Phosphoinositide metabolism and the morphology of human erythrocytes

ATP-depleted human erythrocytes lose their smooth discoid shape and adopt a spiny, crenated form. This shape change coincides with the conversion of phosphatidylinositol-4,5-bisphosphate to phosphatidylinositol and phosphatidic acid to diacylglycerol. Both crenation and lipid dephosphorylation are accelerated by iodoacetamide, and both are reversed by nutrient supplementation. The observed changes in lipid populations should shrink the membrane inner monolayer by 0.6%, consistent with estimates of bilayer imbalance in crenated cells. These observations suggest that metabolic crenation arises from a loss of inner monolayer area secondary to the degradation of phosphatidylinositol-4,5-bisphosphate and phosphatidic acid. A related process, crenation after Ca2+ loading, appears to arise from a loss inositides by a different pathway.     

Fibrinogen and the ultralong-range interaction of human erythrocytes

Fibrinogen, purified by a new method, does not transmit the ultralong-range interaction of erythrocytes. It can be converted into a transmitter by the addition of a preparation of clotting factors used clinically in the treatment of hemophilia B. It is suggested that the addition of the clotting factors induces a conformational change in fibrinogen, which can then polymerize.     

The interaction of 1-fluoro-2,4-dinitrobenzene with amino-phospholipids in membranes of intact erythrocytes,modified erythrocytes,and erythrocytes ghosts

Summary 1-Fluoro-2,4-dinitrobenzene (FDNB) has been used to study the availability of amino-containing phospholipids in erythrocyte membranes and ghosts in an aqueous, isotonic medium. It was found that the addition of bovine serum albumin (BSA) to the medium protects the cells from cation leak and protects some of the amino-phospholipids from reacting with the probe. In isotonic medium without BSA, 46% of the phosphatidylethanolamine and 12% of the phosphatidylserine of erythrocytes and 73% and 21% of these respective lipids of ghosts react with the probe. In the presence of 70 m BSA, 31% of phosphatidylethanolamine and 6.5% of phosphatidylserine of erythrocytes and 59% and 16% of these respective lipids of ghosts react with the probe. The labeling of these lipids does not change under conditions of varying tonicity, or after treatment of erythrocytes with pronase or lysolecithin. The data suggest that 46% of phosphatidylethanolamine and 12% of phosphatidylserine of the erythrocyte membrane are free in a lipid bilayer; 27% and 9% of these respective lipids are loosely bound to proteins which are lost during the preparation of ghosts and 27% of the phosphatidylethanolamine and 79% of the phosphatidylserine are tightly bound to core proteins which remain part of the erythrocyte membrane even after hemolysis.     

Thermohemolysis of erythrocytes

Thermohemolysis kinetic curves of erythrocytes in the temperature interval of 37-75 degrees C in different media and in the course of blood storage were studied. Mechanism of thermohemolysis is proposed. The rate constants of hemolysis stages are introduced. It is shown that these parameters are sensitive to the changes of structural state of erythrocytes.     

Microencapsulation of erythrocytes

Human erythrocytes have been encapsulated in a polyacrylate membrane by a simple precipitation process. The encapsulated cells appeared to remain functional after encapsulation: the consumption of glucose and the ability to reversibly bind oxygen was unimpaired. Furthermore, storage at 4°C for almost 6 months had no effect on the P₅₀ and n₅₀ values. This is the first time to our knowledge that live mammalian cells have been encapsulated in a polymer other than alginate.     

Interfacial instability and the agglutination of erythrocytes by polylysine

Human erythrocytes have been exposed to poylysine of molecular weight range 4 to 220 kDa and concentration range 0.5 to 2,000 /ml at 37°C. Threshold concentrations for cell agglutination by the polycation have been determined for the samples of different molecular weight. Light and electron micrographs show that, in the erythrocyte agglutinates, cell-cell contact is generally made only at discrete, spatially periodic, regions which are distributed over a significant part of the cell surface. The average spacing between contact regions is 0.83 m. The cell membrane has a wavy profile between contact regions. Agglutination occurs only in cell samples whose electrophoretic mobility is significantly altered by polylysine and, in agreement with a previous report, occurs even when the electrophoretic mobility reaches high positive values. The electrophoretic mobility data implies that agglutination requires some protrusion of polylysine from the cell glycocalyx. We discuss how a resulting net attractive intercellular force could act to destabilize the aqueous layer between two cells, allowing surface wave growth which results in spatially periodic contact regions. Examples of situations where cell and membrane contact might be explained by the general concept of interfacial instability are discussed.     

Tissue-specific histones in the erythrocytes of chicken and turtle

Mature erythrocytes from Leghorn chickens contain lysine-rich histone F1 and a tissue-specific histone F2c. The composition of the F1 fraction was found to be similar to the F1 histones in higher vertebrates. In the erythrocytes of a sea turtle (Chelonia mydas), only lysine-rich histones F1 could be detected. One of these fractions (F1b) differed in amino acid composition from the typical F1 histones described in the literature. The F1b histone fraction was not found in turtle liver. Chromatographic analysis of tryptic peptides of the chicken erythrocyte F1 and F2c histones and of the turtle erythrocyte F1a and F1b histones revealed considerable similarities between these four fractions, thus indicating their possible phylogenetic relationships.     

Phospholipid composition of plasma and erythrocytes in the neonate

The total phospholipids and their various classes in erythrocytes and blood plasma were determined quantitatively by means of two-dimensional thin-layer chromatography. The total amount of phospholipids in neonate plasma was approximately half of that found in adult plasma, however, the amount of phospholipids in erythrocytes of the neonate was significantly higher. The differences were observed in some classes of phospholipids in the plasma and erythrocytes of neonates as well as adult human beings.     

Peroxidation of liposomes in the presence of human erythrocytes and induction of membrane damage of erythrocytes by peroxidized liposomes

Hemolysis (Kobayashi, T., Takahashi, K., Yamada, A., Nojima, S. and Inoue, K. (1983) J. Biochem. 93, 675-680) and shedding of acetylcholinesterase-enriched membrane vesicles (diameter 150-200 nm) were observed when human erythrocytes were incubated with liposomes of phosphatidylcholine which contained polyunsaturated fatty acyl chains. These events occurring on erythrocyte membrane were inhibited by radical scavengers or incorporation of alpha-tocopherol into liposomes, suggesting that lipid peroxidation is involved in the process leading to membrane vesiculation and hemolysis. The idea was supported by findings that generation of chemiluminescence, formation of thiobarbituric acid reactive substance, accumulation of conjugated diene compounds in liposomes and decrease of polyunsaturated fatty acids in liposomes occurred concomitantly during incubation. Hemolysis was also suppressed by the addition of extra liposomes, insensitive to peroxidation, or of serum albumin even after the completion of peroxidation of liposomes. These results suggest that peroxidized lipids, responsible for vesiculation and hemolysis, may be formed first in liposomes and then gradually transferred to erythrocyte membranes. The accumulation of these lipids peroxides may eventually cause membrane vesiculation followed by hemolysis.