Identification of Plasmodium knowlesi erythrocyte binding proteins

Plasmodium knowlesi, a malaria of Old World monkeys, invades all Duffy blood group positive human erythrocytes and various New World monkey erythrocytes except Cebus apella. We had previously identified a 135 kDa parasite protein in supernatants of P. knowlesi cultures that bound to Duffy positive but not to Duffy negative human erythrocytes [Haynes et al., J. Exp. Med. 167, 1873-1881 (1988)]. We now use New World monkey erythrocytes as a reagent to identify P. knowlesi proteins in culture supernatants that will bind to all New World monkey erythrocytes susceptible to invasion but not to C. apella erythrocytes, which are refractory to invasion. The 135 kDa protein binds to all New World monkey erythrocytes, including C. appella. Another protein of 155 kDa binds to all New World monkey erythrocytes except C. apella. The 155 kDa protein binds to Old World monkey erythrocytes, the natural host of P. knowlesi; it does not bind to human Duffy positive erythrocytes. This and the previous study are the beginning of the identification of parasite proteins of P. knowlesi that bind to erythrocytes in a receptor specific manner.     

Splenic requirement for antigenic variation and expression of the variant antigen on the erythrocyte membrane in cloned Plasmodium knowlesi malaria.

Variant antigens appear on the surface of Plasmodium knowlesi-infected erythrocytes as the asexual parasite matures and are detected by antibody-mediated schizont-infected cell agglutination (SICA). We now show that cloned parasites can undergo antigenic variation in nonsplenectomized monkeys. In addition, we previously described a new P. knowlesi phenotype in which uncloned parasites passaged in splenectomized monkeys were no longer agglutinable by immune sera. We have designated this new phenotype SICA[-] and the one expressing the variant antigen SICA[+]. Cloned parasites can also switch from SICA[+] to SICA[-] in splenectomized monkeys. The switch from SICA[+] to SICA[-] is a gradual process that requires sequential subpassage in several monkeys. After passage in one monkey, the agglutination titer decreased 4- to 16-fold. Decreased agglutination was associated with decreased antibody binding on all infected erythrocytes as measured by fluorescein-conjugated anti-rhesus monkey immunoglobulin. The asexual malaria parasite can therefore alter its expression of variant antigen in response to the host environment (antivariant antibody or splenectomy). When cloned SICA[-] parasites were inoculated into intact monkeys, two courses of parasitemia were observed: fulminant parasitemia (greater than 20%) and parasitemia that was controlled. Fulminant infections were associated with conversion of the parasite from SICA[-] to SICA[+], i.e., from nonexpression to expression of the variant antigen on the erythrocyte surface. Parasitized erythrocytes remained SICA[-] in those infections that were controlled. It appears, therefore, that the expression of the variant antigen on the erythrocyte surface may influence parasite virulence.     

Plasmodium falciparum antigens associated with membrane structures in the host erythrocyte cytoplasm

Hybridomas were made from mice immunized with plasma membranes from erythrocytes infected with Plasmodium falciparum. Among the monoclonal antibodies produced, a series reacted with antigens in the host cell cytoplasm. Immunoelectron microscopy, along with indirect fluorescent antibody double labeling experiments, were used to further localize the antigens to membrane structures (presumably Maurer's clefts) in the erythrocyte cytoplasm. The epitopes thus localized are found on three parasite proteins (20 kDa, 29 kDa, and 45 kDa) and one parasite glycoprotein (45 kDa). They are likely to be part of a transport system for the parasite.     

Rapid transport of the acidic phosphoproteins ofPlasmodium berghei andP. chabaudi from the intraerythrocytic parasite to the host membrane using a miniaturized fractionation procedure

A miniaturized procedure for the separation of the host erythrocyte membrane from malarial parasites based on saponin lysis and density-gradient centrifugation with Percoll is described. The procedure requires only 20–35 l packed infected erythrocytes, is simple to perform, needs no sophisticated equipment, and can be completed in <2 h. Analysis of the isolated erythrocyte membranes and parasites using marker enzymes and electron microsropy revealed that both the purity and the yield of these fractions were relatively high. Erythrocyte membrane proteins, including spectrin, ankyrin, and band 4.1, were not found on the parasitophorous vacuolar membrane, which remained associated with some but not all of the isolated parasites. Application of this method to pulse-chase experiments indicated that the acidic phosphoproteins ofPlasmodium berghei andP. chabaudi were rapidly transported from the parasite to the erythrocyte membrane immediately after their synthesis. The rapid export of these acidic phosphoproteins from the parasite distinguishes them from other proteins exported by the malarial parasite.     

Characterization of a Plasmodium falciparum polypeptide associated with membrane vesicles in the infected erythrocytes

A Plasmodium falciparum polypeptide (46 kDa) associated with the infected erythrocytes of all asexual stages as well as immature gametocytes was identified by the monoclonal antibody (Mab) 30B8.3. The expression of this protein was not dependent upon the knobby phenotype and was detected in parasites grown either in human or Aotus erythrocytes. The antigen was heatstable, did not label with [14C]glucosamine, and was not sensitive to periodate oxidation. Immunofluorescent staining patterns of Mab 30B8.3 on in vitro cultured parasites varied from punctate (rings and trophozoites) to patchy (trophozoites and schizonts) fluorescence. The Mab 30B8.3 antigen was not detected on the infected erythrocyte surface by conventional wet-mount IFA procedure. However, when parasites were cultured in the presence of Mab 30B8.3, the epitope was detected by the monoclonal antibodies present in the culture medium. Differential extraction of the polypeptide from infected erythrocytes and immune electron microscopy of cryosectioned parasites localized the 30B8.3 epitope primarily on membranes of Maurer's clefts within the infected erythrocyte's cytosol. This 46 kDa polypeptide is unique because it seemed to be an integral membrane protein of the Maurer's clefts/vesicles and it was not secreted into the culture medium nor deposited on the infected erythrocyte membrane. Previous studies indicate that several parasite proteins, excreted extracellularly or deposited on infected erythrocyte membrane, are found to be associated with Maurer's cleft membranes and vesicles. The 46 kDa polypeptide described in this study may play an important role in the transport of the parasite antigens.     

Fractionation of mouse malarious blood according to parasite developmental stage, using a Percoll-sorbitol gradient

Asexual intraerythrocytic malarial parasites permeabilize the membrane of their host cell to small monelectrolytes and anions. Since permeabilization increases with parasite maturation, this property has been used previously to fractionate blood infected with Plasmodium falciparum and P. knowlesi according to the developmental stage of the parasite, using Percoll-sorbitol density gradients. We have extended this method to fractionate mouse blood infected with four species of rodent malaria: P. chahaudi, P. vinckei, P. voelii and P. berghei. While the method works in principle in this case, the polyparasitism which characterizes these species prevented explicit separation according to developmental stage. Hence, erythrocytes harbouring several ring-stage parasites appeared in the same fraction which contained cells hosting a single trophozoite, and polyparasitized trophozoites were associated with singly-infected schizont. This observation implies that permeabilization of the host cell membrane results from the integrated metabolic activity of the parasite(s) and is not related to a specific phase of parasite development.     

Phosphorylation of erythrocyte membrane and cytoskeleton proteins in cells infected with Plasmodium falciparum

Phosphorylation changes in the erythrocyte membrane and cytoskeletal proteins as a consequence of infection by the malarial parasite Plasmodium falciparum were examined. Spectrin, band 3, band 4.1, ankyrin and glycophorin are phosphorylated in normal erythrocytes. As a consequence of invasion by the merozoite, the extracellular stage of the parasite, into 32P-prelabeled normal erythrocytes, all the major 32P-labeled erythrocyte proteins are dephosphorylated. As the parasite develops intracellularly from the immature ring stage to the mature schizont stage, selective phosphorylation of certain host proteins, spectrin, ankyrin and band 3 is observed. Band 4.1 does not appear to incorporate [32P]phosphate at any stage of parasite development. These observed phosphorylation changes may be important in the regulation of the cytoskeletal organization in P. falciparum-infected cells.     

Glycoprotein recognition mediates attachment of Plasmodium chabaudi to mouse erythrocytes

The interaction between Plasmodium falciparum merozoites and human erythrocytes is mediated by specific parasite proteins and sialoglycoproteins (SGPs) on the surface of the host cell. To investigate whether a similar mechanism functions in rodent malaria, a series of experiments was performed to identify the proteins involved in the interaction of Plasmodium chabaudi parasites and mouse erythrocytes. Labeled parasite proteins incubated with purified mouse SGP bound specifically to glycoprotein 2.1. Two parasite proteins (72 and 126 kilodaltons [kDa]) were coprecipitated with antibody directed to mouse erythrocyte membrane proteins. The lower band (72 kDa) as well as a band of 105 kDa were also observed to bind to N-acetyl-D-galactosamine affinity columns, suggesting a carbohydrate component in the binding of these parasites to erythrocytes. These experiments indicate that P. chabaudi possesses specific proteins which recognized SGP on the surface of murine erythrocytes in a manner similar to that of the merozoites of P. falciparum. Thus P. chabaudi in mice may provide an in vivo model of the human parasite for testing ways to inhibit merozoite recognition and invasion of host cells.     

The C-terminal domain of the Plasmodium falciparum acyl-CoA synthetases PfACS1 and PfACS3 functions as ligand for ankyrin

Infection of erythrocytes by the malaria parasite Plasmodium falciparum results in the export of several parasite proteins into the erythrocyte cytoplasm establishing novel interactions between host and parasite proteins, particularly at the membrane skeleton that modifies both the structural and functional properties of the red cell. We present evidences that two members of the P. falciparum acyl-CoA synthetase (PfACS) family, responsible for the activation of long-chain fatty acids by thio-esterification with CoA, are transported in vesicle-like structures toward the host erythrocyte cytoplasm where they interact with the cytoskeletal protein ankyrin. Carboxyl-terminal domain (CTD) overlay studies indicated that PfACS1 and PfACS3 bind to the 78-kDa fragment of ankyrin corresponding with its spectrin-binding domain. Co-immunoprecipitation of ankyrin and PfACS1/3 indicates that at least a fraction of these proteins are physically associated in the infected erythrocytes and provide evidence for a novel specific interaction which suggest that such a binding may bring these enzymes closer to the host erythrocyte membrane where exogenous fatty acids are available.     

Recognition of the parasite infected cell surface determinants by homologous antiserum raised against infected cell membranes

Identification of neo-antigenic determinant(s) on parasite infected cell surface is important to control intracellular infections. Such determinant(s) on the surface of intact Plasmodium berghei infected erythrocytes have not been conclusively demonstrated. To generate polyclonal antiserum selectively recognizing the parasite infected cell surface determinant(s), in natural state, we have examined the efficacy of the homologous immunizations, in BALB/c mice, with the membrane rich preparation of: i) erythrocytes in vivo infected with Plasmodium berghei and, ii) macrophages in vitro infected with Leishmania donovani. Anti-infected erythrocyte membrane antiserum specifically recognized, albeit at low level, the infected cell surface as determined by flow cytometry and immunoelectron microscopy. Immunoprecipitation of radiolabeled antigens revealed at least three parasite proteins of >205 kDa, 160 kDa and 100 kDa specifically present on infected erythrocyte surface. Normal uninfected erythrocytes did not react with the antiserum. Anti-L. donovani-infected macrophage membrane antiserum also recognized only infected macrophage surface and not the normal macrophages. Thus, the approach may find wide application in delineating disease specific determinant(s) on the infected cell surface, particularly to those where animal models are available. Received: 11 February 1997 / Accepted: 7 May 1997     

The mature-parasite-infected erythrocyte surface antigen (MESA) of Plasmodium falciparum associates with the erythrocyte membrane skeletal protein, band 4.1

Several proteins synthesized by mature asexual stages of Plasmodium falciparum interact with the erythrocyte membrane skeleton. One of these is the mature-parasite-infected erythrocyte surface antigen (MESA; also called PfEMP2), a phosphoprotein of 250-300 kDa, which is found on the internal face of the erythrocyte membrane. When MESA is precipitated with anti-MESA antibodies, another phosphoprotein of 80 kDa is co-precipitated. This 80-kDa phosphoprotein was identified by peptide mapping as the erythrocyte membrane component band 4.1. Thus, MESA is apparently anchored at the erythrocyte membrane through an association with band 4.1. Band 4.1 is more intensely phosphorylated in infected erythrocytes and is increased in relative molecular mass in erythrocytes infected by isolates of P. falciparum that cytoadhere.     

The movement of fluorescent endocytic tracers in Plasmodium falciparum infected erythrocytes.

The fluorescent lipophilic probe 1,1'-dihexadecyl-3-3'-3-3'- tetramethylindocarbocyanine (diIC16) inserted in the red cell surface, functioned as a non-exchangeable lipid marker which was not metabolised or toxic in plasmodial cultures. Invasion by Plasmodium falciparum resulted in the internalisation of the lipid, suggesting the uptake of red cell membrane components during parasite entry. The fluorescent lipid was not transported from red cell to parasite membranes at subsequent stages of development, but label in the erythrocyte-derived parasitophorous vacuole was eventually detected in daughter merozoites. Fluorescent dextrans of 10 kDa in the extracellular medium were also not internalised during intraerythrocytic parasite growth. The results support that with the exception of the invasion step, plasmodial infection does not induce endocytosis in the erythrocyte membrane. Despite the lack of endocytosis, both D and L stereoisomers of the head group blocked phospholipid analogue N-4-nitrobenzo-2-oxa-1,3-diazoledipalmitoyl phosphatidylethanolamine (N-NBD-PE) inserted in the erythrocyte membrane, were internalised by mature infected erythrocytes. Lipid internalisation occurred by a non head group dependent parasite mechanism, which could account for the stage-specific uptake of phospholipids observed in mature infected erythrocytes. We were unable to detect the transport of carbocyanine dyes and N-NBD-PE from intracellular parasites back to the erythrocyte membrane. Additionally, the carbocyanine dyes were not transferred between adjacent organisms in a double infected red cell. The data argue for the absence of bulk membrane lipid transport between individual parasites and their host cell bilayer in an infected erythrocyte.     

Merozoite release from Plasmodium falciparum-infected erythrocytes involves the transfer of DiIC₁₆ from infected cell membrane to Maurer's clefts

Merozoite release from infected erythrocytes is a complex process, which is still not fully understood. Such process was characterised at ultra-structural level in this work by labelling erythrocyte membrane with a fluorescent lipid probe and subsequent photo-conversion into an electron-dense precipitate. A lipophilic DiIC₁₆ probe was inserted into the infected erythrocyte surface and the transport of this phospholipid analogue through the erythrocyte membrane was followed up during 48 h of the asexual erythrocyte cycle. The lipid probe was transferred from infected erythrocyte membranes to Maurer’s clefts during merozoite release, thereby indicating that these membranes remained inside host cells after parasite release. Fluorescent structures were never observed inside infected erythrocytes preceding merozoite exit and merozoites released from infected erythrocyte were not fluorescent. However, specific precipitated material was localised bordering the parasitophorous vacuole membrane and tubovesicular membranes when labelled non-infected erythrocytes were invaded by merozoites. It was revealed that lipids were interchangeable from one membrane to another, passing from infected erythrocyte membrane to Maurer’s clefts inside the erythrocyte ghost, even after merozoite release. Maurer’s clefts became photo-converted following merozoite release, suggesting that these structures were in close contact with infected erythrocyte membrane during merozoite exit and possibly played some role in malarial parasite exit from the host cell.     

Acidic phosphoproteins associated with the host erythrocyte membrane of erythrocytes infected with Plasmodium berghei and P. chabaudi

New phosphoproteins appear on the host erythrocyte membrane during Plasmodium berghei and P. chabaudi infection. Distinct proteins having similar properties and all distinguished by isoelectric points of less than 4.0 are identified. Associated with the erythrocyte membranes of P. berghei infected erythrocytes are two proteins with molecular masses of 65 and 46 kDa, whereas 93, 90 and 76 kDa proteins are observed during P. chabaudi infection. These new erythrocyte membrane associated proteins are all of parasite origin as indicated by metabolic labeling with proline and are synthesized during the ring stage of the asexual replicative cycle. Three of these proteins, the 93 kDa P. chabaudi protein and both P. berghei proteins, have been purified and the amino acid composition determined. All three are characterized by a relatively high proportion of aspartate and glutamate residues. Mono-and polyclonal antibodies were also raised against the same three purified proteins. No cross reactivity between these three proteins is observed, but one monoclonal antibody against the 65 kDa P. berghei crossreacts with a 27 kDa mouse erythrocyte protein. Immunofluorescence using the antibodies in combination with subcellular fractionation studies clearly shows that these phosphoproteins are associated with the host erythrocyte membrane and not the parasite.     

Traffic pathways of Plasmodium vivax antigens during intraerythrocytic parasite development

We investigated the secretory traffic of a Plasmodium vivax antigen (Pv-148) synthesised by the parasite during the blood cycle, exported into the host cell cytosol and then transported to the surface membrane of the infected erythrocyte. Studies of the ultrastructure of erythrocytes infected with P. vivax showed that intracellular schizogony is accompanied by the generation of parasite-induced membrane profiles in the erythrocyte cytoplasm. These structures are detectable soon after the parasite invades the erythrocyte and develop an elaborate organisation, leading to a tubovesicular membrane (TVM) network, in erythrocytes infected with mature trophozoites. Interestingly, the clefts formed stacked, flattened cisternae resembling a classical Golgi apparatus. The TVM network stained with the fluorescent Golgi marker Bodipy-ceramide. Specific immunolabelling showed that Pv-148 was transferred from the parasite to the erythrocyte surface membrane via the clefts and the TVM network. These findings suggest that the TVM network is part of the secretory pathways involved in parasite protein transport across the Plasmodium-infected erythrocyte and that Pv- 148 may represent a marker that links the parasite with the host cell cytoplasm and, in turn, with the extracellular milieu.     

Surface proteins of schizont-infected erythrocytes and merozoites of Plasmodium falciparum

Schizont-infected erythrocytes and merozoites were isolated from in vitro cultures of the human parasite, Plasmodium falciparum labeled with various radioactive substrates. The isolated merozoites were viable since they were able to reinvade fresh erythrocytes. On the basis of sensitivity to specific enzymes, eleven proteins synthesised by the parasite, were localised on the surface of the schizont-infected erythrocyte. Eight of these were glycoproteins, six of which appeared to represent three doublets. Five merozoite surface proteins were identified on the basis of their sensitivity to trypsin and chymotrypsin, treatments which also rendered the merozoite incapable of erythrocyte invasion. Merozoites appeared not to contain any glycoproteins; all of the glycoproteins synthesised by the parasite were apparently transported to the surface of the schizont-infected erythrocyte.     

Membrane orientation and antigenic peptides of an immunoprotective 74 kDa Plasmodium knowlesi glycoprotein

Vaccination trials have shown that a purified, 74 kDa glycoprotein, GP74, isolated from the host cell membrane of Plasmodium knowlesi-infected rhesus erythrocytes, can provide protective immunity against P. knowlesi malaria. We have extended this work by a tryptic peptide analysis of the disposition of GP74 in the host cell membrane. Of the 18 peptides characterized by high-performance liquid chromatography only four were accessible to lactoperoxidase-catalyzed radioiodination of non-leaky, schizont-infected host cells from the extracellular space. Metabolic labeling with radioactive glucosamine indicates that two of the surface exposed peptides are glycopeptides, and one of these, peptide 12 appears to carry a dominant antigenic site, according to its reactivity with immunoglobulin from sera of monkeys protected against P. knowlesi malaria.     

Pfsbp1, a Maurer's cleft Plasmodium falciparum protein, is associated with the erythrocyte skeleton

Antibodies from hyperimmune monkey sera, selected by absorption to Plasmodium falciparum-infected erythrocytes, and elution at acidic pH, allowed us to characterize a novel parasite protein, Pfsbp1 (P. falciparum skeleton binding protein 1). Pfsbp1 is an integral membrane protein of parasite-induced membranous structures associated with the erythrocyte plasma membrane and referred to as Maurer's clefts. The carboxy-terminal domain of Pfsbp1, exposed within the cytoplasm of the host cell, interacts with a 35 kDa erythrocyte skeletal protein and might participate in the binding of the Maurer's clefts to the erythrocyte submembrane skeleton. Antibodies to the carboxy- and amino-terminal domains of Pfsbp1 labelled similar vesicular structures in the cytoplasm of Plasmodium chabaudi and Plasmodium berghei-infected murine erythrocytes, suggesting that the protein is conserved among malaria species, consistent with an important role of Maurer's cleft-like structures in the intraerythrocytic development of malaria parasites.     

Band 3 clustering promotes the exposure of neoantigens in Plasmodium falciparum-infected erythrocytes

Erythrocytes infected with the human malaria parasite Plasmodium falciparum become structurally and antigenically modified as a consequence of intracellular parasite development. The new antigens that appear on the surface of the infected erythrocyte originate from parasite-encoded proteins and by modification of the erythrocyte membrane protein band 3. Here, we show that anti-peptide antibodies generated against an amino acid sequence (YETFSKLIKIFQDH) of human band 3, and previously identified as mediating adhesion of infected erythrocytes to CD36, recognized P. falciparum-infected erythrocytes. In addition, sera from individuals living in a malaria endemic area (and who are presumably immune) contained immunoglobulins specific for this region of band 3. The anti-peptide antibodies reacted with the surface excrescences (knobs) on falciparum-infected erythrocytes. In uninfected erythrocytes, the band 3 region was cryptic and its exposure on the falciparum-infected erythrocyte surface required clustering of band 3 protein. Thus, a parasite-induced modification of band 3 promotes adhesion and induces antigenic changes in the P. falciparum-infected erythrocyte.     

Extracellular development of Plasmodium knowlesi erythrocytic stages in an artificial intracellular medium

The development of erythrocytic stages of Plasmodium knowlesi separated from their host cells has been determined in terms of the capacity of the isolated organisms to carry out the synthesis and secretion of proteins. P. knowlesi trophozoites and schizonts were released from host cells by nitrogen decompression and cultivated in a medium consisting of 20 mM Na+; 120 mM K+; 1 mM Mg2+; no Ca2+; 100 mM Cl-; 20 mM HCO3-; 5 mM Hepes [pH 6.73], glucose, vitamins, amino acids and 10% fetal calf serum. The yield was about 97% intact parasites, judging by their ability to maintain a membrane potential, and these parasites had more than 80% the capacity of infected cells for nuclear replication and macromolecule biosynthesis. Pulse and pulse-chase labeling studies with [35S]methionine show that parasite-synthesized proteins with Mr 160 000, 140 000, 100 000 and 58 000 are exported from the parasite in soluble form. Proteins with Mr 140 000, 100 000, 58 000-60 000, 40 000 were recovered in a particulate fraction isolated from the parasite culture fluid. An Mr 62 000 protein synthesized in large amounts by isolated parasites during the last 2h of the developmental cycle, could not be detected in infected erythrocytes, and a minor early Mr 74 000 protein becomes prominent in free parasites but not infected cells toward the end of the developmental cycle. Parasite-synthesized proteins with Mr 230 000, 160 000, 140 000, 62 000, 58 000 and 45 000 were labeled by incubation with radioactive N-acetylglucosamine during short term incubation in vitro. About 80% of label incorporation occurred via N-glycosylation supported by dolichol derived from the blood, and about 20% via glycolytic intermediates.