Functional characterisation of sexual stage specific proteins in Plasmodium falciparum

The various stages of the malaria parasites in the vertebrate host and in the mosquito vector offer numerous candidates for vaccine and drug development. However, the biological complexity of the parasites and the interaction with the immune system of the host continue to frustrate all such efforts thus far. While most of the targets for drug and vaccine design have focused on the asexual stages, the sexual stages of the parasite are critical for transmission and maintenance of parasites among susceptible vertebrate hosts. Sexual stage parasites undergo a series of morphological and biochemical changes during their development, accompanied by a co-ordinated cascade of a distinct expression pattern of sexual stage specific proteins. Mechanisms underlying the developmental switch from asexual parasite to sexual parasite still remain elusive. Methods that can break the malaria transmission cycle thus occupy a central place in the overall malaria control strategies. This paper provides a review of genes expressed in sexually differentiated Plasmodium. In the past few years, a molecular approach based on targeted gene disruption has revealed fascinating biological roles for many of the sexual stage gene products. In addition, we will briefly discuss other functional genomic approaches employed to study not only sexual but also other aspects of host-parasite biology.     

An integrated model of Plasmodium falciparum dynamics

The within-host and between-host dynamics of malaria are linked in myriad ways, but most obviously by gametocytes, the parasite blood forms transmissible from human to mosquito. Gametocyte dynamics depend on those of non-transmissible blood forms, which stimulate immune responses, impeding transmission as well as within-host parasite densities. These dynamics can, in turn, influence antigenic diversity and recombination between genetically distinct parasites. Here, we embed a differential-equation model of parasite-immune system interactions within each of the individual humans represented in a discrete-event model of Plasmodium falciparum transmission, and examine the effects of human population turnover, parasite antigenic diversity, recombination, and gametocyte production on the dynamics of malaria. Our results indicate that the local persistence of P. falciparum increases with turnover in the human population and antigenic diversity in the parasite, particularly in combination, and that antigenic diversity arising from meiotic recombination in the parasite has complex differential effects on the persistence of founder and progeny genotypes. We also find that reductions in the duration of individual human infectivity to mosquitoes, even if universal, produce population-level effects only if near-absolute, and that, in competition, the persistence and prevalence of parasite genotypes with gametocyte production concordant with data exceed those of genotypes with higher gametocyte production. This new, integrated approach provides a framework for investigating relationships between pathogen dynamics within an individual host and pathogen dynamics within interacting host and vector populations.     

Isolation and functional characterization of a dynamin-like gene from Plasmodium falciparum

A novel dynamin-like GTPase gene, Pfdyn1, was cloned from an asexual stage cDNA library of Plasmodium falciparum Dd2 strain. Pfdyn1 contains a highly conserved N-terminal tripartite GTPase domain, a coiled-coil region, and a C-terminal 129 aa unknown function domain. Like yeast Vps1p, it lacks pleckstrin homology domain and proline-rich region. Western blot analysis showed that Pfdyn1 is a Triton X-100 insoluble protein expressed only in the mature sub-stage. Morphological studies indicated that Pfdyn1 is partly co-localized with PfGRP, a known ER-resident protein, and localizes diffusely with several membrane structures and a 60-100 nm vesicle both inside and on surface of the parasites and also in the cytoplasm of infected erythrocytes. The dsRNA originated by C-terminus fragment of Pfdyn1 inhibits markedly the growth of P. falciparum parasite at the erythrocyte stage. Those data showed that Pfdyn1 is a conservative, membrane related protein and plays an essential role for the survival of Plasmodium parasite.     

Examination of a novel head-stalk protein family in Giardia lamblia characterised by the pairing of ankyrin repeats and coiled-coil domains

The intestinal pathogen Giardia lamblia possesses several unusual organelle features, including two equivalent nuclei, no mitochondria or peroxisomes, and a developmentally regulated rough endoplasmic reticulum and Golgi. Giardia also possesses a number of complex and unique cytoskeleton structures that dictate cell shape, motility and attachment. Our investigations of cytoskeletal proteins have revealed the presence of a new protein family. Proteins in this family contain both ankyrin repeats and coiled-coil domains; although these are common protein motifs, their pairing is unique, thus establishing a new class of head-stalk proteins. Examination of the G. lamblia genome shows evidence for at least 18 genes coding for proteins with a series of ankyrin repeats followed by a lengthy coiled-coil domain and at least an additional 14 genes coding for proteins with a prominent coiled-coil domain flanked by two series of ankyrin repeats. We have examined one of these proteins, Giardia Axoneme Associated Protein (GASP-180), in detail. GASP-180 is a 180 kDa protein containing five ankyrin repeats in a 200 amino acid N-terminal domain separated by a short spacer from an approximately 1375 amino acid coiled-coil domain. Using anti-peptide antibodies raised against a unique 20 amino acid sequence found at the C-terminus, we have determined that GASP-180 is present in cytoskeleton extractions of the parasite and localises to the proximal base of the anterior flagellar axonemes. The combination of the localisation and the structural and functional motifs of GASP-180 make it a strong candidate to participate in control of flagellar activity.     

The Plasmodium vivax rhoptry-associated protein 1

Rhoptries are cellular organelles localized at the apical pole of apicomplexan parasites. Their content is rich in lipids and proteins that are released during target cell invasion. Plasmodium falciparum rhoptry-associated protein 1 (RAP1) has been the most widely studied among this parasite species' rhoptry proteins and is considered to be a good anti-malarial vaccine candidate since it displays little polymorphism and induces antibodies in infected humans. Monoclonal antibodies directed against RAP1 are also able to inhibit target cell invasion in vitro and protection against P. falciparum experimental challenge is induced when non-human primates are immunized with this protein expressed in its recombinant form. This study describes identifying and characterizing RAP1 in Plasmodium vivax, the most widespread parasite species causing malaria in humans, producing more than 80 million infections yearly, mainly in Asia and Latin America. This new protein is encoded by a two-exon gene, is proteolytically processed in a similar manner to its falciparum homologue and, as observed by microscopy, the immunofluorescence pattern displayed is suggestive of its rhoptry localization. Further studies evaluating P. vivax RAP1 protective efficacy in non-human primates should be carried out taking into account the relevance that its P. falciparum homologue has as an anti-malarial vaccine candidate.     

Cyclosporin-binding proteins of Plasmodium falciparum

A number of cyclosporins, including certain non-immunosuppressive ones, are potent inhibitors of the intraerythrocytic growth of the human malarial parasite Plasmodium falciparum. The major cyclosporin-binding proteins of P. falciparum were investigated by affinity chromatography on cyclosporin-Affigel followed by sodium dodecyl sulphate-polyacrylamide gel electrophoresis, Western blotting, and peptide mass fingerprinting. The two bands obtained on gels were shown to correspond to cyclophilins, PfCyP-19A (formerly PfCyP-19) and PfCyP-19B, whose genes had been characterised previously. PfCyP-19B was an abundant protein of intraerythrocytic P. falciparum (up to 0.5% of parasite protein) that was present in the highest amounts in schizont-stage parasites. Unexpectedly, given its apparent signal sequence, it was located primarily in the cytosol of the parasite. The peptidyl-prolyl cis-trans isomerase activity of recombinant PfCyP-19B had the same profile of susceptibility to cyclosporin derivatives as the bulk isomerase activity of crude P. falciparum extracts. The binding of cyclosporins to cyclophilins may be relevant to the mechanism of action of the drug in the parasite.     

Identifying and characterising the Plasmodium falciparum merozoite surface protein 10 Plasmodium vivax homologue

Plasmodium vivax malaria is one of the most prevalent parasitic diseases in Asia and Latin-America. The difficulty of maintaining this parasite culture in vitro has hampered identifying and characterising proteins implied in merozoite invasion of red blood cells. We have been able to identify an open reading frame in P. vivax encoding the Plasmodium falciparum merozoite surface protein 10 homologous protein using the partial sequences from this parasite's genome reported during 2004. This new protein contains 479 amino-acids, two epidermal growth factor-like domains, hydrophobic regions at the N- and C-termini, being compatible with a signal peptide and a glycosylphosphatidylinositol anchor site, respectively. The protein is expressed during the parasite's asexual stage and is recognised by polyclonal sera in parasite lysate using Western blot. P. vivax-infected patients' sera highly recognised recombinant protein by ELISA.     

The Plasmodium falciparum heat shock protein 40, Pfj4, associates with heat shock protein 70 and shows similar heat induction and localisation patterns

Human cerebral malaria is caused by the protozoan parasite Plasmodium falciparum, which establishes itself within erythrocytes. The normal body temperature in the human host could constitute a possible source of heat stress to the parasite. Molecular chaperones belonging to the heat shock protein (Hsp) class are thought to be important for parasite subsistence in the host cell, as the expression of some members of this family has been reported to increase upon heat shock. In this paper we investigated the possible functions of the P. falciparum heat shock protein DnaJ homologue Pfj4, a type II Hsp40 protein. We analysed the ability of Pfj4 to functionally replace Escherichia coli Hsp40 proteins in a dnaJ cbpA mutant strain. Western analysis on cellular fractions of P. falciparum-infected erythrocytes revealed that Pfj4 expression increased upon heat shock. Localisation studies using immunofluorescence and immuno-electron microscopy suggested that Pfj4 and P. falciparum Hsp70, PfHsp70-1, were both localised to the parasites nucleus and cytoplasm. In some cases, Pfj4 was also detected in the erythrocyte cytoplasm of infected erythrocytes. Immunoprecipitation studies and size exclusion chromatography indicated that Pfj4 and PfHsp70-1 may directly or indirectly interact. Our results suggest a possible involvement of Pfj4 together with PfHsp70-1 in cytoprotection, and therefore, parasite survival inside the erythrocyte.     

Negative selection of Plasmodium falciparum reveals targeted gene deletion by double crossover recombination.

The genome sequence of Plasmodium falciparum, the causative agent of the most severe form of malaria in humans, rapidly approaches completion, but our ability to genetically manipulate this organism remains limited. Chromosomal integration has only been achieved following the prolonged maintenance of circularised episomal plasmids which selects for single crossover recombinants. It has not been possible to construct genetic deletions via double crossover recombination, presumably due to the low frequency of this event. We have used the Herpes simplex virus thymidine kinase gene and the Escherichia coli cytosine deaminase gene for negative selection of P. falciparum. Parasites were transformed with plasmids expressing the thymidine kinase and cytosine deaminase genes by positive selection for the human dihydrofolate reductase gene. Parasites expressing thymidine kinase are susceptible to the pro-drug ganciclovir while those expressing cytosine deaminase are sensitive to 5-fluorocytosine. Parental parasites were inherently resistant to these drugs. A significant 'bystander effect' was evident in cultures with either ganciclovir or 5-fluorocytosine. Positive and negative selection of the thymidine kinase transformants with both ganciclovir and WR99210 resulted in the selection of parasites containing a genetic deletion of the Pfrh3 gene, the first targeted double crossover deletions in P. falciparum. The use of negative selection for gene disruptions via double crossover recombination will dramatically improve our ability to analyse protein function and opens the possibility of using this strategy for a variety of gene deletion and modification experiments in the analysis of this important infectious agent.     

Plasmodium yoelii: experimental evidences for the conserved epitopes between mouse and human malaria parasite, Plasmodium falciparum

Bioinformatic analyses of gene homologues have revealed functionally conserved epitopes between human and rodent malaria parasites. Here, we present experimental evidence for the presence of functionally and antigenically conserved domains between Plasmodium falciparum and Plasmodium yoelii asexual blood-stages. Merozoite released soluble proteins (MRSPs) from both P. falciparum and P. yoelii bound to heterologous mouse or human red blood cells, respectively. The presence of conserved antigenic epitopes between the two species of parasites was evident by the inhibitory effect of antibodies, developed against P. yoelii in convalescent mice, on P. falciparum growth and merozoite reinvasion in vitro. Furthermore, mice immunized with P. falciparum MRSPs were protected from infection by a P. yoelii challenge. These data indicate that different species of Plasmodium contain antigenically conserved interspecies domains, which are immunogenic and, thus constitute a potential novel antigen source for vaccine development and testing using a mouse model.     

The mechanism of erythrocyte invasion by the malarial parasite, Plasmodium falciparum

Plasmodium falciparum is the most virulent causative agent of malaria in man accounting for 80% of all malarial infections and 90% of the one million annual deaths attributed to malaria. P. falciparum is a unicellular, Apicomplexan parasite, that spends part of its lifecycle in the mosquito and part in man and it has evolved a special form of motility that enables it to burrow into animal cells, a process termed “host cell invasion”. The acute, life threatening, phase of malarial infection arises when the merozoite form of the parasite undergoes multiple cycles of red blood cell invasion and rapid proliferation. Here, we discuss the molecular machinery that enables malarial parasites to invade red blood cells and we focus particularly on the ATP-driven acto-myosin motor that powers invasion.     

Cyclin-dependent kinase homologues of Plasmodium falciparum

The intraerythrocytic asexual cycle of the malarial parasite is complex and atypical: during schizogony the parasite undergoes multiple rounds of DNA replication and asynchronous nuclear division without cytokinesis. This cell cycle deviates from the classical eukaryotic cell cycle model where, 'DNA replicates only once per cell cycle'. A clear understanding of the molecular switches that control this unusual developmental cycle would be of great interest, both in terms of fundamental Plasmodium biology and in terms of novel potential drug target identification. In recent years considerable effort has been made to identify the malarial orthologues of the cyclin-dependent kinases, which are key regulators of the orderly progression of the eukaryotic cell cycle. This review focuses on the current state-of-knowledge of Plasmodium falciparum cyclin-dependent kinase-like kinases and their regulators.     

Advancements in transfection technologies for Plasmodium

Malaria is a global problem that affects millions of people annually. A relatively poor understanding of the malaria parasite biology has hindered vaccine and drug development against this disease. Robust methods for genetic analyses in Plasmodium have been lacking due to the difficulties in its genetic manipulation. Introduction of transfection technologies laid the foundation for genetic dissection of Plasmodium and recent years have seen the development of novel tools for genetic manipulation that will help us delineate the intriguing biology of this parasite. This review focuses on such recent advances in transfection technologies for Plasmodium that have improved our ability to carry out more thorough genetic analyses of the biology of the malaria parasite.     

Plasmodium falciparum: growth response to potassium channel blocking compounds

Potassium channels are essential for cell survival and regulate the cell membrane potential and electrochemical gradient. During its lifecycle, Plasmodium falciparum parasites must rapidly adapt to dramatically variant ionic conditions within the mosquito mid-gut, the hepatocyte and red blood cell (RBC) cytosols, and the human circulatory system. To probe the participation of K⁺ channels in parasite viability, growth response assays were performed in which asexual stage P. falciparum parasites were cultured in the presence of various Ca²⁺-activated K⁺ channel blocking compounds. These data describe the novel anti-malarial effects of bicuculline methiodide and tubocurarine chloride and the novel lack of effect of apamine and verruculogen. Taken together, the data herein imply the presence of K⁺ channels, or other parasite-specific targets, in P. falciparum-infected RBCs that are sensitive to blockade with Ca²⁺-activated K⁺ channel blocking compounds.     

Exploring the proteome of Plasmodium

With the entire genomic sequence of several species of Plasmodium soon to be available, researchers are now focusing on methods to study gene and protein expression at the whole organism level. Traditional methods of characterising and identifying large numbers of proteins from a complex protein mixture have relied predominantly on two-dimensional gel electrophoresis combined with N-terminal sequencing or mass spectrometry of individually prepared proteins. New proteomics methods are now available that are based on resolving small peptides derived from complex protein mixtures by high-resolution liquid chromatography and directly identifying them by tandem mass spectrometry (LC/LC/MS/MS) and sophisticated computer search algorithms against whole genome sequence databases. These newer proteomic methods have the potential to accelerate the reproducible identification of large numbers of proteins from various life cycle stages of Plasmodium and may help to better understand parasite biology and lead to the identification of new targets of vaccines and drugs.     

Identifying and characterising the Plasmodium falciparum RhopH3 Plasmodium vivax homologue

Four Plasmodium species cause malaria in humans, Plasmodium falciparum being the most widely studied to date. All Plasmodium species have paired club-shaped organelles towards their apical extreme named rhoptries that contain many lipids and proteins which are released during target cell invasion. P. falciparum RhopH3 is a rhoptry protein triggering important immune responses in patients from endemic regions. It has also been shown that anti-RhopH3 antibodies inhibit in vitro invasion of erythrocytes. Recent immunisation studies in mice with the Plasmodium yoelii and Plasmodium berghei RhopH3 P. falciparum homologue proteins found that they are able to induce protection in murine models. This study described identifying and characterising RhopH3 protein in Plasmodium vivax; it is encoded by a seven exon gene and expressed during the parasite's asexual stage. PvRhopH3 has similar processing to its homologue in P. falciparum and presents a cellular immunolocalisation pattern characteristic of rhoptry proteins.