Do Toxoplasma gondii apicoplast proteins have antigenic potential? An in silico study.

Toxoplasma gondii, one of the extensively studied Apicomplexan parasites, is prevalent worldwide in animals and humans. Apart from its nuclear genome, T. gondii contains an apicoplast genome in 35 kb length which is originated from a secondary endosymbiotic event. In this study, we aimed to investigate the antigenic potential of apicoplast genome encoded proteins (n:28) of T. gondii using in silico analysis. For this purpose, proteins were primarily predicted to reveal antigenic probability and then, several bioinformatics analyses were applied for all predicted antigenic apicoplast proteins to analyze physico-chemical parameters, subcellular localization and transmembrane domain. Also, further prediction analyses including structural, B cell and MHC-I/II epitope sites as well as post-translational modifications were performed for antigenic proteins that have a signal peptide or a high antigenicity value. Of the 28 apicoplast proteins, 19 were predicted as probable antigen. Among antigenic proteins, ribosomal protein S5, L11 and S2 were predicted to have signal peptide whereas ribosomal protein L36 and S17 were predicted to have a significantly high antigenicity value (P < 0.05). In addition, ribosomal protein S5, L11, S2, L36 and S17 were predicted to have a lot of epitopes which have low IC50 and percentile rank value indicating a strong binding among epitopes and MHC-I/II alleles, and post-translational modifications such as N-linked glycosylation, acetylation and phosphorylation. To the best of authors' knowledge this is the first study to show the antigenic potential and other properties of apicoplast-derived proteins of T. gondii.

Characterization of the ATG8-conjugation system in 2 Plasmodium species with special focus on the liver stage: possible linkage between the apicoplastic and autophagic systems?

Plasmodium parasites successfully colonize different habitats within mammals and mosquitoes, and adaptation to various environments is accompanied by changes in their organelle composition and size. Previously, we observed that during hepatocyte infection, Plasmodium discards organelles involved in invasion and expands those implicated in biosynthetic pathways. We hypothesized that this process is regulated by autophagy. Plasmodium spp. possess a rudimentary set of known autophagy-related proteins that includes the ortholog of yeast Atg8. In this study, we analyzed the activity of the ATG8-conjugation pathway over the course of the lifecycle of Plasmodium falciparum and during the liver stage of Plasmodium berghei. We engineered a transgenic P. falciparum strain expressing mCherry-PfATG8. These transgenic parasites expressed mCherry-PfATG8 in human hepatocytes and erythrocytes, and in the midgut and salivary glands of Anopheles mosquitoes. In all observed stages, mCherry-PfATG8 was localized to tubular structures. Our EM and colocalization studies done in P. berghei showed the association of PbATG8 on the limiting membranes of the endosymbiont-derived plastid-like organelle known as the apicoplast. Interestingly, during parasite replication in hepatocytes, the association of PbATG8 with the apicoplast increases as this organelle expands in size. PbATG3, PbATG7 and PbATG8 are cotranscribed in all parasitic stages. Molecular analysis of PbATG8 and PbATG3 revealed a novel mechanism of interaction compared with that observed for other orthologs. This is further supported by the inability of Plasmodium ATG8 to functionally complement atg8Δ yeast or localize to autophagosomes in starved mammalian cells. Altogether, these data suggests a unique role for the ATG8-conjugation system in Plasmodium parasites.