Antibody-mediated glycophorin C coligation on K562 cells induces phosphatidylserine exposure and cell death in an atypical apoptotic process.

BACKGROUND: Glycophorin C (GPC) is necessary in the maintenance of red blood cell structure. Severe autoimmune hemolytic anemia and hemolytic disease of the fetus and newborn (HDFN) have been associated with Gerbich (Ge) blood group system antigens expressed on GPC. Previous in vitro studies with cord blood progenitor cells have shown that anti-Ge suppresses erythropoiesis. STUDY DESIGN AND METHODS: Here, we evaluated the K562 erythroleukemic cell line to study the cellular effects of a murine anti-GPC. Cell proliferation was evaluated after treatment with anti-GPC. Flow cytometry was used to evaluate exofacial phosphatidylserine (PS) expression and cell viability (propidium iodide binding). Cell morphology was evaluated under light microscopy with cytospin preparations stained with May-Grünwald Giemsa. RESULTS: Anti-GPC dramatically inhibited K562 proliferation and increased PS expression, consistent with cytoplasmic blebbing, suggesting evidence of apoptosis. Z-VAD-FMK, an inhibitor of classical apoptosis, was unable to reverse the suppressive effect of anti-GPC. However, hemin was able to attenuate growth suppression. CONCLUSION: Together, the data suggest that anti-GPC suppresses erythroid proliferation through the induction of nonclassical apoptosis.

In vitro genetic analysis of an erythrocyte determinant of malaria infection.

Invasion of erythrocytes by Plasmodium falciparum is an obligatory step in the life cycle of the parasite. A major challenge is the unambiguous identification and characterization of host receptors. Because erythrocytes lack nuclei, direct genetic analyses have been limited. In this work, we combined an in vitro erythrocyte culture system, which supports P. falciparum invasion and growth, with lentiviral transduction to knock down gene expression. We genetically demonstrate, in an isogenic background, that glycophorin A is required for efficient strain-specific parasite invasion. We establish the feasibility of in vitro systematic functional analysis of essential erythrocyte determinants of malaria and erythrocyte biology.

Kinetic evidence for modulation by glycophorin A of a conformational equilibrium between two states of band 3 (SLC4A1) bound reversibly by the competitive inhibitor DIDS.

Recent evidence has suggested that erythrocytes naturally deficient in glycophorin A (GPA) have a reduced V(max) for monovalent anion exchange. Unanswered is whether miss-folding of band 3 during biosynthesis, or the absence of GPA modulation of properly folded band 3 is responsible. Here, I determine the effect of selective depletion of GPA on the kinetics of reversible binding of the competitive transport inhibitor DIDS (4,4'-diisothiocyanato-2,2'-stilbenedisulfonate) to properly folded band 3. Reversible binding of DIDS follows biphasic kinetics: a fast phase {DIDS+band 3<-->(DIDS-band 3), k(1), k(-1)} and a slower phase {(DIDS-band 3)<-->(DIDS-band 3), k(2), k(-2)}. Selective depletion of GPA was accomplished by pretreating membranes with Triton X-100, over a range where erythrocyte hemolysis is inhibited by the detergent (0% to 0.03%, v/v). Pretreatment with sublytic Triton X-100: (a) virtually completely depleted GPA, (b) did not deplete membrane-bound band 3, and (c) slowed the overall rate of reversible binding of DIDS to band 3. Data analysis and model simulation studies indicated that the decrease in the rate of binding of DIDS was due exclusively to a decrease in k(-2), with no change in the initial rate of binding. Thus, depletion of GPA does not alter the native conformation of band 3 at the DIDS binding site, but rather modulates a conformational equilibrium between two states of the binary complex formed by the competitive inhibitor DIDS, reversibly bound to properly folded band 3.

Host receptors in malaria merozoite invasion.

The clinical manifestations of Plasmodium falciparum malaria are directly linked to the blood stage of the parasite life cycle. At the blood stage, the circulating merozoites invade erythrocytes via a specific invasion pathway often identified with its dependence or independence on sialic acid residues of the host receptor. The invasion process involves multiple receptor-ligand interactions that mediate a complex series of events in a period of approximately 1 min. Although the mechanism by which merozoites invade erythrocytes is not fully understood, recent advances have put a new perspective on the importance of developing a multivalent blood stage-malaria vaccine. In this review, we highlight the role of currently identified host invasion receptors in blood-stage malaria.

Attachment of bovine parvovirus to O-linked alpha 2,3 neuraminic acid on glycophorin A.

The bovine parvovirus (BPV) hemagglutinates human erythrocytes by binding to glycophorin A (GPA). The purpose of this study was to determine which carbohydrate on GPA binds BPV. Treatment of GPA with alpha2,3,-6,-8 neuraminidase eliminated binding of BPV to GPA. Beta-elimination of O-linked sialic acids on GPA eliminated binding, while removal of N-linked carbohydrates using the N-glycosidase PNGase F failed to eliminate binding. Treatment of GPA with a neuraminidase which specifically cleaved alpha2,3 glycosidic bonds eliminated BPV binding and, following this treatment, virus binding to GPA was restored by reconstitution of alpha2,3-linked neuraminic acids. These results indicated the O-linked alpha2,3 neuraminic acids of GPA bind BPV.

Babesia divergens and Plasmodium falciparum use common receptors, glycophorins A and B, to invade the human red blood cell.

Babesiosis has long been recognized as an economically important disease of cattle, but only in the last 30 years has Babesia been recognized as an important pathogen in humans. Invasion of erythrocytes is an integral part of the Babesia life cycle. However, very little information is available on the molecules involved in this process, in contrast to another hemoparasite, Plasmodium falciparum. Using invasion assays into normal red blood cells (RBCs), enzyme-treated cells, and clinically mutant cells, we showed that Babesia divergens uses neuraminidase- and trypsin-sensitive receptors to enter the RBCs, of which glycophorins A and B are the prominent ones. These results could have broad implications relating to evolutionarily conserved mechanisms of host cell entry in these related Apicomplexan parasites and pave the way toward a detailed molecular analysis of erythrocyte invasion in B. divergens.

Production of hemo- and immunoregulatory cytokines by erythroblast antigen+ and glycophorin A+ cells from human bone marrow.

BACKGROUND: Erythroid nuclear cells (ENC) of the bone marrow (BM) have not previously been considered as important producers of wide spectrum of haemo- and immunoregulatory cytokines. The aim of the current work was to confirm the production of the main hemo- and immunoregulatory cytokines in human ENC from BM. RESULTS: We used native human BM ENC in our experiments. We for the first time have shown, that the unstimulated erythroblasts (Gl A+ or AG-EB+) produced a wide spectrum of immunoregulatory cytokines. Human BM ENC produce cytokines such as interleukin (IL)-1beta, IL-2, IL-4, IL-6, interferon (IFN)-gamma, transforming growth factor (TGF)-beta1, tumor necrosis factor (TNF)-alpha and IL-10. They can be sub-divided into glycophorin A positive (Gl A+) and erythroblast antigen positive (AG-EB+) cells. To study potential differences in cytokine expression between these subsets, ENC were isolated and purified using specific antibodies to Gl A and AG-EB and the separated cells were cultivated for 24 hours. The cytokine contents of the supernatant were measured by electrochemiluminescence immunoassay. Quantitative differences in TGF-beta1 and TNF-alpha production were found between Gl A+ and AG-EB+ BM ENC. Furthermore, in vitro addition of erythropoietin (EPO) reduced IFN-gamma and IL-2 production specifically by the AG-EB+ ENC. Thus, Gl A+ and AG-EB+ ENC produce IL-1beta, IL-2, IL-4, IL-6, IFN-gamma, TGF-beta1 and TNF-alpha. Gl A+ ENC also produce IL-10. CONCLUSION: Cytokine production by erythroid nuclear cells suggests that these cells might be involved in regulating the proliferation and differentiation of hematopoietic and immunocompetent cells in human BM.

Capsid region involved in hepatitis A virus binding to glycophorin A of the erythrocyte membrane.

Hepatitis A virus (HAV) has previously been reported to agglutinate human red blood cells at acidic pHs. Treatment of erythrocytes with different enzymes and chemical reagents indicated that HAV attachment is mediated through an interaction with sialylglycoproteins. HAV hemagglutination could be blocked by incubating the virus with glycophorin A, indicating that this sialylglycoprotein is the erythrocyte receptor. The number of receptors used was estimated to be around 500 per cell. At the same time, HAV-induced hemagglutination could also be blocked by either monoclonal antibody H7C27 or an anti-VP3(102-121) ascitic fluid, indicating that lysine 221 of VP1 and the surrounding VP3 residues lining the capsid pit are involved in HAV binding to erythrocytes.

Attachment of bovine parvovirus to sialic acids on bovine cell membranes.

Although it has previously been shown that bovine parvovirus (BPV) attaches to the sialated glycoprotein glycophorin A on erythrocytes, the nature of virus-binding moieties on mammalian nucleated cells is less clear. Buffalo lung fibroblasts (Bu), primary bovine embryonic kidney cells, Madin-Darby bovine kidney cells and bovine embryonic trachea (EBTr) cells were assessed for molecules capable of binding BPV. Competition studies were carried out on both erythrocyte and nucleated cell targets using a variety of sialated compounds and sialic acid-negative compounds. Glycophorin A was found to inhibit BPV binding, while mucin exhibited low-level inhibition. These two sialated compounds also blocked attachment of BPV-modified microsphere carriers to the Bu cell membrane. Influenza A virus was used as a sialic acid competitor and interfered with BPV attachment to erythrocytes and replication in Bu cells. Significantly, the enzyme sialidase removed BPV-binding sites from Bu and EBTr cells. The binding sites could be reconstituted on sialidase-treated cells by the enzymes alpha-2,3-O-sialyltransferase and alpha-2,3-N-sialyltransferase. These results indicated that BPV can attach to sialic acid on cell membranes and that the sialylglycoproteins available for virus attachment appear to contain both N- and O-linked carbohydrate moieties, but that not all members of the sialic acid family can bind BPV. Moreover, there may be other moieties that can bind BPV, which may act as either primary or secondary receptors.

Duffy antigen is important for the lethal effect of the lethal strain of Plasmodium yoelii 17XL.

We studied the potential role of the Duffy antigen and glycophorin A as receptors for rodent malaria parasite invasion of erythrocytes. Parasitemia increased exponentially after infection with Plasmodium berghei NK65, P. chabaudi, and P. vinckei in Duffy antigen knockout, glycophorin A knockout, and wild-type mice, indicating that the Duffy antigen and glycophorin A are not essential for these malaria parasites. However, parasitemia of the Duffy antigen knockout mice infected with P. yoelii 17XL remained constant from day 5 to 14 after infection, and then decreased, resulting in autotherapy. The treatment of P. yoelii 17XL-infected Duffy antigen knockout mice with anti-CD4 antibody increased the parasitemia 15 days after infection and the mice eventually died, indicating that CD-4-positive cells play an important role in the clearance of P. yoelii 17XL at the late stage of the infection.

Mechanism of protein sorting during erythroblast enucleation: role of cytoskeletal connectivity.

During erythroblast enucleation, nuclei surrounded by plasma membrane separate from erythroblast cytoplasm. A key aspect of this process is sorting of erythroblast plasma membrane components to reticulocytes and expelled nuclei. Although it is known that cytoskeletal elements actin and spectrin partition to reticulocytes, little is understood about molecular mechanisms governing plasma membrane protein sorting. We chose glycophorin A (GPA) as a model integral protein to begin investigating protein-sorting mechanisms. Using immunofluorescence microscopy and Western blotting we found that GPA sorted predominantly to reticulocytes. We hypothesized that the degree of skeletal linkage might control the sorting pattern of transmembrane proteins. To explore this hypothesis, we quantified the extent of GPA association to the cytoskeleton in erythroblasts, young reticulocytes, and mature erythrocytes using fluorescence imaged microdeformation (FIMD) and observed that GPA underwent dramatic reorganization during terminal differentiation. We discovered that GPA was more connected to the membrane cytoskeleton, either directly or indirectly, in erythroblasts and young reticulocytes than in mature cells. We conclude that skeletal protein association can regulate protein sorting during enucleation. Further, we suggest that the enhanced rigidity of reticulocyte membranes observed in earlier investigations results, at least in part, from increased connectivity of GPA with the spectrin-based skeleton.

Glycophorin A requirement for expression of O-linked antigens on the erythrocyte membrane.

BACKGROUND: Glycophorin A (GPA) has a large number of sialic acid-containing oligosaccharide chains. GPA is highly conserved among vertebrates, mice with a GPA deletion have not been reported and GPA's physiologic role remains uncertain. RESULTS: GPA-/- homozygotes were obtained by intercrossing GPA+/- heterozygotes based on Mendelian genetics. The amount of O-linked oligosaccharide chains in the erythrocyte membrane of GPA-/- mice decreased to 60% compared to that of the wild-type mice. Flow cytometry and Western blot analysis revealed that the TER antigen that is associated with GPA on the erythrocyte membrane was totally abrogated from the cell surface in GPA-/- mice. Several glycoproteins that were detected with peanut agglutinin (PNA), a lectin that recognizes O-linked oligosaccharide chains, were absent from the GPA-/- erythrocyte membrane. Erythrocytes lacking GPA were more sensitive to hypo-osmotic stress than wild-type erythrocyte. CONCLUSIONS: GPA-/- mice show apparently normal phenotypes at least during the early generations. The disappearance of many glycoproteins recognized by PNA lectin on the GPA-/- erythrocyte membrane proteins suggests that GPA has an essential role in the expression of O-linked antigens on the erythrocyte membrane protein. These interactions of GPA and other glycoproteins may contribute to maintaining the physical strength of the erythrocyte membrane.

Glycophorin C is the receptor for the Plasmodium falciparum erythrocyte binding ligand PfEBP-2 (baebl).

We report in this paper that glycophorin C (GPC) is the receptor for PfEBP-2 (baebl, EBA-140), the newly identified erythrocyte binding ligand of Plasmodium falciparum. PfEBP-2 is a member of the Duffy binding-like erythrocyte binding protein (DBL-EBP) family. Although several reports have been published characterizing PfEBP-2, the identity of its erythrocytic receptor was still unknown. Using a combination of enzymatically treated red blood cells (RBCs) and rare, variant RBCs lacking different surface proteins, we have shown that PfEBP-2 does not bind to cells lacking GPC. Additionally, we found that PfEBP-2 binds differentially to variants of GPC lacking exon 2 or exon 3, and determined that the binding domain on GPC is potentially restricted to amino acid residues 14 through 22 within exon 2. Thus PfEBP-2 is involved in a sialic acid-dependent pathway of invasion, which does not involve glycophorin A or glycophorin B and represents a novel route of entry into the RBCs.

Lectin-erythrocyte interaction with external transmembrane glycophorin saccharides controlling membrane internal cytoskeleta.

Human red blood cell (RBC, erythrocyte) membranes have internal protein skeletons that govern the cells' distinctive discocyte-echinocyte morphology (shape) changes, seen in conventional microscopy. Glycophorin, the cell's transmembrane protein, presents all of its saccharides outside the cell. The protein sector of glycophorin is linked inside to the RBC cytoskeleton, enabling lectins binding to the external saccharides to gain profound control over internal cytoskeleton behavior, expressed by governance of the visibly seen cell shape. Critical lectin binding stoichiometries ((125)I-labeled lectins) equate to the number of glycophorin monomers per RBC, 7 x 10(5) copies/cell. Wheat germ agglutinin lectin (sialic acid specific) binds to glycophorin's outermost (exo) saccharides and exerts tight control over the cell's morphology. Removal of sialic acid groups (desialation) exposes the endosaccharides of glycophorin, enabling peanut agglutinin and Osage orange lectins to gain equally tight control over the RBC's morphology behavior in simple stoichiometric ratios, bound lectin molecules/glycophorin receptor. Thus, lectin specificities for saccharides are sharply in register with the glycophorin external saccharide composition, the sequence along the chains, and the number of copies of protein (stoichiometry). These relationships were determined via RBC shape change equilibria and also via shape change rates. Rate data are somewhat laborious to determine, but are exquisitely sensitive to lectin specificities and in very small lectin concentrations. Both classes of data enable these interactions to be analyzed in lectin and RBC concentrations approximately 100-fold smaller than agglutinating levels.

Glycophorin A-mediated haemolysis of normal human erythrocytes: evidence for antigen aggregation in the pathogenesis of immune haemolysis.

The inexplicable severity of anti-Pr autoimmune haemolytic anaemia led us to test the hypothesis that the haemolysis was primarily due to a change in the function of glycophorin A, on which the Pr antigen is located. The lectins Maclura pomifera and wheat germ agglutinin that bind to glycophorin A induced the haemolysis of normal erythrocytes in vitro. Lectin binding led to an increase in erythrocyte membrane permeability to sodium and potassium, the former resulting in an influx of water and subsequent haemolysis. The response was glycophorin A specific as Concanavalin A, which binds to band 3, did not cause haemolysis and peanut agglutinin only did so after removal of erythrocyte sialic acid. The lectin-induced cation leak was not mediated by activation of cation channels as the inhibitors, tetrodotoxin, amiloride and 4,4' disothiocyanate stilbene 2,2'disulphonate, had no effect, suggesting that the haemolysis was due to exacerbation of the inherent cation permeability of the erythrocyte membrane. A human IgAK anti-Pr autoantibody and a mouse anti-human glycophorin A antibody increased erythrocyte permeability to sodium. The role of glycophorin A in stabilizing and, upon aggregation, destabilizing the phospholipid bilayer is discussed. Our findings may help explain the severity of anti-Pr autoimmune haemolytic anaemia and other pathophysiological changes in human erythrocytes.

Plasmodium falciparum field isolates commonly use erythrocyte invasion pathways that are independent of sialic acid residues of glycophorin A.

Erythrocyte invasion by malaria parasites is mediated by specific molecular interactions. Sialic acid residues of glycophorin A are used as invasion receptors by Plasmodium falciparum. In vitro invasion studies have demonstrated that some cloned P. falciparum lines can use alternate receptors independent of sialic acid residues of glycophorin A. It is not known if invasion by alternate pathways occurs commonly in the field. In this study, we used in vitro growth assays and erythrocyte invasion assays to determine the invasion phenotypes of 15 P. falciparum field isolates. Of the 15 field isolates tested, 5 multiply in both neuraminidase and trypsin-treated erythrocytes, 3 multiply in neuraminidase-treated but not trypsin-treated erythrocytes, and 4 multiply in trypsin-treated but not neuraminidase-treated erythrocytes; 12 of the 15 field isolates tested use alternate invasion pathways that are not dependent on sialic acid residues of glycophorin A. Alternate invasion pathways are thus commonly used by P. falciparum field isolates. Typing based on two polymorphic markers, MSP-1 and MSP-2, and two microsatellite markers suggests that only 1 of the 15 field isolates tested contains multiple parasite genotypes. Individual P. falciparum lines can thus use multiple invasion pathways in the field. These observations have important implications for malaria vaccine development efforts based on EBA-175, the P. falciparum protein that binds sialic acid residues of glycophorin A during invasion. It may be necessary to target parasite ligands responsible for the alternate invasion pathways in addition to EBA-175 to effectively block erythrocyte invasion by P. falciparum.

N-linked oligosaccharides can protect target cells from the lysis mediated by NK cells but not by cytotoxic T lymphocytes: role of NKG2-A.

We have previously shown that glycophorin A (GPA), inserted by electropulsation into the membrane of K562 cells, protected them from natural killer (NK) cell-mediated cytotoxicity and the unique N-linked oligosaccharide of GPA was essential for resistance to occur. The present study demonstrates that the protection level conferred by GPA is similar to the resistance induced by HLA-Cw3 expressed by transfected K562 cells. A monoclonal antibody against NKG2-A, an NK inhibitory receptor interacting with HLA class I antigens and belonging to the C-type lectin receptor, was able to restore the ability of NK cells to lyse K562 cells expressing HLA-Cw3 at the cell membrane but not electroinserted-GPA, suggesting that the N-linked oligosaccharide of GPA cannot be a ligand for NKG2-A. GPA was then electroinserted into the membrane of two lymphoblastoid B-cell lines: one was sensitive to NK cell-mediated lysis, the other was susceptible to cytotoxic CD8+ T-lymphocyte (CTL)-mediated cytotoxicity. The electroinserted GPA protected the target cells from NK-mediated cytotoxicity, whereas it did not modify the cell susceptibility to lysis by CTL. Endoglycosidase F treatment abolished the resistance towards NK cell-mediated lysis, suggesting that N-linked glycans could inhibit mechanisms used by NK cells to exert their cytotoxic function in agreement with our previous results.