S-antigen localization in the erythrocytic stages of Plasmodium falciparum

Localization of the S-antigen of Plasmodium falciparum isolate FCQ27/PNG, from Papua New Guinea, was studied by post-embedding immunoelectron microscopy using affinity-purified rabbit antibodies raised against the repeat region of the antigen. Labelling was found in the parasitophorous vacuole (PV) space of early to late schizonts and in PV-related vesicles within the erythrocyte cytoplasm of schizont-infected cells. Other subcellular structures within the erythrocyte cytoplasm were not labelled. After breakdown of the PV membrane, label was observed around the merozoites, consistent with mixing of the PV contents and erythrocyte cytoplasm. The antigen was not found in uninfected cells, ring stages, trophozoites or associated with free merozoites. Antibodies to FCQ27/PNG S-antigen did not react with other isolates tested, whereas rabbit antibodies to the Palo Alto/Wellcome S-antigen repeat region reacted with isolates FCR3 and ItG2F6 but not with FCQ27/PNG.     

Plasmodium falciparum: identification and localization of a knob protein antigen expressed by a cDNA clone

Differential screening of cDNA libraries constructed from knobby and predominantly knobless Plasmodium falciparum isolates, identified the sequence SD17. Chromosome blotting experiments have shown that this sequence, which is located on chromosome 2 of most isolates, was deleted in the cloned parasite line E12 of the FCQ27/PNG isolate. Here we show that erythrocytes infected with the SD17-containing cloned line D10 have typical knob structures on their surfaces, whereas those infected with the line E12 lack knobs. An expression clone was constructed from SD17 and used to affinity purify antibodies from the sera of individuals living in areas of Papua New Guinea where malaria is endemic. The antibodies reacted in immunoblotting experiments with a single polypeptide that varied in Mr from 85,000 to 105,000 among different isolates. The antigen was not expressed in the knobless clone E12. Postembedding immunoelectron microscopy showed localization of the antigen over the knobs of FC27 and two other isolates, largely on the cytoplasmic side. We conclude that the parasite antigen corresponding to clone SD17 is a knob protein.     

The expression of Plasmodium falciparum bloodstage antigens in Escherichia coli

A library of cDNA clones expressing proteins of the asexual blood stages of a Papua New Guinean isolate of Plasmodium falciparum (isolate FCQ27/PNG (FC27] was constructed in the bacteriophage vector lambda gt11-Amp3. In an in situ colony immunoassay, human serum was used to identify colonies producing natural immunogens. Sera from donors of defined clinical status, or reactive to a defined subset of natural immunogens were used to identify clones of particular interest (for example, clones reacting with convalescent but not with acute serum or clones expressing the isolate specific S-antigen of FC27). Antisera raised by immunizing mice and rabbits with cloned antigens were used to characterize the P. falciparum proteins corresponding to the antigen-positive clones. Nucleotide sequence analysis of an antigen found on the surface of cells infected with ring stage parasites revealed an unusual sequence coding for eight, four and three amino acid repeats rich in acidic amino acids. The discussion centres on the use of cloned antigens as tools for the analysis of the host-protective immune response and selection of candidate vaccine molecules.     

Plasmodium vivax: exoerythrocytic schizonts recognized by monoclonal antibodies against blood-stage schizonts

Exoerythrocytic parasites of Plasmodium vivax grown in human hepatoma cells in vitro were probed with monoclonal antibodies raised against other stages of P. vivax. Monoclonal antibodies specific for four independent antigens on blood-stage merozoites all reacted with exoerythrocytic schizonts and merozoites by immunostaining. The characteristic staining pattern of each monoclonal antibody was similar on both blood- and exoerythrocytic-stage parasites and appeared only in mature schizont segmenters. In contrast, a monoclonal antibody specific for the caveolar-vesicle complex of the infected host cell membrane and a second monoclonal antibody reacting with an unknown internal antigen did not appear to react with exoerythrocytic parasites. We confirm prior reports that monoclonal antibodies against the sporozoite immunodominant repeat antigen react with all exoerythrocytic-stage parasites, but note that as the exoerythrocytic parasite matures the immunostaining is concentrated in plaques reminiscent of germinal centers and apparently distinct from mature merozoites. These results indicate that mature merozoites from either exoerythrocytic or blood-stage parasites are antigenically very similar, but that stage-specific antigens may be found in specialized structures present only in a specific host cell type.     

Sorting of malarial antigens into vesicular compartments within the host cell cytoplasm as demonstrated by immunoelectron microscopy

A double and triple immunogold labeling technique has been applied to demonstrate that several malarial antigens of the erythrocytic stages of Plasmodium falciparum are exported from the parasite into distinct compartments within the host cell cytoplasm. Multiple species of vesicles, each with specifically packaged contents, are consistent with a sorting function of vesicular structures in the Plasmodium infected erythrocyte. During schizogony, two parasite antigens, an S-antigen and a parasitophorous vacuole membrane antigen, QF 116, become packaged into such vesicles and are transported into the erythrocyte cytoplasm. At this stage of parasite development, host cell material is taken in through the parasitophorous vacuole membrane into the vacuolar space surrounding the parasite.     

Molecular cloning and characterisation of the RESA gene,a marker of genetic diversity of <Emphasis Type="Italic">Plasmodium falciparum</Emphasis>

To identity immunodiagnostic antigen genes, a Plasmodium falciparum (Dd2 clone) expression library was screened using human immune sera. The ring-infected erythrocyte surface antigen (RESA) was isolated: this antigen of the resistant clone presents repeat tandem sequences like the 3D7 clone, albeit in different numbers. RESA has been studied as a marker of genetic diversity, with different sizes being observed in different isolates and clones of Plasmodium falciparum. The native protein was localised in cultures by western-blot and immuno-transmission electron microscopy. The antigenicity of RESA was evaluated by ELISA, using the carboxy-terminal repeat region as antigen. The assay’s sensitivity and specificity were 78.2 and 94% respectively.     

Characterization with monoclonal antibodies of a surface antigen of Plasmodium falciparum merozoites

The merozoite, the extracellular form of the erythrocyte stage of the malarial parasite, invades the erythrocyte and develops intracellularly. Cloned hybridoma cell lines secreting monoclonal antibodies directed against the merozoite surface were selected by indirect immunofluorescent assay by using intact isolated merozoites. Monoclonal antibodies to a 200,000 m.w. merozoite surface antigen were selected and were used to characterize this protein and its role in erythrocyte invasion. Immunoelectron microscopy demonstrated that the antigen was located exclusively on the merozoite surface coat, distributed evenly over the entire surface. The 200,000 m.w. protein incorporated [3H]glucosamine, suggesting that it is a glycoprotein and could be purified to homogeneity by using immuno-affinity chromatography. Freshly isolated, invasive merozoites retained the 200,000 m.w. antigen, but the protein was rapidly cleaved to proteins of 90,000 and 50,000 m.w. when the merozoite was extracellular. The 50,000 m.w. fragment was retained the epitope binding to monoclonal antibody 5B1 and were labeled with [3H]glucosamine. Monoclonal antibodies against the 200,000 m.w. antigen partially inhibited merozoite invasion into erythrocytes.     

Immunization of monkeys with a 140 kilodalton merozoite surface protein of Plasmodium knowlesi malaria: appearance of alternate forms of this protein

The merozoite is the invasive stage of the malaria parasite which is released by rupture of the schizont-infected erythrocyte. A monoclonal antibody against a 140 kilodalton (kDa) merozoite surface antigen of Plasmodium knowlesi was used to characterize and to purify this antigen. It was shown by pulse-chase metabolic labeling of mature schizonts that the 140 kDa merozoite antigen was the processed product of a 143 kDa schizont component, and that processing occurred at the time of erythrocyte rupture. Antiserum, prepared by immunizing a rabbit with the 143/140 kDa antigen purified by immunoaffinity chromatography with the monoclonal antibody, strongly inhibited invasion of erythrocytes in vitro; Fab fragments prepared from purified rabbit IgG were inactive at blocking invasion, suggesting that agglutination of merozoites was the mechanism of invasion inhibition. The purified 143/140 kDa antigen was used in Freund's adjuvant to immunize four rhesus monkeys. Two of the immunized animals developed fulminating infections on challenge with 10(4) schizonts, as did the three control animals. The remaining two immunized animals controlled their infections and developed chronic low-grade parasitemias. The animals which were partially protected were those that had developed anti-143/140 kDa antibodies capable of blocking invasion in vitro. Parasites were isolated from the chronic stage of infection (V5 population) and were compared with the original parasite population used for challenge (P population). Inhibition of invasion, immunofluorescence, and immunoprecipitation with anti-143/140 kDa monoclonal antibody, with immune rabbit, and with monkey sera showed that the 143/140 kDa surface antigen had been replaced by multiple cross-reacting alternate antigenic forms of the molecule in the V population. Thus, specific immune response directed against a purified merozoite surface antigen resulted in the replacement of this antigen by variant or mutant forms.     

Changes in repeat number, sequence, and reading frame in S-antigen genes of Plasmodium falciparum.

The S antigens from different isolates of Plasmodium falciparum exhibit extensive size, charge, and serological diversity. We show here that the S-antigen genes behave as multiple alleles of a single locus. The size heterogeneity results from different numbers, lengths, and/or sequences of tandem repeat units encoded within the S-antigen genes. Two genes studied here encode antigenically different S antigens but nevertheless have closely related tandem repeat sequences. We show that antigenic differences can arise because repeats are translated in different reading frames.     

Trafficking of malarial proteins to the host cell cytoplasm and erythrocyte surface membrane involves multiple pathways

During the asexual stage of malaria infection, the intracellular parasite exports membranes into the erythrocyte cytoplasm and lipids and proteins to the host cell membrane, essentially "transforming" the erythrocyte. To investigate lipid and protein trafficking pathways within Plasmodium falciparum-infected erythrocytes, synchronous cultures are temporally analyzed by confocal fluorescence imaging microscopy for the production, location and morphology of exported membranes (vesicles) and parasite proteins. Highly mobile vesicles are observed as early as 4 h postinvasion in the erythrocyte cytoplasm of infected erythrocytes incubated in vitro with C6-NBD-labeled phospholipids. These vesicles are most prevalent in the trophozoite stage. An immunofluorescence technique is developed to simultaneously determine the morphology and distribution of the fluorescent membranes and a number of parasite proteins within a single parasitized erythrocyte. Parasite proteins are visualized with FITC- or Texas red-labeled monoclonal antibodies. Double-label immunofluorescence reveals that of the five parasite antigens examined, only one was predominantly associated with membranes in the erythrocyte cytoplasm. Two other parasite antigens localized only in part to these vesicles, with the majority of the exported antigens present in lipid-free aggregates in the host cell cytoplasm. Another parasite antigen transported into the erythrocyte cytoplasm is localized exclusively in lipid-free aggregates. A parasite plasma membrane (PPM) and/or parasitophorous vacuolar membrane (PVM) antigen which is not exported always colocalizes with fluorescent lipids in the PPM/PVM. Visualization of two parasite proteins simultaneously using FITC- and Texas red-labeled 2 degrees antibodies reveals that some parasite proteins are constitutively transported in the same vesicles, whereas other are segregated before export. Of the four exported antigens, only one appears to cross the barriers of the PPM and PVM through membrane-mediated events, whereas the others are exported across the PPM/PVM to the host cell cytoplasm and surface membrane through lipid (vesicle)-independent pathways.     

The Plasmodium falciparum Erythrocyte Invasion Ligand Pfrh4 as a Target of Functional and Protective Human Antibodies against Malaria

Background

Acquired antibodies are important in human immunity to malaria, but key targets remain largely unknown. Plasmodium falciparum reticulocyte-binding-homologue-4 (PfRh4) is important for invasion of human erythrocytes and may therefore be a target of protective immunity.

Methods

IgG and IgG subclass-specific responses against different regions of PfRh4 were determined in a longitudinal cohort of 206 children in Papua New Guinea (PNG). Human PfRh4 antibodies were tested for functional invasion-inhibitory activity, and expression of PfRh4 by P. falciparum isolates and sequence polymorphisms were determined.

Results

Antibodies to PfRh4 were acquired by children exposed to P. falciparum malaria, were predominantly comprised of IgG1 and IgG3 subclasses, and were associated with increasing age and active parasitemia. High levels of antibodies, particularly IgG3, were strongly predictive of protection against clinical malaria and high-density parasitemia. Human affinity-purified antibodies to the binding region of PfRh4 effectively inhibited erythrocyte invasion by P. falciparum merozoites and antibody levels in protected children were at functionally-active concentrations. Although expression of PfRh4 can vary, PfRh4 protein was expressed by most isolates derived from the cohort and showed limited sequence polymorphism.

Conclusions

Evidence suggests that PfRh4 is a target of antibodies that contribute to protective immunity to malaria by inhibiting erythrocyte invasion and preventing high density parasitemia. These findings advance our understanding of the targets and mechanisms of human immunity and evaluating the potential of PfRh4 as a component of candidate malaria vaccines.     

Radioimmunocytochemical localization of retinal S-antigen with monoclonal antibodies

Two monoclonal antibodies (RSA1/83 and RSA2/83) were developed against a homogeneous preparation of bovine retinal S-antigen. The two hybridomas produced by mouse X mouse hybrid myeloma cells secrete immunoglobulin G. Indirect autoradiography on glutaraldehyde-fixed preparations of bovine explants was used to locate the antigenic site. Antibody RSA1/83 recognizes the antigen primarily in the apical region of the rod outer segment, while antibody RSA2/83 located the antigen both in the outer and inner segments of the rod photoreceptor cells. A distinct band of silver grains also appeared along the inner limiting membrane with both antibodies. Control explants showed no specific labeling pattern over the various retinal compartments.     

Skeleton binding protein 1 (SBP1) of Plasmodium falciparum accumulates in electron-dense material before passing through the parasitophorous vacuole membrane

Plasmodium falciparum proteins involved in vascular endothelial cell adherence are transported to the surface of infected erythrocytes. These proteins are exported through parasite-derived membrane structures within the erythrocyte cytoplasm called Maurer's clefts. Skeleton binding protein 1 (SBP1) is localized in the Maurer's clefts and plays an important role in transporting molecules to the surface of infected erythrocytes. Details of the translocation pathway are unclear and in this study we focused on the subcellular localization of SBP1 at an early intraerythrocytic stage. We performed immunoelectron microscopy using specific anti-SBP1 antibodies generated by immunization with recombinant SBP1 of P. falciparum. At the early trophozoite (ring form) stage, SBP1 was detected within an electron dense material (EDM) found in the parasite cytoplasm and in the parasitophorous vacuolar (PV) space. These findings demonstrate that SBP1 accumulates in EDM in the early trophozoite cytoplasm and is transported to the PV space before translocation to the Maurer's clefts formed in the erythrocyte cytoplasm.     

Immunodetection and localization of protein(s) related to retinal S-antigen (arrestin) in kidney.

S-antigen (arrestin) is a cytosolic protein which regulates phototransduction in retinal rods. A protein immunologically related to S-antigen was identified in fractions from soluble extract of bovine kidney enriched by gel filtration or by immunoaffinity chromatography using a polyclonal antibody to retinal S-antigen. On immunoblots, this protein was recognized by a panel of monoclonal antibodies (mAbs S2D2, S1A3 and S9E2) directed against different S-antigen epitopes and displayed the same apparent molecular mass (48 kDa) as retinal S-antigen. All three mAbs revealed a specific immunoreactivity by indirect immunocytochemical technique on rat kidney sections. The three mAbs recognized some but not all glomerular cells, identified as epithelial cells by immunoelectron microscopy using the mAb S9E2. Both mAbs S2D2 and S1A3 gave a diffuse cytoplasmic staining in all tubule cells. Proximal tubule cells exhibited a weak immunoreactivity, whereas distal and collecting tubule cells were strongly labeled. In contrast, the mAb S9E2 immunoreaction was restricted to a cell subpopulation from distal and collecting tubules corresponding to intercalated cells identified by immunoelectron microscopy. With the mAb S9E2, the labeling of proximal tubule cells was localized in the apical region of the cytoplasm. These results suggest that two or more 48-kDa proteins immunologically cross-reactive with retinal S-antigen are present in kidney. The observed pattern of distribution is in keeping with the hypothesis that such proteins could play a role in the regulation of G-protein-related receptors present in renal glomerulus and tubule epithelial cells.     

Ca2+‐mediated exocytosis of subtilisin‐like protease 1: a key step in egress of Plasmodium falciparum merozoites

Egress of Plasmodium falciparum merozoites from host erythrocytes is a critical step in multiplication of blood‐stage parasites. A cascade of proteolytic events plays a major role in degradation of membranes leading to egress of merozoites. However, the signals that regulate the temporal activation and/or secretion of proteases upon maturation of merozoites in intra‐erythrocytic schizonts remain unclear. Here, we have tested the role of intracellular Ca²⁺ in regulation of egress of P. falciparum merozoites from schizonts. A sharp rise in intracellular Ca²⁺ just before egress, observed by time‐lapse video microscopy, suggested a role for intracellular Ca²⁺ in this process. Chelation of intracellular Ca²⁺ with chelators such as BAPTA‐AM or inhibition of Ca²⁺ release from intracellular stores with a phospholipase C (PLC) inhibitor blocks merozoite egress. Interestingly, chelation of intracellular Ca²⁺ in schizonts was also found to block the discharge of a key protease PfSUB1 (subtilisin‐like protease 1) from exonemes of P. falciparum merozoites to parasitophorous vacuole (PV). This leads to inhibition of processing of PfSERA5 (serine repeat antigen 5) and a block in parasitophorous vacuolar membrane (PVM) rupture and merozoite egress. A complete understanding of the steps regulating egress of P. falciparum merozoites may provide novel targets for development of drugs that block egress and limit parasite growth.     

Germline-specific Antigens Identified by Monoclonal Antibodies in the Nematode Caenorhabditis elegans1

Of 27 monoclonal antibodies identified to react, by indirect immunofluorescent antibody staining, with specific cells and tissues of the nematode Caenorhabditis elegans, we report here three monoclonal antibodies pertaining to the gonadal tissues. One antibody defines an antigen that is distributed over the entire embryo at earlier development and later becomes unique to the gonad, including mature oocytes. The antigens recognized by the other two are distributed asymmetrically in the posterior region of the fertilized egg's cytoplasm destined to become the germline precursor cell. Each antigen is successively segregated only to the germline precursor cells of the developing embryo and, postembryonically, is uniquely localized around the germline cell nuclei of the larvae and adults.     

Invasion and Early Development of Sarcocystis muris (Apicomplexa,Sarcocystidae) in Tissue Cultures1

Ultrastructural observations on the invasion and early development of merozoites (bradyzoites) of Sarcocystis muris in Madin-Darby canine kidney (MDCK) cells are presented. Invading merozoites cause the host cell plasmalemma to invaginate; they form a membrane junction (moving junction) and move into the host cell where they are enclosed in a primary parasitophorous vacuole (PV). Within 30–45 min after becoming intracellular, merozoites begin to vacate the newly established primary PV and move, forming a new membrane junction, into a secondary PV. Simultaneously with the movement of the parasite, the contents of dense granules in the apical part of the merozoites are shed by exocytosis into the lumen of the developing secondary PV. A lamella of the endoplasmic reticulum of the host cell becomes attached to the PV membrane, forming a PV limited by three host cell membranes.     

Analysis of the subcellular localization of huntingtin with a set of rabbit polyclonal antibodies in cultured mammalian cells of neuronal origin: comparison with the distribution of huntingtin in Huntington's disease autopsy brain.

Huntington's disease (HD) is a neurodegenerative disorder with a midlife onset. The disease is caused by expansion of a CAG (glutamine) repeat within the coding region of the HD gene. The molecular mechanism by which the mutated protein causes this disease is still unclear. To study the protein we have generated a set of rabbit polyclonal antibodies raised against different segments of the N-terminal, central and C-terminal parts of the protein. The polyclonal antibodies were affinity purified and characterized in ELISA and Western blotting experiments. All antibodies can react with mouse and human proteins. The specificity of these antibodies is underscored by their recognition of huntingtin with different repeat sizes in extracts prepared from patient-derived lymphoblasts. The antibodies were used in immunofluorescence experiments to study the subcellular localization of huntingtin in mouse neuroblastoma NIE-115 cells. The results indicate that most huntingtin is present in the cytoplasm, whereas a minor fraction is present in the nucleus. On differentiation of the NIE-115 cells in vitro, the subcellular distribution of huntingtin does not change significantly. These results suggest that full-length huntingtin with a normal repeat length can be detected in the nucleus of cycling and non-cycling cultured mammalian cells of neuronal origin. However, in HD autopsy brain the huntingtin-containing neuronal intranuclear inclusions can be detected only with antibodies raised against the N-terminus of huntingtin. Thus several forms of huntingtin display the propensity for nuclear localization, possibly with different functional consequences.