Plasmodium falciparum antigens synthesized by schizonts and stabilized at the merozoite surface by antibodies when schizonts mature in the presence of growth inhibitory immune serum

Some immune sera that inhibit erythrocyte invasion by merozoites also agglutinate the merozoites as they emerge from rupturing schizonts. These immune clusters of merozoites (ICM) possess a surface coat that is cross-linked by antibody and is thicker than the surface coat associated with normal merozoites (NM) obtained from cultures containing preimmune serum. Analysis of metabolically labeled ICM and NM performed by using sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that washed ICM possessed immune complexes containing antigens representative of schizonts and merozoites. Characteristics of the immune complexes included: a) they were not soluble in pH 8 Triton X-100, b) they were soluble at an acid pH, and c) after pH neutralization they were precipitated by using staphylococcal protein A. Merozoite antigens having Mr of 83, 73, and 45 kDa were associated with immune complexes in ICM. The 83 and 73 kDa antigens were recovered in considerably larger quantities from ICM than from NM. Schizont antigens having Mr of 230, 173 (triplet), 152 (doublet), and 31 kDa were associated with immune complexes in ICM, and a 195 kDa antigen(s) from schizonts and merozoites was also present in the immune complexes. In addition, other antigens of Mr 113, 101, 65, and 51 kDa may have been immune complexed. These 15 antigens accounted for less than 30% of the schizont and merozoite antigens recognized by the immune serum. Immune complexes probably formed between antibodies and a) surface antigens of schizont-infected erythrocytes exposed to antibody before schizont rupture, b) surface antigens of merozoites and schizonts exposed during schizont rupture, and c) soluble antigens normally released during schizont rupture. The antibody components of the immune complexes may have prevented rapid degradation or shedding of some antigens from the merozoite surface. Allowing schizonts to rupture in the presence of inhibitory antibodies (to form ICM) is a useful approach to identifying exposed targets of protective immunity against malaria.     

Plasmodium falciparum: two antigens of similar size are located in different compartments of the rhoptry

Two previously described antigens, AMA-1 and QF3, which are located in the rhoptries of Plasmodium falciparum merozoites have polypeptides of similar relative molecular masses. On immunoblots, antibodies to both antigens recognized polypeptides of relative molecular mass 80,000 and 62,000 in all isolates tested. Two-dimensional electrophoresis showed that the isoelectric points of the two antigens were different. QF3 being more basic than AMA-1. AMA-1 was soluble in Triton X-114 whereas QF3 partitioned into the aqueous phase after temperature-dependent phase separation. In immunoelectron microscopic studies. QF3 was found in the body of the rhoptry whereas AMA-1 was consistently found in the neck of the rhoptry. Both antigens gave a punctate double-dot pattern in mature schizonts and merozoites when visualized by fluorescence microscopy, but AMA-1 antibodies also appeared to label the merozoite surface. QF3 was also detected in ring-infected erythrocytes whereas AMA-1 was not. Synthesis of both antigens was first observed in mature trophozoites and immature schizonts. Pulse-chase experiments showed that the Mr 80,000 polypeptide of the AMA-1 gene was subject to immediate processing to the Mr 62,000 product. This cleavage pattern was not stage specific. The Mr 80,000 polypeptide of QF3 was derived from a short-lived Mr 84,000 precursor polypeptide. Processing of the Mr 80,000 polypeptide to an Mr 62,000 polypeptide was restricted to the period of merozoite maturation and reinvasion. Hence AMA-1 and QF3 are different antigens with polypeptides of similar size but located in different compartments of the merozoite rhoptries.     

Monoclonal antibody characterization of the 195-kilodalton major surface glycoprotein of Plasmodium falciparum malaria schizonts and merozoites: identification of additional processed products and a serotype-restricted repetitive epitope

The gp195 from Camp strain parasites was characterized with eight monoclonal antibodies (MAb) that recognize different epitopes on gp195 and three of its merozoite-associated processed products. Four MAb (3H7, 3B10, 7F1, and 4G12) reacted with different epitopes on the 45-kDa glycosylated product (gp45), shown by differences in their reactivities with soluble and immunoblotted gp45. One MAb (7H10) reacted with a conformational epitope probably formed as a result of the interaction of gp45 with a nonglycosylated 45-kDa product (p45). Three other MAb (3D3, 7B11, and 7B2) reacted with different epitopes on a nonglycosylated 83-kDa product (p83), shown by differences in their reactivities against various parasite isolates in immunofluorescent antibody assays. Immunoprecipitation of antigens that were pulse-labeled with [3H]isoleucine and chased with cold isoleucine showed that p45 and gp45 were processed products of gp195 and p83 was sequentially processed into smaller fragments of 73 and 67 kDa (p73 and p67). Immunoblots showed that the 7B11 and 7B2 epitopes were present on p83, p73, and p67, but that the 3D3 epitope was present only on p83 and p73. A two-site immunoassay showed the 3D3 epitope to be repetitive. The 3D3 and 7B11 epitopes were serotype restricted (present in seven and 24 of 33 isolates, respectively), but the other five epitopes were common to all isolates tested. The gp195 and its processed products have Mr that are consistent with the Mr of a number of antigens shown previously to be associated with the immune complexes that are formed when merozoites are agglutinated by antibodies contained in some growth inhibitory immune sera.     

Proteins and antigens of merozoites and sporozoites of Eimeria bovis (Apicomplexa)

Proteins and antigens of first-generation merozoites and sporozoites of Eimeria bovis were examined using standard sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), Western blotting and lactoperoxidase iodination procedures. SDS-PAGE gels revealed both common and unique protein bands in merozoite and sporozoite extracts, ranging in molecular weight (Mr) from 15,000 to 215,000. Nitrocellulose immunoblots of separated proteins, when probed with sera obtained from immunized calves, revealed numerous IgG-binding antigens of Mr 18,000 to 180,000 in merozoites and Mr 28,000 to approximately 118,000 in sporozoites. Although merozoite and sporozoite preparations each contained antigens of different molecular weights, 4 antigens had the same migratory distance in both preparations (Mr 58,000, 70,000, 83,000, 98,000). Of 3 types of immune sera used to probe immunoblots, serum taken from a calf that had been inoculated with oocysts of E. bovis and boosted 10 wk later by subcutaneous injection with 2 X 10(7) live merozoites emulsified in Freund's complete adjuvant consistently identified and reacted more intensely with more antigens of merozoites and sporozoites than the other immune sera tested. Autoradiographic analysis of radioiodinated parasites revealed major surface proteins on merozoites of between 15,000 and 18,000 Mr and 3 surface proteins on sporozoites of Mr 28,000, 77,000, and 183,000. All but the 183,000 protein elicited an IgG antibody response in the host.     

Monoclonal antibody characterization of Plasmodium falciparum antigens in immune complexes formed when schizonts rupture in the presence of immune serum

When Plasmodium falciparum parasites are cultured with some immune sera, merozoites are agglutinated by antibodies to form immune clusters of merozoites and prevent their invasion into erythrocytes. Within these immune clusters of merozoites, several antigens that are normally found in the soluble fraction after detergent extraction accumulate in relatively insoluble immune complexes. From mice immunized with these immune complexes, we obtained hybridomas secreting monoclonal antibodies (mAb) that react with various immune clusters of merozoites antigens, including mAb 3D5, which recognizes a 101-kDa antigen (p101) and mAb, 5E3, which recognizes a 113-kDa antigen (p113). Both mAb reacted with antigens at the surface of schizonts, in the vacuolar space, and at the surface of merozoites before their release from schizont-infected cells. Both p101 and p113 were synthesized by mature trophozoites and young schizonts. In pulse-chase experiments, p113 was processed to 100-, 70-, 55-, and 50-kDa products. Both p101 and p113 appeared in the culture medium when schizont rupture occurred in normal culture medium but were found in immune complexes when schizont rupture occurred in the presence of immune serum. Antibodies in immune complexes, when dissociated with acid and used to probe immunoblots, reacted with affinity-purified p101 and p113. Antigens such as these, which are accessible at the parasite surface and react with antibodies present in immune serum that inhibits parasite invasion, are logical candidates to study in the search for a vaccine against the erythrocytic stages of malaria.     

Plasmodium vivax: exoerythrocytic schizonts recognized by monoclonal antibodies against blood-stage schizonts

Exoerythrocytic parasites of Plasmodium vivax grown in human hepatoma cells in vitro were probed with monoclonal antibodies raised against other stages of P. vivax. Monoclonal antibodies specific for four independent antigens on blood-stage merozoites all reacted with exoerythrocytic schizonts and merozoites by immunostaining. The characteristic staining pattern of each monoclonal antibody was similar on both blood- and exoerythrocytic-stage parasites and appeared only in mature schizont segmenters. In contrast, a monoclonal antibody specific for the caveolar-vesicle complex of the infected host cell membrane and a second monoclonal antibody reacting with an unknown internal antigen did not appear to react with exoerythrocytic parasites. We confirm prior reports that monoclonal antibodies against the sporozoite immunodominant repeat antigen react with all exoerythrocytic-stage parasites, but note that as the exoerythrocytic parasite matures the immunostaining is concentrated in plaques reminiscent of germinal centers and apparently distinct from mature merozoites. These results indicate that mature merozoites from either exoerythrocytic or blood-stage parasites are antigenically very similar, but that stage-specific antigens may be found in specialized structures present only in a specific host cell type.     

Protective antigens of bloodstage Plasmodium knowlesi parasites

The simian malaria Plasmodium knowlesi provides many favourable features as an experimental model; it can be grown in vivo or in vitro. Parasites of defined variant specificity and stage of development are readily obtained and both the natural host and a highly susceptible host are available for experimental infection and vaccination trials. Proteins synthesized by erythrocytic P. knowlesi parasites are characteristic of the developmental stage, as are the alterations that the parasite induces in the red cell surface. Erythrocytic merozoites are anatomically and biochemically complex, their surface alone is covered by at least eight distinct polypeptides. Immune serum from merozoite-immunized rhesus recognizes many parasite components, especially those synthesized by schizonts. All of the merozoite surface components and some of the schizont-infected red cell surface antigens are recognized by such immune sera. Rhesus monkeys rendered immune by repeated infection may by contrast recognize comparatively few antigens; a positive correlation was established for these 'naturally' immunized monkeys between protection and antibody directed against a 74 000 molecular mass antigen. Immunization with this purified antigen confers partial protection. Other putative protective antigens have been identified by monoclonal antibodies that inhibit merozoite invasion of red cells in vitro. The antigens recognized by inhibitory monoclonal antibodies are synthesized exclusively by schizonts and are processed, at the time of schizont rupture and merozoite release, to smaller molecules that are present on the merozoite surface. The multiplicity of protective antigens is clearly demonstrated by the fact that seven distinct merozoite surface antigens are recognized by three different inhibitory monoclonals. None of the protective antigens identified are variant or strain specific.     

Plasmodium berghei XAT: protective 155/160 kDa antigens are located in parasitophorous vacuoles of schizont-stage parasite

Effective blood-stage malaria vaccine candidates have been mainly developed from the proteins in exposed locations on the parasite such as the surface of free merozoites or infected red blood cells. In the present study, we identified and localized novel protective antigens derived from the blood-stage of Plasmodium berghei XAT after establishment of hybridomas producing protective monoclonal antibodies (mAbs) against the parasites. The protective antigens were expressed in schizonts but not in trophozoites, and located in the parasitophorous vacuoles in the infected erythrocyte cytoplasm. The antigens, with molecular weight of 155/160 kDa, were not identical to any merozoite/schizont antigens that have been reported as target molecules recognized by mAbs developed to rodent malaria parasites. The characterization of new malarial antigenic targets of potentially protective antibody responses following infection would give us new insights for the selection of candidate antigens for malaria vaccine.     

Antibodies elicited by a virosomally formulated Plasmodium falciparum serine repeat antigen-5 derived peptide detect the processed 47 kDa fragment both in sporozoites and merozoites

Serine repeat antigen-5 (SERA5) is a candidate antigen for inclusion into a malaria subunit vaccine. During merozoite release and reinvasion the 120 kDa SERA5 precursor protein (P120) is processed, and a complex consisting of an N-terminal 47 kDa (P47) and a C-terminal 18kDa (P18) processing product associates with the surface of merozoites. This complex is thought to be involved in merozoite invasion of and/or egress from host erythrocytes. Here we describe the synthesis and immunogenic properties of virosomally formulated synthetic phosphatidylethanolamine (PE)-peptide conjugates, incorporating amino acid sequence stretches from the N-terminus of Plasmodium falciparum SERA5. Choosing an appropriate sequence was crucial for the development of a peptide that elicited high titers of parasite cross-reactive antibodies in mice. Monoclonal antibodies (mAbs) raised against the optimized peptide FB-23 incorporating amino acids 57-94 of SERA5 bound to both P120 and to P47. Western blotting analysis proved for the first time the presence of SERA5 P47 in sporozoites. In immunofluorescence assays, the mAbs stained SERA5 in all its predicted localizations. The virosomal formulation of peptide FB-23 is suitable for use in humans and represents a candidate component for a multi-valent malaria subunit vaccine targeting both sporozoites and blood stage parasites.     

N-Acetylglucosamine-binding proteins on Plasmodium falciparum merozoite surface

Plasmodium falciparum merozoite surface is specifically labelledwith a neoglycoprotein bearing N-acetylgluco-samine (GlcNAc)residues in a sugar-dependent manner, as shown by affinity cytochemistryin fluorescence and electron microscopy. To ascertain the natureof the sugar receptor, merozoite proteins were blotted and testedby a two-step method using biotinylated GlcNAc—bovineserum albumin (BSA) and streptavidin—peroxidase conjugate.Three parasite proteins were specifically revealed and designatedas Pf 120, Pf 83 and Pf 45 GlcNAc-binding proteins. These proteinsbind to a gel substituted with GlcNAc and are specifically elutedwith 300 mM GlcNAc. Using a rabbit antiserum raised againstPf 83, the Pf 120 GlcNAc-binding protein, in addition to Pf83, was labelled by Western blotting. Comparative analyses withan antibody against the Pf 83 MSP derived from the P.falciparummerozoite surface protein (Pf MSP) indicated that the Pf 83GlcNAc-binding protein is not related to the fragment of thePf MSP antigen. Similarly, the Pf 83 GlcNAc-binding proteinis not related to the apical membrane antigen 1 (AMA 1) whichalso has the same molecular mass. Therefore the Pf 120, Pf 83and Pf 45 GlcNAc-binding proteins which are located on the merozoitesurface and recognize GlcNAc residues could be involved in thebinding of merozoites to the glycoconjugates of the surfaceof the red blood cells. GlcNAc lectin neoglycoprotein Plasmodium falciparum red blood cell     

Serine protease activity in developmental stages of Eimeria tenella

A number of complex processes are involved in Eimeria spp. survival, including control of sporulation, intracellular invasion, evasion of host immune responses, successful reproduction, and nutrition. Proteases have been implicated in many of these processes, but the occurrence and functions of serine proteases have not been characterized. Bioinformatic analysis suggests that the Eimeria tenella genome contains several serine proteases that lack homology to trypsin. Using RT-PCR, a gene encoding a subtilisin-like and a rhomboid protease-like serine protease was shown to be developmentally regulated, both being poorly expressed in sporozoites (SZ) and merozoites (MZ). Casein substrate gel electrophoresis of oocyst extracts during sporulation demonstrated bands of proteolytic activity with relative molecular weights (Mr) of 18, 25, and 45 kDa that were eliminated by coincubation with serine protease inhibitors. A protease with Mr of 25 kDa was purified from extracts of unsporulated oocysts by a combination of affinity and anion exchange chromatography. Extracts of SZ contained only a single band of inhibitor-sensitive proteolytic activity at 25 kDa, while the pattern of proteases from extracts of MZ was similar to that of oocysts except for the occurrence of a 90 kDa protease, resistant to protease inhibitors. Excretory-secretory products (ESP) from MZ contained AEBSF (4-[2-Aminoethyl] benzenesulphonyl fluoride)-sensitive protease activity with a specific activity about 10 times greater than that observed in MZ extracts. No protease activity was observed in the ESP from SZ. Pretreatment of SZ with AEBSF significantly reduced SZ invasion and the release of the microneme protein, MIC2. The current results suggest that serine proteases are present in all the developmental stages examined.     

Structure and development of the surface coat of erythrocytic merozoites of Plasmodium knowlesi

Summary The surface of extracellular merozoites of P. knowlesi is covered with a coat 15–20 nm thick, made up of clusters of filaments standing erect on the plasma membrane. Filaments have stems 2 nm thick, the peripheral ends of which are complex, branching or ending in long trailing threads. Coat filaments occur on the surface of the parasite in regular rows at an early schizont stage, and persist until well after merozoite release. They are sensitive to trypsin and papain, and bind ethanolic phosphotungstate, indicating a proteinaceous nature. They are also removed by exposure to phosphate-buffered saline. Filaments bear negative charges, binding cationised ferritin throughout the depth of the coat and staining with ruthenium red. They cover the whole merozoite surface and mediate intercellular adhesion at distances of 15–150 nm, membrane to membrane. It is suggested that these filaments correspond to a major merozoite surface protein, and are important in the initial capture of red cells.     

Inhibitory effects of erythrocyte membrane proteins on the in vitro invasion of the human malarial parasite (Plasmodium falciparum) into its host cell

The intracellular development of the erythrocytic stage of the malarial parasite (merozoite) is initiated by the attachment of the parasite to the erythrocyte surface. This paper describes an assay system to investigate Plasmodium falciparum merozoite entry into the host cell and reports on three observations regarding this interaction. (a) Merozoites do not invade human erythrocytes treated with either trypsin or neuraminidase, and both enzymes partially cleave glycophorin A, the major erythrocyte surface sialoglycoprotein. (b) A membrane protein fraction containing glycophorin A will, at low concentrations, inhibit the invasion of isolated merozoites into erythrocytes; no other fractions of membrane proteins have appreciable effects on the reinvasion. (c) Merozoites do not reinvade erythrocytes preincubated with F ab' fragments of antibody prepared against glycophorin A. Together, these three observations imply a role for glycophorin A in the attachment of the malarial parasite to the erythrocyte surface.     

High Yield Purification of Plasmodium falciparum Merozoites For Use in Opsonizing Antibody Assays

Plasmodium falciparum merozoite antigens are under development as potential malaria vaccines. One aspect of immunity against malaria is the removal of free merozoites from the blood by phagocytic cells. However assessing the functional efficacy of merozoite specific opsonizing antibodies is challenging due to the short half-life of merozoites and the variability of primary phagocytic cells. Described in detail herein is a method for generating viable merozoites using the E64 protease inhibitor, and an assay of merozoite opsonin-dependent phagocytosis using the pro-monocytic cell line THP-1. E64 prevents schizont rupture while allowing the development of merozoites which are released by filtration of treated schizonts.  Ethidium bromide labelled merozoites are opsonized with human plasma samples and added to THP-1 cells. Phagocytosis is assessed by a standardized high throughput protocol. Viable merozoites are a valuable resource for assessing numerous aspects of P. falciparum biology, including assessment of immune function. Antibody levels measured by this assay are associated with clinical immunity to malaria in naturally exposed individuals. The assay may also be of use for assessing vaccine induced antibodies.       

Proteases in malaria-infected red blood cells

The discrimination between erythrocyte and Plasmodium proteases is now made easier by using synthetic fluorogenic substrates, high-pressure liquid chromatography, reliable methods of cell preparation, as well as radiolabeled extracts from in vitro cultures of P. falciparum. The reinvasion process of an erythrocyte by a merozoite involves specific proteinases, which were recently identified using fluorogenic peptidyl-AEC substrates and by analysis of schizont and merozoite extracts with the gelatin-SDS-PAGE method. The biological targets of both host and parasite proteinases are not yet well characterized because Plasmodium-infected red blood cells contain at least four compartments with different pH values, which could modulate the proteinase activities according to their pH range activity. The processing of the precursor for the major merozoite surface antigens involves cleavage of very specific peptidic bonds by, so far unknown, proteinases. The depletion of the erythrocyte cytoskeleton could depend on a 37 kD proteinase, which cleaves spectrin and the 4.1 component, as shown in P. berghei and P. falciparum species. In contrast to leupeptin, which inhibits the merozoite release from schizont-infected erythrocytes, the structural inhibitor analogous to the Val-Leu-Gly-Lys (or Arg) P. falciparum neutral proteinase substrates appears to block the invasion step of erythrocytes by merozoites and may open new trends in chemotherapeutical strategies.     

Receptors for the Malarial Parasite

Abstract

During the erythrocytic cycle of Plasmodium, the parasite develops within an enclosed space, the parasitophorous vacuole, formed by endocytosis of an invasive stage, the merozoite. Among the erythrocyte membrane proteins possibly acting as a receptor for the attachment of P. falciparum merozoites to human erythrocytes is glycophorin A Isolated glycophorin inhibits merozoite entry in a competitive manner, perhaps via association with a 155 kDa surface protein. Another protein that competitively inhibits merozoite invasion, is band 3, the erythrocyte anion transport protein. The protein bearing Duffy blood group antigens may act to modulate invasion, but does not behave as a receptor.     

Antibodies and Plasmodium falciparum merozoites

There is considerable interest in using merozoite proteins in a vaccine against falciparum malaria. Observations that antibodies to merozoite surface proteins block invasion are a basis for optimism. This article draws attention to important and varied aspects of how antibodies to Plasmodium falciparum merozoites affect red blood cell invasion.     

Identification of surface and internal antigens from spontaneously released Plasmodium falciparum merozoites by radio-iodination and metabolic labelling

Spontaneously released merozoites from synchronous Plasmodium falciparum cultures were isolated in the presence of protease blocker. 1-5 X 10(10) merozoites were obtained in each experiment. The isolated merozoites possessed a thick surface coat and about 80% were invasive to human erythrocytes although they did not subsequently develop into ring stages. Tests using several analytical methods showed the merozoite preparations to be free of any erythrocyte contamination. Six labelled proteins were identified after surface radio-iodination, the largest with a molecular weight of 82 000. All six proteins were precipitated with various immune sera. Four other proteins with molecular weights of 200 000 and 160 000-145 000 (a triplet) were identified by precipitation with the same immune sera after metabolically labelling the merozoites. The six surface proteins were not prominent in the metabolically labelled preparations. Using these methods it is possible to identify and differentiate between surface and internal merozoite antigens.     

Structure and invasive behaviour of Plasmodium knowlesi merozoites in vitro.

The structure and invasive behaviour of extracellular erythrocytic merozoites prepared by a cell sieving method have been studied with the electron microscope. Free merozoites contain organelles similar to those described in late schizonts of Plasmodium knowlesi. Their surface is lined by a coat of short filaments. On mixing with fresh red cells, merozoites at first adhere, then cause the red cell surface to invaginate rapidly, often with the formation of narrow membranous channels in the red cell interior. As the merozoite enters the invagination it forms an attachment by its cell coat to the rim of the pit, and finally leaves this coat behind as it is enclosed in a red cell vacuole. Dense, rounded intracellular bodies then move to the merozoite periphery, and apparently rupture to cause further localized invagination of the red cell vacuole. The merozoite finally loses its rhoptries, the pellicle is reduced to a single membrane and the parasite becomes a trophozoite. Invasion is complete by 1 min after adhesion, and the trophozoite is formed by 10 min.     

Neutral proteases involved in the reinvasion of erythrocytes by Plasmodium merozoites

Neutral proteases of Plasmodium sp erythrocytic stages were studied by means of a sensitive fluorogenic method and gelatin-SDS-PAGE. The substrates gluconoyl-Val-Leu-Gly-Lys(or Arg)-3-amido-9-ethylcarbazole were selectively hydrolyzed by an endopeptidase from rodent Plasmodium berghei (Pb) and Plasmodium chabaudi (Pc) and from human Plasmodium falciparum (Pf) parasites. These endopeptidases were purified from 100,000-g soluble schizont extract by high pressure liquid chromatography; they have a similar Mr of 68,000 in SDS-PAGE, and an optimal activity at pH 7.4. The Pb 68 and Pf 68 endopeptidases were localized in schizonts and also in merozoites as shown by indirect immunofluorescence on Pb merozoites and by the identification of the Pf 68 endopeptidase activity in free viable merozoites. The Pb 68 and Pf 68 endopeptidases belong to the class of cysteine proteases. Analysis by gelatin-SDS-PAGE of a Pb 68 endopeptidase-enriched fraction showed a reproducible 95,000 proteolytic band. The initial extracts showed a similar 95,000 proteolytic band, and also 2 other 90,000 and 85,000 major bands. During reinvasion experiments, it was possible to recover a 95,000 and a 40,000 protease band from supernates of cultures grown in a semidefined medium without serum. Hydrophilic peptide derivatives related to the substrate of Pf 68 endopeptidase are shown to be potential inhibitors of the Pf reinvasion process in vitro.