Your search keyword '"Rifkind, Joseph"' showing total 8 results

1. SOD2 deficiency in hematopoietic cells in mice results in reduced red blood cell deformability and increased heme degradation.

Author

Mohanty JG, Nagababu E, Friedman JS, and Rifkind JM

Subjects

Animals, Erythrocyte Deformability genetics, Erythrocytes enzymology, Erythrocytes metabolism, Erythrocytes physiology, Erythroid Precursor Cells enzymology, Erythroid Precursor Cells metabolism, Erythroid Precursor Cells physiology, Hematopoietic Stem Cells enzymology, Hematopoietic Stem Cells metabolism, Hemoglobins metabolism, Mice, Mice, Knockout, Mice, Transgenic, Oxidation-Reduction, Oxidative Stress physiology, Peroxiredoxins deficiency, Peroxiredoxins genetics, Spectrometry, Fluorescence, Superoxide Dismutase genetics, Erythrocyte Deformability physiology, Hematopoietic Stem Cells physiology, Heme metabolism, Superoxide Dismutase deficiency

Abstract

Among the three types of super oxide dismutases (SODs) known, SOD2 deficiency is lethal in neonatal mice owing to cardiomyopathy caused by severe oxidative damage. SOD2 is found in red blood cell (RBC) precursors, but not in mature RBCs. To investigate the potential damage to mature RBCs resulting from SOD2 deficiency in precursor cells, we studied RBCs from mice in which fetal liver stem cells deficient in SOD2 were capable of efficiently rescuing lethally irradiated host animals. These transplanted animals lack SOD2 only in hematopoietically generated cells and live longer than SOD2 knockouts. In these mice, approximately 2.8% of their total RBCs in circulation are iron-laden reticulocytes, with numerous siderocytic granules and increased protein oxidation similar to that seen in sideroblastic anemia. We have studied the RBC deformability and oxidative stress in these animals and the control group by measuring them with a microfluidic ektacytometer and assaying fluorescent heme degradation products with a fluorimeter, respectively. In addition, the rate of hemoglobin oxidation in RBCs from these mice and the control group were measured spectrophotometrically. The results show that RBCs from these SOD2-deficient mice have reduced deformability, increased heme degradation products, and an increased rate of hemoglobin oxidation compared with control animals, indicative of increased RBC oxidative stress., (Published by Elsevier Inc.)

Published

2013

2. Role of the membrane in the formation of heme degradation products in red blood cells.

Author

Nagababu E, Mohanty JG, Bhamidipaty S, Ostera GR, and Rifkind JM

Subjects

Cells, Cultured, Cytosol metabolism, Erythrocyte Aging, Erythrocytes cytology, Fluorescence, Humans, Hydrogen Peroxide pharmacology, Oxidation-Reduction, Cell Membrane metabolism, Erythrocytes metabolism, Heme metabolism, Hemoglobins metabolism, Oxidative Stress

Abstract

Aims: Red blood cells (RBCs) have an extensive antioxidant system designed to eliminate the formation of reactive oxygen species (ROS). Nevertheless, RBC oxidant stress has been demonstrated by the formation of a fluorescent heme degradation product (excitation (ex) 321 nm, emission (em) 465 nm) both in vitro and in vivo. We investigated the possibility that the observed heme degradation results from ROS generated on the membrane surface that are relatively inaccessible to the cellular antioxidants., Main Methods: Membrane and cytosol were separated by centrifugation and the fluorescence intensity and emission maximum were measured. The effect on the maximum emission of adding oxidized and reduced hemoglobin to the fluorescent product formed when hemin is degraded by hydrogen peroxide (H(2)O(2)) was studied., Key Findings: 90% of the fluorescent heme degradation products in hemolysates are found on the membrane. Furthermore, these products are not transferred from the cytosol to the membrane and must, therefore, be formed on the membrane. We also showed that the elevated level of heme degradation in HbCC cells that is attributed to increased oxidative stress was found on the membrane., Significance: These results suggest that, although ROS generated in the cytosol are neutralized by antioxidant enzymes, H(2)O(2) generated by the membrane bound hemoglobin is not accessible to the cytosolic antioxidants and reacts to generate fluorescent heme degradation products. The formation of H(2)O(2) on the membrane surface can explain the release of ROS from the RBC to other tissues and ROS damage to the membrane that can alter red cell function and lead to the removal of RBCs from circulation by macrophages., (Copyright 2009. Published by Elsevier Inc.)

Published

2010

3. Heme degradation and oxidative stress in murine models for hemoglobinopathies: thalassemia, sickle cell disease and hemoglobin C disease.

Author

Nagababu E, Fabry ME, Nagel RL, and Rifkind JM

Subjects

Animals, Hemoglobin C metabolism, Immunoglobulin G metabolism, Mice, Mice, Transgenic, Anemia, Sickle Cell metabolism, Erythrocytes metabolism, Heme metabolism, Hemoglobin C Disease metabolism, Hemoglobinopathies metabolism, Oxidative Stress, Thalassemia metabolism

Abstract

Red blood cells with abnormal hemoglobins (Hb) are frequently associated with increased hemoglobin autoxidation, accumulation of iron in membranes, increased membrane damage and a shorter red cell life span. The mechanisms for many of these changes have not been elucidated. We have shown in our previous studies that hydrogen peroxide formed in association with hemoglobin autoxidation reacts with hemoglobin and initiates a cascade of reactions that results in heme degradation with the formation of two fluorescent emission bands and the release of iron. Heme degradation was assessed by measuring the fluorescent band at ex 321 nm. A 5.6 fold increase in fluorescence was found in red cells from sickle transgenic mice that expressed exclusively human globins when compared to red cells from control mice. When sickle transgenic mice co-express the gamma M transgene, that expresses HbF and inhibits polymerization, heme degradation is decreased. Mice expressing exclusively hemoglobin C had a 6.9 fold increase in fluorescence compared to control. Heme degradation was also increased 3.5 fold in beta-thalassemic mice generated by deletion of murine beta(major). Membrane bound IgG and red cell metHb were highly correlated with the intensity of the fluorescent heme degradation band. These results suggest that degradation of the heme moiety in intact hemoglobin and/or degradation of free heme by peroxides are higher in pathological RBCs. Concomitant release of iron appears to be responsible for the membrane damage that leads to IgG binding and the removal of red cells from circulation.

Published

2008

4. Studies on heme release from normal and metal ion reconstituted hemoglobin mediated through ionic surfactant.

Author

Venkatesh B, Venkatesh S, Jayadevan S, Rifkind JM, and Manoharan PT

Subjects

Carboxyhemoglobin chemistry, Electric Conductivity, Electron Spin Resonance Spectroscopy, Humans, Indicators and Reagents, Metals, Nickel, Spectrophotometry, Surface-Active Agents, Heme analysis, Hemoglobins chemistry

Abstract

The interaction of metal-substituted hemoglobin (MHb), where M = Ni and Cu (T-state with no O2 and CO binding capability) and Fe (R-state when CO is bound), with cationic cityl trimethyl ammonium bromide (CTAB) and anionic (sodium dodecyl sulfate-SDS) surfactants has been studied using spectroscopic techniques-UV-visible, electron paramagnetic resonance (EPR), and Fourier transform-Raman-with additional supportive evidence coming from conductivity measurements. We observed the loss of 5-coordination in all three hemoglobins below the critical micelle concentration (CMC) of surfactant, with noticeable differences, suggesting differing mechanisms involved in this process. In addition, above the CMC, Ni- and Cu-hemes were found to leave their proteins more easily than Fe-heme, presumably due to weaker or no bond with the proximal histidine in the former. The released heme is stabilized by micellar media through a hydrophobic interaction process. Of the two surfactants, CTAB seems to be capable of releasing the heme better than SDS and it is attributed to the greater hydrophobicity of CTAB though the charge of the surfactant plays an important role., (2004 Wiley Periodicals, Inc)

Published

2005

5. Heme degradation by reactive oxygen species.

Author

Nagababu E and Rifkind JM

Subjects

Animals, Antioxidants chemistry, Endothelium, Vascular metabolism, Erythrocytes metabolism, Humans, Hydrogen Peroxide chemistry, Iron chemistry, Models, Chemical, Oxygen metabolism, Protoporphyrins chemistry, Heme chemistry, Reactive Oxygen Species

Abstract

Heme proteins play a major role in various biological functions, such as oxygen sensing, electron transport, signal transduction, and antioxidant defense enzymes. Most of these reactions are carried out by redox reactions of heme iron. As the heme is not recycled, most cells containing heme proteins have the microsomal mixed function oxygenase, heme oxygenase, which enzymatically degrades heme to biliverdin, carbon monoxide, and iron. However, the red cell with the largest pool of heme protein, hemoglobin, contains no heme oxygenase, and enzymatic degradation of the red cell heme occurs only after the senescent red cells are removed by the reticuloendothelial system. Therefore, only nonenzymatic heme degradation initiated when the heme iron undergoes redox reactions in the presence of oxygen-producing reactive oxygen species takes place in the red cell. Unlike enzymatic degradation, which specifically attacks the alpha-methene bridge, reactive oxygen species randomly attack all the carbon methene bridges of the tetrapyrrole rings, producing various pyrrole products in addition to releasing iron. This review focuses on the literature related to nonenzymatic heme degradation with special emphasis on hemoglobin, the dominant red cell heme protein.

Published

2004

6. Hydrogen-peroxide-induced heme degradation in red blood cells: the protective roles of catalase and glutathione peroxidase.

Author

Nagababu E, Chrest FJ, and Rifkind JM

Subjects

Catalase antagonists & inhibitors, Dose-Response Relationship, Drug, Erythrocyte Aging, Erythrocyte Membrane metabolism, Erythrocytes enzymology, Ferrous Compounds, Flow Cytometry, Fluorescence, Glutathione Peroxidase antagonists & inhibitors, Heme chemistry, Humans, Hydrogen Peroxide pharmacology, Iodoacetamide, Lipid Peroxidation, Nitrites, Oxidation-Reduction, Oxidative Stress, Temperature, Time Factors, Catalase metabolism, Erythrocytes metabolism, Glutathione Peroxidase metabolism, Heme metabolism, Hydrogen Peroxide metabolism

Abstract

Catalase and glutathione peroxidase (GSHPX) react with red cell hydrogen peroxide. A number of recent studies indicate that catalase is the primary enzyme responsible for protecting the red cell from hydrogen peroxide. We have used flow cytometry in intact cells as a sensitive measure of the hydrogen-peroxide-induced formation of fluorescent heme degradation products. Using this method, we have been able to delineate a unique role for GSHPX in protecting the red cell from hydrogen peroxide. For extracellular hydrogen peroxide, catalase completely protected the cells, while the ability of GSHPX to protect the cells was limited by the availability of glutathione. The effect of endogenously generated hydrogen peroxide in conjunction with hemoglobin autoxidation was investigated by in vitro incubation studies. These studies indicate that fluorescent products are not formed during incubation unless the glutathione is reduced to at least 40% of its initial value as a result of incubation or by reacting the glutathione with iodoacetamide. Reactive catalase only slows down the depletion of glutathione, but does not directly prevent the formation of these fluorescent products. The unique role of GSHPX is attributed to its ability to react with hydrogen peroxide generated in close proximity to the red cell membrane in conjunction with the autoxidation of membrane-bound hemoglobin.

Published

2003

7. Site-specific cross-linking of human and bovine hemoglobins differentially alters oxygen binding and redox side reactions producing rhombic heme and heme degradation.

Author

Nagababu E, Ramasamy S, Rifkind JM, Jia Y, and Alayash AI

Subjects

Animals, Benzofurans chemistry, Benzofurans metabolism, Binding Sites, Blood Substitutes chemistry, Blood Substitutes metabolism, Cattle, Cross-Linking Reagents metabolism, Dicarboxylic Acids chemistry, Dicarboxylic Acids metabolism, Heme metabolism, Hemoglobins metabolism, Humans, Hydrogen Peroxide chemistry, Hydrogen Peroxide metabolism, Methemoglobin chemistry, Methemoglobin metabolism, Oxidation-Reduction, Oxygen metabolism, Spectrometry, Fluorescence, Cross-Linking Reagents chemistry, Heme chemistry, Hemoglobins chemistry, Oxygen chemistry

Abstract

Chemically modified human or bovine hemoglobins (Hb) have been developed as oxygen-carrying therapeutics and are currently under clinical evaluation. Oxidative processes, which are in many cases enhanced when modifications are introduced that lower the oxygen affinity, can limit the safety of these proteins. We have carried out a systematic evaluation of two modified human Hbs (O-R-polyHbA(0) and DBBF-Hb) and one bovine Hb (polyHbBv). We have both measured the oxidative products present in the Hb preparations and followed the oxidative reactions during 37 degrees C incubations. Autoxidation, the primary oxidative reaction which initiates the oxidative cascade, is highly correlated with P(50) (R = 0.987; p < 0.002). However, when the results for the other oxidative processes are compared, two different classes of oxidative reactions are identified. The formation of oxyferrylHb, like the rate of autoxidation, increases for all modified Hbs. However, the subsequent reactions, which lead to heme damage and eventually heme degradation, are enhanced for the modified human Hbs but are actually suppressed for bovine-modified Hbs. The rhombic heme measured by electron paramagnetic resonance, which is the initial step that causes irreversible damage to the heme, is found to be a reliable measure of the stability of ferrylHb and has the tendency to produce degradation products. DBBF-Hb, a Hb-based oxygen carrier (HBOC) for which toxic side effects have been well documented, has the highest level of rhombic heme (41-fold greater than for HbA(0)), even though its rate of autoxidation is relatively low. These findings establish the importance of these secondary oxidative reactions over autoxidation in evaluating the toxicity of HBOCs.

Published

2002

8. The pathophysiology of extracellular hemoglobin associated with enhanced oxidative reactions.

Author

Rifkind, Joseph M., Mohanty, Joy G., and Nagababu, Enika

Subjects

HEMOGLOBINS, OXIDATION, PATHOLOGICAL physiology, SUPEROXIDES, HYDROGEN peroxide, MICROCIRCULATION

Abstract

Hemoglobin (Hb) continuously undergoes autoxidation producing superoxide which dismutates into hydrogen peroxide (H2O2) and is a potential source for subsequent oxidative reactions. Autoxidation is most pronounced under hypoxic conditions in the microcirculation and for unstable dimers formed at reduced Hb concentrations. In the red blood cell (RBC), oxidative reactions are inhibited by an extensive antioxidant system. For extracellular Hb, whether from hemolysis of RBCs and/or the infusion of Hb-based blood substitutes, the oxidative reactions are not completely neutralized by the available antioxidant system. Un-neutralized H2O2 oxidizes ferrous and ferric Hbs to Fe(IV)-ferrylHb and OxyferrylHb, respectively. FerrylHb further reacts with H2O2 producing heme degradation products and free iron. OxyferrylHb, in addition to Fe(IV) contains a free radical that can undergo additional oxidative reactions. Fe(III)Hb produced during Hb autoxidation also readily releases heme, an additional source for oxidative stress. These oxidation products are a potential source for oxidative reactions in the plasma, but to a greater extent when the lower molecular weight Hb dimers are taken up into cells and tissues. Heme and oxyferryl have been shown to have a proinflammatory effect further increasing their potential for oxidative stress. These oxidative reactions contribute to a number of pathological situations including atherosclerosis, kidney malfunction, sickle cell disease, and malaria. The toxic effects of extracellular Hb are of particular concern with hemolytic anemia where there is an increase in hemolysis. Hemolysis is further exacerbated in various diseases and their treatments. Blood transfusions are required whenever there is an appreciable decrease in RBCs due to hemolysis or blood loss. It is, therefore, essential that the transfused blood, whether stored RBCs or the blood obtained by an Autologous Blood Recovery System from the patient, do not further increase extracellular Hb. [ABSTRACT FROM AUTHOR]

Published

2015