Naturally occurring anti-band 3 autoantibodies recognize a high molecular weight protein on the surface of Plasmodium falciparum infected erythrocytes

Naturally occurring anti-band 3 autoantibodies bind to erythrocytes infected with a knobby variant of the human malaria Plasmodium falciparum (FCR-3 strain). The autoantibodies recognized a greater than 240 kDa protein in SDS extracts made from surface iodinated infected erythrocytes. The antigen was associated only with erythrocytes infected with a knobby variant, and was removed by trypsin treatment of intact infected cells. By two-dimensional peptide map analysis the antigen was shown to be structurally related to the human erythrocyte anion transporter, band 3.     

Plasmodium falciparum: cytoadherence of malaria-infected erythrocytes to human brain capillary and umbilical vein endothelial cells--a comparative study of adhesive ligands.

The cytoadherence of Plasmodium falciparum-infected erythrocytes (FCR-3 line) to human brain capillary endothelial cells (HBEC), C32 amelanotic melanoma cells, and human umbilical vein endothelial cells (HUVEC) was studied. The adhesion of infected red cells was HBEC > amelanotic melanoma > HUVEC. The presence or absence of the adhesive ligands ICAM-1 (CD54 or intercellular adhesion molecule 1), ICAM-2, and CD36 (= glycoprotein IV) was determined for each of these cells by indirect immunofluorescence using the monoclonal antibodies RR1/1, 6D5, and OKM 5/OKM 8, respectively. It appeared that a major ligand for the FCR-3 line of P. falciparum with amelanotic melanoma cells and HBECs was CD36. Binding to HUVECs was very low, presumably due to their lack of expression of CD36. HBECs, because of their ease of in vitro propagation, long-term maintenance of cytoadherent properties, and their high degree of adhesiveness, will be useful for in vitro studies of adherence.     

Targeted delivery of erythrocytes to human aortic smooth muscle cells

Monoclonal antibodies specific for surface antigens of target cells are supposed to be good vectors for drug transport. It is suggested using monoclonal antibodies that distinguish between smooth muscle and endothelial cells as vectors for directed drug transport to injured (denuded) areas of the blood vessel wall. The following in vitro model was used: monoclonal antibodies were added to cultured vascular smooth muscle or endothelial cells, this was followed by the addition of erythrocytes conjugated with rabbit antimouse antibodies. Spectrometry and scanning electron microscopy were used to assess the results. The erythrocytes, possible containers of drugs, under the experimental conditions were found to bind only to smooth muscle cells. The data obtained suggest that antibody IIG10 discriminating between smooth muscle and endothelial cells provides a specific tool for erythrocyte delivery to smooth muscle cells.     

Plasmodium falciparum: fine structural changes in the cytoskeletons of infected erythrocytes

Following parasitization by Plasmodium falciparum, numerous changes take place in the host erythrocyte membrane. In this study, we used the technique of whole cell mount electron microscopy to determine if the ultrastructure of the erythrocyte cytoskeleton changed following parasitization with knobby and knobless strains of P. falciparum. Using this technique, a network of spectrin filaments (3-10 X 45-120 nm) branching from electron dense junctions (15-25 nm in diameter), the presumed site of bands 4.1 and actin, were visualized. The overall architecture of normal and parasitized erythrocyte cytoskeletons was the same: however, additional patches (35 to 60 nm in size) and aggregates (30 X 150 nm) of electron dense material were present in parasitized skeletons. The ultrastructure of knobby and knobless cytoskeletons was similar, except knobless skeletons usually did not possess the larger aggregates of material. Antigens associated with the erythrocyte cytoskeleton of cells infected with knobby and knobless strains, but not uninfected cells, were demonstrated by indirect immunofluorescence. Results suggest that antigens, associated with the erythrocyte cytoskeleton, may contribute to perturbations in the host erythrocyte membrane.     

Ultrastructural localization of erythrocyte cytoskeletal and integral membrane proteins in Plasmodium falciparum-infected erythrocytes

The distributions of ankyrin, spectrin, band 3, and glycophorin A were examined in Plasmodium falciparum-infected erythrocytes by immunoelectron microscopy to determine whether movement of parasite proteins and membrane vesicles between the parasitophorous vacuole membrane and erythrocyte surface membrane involves internalization of host membrane skeleton proteins. Monospecific rabbit antisera to spectrin, band 3 and ankyrin and a mouse monoclonal antibody to glycophorin A reacted with these erythrocyte proteins in infected and uninfected human erythrocytes by immunoblotting. Cross-reacting malarial proteins were not detected. The rabbit sera also failed to immunoprecipitate [3H]isoleucine labeled malarial proteins from Triton X-100 and sodium dodecyl sulfate (SDS) extracts of infected erythrocytes. These three antibodies as well as the monoclonal antibody to glycophorin A bound to the membrane skeleton of infected and uninfected erythrocytes. The parasitophorous vacuole membrane was devoid of bound antibody, a result indicating that this membrane contains little, if any, of these host membrane proteins. With ring-, trophozoite- and schizont-infected erythrocytes, spectrin, band 3 and glycophorin A were absent from intracellular membranes including Maurer's clefts and other vesicles in the erythrocyte cytoplasm. In contrast, Maurer's clefts were specifically labeled by anti-ankyrin antibody. There was a slight, corresponding decrease in labeling of the membrane skeleton of infected erythrocytes. A second, morphologically distinct population of circular, vesicle-like membranes in the erythrocyte cytoplasm was not labeled with anti-ankyrin antibody. We conclude that membrane movement between the host erythrocyte surface membrane and parasitophorous vacuole membrane involves preferential sorting of ankyrin into a subpopulation of cytoplasmic membranes.     

Rotational dynamics of the integral membrane protein, band 3, as a probe of the membrane events associated with Plasmodium falciparum infections of human erythrocytes

Time-resolved phosphorescence anisotropy was used to study the molecular organisation of band 3 in the erythrocyte membrane. Three different rotational relaxation regimes of mobile band 3 were resolved. These populations may represent different aggregation states of band 3 within the membrane, or they may result from association of band 3 with other proteins at the cytoplasmic surface. The polycation spermine decreases the apparent mobility of band 3 by a mechanism that does not involve the underlying cytoskeleton. A monoclonal antibody directed against the cytoplasmic portion of band 3 can also cause an increase in the immobile fraction of band 3 molecules. This monoclonal antibody will inhibit invasion of erythrocytes by malaria parasites. Membranes prepared from erythrocytes infected with mature stages of the malaria parasite, Plasmodium falciparum, show altered dynamic properties corresponding to a marked restriction of band 3 mobility.     

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.     

The parasitophorous vacuole membrane of Plasmodium falciparum: demonstration of vesicle formation using an immunoprobe

We have applied several immunolabeling techniques using a monoclonal antibody to a Plasmodium falciparum antigen to differentiate morphologically dissimilar membranous structures present in infected erythrocytes. Evidence is presented that cytoplasmic clefts, multimembranous structures and vesicles within the infected cell originate from the parasitophorous vacuole membrane by a process described as budding off. The parasitophorous vacuole membrane and related structures in infected, parasitized erythrocytes reacted with the cyanine dye Merocyanine 540, demonstrating that they are accessible to molecules from the extracellular environment. Immunogold labeling of freeze-fractured preparations and of thin sections of parasitized cells using pre- and post-embedding techniques revealed that each of the membranous structures carried a common parasite antigen, QF 116, which was identified by monoclonal antibody 8E7/55.     

Plasmodium falciparum: CD36 Dependent Cytoadherence or Rosetting of Infected Erythrocytes is Modulated by Knobs

A knobless (K-) line of the FCR-3 isolate of Plasmodium falciparum was obtained by gelatin flotation. Immunofluorescent staining and immunoblots indicated that both the K-line and the K+ (knobby) line from which it was derived contained similar forms of potentially adhesive modified band 3 protein. When the K+ and K-lines were assayed for their cytoadherent and rosetting abilities the K+ line showed a high level of CD36 dependent cytoadherence, whereas the K-line demonstrated a marked pH dependent increase in rosetting. Rosetting was inhibited by the addition of peptides based on band 3 motifs, suggesting that cytoadherence and rosetting involve the same adhesin but that the presence of knobs affects whether the adherent preference of the infected erythrocyte is uninfected red cells or endothelial/C32 amelanotic melanoma cells.     

Plasmodium falciparum: CD36 Dependent Cytoadherence or Rosetting of Infected Erythrocytes is Modulated by Knobs

A knobless (K-) line of the FCR-3 isolate of Plasmodium falciparum was obtained by gelatin flotation. Immunofluorescent staining and immunoblots indicated that both the K-line and the K+ (knobby) line from which it was derived contained similar forms of potentially adhesive modified band 3 protein. When the K+ and K-lines were assayed for their cytoadherent and rosetting abilities the K+ line showed a high level of CD36 dependent cytoadherence, whereas the K-line demonstrated a marked pH dependent increase in rosetting. Rosetting was inhibited by the addition of peptides based on band 3 motifs, suggesting that cytoadherence and rosetting involve the same adhesin but that the presence of knobs affects whether the adherent preference of the infected erythrocyte is uninfected red cells or endothelial/C32 amelanotic melanoma cells.     

Expression of the parasite protein Pc90 in plasma membranes of erythrocytes infected with Plasmodium chabaudi

Erythrocytes infected with the malaria parasite Plasmodium chabaudi contain the neo-protein Pc90 in their plasma membrane. We investigate origin, membrane disposition, and intraerythrocytic traffic of this Pc90. Metabolic labeling of P.-infected erythrocytes, combined with cell fractionation as well as Western blot analysis and immunoprecipitation using a Pc90-recognizing monoclonal antibody, show that Pc90 is synthesized by early to mid trophozoites and is transported without any apparent processing steps to the erythrocyte membrane. Based upon the inaccessibility of Pc90 from the outside in intact erythrocytes and the water solubility of membrane-associated Pc90, it is concluded that Pc90 is localized on the cytoplasmic face of the host erythrocyte membrane. Immunoelectron microscopy using a Pc90-specific monoclonal antibody and the occurrence of soluble Pc90 in host cell cytosol indicate that the Pc90 is transported in both a 'vesicle-bound' and a 'free' form through the erythrocyte cytoplasm.     

Transport of an Mr approximately 300,000 Plasmodium falciparum protein (Pf EMP 2) from the intraerythrocytic asexual parasite to the cytoplasmic face of the host cell membrane

The profound changes in the morphology, antigenicity, and functional properties of the host erythrocyte membrane induced by intraerythrocytic parasites of the human malaria Plasmodium falciparum are poorly understood at the molecular level. We have used mouse mAbs to identify a very large malarial protein (Mr approximately 300,000) that is exported from the parasite and deposited on the cytoplasmic face of the erythrocyte membrane. This protein is denoted P. falciparum erythrocyte membrane protein 2 (Pf EMP 2). The mAbs did not react with the surface of intact infected erythrocytes, nor was Pf EMP 2 accessible to exogenous proteases or lactoperoxidase-catalyzed radioiodination of intact cells. The mAbs also had no effect on in vitro cytoadherence of infected cells to the C32 amelanotic melanoma cell line. These properties distinguish Pf EMP 2 from Pf EMP 1, the cell surface malarial protein of similar size that is associated with the cytoadherent property of P. falciparum-infected erythrocytes. The mAbs did not react with Pf EMP 1. In one strain of parasite there was a significant difference in relative mobility of the 125I-surface-labeled Pf EMP 1 and the biosynthetically labeled Pf EMP 2, further distinguishing these proteins. By cryo-thin-section immunoelectron microscopy we identified organelles involved in the transit of Pf EMP through the erythrocyte cytoplasm to the internal face of the erythrocyte membrane where the protein is associated with electron-dense material under knobs. These results show that the intraerythrocytic malaria parasite has evolved a novel system for transporting malarial proteins beyond its own plasma membrane, through a vacuolar membrane and the host erythrocyte cytoplasm to the erythrocyte membrane, where they become membrane bound and presumably alter the properties of this membrane to the parasite's advantage.     

Monoclonal antibody OKM5 inhibits the in vitro binding of Plasmodium falciparum-infected erythrocytes to monocytes, endothelial, and C32 melanoma cells

Plasmodium falciparum-infected erythrocytes bind in vitro to human endothelial cells, monocytes, and a certain melanoma cell line. Evidence suggests that this interaction is mediated by similar mechanisms which lead to the sequestration of parasitized erythrocytes in vivo through their attachment to endothelial cells of small blood vessels. We show here that monoclonal antibody OKM5, previously shown to react with the membranes of endothelial cells, monocytes, and platelets, also reacts with the C32 melanoma cell line which also binds P. falciparum-infected erythrocytes. At relatively low concentrations, OKM5 inhibits and reverses the in vitro adherence of infected erythrocytes to target cells. As with monocytes, OKM5 antibody recognizes an 125I-labeled protein of approximately 88 Kd on the surface of C32 melanoma cells. It seems likely, therefore, that the 88 Kd polypeptide plays a role in cytoadherence, possibly as the receptor or part of a receptor for a ligand on the surface of infected erythrocytes.     

Structural alteration of the membrane of erythrocytes infected with Plasmodium falciparum

Human erythrocytes infected with five strains of Plasmodium falciparum and Aotus erythrocytes infected with three strains of P. falciparum were studied by thin-section and freeze-fracture electron microscopy. All strains of P. falciparum we studied induced electron-dense conical knobs, measuring 30-40 nm in height and 90-100 nm in diameter on erythrocyte membranes. Freeze-fracture demonstrated that the knobs were distributed over the membrane of both human and Aotus erythrocytes. A distinct difference was seen between the intramembrane particle (IMP) distribution over the knobs of human and Aotus erythrocyte membranes. There was no change in IMP distribution in infected human erythrocyte membranes, but infected Aotus erythrocytes showed an aggregation of IMP over the P face of the knobs with a clear zone at the base. This difference in IMP distribution was related only to the host species and not to parasite strains. Biochemical analysis demonstrated that a higher proportion of band 3 was bound to the cytoskeleton of uninfected Aotus erythrocytes than uninfected human erythrocytes after Triton X-100 extraction. This may account for the different effects of P. falciparum infection on IMP distribution in the two different cell types.     

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.     

Detection of antibodies to variant antigens on Plasmodium falciparum-infected erythrocytes by flow cytometry

BACKGROUND: Naturally induced antibodies binding to surface antigens of Plasmodium falciparum-infected erythrocytes can be detected by direct agglutination of infected erythrocytes or by indirect immunofluorescence on intact, unfixed, infected erythrocytes. Agglutinating antibodies have previously been shown to recognise Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1). This protein is inserted by the parasite into the host cell membrane and mediates the adhesion to the venular endothelium of the host organism in vivo. METHODS: Erythrocytes infected at high parasitaemias with ethidium-bromide-labelled mature forms of P. falciparum parasites were sequentially exposed to immune plasma, goat anti-human immunoglobulin (Ig) G, and fluorescein-isothiocyanate-conjugated rabbit anti-goat Ig. Plasma antibodies recognising antigens exposed on the surface of parasitised erythrocytes were subsequently detected by two-colour flow cytometry. RESULTS: Binding of human antibodies to the surface of erythrocytes infected with adhesive strains of Plasmodium falciparum can be measured by the two-colour flow cytometry (FCM) assay described. In addition, we demonstrate that the adhesive capacity of a parasite isolate correlates with the capacity of human immune plasmas to label the isolate as detected by FCM. We also show that the antigens recognised by the labelling antibodies are strain specific and that their molecular weights are in the range previously described for PfEMP1 antigens. CONCLUSIONS: Our FCM assay predominantly detects antibodies that recognise PfEMP1 and thus constitutes a convenient assay for the analysis of acquisition, maintenance, and diversity of anti-PfEMP1-specific antibodies and for the examination of class and subclass characteristics.     

cDNA sequence encoding a Plasmodium falciparum protein associated with knobs and localization of the protein to electron-dense regions in membranes of infected erythrocytes.

Plasmodium falciparum modifies the host erythrocyte's plasma membrane by the formation of electron-dense structures called knobs. We have produced monoclonal antibodies (McAbs) which specifically bind to the knobs in immunoelectron microscopic experiments with thin sections of parasitized erythrocytes. However, the McAbs fail to bind to the surface of live parasitized erythrocytes. Immunoblotting experiments with these McAbs show the antigen is localized to the erythrocyte plasma membrane. The antigen with which the McAbs react varies in mol. wt from 80 to 95 kd in different knob-producing isolates of P. falciparum and is absent in knobless variants. The McAbs react with the expressed product of a P. falciparum cDNA clone, thus demonstrating that the clone encodes part of this knob-associated protein. The sequence of the cDNA fragment partially overlaps a published cDNA sequence reported to encode the amino-terminal portion of the knob protein, and extends the predicted open reading frame by 190 amino acids. The carboxyl-terminal portion of the predicted amino acid sequence contains a highly charged stretch of approximately 100 amino acid residues. We suggest that this unusual, highly charged region participates in intermolecular salt bridging leading to dense packing of these molecules. This would create the electron-dense regions observed by electron microscopy and might also explain the insolubility of the knob-associated protein in the absence of strong ionic detergents or chaotropic agents.     

Red blood cell targeting to smooth muscle cells

Monoclonal antibody discriminating between endothelial and smooth muscle cells is suggested to be used as a vector for directed transport of drugs to injured (denuded) areas of blood vessel wall. An in vitro model system was used in the studies: vascular smooth muscle or endothelial cells grown on plastic surface were treated with specific mouse monoclonal antibody recognizing an antigen localized on the surface of smooth muscle rather than endothelial cells; then erythrocytes coated with secondary (rabbit antimouse) antibodies were added. The results were analyzed spectrophotometrically or with scanning electron microscopy. Under the experimental conditions, erythrocytes, possible 'containers' for carrying the drugs, were found to bind only to smooth muscle cells. The data show that antibody provides absolute discrimination between endothelial and smooth muscle cells and, thus, may be used as a vector for drug targeting.     

Structural, functional, and antigenic differences between bovine heart endothelial CD36 and human platelet CD36.

Endothelial cell CD36 (glycoprotein IV) has been purified from bovine heart tissue by detergent partitioning and immunoaffinity chromatography. Bovine CD36 differs from human CD36 in its apparent mass (85 versus 88 kDa), primary structure, and immunological cross-reactivity. Of the 18 N-terminal residues identified, 17 conformed to the human CD36 sequence. Mouse monoclonal antibodies E-1 and 8A6 defined bovine- and human-specific epitopes, respectively. Because human CD36 has been identified as a receptor for erythrocytes infected with the malaria parasite Plasmodium falciparum, we examined the ability of bovine CD36 to bind infected erythrocytes. Bovine CD36, unlike human CD36, did not bind infected erythrocytes, suggesting that human CD36-specific structural features are responsible for recognition of the infected erythrocyte ligand.     

Morphological changes in erythrocytes induced by malarial parasites

Host cell alterations induced by Plasmodium falciparum, P. brasilianum, P. vivax and P. malariae were described by electron microscopy and post-embedding immunoelectron microscopy. P. falciparum infection induces knobs, electron-dense material and clefts in the erythrocyte. Clefts are involved in exporting P. falciparum antigen from the parasite to the erythrocyte membrane. P. falciparum antigen is present in knobs which adhere to endothelial cells causing the blockage of cerebral capillaries and ensuing pathological changes in cerebral tissues. P. brasilianum infection induces knobs, short and long clefts and electron-dense material. These structures appear to contain different P. brasilianum antigens. This indicates that each structure functions independently in trafficking P. brasilianum protein to the erythrocyte surface. P. vivax infection induces caveola-vesicle complexes and clefts in the erythrocyte. These structures are also involved in trafficking P. vivax protein from the parasite to the erythrocyte membrane. P. malariae induces caveolae, electron-dense material, vesicles, clefts and knobs in the erythrocyte. Although vesicles and caveolae are seen in the erythrocyte cytoplasm, they do not form caveola-vesicle complexes as seen in P. vivax-infected erythrocytes. They also appear to be involved in trafficking of malaria antigens. These studies, therefore, indicate that host cell changes occur in order to facilitate the transport of malarial antigens to the host cell membrane. The significance of these phenomena is still not clear.