Microneme protein 8 – a new essential invasion factor inToxoplasma gondii

A dynamin is required for the biogenesis of secretory organelles in Toxoplasma gondii

BACKGROUND

Apicomplexans contain only a core set of factors involved in vesicular traffic. Yet these obligate intracellular parasites evolved a set of unique secretory organelles (micronemes, rhoptries, and dense granules) that are required for invasion and modulation of the host cell. Apicomplexa replicate by budding from or within a single mother cell, and secretory organelles are synthesized de novo at the final stage of division. To date, the molecular basis for their biogenesis is unknown.

RESULTS

We demonstrate that the apicomplexan dynamin-related protein B (DrpB) belongs to an alveolate specific family of dynamins that is expanded in ciliates. DrpB accumulates in a cytoplasmic region close to the Golgi that breaks up during replication and reforms after assembly of the daughter cells. Conditional ablation of DrpB function results in mature daughter parasites that are devoid of micronemes and rhoptries. In the absence of these organelles, invasion-related secretory proteins are mistargeted to the constitutive secretory pathway. Mutant parasites are able to replicate but are unable to escape from or invade into host cells.

CONCLUSIONS

DrpB is the essential mechanoenzyme for the biogenesis of secretory organelles in Apicomplexa. We suggest that DrpB is required during replication to generate vesicles for the regulated secretory pathway that form the unique secretory organelles. Our study supports a role of an alveolate-specific dynamin that was required for the evolution of novel, secretory organelles. In the case of Apicomplexa, these organelles further evolved to enable a parasitic lifestyle.

Rab11A-controlled assembly of the inner membrane complex is required for completion of apicomplexan cytokinesis

The final step during cell division is the separation of daughter cells, a process that requires the coordinated delivery and assembly of new membrane to the cleavage furrow. While most eukaryotic cells replicate by binary fission, replication of apicomplexan parasites involves the assembly of daughters (merozoites/tachyzoites) within the mother cell, using the so-called Inner Membrane Complex (IMC) as a scaffold. After de novo synthesis of the IMC and biogenesis or segregation of new organelles, daughters bud out of the mother cell to invade new host cells. Here, we demonstrate that the final step in parasite cell division involves delivery of new plasma membrane to the daughter cells, in a process requiring functional Rab11A. Importantly, Rab11A can be found in association with Myosin-Tail-Interacting-Protein (MTIP), also known as Myosin Light Chain 1 (MLC1), a member of a 4-protein motor complex called the glideosome that is known to be crucial for parasite invasion of host cells. Ablation of Rab11A function results in daughter parasites having an incompletely formed IMC that leads to a block at a late stage of cell division. A similar defect is observed upon inducible expression of a myosin A tail-only mutant. We propose a model where Rab11A-mediated vesicular traffic driven by an MTIP-Myosin motor is necessary for IMC maturation and to deliver new plasma membrane to daughter cells in order to complete cell division.

Apicomplexan parasites are unusual in that they replicate by assembling daughter parasites within the mother cell. This involves the ordered assembly of an Inner Membrane Complex (IMC), a scaffold consisting of flattened membrane cisternae and a subpellicular network made up of microtubules and scaffold proteins. The IMC begins to form at the onset of replication, but its maturation occurs at the final stage of cytokinesis (the last step during cell division) upon the addition of motor (glideosome) components such as GAP45 (Glideosome Associated Protein), Myosin A (MyoA), and Myosin-Tail-Interacting-Protein (MTIP, also known as Myosin Light Chain 1) that are necessary to drive the gliding motility required for parasite invasion. We demonstrate that Rab11A regulates not only delivery of new plasmamembrane to daughter cells, but, importantly, also correct IMC formation. We show that Rab11A physically interacts with MTIP/MLC1, implicating unconventional myosin(s) in both cytokinesis and IMC maturation, and, consistently, overexpression of a MyoA tail-only mutant generates a default similar to that which we observe upon Rab11A ablation. We propose a model where Rab11A-mediated vesicular traffic is required for the delivery of new plasma membrane to daughter cells and for the maturation of the IMC in order to complete cell division.

Do apicomplexan parasite-encoded proteins act as both ligands and receptors during host cell invasion?

Apicomplexan parasites are responsible for a wide range of diseases in animals, including humans, in whom Plasmodium species cause the devastating disease malaria. Several recent discoveries now indicate that these intracellular parasites may use a conserved mechanism to infect their host cells by using parasite-encoded proteins as both parasite ligands and receptors anchored to the host cells.

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.

Host-cell invasion by malaria parasites: insights from Plasmodium and Toxoplasma

Recent years have seen tremendous progress in our understanding of malaria parasite molecular biology. To a large extent, this progress follows significant developments in genetic, molecular and chemical tools available to study the malaria parasites and related Apicomplexa, in particular Toxoplasma gondii. One area of major advancement has been in understanding parasite host-cell invasion, a process that utilizes several essential molecular mechanisms that are conserved across the different lifecycle stages. Here, we summarize some of the most recent experimental data that shed light on the events underlying preparation and execution of malaria parasite invasion and how these insights might relate to the development of new antimalarial drugs.