Ultrastructural localization of erythrocyte cytoskeletal and integral membrane proteins in Plasmodium falciparum-infected erythrocytes

The distributions of ankyrin, spectrin, band 3, and glycophorin A were examined in Plasmodium falciparum-infected erythrocytes by immunoelectron microscopy to determine whether movement of parasite proteins and membrane vesicles between the parasitophorous vacuole membrane and erythrocyte surface membrane involves internalization of host membrane skeleton proteins. Monospecific rabbit antisera to spectrin, band 3 and ankyrin and a mouse monoclonal antibody to glycophorin A reacted with these erythrocyte proteins in infected and uninfected human erythrocytes by immunoblotting. Cross-reacting malarial proteins were not detected. The rabbit sera also failed to immunoprecipitate [3H]isoleucine labeled malarial proteins from Triton X-100 and sodium dodecyl sulfate (SDS) extracts of infected erythrocytes. These three antibodies as well as the monoclonal antibody to glycophorin A bound to the membrane skeleton of infected and uninfected erythrocytes. The parasitophorous vacuole membrane was devoid of bound antibody, a result indicating that this membrane contains little, if any, of these host membrane proteins. With ring-, trophozoite- and schizont-infected erythrocytes, spectrin, band 3 and glycophorin A were absent from intracellular membranes including Maurer's clefts and other vesicles in the erythrocyte cytoplasm. In contrast, Maurer's clefts were specifically labeled by anti-ankyrin antibody. There was a slight, corresponding decrease in labeling of the membrane skeleton of infected erythrocytes. A second, morphologically distinct population of circular, vesicle-like membranes in the erythrocyte cytoplasm was not labeled with anti-ankyrin antibody. We conclude that membrane movement between the host erythrocyte surface membrane and parasitophorous vacuole membrane involves preferential sorting of ankyrin into a subpopulation of cytoplasmic membranes.     

Selective radiolabeling of cell surface proteins to a high specific activity

A procedure was developed for selective radiolabeling of membrane proteins on cells to higher specific activities than possible with available techniques. Cell surface amino groups were derivatized with 125I-(hydroxyphenyl)propionyl groups via 125I-sulfosuccinimidyl (hydroxyphenyl)propionate (125I-sulfo-SHPP). This reagent preferentially labeled membrane proteins exposed at the cell surface of erythrocytes as assessed by the degree of radiolabel incorporation into erythrocyte ghost proteins and hemoglobin. Comparison with the lactoperoxidase-[125I]iodide labeling technique revealed that 125I-sulfo-SHPP labeled cell surface proteins to a much higher specific activity and hemoglobin to a much lower specific activity. Additionally, this reagent was used for selective radiolabeling of membrane proteins on the cytoplasmic face of the plasma membrane by blocking exofacial amino groups with uniodinated sulfo-SHPP, lysing the cells, and then incubating them with 125I-sulfo-SHPP. Exclusive labeling of either side of the plasma membrane was demonstrated by the labeling of some marker proteins with well-defined spatial orientations on erythrocytes. Transmembrane proteins such as the epidermal growth factor receptor on cultured cells could also be labeled differentially from either side of the plasma membrane.     

Interaction of the 140/130/110 kDa rhoptry protein complex of Plasmodium falciparum with the erythrocyte membrane and liposomes

During Plasmodium falciparum merozoite invasion into human and mouse erythrocytes, a 110-kDa rhoptry protein is secreted from the organelle into the erythrocyte membrane. In the present study our interest was to examine the interaction of rhoptry proteins of P. falciparum with the erythrocyte membrane. It was observed that the complex of rhoptry proteins of 140/130/110 kDa bind directly to a trypsin sensitive site on intact mouse erythrocytes, and not human, saimiri, or other erythrocytes. However, when erythrocytes were disrupted by hypotonic lysis, rhoptry proteins of 140/130/110 kDa were found to bind to membranes and inside-out vesicles prepared from human, mouse, saimiri, rhesus, rat, and rabbit erythrocytes. A binding site on the cytoplasmic face of the erythrocyte membrane suggests that the rhoptry proteins may be translocated across the lipid bilayer during merozoite invasion. Furthermore, pretreatment of human erythrocytes with a specific peptide derived from MSA-1, the major P. falciparum merozoite surface antigen of MW 190,000-200,000, induced binding of the 140/130/110-kDa complex. The rhoptry proteins bound equally to normal human erythrocytes and erythrocytes treated with neuraminidase, trypsin, and chymotrypsin indicating the binding site was independent of glycophorin and other major surface proteins. The rhoptry protein complex also bound specifically to liposomes prepared from different types of phospholipids. Liposomes containing PE effectively block binding of the rhoptry proteins to mouse cells, suggesting that there are two binding sites on the mouse membrane for the 140/130/110-kDa complex, one protein and a second, possibly lipid in nature. The results of this study suggest that the 140/130/110 kDa protein complex may interact directly with sites in the lipid bilayer of the erythrocyte membrane.     

Comparison of the Surface Proteins and Glycoproteins On Erythrocytes of Calves Before and During Infection With Babesia Bovis

The surface proteins and glycoproteins on red cells from normal and Babesia bovis-infected calf blood have been compared. Several radiolabeling probes were used to label specifically external membrane molecules which were then separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and identified by autoradiography or fluorography. No differences were observed among the Coomassie Blue-stained membrane proteins of erythrocytes from individual uninfected calves. Comparison of red cells from these animals also indicated no qualitative differences in the surface proteins with accessible tyrosyl residues labeled by lactoperoxidase-catalyzed radioiodnation, although some quantitative variation in the uptake of radioactivity into particular proteins was observed. the major radioiodinated bands on normal bovine erythrocytes had Mr of 165, 130, 90, and 45 kiloDaltons. However, labeling of surface glycoproteins by the periodate/[³H]NaBH₄ and galactose oxidase (± neuraminidase)/[³H]NaBH₄ methods showed significant differences in the surface proteins of red cells from individual uninfected calves. of 14 animals tested, 5 had major labeled glycoproteins of unique Mr. No changes were observed in radioiodinated surface proteins of total red cell samples from infected calves with 0.5-6% parasitemia. Radioiodination of concentrated infected red cells from the same samples (concentrated by selective hypotonic lysis of uninfected erythrocytes in KC1) resulted in the labeling of 3 new surface proteins, with Mr of 118, 115, and 60 kiloDaltons. the same new ¹²⁵I-labeled bands were identified on infected cells from 3 avirulent strains of B. bovis used in vaccine production. Furthermore, in concentrated infected cells there was very poor radiolabeling of major bands strongly labeled on uninfected cells (Mr 165, 130, and 90 kiloDaltons), suggesting parasite-induced loss of these proteins. Although there were some differences in ³H-labeled surface glycoproteins of red cells from normal and. B. bovis -infected blood, they were restricted to minor labeled bands and were not seen consistently. the labeled surface glycoproteins of concentrated infected cells were very similar to those of the uninfected red blood cells from infected blood.     

Erythrocytes contain cytoplasmic glycoproteins. O-linked GlcNAc on Band 4.1

Previously we reported that the novel protein-saccharide linkage, O-linked N-acetylglucosamine (GlcNAc), is found in abundance on proteins associated with the cytoplasmic and nucleoplasmic faces of the nuclear pore complex. Here we demonstrate that O-GlcNAc moieties are also added to human erythrocyte cytoplasmic proteins. Intact or permeabilized erythrocytes, as well as subcellular fractions, were labeled with bovine milk galactosyltransferase and UDP-[3H] galactose. The proportion of the incorporated label found on O-GlcNAc was determined by a variety of chemical and enzymatic techniques. The bulk of the O-GlcNAc residues are found in the cytoplasm of erythrocytes, the majority of which are on an as yet unidentified 65-kDa protein. In addition, we have determined that Band 4.1, a protein which serves as a bridge joining the cytoskeleton to the inner surface of the plasma membrane in erythrocytes, also contains O-GlcNAc moieties. One of the sites of O-GlcNAc addition has been localized to the last 117 amino acids of the carboxy terminus of Band 4.1.     

Identification of Surface Proteins on Viable Plasmodium knowlesi Merozoites

Viable merozoites of Plasmodium knowlesi were isolated and the proteins that were labeled on intact merozoites by lactoperoxidase-catalyzed radioiodination were identified. Sodium dodecyl sulfate polyacrylamide gel electrophoresis and autoradiography of Triton soluble extracts of labeled merozoites demonstrated eight major bands ranging in apparent molecular weight from 150,000 D to 22,000 D. Exposure of intact merozoites to trypsin (10 μg/ml) for 10 min resulted in the loss of the two highest molecular weight proteins (150,000 D and 105,000 D) and the appearance of two new bands at 70,000 D and 62,000 D. Trypsin treatment under these conditions also removed the receptor(s) for merozoite attachment to erythrocytes. Therefore, these high molecular weight proteins are candidates for the merozoite component that attaches to erythrocytes. There was no evidence that the labeled membrane components were serum or erythrocyte membrane components, two potential contaminants in the preparation. Anti-rhesus erythrocyte antibody did not precipitate labeled merozoite proteins. Furthermore, the immunoprecipitation of labeled merozoite proteins by rhesus anti-merozoite serum was not inhibited by erythrocyte ghosts.     

Fluorescent photochemical surface labeling of intact human erythrocytes.

A photolabile nitrene precursor, 3-azido-(2,7)-naphthalene disulfonate (ANDS), has been synthesized and used as a membrane-impermeable probe. The aryl azide was nonfluorescent. When activated by light, a highly reactive nitrene was generated which was capable of nonspecific covalent modifications of hydrophilic regions of cell surfaces. The products of the photolysis were highly fluorescent and modified proteins could be identified by their characteristic fluorescence after electrophoresis on sodium dodecyl sulfate polyacrylamide gels. When intact human erythrocytes were labeled with ANDS, Protein 3, the major membrane protein, and the sialoglycoproteins were modified. No proteins of apparent molecular weight greater than Protein 3 were labeled by ANDS, suggesting that none of these membrane components was exposed to the hydrophilic external surface of the red blood cell. When open erythrocyte stroma were labeled with ANDS, virtually all protein bands detectable by Coomassie blue staining could be shown to contain some fluorescence label. The significance of these findings are discussed with relation to the use of various aryl azides as surface labels of membranes.     

External labeling of human erythrocyte glycoproteins. Studies with galactose oxidase and fluorography.

Glycoproteins of the human erythrocyte membrane were labeled with tritiated sodium borohydride after oxidation of terminal galactosyl and N-acetylgalactosaminyl residues with galactose oxidase. After separation of the polypeptides on polyacrylamide slab gels, a scintillator was introduced into the gel, and the radioactive proteins were visualed by autoradiography (fluorography). The following results were obtained. (a) The erythrocyte membrane contains at least 20 glycoproteins, many of which are minor components. (b) The carbohydrate of all the labeled glycoproteins is exposed only to the outside, since no additional glycoproteins can be labeled in isolated unsealed ghosts. (c) The membrane contains two major groups of glycoproteins. The first group of proteins contains sialic acids linked to the penultimate galactosyl/N-acetylgalactosaminyl residues, which are efficiently labeled only after pretreatment with neuraminidase. The second group has terminal galactosyl/N-acetylgalactosaminyl residues which can be easily labeled without neuraminidase treatment. The glycoproteins from fetal erythrocytes all belong to the first group, whereas only five glycoproteins of erythrocytes from adults belong. (d) Trypsin cleaves the proteins containing sialic acids, and fragments containing carbohydrate remain tightly bound and exposed in the membrane. (e) Pronase cleaves Band 3 in addition to the sialic acid containing glycoproteins, but most of the glycoproteins still remain unmodified in the membrane. (f) No difference is seen between membrane glycoproteins from cells of different ABH blood groups.     

The use of the 2-iminobiotin-avidin interaction for the selective retrieval of labeled plasma membrane components

A general method for the selective retrieval of surface labeled plasma membrane components had been devised. The basis of the technique is the covalent attachment of compounds containing 2-iminobiotin, the cyclic guanidino analog of biotin, onto the cell surface proteins and the use of immobilized avidin to recover the labeled components uncontaminated by other cytosolic and membrane components. The pH-dependent interaction of 2-iminobiotin with avidin makes recovery possible. At high pH the free base form of 2-iminobiotin retains the high affinity specific binding to avidin characteristic of biotin, whereas at acidic pH values, the salt form of the analog interacts poorly with avidin. Model studies on the interaction of 2-iminobiotinylated proteins with avidin-Sepharose 4B show that for tight binding to the affinity matrix, the pH of the column must be 9.5 or higher, that a single 2-iminobiotin group is sufficient for binding, and that proteins with different extents of labeling behave similarly when the low pH buffer is applied. When intact human erythrocytes were sequentially labeled with periodate and 2-iminobiotin hydrazide and the Triton X-100-solubilized plasma membrane proteins were subjected to affinity isolation, the major sialoglycoproteins, periodic acid-Schiff (PAS) 1, PAS 2, and PAS 3, plus two proteins with apparent molecular weights higher than band 3 were retrieved. The recovery of these proteins is not due to a nonspecific adsorption to the affinity matrix.     

Effects of surface proteins of human erythrocyte membrane on the interaction with lipopolysaccharides from <Emphasis Type="Italic">Escherichia coli</Emphasis> O55:B5

The role of erythrocytic surface membrane proteins and membrane charge in the interactions of the erythrocytes with lipopolysaccharides (LPS) isolated from Escherichia coli O55:B5 (LPS _{E. coli} , S-form) has been examined by two independent methods, flow cytometry and cell electrophoresis. Treatment of erythrocytes with trypsin that modifies stereochemical properties of cell surface resulted in a 16% increase in the level of the erythrocyte fluorescence measured after their incubation with fluorescently labeled LPS _{E. coli} . Electrophoretic mobility (EM) of the trypsin-treated erythrocytes was reduced by 16%. The removal of sialic acids from the erythrocyte surface with neuraminidase had no considerable effect either on the relative EM values or fluorescence intensity after the incubation of cells with LPS. The results suggest that the major role in the incorporation of the S-form LPS into the membrane of human erythrocytes is played by stereochemical factors, whereas the cell surface charge is less significant.     

The Rh polypeptide is a major fatty acid-acylated erythrocyte membrane protein

The erythrocyte Rh antigens contain an Mr = 32,000 integral protein which is thought to contribute in some way to the organization of surrounding phospholipid. To search for possible fatty acid acylation of the Rh polypeptide, intact human erythrocytes were incubated with [3H]palmitic acid prior to preparation of membranes and sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography. Several membrane proteins were labeled, but none corresponded to the glycophorins or membrane proteins 1-8. An Mr = 32,000 band was prominently labeled on Rh (D)-negative and -positive erythrocytes and could be precipitated from the latter with anti-D. No similar protein was labeled on membranes from Rhmod erythrocytes, a rare phenotype lacking Rh antigens. Labeling of the Rh polypeptide most likely represents palmitic acid acylation through thioester linkages. The 3H label was not extracted with chloroform/methanol, but was quantitatively eluted with hydroxylamine and co-chromatographed with palmitohydroxamate and free palmitate by thin layer chromatography. The fatty acid acylations occurred independent of protein synthesis and were completely reversed by chase with unlabeled palmitate. It is concluded that the Rh polypeptide is fatty acid-acylated, being a major substrate of an acylation-deacylation mechanism associated with the erythrocyte membrane.     

Proteins exposed at the adult schistosome surface revealed by biotinylation

The human blood-dwelling parasite Schistosoma mansoni can survive in the hostile host environment for decades and must therefore display effective strategies to evade the host immune responses. The surface of the adult worm is covered by a living syncytial layer, the tegument, bounded by a complex multilaminate surface. This comprises a normal plasma membrane overlain by a secreted bilayer, the membranocalyx. Recent proteomic studies have identified constituents of the tegument, but their relative locations remain to be established. We labeled the most exposed surface proteins using two impermeant biotinylation reagents that differed only in length. We anticipated that the two reagents would display distinct powers of penetration, thereby producing a differential labeling pattern. The labeled proteins were recovered by streptavidin affinity and identified by tandem mass spectrometry. A total of 28 proteins was identified, 13 labeled by a long form reagent and the same 13 plus a further 15 labeled by a short form reagent. The parasite proteins included membrane enzymes, transporters, and structural proteins. The short form reagent additionally labeled some cytosolic and cytoskeletal proteins, the latter being constituents of the intracellular spines. Only a single secreted protein was labeled, implying a location between the plasma membrane and the membranocalyx or as part of the latter. Four host proteins, three immunoglobulin heavy chains and C3c/C3dg, a fragment of complement C3, were labeled by both reagents indicating their exposed situation. The presence of the degraded complement C3 implicates inhibition of the classical pathway as a major element of the immune evasion strategy, whereas the recovery of only one truly secreted protein points to the membranocalyx acting primarily as an inert protective barrier between the immune system and the tegument plasma membrane. Collectively the labeled parasite proteins merit investigation as potential vaccine candidates.     

Plasmodium vivax: malarial proteins associated with the membrane-bound caveola-vesicle complexes and cytoplasmic cleft structures of infected erythrocytes

The identification of antigens of parasite origin associated with the altered membrane of Plasmodium vivax-infected erythrocytes was undertaken in this study. The 125I-lactoperoxidase catalyzed surface radiolabeling of trophozoite-infected erythrocytes revealed new bands of 95 and 70 kDa not labeled in normal erythrocytes. Erythrocyte membrane-enriched preparations from [35S]methionine biosynthetically labeled-infected erythrocytes also indicated that in addition to bands at 95 and 70 kDa, several other parasite proteins were possibly membrane associated. Five monoclonal antibodies (Mabs) reactive with P. vivax produced an immunofluorescent pattern of numerous small dots scattered over the entire infected erythrocyte. This pattern mimics that of Schuffner's stippling; small red dots seen in Giemsa-stained P. vivax-infected erythrocytes, which represent accumulations of dye in caveola-vesicle complexes (CVC). Four of the monoclonal antibodies immunoprecipitated a Triton X-100 detergent-insoluble 95-kDa parasite protein which was localized by immunofluorescent assay and immunoelectron microscopy exclusively to the CVC. Two of these Mabs were immunofluorescence reactive with the surface of intact infected erythrocytes in suspension. The fifth Mab, which also localized exclusively to the CVC structures, immunoprecipitated a Triton X-100 extractable protein of 70 kDa. Two other monoclonal antibodies reacted exclusively with the numerous membranous cleft structures found in the cytoplasm of infected erythrocytes. This cleft-associated parasite antigen was 28 kDa in size. Some of these Mabs recognize epitopes and produce similar IFA patterns on erythrocytes infected with P. cynomolgi, P. knowlesi, and P. ovale parasites, but not with P. falciparum- or P. brasilianum-infected erythrocytes.     

Intracellular vesicles involved in the transport of Semliki Forest virus membrane proteins to the cell surface.

The route of transport of Semliki Forest virus (SFV) membrane glycoproteins to the plasma membrane was studied using immunoperoxidase electron microscopy. SFV glycoproteins were localized in cultured BHK-21 fibroblasts infected with a temperature-sensitive mutant ts-1 of SFV, which shows a temperature-dependent, reversible defect in the transport of membrane glycoproteins to the cell surface. At 39 degrees C (restrictive temperature) the viral proteins were retained in the endoplasmic reticulum and the nuclear membrane. After shift of the infected cultures to 28 degrees C (permissive temperature) the proteins were synchronously transported to the Golgi complex. In the Golgi complex the labeled proteins were first (at 2.5 min) detected in large Golgi-associated vacuoles (GAV). Subsequently, i.e., at 5-30 min, the viral glycoproteins appeared in the cisternal stack: at 5 min the label was found in one or two of the proximal cisternae whereas at 15 or 30 min also the more distal cisternae were partially or uniformly labeled. At all time points examined after the temperature-shift, peroxidase label was found in 50 nm vesicles which were frequently coated. At 30 min, in addition to the 50 nm vesicles, larger 80 nm vesicles, which often had a cytoplasmic coat were labeled in the Golgi region. These results identify two major size classes of both coated and smooth vesicles which appear to function in the transport of the viral membrane proteins from the endoplasmic reticulum via distinct GAV and the stacked Golgi cisternae to the plasma membrane.     

Studies on the turnover of proteins of the rat erythrocyte membrane

The membrane proteins of erythrocytes were labeled by injecting L-[14C]-leucine and later L-[3H]leucine into rats, the two injections being 31 days apart. Control animals received the two isotopic forms of L-leucine simultaneously. Deviations in labeling ratio from control patterns were found on sodium dodecyl sulfate-polyacrylamide gel electrophorograms in restricted regions suggestive of turnover or loss of a few small proteins from the membrane between the 31 days. Most of the ghost proteins show no turnover.     

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.     

Molecular Factors Responsible for Host Cell Recognition and Invasion in Plasmodium falciparum1

ABSTRACT. In Plasmodium falciparum. the rhoptries involved in the invasion process are a pair of flask-shaped organelles located at the apical tip of invading stages. They, along with the more numerous micronemes and dense granules, constitute the apical complex in Plasmodium and other members of the phylum Apicomplexa. Several proteins of varying molecular weight have been identified in P. falciparum rhoptries. These include the 225-, 140/130/110-, 80/60/40-, RAP-1 80-, AMA-1 80-, QF3 80-, and 55-kDa proteins. Some of these proteins are lost during schizont rupture and release of merozoites. Others such as the 140/130/110-kDa complex are transferred to the erythrocyte membrane during invasion. The ring-infected surface antigen (RESA). a 155-kDa polypeptide located in dense granules also associates with the erythrocyte membrane during invasion. Erythrocyte-binding studies have demonstrated that both the 140/130/110-kDa rhoptry complex and RESA bind to inside-out-vesicles (IOVs) prepared from human erythrocytes. The 140/130/110-kDa complex also binds to erythrocyte membranes prepared by hypotonic lysis. These proteins, however, do not bind to intact human erythrocytes. In a heterologous erythrocyte model, both the 140/130/110-kDa complex and RESA are shown to bind directly to mouse erythrocytes. Other studies have shown that RESA associates with spectrin in the erythrocyte cytoskeleton. We have recently developed a liposome-binding assay to demonstrate the lipophilic binding properties of the P. falciparum rhoptry complex of 140/130/110 kDa. The rhoptry complex binds to liposomes containing neutrally, positively, and negatively charged phospholipids. However, liposomes containing phosphatidylethanolamine compete effectively for rhoptry protein binding to mouse erythrocytes. The rhoptry complex also binds to membrane and inside-out-vesicles prepared from human erythrocytes and erythrocytes from other species. The rhoptry complex associated with the erythrocyte membrane in ring-infected erythrocytes is accessible to cleavage by phospholipase A. Studies are in progress to identify the molecular epitopes on the individual proteins within the complex responsible for lipid interaction in the erythrocyte bilayer and to determine the specificity of the phospholipid interaction using erythrocyte phospholipids.     

Photoaffinity labeling of procaine-binding sites in normal and sickle cell membranes

A photoaffinity probe, procaine azide, was employed to determine the sites of interaction of procaine in normal and sickle cell erythrocytes. Studies show that the number of binding sites and affinity of procaine to membranes derived from normal and sickled cell erythrocytes were similar, although procaine retards the in vitro formation of irreversibly sickled cells from cells. The results show that procaine azide, a photoaffinity analogue of procaine, is covalently incorporated into both protein (60–70%) and lipid (40–30%) components of the membrane. Sodium dodecyl sulfate-gel electrophoresis of the labeled ghosts show that procaine binds specifically to band 3 and periodic acid-Schiff staining bands in membranes derived from labeled erythrocytes. Binding of procaine or covalent incorporation of procaine azide into membrane proteins does not affect the phosphate transport. Moreover, pre-treatment of intact erythrocytes with 4,4′-diisothiocyano-2,2′-stilbene disulfonate, an anion transport inhibitor, did not affect either the binding or covalent incorporation of procaine azide into erythrocytes. These results indicate that the binding of procaine azide to Band 3 protein occurs at a locus different than that involved in anion translocation process.     

Species variability in the modification of erythrocyte surface proteins by enzymatic probes

Bovine and equine erythrocytes have been studied by three different surface modification techniques to investigate the accessibility of the surface components to the external medium. Lactoperoxidase labeling of equine erythrocytes results in a significant labeling of only one membrane component, a 100 000-mol.wt polypeptide corresponding to the membrane-spanning Component III of human erythrocytes. The major sialoglycoprotein of the equine erythrocyte is not labeled. This is in contradistinction to the situation for human and bovine cells, where both components are labeled. The equine membrane sialoglycoprotein is also not markedly affected by pronase, chymotrypsin or trypsin treatment of whole cells under the treatment conditions used, although it can be cleaved by pronase in isolated membranes. Experiments with the isolated glycoprotein show that its cleavage by trypsin is quite selective, whereas cleavage by pronase and chymotrypsin is much more extensive. Labelling of bovine red cells by galactose oxidase treatment followed by reduction with ³H-labeled borohydride yields radioactivity in only one major peak, that corresponding to the glycoprotein. Pretreatment of the cells with neuraminidase causes a dramatic increase in the labeling. Equine erythrocytes do not show significant labeling by this technique unless a neuraminidase pretreatment has been performed. Then only the major glycoprotein is labeled. Thus the equine glycoprotein is apparently inaccessible to the cell surface by standard surface modification methods, although it is clearly a surface component. These experiments point out some of the limitations of surface labeling and proteolysis methods in probing the accessibility of membrane components. The results suggest that the apparent inaccessibility of the equine glycoprotein is due partially to its structure and partially to its localization in the membrane.     

The transmembrane proteins in the plasma membrane of normal human erythrocytes. Evaluation employing lactoperoxidase and proteases.

The molecular architecture of the human erythrocyte membrane has been probed using lactoperoxidase-catalyzed iodination in conjunction with Pronase hydrolysis. Resealed, hemoglobin-free ghosts were labeled at the cytoplasmic surface and the external membrane surface was subsequently digested with Pronase. Changes in size of the components labeled at the cytoplasmic surface were readily detected by sodium dodecyl sulfate gel electrophoresis. The protein 3 molecular weight class labeled at the cytoplasmic surface was extensively hydrolyzed at the external surface to produce a major 65000 molecular weight fragment and a minor 45000 molecular weight fragment. When resealed membranes were labeled on the external surface the same 65000 molecular weight labeled component is produced. These results unequivocally demonstrate that the same polypeptides in the protein 3 molecular weight class that can be labeled by lactoperoxidase at the cytoplasmic membrane surface are digested by Pronase at the external surface and are, therefore, transmembrane components. Where it is possible to label one surface of a membrane with lactoperoxidase and reseal the membrane this procedure represents an alternate method for establishing transmembrane configuration of membrane proteins.