Membrane glycopeptides from old and young human erythrocytes (Short Communication)

Glycopeptides were extracted by papain digestion from old and young human erythrocyte membranes and fractionated on DEAE-Sephadex A-25. Chemical characterization of the unfractionated samples and of the main peak eluted from the column indicates that glycoproteins of the erythrocyte membrane undergo significant decreases in sialic acid and galactosamine content with aging.     

Clearance of senescent erythrocytes: wheat germ agglutinin distribution on young and old human erythrocytes

To add an additional aspect to the process of recognition and removal of senescent human erythrocytes from the circulation, the binding of wheat germ agglutinin (WGA) to separated young, old and sialidase-treated human erythrocytes is evaluated with the immune-electron microscopical method. WGA/gold conjugate binding to old erythrocytes was lower (27%) than to young erythrocytes and even lower following treatment with sialidase (82%), exhibiting a clustered, non-continuous labeling pattern in all three erythrocyte populations, thus showing a possible redistribution of WGA binding sites. The decrease in bound WGA/gold particles correlates well with the previously reported decrease in surface sialic acid on old erythrocytes. The binding of WGA/gold are indicative of the changes occurring on erythrocyte membrane surfaces when interacting with different agglutinins.     

Differences in intramembrane particle distribution in young and old human erythrocytes

The distribution of intramembrane particles in human erythrocytes was studied by freeze-fracture on young and old cells and compared to that obtained after ATP depletion or following addition of a clustering agent. It was shown that intramembrane particles became aggregated and the mean particle density increased as the cells aged. Likewise, both particle aggregation and increased density were found in young cells after moderate ATP depletion. In contrast, mean particle density was markedly reduced in both cell types after exhaustive depletion. Paradoxically, Zn treatment led to decreased particle density in young cells, whilst producing the opposite effect in aged cells. The results suggest that their low ATP content may account for the increased particle density of senescent cells.     

Binding of lectins to "young" and "old" human erythrocytes

"Old" human erythrocytes showed a 21.2% decrease in cell surface area and a 2% decrease in the number of WGA receptor sites, but a 27% increase in the distribution density of the WGA (lectin) receptor site, when compared with "young" human erythrocytes. For a list of lectin abbreviations, see Materials and methods). Both "young" and "old" erythrocytes exhibited very weak binding activity for 125I-labeled PNA, but there was no difference in binding activity for PNA between "young" erythrocytes and "old" ones. Compared with "young" erythrocytes, decreases in the number and distribution density of receptor sites for five lectins including LPA, Con A, RCA-II, SBA and BPA on the cell surface were observed in aged erythrocytes. "Old" erythrocytes also showed a decrease in the number of PHA-E receptor sites, while the distribution density of the same receptor site remained unchanged. In view of these and other observations, it is thought that human erythrocyte aging is accompanied by elimination of some glycoconjugates which have affinity for six lectins, LPA, Con A, RCA-II, PHA-E, SBA and BPA, whereas no WGA receptor-containing glycoconjugates are released from erythrocyte membranes. Elimination of the glycoconjugates results in shrinkage of erythrocytes to reduce their cell surface areas.     

Confocal Raman microscopy on single living young and old erythrocytes

Raman confocal microscopy, including the techniques of point Raman spectra, line mapping, 2D mapping, and time-dependent spectrum monitoring performed with 514.5 nm excitation light, was used in a comparative study on the distribution and oxidation states of hemoglobin (Hb) in young and old mature erythrocytes. It is demonstrated that in contrast to the homogeneous distribution of the Hb in young cells, there are more Hb distribution around the cell membrane in old erythrocyte. The proteins exhibit some extent of aggregation and conformational change, present less ability of oxidation, and lower oxygenation speed than the Hb in young erythrocytes. Our results also provide the first direct evidence of some intermediate oxygenated states of Hb between the two fully oxygenated (R) and deoxygenated (T) states in living erythrocyte, and give detail information about the conformational change of the intracellular Hb with time during the reoxygenation process. (c) 2008 Wiley Periodicals, Inc. Biopolymers 89: 951-959, 2008.This article was originally published online as an accepted preprint. The "Published Online" date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com.     

Morphological characterization of exovesicles and endovesicles released from human erythrocytes following treatment with amphiphiles.

In order to morphologically characterize exo- and endovesicles released during treatment of erythrocytes with amphiphiles and to look for possible amphiphile-specific effects on the vesiculation pattern, human erythrocytes were treated at 37 degrees C with amphiphiles at concentrations where they exhibit maximum protection against hypotonic haemolysis (cAHmax). Released exo-and endovesicles and treated cells were studied by means of transmission (TEM) and scanning (SEM) electron microscopy. All sphero-echinocytogenic amphiphiles induced a release of both spherical and tubular exovesicles. Dodecyl maltoside, a nonionic amphiphile with a bulky polar head, induced a release of predominantly tubular exovesicles, while all other sphero-echinocytogenic amphiphiles induced a release of predominantly spherical exovesicles. Some branched tubular exovesicles were released by a double-chained cationic amphiphile. Tail- and tongue-like structures were often seen on the exovesicles. Spherical exovesicles were frequently invaginated. Stomatocytogenic amphiphiles induced endovesiculation. In erythrocytes treated with most of the stomatocytogenic amphiphiles the endovesicles were clustered, but with some amphiphiles the endovesicles were randomly distributed. Large ringformed endovesicles (octaethyleneglycol alkyl ethers) and endovesicles in chains (octyl and decyl glucopyranoside) also occurred. The endovesicle membrane was often budding onto the lumen of the vesicle and in some cases this could ultimately lead to a vesicle inside the endovesicle. We conclude that amphiphiles do not only trigger vesiculation, but may also specifically affect the vesiculation processes.     

Comparative study on fluorescent probes distributed in human erythrocytes and platelets

Important cellular functions, such as rheological properties of cells are presumably related to the membrane lipid fluidity which may be approached by the use of fluorescence polarization method. However, biological membranes represent very heterogeneous media and the knowledge of the fluidity of membrane compartments requires the use of different probes. Two fluorescent probes, DPH and its cationic derivative, TMA-DPH, have been employed to probe the lipid fluidity of human platelets and red cell membranes. The results show that the informations given by DPH and TMA-DPH can present important differences, suggesting that DPH and TMA-DPH are localized in different regions of cell membranes. In an attempt to investigate relations between lipid fluidity and rheological properties of red cells, the behavior of probes was studied in a "Couette" viscometer with a device for studying the emissive properties of probes when red cell membranes are under shear conditions.     

Parameters of bioimpedance spectroscopy in young and old erythrocytes

The parameters of bioimpedance spectroscopy (BIS) were studied in suspensions of young and old erythrocytes. The separation of erythrocytes according to age in a density gradient was performed. The BIS parameters, including the extracellular (Re) and intracellular (Ri) fluid resistances, characteristic frequency (Fchar), cell membranes’ capacitance (Cm), and the Alpha parameter of concentrated suspensions of young and old erythrocytes (n = 6) were measured using an ABC-01 Medass bioimpedance analyzer in the frequency range 5–500 kHz. Re (300.4 ± 30.0 and 261.2 ± 21.8 Ω in old and young erythrocytes, respectively, p < 0.05), Ri (86.6 ± 9.1 Ω and 73.4 ± 7.3 Ω in old and young erythrocytes, respectively, p < 0.001), and Alpha (0.305 ± 0.003 and 0.302 ± 0.001 in old and young erythrocytes respectively, p < 0.05) were greater in the suspension of old erythrocytes than in the suspension of young erythrocytes; and Fchar (308.3 ± 42.0 kHz and 347.4 ± 48.0 kHz in old and young erythrocytes, respectively, p < 0.05) and Cm (99.3 ± 10.1 pF and 112.8 ± 6.3 pF in old and young erythrocytes, respectively, p < 0.01) were less in the suspension of old erythrocytes than in the suspension of young erythrocytes. These differences between the BIS parameters of old and young erythrocytes were possibly due to the structural change in erythrocytes during aging (an increase in the concentration of intracellular hemoglobin, the change in the shape of the erythrocyte, their converging due to the decrease in cellular negative surface charge, and an increase in membrane permeability to ions). Thus, the BIS parameters depend on the erythrocyte age composition.     

Bioimpedance spectroscopy parameters of suspensions of young and old erythrocytes

The bioimpedance spectroscopy (BIS) parameters of the suspensions of young and old erythrocytes were studied. The separation of the erythrocytes by age was made by density gradient. The BIS parameters: extracellular (Re) and intracellular (Ri) fluid resistance, characteristic frequency (Fchar), cell membranes capacitance (Cm) and Alpha parameter of concentrate suspensions of young and old erythrocytes were measured on the BIA analyzer ABC-01 "Medass" in the frequency range 5-500 kHz. It was found that Re (300.4 +/- 30.0 Ohm and 261.2 +/- 21.8 Ohm for old and young respectively, p < 0.05), Ri (86.6 +/- 9.1 Ohm and 73.4 +/- 7.3 Ohm for old and young respectively, p < 0.001) and Alpha (0.305 +/- 0.003 and 0.302 +/- 0.001 for old and young respectively, p < 0.05) of the old erythrocytes suspensions were higher, than of the young one, and Fchar (308.3 +/- 42.0 kHz and 347.4 +/- 48.0 kHz for old and young respectively, p <0.05) and Cm (99.3 +/- 10.1 pF and 112.8 +/- 6.3 pF for old and young respectively, p < 0.01) of the old erythrocytes were lower, than of the young one. The found differences between electrical properties of the suspensions of young and old erythrocytes were obviously determined by the alterations of the red blood cells during aging (growth of intracellular hemoglobin concentration, erythrocytes rapprochement because of diminishing of surface negative charge, increase of red blood cell sphericity and cell membrane permeability for ions). Thus the BIS parameters are related to the erythrocyte aging.     

Aging human erythrocytes. Differential sensitivity of young and old erythrocytes to hemolysis induced by peroxide in the presence of thyroxine.

Human erythrocytes were separated according to cell age using albumin density gradients. In the presence of glucose (100 mg%), young cells were able to effectively protect themselves against thyroxine-peroxide induced hemolysis; old cells exhibited less protection. Hemolysis in heterogeneous populations is preceded by lipid peroxidation, K⁺ leak and decreased filtrability of the cells. Hydroxy radical scavengers partially inhibited hemolysis while superoxide dismutase had no effect. It is postulated that the differential sensitivity of young and old erythrocytes to thyroxine-peroxide induced metabolic and morphological alterations may play a role in the recognition and removal of senescent cells from the circulation.     

Calcium pump phosphoenzyme from young and old human red cells

An increase in intracellular Ca(2+) occurs during ageing of human erythrocytes in vivo. The aged cells show a reduced capacity for active Ca(2+) extrusion. Such a defect may arise from pump proteolysis, due to calpain activation by the raised intracellular Ca(2+). To test this possibility, Ca(2+) pump phosphorylation by [gamma-(32)P]ATP was studied on percoll-separated young and old human erythrocytes. After phosphorylation for 30 s with Ca(2+), the amount of phosphoenzyme produced by the young cell membranes was 50% that of the old cells. With Ca(2+) plus La(3+), in contrast, the phosphoenzyme level was nearly the same in both preparations. After a prolonged phosphorylation period (50-90 s), the phosphoenzyme reached almost identical equilibrium levels in both membrane preparations. On the other hand, a single Ca(2+)-dependent radioactive band of about 150 kDa was apparent in both preparations after acidic electrophoresis. Likewise, Western blotting using 5F10 monoclonal antibody also detected a single band of similar molecular weight. These results demonstrate that there is no alteration in either molecular mass or number of active Ca(2+) pump units during cell ageing, thus indicating that the reduced Ca(2+) pumping activity of aged cells does not arise from pump proteolysis.     

Measurement of intracellular Ca2+ in young and old human erythrocytes using 19F-NMR spectroscopy.

Elevated cell calcium has been implicated in functional changes with human erythrocyte aging. However, until recently it has been difficult to measure free ionic intracellular calcium in red cells. We have made use of a fluorinated calcium chelator probe (5,5'-difluoroBAPTA) and fluorine nuclear magnetic resonance (19F-NMR) techniques to measure changes of intracellular Ca2+ concentrations ([Ca2+]i) with cell aging. We have demonstrated in these studies that human erythrocyte [Ca2+]i is significantly elevated as a function of in-vivo aging. Young cells, the least dense fraction of density-separated erythrocytes, contained an average of 62 (+/- 4) nM Ca2+ (+/- S.E.), whereas the oldest, most dense cell fraction contained 221 nM Ca2+ (+/- 25). Mechanisms by which intracellular [Ca2+] increases with in-vivo aging are currently under investigation.