A naturally occurring gene encoding the major surface antigen precursor p190 of Plasmodium falciparum lacks tripeptide repeats.

Plasmodium falciparum merozoites have variable surface proteins that are processed from a 190-kd precursor protein (p190). The gene encoding p190 exists in two allelic forms and cross-over events occurring mainly near the 5' end, combined with isolate-specific tripeptide repeats, contribute to its antigen diversity. We have sequenced a large portion of the p190 gene from the parasite isolate RO-33 (Ghana). Remarkably, the typical N-terminal tripeptide repeat structure is lacking. Apart from mutations in the variable parts, the gene appears identical to the MAD-20 allele (Papua, New Guinea). Southern blot analysis detects p190 genes similar to RO-33 in other parasite isolates independent of their geographical origin. The lack of p190 repeats in RO-33 eliminates the possibility that they are involved in host cell recognition or integration and restricts their function to immune escape.     

Sequence of a cDNA encoding a small polymorphic histidine- and alanine-rich protein from Plasmodium falciparum.

We describe the expression in Escherichia coli, isolation by immunological screening and complete nucleotide sequence of a cDNA clone from the malaria parasite Plasmodium falciparum. The deduced amino acid sequence contains separate blocks of repetitive hexapeptide and pentapeptide sequences and we have confirmed that these represent epitopes by reaction of the corresponding synthetic peptides with human antibodies. As the predicted size is Mr 21,000 and the overall composition is 30% His and 29% Ala, the polypeptide has been termed the small histidine-alanine rich protein (SHARP). This polypeptide is highly polymorphic in different P. falciparum isolates and cross reacts immunologically with a distinct gene product of P. falciparum. Although it is related to the Histidine Rich Protein (HRP) of P. lophurae by virtue of its high His content, it shows no obvious sequence relationship to the HRP outside the repeats.     

Nonpolymorphic regions of p190, a protein of the Plasmodium falciparum erythrocytic stage, contain both T and B cell epitopes

Two conserved regions from the genetically polymorphic p190 molecule of the malaria parasite Plasmodium falciparum have previously been expressed in Escherichia coli as separate polypeptides (190.L and 190.M) or as a single fusion protein (190.N). In the present study we investigated whether human B and T lymphocytes recognize these conserved regions. The more amino-terminal region, 190.L (corresponding to residues 188-363 of the encoded protein sequence) reacted preferentially with sera from donors living in a malaria-endemic area. Also, EBV-transformed B cells, from a healthy donor living in a malaria-mesoendemic area, were fused with a human-mouse hybrid line (SPM4-0), yielding two hybridomas whose products recognized both 190.L and the fusion protein 190.N, but not the 190.M polypeptide. A large number of p190-specific T cell clones were obtained from PBMC of a noninfected donor, after in vitro stimulation with the recombinant fusion protein 190.N. The clones reacted with intact, parasite-derived p190, as well as either 190.L or 190.M. Four clones that recognized the more amino-terminal fragment also responded to infected E. According to these results the more amino-terminal conserved sequences of p190 have the requisites to be immunogenic in humans.     

Conserved sequences flank variable tandem repeats in two S-antigen genes of Plasmodium falciparum

We describe the isolation of two chromosomal DNA fragments from Plasmodium falciparum. These fragments encode the antigenically distinct S antigens of two different P. falciparum isolates, namely FC27 from Papua New Guinea and NF7 from Ghana. The complete nucleotide sequences of both fragments are presented. The fragments are homologous over most of their lengths, including the entire regions flanking the protein coding sequences. Whereas the N- and C-terminal portions of sequences encoding the S antigens are homologous, major portions of the coding sequences are not. The nonhomologous regions are comprised of tandemly repeated sequences, of 33 bp in FC27 and predominantly of 24 bp in NF7. The 33 bp tandem repeats encoded by the FC27 S-antigen gene could not be detected in the NF7 genome. Conversely, the 24 bp tandem repeats encoded by the NF7 S-antigen gene could not be detected in the FC27 genome. The pattern of sequence variation within the repeats of both genes suggests a mechanism for the generation of S-antigen diversity.     

Circumsporozoite Protein Genes of Malaria Parasites (Plasmodium Spp.): Evidence for Positive Selection on Immunogenic Regions

The circumsporozoite (CS) protein is a cell surface protein of the sporozoite, the stage of the life cycle of malaria parasites (Plasmodium spp.) that infects the vertebrate host. Analysis of DNA sequences supports the hypothesis that in Plasmodium falciparum, positive Darwinian selection favors diversity in the T-cell epitopes (peptides presented to T cells by host MHC molecules) of the CS protein. In gene regions encoding T cell epitopes of P. falciparum, the rate of nonsynonymous nucleotide substitution is significantly higher than that of synonymous substitution, whereas this is not true of other gene regions. Furthermore nonsynonymous nucleotide substitutions in these regions cause a change of amino acid residue charge significantly more frequently than expected by chance. By contrast, in Plasmodium cynomolgi, the same regions show no evidence of positive selection, and residue charge is conserved. The CS protein has a central repeat region, which is the target of host antibodies. In P. falciparum, the amino acid sequence of the repeat region is conserved within and between alleles. In P. cynomolgi, on the other hand, there is evidence that positive selection has favored evolution of two different repeat types within a given allele.     

Circumsporozoite protein gene from Plasmodium reichenowi, a chimpanzee malaria parasite evolutionarily related to the human malaria parasite Plasmodium falciparum

We have cloned and sequenced the gene encoding the circumsporozoite (CS) protein of Plasmodium reichenowi a Plasmodium falciparum-like malaria parasite of chimpanzees. Comparison of the two CS proteins reveals both similarities and differences in these two evolutionarily related parasites that have adapted to different hosts. The P. reichenowi CS protein has a new repeat sequence, NVNP, in addition to the P. falciparum-like NANP and NVDP repeats. In the immunodominant TH2R and TH3R regions of the CS protein, the amino acid sequences are similar in both parasite proteins. The differences in the two proteins exist in domains around the conserved regions, Region I and Region II, which are otherwise conserved in the CS proteins of P. falciparum analyzed to date. Studies of parasite protein genes of evolutionarily related malaria parasites, together with other immunologic and biologic characteristics, will help better understand the evolution and host parasite relationship of malaria parasites and may provide a tool for identifying protein determinants for malaria vaccine development.     

A Plasmodium whole-genome synteny map: indels and synteny breakpoints as foci for species-specific genes

Whole-genome comparisons are highly informative regarding genome evolution and can reveal the conservation of genome organization and gene content, gene regulatory elements, and presence of species-specific genes. Initial comparative genome analyses of the human malaria parasite Plasmodium falciparum and rodent malaria parasites (RMPs) revealed a core set of 4,500 Plasmodium orthologs located in the highly syntenic central regions of the chromosomes that sharply defined the boundaries of the variable subtelomeric regions. We used composite RMP contigs, based on partial DNA sequences of three RMPs, to generate a whole-genome synteny map of P. falciparum and the RMPs. The core regions of the 14 chromosomes of P. falciparum and the RMPs are organized in 36 synteny blocks, representing groups of genes that have been stably inherited since these malaria species diverged, but whose relative organization has altered as a result of a predicted minimum of 15 recombination events. P. falciparum-specific genes and gene families are found in the variable subtelomeric regions (575 genes), at synteny breakpoints (42 genes), and as intrasyntenic indels (126 genes). Of the 168 non-subtelomeric P. falciparum genes, including two newly discovered gene families, 68% are predicted to be exported to the surface of the blood stage parasite or infected erythrocyte. Chromosomal rearrangements are implicated in the generation and dispersal of P. falciparum-specific gene families, including one encoding receptor-associated protein kinases. The data show that both synteny breakpoints and intrasyntenic indels can be foci for species-specific genes with a predicted role in host-parasite interactions and suggest that, besides rearrangements in the subtelomeric regions, chromosomal rearrangements may also be involved in the generation of species-specific gene families. A majority of these genes are expressed in blood stages, suggesting that the vertebrate host exerts a greater selective pressure than the mosquito vector, resulting in the acquisition of diversity.     

Variation in the gene encoding a major merozoite surface antigen of the human malaria parasite Plasmodium falciparum.

Plasmodium falciparum merozoites have a variable surface protein of about 195,000 molecular weight which may be involved in strain-specific immunity. We have cloned and sequenced a major portion of the gene encoding this antigen from the CAMP strain and have located sites of preferred mung bean nuclease cleavage around the gene. These sites depend on reaction conditions, but at 40% formamide and 2 units of mung bean nuclease per microgram DNA, the intact gene was excised from the chromosome. Comparison of the CAMP strain gene with the same gene from other strains of P. falciparum by matching available DNA sequences and by DNA hybridization revealed five regions of homology separated by divergent segments. Two of the variable regions encoded three amino acid repeats, predominantly Ser-Gly-Thr and Thr-Glu-Glu. Implications of these findings on the function of the antigen, and possible mechanisms for generation of variants are discussed.     

Positive selection and interallelic recombination at the merozoite surface antigen-1 (MSA-1) locus of Plasmodium falciparum.

DNA sequences of alleles at the merozoite surface antigen-1 (MSA-1) gene locus of the malaria parasite Plasmodium falciparum show evidence of repeated past recombination events between alleles. These include both (1) nonreciprocal recombination events that have homogenized certain gene regions among alleles and (2) reciprocal recombination events that have combined allelic segments with divergent evolutionary histories, thereby enhancing allelic diversity. In three different gene regions, the rate of nonsynonymous nucleotide substitution significantly exceeds that of synonymous nucleotide substitution, implying that positive Darwinian selection has acted to diversify alleles at the amino acid level. The MSA-1 polymorphism seems to be quite ancient; the two major allelic types have been maintained for approximately 35 Myr.     

Differential evidence of natural selection on two leading sporozoite stage malaria vaccine candidate antigens

Experimental malaria vaccines based on two sporozoite stage candidate antigens of Plasmodium falciparum, the circumsporozoite protein (CSP) and thrombospondin-related adhesive protein (TRAP), have undergone clinical trials of efficacy. The relevance of naturally existing polymorphism in these molecules remains unknown. Sequence polymorphism in the genes encoding these antigens was studied in a Gambian population (sample of 48 trap and 44 csp gene sequences) to test for signatures of selection that would result from naturally acquired immunity. Allele frequency distributions were analyzed and compared with data from another population (in Thailand). Patterns of non-synonymous and synonymous polymorphism in P. falciparum and in Plasmodium vivax were compared with divergence from related species. Results indicate that polymorphism in TRAP is under strong selection for amino acid sequence diversity and that allele frequencies are under balancing selection within the Gambian P. falciparum population. There was no such evidence for CSP, calling into question the idea that most polymorphisms in this gene are under immune selection. There was a weak trend for regions known to encode T cell epitopes to have slightly higher indices suggesting balancing selection. Overall, the results predict more allele-specific immunity to TRAP than to CSP and should be considered in design and efficacy testing of vaccine candidates based on these antigens.     

Genomic organization, structure and possible function of histidine-rich proteins of malaria parasites

The current status of histidine-rich proteins in malaria parasites with regard to their genomic organization, protein structure and function is discussed, one of such protein present in an avian malaria parasite Plasmodium lophurae contains about 73% histidine and called as HRP (histidine-rich protein). Among human malaria parasites, in Plasmodium falciparum, only three such proteins have been described, namely knob protein also known as knob associated histidine-rich protein (KP or KAHRP), soluble histidine-alanine rich protein (soluble HARP or PfHRP II) and small histidine-alanine rich protein (SHARP) containing 8, 35 and 30% histidine contents respectively. With rapid emergence of powerful tools in molecular biology the genes of all these histidine-rich proteins have been cloned and sequenced within a short period of time. The genomic organizations of all these proteins are very much similar to each other, in each case the gene contains a signal peptide coding sequence (exon 1) followed by an intron. This intron is followed by the main coding region (exon 2) which has no further intervening sequences. In the main coding region of each gene, the histidine-rich sequences start after 25-30 amino acids from N-terminal end (75-90 nucleotides from 5' in exon 2). All the three histidine-rich proteins of P. falciparum share some homology with the HRP of P. lophurae; they all cross react with anti HRP and incorporate higher amount of exogenous histidine. The relationship between KP and HRP resides in the repeated polyhistidine sequences, (His) 6-9, from the core of the multiple tandem repeats of HRP, whereas, the peptide Ala-His-His is commonly shared by HRP and two other proteins of P. falciparum (soluble HARP and SHARP).(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential selective pressures on the merozoite surface protein 2 locus of Plasmodium falciparum in a low endemic area

195 Plasmodium falciparum merozoite surface protein-2 alleles collected in Tak Province, Thailand, in 1996 and 2006 revealed extremely limited sequence polymorphism except in the variable (V) region, which defines the two allelic families 3D7 and FC27. This pattern is most easily explained by repeated inter-allelic gene conversion events homogenizing alleles outside the V region. Comparison of synonymous and nonsynonymous differences in V regions within allelic families supported the hypothesis that amino acid sequence polymorphism in this region is selectively favored. The pattern of sequence differentiation supported the hypothesis that repeats in the V region have evolved by concerted evolution in the 3D7 family but not in the FC27 family. In the FC27 family two alleles of relatively high frequency were the most common V-region alleles in both 1996 and 2006, while 3D7 alleles constituted a significantly greater proportion of the sequences collected in 2006 (56.1%) than of those collected in 1996 (28.9%). These changes in the frequencies of 3D7 alleles may reflect increased intensity of selection on the P. falciparum population in Thailand as a result of effective control measures that have sharply reduced the incidence of malaria infection.     

Genetic variation and the recent worldwide expansion of Plasmodium falciparum

Plasmodium falciparum, the agent of human malignant malaria, diverged from Plasmodium reichenowi, the chimpanzee parasite, about the time the human and chimpanzee lineages diverged from each other. The absence of synonymous nucleotide variation at ten loci indicates that the world populations of P. falciparum derive most recently from one single strain, or 'cenancestor,' which lived a few thousand years ago. Antigenic genes of P. falciparum (such as Csp, Msp-1, and Msp-2) exhibit numerous polymorphisms that have been estimated to be millions of years old. We have discovered in these antigenic genes short repetitive sequences that distort the alignment of alleles and account for the apparent old age of the polymorphisms. The processes of intragenic recombination that generate the repeats occur at rates about 10(-3) to 10(-2), several orders of magnitude greater than the typical mutational process of nucleotide substitutions. We conclude that the antigenic polymorphisms of P. falciparum are consistent with a recent expansion of the world populations of the parasite from a cenancestor that lived in tropical Africa a few thousand years ago.     

Genetic variation in histidine rich proteins among Indian Plasmodium falciparum population: possible cause of variable sensitivity malaria of rapid diagnostic tests

ABSTRACT: BACKGROUND: Rapid diagnostic tests (RDTs) have revolutionized the diagnosis of malaria. Among the various factors affecting RDTs sensitivity is genetic variation of the antigen used. The genetic variation in PfHRP2 and PfHRP3 proteins was studied among the Indian Plasmodium falciparum isolates. METHODS: One hundred and forty isolates of P. falciparum were collected from six geographical regions of India. Target genes encoding PfHRP2 and PfHRP3 antigens were sequenced to study genetic polymorphism. Minimum detection limit giving a positive rapid diagnostic test was also determined. RESULTS: Extensive variations were observed in amino acid repeat types of PfHRP2 and PfHRP3. PfHRP2 exhibited more polymorphism than PfHRP3. Significant relation was observed between type 2 and type 7 repeats and RDT detection rate as higher number of these repeats showed better sensitivity with RDTs. CONCLUSION: The results provide insights into the genetic diversity of Pfhrp2 and Pfhrp3 genes among Indian P. falciparum population and its relation to RDT sensitivity.     

The Small Ribosomal Subunit RNA Isoforms in Plasmodium Cynomolgi

We report the isolation, characterization and analysis of the small subunit rRNA genes in Plasmodium cynomolgi (Ceylon). As in other Plasmodium species, these genes are present in low copy number, are unlinked and form two types that are distinct in sequence and are expressed stage specifically. The asexually expressed (type A) genes are present in four copies in the Ceylon(-) and in five copies in the Berok(-) strain. Surprisingly, the sexually expressed (type B) gene is present in a single copy. The vast majority of the differences between gene types is confined to the variable regions. The pattern of divergence is different from that observed in Plasmodium berghei or in Plasmodium falciparum. Analysis of the small subunit rRNA sequences of P. cynomolgi, P. berghei and P. falciparum, indicates that the two gene types do not evolve independently but rather interact (through gene conversion or some form of recombination) to such an extent as to erase whatever stage-specific sequence signatures they may have had in the last common ancestor.     

Sequence variation in putative functional domains of the circumsporozoite protein of Plasmodium falciparum. Implications for vaccine development

Sequences of the circumsporozoite protein gene from five isolates of the human malaria parasite Plasmodium falciparum are compared, and the extent of sequence variability within putative functional domains is assessed in terms relating to vaccine efficacy. Nucleotide substitutions were observed outside of the immunodominant domain. Of the substitutions observed outside of the repeat domain, none were silent. The substitutions correlated with biologically functional regions, such as a helper T cell epitope (Th2R) and a region (N1) which may be important in liver invasion. Contrary to previous impressions, the small numbers of amino acid changes in these areas of the protein seem potentially very significant. The immunodominant repeat region displays several characteristics that implicate a rapid evolutionary mechanism, most probably involving recombination. The data supporting this are 1) variable numbers of repeats, 2) a shifting pattern of substitutions among the isolates, and 3) codon bias. The region thus has the potential for very rapid change should an effective anti-repeat vaccine come into use. We conclude that strain variability is significant, that the potential for large scale variation in the repeats is great, and that regions that may be critical for an effective vaccine are polymorphic. Their potential impact on malaria vaccine development must be addressed.     

Major surface antigen p190 of Plasmodium falciparum: detection of common epitopes present in a variety of plasmodia isolates.

Plasmodium falciparum merozoites are covered with polymorphic proteins that are processed from a 190 kd (p190) precursor protein. These are candidates for an antimalarial vaccine. We cloned and expressed a number of DNA fragments, comprising almost the entire p190 gene of the K1 isolate, in Escherichia coli. Pooled human endemic-area sera and rabbit antibodies raised against p190 protein isolated from K1 parasites react with only a limited number of the recombinant proteins. From these studies we could select two antigenic polypeptides containing conserved amino acid stretches of the otherwise highly polymorphic protein. Rabbits and mice injected with the purified recombinant proteins produce antibodies reacting differentially with various isolates of P. falciparum. We obtained antibodies detecting all isolates tested and a monoclonal antibody specific for isolates containing a K1 type allele of the p190 gene.     

Biased amino acid composition in repeat regions of Plasmodium antigens.

Many malarial antigens contain extensive arrays of tandemly repeated short amino acid sequences, and much of the antibody response induced by malaria infections is directed against these repeats. Indeed, it has been hypothesized that these repeats function to elicit a relatively ineffective T-cell-independent antibody response by the host. In order to test this hypothesis, tandem repeats of Plasmodium species were examined for a bias in composition favoring amino acids likely to form epitopes for the antibody. The genome of Plasmodium is very A+T-rich, and nucleotide compositional bias will, in itself, lead to a high proportion of hydrophilic amino acids. When this bias was controlled for, Plasmodium antigens did not show a higher proportion of hydrophilic amino acids than expected, but there was a significant reduction in the proportion of hydrophobic amino acids in the repeats of the antigens. The amino acid composition of the repeats was thus strikingly different from those seen both in the remainder of the antigens and in a sample of Plasmodium falciparum housekeeping genes.     

Plasmodium falciparum: characterization of gene R45 encoding a trophozoite antigen containing a central block of six amino acid repeats.

We describe here an antigen, called R45, expressed by the young trophozoites of Plasmodium falciparum. This antigen contains a block of tandem repeats of six amino acids which are recognized by sera from humans living in endemic areas. The R45 gene is located on chromosome 3. It is present in all strains examined and shows limited size polymorphism. The C-terminal unique region of the protein shows a strong homology with the catalytic domain of the serine protein kinases. Interestingly, the central repeats contain a large number of putative phosphorylation sites. The implications of these features are discussed.     

Cutting edge: a new tool to evaluate human pre-erythrocytic malaria vaccines: rodent parasites bearing a hybrid Plasmodium falciparum circumsporozoite protein

Malaria vaccines containing the Plasmodium falciparum Circumsporozoite protein repeat domain are undergoing human trials. There is no simple method to evaluate the effect of vaccine-induced responses on P. falciparum sporozoite infectivity. Unlike the rodent malaria Plasmodium berghei, P. falciparum sporozoites do not infect common laboratory animals and only develop in vitro in human hepatocyte cultures. We generated a recombinant P. berghei parasite bearing P. falciparum Circumsporozoite protein repeats. These hybrid sporozoites are fully infective in vivo and in vitro. Monoclonal and polyclonal Abs to P. falciparum repeats neutralize hybrid parasite infectivity, and mice immunized with a P. falciparum vaccine are protected against challenge with hybrid sporozoites.