Toxoplasma gondii pathogenesis includes the invasion of host cells by extracellular parasites, replication of intracellular tachyzoites, and differentiation to a latent bradyzoite stage. We present the analysis of seven novel T. gondii insertional mutants that do not undergo normal differentiation to bradyzoites. Microarray quantification of the variation in genome-wide RNA levels for each parasite line and times after induction allowed us to describe states in the normal differentiation process, to analyze mutant lines in the context of these states, and to identify genes that may have roles in initiating the transition from tachyzoite to bradyzoite. Gene expression patterns in wild-type parasites undergoing differentiation suggest a novel extracellular state within the tachyzoite stage. All mutant lines exhibit aberrant regulation of bradyzoite gene expression and notably some of the mutant lines appear to exhibit high proportions of the intracellular tachyzoite state regardless of whether they are intracellular or extracellular. In addition to the genes identified by the insertional mutagenesis screen, mixture model analysis allowed us to identify a small number of genes, in mutants, for which expression patterns could not be accounted for using the three parasite states – genes that may play a mechanistic role in switching from the tachyzoite to bradyzoite stage.
Summary
Two forms of the protozoan parasite Toxoplasma gondii are associated with
intermediate hosts such as humans: rapidly growing tachyzoites are responsible for
acute illness, whereas slowly dividing encysted bradyzoites can remain latent within
the tissues for the life of the host. In order to identify genetic factors associated
with parasite differentiation, we have used a strong bradyzoite‐specific promoter
(identified by promoter trapping) to drive the expression of T. gondii hypoxanthine–xanthine–guanine
phosphoribosyltransferase (HXGPRT) in stable transgenic parasites, providing a stage‐specific
positive/negative selectable marker. Insertional mutagenesis has been carried out
on this parental line, followed by bradyzoite induction in vitro and selection
in 6‐thioxanthine to identify misregulation mutants. Two different mutants fail to
induce the HXGPRT gene efficiently during bradyzoite differentiation. These mutants
are also defective in other aspects of differentiation: they replicate well under
bradyzoite growth conditions, lysing the host cell monolayer as effectively as tachyzoites.
Expression of the major bradyzoite antigen BAG1 is reduced, and staining with Dolichos
biflorus lectin shows reduced cyst wall formation. Microarray hybridizations show that these mutants behave more like tachyzoites at a global level, even under bradyzoite differentiation conditions.
Signaling via the NF-κB cascade is critical for innate recognition of microbial products and immunity to infection. As a consequence, this pathway represents a strong selective pressure on infectious agents and many parasitic, bacterial and viral pathogens have evolved ways to subvert NF-κB signaling to promote their survival. Although the mechanisms utilized by microorganisms to modulate NF-κB signaling are diverse, a common theme is targeting of the steps that lead to IκB degradation, a major regulatory checkpoint of this pathway. The data presented here demonstrate that infection of mammalian cells with Toxoplasma gondii results in the activation of IKK and degradation of IκB. However, despite initiation of these hallmarks of NF-κB signaling, neither nuclear accumulation of NF-κB nor NF-κB-driven gene expression is observed in infected cells. However, this defect was not due to a parasite-mediated block in nuclear import, as general nuclear import and constitutive nuclear-cytoplasmic shuttling of NF-κB remain intact in infected cells. Rather, in T. gondii-infected cells, the termination of NF-κB signaling is associated with reduced phosphorylation of p65/RelA, an event involved in the ability of NF-κB to translocate to the nucleus and bind DNA. Thus, these studies demonstrate for the first time that the phosphorylation of p65/RelA represents an event downstream of IκB degradation that may be targeted by pathogens to subvert NF-κB signaling.
Background information. Toxoplasma gondii is among the most successful parasites, with nearly half of the human population chronically infected. T. gondii has five sHsps [small Hsps (heat-shock proteins)] located in different subcellular compartments. Among them, Hsp20 showed to be localized at the periphery of the parasite body. sHsps are widespread, constituting the most poorly conserved family of molecular chaperones. The presence of sHsps in membrane structures is unusual.Results. The localization of Hsp20 was further analysed using high-resolution fluorescent light microscopy as well as electron microscopy, which revealed that Hsp20 is associated with the outer surface of the IMC (inner membrane complex), in a set of discontinuous stripes following the same spiralling trajectories as the subpellicular microtubules. The detergent extraction profile of Hsp20 was similar to that of GAP45 [45 kDa GAP (gliding-associated protein)], a glideosome protein associated with the IMC, but was different from that of IMC1 protein. Although we were unable to detect interacting protein partners of Hsp20 either in normal or stressed tachyzoites, an interaction of Hsp20 with phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-bisphosphate phospholipids could be observed.Conclusions. Hsp20 was shown to be associated with a specialized membranous structure of the parasite, the IMC. This discontinuous striped-arrangement is unique in T. gondii, indicating that the topology of the outer leaflet of the IMC is not homogeneous.1 To whom correspondence should be addressed (email sangel@intech.gov.ar).
Toxoplasma gondii is an obligate intracellular parasite. When searching for a new cell to invade, the parasites have to confront the stress of being exposed to the extracellular environment. The mechanisms by which T. gondii survives outside the host cells are poorly understood. In this work we show that extracellular parasites form mRNA aggregates with characteristics of stress granules. Intracellular tachyzoites or bradyzoites do not form mRNA granules. We tested different stimuli that trigger granule formation in vitro and discovered that a buffer that mimics the host cell cytosol ionic composition (high potassium) strongly induces granule formation, suggesting that the granules arise when the parasites come in contact with the host cell cytosol during egress. We examined the importance of granule formation for parasite viability and show that the parasite populations that are able to form granules have a growth advantage, increased invasion, and decreased apoptosis in the extracellular environment. Overall, granule formation improves the fitness of extracellular parasites and increases the efficiency of the lytic cycle.
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