Oxidative stress of human erythrocytes by iodate and periodate. Reversible formation of aqueous membrane pores due to SH-group oxidation

Human erythrocytes were exposed to oxidative stress by iodate and periodate. Oxidation causes a time- and concentration-dependent increase in membrane permeability for hydrophilic molecules and ions. The induced leak discriminates nonelectrolytes on the basis of molecular size and exhibits a very low activation energy (Ea = 1-4 kcal.mol-1). These results are reconcilable with the formation of aqueous pores. The pore size was approximated to be between 0.45 and 0.6 nm. This increase in permeability is reversible upon treatment with dithioerythritol. Blocking of membrane thiol groups with N-ethylmaleimide protects the membranes against leak formation. The oxidation causes dithioerythritol-reversible modification of membrane proteins as indicated by the gel electrophoretic behavior. These modifications can also be suppressed by blocking the membrane thiol groups with N-ethylmaleimide. About half of the membrane methionine is oxidized to acid hydrolysis-stable derivatives. A fast saturating increase in diene conjugation was observed in whole cells but not in isolated membranes, with only minor degradation of fatty acid chains. The oxidation of cell membrane lipids as well as oxidation of cell surface carbohydrates are not involved in leak formation. Taken together with earlier data (Deuticke, B., Poser, B., Lütkemeier, P. and Haest, C.W.M. (1983) Biochim. Biophys. Acta 731, 196-210), these findings indicate that formation of disulfide bonds by different oxidative mechanisms results in leaks with similar properties.     

Lateral segregation of membrane lipids and formation of stable rod-shaped membrane projections in erythrocytes treated with long-chain alcohols

Human erythrocytes, incubated with sonicated dispersions of phosphatidylcholine, cholesterol and saturated straight-chain alcohols (C₁₆-C₁₈) develop stiff, rod-shaped, hemoglobin-containing membrane projections within 120 min. The number of these ‘rods’ varies (1–3 per cell), they reach a length of up to 14 μm (twice the cell diameter) and a thickness of 0.3–1.0 μm. ‘Rods’ may be separated from ‘residual cells’ by shear flow and centrifugation without severe hemolysis. Lipid analyses carried out on residual cells and rods indicate lateral segregation of the phospholipids of the outer leaf of the membrane lipid bilayer (phosphatidylcholine and sphingomyelin) and of the alcohol applied. Phosphatidylcholine accumulates in the residual cells, sphingomyelin and the alcohol in the rods. No differences in membrane protein patterns were observed between rods and residual cells. The rod-shape is dependent on the presence of the alcohol, extraction of the alcohol converts rods into hemoglobin-containing spheres without lysis. The formation of rods, which is indicative of a lateral phase separation, is discussed in terms of lipid-lipid interactions and with respect to parameters determining the shape of cells.     

Penetration of 2,4,6-trinitrobenzenesulfonate into human erythrocytes: Consequences for studies on phospholipid asymmetry

The glutathione content of human erythrocytes rapidly diminishes when cells are exposed to 2,4,6-trinitrobenzenesulfonate (20 μmol/l cells) at 37°C. Even at 0°C a slow decrease in glutathione content is observed. The uptake of trinitrobenzenesulfonate by the cells is retarded by inhibitors of the inorganic anion exchange system, indicating that trinitrobenzenesulfonate enters the cells by this pathway.The disappearance of glutathione most probably results from the reaction: 2 GSH + trinitrobenzenesulfonate → GSSG + aminodinitrobenzenesulfonate The reaction of trinitrobenzenesulfonate with glutathione occurs prior to its covalent binding to amino groups of hemoglobin which makes this reaction a more sensitive method of detection of penetration of trinitrobenzenesulfonate into erythrocytes. Results of studies on the asymmetric distribution of phospholipids using trinitrobenzenesulfonate as the only probe should be reconsidered in the light of these new data.     

Reorientation rates and asymmetry of distribution of lysophospholipids between the inner and outer leaflet of the erythrocyte membrane

Labelled lysophospholipids were inserted into the outer layer of the erythrocyte membrane and their reorientation (flip) to the inner layer quantified by following the increase of the fraction of lysophospholipids not extractable by albumin. Flip rate constants were calculated from the kinetics of equilibration of the lysophospholipids between two compartments, the outer and the inner leaf of the bilayer, in the early phase of the flip kinetics where correction for non-enzymatic hydrolysis and acylation could be omitted. The distribution of a lysophospholipid finally attained reflects its affinity for the two layers. Whereas lysophosphatidylcholine has a slight preference for the outer layer of the membrane, lysophosphatidylserine spontaneously concentrates in the inner layer up to a ratio of 4:1. This asymmetry mimics the distribution of phosphatidylserine in the native membrane. Flip rates depend on membrane lipid compositions. They are enhanced by cholesterol depletion. Comparison of various mammalian species demonstrates that erythrocytes with a higher phosphatidylcholine/sphingomyelin ratio and high content of polyunsaturated fatty acids (mouse and rat) have a high transbilayer mobility, in contrast to erythrocytes with a low phosphatidylcholine/sphingomyelin ratio and a low content of polyunsaturated fatty acids (ox). Molecular properties of lysophospholipids influence their transbilayer mobility. Flip rates of lysophospholipids are enhanced not only by unsaturation of their fatty acid, but also by a negative net charge on the headgroup. This indicates that the strongly asymmetric distribution of phosphatidylserine in the native erythrocyte membrane, which is maintained for the lifespan of the cell, does not result from a lack of transbilayer mobility.     

On the mechanism of drug-induced acceleration of phospholipid translocation in the human erythrocyte membrane

Small amphiphilic compounds (M(r)<200 Da) such as anaesthetics and hexane derivatives with different polar groups produced a concentration-dependent acceleration of the slow passive transbilayer movement of NBD-labelled phosphatidylcholine in the human erythrocyte membrane. Above a threshold concentration characteristic for each compound, the flip rate gradually increased at increasing concentrations in the medium. For compound concentrations required to produce a defined flip acceleration, corresponding membrane concentrations were estimated using reported octanol/water partition coefficients. The effective threshold membrane concentrations (50-150 mmol l(-1)) varied in the order: hexylamine>isoflurane=hexanoic acid>hexanol=chloroform>hexanethiol=1,1,2,2-tetrachloroethane>chlorohexane. Apolar hexane, which mainly distributes in the apolar membrane core, was much less effective and supersaturating concentrations were required to enhance flip. Localization of the drug at the lipid-water interface seems to be required for flip acceleration. Such a localization may increase the lateral pressure in this region and the bilayer curvature stress with concomitant decrease of order and rigidity at the interface. This unspecific bilayer perturbation is proposed to enhance the probability of formation of hydrophobic defects in the bilayer, facilitating penetration of the polar head group of the phospholipid into the apolar membrane core.     

Experimental alteration of phospholipid-protein interactions within the human erythrocyte membrane. Dependence on glycolytic metabolism.

Phosphatidylethanolamine in freshly drawn human erythrocytes is trinitrophenylated by 2,4,6-trinitrobenzene sulfonic acid only slowly and to a maximum of 32%. After different preincubation procedures at 37 degrees C in saline media in the absence of glucose (24 h without additive, 1-5 h with 8 mM hexanol or 1-4 h with the SH reagent, 5 mM tetrathionate) the rate of subsequent trinitrophenylation of phosphatidylethanolamine, in the absence of the additives, is greatly enhanced and the amount of phospholipid reacting increased. Glucose or inosine prevent these effects, inhibitors of glycosis abolish this protection. The results indicate that in fresh as well as in glycolysing incubated erythrocytes phosphatidylethanolamine in the outer layer of the membrane lipid is shielded by a protein. Conformational changes of this protein induced by metabolic starvation and perturbing agents expose the phospholipid head group to 2, 4, 6-trinitrobenzene sulfonic acid. In addition, a "flip-flop" of phosphatidylethanolamine from the inner to the outer layer may also contribute to the effects observed.     

Extensive electroporation abolishes experimentally induced shape transformations of erythrocytes: a consequence of phospholipid symmetrization?

As shown in earlier work (M.M. Henszen et al., Mol. Membr. Biol. 14 (1997) 195-204), exposure of erythrocytes to single brief electric field pulses (5-7 kV cm(-1)) enhances the transbilayer mobility of phospholipids and produces echinocytes which can subsequently be transformed into stomatocytes in an ATP-dependent process. These shape transformations arise from partly reversible changes of the transbilayer disposition of phospholipids, in agreement with the bilayer couple concept. Extensive membrane modification by repetitive (相似文献   

Band 3-Mediated Flip-Flop and Phosphatase-Catalyzed Cleavage of a Long-Chain Alkyl Phosphate Anion in the Human Erythrocyte Membrane

In pursuit of the characterization of the recently discovered flippase mode of operation of the anion transporter (band 3, AE1) of the human erythrocyte membrane, the transbilayer translocation (flip) of a fluorescently labeled, membrane-intercalated long-chain alkyl phosphate, 10-(α-napthyl)-1-decyl-phosphate (NDP) was investigated. In contrast to the alkyl sulfonates and esters of phosphatidic acid studied as yet, NDP moves exclusively via band 3. NDP is, however, dephosphorylated at the inner membrane surface by a cytoplasmic phosphatase likely to interact specifically with endofacial membrane structures of the erythrocyte. This phosphatase shares characteristic inhibitor sensitivities with protein tyrosine phosphatases present in the erythrocyte interior. Vanadate as an inhibitor of NDP dephosphorylation provided a means to study the kinetic properties and patterns of inhibition (by inhibitors of anion exchange) and stimulation (by proteolysis of band 3 and aliphatic alcohols) of the flip of NDP. NDP is also an inhibitor of the exchange of hydrophilic anions via band 3, while hydrophilic anions interfere with the flip of NDP. The results are compared with the characteristics of the flip, via Band 3, of other amphiphilic anions and of the exchange of hydrophilic anions. Attempts are presented to understand the low flip rate of long-chain amphiphilic anions on the basis of their molecular properties and the thermodynamics of the ``transition state' of the flip process. Received: 18 February 1998/Revised: 29 May 1998     

Autumn bird migration phenology: A potpourri of wind,precipitation and temperature effects

Climate change has caused a clear and univocal trend towards advancement in spring phenology. Changes in autumn phenology are much more diverse, with advancement, delays, and ‘no change' all occurring frequently. For migratory birds, patterns in autumn migration phenology trends have been identified based on ecological and life‐history traits. Explaining interspecific variation has nevertheless been challenging, and the underlying mechanisms have remained elusive. Radar studies on non‐species‐specific autumn migration intensity have repeatedly suggested that there are strong links with weather. In long‐term species‐specific studies, the variance in autumn migration phenology explained by weather has, nevertheless, been rather low, or a relationship was even lacking entirely. We performed a spatially explicit time window analysis of weather effects on mean autumn passage of four trans‐Saharan and six intra‐European passerines to gain insights into this apparent contradiction. We analysed data from standardized daily captures at the Heligoland island constant‐effort site (Germany), in combination with gridded daily temperature, precipitation and wind data over a 55‐year period (1960–2014), across northern Europe. Weather variables at the breeding and stopover grounds explained up to 80% of the species‐specific interannual variability in autumn passage. Overall, wind conditions were most important. For intra‐European migrants, wind was even twice as important as either temperature or precipitation, and the pattern also held in terms of relative contributions of each climate variable to the temporal trends in autumn phenology. For the trans‐Saharan migrants, however, the pattern of relative trend contributions was completely reversed. Temperature and precipitation had strong trend contributions, while wind conditions had only a minor impact because they did not show any strong temporal trends. As such, understanding species‐specific effects of climate on autumn phenology not only provides unique insights into each species' ecology but also how these effects shape the observed interspecific heterogeneity in autumn phenological trends.