Reactions of reducing xenobiotics with oxymyoglobin. Formation of metmyoglobin, ferryl myoglobin and free radicals: an electron spin resonance and chemiluminescence study

Nitric oxide production from hydroxyurea

Hydroxyurea is a relatively new treatment for sickle cell disease. A portion of hydroxyurea's beneficial effects may be mediated by nitric oxide, which has also drawn considerable interest as a sickle cell disease treatment. Patients taking hydroxyurea show a significant increase in iron nitrosyl hemoglobin and plasma nitrite and nitrate within 2 h of ingestion, providing evidence for the in vivo conversion of hydroxyurea to nitric oxide. Hydroxyurea reacts with hemoglobin to produce iron nitrosyl hemoglobin, nitrite, and nitrate, but these reactions do not occur fast enough to account for the observed increases in these species in patients taking hydroxyurea. This report reviews recent in vitro studies directed at better understanding the in vivo nitric oxide release from hydroxyurea in patients. Specifically, this report covers: (1) peroxidase-mediated formation of nitric oxide from hydroxyurea; (2) nitric oxide production after hydrolysis of hydroxyurea to hydroxylamine; and (3) the nitric oxide-producing structure-activity relationships of hydroxyurea. Results from these studies should provide a better understanding of the nitric oxide donor properties of hydroxyurea and guide the development of new hydroxyurea-derived nitric oxide donors as potential sickle cell disease therapies.

Immobilized Enzyme Electron Spin Resonance: A Method for Detecting Enzymatically Generated Transient Radicals

The study of enzymatically generated, transient radicals provides valuable information about radical reactivity as well as enzyme function. ESR methods to detect transient radicals are generally based on continuous flow and have the potential to consume large quantities of enzyme, substrate, and buffer. Experimental approaches have been pursued to minimize sample volumes, although none have made the continuous-flow ESR approach generally applicable for enzymes and substrates available in limited quantities. We have developed an alternative approach to the traditional continuous-flow ESR method that provides the same high-resolution ESR spectra, but does not consume large quantities of enzyme, substrate, or buffer. The method utilizes enzyme immobilized onto an inert substrate packed directly into an ESR flat cell. Flowing substrate solution over the immobilized enzyme generates in situ, transient radicals, which can then be observed on the submillisecond time scale. We have termed this method "immobilized enzyme ESR," abbreviated IE-ESR. In this paper, we have described the details of the IE-ESR technique and have presented data collected using the IE-ESR technique for transient radicals from limited quantity enzymes, limited quantity substrates, and D2O buffers. An extension of this technique to ESR spin trapping has also been discussed.

Urease enhances the formation of iron nitrosyl hemoglobin in the presence of hydroxyurea

Although it has been shown that hydroxyurea (HU) therapy produces measurable amounts of nitric oxide (NO) metabolites, including iron nitrosyl hemoglobin (HbNO) in patients with sickle cell disease, the in vivo mechanism for formation of these is not known. Much in vitro data and some in vivo data indicates that HU is the NO donor, but other studies suggest a role for nitric oxide synthase (NOS). In this study, we confirm that the NO-forming reactions of HU with hemoglobin (Hb) or other blood constituents is too slow to account for NO production measured in vivo. We hypothesize that, in vivo, HU is partially metabolized to hydroxylamine (HA), which quickly reacts with Hb to form methemoglobin (metHb) and HbNO. We show that addition of urease, which converts HU to HA, to a mixture of blood and HU, greatly enhances HbNO formation.

Antioxidant mechanisms of nitric oxide against iron-catalyzed oxidative stress in cells

Three distinct antioxidant pathways are considered through which iron-catalyzed oxidative stress may be regulated by nitric oxide (NO). The first two pathways involve direct redox interactions of NO with iron catalytic sites and represent a fast response that may be considered an emergency mechanism to protect cells from the consequences of acute and intensive oxidative stress. These are (i) NO-induced nitrosylation at heme and non-heme iron catalytic sites that is capable of directly reducing oxoferryl-associated radicals, (ii) formation of nitrosyl complexes with intracellular "loosely" bound redox-active iron, and (iii) an indirect regulatory pathway that may function as an adaptive mechanism that becomes operational upon long-term exposure of cells to NO. In the latter pathway, NO down-regulates expression of iron-containing proteins to prevent their catalytic prooxidant reactions.

Detection of free radicals generated from hydrogen peroxide, gallic acid and haemoprotein chemiluminescence system by electron spin resonance spectroscopy

Low-level chemiluminescence is produced in a hydrogen peroxide (H(2)O(2))/gallic acid/haemoprotein system with single broad peaks around 520 nm, regardless of the biological role of the haemoprotein. The free haem iron systems (haemin and haematin systems) gave a higher photon intensity (1.5 x 10(4) and 2.0 x 10(4) cps) than that of the H(2)O(2)/gallic acid/haematoporphyrin system. These results indicated that haem iron plays a significant role in the photon emission of haemoprotein systems. A free radical with a g value of 2. 0058 was detected through a direct electron spin resonance (ESR) method. The photon intensity of the H(2)O(2)/gallic acid/haemoprotein system decreased in the order: HRP > cytochrome c > myoglobin > haemoglobin, and this corresponded to the decrease in radical intensity. These results indicated that the formation of the free radical with a g value of 2.0058 may be the key step for chemiluminescence in the H(2)O(2)/gallic acid/haemoprotein system. A quartet line similar to DMPO-OH adducts and uncomplexed free radicals (g = 2.0058) was detected using the ESR spin-trapping method in the H(2)O(2)/gallic acid/cytochrome c system.

Free radical formation and erythrocyte membrane alterations during MetHb formation induced by the BHA metabolite, tert-butylhydroquinone

Erythrocyte membranes are altered as a consequence of oxidative stress following the incubation of intact erythrocytes with one of the major metabolites of the antioxidant butylated hydroxyanisole (BHA), tertbutylhydroquinone(tBHQ). Arather persistent semiquinone radical was observed by electron spin resonance (ESR) spectroscopy when tBHQ was incubated with either homogeneous oxyhemoglobin solutions or suspensions of intact erythrocytes. Erythrocyte ghosts prepared from fresh control erythrocytes and ghosts from erythrocytes preincubated with BHA and its metabolite, tBHQ, were subjected to polyacrylamide gel electrophoresis (SDS-PAGE). Only minor changes of the electrophoresis pattern relative to the control was observed in the BHA incubations whereas tBHQ significantly increased the amount of high molecular weight degradation products of erythrocyte membrane constituents. These changes were only observed when incubations were performed in the presence of oxygen. In control experiments where heme oxygen was replaced by carbon monoxide, no membrane degradation products appeared. These observations can be interpreted in terms of metabolic activation of the antioxidant BHAvia tBHQ to the tert-butylsemiquinone free radical and finally to the corresponding quinone, thereby leading to harmful effects on erythrocyte membrane structures. Moreover, deleterious effects on other biological membranes are also likely to occur.

The effects of xenobiotics on erythrocytes

1. Methemoglobin formation was observed when erythrocytes were incubated with xenobiotics such as hydroxylamines or phenols, other metabolites resulting from the interaction of these compounds with erythrocytes being reactive free radicals derived from the respective xenobiotic, and a ferryl-heme oxo-complex. 2. Steady-state levels of these reaction products depended on the permeability of the erythrocyte membrane for the various methemoglobin (MetHb) generators and the presence of antioxidants that downregulate the radicals formed. 3. Electron spin resonance (ESR) spectra of xenobiotic-derived free radicals could be obtained only from the readily water soluble hydroxylamines, whereas the poorly water soluble phenolic compounds did not allow the use of concentrations required for the generation of detectable amounts of ESR-sensitive metabolites in erythrocytes. 4. Previous investigations with oxyhemoglobin solutions and with the MetHb/H2O2 model systems have shown that, apart from ESR-sensitive radical species, excited reaction intermediates such as compound 1 ferryl hemoglobin can be detected as well by using chemiluminescence measurements. 5. A strong correlation was found between the intensity of the emitted light and the MetHb formation rate, indicating that the production of compound 1 ferryl hemoglobin is closely related to the MetHb formation step. 6. The sensitivity of the photon-counting method allowed measurements of excited species in intact erythrocytes not only with the readily soluble hydroxylamines, but also with the less soluble phenolic compounds. 7. In addition, parameters indicative of xenobiotic-induced oxidative alterations were found: a significant decrease in intraerythrocytic thiol levels was a result of all compounds that initiate MetHb formation, as also described for slowly reacting xenobiotics. 8. With the most reactive compound investigated, unsubstituted hydroxylamine, a significant release of iron from the oxidatively modified hemoglobin was detected, facilitated by binding of this transition metal to hydroxylamine and its final oxidation product, nitric oxide. 9. The use of the ESR spin-labeling technique revealed membrane alterations of erythrocytes exposed to the reducing MetHb generators presented in this study. 10. A direct action of BHA and BHT on the integrity of the erythrocyte membrane was observed, leading to hemolysis independent of the formation of prooxidant species. 11. The presence of strong prooxidants (radicals) was indicated both by fluidity changes in the membrane and by an oxidative decrease in cytosolic thiol levels.

Time resolved absorption study of the reaction of hydroxyurea with sickle cell hemoglobin

Hydroxyurea has been mixed with hemoglobin S and the reaction was studied using electronic absorption spectroscopy as a function of time and wavelength. The rate of conversion of oxyhemoglobin S to other species was determined and the nature of the reaction products was studied. We also report the formation of methemoglobin (and other reaction products) when deoxyhemoglobin S is combined with hydroxyurea. The probable increase in the formation of methemoglobin, and other potential reaction products such as nitric oxide-hemoglobin, in patients with sickle cell anemia who are taking hydroxyurea as a therapeutic drug is discussed in terms of the pathophysiology of the disease. It is proposed that methemoglobin and possibly nitric oxide-hemoglobin formation may partially explain beneficial effects observed in these patients before their levels of fetal hemoglobin have increased.

Nitric oxide formation from hydroxylamine by myoglobin and hydrogen peroxide

Hydroxylamine (HA), which is a natural product of mammalian cells, has been shown to possess vasodilatory properties in several model systems. In this study, HA and methyl-substituted hydroxylamines, N-methylhydroxylamine (NMHA) and N,N-dimethylhydroxylamine (NDMHA), have been tested for their ability to generate free diffusible nitric oxide (NO) in the presence of myoglobin (Mb) and hydrogen peroxide. A NO-specific conversion of 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (carboxy-PTIO) to 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl (carboxy-PTI), measured by electron spin resonance (ESR) spectroscopy, along with nitrite and nitrate production, was observed for HA but not for NMHA and NDMHA. ESR measurements at 77 K showed the formation of the ferrous nitrosyl myoglobin, Mb-NO, in the reaction mixtures containing Mb, H2O2 and HA. Our data also demonstrate that Mb-NO is an end product of the reaction pathway involving Mb, H2O2 and HA, rather than a reaction intermediate in the formation of NO. In summary, our results demonstrate a possible pathway of NO formation from HA, however, the significance of this mechanism for bioactivation of HA in vivo is unknown at the present time.

Hydroxylamine and phenol-induced formation of methemoglobin and free radical intermediates in erythrocytes

As previously shown with isolated oxyhemoglobin, methemoglobin formation can also be induced in intact erythrocytes by hydroxylamine compounds and substituted phenols such as butylated hydroxyanisole (BHA). Electron spin resonance investigations revealed that, accordingly, free radical intermediates were formed in erythrocytes from hydroxylamine, N,N-dimethylhydroxylamine, and N-hydroxyurea. Due to the low stability of the dihydronitroxyl radicals, their detection required the use of a continuous flow system and relatively high amounts of the reactants. As has already been demonstrated with the solubilized hemoglobin system, hemoglobin of intact erythrocytes also reacts with the more hydrophilic xenobiotics such as hydroxylamine. However, the reaction rate was slightly reduced, indicating the existence of an incomplete permeability barrier for these compounds. The limited solubility of phenolic compounds in the aqueous buffer of suspended erythrocytes (in combination with the strict requirement of osmolarity in order to prevent hemolysis) impeded the direct detection of the respective phenoxyl radicals previously reported in hemoglobin solutions. However, in accordance with earlier findings in homogeneous reaction systems, chemiluminescence was observed as well, indicating the existence of a further reaction intermediate, which was also obtained in pure hemoglobin solutions when mixed with the respective reactants. As has recently been demonstrated, this light emission is indicative of the existence of highly prooxidative compound I intermediates during methemoglobin formation. Prooxidant formation in erythrocytes is reflected by a significant decrease in thiol levels even with those compounds where free radical formation was not directly detectable by ESR spectroscopy. The use of the spin-labeling technique revealed membrane effects as a result of oxidative stress. Oxidative metabolism of hemoglobin with hydroxylamine caused a release of low molecular weight iron. The marked hemolysis observed in the presence of BHA results from a direct membrane effect of this compound rather than a consequence of free radical-induced oxidative stress. A correlation of the different results is discussed in terms of possible toxicological consequences.

Chemiluminescence and EPR studies on the excitation site of ferric-heme-oxo complexes of natural and model heme systems

Chemiluminescence was detected both in the reaction system of H2O2 plus heme proteins such as methemo- and metmyoglobin and ferric-protoheme complexes used as a model system. The intensity of chemiluminescence was found to be mediated by ligand binding to the sixth coordination site of the ferric-protoheme compounds, e.g. chemiluminescence was not observed with the bisimidazole ferric-protoheme complex. On the other hand the pentacoordinated histidine ferric-protoheme complex exhibited strong light emission. Comparative studies with various ligand-heme compounds elucidated that light emission was inversely correlated with the binding strength of the respective ligand at the sixth coordination site. The basic reaction mechanism causing the establishment of an excited state was studied by monitoring chemiluminescence and EPR signal formation of ligand-modified heme proteins in the presence of different electron donors. External electron donors such as Trolox C, TMPD and ascorbic acid affected a strong reduction in the development of chemiluminescence suggesting the essential involvement of an inner-molecular electron transfer process. Our results allow the conclusion that chemiluminescence is generated from the decay of an excited state of oxo-heme compounds established as a result of a one electron transfer step from a ligand group to heme iron.