivatives appear in the bile predominantly as the menadione-S-glutathione conjugate, thiodione (60%), or as conjugates derived therefrom (17%). About 10% appear as menadione glucuronides. The excretion of taurocholate into bile is strongly inhibited upon menadione infusion. The inhibition of taurocholate excretion is small in livers with a low content of Se-GSH-peroxidase and in glutathione-depleted livers. In these livers intracellular GSSG and biliary GSSG release remain at low values, although menadione still imposes oxidative stress as indicated by an oxidation of intracellular NADPH. Under anoxic conditions menadione has little influence on both the NADPH and GSH redox systems and also on biliary taurocholate excretion. The amount of thiodione released into bile is similar to that found under normoxia, whereas the amount of glucuronidated products almost doubled. We conclude (a) that intracellular formation of GSSG by menadione occurs via the generation of hydrogen peroxide; (b) that the inhibition of biliary taurocholate excretion by menadione is related to the increased formation of glutathione disulfide; and (c) that menadione derivatives show little, if any, contribution to the inhibition of taurocholate excretion.     

Effects of vanadate, menadione and menadione analogs on the Ca2+-activated K+ channels in human red cells. Possible relations to membrane-bound oxidoreductase activity

The modulation of the Ca2+- (or Pb2+-)activated K+ permeability in human erythrocytes by vanadate, menadione and chloro-substituted menadione analogs was investigated by measurements of K+ fluxes and single-channel currents. Vanadate and menadione stimulate the K+ permeability by increasing the probability of channel openings; the menadione analogs, on the other hand, inhibit the K+ permeability by increasing the probability of channel closings. The compounds used in these experiments also interact with oxidoreductases; it is demonstrated that menadione analogs in contrast to menadione strongly inhibit the membrane-bound dehydrogenase in the erythrocytes. Concentrations of Pb2+ above 10 mumol/l, but not of Ca2+, inhibit the enzyme activity as well as the K+ permeability. The parallel effects on dehydrogenase activity and the K+ channels suggest a direct relationship between these two systems in the membrane of erythrocytes.     

Measurement of menadione in urine by HPLC

Menadione is a metabolite of vitamin K that is excreted in urine. A high performance liquid chromatography (HPLC) method using a C₃₀ column, post-column zinc reduction and fluorescence detection was developed to measure urinary menadione. The mobile phase was composed of 95% methanol with 0.55% aqueous solution and 5% DI H₂O. Menaquinone-2 (MK-2) was used as an internal standard. The standard calibration curve was linear with a correlation coefficient (R²) of 0.999 for both menadione and MK-2. The lower limit of quantification (LLOQ) was 0.3 pmole menadione/mL urine. Sample preparation involved hydrolysis of menadiol conjugates and oxidizing the released menadiol to menadione. Using this method, urinary menadione was shown to increase in response to 3 years of phylloquinone supplementation. This HPLC method is a sensitive and reproducible way to detect menadione in urine.     

The pro-oxidant role of protein SH groups of hemoglobin in rat erythrocytes exposed to menadione.

Menadione is selectively toxic to erythrocytes. Although GSH is considered a primary target of menadione, intraerythrocyte thiolic alterations consequent to menadione exposure are only partially known. In this study alterations of GSH and protein thiols (PSH) and their relationship with methemoglobin formation were investigated in human and rat red blood cells (RBC) exposed to menadione. In both erythrocyte types, menadione caused a marked increase in methemoglobin associated with GSH depletion and increased oxygen consumption. However, in human RBC, GSH formed a conjugate with menadione, whereas, in rat RBC it was converted to GSSG, concomitantly with a loss of protein thiols (corresponding to menadione arylation), and an increase in glutathione-protein mixed disulfides (GS-SP). Such differences were related to the presence of highly reactive cysteines, which characterize rat hemoglobin (cys beta125). In spite of the greater thiol oxidation in rat than in human RBC, methemoglobin formation and the rate of oxygen consumption elicited by menadione in both species were rather similar. Moreover, in repeated experiments under N2 or CO-blocked heme, it was found that menadione conjugation (arylation) in both species was not dependent on the presence of oxygen or the status of heme. Therefore, we assumed that GSH (human RBC) and protein (rat RBC) arylation was equally responsible for increased oxygen consumption and Hb oxidation. Moreover, thiol oxidation of rat RBC was strictly related to methemoglobin formation.     

Cytotoxicity of quinone drugs on highly proliferative human leukemia T cells: reactive oxygen species generation and inactive shortened SOD1 isoform implications

Drugs containing the quinone group were tested on hyperproliferative leukemia T cells (HLTC: Jhp and Jws) and parental Jurkat cells. Doxorubicin, menadione and adaphostin produced different effects on these cell lines. Rapid doxorubicin-induced cell death in Jurkat cells was mediated by caspase activation. Doxorubicin-induced cell death of HLTCs was delayed due to the absence of caspase-3 and -8 expression. Delayed HLTC cell death was mediated and triggered by the generation of reactive oxygen species (ROS). Other drugs containing quinone groups, such as menadione and adaphostin, were also tested on HLTC and both were toxic by a caspase-independent mechanism. The toxicity of these drugs correlated with the generation of the superoxide anion, which increased and was more effective in HLTCs than in parental Jurkat cells. Accordingly, SOD1 activity was much lower in HLTCs than in Jurkat cells. This lower SOD1 activity in HLTCs was associated not only with the absence of the wild-type (16 kDa) SOD1 monomer but also with the presence of a shortened (14 kDa) SOD1 monomer isoform. Moreover, the cytotoxicity of drugs containing the quinone group was prevented by incubation with manganese(III) tetrakis (4-benzoic acid) porphyrin (MnTBAP), a cell-permeable superoxide dismutase mimetic and a potent inhibitor of oxidation. These findings could explain the sensitivity of HLTCs to drugs containing the quinone group using a mechanism dependent on oxidative stress. These observations can also be useful to target hyperproliferative leukemias that are resistant to the classical caspase-dependent apoptotic pathway.     

Activation of ErbB2 by 2-methyl-1,4-naphthoquinone (menadione) in human keratinocytes: role of EGFR and protein tyrosine phosphatases

Activation of ErbB receptor tyrosine kinases triggers multiple signaling pathways that regulate cellular proliferation and survival. We here demonstrate that ErbB2 is activated via the epidermal growth factor receptor (EGFR) upon exposure of cultured human keratinocytes to 2-methyl-1,4-naphthoquinone (menadione). Both ErbB2 and EGFR are shown to be regulated by protein tyrosine phosphatases that are inhibited by menadione, giving rise to the hypothesis that phosphatase inhibition by menadione may result in a net activation of EGFR and an enhanced ErbB2 phosphorylation. Isolated PTP-1B, a protein tyrosine phosphatase known to be associated with ErbB receptors, is demonstrated to be inhibited by menadione.     

Therapeutic doses of menadione reduce the rotenone-induced inhibition of respiration and membrane potential generation in mitochondria

Menadione restores the rotenone-inhibited respiration of diaphragm muscle pieces in approximately the same degree as the respiration of heart mitochondria, i.e., to 30-40%. The respiration of heart mitochondria induced by 2-5 microM menadione (after its inhibition by rotenone) is partly coupled with ATP synthesis whose rate is much lower than that of oxidation of NAD-dependent substrates. The effects of menadione and mitochondrial energetics inhibitors on lymphocyte respiration and rhodamine 123 fluorescence in individual lymphocytes and their suspensions were compared. Menadione (2--5 microM) increased the rotenone + oligomycin suppressed delta psi m in lymphocytes. At 5-40 microM menadione did not act as an uncoupler and had little effect on the uncoupled lymphocyte respiration. All these effects were observed at menadione concentrations close to therapeutic ones. Vicasol, a water-soluble analog of menadione, exerted a similar effect.     

Multiple signals modulate the activity of the complex sensor kinase TodS

The reason for the existence of complex sensor kinases is little understood but thought to lie in the capacity to respond to multiple signals. The complex, seven‐domain sensor kinase TodS controls in concert with the TodT response regulator the expression of the toluene dioxygenase pathway in Pseudomonas putida F1 and DOT‐T1E. We have previously shown that some aromatic hydrocarbons stimulate TodS activity whereas others behave as antagonists. We show here that TodS responds in addition to the oxidative agent menadione. Menadione but no other oxidative agent tested inhibited TodS activity in vitro and reduced P_todX expression in vivo. The menadione signal is incorporated by a cysteine‐dependent mechanism. The mutation of the sole conserved cysteine of TodS (C320) rendered the protein insensitive to menadione. We evaluated the mutual opposing effects of toluene and menadione on TodS autophosphorylation. In the presence of toluene, menadione reduced TodS activity whereas toluene did not stimulate activity in the presence of menadione. It was shown by others that menadione increases expression of glucose metabolism genes. The opposing effects of menadione on glucose and toluene metabolism may be partially responsible for the interwoven regulation of both catabolic pathways. This work provides mechanistic detail on how complex sensor kinases integrate different types of signal molecules.     

Comparative analysis of cytosolic and solubilized mitochondrial menadione reductases from rat liver]

The kinetic properties of cytosolic and solubilized mitochondrial menadione reductases (EC 1.6.99.2) from rat liver were compared. The mechanism of the reaction of cytosolic and mitochondrial menadione reductases with NADH and 4-anilino-5-methoxy-1,2-benzoquinone (AMOBQ) as substrates obeys the "ping-pong" kinetics. AMOBQ is a competitive inhibitor of cytosolic menadione reductase (Ki = 219 microM). Both menadione reductases have similar or identical values of true and effective kinetic constants and similar electrophoretic mobilities.     

The effect of fast electrons and menadione on the structural-functional status of Ehrlich ascites carcinoma cells in the early periods following irradiation

Irradiation of Ehrlich ascites tumor cells stimulates oxygen consumption, and menadione suppresses cell respiration. The combined effect of the two factors produces an additional, in comparison with the effect of menadione alone, inhibition of the rate of oxygen consumption by cells. There is an additive effect of radiation and menadione with regard to the level of cell thiols and interphase cell death.     

Menadione (Vitamin K3) Is a Catabolic Product of Oral Phylloquinone (Vitamin K1) in the Intestine and a Circulating Precursor of Tissue Menaquinone-4 (Vitamin K2) in Rats

Mice have the ability to convert dietary phylloquinone (vitamin K₁) into menaquinone-4 (vitamin K₂) and store the latter in tissues. A prenyltransferase enzyme, UbiA prenyltransferase domain-containing 1 (UBIAD1), is involved in this conversion. There is evidence that UBIAD1 has a weak side chain cleavage activity for phylloquinone but a strong prenylation activity for menadione (vitamin K₃), which has long been postulated as an intermediate in this conversion. Further evidence indicates that when intravenously administered in mice phylloquinone can enter into tissues but is not converted further to menaquinone-4. These findings raise the question whether phylloquinone is absorbed and delivered to tissues in its original form and converted to menaquinone-4 or whether it is converted to menadione in the intestine followed by delivery of menadione to tissues and subsequent conversion to menaquinone-4. To answer this question, we conducted cannulation experiments using stable isotope tracer technology in rats. We confirmed that the second pathway is correct on the basis of structural assignments and measurements of phylloquinone-derived menadione using high resolution MS analysis and a bioassay using recombinant UBIAD1 protein. Furthermore, high resolution MS and ¹H NMR analyses of the product generated from the incubation of menadione with recombinant UBIAD1 revealed that the hydroquinone, but not the quinone form of menadione, was an intermediate of the conversion. Taken together, these results provide unequivocal evidence that menadione is a catabolic product of oral phylloquinone and a major source of tissue menaquinone-4.     

Menadione- (2-methyl-1,4-naphthoquinone-) dependent enzymatic redox cycling and calcium release by mitochondria

The results presented in this paper reveal the existence of three distinct menadione (2-methyl-1,4-naphthoquinone) reductases in mitochondria: NAD(P)H:(quinone-acceptor) oxidoreductase (D,T-diaphorase), NADPH:(quinone-acceptor) oxidoreductase, and NADH:(quinone-acceptor) oxidoreductase. All three enzymes reduce menadione in a two-electron step directly to the hydroquinone form. NADH-ubiquinone oxidoreductase (NADH dehydrogenase) and NAD(P)H azoreductase do not participate significantly in menadione reduction. In mitochondrial extracts, the menadione-induced NAD(P)H oxidation occurs beyond stoichiometric reduction of the quinone and is accompanied by O2 consumption. Benzoquinone is reduced more rapidly than menadione but does not undergo redox cycling. In intact mitochondria, menadione triggers oxidation of intramitochondrial pyridine nucleotides, cyanide-insensitive O2 consumption, and a transient decrease of delta psi. In the presence of intramitochondrial Ca2+, the menadione-induced oxidation of pyridine nucleotides is accompanied by their hydrolysis, and Ca2+ is released from mitochondria. The menadione-induced Ca2+ release leaves mitochondria intact, provided excessive Ca2+ cycling is prevented. In both selenium-deficient and selenium-adequate mitochondria, menadione is equally effective in inducing oxidation of pyridine nucleotides and Ca2+ release. Thus, menadione-induced Ca2+ release is mediated predominantly by enzymatic two-electron reduction of menadione, and not by H2O2 generated by menadione-dependent redox cycling. Our findings argue against D,T-diaphorase being a control device that prevents quinone-dependent oxygen toxicity in mitochondria.     

Menadione stress in Saccharomyces cerevisiae strains deficient in the glutathione transferases

Using S. cerevisiae as a eukaryotic cell model we have analyzed the involvement of both glutathione transferase isoforms, Gtt1 and Gtt2, in constitutive resistance and adaptive response to menadione, a quinone which can exert its toxicity as redox cycling and/or electrophiles. The detoxification properties, of these enzymes, have also been analyzed by the appearance of S-conjugates in the media. Direct exposure to menadione (20 mM/60 min) showed to be lethal for cells deficient on both Gtt1 and Gtt2 isoforms. However, after pre-treatment with a low menadione concentration, cells deficient in Gtt2 displayed reduced ability to acquire tolerance when compared with the control and the Gtt1 deficient strains. Analyzing the toxic effects of menadione we observed that the gtt2 mutant showed no reduction in lipid peroxidation levels. Moreover, measuring the levels of intracellular oxidation during menadione stress we have shown that the increase of this oxidative stress parameter was due to the capacity menadione possesses in generating reactive oxygen species (ROS) and that both GSH and Gtt2 isoform were required to enhance ROS production. Furthermore, the efflux of the menadione-GSH conjugate, which is related with detoxification of xenobiotic pathways, was not detected in the gtt2 mutant. Taken together, these results suggest that acquisition of tolerance against stress generated by menadione and the process of detoxification through S-conjugates are dependent upon Gtt2 activity. This assessment was corroborated by the increase of GTT2 expression, and not of GTT1, after menadione treatment.     

Inhibition of apoptosis by menadione on exposure to UVA

Quinones are widely distributed in the environment, both as natural products and as pollutants. This paper reports that one of the simplest quinones, 2-methyl-1,4-naphthoquinone (menadione), effectively inhibited apoptosis in the presence of UVA. Menadione suppressed the apoptosis induced by serum depletion and cell detachment. This effect was significantly enhanced by UVA irradiation. An antioxidant, N-acetylcysteine, completely inhibited the antiapoptotic effects of both menadione itself and menadione plus UVA, and peroxidation of the cells after treatment was observed using a probe to detect the intracellular production of peroxides. By contrast, 2-hydroxy-1,4-naphtoquinone (lawsone) showed no antiapoptotic effect in the presence or absence of UVA. Lawsone is reported not to undergo the redox process that produces reactive oxygen species. These results indicated that intracellular peroxidation contributed to the antiapoptotic effects of both menadione itself and menadione plus UVA. Dysregulation of the apoptotic process is critical to carcinogenesis. The photosensitization of quinone compounds as it relates to the inhibition of apoptosis should be examined in the future.     

Saccharomyces cerevisiae has distinct adaptive responses to both hydrogen peroxide and menadione.

Treatment of Saccharomyces cerevisiae cells with low concentrations of either hydrogen peroxide or menadione (a superoxide-generating agent) induces adaptive responses which protect cells from the lethal effects of subsequent challenge with higher concentrations of these oxidants. Pretreatment with menadione is protective against cell killing by hydrogen peroxide; however, pretreatment with hydrogen peroxide is unable to protect cells from subsequent challenge with menadione. This suggests that the adaptive responses to these two different oxidants may be distinct.     

Oxidative stress resistance of Escherichia coli strains deficient in glutathione biosynthesis

Sensitivity to various oxidants was determined for Escherichia coli strains JTG10 and 821 deficient in biosynthesis of glutathione (gsh-) and their common parental strain AB1157 (gsh+). The three strains showed identical sensitivity to H2O2. E. coli 821 was more resistant than AB1157 and JTG10 to menadione, cumene hydroperoxide, and N-ethylmaleimide. This resistance was not related to the gsh mutation because the other gsh- mutant and the parental strain showed similar sensitivity to these oxidants. The measured activities of NADPH:menadione diaphorase and glucose-6-phosphate dehydrogenase and the extracellular level of menadione suggested that the enhanced resistance of E. coli 821 to menadione might be due to decreased diaphorase activity, but not to a lowered rate of menadione uptake.