Hemolysis of rabbit erythrocytes in the presence of copper ions

The hemolysis of red blood cells (RBC) induced by Cu(II) is modified by ceruloplasmin (Cp) and albumin. The time course of hemolysis for rabbit RBC by Cu(II) consisted of two parts, an induction period followed by a catastrophic lysis period. The induction period decreased and the lysis rate increased with increasing Cu(II) concentration. Cp or albumin, modified Cu(II) induced hemolysis, by increasing the duration of the induction period and decreasing the overall rate of hemolysis of RBC. The catastrophic lysis period coincided with a sharp increase in the formation of metHb within the cell and in a rapid uptake of Cu(II). The presence of Cp led to an increase in the induction period prior to the rapid increase in metHb formation and in Cu(II) uptake. Porcine Cp was prepared with either two or three nonprosthetic copper binding sites (sites where Cu(II) is easily removed by passing over Chelex-100). Cp with three nonprosthetic binding sites gave more protection than Cp with two. Likewise, albumin can be prepared with three and five nonprosthetic copper binding sites. The albumin with five sites gave more protection than the albumin with three sites.     

Methods of nitric oxide detection in plants: A commentary

Over the last decade nitric oxide (NO) has been shown to influence a range of processes in plants. However, when, where and even if NO production occurs is controversial in several physiological scenarios in plants. This arises from a series of causes: (a) doubts have arisen over the specificity of widely used 4,5-diaminofluorescein diacetate (DAF-2DA)/4-amino-5-methylamino-2,7-difluorofluorescein (DAF-FM) dyes for NO, (b) no plant nitric oxide synthase (NOS) has been cloned, so that the validity of using mammalian NOS inhibitors to demonstrate that NO is being measured is debatable, (c) the NO scavenger 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-l-oxyl-3-oxide (cPTIO) needs to be used with caution, and (d) some discrepancies between assays for in planta measurements and another based on sampling NO from the gas phase have been reported. This review will outline some commonly used methods to determine NO, attempt to reconcile differing results obtained by different laboratories and suggest appropriate approaches to unequivocally demonstrate the production of NO.     

Dynamics of α-Hb chain binding to its chaperone AHSP depends on heme coordination and redox state

Background

AHSP is an erythroid molecular chaperone of the α-hemoglobin chains (α-Hb). Upon AHSP binding, native ferric α-Hb undergoes an unprecedented structural rearrangement at the heme site giving rise to a 6th coordination bond with His(E7).

Methods

Recombinant AHSP, WT α-Hb:AHSP and α-Hb^HE7Q:AHSP complexes were expressed in Escherichia coli. Thermal denaturation curves were measured by circular dichroism for the isolated α-Hb and bound to AHSP. Kinetics of ligand binding and redox reactions of α-Hb bound to AHSP as well as α-Hb release from the α-Hb:AHSP complex were measured by time-resolved absorption spectroscopy.

Results

AHSP binding to α-Hb is kinetically controlled to prevail over direct binding with β-chains and is also thermodynamically controlled by the α-Hb redox state and not the liganded state of the ferrous α-Hb. The dramatic instability of isolated ferric α-Hb is greatly decreased upon AHSP binding. Removing the bis-histidyl hexacoordination in α-HbH58(E7)Q:AHSP complex reduces the stabilizing effect of AHSP binding. Once the ferric α-Hb is bound to AHSP, the globin can be more easily reduced by several chemical and enzymatic systems compared to α-Hb within the Hb-tetramer.

Conclusion

α-Hb reduction could trigger its release from AHSP toward its final Hb β-chain partner producing functional ferrous Hb-tetramers. This work indicates a preferred kinetic pathway for Hb-synthesis.

General significance

The cellular redox balance in Hb-synthesis should be considered as important as the relative proportional synthesis of both Hb-subunits and their heme cofactor. The in vivo role of AHSP is discussed in the context of the molecular disorders observed in thalassemia.     

Decay Studies of Dmpo-Spin Adducts of Free Radicals Produced by Reactions of Metmyoglobin and Methemoglobin with Hydrogen Peroxide

The 5, 5-dimethyl-1-pyrroline-N-oxide (DMPO) spin adduct of myoglobin (Mb) or hemoglobin (Hb) was formed when metmyoglobin (MetMb) or methemoglobin (MetHb) reacted with H₂O₂ in the presence of DMPO, and both decayed with half-life of a few minutes. The DMPO spin adduct of Mb decayed with biphasic kinetics with k₁ = 0.645 min^-1 and k₂ = 0.012 min^-1, indicating that the spin adduct consisted of two kinetically heterogeneous species, stable and unstable ones. The DPMO spin adduct of Hb, however, was homogeneous. Decay of both spin adducts was accelerated in the presence of tyrosine, tryptophan or cysteine, but not phenylalanine, methionine or histidine. The decay obeyed the first order kinetics at varying concentrations of the spin adducts. The decay was accelerated by denaturation and proteolysis of protein moiety. The decay rate was not affected by the extra addition of MetMb or MetHb to each spin adduct. The decay rate of the spin adduct of Mb was increased by hematin in the presence of H₂O₂ and decreased by catalase. Decay of stable spin adduct of Mb, however, was not significantly changed under any experimental conditions used. These results led us to conclude that instability of the DMPO-spin adducts of Mb and Hb is due to intramolecular redox reactions between the spin adducts and amino acid residues and/or products of the reaction between heme and H₂O₂.     

Membrane cholesterol contents influence the protective effects of quercetin and rutin in erythrocytes damaged by oxidative stress

Flavonoids are potent scavengers of reactive oxygen species (ROS) that effectively prevent erythrocyte oxidation. Their antioxidant activities are governed by their structural characteristics and their ability to interact with and penetrate lipid bilayers. In order to gain a better understanding of the relationship between cholesterol contents and the antioxidant effectiveness of flavonoids against oxidative damage induced by ROS in cells, here we analyzed the integrity and structural stability of cholesterol-modified (enriched or depleted) and control erythrocytes exposed to tert-butyl hydroperoxide in the presence of quercetin or rutin. In control and cholesterol-enriched erythrocytes, quercetin provided greater protection against lipid peroxidation, ROS formation, and it preserved better cellular integrity than rutin. Both antioxidants suppressed the alterations in membrane fluidity and lipid losses with similar efficiency, reducing hemoglobin oxidation by 30% and GSH losses by 60% in the above-mentioned erythrocytes. Cholesterol depletion reduced the efficiency of the antioxidant power of both flavonoids against oxidative damage induced in the erythrocyte membrane, while a stronger degree of protection of GSH and hemoglobin contents was observed, mainly in the presence of rutin. These findings suggest a preferential incorporation of the antioxidants into the membranes from erythrocytes with normal and high cholesterol contents, whereas they would mainly be located in the cytoplasm of cholesterol-depleted erythrocytes.     

A methemoglobin-dependent and plasma-stimulated experimental model of oxidative hemolysis

Incubation of human red blood cells with ter-butyl hydroperoxide (tBHP) causes depletion of GSH and the production of highly reactive oxygen derivatives, notably hydroxyl (OH^?) radicals, followed by lysis of the cells. These effects are related to the formation of methemoglobin (MetHb), which catalyzes the homolytic cleavage of tBHP to form OH^? radicals. Lysis of red blood cells is the result of lipid peroxidation of membrane components and formation of protein aggregates and is enhanced if the tBHP-treated cells are resuspended in autologous plasma or serum. The tBHP-treated cells provide a useful model for analysis of the sequence of events in oxidative hemolysis.     

The production of activated oxygen species by an interaction of methemoglobin with ascorbate

Ascorbate reacts with methemoglobin to produce reactive oxygen species, most probably hydroxyl radicals. The main features of this system are: a) disappearance of ascorbate; b) consumption of oxygen with an ascorbate/O2 stoichiometry of 2:1; c) requirement of unliganded heme iron; d) formation of H2O2. The proposed mechanism involves an ascorbate-mediated interconversion of methemoglobin and oxy-hemoglobin, resulting in the production of H2O2. This product is decomposed by hemoglobin to produce hydroxyl radicals according to a Fenton-like reaction in which ascorbate recycles methemoglobin to hemoglobin. Alternative pathways of formation and of decomposition of H2O2 in this system appear to play a minor role.