Identification of Plasmodium falciparum family of SNAREs

SNARE proteins function as specificity determinants in all eukaryotic vesicle-mediated transport pathways. Although the intra-erythrocytic parasite Plasmodium falciparum is known to target nuclear-encoded proteins via transport vesicles to several destinations within and beyond its plasma membrane, little is known about the role of SNARE proteins in these unusual trafficking pathways. In this study, we identified and compared the subunit structure of P. falciparum homologues of SNAREs (PfSNAREs) with their complements in mammals, and determined the subcellular localizations of some family members. A comprehensive bioinformatics analysis of the P. falciparum genome revealed 18 SNARE-like proteins that could be classified into five main phylogenetic groups: membrin-like, Bet1-like, VAMP-like, syntaxin5-like, and a P. falciparum-specific syntaxin-like subfamily. Unique to some PfSNARE proteins were presence of atypical amino acid residues at the "0" layer position, presence of up to two transmembrane segments, and frequent occurrence of low-complexity regions. Subcellular distribution of green fluorescence protein (GFP)-tagged P. falciparum SNARE orthologues indicates that PfSyn5p and PfSec22p are partly associated to ER and Golgi compartments, and to other punctuated structures within the parasite plasma membrane. Our data confirms of a conserved SNARE-mediated anterograde transport system in the parasite and argues against any involvement of these two SNAREs in vesicular trafficking within the host cell compartment.     

Identification and characterization of the Plasmodium falciparum RhopH2 ortholog in Plasmodium vivax

Plasmodium vivax is one of the most important human malaria species that is geographically widely endemic and potentially affects a larger number of people than its more notorious cousin, Plasmodium falciparum. During invasion of red blood cells, the parasite requires the intervention of high molecular weight complex rhoptry proteins (RhopH) that are also essential for cytoadherence. PfRhopH2, a member of the RhopH multigene family, has been characterized as being crucial during P. falciparum infection. This study describes identifying and characterizing the pfrhoph2 orthologous gene in P. vivax (hereinafter named pvrhoph2). The PvRhopH2 is a 1,369-amino acid polypeptide encoded by PVX_099930 gene, for which orthologous genes have been identified in other Plasmodium species by bioinformatic approaches. Both P. falciparum and P. vivax genes contain nine introns, and there is a high degree of similarity between the deduced amino acid sequences of the two proteins. Moreover, PvRhopH2 contains a signal peptide at its N-terminus and 12 cysteines predominantly in its C-terminal half. PvRhopH2 is localized in one of the apical organelles of the merozoite, the rhoptry, and the localization pattern is similar to that of PfRhopH2 in P. falciparum. The recombinant PvRhopH2 protein is recognized by serum antibodies of patients naturally exposed to P. vivax, suggesting that PvRhopH2 is immunogenic in humans.     

Identification of a polyclonal B-cell activator in Plasmodium falciparum

Polyclonal B-cell activation and hypergammaglobulinemia are prominent features of human malaria. We report here that Plasmodium falciparum-infected erythrocytes directly adhere to and activate peripheral blood B cells from nonimmune donors. The infected erythrocytes employ the cysteine-rich interdomain region 1alpha (CIDR1alpha) of P. falciparum erythrocyte membrane protein 1 (PfEMP1) to interact with the B cells. Stimulation with recombinant CIDR1alpha induces proliferation, an increase in B-cell size, expression of activation molecules, and secretion of immunoglobulins (immunoglobulin M) and cytokines (tumor necrosis factor alpha and interleukin-6). Furthermore, CIDR1alpha binds to Fab and Fc fragments of human immunoglobulins and to immunoglobulins purified from the sera of different animal species. This binding pattern is similar to that of the polyclonal B-cell activator Staphylococcus aureus protein A. Our findings shed light on the understanding of the molecular basis of polyclonal B-cell activation during malaria infections. The results suggest that the var gene family encoding PfEMP1 has evolved not only to mediate the sequestration of infected erythrocytes but also to manipulate the immune system to enhance the survival of the parasite.     

Identification of putative Plasmodium falciparum mefloquine resistance genes

Mefloquine is an effective antimalarial drug; however, resistant strains of the human malarial pathogen, Plasmodium falciparum, are beginning to arise. The yeast Saccharomyces cerevisiae is sensitive to mefloquine, enabling a screen for P. falciparum genes involved in resistance. Yeast were transformed with a P. falciparum expression library, followed by selection on mefloquine plates and sequencing of plasmids that conferred resistance. We characterized the four genes that conferred the strongest mefloquine-resistant phenotype in yeast. All four (PFD0090c, PFI0195c, PF10_0372 and PF14_0649) are uncharacterized P. falciparum genes from distinct chromosomes (4, 9, 10 and 14, respectively). The mefloquine-resistant phenotype was dependent on induction of the P. falciparum gene and independent of vector context. PFI0195c, which likely encodes a small GTPase activator (GAP), also conferred resistance to cycloheximide and halofantrine in yeast. Immunolocalization of the encoded protein to the Golgi complex in yeast is consistent with potential GAP function. The other three candidate proteins localized to the cytoplasm and plasma membrane (PF14_0649), nuclear envelope/ER (PF10_0372) and Golgi (PFD0090c) of yeast. Analysis of mefloquine-resistant P. falciparum strains and the mefloquine-sensitive strain, W2, by sequencing and semi-quantitative RT-PCR identified no relevant mutations in the resistant strains but showed that PFI0195c was upregulated in two out of three resistant strains and PF14_0649 was upregulated in all resistant strains tested.     

Innate immune recognition of an AT-rich stem-loop DNA motif in the Plasmodium falciparum genome

Although Toll-like receptor 9 (TLR9) has been implicated in cytokine and type I interferon (IFN) production during malaria in humans and mice, the high AT content of the Plasmodium falciparum genome prompted us to examine the possibility that malarial DNA triggered TLR9-independent pathways. Over 6000 ATTTTTAC ("AT-rich") motifs are present in the genome of P.?falciparum, which we show here potently induce type I IFNs. Parasite DNA, parasitized erythrocytes and oligonucleotides containing the AT-rich motif induce type I IFNs via a pathway that did not involve the previously described sensors TLR9, DAI, RNA polymerase-III or IFI16/p204. Rather, AT-rich DNA sensing involved an unknown receptor that coupled to the STING, TBK1 and IRF3-IRF7 signaling pathway. Mice lacking IRF3, IRF7, the kinase TBK1 or the type I IFN receptor were resistant to otherwise lethal cerebral malaria. Collectively, these observations implicate AT-rich DNA sensing via STING, TBK1 and IRF3-IRF7 in P.?falciparum malaria.     

Identification of polymorphic antioxidant response elements in the human genome

Human Molecular Genetics      

Identification of protein complexes in detergent-resistant membranes of Plasmodium falciparum schizonts

Merozoite surface proteins of the human malaria parasite Plasmodium falciparum are involved in initial contact with target erythrocytes, a process that begins a cascade of events required for successful invasion of these cells. In order to identify complexes that may play a role in invasion we purified detergent-resistant membranes (DRMs), known to be enriched in merozoite surface proteins, and used blue native-polyacrylamide gel electrophoresis (BN-PAGE) to isolate high molecular weight complexes for identification by mass spectrometry. Sixty-two proteins were detected and these mostly belonged to expected DRM proteins classes including GPI-anchored, multi-membrane spanning and rhoptry proteins. Proteins from seven known complexes were identified including MSP-1/7, the low (RAP1/2 and RAP1/3), and high (RhopH1/H2/H3) molecular weight rhoptry complexes, and the invasion motor complex (GAP45/GAP50/myosinA). Remarkably, a large proportion of identified spectra were derived from only 4 proteins: the GPI-anchored proteins MSP-1 and Pf92, the putative GPI-anchored protein Pf113 and RAP-1, the core component of the two RAP complexes. Each of these proteins predominated in high molecular weight species suggesting their aggregation in much larger complexes than anticipated. To demonstrate that the procedure had isolated novel complexes we focussed on MSP-1, which predominated as a distinct species at approximately 500 kDa by BN-PAGE, approximately twice its expected size. Chemical cross-linking supports the existence of a stable MSP-1 oligomer of approximately 500 kDa, probably comprising a highly stable homodimeric species. Our observations also suggests that oligomerization of MSP-1 is likely to occur outside the C-terminal epidermal growth factor (EGF)-like domains. Confirmation of MSP-1 oligomerization, together with the isolation of a number of known complexes by BN-PAGE, makes it highly likely that novel interactions occur amongst members of this proteome.     

Identification in Plasmodium falciparum of a protein specifically binding human fibronectins

A fibronectin binding protein (FnBp) was identified in 3H isoleucine labeled P. falciparum schizonts using affinity chromatography on human fibronectin (Fn) coupled to Sepharose 4B. After incubation of Nonidet-P 40 parasite lysate with Fn-Sepharose, elution was performed with SDS-PAGE buffer. Analysis of FnBp by SDS-PAGE demonstrated a major band which migrated with an apparent Mr of 70,000 under reducing conditions. This band was not found when human or rabbit IgG coupled Sepharose 4B were used instead of Fn as control.     

Identification of the Plasmodium chabaudi homologue of merozoite surface proteins 4 and 5 of Plasmodium falciparum

Previous studies of Plasmodium falciparum have identified a region of chromosome 2 in which are clustered three genes for glycosylphosphatidylinositol (GPI)-anchored merozoite surface proteins, MSP2, MSP5, and MSP4, arranged in tandem. MSP4 and MSP5 both encode proteins 272 residues long that contain hydrophobic signal sequences, GPI attachment signals, and a single epidermal growth factor (EGF)-like domain at their carboxyl termini. Nevertheless, the remainder of their protein coding regions are quite dissimilar. The locations and similar structural features of these genes suggest that they have arisen from a gene duplication event. Here we describe the identification of the syntenic region of the genome in the murine malaria parasite, Plasmodium chabaudi adami DS. Only one open reading frame is present in this region, and it encodes a protein with structural features reminiscent of both MSP4 and MSP5, including a single EGF-like domain. Accordingly, the gene has been designated PcMSP4/5. The homologue of the P. falciparum MSP2 gene could not be found in P. chabaudi; however, the amino terminus of the PcMSP4/5 protein shows similarity to that of MSP2. The PcMSP4/5 gene encodes a protein with an apparent molecular mass of 36 kDa, and this protein is detected in mature stages of the parasite. The protein partitions in the detergent-enriched phase after Triton X-114 fractionation and is localized to the surfaces of trophozoites and developing and free merozoites. The PcMSP4/5 gene is transcribed in both ring and trophozoite stages but appears to be spliced in a stage-specific manner such that the central intron is spliced from the mRNA in the parasitic stage in which the protein is expressed.     

Interferon regulatory factor-1 polymorphisms are associated with the control of Plasmodium falciparum infection

We describe the haplotypic structure of the interferon regulatory factor-1 (IRF-1) locus in two West African ethnic groups, Fulani and Mossi, that differ in their susceptibility and immune response to Plasmodium falciparum malaria. Both populations showed significant associations between IRF-1 polymorphisms and carriage of P. falciparum infection, with different patterns of association that may reflect their different haplotypic architecture. Genetic variation at this locus does not therefore account for the Fulani-specific resistance to malaria while it could contribute to parasite clearance's ability in populations living in endemic areas. We then conducted a case-control study of three haplotype-tagging single nucleotide polymorphisms (htSNPs) in 370 hospitalised malaria patients (160 severe and 210 uncomplicated) and 410 healthy population controls, all from the Mossi ethnic group. All three htSNPs showed correlation with blood infection levels in malaria patients, and the rs10065633 polymorphism was associated with severe disease (P=0.02). These findings provide the first evidence of the involvement in malaria susceptibility of a specific locus within the 5q31 region, previously shown to be linked with P. falciparum infection levels.     

Identification of proteins from Plasmodium falciparum that are homologous to reticulocyte binding proteins in Plasmodium vivax

Plasmodium falciparum infections can be fatal, while P. vivax infections usually are not. A possible factor involved in the greater virulence of P. falciparum is that this parasite grows in red blood cells (RBCs) of all maturities whereas P. vivax is restricted to growth in reticulocytes, which represent only approximately 1% of total RBCs in the periphery. Two proteins, expressed at the apical end of the invasive merozoite stage from P. vivax, have been implicated in the targeting of reticulocytes for invasion by this parasite. A search of the P. falciparum genome databases has identified genes that are homologous to the P. vivax rbp-1 and -2 genes. Two of these genes are virtually identical over a large region of the 5' end but are highly divergent at the 3' end. They encode high-molecular-mass proteins of >300 kDa that are expressed in late schizonts and localized to the apical end of the merozoite. To test a potential role in merozoite invasion of RBCs, we analyzed the ability of these proteins to bind to mature RBCs and reticulocytes. No binding to mature RBCs or cell preparations enriched for reticulocytes was detected. We identified a parasite clone that lacks the gene for one of these proteins, showing that the gene is not required for normal in vitro growth. Antibodies to these proteins can inhibit merozoite invasion of RBCs.     

Identification of transmembrane region and orientation of aquaglyceroporin of Plasmodium falciparum

Aquaglyceroporin is a subclass of aquaporin water channels. This protein is also a focused potential drug target for falciparum malaria. However, the knowledge about the structure of this protein is limited. In this communication, the author performed a study to determine the transmembrane region and orientation of aquaglyceroporin of Plasmodium falciparum . According to this study, six transmembrane regions of aquaglyceroporin of P. falciparum can be identified. These regions can be the focused target for future drug development.     

Role of cis-regulatory elements on the ring-specific hrp3 promoter in the human parasite Plasmodium falciparum

Identification of promoter elements responsible for regulation of gene expression has been hampered by the AT richness of P. falciparum intergenic regions. Nested deletions of histidine-rich protein 3 (hrp3) promoter suggested the presence of a multipartite ring-specific element. Linker scanning (LS) of this ring-specific promoter showed that the alteration of several promoter regions decreased the luciferase activity compared to the wild-type configuration, indicating that these regions played a role in gene expression. No homology was observed by comparison of putative regulatory elements of other genes identified by bioinformatic analysis with the hrp3 enhancer, implying a different mechanism of gene regulation by the hrp3 promoter. LS and deletion analysis of the 5′ untranslated region (UTR) of the hrp3 suggested that this region contains elements which interact with promoter elements to regulate gene expression. Analysis of the intron in the UTR region suggested that this region does not play a role in stage specificity in the hrp3 promoter. Together, our results indicate the presence of multiple mechanisms of gene regulation in the parasite.     

Identification of plasma membrane proteins involved in the hepatocyte invasion of Plasmodium falciparum sporozoites

To determine whether surface proteins of hepatocytes might be involved in the sporozoite invasion, plasma membrane proteins were prepared from human livers with CHAPS (3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulphonate) and radiolabelled with 125I (Iodogen; 1,3,4,6-tetrachloro-3 alpha,6 alpha-diphenylglycoluril). The labelled proteins were incubated with Plasmodium falciparum sporozoites and cross-linked with DSP (dithio-bis-succinimidylpropionate). Radiolabelled proteins released by reduction after repeated washing of the sporozoite-complex were separated by SDS-PAGE and autoradiographed. Two human hepatocyte membrane proteins of 20 and 55 kDa were found to be involved in the initial binding of P. falciparum sporozoites. The electrophoretically purified 20- and 55-kDa proteins both inhibited the binding of the corresponding radiolabelled proteins to P. falciparum sporozoites and reduced the invasion of sporozoites in an in vitro assay. We propose that these 20-kDa and 55-kDa proteins represent putative human hepatocyte receptors for P. falciparum sporozoite invasion.     

Identification and purification of glucose phosphate isomerase of Plasmodium falciparum.

The multiplication of malaria parasites within red blood cells is energy dependent. Since these parasites lack a functional tricarboxylic acid cycle, the energy needs of the parasite are met by anaerobic glycolysis of exogenous glucose. High levels of glycolytic enzymes such as fructose-1,6-diphosphate aldolase, phosphoglycerate kinase and pyruvate kinase have been detected in infected erythrocytes. Here we report a 4-9 times increase in glucose phosphate isomerase (GPI) activity of infected erythrocytes over that of normal erythrocytes. This increase is of parasitic origin, as additional enzyme bands were observed in lysates of infected erythrocytes. The expression of GPI parallels parasite maturation and reaches a maximum at the trophozoite/schizont stage. Two distinct but closely related activity patterns consisting of 3-4 GPI isoenzymes (not shown in normal erythrocytes) with neutral to weakly acidic isoelectric points were observed in 6 P. falciparum isolates tested by isoelectric focusing. The purified P. falciparum GPI has an apparent size of 66 kDa. No size variation was observed in the 6 P. falciparum isolates studied. Furthermore, antiserum raised against this protein in BALB/c mice specifically inhibits parasite encoded GPI activity while no effect was observed on host enzyme activity.