Formation of mRNP granules in Toxoplasma gondii during the lytic cycle.

Two poly(A) binding proteins (PABPs) of Toxoplasma gondii, were identified and characterized. They were named TgPABPC and TgPABPN as they were found to localize in the cytoplasm and nucleus respectively. TgPABPC, which colocalizes with mRNA granules, is therefore used as a cellular marker of mRNP granules. We detected that the formation of mRNP granules was independent of polymerized microtubules, and that the granules were distributed stochastically within the cytosol. Formation of mRNP granules was found to occur prior to parasite egress when a Ca2+ ionophore is used to induce egress. It was also found that maturation of mRNP granules could be described as a two-phase process. First, prior to host cell lysis, mRNP granules were formed rapidly within the cytosol. Second, the mRNP granule load was reduced within 10 min post egress. To investigate the link between translational state and mRNP granule formation, treatments with salubrinal, nutrient deprivation, and pH stress were used. While salubrinal induced granule formation in tachyzoites, nutrient starvation and pH stress showed no induction effect on mRNP granule formation. Interestingly, salubrinal treatment in bradyzoites did not induce RNP granule formation, thus suggesting that mRNP granule formation is not a ubiquitous response or directly related to translational repression. Instead, mRNP granule formation is likely a response to the rapid increase in non-translating RNA brought on by sudden changes in translational state.

Toxoplasma gondii infection induces the formation of host's nuclear granules containing poly(A)-binding proteins.

To study the mechanism by which human host cells respond to an infection of Toxoplasma gondii, we monitored the level of poly(A)-binding protein (PABP), an indicator of translation. Here, we report an observation of the relocalization of PABPs in human host cells upon T. gondii infection. Notably, the aggregates of PABPs formed upon infection are mainly found in the nucleus, which is a different response from that found after exposure to heat shock. Pyrimethamine treatment of the infected monolayers inhibits the multiplicity of the parasite and reverses the relocalization of PABP aggregates. This active interaction between the infected mammalian host cells and T. gondii appears to be different from that caused by viral infection.

Antisense technologies in the studying of Toxoplasma gondii.

This review covers a brief history of antisense RNAs and its applications, and summarizes the current stage of antisense technologies used in Toxoplasma gondii, a fascinating model organism with a unique characteristic blend of genetic regulatory systems normally found in plants or animals. Based on the current knowledge of regulatory RNAs and non-coding RNA (ncRNA), the antisense technologies are reviewed according to the classification of ncRNAs, which are roughly categorized into small, ranging from ~20-200 nucleotides in length, and long >200 nucleotides. Techniques utilizing small regulatory RNAs such as siRNA, miRNA, antagomirs, ribozymes and morpholino oligomers are discussed along with long non-coding RNA (lncRNA) including antisense and double stranded. These antisense technologies can be used in forward and reverse genetics studies. The future of technologies is limitless, particularly by combining these technologies with conventional methods, and should allow for ever greater understanding of gene regulation of the organism and related pathogenic microorganisms.