Isolation and partial characterization of the human erythrocyte band 7 integral membrane protein.

Monoclonal antibodies to the Mr 31,000 major integral membrane protein of the human erythrocyte band 7 region were used to identify the corresponding polypeptide chain and epitope-carrying fragments on immunoblots. Analysis of the erythrocyte membrane, membrane fractions, and cytosol revealed that the Mr 31,000 band 7 integral membrane protein is unique and not related to any of the other water-soluble or membrane-bound band 7 components. Cross-reacting proteins were identified in the membranes of other mammalian erythrocytes and in cell lines of epithelial and lymphoid origin. Proteolytic digestion of intact human erythrocytes or erythrocyte membranes demonstrated that the band 7 integral membrane protein has an intracellular domain larger than Mr 12,000; it does not have an extracellular one. One of the monoclonal antibodies was employed for the isolation of band 7 integral membrane protein by immunoaffinity chromatography; subsequent Edman degradation revealed a blocked N-terminus.     

Biochemistry of the erythrocyte Rh polypeptides: a review

The clinically important Rh blood group system is complex, consisting of multiple distinct antigens. Despite clinical recognition for over 50 years, the Rh blood group antigens have remained poorly understood on a molecular level until the recent identification and characterization of the "Rh polypeptides," the core structural proteins of the Rh antigens. This group of erythrocyte membrane proteins of molecular weight 30,000-35,000 daltons was first recognized by employing Rh-specific antibodies to immunoprecipitate radiolabeled components of erythrocyte membranes. By using antibodies specific for the Rh D, c, and E antigens, a series of highly related non-identical proteins were immunoprecipitated, indicating that the Rh antigens are composed of multiple related proteins. The Rh polypeptides have been purified and characterized, and they were found to have several unusual biochemical characteristics. The Rh polypeptides penetrate the membrane bilayer; they are linked to the underlying membrane skeleton; they are covalently fatty acid acylated with palmitate. While the Rh antigenic reactivity is unique to human erythrocytes, the Rh polypeptides have been isolated from erythrocytes of diverse species and are thought to be fundamental components of all mammalian erythrocyte membranes. The functional role of the Rh polypeptides remains undefined, but a role in the organization of membrane phospholipid is suspected.     

Transbilayer movement of phosphatidylserine in nonhuman erythrocytes: evidence that the aminophospholipid transporter is a ubiquitous membrane protein

A 31-32-kDa integral membrane protein has been previously identified in erythrocytes as the protein most likely to be responsible for the transbilayer movement of phosphatidylserine (PS) [Connor & Schroit (1988) Biochemistry 27, 848-851]. Using similar techniques, we have identified analogous proteins of identical molecular weights in bovine, equine, ovine, porcine, canine, caprine, and rhesus red blood cells. Similar to human red blood cells, all of the mammalian cells were able to specifically transport an exogenously supplied fluorescent PS analogue from their outer-to-inner membrane leaflet. In addition, transport could be reversibly inhibited with the sulfhydryl-specific inhibitor pyridyldithioethylamine (PDA). PDA-sensitive PS transport was also observed in nucleated human and murine cell lines. Analysis of isolated plasma membranes from 125I-PDA-labeled cells revealed marked labeling of a 32,000-Da component. Attempts to inhibit PS transport by treating the cells with proteases, lectins, or antibody suggested that the 32-kDa polypeptide is an integral membrane protein that does not contain sites critical to its function at the cell surface.     

Isolation, partial chemical and biological characterization of thymone B

A new approach to the study of the molecular arrangements of proteins in membranes is described. Irradiation with visible light of native erythrocytes or washed erythrocyte membranes suspended in buffers containing a) riboflavin, fluorescein or fluorescein coupled to dextran and b) ³H-labelled tryptophan resulted in incorporation of radioactivity into the membrane proteins. Polyacrylamide gel electrophoresis of solubilized membranes followed by radioactivity measurements of the separated membrane proteins revealed that in native erythrocytes the protein components known to be located at the exterior cell surface, Band 3 and the major sialoglycoproteins became specifically labelled, whereas in washed lysed cells all of the major membrane proteins were labelled.     

Response of erythrocytes to heat in the presence of D2O, glycerol, and anisotonic saline

Mammalian erythrocytes that lack cytoplasmic organelles and a nucleus are a useful model for studying the effect of heat on the cell membrane and cytoskeleton. The effect of heat on the membrane bilayer and cytoskeleton of erythrocytes is remarkably similar to that observed in nucleated cells. Some concentrations of D2O and glycerol can effectively protect erythrocytes from heat-induced damage to the membrane and cytoskeleton. These results are similar to observations in nucleated cells. Heating erythrocytes in some concentrations of anisotonic NaCl solutions reduced damage, an observation that does not apply to enhanced killing of nucleated cells. This difference implies that some components of the cytoplasm or nucleus, or both, may contribute to the enhancement of cytotoxicity of nucleated cells when they are heated in the anisotonic NaCl solution. Incremental heating, dividing a heat treatment into two fractions, and preheating of erythrocytes all modify the effect of heat on erythrocytes slightly, but the results suggest little, if any, development of thermotolerance. The response of chicken erythrocytes is similar to that of mammalian erythrocytes, although higher temperatures are required to produce a heat effect in chicken erythrocytes. These observations suggest that the characteristic differences in heat sensitivity in nucleated and enucleated cells involve components other than the cell membrane.     

Phosphorylation in membranes of intact human erythrocytes.

Studies of phosphorylation in membranes of intact human erythrocytes were performed by incubating erythrocytes in inorganic [32P]phosphate. Analysis of membrane proteins by polyacrylamide gel electrophoresis showed a pattern of phosphorylation similar to that observed when ghost membranes were incubated with [gamma-32P]ATP. Membrane lipid phosphorylation was also similar in intact cells and ghosts. The most heavily phosphorylated lipid, polyphosphoinositide, was closely associated with glycophorin A, the major erythrocyte membrane sialoglycoprotein obtained when the sialoglycoprotein fraction was isolated by the lithium diiodosalicylate-phenol partition procedure. Only 1 molecule of glycophorin A out of every 100 was found to be phosphorylated, and the phosphate exchange occurred specifically in the COOH-terminal intracellular portion of glycophorin A. These studies show that the human erythrocyte can be used as a model for membrane phosphorylation in an intact cell system.     

Apoptosis and eryptosis: Striking differences on biomembrane level

The cell plasma membrane plays an essential role in programmed cell death of nucleated cells (apoptosis) and erythrocytes (eryptosis), and its changes due to loss of transmembrane asymmetry are quite similar. However, nucleated cells possess the network of intracellular membranes, which are missing in erythrocytes. Providing comparative studies with series of molecular probes, we observe dramatic differences in membrane lipid order in the course of apoptosis and eryptosis. In contrast to nucleated cells, in which a significant drop of the lipid order in the plasma membrane is observed, the erythrocyte membrane retains the relatively high level of the lipid order. Observation in nucleated cells of significant differences between inner and plasma membranes and detection of apoptotic bodies with different organization suggest that the decrease in the lipid order of their plasma membrane could be at least partially explained by the phospholipid and/or cholesterol exchange between membranes. Such features are absent in erythrocytes.     

Alkylacyl glycerophosphoinositol in human and bovine erythrocytes. Molecular species composition and comparison with glycosyl-inositolphospholipid anchors of erythrocyte acetylcholinesterases.

Glycosyl-inositolphospholipid (glycosyl-PtdIns) anchors of proteins in mammalian cells which have been analyzed so far are exclusively of the alkylacyl type. However, little is known about the putative precursor of glycosyl-PtdIns, the alkylacyl derivative of glycerophosphoinositol (GroPIns), in these cells since it is generally believed that cellular GroPIns consists of diacyl-type molecular species only. In this report, we describe the isolation and identification of alkylacyl GroPIns molecular species in both human and bovine erythrocytes, and compare it with the molecular species compositions of the glycosyl-PtdIns anchors of human and bovine erythrocyte acetylcholinesterase. Diradyl GroPIns was isolated from lipid extracts of ghost membranes and treated with phospholipase C. Diradylglycerols of the glycosyl-PtdIns anchors of affinity-purified human and bovine erythrocyte acetylcholinesterase were generated by sequential treatment with glycoprotein phospholipase D and acidic phosphatase and by PtdIns-specific phospholipase C, respectively. Diradylglycerols were subsequently converted into benzoate derivatives and separated into diacyl, alkylacyl, and alkenylacylglycerol subclasses. The molecular species compositions were quantitated and determined by combined HPLC/mass spectrometry. We found that human and bovine erythrocyte membrane diradyl GroPIns consist of 1.5-4.8% alkylacyl GroPIns. Molecular species analysis showed a heterogeneous species composition for both human and bovine erythrocyte alkylacyl GroPIns. Their compositions are distinctly different from those of human and bovine erythrocyte acetylcholinesterase glycosyl-PtdIns anchors. The number of alkylacyl GroPIns molecules/cell is roughly equal with the number of glycosyl-PtdIns-anchored proteins in human erythrocytes.     

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.     

Structural effects in vitro of the anti-inflammatory drug diclofenac on human erythrocytes and molecular models of cell membranes

Diclofenac, a nonsteroidal anti-inflammatory drug (NSAID), has been widely investigated in terms of its pharmacological action, but less is known about its effects on cell membranes and particularly on those of human erythrocytes. In the present work, the structural effects on the human erythrocyte membrane and molecular models have been investigated and reported. This report presents the following evidence that diclofenac interacts with red cell membranes: a) X-ray diffraction and fluorescence spectroscopy of phospholipid bilayers showed that diclofenac interacted with a class of lipids found in the outer moiety of the erythrocyte membrane; b) in isolated unsealed human erythrocyte membranes (IUM) the drug induced a disordering effect on the acyl chains of the membrane lipid bilayer; c) in scanning electron microscopy (SEM) studies on human erythrocytes it was observed that the drug induced changes different from the normal biconcave morphology of most red blood cells. This is the first time in which structural effects of diclofenac on the human erythrocyte membrane have been described.     

Evidence for the participation of cytosolic protein kinases in membrane phosphorylation in intact erythrocytes.

The effects of adenosine 3':5'-monophosphate (cyclic AMP) on the phosphorylation of membrane proteins in intact rabbit and human erythrocytes were investigated. The addition of cyclic AMP to intact human or rabbit erythrocytes results in an increase in the incorporation of ortho[32P]phosphate into several membrane protein components which are known to serve as substrates for the cyclic-AMP-dependent protein kinases. Thus this increase in protein phsophorylation is probably due to the activation of either soluble or membrane-bound cyclic-AMP-dependent protein kinases. Incubation of human erythrocytes in the presence of ortho [32P]phosphate and cyclic AMP also leads to the phosphorylation of a membrane protein component, band 7, which has not been previously detected in the autophosphorylation of isolated ghosts. Since rabbit erythrocyte membranes do not contain any cyclic-AMP-dependent protein kinase, the results suggest that cytoplasmic kinases also play a role in the phosphorylation of membrane proteins in intact cells.     

Unique properties of the camel erythrocyte membrane: II. Organization of membrane proteins

Camel erythrocyte membranes are distinguished by some unique properties of stability and composition. Notable is their abundance in proteins (protein: lipid ratio of 3 : 1). Membrane proteins of camel erythrocytes were compared with those of human erythrocytes, which have been intensively investigated. Proteins were extracted with various aqueous media (EDTA, alkaline or high ionic strength) and with ionic and non-ionic detergents and were analyzed by gel electrophoresis. In membranes of camel erythrocytes, the peripheral proteins constitute, proportionally, a much smaller fraction of total proteins than in the human erythrocyte, while their distribution is identical per unit of surface area. The camel erythrocyte membrane is particularly rich in integral proteins and in intramembranous particles. The proteins in this membrane are more closely organized than in the human system, as revealed by crosslinking and freeze-etching studies. It is proposed that protein-protein interaction of integral proteins, presumably constituting an “integral skeleton”, is a dominant structural feature stabilizing the camel erythrocyte membrane.     

Characterization of an orthorhombic crystal form of iron-containing superoxide dismutase from Escherichia coli B.

Human erythrocytes were treated with the diazonium salt of oligodeoxythymidylic acid 5′-p-aminophenylphosphate, a reagent that does not penetrate the plasma membrane. Ghosts were isolated, and the oligomers, covalently linked at their 5′ ends to the outer surface of the membrane, were extended by treatment with terminal deoxynucleotidyl transferase in the presence of deoxythymidine triphosphate. The membranes were dissolved in sodium dodecyl sulfate, and complexes containing cell surface components were isolated by hybridization to polyriboadenylic acid-agarose. The cell surface components were regenerated by treatment with nuclease P₁ in the presence of Triton X100. Sodium dodecyl sulfate/polyacrylamide gels of the regenerated material showed bands III, PAS-1, PAS-2, and PAS-3, i.e. the major proteins known to be accessible at the outer surface of the human erythrocyte. The method should be useful for the isolation of surface components in other cell types.     

Demonstration of immunoreactive forms of erythrocyte protein 4.2 in nonerythroid cells and tissues

Protein 4.2 is a major component of the erythrocyte membrane cytoskeleton. Here we show that immunoreactive forms of human (Mr 72,000) and pig (Mr 75,000) protein 4.2 are also associated with the plasma membrane of various nonerythroid cells and tissues, such as platelets, brain, and kidney. Protein 4.2 can be extracted from platelet membranes under the same conditions (pH 11, 1 M KI, 1 M urea) which are required to extract protein 4.2 from the erythrocyte plasma membrane. The demonstration of protein 4.2 in nucleated cells that contain also several other proteins of the erythrocyte membrane cytoskeleton indicates some general principles underlying the molecular construction of the plasma membrane in erythrocytes and nonerythroid cells.     

Quantitative composition and characterization of the proteins in membrane vesicles released from erythrocytes by dimyristoylphosphatidylcholine. A membrane system without cytoskeleton

Membrane vesicles were prepared by incubation of human erythrocytes with dimyristoylphosphatidylcholine [3] and isolated by isopycnic centrifugation on Dextran density gradients. Protein analyses were carried out with crossed immunoelectrophoresis and dodecylsulfate polyacrylamide gel electrophoresis. The right-side-out-oriented membrane vesicles contained membrane and cytoplasmic proteins of the erythrocyte but lacked cytoskeletal components. Comparison of proteins in vesicles and erythrocyte membranes showed that acetylcholinesterase was enriched two to six times in the vesicles relative to both membrane-spanning proteins, band 3, and glycophorin. Two further, hitherto unidentified, sialic acid-containing membrane antigens were found in the vesicles. Both faced the outside of the membranes and were enriched two to seven times. Ankyrin was not present in the membrane vesicles and spectrin could not be detected by dodecylsulfate polyacrylamide gel electrophoresis. We suggest that the redistribution of proteins in the vesicles reflects differences in their interactions with other membrane components and their relative mobility within the erythrocyte membrane.     

Mechanical lysis of human erythrocytes. Membrane stabilization by plasma proteins]

Mechanical properties of erythrocyte membranes play an important role in red cell functions. Stability of human erythrocytes under deforming mechanical tensions which occur in the rapidly moving fluid is studied. The activation energy of the mechanical hemolysis determined by the temperature dependence of the hemolysis rate is 55 + 7 kJ/mol. The fragility of erythrocytes rises sharply as the salt concentrations increase. Glutaric dialdehyde forms a certain number of interprotein bonds which increase the fragility of erythrocytes. The mechanical stability of the erythrocyte membrane falls at high (0.5 M) ethanol concentrations. Blood plasma proteins, particularly human serum albumin, have a pronounced stabilizing effect. The hemolysis occurring during the rapid mixing is not probably associated with an osmotic mechanism since high sucrose concentrations do not prevent this process. The mechanical hemolysis depends both on the deforming tension arising in the membrane and on the state of the erythrocyte membrane.     

Hypochlorous acid-induced lysis of human erythrocytes. Inhibition of cellular damage by the isoflavonoid genistein-8-C-glucoside

Erythrocyte damage induced by hypochlorous acid (HOCl) results in cell lysis developing with time after the oxidant is removed (post-hemolysis). The apparent rate constant of post-hemolysis depends on time of incubation in the presence of HOCl and concentration of this oxidant. HOCl-dependent damage of erythrocyte membranes is associated with uncompetitive inhibition of the membrane-bound acetylcholinesterase. Genistein-8-C-glucoside is an isoflavonoid isolated from the flowers of Lupinus luteus L.; in aqueous solution, genistein-8-C-glucoside (0.5-2 mM) efficiently inhibited HOCl-induced damage to erythrocytes similar to the known HOCl scavengers taurine and reduced glutathione. This bioflavonoid can protect the erythrocyte membrane (and to a lesser extent, intraerythrocytic components) by interacting with the reactive chlorine species including hypochlorous acid and membrane-bound chloroamines formed in the reaction of HOCl with erythrocyte membrane proteins.     

Atomic Force Microscopy of Asymmetric Membranes from Turtle Erythrocytes

The cell membrane provides critical cellular functions that rely on its elaborate structure and organization. The structure of turtle membranes is an important part of an ongoing study of erythrocyte membranes. Using a combination of atomic force microscopy and single-molecule force spectroscopy, we characterized the turtle erythrocyte membrane structure with molecular resolution in a quasi-native state. High-resolution images both leaflets of turtle erythrocyte membranes revealed a smooth outer membrane leaflet and a protein covered inner membrane leaflet. This asymmetry was verified by single-molecule force spectroscopy, which detects numerous exposed amino groups of membrane proteins in the inner membrane leaflet but much fewer in the outer leaflet. The asymmetric membrane structure of turtle erythrocytes is consistent with the semi-mosaic model of human, chicken and fish erythrocyte membrane structure, making the semi-mosaic model more widely applicable. From the perspective of biological evolution, this result may support the universality of the semi-mosaic model.     

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.