Open-Label Allopregnanolone Treatment of Men with Fragile X-Associated Tremor/Ataxia Syndrome.

Fragile X-associated tremor/ataxia syndrome (FXTAS) is a late-onset neurodegenerative disorder affecting approximately 45% of male and 16% of female carriers of the FMR1 premutation over the age of 50 years. Currently, no effective treatment is available. We performed an open-label intervention study to assess whether allopregnanolone, a neurosteroid promoting regeneration and repair, can improve clinical symptoms, brain activity, and magnetic resonance imaging (MRI) measurements in patients with FXTAS. Six patients underwent weekly intravenous infusions of allopregnanolone (2-6 mg over 30 min) for 12 weeks. All patients completed baseline and follow-up studies, though MRI scans were not collected from 1 patient because of MRI contraindications. The MRI scans from previous visits, along with scans from 8 age-matched male controls, were also included to establish patients' baseline condition as a reference. Functional outcomes included quantitative measurements of tremor and ataxia and neuropsychological evaluations. Brain activity consisted of event-related potential N400 word repetition effect during a semantic memory processing task. Structural MRI outcomes comprised volumes of the hippocampus, amygdala, and fluid-attenuated inversion recovery hyperintensities, and microstructural integrity of the corpus callosum. The results of the study showed that allopregnanolone infusions were well tolerated in all subjects. Before treatment, the patients disclosed impairment in executive function, verbal fluency and learning, and progressive deterioration of all MRI measurements. After treatment, the patients demonstrated improvement in executive functioning, episodic memory and learning, and increased N400 repetition effect amplitude. Although MRI changes were not significant as a group, both improved and deteriorated MRI measurements occurred in individual patients in contrast to uniform deterioration before the treatment. Significant correlations between baseline MRI measurements and changes in neuropsychological test scores indicated the effects of allopregnanolone on improving executive function, learning, and memory for patients with relatively preserved hippocampus and corpus callosum, while reducing psychological symptoms for patients with small hippocampi and amygdalae. The findings show the promise of allopregnanolone in improving cognitive functioning in patients with FXTAS and in partially alleviating some aspects of neurodegeneration. Further studies are needed to verify the efficacy of allopregnanolone for treating FXTAS.

Kinetic and proteomic analyses of S-nitrosoglutathione-treated hexokinase A: consequences for cancer energy metabolism.

Mammalian hexokinase (HXK) is found at the outer mitochondrial membrane, exposed to mitochondrial oxygen- and nitrogen-radicals. Given the important role of this enzyme in metabolic pathways and diseases, the effect of S-nitrosoglutathione (GSNO) on HXK A structure and activity was studied. To focus on the catalytic domain, yeast HXK A was used because it has a significant homology to the mammalian domain that contains both the regulatory and catalytic sites. Biologically relevant [GSNO]/[HXK] caused a significant decrease in V(max) with glucose (but not with fructose), along with oxidation of 5 Met and nitration of 4 Tyr. Preincubation of HXK with glucose abrogated the effect of GSNO whereas fructose was ineffective. These results are interpreted by considering the tight binding of glucose to the enzyme as opposed to that of fructose. The segment comprised from amino acids 304 to 306 contained the most modifications. Given that this sequence is highly conserved in HXK from various species, a decline in activity is expected when a high-affinity substrate is presented. Considering that changes in primary structure are envisioned at high [GSNO]/[HXK] ratios, like those present under normal conditions, it could be hypothesized that the high concentration of hexokinase present in fast growing tumors may serve not only to sustain high glycolysis rates, but also to minimize protein damage that might result in activity decline, compromising energy metabolism.

Tyrosine oxidation products: analysis and biological relevance.

Dityrosine is found in several proteins as a product of UV irradiation, gamma-irradiation, aging, exposure to oxygen free radicals, nitrogen dioxide, peroxynitrite, and lipid hydroperoxides. Interest of dityrosine in proteins is based on its potential as a specific marker for oxidatively damaged proteins and their selective proteolysis, hence it could be used as a marker for oxidative stress. Dityrosine is also the product of normal post-translational processes affecting specific structural proteins. Since post-translational modification of a given amino acid in a protein is equivalent to the substitution of that residue by an analogue, it has been proposed that the covalent modification of amino acids may serve as a "marking" step for protein degradation.

Freshening of the Ross Sea during the late 20th century.

Ocean measurements in the Ross Sea over the past four decades, one of the longest records near Antarctica, reveal marked decreases in shelf water salinity and the surface salinity within the Ross Gyre. These changes have been accompanied by atmospheric warming on Ross Island, ocean warming at depths of approximately 300 meters north of the continental shelf, a more negative Southern Oscillation Index, and thinning of southeast Pacific ice shelves. The freshening appears to have resulted from a combination of factors, including increased precipitation, reduced sea ice production, and increased melting of the West Antarctic Ice Sheet.

Nitric oxide synthase in porcine heart mitochondria: evidence for low physiological activity.

The capacity of isolated porcine heart mitochondria to produce nitric oxide (NO) via mitochondrial NO synthase (NOS) was evaluated. The mitochondrial NOS content and activity (0.2 nmol NO x mg mitochondrial protein(-1) x min(-1)) were approximately 10 times lower than previously reported for the rat liver. No evidence for mitochondrial NOS-generated NO was found in mitochondrial suspensions based on the lack of NO production and the lack of effect of either L-arginine or NOS inhibitors on the rate of respiration. The reason that even the low mitochondrial NOS activity did not result in net NO production and metabolic effects is because the mitochondrial metabolic breakdown of NO (1-4 nmol NO x mg mitochondrial protein(-1) x min(-1)) was greater than the maximum rate of NO production measured in homogenates. These data suggest that NO production at the mitochondria via NOS is not a significant source of NO in the intact heart and does not regulate cardiac oxidative phosphorylation.

Metabolism of S-nitrosoglutathione in intact mitochondria.

S-nitrosation of protein thiol groups by nitric oxide (NO*) is a widely recognized protein modification. Only few intracellular S-nitrosated proteins have been identified and it has been reported that S-nitrosation/denitrosation can serve as a regulatory process in signal-transduction pathways. Given the potential physiological importance of S-nitrosothiols, and considering that mitochondria are endowed with high levels of thiols and the biochemical requisites for synthesizing NO*, we examined the occurrence of S-nitrosoglutathione (GSNO) in intact, coupled rat liver mitochondria. These organelles contained 0.34 nmol of GSNO/mg of protein, detected by HPLC with UV-visible and electrochemical detections. This concentration was dynamically modulated by the availability of NO*; its decay was affected mainly by GSH and superoxide dismutase in a reaction that entailed the generation of GSSG. On the basis of the relatively long half-life of GSNO and the negligible recovery of NO* during its decay, roles for GSNO as a storage and transport molecule for NO* are discussed. Moreover, the formation of GSNO and its reaction with GSH can be considered to be partly responsible for the catabolism of NO* via a complex mechanism that might result in the formation of hydroxylamine, nitrite or nitrous oxide depending upon the availability of oxygen, superoxide dismutase and glutathione. Finally, the high concentrations of GSH in the cytosol and mitochondria might favour the formation of GSNO by reacting with NO* 'in excess', thereby avoiding damaging side reactions (such as peroxynitrite formation), and facilitate the inactivation of NO* by generating other nitrogen-related species without the chemical properties characteristic of NO*.

Mechanism of the formation and proteolytic release of H2O2-induced dityrosine and tyrosine oxidation products in hemoglobin and red blood cells.

Oxyhemoglobin exposed to a continuous flux of H(2)O(2) underwent oxidative modifications, including limited release of fluorescent fragmentation products. The main fragments formed were identified as oxidation products of tyrosine, including dopamine, dopamine quinone, and dihydroxyindol. Further release of these oxidation products plus dityrosine was only seen after proteolytic degradation of the oxidatively modified hemoprotein. A possible mechanism is proposed to explain the formation of these oxidation products that includes cyclization, decarboxylation, and further oxidation of the intermediates. Release of dityrosine is proposed as a useful technique for evaluating selective proteolysis after an oxidative stress, because dityrosine is metabolically stable, and it is only released after enzymatic hydrolysis of the oxidatively modified protein. The measurement can be accomplished by high performance liquid chromatography with fluorescence detection or by high efficiency thin layer chromatography. Comparable results, in terms of dityrosine release, were obtained using red blood cells of different sources after exposing them to a flux of H(2)O(2). Furthermore, dityrosine has been reported to occur in a wide variety of oxidatively modified proteins. These observations suggest that dityrosine formation and release can be used as a highly specific marker for protein oxidation and selective proteolysis.

The modulation of oxygen radical production by nitric oxide in mitochondria.

Biological systems that produce or are exposed to nitric oxide (NO radical) exhibit changes in the rate of oxygen free radical production. Considering that mitochondria are the main intracellular source of oxygen radicals, and based on the recently documented production of NO(radical) by intact mitochondria, we investigated whether NO(radical), produced by the mitochondrial nitric-oxide synthase, could affect the generation of oxygen radicals. Toward this end, changes in H(2)O(2) production by rat liver mitochondria were monitored at different rates of endogenous NO(radical) production. The observed changes in H(2)O(2) production indicated that NO(radical) affected the rate of oxygen radical production by modulating the rate of O(2) consumption at the cytochrome oxidase level. This mechanism was supported by these three experimental proofs: 1) the reciprocal correlation between H(2)O(2) production and respiratory rates under different conditions of NO(radical) production; 2) the pattern of oxidized/reduced carriers in the presence of NO(radical), which pointed to cytochrome oxidase as the crossover point; and 3) the reversibility of these effects, evidenced in the presence of oxymyoglobin, which excluded a significant role for other NO(radical)-derived species such as peroxynitrite. Other sources of H(2)O(2) investigated, such as the aerobic formation of nitrosoglutathione and the GSH-mediated decay of nitrosoglutathione, were found quantitatively negligible compared with the total rate of H(2)O(2) production.

Iron primes hepatic macrophages for NF-kappaB activation in alcoholic liver injury.

NF-kappaB activation induced by lipopolysaccharide (LPS) in cultured hepatic macrophages (HM) may be abrogated by pretreatment of cells with a lipophilic iron chelator, 1,2-dimethyl-3-hydroxypyrid-4-one (L1, deferiprone), suggesting a role for iron in this molecular event [M. Lin, M., R. A. Rippe, O. Niemelä, G. Brittenham, and H. Tsukamoto, Am. J. Physiol. 272 (Gastrointest. Liver Physiol. 35): G1355-G1364, 1997]. To ascertain the relevance in vivo of this hypothesis, HM from an experimental model of alcoholic liver injury were examined for the relationship between nuclear factor (NF)-kappaB activation and iron storage. HM showed a significant increase in nonheme iron concentration (+70%), accompanied by enhanced generation of electron paramagnetic resonance-detected radicals (+200%), NF-kappaB activation (+100%), and tumor necrosis factor-alpha (+150%) and macrophage inflammatory protein-1 (+280%) mRNA induction. Treatment of the cells ex vivo with L1 normalized all these parameters. HM content of ferritin protein, ferritin L chain mRNA, and hemeoxygenase-1 mRNA and splenic content of nonheme iron were increased, suggesting enhanced heme turnover as a cause of the increased iron storage and NF-kappaB activation. To test this possibility, increased iron content in HM was reproduced in vitro by phagocytosis of heat-treated red blood cells. Treatment caused a 40% increase in nonheme iron concentration and accentuated LPS-induced NF-kappaB activation twofold. Both effects could be abolished by pretreatment of cells with zinc protoporphyrin, a hemeoxygenase inhibitor. To extend this observation, animals were splenectomized before 9-wk alcohol feeding. Splenectomy resulted in further increments in HM nonheme iron storage (+60%) and NF-kappaB activation (+90%) and mononuclear cell infiltration (+450%), particularly around the iron-loaded HM in alcohol-fed animals. These results support the pivotal role of heme-derived iron in priming HM for NF-kappaB activation and expression of proinflammatory genes in alcoholic liver injury.

The reaction of nitric oxide with ubiquinol: kinetic properties and biological significance.

The reaction of nitric oxide (*NO) with ubiquinol-0 and ubiquinol-2, short-chain analogs of coenzyme Q, was examined in anaerobic and aerobic conditions in terms of formation of intermediates and stable molecular products. The chemical reactivity of ubiquinol-0 and ubiquinol-2 towards *NO differed only quantitatively, the reactions of ubiquinol-2 being slightly faster than those of ubiquinol-0. The ubiquinol/*NO reaction entailed oxidation of ubiquinol to ubiquinone and reduction of *NO to NO-, the latter identified by its reaction with metmyoglobin to form nitroxylmyoglobin and indirectly by measurement of nitrous oxide (N2O) by gas chromatography. Both the rate of ubiquinone accumulation and *NO consumption were linearly dependent on ubiquinol and *NO concentrations. The stoichiometry of *NO consumed per either ubiquinone formed or ubiquinol oxidized was 1.86 A 0.34. The reaction of *NO with ubiquinols proceeded with intermediate formation of ubisemiquinones that were detected by direct EPR. The second order rate constants of the reactions of ubiquinol-0 and ubiquinol-2 with *NO were 0.49 and 1.6 x 10(4) M(-1)s(-1), respectively. Studies in aerobic conditions revealed that the reaction of *NO with ubiquinols was associated with O2 consumption. The formation of oxyradicals - identified by spin trapping EPR- during ubiquinol autoxidation was inhibited by *NO, thus indicating that the O2 consumption triggered by *NO could not be directly accounted for in terms of oxyradical formation or H2O2 accumulation. It is suggested that oxyradical formation is inhibited by the rapid removal of superoxide anion by *NO to yield peroxynitrite, which subsequently may be involved in the propagation of ubiquinol oxidation. The biological significance of the reaction of ubiquinols with *NO is discussed in terms of the cellular O2 gradients, the steady-state levels of ubiquinols and *NO, and the distribution of ubiquinone (largely in its reduced form) in biological membranes with emphasis on the inner mitochondrial membrane.

The role of mitochondrial glutathione in DNA base oxidation.

The objective of this study was to elucidate the role of mitochondrial GSH in the reactions leading to mitochondrial DNA oxidative damage in terms of 8-hydroxy-desoxyguanosine (8-HOdG) accumulation. With this purpose, tightly coupled mitochondria depleted of matrix GSH were used and the effects of H2O2 (generated during the oxidation of substrates) on 8-HOdG levels were investigated. Mitochondrial integrity, assessed by O2 uptake, respiratory control and P/O ratios, was conserved upon depletion of GSH up to 95%. The rates of H2O2 production linked to the oxidation of endogenous substrates by control and GSH-depleted mitochondria were similar. Succinate (in the absence or presence of antimycin A) enhanced the rate H2O2 production to a similar extent in both control and GSH-depleted mitochondria. These rates of H2O2 production accounted for 1.5-2.5% of the rate of O2 uptake. The levels of 8-HOdG in GSH-depleted mitochondria were 35-50% lower than those in control mitochondria, when measured at different H2O2 production rates. Conversely, in experiments carried out with calf thymus DNA with different Cu/Fe content, GSH increased 1.4-2.4-fold the accumulation of 8-HOdG. These values were further enhanced (44-50%) by superoxide dismutase and decreased by catalase. The lower levels of 8-HOdG in GSH-depleted mitochondria and the higher levels in GSH-supplemented calf thymus DNA suggest a role for the non-protein thiol in the reactions leading to mtDNA oxidative damage. These findings are interpreted in terms of the redox transitions involving O2, GSH, and metal catalysts bound to DNA. A mechanism is proposed by which GSH plays a critical role in the reduction of DNA-Cu complexes and decays by free radical pathways kinetically regulated by superoxide dismutase.

Extracellular activation of fluorinated aziridinylbenzoquinone in HT29 cells EPR studies.

The plasma membrane of HT29 human colon carcinoma cells was characterized by EPR spectroscopy as the site for redox activation of 3,6-difluoro-2,5-bis(aziridinyl)-1,4-benzoquinone (F-DZQ). Supplementation of HT29 cells with F-DZQ yielded an EPR signal ascribed to the semiquinone species; the hyperfine splitting constants of the 11-line spectrum were 1.4 and 1.35 G for aN and aF, respectively. The intensity of the EPR signal was inhibited competitively by potassium ferricyanide, a compound which has no access to the intracellular milieu and used to evaluate transmembrane NADH-ferricyanide reductase activity. The extracellular localization of the signal was confirmed by using chromium trioxalate, a membrane-impermeant spin-broadening agent, which abolished in a concentration-dependent manner the semiquinone signal originating from the metabolism of F-DZQ by HT29 cells. The intensity of the semiquinone signal was decreased by agents which block sulfhydryl groups upon alkylation, fluorodinitrobenzene and p-chloromercuribenzoate, presumably acting on plasma membrane dehydrogenases. Other flavin dehydrogenase inhibitors, such as allopurinol, deprenyl or clorgyline, and D-arginine or NG-methyl-L-arginine did not affect the EPR signal. Conversely, the intensity of the semiquinone signal was increased upon supplementation of HT29 cells with glucose and insulin, which may enhance the intracellular levels of electron donors for the transplasma membrane dehydrogenase activity. The extracellular semiquinone signal was abolished by superoxide dismutase by a mechanism implying displacement of the equilibrium of the autoxidation reaction. Formation of oxygen-centered radicals during this redox activity was evaluated by EPR in conjunction with the spin trap 4-POBN. A composite signal consisting of the spin adducts of methyl, hydroxyl and superoxide radicals was observed (the former arising from hydroxyl radical attack on the quinone solvent, dimethylsulfoxide). The formation of these spin adducts was abolished by superoxide dismutase and their detection became impossible in the presence of the line broadening agent chromiun trioxalate, thus indicating their extracellular formation and localization, respectively. The occurrence of a redox site at the plasma membrane of HT29 cells for the activation of this halogenated aziridinylbenzoquinone is discussed in terms of its significance for intracellular processes and a build-up of oxyradicals in the extracellular milieu.

Oxidation of adrenaline by ferrylmyoglobin.

The oxidation of adrenaline by ferrylmyoglobin, the product formed by the oxidation of myoglobin with H2O2, was examined by absorption, fluorescence, and EPR spectroscopy in terms of the formation of intermediate free radicals and stable molecular products and the binding of adrenaline oxidation products to the apoprotein. The reaction of adrenaline with ferrylmyoglobin resulted in reduction of the hemoprotein to metmyoglobin and consumption of adrenaline. Quantification of metmyoglobin formed per adrenaline yielded a ratio of 1.66. The reaction was found first order on adrenaline concentration and second order on ferrylmyoglobin concentration. This, together with the above ratio, suggested a mechanism by which two oxoferryl moieties (ferrylmyoglobin) were reduced by adrenaline yielding metmyoglobin and the o-semiquinone state of adrenaline. The decay of the o-semiquinone to adrenochrome was confirmed by an increase in absorbance at 485 nm. The product was nonfluorescent; alkalinization of the reaction mixture resulted in a strong fluorescence at 540 nm ascribed to 3,5,6-trihydroxyindol or adrenolutin. Hence, adrenochrome and its alkali-catalyzed product, adrenolutin, are the major molecular products formed during the oxidation of adrenaline by ferrylmyoglobin. Semiquinones formed during the adrenaline/ferrylmyoglobin interaction were detected by EPR, spin stabilizing these species with Mg2+. The six-line EPR spectrum observed (aN=4.5 G, aN(CH3)=5.1, and a2H=0.91; g=2.0040) may be assigned to the semiquinone forms of adrenochrome and/or adrenolutin or a composite of these species. The intensity of the EPR signal increased with time and its subsequent decay followed a second-order kinetics as inferred by the proportionality of the square of the EPR line intensity with H2O2 concentration. Heme destruction and lysine loss, inherent in the reaction of metmyoglobin with H2O2, were prevented 80 and 34% by adrenaline, respectively. The low protection exerted by adrenaline against lysine loss was possibly due to the formation of Schiff bases between the epsilon-NH2 group of lysine and the o-quinone oxidation product(s) of adrenaline. The yield of Schiff base formation was 20-25%. The autoxidation of adrenaline at physiological pH is extremely slow or nonexistent. These data provide a rationale for the primary oxidation of adrenaline by the pseudoperoxidatic activity of ferrylmyoglobin and suggest implications of the free radicals thereby formed for the oxidative damage in reperfusion injury.

Production of nitric oxide by mitochondria.

The production of NO. by mitochondria was investigated by electron paramagnetic resonance using the spin-trapping technique, and by the oxidation of oxymyoglobin. Percoll-purified rat liver mitochondria exhibited a negligible contamination with other subcellular fractions (1-4%) and high degree of functionality (respiratory control ratio = 5-6). Toluene-permeabilized mitochondria, mitochondrial homogenates, and a crude preparation of nitric oxide synthase (NOS) incubated with the spin trap N-methyl-D-glucamine-dithiocarbamate-FeII produced a signal ascribed to the NO. spin adduct (g = 2.04; aN = 12.5 G). The intensity of the signal increased with time, protein concentration, and L-Arg, and decreased with the addition of the NOS inhibitor NG-monomethyl-L-arginine. Intact mitochondria, mitochondrial homogenates, and submitochondrial particles produced NO. (followed by the oxidation of oxymyoglobin) at rates of 1.4, 4.9, and 7.1 nmol NO. x (min.mg protein)-1, respectively, with a Km for L-Arg of 5-7 microM. Comparison of the rates of NO. production obtained with homogenates and submitochondrial particles indicated that most of the enzymatic activity was localized in the mitochondrial inner membrane. This study demonstrates that mitochondria are a source of NO., the production of which may effect energy metabolism, O2 consumption, and O2 free radical formation.

Purification and characterization of a nitric-oxide synthase from rat liver mitochondria.

The biosynthesis of nitric oxide (NO.) in different cell types occurs concomitantly with the conversion of L-arginine to L-citrulline by the enzyme nitric-oxide synthase (NOS). NO. has been identified as a major participant in a number of basic physiological functions such as neurotransmission, vasodilation, and immune response. At the subcellular level, mitochondria have been identified as targets for NO.; however, to date, no unambiguous evidence has been presented to identify these organelles as sources of NO.. In this study, a NOS was isolated to homogeneity from Percoll-purified rat liver mitochondria. Kinetic parameters, molecular weight, requirement of cofactors, and cross-reactivity to monoclonal antibodies against macrophage NOS suggest similarities to the inducible form. However, the constitutive expression of the mitochondrial enzyme and its main membrane localization indicate the presence of either a distinctive isoform or a macrophage isoform containing posttranslational modifications that lead to different subcellular compartments. The detection of NADPH-oxidizing activities and a production of superoxide anion catalyzed by mtNOS and recombinant cytochrome P450 reductase were consistent with the sequence homology reported for these two proteins. Given the role of NO. as cellular transmitter, messenger, or regulator, the presence of a functionally active mitochondrial NOS may have important implications for the intermediary metabolism.

Functional implications of nitric oxide produced by mitochondria in mitochondrial metabolism.

The effects of endogenous production of NO., catalysed by the mitochondrial nitric oxide synthase (NOS), on mitochondrial metabolism were studied. The respiratory rates of intact mitochondria in State 4 were decreased by 40% and 28% with succinate and malate-glutamate, respectively, in the presence of L-arginine (L-Arg); conversely, the O2 uptake with NG-methyl-L-arginine (NMMA), a competitive inhibitor of NOS, was increased. The production of NO. and the inhibition of the respiratory rates were dependent on the metabolic state in which mitochondria were maintained: NO. production was probably supported by mitochondrial NADPH, the latter maintained by the energy-dependent transhydrogenase. In addition to the decline in the respiratory rate, an inhibition of ATP synthesis was also observed (40-50%) following supplementation with L-Arg. The dependence of the respiratory rates of mitochondria in State 3 and cytochrome oxidase activities on O2 concentrations with either L-Arg or NMMA indicated that both processes were competitively inhibited by NO. at the cytochrome oxidase level. This inhibition can be explained by the interaction of NO. with cytochrome oxidase at the binuclear centre. The role of NO. as a physiological modulator of cytochrome oxidase is discussed in terms of cellular metabolism.

Quinones increase gamma-glutamyl transpeptidase expression by multiple mechanisms in rat lung epithelial cells.

gamma-Glutamyl transpeptidase (GGT) plays an important role in glutathione (GSH) metabolism. GGT expression is increased in oxidant-challenged cells; however, the signaling mechanisms involved are uncertain. The present study used 2,3-dimethoxy-1,4-naphthoquinone (DMNQ), a redox cycling quinone that continuously produced H2O2 in rat lung epithelial L2 cells. It was found that DMNQ increased GGT mRNA content by increasing transcription, as measured by nuclear run-on. This was accompanied by increased GGT specific activity. Cycloheximide, a protein synthesis inhibitor, blocked neither the increased GGT mRNA content nor the increased GGT transcription rate caused by DMNQ, suggesting that increased GGT transcription was a direct rather than secondary response. Previous data from this laboratory (R.-M. Liu, H. Hu, T. W. Robinson, and H. J. Forman. Am. J. Respir. Cell Mol. Biol. 14: 186-191, 1996) showed that tert-butylhydroquinone (TBHQ) increased GGT mRNA content by increasing its stability. TBHQ differs markedly from DMNQ in terms of its conjugation with GSH and H2O2 generation. Together, the data suggest that quinones upregulate GGT through multiple mechanisms, increased transcription and posttranscriptional modulation, which are apparently mediated through generation of reactive oxygen species and GSH conjugated formation, respectively.

Reactions of halogen-substituted aziridinylbenzoquinones with glutathione. Formation of diglutathionyl conjugates and semiquinones.

The reaction between glutathione and 2,5-diaziridinyl-1,4-benzoquinones bearing halogen substituents at C3 and C6 was examined in terms of the formation of glutathionyl-quinone conjugates and semiquinones by HPLC with UV detection, mass spectroscopy and EPR. The reactivity of the halogen atoms toward sulfur substitution is the primary reaction leading to the formation of mono- and di-glutathionyl-substituted quinones. The relative formation of these conjugates depended on the GSH/quinone molar ratios. At GSH/quinone molar ratios below unity, the products observed were the reduced form of the parent quinone, a dithioether derivative and GSSG. Disulfide formation accounted for 60-68% of total GSH consumed. EPR analysis of these reaction mixtures showed a 5-line spectrum (1:2:3:2:1 relative intensities) with 2 equivalent N (aN = 1.98 G) and assigned to the semiquinone form of dichloro- diaziridinylbenzoquinone. Semiquinone quantification by double integration of the EPR signals and interpolation with an adequate standard revealed that the amount of semiquinone formed per GSH consumed was 0.98. At GSH/quinone molar ratios above unity (4, 10 and 100 molar excess of GSH) a pattern of products emerged consisting of 3,6-diglutathionyl quinones with two, one and no aziridinyl moieties, identified by mass spectral analysis. EPR studies revealed that these compounds were minor components of a composite EPR spectrum (a 3-line signal with 1:1:1 relative intensities, 1 equivalent N (aN = 1.73 G) and 1 H (aH = 1.45 G) or a 3-line signal with 1:2:1 relative intensities and 2 equivalent H (aH = 1.4 G). These minor components were assigned to the diglutathionyl conjugates bearing one- or no aziridinyl moiety, respectively. The major component in the EPR signal showed a 3-line spectrum (1:1:1 relative intensity) with 1 equivalent N (aN = 1.7 G) and a g shift of -0.96 G. This spectrum was assigned to a triglutathionyl conjugate of a monoaziridinylbenzoquinone. This major component was also observed when GSH/quinone mixtures were incubated with the two-electron transfer flavoprotein NAD(P)H:quinone oxidoreductase. The semiquinone signals were abolished by superoxide dismutase. In the presence of catalase, the contribution of these components to the overall EPR spectrum was equal. These data are discussed in terms of the one-electron transfer steps encompassed by thiol oxidation and semiquinone formation and the two-electron transfers inherent in sulfur substitution and aziridinyl group loss.

Heme protein radicals: formation, fate, and biological consequences.

The oxidation of myoglobin by H2O2 yields ferrylmyoglobin, which contains two oxidizing equivalents: the oxoferryl complex and an amino acid radical. This study examines the electron paramagnetic resonance (EPR) properties of the resulting amino acid radicals and their inherent kinetic features at [H2O2]/[protein] ratios close to physiological conditions (i.e., < or = 1). The EPR spectrum obtained with continuous flow at room temperature consisted of a composite of three signals: a low intensity signal and two high intensity signals. The former had a g-value of 2.014, contributed 10-15% to the overall spectrum and was ascribed to a peroxyl radical. Of the two high intensity signals, one consisted of a six-line spectrum (g = 2.0048) that contributed approximately 17-19% to the overall signal; hyperfine splitting constants to ring protons permitted to identify this signal as a tyrosyl radical. The other high intensity signal (with similar g-value and underlying that of the tyrosyl radical) was ascribed to an aromatic amino acid upon comparison with the EPR characteristics for radicals in aromatic amino acid-containing peptides. Analysis of these data in connection with amino acid analysis and the EPR spectra obtained under similar conditions with another hemoprotein, hemoglobin, allowed to suggest a mechanism for the formation of the protein radicals in myoglobin. The aromatic amino acid radical was observed to be relatively long lived in close proximity to the heme iron. Hence, it is likely that this is the first site of protein radical; reduction of the oxoferryl complex by Tyr (FeIV=O + Tyr-OH + H+ --> FeIII + H2O + Tyr-O.)--and alternatively by other amino acids--leads to the subsequent formation of other amino acid radicals within an electron-transfer process throughout the protein. This view suggests that the protein radical(s) is highly delocalized within the globin moiety in a dynamic process encompassing electron tunneling through the backbone chain or H-bonds and leading to the formation of secondary radicals.

Enzymic- and thiol-mediated activation of halogen-substituted diaziridinylbenzoquinones: redox transitions of the semiquinone and semiquinone-thioether species.

Activation of 2,5-diaziridinyl-1,4-benzoquinones bearing halogen (Cl, Br, or F) substituents at C3 and C6 by NADPH-cytochrome P450 reductase and glutathione nucleophilic substitution was examined in terms of free radical production and DNA strand scission. A semiquinone species was observed by direct ESR in aerobic conditions during: (a) NADPH-cytochrome P450 reductase-catalyzed reduction of the above quinones. (b) The interaction of these quinones with GSH entailing primarily reactivity of halogen substituents toward sulfur substitution. (c) NADPH-cytochrome P450 reductase-catalyzed activation of products resulting from the quinone/GSH interaction. The semiquinone ESR signal observed during enzymic catalysis was suppressed by superoxide dismutase and was not affected by catalase. ESR studies in conjunction with the spin trapping technique on the autoxidation of the semiquinones formed by the above reaction pathways indicated the formation of superoxide radicals. In addition, thiyl radicals were formed during the reactions following glutathione necleophilic substitution of the above quinones. The ESR signals of both superoxide and thiyl radicals were abolished by superoxide dismutase. No hydroxyl radicals were formed in solution during the redox transitions of these halogen-containing diaziridinylbenzoquinones. Bioreductive activation of these compounds via NADPH-cytochrome P450 reductase or sulfur nucleophilic substitution was associated with the formation of DNA strand breaks. This process was substantially inhibited (74-86%) by superoxide dismutase and to a lesser extent (23-31%) by catalase. It is suggested that DNA strand breakage proceeds in a manner entailing a semiquinone-dependent reduction of metal-ligands bound at the DNA surface and leading to site-specific, hydroxyl radical production.