Characterization of a high-molecular-weight phosphoprotein synthesized by the human malarial parasite Plasmodium falciparum

Malaria and the red blood cell membrane

Malaria is the most serious and widespread parasitic disease of humans and is arguably the commonest disease of red blood cells (RBCs). Malaria has exerted a powerful effect on human evolution and selection for resistance has led to the appearance and persistence of a number of inherited diseases. After parasite invasion, RBCs are progressively and dramatically modified. New structures appear inside the RBC and novel parasite proteins are exported to the erythrocyte cytoplasm and membrane skeleton. Radical biochemical, morphological, and rheological alterations manifest as increased membrane rigidity, reduced cell deformability, and greater adhesiveness for the vascular endothelium and other blood cells. Numerous protein-protein interactions between the malaria-parasite and the host RBC are important for many aspects of parasite biology and the pathogenesis of malaria. In addition, there are many other parasite proteins located within the infected red cell and at the membrane skeleton, for which no precise functional roles have yet been elucidated. Sequencing and annotation of the complete genome of Plasmodium falciparum, the production of proteomic and transcriptomic profiles of parasites, and the development of a transfection system for the asexual stage of the parasite are all recent achievements that should advance understanding of the molecular mechanisms that underlie the parasite-induced functional alterations in red cells.

The malaria-infected red blood cell: structural and functional changes

The asexual stage of malaria parasites of the genus Plasmodium invade red blood cells of various species including humans. After parasite invasion, red blood cells progressively acquire a new set of properties and are converted into more typical, although still simpler, eukaryotic cells by the appearance of new structures in the red blood cell cytoplasm, and new proteins at the red blood cell membrane skeleton. The red blood cell undergoes striking morphological alterations and its rheological properties are considerably altered, manifesting as red blood cells with increased membrane rigidity, reduced deformability and increased adhesiveness for a number of other cells including the vascular endothelium. Elucidation of the structural changes in the red blood cell induced by parasite invasion and maturation and an understanding of the accompanying functional alterations have the ability to considerably extend our knowledge of structure-function relationships in the normal red blood cell. Furthermore, interference with these interactions may lead to previously unsuspected means of reducing parasite virulence and may lead to the development of novel antimalarial therapeutics.

Plasmodium falciparum: structural and functional domains of the mature-parasite-infected erythrocyte surface antigen

The mature parasite-infected erythrocyte surface antigen (MESA) is a protein exported to the membrane skeleton of the infected red cell, where it forms a strong noncovalent interaction with the host red cell protein, protein 4.1. The complete gene structure of MESA from the Ugandan isolate Palo Alto is described. Comparison to the previously reported MESA sequence from the Papua New Guinean cloned line D10 reveals strong conservation of the general gene structure of a short first exon and a long second exon. The exact exon/intron boundaries were determined by the generation and sequencing of a cDNA from this region. The MESA gene from both isolates consists of seven blocks of repeats that are identical in order. Repeat blocks are conserved to a high degree; however, differences are noted in most blocks in the form of scattered mutations or differences in repeat numbers. Previous work had shown that synthetic peptides spanning a 19-residue region could inhibit the binding of MESA to protein 4.1. Removal of this region from MESA almost completely abolished the binding of MESA to IOVs. Sequencing of this region from a number of laboratory and field isolates demonstrates complete conservation of the cytoskeletal binding domain and flanking sequences.

Defining the minimal domain of the Plasmodium falciparum protein MESA involved in the interaction with the red cell membrane skeletal protein 4.1

During part of its life cycle, the protozoan parasite Plasmodium falciparum lives within the human red blood cell and modifies both the structural and functional properties of the red cell. It does this by synthesizing a number of polypeptides that it transports into the red cell cytoplasm and to the red cell membrane. One of these transported proteins, MESA (mature parasite-infected erythrocyte surface antigen), is anchored to the red cell membrane by noncovalent interaction with erythrocyte protein 4.1. We have utilized a combination of in vitro transcription and translation and a membrane binding assay to identify the protein sequence involved in anchoring MESA to the membrane. Labeled fragments of different regions of the MESA protein were evaluated for their ability to bind to inside-out vesicle membrane preparations of human red cells. Binding was dependent on the presence of red cell membrane proteins and was abolished either by trypsin treatment or by selective depletion of membrane proteins. Binding was specific and could be inhibited by the addition of competing protein, with an IC50 of (6.3 +/- 1.2) x 10(-7) M, indicative of a moderate affinity interaction. Fractionation studies demonstrated that binding fragments interacted most efficiently with membrane protein fractions that had been enriched in protein 4.1. Binding inhibition experiments using synthetic peptides identified the binding domain of MESA for protein 4.1 as a 19-residue sequence near the amino terminus of MESA, a region capable of forming an amphipathic helix.

The secretary pathway of plasmodium falciparum regulates transport of p82/RAP1 to the rhoptries

The rhoptries of Plasmodium falciparum are formed during a restricted period in the asexual erythrocytic cycle. The steps required for rhoptry biogenesis and the pathway for targeting proteins to the rhoptries have not been elucidated. Using the maturation of the Rhoptry-Associated Protein 1 (RAP-1) gene product to study these steps, it is reported here that a secretory pathway controls transport of protein complexes containing RAP-1 products to the rhoptries. Both brefeldin A (BFA) and low temperature reversibly block the processing of an 86-kDa precursor (Pr86) to the mature 82-kDa RAP-1 product (p82). Furthermore, the points of action of BFA and low temperature appear to overlap since their sequential application reversibly prevents Pr86 processing. Treatment of intact cells with N-ethylmaleimide, which prevents the fusion of transport vesicles with Golgi membranes in other eukaryotic cells, irreversibly blocks processing of Pr86. The role of the secretory pathway in targeting p82 protein complexes to the rhoptries product of RAP-1. These in vitro results also reveal that the RAP-1 product contains a cleavable N-terminal signal peptide and appears to be initially synthesized as an 84-kDa protein. The above data indicate that transport of p82 to the rhoptries is regulated by the secretory pathway and that the RAP-1 primary translation product differs in apparent molecular weight from the in vivo precursor Pr86. Our results suggest that rhoptry biogenesis is controlled in part by the secretory pathway and that the RAP-1 gene product acquires a previously undetected protein modification during its maturation.

Parasite-induced changes to localized erythrocyte membrane deformability in Plasmodium falciparum cultures

The effect of intra-erythrocyte development of the Plasmodium falciparum parasite on local deformability of human erythrocyte membranes was studied by aspiration of cells into 0.56 micron diameter pores in polycarbonate filters and examination, after fixing, with a scanning electron microscope. As the aspiration pressure increased, the erythrocyte membrane was extruded into the filter pores. The pressure dependence of the protrusion length and the minimum pressure required to produce any deformation provided measures of the membrane shear and the bending moduli, respectively. At the trophozoite and, to a greater extent, schizont stage of development, host cell membrane deformability was significantly decreased. There was no appreciable difference between uninfected and ring-infected erythrocytes.

Repeat structures in a Plasmodium falciparum protein (MESA) that binds human erythrocyte protein 4.1

The mature-parasite-infected erythrocyte surface antigen (MESA, also known as PfEMP-2 and pp300) of Plasmodium falciparum is a phosphoprotein of approx. 250-300 kDa that is exported from the parasite to the erythrocyte membrane skeleton where it binds to protein 4.1. Determination of the primary sequence of MESA reveals that it is encoded by 2 exons, a structure common to other exported proteins of P. falciparum. The MESA protein is heavily charged and contains 7 distinct repeat regions that compose over 60% of the protein. The predicted secondary structure suggests that MESA is a fibrillar protein and it shows similarity to a number of cytoskeletal and neurofilament proteins, including myosin, a protein that itself binds to protein 4.1.

Malarial proteins that interact with the erythrocyte membrane and cytoskeleton

Several distinct classes of Plasmodium proteins have been proposed to interact with the submembrane skeleton of the erythrocyte based upon differential solubility and subcellular localization studies. That the parasite affects the erythrocyte membrane by interacting with the submembrane skeleton is an attractive hypothesis since the membrane skeleton likely regulates many aspects of membrane topography and function. The precise interactions between host and parasite proteins at the molecular level and how the parasite proteins are transported to the erythrocyte membrane are not completely understood. Experiments addressing these questions are under way, and such studies will provide valuable information about the host-parasite interface. In addition, the characterization of the interaction of Plasmodium proteins with the host erythrocyte membrane may also provide new insight into the structure and function of the erythrocyte membrane or membranes in general.

Localization and stage specific phosphorylation of Plasmodium falciparum phosphoproteins during the intraerythrocytic cycle

Fifty-nine Plasmodium falciparum specific phosphoproteins with molecular weights between 15,000 and 192,000 were analyzed by SDS-PAGE and two-dimensional gel electrophoresis. 40 phosphoproteins were identified by [gamma-32P]ATP labeling of cell lysates, 19 by [32P]orthophosphate labeling of parasitic cultures in vivo. Changes in the phosphorylation pattern during the infectious erythrocytic cycle were determined for all proteins. In parallel, cell fractionation studies were done to follow up possible changes in the cellular distribution of these proteins. Several phosphoproteins are associated with the membrane fraction of infected erythrocytes. One pair of proteins of approx. 88 kDa and a pI of about 5.0 was further characterized. Both proteins are located in the parasitic fractions as well as in the membrane of infected erythrocytes during the entire cycle. Phosphorylation of these proteins, however, is restricted to the trophozoite and schizont stages. Peptide mapping studies demonstrated that both proteins are identical with the exception of minor modifications which are probably not the result of differences in phosphorylation.

Cloning and expression of genomic DNA sequences coding for putative erythrocyte membrane-associated antigens of Plasmodium falciparum

Genomic DNA fragments of Plasmodium falciparum generated by mung bean nuclease digestion were cloned in the lambda expression vector lambda JK2. The resulting library was screened with a rabbit antiserum raised against purified membranes of P. falciparum-infected erythrocytes and with a serum pool from immune humans from an endemic area of Liberia. Positive clones were rescreened with a series of human and monkey sera. Twelve selected clones were analysed in detail. Four of them corresponded to already described membrane-associated P. falciparum antigens. The other positive clones contained inserts which, according to the nucleotide sequence, Southern blot analysis and immunological characteristics, correspond to so far unknown antigens.

Knobs, knob proteins and cytoadherence in falciparum malaria

1. The sequestration of trophozoite and schizont infected erythrocytes (IRBC) in post-capillary venules of host internal organs causes most of the morbidity and mortality in falciparum malaria. It is a knob mediated cytoadherence phenomenon where knobs act as the focal junction between IRBC and host endothelial cell. Knobless (K-) parasites, isolated from cultures (not yet isolated from in vivo), do not cause virulent infections. Knobs thus play an important role in pathophysiology of falciparum malaria. 2. The chemical composition of knobs is partly explored, several proteins (Known as knob proteins) have been identified. According to their function they can be classified as (a) knob-inducing protein, "KAHRP" (b) knob-associated cytoadherent proteins, e.g. PFEMP-1, modified band 3 and an antigen recognized by monoclonal 33G2 and (c) knob-associated structural protein, e.g. PFEMP-2/MESA/PP-300. Most of them show size polymorphism among different isolates. Only KAHRP and MESA/PFEMP-2 have been studied at molecular level. Their chromosomal locations have been identified such as KAHRP on chromosome 2 and MESA/PFEMP-2 on chromosomes 5 and 6. 3. The receptor molecules on endothelial cells for knob ligands have been identified and partially characterized. 4. Knob ligands and their receptor molecules can play an important role in developing the immunotherapeutic reagents. 5. Based on the available data a tentative hypothesis has been proposed about the loss of knobs in vitro. Nevertheless, this needs further support from other experimental evidence. 6. Future work should be directed towards the structure and function of knob proteins and their interactions with each other as well as with host proteins. Regulation of expression of knobs and knob protein(s), evaluation of knob antigens for immunotherapy of severe falciparum malaria and for a malaria vaccine also require further investigations.

Plasmodium falciparum: hetero-oligomeric complexes of rhoptry polypeptides

We have previously described several monoclonal antibodies (McAbs) which specifically recognize antigens in the rhoptries of Plasmodium falciparum and which immunoprecipitate polypeptides of 82, 70, 67, 39, and 37 kDa. We now show that only p82, p70, p67, and a 86-kDa precursor (Pr86) of p82 possessed epitopes for these McAbs. These four proteins were not synthesized until schizogony. These results and proteolysis experiments indicated that Pr86, p82, p70, and p67 were the products of the same gene, whereas the dissimilar digestion patterns of p39 and p37 suggested that p39 was encoded by a second gene and p37 by yet another. Complexes of these proteins (termed RI complexes) are maintained by noncovalent interactions since the ionic detergent SDS was sufficient to dissociate them into individual polypeptides. Sucrose gradient centrifugation demonstrated that RI complex formation was not dependent on the presence of antibody and that these complexes had higher sedimentation rates than the 185-kDa P. falciparum merozoite glycoprotein. Covalent crosslinking with the reversible, homobifunctional, primary amine-specific reagent 3,3'-dithiobis(sulfosuccinimidylpropionate) followed by RI McAb immunoprecipitation resulted in purification of intact complexes which were not dissociable by SDS alone. Immunodepletion experiments with a subtype of RI McAb which does not immunoprecipitate p37 suggested that the binding of p39 and p37 to the other RI proteins was mutually exclusive. Therefore, the minimal composition of the RI complexes is one molecule of Pr86, p82, p70, or p67 and one of p39 or p37. The epitopes of Pr86, p82, p70, and p67 for the RI McAbs were sensitive to disulfide bond reduction. Surprisingly, reduction increased their electrophoretic mobilities. This enhanced mobility could not be accounted for by post-translational glycosylation, phosphorylation, or acylation, or by covalent attachment via the sulfhydryl moiety of cysteine residues to additional parasite proteins. We suggest that, due to an asymmetric distribution of amino acids in the Pr86-class molecules, SDS binding results in a lower charge to mass ratio in the native folded polypeptides and a higher charge to mass ratio upon disulfide bond reduction and unfolding of the polypeptides.

Protein phosphorylation during the asexual life cycle of the human malarial parasite Plasmodium falciparum

Recent evidence has suggested that extensive changes in the phosphorylation profile of red cell membrane proteins are associated with the invasion and development of the malarial parasite. In order to further define the role of parasite protein phosphorylation in these events we have looked at this phosphorylation using: (1) continuous metabolic labelling with [32P]orthophosphate, (2) pulse-labelling with [32P]orthophosphate and [35S]methionine, (3) autophosphorylation of infected cells using [gamma-32P]ATP, (4) invasion of prelabelled red cells. Many parasite proteins were labelled, some differentially according to the phosphorylation protocol employed, and we were able to partially characterise several of the major parasite phosphoproteins in terms of their association with host cell membrane and the stage specificity of phosphorylation.

Cross-reactive asparagine-rich determinants shared between several blood-stage antigens of Plasmodium falciparum and the circumsporozoite protein

From a Plasmodium falciparum cDNA expression library derived from mRNA of the asexual blood stages, we isolated and sequenced five different cDNA clones whose predicted protein products were unusually rich in asparagine (Asn). Two of the clones, R5 and G5, contain tandem imperfectly repeated sequences based on Asn-Asn-Thr (NNT) and Asn-Asn-Met (NNM) respectively. The other three, E4, C5 and R13, as well as G5, contain stretches of polyasparagine varying in length from 2 to 26 residues. Results of DNA blotting experiments with the individual cDNA sequences as probes suggest that each of the five clones corresponds to a different P. falciparum gene. The fragments of P. falciparum proteins expressed by the cDNA clones shared cross-reactive antigenic determinants which were present on multiple P. falciparum proteins. In immunoblotting experiments, owl monkey antibodies selected for binding to the polypeptide expressed by clone E4, C5 or G5 reacted with the expressed proteins from all 5 clones, and with at least 10 proteins from schizont infected erythrocytes. The cross-reactive epitopes could be modeled by two Asn-rich peptide structures: (1) (NNT)8, whose sequence was based on the R5 repeat; and (2) (NPNA)6, whose sequence was based on the Asn-rich repeat of the P. falciparum circumsporozoite protein (CSP). Antibodies that bound to each peptide were selected from sera of immune monkeys that had never been exposed to sporozoites. The selected antibodies bound all 5 expressed proteins in immunoblotting assays and also bound to several proteins from parasitized erythrocytes. Such cross reactivity between the CSP repeating unit and several blood-stage antigens has not been previously reported.

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.