Toxoplasma gondii myosins B/C: one gene, two tails, two localizations, and a role in parasite division.

In apicomplexan parasites, actin-disrupting drugs and the inhibitor of myosin heavy chain ATPase, 2,3-butanedione monoxime, have been shown to interfere with host cell invasion by inhibiting parasite gliding motility. We report here that the actomyosin system of Toxoplasma gondii also contributes to the process of cell division by ensuring accurate budding of daughter cells. T. gondii myosins B and C are encoded by alternatively spliced mRNAs and differ only in their COOH-terminal tails. MyoB and MyoC showed distinct subcellular localizations and dissimilar solubilities, which were conferred by their tails. MyoC is the first marker selectively concentrated at the anterior and posterior polar rings of the inner membrane complex, structures that play a key role in cell shape integrity during daughter cell biogenesis. When transiently expressed, MyoB, MyoC, as well as the common motor domain lacking the tail did not distribute evenly between daughter cells, suggesting some impairment in proper segregation. Stable overexpression of MyoB caused a significant defect in parasite cell division, leading to the formation of extensive residual bodies, a substantial delay in replication, and loss of acute virulence in mice. Altogether, these observations suggest that MyoB/C products play a role in proper daughter cell budding and separation.

Peptides that mimic Candida albicans-derived beta-1,2-linked mannosides.

Beta-1,2-linked mannosides from Candida albicans phosphopeptidomannan (PPM) bind to macrophages through a receptor independent from the macrophage alpha-linked mannose receptor and stimulate these cells to secrete immune mediators. Anti-beta-1,2-linked mannoside but not anti-alpha-linked mannoside antibodies produced after immunization with neoglycoproteins protect animals from disseminated candidiasis. In this study, peptides that mimic beta-1,2-linked mannosides were isolated using phage display methodology. A phage library expressing random peptides was panned with an anti-beta-1,2-linked mannoside monoclonal antibody (mAb). After three rounds of biopanning, the isolated phages were able to inhibit recognition of C. albicans by the mAb. Sixty percent of the phages had an identical DNA insert corresponding to the peptide sequence FHENWPS that was recognized specifically by the mAb. Injection of KLH-coupled peptide into mice generated high titers of polyclonal antibodies against C. albicans yeast cell walls. The anti-FHENWPS antibodies bound to C. albicans PPM and were inhibited by soluble beta-1,2-mannotetraose. Together, these data provide evidence for mimotopic activity of the peptide selected by biopanning with the anti-beta-1,2-oligomannoside mAb.

The differential expression of multiple isoenzyme forms during stage conversion of Toxoplasma gondii: an adaptive developmental strategy.

The apicomplexan parasite Toxoplasma gondii has the ability to switch between a rapidly replicating tachyzoite and a slowly dividing encysted bradyzoite within its intermediate hosts such as humans or other warm-blooded vertebrates. It is likely that in vivo, the tachyzoites differentiate into encysted bradyzoites in response to the immune system attack during disease progression. As part of a developmental strategy and, in order to survive within infected hosts, T. gondii tachyzoites undergo profound metabolic and morphological changes by differentiating into encysted bradyzoites. Bradyzoites are characterised by their resistance to both the immune system and chemotherapy. The stimulus that triggers Toxoplasma encystation and the molecular mechanisms triggering the switch from tachyzoite to bradyzoite remain unknown. It is very important to elucidate these mechanisms since bradyzoites within tissue cysts are not only the source of infection transmitted from domestic animals to humans, but can also be converted into tachyzoites that are the cause of fatal toxoplasmic encephalitis in acquired immunodeficiency syndrome patients. In this review, I focus on recent efforts towards the characterisation of genes that encode several stage-specific isoenzymes. The picture emerging from these studies is that stage-specific expression of isoenyzmes having different biochemical properties accompanies the interconversion of tachyzoite into bradyzoite, and vice versa. It can be hypothesised that the difference found between these enzymatic activities may be instrumental in maintaining some major parasitic metabolisms such as glycolysis in pace with the stage-specific requirements of carbohydrate or polysaccharide biosynthesis.

Differential expression of two plant-like enolases with distinct enzymatic and antigenic properties during stage conversion of the protozoan parasite Toxoplasma gondii.

The precise molecular mechanisms underlying the switch between the two developmental stages of Toxoplasma gondii, and the metabolic adaptations occurring during this stage conversion are poorly understood. Because inhibitors of mitochondrial respiration are known to trigger differentiation from tachyzoite into bradyzoite stages, we believe that some of the switch components may be sought in the regulation of central carbohydrate metabolism. We have previously described a cDNA encoding a bradyzoite-specific enolase, ENO1. We now report the isolation and characterization of another enolase-encoding cDNA (ENO2) that is expressed preferentially in the tachyzoite stage. The deduced amino acid sequences of ENO1 and ENO2 share 73.65 % identity. They both display significant homologies to plant enolases with the presence of two plant-like peptide insertions, a pentapeptide EWGW(Y)C(S) and a dipeptide EK (or DK). We demonstrate that deletions of the ENO1 pentapeptide motif on its own or together with the dipeptide reduce drastically the affinity for the 2PGA substrate, suggesting that the evolutionary acquisition of these peptides in enolases of land plants and apicomplexan parasites contribute a specific function to their enzymatic activities. T. gondii ENO1 and ENO2 were also expressed as active recombinant enzymes in Escherichia coli. While ENO1 and ENO2 display similar K(m) values, the pure tachyzoite-specific enzyme (ENO2) has a threefold specific activity at V(max) compared with that of the bradyzoite-specific enolase (ENO1). Moreover, immunoblot analyses performed using polyclonal antibodies raised against the recombinant enzymes revealed that the native enolase in tachyzoite and bradyzoite are also antigenically distinct. Taken together, our results indicate that the differences witnessed between the two activities may be instrumental in maintaining glycolysis in pace with the distinct stage-specific requirements of carbohydrate metabolism.

Molecular cloning, functional complementation in Saccharomyces cerevisiae and enzymatic properties of phosphatidylinositol synthase from the protozoan parasite Toxoplasma gondii.

The obligate intracellular parasite Toxoplasma gondii, the causative agent of toxoplasmosis, switches between the rapidly dividing tachyzoite and the slowly replicating bradyzoite in intermediate hosts such as humans and domestic animals. We have recently identified a bradyzoite cDNA encoding a putative phosphatidylinositol (PtdIns) synthase using a subtractive library [Yahiaoui, B., Dzierszinski, F., Bernigaud, A., Slomianny, C., Camus, D., and Tomavo, S. (1999) Mol. Biochem. Parasitol. 99, 223-235]. Here, we report the cloning of another cDNA encoding PtdIns synthase that is exclusively expressed in the tachyzoite stage. The two transcripts are encoded by two different genes, which are stage-specifically regulated. The deduced amino-acid sequence (258 amino acids with a calculated total molecular mass of 27.8 kDa) of the tachyzoite-specific cDNA shares a significant degree of identity (between 26.5 and 30.1%) to the PtdIns synthases from human, rat, Arabidopsis thaliana and yeast. Interestingly, the putative protein encompasses an N-terminal extension that is approximately 40 amino-acids longer than that of PtdIns synthases from other organisms. Functional complementation realized by tetrad analysis of segregants of a Saccharomyces cerevisiae PtdIns synthase-deficient mutant (PIS1/pis1:kanMX4) showed that only the T. gondii putative PtdIns synthase truncated at its N-terminal extension is able to restore the viability of the cells. We demonstrate that this protein expressed in yeast transformants is functionally active in the membrane preparation and requires manganese and magnesium ions for activity. To our knowledge, this is the first report on the molecular cloning and functional analysis of a gene encoding a PtdIns synthase in protozoan parasites.

Targeted disruption of the glycosylphosphatidylinositol-anchored surface antigen SAG3 gene in Toxoplasma gondii decreases host cell adhesion and drastically reduces virulence in mice.

The protozoan parasite Toxoplasma gondii is able to invade a broad range of cells within its mammalian hosts through mechanisms that are not yet fully understood. Several glycosylphosphatidylinositol-anchored antigens found in the parasite membrane are considered as major determinants in the critical interactions with the host cell. We have discovered that two of these surface antigens, SAG1 and SAG3, share significant identity, with considerable similarities in structure, suggesting an overall conserved topology. To investigate their physiological roles further, we have generated T. gondii mutants deficient in SAG3 through gene disruption. The disrupted strains display at least a twofold reduction in host cell invasion when compared with wild-type parasites. This correlated with a similar decrease in host cell adhesion in the SAG3 null mutants. Importantly, the null SAG3 mutants show attenuated infectivity, with a markedly reduced capacity to cause mortality in mice, whereas both wild-type and complemented mutants that re-expressed SAG3 were lethal at the same doses. Taken together, our results indicate that SAG3 is one member of the redundant system of T. gondii receptors that act as ligands mediating host cell recognition and attachment.

Characterization of cytochrome b from Toxoplasma gondii and Q(o) domain mutations as a mechanism of atovaquone-resistance.

Atovaquone is active in vitro against the tachyzoites of Toxoplasma gondii at nanomolar concentrations and is used clinically to treat acute cases of human toxoplasmosis. In pursuit of the mechanism of action of atovaquone against T. gondii and to understand how resistance might arise, drug-resistant mutants were generated and examined. The previously uncloned cytochrome b gene of T. gondii was cloned and sequenced from wild type and resistant strains as this was a likely candidate for the target of the drug and thus a source of resistance. Mutations are present within the cytochrome b gene of atovaquone-resistant parasites (M129L and I254L) and represent alterations in two different regions of the ubiquinol-binding pocket (Q(o) domain) of cytochrome b, suggesting that atovaquone interferes with electron transport at the cytochrome bc(1) complex in T. gondii. A structural model for how this hydroxynaphthoquinone is binding within the Q(o) domain is presented. Further analysis of the cytochrome b gene suggested that the protein may differ from other homologues by terminating within the mitochondrial membrane. Cytochrome b becomes the first complete mitochondrial gene and cognate protein to be described for T. gondii.

Molecular cloning, expression analysis and iron metal cofactor characterisation of a superoxide dismutase from Toxoplasma gondii.

A genomic region of 12 kb encompassing the gene encoding the superoxide dismutase (SOD) of Toxoplasma gondii has been cloned. The gene contains four exons of 121, 42, 381 and 59 bp which are separated by three introns of 321, 202, and 577 bp, respectively. The open reading frame can be translated into a protein of 201 amino acids with a molecular mass of 22.6 kDa. Alignment indicated that it is a FeSOD, a type only found in bacteria, protozoa and chloroplast of higher plants. Recombinant SOD was expressed in a Escherichia coli double mutant lacking both MnFeSOD and FeSODs. The presence of iron as metal cofactor was confirmed by measurements of iron by absorption mass spectrometry and electron paramagnetic resonance studies. Semi-quantitative reverse transcribed polymerase chain reaction experiments showed a similar amount of SOD transcripts in two developmental stages of T. gondii. Antibodies raised against the purified recombinant protein detected SOD protein in both bradyzoite and tachyzoite forms suggesting this SOD might be essential for the intracellular growth of both developmental stages. Southern blot analysis indicated that SOD occured as a single copy gene in T. gondii genome.

Molecular cloning, organellar targeting and developmental expression of mitochondrial chaperone HSP60 in Toxoplasma gondii.

The obligate intracellular protozoan parasite Toxoplasma gondii has a single tubular mitochondrion. During infection, it recruits the host cell's mitochondria abutting to the intracellular vacuole, that contains the parasites. The respective contribution of host and parasitic mitochondria in the intracellular growth of T. gondii remains unknown. Heat shock protein, HSP60 has been reported in all eukaryotes examined, as an essential chaperone required for the folding and multimeric complex assembly of mitochondrial proteins. Here, we report the isolation and molecular characterization of two cDNAs corresponding to a single T. gondii gene coding for HSP60. Using a model fusion protein, preHSP60-chloramphenicol acetyl transferase (CAT), we demonstrate that the classical 22 amino acid mitochondrial presequence and the adjacent 32 amino acids of the mature protein are both required for the in vivo import into T. gondii mitochondria. The T. gondii HSP60 gene composed of five introns and six exons is transcribed into two related but differently spliced transcripts. Whereas the two transcripts can be detected in both developmental stages within the intermediate host, their levels are significantly increased in bradyzoites when compared to tachyzoites. By immunoblot analysis, the predicted 60-kDa protien corresponding to HSP60 was detected in both tachyzoite and bradyzoite forms. Using immunofluorescence assays. the polyclonal antibodies specific to T. gondii HSP60 recognized the mitochondrion in tachyzoites, as expected. In contrast, these antibodies reacted against two unknown vesicular bodies which are distinct from the classical mitochondrial pattern in bradyzoites. Taken together. these expression patterns of mitochondrial chaperone HSP60 suggests stage-specific induction of the respiratory pathway in the protozoan parasite T. gondii.

The protozoan parasite Toxoplasma gondii expresses two functional plant-like glycolytic enzymes. Implications for evolutionary origin of apicomplexans.

The recent discovery of a vestigial, nonphotosynthetic plastid ("apicoplast") in the Apicomplexa has considerably modified our perception of the evolutionary origin of these parasites. Phylogenetic analysis and the presence of four surrounding membranes of the apicoplast provide important support for the hypothesis that apicomplexans have acquired their apicoplast by secondary endosymbiosis, probably from a green alga. This suggests that genes encoding predicted homologs of proteins of green algae or related photosynthetic lineages could have entered the nucleus of apicomplexan parasites by transfer from the ancestor harboring the apicoplast. We describe here complementary DNAs encoding two Toxoplasma gondii glycolytic enzymes, glucose-6-phosphate isomerase (G6-PI) and enolase, which have considerable identities with land plant counterparts. Both cDNAs of T. gondii complement Escherichia coli mutants lacking G6-PI and enolase genes and lead to the expression of active enzymes. In the drug untreatable encysted bradyzoites of T. gondii, G6-PI and enolase genes are overexpressed or exclusively expressed at both transcriptional and protein levels. Moreover, three-dimensional models and protein phylogeny confirmed that G6-PIs and enolases of T. gondii, Plasmodium falciparum, and land plants are closely related. Because these glycolytic enzymes are plant homologs, which differ from those of animals, they will be useful to trace the evolutionary origin of Apicomplexa and might offer novel chemotherapeutic targets in diseases caused by apicomplexan parasites.

Isolation and characterization of a subtractive library enriched for developmentally regulated transcripts expressed during encystation of Toxoplasma gondii.

To survive within infected hosts, Toxoplasma gondii undergoes profound metabolic and morphological changes by differentiating into a cyst characterized by its resistance to the immune system and chemotherapy. The stimulus that triggers Toxoplasma encystation and the molecular mechanisms regulating the bradyzoite phenotype are still unknown. Here, we developed a differentiation method in conjunction with a selective and subtracted cDNA strategy devised to identify developmentally regulated transcripts. We isolated and analyzed 65 cDNA clones. In addition to bradyzoite specific cDNAs previously reported, we demonstrate that twelve genes are exclusively or preferentially transcribed in the encysted bradyzoite forms of T. gondii using semi-quantitative RT-PCR. Among cDNAs identified, are those encoding predicted homologues of chaperones (mitochondrial heat shock protein 60, T-complex protein 1), DNA-damage repair protein, phosphatidylinositol synthase, glucose-6-phosphate isomerase and enolase. The identification of these genes opens the way for further study of molecular mechanisms controlling gene expression during T. gondii encystation.

Stimulation of human T lymphocytes obtained from Toxoplasma gondii-seronegative persons by proteins derived from T. gondii.

Toxoplasma gondii antigens are superantigens in mice. To investigate a superantigen effect in humans, lymphocytes from T. gondii-seronegative subjects were studied for proliferation to T. gondii antigens (TA). Marked cellular proliferation, predominantly of CD4+ lymphocytes, was apparent. TA elicited expansions of Vbeta-bearing lymphocytes in all subjects, but different Vbeta-bearing lymphocytes were expanded in different subjects in both CD4+ and CD8+ subpopulations. Cord blood cells also proliferated to TA. Previously fixed antigen-presenting cells were unable to present TA. Thus, T. gondii appears to produce a molecule(s) that induces polyclonal activation of human T cells and requires antigen processing to mediate this effect. That T. gondii does not appear to behave as a superantigen in humans is important in understanding the pathogenesis of T. gondii infection in immunocompromised hosts and in the design of anti-T. gondii vaccines.

Genetic and biochemical analysis of development in Toxoplasma gondii.

Toxoplasma gondii has recently come under intense study as a model for intracellular parasitism because it has a number of properties that facilitate experimental manipulation. Attention is now being turned towards understanding the developmental biology of this complex parasite. The differentiation between the two asexual stages, the rapidly growing tachyzoites and the more slowly dividing, encysted bradyzoites, is of particular interest. Progression from the former to the latter is influenced by the host's immune response. This paper describes current progress on a number of research fronts, all aimed at understanding the triggers that push the tachyzoite-bradyzoite equilibrium in one or other direction and the changes that occur in gene expression (and ultimately metabolism and function). Chief among the techniques used for these studies are genetics and molecular genetics. Recent progress in these areas is described.

Interconnection between organellar functions, development and drug resistance in the protozoan parasite, Toxoplasma gondii.

The protozoan parasite Toxoplasma gondii causes severe disease in animals and humans. In AIDS patients, for example, the encephalitis it produces is a major cause of death. Part of the very successful strategy adopted by the parasite centers on its ability to differentiate from the actively growing tachyzoite form to a chronic, almost latent state called the bradyzoite. The molecular signals and precise triggers involved in this differentiation process are not known. Drugs for treating toxoplasmosis are not capable of clearing the infection apparently because of their inability to eradicate the bradyzoites. Recently, as part of our efforts to understand the mode of action of a promising new drug, atovaquone, we have generated and analysed a mutant that is resistant to this drug. Surprisingly, we found that this mutant is predisposed to spontaneously differentiate from the tachyzoite to bradyzoite form in vitro (Tomavo & Boothroyd, submitted). Given that atovaquone is believed to act on the parasite mitochondria, we were interested to explore the relationship between mitochondrial function and differentiation. We find that atovaquone and a number of other drugs targeted to mitochondria will cause wild type parasites to differentiate from tachyzoites to bradyzoites suggesting some sort of adaptive response to a decrease in mitochondrial activities. The fact that atovaquone-resistant mutants are hypersensitive to clindamycin, a drug believed to work on the putative plastid of these parasites, suggests a model for how the mitochondrion and plastid interact and how they may be tied into the process and state of differentiation. This model is presented and discussed.

Similarities between the primary structures of two distinct major surface proteins of Toxoplasma gondii.

Toxoplasma gondii possesses a 43-kDa surface protein (SAG3) that is expressed by all invasive stages. We have cloned and sequenced cDNAs encoding SAG3, with the longest one encoding a primary product of 385 amino acid residues. The deduced amino acid sequence contains a putative NH2-terminal signal sequence, as well as a glycosylphosphatidylinositol anchor attachment site. It is characterized by 12 cysteine residues whose distribution suggests a tandem duplication of a single ancestral motif containing 6 cysteine residues. Although no DNA sequence analogies were found, comparative amino acid sequence analysis detected a resemblance to SAG1, which is the major surface antigen specifically expressed by the proliferative tachyzoite stage. Despite a low degree of identity between the two amino acid sequences (24%), the conservative distribution of the cysteine and tryptophan residues, as well as of repeated motifs, together with oligopeptide identities suggest similar folding and possibly similar function for both proteins.

Immunolocalization and characterization of the low molecular weight antigen (4-5 kDa) of Toxoplasma gondii that elicits an early IgM response upon primary infection.

A striking feature of toxoplasmic seroconversion is the prominent and early IgM response to a low molecular weight antigen of 4-5 kDa. Two different monoclonal antibodies directed against the 4-5 kDa antigen have been generated and used to characterize this molecule. Using these monoclonal antibodies, we could demonstrate the surface localization of the low M(r) antigen by immunofluorescence and immuno-electron microscopy assays. By immunoblotting, we observed that one of the monoclonal antibodies was unable to recognize the 4-5 kDa antigen in tachyzoites propagated in cell culture, indicating an epitope variability between Toxoplasma gondii tachyzoites grown in vivo and in vitro. We discuss the implications of this latter finding in the design of diagnostic reagents.

Evidence for N-linked glycosylation in Toxoplasma gondii.

In this paper we report experiments demonstrating the presence of N-linked oligosaccharide structures in Toxoplasma gondii tachyzoites, providing the first direct biochemical evidence that this sporozoan parasite is capable of synthesizing N-linked glycans. The tachyzoite surface glycoprotein gp23 was metabolically labelled with [3H]glucosamine and [3H]mannose. Gel-filtration chromatography on Bio-Gel P4 columns produced four radiolabelled N-linked glycopeptides which were sensitive to peptidase-N-glycanase F, but resistant to endoglycosidases H and F. Using chemical analysis and exoglycosidase digestions followed by Dionex-high-pH anion-exchange chromatography and size fractionation on Bio-Gel P4 we show that gp23 has N-linked glycans in the hybrid- or complex-type structure composed of N-acetylgalactosamine, N-acetylglucosamine and mannose and devoid of sialic acid and fucose residues. In addition, the sensitivity of glycopeptides from glycoprotein extracts to endoglycosidases H and F revealed the in vivo synthesis of oligomannose-type structures by T. gondii tachyzoites. We have extended these findings by demonstrating the ability of T. gondii microsomes to synthesize in vitro a glucosylated lipid-bound high-mannose structure (Glc3Man9GlcNAc2) that is assumed to be identical with the common precursor for N-glycosylation in eukaryotes.