Developmental differentiation between tachyzoites and bradyzoites of Toxoplasma gondii

An important event in the pathogenesis of toxoplasmosis is the interconversion between the bradyzoite and the tachyzoite stage of Toxoplasma gondii within the intermediate host. The factors that influence either cyst formation (bradyzoites) or reactivation (tachyzoites) are unknown. Uwe Gross, Wolfgang Bohne, Martine Soête and Jean Fran?ois Dubremetz here describe current knowledge about the mechanisms that might lead to the induction of stage differentiation of this protozoan parasite.     

Comparative ultrastructure of tachyzoites, bradyzoites, and tissue cysts of Neospora caninum and Toxoplasma gondii

The ultrastructure of tachyzoites, bradyzoites and tissue cysts of the NC-1, NC-5 and NC-Liverpool strains of Neospora caninum are reviewed and compared with those of the VEG and ME-49 strains of Toxoplasma gondii. While each stage of N. caninum and T. gondii shared many ultrastructural characteristics, each parasite stage also had certain features or organelles that could be used to distinguish the two parasites. Some of the most prominent ultrastructural differences occurred in the number, appearance and location of rhoptries, looped-back rhoptries, micronemes, dense granules, small dense granules and micropores. The tissue cysts of both parasites were also basically similar, being surrounded by a cyst wall and not compartmentalised by septa. The cyst wall of N. caninum was irregular and substantially thicker, 0.5-4 microm, than those of T. gondii which were smooth and 0.5 microm thick.     

The in vitro model of tissue cyst formation in Toxoplasma gondii

Fundamental advances in the development and design of drugs for toxoplasmosis will only follow a more-thorough understanding o f the basic biology of Toxoplasma gondii tissue cyst formation. Tim McHugh, Richard Holliman and Philip Butcher here describe the in vitro model of tissue cyst formation in T. gondii.     

Identification of circulating antigens, including an immunoglobulin binding protein, from Toxoplasma gondii tissue cyst and tachyzoites in murine toxoplasmosis

Here we describe the identification of Toxoplasma gondii circulating antigens in sera of BALB/c mice experimentally infected with either the virulent RH strain, or the cystogenic WTD1 strain or with an isolate from a human patient. The circulating antigens were identified by immunoblot in tachyzoite (RH strain) and in tissue cyst (ME-49 strain) crude antigens, using antibodies produced by immunisation of BALB/c mice with homologous sera from infected animals. The most relevant tachyzoite antigen identified are in the following four clusters of 109-94, 67-57, 35-31 and 28-21 kDa. Tissue cyst-specific circulating antigens, like the 18 kDa one, were detected in sera from mice infected with the cystogenic strains. These immune sera, after depletion of tachyzoite specific antibodies, recognised three tissue cysts antigens with Mr of 120, 79 and 48 kDa, and a cluster of antigens in the range of 68-53 kDa. We produced monoclonal antibodies by fusion of myeloma cells with lymphocytes from the mouse immunised with circulating antigens from the RH strain. One of the clones (3A11/H12) obtained, secretes IgG(1) and recognises a peptide epitope from a tachyzoite 67 kDa protein. This parasite protein also binds irrelevant mouse IgG(1) as well as immunoglobulins from other species. The reactivity with non-specific antibodies was inhibited by preincubation with 2% normal mouse and goat serum, while the reaction with the monoclonal antibody 3A11/H12 was not. Furthermore, a biotinylated F(ab')(2) of an irrelevant mouse IgG(1) did not show any reactivity while the F(ab')(2) of the monoclonal antibody 3A11/H12 reacts specifically with the 67 kDa antigen suggesting that this circulating antigen is a putative Fc binding protein.     

Characterisation of hexokinase in Toxoplasma gondii tachyzoites

We have cloned the hexokinase [E.C. 2.7.1.1] gene of Toxoplasma gondii tachyzoite and obtained an active recombinant enzyme with a calculated molecular mass of 51,465Da and an isoelectric point of 5.82. Southern blot analysis indicated that the hexokinase gene existed as a single copy in the tachyzoites of T. gondii. The sequence of T. gondii hexokinase exhibited the highest identity (44%) to that of Plasmodium falciparum hexokinase and lower identity of less than 35% to those of hexokinases from other organisms. The specific activity of the homogeneously purified recombinant enzyme was 4.04 micromol/mg protein/min at 37 degrees C under optimal conditions. The enzyme could use glucose, fructose, and mannose as substrates, though it preferred glucose. Adenosine triphosphate was exclusively the most effective phosphorus donor, and pyrophosphate did not serve as a substrate. K(m) values for glucose and adenosine triphosphate were 8.0+/-0.8 microM and 1.05+/-0.25mM, respectively. No allosteric effect of substrates was observed, and the products, glucose 6-phosphate and adenosine diphosphate, had no inhibitory effect on T. gondii hexokinase activity. Other phosphorylated hexoses, fructose 6-phosphate, trehalose 6-phosphate which is an inhibitor of yeast hexokinase, and pyrophosphate, also did not affect T. gondii hexokinase activity. Native hexokinase activity was recovered in both the cytosol and membrane fractions of the whole lysate of T. gondii tachyzoites. This result suggests that T. gondii hexokinase weakly associates with the membrane or particulate fraction of the tachyzoite cell.     

Ultrastructure of tachyzoites, bradyzoites and tissue cysts of Neospora caninum

Dividing tachyzoites of Neospora caninum were 4 x 3 microns and had ultrastructural characteristics typical for the cyst-forming coccidia. Unusual ultrastructural characteristics of fully-formed tachyzoites included no micropores, 8-12 anterior and 4-6 posterior rhoptries, and a few posterior micronemes. Most tachyzoites were located free in the host cell cytoplasm; only a few occurred within a parasitophorous vacuole. Parasite multiplication appeared to be rapid because most organisms were in various stages of endodyogeny. Neural tissue cysts of N. caninum were 24.3 x 19.2 microns and contained 50-200 bradyzoites (7.3 x 1.5 microns), which lacked micropores. The cyst wall was 0.74-1.12 microns thick and consisted of the primary cyst wall (the parasitophorous vacuole membrane) and a thick granular layer with electron-dense vesicles.     

Experimental tissue cyst induced Toxoplasma gondii infections in dogs

Tissue cyst induced Toxoplasma gondii infections were examined in 2 beagle dogs orally inoculated with tissue cysts. Neither dog developed clinical signs of toxoplasmosis. Both dogs developed low antibody titers to T. gondii. The MAT and IFAT were superior to the LAT and IHT tests for detecting antibodies to T. gondii.     

Toxoplasma gondii RH Ankara: production of evolving tachyzoites using a novel cell culture method

Nitric oxide (NO) and NO-derived reactive nitrogen species (RNS) are present in the food vacuole (FV) of Plasmodium falciparum trophozoites. The product of PFL1555w, a putative cytochrome b₅, localizes in the FV membrane, similar to what was previously observed for the product of PF13_0353, a putative cytochrome b₅ reductase. These two gene products may contribute to NO generation by denitrification chemistry from nitrate and/or nitrite present in the erythrocyte cytosol. The possible coordination of NO to heme species present in the food vacuole was probed by resonance Raman spectroscopy. The spectroscopic data revealed that in situ generated NO interacts with heme inside the intact FVs to form ferrous heme nitrosyl complexes that influence intra-vacuolar heme solubility. The formation of heme nitrosyl complexes within the FV is a previously unrecognized factor that could affect the equilibrium between soluble and crystallized heme within the FV in vivo.     

Optimization of the cryopreservation of biological resources,Toxoplasma gondii tachyzoites,using flow cytometry

The conservation of Toxoplasma gondii strains isolated from humans and animals is essential for conducting studies on Toxoplasma. Conservation is the main function of the French Biological Toxoplasma Resource Centre (BRC Toxoplasma, France, http://www.toxocrb.com/). In this study, we have determined the suitability of a standard cryopreservation methodology for different Toxoplasma strains using the viability of tachyzoites assayed by flow cytometry with dual fluorescent labelling (calcein acetoxymethyl ester and propidium iodide) of tachyzoites. This method provides a comparative quantitative assessment of viability after thawing. The results helped to define and refine quality criteria before tachyzoite cryopreservation and optimization of the cryopreservation parameters. The optimized cryopreservation method uses a volume of 1.0 mL containing 8 × 10⁶ tachyzoites, in Iscove's Modified Dulbecco's Medium (IMDM) containing 10% foetal calf serum (FCS). The cryoprotectant additive is 10% v/v Me₂SO without incubation. A cooling rate of ∼1 °C/min to −80 °C followed, after 48 h, by storage in liquid nitrogen. Thawing was performed using a 37 °C water bath that produced a warming rate of ∼100 °C/min, and samples were then diluted 1:5 in IMDM with 5% FCS, and centrifuged and resuspended for viability assessment.     

Transcriptional modification of host cells harboring Toxoplasma gondii bradyzoites prevents IFN gamma-mediated cell death

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Developmentally regulated biosynthesis of carbohydrate and storage polysaccharide during differentiation and tissue cyst formation in Toxoplasma gondii

Toxoplasma gondii belongs to the Apicomplexa phylum, which comprises protozoan parasites of medical and veterinary significance, responsible for a wide variety of diseases in human and animals, including malaria, toxoplasmosis, coccidiosis and cryptosporidiosis. During infection in the intermediate host, T. gondii undergoes stage conversion between the rapidly replicating tachyzoite that is responsible for acute toxoplasmosis and the dormant or slowly dividing encysted bradyzoite. The tachyzoite-bradyzoite interconversion is central to the pathogenic process and is associated with the life-threatening recrudescence of infection observed in immunocompromised patients such as those suffering from AIDS. In chronic infections, the bradyzoites are located within tissue cysts found predominantly in brain and muscles. The tissue cyst is enclosed by a wall containing specific lectin binding sugars while the bradyzoites have accumulated large amounts of the storage polysaccharide of glucose, amylopectin. Our recent findings have identified several genes and proteins associated with amylopectin synthesis or degradation and glucose metabolism, including different isoforms of certain glycolytic enzymes, which are stage-specifically expressed during tachyzoite-bradyzoite interconversion. Here, we will discuss how the genes and enzymes involved in carbohydrate metabolisms are used as molecular and biochemical tools for the elucidation of molecular mechanisms controlling T. gondii stage interconversion and cyst formation.     

Development of an in vitro model of Toxoplasma gondii cyst formation

Abstract Toxoplasma gondii tissue cyst reactivation is a major pathogenic mechanism in ocular toxoplasmosis, disease associated with AIDS and organ transplantation. The mechanisms associated with cyst formation and reactivation have not been elucidated. The complexity of studying these issues in animal models has led to the development of in vitro tissue culture strategies for cyst formation. In the present study we have adopted the human embryonic lung fibroblast (HEL) as the host cell and have compared the cyst forming abilities of eight clinical isolates. We describe by transmission electron microscopy and quantitative light microscopy the development of cysts in vitro. The numbers of in vitro cysts increased with time for all isolates. Cyst cultures were stabilised by manipulation of the free parasite load, an observation not previously recorded. Thus, in this paper we describe a viable model for the analysis of the mechanisms of Toxoplasma cyst development.     

Toxoplasma gondii: redistribution of monoclonal antibodies on tachyzoites during host cell invasion

Immunodetection of protein P30, a major surface antigen of Toxoplasma gondii tachyzoites, by a specific monoclonal antibody has demonstrated a homogenous distribution of this antigen on the surface of intra- and extracellular tachyzoites at all stages of their endodyogenic development. On living zoites, no redistribution of anti-P30 was obtained, contrasting with the capping obtained with antiserum to T. gondii. Upon invasion of a host cell, however, most of the coat of anti-P30 was shed from preincubated zoites at the level of the moving junction governing the entry of the parasite into the host cell.     

Host cell egress and invasion induce marked relocations of glycolytic enzymes in Toxoplasma gondii tachyzoites

Apicomplexan parasites are dependent on an F-actin and myosin-based motility system for their invasion into and escape from animal host cells, as well as for their general motility. In Toxoplasma gondii and Plasmodium species, the actin filaments and myosin motor required for this process are located in a narrow space between the parasite plasma membrane and the underlying inner membrane complex, a set of flattened cisternae that covers most the cytoplasmic face of the plasma membrane. Here we show that the energy required for Toxoplasma motility is derived mostly, if not entirely, from glycolysis and lactic acid production. We also demonstrate that the glycolytic enzymes of Toxoplasma tachyzoites undergo a striking relocation from the parasites' cytoplasm to their pellicles upon Toxoplasma egress from host cells. Specifically, it appears that the glycolytic enzymes are translocated to the cytoplasmic face of the inner membrane complex as well as to the space between the plasma membrane and inner membrane complex. The glycolytic enzymes remain pellicle-associated during extended incubations of parasites in the extracellular milieu and do not revert to a cytoplasmic location until well after parasites have completed invasion of new host cells. Translocation of glycolytic enzymes to and from the Toxoplasma pellicle appears to occur in response to changes in extracellular [K(+)] experienced during egress and invasion, a signal that requires changes of [Ca(2+)](c) in the parasite during egress. Enzyme translocation is, however, not dependent on either F-actin or intact microtubules. Our observations indicate that Toxoplasma gondii is capable of relocating its main source of energy between its cytoplasm and pellicle in response to exit from or entry into host cells. We propose that this ability allows Toxoplasma to optimize ATP delivery to those cellular processes that are most critical for survival outside host cells and those required for growth and replication of intracellular parasites.     

Toxoplasma gondii maintenance in tissue culture: a new efficient method for culturing RH tachyzoites

We describe here a new tissue culture method for prolonged laboratory maintenance of tachyzoites of the highly virulent RH strain of Toxoplasma gondii. Using a rapidly proliferating murine tumor cell line (YAC-1), the method described is easy to perform and is as or more efficient (both in terms of yield and cost) than other traditional methods for maintenance of the parasite. Furthermore, upon prolonged maintenance (greater than 160 days) in YAC-1 tissue culture, the pathogenicity of the parasite, as well as its capacity to elicit an immune response, are comparable to that of organisms maintained in mice. We conclude therefore, that the method described herein is a suitable alternative to the traditional method of maintenance of virulent RH strain T. gondii tachyzoites.     

Development and ultrastructure of Besnoitia oryctofelisi tachyzoites,tissue cysts,bradyzoites, schizonts and merozoites

Development and structure of different life cycle stages of Besnoitia oryctofelisi which has a rabbit-cat life cycle was studied by light and transmission electron microscopy. For light microscopy, Besnoitia oryctofelisi-infected tissues were stained with haematoxylin-eosin, periodic acid Schiff (PAS) reagent, and immunohistochemically with rabbit anti-B. oryctofelisi polyclonal antibodies and anti-BAG-1 antibodies. In vitro and in vivo-derived tachyzoites were 5-6 microm long and they were found to divide by endodyogeny. In tachyzoites, the nucleus was often central, and micronemes were few and located anterior to the nucleus. Earliest tissue cysts were seen in gerbils starting 12 days p.i. Early tissue cysts had an outer PAS-positive cyst wall, a middle PAS-negative host cell layer, and an inner PAS-negative parasitophorous vacuolar membrane. Organisms in early tissue cysts were PAS-negative, did not stain with anti-BAG-1 antibodies, and amylopectin granules and enigmatic bodies were absent. Tissue cysts beginning 17 days p.i. contained organisms that became PAS-positive and reacted with anti-BAG-1 antibodies, indicating they were bradyzoites. Immunoreactivity with polyclonal anti-B. oryctofelisi antibodies suggested that Besnoitia species bradyzoites are encapsulated by the host cell. Bradyzoites (10 microm) were about twice the length of tachyzoites and contained enigmatic bodies characteristic of Besnoitia bradyzoites. Unlike tachyzoites and tissue cysts, schizonts were located intravascularly in the lamina propria of the small intestine of cats. Merozoites were 5-6 microm long, had few rhoptries and amylopectin granules, had numerous micronemes and had a terminal nucleus.