Proteins and glycoproteins of membranes from developing chick red cells

A Comprehensive Review of Our Current Understanding of Red Blood Cell (RBC) Glycoproteins

Human red blood cells (RBC), which are the cells most commonly used in the study of biological membranes, have some glycoproteins in their cell membrane. These membrane proteins are band 3 and glycophorins A-D, and some substoichiometric glycoproteins (e.g., CD44, CD47, Lu, Kell, Duffy). The oligosaccharide that band 3 contains has one N-linked oligosaccharide, and glycophorins possess mostly O-linked oligosaccharides. The end of the O-linked oligosaccharide is linked to sialic acid. In humans, this sialic acid is N-acetylneuraminic acid (NeuAc). Another sialic acid, N-glycolylneuraminic acid (NeuGc) is present in red blood cells of non-human origin. While the biological function of band 3 is well known as an anion exchanger, it has been suggested that the oligosaccharide of band 3 does not affect the anion transport function. Although band 3 has been studied in detail, the physiological functions of glycophorins remain unclear. This review mainly describes the sialo-oligosaccharide structures of band 3 and glycophorins, followed by a discussion of the physiological functions that have been reported in the literature to date. Moreover, other glycoproteins in red blood cell membranes of non-human origin are described, and the physiological function of glycophorin in carp red blood cell membranes is discussed with respect to its bacteriostatic activity.

Structure of a sialo-oligosaccharide from glycophorin in carp red blood cell membranes

We isolated a high-purity carp glycophorin from carp erythrocyte membranes and prepared the oligosaccharide fraction from glycophorin by β-elimination [1]. The oligosaccharide fraction was separated into two components (P-1 and P-2) using a Glyco-Pak DEAE column. These O-linked oligosaccharides (P-1 and P-2) were composed of glucose, galactose, fucose, N-acetylgalactosamine and N-glycolylneuraminic acid (NeuGc). The P-1 and P-2 contained one and two NeuGc residues, respectively, and the P-1 exhibited bacteriostatic activity [1]. Using NMR and GC-MS, we determined that the structure of the bacteriostatic P-1 was NeuGcα2→6 (Fucα1→4) (Glcα1→3) Galβ1→4GalNAc-ol. This O-linked oligosaccharide was unique for a vertebrate with respect to the hexosamine and hexose linkages and its non-chain structure.

Isolation and characterization of glycophorin from carp red blood cell membranes

We isolated a high-purity carp glycophorin from carp erythrocyte membranes following extraction using the lithium diiodosalicylate (LIS)-phenol method and streptomycin treatment. The main carp glycophorin was observed to locate at the position of the carp and human band-3 proteins on an SDS-polyacrylamide gel. Only the N-glycolylneuraminic acid (NeuGc) form of sialic acid was detected in the carp glycophorin. The oligosaccharide fraction was separated into two components (P-1 and P-2) using a Glyco-Pak DEAE column. We observed bacteriostatic activity against five strains of bacteria, including two known fish pathogens. Fractions from the carp erythrocyte membrane, the glycophorin oligosaccharide and the P-1 also exhibited bacteriostatic activity; whereas the glycolipid fraction and the glycophorin fraction without sialic acid did not show the activity. The carp glycophorin molecules attach to the flagellum of V. anguillarum or the cell surface of M. luteus and inhibited bacterial growth.

A mixing chamber to enucleate avian and fish erythrocytes: preparation of their plasma membrane

Biochemical studies of the plasma membrane and the cytoskeleton of nucleated erythrocytes are strongly limited by the difficulties encountered in enucleating large quantities of cells. We describe an easily built hydrodynamic system which allows rapid preparation of large amounts of avian and fish erythrocyte plasma membranes. The contents of two 25-ml syringes containing hemolyzed nucleated erythrocytes are forced through four capillaries to a specially designed mixing chamber which fills a collecting syringe. The 50-ml erythrocyte suspension can be processed in 2 s. The high speed flow is achieved with a hand-activated piston. The turbulences in the mixing chamber are carried to an optimal efficiency by the vis-à-vis disposition of the four mixing jets. The enucleated membranes are separated from the nuclei and residual nucleated cells by differential centrifugations. They do not show contamination with nuclear material. Erythrocytes from chicken and trout have been used. They present striking differences in their stability toward hydrodynamic disruption, erythrocytes from chicken being far more stable. Ninety-five percent of trout erythrocytes are enucleated after only one run through the mixing chamber. Two runs performed at the maximal flow rate are necessary to enucleate chicken erythrocytes with a yield of 80%. In the former case most of the purified enucleated plasma membranes are fragmented in small vesicles while they retain a large size in the case of chicken erythrocytes. The proteins of the membranes thus prepared are characterized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis: we found that erythrocyte membranes from trout are remarkable for their small spectrin content compared to those from chicken.

N-acetyl-9-O-acetylneuraminic acid, the receptor determinant for influenza C virus, is a differentiation marker on chicken erythrocytes

Erythrocytes from chicken of different age were analysed for their agglutinability by influenza C virus, which has been shown recently to use N-acetyl-9-O-acetylneuraminic acid as a high-affinity receptor determinant for the attachment to cells. Only with birds not younger than six days complete agglutination of the erythrocytes was observed. The hemagglutination titer which was initially low reached its maximum value at the age of about 20 days. Sialic acid was isolated from erythrocytes, purified and analysed by colorimetry, thin-layer chromatography, high-performance liquid chromatography, and gas-liquid chromatography-mass spectrometry. The sialic acid content of erythrocytes from one-day old and adult chicken was 21 micrograms and 18 micrograms sialic acid/ml packed erythrocytes, respectively. While N-acetylneuraminic acid was the major type of sialic acid on erythrocytes from both one-day old and adult chicken, N-acetyl-9-O-acetylneuraminic acid was only detected on red blood cells from adult animals accounting for 30-40% of total sialic acid. These results indicate that N-acetyl-9-O-acetylneuraminic acid, in addition to serving as a receptor determinant for influenza C virus, represents a developmental marker on chicken erythrocytes.

Comparison of human and pigeon erythrocyte membrane proteins by one- and two-dimensional gel electrophoresis

Pigeon and human bands 1 and 2 (spectrin) and 5 (actin) are conserved. Band 3 anion porters have similar SDS positions, but the pigeon porter has a higher isoelectric point. Both anion porters are inhibited by similar doses of pyridoxal phosphate. Many differences are apparent in minor bands.

Determination of polypeptide chain molecular weights of human and bovine band 3 protein from erythrocyte membranes by low-angle laser light scattering combined with high-performance gel chromatography in the presence of sodium dodecyl sulfate

Polypeptide chain molecular weights of human and bovine band 3 proteins which are glycoproteins of the erythrocyte membrane were determined as 101,000 +/- 2000 for the former and 107,000 +/- 2000 for the latter by using the low-angle laser light scattering technique combined with a high-performance gel chromatography column, an ultraviolet spectrophotometer and a differential refractometer in the presence of sodium dodecyl sulfate. The advantage of this method is that, unlike the sedimentation equilibrium technique, neither information on the binding to proteins of all ligands present nor the partial specific volume is required to evaluate the polypeptide chain molecular weight of proteins in a multicomponent system.

Locus of N-ethylmaleimide action on sugar transport in nucleated erythrocytes

Goose red blood cells were studied as a model for metabolic regulation of sugar transport. In contrast to their action in human erythrocytes, sulfhydryl-blocking agents such as N-ethylmaleimide (NEM) stimulated 3-O-methylglucose transport markedly in goose red blood cells. The effect of NEM was further enhanced when adenosine 5'-triphosphate (ATP) was first depleted by 2,4-dinitrophenol treatment or anoxia. Only sulfhydryl-blocking agents that enter the cell were effective transport stimulators, and the effect was not altered by substrates of the transporter. In nucleated red blood cell ghosts, NEM inhibited 3-O-methylglucose transport. Results of these studies with intact cells were consistent with the hypothesis that free sulfhydryl groups are essential for regulation of transporter activity rather than for the transport process itself. The locus of NEM action appears to be either on the cytoplasmic side of the membrane or partially located in the cytoplasm. ATP depletion may expose previously masked sulfhydryl groups, producing an enhanced reaction with sulfhydryl-blocking agents and a highly stimulated rate of sugar transport.

Alprenolol binding and cyclic AMP production in embryonic chick red cells during erythropoiesis

We have measured alprenolol binding and cyclic AMP production in erythroid cells taken from chick embryos incubated from 8 days to hatching and in cells from the adult. Beta-adrenergic receptor number and affinity measured by alprenolol binding are essentially unchanged in red cell membranes prepared from 8- through 17-day embryos. Receptor number was found to be half as much in the adult. Erythroid cells from embryos of all ages studied show stimulation of cyclic AMP production when incubated with epinephrine, and most of the cyclic AMP produced remains intracellular. Inasmuch as the cells from younger embryos can in fact produce cyclic AMP, the previously-reported lack of epinephrine sensitivity of cation transport in the red cells of younger embryos (Wacholtz et al., 1978) cannot be attributed to the lack of functional receptors or to an impairment of cyclic AMP production.

Plasmodium lophurae: membrane proteins of erythrocyte-free plasmodia and malaria-infected red cells

Plasma membranes of normal duckling erythrocytes were prepared by blender homogenization and nitro-en decompression. Surface membrane vesicles of red cells infected with the avian malaria Plasmodium lophurae were produced by nitrogen decompression. Membranes of erythrocyte-free malaria parasites were removed from cytoplasmic constituents by Dounce homogenization. These membranes were collected by centrifugation in a sucrose step gradient and purified on a linear sucrose gradient. Red cell membranes had a buoyant density of 1.159 g/cm3, whereas plasmodial membranes banded at 2 densities: 1.110 g/cm3 and 1.158 g/cm3. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the isolated red cell membranes revealed 7 major protein bands with molecular weights (MW) ranging from 230, 000 to 22,000, and 3 glycoprotein bands with MW of 160,000, 88,000 and 37,000. Parasite membranes also had 7 major bands with MW ranging from 100,000 to 22,000. No glycoproteins were identifiable in these membranes. The proteins of the surface membranes from infected red cells had MW similar to those from normal red cells; however, there was some evidence of a reduction in the amount of the high MW polypeptides. The red cell membrane contained 79 nmoles sialic acid/mg membrane protein, whereas plasmodial membranes had 8 nmoles sialic acid/mg membrane protein. The sialic acid content of the surface membranes of infected red cells was significantly smaller than that of normal cells. Lactoperoxidase-glucose oxidase-catalyzed iodination of intact normal and malaria-infected erythrocytes labeled 7 surface components. Although no observable differences in iodinatable proteins were seen in these preparations, there was a striking reduction in the iodinatability of erythrocytic membranes obtained from P. lophurae-infected cells. Erythrocyte-free plasmodia bound very little radioactive iodine; the small amount of radioactivity was distributed among 3 major bands with MW of 42,000, 32,000 and 28,000. It is suggested that the alterations of the surface of the P. lophurae-infected erythrocyte do not occur by a wholesale insertion of plasmodial membrane proteins into the red cell plasma membrane, but rather that there are parasite-mediated modifications of existing membrane polypeptides.

Changes in membrane structure and function during chick embryonic erythropoiesis

We found considerable differences in the pattern of membrane proteins as well as in the relative amounts of individual components in isolated chick red blood cell membranes during the course of embryonic development. Of special interest in the increase in the relative amounts of two major polypeptides, band 3 and 3.1 (MW 100,000 daltons) with increasing age of the cells. With respect to functional studies, we found that the magnitude of sulfate influx decreases with increasing age of the embryo. Furthermore, the activity of ouabain-sensitive ATPase increases with increasing age (2.5-day embryo to adult). In addition, both the basal and the fluoride-stimulated adenylate cyclase activities decrease as the embryo age increases, whereas the enzyme sensitivity to epinephrine increases with increasing age of the embryo.

Asynchronous termination of plasma membrane protein synthesis in erythroid cells

In this study we focused our attention on the terminal stages of cellular differentiation and asked the question whether the turning off of gene activity is via a general mechanism whereby all proteins are turned off synchronously, or if it is regulated specifically. We examined this problem by measuring the relative rates of synthesis of the plasma membrane proteins in cells that are near the final stages of erythroid differentiation. Our results show that although the rates of synthesis of all proteins decline during maturation the relative rates of decline are different among the various membrane proteins, indicating that the termination of plasma membrane protein synthesis during terminal differentiation is asynchronous.