Peroxynitrite inhibits glutathione S-conjugate transport

Peroxynitrite and 4-Hydroxynonenal Inactivate Breast Cancer Resistance Protein/ABCG2

Oxidative stress may arise from a variety of pathologies and results in the formation of toxic and reactive chemical species. Extensive research has been done to establish mechanisms of formation and cytotoxic effects of a number of different products of oxidation stress including peroxynitrite (PN) and 4-hydroxynonenal (4HNE). However, relatively few studies have investigated their effects on ATP-binding cassette (ABC) transporters. The objective of this investigation was to determine the effects of PN and 4HNE on BCRP/ABCG2. To eliminate the effect of metabolic enzymes, the experiments were carried out with inside-out Sf9 membrane vesicles overexpressing BCRP/ABCG2 using riboflavin as a substrate. The experiments revealed that PN produced IC₅₀ of about 31.2 ± 2.7 μM, based upon initial concentrations. The IC₅₀ for 4HNE was estimated to be 92 ± 1.4 μM. Preincubation of membrane vesicles with either PN or 4HNE caused the maximal rate of transport (V_max) to drop drastically, up to 19 times, with no or much smaller effect on K_m. Thus, PN and 4NE can inhibit BCRP transport activity.

Nitric oxide induced oxidative changes in erythrocyte membrane components

The effects of NO in its environment may vary considerably depending on various factors. This study shows oxidative mechanism of cellular membrane alterations, which is not associated with triggering of ONOOH generation but is induced by pure NO. Our investigation examined the influence of low concentration of NO (0.1; 0.2 mmol/l) on the qualitative changes of structure and dynamics of erythrocyte membrane. NO causes a statistically significant increase in membrane fluidity on different depths of lipid bilayer that is correlated with increase of lipids peroxidation. Statistically significant changes in the conformational state of cytoskeleton proteins were also detected. NO can be considered as a molecule responsible for determining rheological properties of erythrocytes membrane. Therefore, we propose that NO acts as pro-oxidant molecule at concentrations for which membrane appeared to be the first target before it entered the cytosol.

Hypochlorous acid inhibits glutathione S-conjugate export from human erythrocytes

It was found that the hypochlorous acid (HOCl) inhibits the active efflux of glutathione S-conjugates, 2,4-dinitrophenyl-S-glutathione (DNP-SG, c(50%)=258+/-24 microM HOCl) and bimane-S-glutathione (B-SG, c(50%)=125+/-16 microM HOCl) from human erythrocytes, oxidises intracellular reduced glutathione (the ratio [HOCl]/[GSH](oxidized)=4) and inhibits basal as well as 2,4-dinitrophenol- (DNP) and 2,4-dinitrophenyl-S-glutathione (DNP-SG)-stimulated Mg(2+)-ATPase activities of erythrocyte membranes. Multidrug resistance-associated protein (MRP1) mediates the active export of glutathione S-conjugates in mammalian cells, including human erythrocytes. A direct impairment of erythrocyte membrane MRP by hypochlorous acid was shown by electrophoresis and immunoblotting (c(50%)=478+/-36 microM HOCl). The stoichiometry of the MRP/HOCl reaction was 1:1. These results demonstrate that MRP can be one of the cellular targets for the inflammatory mediator hypochlorous acid.

Chlorodinitrobenzene-mediated damage in the human erythrocyte membrane leads to haemolysis

1-chloro-2,4-dinitrobenzene (CDNB), an intracellular glutathione-depleting agent, has been shown to have an adverse effect on erythrocyte membrane integrity. In the current study, we have demonstrated that CDNB caused haemolysis of human red blood cells (RBC) at higher concentrations (>or= 5 mM). The haemolysis induced by CDNB was preceded by the leakage of K(+) from the cells suggesting the colloid-osmotic nature of this lysis. The inclusion of molecules of increasing size in the extracellular media inhibited both the rate and extent of haemolysis thus supporting the proposal of CDNB-induced pore formation. The size of membrane lesions increased with an increase in the concentration of CDNB. SDS-PAGE demonstrated that CDNB causes the polymerisation and/or fragmentation of membrane proteins. Although CDNB has been shown to cause a drastic reduction in membrane thiols, our data suggest that the CDNB-induced formation of membrane disulfide bonds as a prima facie cause of permeability enhancement is unlikely.

Erythrocyte membrane ATP binding cassette (ABC) proteins: MRP1 and CFTR as well as CD39 (ecto-apyrase) involved in RBC ATP transport and elevated blood plasma ATP of cystic fibrosis

In addition to the better-known roles of the erythrocyte in the transport of oxygen and carbon dioxide, the concept that the red blood cell is involved in the transport and release of ATP has been evolving (J. Luthje, Blut 59, 367, 1989; G. R. Bergfeld and T. Forrester, Cardiovasc. Res. 26, 40, 1992; M. L. Ellsworth et al., Am. J. Physiol. 269, H2155, 1995; R. S. Sprague et al., Am. J. Physiol. 275, H1726, 1998). Membrane proteins involved in the release of ATP from erythrocytes now appear to include members of the ATP binding cassette (ABC) family (C. F. Higgins, Annu. Rev. Cell Biol. 8, 67, 1992; C. F. Higgins, Cell 82, 693, 1995). In addition to defining physiologically the presence of ABC proteins in RBCs, accumulating gel electrophoretic evidence suggests that the cystic fibrosis transmembrane conductance regulator (CFTR) and the multidrug resistance-associated protein (MRP1), respectively, constitute significant proteins in the red blood cell membrane. As such, this finding makes the mature erythrocyte compartment a major mammalian repository of these important ABC proteins. Because of its relative structural simplicity and ready accessibility, the erythrocyte offers an ideal system to explore details of the physiological functions of ABC proteins. Moreover, the presence of different ABC proteins in a single membrane implies that interaction among these proteins and with other membrane proteins may be the norm and not the exception in terms of modulation of their functions.

Characterization of erythrocyte compounds in asphyxiated newborns

Perinatal hypoxic-ischemic damage remains a major cause of acute mortality in infants. In our study we have shown that ATP-powered calcium pump was degraded in asphyxiated erythrocyte membranes. Moreover, the activity of Ca2+-ATPase, the enzyme that is solely responsible for maintenance of calcium homeostasis in erythrocytes, was reduced by 50% compared to healthy newborns. We have also detected the enhanced lipid peroxidation in asphyxiated erythrocyte ghosts. To elucidate the potential mechanisms of the calcium pump damage, we have examined the effect of peroxynitrite on Ca2+-ATPase purified from adult human erythrocyte membranes. We have concluded that calcium pump is a direct target for peroxynitrite action in vitro. Our results indicate that erythrocyte membrane compounds could be a primary target for asphyxia-induced damage, and the impairment of the plasma membrane Ca2+-ATPase function could be, in part, mediated by reactive oxygen species.

Radiation inactivation suggests that human multidrug resistance-associated protein 1 occurs as a dimer in the human erythrocyte membrane

Molecular masses of functional units of two components of 2, 4-dinitrophenyl-S-glutathione (DNP-SG) transport across the erythrocyte membrane determined by radiation inactivation were 437 +/- 69 kDa for the high-affinity component and 466 +/- 67 kDa for the low-affinity component. These results confirm that the multidrug resistance-associated protein (MRP) 1 is responsible for the high-affinity DNP-SG transport across the erythrocyte membrane and suggest that MRP1 exists in the membrane as a dimer. The molecular size of the low-affinity transporter is similar if not identical to that of MRP1. Moreover, while the molecular mass of the DNP-SG-ATPase activity of the erythrocyte membrane corresponds also to that of MRP (375 +/- 36 kDa), the molecular mass of the functional unit of dinitrophenol-stimulated ATPase is significantly lower (232 +/- 26 kDa), which suggests that thisactivity is linked to a different protein, perhapsaminophospholipid translocase.