Expression of the major red cell sialoglycoprotein, glycophorin A, in the human leukemic cell line K562.

We have found that the human leukemic cell line K562 (Lozzio, C.B., and Lozzio, B.B. (1975) Blood 45, 321-334) synthesizes a surface membrane glycoprotein which is identical or closely similar to the major red cell sialoglycoprotein, glycophorin A. The protein can be precipitated by specific anti-glycophorin A antiserum both from surface-labeled and metabolically labeled K562 cells. Cyanogen bromide cleavage of glycophorin A from red cells and the K562 cell protein gives apparently identical fragments, and the glycopeptides and oligosaccharides obtained after Pronase and mild alkaline treatment are closely similar. An antiserum made against intact K562 cells and absorbed with normal human white blood cells precipitated surface-labeled glycophorin A from erythrocytes. The amount of glycophorin A per cell in erythrocytes and K562 cells was very similar when determined by radioimmunoassay. The K562 cells contained blood group MN activity when tested with rabbit anti-M and anti-N sera. When incubated at 37 degrees C with rabbit anti-glycophorin A F(AB)2 fragments and fluorescent sheep anti-rabbit IgG, partial redistribution of glycophorin A (patching and capping) was seen in K562 cells but not in erythrocytes.     

Organization of membrane lipids and proteins in human En(a-) erythrocytes that lack the major sialoglycoprotein, glycophorin A. A spin-label study.

Membrane fluidity was studied by electron-spin-resonance techniques in human En(a-) erythrocytes that lack the major membrane sialoglycoprotein, glycophorin A. By using stearic acid spin labels with a doxyl group in the C-12 or C-15 positions, we demonstrated that the hydrophobic core in these cells was more fluid than in normal cells. Surface-located regions in isolated En(a-) membranes, when probed with stearic acid labelled in the C-5 position, appeared more stable than in normal membranes. In isolated En(a-) membranes, protein motion was decreased when probed with a nitroxide derivative of maleimide. After incubation with anti-(glycophorin A) antibodies protein motion and membrane fluidity were increased in normal membranes. This effect was observed also after spectrin depletion, which by itself increased protein motion but decreased membrane fluidity in the hydrophobic core of the membrane. The results show that membrane proteins influence the fluidity of membrane lipids.     

The major sialoglycoprotein of human T-lympocytes

Human, peripheral-blood T-lymphocytes and human, T-lymphoblastoid cells of a MOLT 4B cell-line were surface-labeled by lactoperoxidase-catalyzed iodination, periodate and sodium borotritide, and galactose oxidase and sodium borotritide, and analyzed by dodecyl sodium sulfate-polyacrylamide gel-electrophoresis. Both types of cells were found to show a major, cell-surface sialoglycoprotein with an apparent mol. wt. of 95 000. After neuraminidase treatment, this glycoprotein showed a higher mol. wt. of 120 000. The major sialoglycoprotein of both types of cells bound to wheat-germ agglutinin and concanavalin A and, after neuraminidase treatment, to Arachis hypogaea agglutinin. The glycopeptides obtained from these glycoproteins by Pronase digestion gave similar elution-profiles on Sephadex G-50 gel filtration. These results suggest that the major sialoglycoprotein of normal T cells and that of MOLT 4B cells are very similar, if not identical.     

Evolution of glycophorin A in the hominoid primates studied with monoclonal antibodies, and description of a sialoglycoprotein analogous to human glycophorin B in chimpanzee

Comparison of human and primate erythrocyte membrane sialoglycoproteins showed that common chimpanzee, dwarf chimpanzee, gorilla, orangutan, and gibbon have major periodic acid Schiff-positive proteins resembling human glycophorin A (GPA) monomer and dimer in electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels. Immunoperoxidase staining of Western blots with monoclonal antibodies to human GPA showed that these primate bands express some GPA antigenic determinants. A new sialoglycoprotein analogous to human glycophorin B (GPB) was detected in common chimpanzee. Although human MN blood group phenotype results from an amino acid polymorphism of GPA, Western blots showed that in chimpanzee sialoglycoprotein (GPAch) always expresses the M blood group, whereas chimpanzee sialoglycoprotein (GPBch) expresses either the N blood group or a null phenotype. This result explains the detection of M and MN, but not of N, blood group phenotypes in chimpanzee. GPBch has higher apparent m.w. than human GPB, is present in the erythrocyte membrane in greater quantity than human GPB, and contains trypsin cleavage site(s) and the 10F7 determinant (both found on human GPA but not GPB). Expression of human GPA antigenic determinants was consistent with the phylogeny of the hominoid primates; common and dwarf chimpanzee expressed most of the determinants tested, gorilla and orangutan an intermediate number, and gibbon and siamang the least. Of the GPA antigenic determinants examined, the MN blood group determinants were most consistently expressed during evolution of the hominoid primates. The results suggested that variability in expression of GPA antigenic determinants between species was due to both differences in amino acid sequence and glycosylation.     

A revision of the N-terminal structure of sialoglycoprotein D (glycophorin C) from human erythrocyte membranes

The amino-acid sequence of the N-terminal tryptic glycopeptide of a minor sialoglycoprotein (component D, glycophorin C) from human erythrocyte membranes was re-investigated and revised at the positions 12, 44, 47 and 48. Based on these and previous (Dahr, W. et al., Eur. J. Biochem. 125, 57-62, 1982) studies, the fragment exhibits the following structure (one-letter-code for amino acids, + = glycosylation): (Formula: see text).     

Rearrangements of the red-cell membrane glycophorin C (sialoglycoprotein beta) gene. A further study of alterations in the glycophorin C gene.

We have cloned portions of the glycophorin C (sialoglycoprotein beta) gene from individuals with red cells of normal, Gerbich and Yus phenotypes. The clones contain up to three exons of the glycophorin C gene (designated exons 2, 3 and 4). Analysis by restriction mapping and DNA sequencing confirmed that the deletions causing the Gerbich and Yus phenotypes are located entirely within the glycophorin C gene. Sequencing of the normal gene showed that not only do exon 2 and exon 3 have related DNA sequences, but also that both the 5' and 3' flanking intronic DNA sequences are almost identical. The two variant genes each lack a different exon: the Yus type gene lacks exon 2, whereas the Gerbich-type gene lacks exon 3. We suggest that the observed deletions are due to recombination between the regions of homologous intronic repeats. We also provide evidence that an unequal cross-over mechanism may be responsible for a number of observed glycophorin C gene rearrangements, including an insertion mutation in Lewis II (Lsa)-type red cells that has not previously been reported.     

Common peptide epitopes in glycophorin and the endothelial sialoglycoprotein gp60.

Polyclonal anti-serum made against murine glycophorin gp3 (alpha gp) recognizes the endothelial albumin binding glycoprotein, gp60. In this study, we investigated the nature (peptide vs. carbohydrate) of the common epitope. First, a new technique was developed to remove oligosaccharides from glycoproteins that were first immobilized on filters and then subjected to beta-elimination. When greater than 90% of the glycans of gp60 were removed, alpha gp still recognized gp60 without apparent loss of affinity. Second, we used brefeldin A to accumulate unglycosylated glycophorin precursors in order to affinity-purify peptide-specific alpha gp immuno-globulins; these antibodies recognized gp60. Finally, alpha gp recognized from in vitro translations a 48 kDa putative polypeptide precursor of gp60. These different approaches indicate that gp60 and gp3 have at least one common epitope in their peptide backbones.     

Leukosialin, a major sialoglycoprotein on human leukocytes as differentiation antigens

Most blood cells derived from the bone-marrow are known to possess only a limited number of heavily sialylated glycoproteins. We have recently isolated a major sialoglycoprotein on leukocytes and found that this glycoprotein, termed leukosialin, is ubiquitously present on various human leukocytes, granulocytes, monocytes/macrophages and T- and B-lymphocytes. Our studies showed that leukosialin is significantly glycosylated by O-linked oligosaccharides (90 chains/molecule). The structures of those O-linked oligosaccharides are characteristic to each cell lineage and maturation stage. The polypeptide portion of these molecules are, however, apparently the same, with a molecular size of 52 KDa. So it will be interesting to explore the possibility that leukosialin expresses different functions by having different O-glycosylation in a variety of hematopoietic cells.     

Isolation and characterization of leukosialin, a major sialoglycoprotein on human leukocytes

A major sialoglycoprotein (previously called gp105) on the human erythroleukemic cell line K562 was purified, and specific antibodies were raised in a rabbit. A number of different hematopoietic cell lines belonging to erythroid, myeloid, T-lymphoid, and B-lymphoid cell lineages were found to possess glycoproteins that were immunoprecipitated by these antibodies. However, the apparent molecular weights differed between cell lines, ranging from 113,000 to 150,000. In almost all cases, the immune precipitated molecule corresponded to the major sialoglycoprotein of the respective cell. Pulse-chase experiments showed that all cells produced an early precursor form of the molecule of 54 kDa, which was susceptible to endo-beta-N-acetylglucosaminidase H to give an apoprotein of 52 kDa. Neuraminidase treatment of the mature forms resulted in a characteristic decrease of the mobility in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (apparent molecular weights from 150,000 to 183,000). Amino acid analysis of the glycoprotein isolated from HL-60 cells showed a high content of serine, threonine, and proline, and the carbohydrate composition was compatible with the presence of a large number (approximately 90) of O-linked carbohydrate chains. The name leukosialin is proposed for this sialoglycoprotein, which seems to be widely distributed, but differently glycosylated, on leukocytes with diverse functions. In the following paper (Carlsson, S.R., Sasaki, H., and Fukuda, M. (1986) J. Biol. Chem. 261, 12787-12795), we demonstrate that the structures of O-linked oligosaccharides vary significantly depending on the cells from which leukosialin was isolated.     

Isolation and properties of gamma protein,the major transmembrane sialoglycoprotein of the HeLa cell

The surface of the HeLa cell is composed of a heterogeneous population of sialogly coproteins which undergo lectin-mediated endocytosis (Kramer and Canellakis, Biochim Biophys Acta 551:328, 1979). One such sialoglyco-protein, gamma protein, is the major periodate-Schiff-reactive and [³H]-glucosamine-labeled component of the plasma membrane; it has an apparent molecular weight of 165,000. Gamma protein is also the major [¹²⁵I]-wheat germ agglutinin-binding component in sodium dodecyl sulfate gels. Neuraminidase digestion of HeLa cells abolishes binding of [¹²⁵I]-wheat germ agglutinin to gamma protein, and pretreatment of cells with wheat germ agglutinin protects gamma protein from desialation by neuraminidase. suggesting that wheat germ agglutinin binds to the sialic acid residues of gamma protein at the cell surface. Gamma protein can be extracted with various detergents but not with high-salt, chelating, or chaotropic agents. Intact inside-out plasma membrane vesicles have been prepared from HeLa cells that had phagocytosed latex particles. Treatment of these isolated vesicles with trypsin reduces the molecular weight of gamma protein. These results suggest that gamma protein is an integral membrane protein that spans the plasma membrane. Gamma protein can be purified to homogeneity by sequential lithium diiodosalicylate-phenol extraction, wheat germ agglutinin-agarose affinity chromatography, and preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Freeze-fracture electron microscopy of human erythrocytes lacking the major membrane sialoglycoprotein

Human erythrocytes of blood group En (a-), a rare homozygous condition involving a complete lack of the major sialoglycoprotein of the cell membrane (glycophorin A), were compared with erythrocytes from normal (En(a+)) individuals by freeze-fracture electron microscopy. No decrease in number, or variation in morphology, of the intramembranal particles of En (a-) cells was detectable. These results show that the erythrocyte sialoglycoprotein is not essential for the maintenance of the integrity of the intramembranal particles of the human erythrocyte membrane.     

Isolation and partial characterization of the major sialoglycoprotein of human T-lymphoblastoid cells of a MOLT-4B cell line.

A sialoglycoprotein with an approx. mol.wt. of 95000 was isolated from human lymphoblastoid cells of a MOLT-4B cell line, which was of human T-lymphocyte origin, by ion-exchange chromatography, affinity chromatography on a column of wheat-germ agglutinin-Sepharose and preparative slab-gel electrophoresis. The localization of this glycoprotein on the cell surface was indicated by surface labelling by the periodate/NaB3H4 and lactoperoxidase-catalysed iodination methods. Carbohydrate analyses of this glycoprotein revealed that its total carbohydrate content is 28% (w/w), and it contains fucose, galactose, mannose, N-acetylglucosamine, N-acetylgalactosamine and sialic acid in molar proportions 1.0:4.0:3.7:3.5:1.2:2.5, suggesting that it has two types of sugar chain, i.e. sugar chains like those of serum glycoproteins and sugar chains of the type found in mucins. Actually, alkaline borohydride treatment of this glycoprotein yielded tri- and tetra-saccharide, the latter containing 1 molecule of fucose in addition to each molecule of galactose, N-acetylgalactosamine and sialic acid. This glycoprotein bound to Ricinus communis agglutinin and concanavalin A as well as to wheat-germ agglutinin.     

The major sialoglycoprotein of the human erythrocyte membrane. Release with a non-ionic detergent and purification.

The major sialoglycoprotein of the human erythrocyte membrane has been selectively released by the non-ionic detergent Tween 20 and further purified in detergent-free buffers by hydroxyapatite chromatography and, finally, by hydrophobic interaction chromatography on pentyl-Sepharose. The purified glycoprotein shows one main zone, PAS-1, and up to three minor zones after staining both for protein and carbohydrate in polyacrylamide gel electrophoresis in the presence of dodecyl sulfate. The relative staining intensities are concentration dependent. When the purified glycoprotein has been heated to 100 degrees C in dodecyl sulfate, more stain appears in the most rapid zone, PAS-2, and less in the slower zones, indicating a disaggregation of oligomeric forms of this glycoprotein, including a dimer, PAS-1.     

Subunit structure of human erythrocyte glycophorin A.

Glycophorin A is a sialoglycoprotein isolated from human erythrocyte membranes which seems to exist as stable dimeric complexes in the presence of sodium dodecyl sulfate. When analyzed by dodecyl sulfate acrylamide electrophoresis this molecule forms two PAS-stainable bands (PAS-U and PAS-2) which are reversibly interconvertible. This change in electrophoretic mobility is dependent on the concentration of dodecyl sulfate, the use of Trisbuffer systems, the protein concentration in the incubation mixture, and the duration and temperature of incubation before electrophoresis. Reducing agents do no influence the results. Chromatography of the sialoglycopeptides on Sepharose columns in dodecyl sulfate before and after heat treatment gave similar results. A small hydrophobic peptide (T-6) derived from glycophorin A was able to prevent reassociation of the monomeric subunits back to the higher molecular weight form. This peptide was able to bind to the subunit of glycophorin A, but not to the high molecular weight complex. These results are consistent with a model of glycophorin A composed of two subunits which can dissociate and reassociate in the presence of detergents. These subunits may interact via the hydrophobic portions of the polypeptide chains.     

The major sialoglycoprotein of the human erythrocyte membrane. Release with a non-ionic detergent and purification

The major sialoglycoprotein of the human erythrocyte membrane has been selectively released by the non-ionic detergent Tween 20 and further purified in detergent-free buffers by hydroxyapatite chromatography and, finally, by hydrophobic interaction chromatography on pentyl-Sepharose. The purified glycoprotein shows one main zone, PAS-1, and up to three minor zones after staining both for protein and carbohydrate in polyacrylamide gel electrophoresis in the presence of dodecyl sulfate. The relative staining intensities are concentration dependent. When the purified glycoprotein has been heated to 100 °C in dodecyl sulfate, more stain appears in the most rapid zone, PAS-2, and less in the slower zones, indicating a disaggregation of oligomeric forms of this glycoprotein, including a dinier, PAS-1.     

The membrane change in En(a-) human erythrocytes. Absence of the major erythrocyte sialoglycoprotein.

We investigated the membrane of En(a-) human erythrocytes as part of a study of the structure and biochemical function of the surface glycoproteins of the mammalian cell. 2. En(a-) erythrocytes were selected because they have more extensive changes at the cell surface than any other known erythrocyte variant. 3. Our results show that in En(a-) erythrocytes: (a) the major membrane sialoglycoprotein is lacking; (b) the other major membrane-penetrating glycoprotein (band 3) has an altered electrophoretic mobility. 4. The apparent clinical normality of En(a-) cells suggests that the change in band 3 may compensate for the loss of the membrane sialoglycoproteins. It is clear that a viable erythrocyte can exist despite the absence of one of its major surface components.