Interaction between complement proteins C5b-7 and erythrocyte membrane sialic acid.

The initial phase of membrane attack by complement is the interaction between C5b6, C7, and the cell membrane that leads to the insertion of C5b-7. Here we investigate the role of sialic acid residues in the assembly of C5b-7 intermediates on erythrocyte cell membranes. We find that C5b6 binds to glycophorin, whereas C5 or C6 does not bind, and desialylation of the glycophorin abolishes C5b6 binding. Complement lysis is inhibited by either masking glycophorin sialic acid with F(ab) fragments of an mAb, or by removal of the sialylated region of glycophorin by mild trypsinization. Gangliosides inhibit C5b-7 deposition when added to the aqueous phase. Asialogangliosides and synthetic gangliosides lacking the carboxylic acid residue have no inhibitory activity. We conclude that C5b6 binds to sialylated molecules on the erythrocyte surface. We propose a new model of membrane attack in which C5b6 initially binds to membranes via ionic forces. C7 then binds to C5b6, disrupting the ionic interaction and leading to the exposure of hydrophobic domains. Sialic acid is known to inhibit complement activation. Thus, these findings reveal a paradoxical role for sialic acid in complement attack; the presence of sialic acid inhibits the generation of C5b6, but once the membrane attack pathway is initiated, sialic acid enhances complement lysis.

Increased efficiency of binding of nascent C3b to the erythrocytes of chronic cold agglutinin disease.

The pathogenesis of chronic cold agglutinin disease (CCAD) has been enigmatic. To determine if abnormal erythrocyte membrane constituents might provide the stimulus for antibody production, we compared the electrophoretic pattern of radiolabeled membrane glycoproteins of four patients with CCAD to that of normal control erythrocytes. For the CCAD erythrocytes, fluorographs revealed the appearance of an abnormal band whose molecular weight was estimated at 126,000 D. Using two-dimensional gel analysis and immunoblotting techniques, it was determined that the 126,000 D glycoprotein consisted predominately of polymeric glycophorin-alpha. Previous investigations had suggested that abnormalities in glycophorin-alpha influence the functional activity of the complement system. When purified complement (C)3 was activated in the fluid-phase by cobra venom factor complexes, CCAD erythrocytes bound nascent C3b 7-27 times more efficiently than normal erythrocytes. Normal erythrocytes could be induced to manifest the appearance of the 126,000 D band, and the increased efficiency of binding of nascent C3b by incubation with CCAD serum or with the purified cold agglutinin antibody plus autologous serum, but not with the purified antibody alone or the purified antibody plus EDTA-chelated autologous serum. These studies demonstrate that the interactions of IgM cold-reacting antibody and complement with glycophorin induce changes in the biophysical properties of the erythrocyte membrane which modify subsequent interactions with complement.

Partial amino acid sequence of glycophorin from porcine erythrocyte membranes.

Glycophorin from porcine erythrocyte membranes was digested with trypsin and chymotrypsin. Some of the peptides were isolated by conventional techniques. The amino acid sequence was determined for two isolated peptides: a chymotryptic glycopeptide of 19 residues and a tryptic peptide of 36 residues which represented the carboxy terminal of the glycophorin.

Isolation of glycophorin with deoxycholate.

In a previous communication we reported that human erythrocyte glycophorin prepared by the lithium diiodosalicylate phenol procedure contains approximately 10 mol of lithium diiodosalicylate per mol of glycophorin, and further we showed that this bound lithium diiodosalicylate is difficult to remove by detergents or organic solvents (Romans, A.Y. and Segrest, J.P. (1978) Biochim. Biophys. Acta 511, 297-301). In the present communication we report an alternative purification procedure for glycophorin in which sodium deoxycholate is substituted for lithium diiodosalicylate; the sodium deoxycholate is subsequently removed by gel filtration. Utilizing this procedure, 25-30 mg glycophorin are obtained per gram of lyophilized erythrocyte ghosts. The glycophorin prepared by the sodium deoxycholate procedure, after a single gel filtration step, contains less than 1 mol of sodium deoxycholate per mol glycophorin and is colorless compared with glycophorin prepared by the lithium diiodosalicylate procedure, which has a distint reddish-brown cast.

Integral membrane protein interaction with Triton cytoskeletons of erythrocytes.

The organization of erythrocyte membrane lipids and proteins has been studied following the release of cytoplasmic components with the non-ionic detergent Triton X-100. After detergent extraction, a detergent-resistant complex called the erythrocyte cytoskeleton is separated from detergent, solubilized lipid and protein by sucrose buoyant density sedimentation. In cytoskeletons prepared under isotonic conditions all of the major erythrocyte membrane proteins are retained except for the integral protein, glycophorin, which is quantitatively solubilized and another integral glycoprotein, band 3, which is only 60% removed. When cytoskeletons are prepared in hypertonic KCl solutions, band 3 is fully solubilized along with bands 2.1 and 4.2 and several minor components. The resulting cytoskeletons have the same morphology as those prepared in isotonic buffer but they are composed of only three major peripheral proteins, spectrin, actin and band 4.1. We have designated this peripheral protein complex the 'shell' of the erythrocyte membrane, and have shown that the attachment of band 3 to the shell satisfies the criteria for a specific interaction. Although Triton did affect erythrocyte shape, cytoskeleton lipid content and the activity of membrane proteases, there was no indication that Triton altered the attachment of band 3 to the shell. We suggest that band 3 attaches to the shell as part of a ternary complex of bands 2.1, 3 and 4.2.

Preparation of cyanogen bromide fragments of MM, NN, and MN glycoproteins (glycophorins) from human erythrocyte membranes of single donors.

A procedure is described for the preparation of three cyanogen bromide fragments of the MM, NN, or MN glycoprotein (glycophorin) of the human erythrocyte membranes, from erythrocytes of single donors. The fragments are obtained in pure form and excellent yields by employing procedures which include proteolytic inhibitors during membrane processing, thorough delipidation of the glycoprotein, and CNBr cleavage conditions which lead to quantitative fragmentation without loss of carbohydrates. A phenol-urea extraction resolves the two glycopeptide fragments from the carbohydrate-free fragment. The two glycopeptides are further purified by Bio-Gel P-6 and P-100 chromatography. The three fragments include the amino terminal 8 residue glycopeptide, a large glycopeptide form the middle of the molecule which bears the Asn-linked oligosaccharide and 8--9 O-glycosidically linked units, and a carboxyl terminal, carbohydrate-free, approx. 50 residue fragment. Their amino acid and carbohydrate composition, and size, are in close agreement with the sequence data of Tomita, M., Furthmayr, H. and Marchesi, V.T. (Biochemistry (1978), 17, 4756--4770). The fragments represent three well delineated portions of the glycoprotein molecule.

Glycophorin-enriched vesicles obtained by a selective extraction of human erythrocyte membranes with a non-ionic detergent.

A method is described for isolating glycophorin-enriched vesicles from human erythrocytes by extracting membranes that were incubated for 30 min at 37 degrees C at pH 4.5 and washed at low and high ionic strength with the nonionic detergent Triton X-100. The extracts were 11.8 +/- 2.4 fold enriched in glycophorin and contained 325 +/- 69 microgram sialic acid/mg protein, which represented 61 +/- 16% of the total sialic acid. Upon removal of Triton X-100 one third of the total glycophorin forms glycophorin-enriched vesicles with coextracted, endogenous lipids as shown sedimintation, dextran-density gradient centrifugation, and electron microscopy. Addition of exogenous lipids increased the fraction of glycophorin-enriched vesicles up to 87%. The incorporation of glycophorin in the membrane was shown by hemagglutination inhibition assays using anti-M sera and by the accessibility of glycophorin to trypsin. Freeze-fractured vesicles did not reveal intramembranous particles. The selectivity of the extraction procedure is not simply due to chemical constraints introduced by disulfide cross-linkage of protein component 3, because only 20% of this protein undergo disulfide cross-linking. The selective extraction of glycophorin implies that glycophorin is segregated from protein component 3 and thus from intramembranous particles when erythrocyte membranes have been incubated at pH 4.5. This segregation may precede aggregation of intramembranous particles.

Binding of lithium diiodosalicylate to glycophorin.

Glycophorin was purified from human erythrocyte ghosts by the lithium diiodosalicylate -phenol procedure utilizing 125I-labeled lithium diiodosalicylate. The glycophorin preparation was found to contain 8.9 +/- 2.1 mol lithium diiodosalicylate per mol glycophorin. This bound lithium diiodosalicylate cannot be removed by extensive washings with a variety of polar organic solvents nor by treatment with the detergent, sodium deoxycholate. Further, the hydrophobic peptide produced from glycophorin by trypsin digestion contained 3.4 mol lithium diiodosalicylate per mol peptide.

The role of protein-linked oligosaccharide in the bilayer stabilization activity of glycophorin A for dioleoylphosphatidylethanolamine liposomes.

The importance of the protein-linked carbohydrates for the stabilization of dioleoylphosphatidylethanolamine (DOPE) bilayers has been investigated using glycophorin A, the major sialoglycoprotein of the human erythrocyte membrane, as a stabilizer. Two major types of glycophorin, differing in the sialic acid content, were used in the study. Type MM contains 19.2 +/- 2.5 sialic residues per molecule of glycophorin, and type NN contains 10.8 +/- 1.2. Type MM could stabilize DOPE bilayers at 0.5 mol%, whereas type NN was unable to do so even at 1 mol%. The importance of the sialic acid content to the stabilization activity of glycophorin was further confirmed by the observation that the neuraminidase-treated type MM showed a lower stabilization activity than the untreated type. Since type NN had no stabilizing activity, we attempted to couple a trisaccharide, NeuNAc----Gal----Glc, to type NN by reductive amination. 2.5 +/- 0.8 saccharide chains were added per molecule of type NN. The trisaccharide-attached type NN showed a greater stabilization activity than the parent type NN molecule, indicating again that the sialic acid content of the stabilizer molecule determines the stabilization activity. Addition of wheat-germ agglutinin (WGA), which binds to the sialic acid residues of a glycoprotein, to type MM-stabilized liposomes caused rapid aggregation and destabilization of liposomes, resulting in leakage of an entrapped marker, calcein. The aggregation increased with increasing amount of the lectin; however, the leakage rate was maximum at an optimum concentration of WGA. These results are discussed in terms of the role of sialic acid in the interfacial hydration and charge repulsion which determines the DOPE bilayer stability.

Amino acid sequence of monkey erythrocyte glycophorin MK. Its amino acid sequence has a striking homology with that of human glycophorin A.

A major sialoglycoprotein, glycophorin MK, was isolated from monkey erythrocyte membranes by extraction with lithium diiodosalicylate and partition in aqueous phenol. Chemical analysis of glycophorin MK revealed that the glycophorin consists of 51% protein and 49% carbohydrate by weight, and contains no N-glycosidic oligosaccharide units. Only N-glycolylneuraminic acid (Neu5Gc) was detected as sialic acid. The amino acid sequence of glycophorin MK was determined, which demonstrated that the glycophorin consists of 144 amino acid residues and 18 oligosaccharide units linked O-glycosidically to the peptide backbone through serine or threonine residues. The molecular weight was estimated to be about 35,000 based on the amino acid residues and carbohydrate content. By comparison of the amino acid sequence with those of human, equine and porcine glycophorins, a striking sequence homology was observed between monkey and human glycophorin. Glycophorin MK demonstrated both M and N blood group activities.

Selective solubilization by melittin of glycophorin A and acetylcholinesterase from human erythrocyte ghosts.

Melittin, the main basic and hydrophobic peptide of bee venom, has been used for solubilizing membrane components of the human erythrocyte ghost. Up to 1.0 mM, it does not extract any phospholipid. Between 0.1 and 1.0 mM, it solubilizes partially glycophorin A and acetylcholinesterase. When the membrane is first degraded by phospholipase A2, the solubilization of both proteins by melittin is total, and 48% of the phospholipids are removed, mainly as lysoproducts, whereas phospholipase A2, by itself, has no solubilizing properties. In its melittin-solubilized state, acetylcholinesterase is in a dimeric form and displays a slow time-dependent irreversible inactivation. Triton X-100 at 1.0% (v/v) interrupts the inactivation. We suggest that melittin binds to the hydrophobic site of acetylcholinesterase which anchors it in the lipid bilayer.

Isolation and influenza virus receptor activity of glycophorins B, C and D from human erythrocyte membranes.

(1) Glycophorins (GPs) AM, AN, B, C and D were each isolated into a high state of purity from human erythrocyte membranes by a combination of lithium diiodosalicylate (LIS)-phenol extraction, gel-filtration with Bio-Gel A1.5m and HPLC with LiChrospher 1000 TMAE. (2) GPs-B, -C and -D reacted with influenza A and B viruses as well as GPs-AM and -AN and the order of reactivities against two viruses of the glycophorins was as follows: GP-B > GP-C > GP-AM = GP-AN >> GP-D for the former virus and GP-C > GP-B > GP-AM = GP-AN >> GP-D for the latter virus.

Evidence for the preferential interaction of glycophorin with negatively charged phospholipids.

Glycophorin, extracted from the erythrocyte membrane after treatment with lithium-diiodo-salicylate, still contains a significant amount of phospholipid, consisting predominantly of phosphatidylserine. Methods are described which lead to a full delipidation of the protein. After treatment with neuraminidase, delipidated glycophorin shows a preferential interaction with monolayers of negatively-charged phospholipids. This lipid-protein interaction is decreased by the presence of cholesterol in the lipid film.

Modification of glycophorin A during oxidation of erythrocyte membrane.

Human erythrocyte ghosts were oxidized with tert-butyl hydroperoxide and subsequently treated with tritiated borohydride to label the membrane proteins modified during the membrane oxidation. From the ghosts, oxidized-and-tritiated glycophorin A was isolated and characterized. No intermolecular cross-links were observed as analyzed by sodium dodecylsulfate gel electrophoresis. But, the number of lysine residues was significantly reduced and susceptibility to proteinases such as trypsin, chymotrypsin and pronase was lower than that of control glycophorin A. Trypsinization of the oxidized-and-tritiated glycophorin A gave insoluble and soluble trypsin fragments. After dansylation, N-terminal amino acids of the trypsin-fragments were determined. Dansyl amino acids from the insoluble trypsin fragments were not identical with those from control insoluble counterparts in the membrane-spanning region of glycophorin A molecule. Fractionation by gel filtration of dansyl-soluble trypsin fragments, and the N-terminal amino acid analysis of the fractionated peptides indicated that the peptides derived from the glycosylated region located in the outside of the membrane matrix were identical with those from control soluble counterparts. The results suggest that the glycosylated outside region of glycophorin A was modified only slightly but the hydrophobic membrane-spanning region was extensively modified during membrane oxidation, most likely by oxidized lipids.

Sialic acid-dependent binding of baculovirus-expressed recombinant antigens from Plasmodium falciparum EBA-175 to Glycophorin A.

The Plasmodium falciparum Erythrocyte Binding Antigen-175, EBA-175, is a soluble merozoite stage parasite protein which binds to glycophorin A surface receptors on human erythrocytes. We have expressed two conserved cysteine-rich regions, region II and region VI, of this protein as soluble His-tagged polypeptides in insect cell culture, and have tested their function in erythrocyte and glycophorin A binding assays. Recombinant region II polypeptides comprised of the F2 sub-domain or the entire region II (F1 and F2 sub-domains together) bound to erythrocytes and to purified glycophorin A in a manner similar to the binding of native P. falciparum EBA-175 to human red cells. Removal of sialic acid residues from the red cell surface totally abolished recombinant region II binding, while trypsin treatment of the erythrocyte surface reduced but did not eliminate recombinant region II binding. Synthetic peptides from three discontinuous regions of the F2 sub-domain of region II inhibited human erythrocyte cell binding and glycophorin A receptor recognition. Immune sera raised against EBA-175 recombinant proteins recognized native P. falciparum-derived EBA-175, and sera from malaria-immune adults recognized recombinant antigens attesting to both the antigenicity and immunogenicity of proteins. These results suggest that the functionally-active recombinant region II domain of EBA-175 may be an attractive candidate for inclusion in multi-component asexual blood stage vaccines.

Glycophorin A inhibits lysis by the complement attack phase.

A glycoprotein from human erythrocyte membranes has been found to inhibit lysis of target cells by the attack-phase components C5-C9 from human complement. The inhibiting molecule was purified and identified as glycophorin A. Thus, glycophorin A may have a regulatory function in the lytic complement attack on isologous cells.

Preparation of supported planar lipid membranes containing transmembrane proteins.

A new method has been developed for preparation of supported planar lipid membranes containing transmembrane proteins. Phosphatidylcholine and glycophorin A were deposited on the surface of alkylated glass coverslips by dialysis. The planar lipid membranes prepared in this manner were examined for the binding of wheat germ agglutinin agarose. The binding of the agarose to these membranes is dependent on the membrane fluidity. The advantages of this technique are: (1) a supported planar membrane can be more readily prepared, and (2) less amounts of membrane proteins are needed for reconstitution.

Isolation and characterization of two glycophorins from horse erythrocyte membranes.

Crude glycophorin fraction was prepared from horse erythrocyte membranes by extraction with lithium diiodosalicylate and partition in aqueous phenol. Two glycophorins, designated glycophorins HA and HB, were isolated by two different techniques: preparative gel electrophoresis in the presence of sodium dodecyl sulfate and ion-exchange chromatography in the presence of the nonionic detergent Ammonyx LO. Each glycophorin formed at least two bands on gel electrophoresis, which corresponded to a dimeric form and a monomeric form. Glycophorin HA, the major component, had a blocked amino-terminus and consisted of 70% protein and 30% carbohydrate. Glycophorin HB, the minor component, had threonine as the amino-terminus and consisted of 80% protein and 20% carbohydrate. Since glycophorin HB showed a chemical composition distinct from that of glycophorin HA, glycophorin HB was not a partially degraded form of glycophorin HA.

Improved method for the isolation and preliminary characterization of human DAF (decay-accelerating factor).

DAF (decay-accelerating factor) is one of the integral membrane proteins of erythrocytes, and is considered to play an important role in the regulation of complement activation. The purification of DAF has been impeded by the difficulty in removing glycophorin. We devised an effective method for removing glycophorin. Through the limited trypsinization of stromata prior to the extraction of DAF, glycophorin was readily digested so that the DAF could be purified free of glycophorin by DEAE-Sephacel and Bio-Gel A 0.5 m chromatographies. On SDS-PAGE, DAF from trypsinized stromata showed the same mobility as that from native stromata: its molecular weight was estimated to be about 70 kDa. Amino acid analysis of DAF showed high contents of serine and glutamic acid. The amino-terminal sequence of DAF prepared by the present method, determined for the 29 residues, did not show significant homology with that of glycophorin.

Glycophorins of bovine erythrocyte membranes. Isolation and preliminary characterization of the major component.

Crude glycophorin fraction was prepared from bovine erythrocyte membranes by extraction with lithium diiodosalicylate and partition in aqueous phenol. The crude fraction was further separated into three fractions by gel chromatography and ion-exchange chromatography. The major fraction, designated glycophorin BA, accounts for 80% of the crude fraction. Its carbohydrate content was 79% by weight including galactose, N-acetylgalactosamine, N-acetylglucosamine and N-glycolylneuraminic acid. Iodosobenzoate treatment of glycophorin BA produced two fragments; one is a highly glycosylated segment and the other a hydrophobic peptide. The amino-terminal sequence of the hydrophobic peptide representing the carboxyl-terminal half of glycophorin BA was determined. The other two fractions, IIIa and IIIb, were still heterogeneous when analyzed by gel electrophoresis. Fraction IIIa contained two glycophorins having apparent molecular weights of 46,000 and 42,000, while fraction IIIb contained a glycoprotein having a marked tendency to aggregate.