Variant proteins of the Plasmodium falciparum RIFIN family show distinct subcellular localization and developmental expression patterns.

In order to avoid immune recognition in favor of a chronic infection, the malaria parasite Plasmodium falciparum has developed means to express clonally variant antigens at the surface of the infected erythrocyte (IE). Proteins of the var and rif multicopy gene families, encoding PfEMP1 and RIFINs, respectively, have been implicated in these processes. Here, we studied members of the latter family and present data revealing different subcellular localization patterns for RIFIN variants belonging to two distinct subgroups, which have been designated A- and B-type RIFINs. While A-type RIFINs were found to be associated with the parasite and transported to the surface of infected erythrocytes via Maurer's clefts, B-type RIFINs appeared to be mostly retained inside the parasite. However, expression of both subtypes does not seem to be mutually exclusive. Moreover, both A- and B-type variants were also expressed in the merozoite, present either in the apical region (A-type) or in the cytosol (B-type). The presence of RIFINs in merozoites suggests that antigenic variation in P. falciparum is not only restricted to parasite-derived proteins at the IE surface, but the phenomenon also prevails in other life cycle stages. Interestingly, some RIFIN variants were detected only in intracellular stages and not in merozoites, pointing to differential developmental expression patterns for distinct members of this large protein family.

A novel DBL-domain of the P. falciparum 332 molecule possibly involved in erythrocyte adhesion.

Plasmodium falciparum malaria is brought about by the asexual stages of the parasite residing in human red blood cells (RBC). Contact between the erythrocyte surface and the merozoite is the first step for successful invasion and proliferation of the parasite. A number of different pathways utilised by the parasite to adhere and invade the host RBC have been characterized, but the complete biology of this process remains elusive. We here report the identification of an open reading frame (ORF) representing a hitherto unknown second exon of the Pf332 gene that encodes a cysteine-rich polypeptide with a high degree of similarity to the Duffy-binding-like (DBL) domain of the erythrocyte-binding-ligand (EBL) family. The sequence of this DBL-domain is conserved and expressed in all parasite clones/strains investigated. In addition, the expression level of Pf332 correlates with proliferation efficiency of the parasites in vitro. Antibodies raised against the DBL-domain are able to reduce the invasion efficiency of different parasite clones/strains. Analysis of the DBL-domain revealed its ability to bind to uninfected human RBC, and moreover demonstrated association with the iRBC surface. Thus, Pf332 is a molecule with a potential role to support merozoite invasion. Due to the high level of conservation in sequence, the novel DBL-domain of Pf332 is of possible importance for development of novel anti-malaria drugs and vaccines.

Characterization of Maurer's clefts in Plasmodium falciparum-infected erythrocytes.

In 1902 Georg Maurer was the first to publish a detailed description of Giemsa-stained structures in the cytosol of Plasmodium falciparum-infected erythrocytes, today known as Maurer's clefts. Later when clefts were seen by electron microscopy, the description was modified to also include these, which has caused disagreement over the composition of Maurer's clefts. For that reason, Maurer's clefts were characterized during intraerythrocytic development of P. falciparum by simultaneously staining cytosolic structures with antibodies using indirect immunofluorescence assays and with Giemsa. At least three groups of antigens, P. falciparum erythrocyte membrane protein 1 (PfEMP1)/ RIFIN/SURFIN, P. falciparum histidine-rich protein 2 (PfHRP2), and exported proteins 1 and 2 (Exp1 and Exp2), were detected in distinct Giemsa-stained structures in the cytosol of infected erythrocytes, but PfHRP2 and Exp1/Exp2 were not found in clefts by transmission electron microscopy. Therefore, Maurer's clefts as defined by staining with Giemsa comprise a number of cytoplasmic structures and antigens not included in structures called clefts and seen by electron microscopy.

SURFIN is a polymorphic antigen expressed on Plasmodium falciparum merozoites and infected erythrocytes.

The surfaces of the infected erythrocyte (IE) and the merozoite, two developmental stages of malaria parasites, expose antigenic determinants to the host immune system. We report on surface-associated interspersed genes (surf genes), which encode a novel polymorphic protein family, SURFINs, present on both IEs and merozoites. A SURFIN expressed in 3D7 parasites, SURFIN4.2, was identified by mass spectrometric analysis of peptides cleaved off the surface of live IEs with trypsin. SURFINs are encoded by a family of 10 surf genes, including three predicted pseudogenes, located within or close to the subtelomeres of five of the chromosomes. SURFINs show structural and sequence similarities with exported surface-exposed proteins (PvSTP1, PkSICAvar, PvVIR, Pf332, and PfEMP1) of several Plasmodium species. SURFIN4.2 of a parasite other than 3D7 (FCR3S1.2) showed polymorphisms in the extracellular domain, suggesting sequence variability between genotypes. SURFIN4.2 not only was found cotransported with PfEMP1 and RIFIN to the IE surface, but also accumulated in the parasitophorous vacuole. In released merozoites, SURFIN4.2 was present in an amorphous cap at the parasite apex, where it may be involved in the invasion of erythrocytes. By exposing shared polymorphic antigens on IEs and merozoites, the parasite may coordinate the antigenic composition of these attachment surfaces during growth in the bloodstream.

Common trafficking pathway for variant antigens destined for the surface of the Plasmodium falciparum-infected erythrocyte.

Intraerythrocytic Plasmodium falciparum exports proteins to the cytosol and to the plasma membrane of the host cell. We here present data revealing the existence of a unique common pathway for the surface bound traffic of the clonally variant antigens, repeated-interspersed-antigen (RIFINS) and P. falciparum erythrocyte-membrane-protein-1 (PfEMP1). RIFIN- and PfEMP1-specific antibodies were found to stain single small vesicles (SSV) that bud off from the parasitophorus vacuolar membrane (PMV) at 6-10 h post-invasion. Large multimeric vesicle (LMV) assemblies, composed of subunits each of a similar size to that of a SSV, appeared as the dominant vesicle type carrying the variant antigens in the cytosol as the parasites developed into early trophozoite stages (> or = 16 h post-invasion). Later, more than 24 h post-invasion, large spinle-like vesicles (LSLV) built up as the LMV approached and accumulated underneath the erythrocyte membrane. LMV were found to associate both with the Maurer's cleft antigen Pf332 and with lipids as seen by fluorescent BODIPY-Ceramide staining. Co-traffic of Pf332 with RIFINS and PfEMP1 occurred in sub-compartmentalized LMV, as the variant antigens co-localized at the outer rim while Pf332 occupied the core of the vesicle complex. Formation of LMV for the trafficking of RIFINS and PfEMP1 is a prominent feature of freshly isolated P. falciparum and of in vitro propagated K+ as well as K- parasites, seemingly independent of the knob-associated histidine-rich protein (KAHRP). In vitro cultured 3D7 clones lack LMV formation and traffic the variant antigens in vesicles of a similar size to that of the SSV.