A malaria serological map indicating the intersection between parasite antigenic diversity and host antibody repertoires

A malaria vaccine targeting Plasmodium falciparum remains a strategic goal for malaria control. If a polyvalent vaccine is to be developed, its subunits would probably be chosen based on immunogenicity (concentration of elicited antibodies) and associations of selected antigens with protection. We propose an additional possible selection criterion for the inclusion of subunit antigens; that is, coordination between elicited antibodies. For the quantitative estimation of this coordination, we developed a malaria serological map (MSM). Construction of the MSM was based on three categories of variables: (i) malaria antigens, (ii) total IgG and IgG subclasses, (iii) different sources of plasma. To validate the MSM, in this study, we used four malaria antigens (AMA1, MSP2-3D7, MSP2-FC27 and Pf332-C231) and re-grouped the plasma samples into five pairs of subsets based on age, gender, residence, HbAS and malaria morbidity in 9?years. The plasma total IgG and IgG subclasses to the test antigens were measured, and the whole material was used for the MSM construction. Most of the variables in the MSM were previously tested and their associations with malaria morbidity are known. The coordination of response to each antigens pair in the MSM was quantified as the correlation rate (CR?=?overall number of significant correlations/total number of correlations × 100?%). Unexpectedly, the results showed that low CRs were mostly associated with variables linked with malaria protection and the antigen eliciting the least CRs was the one associated with protection. The MSM is, thus, of potential value for vaccine design and understanding of malaria natural immunity.     

Redox sensing and signaling by malaria parasite in vertebrate host

Plasmodium parasites, which is responsible to cause malaria, are also exceedingly receptive to oxidative stress during their intraerythrocytic life stage as they devour haemoglobin inside their food vacuoles and engender toxic haem moieties and reactive oxygen species (ROS). Other than, several studies suggest that the generation of reactive oxygen and nitrogen species (ROS and RNS) associated with oxidative stress, plays a decisive role in the ripeness of systemic complications caused by malaria. Malaria infection provokes the generation of hydroxyl radicals (OH^?), which most probably is the main reason for the induction of oxidative stress and apoptosis. In this study, it has been described to understand how redox molecules and NO carry out their diverse functions in both parasites and host. It is very important to understand the chemical reactions that produce those outcomes and how its regulation carried out by parasite during erythrocytic phase.

     

A stretch-activated anion channel is up-regulated by the malaria parasite plasmodium falciparum

A recent study on malaria-infected human red blood cells (RBCs) has shown induced ion channel activity in the host cell membrane, but the questions of whether they are host- or parasite-derived and their molecular nature have not been resolved. Here we report a comparison of a malaria-induced anion channel with an endogenous anion channel in Plasmodium falciparum -infected human RBCs. Ion channel activity was measured using the whole-cell, cell-attached and excised inside-out configurations of the patch-clamp method. Parasitised RBCs were cultured in vitro , using co-cultured uninfected RBCs as controls. Unstimulated uninfected RBCs possessed negligible numbers of active anion channels. However, anion channels could be activated in the presence of protein kinase A (PKA) and ATP in the pipette solution or by membrane deformation. These channels displayed linear conductance (∼15 pS), were blocked by known anion channel inhibitors and showed the permeability sequence I⁻ > Br⁻ > Cl⁻. In addition, in less than 5 % of excised patches, an outwardly rectifying anion channel (∼80 pS, outward conductance) was spontaneously active. The host membrane of malaria-infected RBCs possessed spontaneously active anion channel activity, with identical conductances, pharmacology and selectivity to the linear conductance channel measured in stimulated uninfected RBCs. Furthermore, the channels measured in malaria-infected RBCs were shown to have a low open-state probability ( P _o) at positive potentials, which explains the inward rectification of membrane conductance observed when using the whole-cell configuration. The data are consistent with the presence of two endogenous anion channels in human RBCs, of which one (the linear conductance channel) is up-regulated by the malaria parasite P. falciparum .     

Structural and functional homology between duck and chicken interferon-gamma

The Duck interferon gamma (DuIFN-gamma) cDNA was cloned from a phytohaemaglutinin-stimulated duck spleen cDNA library screened using a chicken IFN-gamma (ChIFN-gamma) cDNA probe. The DuIFN-gamma cDNA is 1392 nt long and shows 99% and 80% sequence identity with another cloned DuIFN-gamma cDNA, and with ChIFN-gamma cDNA, respectively. The cDNA contains a 495 bp ORF that encodes a putative 164 amino acid (AA) protein that shares 67% identity with ChIFN-gamma, but only 30-35% identity with mammalian IFN-gamma. The predicted three-dimensional (3D) structures of DuIFN-gamma and ChIFN-gamma are similar when analysed by comparative protein modelling. Culture supernatant collected from COS cells transfected with DuIFN-gamma cDNA was able to activate nitrite secretion from a chicken macrophage cell line (HD11) in a dose-dependent fashion. This activity could not be neutralised by an anti-ChIFN-gamma monoclonal antibody (Mab 85) that was able to neutralise the activity of ChIFN-gamma. Recombinant DuIFN-gamma (rDuIFN-gamma) protein was expressed in E. coli as an N-terminally His-tagged protein and was purified on a nickel affinity column. The eluted protein, which was detected as a approximately 18 kDa band with a purity of >90%, was also detected by Western blot using the anti-ChIFN-gamma monoclonal antibody (Mab 9.1). The rDuIFN-gamma was shown to activate nitrite secretion by HD11 cells in a dose-dependent fashion with a specific activity that was approximately 16-fold lower than a rChIFN-gamma control. Two rabbit antisera raised against rDuIFN-gamma were able to neutralise COS cell-expressed DuIFN-gamma activity; one of these also neutralised ChIFN-gamma activity. These findings indicate that DuIFN-gamma shares structural and functional identity with ChIFN-gamma, which is consistent with our previous results which demonstrated cross reactivity with other lymphokines from the two species.     

Interactions between malaria parasites and the host immune system

Malaria remains one of the greatest impediments to development in many tropical regions of the world. Understanding host immune responses to malaria parasites is crucial for the effective design and implementation of new vaccines and drugs. Recent research has seen the identification of the first pattern recognition receptor (TLR9) on dendritic cells for a defined product of malaria infection (hemozoin). In addition, progress has been made in understanding the role of dendritic cell subsets in malaria, and how they promote specific components of the host immune response. Potentially important advances in vaccine design have also been made by inserting a Plasmodium sporozoite epitope into the yellow fever vaccine 17D, as well as using a whole, live-attenuated sporozoite vaccine.     

The Plasmodium liver-stage parasitophorous vacuole: A front-line of communication between parasite and host

The intracellular development and differentiation of the Plasmodium parasite in the host liver is a prerequisite for the actual onset of malaria disease pathology. Since liver-stage infection is clinically silent and can be completely eliminated by sterilizing immune responses, it is a promising target for urgently needed innovative antimalarial drugs and/or vaccines. Discovered more than 65 years ago, these stages remain poorly understood regarding their molecular repertoire and interaction with their host cells in comparison to the pathogenic erythrocytic stages. The differentiating and replicative intrahepatic parasite resides in a membranous compartment called the parasitophorous vacuole, separating it from the host-cell cytoplasm. Here we outline seminal work that contributed to our present understanding of the fundamental dynamic cellular processes of the intrahepatic malarial parasite with both specific host-cell factors and compartments.     

A heat shock-like protein from the human malaria parasite plasmodium falciparum induces autoantibodies

The humoral immune response to a 72-kDa heat shock-like protein of Plasmodium falciparum has been analyzed using mouse monoclonal antibodies (mAb) and human immune sera. Three regions of the molecule containing B cell epitopes were identified by screening a sublibrary encoding the COOH-terminal half of the antigen with the mAb. One B cell epitope mapped to a region poorly conserved between the parasite 72-kDa polypeptide and mammalian heat-shock proteins (Hsp 70). Another mAb, G10C9, reacted with an amino acid region that has a high degree of homology with mouse (87.5%) and human (81.2%) Hsp 70. Both mouse and human cells were recognized by this mAb when analyzed by indirect immunofluorescence and by two-dimensional immunoblots. Sera from humans infected with malaria also recognized the human Hsp 70. Thus, our results indicate that autoantibodies directed against host Hsp 70 can be induced by the homologous parasite protein.     

Acid extrusion from the intraerythrocytic malaria parasite is not via a Na(+)/H(+) exchanger

The intraerythrocytic malaria parasite, Plasmodium falciparum maintains an intracellular pH (pH(i)) of around 7.3. If subjected to an experimentally imposed acidification the parasite extrudes H(+), thereby undergoing a pH(i) recovery. In a recent study, Bennett et al. [Bennett TN, Patel J, Ferdig MT, Roepe PD. P. falciparum Na(+)/H(+) exchanger activity and quinine resistance. Mol Biochem Parasitol 2007;153:48-58] used the H(+) ionophore nigericin, in conjunction with an acidic medium, to acidify the parasite cytosol, and then used bovine serum albumin (BSA) to scavenge the nigericin from the parasite membrane. The ensuing Na(+)-dependent pH(i) recovery, seen following an increase in the extracellular pH, was attributed to a plasma membrane Na(+)/H(+) exchanger. This is at odds with previous reports that the primary H(+) extrusion mechanism in the parasite is a plasma membrane V-type H(+)-ATPase. Here we present evidence that the Na(+)-dependent efflux of H(+) from parasites acidified using nigericin/BSA is attributable to Na(+)/H(+) exchange via residual nigericin remaining in the parasite plasma membrane, rather than to endogenous transporter activity.     

Serum containing tumor necrosis factor is cytotoxic for the human malaria parasite Plasmodium falciparum.

Sera (BCG-lipopolysaccharide [LPS] serum) were obtained from mice infected with Mycobacterium bovis BCG 2 h after intravenous administration of bacterial endotoxin (LPS). Varying concentrations of sera were added to cultures of Plasmodium falciparum-infected human erythrocytes; parasite viability was assessed by hypoxanthine incorporation after 4 days in culture. At concentrations of 1 to 3%, cultures treated with BCG-LPS serum showed a two- to threefold increase in hypoxanthine incorporation; at higher concentrations (4 to 8%), hypoxanthine incorporation fell to 2 to 5% of that in control cultures. Concurrent assays with control sera (from untreated mice or mice treated with BCG or LPS alone) caused some stimulation but no inhibition at up to 8% concentration. Examination of cultures treated with BCG-LPS serum showed morphological, deterioration of parasites within erythrocytes. The presence of tumor necrosis factor in the BCG-LPS serum was confirmed by using a standard L-cell cytotoxicity assay. In addition, rabbit antiserum against partially purified tumor necrosis factor protected intraerythrocytic forms of P. falciparum from the toxic effects of BCG-LPS serum. These data suggest that the factor in BCG-LPS serum that is toxic to P. falciparum in human erythrocytes is antigenically similar or identical to tumor necrosis factor. This nonantibody mediator of killing may play a role in human malaria.     

Extensive proteolytic processing of the malaria parasite merozoite surface protein 7 during biosynthesis and parasite release from erythrocytes

In Plasmodium falciparum, merozoite surface protein 7 (MSP7) was originally identified as a 22kDa protein on the merozoite surface and associated with the MSP1 complex shed during erythrocyte invasion. MSP7 is synthesised in schizonts as a 351-amino acid precursor that undergoes proteolytic processing. During biosynthesis the MSP1 and MSP7 precursors form a complex that is targeted to the surface of developing merozoites. In the sequential proteolytic processing of MSP7, N- and C-terminal 20 and 33kDa products of primary processing, MSP7(20) and MSP7(33) are formed and MSP7(33) remains bound to full length MSP1. Later in the mature schizont, MSP7(20) disappears from the merozoite surface and on merozoite release MSP7(33) undergoes a secondary cleavage yielding the 22kDa MSP7(22) associated with MSP1. In free merozoites, both MSP7(22) and a further cleaved product, MSP7(19) present only in some parasite lines, were detected; these two derivatives are shed as part of the protein complex with MSP1 fragments during erythrocyte invasion. Primary processing of MSP7 is brefeldin A-sensitive while secondary processing is resistant to both calcium chelators and serine protease inhibitors. Primary processing of MSP7 occurs prior to that of MSP1 in a post-Golgi compartment, whereas the secondary cleavage occurs on the surface of the developing merozoite, possibly at the time of MSP1 primary processing and well before the secondary processing of MSP1.     

Epitope homology between bacterial heat shock protein and self-proteins in the host cell.

Mouse monoclonal antibodies (MAbs) showing distinct reactivity against the 60-kilodalton (kDa) antigen heat shock protein of Yersinia enterocolitica, designated cross-reacting protein antigen (CRPA), have previously been established. The reactivities of these MAbs (5C3 and 3C8) against mouse and human host cells were studied by Western blotting and flow cytometric analysis. The results indicated that epitopes on the bacterial 60-kDa heat shock protein are present on various molecules in mouse spleen cells and human B cells. An epitope recognized by MAb 5C3 was expressed on the mouse and human host cell surface, and an epitope recognized by MAb 3C8 was also expressed on the human host cell surface.     

Human malaria parasite orotate phosphoribosyltransferase: functional expression, characterization of kinetic reaction mechanism and inhibition profile

Plasmodium falciparum, the causative agent of the most lethal form of human malaria, relies on de novo pyrimidine biosynthesis. A gene encoding orotate phosphoribosyltransferase (OPRT), the fifth enzyme of the de novo pathway catalyzing formation of orotidine 5'-monophosphate (OMP) and pyrophosphate (PP(i)) from 5-phosphoribosyl-1-pyrophosphate (PRPP) and orotate, was identified from P. falciparum (pfOPRT). The deduced amino acid sequence for pfOPRT was compared with OPRTs from other organisms and found to be most similar to that of Escherichia coli. The catalytic residues and consensus sequences for substrate binding in the enzyme were conserved among other organisms. The pfOPRT was exceptional in that it contained a unique insertion of 20 amino acids and an amino-terminal extension of 66 amino acids, making the longest amino acid sequence (281 amino acids with a predicted molecular mass of 33kDa). The cDNA of the pfOPRT gene was cloned, sequenced and functionally expressed in soluble form. The recombinant pfOPRT was purified from the E. coli lysate by two steps, nickel metal-affinity and gel-filtration chromatography. From 1l E. coli culture, 1.2-1.5mg of pure pfOPRT was obtained. SDS-PAGE revealed that the pfOPRT had a molecular mass of 33kDa and analytical gel-filtration chromatography showed that the enzyme activity eluted at approximately 67kDa. Using dimethyl suberimidate to cross-link neighboring subunits of the pfOPRT, it was confirmed that the native enzyme exists in a dimeric form. The steady state kinetics of initial velocity and product inhibition studies indicate that the enzyme pfOPRT follows a random sequential kinetic mechanism. Compounds aimed at the pfOPRT nexus may act against the parasite through at least two mechanisms: by directly inhibiting the enzyme activity, or be processed to an inhibitor of thymidylate synthase. This study provides a working system with which to investigate new antimalarial agents targeted against P. falciparum OPRT.     

The war between the malaria parasite and the immune system: immunity,immunoregulation and immunopathology

Throughout history malaria has proved to be a significant threat to human health. Between 300 and 500 million clinical cases occur each year worldwide, approximately 2 million of which are fatal, primarily in children. The vast majority of malaria‐related deaths are due to infection with Plasmodium falciparum; P. vivax causes severe febrile illness but is rarely fatal. Following repeated exposure to infection, people living in malaria endemic areas gradually acquire mechanisms to limit the inflammatory response to the parasite that causes the acute febrile symptoms (clinical immunity) as well as mechanisms to kill parasites or inhibit parasite replication (antiparasite immunity). Children, who have yet to develop protective immune mechanisms are thus at greater risk of clinical malaria, severe disease and death than adults. However, two epidemiological observations indicate that this is, perhaps, an oversimplified model. Firstly, cerebral malaria – a common manifestation of severe malaria – typically occurs in children who have already acquired a significant degree of antimalarial immunity, as evidenced by lower mean parasite densities and resistance to severe anaemia. One potential explanation is that cerebral malaria is, in part, an immune‐mediated disease in which immunological priming occurs during first infection, eventually leading to immunopathology on re‐infection. Secondly, among travelers from nonendemic areas, severe malaria is more common – and death rates are higher – in adults than in children. If severe malaria is an immune‐mediated disease, what might be priming the immune system of adults from nonendemic areas to cause immunopathology during their first malaria infection, and how do adults from endemic areas avoid severe immunopathology? In this review we consider the role of innate and adaptive immune responses in terms of (i) protection from clinical malaria (ii) their potential role in immunopathology and (iii) the subsequent development of clinical immunity. We conclude by proposing a model of antimalarial immunity which integrates both the immunological and epidemiological data collected to date.     

Enzymes of purine and pyrimidine metabolism from the human malaria parasite, Plasmodium falciparum

Plasmodium falciparum trophozoites were isolated by mechanical rupture of infected human erythrocytes followed by a series of differential centrifugation steps. After lysis with sonication, the 100 000 x g supernatant of parasites and uninfected host cells was used to determine the specific activities of a number of enzymes involved in purine and pyrimidine metabolism. P. falciparum possessed the purine salvage enzymes: adenosine deaminase, purine nucleoside phosphorylase, hypoxanthine-guanine phosphoribosyltransferase (PRTase), xanthine PRTase, adenine PRTase, adenosine kinase. The last two enzymes, however, were present at much lower activity levels. Hypoxanthine was converted (presumably via IMP) into adenine and guanine nucleotides only in the presence both of supernatant and membrane fractions of P. falciparum. Two enzymes involved in the de novo synthesis of pyrimidines, orotic acid PRTase, and orotidine 5'-phosphate decarboxylase, were present in parasite extracts as were the enzymes for pyrimidine nucleotide phosphorylation: UMP-CMP kinase, dTMP kinase, nucleoside diphosphate kinase. Xanthine oxidase, CTP synthetase, cytidine deaminase and several kinases for the salvage of pyrimidine nucleosides were not detected in the parasites. Both phosphoribosyl pyrophosphate synthetase and uracil PRTase were present but at low activity levels. Human erythrocytes displayed similar but not identical enzyme patterns. Enzyme specific activities, however, were generally much lower than those of the corresponding parasite enzymes.