Cytochrome c-mediated oxidation of hydroethidine and mito-hydroethidine in mitochondria: identification of homo- and heterodimers

Here we report that ferricytochrome c (cyt c(3+)) induces oxidation of hydroethidine (HE) and mitochondria-targeted hydroethidine (Mito-HE or MitoSOX Red) forming highly characteristic homo- and heterodimeric products. Using an HPLC-electrochemical (EC) method, several products were detected from cyt c(3+)-catalyzed oxidation of HE and Mito-HE and characterized by mass spectrometry and NMR techniques as follows: homodimers (HE-HE, E(+)-E(+), Mito-HE-Mito-HE, and Mito-E(+)-Mito-E(+)) and heterodimers (HE-E(+) and Mito-HE-Mito-E(+)), as well as the monomeric ethidium (E(+)) and mito-ethidium (Mito-E(+)). Similar products were detected when HE and Mito-HE were incubated with mitochondria. In contrast, mitochondria depleted of cyt c(3+) were much less effective in oxidizing HE or Mito-HE to corresponding dimeric products. Unlike E(+) or Mito-E(+), the dimeric analogs (E(+)-E(+) and Mito-E(+)-Mito-E(+)) were not fluorescent. Superoxide (O(2)(*-)) or Fremy's salt reacts with Mito-HE to form a product, 2-hydroxy-mito-ethidium (2-OH-Mito-E(+)) that was detected by HPLC. We conclude that HPLC-EC but not the confocal and fluorescence microscopy is a viable technique for measuring superoxide and cyt c(3+)-dependent oxidation products of HE and Mito-HE in cells. Superoxide detection using HE and Mito-HE could be severely compromised due to their propensity to undergo oxidation.     

The confounding effects of light, sonication, and Mn(III)TBAP on quantitation of superoxide using hydroethidine

Previously, we showed that hydroethidine (HE) reacts with intracellular superoxide radical anion (O2-*) to form a unique fluorescent marker product, 2-hydroxyethidium cation (2-OH-E+), that was not formed from HE reaction with other biologically relevant oxidants (H. Zhao et al. Proc. Natl. Acad. Sci. USA102:5727-5732; 2005). Here we rigorously assessed the confounding effects of light, sonication, and Mn(III)TBAP on 2-OH-E+, the HE/O2-* reaction product. Results indicate that continuous exposure to visible light induced photo-oxidation of HE to ethidium cation (E+) by a 2-OH-E+ -dependent mechanism. Treatment of HE with ultrasound, a frequently used technique to lyse cell membranes, induced 2-OH-E+ from in situ generation of O2-*. Mn(III)TBAP, a cell-permeable metal-porphyrin complex used as a catalytic antioxidant, reacts with HE to form E+. This finding provides an alternative interpretation for Mn(III)TBAP effects during the HE/O2-* reaction. In order to correctly interpret the HE reaction with O2-* in cells, it is therefore imperative that HE and HE-derived products be measured by HPLC. A new and improved HPLC-electrochemical (HPLC-EC) detection has been developed for analysis of intracellular O2-*. The HPLC-EC method is at least 10 times more sensitive than the HPLC-fluorescence technique for detecting O2-* in cells.     

Superoxide radical detection in cells, tissues, organisms (animals, plants, insects, microorganisms) and soils

A simple protocol is presented for the assessment of superoxide radical in organisms (animal/plant tissues, microorganisms, cell cultures, biological/culture fluids) and soils, through the quantification of 2-hydroxyethidium (2-OH-E+), its specific reaction product with hydroethidine (HE). It is an alternative to the quantification of 2-OH-E+ by HPLC (restricted to cell cultures), offering the advantage of the in vivo assessment of superoxide radical in a wide range of experimental systems. The protocol includes alkaline-acetone extraction of the sample, purification by microcolumn cation exchange and hydrophobic chromatographies, and fluorescence detection of the isolated 2-OH-E+/HE-oxidation products mixture before and after consumption of 2-OH-E+ by a horseradish peroxidase/hydrogen peroxide system. The protocol is sensitive at <1 pmol 2-OH-E+ per mg protein (extended to the femto level when using large samples) in biological systems, and in soils at 9 pmol superoxide radical per gram of soil. The protocol includes a cytochrome c-based subprotocol for superoxide radical detection in soils at 770 pmol g(-1) soil. For processing ten samples and depending on the experimental material used (soil or biological), the approximate procedure time would be 2-7 h.     

Pulse radiolysis and steady-state analyses of the reaction between hydroethidine and superoxide and other oxidants

Hydroethidine (HE) is a cell-permeable probe used for the intracellular detection of superoxide. Here, we report the direct measurement of the rate constant between hydroethidine and superoxide radical anion using the pulse radiolysis technique. This reaction rate constant was calculated to be ca. 2 x 10(6) M(-1) s(-1) in water:ethanol (1:1) mixture. The spectral characteristics of the intermediates indicated that the one-electron oxidation product of HE was different from the one-electron reduction product of ethidium (E+). The HPLC-electrochemical measurements of incubation mixtures containing HE and the oxygenated Fenton's reagent (Fe2+/DTPA/H2O2) in the presence of aliphatic alcohols or formate as a superoxide generating system revealed 2-OH-E+ as a major product. Formation of 2-OH-E+ by the Fenton's reagent without additives was shown to be superoxide dismutase-sensitive and we attribute the formation of superoxide radical anion to the one-electron reduction of oxygen by the DTPA-derived radical. Addition of tert-butanol, DMSO, and potassium bromide to the Fenton's system caused inhibition of 2-OH-E+ formation. Results indicate that reducing and oxidizing radicals have differential effects on the formation of 2-OH-E+.     

Mechanistic similarities between oxidation of hydroethidine by Fremy's salt and superoxide: stopped-flow optical and EPR studies

We have previously shown that superoxide radical anion (O2.-) reacts with hydroethidine (HE) to form a product that is distinctly different from ethidium (E+) (Zhao et al., Free Radic. Biol. Med. 34:1359; 2003). The structure of this product was recently determined as the 2-hydroxyethidium cation (2-OH-E+) (Zhao et al., Proc. Natl. Acad. Sci. USA 102:5727; 2005). In this study, using HPLC and mass spectrometry techniques, we show that 2-OH-E+ is formed from the reaction between HE and nitrosodisulfonate radical dianion (NDS) or Fremy's salt. The reaction kinetics and mechanism were determined using steady-state and time-resolved optical and EPR techniques. Within the first 50 ms, an intermediate was detected. Another intermediate absorbing strongly at 460 nm and weakly at 670 nm was detected within a second. The structure of this species was assigned to an imino quinone derivative of HE. The stoichiometry of the reaction indicates that two molecules of NDS were needed to oxidize a molecule of HE. We postulate that the first step of the reaction involves the hydrogen atom abstraction from HE to form an aminyl radical that reacts with another molecule of NDS to form an adduct that decomposes to an imino quinone derivative of HE. A similar mechanism has been proposed for the reaction between HE and O2.-. The reaction between HE and the Fremy's salt should provide a facile route for the synthesis of 2-OH-E+, a diagnostic marker product of the HE/O2.- reaction.     

Kinetic analysis and mechanistic aspects of autoxidation of catechins

A peroxidase-based bioelectrochemical sensor of hydrogen peroxide (H(2)O(2)) and a Clark-type oxygen electrode were applied to continuous monitoring and kinetic analysis of the autoxidation of catechins. Four major catechins in green tea, (-)-epicatechin, (-)-epicatechin gallate, (-)-epigallocatechin, and (-)-epigallocatechin gallate, were used as model compounds. It was found that dioxygen (O(2)) is quantitatively reduced to H(2)O(2). The initial rate of autoxidation is suppressed by superoxide dismutase and H(+), but is independent of buffer capacity. Based on these results, a mechanism of autoxidation is proposed; the initial step is the one-electron oxidation of the B ring of catechins by O(2) to generate a superoxide anion (O(2)(*-)) and a semiquinone radical, as supported in part by electron spin resonance measurements. O(2)(*-) works as a stronger one-electron oxidant than O(2) against catechins and is reduced to H(2)O(2). The semiquinone radical is more susceptible to oxidation with O(2) than fully reduced catechins. The autoxidation rate increases with pH. This behavior can be interpreted in terms of the increase in the stability of O(2)(*-) and the semiquinone radical with increasing pH, rather than the acid dissociation of phenolic groups. Cupric ion enhances autoxidation; most probably it functions as a catalyst of the initial oxidation step of catechins. The product cuprous ion can trigger a Fenton reaction to generate hydroxyl radical. On the other hand, borate ion suppresses autoxidation drastically, due to the strong complex formation with catechins. The biological significance of autoxidation and its effectors are also discussed.     

Autocrine/paracrine pattern of superoxide production through NAD(P)H oxidase in coronary arterial myocytes

The present study tested the hypothesis that membrane-bound NAD(P)H oxidase in coronary arterial myocytes (CAMs) is capable of producing superoxide (O(2)(*-)) toward extracellular space to exert an autocrine- or paracrine-like action in these cells. Using a high-speed wavelength-switching fluorescent microscopic imaging technique, we simultaneously monitored the binding of dihydroethidium-oxidizing product to exogenous salmon testes DNA trapped outside CAMs and to nuclear DNA as indicators of extra- and intracellular O(2)(*-) production. It was found that a muscarinic agonist oxotremorine (OXO; 80 microM) increased O(2)(*-) levels more rapidly outside than inside CAMs. In the presence of superoxide dismutase (500 U/ml) plus catalase (400 U/ml) and NAD(P)H oxidase inhibitor diphenylene iodonium (50 microM) or apocynin (100 microM), these increases in extra- and intracellular O(2)(*-) levels were substantially abolished or attenuated. The O(2)(*-) increase outside CAMs was also confirmed by detecting oxidation of nitro blue tetrazolium and confocal microscopic localization of Matrigel-trapped OxyBURST H(2)HFF Green BSA staining around these cells. By electron spin resonance spectrometry, the extracellular accumulation of O(2)(*-) was demonstrated as a superoxide dismutase-sensitive component outside CAMs. Furthermore, RNA interference of NAD(P)H oxidase subunits Nox1 or p47 markedly blocked OXO-induced increases in both extra- and intracellular O(2)(*-) levels, whereas small inhibitory RNA of Nox4 only attenuated intracellular O(2)(*-) accumulation. These results suggest that Nox1 represents a major NAD(P)H oxidase isoform responsible for extracellular O(2)(*-) production. This rapid extracellular production of O(2)(*-) seems to be unique to OXO-induced M(1)-receptor activation, since ANG II-induced intra- and extracellular O(2)(*-) increases in parallel. It is concluded that the outward production of O(2)(*-) via NAD(P)H oxidase in CAMs may represent an important producing pattern for its autocrine or paracrine actions.     

Oxidative chemistry of fluorescent dyes: implications in the detection of reactive oxygen and nitrogen species

HE (hydroethidine), a widely used fluorescent dye for detecting intracellular superoxide, undergoes specific oxidation and hydroxylation reactions. The reaction between HE and O2?- (superoxide radical) yields a diagnostic marker product, 2-hydroxyethidium. This is contrary to the popular notion that O2?- oxidizes HE to form ethidium. HE, however, undergoes a non-specific oxidation to form ethidium in the presence of other oxidants (hydroxyl radical, peroxynitrite and perferryl iron) and other dimeric products. The mitochondria-targeted HE analogue Mito-SOX? undergoes the same type of oxidative chemistry to form products similar to those formed from HE. On the basis of the oxidative chemical mechanism of HE and Mito-SOX?, we conclude that flurorescence microscopy or related techniques are not sufficient to measure the superoxide-specific hydroxylated products. HPLC methodologies are required to separate and identify these products. Peroxynitrite reacts rapidly and stoichiometrically with boronates to form specific products. Assays using fluorescent-based boronate probes will be more reliable for peroxynitrite determination than those using either dichlorodihydrofluorescein or dihydrorhodamine.     

Radical-induced oxidation of trans-resveratrol

trans-Resveratrol (RVT) (3,5,4'-trihydroxystilbene), a polyphenolic constituent of red wine, is thought to be beneficial in reducing the incidence of cardiovascular diseases, partly via its antioxidant properties. However, the mechanism of action by which trans-resveratrol displays its antioxidant effect has not been totally unravelled. This study aimed at establishing a comprehensive scheme of the reaction mechanisms of the direct scavenging of HO(*) and O(2)(*-) radicals generated by water gamma radiolysis. Aerated aqueous solutions of trans-RVT (from 10 to 100μmolL(-1)) were irradiated with increasing radiation doses (from 25 to 400Gy) and further analyzed by UV-visible absorption spectrophotometry for detection of trans-RVT oxidation products. Separation and quantification of RVT and its four oxidation products previously identified by mass spectrometry, i.e., piceatannol (PCT), 3,5-dihydroxybenzoic acid (3,5-DHBA), 3,5-dihydroxybenzaldehyde (3,5-DHB) and para-hydroxybenzaldehyde (PHB), were performed by HPLC/UV-visible spectrophotometry. Determination of the radiolytic yields of trans-RVT consumption and oxidation product formation has allowed us to establish balance between trans-RVT disappearance and the sum of oxidation products formation. Under our conditions, O(2)(-) radicals seemed to poorly initiate oxidation of trans-RVT, whereas the latter, whatever its initial concentration, quantitatively reacted with HO() radicals, via a dismutation mechanism. Two reaction pathways involving HO()-induced trans-RVT primary radicals have been proposed to explain the formation of the oxidation end-products of trans-RVT.     

Secondary structural analysis of the Na(+),K(+)-ATPase and its Na(+) (E(1)) and K(+) (E(2)) complexes by FTIR spectroscopy

The Na(+),K(+)-ATPase is an integral membrane protein which transports sodium and potassium cations against an electrochemical gradient. The transport of Na(+) and K(+) ions is presumably connected to an oscillation of the enzyme between the two conformational states, the E(1) (Na(+)) and the E(2) (K(+)) conformations. The E(1) and E(2) states have different affinities for ligand interaction. However, the determination of the secondary structure of this enzyme in its sodium and potassium forms has been the subject of much controversy. This study was designed to provide a quantitative analysis of the secondary structure of the Na(+),K(+)-ATPase in its sodium (E(1)) and potassium (E(2)) states in both H(2)O and D(2)O solutions at physiological pH, using Fourier transform infrared (FTIR) with its self-deconvolution and second derivative resolution enhancement methods, as well as curve-fitting procedures. Spectroscopic analysis showed that the secondary structure of the sodium salt of the Na(+),K(+)-ATPase in H(2)O solution contains alpha-helix 19.8+/-1%, beta-sheet 25.6+/-1%, turn 9.1+/-1%, and beta-anti 7.5+/-1%, whereas in D(2)O solution, the enzyme shows alpha-helix 16.8+/-1%, beta-sheet 24.5+/-1.5%, turn 10.9+/-1%, beta-anti 9.8+/-1%, and random coil 38.0+/-2%. Similarly, the potassium salt in H(2)O solution contains alpha-helix 16.6+/-1%, beta-sheet 26.4+/-1.5%, turn 8.9+/-1%, and beta-anti 8.1+/-1%, while in D(2)O solution it shows alpha-helix 16.2+/-1%, beta-sheet 24.5+/-1.5%, turn 10.3+/-1%, beta-anti 9.0+/-1%, and random coil 40+/-2%. Thus the main differences for the sodium and potassium forms of the Na(+),K(+)-ATPase are alpha-helix 3.2% in H(2)O and 0.6% in D(2)O, beta-sheet (pleated and anti) 1.5% in H(2)O and random structure 2% (D(2)O), while for other minor components (turn structure), the differences are less than 1%.     

Rapid determination of seed vigor based on the level of superoxide generation during early imbibition.

It has been reported that a large amount of reactive oxygen species (ROS) is produced during seed imbibition and this ROS is related to seed vigor. To make this physiological mechanism clear, we have used 2-methyl-6-(4-methoxyphenyl)-3,7-dihydroimidazo(1,2-alpha)pyrazin-3-one (MCLA) as a sensitive and physiologically compatible probe for the determination of superoxide anion (O(2)(*-)) production in vivo. Our results showed that dry rice (Oryzae sativa L.) seed embryo cells possessed the capacity to generate O(2)(*-). Conversely, the O(2)(*-) production of seed embryo cells was inhibited by quinacrine (QA) and diphenylene iodonium (DPI), two specific inhibitors of NADPH oxidase, and O(2)(*-) induced MCLA-mediated chemiluminescence was also blocked by superoxide dismutase (SOD). Additionally, O(2)(*-) -production ability increased dramatically in a NADPH-dependent way in the plasma membrane protein abstract from rice seed embryo cells, whereas SOD and the inhibitors mentioned above suppressed O(2)(*-) production. These preliminary results suggested that rice seeds contained intrinsic NADPH oxidase activity. To validate this conclusion, dichlorofluorescein (DCF) fluorescence staining was used (observed under a laser scanning microscope, LSM) to reflect the in situ assessment of O(2)(*-) -generation. The position of O(2)(*-) production located at the plasma membrane. Additionally the ability to synthesize O(2)(*-) was activated directly by calcium ions. These observations are in accord with the character of NADPH oxidase catalyzed O(2)(*-) -generation. All these results indicated that NADPH oxidase contribute to O(2)(*-) production and release to the outside. We concluded that NADPH oxidase plays an intrinsic role as an NADPH sensor, so, measuring the O(2)(*-) one can monitor the NADPH concentration, which is an index of seed vigor. Therefore the O(2)(*-) generation during early imbibition can serve as a rapid measurement of seed vigor.     

Production of superoxide anion and hydrogen peroxide by capacitating buffalo (Bubalus bubalis) spermatozoa

In the present study attempts were made to detect and quantify the generation of superoxide anion (O(2)(*-)) and hydrogen peroxide (H(2)O(2)) by capacitating buffalo spermatozoa. Ejaculated buffalo spermatozoa were suspended in sp-TALP medium at 50x10(6)mL(-1) and incubated at 38.5 degrees C with 5% CO(2) in air in the absence or presence of heparin (a capacitation inducer) or reduced nicotinamide adenine dinucleotide phosphate (NADPH) or diphenyleneiodonium (DPI, a flavoprotein inhibitor) for 6h. Production rate of O(2)(*-) and H(2)O(2) by spermatozoa at different hours of capacitation were measured by cytochrome c reduction and phenol red oxidation assays, respectively. Spermatozoa generated both O(2)(*-) and H(2)O(2) spontaneously and following stimulation with heparin and a significant increase of O(2)(*-) production was observed in the presence of NADPH. However, DPI inhibited this NADPH-induced O(2)(*-) production and suggested for existence of putative NADPH-oxidase that constitute a specific O(2)(*-) generating systems in buffalo spermatozoa. Results of our study indicated that buffalo spermatozoa generate O(2)(*-) and H(2)O(2) and production of these free radicals is induced during capacitation.     

The pro-oxidative activity of SOD and nitroxide SOD mimics.

Native Cu,Zn-SOD and synthetic SOD mimics sometimes demonstrate an apparently anomalous bell-shaped dose-response relationship when protecting various biological systems from oxidative stress. Several mechanisms have been proposed to account for such an effect, including: overproduction of H(2)O(2), peroxidative activity of SOD, and opposing roles played by O(2)(*-) in both initiation and termination of radical chain reactions. In the present study, ferrocyanide and thiols, which are susceptible to one-electron and two-electron oxidation, respectively, were subjected to a flux of superoxide in the presence and absence of SOD or SOD mimics. The results show that 1) either O(2)(*-)/HO(2)(*) or H(2)O(2) alone partially inactivates papain, whereas when combined they act synergistically; 2) nitroxide SOD mimics, but not SOD, exhibit a bell-shaped dose-response relationship in protecting papain from inactivation; 3) SOD, which at low dose inhibits superoxide-induced oxidation of ferrocyanide, loses its antioxidative effect as its concentration increases. These findings offer an additional explanation for the pro-oxidative activity of SOD and SOD mimics without invoking any dual activity of O(2)(*-) or a combined effect of SOD and H(2)O(2). The most significant outcome of an increase in SOD level is a decrease of [O(2)(*-)](steady state), rather than any notable elevation of [H(2)O(2)](steady state). As a result, the reaction kinetics of the high oxidation state of each catalyst is altered. In the presence of ultra-low [O(2)(*-)](steady state), the oxidized form of SOD [Cu(II),Zn-SOD] or SOD mimic (oxo-ammonium cation) does not react with O(2)(*-) but rather oxidizes the target molecule that it was supposed to have protected. Consequently, these catalysts exert an anti- or pro-oxidative effect depending on their concentration.     

Inhibition of heat shock protein 90 (hsp90) in proliferating endothelial cells uncouples endothelial nitric oxide synthase activity

Dual increases in nitric oxide ((*)NO) and superoxide anion (O(2)(*-)) production are one of the hallmarks of endothelial cell proliferation. Increased expression of endothelial nitric oxide synthase (eNOS) has been shown to play an important role in maintaining high levels of (*)NO generation to offset the increase in O(2)(*-) that occurs during proliferation. Although recent reports indicate that heat shock protein 90 (hsp90) associates with eNOS to increase (*)NO generation, the role of hsp90 association with eNOS during endothelial cell proliferation remains unknown. In this report, we examine the effects of endothelial cell proliferation on eNOS expression, hsp90 association with eNOS, and the mechanisms governing eNOS generation of (*)NO and O(2)(*-). Western analysis revealed that endothelial cells not only increased eNOS expression during proliferation but also hsp90 interactions with the enzyme. Pretreatment of cultures with radicicol (RAD, 20 microM), a specific inhibitor that does not redox cycle, decreased A23187-stimulated (*)NO production and increased L(omega)-nitroargininemethylester (L-NAME)-inhibitable O(2)(*-) generation. In contrast, A23187 stimulation of controls in the presence of L-NAME increased O(2)(*-) generation, confirming that during proliferation eNOS generates (*)NO. Our findings demonstrate that hsp90 plays an important role in maintaining (*)NO generation during proliferation. Inhibition of hsp90 in vascular endothelium provides a convenient mechanism for uncoupling eNOS activity to inhibit (*)NO production. This study provides new understanding of the mechanisms by which ansamycin antibiotics inhibit endothelial cell proliferation. Such information may be useful in the development and design of new antineoplastic agents in the future.     

Long-term regulation of Na+,K+-ATPase in opossum kidney cells by ouabain

Na(+),K(+)-ATPase, a basolateral transporter responsible for tubular reabsorption of Na(+) and for providing the driving force for vectorial transport of various solutes and ions, can also act as a signal transducer in response to the interaction with steroid hormones. At nanomolar concentrations ouabain binding to Na(+),K(+)-ATPase activates a signaling cascade that ultimately regulates several membrane transporters including Na(+),K(+)-ATPase. The present study evaluated the long-term effect of ouabain on Na(+),K(+)-ATPase activity (Na(+) transepithelial flux) and expression in opossum kidney (OK) cells with low (40) and high (80) number of passages in culture, which are known to overexpress Na(+),K(+)-ATPase (Silva et al., 2006, J Membr Biol 212, 163-175). Activation of a signal cascade was evaluated by quantification of ERK1/2 phosphorylation by Western blot. Na(+),K(+)-ATPase activity was determined by electrophysiological techniques and expression by Western blot. Incubation of cells with ouabain induced activation of ERK1/2. Long-term incubation with ouabain induced an increase in Na(+) transepithelial flux and Na(+),K(+)-ATPase expression only in OK cells with 80 passages in culture. This increase was prevented by incubation with inhibitors of MEK1/2 and PI-3K. In conclusion, ouabain-activated signaling cascade mediated by both MEK1/2 and PI-3K is responsible for long-term regulation of Na(+) transepithelial flux in epithelial renal cells. OK cell line with high number of passages is suggested to constitute a particular useful model for the understanding of ouabain-mediated regulation of Na(+) transport.     

Oxygen activation during oxidation of methoxyhydroquinones by laccase from Pleurotus eryngii

Oxygen activation during oxidation of the lignin-derived hydroquinones 2-methoxy-1,4-benzohydroquinone (MBQH(2)) and 2, 6-dimethoxy-1,4-benzohydroquinone (DBQH(2)) by laccase from Pleurotus eryngii was examined. Laccase oxidized DBQH(2) more efficiently than it oxidized MBQH(2); both the affinity and maximal velocity of oxidation were higher for DBQH(2) than for MBQH(2). Autoxidation of the semiquinones produced by laccase led to the activation of oxygen, producing superoxide anion radicals (Q(*-) + O(2) <--> Q + O(2)(*-)). As this reaction is reversible, its existence was first noted in studies of the effect of systems consuming and producing O(2)(*-) on quinone formation rates. Then, the production of H(2)O(2) in laccase reactions, as a consequence of O(2)(*-) dismutation, confirmed that semiquinones autoxidized. The highest H(2)O(2) levels were obtained with DBQH(2), indicating that DBQ(*-) autoxidized to a greater extent than did MBQ(*-). Besides undergoing autoxidation, semiquinones were found to be transformed into quinones via dismutation and laccase oxidation. Two ways of favoring semiquinone autoxidation over dismutation and laccase oxidation were increasing the rate of O(2)(*-) consumption with superoxide dismutase (SOD) and recycling of quinones with diaphorase (a reductase catalyzing the divalent reduction of quinones). These two strategies made the laccase reaction conditions more natural, since O(2)(*-), besides undergoing dismutation, reacts with Mn(2+), Fe(3+), and aromatic radicals. In addition, quinones are continuously reduced by the mycelium of white-rot fungi. The presence of SOD in laccase reactions increased the extent of autoxidation of 100 microM concentrations of MBQ(*-) and DBQ(*-) from 4.5 to 30.6% and from 19.6 to 40.0%, respectively. With diaphorase, the extent of MBQ(*-) autoxidation rose to 13.8% and that of DBQ(*-) increased to 39.9%.     

Antimycin A and lipopolysaccharide cause the leakage of superoxide radicals from rat liver mitochondria

Here we show that both Antimycin A, a respiratory chain inhibitor inducing apoptosis, and endotoxic shock, a syndrome accompanied by both necrosis and apoptosis, cause not only an increase but also the leakage of superoxide radicals (O(2)(*-)) from rat heart mitochondria (RHM), while O(2)(*-) generated in intact RHM do not escape from mitochondria. This was shown by a set of O(2)(*-)-sensitive spin probes with varying hydrophobicity. The levels of O(2)(*-) detected in intact RHM gradually increase as the hydrophobicity of spin probes increases and were not sensitive to superoxide dismutase (SOD) added to the incubation medium. Both Antimycin A and endotoxic shock elevated O(2)(*-) levels. Elevated O(2)(*-) levels became sensitive to SOD but in a different manner. The determination of O(2)(*-) with water-soluble PPH was fully sensitive to SOD, while the determination of O(2)(*-) with the more hydrophobic CMH and CPH was only partially sensitive to SOD, suggesting the release of a portion of O(2)(*-) into the surrounding medium.     

Cellular toxicity of elsinochrome phytotoxins produced by the pathogenic fungus, Elsino? fawcettii causing citrus scab.

Elsinochromes are the red/orange pigments produced by many Elsino? fungal species and are structurally similar to the phytotoxin, cercosporin. Here, pigments were extracted from cultures of a citrus pathogen, Elsino? fawcettii and tested for cellular toxicity. On irradiation with light, elsinochromes rapidly killed suspension cultured citrus and tobacco cells. The toxicity was decreased by adding the singlet oxygen ((1)O(2)) quenchers (bixin (carotenoid carboxylic acid), DABCO (1, 4-diazabicyco octane), ascorbate or reduced glutathione). Application of elsinochromes onto rough lemon leaves resulted in necrotic lesions, whereas lesion development was inhibited by the addition of bixin, DABCO or ascorbate, but not a-tocopherol. Incubation of rough lemon leaf discs with elsinochromes in the light induced a steady increase of electrolyte leakage. Compared with two photosensitizing compounds, hematoporphyrin and cercosporin, the accumulation of (1)O(2) induced by elsinochromes after irradiation was indicated by successful detection of the cholesterol oxidation product, 5a-hydroperoxide. Addition of a potent quencher, beta-carotene prevented 5alpha-hydroperoxide production. Elsinochromes generated superoxide ions (O(2)(*-)), whereas accumulation of O(2)(*-)was blocked by addition of the superoxide dismutase, a scavenger of O(2)(*-), but not the (1)O(2)-quencher, DABCO. Our study indicated that elsinochromes are functioning as photosensitizing compounds that produce (1)O(2)and O(2)(*-), and exert toxicity to plant cells.     

Steroid structure and function. Molecular conformation of 4-hydroxyestradiol and its relation to other catechol estrogens

Hydroxylation of estrogens at C(2) or C(4) effects differentially their binding affinity to and dissociation rate from the estrogen receptor. The X-ray crystal structure of 4-hydroxyestradiol (4-OH-E2) is reported here and compared with that of 2-hydroxyestradiol (2-OH-E2), the 2- and 4-hydroxylated derivatives of estrone (E1) and with that of the parent estrogens, E1 and E2. The overall molecular shape and hydrogen bonding patterns of each were examined for their possible relevance to their binding to the estrogen receptor and their biological activity. A shift in the B-ring conformation away from the symmetrical 7 alpha,8 beta-half-chair form toward the 8 beta-sofa form is induced by both 2- and 4-hydroxy substitution. This shift appears to be larger in the case of E2 than E1 derivatives and to be correlated with an observed change in the hydrogen bonding potential of the C(3) hydroxyl. In 4-OH-E2, as in E2 and 4-OH-E1, the C(3) hydroxyl functions both as a hydrogen bond donor and acceptor. In contrast in 2-OH-E2 the hydroxyl functions only as a donor. The markedly reduced affinity of 2-hydroxylated estrogens for the estrogen receptor could be due to a combination of steric interactions, competition between O(2) and O(3) for hydrogen bonds for a common site on the receptor, and to general interference with hydrogen bond formation of O(3). The C(4) hydroxyl participates in the formation of a chain of hydrogen bonds in the solid state that is similar to a chain seen in single crystals of E2. The presence of a similar chain of hydrogen bonds involving O(3) in the receptor site could account for the decreased dissociation rate of the 4-OH-E2 receptor complex.     

Metabolism of [3H]2-hydroxyestradiol by cultured porcine granulosa cells: evidence for the presence of a catechol-O-methyltransferase pathway and a direct stimulatory effect of 2-methoxyestradiol on progesterone production

Porcine granulosa cells synthesize and respond to catecholestrogens, but the stimulatory potency of catecholestrogens on progesterone production is much less than that of estradiol (E2). Therefore, to determine if metabolism of catecholestrogens by granulosa cells could account for the reduced potency of 2-hydroxyestradiol (2-OH-E2) observed in vitro, porcine granulosa cells were cultured with [3H]2-OH-E2 and medium collected at 0, 0.5, 1, 2, 4, 6, or 12 h in the presence or absence of 1 microgram/ml 2-OH-E2, 0.5 mM L-ascorbate or 10 microM U-0521 (a specific catechol-O-methyltransferase inhibitor). Metabolism of [3H]2-OH-E2 was very rapid with only 16% of the original [3H]2-OH-E2 remaining after 4 h exposure to cells. The main metabolite comigrated with 2-methoxyestradiol (2-MeO-E2) on thin-layer chromatography. Although appreciable degradation of [3H]2-OH-E2 occurred with time in the absence of cells, formation of the O-methyl derivative was minimal. Rather, formation of polar metabolites occurred in the absence of cells. Ascorbate dramatically reduced this noncellular degradation. Ascorbate added to cell cultures had no effect on the rate of formation of O-methyl products but slowed the formation of polar compounds as well as the overall rate of degradation of [3H]2-OH-E2 by nearly 2-fold. U-0521 completely blocked the formation of O-methyl products, slowed the overall rate of degradation of [3H]2-OH-E2 by half and resulted in an increase in polar metabolites. The effects of U-0521 and ascorbate on 2-OH-E2-stimulated progesterone production in vitro was also examined. Ascorbate (0.5 mM) enhanced the effect of 2-OH-E2 (but not E2) on progesterone production by 2-fold (p less than 0.05). The addition of 10 microM U-0521 in the presence of 0.5 mM ascorbate had no effect on 1 microgram/ml 2-OH-E2-stimulated progesterone production, but it increased (p less than 0.05) the response to 4 micrograms/ml 2-OH-E2. The effects of 2-MeO-E2, 2-OH-E2, and E2 on progesterone production by cultured granulosa cells were then compared. The ED50 of E2 was 6- to 8-fold lower than that of 2-OH-E2 and 2-MeO-E2, whereas the ED50 of 2-OH-E2 was 15% lower than that of 2-MeO-E2. In the presence of ascorbate (0.5 mM), the maximal effect of E2 and 2-OH-E2 was approximately equal, whereas 2-OH-E2 was nearly 2-fold more efficacious than 2-MeO-E2.(ABSTRACT TRUNCATED AT 400 WORDS)