Apicomplexan parasites secrete transmembrane (TM) adhesive proteins as part of the process leading to host cell attachment and invasion. These microneme proteins are cleaved in their TM domains by an unidentified protease termed microneme protein protease 1 (MPP1). The cleavage site sequence (IAYGG), mapped in the Toxoplasma gondii microneme proteins TgMIC2 and TgMIC6, is conserved in microneme proteins of other apicomplexans including Plasmodium species. We report here the characterisation of novel T. gondii proteins belonging to the rhomboid family of intramembrane-cleaving serine proteases. T. gondii possesses six genes encoding rhomboid-like proteins. Four are localised along the secretory pathway and therefore constitute possible candidates for MPP1 activity. Toxoplasma rhomboids TgROM1, TgROM2 and TgROM5 cleave the TM domain of Drosophila Spitz, an established substrate for rhomboids from several species, demonstrating that they are active proteases. In addition, TgROM2 cleaves chimeric proteins that contain the TM domains of TgMIC2 and TgMIC12. q
Abstractdetermine the generation of the responses that cause intestinal helminth resistance. AcknowledgementsOur work was supported by project GV04B-107 de la Conselleria de Cultura, Educació i Esport de la Generalitat Valenciana (Spain). We thank all of the researchers who helped us to compile the registry. (Trematoda: Echinostomatidae) in Spain and a discussion on the relationships within the 'revolutum' group based on cercarial chaetotaxy. References
Immediately prior to invasion Toxoplasma gondii tachyzoites release a large number of micronemal proteins (TgMICs) that participate in host cell attachment and penetration. The TgMIC4-MIC1-MIC6 complex was the first to be identified in T. gondii and has been recently shown to be critical in invasion. This study establishes that the N-terminal throm-bospondin type I repeat-like domains (TSR1-like) from TgMIC1 function as an independent adhesin as well as promoting association with TgMIC4. Using the newly solved three-dimensional structure of the C-terminal domain of TgMIC1 we have identified a novel Galectin-like fold that does not possess carbohydrate binding properties and redefines the architecture of TgMIC1. Instead, the TgMIC1 Galectin-like domain interacts and stabilizes TgMIC6, which provides the basis for a highly specific quality control mechanism for successful exit from the early secretory compartments and for subsequent trafficking of the complex to the micronemes.Toxoplasma gondii is a protozoan parasite of the phylum Apicomplexa, which infects virtually all warm-blooded animals and invades almost any cell type. Host cell invasion by this obligate intracellular parasite is an active process initiated by the formation of a tight association/junction with the host cell plasma membrane and leading to the creation of a parasitophorous vacuole. Contact with the host cell results in an increase in parasite intracellular calcium ions, which trigger apical organelles called micronemes to discharge their contents (1). Several micronemal proteins act as ligands for host cell receptors (2), while TgMIC2 and other transmembrane proteins establish a connection with the parasite actinomyosin system via their cytoplasmic tail (3), thus providing the motive force for penetration (4). It is becoming increasingly apparent that many microneme proteins are found in stable adhesive complexes, which are formed in the endoplasmic reticulum, and normally comprise an escorter protein, which is responsible for correct micronemal targeting, and one or more soluble effector proteins. The first such complex to be discovered in T. gondii was TgMIC4-MIC1-MIC6, in which TgMIC6 fulfils the role of the escorter protein, whereas TgMIC1 and TgMIC4 function as adhesins (5). Although TgMIC4-MIC1-MIC6 and the recently identified micronemal complex, TgMIC3-MIC8 (5, 6), are individually dispensable, the generation of double knock-outs for TgMIC1 and TgMIC3 renders the parasites avirulent in vivo, demonstrating functional synergy between these complexes (7). Deletion of the mic1 gene in T. gondii also confirmed the specific and critical role played by TgMIC1 in host cell attachment and invasion in vitro.Micronemal proteins have a modular structure with common themes in domain organization, for example many possess thrombospondin type-1 repeat domains (TSR1), 4 apple (or PAN) domains, and epidermal growth factor-like (EGF) domains (8). A schematic representation of the organization within the TgMIC4-MIC1-MIC6 complex is depicted in Fig. 1. Tg...
A picomplexan pathogens replicate exclusively within the confines of a host cell. Entry into (invasion) and exit from (egress) these cells requires an array of specialized parasite molecules, many of which have long been considered to have potential as targets of drug or vaccine-based therapies. In this chapter the authors discuss the current state of knowl› edge regarding the role of parasite proteolytic enzymes in these critical steps in the life cycle of two clinically important apicomplexan genera, Plasmodium and Toxoplasma. At least three dis› tinct proteases of the cysteine mechanistic class have been implicated in egress of the malaria parasite from cells of its vertebrate and insect host. In contrast, the bulk of the evidence indi› cates a prime role for serine proteases of the subtilisin and rhomboid families in invasion by both parasites. Whereas proteases involved in egress may function predominantly to degrade host cell structures, proteases involved in invasion probably act primarily as maturases and *sheddases', required to activate and ultimately remove ligands involved in interactions with the host cell.
Rhomboids (ROMs) constitute a family of polytopic serine proteases conserved throughout evolution. The obligate intracellular parasite Toxoplasma gondii possesses six genes coding for ROM-like proteases that are targeted to distinct subcellular compartments: TgROM1 localizes to regulated secretory organelles, micronemes, TgROM2 is present in the Golgi, while TgROM4 and TgROM5 are found in the pellicle of the parasite. The targeting mechanism/s of ROM proteins is an aspect that has not yet been assessed. The existence of TgROM family members localized to different subcellular compartments provides a convenient system to study their sorting mechanisms in a genetically tractable organism that possesses an elaborate secretory pathway and conserved trafficking machineries. In this study, we experimentally established the topology of TgROM1 and TgROM4 at the plasma membrane and applied domain-exchange and site-directed mutagenesis approaches to identify critical sorting determinants on the N-terminal cytosolic domains of TgROM2 and TgROM1 that confer their Golgi and post-Golgi localizations, respectively.
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