The ring-infected erythrocyte surface antigen of Plasmodium falciparum associates with spectrin in the erythrocyte membrane.

The malaria parasite Plasmodium falciparum synthesises a protein, RESA, which associates with the membrane of newly invaded erythrocytes. Using spent supernatants from P. falciparum growing in culture as a source of soluble RESA we have developed an assay to examine the characteristics of RESA binding to the erythrocyte membrane in vitro. RESA associated with the Triton X-100 insoluble proteins on the inner face of the host erythrocyte membrane but did not bind to the outer surface of intact erythrocytes. Other proteins present in culture supernatants did not bind to the erythrocyte membrane. RESA was co-sedimented with the ternary complex formed between actin, spectrin and band 4.1 and co-precipitated with spectrin precipitated with anti-spectrin antibodies. The extent of association between RESA and the inner face of the erythrocyte membrane was reduced by the inclusion of excess purified spectrin in the assay. Thus, RESA appears to be associated with spectrin in the erythrocyte membrane skeleton.     

In vivo studies support the role of trafficking and cytoskeletal-binding motifs in the interaction of MESA with the membrane skeleton of Plasmodium falciparum-infected red blood cells

In red blood cells (RBCs) infected with the malaria parasite Plasmodium falciparum, a 19-residue region of the mature parasite-infected erythrocyte surface antigen (MESA) associates with RBC cytoskeleton protein 4.1R; an interaction essential for parasite survival. This region in MESA is adjacent to a host targeting motif found in other malaria parasite proteins exported to the membrane skeleton. To demonstrate function of these motifs in vivo, regions of MESA fused to a reporter were expressed in malaria parasites. Immunochemical analyses confirmed the requirement for both motifs in the trafficking and interaction of MESA with the cytoskeleton and demonstrates their function in vivo.     

红内期恶性疟原虫转运系统研究进展

恶性疟原虫在终末分化的红细胞中发育生长,虽然可以有效的逃避宿主免疫系统的攻击,但同时也面临没有现成的转运系统可供利用等方面的挑战。事实上,红内期疟原虫发展了一套新的转运系统用于其自身蛋白在宿主红细胞中的转运。本文将综述最近几年来红内期恶性疟原虫有关转运信号、蛋白分选和转运等机制方面的最新进展。     

Movement of a falciparum malaria protein through the erythrocyte cytoplasm to the erythrocyte membrane is associated with lysis of the erythrocyte and release of gametes.

Erythrocytes containing mature gametocytes of Plasmodium falciparum circulate in the blood until they are ingested by a mosquito, an event that triggers gametogenesis and lysis of the infected erythrocyte. It was previously shown that a parasite protein (Pf155/RESA) accumulates in the erythrocyte cytoplasm next to the parasitophorous vacuolar membrane (S. Uni, A. Masuda, M. J. Stewart, R. Nussenzweig, and M. Aikawa, Am. J. Trop. Med. Hyg., 36:481-488, 1987). Using a monoclonal antibody to Pf155/RESA and rabbit sera to two different repeat peptides of Pf155/RESA, we have studied the location of Pf155/RESA after induction of gametogenesis. Five minutes after triggering gametogenesis, the parasitophorous membrane no longer surrounded the parasite, bringing the parasite membrane in contact with the erythrocyte cytoplasm. Clear spaces appeared throughout the hemoglobin-rich host cytoplasm; Pf155/RESA was now localized in the cytoplasm directly surrounding the spaces. No membrane existed between the spaces and the erythrocyte cytoplasm. The spaces with surrounding Pf155/RESA protein extended to the erythrocyte membrane. After lysis of the erythrocyte membrane (15 min after triggering gametogenesis), the protein was distributed along the erythrocyte membrane and throughout the space between the gamete and the erythrocyte membrane. The mechanism by which Pf155/RESA remained aggregated around the spaces and its role in erythrocyte lysis are unknown. It is of interest that the parasite appeared to use the same molecule during invasion of erythrocytes and during release of gametes from infected erythrocytes.     

Plasmodium falciparum signal peptidase is regulated by phosphorylation and required for intra-erythrocytic growth

The human malaria parasite Plasmodium falciparum exports a variety of its proteins through its endoplasmic reticulum (ER) based secretory pathway in order to survive in the host erythrocyte. Signal peptidases are membrane-bound endopeptidases and have an important role in the transport and maturation of these parasite proteins. Prokaryotic signal peptidases are indispensable enzymes required for the removal of N-terminal signal peptide from the secretory proteins. Eukaryotic signal peptidases exist as multimeric protein complex in the ER and the catalytic subunit of this complex catalyzes removal of the N-terminal signal peptide from preproteins. All the signal peptidases contain five regions of high-sequence similarity referred to as boxes A-E. Here we report characterization of the catalytic subunit of signal peptidase complex (SPC) from P. falciparum. This protein designated as PfSP21 shows homology with the similar subunit from other sources and contains all the conserved boxes A-E. PfSP21 is able to cleave the peptide substrate containing the signal peptidase cleavage site. PfSP21 is phosphorylated by protein kinase C and its enzyme activity was upregulated after this phosphorylation. Immunofluorescence assay studies revealed that PfSP21 is localized in the ER of P. falciparum. PfSP21 dsRNA specifically inhibits the growth of P. falciparum in culture and this inhibition is most likely due to the decrease in the amount of endogenous PfSP21 protein. These studies demonstrate the characterization of a functional subunit of SPC from P. falciparum and should make an important contribution in our better understanding of the complex process of protein translocation in the parasite.     

The C-terminal domain of the Plasmodium falciparum acyl-CoA synthetases PfACS1 and PfACS3 functions as ligand for ankyrin

Infection of erythrocytes by the malaria parasite Plasmodium falciparum results in the export of several parasite proteins into the erythrocyte cytoplasm establishing novel interactions between host and parasite proteins, particularly at the membrane skeleton that modifies both the structural and functional properties of the red cell. We present evidences that two members of the P. falciparum acyl-CoA synthetase (PfACS) family, responsible for the activation of long-chain fatty acids by thio-esterification with CoA, are transported in vesicle-like structures toward the host erythrocyte cytoplasm where they interact with the cytoskeletal protein ankyrin. Carboxyl-terminal domain (CTD) overlay studies indicated that PfACS1 and PfACS3 bind to the 78-kDa fragment of ankyrin corresponding with its spectrin-binding domain. Co-immunoprecipitation of ankyrin and PfACS1/3 indicates that at least a fraction of these proteins are physically associated in the infected erythrocytes and provide evidence for a novel specific interaction which suggest that such a binding may bring these enzymes closer to the host erythrocyte membrane where exogenous fatty acids are available.     

Maurer's clefts--a novel secretory organelle?

During intra-erythrocytic development, the human malarial parasite Plasmodium falciparum extensively remodels its adopted cellular home by exporting proteins beyond the confines of its own plasma membrane, but is, however, faced with a major problem: the lack of an endogenous protein trafficking machinery within the host erythrocyte. Thus, in order to export proteins the parasite has to install its own protein export system within the host erythrocyte. A growing body of evidence suggests that Maurer's clefts, parasite-derived membranous structures in the cytosol of the host cell, are a crucial component of this protein sorting and trafficking machinery. In this review we summarize our current understanding of the ultra-structure of Maurer's clefts and their role in protein transport process.     

LANCL1, an erythrocyte protein recruited to the Maurer's clefts during Plasmodium falciparum development

As the malarial parasite Plasmodium falciparum develops inside the erythrocyte, parasite-derived membrane structures, referred to as Maurer's clefts, play an important role in parasite development by delivering parasite proteins to the host cell surface, and participating in the assembly of the cytoadherence complex, essential for the pathogenesis of cerebral malaria. PfSBP1 is an integral membrane protein of the clefts, interacting with an erythrocyte cytosolic protein, identified here as the human Lantibiotic synthetase component C-like protein LANCL1. LANCL1 is specifically recruited to the surface of Maurer's clefts in P. falciparum mature blood stages. We propose that the interaction between PfSBP1 and LANCL1 is central for late steps of the parasite development to prevent premature rupture of the red blood cell membrane.     

A conserved domain targets exported PHISTb family proteins to the periphery of Plasmodium infected erythrocytes

During blood-stage infection, malaria parasites export numerous proteins to the host erythrocyte. The Poly-Helical Interspersed Sub-Telomeric (PHIST) proteins are an exported family that share a common ‘PRESAN’ domain, and include numerous members in Plasmodium falciparum, Plasmodium vivax and Plasmodium knowlesi. In P. falciparum, PHIST proteins have been implicated in protein trafficking and intercellular communication. A number of PHIST proteins are essential for parasite survival. Here, we identify nine members of the PHISTb sub-class of PHIST proteins, including one protein known to be essential for parasite survival, that localise to the erythrocyte periphery. These proteins have solubility characteristics consistent with their association with the erythrocyte cytoskeleton. Together, an extended PRESAN domain, comprising the PRESAN domain and preceding sequence, form a novel targeting-domain that is sufficient to localise a protein to the erythrocyte periphery. We validate the role of this domain in RESA, thus identifying a cytoskeleton-binding domain in RESA that functions independently of its known spectrin-binding domain. Our data suggest that some PHISTb proteins may act as cross-linkers of the erythrocyte cytoskeleton. We also show for the first time that peripherally-localised PHISTb proteins are encoded in genomes of P. knowlesi and vivax indicating a conserved role for the extended PRESAN domain of these proteins in targeting to the erythrocyte periphery.     

Characterisation of a delta-COP homologue in the malaria parasite,Plasmodium falciparum

The mature human erythrocyte is a simple haemoglobin-containing cell with no internal organelles and no protein synthesis machinery. The malaria parasite invades this cell and develops inside a parasitophorous vacuole (PV). The parasite exports proteins into the erythrocyte to bring about extensive remodelling of its adopted cellular home. Plasmodial homologues of two COPII proteins, PfSar1p and PfSec31p, are exported to the erythrocyte cytosol where they appear to play a role in the trafficking of proteins across the erythrocyte cytoplasm [Eur. J. Cell Biol. 78 (1999) 453; J. Cell Sci. 114 (2001) 3377]. We have now characterised a homologue of the COPI protein, delta-COP. A recombinant protein corresponding to 90% of the Pfdelta-COP sequence was used to raise antibodies. The affinity-purified antiserum recognised a protein with an apparent M(r) of 58 x 10(3) on Western blots of malaria parasite-infected erythrocytes but not on blots of uninfected erythrocytes. Pfdelta-COP was shown to be largely insoluble in non-ionic detergent, possibly suggesting cytoskeletal attachment. Confocal immunofluorescence microscopy of parasitised erythrocytes was used to show that, in contrast to the COPII proteins, Pfdelta-COP is located entirely within the parasite. The location of Pfdelta-COP partly overlaps that of the endoplasmic reticulum (ER)-located protein, PfERC, and partly that of the trans-Golgi-associated protein, PfRab6. Treatment of ring-stage plasmodium-infected erythrocytes with brefeldin A (BFA) inhibited development of the ER structure within the parasite cytosol and prevented the trafficking of the P. falciparum erythrocyte membrane protein-1, PfEMP1, to the erythrocyte cytosol. The Pfdelta-COP and PfSec31p populations each appear to be associated with the restricted ER structure in brefeldin-treated rings. When more mature stage parasites were treated with BFA, erythrocyte cytosol-located populations of parasite proteins were not reorganised, however, the overlap between Pfdelta-COP and PfERC in parasite cytosol was more complete suggesting a possible redistribution of the Golgi compartment into the ER. These data support the suggestion that both COPI and COPII proteins are involved in the trafficking of proteins within the parasite cytoplasm. However, only COPII proteins are exported to the erythrocyte cytosol to establish a vesicle-mediated protein trafficking pathway to the erythrocyte membrane.     

N-terminal processing of proteins exported by malaria parasites

Malaria parasites utilize a short N-terminal amino acid motif termed the Plasmodium export element (PEXEL) to export an array of proteins to the host erythrocyte during blood stage infection. Using immunoaffinity chromatography and mass spectrometry, insight into this signal-mediated trafficking mechanism was gained by discovering that the PEXEL motif is cleaved and N-acetylated. PfHRPII and PfEMP2 are two soluble proteins exported by Plasmodium falciparum that were demonstrated to undergo PEXEL cleavage and N-acetylation, thus indicating that this N-terminal processing may be general to many exported soluble proteins. It was established that PEXEL processing occurs upstream of the brefeldin A-sensitive trafficking step in the P. falciparum secretory pathway, therefore cleavage and N-acetylation of the PEXEL motif occurs in the endoplasmic reticulum (ER) of the parasite. Furthermore, it was shown that the recognition of the processed N-terminus of exported proteins within the parasitophorous vacuole may be crucial for protein transport to the host erythrocyte. It appears that the PEXEL may be defined as a novel ER peptidase cleavage site and a classical N-acetyltransferase substrate sequence.     

Recognition of variant Rifin antigens by human antibodies induced during natural Plasmodium falciparum infections

Antibodies from individuals living in areas where malaria is endemic are known to react with parasite-derived erythrocyte surface proteins. The major immunogenic and clonally variant surface antigen described to date is Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP-1), which is encoded by members of the multicopy var gene family. We report here that rifin proteins (RIF proteins), belonging to the largest known family of variable infected erythrocyte surface-expressed proteins, are also naturally immunogenic. Recombinant RIF proteins were used to analyze the antibody responses of individuals living in an area of intense malaria transmission. Elevated anti-rifin antibody levels were detected in the majority of the adult population tested, whereas the prevalence of such antibodies was much lower in malaria-exposed children. Despite the high degree of diversity between rif sequences and the high gene copy number, it appears that P. falciparum infections can induce antibodies that cross-react with several variant rifin molecules in many parasite isolates in a given community, and the immune response is most likely to be stable over time in a hyperendemic area. The protein was localized by fluorescence microscopy on the membrane of ring and young trophozoite-infected erythrocytes with antibodies from human immune sera with specificities for recombinant RIF protein.     

Functional analysis of Plasmodium falciparum apical membrane antigen 1 utilizing interspecies domains

Plasmodium falciparum apical membrane antigen 1 (AMA1) is a leading malaria vaccine candidate whose function has not been unequivocally defined. Partial complementation of function can be achieved by exchanging the AMA1 of P. falciparum (PfAMA1) with that of P. chabaudi (PcAMA1). In this study, parasites expressing chimeric AMA1 proteins were created to identify domains of PfAMA1 critical in erythrocyte invasion and which are important immune targets. We report that specific chimeric AMA1 proteins containing domains I to III from PfAMA1 and PcAMA1 were able to complement PfAMA1 function in erythrocyte invasion. We demonstrate that domain III does not contain dominant epitope targets of antibodies raised against Escherichia coli expressed and refolded PfAMA1 ectodomain. Furthermore, we generated a parasite line in which the N-terminal pro region of PfAMA1 does not undergo proteolytic cleavage and show that its removal is necessary for PfAMA1 function.     

A novel Plasmodium falciparum ring stage protein, REX, is located in Maurer's clefts

The asexual stages of the malaria parasite Plasmodium falciparum develop inside erythrocytes of the human host. Erythrocytes are highly specialized cells lacking organelles and trafficking machinery. The parasite must therefore establish its own transport system to export proteins and waste and import nutrients. A number of parasite-derived structures, implicated in trafficking, appear in the infected red blood cell at the late ring stage. We have identified a novel gene transcribed in ring stage parasites coding for a protein designated the ring exported protein, REX. REX is located in a red cell modification known as the Maurer's clefts, which are parasite induced structures implicated in trafficking of parasite proteins to the red blood cell surface. REX contains predicted coiled-coil regions and a region with similarity to a domain in vesicle-tethering proteins. REX persists in Maurer's clefts throughout the infection of the erythrocyte, where it may play a role in the biogenesis and/or function of this organelle.     

A gene-family encoding small exported proteins is conserved across Plasmodium genus

A gene-family, named sep, encoding small exported proteins conserved across Plasmodium species has been identified. SEP proteins (13-16 kDa) contain a predicted signal peptide at the NH(2)-terminus, an internal hydrophobic region and a polymorphic, low-complexity region at the carboxy-terminus. One member of the Plasmodium berghei family, Pbsep1, encodes an integral membrane protein expressed along the entire erythrocytic cycle. Immunolocalisation results indicated that PbSEP1 is targeted to the membrane of the parasitophorous vacuole up to the early phases of schizogony, while, in late schizonts, it re-locates in structures within the syncitium. After erythrocyte rupture, PbSEP1 is still detectable in free merozoites thus suggesting its involvement in the early steps of parasite invasion. Seven members of the sep-family in Plasmodium falciparum have been identified. Two of them correspond to previously reported gene sequences included in a family of early transcribed membrane proteins (etramp). Structural, functional and phylogenetic features of the sep family, shown in the present work, supercede this previous classification. PfSEP proteins are exported beyond the parasite membrane and translocated, early after invasion, to the host cell compartment in association with vesicle-like structures. Colocalisation results indicated that PfSEP-specific fluorescence overlaps, at the stage of trophozoite, with that of Pf332, a protein associated with Maurer's clefts, membranous structures in the cytosol of parasitised red blood cells, most probably involved in trafficking of parasite proteins. The specific signals necessary to direct SEP proteins to the vacuolar membrane in P. berghei or to the host cell compartment in P. falciparum remain to be determined.     

Features of mimicry in Plasmodium falciparum

In this study, we aim to show, by comparing the amino-acid sequences of several antigens of Plasmodium falciparum with those of some proteins manufactured by the host immune system, that the parasite appears to have a remarkable capacity for mimicry. This would help greatly to reduce the efficiency of the immune response during its asexual cycle. Indeed, the major sporozoite surface protein (CSP) has amino-acid sequences in common with interleukin 1; homologies between Pf 11, expressed at the trophozoite stage, and thymosin alpha 1 may be found. Lastly, RESA present at the schizont stage and protein S liberated when the parasitized erythrocyte is lysed, have sequences in common, respectively with thymosin alpha 1 and thymulin.     

The N-terminal extension of the P. falciparum GBP130 signal peptide is irrelevant for signal sequence function

The malaria parasite P. falciparum exports a large number of proteins to its host cell, the mature human erythrocyte. Although the function of the majority of these proteins is not well understood, many exported proteins appear to play a role in modification of the erythrocyte following invasion. Protein export to the erythrocyte is a secretory process that begins with entry to the endoplasmic reticulum. For most exported proteins, this step is mediated by hydrophobic signal peptides found towards the N-terminal end of proteins. The signal peptides present on P. falciparum exported proteins often differ in length from those found in other systems, and generally contain a highly extended N-terminal region. Here we have investigated the function of these extended N-terminal regions, using the exported parasite protein GBP130 as a model. Surprisingly, several deletions of the extended N-terminal regions of the GBP130 signal peptide have no effect on the ability of the signal peptide to direct a fluorescent reporter to the secretory pathway. Addition of the same N-terminal extension to a canonical signal peptide does not affect transport of either soluble or membrane proteins to their correct respective subcellular localisations. Finally, we show that extended signal peptides are able to complement canonical signal peptides in driving protein traffic to the apicoplast of the parasite, and are also functional in a mammalian cell system. Our study is the first detailed analysis of an extended P. falciparum signal peptide and suggests that N-terminal extensions of exported Plasmodium falciparum proteins are not required for entry to the secretory system, and are likely to be involved in other, so far unknown, processes.     

MESA is a Plasmodium falciparum phosphoprotein associated with the erythrocyte membrane skeleton

The mature-parasite-infected erythrocyte surface antigen (MESA) of Plasmodium falciparum is an antigenically variable, high molecular weight protein of trophozoites and schizonts that is located at the erythrocyte surface membrane. It is first synthesized at the late ring stage and continues to be synthesized until late schizogony. MESA cannot be detected on the external surface of erythrocytes infected by trophozoites and early schizonts but is located at the internal surface in association with the erythrocyte membrane skeleton. The degree of association with the membrane skeleton varies among parasite lines, being greater in knobby parasite lines. MESA is phosphorylated and is present in a similar location to another phosphoprotein, the ring-infected erythrocyte surface antigen (RESA). However, it differs from RESA in being detected at a later stage of asexual development of the parasite.