Monooxygenase activity of human hemoglobin: role of quaternary structure in the preponderant activity of the beta subunits within the tetramer

Differential gene expression in Iberian green frogs (Pelophylax perezi) inhabiting a deactivated uranium mine

Iberian green frogs (Pelophylax perezi) were found inhabiting a deactivated uranium mine, especially an effluent pond, seriously contaminated with metals and radionuclides. These animals were previously assessed for oxidative stress parameters and did not revealed significant alterations. In order to better understand which mechanisms may be involved in the ability to withstand permanent contamination gene expression analysis was performed in the liver, through suppression subtractive hybridization (SSH). The SSH outcome in the liver revealed the up-regulation of genes coding for the ribosomal protein L7a and for several proteins typical from blood plasma: fibrinogen, hemoglobin and albumin. Besides their normal function, some of these proteins can play an important role as protective agents against oxidative stress. This work provides new insights on possible basal protection mechanisms that may act in organisms exposed chronically to contamination.

Neuroglobin and cytoglobin as potential enzyme or substrate

The possible enzymatic activities of neuro- and cytoglobin as well as their potential function as substrates in enzymatic reactions were studied. Neuro- and cytoglobin are found to show no appreciable superoxide dismutase, catalase, and peroxidase activities. However, the internal disulfide bond (CD7-D5) of human neuroglobin can be reduced by thioredoxin reductase. Furthermore, our in vivo and in vitro studies show that Escherichia coli cells contain an enzymatic reducing system that keeps the heme iron atom of neuroglobin in the Fe(2+) form in the presence of dioxygen despite the high autoxidation rate of the molecule. This reducing system needs a low-molecular-weight compound as co-factor. In vitro tests show that both NADH and NADPH can play this role. Furthermore, the reducing system is not specific for neuroglobin but allows the reduction of the ferric forms of other globins such as cytoglobin and myoglobin. A similar reducing system is present in eukaryotic tissue protein extracts.

Metabolism of Pyrogallol to Purpurogallin by Human Erythrocytic Hemoglobin

The aim of this study was to investigate the oxido-reductive reactions of human hemoglobin with pyrogallol and the metabolism of pyrogallol by the protein, which contains a protoporphyrin IX like cytochrome P-450. Pyrogallol, having three hydroxy groups at the adjacent positions in the benzene ring, oxidized human oxyhemoglobin to methemoglobin and reduced human methemoglobin to oxyhemoglobin. Since superoxide dismutase and catalase inhibited these reactions extensively, active oxygens such as superoxide and hydrogen peroxide were considered to be involved in the oxido-reductive reaction of human hemoglobin by pyrogallol. It was also found that the metabolism of pyrogallol to purpurogallin occurred quickly in human erythrocytes, i.e., when pyrogallol was added to human erythrocyte suspension, it oxidized intracellular hemoglobin and produced purpurogallin. The metabolism of pyrogallol to purpurogallin was explained by the pyrogallol oxidation with superoxide and hydrogen peroxide produced during the oxido-reductive reactions of human hemoglobin with pyrogallol. The present results show that human erythrocytes can metabolize pyrogallol, suggesting that the cells may be involved in the metabolism of some drugs in the human body.

Description of hemoglobin oxygenation under universal solution conditions by a global allostery model with a single adjustable parameter

The Monod-Wyman-Changeux allosteric model parameters evaluated from accurate oxygen equilibrium curves (OECs) of hemoglobin that were measured in an extremely wide range of structural constraints, imposed by allosteric effectors, yielded a closed circle when log K(T) and log K(R) were plotted against log L(0) and log L(4), respectively, showing novel phenomena that L(0) and L(4) have a maximal value and a minimal value, respectively, and K(T) and K(R) vary by more than three orders of magnitude. These phenomena were successfully described by a global allostery model, which mathematically keeps the frame work of the MWC model, but allows that K(T) under a set of solution conditions becomes larger than K(R) under another set of solution conditions and postulates that a representative allosteric effector binds to both the T and R states with a lower affinity but with a larger stoichiometry for the R state than for the T state. Thus, this global model can describe any given OEC measured under universal solution conditions with the single adjustable parameter, the concentration of the representative effector.

Antioxidant activities of different hemoglobin derivatives

The antioxidant activity of hemoglobin was examined by studying both its peroxidase activity and its interaction with the superoxide anion. The peroxidase activity of both the subunits (alpha and beta) was reduced with respect to the alpha 2 beta 2 tetramer and heme-oxidation was found to be associated with a decrease in this activity. Lucigenin-amplified chemiluminescence experiments have shown that at low pH, the presence of hemoglobin reduces the level of superoxide anion generated by the xanthine/xanthine oxidase system (met-Hb is more efficient in reducing the level of O2- than oxy-hemoglobin). These results confirm that hemoglobin may be of importance in providing protection against oxidative damage to erythrocytes.

The multiple functions of hemoglobin

The aim of this review is to focus and discuss several parallel biological functions of hemoglobin besides its basic function of oxygen transport. In light of the information present in the literature the following possible physiological roles of hemoglobin are discussed: (1) hemoglobin as molecular heat transducer through its oxygenation-deoxygenation cycle, (2) hemoglobin as modulator of erythrocyte metabolism, (3) hemoglobin oxidation as an onset of erythrocyte senescence, (4) hemoglobin and its implication in genetic resistance to malaria, (5) enzymatic activities of hemoglobin and interactions with drugs, and (6) hemoglobin as source of physiological active catabolites.

Hydroxylation and dealkylation reactions catalyzed by hemoglobin

Red blood cells contain many enzymes that are akin to those that catalyze xenobiotic metabolism in liver and other tissues. An obvious exception is the cytochrome P-450 system that is found in virtually all other tissues. In vitro studies, however, have shown that hemoglobin can be a broad monooxygenase catalyst, exhibiting the properties of a monooxygenase enzyme. Thus, catalysis by Hb displays typical Michaelis-Menten kinetics, dependence on the native protein, coupling to NADPH-dependent flavoprotein reductases, and inhibition by carbon monoxide. The reconstituted system containing Hb along with P-450 reductase utilizes NADPH and O2 to catalyze typical monooxygenase reactions, including O- and N-demethylations as well as aromatic and aliphatic hydroxylations, and the catalytic cycle appears to mimic the typical P-450 mechanism. Turnover numbers for aniline hydroxylation are similar for Hb and P-450 reconstituted systems, whereas P-450 systems are more effective for other reactions. Catalysis by Hb seems to be restricted to the beta-heme sites of the tetramer, reflecting more facile substrate access. Overall the similarities and differences between Hb and P-450 provide an opportunity to examine the basis for their differential monooxygenase or peroxidase/peroxygenase activities in a comparative manner. Hb may be especially useful in delineating the early events in the respective reaction schemes, because it can be studied in various stable redox/ligand states, including the oxyferrous form. Similar hemoglobin-catalyzed oxidative biotransformations occur within intact erythrocytes, but apparent turnover numbers are much lower than those with the reconstituted Hb system, suggesting different mechanisms of catalysis. Although Hb-mediated oxidase activity in erythrocytes is low relative to other sites of xenobiotic metabolism, it may contribute to in situ activation of xenobiotics leading to oxidative stress, disruption of sulfhydryl homeostasis in the erythrocytes, covalent modification of Hb, and hemolysis.

Thioltransferase is a specific glutathionyl mixed disulfide oxidoreductase

To study the substrate specificity and mechanism of thioltransferase (TTase) catalysis, we have used 14C- and 35S-radiolabeled mixed disulfides of cysteine and glutathione (GSH) with various cysteine-containing proteins. These protein mixed disulfide substrates were incubated with glutathione, glutathione disulfide (GSSG) reductase, and NADPH in the presence or absence of thioltransferase. Glutathione-dependent reduction of protein mixed disulfides was monitored both by release of trichloroacetic acid soluble radiolabel and by formation of GSSG in an NADPH-linked spectrophotometric assay. GSH-dependent dethiolation of [35S]glutathione-papain mixed disulfide (papain-SSG) and the corresponding bovine serum albumin mixed disulfide (BSA-SSG) were catalyzed by thioltransferase (from human red blood cells) as shown by the radiolabel assay, and equivalent rates were measured by the spectrophotometric assay. Dethiolation of [35S]hemoglobin-glutathione mixed disulfide (Hb-SSG) was also catalyzed by TTase. In contrast, TTase did not catalyze GSH-dependent dethiolation of [14C]papain-SScysteine or [14C]BSA-SScysteine as measured by the radiolabel assay. [14C]Hb-SScysteine and Hb-SScysteamine also did not serve as substrates. In separate experiments, TTase from rat liver displayed analogous selectivity. Thus, thioltransferase (glutaredoxin) appears to be specific for glutathione-containing mixed disulfides. Apparent TTase catalysis of GSSG formation from the papain- and BSA-SScysteine mixed disulfides was observed by the spectrophotometric assay, but a lag phase occurred consistent with preenzymatic formation of GSScysteine which could serve as the actual TTase substrate. Two-substrate kinetic studies of TTase with GSH and GSScysteine gave patterns of parallel lines on double-reciprocal plots (1/V vs 1/[S]), consistent with a simple ping-pong mechanism involving a TTase-SSG intermediate.

Enzymic N-demethylation reaction catalysed by red blood cell cytosol

Red blood cell cytosol promotes enzymic N-demethylation reactions which display typical Michaelis-Menten kinetics with respect to N-methylaniline as substrate. The demethylase activity is linked with hemoglobin (Hb) and is enhanced in the presence of NADH and the NADH-methemoglobin reductase system. It has been adduced that Hb in its oxygenated form is involved in the reaction.

Activation of some aromatic amines to mutagenic products by human red blood cell cytosol

The ability of human red blood cell cytosol to activate aromatic amines was evaluated with the Ames test using Salmonella typhimurium TA98 in the liquid preincubation condition. While negative results were obtained with 4-acetylaminofluorene (4AAF) and 1-naphtylamine (1NA), a slight response was observed for 4-aminobiphenyl (4ABP) and 2-naphthylamine (2NA). Human red blood cell cytosol was able to activate 2-aminofluorene (2AF), 2-acetylaminofluorene (2AAF) and 2-aminoanthracene (2AA) to mutagenic intermediates. Extracts of human red blood cell cytosol incubated with 2AF were analyzed by gas chromatography: N-hydroxy-2-aminofluorene was identified as a metabolite.

Thioltransferase in human red blood cells: purification and properties

Thioltransferase activity was identified and the enzyme purified to apparent homogeneity from human red blood cells. Activity was measured as glutathione-dependent reduction of the prototype substrate hydroxyethyl disulfide; formation of oxidized glutathione (GSSG) was coupled to NADPH oxidation by GSSG reductase (1 unit of activity = 1 mumol/min of NADPH oxidized). The thioltransferase-GSH-GSSG reductase system was shown also to catalyze the regeneration of hemoglobin from the mixed disulfide hemoglobin-S-S-glutathione (HbSSG) and to reactivate the metabolic control enzyme phosphofructokinase (PFK) after oxidation of its sulfhydryl groups. On a relative concentration basis, thioltransferase was about 1200 times more efficient than dithiothreitol in reactivation of phosphofructokinase; e.g., 500 microM DTT was required to effect the same extent of reactivation as that of 0.4 microM TTase. The GSH plus GSSG reductase system without thioltransferase was ineffective for reduction of HbSSG or reactivation of PFK. The average amount of thioltransferase in intact erythrocytes was calculated to be 4.6 units/g of Hb at 25 degrees C. This level of activity is about the same as those of other enzymes that participate in sulfhydryl maintenance in red blood cells, such as GSSG reductase and glucose-6-phosphate dehydrogenase. These results suggest a physiological role for the thioltransferase in erythrocyte sulfhydryl homeostasis. Certain properties of the human erythrocyte thioltransferase resemble those of other mammalian thioltransferase and glutaredoxin enzymes. Thus, the human erythrocyte enzyme, purified about 28,000-fold to apparent homogeneity, is a single polypeptide with a molecular weight of 11,300. Its N-terminus is blocked, it is heat stable, and it contains four cysteine residues per protein molecule. However, the human erythrocyte thioltransferase is a distinct protein based on its amino acid composition. For example, it contains no methionine residues; whereas the related mammalian enzymes described to date have at least one internal methionine residue in their largely homologous sequences.

Red blood cells generate nitric oxide from directly acting, nitrogenous vasodilators

Human red blood cells (RBC) incubated under nitrogen with methylene blue and glucose at physiological temperature and pH can be used to test for the biotransformation of nitrogenous vasodilators to nitric oxide (NO). The NO generated was trapped as nitrosylated heme by reduced subunits (hemeII) on various hemoglobin valency species and quantified by electron paramagnetic resonance spectroscopy. It was possible to separate the various valency species of hemoglobin present in the mixture as (alpha 2 + beta 2)2, (alpha 2 + beta 3+)2, (alpha 3 + beta 2+)2, or (alpha 3 + beta 3+)2 by isoelectric focusing (IEF) unless cyanide (from nitroprusside) or azide was present in the mixture. These anions bind tenaciously to oxidized subunits (hemeIII) and prevent the separation of the various species by IEF. The fully oxidized tetramer, (alpha 3 + beta 3+)2, does not bind NO, but the other three species have hemeII units which can be nitrosylated. In the absence of cyanide or azide the valency species could be separated by IEF, and it was possible to quantify the degree of nitrosylation on each individual species. The various agents tested (nitrite, glyceryl trinitrate, hydroxylamine, hydralazine, nitroprusside, and azide) produced different patterns of valency species and degrees of nitrosylation of hemeII. When hemeIII ligands were present or in cases of very low yields, it was still possible to quantify the total concentration of NO-hemeII in the mixture. Thus, the method could still be used to test for NO formation. All of the so-called NO vasodilators tested yielded detectable amounts of NO in the system.

Genetic activity of 2-aminofluorene in the salmonella/erythrocyte mutagenicity assay

In a previous study, we demonstrated the activation of cyclophosphamide by mouse erythrocytes in a yeast test using the D7 strain of Saccharomyces cerevisiae. The present study provides further information on the ability of washed red blood cells from mice to activate 2-aminofluorene (2-AF) detected as an increase in mutation frequency of the tester strain, TA1538 (frameshift mutation) of Salmonella typhimurium. The 2-AF was tested at different concentrations (1-8 micrograms/plate) using both the liquid-suspension test and the agar-plate test. For comparison, the bioactivation of 2-AF by the hepatic postmitochondrial supernatant (S9 fraction) from Aroclor-1254-induced rats was studied. 2-AF was only found to be clearly mutagenic in the agar-plate test with both activation systems. The genetic response obtained with the erythrocytes appeared to be related to the number of cells/plate. At the lowest dose, slight differences are observed when genotoxic effects were compared to those with the S9 fraction.