In vitro human cell-free expression system for synthesis of malaria proteins.

In this study, we performed cell-free expression of Plasmodium proteins using the in vitro human cell-free protein expression systems for DNA and mRNA. Malaria rhoptry genes (PFc14_0344, PFc0120w, PY01759, PY00763, PY07482, and PY04666) and a Maurer's cleft gene (PfA0680c) identified from proteome analysis studies were cloned into the pT7CFE1-CHis expression vector. Following a coupled transcription-translation procedure, expressed proteins were analyzed by His-tag staining and by western blotting using protein specific antibodies and nickel-horseradish peroxidase (HRP) for histidine detection. Antibodies against whole rhoptries of Plasmodium falciparum and Plasmodium yoelii merozoites and antibodies specific for the PfMC-2TM protein identified translated proteins. The rhoptry specific antibodies exhibited cross reactivity among the expressed proteins of P. falciparum and P. yoelii. The results demonstrate that the in vitro human cell-free protein expression system is suitable for rapid expression and screening of malaria vaccine candidates and diagnostic biomarkers.

A Plasmodium falciparum protein located in Maurer's clefts underneath knobs and protein localization in association with Rhop-3 and SERA in the intracellular network of infected erythrocytes.

We report on the characterization of monoclonal antibodies against Plasmodium falciparum schizonts, which recognize parasite proteins of 130 kDa and 20 kDa. The 130-kDa protein was released by alkaline sodium carbonate treatment, suggesting that the protein is a peripheral membrane protein, while the 20-kDa protein remained associated with the membranes following alkali treatment, suggesting it may be an integral membrane protein. Both proteins were localized to large cytoplasmic vesicles within the cytoplasm of trophozoite and schizont-infected erythrocytes by immunofluorescence assay and confocal microscopy. Both proteins colocalized with Bodipy-ceramide in trophozoite and immature schizont-infected erythrocytes, but not in segmenters. The 130-kDa protein was localized by immunoelectron microscopy (IEM) to Maurer's clefts underneath knobs in a knobby and cytoadherent (K +/ C+) P. falciparum strain. No IEM reactivity was obtained in a knobless and non-cytoadherent (K-/C-)

Sequence analysis of the Rhop-3 gene of Plasmodium yoelii.

The 110 kDa/Rhop-3 rhoptry protein of Plasmodium falciparum is non-covalently associated with two other proteins, the 140 kDa Rhop-1 and the 130 kDa Rhop-2. cDNAs encoding Rhop-3 from Plasmodium yoelii were isolated using rhoptry-specific antisera from Plasmodium falciparum, P. yoelii, and Plasmodium chabaudi. The cDNAs encoded peptides with partial homology to the C-terminal region (residues 541-861) of P. falciparum Rhop-3. Core regions of homology to the P. falciparum gene will be useful in determining the biological role of Rhop-3 and its potential as a vaccine candidate for malaria.

Isolation of merozoite rhoptries, identification of novel rhoptry-associated proteins from Plasmodium yoelii, P. chabaudi, P. berghei, and conserved interspecies reactivity of organelles and proteins with P. falciparum rhoptry-specific antibodies.

Rhoptries were isolated from merozoites of P. yoelii (17 XL), P. chabaudi adami and P. berghei (K-173), using sucrose gradient density centrifugation. Mouse antisera was prepared against the organelles and characterized. Antibodies specific for a known P. yoelii rhoptry protein were used to identify gradient fractions containing rhoptries and electron microscopy was used to confirm rhoptry enrichment and organelle morphology. Western blotting analysis of the gradients with organelle-specific antisera from each species, revealed several major cross-reactive interspecies protein bands of approximately 235, 210, 180, 160/170, 140, and 96-110 kDa, predominantly in densities of 1.12 and 1.15 g/ml. The parasite origin of the proteins was verified by immunoprecipitation, and reactive epitopes localized to the rhoptries by IEM. By Western blotting antisera specific for P. falciparum rhoptries reacted with protein bands of approximately 96-110 kDa in schizont extracts, and gradient fractions of density 1.12 and 1.15 g/ml from all three rodent malaria species, as well as with the rhoptries in P. yoelii, P. chabaudi, and P. berghei merozoites by IEM. We conclude that the three rodent malaria species and P. falciparum share conserved interspecies epitopes.

Seroprevalence and specificity of human responses to the Plasmodium falciparum rhoptry protein Rhop-3 determined by using a C-terminal recombinant protein.

Rhoptry proteins participate in invasion of erythrocytes by malaria parasites. Antibodies to some of these proteins can inhibit invasion and partially protect monkeys from disease. To examine human serological responses to the 110-kDa component (Rhop-3) of the high-molecular-weight rhoptry protein complex, two cDNA clones corresponding to Rhop-3 were identified by immunologic screening. A recombinant protein representing the C-terminal one-third of the Rhop-3 was used to assess the seroprevalence to this protein in geographically isolated populations with different patterns of malaria transmission. The immunoglobulin G (IgG) positivity rate for the recombinant Rhop-3 in an enzyme-linked immunosorbent assay was 30% in an area of Papua New Guinea where malaria is holoendemic. In Kenya, the prevalence rates were 43 and 36%, respectively, in an area of hyperendemicity and an area of seasonal transmission. By contrast, rates of IgG seroprevalence to an extract of Gambian strain of Plasmodium falciparum were 48, 90, and 97% respectively, in these populations. In these areas, the pattern of antibody recognition of Rhop-3 is more similar (1.7-fold maximum difference) than the parasite extract (5-fold difference). The difference in seroresponses may represent antigenic polymorphism in different parasite strains, while their similarity for the Rhop-3 fragment may represent conservation of this protein. Recombinant- and parasite extract-specific IgG was not found in individuals infected only with Plasmodium vivax. Cross-reactivity was seen in the IgM assay. In Mombasa (Kenya), maternal and cord Rhop-3-specific IgG activities were similar. Fetal antigen-specific IgM reactivity was generally undetectable for all antigens.

Rhoptry organelles of the apicomplexa: Their role in host cell invasion and intracellular survival.

Members of the phylum Apicomplexa are obligate intracellular parasites that invade erythrocytes, lymphocytes, macrophages or cells of the alimentary canal in various vertebrate species. Organelles within the apical complex of invasive stages facilitate host cell invasion. Parasites in this phylum cause some of the most debilitating diseases of medical and veterinary importance. These include malaria, toxoplasmosis, babesiosis, theileriosis (East Coast fever), and coccidiosis in poultry and livestock. In recent years, opportunistic infections caused by Cryptosporidium parvum, and recrudescent Toxoplasma gondii infections in AIDS patients have prompted intensified efforts in understanding the biology of these parasites. In this review, Tobili Sam-Yellowe examines the unifying and variant molecular features of rhoptry proteins, and addresses the role of multigene families in organelle function: the biogenesis of the rhoptries will also be examined, in an attempt to understand the sequence of events leading to successful packaging, modification and processing of proteins within the organelle.

Plasmodium falciparum: effects of membrane modulating agents on direct binding of rhoptry proteins to human erythrocytes.

We studied the effects of membrane modulation on the interaction of Plasmodium falciparum rhoptry proteins of 140/130/110 kDa (Rhop-H) with human and mouse erythrocytes. Cells treated with 2-(2-methoxyethoxy)ethyl-8-(cis-2-n-octylcyclopropyl)octanoate, myristoleyl alcohol, and proteins extracted with sublytic concentrations of membrane solubilizing detergents were used in erythrocyte binding assays. Protein binding was evaluated by immunoblotting using Rhop-H- and SERA-specific antisera, 1B9, K15, and 5E3, respectively. Protein binding to liposomes prepared with dipalmitoyl-L-alpha-phosphatidylcholine (DPPC) or dilauroyl-L-alpha-phosphatidylcholine (DLPC) was also examined. Our results show that erythrocyte membrane modulation markedly enhanced direct Rhop-H binding to intact human erythrocytes. Binding of SERA to intact human erythrocytes appeared unaffected. Both DPPC and DLPC liposomes had similar Rhop-H and SERA protein binding activities. However, binding to DLPC liposomes was reduced. Rhop-H and SERA extracted with the detergents octanoyl-N-methylglucamide, decanoyl-N-methylglucamide, sodium deoxycholate, and 3-[(3-cholamidopropyl)dimethylammonio]-1-propane sulfonate bound directly to intact human erythrocytes, probably by partitioning hydrophobically into the membranes. Sodium carbonate treatment demonstrated a nonintegral association of Rhop-H with the erythrocyte membrane during invasion. Membrane modulation may expose cryptic phospholipid binding sites in the bilayer.

Plasmodium falciparum rhoptry proteins of 140/130/110 kd (Rhop-H) are located in an electron lucent compartment in the neck of the rhoptries.

To investigate in more detail the structure of the high molecular weight rhoptry protein complex of Plasmodium falciparum, Rhop-H (140/130/110 kd), the complex was affinity purified from parasite extracts using rhoptry protein specific antisera prepared against Rhop-H proteins bound to and eluted from Balb/c mouse erythrocytes, using 0.5 M NaCl. The individual proteins (140 kd/Rhop-1, 130 kd/Rhop-2, and 110 kd/Rhop-3) were separated, electroeluted, and monospecific polyclonal antisera prepared against the individual proteins, and against the affinity purified complex. Immunofluorescence assays and immunoelectron microscopic studies were performed to verify the subcellular localization of the Rhop-H epitopes. Immunoblotting and immunoprecipitation assays were also performed. We report novel findings regarding the localization of the rhoptry proteins to an electron lucent compartment in the neck of the rhoptries. Analysis of the amino acid composition of the individually purified Rhop-H proteins demonstrated a predominance of negatively charged (E, D) as well as hydrophobic residues (L, A, P, S) in the three proteins. The percentage of negatively charged residues was high for all three proteins. Similarities in amino acid composition for the three proteins supports the previous data demonstrating shared properties such as erythrocyte and liposome binding, for the three proteins. Results of antibody characterizations using rhoptry protein specific antisera demonstrate the immunodominance of the Rhop-H complex.

Plasmodium falciparum: analysis of protein-protein interactions of the 140/130/110-kDa rhoptry protein complex using antibody and mouse erythrocyte binding assays.

The high-molecular-weight rhoptry proteins of Plasmodium falciparum exist in a multiprotein complex consisting of proteins of 140, 130, and 110 kDa. The complex of rhoptry proteins binds to human and mouse erythrocyte membranes in association with a 120-kDa SERA protein. These proteins are believed to participate in the process of erythrocyte invasion. We have used six different antibodies (polyclonal and monoclonal) known to precipitate the high-molecular-weight rhoptry protein complex (HMWC) to analyze the structural relationship of proteins within the complex. Limited proteolysis of immune complexes (IC) immobilized on Sepharose beads (protein "footprinting") and binding of SV8 protease generated peptides to intact mouse erythrocytes was performed. The 140-kDa polypeptide was more susceptible to protease digestion followed by the 130- and 110-kDa polypeptides. The susceptibility of the 140-kDa polypeptide to protease digestion was independent of the type of precipitating antibody. We identified a 120-kDa protein as the major proteolytic fragment of the 140-kDa protein. SV8 protease generated peptide fragments derived from the 110- and 130-kDa proteins contained putative mouse erythrocyte binding domains. Immunoprecipitation of SV8-generated peptides gave peptide profiles similar to those obtained with protein "footprinting". Additional experiments performed to investigate the stability of the HMWC using chaotropic and lyotropic agents demonstrated that the HMWC was stable to perturbatory reagents known to disaggregate macromolecular complexes. Solubilization of schizonts with 6 M urea and 4 M MgCl2 followed by IC formation led to differential precipitation of the 110-kDa polypeptide, while solubilization with 3 M KCl resulted in the differential precipitation of the 140- and 130-kDa polypeptides, suggesting that both proteins may be in direct association. Treatment of immobilized IC with different perturbatory agents including 6 M urea, 3 M KCl, 4 M MgCl2, or 2% SDS from an insoluble matrix resulted in the elution of the intact complex. The mouse erythrocyte binding property of the HMWC is conserved among different geographical isolates of P. falciparum. The results provide insights concerning the mechanism of protein-protein interaction within the complex.

Monoclonal antibody epitope mapping of Plasmodium falciparum rhoptry proteins.

Plasmodium falciparum rhoptry proteins of the 140/130/110-kDa high molecular weight complex (HMWC) are secreted into the erythrocyte membrane during merozoite invasion. Epitopes of membrane-associated HMWC proteins can be detected using rhoptry-specific antibodies by immunofluorescence assays. Phospholipase treatment of ring-infected intact human erythrocytes, membrane ghosts, and inside-out vesicles results in the release of the HMWC as demonstrated by immunoblotting. We characterized the membrane-associating properties of the 110-kDa protein in more detail. PLA2 from three different sources; bee venom, Naja naja venom, and porcine pancreas, were examined and all were equally effective in releasing the 110-kDa protein. Furthermore, PLA2 activity was inhibited by o-phenanthroline, quinacrine, maleic anhydride, and partially by p-bromophenacyl bromide, indicating that the activity of PLA2 is specific. Using sequential protease and phospholipase digestion experiments to map the immunoreactive and functional epitopes of the 110-kDa protein, a 35-kDa protease-resistant protein associated with mouse and human erythrocyte membranes was identified. Limited proteolysis of the 110-kDa protein and analysis by immunoblotting demonstrated several immunoreactive cleavage products, including a highly protease-resistant peptide fragment of approximately 35-kDa which corresponds to the membrane-associated protein. Epitope mapping of the 130-kDa rhoptry protein resulted in a different pattern of cleavage products. Stage-specific metabolic labeling of P. falciparum with [3H] palmitate and [3H] myristate was performed to determine the lipophilic properties of the HMWC. Results showed the incorporation of label into proteins of approximate molecular weight 200 and 45-kDa, predominantly in the late schizont stage. Interestingly, proteins of 140 and 110/100-kDa, corresponding to [35S] methionine-labeled proteins were labeled with [3H]palmitate in ring-infected erythrocyte membranes. However, these proteins were not immunoprecipitated by a rhoptry protein-specific monoclonal antibody, 1B9. Similar label incorporation was not obtained with [3H]myristate. In Triton X-114 solubility studies, the HMWC proteins partitioned into the aqueous phase, suggesting that they are not integral membrane proteins. In addition, the proteins were extracted by 100 mM Na2CO3, pH 11.5, and immunoprecipitated by rhoptry-specific antibody. These results suggest that the HMWC proteins may exist in a soluble and membrane bound form. The latter may participate in membrane expansion and the formation of the parasitophorous vacuole during merozoite invasion.

Molecular factors responsible for host cell recognition and invasion in Plasmodium falciparum.

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.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Binding of Plasmodium falciparum rhoptry proteins to mouse erythrocytes and their possible role in invasion.

Rhoptry proteins of Plasmodium falciparum merozoites, of 140, 130, and 110 kDa, identified by co-precipitation with Mab.1B9, bind selectively to mouse erythrocytes and reticulocytes. The properties of binding are shown to correlate with invasion of P. falciparum into mouse erythrocytes. Invasion of two strains of P. falciparum 7G8 and FCR-3, into mouse erythrocytes was examined, and was found to differ significantly. The 7G8 strain invades mouse erythrocytes at a rate of 40-60% compared to invasion into human erythrocytes, whereas FCR-3 invades at a rate of 5-15%. Both strains of P. falciparum preferentially invade reticulocytes in the in vitro invasion assay. This correlated with an increase in the amount of rhoptry protein of the 7G8 strain bound to mouse erythrocytes, compared to the FCR-3 strain and an increased binding to reticulocytes compared to mature erythrocytes. Binding of the rhoptry proteins and merozoite invasion into the erythrocyte is blocked in erythrocytes treated with trypsin and chymotrypsin but not in neuraminidase-treated erythrocytes, suggesting that the putative receptor site is exposed and accessible on the erythrocyte surface. Rabbit antiserum against gp3, the major glycophorin of mouse erythrocytes, blocks binding of the rhoptry proteins to erythrocytes and reduces merozoite invasion into mouse erythrocytes by 50%. Binding of rhoptry proteins to mouse reticulocytes was not blocked by alpha gp3 indicating a receptor difference between reticulocytes and erythrocytes. Mab.1B9 reduces merozoite invasion but does not decrease binding of the rhoptry proteins to the mouse erythrocyte. The mouse erythrocyte serves as a useful model to study the receptor-ligand interaction of rhoptry proteins and host surface proteins and to define the role of the rhoptry proteins during the invasion process.

Secretion of Plasmodium falciparum rhoptry protein into the plasma membrane of host erythrocytes.

The rhoptry is an organelle of the malarial merozoite which has been suggested to play a role in parasite invasion of its host cell, the erythrocyte. A monoclonal antibody selected for reactivity with this organelle identifies a parasite synthesized protein of 110 kD. From biosynthetic labeling experiments it was demonstrated that the protein is synthesized midway through the erythrocytic cycle (the trophozoite stage) but immunofluorescence indicates the protein is not localized in the organelle until the final stage (segmenter stage) of intraerythrocytic development. Immunoelectron microscopy shows that the protein is localized in the matrix of the rhoptry organelle and on membranous whorls secreted from the merozoite. mAb recognition of the protein is dithiothreitol (DTT) labile, indicating that the conformation of the epitope is dependent on a disulfide linkage. During erythrocyte reinvasion by the extracellular merozoite, immunofluorescence shows the rhoptry protein discharging from the merozoite and spreading around the surface of the erythrocyte. The protein is located in the plasma membrane of the newly invaded erythrocyte. These studies suggest that the 110-kD rhoptry protein is inserted into the membrane of the host erythrocyte during merozoite invasion.