Interaction of ubisemiquinone with succinate dehydrogenase and the cytochrome chain of mitochondria

The free radical EPR signals of ubisemiquinone in mitochondria and submitochondrial particles (SMP) were investigated. One of the signals observed under the conditions of the respiratory chain highly oxidized and characterized by an unusually short time of the spin-lattice relaxation has previously been termed as SQ-2. The intensity of SQ-2 in SMP strongly depends on pH, the maximal concentration of QH. is reached at about 8.5. The signal is absent in the succinate dehydrogenase-depleted SMP and is highly sensitive to specific inhibitors of succinate: CoQ-oxidoreductase, such as alpha-thenoyltrifluoroacetone and carboxin. In SMP SQ-2 disappears in the presence of low concentrations of ferricyanide, while in mitochondria this non-penetrating oxidant provokes the appearance of SQ-2. The data obtained suggest that SQ-2 belongs to a stable ubisemiquinone which forms a complex with a FeS center of succinate dehydrogenase, is localized at the M-side of the membrane, and is kinetically isolated from the cytochrome chain. Oxidation of the terminal segment of the respiratory chain of mitochondria and SMP reduced by succinate in the presence of antimycin, is in some cases accompanied by an appearance of a strong free radical EPR signal which is stable at 77K but disappears rapidly in the frozen samples at -30- -40 degrees C. It is suggested that the signal is generated by an antimycin-insensitive oxidation of QH2 to QH. via the branch of the respiratory chain comprised of the Rieske FeS-protein and cytochrome c1. The mechanisms of how the two-electron oxidation-reduction of CoQ is coupled with the one-electron transfer through the cytochromes and FeS centers in the respiratory chain are discussed.     

Effects of L-arginine and NG-nitro L-arginine methyl ester (L-NAME) on ischemia/reperfusion injury of skeletal muscle, small and large intestines

This study analyzed the effects of L-arginine and non-specific nitric oxide (NO) synthase blocker (L-NAME) on structural and metabolic changes in experimental ischemia/reperfusion injury in the rat. Histopathological evaluation of rat tissues after reperfusion was also performed. The animals were divided into four groups: [1] nonischemic control, [2] ischemia 4 hrs/repefusion 30, 60, 120 min, [3] ischemia/reperfusion after L-arginine administration, [4] ischemia/reperfusion, after L-arginine, and L-NAME. L-arginine (500 mg/kg) and L-NAME (75 micromol/rat/day) were administrated orally for 5 days before experiment. Concentrations of free radicals, CD-62P, CD-54 and malonyl dialdehyde (MDA) in tissues, and MDA and NO levels in sera were determined. Free radical levels significantly increased in reperfused skeletal muscle, small and large intestines. In large bowel, reperfusion increased MDA levels and evoked a rise of endotoxin level while NO levels decreased. Histological studies showed an increase in the number of lymphocytes in both intestines. Administration of L-arginine reduced leukocyte adherence associated with ischemia-repefusion injury, decreased the levels of free radicals and MDA in the examined tissues, and inhibited the release of endotoxins into blood. L-arginine-treated animals showed higher serum NO levels and reduced leukocyte bowel infiltration. Concomitant L-NAME administration reduced serum NO and tissue free radical [corrected] levels, but did not affect intestinal leukocyte infiltration. L-arginine could ameliorate intestinal ischemia/reperfusion injury and constitute a possible protective mechanism by decreasing neutrophil-endothelial interactions, stimulating free radical scavenging and reducing lipid peroxidation.     

Free radical centers in the dog myocardial tissue in regional ischemia

The effect of regional ischemia on canine myocardial in situ free radical species was studied by the EPR method. Rapid fixation of heart muscle samples by freezeclamping was performed at the following physiological states: native myocardial blood circulation, regional ischemia with the presence of collateral circulation, total ischemia, and postischemic reperfusion. EPR spectra of the samples at -40 degrees C exhibited two free radical signals from the semireduced forms of ubiquinone and flavine coenzymes. Upon transition from normal blood supply to regional ischemia, an increase in the contribution of the flavine signal was registered, but reperfusion resulted in the recovery of the characteristics of EPR signals. It was found that the increase in the intensity of collateral circulation in the ischemic area led to an increase in the portion of ubisemiquinone in the integral EPR signal, whereas in total ischemia this signal was not registered. It was shown that the changes in spectral characteristics of integral free radical signals are accompanied by changes in their relaxation parameters.     

Protective effects of antioxidative serotonin derivatives isolated from safflower against postischemic myocardial dysfunction

N-(p-Coumaroyl)serotonin (C) and N-feruroylserotonin (F) with antioxidative activity are present in safflower oil. The protective effects of C and F were investigated in perfused guinea-pig Langendorff hearts subjected to ischemia and reperfusion. Changes in cellular levels of high phosphorous energy, NO and Ca²⁺ in the heart together with simultaneous recordings of left ventricular developed pressure (LVDP) were monitored by an nitric oxide (NO) electrode, fluorometry and ³¹P-NMR. The rate of recovery of LVDP from ischemia by reperfusion was 30.8% in the control, while in the presence of C or F a gradual increase to 63.2 or 61.0% was observed. Changes of transient NO signals (T_NO) released from heart tissue in one contraction (LVDP) were observed to be upside-down with respect to transient fura-2-Ca²⁺ signals (T_Ca) and transient O₂ signals detected with a pO₂ electrode. At the final stage of ischemia, the intracellular concentration of Ca²⁺ ([Ca²⁺]_i) and the release of NO increased with no twitching and remained at a high steady level. The addition of C increased the NO level at the end of ischemia compared with the control, but [Ca²⁺]_i during ischemia decreased. On reperfusion, the increased diastolic level of T_Ca and T_NO returned rapidly to the control level with the recovery of LVDP. By in vitro EPR, C and F were found to directly quench the activity of active radicals. Therefore, it is concluded that the antioxidant effects of two derivatives isolated from safflower play an important role in ischemia-reperfusion hearts in close relation with NO.     

Effect of ACE inhibitor captopril and L-arginine on the metabolism and on ischemia-reperfusion injury of the isolated rat heart

We investigated the effects of in vivo treatment with the angiotensin-converting enzyme inhibitor (ACE-I) captopril and/or of in vitro administration of L-arginine on the metabolism and ischemia-reperfusion injury of the isolated perfused rat myocardium. Captopril (50 mg/l in drinking water, 4 weeks) raised the myocardial content of glycogen. After 25-min global ischemia, captopril treatment, compared with the controls, resulted in lower rates of lactate dehydrogenase release during reperfusion (8.58 +/- 1.12 vs. 13.39 +/- 1.88 U/heart/30 min, p<0.05), lower myocardial lactate contents (11.34 +/- 0.93 vs. 21.22 +/- 4.28 micromol/g d.w., p<0.05) and higher coronary flow recovery (by 25%), and prevented the decrease of NO release into the perfusate during reperfusion. In control hearts L-arginine added to the perfusate (1 mmol/l) 10 min before ischemia had no effect on the parameters evaluated under our experimental conditions, presumably because of sufficient saturation of the myocardium with L-arginine. In the hearts of captopril-treated rats, L-arginine further increased NO production during reperfusion and the cGMP content before ischemia. Our results have shown that long-term captopril treatment increases the energy potential and has a beneficial effect on tolerance of the isolated heart to ischemia. L-arginine added into the perfusate potentiates the effect of captopril on the NO signaling pathway.     

The effects of ionizing radiation on DNA: the role of thiols as radioprotectors

Electron loss from N-(2-mercaptopropionyl) glycine (PSH) gave an EPR detectable radical anion, PS-.SP(-). When the PSH derivative was frozen in aqueous DNA solutions to 77 K and exposed to ionizing radiation, normal damage to the DNA was detected by EPR spectroscopy. However, on annealing above 77 K, central EPR features for the DNA base radical cations and anions gave central features assigned to PS-.SP(-) sigma*-radical anions, together with outer features for 5-6-dihydro-5-thymyl radicals, TH.. It is proposed that on freezing, the PSH molecules are constrained into a glassy region around the DNA, and that, on annealing, electron donation gives PS. radicals, with loss of quanine radical-cations, G(.+). The PS. radicals were not detectable, but on reaction with another PSH molecule, gave good EPR spectra for PS-.SP(-) radical-anions. These results indicate that PSH had little effect on the yield of the other base radicals C(.-)/T(.-). Also, growth of TH. radicals, formed from protonated thymine radical-anions, T(.-), were detected. We conclude that the primary effect of PSH is to capture the G(.+) centers, and thus could either prevent or repair radiation damage to DNA.     

Synergic effects of NO and oxygen free radicals in the injury of ischemia-reperfused myocardium——ESR studies on NO free radicals generated from ischemia-reperfused myocardium

The ESR signal of NO bound to hemoglobin was detected during the ischemia-reperfusion of myocardium with low temperature ESR technique, and the synergic effects of NO and oxygen free radicals in the injury of the process were studied with this technique. Oxygen free radicals and NO bound to β-subunit of hemoglobin (β-NO complex) could be detected simultaneously in the ischemia-reperfused myocardium. Those signals could not be detected from the normal myocardium even in the presence of L-arginme. However, those signals could be detected and were dose-dependent with L-arginine in the ischemia-reperfused myocardiums and the signal could be suppressed with the inhibitor of NO synthetase, NG-nitro-L-arginine methylester (NAME). Measurement of the activities of lactate dehydrogenase (LDH) and creatine kinase (CK) in the coronary artery effluent of ischemia-reperfused heart showed that L-arginine at lower concentration (<1 mmol/L) could protect the heart from the ischemia-reperfusion injury but at higher con     

Generation of superoxide radicals by heart mitochondria: study by spin trapping under continuous oxygenation

The generation of superoxide radicals by isolated rat heart mitochondria was studied by the spin trapping technique. The sample was placed into the cavity of an EPR spectrometer in a thin-wall teflon capillary tube, which made it possible to maintain the partial oxygen pressure in the mitochondrial suspension at a constant level. Tiron was used as a spin trap, and the intensity of its EPR signal corresponded to the rate of O2-. formation in the sample. The addition of oxidation substrates (succinate, glutamate, and malate) into the incubation mixture caused the appearance of the Tiron EPR signal. The rate of superoxide radical generation by heart mitochondria strongly increased in the presence of antimycin A, an inhibitor of the Q-cycle in complex III of the respiratory chain, but it was completely depressed by another inhibitor of Q-cycle myxothiazol. The inhibition of the reverse electron transport in complex I of the respiratory chain by rotenone (oxidation substrate--succinate) caused a substantial decrease in the rate of O2-. formation by mitochondria.     

Involvement of inducible nitric oxide synthase in hydroxyl radical-mediated lipid peroxidation in streptozotocin-induced diabetes

Free radical production is implicated in the pathogenesis of diabetes mellitus, where several pathways and different mechanisms were suggested in the pathophysiology of the complications. In this study, we used electron paramagnetic resonance (EPR) spectroscopy combined with in vivo spin-trapping techniques to investigate the sources and mechanisms of free radical formation in streptozotocin-induced diabetic rats. Free radical production was directly detected in the diabetic bile, which correlated with lipid peroxidation in the liver and kidney. EPR spectra showed the trapping of a lipid-derived radical. Such radicals were demonstrated to be induced by hydroxyl radical through isotope-labeling experiments. Multiple enzymes and metabolic pathways were examined as the potential source of the hydroxyl radicals using specific inhibitors. No xanthine oxidase, cytochrome P450s, the Fenton reaction, or macrophage activation were required for the production of radical adducts. Interestingly, inducible nitric oxide synthase (iNOS) (apparently uncoupled) was identified as the major source of radical generation. The specific iNOS inhibitor 1400W as well as L-arginine pretreatment reduced the EPR signals to baseline levels, implicating peroxynitrite as the source of hydroxyl radical production. Applying immunological techniques, we localized iNOS overexpression in the liver and kidney of diabetic animals, which was closely correlated with the lipid radical generation and 4-hydroxynonenal-adducted protein formation, indicating lipid peroxidation. In addition, protein tyrosine nitration occurred in the diabetic target organs. Taken together, our studies support inducible nitric oxide synthase as a significant source of EPR-detectable reactive intermediates, which leads to lipid peroxidation and may contribute to disease progression as well.     

Measurement of superoxide-derived free radicals in the reperfused heart. Evidence for a free radical mechanism of reperfusion injury

There has been considerable controversy regarding the role of oxygen free radicals as important mediators of cell damage in reperfused myocardium. This controversy regards whether superoxide and hydroxyl free radicals are generated on reperfusion and if these radicals actually cause impaired contractile function. In this study, EPR studies using the spin trap 5,5-dimethyl-1-pyroline-n-oxide (DMPO) demonstrate the formation of .OH and R. free radicals in the reperfused heart. EPR signals of DMPO-OH, aN = aH = 14.9 G, and DMPO-R aN = 15.8 G aH = 22.8 G are observed, with peak concentrations during the first minute of reperfusion. It is demonstrated that these radicals are derived from .O2- since reperfusion in the presence of enzymatically active recombinant human superoxide dismutase markedly reduced the formation of these signals while inactive recombinant human superoxide dismutase had no effect. On reperfusion with perfusate pretreated to remove adventitial iron, the concentration of the DMPO-OH signal was increased 2-fold and a 4-fold decrease in the DMPO-R signal was observed demonstrating that iron-mediated Fenton chemistry occurs. Hearts reperfused with recombinant human superoxide dismutase exhibited improved contractile function in parallel with the marked reduction in measured free radicals. In order to determine if the reperfusion free radical burst results in impaired contractile function, simultaneous measurements of free radical generation and contractile function were performed. A direct relationship between free radical generation and subsequent impaired contractile function was observed. These studies suggest that superoxide derived .OH and R. free radicals are generated in the reperfused heart via Fenton chemistry. These radicals appear to be key mediators of myocardial reperfusion injury.     

Role of xanthine oxidase inhibitor as free radical scavenger: a novel mechanism of action of allopurinol and oxypurinol in myocardial salvage

Xanthine oxidase (XO) has been hypothesized to be a potential source of oxygen-derived free radicals during reperfusion of ischemic myocardium based on the fact that allopurinol, a XO-inhibitor, can reduce reperfusion injury. In this communication we report that both allopurinol and oxypurinol, the principle metabolite of allopurinol, prevent the reperfusion injury in isolated pig heart. However, we found that neither pig heart nor pig blood contain any XO activity. Our study showed a direct free radical scavenging action of these XO-inhibitors during ischemia and reperfusion, as judged by the reduction of free radical signals when compared using an Electron Paramagnetic Resonance Spectrometer. Using a Luminometer, we also confirmed that both allopurinol and oxypurinol can scavenge ClO2, HOCl, and significantly inhibit free radical signals generated by activated neutrophils. These XO-inhibitors, however, failed to scavenge O2. and OH. radicals. Our results suggest that these XO-inhibitors salvaged the ischemic-reperfused myocardium by scavenging free radicals, and not by inhibiting XO in the pig heart.     

Effects of nitric oxide donor and inhibitor on prostaglandin E2-like activity, malondialdehyde and reduced glutathione levels after skeletal muscle ischemia-reperfusion.

Oxygen free radicals are implicated in the pathophysiology of ischemia-reperfusion (I/R) injury in skeletal muscle. Nitric oxide (NO) and prostaglandin E2 (PGE2) are important regulators of the microcirculation in skeletal muscle. The effects of L-arginine, substrate for NO, and N(G)-nitro L-arginine methyl ester (L-NAME) on PGE2 synthesis, lipid peroxidation and reduced glutathione (GSH) levels was investigated in the rat gastrocnemius muscle after 3 h of reperfusion following 2 h of ischemia. Lipid peroxidation and GSH levels showed a non-significant changes in the I/R groups compared to the control group. According to these results, it can be assumed that skeletal muscle can resist 2 h of ischemia followed by 3 h of reperfusion-induced oxidative stress. PGE2-like activity in the gastrocnemius muscle increased in the L-NAME treated and I/R groups. L-arginine administration reversed the increase in PGE2-like activity of reperfused skeletal muscle. These findings support the conclusion that endothelium-derived PGE2 synthesis increases during reperfusion and suggest that PGE2 may have a protective role in the maintenance of endothelial function.     

Generation of free oxygen radicals in heart mitochondria: Effect of hypoxia-reoxygenation

The relationship between the rate of generation of superoxide radicals and the duration of hypoxia has been studied in isolated heart mitochondria with the use of the spin trap sodium 4,5dihydroxybenzene-1,3-disulfonate. The EPR spectra were recorded from a mitochondrial suspension placed in a gas-permeable capillary under conditions of regulated partial oxygen pressure. Earlier we have shown that the mitochondria isolated from perfused hearts after 30-min ischemia display a higher rate of superoxide generation than those from controls. However, in isolated mitochondria the EPR signal from 4,5-dihydroxybenzene-1,3-disulfonate increased already after 10-min hypoxia, but its intensity remained the same in the mitochondria subjected to 30-, 45-, and 60-min hypoxia. Thus, the isolated mitochondria in the incubation medium are less sensitive to hypoxia than the mitochondria from cardiomyocytes of an ischemic heart.     

A novel protocol to identify and quantify all spin trapped free radicals from in vitro/in vivo interaction of HO(.-) and DMSO: LC/ESR, LC/MS, and dual spin trapping combinations

When dimethyl sulfoxide (DMSO) is oxidized via hydroxyl radical (HO(.-)), it forms methyl radicals ((.-)CH(3)) that can be spin trapped and detected by electron spin resonance (ESR). This ESR spin trapping technique has been widely used in many biological systems to indicate in vivo HO(.-) formation. However, we recently reported that (.-)CH(3) might not be the only carbon-centered radical that was trapped and detected by ESR from in vivo DMSO oxidation. In the present study, newly developed combination techniques consisting of dual spin trapping (free radicals trapped by both regular and deuterated alpha-[4-pyridyl 1]-N-tert-butyl nitrone, d(0)/d(9)-POBN) followed by LC/ESR and LC/MS were used to characterize and quantify all POBN-trapped free radicals from the interaction of HO(.-) and DMSO. In addition to identifying the two well-known free radicals, (.-)CH(3) and (.-)OCH(3), from this interaction, we also characterized two additional free radicals, (.-)CH(2)OH and (.-)CH(2)S(O)CH(3). Unlike ESR, which can measure POBN adducts only in their radical forms, LC/MS identified and quantified all three redox forms, including the ESR-active radical adduct and two ESR-silent forms, the nitrone adduct (oxidized adduct) and the hydroxylamine (reduced adduct). In the bile of rats treated with DMSO and POBN, the ESR-active form of POBN/(.-)CH(3) was not detected. However, with the addition of the LC/MS technique, we found approximately 0.75 microM POBN/(.-)CH(3) hydroxylamine, which represents a great improvement in radical detection sensitivity and reliability. This novel protocol provides a comprehensive way to characterize and quantify in vitro and in vivo free radical formation and will have many applications in biological research.     

Transformations of dinitrosyl iron complexes in an isolated rat heart after introduction of this substance into perfusion medium

The objective of the present research was to study transformations of various physiological NO forms in an isolated rat heart, perfused with the medium containing dinitrosyl iron complexes with glutathione ligand (DNIC-GH). We showed that such aerobic perfusion resulted in accumulation of mostly diamagnetic NO physiological forms (S-nitrosothiols) in myocardial tissue. They were transformed into protein-bound mononuclear dinitrosyl iron complexes during subsequent total ischemia. Meantime, DNIC-GH injection on the onset of ischemia resulted in changes in the state of mitochondrial respiratory chain, characterized by the increase in myocardial concentration of flavosemiquinones.     

Measurement and characterization of postischemic free radical generation in the isolated perfused heart

Electron paramagnetic resonance spectroscopy has been applied to measure radical generation in the postischemic heart; however, there is controversy regarding the methods used and the conclusion as to whether radicals are generated. In order to resolve this controversy, direct and spin trapping measurements of the time course and mechanisms of radical generation were performed in isolated perfused rabbit hearts. In reperfused tissue, 3 prominent radical signals are observed: A, isotropic g = 2.004 suggestive of a semiquinone; B, anisotropic g parallel = 2.033 and g perpendicular = 2.005 suggestive of ROO.; and C, a triplet g = 2.000 and aN = 24 G suggestive of a nitrogen centered radical. B and C, however, are highly labile and disappear at temperatures probably encountered in some previous studies. In normally perfused hearts, A is observed with only small amounts of B and C. During ischemia, B and C increase reaching a maximum after 45 min while A decreases. On reflow with oxygenated perfusate all 3 signals increase. With varying duration of ischemia and reflow, peak signal intensities occurred after 15 s of reflow following 30 min of ischemia. Reperfusion with superoxide dismutase, deferoxamine, or mannitol abolished the reperfusion increase of B. Measurements performed with the spin trap 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO) demonstrated a similar time course of radical generation with prominent DMPO-OH and DMPO-R signals peaking between 10 and 20 s of reflow. Superoxide dismutase and deferoxamine also quenched these signals. Thus, .O2- derived .OH, R., and ROO. radicals are generated in postischemic myocardium. While the experimental techniques used can result in loss of intrinsic radicals and generation of extraneous radicals, with proper care and controls valid measurements of free radicals in biological tissues can be performed.     

Nitric oxide — a retrograde messenger for carbon monoxide signaling in ischemic heart

To examine the intracellular signaling mechanism of NO in ischemic myocardium, isolated working rat hearts were made ischemic for 30 min followed by 30 min of reperfusion. A separate group of hearts were pre-perfused with 3 mM L-arginine in the presence or absence of 650 M of protoporphyrin, a heme oxygenase inhibitor for 10 min prior to ischemia. The release of NO was monitored using an on-line amperometric sensor placed into the right atrium. The aortic flow and developed pressure were examined to determine the effects of L-arginine on ischemic/reperfusion injury. Induction for the expression of heme oxygenase was studied by Northern hybridization. For signal transduction experiments, sarcolemmal membranes were radiolabeled by perfusing the isolated hearts with [³H] myoinositol and [¹⁴C] arachidonic acid. Biopsies were processed to determine the isotopic incorporation into various phosphoinositols as well as phosphatidic acid and diacylglycerol. cGMP was assayed by radioimmunoassay and SOD content was determined by enzymatic analysis. The release of NO was diminished following ischemia and reperfusion and was augmented by L-arginine. L-arginine reduced ischemic/reperfusion injury as evidenced by the enhanced myocardial functional recovery. Protoporphyrin modulated the effects of L-arginine. cGMP, which was remained unaffected by ischemia and reperfusion, was stimulated significantly after L-arginine treatment. The NO-mediated augmentation of cGMP was reduced by protoporphyrin suggesting that part of the effects may be mediated by CO generated through the heme oxygenase pathway. Reperfusion of ischemic myocardium resulted in significant accumulation of radiolabeled inositol phosphate, inositol bisphosphate, and inositol triphosphate. Isotopic incorporation of [³H] inositol into phosphatidylinositol, phosphatidylinositol-4-phosphate, and phosphatidylinositol-4,5-bisphosphate was increased significantly during reperfusion. Reperfusion of the ischemic heart prelabeled with [¹⁴C] arachidonic acid resulted in modest increases in [¹⁴C] diacylglycerol and [¹⁴C] phosphatidic acid. Pretreatment of the heart with L-arginine significantly reversed this enhanced phosphodiesteratic breakdown during ischemia and early reperfusion. However, at the end of the reperfision the inhibitory effect of L-arginine on the phosphodiesterases seems to be reduced. In L-arginine treated hearts, SOD activity was progressively decreased with the duration of reperfusion time. The results suggests for the first time that NO plays a significant role in transmembrane signaling in the ischemic myocardium. This signaling appears to be on- and off- nature, and linked with SOD content of the tissue. The signaling is transmitted via cGMP and opposes the effects of phosphodiesterases by inhibiting the ischemia/reperfusion-induced phosphodiesteratic breakdown. Our results also suggest that NO activates heme oxygenase which further stimulates the production of cGMP presumably by CO signaling. Thus, NO not only potentiates cGMP mediated intracellular signaling, it also functions as a retrograde messenger for CO signaling in heart.     

Increased L-arginine uptake and inducible nitric oxide synthase activity in aortas of rats with heart failure

L-Arginine crosses the cell membrane primarily through the system y(+) transporter. The aim of this study was to investigate the role of L-arginine transport in nitric oxide (NO) production in aortas of rats with heart failure induced by myocardial infarction. Tumor necrosis factor-alpha levels in aortas of rats with heart failure were six times higher than in sham rats (P < 0.01). L-Arginine uptake was increased in aortas of rats with heart failure compared with sham rats (P < 0.01). Cationic amino acid transporter-2B and inducible (i) nitric oxide synthase (NOS) expression were increased in aortas of rats with heart failure compared with sham rats (P < 0.05). Aortic strips from rats with heart failure treated with L-arginine but not D-arginine increased NO production (P < 0.05). The effect of L-arginine on NO production was blocked by L-lysine, a basic amino acid that shares the same system y(+) transporter with L-arginine, and by the NOS inhibitor N(G)-nitro-L-arginine methyl ester (L-NAME). Treatment with L-lysine and L-NAME in vivo decreased plasma nitrate and nitrite levels in rats with heart failure (P < 0.05). Our data demonstrate that NO production is dependent on iNOS activity and L-arginine uptake and suggest that L-arginine transport plays an important role in enhanced NO production in heart failure.     

Effects of tocopheryl quinone on the heart: model experiments with xanthine oxidase, heart mitochondria, and isolated perfused rat hearts

It is generally accepted that the protection effect of biological tissues by vitamin E is due to its radical scavenging potency in membranes, thereby being transformed to a vitamin E radical. A deficiency of appropriate reductants, which recycle vitamin E radicals back to its antioxidative active form, causes an irreversible degradation of vitamin E leading to tocopheryl quinone (TQ). TQ-like compounds were shown to result from both vitamin E and corresponding hydrophilic analogues of this antioxidant in vitro. In vivo elevated concentrations of tocopheryl quinones were detected after oxidative stress and TQ supplementation as well. Quinones in general are known to be efficient one-electron donors and acceptors. Therefore the question arises whether TQ-like compounds can undergo redox-cycling in conjunction with redox-active enzymes in the heart, thereby producing harmful oxygen radicals, or whether these compounds exhibit antioxidant properties. In order to elucidate this question we focused our interest on the interaction of TQ and a corresponding short-chain homologue (TQ(0)) with xanthine oxidase and heart mitochondria. Furthermore, we tested the influence of TQ on the recovery of isolated perfused rat hearts after ischemia/reperfusion. Our experiments revealed that hydrophilic TQ(0) was univalently reduced by xanthine oxidase (XOD) yielding semiquinone radicals in the absence of oxygen. However, under aerobic conditions TQ(0) enhanced the O(2)(*)(-) radical output of XOD. In the mitochondrial respiratory chain TQ was shown to interact with high potential cytochrome b in the bc(1) complex specifically. In contrast to the system XOD/TQ(0), lipophilic TQ in submitochondrial particles decreased the O(2)(*)(-) radical release during regular respiration possibly due to its interaction with b-cytochromes in the mitochondrial respiratory chain. In isolated rat hearts perfused with liposomes containing lipophilic TQ, it was efficiently accumulated in the heart tissue. When hearts were subjected to conditions of ischemia/reperfusion, infusion of TQ prior to ischemia significantly improved the recovery of hemodynamic parameters. Our results demonstrate that TQ derivatives may induce pro-oxidative and antioxidative effects depending on the distribution of TQ derivatives in the heart tissue and the interacting redox system.     

Nitric oxide and reactive nitrogen species in airway epithelial signaling and inflammation

Nitric oxide (NO(.-)) is produced by many diverse cell types as a cellular or intracellular signaling molecule, by the activation of nitric oxide synthases (NOSs). All three known NOS isoforms are expressed within the respiratory tract and mediate various airway functional properties such as airway smooth muscle tone, ciliary function, epithelial electrolyte transport, and innate host defense. The respiratory epithelium is a major source of NO(.-), in which it regulates normal epithelial cell function and signaling as well as signaling pathways involved in airway inflammation. In addition to its normal physiological properties, increased airway NO(.-) production in inflammatory respiratory tract diseases such as asthma may activate additional signaling mechanisms to regulate inflammatory-immune pathways, and epithelial barrier (dys)function or repair. The biological actions of NO(.-) are controlled at various levels, including mechanisms that regulate NOS localization and activation, and variable oxidative metabolism of NO(.-), resulting in generation of bioactive reactive nitrogen species (RNS). Moreover, in addition to altered production of NO(.-) or RNS, the presence of various target enzymes and/or metabolic regulators of NO(.-)/RNS can be dramatically altered during airway inflammatory conditions, and contribute to alterations in NO(.-)-mediated signaling pathways in disease. This review summarizes current knowledge regarding NO(.-)-mediated epithelial signaling, as well as disease-related changes in airway NOS biology and target enzymes that affect NO(.-)/RNS signaling mechanisms. A detailed understanding of these various changes and their impact on NO(.-) signaling pathways are needed to fully appreciate the contributions of NO(.-)/RNS to airway inflammation and to develop suitable therapeutic approaches based on regulating NO(.-) function.