Catherine Braun-Breton

A novel mechanism for egress of malarial parasites from red blood cells.

The culminating step of the intraerythrocytic development of Plasmodium falciparum, the causative agent of malaria, is the spectacular release of multiple invasive merozoites on rupture of the infected erythrocyte membrane. This work reports for the first time that the whole process, taking place in time scales as short as 400 milliseconds, is the result of an elastic instability of the infected erythrocyte membrane. Using high-speed differential interference contrast (DIC) video microscopy and epifluorescence, we demonstrate that the release occurs in 3 main steps after osmotic swelling of the infected erythrocyte: a pore opens in ~ 100 milliseconds, ejecting 1-2 merozoites, an outward curling of the erythrocyte membrane is then observed, ending with a fast eversion of the infected erythrocyte membrane, pushing the parasites forward. It is noteworthy that this last step shows slight differences when infected erythrocytes are adhering. We rationalize our observations by considering that during the parasite development, the infected erythrocyte membrane acquires a spontaneous curvature and we present a subsequent model describing the dynamics of the curling rim. Our results show that sequential erythrocyte membrane curling and eversion is necessary for the parasite efficient angular dispersion and might be biologically essential for fast and numerous invasions of new erythrocytes.

Export of PfSBP1 to the Plasmodium falciparum Maurer’s Clefts

The human malaria parasite Plasmodium falciparum exports determinants of virulence and pathology to destinations within the host erythrocyte, including the erythrocyte cytoplasm, plasma membrane and membrane profiles of parasite origin termed Maurer’s clefts. Most of the exported proteins contain a conserved pentameric motif termed plasmodial export element (PEXEL)/vacuolar transfer signal (VTS) that functions as a cleavable sorting signal permitting export to the host erythrocyte. However, there are some exported proteins, such as the skeleton‐binding protein 1 (PfSBP1) that lack the PEXEL/VTS motif and that are not N‐terminally processed, suggesting the presence of alternative sorting signals and/or mechanisms. In this study, we have investigated trafficking of PfSBP1 to the Maurer’s clefts. Our data show that the transmembrane domain of PfSBP1 functions as an internal signal sequence for entry into the parasite’s secretory pathway and for transport to the parasite plasma membrane. Trafficking beyond the parasite’s plasma membrane required additional N‐terminal domains, which are characterized by a high negative net charge. Biochemical data indicate that these domains affect the solubility and extraction profile, the orientation of the protein within the membrane and the subcellular localization. Our findings suggest new principles of protein export in P.u2003falciparum‐infected erythrocytes.

Human erythrocyte remodelling during Plasmodium falciparum malaria parasite growth and egress.

The intra‐erythrocyte growth and survival of the malarial parasite Plasmodium falciparum is responsible for both uncomplicated and severe malaria cases and depends on the parasites ability to remodel its host cell. Host cell remodelling has several functions for the parasite, such as acquiring nutrients from the extracellular milieu because of the loss of membrane transporters upon erythrocyte differentiation, avoiding splenic clearance by conferring cytoadhesive properties to the infected erythrocyte, escaping the host immune response by exporting antigenically variant proteins at the red blood cell surface. In addition, parasite‐induced changes at the red blood cell membrane and sub‐membrane skeleton are also necessary for the efficient release of the parasite progeny from the host cell. Here we review these cellular and molecular changes, which might not only sustain parasite growth but also prepare, at a very early stage, the last step of egress from the host cell.

Novel Plasmodium falciparum Maurer's clefts protein families implicated in the release of infectious merozoites.

The pathogenicity of the most deadly human malaria parasite, Plasmodium falciparum, relies on the export of virulence factors to the surface of infected erythrocytes. A novel membrane compartment, referred to as Maurers clefts, is transposed to the host erythrocyte, acting as a marshal platform in the red blood cell cytoplasm, for exported parasite proteins addressed to the host cell plasma membrane. We report here the characterization of three new P.u2009falciparum multigene families organized in 9 highly conserved clusters with the Pfmc‐2tm genes in the subtelomeric regions of parasites chromosomes and expressed at early trophozoite stages. Like the PfMC‐2TM proteins, the PfEPF1, 3 and 4 proteins encoded by these families are exported to the Maurers clefts, as peripheral or integral proteins of the Maurers cleft membrane and largely exposed to the red cell cytosolic face of this membrane. A promoter titration approach was used to question the biological roles of these P.u2009falciparum‐specific exported proteins. Using the Pfepf1 family promoter, we observed the specific downregulation of all four families, correlating with the inefficient release of merozoites while the parasite intra‐erythrocytic maturation and Maurers clefts morphology were not impacted.

Plasmodium CDP-DAG synthase: an atypical gene with an essential N-terminal extension.

Cytidine diphosphate diacylglycerol synthase (CDS) diverts phosphatidic acid towards the biosynthesis of CDP-DAG, an obligatory liponucleotide intermediate in anionic phospholipid biosynthesis. The 78kDa predicted Plasmodium falciparum CDS (PfCDS) is recovered as a 50 kDa conserved C-terminal cytidylyltransferase domain (C-PfCDS) and a 28kDa fragment that corresponds to the unusually long hydrophilic asparagine-rich N-terminal extension (N-PfCDS). Here, we show that the two fragments of PfCDS are the processed forms of the 78 kDa pro-form that is encoded from a single transcript with no alternate translation start site for C-PfCDS. PfCDS, which shares 54% sequence identity with Plasmodium knowlesi CDS (PkCDS), could substitute for PkCDS in P. knowlesi. Experiments to disrupt either the full-length or the N-terminal extension of PkCDS indicate that not only the C-terminal cytidylyltransferase domain but also the N-terminal extension is essential to Plasmodium spp. PkCDS and PfCDS introduced in P. knowlesi were processed in the parasite, suggesting a conserved parasite-dependent mechanism. The N-PfCDS appears to be a peripheral membrane protein and is trafficked outside the parasite to the parasitophorous vacuole. Although the function of this unusual N-PfCDS remains enigmatic, the study here highlights features of this essential gene and its biological importance during the intra-erythrocytic cycle of the parasite.

New Export Pathway in Plasmodium falciparum-Infected Erythrocytes: Role of the Parasite Group II Chaperonin, PfTRiC.

The export of numerous proteins to the plasma membrane of its host erythrocyte is essential for the virulence and survival of the malaria parasite Plasmodium falciparum. The Maurers clefts, membrane structures transposed by the parasite in the cytoplasm of its host erythrocyte, play the role of a marshal platform for such exported parasite proteins. We identify here the export pathway of three resident proteins of the Maurers clefts membrane: the proteins are exported as soluble forms in the red cell cytoplasm to the Maurers clefts membrane in association with the parasite group II chaperonin (PfTRIC), a chaperone complex known to bind and address a large spectrum of unfolded proteins to their final location. We have also located the domain of interaction with PfTRiC within the amino‐terminal domain of one of these Maurers cleft proteins, PfSBP1. Because several Maurers cleft membrane proteins with different export motifs seem to follow the same route, we propose a general role for PfTRiC in the trafficking of malarial parasite proteins to the host erythrocyte.

Characterization of Toxoplasma DegP, a rhoptry serine protease crucial for lethal infection in mice

During the infection process, Apicomplexa discharge their secretory organelles called micronemes, rhoptries and dense granules to sustain host cell invasion, intracellular replication and to modulate host cell pathways and immune responses. Herein, we describe the Toxoplasma gondii Deg-like serine protein (TgDegP), a rhoptry protein homologous to High temperature requirement A (HtrA) or Deg-like family of serine proteases. TgDegP undergoes processing in both types I and II strains as most of the rhoptries proteins. We show that genetic disruption of the degP gene does not impact the parasite lytic cycle in vitro but affects virulence in mice. While in a type I strain DegPI appears dispensable for the establishment of an infection, removal of DegPII in a type II strain dramatically impairs the virulence. Finally, we show that KO-DegPII parasites kill immunodeficient mice as efficiently as the wild-type strain indicating that the protease might be involved in the complex crosstalk that the parasite engaged with the host immune response. Thus, this study unravels a novel rhoptry protein in T. gondii important for the establishment of lethal infection.

Red Blood Cell Spectrin Skeleton in the Spotlight

Das et al. recently reported a role for the major merozoite surface protein MSP1 in malarial parasite egress from the red blood cell (RBC). On the basis of these new data and physical considerations, we propose an updated model for the main steps of this essential process for parasite proliferation.

Establishment of Plasmodium falciparum Extracellular Compartments in its Host Erythrocyte

Upon invasion of mature erythrocytes, the malaria parasite Plasmodium falciparum establishes itself inside a self-induced parasitophorous vacuole, which forms a selective barrier between the parasite surface and its host cell cytosol and creates a very special biological niche for the parasite. To have access to nutrients and escape the host defences, the parasite extensively modifies this parasitophorous vacuole, eventually transforming it into a transit compartment for parasite proteins exported to the host cell and responsible for functional and structural alterations of the mature erythrocyte. One of the major modifications is the transposition of a cisternae-like compartment, named the Maurer’s clefts, which plays the role of a marshal platform for parasite proteins exported to the host cell. Here we shall review what is known about the biogenesis and dynamics of the parasitophorous vacuole and Maurer’s clefts and explore how molecular chaperones and co-chaperones could be key factors in the dynamics of these compartments and in the remodelling of the erythrocyte, necessary for the parasite growth, multiplication and survival.

Sequential Membrane Rupture and Vesiculation during Plasmodium berghei Gametocyte Egress from the Red Blood Cell

Malaria parasites alternate between intracellular and extracellular stages and successful egress from the host cell is crucial for continuation of the life cycle. We investigated egress of Plasmodium berghei gametocytes, an essential process taking place within a few minutes after uptake of a blood meal by the mosquito. Egress entails the rupture of two membranes surrounding the parasite: the parasitophorous vacuole membrane (PVM), and the red blood cell membrane (RBCM). High-speed video microscopy of 56 events revealed that egress in both genders comprises four well-defined phases, although each event is slightly different. The first phase is swelling of the host cell, followed by rupture and immediate vesiculation of the PVM. These vesicles are extruded through a single stabilized pore of the RBCM, and the latter is subsequently vesiculated releasing the free gametes. The time from PVM vesiculation to completion of egress varies between events. These observations were supported by immunofluorescence microscopy using antibodies against proteins of the RBCM and PVM. The combined results reveal dynamic re-organization of the membranes and the cortical cytoskeleton of the erythrocyte during egress.