Apicoplast targeting of a Toxoplasma gondii transmembrane protein requires a cytosolic tyrosine-based motif.

Toxoplasma gondii, like most apicomplexan parasites, possesses an essential relict chloroplast, the apicoplast. Several apicoplast membrane proteins lack the bipartite targeting sequences of luminal proteins. Vesicles bearing these membrane proteins are detected during apicoplast enlargement, but the means of cargo selection remains obscure. We used a combination of deletion mutagenesis, point mutations and protein chimeras to identify a short motif prior to the first transmembrane domain of the T. gondii apicoplast phosphate transporter 1 (APT1) that is necessary for apicoplast trafficking. Tyrosine 16 was essential for proper localization; any substitution resulted in misdirection of APT1 to the Golgi body. Glycine 17 was also important, with significant Golgi body accumulation in the alanine mutant. Separation of at least eight amino acids from the transmembrane domain was required for full motif function. Similarly placed YG motifs are present in apicomplexan APT1 orthologs and the corresponding N-terminal domain from Plasmodium vivax was able to route T. gondii APT1 to the apicoplast. Differential permeabilization showed that both the N- and C-termini of APT1 are exposed to the cytosol. We propose that this YG motif facilitates APT1 trafficking via interactions that occur on the cytosolic face of nascent vesicles destined for the apicoplast.

3-Methyladenine blocks Toxoplasma gondii division prior to centrosome replication.

The apicomplexan Toxoplasma gondii replicates by endodyogeny, in which replicated organelles assemble into nascent daughter buds within the maternal parasite. The mechanisms governing this complex sequence are not understood. We now report that the kinase inhibitor 3-methlyadenine (3-MA) efficiently blocks T. gondii replication. The inhibition could not be attributed to the effects of 3-MA on mammalian phosphatidylinositol 3-kinase and host cell autophagy. Furthermore, we show that accumulation of host lysosomes around the parasitophorous vacuoles was unaffected. Most 3-MA-treated parasites failed to form daughter buds or replicate DNA, indicating arrest in G1 or early S-phase. Some 3-MA-treated parasites displayed abortive cell division, in which nuclear segregation to malformed daughter buds was incomplete or asymmetrical. Electron microscopy revealed the presence of residual body-like structures in many vacuoles, even in the absence of daughter buds. Most treated parasites had otherwise normal morphology and were able to resume replication upon drug removal. 3-MA-treated and control parasites were similar with respect to the extent of Golgi body division and apicoplast elongation; however, treated parasites rarely possessed replicated centrosomes or apicoplasts. These data are suggestive of a generalized blockade of T. gondii cell cycle progression at stages preceding centrosome replication, rather than arrest at a specific checkpoint. We hypothesize that 3-MA treatment triggers a cell cycle pause program that may serve to protect parasites during periods, such as subsequent to egress, when cell cycle progression might be deleterious. Elucidation of the mechanism of 3-MA inhibition may provide insight into the control of parasite growth.

Evolving insights into protein trafficking to the multiple compartments of the apicomplexan plastid.

The apicoplast is a relict plastid found in many medically important apicomplexan parasites, such as Plasmodium and Toxoplasma. Phylogenetic analysis and the presence of four bounding membranes indicate that the apicoplast arose from a secondary endosymbiosis. Here we review what has been discovered about the complex journey proteins take to reach compartments of the apicoplast. The targeting sequences for luminal proteins are well-defined, but those routing proteins to other compartments are only beginning to be studied. Recent work suggests that the trafficking mechanisms involve a variety of molecules of different phylogenetic origins. We highlight some remaining questions regarding protein trafficking to this divergent organelle.

Sequential processing of the Toxoplasma apicoplast membrane protein FtsH1 in topologically distinct domains during intracellular trafficking.

FtsH proteins are hexameric transmembrane proteases found in chloroplasts, mitochondria and bacteria. In the protozoan Toxoplasma gondii, FtsH1 is localized to membranes of the apicoplast, a relict chloroplast present in many apicomplexan parasites. We have shown that although T. gondii FtsH1 lacks the typical bipartite targeting presequence seen on apicoplast luminal proteins, it is targeted to the apicoplast via the endoplasmic reticulum. In this report, we show that FtsH1 undergoes processing events to remove both the N- and C-termini, which are topologically separated by the membrane in which FtsH1 is embedded. Pulse-chase analysis showed that N-terminal cleavage precedes C-terminal cleavage. Unlike the processing of the N-terminal transit peptide of luminal proteins, which occurs in the apicoplast, analysis of ER-retained mutants showed that N-terminal processing of FtsH1 occurs in the endoplasmic reticulum. Two of four FtsH1 mutants bearing internal epitope tags accumulated in structures peripheral to the apicoplast, implying that FtsH1 trafficking is highly sensitive to changes in protein structure. These mutant proteins did not undergo C-terminal processing, suggesting that this processing step occurs after localization to the plastid. Mutation of the peptidase active site demonstrated that neither processing event occurs in cis. These data support a model in which multiple proteases act at different points of the trafficking pathway to form mature FtsH1, making its processing more complex than other FtsHs and unique among apicoplast proteins described thus far.

A thioredoxin family protein of the apicoplast periphery identifies abundant candidate transport vesicles in Toxoplasma gondii.

Toxoplasma gondii, which causes toxoplasmic encephalitis and birth defects, contains an essential chloroplast-related organelle to which proteins are trafficked via the secretory system. This organelle, the apicoplast, is bounded by multiple membranes. In this report we identify a novel apicoplast-associated thioredoxin family protein, ATrx1, which is predominantly soluble or peripherally associated with membranes, and which localizes primarily to the outer compartments of the organelle. As such, it represents the first protein to be identified as residing in the apicoplast intermembrane spaces. ATrx1 lacks the apicoplast targeting sequences typical of luminal proteins. However, sequences near the N terminus are required for proper targeting of ATrx1, which is proteolytically processed from a larger precursor to multiple smaller forms. This protein reveals a population of vesicles, hitherto unrecognized as being highly abundant in the cell, which may serve to transport proteins to the apicoplast.

A membrane protease is targeted to the relict plastid of toxoplasma via an internal signal sequence.

The apicoplast is a secondary plastid found in Toxoplasma gondii, Plasmodium species and many other apicomplexan parasites. Although the apicoplast is essential to parasite survival, little is known about the protein constituents of the four membranes surrounding the organelle. Luminal proteins are directed to the endoplasmic reticulum (ER) by an N-terminal signal sequence and from there to the apicoplast by a transit peptide domain. We have identified a membrane-associated AAA protease in T. gondii, FtsH1. Although the protein lacks a canonical bipartite-targeting sequence, epitope-tagged FtsH1 colocalizes with the recently identified apicoplast membrane marker APT1 and immunoelectron microscopy confirms the residence of FtsH1 on plastid membranes. Trafficking appears to occur via the ER because deletion mutants lacking the peptidase domain are retained in the ER. When extended to include the peptidase domain, the protein trafficks properly. The transmembrane domain is required for localization of the full-length protein to the apicoplast and a truncation mutant to the ER. Thus, at least two distinct regions of FtsH1 are required for proper trafficking, but they differ from those of luminal proteins and would not be detected by the algorithms currently used to identify apicoplast proteins.

Cell cycle-regulated vesicular trafficking of Toxoplasma APT1, a protein localized to multiple apicoplast membranes.

The apicoplast is a relict plastid essential for viability of the apicomplexan parasites Toxoplasma and Plasmodium. It is surrounded by multiple membranes that proteins, substrates and metabolites must traverse. Little is known about apicoplast membrane proteins, much less their sorting mechanisms. We have identified two sets of apicomplexan proteins that are homologous to plastid membrane proteins that transport phosphosugars or their derivatives. Members of the first set bear N-terminal extensions similar to those that target proteins to the apicoplast lumen. While Toxoplasma gondii lacks this type of translocator, the N-terminal extension from the Plasmodium falciparum sequence was shown to be functional in T. gondii. The second set of translocators lacks an N-terminal targeting sequence. This translocator, TgAPT1, when tagged with HA, localized to multiple apicoplast membranes in T. gondii. Contrasting with the constitutive targeting of luminal proteins, the localization of the translocator varied during the cell cycle. Early-stage parasites showed circumplastid distribution, but as the plastid elongated in preparation for division, vesicles bearing TgAPT1 appeared adjacent to the plastid. After plastid division, the protein resumes a circumplastid colocalization. These studies demonstrate for the first time that vesicular trafficking likely plays a role in the apicoplast biogenesis.