Immune pressure selects for Plasmodium falciparum parasites presenting distinct red blood cell surface antigens and inducing strain-specific protection in Saimiri sciureus monkeys.

The passive transfer of specific antibodies to a naive splenectomized Saimiri sciureus monkey infected with the Palo Alto FUP/SP strain of Plasmodium falciparum resulted in the emergence of parasites resistant to the transferred antibodies. Molecular typing indicated that the original and resistant parasites were isogenic. Saimiri monkeys primed with original parasites were fully susceptible to a challenge by the resistant ones, and vice versa. This absence of crossprotection indicates that strain-specific determinants would be the major targets of protective immunity developed in these monkeys. Phenotypic analysis showed that the surface of the infected red blood cells differed in both lines. Original parasites formed rosettes, autoagglutinated, presented characteristic knobs at the surface of the infected red blood cell, and did not agglutinate in the presence of a pool of human immune sera. In contrast, the resistant parasites did not form rosettes, did not spontaneously autoagglutinate, presented abnormal flattened knobs, and formed large aggregates in the presence of a pool of human immune sera. The presence of strain-specific determinants at the surface of the resistant parasites was confirmed by surface immunofluorescence and agglutination using homologous Saimiri serum. Neither the original nor the resistant parasites cytoadhered to an amelanotic melanoma cell line, suggesting that cytoadherence and agglutination can be dissociated. These results indicate that parasites that differ by the antigens exposed at the surface of the red blood cell induce strain-specific immunity. Furthermore they show that rosetting and nonrosetting parasites differ in their antigenic properties and do not crossprotect.

The Toxoplasma gondii rhoptry protein ROP 2 is inserted into the parasitophorous vacuole membrane, surrounding the intracellular parasite, and is exposed to the host cell cytoplasm.

The origin of the vacuole membrane surrounding the intracellular protozoan parasite Toxoplasma gondii is not known. Although unique secretory organelles, the rhoptries, discharge during invasion of the host cell and may contribute to the formation of this parasitophorous vacuole membrane (PVM), no direct evidence for this hypothesis exists. Using a novel approach we have determined that parasite-encoded proteins are present in the PVM, exposed to the host cell cytoplasm. In infected cells incubated with streptolysin-O or low concentrations of digitonin, the host cell plasma membrane was selectively permeabilized without significantly affecting the integrity of the PVM. Antisera prepared against whole parasites or a parasite fraction enriched in rhoptries and dense granules reacted with the PVM in these permeabilized cells, indicating that parasite-encoded antigens were exposed on the cytoplasmic side of the PVM. Parasite antigens responsible for this staining of the PVM were identified by fractionating total parasite proteins by SDS-PAGE and velocity sedimentation, and then affinity purifying "fraction-specific" antibodies from the crude antisera. Proteins responsible for the PVM-staining, identified with fraction-specific antibodies, cofractionated with known rhoptry proteins. The gene encoding one of the rhoptry proteins, ROP 2, was cloned and sequenced, predicting and integral membrane protein. Antibodies specific for ROP 2 reacted with the intact PVM. These results provide the first direct evidence that rhoptry contents participate in the formation of the PVM of T. gondii and suggest a possible role of ROP 2 in parasite-host cell interactions.

Rosetting in Plasmodium falciparum: a cytoadherence phenotype with multiple actors.

The capacity of Plasmodium falciparum-infected red blood cells to bind uninfected red blood cells ("rosetting") has been associated with high parasite density in numerous geographic areas and with severe malaria in African children. We summarize here the associations that have emerged from field studies and describe the various experimental models of rosetting that have been developed. A variety of erythrocyte receptors, several serum factors and a number of rosette-mediating PfEMP1 adhesins have been identified. Several var genes code for rosette-forming PfEMP1 adhesins in each P. falciparum genome, so that each clonal line has the capacity to generate distinct types of rosettes. To clarify their respective role in malaria pathogenesis, each of the multiple ligand/receptor interactions should be further studied for fine specificity, binding affinity and the impact of the large population polymorphism of the parasite variant repertoires should be assessed. Interestingly, some major human erythrocyte surface polymorphisms have been identified as affecting rosette formation, consistent with a role for rosetting in life-threatening falciparum malaria.

Characterization of a conserved extrachromosomal element isolated from the avian malarial parasite Plasmodium gallinaceum.

We have identified a conserved, repeated, and highly transcribed DNA element from the avian malarial parasite Plasmodium gallinaceum. The element produced multiple transcripts in both zygotes and asexual blood stages of this parasite. It was found to be highly conserved in all of five malarial species tested and hybridized at reduced stringency to other members of the phylum Apicomplexa, including the genera Babesia, Eimeria, Toxoplasma, and Theileria. The copy number of the element was about 15, and it had a circularly permuted restriction map with a repeat unit length of about 6.2 kilobases. It could be separated from the main genomic DNA by using sucrose gradients and agarose gels, and it migrated separately from the recognized Plasmodium chromosomes on pulse-field gels. In the accompanying paper (S. M. Aldritt, J. T. Joseph, and D. F. Wirth, Mol. Cell. Biol. 9:3614-3620, 1989), evidence is presented that element contains the mitochondrial genes for the protein cytochrome b and a fragment of the large rRNA. We postulate that this element is an episome in the mitochondria of the obligate parasites belonging to the phylum Apicomplexa.

Synthesis of a chicken ovalbumin-like protein in the yeast Saccharomyces cerevisiae.

A cDNA sequence coding for chicken ovalbumin was fused to the beginning of the Escherichia coli lactose operon and recombined in vitro with a composite vector plasmid which can be propagated in both E. coli and Saccharomyces cerevisiae. Such plasmids direct the synthesis of an ovalbumin-like protein (OLP) in both microorganisms, probably because the E. coli lac regulatory region has some promoter activity in yeast. The yeast strains produce about 1 000 to 5 000 molecules of ovalbumin-like protein per cell.

Secretion into the bacterial periplasmic space of chicken ovalbumin synthesized in Escherichia coli.

Ovalbumin is secreted by the tubular gland cells without cleavage of a signal sequence at the N-terminus. In Escherichia coli strains which produce a chicken ovalbumin-like protein (OLP) from a plasmid-cloned gene, the OLP is synthesized on membrane-bound polysomes and secreted without cleavage into the periplasmic space. In contrast, a deleted protein, which lacks 126 amino acids in the N-terminal half, is not secreted and is synthesized from free polysomes. Our results are compatible with the presence, in the N-terminal half of the molecule, of a signal sequence necessary for the transport across the membrane.

Plasmodium falciparumin the squirrel monkey (Saimiri sciureus): infection of non-splenectomised animals as a model for exploring clinical manifestations of malaria.

Plasmodium falciparum infection in humans leads to a variety of symptoms ranging from an influenza-like syndrome to life-threatening complications. Animal models are useful tools for the detailed analysis of the interaction between both parasite and host factors leading to these various clinical manifestations. In this review, examining the different clinical, parasitological and haematological parameters associated with P. falciparum infection in spleen-intact monkeys, we propose this model as a good alternative for exploring some aspects of the host-parasite relationship in malaria.

Plaque antibody selection: rapid immunological analysis of a large number of recombinant phage clones positive to sera raised against Plasmodium falciparum antigens.

A library of Plasmodium falciparum genomic DNA on the lambda gt11 phage vector was screened for clones positive to a rabbit serum raised against a purified fraction of P. falciparum proteins and a pool of sera from malaria patients. The positive clones were characterized with antibodies purified by the plaque antibody selection technique. This technique consist of purifying specific antibodies on a nitrocellulose filter blotted directly on a lawn of plaques of an antigen-producing phage clone. The purified antibodies are then used as a probe in a Western blot of parasite protein extract, for preliminary characterization of the clones. Using this method, two different clones coding for P. falciparum antigens were identified with the rabbit serum and about 20 with the human sera. This method can be of general use, i.e. it is not limited to parasite systems, and facilitates the immunological analysis and identification of a large number of clones.

In vitro phagocytosis inhibition assay for the screening of potential candidate antigens for sub-unit vaccines against the asexual blood stage of Plasmodium falciparum.

We have previously established a direct correlation between immune protection against the asexual blood stage Plasmodium falciparum infection and the presence of opsonizing antibodies promoting phagocytosis of parasitized red blood cells. In the present communication we describe an in vitro assay for measuring phagocytosis inhibition (PIA) specific for P. falciparum-infected erythrocytes. The phagocytosis inhibition assay is a simple procedure for screening potential candidates for sub-unit vaccines against P. falciparum based on the correlation between opsonizing antibodies and immunoprotection. The assay was used to analyse 18 recombinant molecules, corresponding to 11 distinct antigens of P. falciparum. Pre-incubation and selective antibody depletion experiments demonstrate the antigen-antibody specificity of the PIA. The presence of epitopes participating as targets of opsonic antibodies were demonstrated in six distinct polypeptide antigens.

In vivo and in vitro derived Palo Alto lines of Plasmodium falciparum are genetically unrelated.

The Uganda Palo Alto strain of Plasmodium falciparum (FUP) is routinely used as a reference isolate in a number of laboratories. It is one of the few P. falciparum strains that can both be propagated in vivo in monkeys and maintained in culture. The Palo Alto parasites have been characterized for several biochemical and molecular markers, but many of the data reported so far are contradictory. We have analyzed and compared by Southern blotting, PCR and DNA sequencing, several DNA preparations obtained from different FUP lines and from the FCR3 strain. We show here that FUP lines propagated in Saimiri monkeys (FUP/S) and those maintained in culture (FUP/C) for many years in our laboratory differ in the various genetic markers investigated (P190, MSA2, S-Ag, KAHRP, 96 tR, pPFPA rep 20 and pPF 11.1). Therefore, at the present, two genetically unrelated strains of P. falciparum widely distributed over numerous laboratories are designated FUP/Palo Alto. When the Saimiri-propagated FUP/S line was used to initiate an in vitro culture in human red blood cells, no evidence of instability or genetic drift was obtained. The growth rate and genomic characteristics remained constant for several months. Likewise, the FUP/C line was found unchanged after three transfers in Saimiri monkeys. FUP/CP parasites were shown to be genetically closely related to FCR3. In addition, a subline of FUP/C strain selected by repeated flotation on gelatin was found to differ in several characters such as KHARP, P190 and S-antigen genes, which are known to be located on different chromosomes.

Plasmodium chabaudi antigens synthesized in an mRNA-dependent cell-free translation system.

Intact RNAs were isolated from Plasmodium chabaudi growing synchronously in mice at different stages of the erythrocytic cycle. Translation of the mRNAs using rabbit reticulocyte lysate showed stage-specific patterns comparable to those observed in vivo. Many antigens of P. chabaudi are produced by translation in the rabbit reticulocyte lysate. Some other antigens are predominantly synthesized at a particular stage, indicating that the mRNA populations differ from one stage to another.

The virulent Saimiri-adapted Palo Alto strain of Plasmodium falciparum does not express the ring-infected erythrocyte surface antigen.

The Palo Alto strain of Plasmodium falciparum is highly virulent for the Saimiri sciureus monkey. We have observed that these parasites do not express the Ring-infected erythrocyte surface antigene (RESA) gene. Immunoblots indicated that the Pf155/RESA protein was absent. The RESA mRNA could not be detected. Polymerase chain reaction and Southern blot analysis demonstrated that this lack of expression is due to gene rearrangements. The majority of the Palo Alto parasites have a deletion of the entire RESA gene, whereas in a minor fraction the RESA sequences remain detectable, but the 5' miniexon 1 is inverted. These data show that the RESA protein is dispensable for in vivo parasite growth, at least in Saimiri monkeys.

Cloning of cDNAS that code for Plasmodium chabaudi antigens of the erythrocytic forms and cross-hybridize with P. falciparum.

Several Plasmodium chabaudi antigens are synthesized and the corresponding mRNAs are detected by cell-free translation only during specific stages of the erythrocytic cycle. Ring stage mRNA was used to construct a cDNA library in the plasmid vector pBR 322. The library was screened by differential hybridization with cDNA specific for ring stage parasites or schizonts. Two clones which showed some stage specificity and seven which did not were retained. Three clones were characterized by hybrid-selected translation. Clones 451, 148 and 443 contain sequences homologous to the messages for a 27 kDa stage-specific antigen, a 37 kDa early antigen and a 24 kDa antigen, respectively. The nine clones cross-hybridize to various degrees with cDNA from P. falciparum but cross hybridization intensities do not reflect the strength of immunological cross-reactivity.

Evidence for distinct prototype sequences within the Plasmodium falciparum Pf60 multigene family.

Using oligonucleotides derived from Pf60.1, a member of the Plasmodium falciparum Pf60 multigene family, numerous fragments were amplified from genomic and cDNA from the 3D7 P. falciparum clone. DNA sequencing showed that the various fragments presented considerable diversity, indicating that the 3D7 repertoire contains at least 20 distinct versions of the region analysed. The various sequences aligned with either of two prototype sequences. Characteristic of the A-type was the presence of a 21 bp motif, present in variable copy number, as well as a sequence homologous to the Babesia sp. RAP-1 consensus. The B prototype sequence did not present such features and substantially differed from the A-type, due to accumulation of point mutations and numerous triplet deletions. Consistent with the marked differences between both sub-families, individual members from each sub-family did not cross-hybridise, produced distinct multiple band patterns on Southern blots and distinct chromosome profiles. Numerous hybrid sequences were observed. Interestingly, most var genes and var-related unspliced cDNAs described so far are of A/B hybrid type. These data suggest that the family has evolved by successive amplifications from two ancestral copies, with accumulation of mutations, as well as recombination and/or gene conversion events.

Molecular characterization of the heat shock protein 90 gene of the human malaria parasite Plasmodium falciparum.

We report here the nucleotide sequence of hsp90 (heat shock protein 90) of Plasmodium falciparum. Computer analysis of the deduced protein sequence revealed an unusually large region of charged amino acids when compared to hsp90 from other species. This region shows striking homology to the calcium binding domain of calreticulin, the major calcium binding protein of endoplasmic reticulum. Phylogenetic tree analysis indicates that P. falciparum hsp90 is more closely related to hsp90 from plants than to hsp90 from vertebrates or other parasites. The malaria hsp90 is an ATP binding protein encoded by a single gene constitutively expressed in both asexual (trophozoite) and sexual (gametocyte) stage parasites. The hsp90 protein is homologous to a previously identified 90-kDa antigen strongly recognised by both sera from vaccinated monkeys and monoclonal antibody XIV/7.

Chromosome size variation in the malaria parasite of rodents, Plasmodium chabaudi.

Pulsed field gradient gel electrophoresis has been used to identify at least 10 large DNA fragments in the genome of the rodent malaria species Plasmodium chabaudi. The fragments range in size from approximately 650 to 5000 kb. All the fragments contain sequences homologous to a P. berghei telomere probe, suggesting that they represent intact chromosomes. Ribosomal RNA genes and P. chabaudi cDNA sequences have been mapped to specific fragments. The fragments vary in size in different cloned isolates of the parasite. In a cross between two cloned parasites differing in the sizes of chromosomes 4 and 5, independent segregation of each chromosome occurred during meiosis.

Characterization of microneme proteins of Toxoplasma gondii.

Three microneme proteins of Toxoplasma gondii have been characterized using 3 monoclonal antibodies and a recombinant protein specific antiserum. In all cases, apical labeling of tachyzoites and bradyzoites was observed by indirect immunofluorescence assay. Immunogold localization on ultrathin sections of bradyzoites or tachyzoites showed a specific labeling of micronemes. The following proteins were characterized using 2-dimensional gel electrophoresis and Western immunoblotting: Mic 1 (60 kDa, Pi 6.5), Mic 2 (120 kDa, Pi 5) and Mic 3 (90 kDa, Pi 6.75). The 90-kDa protein (Mic 3) is a heterodimer of two 38-kDa polypeptides (Pi 6.7 and 6.75 respectively) linked by disulfide bridges. Metabolic labeling and immunoprecipitation assays showed that at least one of the 38-kDa polypeptides was processed from a 40-kDa precursor. No processing was observed during the biosynthesis of the 120- and 60-kDa polypeptides.

Characterisation of the binding sites of monoclonal antibodies reacting with the Plasmodium falciparum rhoptry protein RhopH3.

Twenty one mouse monoclonal antibodies reacting or cross-reacting with the Plasmodium falciparum RhopH3 protein reacted with Ag44, a recombinant antigen expressing the 134 C-terminal RhopH3 residues. Using overlapping peptides scanning this region, two major binding sites were identified. The first one, recognised by eight anti-RhopH3 and seven cross-reacting mAbs, was mapped to the sequence Thr Asp Asn Thr Tyr or Thr Asp Asn Thr Tyr Lys (aa 823-828), depending on the support used for synthesis. Binding specificity and affinity were investigated for a subset of four mAbs reacting with this epitope, including one growth inhibitory mAb. Systematic replacements showed that the various mAbs had similar requirements. The inhibitory mAb presented a higher affinity for this sequence and bound to the adjacent sequence, Tyr Lys Glu Met Glu Leu (aa 827-832). A 2nd binding site, located around residue 850, was recognised by two anti-RhopH3 mAbs, which reacted exclusively with the 110 kDa RhopH3 polypeptide, unlike the other mAbs, which reacted with the 110 and 105 kDa RhopH3 antigens. This suggested that the 105 kDa RhopH3 polypeptide derives from the 110 kDa by C-terminal processing. Experimental evidence substantiating this conclusion was provided by the observation that antisera raised to peptides located upstream of the putative cleavage site reacted with both the 110 kDa and 105 kDa polypeptides, whereas antisera raised to the 45 C-terminal amino acids of RhopH3 reacted exclusively with the larger, 110 kDa product. The biological significance of this processing is discussed.

The S-antigen of Plasmodium falciparum Palo Alto represents a new S-antigen serotype.

The S-antigen from the Palo Alto isolate of Plasmodium falciparum has been characterized. The partial sequence for the gene coding for this antigen (clone 281) reveals the presence of tandem repeats of eight amino acids which defines a new S-antigen serotype. Antibodies raised against the 281 recombinant clone reacted with a 140 kDa antigen by immunoblotting with parasite extracts and culture supernatants. The 140 kDa peptide was also identified by immunoprecipitation of metabolic labelled parasites. The 281 mouse antiserum was used to localize the antigen on parasite smears by indirect immunofluorescence assay and more precisely by immunoelectron microscopy. The S-antigen is localized within the parasitophorous vacuole. Furthermore, different isolates were examined for the presence of the Palo Alto S-antigen specificity.

Molecular cloning of GRA4, a Toxoplasma gondii dense granule protein, recognized by mucosal IgA antibodies.

Clones which were selected from a Toxoplasma gondii expression library with the immune serum from a T. gondii-infected rabbit, were further screened using milk and intestinal secretions from mice which had been orally infected with T. gondii cysts. The gene products of several clones reacted strongly with milk IgA and weakly with intestinal IgA. Three of these clones (5.1, 36.1, 37.4) were shown to encode a dense granule protein of 40 kDa (GRA4). The GRA4 protein co-migrates with one of the T. gondii antigens recognized by mucosal IgA. The complete nucleotide sequence of GRA4 has been obtained by cloning genomic T. gondii BamHI fragments containing the 37.4 DNA insert. The coding sequence contains no intron. The deduced amino acid sequence indicates a proline rich (12%) product with an internal hydrophobic region of 19 amino acids and a potential site of N-glycosylation. The primary translation product with a theoretical size of 36,260 Da contains a putative N-terminal signal sequence of 20 amino acids but no apparent glycolipid anchor sequence. Quantitation of the GRA4 gene and Southern blot analysis suggested that the GRA4 gene is single copy. GRA4 gene is translated in tachyzoites to yield a single mRNA species of about 1900 bases.