RON5 Is Critical for Organization and Function of the Toxoplasma Moving Junction Complex

Apicomplexans facilitate host cell invasion through formation of a tight-junction interface between parasite and host plasma membranes called the moving junction (MJ). A complex of the rhoptry neck proteins RONs 2/4/5/8 localize to the MJ during invasion where they are believed to provide a stable anchoring point for host penetration. During the initiation of invasion, the preformed MJ RON complex is injected into the host cell where RON2 spans the host plasma membrane while RONs 4/5/8 localize to its cytosolic face. While much attention has been directed toward an AMA1-RON2 interaction supposed to occur outside the cell, little is known about the functions of the MJ RONs positioned inside the host cell. Here we provide a detailed analysis of RON5 to resolve outstanding questions about MJ complex organization, assembly and function during invasion. Using a conditional knockdown approach, we show loss of RON5 results in complete degradation of RON2 and mistargeting of RON4 within the parasite secretory pathway, demonstrating that RON5 plays a key role in organization of the MJ RON complex. While RON8 is unaffected by knockdown of RON5, these parasites are unable to invade new host cells, providing the first genetic demonstration that RON5 plays a critical role in host cell penetration. Although invasion is not required for injection of rhoptry effectors into the host cytosol, parasites lacking RON5 also fail to form evacuoles suggesting an intact MJ complex is a prerequisite for secretion of rhoptry bulb contents. Additionally, while the MJ has been suggested to function in egress, disruption of the MJ complex by RON5 depletion does not impact this process. Finally, functional complementation of our conditional RON5 mutant reveals that while proteolytic separation of RON5 N- and C-terminal fragments is dispensable, a portion of the C-terminal domain is critical for RON2 stability and function in invasion.     

Identification of a new rhoptry neck complex RON9/RON10 in the Apicomplexa parasite Toxoplasma gondii

Apicomplexan parasites secrete and inject into the host cell the content of specialized secretory organelles called rhoptries, which take part into critical processes such as host cell invasion and modulation of the host cell immune response. The rhoptries are structurally and functionally divided into two compartments. The apical duct contains rhoptry neck (RON) proteins that are conserved in Apicomplexa and are involved in formation of the moving junction (MJ) driving parasite invasion. The posterior bulb contains rhoptry proteins (ROPs) unique to an individual genus and, once injected in the host cell act as effector proteins to co-opt host processes and modulate parasite growth and virulence. We describe here two new RON proteins of Toxoplasma gondii, RON9 and RON10, which form a high molecular mass complex. In contrast to the other RONs described to date, this complex was not detected at the MJ during invasion and therefore was not associated to the MJ complex RON2/4/5/8. Disruptions of either RON9 or RON10 gene leads to the retention of the partner in the ER followed by subsequent degradation, suggesting that the RON9/RON10 complex formation is required for proper sorting to the rhoptries. Finally, we show that the absence of RON9/RON10 has no significant impact on the morphology of rhoptry, on the invasion and growth in fibroblasts in vitro or on virulence in vivo. The conservation of RON9 and RON10 in Coccidia and Cryptosporidia suggests a specific relation with development in intestinal epithelial cells.     

The RON2-AMA1 interaction is a critical step in moving junction-dependent invasion by apicomplexan parasites

Obligate intracellular Apicomplexa parasites share a unique invasion mechanism involving a tight interaction between the host cell and the parasite surfaces called the moving junction (MJ). The MJ, which is the anchoring structure for the invasion process, is formed by secretion of a macromolecular complex (RON2/4/5/8), derived from secretory organelles called rhoptries, into the host cell membrane. AMA1, a protein secreted from micronemes and associated with the parasite surface during invasion, has been shown in vitro to bind the MJ complex through a direct association with RON2. Here we show that RON2 is inserted as an integral membrane protein in the host cell and, using several interaction assays with native or recombinant proteins, we define the region that binds AMA1. Our studies were performed both in Toxoplasma gondii and Plasmodium falciparum and although AMA1 and RON2 proteins have diverged between Apicomplexa species, we show an intra-species conservation of their interaction. More importantly, invasion inhibition assays using recombinant proteins demonstrate that the RON2-AMA1 interaction is crucial for both T. gondii and P. falciparum entry into their host cells. This work provides the first evidence that AMA1 uses the rhoptry neck protein RON2 as a receptor to promote invasion by Apicomplexa parasites.     

The C-terminus of Toxoplasma RON2 provides the crucial link between AMA1 and the host-associated invasion complex

Host cell invasion by apicomplexan parasites requires formation of the moving junction (MJ), a ring-like apposition between the parasite and host plasma membranes that the parasite migrates through during entry. The Toxoplasma MJ is a secreted complex including TgAMA1, a transmembrane protein on the parasite surface, and a complex of rhoptry neck proteins (TgRON2/4/5/8) described as host cell-associated. How these proteins connect the parasite and host cell has not previously been described. Here we show that TgRON2 localizes to the MJ and that two short segments flanking a hydrophobic stretch near its C-terminus (D3 and D4) independently associate with the ectodomain of TgAMA1. Pre-incubation of parasites with D3 (fused to glutathione S-transferase) dramatically reduces invasion but does not prevent injection of rhoptry bulb proteins. Hence, the entire C-terminal region of TgRON2 forms the crucial bridge between TgAMA1 and the rest of the MJ complex but this association is not required for rhoptry protein injection.     

The moving junction of apicomplexan parasites: a key structure for invasion

Most Apicomplexa are obligate intracellular parasites and many are important pathogens of human and domestic animals. For a successful cell invasion, they rely on their own motility and on a firm anchorage to their host cell, depending on the secretion of proteins and the establishment of a structure called the moving junction (MJ). The MJ moves from the apical to the posterior end of the parasite, leading to the internalization of the parasite into a parasitophorous vacuole. Based on recent data obtained in Plasmodium and Toxoplasma, an emerging model emphasizes a cooperative role of secreted parasitic proteins in building the MJ and driving this crucial invasive process. More precisely, the parasite exports the microneme protein AMA1 to its own surface and the rhoptry neck RON2 protein as a receptor inserted into the host cell together with other RON partners. Ongoing and future research will certainly help refining the model by characterizing the molecular organization within the MJ and its interactions with both host and parasite cytoskeleton for anchoring of the complex.     

Expression and localization of rhoptry neck protein 5 in merozoites and sporozoites of Plasmodium yoelii

Host cell invasion by Apicomplexan parasites marks a crucial step in disease establishment and pathogenesis. The moving junction (MJ) is a conserved and essential feature among parasites of this phylum during host cell invasion, thus proteins that associate at this MJ are potential targets of drug and vaccine development. In both Toxoplasma gondii and Plasmodium falciparum, a micronemal protein, Apical Membrane Antigen 1 (AMA1), and Rhoptry Neck proteins (RONs; RON2 and RON4) form an essential complex at the MJ. A new RON member, RON5, was shown to be important to stabilize RON2 during development and to associate with the MJ complex in T. gondii and also to be immunoprecipitated by anti-AMA1 antibody in P. falciparum. However, the detailed molecular nature of RON5 in Plasmodium is not well understood. In this study, Plasmodium yoelii RON5 gene (pyron5) was identified as an ortholog of P. falciparum and Plasmodium berghei ron5. The pyron5 exon–intron structure was validated by comparing genomic DNA sequences and experimentally determining full-length complementary DNA sequence. PyRON5 was detected in water-insoluble fractions but no reliable transmembrane domain(s) were predicted by transmembrane prediction algorithms. PyRON5 formed a complex with PyRON4, PyRON2, and PyAMA1 in late schizont protein extract. Taken together, we infer that these results suggest that PyRON5 associates with membrane indirectly via other MJ components. Indirect immunofluorescence assay and immunoelectron microscopy localized PyRON5 at the rhoptry neck of the late schizont merozoites and at the rhoptry of sporozoites. The two-stage expression of PyRON5 suggests that PyRON5 plays roles in invasion not only of erythrocytes, but also of mosquito salivary glands and/or mammalian hepatocytes.     

Identification of three novel Toxoplasma gondii rhoptry proteins

The rhoptries are key secretory organelles from apicomplexan parasites that contain proteins involved in invasion and modulation of the host cell. Some rhoptry proteins are restricted to the posterior bulb (ROPs) and others to the anterior neck (RONs). As many rhoptry proteins have been shown to be key players in Toxoplasma invasion and virulence, it is important to identify, understand and characterise the biological function of the components of the rhoptries. In this report, we identified putative novel rhoptry genes by identifying Toxoplasma genes with similar cyclical expression profiles as known rhoptry protein encoding genes. Using this approach we identified two new rhoptry bulb (ROP47 and ROP48) and one new rhoptry neck protein (RON12). ROP47 is secreted and traffics to the host cell nucleus, RON12 was not detected at the moving junction during invasion. Deletion of ROP47 or ROP48 in a type II strain did not show major influence in in vitro growth or virulence in mice.     

The rhoptry neck protein RON4 re-localizes at the moving junction during Toxoplasma gondii invasion

Host cell invasion in the Apicomplexa is unique in its dependency on a parasite actin-driven machinery and in the exclusion of most host cell membrane proteins during parasitophorous vacuole (PV) formation. This exclusion occurs at a junction between host cell and parasite plasma membranes that has been called the moving junction, a circumferential zone which forms at the apical tip of the parasite, moves backward and eventually pinches the PV from the host cell membrane. Despite having been described by electron microscopic studies 30 years ago, the molecular nature of this singular structure is still enigmatic. We have obtained a monoclonal antibody that recognizes the moving junction of invading tachyzoites of Toxoplasma gondii, in a pattern clearly distinct from those described so far for microneme and rhoptry proteins. The protein recognized by this antibody has been affinity purified. Mass spectrometry analysis showed that it is a rhoptry neck protein (RON4), a hypothetical protein with homologues restricted to Apicomplexa. Our findings reveals for the first time the participation of rhoptry neck proteins in moving junction formation and strongly suggest the conservation of this structure at the molecular level among Apicomplexa.     

Novel components of the Apicomplexan moving junction reveal conserved and coccidia-restricted elements

Apicomplexan parasites generally invade their host cells by anchoring the parasite to the host membrane through a structure called the moving junction (MJ). This MJ is also believed to sieve host proteins from the nascent parasitophorous vacuole membrane, which likely protects the pathogen from lysosomal destruction. Previously identified constituents of the Toxoplasma MJ have orthologues in Plasmodium , indicating a conserved structure throughout the Apicomplexa. We report here two novel MJ proteins, RON5 and RON8. While RON5 is conserved in Plasmodium , RON8 appears restricted to the coccidia. RON8, which is likely essential, co-immunoprecipitates RON5 and known MJ proteins from extracellular parasites, indicating that a preformed complex exists within the parasites. Upon secretion, we show that RON8 within the MJ localizes to the cytoplasmic face of the host plasma membrane. To examine interactions between RON8 and the host cell, we expressed RON8 in mammalian cells and show that it targets to its site of action at the periphery in a manner dependent on the C-terminal portion of the protein. The discovery of RON5 and RON8 provides new insight into conserved and unique elements of the MJ, furthering our understanding of how the MJ contributes to the intricate mechanism of Apicomplexan invasion.     

Independent roles of apical membrane antigen 1 and rhoptry neck proteins during host cell invasion by apicomplexa

During invasion, apicomplexan parasites form an intimate circumferential contact with the host cell, the tight junction (TJ), through which they actively glide. The TJ, which links the parasite motor to the host cell cytoskeleton, is thought to be composed of interacting apical membrane antigen 1 (AMA1) and rhoptry neck (RON) proteins. Here we find that, in Plasmodium berghei, while both AMA1 and RON4 are important for merozoite invasion of erythrocytes, only RON4 is required for sporozoite invasion of hepatocytes, indicating that RON4 acts independently of AMA1 in the sporozoite. Further, in the Toxoplasma gondii tachyzoite, AMA1 is dispensable for normal RON4 ring and functional TJ assembly but enhances tachyzoite apposition to the cell and internalization frequency. We propose that while the RON proteins act at the TJ, AMA1 mainly functions on the zoite surface to permit correct attachment to the cell, which may facilitate invasion depending on the zoite-cell combination.     

Erythrocyte invasion: vocabulary and grammar of the Plasmodium rhoptry

Malaria is a dangerous infectious disease caused by obligate intracellular protozoan Plasmodium parasites. In the vertebrate host, erythrocyte recognition and establishment of a nascent parasitophorous vacuole are essential processes, and are largely achieved using molecules located in the microorganelles of the invasive-stage parasites. Recent proteome analyses of the phylogenetically related Toxoplasma parasite have provided protein catalogs for these microorganelles, which can now be used to identify orthologous proteins in the Plasmodium genome. Of importance is the formation of a complex between the proteins secreted from the rhoptry neck portion (RONs) and micronemes (AMA1), which localize at the moving junction during parasite invagination into the host cell. In this article I review the largely unexplored paradigm of the malaria merozoite rhoptry, focusing on the high molecular weight rhoptry protein complex (the RhopH complex), and speculate on its grammar during invasion.     

Export of a Toxoplasma gondii Rhoptry Neck Protein Complex at the Host Cell Membrane to Form the Moving Junction during Invasion

One of the most conserved features of the invasion process in Apicomplexa parasites is the formation of a moving junction (MJ) between the apex of the parasite and the host cell membrane that moves along the parasite and serves as support to propel it inside the host cell. The MJ was, up to a recent period, completely unknown at the molecular level. Recently, proteins originated from two distinct post-Golgi specialised secretory organelles, the micronemes (for AMA1) and the neck of the rhoptries (for RON2/RON4/RON5 proteins), have been shown to form a complex. AMA1 and RON4 in particular, have been localised to the MJ during invasion. Using biochemical approaches, we have identified RON8 as an additional member of the complex. We also demonstrated that all RON proteins are present at the MJ during invasion. Using metabolic labelling and immunoprecipitation, we showed that RON2 and AMA1 were able to interact in the absence of the other members. We also discovered that all MJ proteins are subjected to proteolytic maturation during trafficking to their respective organelles and that they could associate as non-mature forms in vitro. Finally, whereas AMA1 has previously been shown to be inserted into the parasite membrane upon secretion, we demonstrated, using differential permeabilization and loading of RON-specific antibodies into the host cell, that the RON complex is targeted to the host cell membrane, where RON4/5/8 remain associated with the cytoplasmic face. Globally, these results point toward a model of MJ organization where the parasite would be secreting and inserting interacting components on either side of the MJ, both at the host and at its own plasma membranes.     

Proteomic analysis of rhoptry organelles reveals many novel constituents for host-parasite interactions in Toxoplasma gondii

Rhoptries are specialized secretory organelles that are uniquely present within protozoan parasites of the phylum Apicomplexa. These obligate intracellular parasites comprise some of the most important parasites of humans and animals, including the causative agents of malaria (Plasmodium spp.) and chicken coccidiosis (Eimeria spp.). The contents of the rhoptries are released into the nascent parasitophorous vacuole during invasion into the host cell, and the resulting proteins often represent the literal interface between host and pathogen. We have developed a method for highly efficient purification of rhoptries from one of the best studied Apicomplexa, Toxoplasma gondii, and we carried out a detailed proteomic analysis using mass spectrometry that has identified 38 novel proteins. To confirm their rhoptry origin, antibodies were raised to synthetic peptides and/or recombinant protein. Eleven of 12 of these yielded antibody that showed strong rhoptry staining by immunofluorescence within the rhoptry necks and/or their bulbous base. Hemagglutinin epitope tagging confirmed one additional novel protein as from the rhoptry bulb. Previously identified rhoptry proteins from Toxoplasma and Plasmodium were unique to one or the other organism, but our elucidation of the Toxoplasma rhoptry proteome revealed homologues that are common to both. This study also identified the first Toxoplasma genes encoding rhoptry neck proteins, which we named RONs, demonstrated that toxofilin and Rab11 are rhoptry proteins, and identified novel kinases, phosphatases, and proteases that are likely to play a key role in the ability of the parasite to invade and co-opt the host cell for its own survival and growth.     

Rhoptries: an arsenal of secreted virulence factors

Apicomplexan parasites use actin-based motility coupled with regulated protein secretion from apical organelles to actively invade host cells. Crucial in this process are rhoptries, club-shaped secretory organelles that discharge their contents during parasite invasion into host cells. A proteomic analysis of the rhoptries in Toxoplasma gondii demonstrated that this organelle contains a number of novel rhoptry proteins (ROPs) including serine-threonine kinases and protein phosphatases. A subset of rhoptry proteins called RONs have been shown to target the moving junction, which plays a key role in invasion and parasitophorous vacuole formation. Other ROP proteins have various destinations in the host cell including the host cell nucleus and the parasitophorous vacuole, probably reflecting their distinct targets and roles. Forward genetic analysis recently revealed that secretory ROP kinases dramatically influence host gene expression and are the major parasite virulence factors. Thus, ROP proteins are functionally analogous (though not homologous) to effectors released by type III and IV secretion systems, which are factors that play an important role in bacterial virulence. Deciphering the role of ROP effectors may allow specific disruption of these factors, thus offering new options for preventing disease.     

Focus on the ringleader: the role of AMA1 in apicomplexan invasion and replication

Apicomplexan parasites exhibit an unusual mechanism of host cell penetration. A central player in this process is the protein apical membrane antigen 1 (AMA1). Although essential for invasion, the precise functional roles AMA1 plays have been unclear. Several recent studies have provided important functional insight into its role within the multiprotein complex that comprises the moving junction (MJ). Initially formed at the apical tip of the invading parasite, the MJ represents a ring-like region of contact between the surfaces of the invading parasite and the host cell as the invaginated host plasma membrane is forced inward by the penetrating parasite. This review discusses these and other recent insights into AMA1 with particular emphasis on studies conducted in Plasmodium and Toxoplasma.     

Plasmodial ortholog of Toxoplasma gondii rhoptry neck protein 3 is localized to the rhoptry body

The proteins in apical organelles of Plasmodium falciparum merozoite play an important role in invasion into erythrocytes. Several rhoptry neck (RON) proteins have been identified in rhoptry proteome of the closely-related apicomplexan parasite, Toxoplasma gondii. Recently, three of P. falciparum proteins orthologous to TgRON proteins, PfRON2, 4 and 5, were found to be located in the rhoptry neck and interact with the micronemal protein apical membrane antigen 1 (PfAMA1) to form a moving junction complex that helps the invasion of merozoite into erythrocyte. However, the other P. falciparum RON proteins have yet to be characterized. Here, we determined that "PFL2505c" (hereafter referred to as pfron3) is the ortholog of the tgron3 in P. falciparum and characterized its protein expression profile, subcellular localization, and complex formation. Protein expression analysis revealed that PfRON3 was expressed primarily in late schizont stage parasites. Immunofluorescence microscopy (IFA) showed that PfRON3 localizes in the apical region of P. falciparum merozoites. Results from immunoelectron microscopy, along with IFA, clarified that PfRON3 localizes in the rhoptry body and not in the rhoptry neck. Even after erythrocyte invasion, PfRON3 was still detectable at the parasite ring stage in the parasitophorous vacuole. Moreover, co-immunoprecipitation studies indicated that PfRON3 interacts with PfRON2 and PfRON4, but not with PfAMA1. These results suggest that PfRON3 partakes in the novel PfRON complex formation (PfRON2, 3, and 4), but not in the moving junction complex (PfRON2, 4, 5, and PfAMA1). The novel PfRON complex, as well as the moving junction complex, might play a fundamental role in erythrocyte invasion by merozoite stage parasites.     

The Plasmodium rhoptry associated protein complex is important for parasitophorous vacuole membrane structure and intraerythrocytic parasite growth

Plasmodium parasites must invade erythrocytes in order to cause the disease malaria. The invasion process involves the coordinated secretion of parasite proteins from apical organelles that include the rhoptries. The rhoptry is comprised of two compartments: the neck and the bulb. Rhoptry neck proteins are involved in host cell adhesion and formation of the tight junction that forms between the invading parasite and erythrocyte, whereas the role of rhoptry bulb proteins remains ill‐defined due to the lack of functional studies. In this study, we show that the rhoptry‐associated protein (RAP) complex is not required for rhoptry morphology or erythrocyte invasion. Instead, post‐invasion when the parasite is bounded by a parasitophorous vacuolar membrane (PVM), the RAP complex facilitates the survival of the parasite in its new intracellular environment. Consequently, conditional knockdown of members of the RAP complex leads to altered PVM structure, delayed intra‐erythrocytic growth, and reduced parasitaemias in infected mice. This study provides evidence that rhoptry bulb proteins localising to the parasite–host cell interface are not simply by‐products of the invasion process but contribute to the growth of Plasmodium in vivo.     

Molecular dissection of host cell invasion by the apicomplexans: the glideosome

Gliding motility is an essential and fascinating apicomplexan-typical adaptation to an intracellular lifestyle. Apicomplexan parasites rely on gliding motility for their migration across biological barriers and for host cell invasion and egress. This unusual substratedependent mode of locomotion involves the concerted action of secretory adhesins, a myosin motor, factors regulating actin dynamics and proteases. During invasion, complexes of soluble and transmembrane micronemes proteins (MICs) and rhoptry neck proteins (RONs) are discharged to the apical pole of the parasite, some protein acts as adhesins and bind to host cell receptors whereas others are involved in the moving junction formation. These complexes redistribute towards the posterior pole of the parasite via a physical connection to the parasite actomyosin system and are eventually released from the parasite surface by the action of parasite proteases.