Merozoite surface protein-1 (MSP-1, also referred to as P195, PMMSA or MSA 1) is one of the most studied of all malaria proteins. The protein is found in all malaria species investigated and structural studies on the gene indicate that parts of the molecule are well-conserved. Studies on Plasmodium falciparum have shown that the protein is in a processed form on the merozoite surface, a result of proteolytic cleavage of the large precursor molecule. Recent studies have identified some of these cleavage sites. During invasion of the new red cell most of the MSP1 molecule is shed from the parasite surface except for a small C-terminal fragment which can be detected in ring stages. Analysis of the structure of this fragment suggests that it contains two growth factor-like domains that may have a functional role.
The 19kDa, C-terminal fragment of the major surface protein of Plasmodium falciparum (PfMSP1(19)) is a candidate for inclusion in a subunit malaria vaccine. In this study, we show that PfMSP1(19)-specific antibodies, affinity purified from malaria-immune human serum, can: (i) compete with invasion-inhibitory monoclonal antibodies for binding to PfMSP1(19) and (ii) mediate inhibition of parasite growth in vitro, in the absence of complement and mononuclear cells, at physiological antibody concentrations (100 micrograms/ml). Parasites expressing either the Kl or 3D7 allele of PfMSP1(19) were equally susceptible to inhibition of merozoite invasion, indicating that the target epitopes of inhibitory antibodies are conserved or cross-reactive. These studies suggest that vaccines designed to induce antibodies to PfMSP1(19) may protect against the high levels of malaria parasitaemia which are associated with clinical disease.
SummaryCalcium-dependent protein kinases play a pivotal role in calcium signalling in plants and some protozoa, including the malaria parasites. They are found in various subcellular locations, suggesting an involvement in multiple signal transduction pathways. Recently, Plasmodium falciparum calcium-dependent protein kinase 1 (PfCDPK1) has been found in the membrane and organelle fraction of the parasite. The kinase contains three motifs for membrane binding at its Nterminus, a consensus sequence for myristoylation, a putative palmitoylation site and a basic motif. Endogenous PfCDPK1 and the in vitro translated kinase were both shown to be myristoylated. The supposed membrane attachment function of the basic cluster was experimentally verified and shown to participate together with N -myristoylation in membrane anchoring of the kinase. Using immunogold electron microscopy, the protein was detected in the parasitophorous vacuole and the tubovesicular system of the parasite. Mutagenesis of the predicted acylated residues and the basic motif confirmed that dual acylation and the basic cluster are required for correct targeting of Aequorea victoria green fluorescent protein to the parasitophorous vacuole, suggesting that PfCDPK1 as the leishmanial hydrophilic acylated surface protein B is a representative of a novel class of proteins whose export is dependent on a 'non-classical' pathway involving N -myristoylation/palmitoylation.
The major merozoite surface protein of Plasmodium falciparum (PfMSP1) is a candidate antigen for a malaria vaccine. A 19-kDa C-terminal processing product of PfMSP1 (PfMSP1 19) is composed of two domains sharing a cysteine-rich motif with epidermal growth factor (EGF) and is the target of monoclonal antibodies which block erythrocyte invasion in vitro. We have evaluated human antibody responses to PfMSP1 19 by using recombinant proteins representing the EGF motifs encoded by the two main alleles of the MSP1 gene. We find that both EGF motifs are antigenic but that only 10 to 20% of malaria-exposed individuals have serum antibodies that recognized either of the motifs. When both EGF motifs were expressed together as a single protein, they were recognized by more than 40% of sera from malaria-exposed individuals. Major epitopes recognized by human antibodies are dependent upon the correct tertiary structure of the protein and are cross-reactive between the different allelic sequences of PfMSP1 19. This suggests that antibodies induced by vaccination with one or the other allelic forms of the protein could recognize all strains of P. falciparum. Immunoglobulin G (IgG) subclass-specific enzyme immunoassays indicate that PfMSP1 19 antibodies are predominantly of the IgG1 subclass.
In areas where Plasmodium falciparum is endemic, immunoglobulin G is acquired by the fetus in utero, mainly during the third trimester of pregnancy. The potential protective effect of transferred anti-P. falciparum maternal antibodies was examined in a longitudinal study of 100 infants from birth to 1 year of age. The probability of acquiring a P. falciparum infection and developing an episode of clinical malaria was determined in relation to the P. falciparum-specific antibody level of the infant at birth against P. falciparum schizont antigen or recombinant merozoite surface protein MSP1 19 antigen. The risk of acquiring an episode of clinical malaria increased from birth to 6 months of age, after which it decreased. The overall prevalence of P. falciparum parasitemia was highest (48.9%) in the 6-month-old infants. The age-specific hematocrit value showed the lowest mean value (30.2) from 6 to 9 months, and the spleen rate was the highest (69.8%) at the same age. There was a lower risk of developing an episode of clinical malaria during the first year of life in the infants with high levels of anti-MSP1 19 antibodies at birth. The level of maternally derived overall anti-schizont antigen antibodies did not seem to play a role in the relative risk of developing malaria infection or disease during the first year of life, though the level of specific anti-MSP1 19 antibodies may be associated with protection.
Plasmodium falciparum, a unicellular parasite that causes human malaria, infects erythrocytes where it develops within a vacuole. The vacuolar membrane separates the parasite from the erythrocyte cytosol. Some secreted parasite proteins remain inside the vacuole, and others are transported across the vacuolar membrane. To identify the protein sequences responsible for this distribution we investigated the suitability of the green fluorescent protein and luciferase as reporters in transiently transfected parasites. Because of the higher sensitivity of the enzymatic assay, luciferase was quantified 3 days after transfection, whereas reliable detection of green fluorescent protein required prolonged drug selection. Luciferase was confined to the parasite cytosol in subcellular fractions of infected erythrocytes. When parasites were transfected with a hybrid gene coding for the cleavable N-terminal signal peptide of a secreted parasite protein fused to luciferase, the reporter protein was secreted. It was recovered with the vacuolar content and the erythrocyte cytosol. The results suggest that no specific protein sequences are required for translocation across the vacuolar membrane. The high local concentration of luciferase within the vacuole argues against free diffusion, and thus transport into the erythrocyte cytosol must involve a ratelimiting step.Plasmodium falciparum, the parasite that causes the most severe form of malaria, spends part of its life cycle in human erythrocytes. Here it resides within the so-called parasitophorous vacuole, which is bound by the parasitophorous vacuolar membrane (PVM).1 The vacuole constitutes a separate compartment in the infected red blood cell (iRBC) that is distinct from the cytosol of the parasite and from the cytosol of the erythrocyte, respectively (1). Most proteins secreted from P. falciparum are not released into an extracellular space but are transported to various destinations within the iRBC: the parasitophorous vacuole or the erythrocyte cytosol. Membranebound proteins are found in the PVM and erythrocyte plasma membrane (2, 3). It is completely unknown which information within a polypeptide chain determines whether a protein is transported across the PVM. Recently we described experimental evidence for a transport pathway that involves the release of secreted parasite proteins into the vacuolar space and translocation across the PVM in a subsequent step (4). This model infers that a sorting mechanism must operate within the vacuole that discriminates between vacuolar resident proteins and proteins destined for a location beyond the PVM (5). Sorting could involve two different principles: the retention of vacuolar proteins or, alternatively, the recognition of protein signals that mediate translocation across the PVM.A widely used experimental approach for the identification of protein targeting and sorting signals in eukaryotic cells is the fusion of putative signal sequences to reporter proteins and their subsequent localization in the transfected cell. Although...
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