A Babesia bovis merozoite protein with a domain architecture highly similar to the thrombospondin-related anonymous protein (TRAP) present in Plasmodium sporozoites

Recognition and invasion of host cells is a key step in the life-cycle of all apicomplexan parasites. The thrombospondin-related anonymous protein (TRAP) of Plasmodium sporozoites is directly involved in both processes and shares conserved adhesive domains with micronemal transmembrane proteins of other apicomplexans. Here, we report the cloning and characterization of a Babesia bovis TRAP homologue (BbTRAP). It was predicted to be a type 1 transmembrane protein containing a von Willebrand Factor A domain (vWFA), a thrombospondin type 1 domain (TSP1), a conserved transmembrane region and a conserved cytoplasmic C-terminus, thus resembling the domain arrangement of Plasmodium TRAP. In contrast to Plasmodium TRAP, BbTRAP was shown to be present during the asexual erythrocytic cycle, being located mainly at the apical side of merozoites. Polyclonal rabbit antisera directed against synthetic peptides derived from the TSP1 domain or the C-terminal end of the ectodomain were shown to inhibit erythrocyte invasion in vitro. Both antisera recognized a 75 kDa protein in merozoite extracts as well as in a protein fraction that was secreted into the extracellular milieu during in vitro invasion of erythrocytes.     

Characterization of the Babesia gibsoni P18 as a homologue of thrombospondin related adhesive protein

Thrombospondin related adhesive proteins (TRAPs) are well conserved among several apicomplexans. In this study, we reported the identification of the Babesia gibsoni P18, designated by our group previously, as a homologue of TRAP and renamed the P18 as the B. gibsoni TRAP (BgTRAP). The amino acid sequence of BgTRAP consists of several typical regions, including a signal peptide, a vonWillebrand factor A domain, a thrombospondin type 1 domain, a transmembrane region, and a cytoplasmic C-terminus. The B. gibsoni infected dog serum recognized recombinant BgTRAP expressed in E. coli by Western blotting. The antiserum against recombinant BgTRAP recognized an 80kDa protein in the lysate of infected erythrocytes (RBCs), which was detectable in the micronemal area of the parasites by confocal microscopic observation. The BgTRAP showed a bivalent cation-independent binding to canine RBC, and the specific antiserum was found to inhibit the growth of B. gibsoni in the infected severe combined immune deficiency mice given canine RBC. These results suggest that the BgTRAP is a new member of TRAP family identified from the merozoites of B. gibsoni and functionally important in merozoite invasion; this protein may be useful as a vaccine candidate against canine B. gibsoni infection.     

Antibodies to a conserved-motif peptide sequence of the Plasmodium falciparum thrombospondin-related anonymous protein and circumsporozoite protein recognize a 78-kilodalton protein in the asexual blood stages of the parasite and inhibit merozoite invasion in vitro.

Athrombospondin-related anonymous protein (TRAP) of the human malaria parasite Plasmodium falciparum shares highly conserved amino acid sequence motifs with the circumsporozoite protein of all plasmodia sequenced so far, as well as with unrelated proteins like thrombospondin and properdin. Although it was first described as an asexual blood stages protein, there has been some controversy about its expression in these stages. Pursuant to our interest in the conserved sequences within the malaria antigens, we synthesized an 18-residue peptide (18-mer) representing a conserved motif of TRAP and raised polyclonal antibodies against it. In an immunoblot assay in which we probed proteins from the asexual blood stages of the parasite, we found that this antibody recognized predominantly a 78-kDa protein in the whole parasite lysate. Furthermore, in another immunoblot, the recombinant TRAP constructs containing the conserved-motif sequence were distinctly recognized by the antipeptide antibodies, whereas a construct lacking the motif sequence was not, suggesting that the antibodies specifically cross-reacted with a protein which might be a TRAP-like protein present in the asexual blood stages of the parasite. Also, in an immunofluorescence assay, this antibody brightly stained the acetone-fixed trophozoites of the parasite. Most significantly, anti-18-mer immunoglobulin G, as well as antipeptide antibody against a smaller (nonamer) construct representing the most conserved motif within the 18-mer, inhibited the merozoite invasion of erythrocytes in a dose-dependent manner. These results provide evidence of the expression of TRAP or a TRAP-like protein in the asexual blood stages of the parasite and of a possible role of the conserved motifs in the parasite-host cell interaction during the process of invasion.     

Antibodies against thrombospondin-related anonymous protein do not inhibit Plasmodium sporozoite infectivity in vivo

Thrombospondin-related anonymous protein (TRAP), a candidate malaria vaccine antigen, is required for Plasmodium sporozoite gliding motility and cell invasion. For the first time, the ability of antibodies against TRAP to inhibit sporozoite infectivity in vivo is evaluated in detail. TRAP contains an A-domain, a well-characterized adhesive motif found in integrins. We modeled here a three-dimensional structure of the TRAP A-domain of Plasmodium yoelii and located regions surrounding the MIDAS (metal ion-dependent adhesion site), the presumed business end of the domain. Mice were immunized with constructs containing these A-domain regions but were not protected from sporozoite challenge. Furthermore, monoclonal and rabbit polyclonal antibodies against the A-domain, the conserved N terminus, and the repeat region of TRAP had no effect on the gliding motility or sporozoite infectivity to mice. TRAP is located in micronemes, secretory organelles of apicomplexan parasites. Accordingly, the antibodies tested here stained cytoplasmic TRAP brightly by immunofluorescence. However, very little TRAP could be detected on the surface of sporozoites. In contrast, a dramatic relocalization of TRAP onto the parasite surface occurred when sporozoites were treated with calcium ionophore. This likely mimics the release of TRAP from micronemes when a sporozoite contacts its target cell in vivo. Contact with hepatoma cells in culture also appeared to induce the release of TRAP onto the surface of sporozoites. If large amounts of TRAP are released in close proximity to its cellular receptor(s), effective competitive inhibition by antibodies may be difficult to achieve.     

Multimerization of the Toxoplasma gondii MIC2 integrin-like A-domain is required for binding to heparin and human cells

Toxoplasma gondii is an obligate intracellular parasite that causes toxoplasmosis in humans and animals. To invade host cells, T. gondii deploys the contents of its apically oriented secretory organelles that include the micronemes. Contained within the micronemes are proteins that possess adhesive motifs resembling those found in mammalian proteins. The micronemal protein MIC2 is a member of the thrombospondin-related anonymous protein (TRAP) family of adhesive proteins, which characteristically feature at least one integrin-like A-domain. Because of its strict conservation within the family, we sought to define the role of this domain by testing the adhesive properties of recombinant MIC2 A-domain fusion proteins. Since MIC2 is found as a multimeric species in parasite lysate, we also wanted to test whether recombinant MIC2 A-domain bound to its substrate in a multimeric state. In vitro assays of binding to several different potential receptors revealed that the MIC2 A-domain binds specifically to heparin, a ubiquitous sulfated proteoglycan found in the extracellular matrix (ECM). Additional studies demonstrated that this binding is not dependent on the MIDAS site, a well-conserved divalent cation-binding motif that the MIC2 A-domain shares with its mammalian counterparts. The recombinant MIC2 A-domain bound to heparin as a high molecular weight species, as did MIC2 from parasite lysate, indicating that the recombinant A-domain mimics the binding of native MIC2. Multimerization of MIC2 may increase the number of interactions with host cell receptors, thereby forming a multivalent adhesive junction during parasite entry.     

von Willebrand Factor A domain-related protein, a novel microneme protein of the malaria ookinete highly conserved throughout Plasmodium parasites.

The mosquito-invasive form of the malarial parasite, the ookinete, develops numerous secretory organelles, called micronemes, in the apical cytoplasm. Micronemal proteins are thought to be secreted during midgut invasion and to play a crucial role in attachment and motility of the ookinete. We found a novel ookinete micronemal protein of rodent malarial parasite Plasmodium berghei, named P. berghei von Willebrand factor A domain-related protein (PbWARP), and report it here as a putative soluble adhesive protein of the ookinete. The PbWARP gene contained a single open reading frame encoding a putative secretory protein of 303 amino acids, with a von Willebrand factor type A module-like domain as a main component. Western blot analysis demonstrated that PbWARP was firstly produced 12 h after fertilization by maturing ookinetes as SDS-resistant complexes. Recombinant PbWARP produced with a baculovirus system also formed SDS-resistant high-order oligomers. Immuno-electron microscopic studies showed that PbWARP was randomly distributed in the micronemes. PbWARP homologues also exist in human malarial parasites, Plasmodium falciparum and Plasmodium vivax. Highly conserved primary structures of PbWARP homologues among these phylogenetically distant Plasmodium species suggest their functional significance and the presence of a common invasion mechanism widely utilized throughout Plasmodium parasites.     

Human papillomavirus type 16 E6 proteins with glycine substitution for cysteine in the metal-binding motif.

The human papillomavirus type 16 (HPV 16) E6 is a 151 amino acid protein containing four metal-binding motifs, Cys-X-X-Cys. We constructed and characterized three mutants with Gly substitutions for Cys within the motif; for Cys-66, for Cys-136, and for both, respectively. Zinc binding to bacterially expressed E6 was markedly reduced by the substitution for Cys-66, but DNA binding was unaffected by any of these mutations. Immunofluorescence staining showed that, whereas the E6 expressed in monkey COS-1 cells appeared mostly nuclear, the Cys-66 mutant appeared cytoplasmic. Subcellular fractionation followed by immunoprecipitation showed that the E6 in COS-1 cells was located in the membrane, nuclear, and nuclear-wash fractions, but not in the soluble cytoplasmic fraction, and that the nuclear Cys-66 protein was markedly reduced. The mutant proteins in COS-1 cells appeared to be less stable than the wild type, because the immunofluorescent cells were fewer and because the E6 bands in autoradiograms were less dense. The substitution mutants lost their capacity to enhance HPV 16 E7 transformation of rat 3Y1 cells. The data indicate that Cys-66 plays a crucial role for zinc binding and nuclear localization of E6 and that both Cys-66 and Cys-136 are required for a stable or functional structure of E6.     

Cloning,sequencing and recombinant expression of the open reading frame encoding a novel member of the <Emphasis Type="Italic">Sarcocystis muris</Emphasis> (Apicomplexa) microneme lectin family

Micronemes are characteristic secretory organelles located within the apical cell region of apicomplexan parasites. The protein contents are exocytosed during an early phase of host cell invasion and contribute to parasite motility and the invasion of target cells. We report here on the cloning and heterologous expression of a novel member of the Sarcocystis muris microneme lectin family. The deduced amino acid sequence is in total agreement with that obtained after sequencing the native protein and is characterized by two copies of the apple domain motif. The recombinant polypeptide is expressed in a biologically active conformation as demonstrated by its galactose binding properties.     

Characterization of the gene encoding sporozoite surface protein 2, a protective Plasmodium yoelii sporozoite antigen.

Sporozoite surface protein 2 (SSP2) is a 140-kDa, protective sporozoite surface protein from Plasmodium yoelii distinct from the circumsporozoite protein (CSP). A genomic clone containing the SSP2 gene was isolated and sequenced to determine its size, structural organization and deduced primary amino acid sequence. The coding sequence consists of a single, long open reading frame encoding 826 amino acids. The overall structure of SSP2 is similar to that of the CSP, consisting of a central region of immunogenic amino acid repeats flanked by non-repetitive sequence. SSP2 has one copy of a thrombospondin repeat motif in common with several cell adhesion molecules as well as with the CSP and the thrombospondin related anonymous protein (TRAP) of P. falciparum. Additionally, SSP2 shares substantial sequence similarity to TRAP, suggesting that TRAP is the analogue of SSP2 in P. falciparum.     

A microneme protein from Eimeria tenella with homology to the Apple domains of coagulation factor XI and plasma pre-kallikrein

Microneme organelles are present in all apicomplexan protozoa and contain proteins that are critical for parasite motility and host cell invasion. One apicomplexan-wide family of microneme proteins has been identified with members that are characterised by the possession of thrombospondin type I repeats, conserved adhesive motifs which are implicated in binding to glycosaminoglycan chains. In this paper we describe a micronemal glycoprotein, EtMIC 5, from Eimeria tenella which contains eleven cysteine-rich motifs that have striking similarity to the adhesive Apple (A-) domains of blood coagulation factor XI and plasma pre-kallikrein. EtMIC 5 is confined to an intracellular location in resting sporozoites but is translocated to the parasite surface and secreted into the culture supernatant during parasite infection of MDBK cells. During intracellular replication, the protein is switched off in early schizogony and is then re-expressed within the apical tips of newly formed merozoites. A-domain sequences were also found in microneme proteins from Sarcocystis muris and Toxoplasma gondii and in a protein of unknown localisation from Eimeria acervulina. These studies suggest that A-domain containing proteins may comprise a novel apicomplexan-wide family of microneme adhesins.     

N-terminal processing of proteins exported by malaria parasites

Malaria parasites utilize a short N-terminal amino acid motif termed the Plasmodium export element (PEXEL) to export an array of proteins to the host erythrocyte during blood stage infection. Using immunoaffinity chromatography and mass spectrometry, insight into this signal-mediated trafficking mechanism was gained by discovering that the PEXEL motif is cleaved and N-acetylated. PfHRPII and PfEMP2 are two soluble proteins exported by Plasmodium falciparum that were demonstrated to undergo PEXEL cleavage and N-acetylation, thus indicating that this N-terminal processing may be general to many exported soluble proteins. It was established that PEXEL processing occurs upstream of the brefeldin A-sensitive trafficking step in the P. falciparum secretory pathway, therefore cleavage and N-acetylation of the PEXEL motif occurs in the endoplasmic reticulum (ER) of the parasite. Furthermore, it was shown that the recognition of the processed N-terminus of exported proteins within the parasitophorous vacuole may be crucial for protein transport to the host erythrocyte. It appears that the PEXEL may be defined as a novel ER peptidase cleavage site and a classical N-acetyltransferase substrate sequence.     

The Aalpha6 locus: its relation to mating-type regulation of sexual development in Schizophyllum commune

We have isolated and examined the Aalpha6 mating-type locus of Schizophyllum commune as a first step toward resolving a functional difference between this locus and the Aalpha loci previously studied. Our analyses show Aalpha6 to be remarkably similar to the Aalpha loci of known structure. The locus is composed of two, divergently transcribed genes similar in size to known Z and Y genes of the Aalpha loci. We have termed the two genes, Z6 and Y6, on the basis of their demonstrated mating activities and encoded protein motifs. The Z6 gene encodes a homeodomain-related sequence, two acidic regions and a predicted coiled-coil motif. The Y6 gene encodes a homeodomain, predicted coiled-coil motif, two regions with homology to the Abeta locus gene V6, a basic region encoding a putative nuclear localization sequence and a serine-rich region. The Z6 and Y6 proteins share these features with the other known Z and Y proteins, respectively. One of the two amino acid sequences with homology to the AbetaV6 protein has not previously been reported.     

A Conserved Apicomplexan Microneme Protein Contributes to Toxoplasma gondii Invasion and Virulence

The obligate intracellular parasite Toxoplasma gondii critically relies on host cell invasion during infection. Proteins secreted from the apical micronemes are central components for host cell recognition, invasion, egress, and virulence. Although previous work established that the sporozoite protein with an altered thrombospondin repeat (SPATR) is a micronemal protein conserved in other apicomplexan parasites, including Plasmodium, Neospora, and Eimeria, no genetic evidence of its contribution to invasion has been reported. SPATR contains a predicted epidermal growth factor domain and two thrombospondin type 1 repeats, implying a role in host cell recognition. In this study, we assess the contribution of T. gondii SPATR (TgSPATR) to T. gondii invasion by genetically ablating it and restoring its expression by genetic complementation. Δspatr parasites were ∼50% reduced in invasion compared to parental strains, a defect that was reversed in the complemented strain. In mouse virulence assays, Δspatr parasites were significantly attenuated, with ∼20% of mice surviving infection. Given the conservation of this protein among the Apicomplexa, we assessed whether the Plasmodium falciparum SPATR ortholog (PfSPATR) could complement the absence of the TgSPATR. Although PfSPATR showed correct micronemal localization, it did not reverse the invasion deficiency of Δspatr parasites, because of an apparent failure in secretion. Overall, the results suggest that TgSPATR contributes to invasion and virulence, findings that have implications for the many genera and life stages of apicomplexans that express SPATR.     

A second merozoite surface protein (MSP-4) of Plasmodium falciparum that contains an epidermal growth factor-like domain.

Merozoite surface proteins of Plasmodium falciparum play a critical role in the invasion of human erythrocytes by the malaria parasite. Here we describe the identification of a novel protein with a molecular mass of 40 kDa that is found on the merozoite surface of P. falciparum. We call this protein merozoite surface protein 4 (MSP-4). Evidence for the surface location of MSP-4 includes (i) a staining pattern that is consistent with merozoite surface location in indirect immunofluorescent studies of cultured parasites, (ii) localization of MSP-4 in the detergent phase in Triton X-114 partitioning studies, and (iii) nucleotide sequencing studies which predict the presence of an N-terminal signal sequence and a hydrophobic C-terminal sequence in the protein. Immunoprecipitation studies of biosynthetically labelled parasites with [3H] myristic acid indicated that MSP-4 is anchored on the merozoite surface by a glycosylphosphatidylinositol moiety. Of considerable interest is the presence of a single epidermal growth factor-like domain at the C terminus of the MSP-4 protein, making it the second protein with such a structure to be found on the merozoite surface.     

A RGG motif protein is involved in Toxoplasma gondii stress-mediated response

The molecular mechanisms controlling gene expression are still poorly understood in apicomplexan parasites. Here, we report the characterization of a homolog of the single strand binding proteins (named TgSsossB) in Toxoplasma gondii. We previously showed that TgSsossB interacts with the TgAlba proteins that are involved in translation regulation. We examined the role of TgSsossB in stress-mediated response, and particularly the role of its arginine–glycine–glycine (RGG) repeats domain. TgSsossB recombinant protein is able to bind to single strand DNA and RNA in a sequence-independent manner, but not to double stranded DNA. We showed that the RGG motif is not involved in this ability to bind to nucleic acid. We produced a mutant tagged strain lacking the RGG motif of TgSsossB using the knock-in strategy. We observed that this strain exhibited a fitness defect compared with the parental parasites. Moreover, the mutant strain produced fewer plaques in stress conditions, a defect that is due to a slow growth phenotype when extracellular parasites are exposed to stress. At the molecular level, we showed that the TgSsossB protein lacking a RGG motif lost its ability to interact with TgAlba2 and an isoform of TgAlba1, indicating that the TgAlba complex is likely non-functional in those parasites. Thus, our findings define the RGG domain of TgSsossB as a protein–protein interaction platform and underline the role of the TgAlba–TgSsossB complex in stress-mediated response.