Cloned DNA fragment specifying major outer membrane protein a in Escherichia coli K-12.

Plasmid pMC44 is a recombinant plasmid that contains a 2-megadalton EcoRI fragment of Escherichia coli K-12 DNA joined to the cloning vehicle, pSC101. The polypeptides specified by plasmid pMC44 were identified and compared with those specified by pSC101 to determine those that are unique to pMC44. Three polypeptides specified by plasmid pMC44 were localized in the cell envelope fraction of minicells: a Sarkosyl-insoluble outer membrane polypeptide (designated M2), specified by the cloned 2-megadalton DNA fragment, and two Sarkosyl-soluble membrane polypeptides specified by the cloning plasmid pSC101. Bacteria containing plasmid pMC44 synthesized quantities of M2 approximately equal to the most abundant E. coli K-12 outer membrane protein. Evidence is presented that outer membrane polypeptide M2, specified by the recombinant plasmid pMC44, is the normal E. coli outer membrane protein designated protein a by Lugtenberg and 3b by Schnaitman.     

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.     

Expression of cloned cDNA for a major surface antigen of Plasmodium falciparum merozoites

A cDNA library of P. falciparum was constructed. Using size-selected mRNA as a probe several clones were isolated which hybridized to mRNAs larger than 5 kilobases (kb). The cDNA insert of pFC 17, which hybridizes to 5.6-kb mRNA was expressed by fusion to anthranilate synthetase I in a plasmid expression vector. The expressed fusion protein was shown to contain epitopes of a 195-kDa protein which is the precursor to 3 major surface antigens of P. falciparum merozoites.     

Plasmodium vivax: cloning and expression of a major blood-stage surface antigen

Plasmodium vivax is a highly prevalent malaria pathogen of man; the following report is the first to describe the cloning and expression of a major asexual erythrocytic stage antigen of this species. The screening of a genomic DNA expression library with a monoclonal antibody directed against a 200-kDa surface component (Pv200) of the more mature schizonts of P. vivax led to the selection of a recombinant bacterial clone which produced a fusion protein. Mouse and rabbit immune sera raised against the purified fusion protein recognized the 200-kDa parasite antigen on Western blots and reacted with the surface of segmenters by immunofluorescence. Sequencing of the 1.9-kb P. vivax DNA insert coding for this fusion protein revealed a 45-47% homology at the nucleotide level with the P. falciparum gene of a parasite surface antigen, Pf195, which has been shown to be a promising candidate for a malaria vaccine in primates and in man.     

Sialic acid-dependent binding of Plasmodium falciparum merozoite surface antigen, Pf200, to human erythrocytes

Plasmodium falciparum merozoites, the extracellular stage of the erythrocytic cycle of the human malarial parasite, specifically invade human E. The major determinant of that specificity is the sialic acid residues of E glycophorin. In the present study we show that the merozoite surface Ag, Pf200 (m.w. 195,000 to 205,000), of two different isolates of P. falciparum, binds to the surface of human E but not E from other species not invaded by P. falciparum. Pf200 does not bind to neuraminidase-treated E, indicating the interaction is dependent on sialic acid residues. Binding is inhibited by soluble glycophorin and selective mAb against the glycosylated domain of glycophorin, but not by a mAb against the peptide domain of glycophorin. mAb.5B1 previously identified as reacting with Pf 200, blocks binding of the protein to the E. Binding between Pf200 and the E is not high affinity, as Pf200 can be released from the surface by 0.25 M NaCl.     

恶性疟原虫子孢子CS抗原融合基因的表达及其生物活性

采用遗传工程技术获得了含有恶性疟原虫子孢子CS抗原融合基因的重组质粒pMC055－CS的工程菌株,能高效分泌CS抗原的融合蛋白至胞外,可达25mg／L．具有霍乱毒素B亚单位（CT－B）和子孢子CS的抗原性．将纯化的融合蛋白免疫C57纯系小鼠,免疫后抗CT－B抗体滴度可达1：3200～6400,抗CS抗体滴度可达1：320～640．免疫小鼠采用约氏疟子孢子腹腔攻击,保护率达34～45％．     

Characterization of eight excision plasmids of Pseudomonas syringae pv. phaseolicola

Summary Pseudomonas syringae pv. phaseolicola strain LR719 contains a 150 kilobase pair (kb) plasmid pMC7105, stably integrated into its chromosome. Occasionally, single colony isolates of this strain contain an excision plasmid. Eight unique excision plasmids were selected and characterized by BamHI restriction endonuclease and blot hybridization analyses. These plasmids ranged in size from 35 to 270 kb; the largest contained approximately 130 kb of chromosomal DNA sequences. Restriction maps of pMC7105 were developed to deduce the site of integration and to identify the fragments in which recombination occurred to produce each excision plasmid. The eight excision plasmids were arranged into five classes based on the sites where excision occurs. A 20 kb region of pMC7105, which includes BamHI fragment 9 and portions of adjacent fragments, is present in all excision plasmids and thought to contain the origin of replication. The site of integration on pMC7105 maps within BamHI fragment 8. This fragment shows homology with seven other BamHI fragments of pMC7105 and with five chromosomal fragments identified among the excision plasmids. The data strongly suggest that the integration of pMC7105 may have occurred at a repetitive sequence present on the chromosome and on the plasmid.     

A genetic screen for improved plasmid segregation reveals a role for Rep20 in the interaction of Plasmodium falciparum chromosomes

Bacterial plasmids introduced into the human malaria parasite Plasmodium falciparum replicate well but are poorly segregated during mitosis. In this paper, we screened a random P.falciparum genomic library in order to identify sequences that overcome this segregation defect. Using this approach, we selected for parasites that harbor a unique 21 bp repeat sequence known as Rep20. Rep20 is one of six different repeats found in the subtelomeric regions of all P.falciparum chromosomes but which is not found in other eukaryotes or in other plasmodia. Using a number of approaches, we demonstrate that Rep20 sequences lead to dramatically improved episomal maintenance by promoting plasmid segregation between daughter merozoites. We show that Rep20(+), but not Rep20(-), plasmids co-localize with terminal chromosomal clusters, indicating that Rep20 mediates plasmid tethering to chromosomes, a mechanism that explains the improved segregation phenotype. This study implicates a direct role for Rep20 in the physical association of chromosome ends, which is a process that facilitates the generation of diversity in the terminally located P.falciparum virulence genes.     

Passive immunoprotection of Plasmodium falciparum-infected mice designates the CyRPA as candidate malaria vaccine antigen

An effective malaria vaccine could prove to be the most cost-effective and efficacious means of preventing severe disease and death from malaria. In an endeavor to identify novel vaccine targets, we tested predicted Plasmodium falciparum open reading frames for proteins that elicit parasite-inhibitory Abs. This has led to the identification of the cysteine-rich protective Ag (CyRPA). CyRPA is a cysteine-rich protein harboring a predicted signal sequence. The stage-specific expression of CyRPA in late schizonts resembles that of proteins known to be involved in merozoite invasion. Immunofluorescence staining localized CyRPA at the apex of merozoites. The entire protein is conserved as shown by sequencing of the CyRPA encoding gene from a diverse range of P. falciparum isolates. CyRPA-specific mAbs substantially inhibited parasite growth in vitro as well as in a P. falciparum animal model based on NOD-scid IL2Rγ(null) mice engrafted with human erythrocytes. In contrast to other P. falciparum mouse models, this system generated very consistent results and evinced a dose-response relationship and therefore represents an unprecedented in vivo model for quantitative comparison of the functional potencies of malaria-specific Abs. Our data suggest a role for CyRPA in erythrocyte invasion by the merozoite. Inhibition of merozoite invasion by CyRPA-specific mAbs in vitro and in vivo renders this protein a promising malaria asexual blood-stage vaccine candidate Ag.     

恶性疟原虫子孢子CS抗原融合基因的克隆

利用381-A型DNA合成仪,参照恶性疟原虫子孢子CS抗原决定簇相应氨基酸的核苷酸序列,设计了CS-Ⅰ和CS-Ⅱ两个片段。以噬菌体M13mp18质粒作为载体,将两片段进行磷酸化、退火、连接和克隆,经过原位杂交,序列分析,获得了(NANP)_(10)重复串联基因的重组质粒M13mp18-CS。再以酶切,从重组质粒中回收(NANP)_(10)次的片段,将其片段基因与CT-B基因融合,最后将融合基因CT-B-CS插入载体PMC055中,成功地得到含有(NANP)_(10)与CT-B基因融合的重组质粒pMC055-CS。     

Reactivity of the human monoclonal antibody 33G2 with repeated sequences of three distinct Plasmodium falciparum antigens

The human mAb 33G2 has high capacity to inhibit in vitro invasion of erythrocytes by Plasmodium falciparum merozoites and, thus, is of special interest with regard to protective immunity against the parasite. In order to obtain more information about asexual blood stage Ag of P. falciparum that are seen by this antibody, material from synchronized P. falciparum cultures was studied by immunofluorescence, immunoelectron microscopy, and immunoblotting. Reactivity was mainly confined to the membrane of infected erythrocytes. Soon after merozoite invasion the antibody stained the erythrocyte membrane. This membrane-associated staining faded during intracellular development of the parasites. Beginning about 18 h after invasion, a dotted pattern appeared which increased in strength with time and persisted to schizont rupture. Pf155/RESA was the major Ag recognized in immunoblots of parasites collected throughout the entire erythrocytic cycle, although other polypeptides also bound the antibody. Among these was a 260-kDa polypeptide found in late trophozoites and schizonts. The specificity of the antibody was analyzed with synthetic peptides corresponding to repeated sequences in the P. falciparum Ag Pf155/RESA, Pf11.1, and Ag332. Synthetic peptides related to Ag332 were the most efficient inhibitors of antibody binding in immunofluorescence studies and cell ELISA. A beta-galactosidase-Ag332 fusion protein was also efficient in reversing reinvasion inhibition caused by 33G2. These results define a family of cross-reactive P. falciparum Ag recognized by mAb 33G2 and suggest that Ag332 was its original target.     

Vaccination against malaria: recent advances and the problems of antigenic diversity and other parasite evasion mechanisms

Due to the complexity of the malaria life cycle and the stage-specificity of immunity, a malaria vaccine will most likely be multicomponent, directed against surface epitopes on sporozoites, infected erythrocytes, merozoites and gametes. The CSP antigen of sporozoites is best understood at the structural and immunochemical level and vaccine trials employing peptides derived from this protein are currently underway. To date, no antigenic diversity of the immunodominant repeat epitope of the CSP protein has been uncovered in natural isolates of P. falciparum, raising optimism for eventual applicability of the laboratory trials to a field vaccine. Numerous surface antigens on merozoites and gametes have been identified with monoclonal antibodies and shown to be potential vaccine targets based on in vitro and in vivo studies with these antibodies. The problem of antigenic diversity and parasite lability seems acute in the asexual blood stages, and perhaps also with transmission-blocking antigens of gametes. Ways must be found to identify invariant surface epitopes that are so critical to parasite survival that in the face of a potentially lethal immune response mutant organisms cannot alter the target epitope and evade destruction.     

Crystal structure of a Fab complex formed with PfMSP1-19, the C-terminal fragment of merozoite surface protein 1 from Plasmodium falciparum: a malaria vaccine candidate

Merozoite surface protein 1 (MSP1) is the major protein component on the surface of the merozoite, the erythrocyte-invasive form of the malaria parasite Plasmodium. Present in all species of Plasmodium, it undergoes two distinct proteolytic maturation steps during the course of merozoite development that are essential for invasion of the erythrocyte. Antibodies specific for the C-terminal maturation product, MSP1-19, can inhibit erythrocyte invasion and parasite growth. This polypeptide is therefore considered to be one of the more promising malaria vaccine candidates. We describe here the crystal structure of recombinant MSP1-19 from P.falciparum (PfMSP1-19), the most virulent species of the parasite in humans, as a complex with the Fab fragment of the monoclonal antibody G17.12. This antibody recognises a discontinuous epitope comprising 13 residues on the first epidermal growth factor (EGF)-like domain of PfMSP1-19. Although G17.12 was raised against the recombinant antigen expressed in an insect cell/baculovirus system, it binds uniformly to the surface of merozoites from the late schizont stage, showing that the cognate epitope is exposed on the naturally occurring MSP1 polypeptide complex. Although the epitope includes residues that have been mapped to regions recognised by invasion-inhibiting antibodies studied by other workers, G17.12 does not inhibit erythrocyte invasion or MSP1 processing.     

Characterization of a high-molecular-weight phosphoprotein synthesized by the human malarial parasite Plasmodium falciparum

During its intra-erythrocytic cycle, Plasmodium falciparum synthesizes a protein of apparent Mr 250,000-300,000. Its precise size is dependent on the P. falciparum isolate examined. This protein contains phosphate covalently bound to one or more serine residues and hence is termed PP300. Monoclonal antibody, McAb4-1F, binds to PP300 on immunoblots of protein extracts from all parasite isolates tested, both those exhibiting and those lacking the knob phenotype. Using McAb4-1F, the polypeptide was shown to be physically associated with the plasma membrane in a membrane-isolation procedure. However, in an indirect immunofluorescence assay the McAb appeared to bind to antigen associated with the erythrocyte plasma membrane in parasitized cells. However, it reacted only to fixed, not unfixed, parasitized erythrocytes indicating that the epitope is not normally exposed to extracellular antibodies. Clone 29-2 was isolated by a McAb4-1F immunoscreen of a P. falciparum complementary DNA (cDNA) expression library created in pUC8. Rat anti-clone serum which was raised to the purified protein encoded by the lacZ-29-2 fusion in pUC8 reacted with PP300 in immunoblots of parasite antigen. In Southern-blot analyses of parasite DNA digested with EcoRI, HindIII, or EcoRV, the 29-2 DNA insert hybridized to more than one fragment even though the insert lacked internal sites for these enzymes. In addition, hybridization studies were conducted using two oligodeoxy-nucleotides which were constructed based on the sequence of a cDNA clone which encoded part of a similar high-molecular-weight P. falciparum protein [Coppel et al., Mol. Biochem. Parasitol. 20 (1986) 265-277]. Analysis of these results indicates that the two cDNA sequences are parts of the same gene or a family of related genes.     

Phage-displayed peptides bind to the malarial protein apical membrane antigen-1 and inhibit the merozoite invasion of host erythrocytes

Apical membrane antigen-1 (AMA1) is a transmembrane protein present on the surface of merozoites that is thought to be involved in the process of parasite invasion of host erythrocytes. Although it is the target of a natural immune response that can inhibit invasion, little is known about the molecular mechanisms by which AMA1 facilitates the invasion process. In an attempt to identify peptides that specifically interact with and block the function of AMA1, a random peptide library displayed on the surface of filamentous phage was panned on recombinant AMA1 from Plasmodium falciparum. Three peptides with affinity for AMA1 were isolated, and characterization of their fine binding specificities indicated that they bind to a similar region on the surface of AMA1. One of these peptides was found to be a potent inhibitor of the invasion of P. falciparum merozoites into human erythrocytes. We propose that this peptide blocks interaction between AMA1 and a ligand on the erythrocyte surface that is involved in a critical step in malarial invasion. The identification and characterization of these peptide inhibitors now permit an evaluation of the essential requirements that are necessary for efficient neutralization of merozoite invasion by blocking AMA1 function.     

Genetic diversity and natural selection at the domain I of apical membrane antigen-1 (AMA-1) of Plasmodium falciparum in isolates from Iran

The apical membrane antigen-1 (AMA-1) of Plasmodium falciparum is a prime malaria asexual blood-stage vaccine candidate. Antigenic variation is one of the main obstacles in the development of a universal effective malaria vaccine. The extracellular region of P. falciparum AMA-1 (PfAMA-1) consists of three domains (I-III), of which the domain I is the most diverse region of this antigen. The objective of our study was to investigate and analyze the extent of genetic diversity and the effectiveness of natural selection at the AMA-1 domain I of P. falciparum in isolates from Iran. A fragment of ama-1 gene spanning domain I was amplified by nested PCR from 48 P. falciparum isolates collected from two major malaria endemic areas of Iran during 2009 to August 2010 and sequenced. Genetic polymorphism and statistical analyses were performed using DnaSP and MEGA software packages. Analysis of intrapopulation diversity revealed relatively high nucleotide and haplotype diversity at the PfAMA-1 domain I of Iranian isolates. Neutrality tests provided strong evidence of positive natural selection acting on the sequenced gene region. The findings also demonstrated that, in addition to natural selection, intragenic recombination may contribute to the diversity observed at the domain I. The results obtained will have significant implications in the design and the development of an AMA-1-based vaccine against falciparum malaria.     

cDNA cloning and structure of mouse putative Ah receptor.

Mouse cDNA clones for a putative Ah receptor have been isolated from a cDNA library of mRNA from Hepa-1 cells by an oligonucleotide probe produced by PCR with a pair of primers which was synthesized according to the reported N-terminal sequence of 26 amino acids. The cDNA clones encode a polypeptide of 805 amino acids with a helix-loop-helix motif and with some similarity to a certain region designated PAS of Drosophila Per and Sim, and human Arnt protein. Cotransfection of an expression vector of the Ah receptor with a reporter plasmid pMC6.3k consisting of CYP1A1 promoter and CAT structural gene into CV-1 cells enhanced the CAT expression in response to added 3-methylcholanthrene.     

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.