Subliminal and supraliminal processing of reward-related stimuli in anorexia nervosa.

BACKGROUND: Previous studies have highlighted the role of the brain reward and cognitive control systems in the etiology of anorexia nervosa (AN). In an attempt to disentangle the relative contribution of these systems to the disorder, we used functional magnetic resonance imaging (fMRI) to investigate hemodynamic responses to reward-related stimuli presented both subliminally and supraliminally in acutely underweight AN patients and age-matched healthy controls (HC). METHODS: fMRI data were collected from a total of 35 AN patients and 35 HC, while they passively viewed subliminally and supraliminally presented streams of food, positive social, and neutral stimuli. Activation patterns of the group × stimulation condition × stimulus type interaction were interrogated to investigate potential group differences in processing different stimulus types under the two stimulation conditions. Moreover, changes in functional connectivity were investigated using generalized psychophysiological interaction analysis. RESULTS: AN patients showed a generally increased response to supraliminally presented stimuli in the inferior frontal junction (IFJ), but no alterations within the reward system. Increased activation during supraliminal stimulation with food stimuli was observed in the AN group in visual regions including superior occipital gyrus and the fusiform gyrus/parahippocampal gyrus. No group difference was found with respect to the subliminal stimulation condition and functional connectivity. CONCLUSION: Increased IFJ activation in AN during supraliminal stimulation may indicate hyperactive cognitive control, which resonates with clinical presentation of excessive self-control in AN patients. Increased activation to food stimuli in visual regions may be interpreted in light of an attentional food bias in AN.

Activity in high-level brain regions reflects visibility of low-level stimuli.

Stimulus visibility is associated with neural signals in multiple brain regions, ranging from visual cortex to prefrontal regions. Here we used functional magnetic resonance imaging (fMRI) to investigate to which extent the perceived visibility of a "low-level" grating stimulus is reflected in the brain activity in high-level brain regions. Oriented grating stimuli were presented under varying visibility conditions created by backward masking. Visibility was manipulated using four different stimulus onset asynchronies (SOAs), which created a continuum from invisible to highly visible target stimuli. Brain activity in early visual areas, high-level visual brain regions (fusiform gyrus), as well as parietal and prefrontal brain regions was significantly correlated with subjects' psychometric visibility functions. In addition, increased stimulus visibility was reflected in the functional coupling between low and high-level visual areas. Specifically, neuroimaging signals in the middle occipital gyrus were significantly more correlated with signals in the inferior temporal gyrus when subjects successfully perceived the target stimulus than when they did not. These results provide evidence that not only low-level visual but also high-level brain regions reflect visibility of low-level grating stimuli and that changes in functional connectivity reflect perceived stimulus visibility.

Evidence for two-stage binding by the 175-kD erythrocyte binding antigen of Plasmodium falciparum.

Plasmodium falciparum malaria merozoites invade human erythrocytes bearing sialic acid in a multistage process involving the sialic acid-dependent binding of a malaria molecule, the 175-kD erythrocyte binding antigen (EBA-175). We show here that after the initial interaction of EBA-175 with its sialic acid-containing erythrocyte determinant, endogenous proteases can cleave EBA-175 to 65-kD fragment(s), whose binding to erythrocytes is sialic acid independent. A 65-kD fragment was immunoprecipitated by antibodies against peptides between residues 354 and 1061 but not beyond residue 1062. Binding experiments utilizing combinations of native protein, expression-PCR-synthesized EBA-175 polypeptides, peptide synthesis, and antibodies, demonstrated that sialic acid-independent binding could be further mapped to a small (about 40-amino acid) homologous part of the dimorphic allelic region of EBA-175, residues 898-938 (Camp strain numbering). These data support a two-step binding hypothesis and are discussed in relation to the formation of a junction between the merozoite and the erythrocyte, and the finding that after the interaction of some viruses with specific cellular receptors, they undergo conformational changes or cleavage permitting membrane fusion with the host cell.

Determinants on surface proteins of Plasmodium knowlesi merozoites common to Plasmodium falciparum schizonts.

In this report and (R. Schmidt-Ullrich, L. H. Miller, and D. F. H. Wallach. Manuscript in preparation.), we have demonstrated that malaria proteins on the surface of merozoites and infected erythrocytes cross-react between at least two primate malarias, Plasmodium knowlesi and P. falciparum. Sera from five Gambian adults who were highly immune to P. falciparum were used as a reagent to study the cross-reactivity between P. falciparum schizonts and surface proteins on P. knowlesi merozoites. Although the sera bound to the surface of viable, intact P. knowlesi merozoites, the sera did not block invasion of rhesus erythrocytes. 125I-lactoperoxidase-labeled surface proteins on merozoites formed complexes with the antibody. All major protein bands seen in the electrophoresis of the original Triton extract were bound by the immune sera. Because Gambians have never been exposed to P. knowlesi malaria, the antibodies that reacted with P. knowlesi merozoites must be directed against antigens of another parasite such as P. falciparum. We tested this hypothesis by competition for antibody in a Gambian serum between Triton-extracted antigens from P. falciparum schizont-infected erythrocytes and from surface-labeled P. knowlesi merozoites. P. falciparum inhibited the reaction, thus indicating cross-reaction between antigens in P. falciparum schizonts and P. knowlesi merozoites.

Receptor-like specificity of a Plasmodium knowlesi malarial protein that binds to Duffy antigen ligands on erythrocytes.

A 135-kD parasite protein, a minor component of the Plasmodium knowlesi malaria radiolabeled proteins released into culture supernatant at the time of merozoite release and reinvasion, specifically bound to human erythrocytes that are invaded and carry a Duffy blood group determinant (Fya or Fyb), but did not bind to human erythrocytes that are not invaded and do not carry a Duffy determinant (FyFy). Specific anti-Duffy antibodies blocked the binding of the 135-kD protein to erythrocytes carrying that specific Duffy determinant. Purified 135-kD protein bound specifically to the 35-45-kD Duffy glycoprotein on a blot of electrophoretically separated membrane proteins from Fya and Fyb erythrocytes but not from FyFy erythrocytes. Binding of the 135-kD protein was consistently greater to Fyb than to Fya both on the blot and on intact erythrocytes. The 135-kD protein also bound to rhesus erythrocytes that are Fyb and are invaded, but not to rabbit or guinea pig erythrocytes that are Duffy-negative and are not invaded. Cleavage of the Duffy determinant by pretreating Fyb human erythrocytes with chymotrypsin greatly reduced both invasion and binding of the 135-kD protein, whereas pretreating Fyb erythrocytes with trypsin had little effect on the Duffy antigen, the 135-kD protein binding, or on invasion. However, instances of invasion of other enzyme-treated erythrocytes that are Duffy-negative and do not bind the 135-kD protein suggest that alternative pathways for invasion do exist.

Evidence for differences in erythrocyte surface receptors for the malarial parasites, Plasmodium falciparum and Plasmodium knowlesi.

Human erythrocytes lacking various blood group determinants were susceptible to invasion by Plasmodium falciparum including Duffy-negative erythrocytes that are refractory to invasion by Plasmodium knowlesi. Erythrocytes treated with trypsin or neuraminidase had reduced susceptibility of P. falciparum and normal susceptibility to P. knowlesi. Chymotrypsin treatment (0.1 mg/ml) blocked invasion only by P. knowlesi. The differential effect of enzymatic cleavage of determinats from the erythrocyte surface on invasion by these parasites suggests that P. falciparum and P. knowlesi interact with different determinants on the erythrocyte surface.

A malaria invasion receptor, the 175-kilodalton erythrocyte binding antigen of Plasmodium falciparum recognizes the terminal Neu5Ac(alpha 2-3)Gal- sequences of glycophorin A.

Plasmodium falciparum malaria parasites invade human erythrocytes by means of a parasite receptor for erythrocytes, the 175-kD erythrocyte binding antigen (EBA-175). Similar to invasion efficiency, binding requires N-acetylneuraminic acid (Neu5Ac) on human erythrocytes, specifically the glycophorins. EBA-175 bound to erythrocytes with receptor-like specificity and was saturable. The specificity of EBA-175 binding was studied to determine if its binding is influenced either by simple electrostatic interaction with the negatively charged Neu5Ac (on the erythrocyte surface); or if Neu5Ac indirectly affected the conformation of an unknown ligand, or if Neu5Ac itself in specific linkage and carbohydrate composition was the primary ligand for EBA-175 as demonstrated for hemagglutinins of influenza viruses. Most Neu5Ac on human erythrocytes is linked to galactose by alpha 2-3 and alpha 2-6 linkages on glycophorin A. Soluble Neu5Ac by itself in solution did not competitively inhibit the binding of EBA-175 to erythrocytes, suggesting that linkage to an underlying sugar is required for binding in contrast to charge alone. Binding was competitively inhibited only by Neu5Ac(alpha 2-3)Gal-containing oligosaccharides. Similar oligosaccharides containing Neu5Ac(alpha 2-6)Gal-linkages had only slight inhibitory effects. Binding inhibition assays with modified sialic acids and other saccharides confirmed that oligosaccharide composition and linkage were primary factors for efficient binding. EBA-175 bound tightly enough to glycophorin A that the complex could be precipitated with an anti-glycophorin A monoclonal antibody. Selective cleavage of O-linked tetrasaccharides clustered at the NH2 terminus of glycophorin A markedly reduced binding in inhibition studies. We conclude that the Neu5Ac(a2,3)-Gal- determinant on O-linked tetrasaccharides of glycophorin A appear to be the preferential erythrocyte ligand for EBA-175.

Primary structure of the 175K Plasmodium falciparum erythrocyte binding antigen and identification of a peptide which elicits antibodies that inhibit malaria merozoite invasion.

The Plasmodium falciparum gene encoding erythrocyte binding antigen-175 (EBA-175), a putative receptor for red cell invasion (Camus, D., and T. J. Hadley. 1985. Science (Wash. DC). 230:553-556.), has been isolated and characterized. DNA sequencing demonstrated a single open reading frame encoding a translation product of 1,435 amino acid residues. Peptides corresponding to regions on the deduced amino acid sequence predicted to be B cell epitopes were assessed for immunogenicity. Immunization of mice and rabbits with EBA-peptide 4, a synthetic peptide encompassing amino acid residues 1,062-1,103, produced antibodies that recognized P. falciparum merozoites in an indirect fluorescent antibody assay. When compared to sera from rabbits immunized with the same adjuvant and carrier protein, sera from rabbits immunized with EBA-peptide 4 inhibited merozoite invasion of erythrocytes in vitro by 80% at a 1:5 dilution. Furthermore, these sera inhibited the binding of purified, authentic EBA-175 to erythrocytes, suggesting that their activity in inhibiting merozoite invasion of erythrocytes is mediated by blocking the binding of EBA-175 to erythrocytes. Since the nucleotide sequence of EBA-peptide 4 is conserved among seven strains of P. falciparum from throughout the world (Sim, B. K. L. 1990. Mol. Biochem. Parasitol. 41:293-296.), these data identify a region of the protein that should be a focus of vaccine development efforts.

Structure of the gene encoding the immunodominant surface antigen on the sporozoite of the human malaria parasite Plasmodium falciparum.

The gene for the circumsporozoite (CS) protein of Plasmodium falciparum has been cloned and its nucleotide sequence determined. The gene encodes a protein of 412 amino acids as deduced from the nucleotide sequence. The protein contains 41 tandem repeats of a tetrapeptide, 37 of which are Asn-Ala-Asn-Pro and four of which are Asn-Val-Asp-Pro. Monoclonal antibodies against the CS protein of Plasmodium falciparum were inhibited from binding to the protein by synthetic peptides of the repeat sequence. The CS protein of Plasmodium falciparum and the CS protein of a simian malaria parasite, Plasmodium knowlesi, have two regions of homology, one of which is present on either side of the repeat. One region contains 12 of 13 identical amino acids. Within the nucleotide sequence of this region, 25 of 27 nucleotides are conserved. The conservation of these regions in parasites widely separated in evolution suggests that they may have a function such as binding to liver cells and may represent an invariant target for immunity.

Personalized risk prediction of postoperative cognitive impairment - rationale for the EU-funded BioCog project.

Postoperative cognitive impairment is among the most common medical complications associated with surgical interventions - particularly in elderly patients. In our aging society, it is an urgent medical need to determine preoperative individual risk prediction to allow more accurate cost-benefit decisions prior to elective surgeries. So far, risk prediction is mainly based on clinical parameters. However, these parameters only give a rough estimate of the individual risk. At present, there are no molecular or neuroimaging biomarkers available to improve risk prediction and little is known about the etiology and pathophysiology of this clinical condition. In this short review, we summarize the current state of knowledge and briefly present the recently started BioCog project (Biomarker Development for Postoperative Cognitive Impairment in the Elderly), which is funded by the European Union. It is the goal of this research and development (R&D) project, which involves academic and industry partners throughout Europe, to deliver a multivariate algorithm based on clinical assessments as well as molecular and neuroimaging biomarkers to overcome the currently unsatisfying situation.

Falciparum malaria parasites invade erythrocytes that lack glycophorin A and B (MkMk). Strain differences indicate receptor heterogeneity and two pathways for invasion.

To determine the ligands on erythrocytes for invasion by Plasmodium falciparum, we tested invasion into MkMk erythrocytes that lack glycophorins A and B and enzyme-treated erythrocytes by parasites that differ in their requirement for erythrocyte sialic acid. The 7G8 strain invaded MkMk erythrocytes and neuraminidase-treated normal erythrocytes with greater than 50% the efficiency of normal erythrocytes. In contrast, the Camp strain invaded MkMk erythrocytes at 20% of control and neuraminidase-treated normal erythrocytes at only 1.8% of control. Invasion of MkMk erythrocytes by 7G8 parasites was unaffected by treatment with neuraminidase but was markedly reduced by treatment with trypsin. In contrast, invasion of MkMk cells by Camp parasites was markedly reduced by neuraminidase but was unaffected by trypsin. We conclude that the 7G8 and Camp strains differ in ligand requirements for invasion and that 7G8 requires a trypsin sensitive ligand distinct from glycophorins A and B.

Protein disulfide isomerase assisted protein folding in malaria parasites.

In eukaryotes, the formation of protein disulfide bonds among cysteine residues is mediated by protein disulfide isomerases and occurs in the highly oxidised environment of the endoplasmic reticulum. This process is poorly understood in malaria parasites. In this paper, we report the gene isolation, sequence and phylogenetic comparisons, protein structure and thioredoxin-domain analyses of nine protein disulfide isomerases-like molecules from five species of malaria parasites including Plasmodium falciparum and Plasmodium vivax (human), Plasmodium knowlesi (simian) and Plasmodium berghei and Plasmodium yoelii (murine). Four of the studied protein disulfide isomerases belong to P. falciparum malaria and have been named PfPDI-8, PfPDI-9, PfPDI-11 and PfPDI-14, based on their chromosomal location. Among these, PfPDI-8 bears the closest similarity to a prototype PDI molecule with two thioredoxin domains (containing CGHC active sites) and a C-terminal Endoplasmic reticulum retrieval signal, SEEL. PfPDI-8 is expressed during all stages of parasite life cycle and is highly conserved (82-96% identity at amino acid level) in the other four Plasmodium species studied. Detailed biochemical analysis of PfPDI-8 revealed that this molecule is a potent oxido-reductase enzyme that facilitated the disulfide-dependent conformational folding of EBA-175, a leading malaria vaccine candidate. These studies open the avenues to understand the process of protein folding and secretory pathway in malaria parasites that in turn might aid in the production of superior recombinant vaccines and provide novel drug targets.

Identification of Plasmodium knowlesi erythrocyte binding proteins.

Plasmodium knowlesi, a malaria of Old World monkeys, invades all Duffy blood group positive human erythrocytes and various New World monkey erythrocytes except Cebus apella. We had previously identified a 135 kDa parasite protein in supernatants of P. knowlesi cultures that bound to Duffy positive but not to Duffy negative human erythrocytes [Haynes et al., J. Exp. Med. 167, 1873-1881 (1988)]. We now use New World monkey erythrocytes as a reagent to identify P. knowlesi proteins in culture supernatants that will bind to all New World monkey erythrocytes susceptible to invasion but not to C. apella erythrocytes, which are refractory to invasion. The 135 kDa protein binds to all New World monkey erythrocytes, including C. appella. Another protein of 155 kDa binds to all New World monkey erythrocytes except C. apella. The 155 kDa protein binds to Old World monkey erythrocytes, the natural host of P. knowlesi; it does not bind to human Duffy positive erythrocytes. This and the previous study are the beginning of the identification of parasite proteins of P. knowlesi that bind to erythrocytes in a receptor specific manner.

Characterization of the 175-kilodalton erythrocyte binding antigen of Plasmodium falciparum.

EBA-175 is a soluble 175-kDa Plasmodium falciparum antigen that is released into culture supernatants during rupture of schizont-infected erythrocytes. EBA-175 binds to erythrocytes and binding is sialic acid-dependent. A clone expressing the gene encoding EBA-175 was obtained previously by screening a genomic DNA expression library with antibodies that had been affinity-purified from EBA-175. Antibodies were raised against a 43-amino-acid peptide (EBA-peptide 4) synthesized according to the deduced amino acid sequence. Antibodies to peptide 4 and affinity-purified antibodies specific for EBA-175 were used to characterize further EBA-175 giving the following results: (1) EBA-175 differs biochemically and immunologically from other reported malarial antigens; (2) the EBA-175s from six geographical isolates of P. falciparum are antigenically conserved; (3) EBA-175 is expressed during schizogony as a 190-kDa protein which is larger than the culture supernatant form of the antigen. The 190-kDa form of the protein is recovered from the cell pellet in schizont-infected erythrocytes and partitions to the soluble fraction when extracted with detergent; (4) release of soluble EBA-175 into the culture supernatant coincides with schizont rupture; (5) there was no observable change in pI (pI = 6.86) by isoelectric focusing between the cellular and supernatant species of the protein; and (6) release of EBA-175 into the culture supernatant is inhibited by the addition of chymostatin and leupeptin. The continued research into the role of EBA-175 during erythrocyte invasion may aid in vaccine development for malaria.

Selective stage-specific changes in the permeability to small hydrophilic solutes of human erythrocytes infected with Plasmodium falciparum.

The permeability characteristics of Plasmodium falciparum-infected human erythrocytes to various 3H-labelled solutes were measured during the maturation of the parasites in sorbitol-synchronised cultures. Using [14C]inulin as the extracellular marker, estimates were made of the influx kinetics of [3H]amino acids into trichloroacetic acid (TCA)-soluble pools within the erythrocyte and concomitant incorporation into TCA-precipitable material. These measurements provided values of the rates of protein synthesis by the parasite and the initial influx rates for the transport of precursor amino acids into the erythrocyte. For about 12-15 h after parasitisation, the influx of L-[3H]glutamine remained at a low level comparable to that in the uninfected cell (2-9 nmol g-1 cells min-1). As pigment appeared in the trophozoite, the initial rate of influx of L-glutamine increased to a value up to 100-fold higher than in the uninfected erythrocyte. The increase in permeability affected only the parasitised cells in a culture of partially infected erythrocytes, and was selective with respect to substrate since the influx kinetics for both [3H]isoleucine and [3H]arginine were not affected by parasitisation. The permeability changes occurred mainly over a 4-8 h period in the development of the young trophozoite, during which time [3H]glycine influx was enhanced by a factor of 3-10, with a comparable increase in the uptake of myo-[3H]inositol. L-[3H]glutamate, which did not penetrate significantly into uninfected erythrocytes, entered red cells infected with mature trophozoites at a rate which was much less than 1% of the parasite-induced-L-glutamine influx. At the stages when the permeability to L-glutamine was markedly enhanced, parasitised cells remained impermeable to [3H]sucrose. An analysis of the relative 3H activities in glutathione and free amino acid pools indicated that, if L-glutamine permeation did not increase during parasite maturation beyond the ring stage, or was blocked by a potential antimalarial compound, an insufficient supply of L-glutamine would be available for the increased rates of parasite protein synthesis and glutathione turnover within the red cell.

Characterization of gp195 processed products purified from Plasmodium falciparum culture supernates.

Schizonts of the malaria parasite Plasmodium falciparum synthesize a 195 kDa surface glycoprotein (gp195) that is processed into several smaller products including one of 83 kDa, which, in the case of the Camp strain, is sequentially processed into 73 and 67 kDa products. gp195 and its processing intermediates larger than 83 kDa were not precipitated from culture supernates, but the 83 and 73 kDa products were precipitated by three monoclonal antibodies (McAbs). The 83 and 73 kDa products were affinity purified from culture supernates by adsorbing to McAb 7B2 coupled to Affigel 10 and eluting either with 0.2 N acetic acid, pH 2.8, or with 3 M potassium isothiocyanate (KSCN). The epitope recognized by McAb 7B2 was denatured by acid elution but could be regenerated by treating with 8 M urea followed by dialysis. The implications of renaturing antigens to regenerate epitopes should be considered in studies on the purification, function and immunogenicity of malaria antigens.

Studies on the role of red blood cell glycoproteins as receptors for invasion by Plasmodium falciparum merozoites.

The mechanism of invasion of human red blood cells by Plasmodium falciparum merozoites has been studied by several indirect methods. Red blood cells of the S+s+U+ and S-s-U- blood group phenotypes were trypsin treated and their susceptibility to invasion measured. Trypsin-treated S+s+U+ cells lack the portion of glycophorin A which bears the MN blood group determinants but possess glycophorin B, whereas trypsin-treated S-s-U- cells lack both the glycophorin A MN determinants and the glycophorin B molecule. Since the treated S-s-U- cells showed an even greater loss in susceptibility to invasion that the treated S+s+U+ cells, we conclude that glycophorin B does have a role In merozoite recognition, although it appears less important than glycophorin A. Attempts to decrease invasion by pretreatment with glycosidases were unsuccessful, except for the previously reported effect of neuraminidase. N-acetyl-D-glucosamine decreases the appearance of ring-stage parasites after in vitro reinvasion of P. falciparum. However, the persistence of intact and lysed schizont-infected cells when N-acetyl-D-glucosamine was present, several hours after disappearance of these cells from control cultures, leads us to conclude that this sugar has a deleterious effect on terminal stages of parasite maturation. It is therefore not possible to conclude that N-acetyl-D-glucosamine inhibits merozoite attachment and reinvasion specifically by competition for the receptor.

Two alleles of the 175-kilodalton Plasmodium falciparum erythrocyte binding antigen.

EBA-175, erythrocyte binding antigen 175, is a 175-kDa antigen of Plasmodium falciparum which has been shown to be involved in the recognition of erythrocytes by merozoites and may be involved in the process of erythrocyte invasion. Invasion of erythrocytes by Camp strain merozoites is inhibited by pre-treatment of red blood cells by EBA-175 from the heterologous strain, FCR-3. The sequence of the Camp strain has been published and we report here the sequence of the FCR-3 strain. The sequences are nearly identical except for a 423-bp segment in the FCR-3 strain, F-segment, that is not found in the Camp strain and a 342-bp segment, C-segment, present in the Camp strain but not in the FCR-3 strain. The locations of these two segments are different in Camp and FCR-3 EBA-175 genes and there is little DNA or amino acid sequence homology between them. The essentially dimorphic alleles, F-segment and C-segment, are conserved in all isolates examined to date. Evidence of genetic cross-over between the FCR-3 and the Camp EBA-175 genes was not observed in the analysis of a limited number of wild isolates. The continued study of the biological relevance of these sequence divergences in EBA-175 may further elucidate the sequence of events resulting in merozoite invasion of erythrocytes.

Binding of Plasmodium falciparum 175-kilodalton erythrocyte binding antigen and invasion of murine erythrocytes requires N-acetylneuraminic acid but not its O-acetylated form.

Sialic acid on human erythrocytes is involved in invasion by the human malaria parasite, Plasmodium falciparum. Mouse erythrocytes were used as a reagent to explore the question of whether erythrocyte sialic acid functions as a nonspecific negative charge or whether the sialic acid is a necessary structural part of the receptor for merozoites. Human erythrocytes contain N-acetylneuraminic acid (Neu5Ac), whereas mouse erythrocytes, which are also invaded by P. falciparum merozoites, contain 9-O-acetyl-N-acetylneuraminic acid (Neu5,9Ac2) and N-glycoloylneuraminic acid (Neu5Gc), in addition to Neu5Ac. We compared the effects of sialidase and influenza C virus esterase treatments of mouse erythrocytes on invasion and the binding of a 175-kDa P. falciparum protein (EBA-175), a sialic acid-dependent malaria ligand implicated in the invasion process. Sialidase-treated mouse erythrocytes were refractory to invasion by P. falciparum merozoites and failed to bind EBA-175. Influenza C virus esterase, which converts Neu5,9Ac2 to Neu5Ac, increased both invasion efficiency and EBA-175 binding to mouse erythrocytes. Thus, the parasite and EBA-175 discriminate between Neu5Ac and Neu5,9Ac2, that is, the C-9 acetyl group interferes with EBA-175 binding and invasion by P. falciparum merozoites. This indicates that sialic acid is part of a receptor for invasion.

Localization of the major Plasmodium falciparum glycoprotein on the surface of mature intraerythrocytic trophozoites and schizonts.

The subcellular location of the major malarial glycoprotein in erythrocytes infected with schizonts of Plasmodium falciparum has been studied by two methods. In the first, glycoproteins were labelled with [3H]glucosamine or [3H]isoleucine during in vitro culture. Trypsin treatment of intact infected erythrocytes caused no major qualitative or quantitative changes in [3H]glucosamine labelled glycoproteins or [3H]isoleucine labelled proteins separated by sodium dodecylsulfate polyacrylamide gel electrophoresis. However, in the presence of Triton X-100 the labelled glycoproteins and proteins were completely cleaved by trypsin. In the second method, two monoclonal antibodies which specifically immunoprecipitate the major 195 kDa glycoprotein failed to react on indirect immunofluorescence with intact non-fixed schizont-infected erythrocytes, but reacted strongly with saponin released schizonts indicating specificity for the surface of mature intracellular parasites. Immunoelectronmicroscopy using ferritin-conjugated secondary antibody confirmed the location of the epitope(s) recognized by these monoclonals on the surface of intracellular parasites. Ferritin particles were not associated with knob-bearing erythrocyte membranes. The results indicate that only a small proportion or none of the 195 kDa glycoprotein is on the surface of the infected erythrocyte and that the largest proportion is expressed on the surface of mature intraerythrocytic parasites.