Formation of the food vacuole in Plasmodium falciparum: a potential role for the 19 kDa fragment of merozoite surface protein 1 (MSP1(19)).

Plasmodium falciparum Merozoite Surface Protein 1 (MSP1) is synthesized during schizogony as a 195-kDa precursor that is processed into four fragments on the parasite surface. Following a second proteolytic cleavage during merozoite invasion of the red blood cell, most of the protein is shed from the surface except for the C-terminal 19-kDa fragment (MSP1(19)), which is still attached to the merozoite via its GPI-anchor. We have examined the fate of MSP1(19) during the parasite's subsequent intracellular development using immunochemical analysis of metabolically labeled MSP1(19), fluorescence imaging, and immuno-electronmicroscopy. Our data show that MSP1(19) remains intact and persists to the end of the intracellular cycle. This protein is the first marker for the biogenesis of the food vacuole; it is rapidly endocytosed into small vacuoles in the ring stage, which coalesce to form the single food vacuole containing hemozoin, and persists into the discarded residual body. The food vacuole is marked by the presence of both MSP1(19) and the chloroquine resistance transporter (CRT) as components of the vacuolar membrane. Newly synthesized MSP1 is excluded from the vacuole. This behavior indicates that MSP1(19) does not simply follow a classical lysosome-like clearance pathway, instead, it may play a significant role in the biogenesis and function of the food vacuole throughout the intra-erythrocytic phase.

Identification and characterization of the Plasmodium yoelii PyP140/RON4 protein, an orthologue of Toxoplasma gondii RON4, whose cysteine-rich domain does not protect against lethal parasite challenge infection.

Previously, we identified a Plasmodium yoelii YM 140-kDa merozoite protein, designated PyP140, which formed a complex with apical membrane antigen 1 (AMA1). Furthermore, we produced a nonprotective monoclonal antibody (MAb), 48F8, that immunoprecipitated metabolically labeled PyP140 and localized the protein to the merozoite's apical end and, less frequently, to the merozoite surface, as observed by immunofluorescence assay (IFA). Here, using MAb 48F8, we have identified the pyp140 gene by screening a P. yoelii lambda-Zap cDNA expression library. The pyp140 cDNA covers approximately 90% of the putative open reading frame (ORF) of PY02159 from the P. yoelii NL genome sequencing project. Analysis of the complete gene identified the presence of two introns. The ORF encodes a 102,407-Da protein with an amino-terminal signal sequence, a series of three unique types of repeats, and a cysteine-rich region. The binding site of MAb 48F8 was also identified. A BLAST search with the deduced amino acid sequence shows significant similarity with the Toxoplasma gondii RON4 protein and the Plasmodium falciparum RON4 protein, and the sequence is highly conserved in other Plasmodium species. We produced the cysteine-rich domain of PyP140/RON4 by using the Pichia pastoris expression system and characterized the recombinant protein biochemically and biophysically. BALB/c mice immunized with the protein formulated in oil-in-water adjuvants produced antibodies that recognize parasitized erythrocytes by IFA and native PyP140/RON4 by immunoblotting but failed to protect against a lethal P. yoelii YM infection. Our results show that PyP140/RON4 is located within the rhoptries or micronemes. It may associate in part with AMA1, but the conserved cysteine-rich domain does not appear to elicit inhibitory antibodies, a finding that is supported by the marked sequence conservation in this protein within Plasmodium spp., suggesting that it is not under immune pressure.

Extensive proteolytic processing of the malaria parasite merozoite surface protein 7 during biosynthesis and parasite release from erythrocytes.

In Plasmodium falciparum, merozoite surface protein 7 (MSP7) was originally identified as a 22kDa protein on the merozoite surface and associated with the MSP1 complex shed during erythrocyte invasion. MSP7 is synthesised in schizonts as a 351-amino acid precursor that undergoes proteolytic processing. During biosynthesis the MSP1 and MSP7 precursors form a complex that is targeted to the surface of developing merozoites. In the sequential proteolytic processing of MSP7, N- and C-terminal 20 and 33kDa products of primary processing, MSP7(20) and MSP7(33) are formed and MSP7(33) remains bound to full length MSP1. Later in the mature schizont, MSP7(20) disappears from the merozoite surface and on merozoite release MSP7(33) undergoes a secondary cleavage yielding the 22kDa MSP7(22) associated with MSP1. In free merozoites, both MSP7(22) and a further cleaved product, MSP7(19) present only in some parasite lines, were detected; these two derivatives are shed as part of the protein complex with MSP1 fragments during erythrocyte invasion. Primary processing of MSP7 is brefeldin A-sensitive while secondary processing is resistant to both calcium chelators and serine protease inhibitors. Primary processing of MSP7 occurs prior to that of MSP1 in a post-Golgi compartment, whereas the secondary cleavage occurs on the surface of the developing merozoite, possibly at the time of MSP1 primary processing and well before the secondary processing of MSP1.

Apical expression of three RhopH1/Clag proteins as components of the Plasmodium falciparum RhopH complex.

The Plasmodium falciparum high molecular mass rhoptry protein ('PfRhopH') complex is important for parasite growth and comprises three distinct gene products: RhopH1, RhopH2 and RhopH3. We have previously shown that P. falciparum RhopH1 is encoded by either PFC0110w (clag3.2) or PFC0120w (clag3.1), members of the previously-named clag (cytoadherence-linked asexual gene) multigene family. In this report, we have further characterized rhoph1/clag members in terms of gene structure, transcription and protein expression. The cDNA sequences for all five rhoph1/clag members were determined, confirming previous in silico predictions of intron-exon boundaries. All member genes were transcribed in HB3 and 3D7 parasite lines, but clag3.2 was not transcribed in Dd2 parasites. The peak abundance of transcripts for all genes was observed during the late schizont stage. Antisera specific to Clag2 and Clag3.1 localized these proteins to the apical end of merozoites in segmented schizonts, and both proteins are found to be components of the PfRhopH complex. PfRhopH complex that was immunoprecipitated with anti-Clag9 antibody contained neither Clag2 nor Clag3.1, thereby suggesting that PfRhopH complexes contain only individual rhoph1/clag gene products. Since the PfRhopH complex binds the erythrocyte surface, and RhopH2 and RhopH3 are encoded by single copy genes, the RhopH1/Clag proteins may serve to confer some degree of specificity to the roles of the individual complexes.

The Plasmodium falciparum clag9 gene encodes a rhoptry protein that is transferred to the host erythrocyte upon invasion.

The first gene characterizing the clag (cytoadherence linked asexual gene) family of Plasmodium falciparum was identified on chromosome 9. The protein product (Clag9) was implicated in cytoadhesion, the binding of infected erythrocytes to host endothelial cells, but little information on the biochemical characteristics of this protein is available. Other genes related to clag9 have been identified on different chromosomes. These genes encode similar amino acid sequences, but clag9 shows least conservation. Clag9 was detected in schizonts, merozoites and ring-stage parasites after protease digestion and peptide analysis by mass spectrometry. Using antisera raised against unique regions of Clag9 and against RhopH2, a component of the RhopH high-molecular-mass protein complex of merozoites, immunofluorescence co-localized the two proteins to the apical region of merozoites. Immunoelectron microscopy co-localized Clag9 and RhopH2 exclusively to the basal bulb region of rhoptries rather than to their apical ducts. The same Clag9-specific antibodies bound the RhopH complex, and the protein was detected in the complex purified by antibodies to RhopH2. Clag9 protein was also shown to be present in ring-stage parasites, carried through from the previous cycle with the RhopH complex, in a location identical to that of RhopH2. Transcription of the clag9 gene was shown to occur at the same time as the genes for other members of the RhopH complex, rhoph2 and 3. The results indicate that Clag9 is part of the RhopH complex and suggest that, within this complex, the protein previously designated RhopH1 is composed of more than one protein product of the clag gene family. The results cast doubt on a direct role for Clag9 in cytoadhesion; we suggest that the primary role of the RhopH complex is in remodelling the infected red blood cell after invasion by the merozoite. The complex may have multiple functions dependent on its exact composition, which may include, with respect to Clag9, a contribution to the mechanism of cytoadhesion.

Characterisation of the rhoph2 gene of Plasmodium falciparum and Plasmodium yoelii.

The high molecular mass protein complex (RhopH) in the rhoptries of the malaria parasite consists of three distinct polypeptides with estimated sizes in Plasmodium falciparum of 155kDa (PfRhopH1), 140kDa (PfRhopH2) and 110kDa (PfRhopH3). Using a number of reagents, including a new mAb 4E10 that is specific for the PfRhopH complex, it was shown that the RhopH complex is synthesised during schizogony and transferred intact to the ring stage in newly invaded erythrocytes. The genes encoding RhopH1 and RhopH3 have already been identified and characterised in both P. falciparum and Plasmodium yoelii. In this report, we describe the identification of the gene for RhopH2 in both these parasite species. Peptide sequences were obtained from purified RhopH2 proteins and used to generate oligonucleotide primers and search malaria sequence databases. In a parallel approach, mAb 4E10 was used to identify a clone coding for RhopH2 from a P. falciparum cDNA library. The sequences of both P. falciparum and P. yoelii genes for RhopH2 were completed and compared. They both contain nine introns and there is a high degree of similarity between the deduced amino acid sequences of the two proteins. The P. falciparum gene is a single copy gene located on chromosome 9, and is transcribed in schizonts.

Protective immune responses to the 42-kilodalton (kDa) region of Plasmodium yoelii merozoite surface protein 1 are induced by the C-terminal 19-kDa region but not by the adjacent 33-kDa region.

Vaccination of mice with the 42-kDa region of Plasmodium yoelii merozoite surface protein 1 (MSP1(42)) or its 19-kDa C-terminal processing product (MSP1(19)) can elicit protective antibody responses in mice. To investigate if the 33-kDa N-terminal fragment (MSP1(33)) of MSP1(42) also induces protection, the gene segment encoding MSP1(33) was expressed as a glutathione S-transferase (GST) fusion protein. C57BL/6 and BALB/c mice were immunized with GST-MSP1(33) and subsequently challenged with the lethal P. yoelii YM blood stage parasite. GST-MSP1(33) failed to induce protection, and all mice developed patent parasitemia at a level similar to that in naive or control (GST-immunized) mice; mice immunized with GST-MSP1(19) were protected, as has been shown previously. Specific prechallenge immunoglobulin G (IgG) antibody responses to MSP1 were analyzed by enzyme-linked immunosorbent assay and immunofluorescence. Despite being unprotected, several mice immunized with MSP1(33) had antibody titers (of all IgG subclasses) that were comparable to or higher than those in mice that were protected following immunization with MSP1(19). The finding that P. yoelii MSP1(33) elicits strong but nonprotective antibody responses may have implications for the design of vaccines for humans based on Plasmodium falciparum or Plasmodium vivax MSP1(42).

A malaria merozoite surface protein (MSP1)-structure, processing and function

Merozoite surface protein-1 (MSP-1, also referred to as P195, PMMSA or MSA 1) is one of the most studied of all malaria proteins. The proteins. The protein is found in all malaria species investigated and structural studies on the gene indicate that parts of the molecule are well-conserved. Studies on Plasmodium falciparum have shown that the protein is in a processed form on the merozoite surface, a result of proteolytic cleavage of the large percursor molecule. Recent studies have identified some of these cleavage sites. During invasion of the new red cell most of the MSP1 molecule is shed from the parasite surface except for a small C-terminal fragment which can be detected in ring stages. Analysis of the structure of this fragment suggests that it contains two growth factor-like domains that may have a functional role