A perspective on exogenous redox regulation mediated by transfused RBCs subject to the storage lesion.

Granted with a potent ability to interact with and tolerate oxidative stressors, RBCs scavenge most reactive oxygen and nitrogen species (RONS) generated in circulation. This essential non-canonical function, however, renders RBCs susceptible to damage when vascular RONS are generated in excess, making vascular redox imbalance a common etiology of anemia, and thus a common indication for transfusion. This accentuates the relevance of impairments in redox metabolism during hypothermic storage, as the exposure to chronic oxidative stressors upon transfusion could be exceedingly deleterious to stored RBCs. Herein, we review the prominent mechanisms of the hypothermic storage lesion that alter the ability of RBCs to scavenge exogenous RONS as well as the associated clinical relevance.

Oxidative degradation perturbs physico-chemical properties of hemoglobin in cigarette smokers: a threat to different biomolecules.

CONTEXT: Cigarette smokers develop structural modification in hemoglobin (Hb) and this modification enable Hb to undergo higher rate of auto-oxidation, leading to generation of further intracellular ROS. OBJECTIVE: In this study, we exhibited the possible cause and consequences of Hb modification in cigarette smokers. METHODS: Twenty-two smokers and 16 nonsmokers, aged 25 to 35 years, having a smoking history of 7-10 years were recruited in this study. Carbonyl content, ferryl form, peroxidase-like and esterase-like activities of Hb were assayed. Free iron release by Hb, erythrocyte membrane-bound Hb and plasma Hb were also measured along with assessment of important biomolecular degradations by Hb. RESULTS AND DISCUSSION: Increase in carbonyl content in Hb indicates its oxidative degradation. Increase in ferryl Hb formation, peroxidase-like activity and decrease in esterase like activity of Hb along with increased release of nonheme iron (from Hb) clearly indicates alteration in physico-chemical properties of Hb in smokers. Moreover, increase in erythrocyte membrane-bound Hb and plasma-free Hb provide further evidences for higher rate of Hb oxidation in smokers' erythrocyte. The rates of protein, lipid, sugar and DNA degradation were noticed to be higher by smokers' Hb; and were further attenuated by desferrioxamine as well as mannitol. CONCLUSION: We conclude that in cigarette smokers, there is oxidative degradation of Hb and the degradation causes alteration in its physico-chemical properties, which in turn may degrade different biomolecules in its close vicinity by releasing more iron and production of more superoxide as well as hydroxyl radical.

Ferryl Hemoglobin and Heme Induce A1-Microglobulin in Hemorrhaged Atherosclerotic Lesions with Inhibitory Function against Hemoglobin and Lipid Oxidation.

Infiltration of red blood cells into atheromatous plaques and oxidation of hemoglobin (Hb) and lipoproteins are implicated in the pathogenesis of atherosclerosis. α1-microglobulin (A1M) is a radical-scavenging and heme-binding protein. In this work, we examined the origin and role of A1M in human atherosclerotic lesions. Using immunohistochemistry, we observed a significant A1M immunoreactivity in atheromas and hemorrhaged plaques of carotid arteries in smooth muscle cells (SMCs) and macrophages. The most prominent expression was detected in macrophages of organized hemorrhage. To reveal a possible inducer of A1M expression in ruptured lesions, we exposed aortic endothelial cells (ECs), SMCs and macrophages to heme, Oxy- and FerrylHb. Both heme and FerrylHb, but not OxyHb, upregulated A1M mRNA expression in all cell types. Importantly, only FerrylHb induced A1M protein secretion in aortic ECs, SMCs and macrophages. To assess the possible function of A1M in ruptured lesions, we analyzed Hb oxidation and heme-catalyzed lipid peroxidation in the presence of A1M. We showed that recombinant A1M markedly inhibited Hb oxidation and heme-driven oxidative modification of low-density lipoproteins as well plaque lipids derived from atheromas. These results demonstrate the presence of A1M in atherosclerotic plaques and suggest its induction by heme and FerrylHb in the resident cells.

Cigarette smokers develop structurally modified hemoglobin: a possible way of increasing oxidative stress.

CONTEXT: Increased levels of free radicals and various reactive species along with reduced antioxidant defence system are the major threat to erythrocyte in tobacco smokers. Thus, the hemoglobin (Hb) within the erythrocyte is very prone to oxidative damage. Earlier reports suggest that cigarette smoking is related with the glutathionylation and formation of adducts of Hb. OBJECTIVE: We have highlighted the possible changes in secondary and tertiary structures of Hb in cigarette smokers and its physiological consequences. MATERIAL AND METHOD: Twenty smokers and 18 non-smokers, aged 25-35 years were volunteered in this study. We used flow cytometry for measuring intracellular reactive oxygen species (IcROS). The purified Hb was subjected to different spectrophotometric, fluoremetric and circular dichroic (CD) analysis. The hydrophobicity, thermal stability, heme release and oxidation of purified Hb were also studied. RESULT: We observed that the IcROS was also higher in cigarette smokers than non-smokers. The data of intrinsic fluorescence, synchronous fluorescence and tryptophan quenching studies showed that the microenvironments of ß37 tryptophan and tyrosine residues of Hb were moved toward more hydrophobic region in cigarette smokers. Increased hydrophobicity and thermal stability furthermore indicated more compactness of smokers' hemoglobin. From CD spectra, we confirmed an overall modification of the secondary and tertiary structures of hemoglobin in smokers. Both auto- and co-oxidation rates of purified Hb were found to be higher in cigarette smokers. DISCUSSION AND CONCLUSION: We conclude that the modified Hb in cigarette smokers may further enhance the oxidative insult within the cell.

Hemoglobin Oxidation Reactions in Stored Blood.

Hemoglobin (Hb) inside and outside the red blood cells (RBCs) undergoes constant transformation to an oxidized form in a process known as autoxidation. The ferrous heme iron (Fe2+) of the prosthetic group is spontaneously transformed into an oxidized ferric (Fe3+) form, but under oxidative stress conditions a higher oxidation ferryl heme (Fe4+) is also formed. Although Fe3+ is a non-functional form of Hb, the Fe4+ is also extremely reactive towards other biological molecules due to its high redox potential. The RBC contains an effective reductive machinery that maintains Hb in the functional form with little oxidation during its life span. The redox transformation of Hb occurs to a lesser extent in young RBCs; it may, however, have detrimental effects on the integrity of these cells during ex vivo storage or when RBCs are subjected to pathogen reduction processes. In this review, Hb oxidation reactions ("oxidative lesion") will be described, including details of how these reactions might impact the clinical use of stored or processed blood for therapeutic purposes.

Overview on hydrogen sulfide-mediated suppression of vascular calcification and hemoglobin/heme-mediated vascular damage in atherosclerosis.

Vulnerable atherosclerotic plaques with hemorrhage considerably contribute to cardiovascular morbidity and mortality. Calcification is the main characteristic of advanced atherosclerotic lesions and calcified aortic valve disease (CAVD). Lyses of red blood cells and hemoglobin (Hb) release occur in human hemorrhagic complicated lesions. During the interaction of cell-free Hb with plaque constituents, Hb is oxidized to ferric and ferryl states accompanied by oxidative changes of the globin moieties and heme release. Accumulation of both ferryl-Hb and metHb has been observed in atherosclerotic plaques. The oxidation hotspots in the globin chain are the cysteine and tyrosine amino acids associated with the generation of Hb dimers, tetramers and polymers. Moreover, fragmentation of Hb occurs leading to the formation of globin-derived peptides. A series of these pro-atherogenic cellular responses can be suppressed by hydrogen sulfide (H2S). Since H2S has been explored to exhibit a wide range of physiologic functions to maintain vascular homeostasis, it is not surprising that H2S may play beneficial effects in the progression of atherosclerosis. In the present review, we summarize the findings about the effects of H2S on atherosclerosis and CAVD with a special emphasis on the oxidation of Hb/heme in atherosclerotic plaque development and vascular calcification.

Free radical scavenging activity of silibinin in nitrite-induced hemoglobin oxidation and membrane fragility models.

Free radical formation in heme proteins is recognized as a factor in mediating the toxicity of many drugs. Xenobiotics and drug therapy-related toxicity, due to oxidative modification of hemoglobin (Hb), has been attributed in part to the uncontrolled oxidative reactions. A variety of antioxidant strategies to ameliorate potential oxidative damage in vivo have been suggested. The present study was designed to evaluate the dose-response relationship of the free radical scavenging properties of silibinin dihemisuccinate (SDH) in nitrite-induced Hb oxidation in vitro and in vivo. Different concentrations of SDH were added, before and after different intervals of inducing Hb oxidation in erythrocytes lysate, and formation of methemoglobin (MetHb) was monitored spectrophotometrically; the same approach was utilized to evaluate the effect of the same doses of SDH on the integrity of erythrocytes after induction of hemolysis. Moreover, the most effective dose of SDH was administered in rats before challenge with toxic dose of sodium nitrite, and MetHb formation was monitored as mentioned before. The results showed that in both in vitro and in vivo models, SDH successfully attenuates Hb oxidation after challenge with sodium nitrite; this protective effect was not related to the stage of the catalytic stage of Hb oxidation, though the effect was more prominent when the compound was administered before nitrite. In conclusion, SDH can effectively, in concentration-dependent pattern, attenuate sodium nitrite-induced Hb oxidation and maintain integrity of red blood cells both in vitro and in vivo.

Effect of hydrogen peroxide on normal and acatalasemic mouse erythrocytes.

OBJECTIVES: Normal and acatalasemic mouse erythrocytes were used to clarify the relationship between oxidative damage in H2O2-treated erythrocytes and catalase activity. DESIGN & METHODS: Generation of hydrolysis-resistant erythrocytes and hemolysis were examined. The osmotic fragility test, the negative charges and the number of membrane-flickering erythrocytes among the H2O2-treated erythrocytes were investigated. RESULTS: Small amounts of hydrolysis-resistant mouse erythrocytes were generated by treatment with 0.1 mM H2O2, and the amount of acatalasemic erythrocytes was larger than untreated controls. Hemolysis in the acatalasemic erythrocytes was observed 30 min after the addition of the H2O2. A drastic increase in hydrolysis-resistant erythrocytes and a loss of membrane proteins in the acatalasemic erythrocytes were found as a result of the addition of 1 mM H2O2. Hemolysis in normal erythrocytes was observed at 3 mM H2O2. CONCLUSIONS: Catalase is a potent H2O2-scavenger even in acatalasemic mouse erythrocytes. It is concluded that the drastic increase of hydrolysis-resistant erythrocytes is induced by a loss of membrane function and is associated with the low catalase activity in these cells.

New role for an old molecule: The 2,3-diphosphoglycerate case.

BACKGROUND: Aerobic organisms have to overcame the dangerous species derived from the unquestionable favorable effects due to the utilization of oxygen in the cellular respiration. 2,3-Diphosphoglycerate (DPG) could be one of the molecules able to perform different role inside the cells and (from the data obtained from our experimental work) may help cellular components, in particular hemoglobin, to scavenge reactive oxygen species (ROS) and reactive nitrogen species (RNS). METHODS: Therefore, we have investigated the kinetic and antioxidant properties of this molecule against the main biological reactive species and the protective role of this molecules on hemoglobin treated with strong oxidant. RESULTS: DPG, at the physiological concentration is able to scavenge hydroxyl radical, peroxyl radical, cation radicals and to chelate iron in the reduced state. Moreover it is able to avoid oxidation of iron inside the hemoglobin following treatment with nitrite and tert-butyl hydroperoxide (t-BOOH). On the other side, it is not able to protect membrane components from oxidative burning. This different behavior towards radical species is probably linked to the polarity of the molecule and also the high levels of charged groups present on the surface of DPG, that avoid the possibility to act in an environment almost completely hydrophobic, as inside the membrane, where reactive species produce the main damages during the reactions of peroxidation. CONCLUSIONS: This is the first paper dealing with the potential role of DPG not only as a modulator of oxygen affinity in hemoglobin, but also as a scavenger of radicals.

Interactions between peroxiredoxin 2, hemichrome and the erythrocyte membrane.

Peroxiredoxin 2 (Prx2) is an abundant antioxidant protein in erythrocytes that protects against hemolytic anemia resulting from hemoglobin oxidation and Heinz body formation. A small fraction of Prx2 is bound to the cell membrane, but the mechanism and relevance of binding are not clear. We have investigated Prx2 interactions with the erythrocyte membrane and oxidized hemoglobin and whether these interactions are dependent on Prx2 redox state. Membrane binding of Prx2 in erythrocytes decreased when the cells were treated with H2O2, but studies with purified Prx2 and isolated ghosts showed that the interaction was independent of Prx2 redox state. Hemoglobin oxidation leads to the formation of hemichrome, a denatured form of the protein that binds to Band3 protein in the cell membrane as part of the senescence process and is a precursor of Heinz bodies. Hemichrome competed with Prx2 and decreased Prx2 binding to the membrane, potentially explaining the decreased binding in oxidant-exposed cells. The increased membrane binding of Prx2 seen with increasing intracellular calcium was less sensitive to H2O2 or hemichrome, suggesting an alternative mode of binding. Prx2 was also shown to exhibit chaperone-like activity by retarding the precipitation of pre-formed hemichrome. Our results suggest that Prx2, by restricting membrane binding of hemichrome, could impede Band3 clustering and exposure of senescence antigens. This mechanism, plus the observed chaperone activity for oxidized hemoglobin, may help protect against hemolytic anemia.

Red blood cell, hemoglobin and heme in the progression of atherosclerosis.

For decades plaque neovascularization was considered as an innocent feature of advanced atherosclerotic lesions, but nowadays growing evidence suggest that this process triggers plaque progression and vulnerability. Neovascularization is induced mostly by hypoxia, but the involvement of oxidative stress is also established. Because of inappropriate angiogenesis, neovessels are leaky and prone to rupture, leading to the extravasation of red blood cells (RBCs) within the plaque. RBCs, in the highly oxidative environment of the atherosclerotic lesions, tend to lyse quickly. Both RBC membrane and the released hemoglobin (Hb) possess atherogenic activities. Cholesterol content of RBC membrane contributes to lipid deposition and lipid core expansion upon intraplaque hemorrhage. Cell-free Hb is prone to oxidation, and the oxidation products possess pro-oxidant and pro-inflammatory activities. Defense and adaptation mechanisms evolved to cope with the deleterious effects of cell free Hb and heme. These rely on plasma proteins haptoglobin (Hp) and hemopexin (Hx) with the ability to scavenge and eliminate free Hb and heme form the circulation. The protective strategy is completed with the cellular heme oxygenase-1/ferritin system that becomes activated when Hp and Hx fail to control free Hb and heme-mediated stress. These protective molecules have pharmacological potential in diverse pathologies including atherosclerosis.